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20:17
Regulatory Mechanisms for
Specification and Patterning
of Plant Vascular Tissues
Ana Caño-Delgado,1,∗ Ji-Young Lee,2,3,∗
and Taku Demura4,5,∗
1
Molecular Genetics Department, Center for Research in Agricultural Genomics, Barcelona
08034, Spain; email: [email protected]
2
Boyce Thompson Institute for Plant Research, Ithaca, NY 14853; email: [email protected]
3
Department of Plant Biology, Cornell University, Ithaca, NY 14853
4
RIKEN Plant Science Center, Yokohama, Kanagawa 230-0045, Japan
5
Graduate School of Biological Sciences, Nara Institute of Science and Technology, Ikoma,
Nara 630-0136, Japan; email: [email protected]
Annu. Rev. Cell Dev. Biol. 2010. 26:605–37
Key Words
First published online as a Review in Advance on
June 29, 2010
vascular, procambium, xylem, phloem, auxin, brassinosteroids,
regulatory networks
The Annual Review of Cell and Developmental
Biology is online at cellbio.annualreviews.org
This article’s doi:
10.1146/annurev-cellbio-100109-104107
c 2010 by Annual Reviews.
Copyright All rights reserved
1081-0706/10/1110-0605$20.00
∗
These authors contributed equally to this work.
Abstract
Plant vascular tissues, the conduits of water, nutrients, and small
molecules, play important roles in plant growth and development. Vascular tissues have allowed plants to successfully adapt to various environmental conditions since they evolved 450 Mya. The majority of
plant biomass, an important source of renewable energy, comes from
the xylem of the vascular tissues. Efforts have been made to identify the
underlying mechanisms of cell specification and patterning of plant vascular tissues and their proliferation. The formation of the plant vascular
system is a complex process that integrates signaling and gene regulation at transcriptional and posttranscriptional levels. Recently, a wealth
of molecular genetic studies and the advent of cell biology and genomic
tools have enabled important progress toward understanding its underlying mechanisms. Here, we provide a comprehensive review of the cell
and developmental processes of plant vascular tissue and resources recently available for studying them that will enable the discovery of new
ways to develop sustainable energy using plant biomass.
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Contents
VASCULAR TISSUE
SPECIFICATION AND
PATTERNING . . . . . . . . . . . . . . . . .
Initiation of Vascular Tissues in
Developing Embryos . . . . . . . . . .
Postembryonic Development of
Vascular Tissues . . . . . . . . . . . . . .
Vascular Tissue Formation During
Plant Growth: Venation . . . . . . .
Vascular Tissue Formation During
Plant Growth: Secondary
Growth . . . . . . . . . . . . . . . . . . . . . . .
Vascular Cell Type Specification
and Gene Expression . . . . . . . . . .
HORMONAL REGULATION OF
VASCULAR TISSUE/CELL
SPECIFICATION . . . . . . . . . . . . . . .
The Roles of Auxin in Vascular
Cell Differentiation . . . . . . . . . . . .
Auxin Transport in Vascular
Patterning . . . . . . . . . . . . . . . . . . . .
Brassinosteroid Signaling During
Vascular Development . . . . . . . . .
Cytokinins During Vascular Cell
Differentiation . . . . . . . . . . . . . . . .
606
606
607
612
612
613
616
616
617
618
621
VASCULAR TISSUE
SPECIFICATION AND
PATTERNING
Plant vascular
system: a complex of
conducting tissues
composed of xylem,
phloem, and
procambium/cambium
Xylem: waterconducting tissue
composed of xylem
vessel elements (more
generally tracheary
elements), fibers, and
other metabolic cells
(called parenchymas)
606
Initiation of Vascular Tissues
in Developing Embryos
The prepatterning of the plant vascular system
in developing embryos provides an important stepping stone toward postembryonic
patterning and growth of vascular tissues
and their associated organs. Immediately
after fertilization, zygotes divide three times
in an isodiametric manner. After reaching
the octant stage, the cells in the lower tier
proliferate differentially from those in the
upper tier, generating elongated cells in the
lower middle part of the embryo (Berleth &
Caño-Delgado
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Lee
Demura
TRANSCRIPTIONAL
REGULATION OF VASCULAR
CELL SPECIFICATION . . . . . . . .
HD-ZIP III/KAN/microRNA
System Responsible for Early
Vascular Development . . . . . . . . .
Positive Regulators of Xylem Cell
Specification . . . . . . . . . . . . . . . . . .
Fine-Tuning of Gene Expression
During Xylem Cell
Specification . . . . . . . . . . . . . . . . . .
Regulators of Phloem Cell
Specification . . . . . . . . . . . . . . . . . .
TOWARD COMPREHENSIVE
REGULATORY NETWORKS
AND SIGNALING IN
VASCULAR TISSUE
SPECIFICATION AND
PATTERNING . . . . . . . . . . . . . . . . .
Cell Biology Resources: Vascular
Cell Type–Specific Markers . . . .
Theoretical Modeling for the
Study of Vascular Patterning . . .
Toolkits for the Understanding
of Vascular Cell Specification
and Differentiation . . . . . . . . . . . .
622
623
623
624
625
625
625
628
628
Jurgens 1993, Busse & Evert 1999a, Hardtke
& Berleth 1998). These elongated cells that
will become procambium cells further extend
in the apical direction toward the future
cotyledons of early heart-stage embryos and
create a single network of vascular precursors
(Figure 1). In some species, xylem and phloem
begin to differentiate from procambium in
mature embryos, but in many others vascular
tissue differentiation only starts after the seed
germinates (Esau 1965, Sundberg 1983).
Auxin regulates the initiation of procambial
cells in the lower tier of the octant stage of embryos. In the absence of auxin signaling mediated by MONOPTEROS (MP), an auxinresponsive factor, procambial cells in embryos
do not form properly (Berleth & Jurgens 1993,
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Zygote
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16-cell
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Early globular
Globular
Early heart
Figure 1
Establishment of the procambium during embryogenesis. At the globular stage, cells in the lower tier start
elongation, whereas those in the upper tier ( yellow) stay isodiametric. These elongated cells ( purple) become
procambium.
Hardtke & Berleth 1998), which subsequently
results in the failure of postembryonic growth
of vascular tissues.
Postembryonic Development
of Vascular Tissues
Although the vascular tissues are connected
throughout the postembryonic plant body,
their organization is distinctive in each organ.
In the root, vascular tissues form a cylindrical
structure that is consecutively surrounded
by the radial tissues, pericycle, endodermis,
cortex, and epidermis. Xylem develops in the
center of the vascular cylinder and branches
toward the pericycle. These xylem branches
alternate with phloem (Figure 2). The organization of xylem branches and phloem tends
to be unique to each species, suggesting that
these characteristics are genetically controlled.
A basic helix-loop-helix transcription factor
(TF), LONESOME HIGHWAY, is a potential regulator of this vascular patterning
(Ohashi-Ito & Bergmann 2007). Its knockout
mutant generates only one pole of xylem
and phloem (monoarch) instead of two poles
(diarch) in Arabidopsis thaliana roots.
Specification and differentiation of xylem
vessel types in the root are temporally and
spatially regulated (Table 1). Although the
precursors of xylem are established in the root
meristem, their differentiation does not start
until the stage when roots actively elongate
and develop hairs in the epidermis. Xylem
vessel precursors on the periphery of the xylem
axis differentiate earlier than those in the inner
layers and differentiate into protoxylem, xylem
vessels with spirally patterned secondary cell
www.annualreviews.org • Plant Vascular Patterning
Phloem: nutrientconducting tissue
composed of phloem
sieve cells and
companion cells;
protophloem and
metaphloem constitute
the primary phloem
Procambium: the
meristematic tissues
from which xylem and
phloem develop
TF: transcription
factor
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Auxin
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PIN1, SCF/VAN3, VAB
MP
ATHB-8
Adaxial
Leaf
Abaxial
Stem
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COV1, HCA,
PXY, HD-ZIP III,
ARBORKNOX1/2
Phloem mother cell
Cambium
Xylem mother cell
Hypocotyl
Cell growth
Secondary cell
wall formation
Cell death
CLE/PXY
APL
VND6
Root
VND7
?
?
High HD-ZIP III
miR165/166
Low HD-ZIP III
SHR/SCR
Pericycle
Phloem sieve cells
Phloem companion cells
Epidermis
Procambium/cambium
Endodermis
Quiescent center
Endodermis/cortex initial
Cortex
Metaxylem vessel
Protoxylem vessel
Figure 2
Vascular tissue patterning during postembryonic growth and development, and representative regulators.
Vascular tissues are connected as a single network in plants; however, their organization changes in different
parts of a plant body. (left) How vascular tissues are connected in a plant body. (right) More detailed
organizations of vascular tissues in leaf, stem, and root. Representative regulators or pathways in vascular
patterning are listed in red boxes. APL, ALTERED PHLOEM DEVELOPMENT; ATHB-8, class III
homeodomain transcription factor 8; CLE, CLAVATA3-like small protein ligands; COV1,
CONTINUOUS VASCULAR RING 1; HD-ZIP III, class III homeodomain-leucine zipper;
HCA, HIGH CAMBIAL ACTIVITY; miR, microRNA; MP, MONOPTEROS; PIN1, auxin efflux carrier;
PXY, PHLOEM INTERCALATED WITH XYLEM; SCF/VAN3, SCARFACE; SCR, SCARECROW;
SHR, SHORT ROOT; VAB, VAN3 binding protein; VND, VASCULAR-RELATED NAC-DOMAIN
PROTEIN.
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Table 1
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Genes involved in vascular tissue development
Gene name
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Gene family
Function
Reference
PHABULOSA (PHB)
HD-ZIP III TF
Regulate xylem cell type patterning in the
root; collateral vascular patterning in stems
and leaves
Emery et al. (2003),
Itoh et al. (2008),
Zhong & Ye (2004)
PHAVOLUTA (PHV )
HD-ZIP III TF
Regulate xylem cell type patterning in the
root; collateral vascular patterning in stems
and leaves
Emery et al. (2003),
Itoh et al. (2008),
Zhong & Ye (2004)
REVOLUTA (REV )
HD-ZIP III TF
Regulate xylem cell type patterning in the
root; collateral vascular patterning in stems
and leaves
Emery et al. (2003),
Itoh et al. (2008),
Zhong & Ye (2004)
ATHB-8
HD-ZIP III TF
Regulate xylem cell type patterning in the
root; collateral vascular patterning in stems
and leaves; leaf procambial cell growth in
response to auxin
Donner et al. (2009),
Emery et al. (2003),
Itoh et al. (2008),
Zhong & Ye (2004)
ATHB-15/CORONA (CNA)
HD-ZIP III TF
Regulate xylem cell type patterning in the
root; collateral vascular patterning in stems
and leaves
Emery et al. (2003),
Itoh et al. (2008),
Zhong & Ye (2004)
MONOPTEROS (MP)
ARF
Establishment of procambium during
embryo- and postembryogenesis
Berleth & Jurgens (1993),
Hardtke & Berleth
(1998)
LONESOME HIGHWAY
(LHW )
bHLH TF
Vascular patterning in the root; mutant
forms monoarch vasculature instead of
diarch in the Arabidopsis root
Ohashi-Ito & Bergmann
(2007)
SHORT ROOT (SHR)
GRAS TF
Regulate the xylem cell type patterning in
the root by activating miR165/166
Carlsbecker et al. (2010)
SCARECROW (SCR)
GRAS TF
Regulate the xylem cell type patterning in
the root by activating miR165/166
Carlsbecker et al. (2010)
ALTERED PHLOEM
DEVELOPMENT (APL)
Myb TF
Phloem formation in the root; the mutant
forms ectopic xylem in the phloem pole
Bonke et al. (2003)
CLE 41/44
CLAVATA3-like small
protein ligands
Inhibit vascular differentiation in the
procambium
Hirakawa et al. (2008),
Whitford et al. (2008)
PXY
CLAVATA1-like
LRR-receptor kinase
Inhibit vascular differentiation in the
procambium by binding to CLE 41/44;
spatial patterning of vascular tissues in
stems
Fisher & Turner (2007),
Hirakawa et al. (2008)
CONTINUOUS VASCULAR
RING 1 (COV1)
a membrane-localized
protein
Regulate the density of vascular bundles in
the stem
Parker et al. (2003)
SCARFACE (SFC)
ARF-GAP
Vein patterning by regulating the auxin
transport pathway
Deyholos et al. (2000),
Koizumi et al. (2005),
Sieburth et al. (2006)
CVP2
inositol polyphosphate
5 -phosphatase
Vein patterning by regulating the auxin
transport pathway
Carland & Nelson (2004),
Carland et al. (2002)
ARBORKNOX1 and 2
KNOX TF
Repress the differentiation of vascular tissues
Du et al. (2009)
VND 6
NAC TF
Promote metaxylem formation
Kubo et al. (2005)
VND 7
NAC TF
Promote protoxylem formation
Kubo et al. (2005)
BRI1
LRR-receptor kinase
Promote xylem differentiation and vascular
bundle number
Caño-Delgado et al.
(2004)
(Continued )
www.annualreviews.org • Plant Vascular Patterning
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Table 1
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(Continued )
Gene name
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Gene family
Function
Reference
BRL1
LRR-receptor kinase
Provascular-specific receptor that promotes
xylem formation in the shoot inflorescence
stem
Caño-Delgado et al.
(2004)
BRL3
LRR-receptor kinase
Phloem-specific receptor necessary to
maintain collateral patterning of vascular
bundles in the shoot inflorescence stem
Caño-Delgado et al.
(2004)
VH1/BRL2
LRR-receptor kinase
Provascular cell-specific receptor that affects
leaf vasculature
Clay & Nelson (2002)
VIT
VH1-interacting TPRcontaining protein
Participates in initial stages of vascular
strand formation
Ceserani et al. (2009)
VIK
VH1-interacting
kinase
Participates in late stages of vascular strand
formation
Ceserani et al. (2009)
WOODEN LEG (WOL)/
CRE1/AHK4
Histidine kinase (HK)
receptor protein
Cytokinin receptor necessary for early
procambial cell divisions in embryogenesis;
the wol mutant has increased numbers of
protoxylem cell files and loss of other cell
types in the root vasculature
Caño-Delgado et al.
(2000), Mähönen et al.
(2000), Scheres et al.
(1995)
ARABIDOPSIS HISTIDINE
PHOSPHOTRANSFER
PROTEIN 6 (AHP6)
Cytokinin signaling
inhibitor
Restricts the domain of cytokinin activity by
allowing protoxylem differentiation in a
spatially specific manner
Mähönen et al. (2006a)
PIN1
Auxin-efflux carrier
PIN1 is expressed in vascular tissues; a pin1
mutant impairs vein pattern formation,
producing ectopic differentiated veins in
leaves and additional vascular bundles in
shoots; pin1 phenotypes are similar to
NPA treatments
Galweiler et al. 1998,
Ibañes et al. 2009,
Mattsson et al. (1999,
2003), Wenzel et al.
(2008)
TF, transcription factor; LRR, leucine-rich repeat.
walls. By contrast, xylem vessel precursors in
the inner layers differentiate into metaxylem
with reticulate or annular secondary cell walls.
This xylem patterning in the Arabidopsis root
is regulated by both transcriptional and posttranscriptional regulations that are mediated
by GRAS (GAI, RGA, SCR) family TFs,
SHORT ROOT (SHR) and SCARECROW
(SCR), and five class III homeodomain-leucine
zipper (HD-ZIP III) TFs (Carlsbecker et al.
2010). SHR proteins, produced in the vascular
cylinder, move into the endodermis layer and
activate the expression of SCR (Helariutta et al.
2000, Levesque et al. 2006, Nakajima et al.
2001). These two TFs form complexes and
activate two genes encoding microRNA (miR)
165/166 in the endodermis layer. Subsequently,
miR 165/166 diffuses out of the endodermis and
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leads the degradation of mRNAs of HD-ZIP III
TFs in the periphery of the vascular cylinder.
In the absence of miR-mediated mRNA degradation, protoxylem in the xylem periphery is
replaced by metaxylem owing to a high level of
HD-ZIP III TFs throughout the xylem axis. In
addition to specifying metaxylem cell fate with
their high dosages, HD-ZIP III TFs drive the
de novo xylem formation. As multiple HD-ZIP
III TFs are knocked out, the metaxylem in
the center of the xylem axis is replaced by the
protoxylem. When all five HD-ZIP III TFs
are knocked out, xylem formation is no longer
detected in the root (Carlsbecker et al. 2010).
The development of phloem in the root
meristem starts with the asymmetric cell division of phloem initials, which forms phloem
sieve cells and companion cells. ALTERED
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PHLOEM DEVELOPMENT (APL), a myb
family TF, promotes the asymmetric cell division of a phloem initial in Arabidopsis roots
(Bonke et al. 2003). Interestingly, in apl mutants the phloem initial cell not only fails to
undergo asymmetric cell division but also turns
into ectopic xylem. When APL is ectopically
expressed, differentiation of xylem precursors is
suppressed. These observations suggest that, in
addition to promoting asymmetric cell division
for phloem formation, APL regulates signaling
processes that suppress xylem differentiation.
Xylems and phloems always develop in
parallel along the boundaries of procambium/
cambium, the vascular stem cells. Recent
studies suggest that the procambium/cambium
mediates the signaling that sets up the boundaries between xylem and phloem. This signaling
is regulated by CLAVATA3 (CLV3)-like small
protein ligands (CLEs) and their receptor-like
protein kinase. CLE 41/44 secreted from
the phloem bind to CLV1-like leucine rich
repeat (LRR) receptor-like kinase (RLK),
PXY (PHLOEM INTERCALATED WITH
XYLEM), which is specifically expressed in the
procambium/cambium (Fisher & Turner
2007). This interaction is important for
regulating cell division activity in the procambium/cambium and for balancing the
pluripotent procambial/cambial cells and
differentiating xylem and phloem (Etchells &
Turner 2010, Hirakawa et al. 2008, Whitford
et al. 2008). Ectopic expression studies of
CLE41 and PXY suggested that a higher
dosage of CLE41 than PXY promotes cell
division but inhibits xylem cell differentiation,
whereas equal dosages of CLE41 and PXY
balance cell division and xylem differentiation.
However, the cell proliferation activity of
CLE41 requires PXY; in a pxy mutant, cell
proliferation by ectopic CLE41 expression was
suppressed (Etchells & Turner 2010).
Unlike vascular tissues in the root, which
are organized in a cylindrical structure, those in
stems are arranged collaterally (Figure 2) or bicollaterally. For vascular tissues in the shoot to
connect to those in the root, the reorganization
of the xylem and phloem strands should happen
in the transition zone between the shoot and
the root. Anatomical characterization showed
that xylem and phloem strands in the root vascular cylinder bifurcate in the hypocotyl area
to reorganize in stems and leaves (Busse &
Evert 1999b). In stems and leaves with collateral vascular bundles, xylem is specified in the
adaxial (toward the meristem) and phloem in
the abaxial (away from the meristem) regions.
In stems and leaves with bicollateral vascular
bundles, phloem forms both inside and outside
the xylem.
Collateral vascular patterning is disrupted
when miR 165/166 fails to suppress HD-ZIP III
TFs (Emery et al. 2003, Itoh et al. 2008, Zhong
& Ye 2004). Dominant gain-of-function mutants of REVOLUTA (REV) in Arabidopsis and
ectopic expression of miR-resistant HD-ZIP III
TFs in rice result in the formation of amphivasal
vascular bundles (xylem surrounds phloem) in
stems and leaves. However, the loss of three
closely related HD-ZIP III TFs PHABULOSA
(PHB), PHAVOLUTA (PHV), and REV in Arabidopsis results in amphicribal vascular bundles
(phloem surrounds xylem).
Regulators of vascular patterning in stems
and leaves are also involved in the determination of the polarity of lateral organs (Husbands
et al. 2009). Mutations causing amphivasal
bundles result in leaves that are radialized
with adaxial surface features throughout.
Conversely, those causing amphicribal bundles
result in abaxialized leaves (Emery et al. 2003).
An answer to how gene regulatory programs
involved in vascular patterning are related to
the polarity of lateral organs could emerge
with a more thorough understanding of the
underlying molecular mechanisms in each
developmental process.
A genetic study showed that the regulation
of vascular bundle densities is also important for
the plant growth and development. The stems
of cov1 (continuous vascular ring) (Parker et al.
2003) and hca (high cambial activity) (Pineau
et al. 2005) mutants develop a higher density
of vascular bundles and promote more cambium development than do wild-type stems.
The COV1 gene encodes a membrane-localized
www.annualreviews.org • Plant Vascular Patterning
LRR: leucine-rich
repeat
RLK: receptor-like
kinase
Vascular bundle:
a discrete strand of
xylem and phloem
cells separated by
procambium
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protein whose molecular function is yet to be
discovered.
SAM: shoot apical
meristem
Vascular Tissue Formation During
Plant Growth: Venation
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PAT: polar auxin
transport
Secondary growth:
the radial growth of
stems and roots driven
by cell division from
the cambium; the
meristem that is
established
postembryonically
612
As plants grow apically, lateral organs continuously develop from the shoot apical meristem (SAM). As lateral organs emerge, vascular tissues grow toward organ primordia
and branch in apical and lateral directions to
form veins, the networks of vascular bundles.
Temporal and spatial organizations of veins
are diverse and unique to plant lineages, but,
in a broad sense, veins are reticulate in dicots and striate in monocots. The highly ordered vein growth patterns (Nelson & Dengler
1997) suggest the presence of positional information that spatially and temporally regulates
vein growth. Theoretical studies suggested that
the positional information that emerges from
the organ primordia canalizes into the subset
of cells of future veins. Experimental studies
on auxin distribution and signaling suggested
that auxin might be the positional information
(Sachs & Woolhouse 1981). The auxin efflux
carrier, PIN-FORMED1 (PIN1), visually supports this auxin canalization theory. Auxin induces PIN1 expression, and PIN1 proteins are
localized in the basal region of the cells from
which auxin flows. PIN1 is also expressed in
the cells that will become the vascular strand
(Galweiler et al. 1998). Its expression domains
were shown to acropetally expand through the
future veins as leaf primordia emerged and grew
(Scarpella et al. 2006). When the veins were
about to bifurcate, PIN1 localization in the bifurcating cell became bipolar. This further supports the hypothesis that auxin flow directs vascular tissue specification.
PIN proteins cycle between plasma membranes and endosomes via the activity of
an ADP ribosylation factor–guanyl nucleotide
exchange factor (ARF-GEF), GNOM (GN)
(Geldner et al. 2003). The importance of polar auxin transport (PAT) in vein growth and
patterning was further supported by the finding that mutations in components of auxin
Caño-Delgado
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transport resulted in abnormal vein patterning. One mutant, scarface (sfc) or van3, generates dense but fragmented vein islands on
leaves and cotyledons. This phenotype is caused
by the mutation of a gene encoding ADP ribosylation factor GTPase activating protein
(ARF-GAP) (Deyholos et al. 2000, Koizumi
et al. 2005, Sieburth et al. 2006), a modulator of ARF-GEF involved in vesicle trafficking. SFC/VAN3, localized in the transGolgi network, interacts with COTYLEDON
VASCULAR PATTERN 2 (CVP2), which encodes inositol polyphosphate 5 -phosphatases
(Carland & Nelson 2004). The phosphatidyl
inositol-4-phosphate generated by CVP2 acts
as a ligand of SFC/VAN3 and its interactor
VAB (VAN3 binding protein) and then modulates the ARF-GAP activity of SFC/VAN3
(Carland & Nelson 2009, Naramoto et al.
2009). In the absence of ARF-GEF activities,
PIN1 failed to localize properly in response to
polar auxin transport (Sieburth et al. 2006).
For cells through which auxin is canalized to be specified into vascular cell precursors, specific transcriptional regulation should
be initiated. A recent study suggests that one
of the earliest responsive transcriptional regulators of auxin is HD-ZIP III TF ATHB-8
(ARABIDOPSIS THALIANA HOMEOBOX
PROTEIN-8) (Donner et al. 2009). ATHB-8
is directly activated by MP. ATHB-8 subsequently directs the formation of preprocambial cells and further induces the expression of
PIN1, which was also shown to be auxin responsive (Scarpella et al. 2006).
Vascular Tissue Formation During
Plant Growth: Secondary Growth
Most vascular plants grow in both apical and
radial directions. The radial growth, or secondary growth, in stems and roots is promoted by the active proliferation of vascular
cells in the cambium. Although cell division activities in the cambium are most pronounced
in perennial tree species, they also occur in
herbaceous plants. The only exceptional case is
monocots. Unlike in other flowering plants
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and gymnosperms, in monocots the cambium
does not develop likely because of the loss of
cambium formation capabilities before their
divergence.
In the root, the cambium is derived from the
procambium and the pericycle on the xylem
axis (Baum et al. 2002, Sundberg 1983). In the
stem, the procambium in the vascular bundle
(called fascicular cambium) and cells between
the vascular bundles (interfascicular cambium)
together form the cambium (Esau 1977). Of
daughter cells generated in the cambium,
only those located farther from the cambium
differentiate into vascular cells; cells located
in the center of stems and roots differentiate
into xylem, and cells located in the periphery
of stems and roots differentiate into phloem
(Figure 2). This asymmetric cell division and
differentiation helps maintain the pluripotent
stem cell population in the cambium and
the polar organization of xylem and phloem.
Cambial activities heavily depend on temperature, light, and resource availability, and likely
integrate many internal and external signals.
Mutant screening in Arabidopsis identified
that cov1 (Parker et al. 2003) and hca (Pineau
et al. 2005) mutants that develop vascular bundles in a higher density also have higher cambium activities. Distinct from COV1 and HCA,
PXY seems to be involved in the spatial patterning of vascular tissues. Unlike in the wild
type, in a pxy mutant, phloem and xylem do not
differentiate in a polar manner, which results
in an unclear boundary between phloem and
xylem (Fisher & Turner 2007). As described
above, this gene, which encodes an LRR RLK
similar to CLV1, is also involved in the spatial patterning of xylem and phloem in the procambium of roots and stems, which suggests
overlapping regulatory programs in the stem
cells for primary and secondary vascular tissue
development.
Recent genome-wide gene expression profiling in the cambial zone of Arabidopsis and Populus has started to reveal more genes involved in
secondary growth (Schrader et al. 2004b, Zhao
et al. 2005). Expression profiling in the cambial
zone in Populus suggested that SAM and cam-
bium may share a partially overlapping molecular mechanism. In SAM, CLV and WUSCHEL
(WUS) form a feedback loop that balances an
undifferentiated stem cell population with cells
that will differentiate (Dodsworth 2009). Independently of the WUS-CLV pathway, SHOOT
MERISTEMLESS (STM) plays important roles
in maintaining stem cells in SAM (Long et al.
1996). Interestingly, the two genes most closely
related to CLV1 in Populus were found to
be induced in the xylem and phloem sides
of cambium, respectively. Furthermore, WUSlike genes and CLEs were also highly induced
in the cambial zone. A recent finding of expression and promotion of stem cell division of WUSCHEL-related HOMEOBOX 4
(WOX4) in the procambium/cambium of Arabidopsis and tomato further support the conserved mechanism of the WUS-CLV pathway
in the SAM and vascular stem cells ( Ji et al.
2010). Putative orthologous genes of STM and
its indirect downstream regulator BREVIPEDICELLUS (BP) in Populus, ARBORKNOX1 and
2, were also highly induced in the cambial zone
(Du et al. 2009, Groover et al. 2006). Functional analyses of ARBORKNOX1 and 2 suggested that these genes repress the differentiation of vascular tissues, by which they likely
maintain the stem cell population in the cambial zone.
Many perennial trees living in areas with
distinctive seasons undergo reprogramming of
meristem activities as the seasons change. Comparison of gene expression profiles in dormant and active cambium showed dramatic
changes in overall gene expression. In particular, many genes involved in meristem activities and cell cycle regulation were found to be
downregulated. By contrast, genes involved in
stress responses and dormancy were upregulated (Schrader et al. 2004a).
Vascular Cell Type Specification
and Gene Expression
Genetic screening in model species has identified several key regulators in the specification and patterning of vascular cell types.
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Transdifferentiation:
differentiation of
already differentiated
cells with distinct
functions into different
cell types
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FACS: fluorescenceactivated cell sorter
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However, approaches that rely only on forward
genetics to identify the connectivity among the
regulators and their downstream genes have
been difficult because visualizing vascular tissue phenotypes in stems and roots requires several histological procedures. In recent years,
genome sequencing of several vascular plants,
advancement in high-throughput technologies
for gene expression profiling, and development
of tools for targeted gene expression perturbation have dramatically shifted the direction
of research. Large-scale gene expression profiling using various perturbation approaches has
yielded information about genes that are expressed in vascular cell types and their dynamic
changes during vascular cell specification and
differentiation that has allowed for the identification of regulators involved in vascular tissue
development.
Gene expression dynamics in xylem are
particularly interesting because many changes
occur during its specification and differentiation. In Zinnia and Arabidopsis, leaf mesophyll
cells or subcultured suspension cells can be
induced to transdifferentiate into xylem cells
in the cell culture systems. Using this in vitro
culture system, global gene expression changes
during transdifferentiation were identified
(Demura et al. 2002, Kubo et al. 2005). These
global gene expression profiles revealed gene
sets that are induced in a specific stage of
transdifferentiation. Noticeably, seven NAC
(NO APICAL MERISTEM, ATAF1, ATAF2,
and CUC2) domain TFs were induced during
xylem differentiation in Arabidopsis and Zinnia;
these were therefore named VASCULARRELATED NAC-DOMAIN PROTEINs
(VNDs). Among them, ectopic expression
of VND6 in Arabidopsis triggered ectopic
metaxylem formation. By contrast, ectopic
VND7 resulted in ectopic protoxylem formation. However, their knockout mutant did not
show any phenotype, suggesting the presence
of genetic redundancy. These studies demonstrate that well-designed large-scale gene
expression experiments can successfully identify regulators that are unlikely to be revealed
otherwise.
Caño-Delgado
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Lee
Demura
During plant development, neighboring
cell types specify and differentiate together.
Therefore, it is important to understand how
gene expression for the specification and differentiation of cell types of interest is regulated
in the context of neighboring cell types and
the organs they inhabit. High-resolution transcriptome data at the cell type level can serve
as resources for addressing such questions and
those regarding further regulatory networks
(Lee et al. 2005). In Arabidopsis root, transcriptome profiling of all major cell types has been
completed using cell sorting–microarray technology (Birnbaum et al. 2003, 2005; Brady et al.
2007; Lee et al. 2006; Nawy et al. 2005), which
tags the cell type with fluorescent markers
(described in more detail below). Specifically,
roots expressing cell type–specific fluorescent
markers are digested with cell wall–digesting
enzymes to generate protoplasts. Fluorescent
protoplasts are isolated with a fluorescenceactivated cell sorter (FACS), and their RNA is
isolated, amplified, and labeled for hybridization to microarrays. Using this method, 19
cell type–specific expression datasets were
generated. These include two xylem datasets
(early xylem precursors, differentiating xylem)
and three phloem datasets (protophloem
sieve cells, phloem sieve cells and companion
cells, mature companion cells). A search for
cell type–enriched genes in these 19 datasets
showed the highest number of enriched genes
in xylem. Among them, genes enriched in
early xylem were found to be involved in
translation initiation and elongation, RNA
binding and processing, and mitosis. In differentiating xylem, genes involved in secondary
cell wall biosynthesis were most significantly
enriched (Brady et al. 2007). Based on the root
expression atlas, cell type–specific expression
of representative transcriptional regulators
was validated by generating transgenic lines
expressing green fluorescent protein (GFP)
under 5 upstream intergenic regions of transcriptional regulators (Table 2). Comparing
their expression patterns with root expression
data using an unbiased image analysis suggested
that the cell sorting–based root expression atlas
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Summary of vascular cell type markers available
Reporter
Marked cells
Description
Reference
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
by Universitat Autonoma de Barcelona on 12/09/13. For personal use only.
Provascular
pWOL-GFP
Stele
Root stele at the root meristem and starts to
fade from elongation zone
Mähönen et al. (2000),
Birnbaum et al. (2003)
pATHB-8-GUS
Provascular cells
Provascular cells in the root meristem and at
the hipocotyl, leaves, and stems
(see Figure 3)
Baima et al. (1995),
Scarpella et al.
(2004, 2006)
pATHB-15-GUS
Provascular cells
Provascular cells in the root and vascular
bundles of inflorescence stems
Ohashi-Ito & Fukuda
(2003), Fisher & Turner
(2007)
pPXY-GUS
Procambial cells
Provascular tissues in the inflorescence
vascular bundles
Fisher & Turner (2007),
Hirakawa et al. (2008)
pBRL1-GUS
Procambial, phloem,
and phloem-pericycle
cells
Spatial distribution in the provascular and
phloem cells at the stem vascular bundles
Caño-Delgado et al.
(2004)
pBRL3-GUS
Stele, procambial cells
differentiating into
xylem
Provascular cells from the elongation zone
of the root; provascular tissues in the
inflorescence stem
Caño-Delgado et al.
(2004)
A8 (pAT3G48100-GFP)
Procambial cells
GFP in the lateral root cap and stele
procambium of the root meristem
Lee et al. (2006)
pAHP6-GFP
Protoxylem and
adjacent pericycle
cells
Primary root
Mähönen et al. (2006a)
pVND6-YFPnls
Differentiating
metaxylem
Tracheary element differentiation expressed
in roots
Kubo et al. (2005)
pVND7-YFPnls
Differentiating
protoxylem
Tracheary element differentiation expressed
in roots
Kubo et al. (2005)
ProASL19:EGFP-GUS
Differentiating xylem
Primary root
Soyano et al. (2008)
ProASL20:EGFP-GUS
Differentiating xylem
Primary root
Soyano et al. (2008)
pXCP2:GUS
Xylem
Xylem cell death
Funk et al. (2002)
pACL5-GUS
Xylem
Xylem differentiation in root, hypocotyls,
and shoots
Muñiz et al. (2008)
S18 (pAT5G12870-GFP)
Maturing xylem cells
Starts from mid-elongation and stops
halfway; GFP switches from protoxylem to
metaxylem
Lee et al. (2006)
S4 (pAT3G25710-GFP)
Xylem
Very weak GFP from xylem precursors in
the root meristem
Lee et al. (2006)
J2501
Pericycle, protoxylem,
metaxylem, phloem
Characterized in the primary root
J1721
Protoxylem, collumela
Strong labeling in the primary root; also
associated expression in the QC and
columella cells (see Figure 3)
S22 (pAT4G28140-GFP)
Xylem
GFP in xylem from meristematic to early
maturation zones of the root
Lee et al. (2006)
S20 (pAT1G71930-GFP)
Xylem
GFP in the xylem of elongation and the
maturation zone of the root
Lee et al. (2006)
Xylem
pXYN3-YFPnls
(Continued )
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Table 2
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(Continued )
Reporter
Marked cells
Description
Reference
proAPL-GUS;
proAPL-GFP
Developing pSE and mSE and
CC: loss of GFP in mature
pSE is accompanied by strong
GFP in neighboring CC; GFP
reappears in immature mSE
From mid-meristematic zone to top. Strong
at the start, then fades, then become stronger
when root hair becomes mature length
Bonke et al. (2003)
S32 (pAT2G18380-GFP)
Phloem sieve cells
Root protophloem and metaphloem sieve
cells from the vascular initials to top
Lee et al. (2006)
SUC2
Companion cells
Companion cells starting from elongation;
GFP is stronger when root hair is obvious
(2 mm from tip)
Imlau et al. (1999)
pPP2–2 A-YFPnls
Phloem
Companion cells in the elongation zone of
the root (see Figure 3)
PD markers
Phloem
PD1 to PD6 report GUS expression in
distinct phloem domains at different
developmental stages
Bauby et al. (2007)
S29 (pAT2G37590-GFP)
Phloem precursor
GFP in the phloem precursors of the root
meristem
Lee et al. (2006)
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Phloem
GFP, green fluorescent protein; YFPnls, nuclear-localized yellow fluorescent protein; QC, quiescent center; GUS, β-glucuronidase.
well represents the in vivo expression patterns
of the genes (Lee et al. 2006, Mace et al. 2006).
Vascular development in monocots is
understudied in comparison with eudicots. Recently, the gene expression atlas for the major
tissues and organs of rice, including vascular
tissues, was generated using the laser capture
microdissection technique ( Jiao et al. 2009,
Nelson et al. 2006). Among the 1,126 rice
genes identified as orthologs of genes in
Arabidopsis, 112 were more than twofold
enriched in vascular tissue compared with
the cortex. Furthermore, 77 of the 112 were
also enriched under the same criteria using
Arabidopsis root expression data ( Jiao et al.
2009). This suggests significant conservation
of expression patterns in the vascular tissues of
evolutionarily divergent plants.
BR: brassinosteroid
TE: tracheary
element
HORMONAL REGULATION OF
VASCULAR TISSUE/CELL
SPECIFICATION
Plant hormones play essential roles in the control of vascular development. An increasing
616
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number of studies, mostly carried out in the
model systems Arabidopsis, Zinnia, and Populus, have shown that the plant hormones
auxin, brassinosteroid (BR), and cytokinin,
among others, play unique and interconnected
roles during distinct vascular development
events.
The Roles of Auxin in Vascular
Cell Differentiation
Indole-3-acetic acid (IAA, the predominant
auxin in higher plants) is essential for vascular tissue development. It promotes cambial
cell divisions (Schrader et al. 2004a, Ye 2002,
Ye & Varner 1994), induces the differentiation of xylem tracheary elements (TEs) (Aloni
1987; Fosket & Torrey 1969; Fukuda 1997,
2004; Fukuda & Komamine 1980; Sachs &
Woolhouse 1981; Yoshida et al. 2009), and contributes to the maintenance of vascular continuity along different plant organs (Berleth et al.
2000, Hardtke & Berleth 1998, Scarpella et al.
2006).
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A variety of approaches, including classical
physiology, genetics, and transcriptomics, have
contributed to substantially advancing our
understanding of the role of auxin signaling,
responsiveness, and transport in plant vascular
development. It is well established that IAA
application can define the sites of vascular cell
differentiation. Initial physiological studies into
sterile-cultured stem pith sections of tobacco
(Nicotiana tabacum) (Clutter 1960) and soybean
(Glycine max) callus (Fosket & Torrey 1969), as
well as later research using the mesophyll cell
culture system from Zinnia, demonstrated that
exogenous auxin application triggers xylem TE
differentiation (Fukuda & Komamine 1980).
Further supporting this idea, the application
of 1-N-naphthylphthalamic acid (NPA), the
inhibitor of PAT, prevents TE differentiation.
Molecular studies using Zinnia as a model
system identified several auxin signaling and
transport genes that participate in TE differentiation [homologs of Arabidopsis Aux/IAA,
auxin response factors (ARFs), and auxin influx
and efflux carriers] (Demura et al. 2002, Milioni
et al. 2001, Yoshida et al. 2009). However, the
precise mechanism by which increasing auxin
levels can trigger the differentiation of xylem
cells remains to be identified.
Studies of secondary growth in tree species
have shown that the highest levels of auxin are
found in the cambium of Pinus and Populus,
consistent with a role for auxin in maintaining
cambial cell identity (Uggla et al. 1996, 1998).
In Pinus, auxin concentrations determined by
fine gas chromatography–mass spectrometry
techniques were found to peak at the cambial
meristematic cells. The endogenous auxin levels measured in tree species confirmed mathematical predictions for a correlation between
changes in cambial cell polarity and auxin gradient distribution in those cells (Kramer et al.
2008). A transcriptional study from cambial
meristematic cells in poplar demonstrated that
increased auxin levels in those cells positively
correlate with the upregulation of cell cycle–
related genes (Schrader et al. 2004b).
Beyond the physiological and transcriptomics experiments, in-depth characterization
of Arabidopsis mutants has been fundamental
for understanding how auxin signaling mediates vascular development (see the section on
venation above). Genetic approaches permitted
the identification of YUCCA (Yucca1) family
members that encode a flavin monooxygenaselike enzyme involved in auxin biosynthesis in
Arabidopsis (Cheng et al. 2006, Zhao et al.
2001). Although Yucca gain-of-function mutants have an ∼50% increase in free auxin compared with wild-type plants, these plants do not
exhibit an increased number of shoot vascular
bundles compared with the wild type (Ibañes
et al. 2009). Conversely, double and triple lossof-function mutants yuc1yuc4 and yuc1yuc2yuc4
have simplified leaf venation patterns (Cheng
et al. 2006). Based on these findings, auxin distribution rather than auxin level was proposed
to drive vascular patterning, although a minimum threshold of local auxin levels may be required to initiate vascular strand formation.
NPA: 1-Nnaphthylphthalamic
acid
Auxin Transport
in Vascular Patterning
PAT is required for the formation of a continuous vascular strand. A series of physiological
experiments have demonstrated that local
application of IAA induces vascular strand
formation, and a new functional vein will
extend basally from locally applied IAA (Aloni
1987, Fukuda 2004, Sachs & Woolhouse 1981,
Sauer et al. 2006, Sieburth & Deyholos 2006,
Ye 2002). Auxin is synthesized in the shoot apex
and transported via a unique mechanism that
is central to axis formation and patterning in
plants (for recent reviews, see Petrasek & Friml
2009, Smith & Bayer 2009, Vanneste & Friml
2009). The directionality of this transcellular
transport depends on gradients of auxin influx
and efflux carriers that continuously cycle
between plasma membrane and intracellular
compartments (Kramer 2004, 2009). The polar
localization of auxin carriers in the plasma
membrane determines the directionality of the
flow. Thus, PAT generates auxin maxima and
gradients within tissues that are instrumental
in the regulation of various developmental
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processes, including vascular tissue formation
(Smith & Bayer 2009).
Recent studies have shown that auxin controls PIN1 protein localization, which is likely
to provide a positive feedback loop for the
formation of vascular strands (Scarpella et al.
2006), thus refining the original prediction of
the auxin flow canalization hypothesis (Sachs &
Woolhouse 1981). Auxin efflux carriers belong
to PIN family members of transmembrane proteins that are asymmetrically distributed at the
basal end of PAT-competent cells (for a recent
review see Petrasek & Friml 2009). An appropriate asymmetric localization of efflux carriers
is needed to elicit auxin maxima at the position
of vascular bundles in the shoot of Arabidopsis
(Galweiler et al. 1998, Ibañes et al. 2009). Auxin
transport inhibition by NPA treatment or pin1
mutations impairs vein pattern formation producing ectopic differentiated veins in leaves and
additional vascular bundles in shoots (Ibañes
et al. 2009; Mattsson et al. 1999, 2003; Wenzel
et al. 2008) (Figure 3). It has been shown that
NPA blocks PIN1 cycling (Geldner et al. 2001),
and the phenotypes of NPA-treated plants are
similar to those of pin1 mutants (Berleth et al.
2000; Mattsson et al. 1999, 2003; Okada et al.
1991; Sieburth & Deyholos 2006; Wenzel et al.
2008). Despite the evidence showing that auxin
influx carrier AUX1/LAX family members impact plant gravitropism (Bennett et al. 1996,
Marchant et al. 1999, Swarup et al. 2005), lateral root initiation (Swarup et al. 2001, 2008),
and phyllotaxy (Bainbridge et al. 2008, Bayer
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BL: brassinolide
et al. 2009), their effects in vascular patterning
if any, await to be studied.
Brassinosteroid Signaling During
Vascular Development
To date, most of the knowledge concerning the
role of steroid hormone BRs in vascular development has been contributed by physiological
studies in Zinnia and Arabidopsis.
Brassinosteroid studies in Zinnia. BRs act
at later stages to promote TE differentiation
in Zinnia xylogenic cell cultures (Fukuda 1997,
Yamamoto et al. 1997). In these cultures, the
levels of BR intermediates peak at the transition
from undifferentiated cells to TEs (Yamamoto
et al. 2001). Moreover, the BR synthesis inhibitors uniconazole and brassinazole prevent
xylem differentiation (Asami et al. 2000), which
can be restored by exogenous application
of BR. Notably, BR biosynthetic enzymes
ZeDWF4 and ZeCPD1 appear to be expressed
in differentiating procambial and xylem cells
(Yamamoto et al. 2007). It has been shown that
BRs regulate the differentiation from procambium to xylem through specific members of the
ZeHD-ZIP III family (Fukuda 2004, OhashiIto & Fukuda 2003, Ohashi-Ito et al. 2002).
The expression of ZeHB-12 is induced by exogenous brassinolide (BL) application, whereas
the inducible expression of the ZeHB-12 transcript in Arabidopsis was shown to promote the
−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−→
Figure 3
Modeling vascular patterning at the shoot inflorescence stem of Arabidopsis. (a) Primary vascular bundle (VB)
pattern scheme: procambium ( yellow), protoxylem (light blue), xylem and interfascicular fibers (IFs) (dark
blue), and phloem (orange). (b) Auxin maxima (blue), driven by polar transport ( gray arrows, plotted outside
cells for clarity), position VBs along the vascular ring of cells (black boxes). (c) Numerical simulation results for
auxin concentration ([Auxin]) in arbitrary units along a ring of NF = 210 final cells arising from an initial
pool of Ni = 120 progenitor cells; x and y stand for spatial coordinates (wild-type average diameter used).
(e, g) Simulation results for the auxin concentration along a ring of a few (e) and many ( g) cells, mimicking
brassinosteroid (BR)-loss- and gain-of-function mutants, respectively. Parameter values as in (c) with
(e) Ni = 80, NF = 100 and ( g) Ni = 135, NF = 250 cells. These figures are from Ibañes et al. (2009) and
are reproduced with permission of the Proceedings of the National Academy of Sciences, USA. Vascular defects in
the VBs of BR mutants are shown by comparing a cross section at the base of the inflorescence of a wild-type
Col-0 plant (d ), a mutant with reduced BR signaling, bri1-116 ( f ), and a mutant with enhanced BR
signaling, bes1-D (h).
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a
b
[Auxin] (arb. units)
d
6
5
4
3
2
1
0
6
c
4
2
0
4
400
200
–400
–200
[Auxin] (arb. units)
x (μm)
6
5
4
3
2
1
0
0
200
0 y (μm)
–200
–400
400
500 μm
6
e
4
2
f
0
–400
–200
0
x (μm)
200
–400
400
–200
0
200
400
y (μm)
200 μm
h
[Auxin] (arb. units)
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Auxin
maxima
6
5
4
3
2
1
0
6
g
4
2
0
400
200
–400
–200
0
x (μm)
200
400
0 y (μm)
–200
–400
500 μm
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a
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b
BRI1-like members
20:17
BRL2/VH1
BL
OH
OH
C
ID
C
HO
C
O
At4g39400
At1g55610
At3g13380
HO
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
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O
c
ID
At4g39400
d
SERK3/BAK1-like
C
PXY/CLV1-like
CLE41/44
At5g61480
At1g08590
At4g28650
At1g71830
At4g30520
Figure 4
Leucine-rich repeat (LRR)-receptor proteins involved in vascular development.
To date only a few LRR receptor-like kinase proteins have been related to
plant vascular development. Interestingly, LRR-receptor signaling during
vascular development can be triggered by binding of protein (CLE41/44) and
nonprotein [brassinolide (BL)] ligands, which are perceived by the PXY
receptor and the BR-INSENSITIVE 1 (BRI1)-family of LRR-receptors,
respectively. (a,b) Schematic representation of BRI1 family members, BRI1,
BRL1, and BRL3 (encoded by At4g39400, At1g55610, and At3g13380,
respectively), which bind to BL via the extracellular LRR and the 70-amino
acid island domain (ID) (Caño-Delgado et al. 2004, Kinoshita et al. 2005). To
date, the ligand for provascular specific receptor BRL2/VH1 (At2g01950) is
not known. The SERK1 (SOMATIC EMBRYOGENESIS
RECEPTOR-LIKE KINASE 1) receptor (encoded by At1g71830) is expressed
in the root vasculature (Kwaaitaal & de Vries 2007), and a homolog of
SERK3/BAK1-like protein (encoded by At4g30520) is induced by ZeHD12 in
the vasculature (Ohashi-Ito et al. 2005). (c,d ) PXY (encoded by At5g61480) is
specifically involved in vascular bundle polarity (Fisher & Turner 2007), and
photoaffinity labeling experiments showed that CLE41/CLE44 peptides bind
to the PXY receptor (Hirakawa et al. 2008). Two closely related LRR-kinase
proteins (encoded by At1g08590 and At4g28650) named PXY-LIKE (PXL1
and PXL2, respectively) have been proposed to function redundantly with PXY
in vascular development.
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expression of BRL3 (BRASSINOSTEROID
RECEPTOR LIKE 3) and a BAK1/SERK3like (BRI1 ASSOCIATED RECEPTOR
KINASE 1/SOMATIC EMBRYOGENESIS
RECEPTOR KINASE 3) gene (At4g30520) in
the shoot vasculature (Ohashi-Ito et al. 2005;
Figure 4). On this basis, it has been proposed
that BRL3 together with BAK1/SERK3-like
receptors (At4g30520) may mediate xylemspecific BR signaling events downstream of
ZeHB-12, but the potential gene regulatory
loops connecting BR signaling to Class III
homeodomain family members are yet to be
characterized.
Brassinosteroid signaling during vascular
development in Arabidopsis. BRs have been
shown to play important roles in promoting
cell expansion and vascular development in several plant species (Vert & Chory 2006). Unlike their animal counterparts, BRs in plants
are perceived at the plasma membrane by direct binding with BRI1 (BR-INSENSITIVE
1) (Kinoshita et al. 2005, Wang et al. 2001),
a LRR-RLK protein that acts in concert with
BAK1/SERK3, a related LRR-RLK, to transduce BR signals into the cytoplasm (Li et al.
2002, Russinova et al. 2004). The downstream
signaling events of the BRI1 receptor are
among the best-characterized signaling pathways in plants. In addition to the BRI1 receptor, two BRI1-homolog proteins, BRL1 and the
BRL3 (BRASSINOSTEROID RECEPTOR
LIKE 1 and 3, respectively), have been identified as binding BRs with high affinity (CañoDelgado et al. 2004, Kinoshita et al. 2005).
These receptors are predominantly expressed
in provascular tissues. Based on the phenotypes of double- and triple-mutant combinations, BRI1 family members were proposed
to function redundantly in the elaboration of
xylem: phloem differentiation ratios at the vascular bundles of the shoot inflorescence stem.
In addition to BRI1, BRL1, and BRL3,
the LRR-receptor kinase protein VH1
(VASCULAR HIGHWAY 1)/BRL2 was
identified as expressed in the procambium and
required for normal phloem function (Clay
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& Nelson 2002). VH1/BRL2 belongs to the
BRI1-like family, each member of which is
characterized by the presence of a 70-amino
acid island domain (ID) that interrupts the
extracellular LRRs (Caño-Delgado et al. 2004,
Clay & Nelson 2002, Li & Chory 1997;
Figure 4). Although the ID is required for
BL binding (Kinoshita et al. 2005, Wang
et al. 2001), the VH1/BRL2 receptor was not
able to bind BL with high affinity; neither
did complementary bri1 mutant phenotypes
when expressed under the control of a BRI1
promoter. A recent search for VH1/BRL2
interactive proteins identified a tetratricopeptide repeat (TPR)-containing protein, VIT
(VH1-interacting TPR-containing protein),
and a MAP kinase kinase kinase, VIK (VH1interacting kinase), that function in initial
and later stages of vascular strand formation,
respectively (Ceserani et al. 2009). Together,
the characterization of these four BRI1-like
receptors offers an excellent example of
functional diversity in RLK subfamilies in Arabidopsis. Among the more than 200 annotated
LRR-RLK proteins in Arabidopsis, only the
signaling triggered by BL, a nonprotein ligand
that binds BRI1, BRL1, and BRL3 receptors
(Caño-Delgado et al. 2004, Clay & Nelson
2002, Kinoshita et al. 2005, Li & Chory 1997,
Wang et al. 2001), and the PXY-like family
of receptors that binds to CLE41/44 peptides,
have been reported to function in vascular
development (Hirakawa et al. 2008, Whitford
et al. 2008; Figure 4). Meanwhile, the nature
of the ligand triggering VH1/BRL2 response
in vascular development is yet to be discovered.
Initial evidence for a role for BRs in Arabidopsis vascular development comes from the
characterization of BR-deficient mutants cpd
and dwf7 (Choe et al. 2001, Szekeres et al. 1996)
and perception mutants (Caño-Delgado et al.
2004). A recent comprehensive analysis of BR
mutants has permitted researchers to consider a
role for BRs in promoting vascular bundle formation (Ibañes et al. 2009; Figure 3). Mutants
with reduced BRI1 receptor activity, signaling,
or levels (Li & Chory 1997, Szekeres et al.
1996) were found to have a reduced number of
vascular bundles and auxin maxima, whereas
mutants with increased BR signaling (Wang
et al. 2002, Yin et al. 2002) or levels (Choe et al.
2001) exhibited an increased number of vascular
bundles. This study proposes that BR signaling
promotes procambial cell division during the
elaboration of the vascular pattern. The roles
of BRs in cell proliferation have remained controversial to date (Clouse et al. 1996, Miyazawa
et al. 2003); future experiments to determine
whether BRs primarily control the meristematic function of procambial cells are needed.
Cytokinins During Vascular
Cell Differentiation
Physiological experiments in Zinnia xylogenic
cultures have shown that the hormone cytokinin in conjunction with auxin promotes
the differentiation of TEs (Aloni 1987, Fukuda
1997, Fukuda & Komamine 1980). Based on
the recent characterization of cytokinin signaling components in poplar stems, cytokinins
have been shown to contribute to the maintenance and proliferation of cambial cells in
tree species (Matsumoto-Kitano et al. 2008,
Nieminen et al. 2008). Transgenic trees expressing a cytokinin catabolic gene from Arabidopsis (CYTOKININ OXIDASE 2) exhibit
reduced cambial activity that correlates with a
reduction in radial plant growth, indicating that
cytokinin promotes cambial cell divisions.
In Arabidopsis, elegant genetic studies have
shown the importance of cytokinin in several
aspects of vascular development, including
proliferation, patterning, and differentiation of
distinct vascular cells types (reviewed in Elo
et al. 2009, Mähönen et al. 2006b). The wooden
leg (wol ) mutant allele exhibits an increased
number of protoxylem cell files and loss of
other cell types in the root vasculature (CañoDelgado et al. 2000, Mähönen et al. 2000,
Scheres et al. 1995). The wol mutant has a point
mutation (T278I) in the WOL/CRE1/AHK4
histidine-kinase (HK) receptor protein that
binds to cytokinin, which is necessary for early
procambial cell divisions in embryogenesis
(Mähönen et al. 2000). Cytokinin response
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occurs via a two-component signaling process
in which the HK receptor transfers a phosphate
to downstream response regulators (Hwang &
Sheen 2001). Triple-knockout mutants for all
three genes encoding CRE-family receptors,
ahk2, ahk3, and wol/cre1/ahk4, as well as mutations in type-B response regulators ARR1,
ARR10, and ARR12, exhibit similar vascular
defects to those of wol mutants (Mähönen et al.
2000, Yokoyama et al. 2007). Furthermore,
the vascular phenotypes of wol mutants are
phenocopied by plants with depleted levels of
cytokinins, such as transgenic lines expressing
a CYTOKININ OXIDASE (CKX) under the
control of a procambium-specific WOL/CRE1
promoter (Mähönen et al. 2000). Suppressor
mutagenesis of wol mutants led to the identification of ahp6 mutants able to overcome
the wol ability to form protoxylem (Mähönen
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et al. 2006a). ARABIDOPSIS HISTIDINE
PHOSPHOTRANSFER
PROTEIN
6
(AHP6) encodes a cytokinin signaling inhibitor that restricts the domain of cytokinin
activity to permit protoxylem differentiation
in a spatially specific manner. Collectively,
these studies have demonstrated that cytokinin
signaling has a key role in promoting and maintaining the identities of vascular cells other
than protoxylem in the Arabidopsis primary
root.
TRANSCRIPTIONAL
REGULATION OF VASCULAR
CELL SPECIFICATION
Recently, many transcriptional regulators responsible for vascular cell specification have
been identified (Figure 5).
Meristematic cells
MP
BDL
ATHB-8
Vascular cells
PHB, PHV, REV
Micro RNA165/166
KAN1, KAN2, KAN3
Xylem
Phloem
XND1
APL
ASL19/LBD30
ASL20/LBD18
EgMYB1
VND7
VND6
NST1, SND1/NST3
MYB20/42/43/52/54/58/63/69/85/103, SND2/3, KNAT7, EgMYB2
PXV
MXV
XF
SE
CC
Figure 5
Transcriptional network during vascular cell specification. PXV, protoxylem vessel; MXV, metaxylem vessel;
XF, xylary fiber; SE, sieve element; CC, companion cell. Arrows indicate activation; red inhibition lines
indicate repression.
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HD-ZIP III/KAN/microRNA
System Responsible for Early
Vascular Development
At the initiation of vascular development, an
auxin-responsive transcriptional activator, MP,
which belongs to a family of ARFs, regulates
the specification of procambial cells through
the direct activation of expression of ATHB-8,
encoding one of the HD-ZIP III TFs (Donner
et al. 2009). Although BODENLOS (BDL), an
auxin-inducible transcriptional regulator, interacts with MP to suppress MP function in the
absence of an auxin signal (Eshed et al. 2001),
in the presence of auxin, BDL releases MP to
activate the expression of downstream genes including ATHB-8, resulting in the initiation of
vascular cell specification.
In the shoot, xylem and phloem tissues are
specified from the procambial cells through a
fine regulation by two distinct classes of TFs:
HD-ZIP IIIs and KANADIs (KANs), the latter of which are GARP-type TFs, which are
closely associated with the determination of
adaxial-abaxial polarity during plant development (Emery et al. 2003). In Arabidopsis, the simultaneous loss-of-function mutations in three
HD-ZIP III genes, PHB, PHV, and REV, and
in three KAN genes, KAN1 to KAN3, result
in amphicribal (phloem surrounds xylem) and
amphivasal (xylem surrounds phloem) vascular
bundles, respectively (Emery et al. 2003), suggesting antagonistic functions for these HDZIP III and KAN genes in transcriptional regulation of xylem-phloem specification. It was also
suggested that two other HD-ZIP III genes in
Arabidopsis, ATHB-8 and ATHB-15/CORONA
(CNA), function, at least in part, antagonistically to REV on the basis of an analysis of the
rev athb-8 athb-15/cna triple mutant in which
the defect in interfascicular fiber development
in one of the rev mutant alleles (rev-6) was partially suppressed (Prigge et al. 2005).
Because microRNA 165/166 specifically
targets to the predicted sterol/lipid-binding
START domains of HD-ZIP III mRNAs and
then degrades the mRNAs, ectopic expression
of microRNA 165/166 results in a significant
reduction in the expression of these HD-ZIP
III genes (Kim et al. 2005, Zhong & Ye 2007).
Mutations in the microRNA-target sequences
of HD-ZIP III genes without any alteration of
the amino acid sequences, however, increases
the stability of their transcripts that are accompanied by amphivasal vascular bundles (Emery
et al. 2003, Juarez et al. 2004, McConnell
et al. 2001, McHale & Koning 2004, Zhong
& Ye 2004). Moreover, KAN genes might
regulate HD-ZIP III expression negatively via
microRNA 165/166 accumulation (Engstrom
et al. 2004).
In Zinnia cell cultures, the expression of
the Zinnia homologs of Arabidopsis HD-ZIP III
genes is enhanced during transdifferentiation
of mesophyll cells into xylem TEs and is repressed by the application of BR biosynthesis
inhibitors (Ohashi-Ito et al. 2002, Ohashi-Ito
& Fukuda 2003). These data suggest that the
HD-ZIP III/KAN/microRNA system orchestrates the transcriptional regulation of vascular
tissue specification in response to auxin and BR
signaling.
Positive Regulators of Xylem Cell
Specification
Several TFs, including members of the LIM,
MYB, and NAC families, have been identified as regulators of xylem cell development.
NtLIM1, a member of the LIM TF family with
a zinc-finger motif, specifically binds to the
promoter sequence of lignin biosynthetic genes
expressed in xylem and transiently activates
transcription of the lignin biosynthetic genes in
tobacco protoplasts (Kawaoka et al. 2000). Eucalyptus EgMYB2, a member of the R2R3-MYB
TF family, binds to promoters of xylem-specific
EgCCR and EgCAD2, which encode terminal
enzymes of lignin biosynthesis; cinnamoylCoA reductase (CCR); and cinnamyl alcohol
dehydrogenase (CAD); it also regulates
the transcription of EgCCR and EgCAD2
(Goicoechea et al. 2005). The secondary cell
walls of xylem fibers in tobacco plants overexpressing EgMYB2 are dramatically thickened
with altered lignin profiles, suggesting that
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EgMYB2 is a positive regulator of xylem cell
development (Goicoechea et al. 2005).
The NAC-domain TFs, VND1 to VND7,
are expressed in the Arabidopsis in vitro xylem
vessel inducible system in which subcultured
suspension cells differentiate into xylem vessel
elements at a high frequency in the presence
of BL (Kubo et al. 2005). Of these, VND6 and
VND7 have striking roles in regulating vessel
cell specification in cooperation with other
VND genes. The ectopic expression of VND6
and VND7 genes in Arabidopsis and poplar
causes transdifferentiation of diverse cells such
as epidermal cells, mesophyll cells, and guard
cells into two different types of vessel cells
similar to metaxylem vessels (VND6: with
reticulate and pitted secondary cell walls) and
protoxylem vessels (VND7: with annular and
spiral secondary cell walls). Furthermore, a
dominant repression of VND6 or VND7 by fusion with an artificial repressor domain (SRDX)
inhibits vessel formation in the metaxylem
or protoxylem of roots, respectively, and the
expression of the C terminus–truncated VND7
protein under the control of the native VND7
promoter causes a strong inhibitory effect on
the formation of all vessel types, as VND7
forms heterodimers with other VND proteins
(Kubo et al. 2005, Yamaguchi et al. 2008).
Two other Arabidopsis NAC-domain TFs,
NAC SECONDARY WALL THICKENING PROMOTING FACTOR1 (NST1) and
SECONDARY WALL ASSOCIATED NAC
DOMAIN PROTEIN1 (SND1)/NST3, are
expressed in xylary fibers and in interfascicular
fibers that develop between the vascular bundles of inflorescence stems and act redundantly
in the regulation of secondary cell wall thickening of these fibers (Ko et al. 2007; Mitsuda
et al. 2005, 2007; Zhong et al. 2006, 2007b).
Because VNDs, NST1, and SND1/NST3
phylogenetically belong to the same subfamily,
it is plausible that these proteins have similar
sets of downstream targets associated with the
transcriptional network regulating secondary
cell wall thickening. In fact, MYB46 and MYB83
are most homologous to EgMYB2, which has
been proposed to regulate the expression of
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lignin-related genes (Goicoechea et al. 2005),
are common direct targets of these NACs,
which redundantly function to turn on the entire secondary cell wall biosynthetic program
in vessels and fibers (McCarthy et al. 2009;
N. Nishikubo, Y. Nakano, and T. Demura,
unpublished results). Moreover, several other
TFs, including two NACs (SND2 and SND3),
10 MYBs (MYB20, 42, 43, 52, 54, 58, 63, 69, 85,
and 103), and a Knotted-like homeobox protein
(KNAT7), comprise the transcriptional network for secondary cell wall thickening (Zhong
et al. 2007a, Zhong et al. 2007b, Zhou et al.
2009).
Fine-Tuning of Gene Expression
During Xylem Cell Specification
Several other TFs play essential roles in finetuning gene expression programs that control xylem cell specification (Soyano et al.
2008). Two immature vessel-specific members of the Arabidopsis AS2/LDB family, AS2LIKE19 (ASL19)/LBD30 and ASL20/LBD18,
function in a positive feedback loop system to
maintain and promote the expression of VND7
required for vessel cell specification. Overexpression of ASL19/LBD30 and ASL20/LBD18
induces ectopic TE differentiation with ectopic
expression of VND7. By contrast, expression of
ASL20/LBD18 fused with the artificial repressor domain, SRDX, under the control of its
native promoter results in formation of aberrant vessels, which suggests that these TFs regulate vessel cell specification positively. Furthermore, overexpression of VND6 and VND7
enhances the expression of ASL19/LBD30 and
ASL20/LBD18, whereas dominant repression
of VND6 and VND7 remarkably downregulates the expression of ASL19/LBD30 and
ASL20/LBD18 (Soyano et al. 2008).
XYLEM NAC DOMAIN1 (XND1), which
is highly expressed in xylem (Zhao et al. 2005)
and during in vitro vessel differentiation in Arabidopsis subcultured cells (Kubo et al. 2005), is
a possible negative regulator of vessel cell specification (Zhao et al. 2008). Although XND1
knockout plants exhibit relatively normal
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phenotype, overexpression of XND1 results in
extreme dwarfism that is probably caused by
the absence of vessel cells accompanied by little
or no expression of two xylem-marker genes,
XCP2 and XSP1 (Funk et al. 2002; Zhao et al.
2000, 2005).
EgMYB1, a member of R2R3 MYB family
preferentially expressed in the secondary xylem
of Eucalyptus trees, binds specifically to ciselement MBSIIG, contained in the promoter of
EgCCR, and represses the transcription of two
lignin biosynthetic genes, EgCCR and EgCAD2
(Legay et al. 2007). These results suggest
that EgMYB1 is a negative regulator of the
lignin biosynthetic pathway during xylem cell
development.
Regulators of Phloem
Cell Specification
In contrast to our extensive knowledge of regulation of cell specification in xylem, there is
a relative lack of information on regulation in
phloem. APL, a member of the MYB family
of TFs, is the only previously identified regulator of phloem cell specification (Bonke et al.
2003). APL is specifically expressed in immature phloem cells, and the apl mutant exhibits
a seedling-lethal phenotype with a defect in
phloem cell specification that results in the development of cells with characteristics of xylem
vessel cells at the phloem poles, which are normally composed of two types of phloem cells,
sieve elements and companion cells. Overexpression of APL in vascular cells prevents or delays xylem cell differentiation, suggesting that
APL functions as a negative regulator of xylem
cell specification in phloem positions, which
might be mediated via a CLE/PXY pathway
(see the section on Postembryonic Development of Vascular Tissues above).
TOWARD COMPREHENSIVE
REGULATORY NETWORKS
AND SIGNALING IN VASCULAR
TISSUE SPECIFICATION
AND PATTERNING
Genome-wide gene expression profiling
data in vascular tissues in Arabidopsis, rice,
Populus, and Zinnia have identified a plethora
of genes that might be involved in the regulation of patterning and the specification of
vascular tissues (Birnbaum et al. 2003, Brady
et al. 2007, Demura et al. 2002, Jiao et al. 2009,
Kubo et al. 2005, Schrader et al. 2004a). One of
the next challenges is to unravel the underlying
gene regulatory networks, which are also
intercalated with complex hormone signaling
processes during vascular tissue development.
To address these questions, we need more
visual and molecular tools in both current
model species and more diverse plant species.
Resolving complex gene regulation and signaling also requires more systematic inference
of underlying mechanisms using mathematical
models. Here we summarize recently developed tools and modeling approaches in plant
vascular research.
Cell Biology Resources: Vascular Cell
Type–Specific Markers
The inner localization of the vascular tissues
and the lack of cell biology tools to trace
vascular differentiation in intact plants have
hampered the study of plant vascular development in the past. Initial genetic screenings
based on overall root anatomy and histological
staining of cell walls identified some key regulators of vascular patterning and differentiation
(Bonke et al. 2003, Mähönen et al. 2000) and
cell wall biosynthesis (Caño-Delgado et al.
2000, Turner & Somerville 1997). However,
the lack of tools for easy visualization of plant
vasculature has limited the identification of
mutants with primary and/or specific defects
in vascular development. The advent of GFPbased reporters has provided an important
breakthrough in the study of vascular dynamics
in intact plants (Figure 6). The identification
and characterization of vascular cell type–
specific markers allow for the study of vascular
ontogeny in vivo (Scarpella et al. 2004, 2006;
Wenzel et al. 2008) and serve as a basis for
noninvasive screens of mutants with defects
in vascular development (A.I. Caño-Delgado,
unpublished results) and for the study of
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b
c
d
pSUC2-GFP
pBRL1-YFPnls
e
f
g
h
i
pATHB-8-GUS
pATHB-8-GUS
J1721
pPP2-YFPnls
pPXY-GUS
j
k
l
S4
S32
S29
m
n
o
p
q
100 μm
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u
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S20
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gene expression profiles using vascular cell
type–based transcriptomics and proteomics
(Birnbaum et al. 2003, Brady et al. 2007, Galbraith & Birnbaum 2006, Mustroph et al. 2009).
The increasing number of vascular reporters
available facilitates the genetic and molecular
characterization of vascular patterning in Arabidopsis (summarized in Table 2). The initiation of leaf and root vascular primordia can
be observed following procambium formation
with the reporter expression of HD-ZIP III TF
ATHB-8 (Baima et al. 1995; Scarpella et al.
2004, 2006). In the Arabidopsis root, ATHB8 traces the expression of provascular, quiescent center and columella cells, whereas it
marks preprovascular patterning during leaf development (Figure 6). Similar reporters have
been shown to trace the expression of procambial cells at both root and shoot inflorescence stems, such as ATHB-8’s closest homolog ATHB-15 (Ohashi-Ito & Fukuda 2003).
The whole stele of the Arabidopsis primary root
can be traced using the pWOL:GFP marker
(Mähönen et al. 2000). Markers reflecting
xylem differentiation such as pACL5:GUS and
pXCP2:GUS specifically report xylem differen-
tiation in several plant organs (Funk et al. 2002,
Muñiz et al. 2008), whereas the expression of
YFPnls or GUS driven by pVND7 and
pVND6, respectively, in the root can efficiently
trace the earlier stages of differentiation of both
of protoxylem and metaxylem (VND7) and
of centrally located metaxylem (VND6) during primary vascular development (Kubo et al.
2005; Figure 6). Markers S4, S18, S20, and
S22 (Lee et al. 2006) tag root xylem vessels
at different developmental stages (Figure 6).
Phloem-associated tissues can be visualized in
vivo by following the reporter expression of
the proAPL:GUS/proAPL:GFP (Bonke et al.
2003, Mähönen et al. 2006a), pSUC2-GFP
(Imlau et al. 1999), and pBRL1-GUS/pBRL1YFP markers (Caño-Delgado et al. 2004;
A.I. Caño-Delgado, unpublished observations)
(Figure 6) as well as root markers S29 and S32
(Lee et al. 2006). Interestingly, phloem markers
such as pSUC2-GFP have proven to be valuable not only for the characterization of mutants with vascular anatomical defects but also
for the identification of mutants with impaired
intercellular transport functions in Arabidopsis
(Benitez-Alfonso et al. 2009).
←−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−
Figure 6
Expression of vascular reporters in different plant organs. pATHB-8:GUS expression (Baima et al. 1995) at
the shoot apex of the leaf primordial of (a) 4-day-old and (b) 6-day-old plants. (c) pSUC2-green fluorescent
protein (GFP) expression in the phloem cells of 6-day-old cotyledons (Imlau et al. 1999). The inset shows
the vein patterning revealed by pSUC2-GFP expression in the phloem of the leaf of a 12-day-old plant.
(d ) Detail of phloem expression in the vascular bundle of an inflorescence stem by a pBRL1-YFPnls marker
(A.I. Caño-Delgado, unpublished research). (e) pATHB-8-GUS expression in the provascular cells, quiescent
center (QC), and collumela cells at the primary root and ( f ) pATHB-8-GUS expression at the emergence of
a lateral root primordia. ( g, h) Confocal median sections of J1751 marker expression at root provascular,
QC, and collumela cells ( g); phloem marker pPP2-YFPnls expression in the differentiation zone of the root
(h) (A. Caño-Delgado, unpublished observations). (i ) Detail of provascular expression in the vascular bundle
of the inflorescence stem by pPXY-GUS marker (Fisher & Turner 2007). ( j, m) Longitudinal and radial
confocal sections of AT3G25710 (S4)::GFP. GFP is specific to the xylem precursors. (k, n) Longitudinal and
radial confocal sections of AT2G18380 (S32)::GFP. GFP is specific to the protophloem sieve cells.
(l, o) Longitudinal and radial confocal sections of AT2G37590 (S32)::GFP. GFP is specific to the phloem
precursors. ( p, q) pVND6-YFPnls ( p) and pVND7-YFPnls (q) expression in metaxylem and protoxylem
(Kubo et al. 2005). (r) Longitudinal confocal sections of phloem marker pSULT2-YFPnls. (s) Longitudinal
confocal sections of AT5G12870 (S18)::GFP. (t) AT1G71930 (S20)::GFP. GFP is specific to the
differentiating xylem vessels. (u, v) AT3G48100 (A8)::GFP. GFP is specific to the procambium of the root
meristem and the root cap (Lee et al. 2006). Propidium iodine (red ) was used as a counterstain. All root
images were taken from 6-day-old plants. Pictures of pATHB-8-GUS and pPXY-GUS reporters are
courtesy of G. Morelli and S. Turner. GFP, green fluorescent protein; GUS, β-glucuronidase; YFPnls,
nuclear-localized yellow fluorescent protein.
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In addition to the promoter fusion markers, the study of the transactivation system using the GAL4-based enhancer trap has elicited
numerous markers that exhibit vascular cell
type–specific expression patterns at high temporal and spatial resolution (Bauby et al. 2007,
Ckurshumova et al. 2009, Haseloff 1999,
Haseloff et al. 1997).
Theoretical Modeling for the Study
of Vascular Patterning
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Plant vascular patterning has attracted the attention of mathematicians for more than a century. Initially, the study of vascular patterning was merely theoretical and led researchers
to propose several mechanisms for the regulation of vein formation in leaves (Meinhardt
1982, Mitchison 1981, Rolland-Lagan &
Prusinkiewicz 2005), although experimental
demonstrations of the plausibility of some of
these mathematical simulations did not occur
until recently (Benkova et al. 2003, Reinhardt
et al. 2003).
Sachs originally proposed the canalization
hypothesis as a mechanism for differentiation
of vascular strands connecting auxin sources to
sinks (Sachs 1969). Based on this hypothesis,
the formation of plant vascular networks is currently understood as an auxin-transport-based
mechanism led by PIN1 protein accumulation
and polarization (Sauer et al. 2006, Scarpella
et al. 2006; for a recent review see Petrasek
& Friml 2009). In recent years, mathematical
predictions have also served to guide the genetic and cellular analysis of plant hormonal action in triggering organ initiation at the shoot,
root, and vascular meristems (de Reuille et al.
2006, Grieneisen et al. 2007, Ibañes et al. 2009,
Jonsson et al. 2006, Prusinkiewicz et al. 2009,
Smith et al. 2006). By modeling auxin distribution, these studies demonstrated the relevance
of PAT in creating the auxin maxima necessary for plant organogenesis. In relation to vascular patterning, work by Ibañes et al. (2009)
has shown that periodic auxin maxima controlled by polar transport and not by the overall auxin level underlie vascular bundle spacing
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(Figure 3). This innovative study provides evidence that PAT acts in connection with BR
signaling. BRs have been proposed to modulate the procambial cell number needed to set
the number of auxin maxima at the shoot vasculature (Ibañes et al. 2009).
Another recent modeling example (Bayer
et al. 2009) proposed a dual-polarization model
for both phyllotaxis and the formation of leaf
vascular strands and predicted transient apical polarization at the tip of the leaf midvein,
which was confirmed by subsequent experiments in Arabidopsis and tomato plants. Interestingly, this model provides a unified view of
phyllotaxis and vein initiation. Overall, these
studies demonstrate the importance of mathematical analysis and computational modeling
in advancing the understanding of diverse aspects of vascular development. Future studies
should aim to develop a unified model that explains the initiation of vascular primordia at the
shoot apex and its connection to various vascular organs in the plant. In years to come, the
joint work between physicists and biologists will
certainly disclose how the distinct factors controlling vascular morphogenesis integrate with
other developmental processes, such as the formation of lateral shoot organs, lateral roots,
and phyllotaxis, that contribute to overall plant
architecture.
Toolkits for the Understanding
of Vascular Cell Specification
and Differentiation
In vitro cell and tissue culture systems could
expand our knowledge of vascular cell development. Although no effective system has been
developed to study phloem cell differentiation,
several xylem cell differentiation systems offer
us a chance to analyze the molecular mechanisms (Turner et al. 2007). The Zinnia system,
in which mechanically isolated leaf mesophyll
cells can be hormonally induced to transdifferentiate into TEs, has been studied from various perspectives, including hormonal control,
cell-to-cell interaction, and global gene expression (Demura & Fukuda 2007, Fukuda 1997,
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Fukuda & Komamine 1980, Turner et al. 2007).
Although this system has proven to be valuable,
the lack of an efficient transformation protocol limits its utility. Recently, a method to introduce DNA/RNA efficiently into Zinnia cells
by electroporation-based transient transformation has been established (Endo et al. 2008). It
was successfully used to identify two novel proteins, TED6 and TED7, which can modulate
secondary cell wall formation of TEs, as potential components in the secondary cell wall
synthesis machinery (Endo et al. 2009). Arabidopsis subcultured suspension cells can also be
induced to form TEs in vitro in the presence
of BL; global gene expression and microtubule
dynamics have been described using this system (Kubo et al. 2005, Oda et al. 2005). The
suspension cell cultures of tobacco and the callus cultures of radiata pine, both of which produce xylogenic cells with thickened secondary
cell walls, also provide us with opportunities
to analyze xylem cell differentiation in nonmodel systems (Millar et al. 2009, Wagner et al.
2007).
Wood formation in tree species is an excellent model for understanding vascular development. Populus is accepted as a model tree
species for several reasons, including the completion of genome sequencing (Tuskan et al.
2006), many molecular tools, including microarrays and genetic maps, the ease of genetic
transformation, vegetative propagation, and genetic hybridization (Taylor 2002). Genome sequencing of Eucalyptus trees is also progressing
(E. grandis in the United States and E. camaldulensis in Japan), which will allow us to expand
our knowledge of wood formation. Expressed
sequence tags generated from wood-forming
tissues of other tree species increase our understanding of wood formation in combination
with microarray-based gene expression analysis
(Demura & Fukuda 2007). Because of difficulties in genetic transformation and the long lifetime of most tree species, it would be efficient to
use transient gene introduction systems such as
Agrobacterium-mediated introduction of transgenes into growing wood-producing tissue of
Eucalyptus (Spokevicius et al. 2005).
SUMMARY POINTS
1. Genetic screenings in Arabidopsis have identified several key regulators of vascular
patterning.
2. Auxin distribution primes vascular initiation and maintains vascular vein continuity in
the plant.
3. Brassinosteroids induce xylem differentiation in Zinnia cell cultures and contribute to
vascular bundle patterning at the inflorescence stem of Arabidopsis.
4. Cytokinins control vascular cell proliferation as well as the differentiation of provascular
cells into phloem and metaxylem.
5. A transcriptional network that controls vascular cell specification has been identified.
6. A systems biology approach that integrates novel molecular and cell biology tools, bioinformatics, and physics will further our understanding of vascular development and the
evolution of vascular plants.
FUTURE ISSUES
1. How are gene regulatory programs involved in vascular patterning related to those involved in the polarity of lateral organs?
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2. How does procambium/cambium contribute to the patterning and proliferation of vascular tissues?
3. What are the molecular mechanisms that drive the maturation of phloem, in particular
cell elongation, enucleation, and communication between sieve cells and companion
cells?
4. What is the hierarchy of hormonal action in the control of provascular cell specification,
division, and differentiation?
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
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5. How are molecular mechanisms revealed in model systems conserved in nonmodel
plants?
DISCLOSURE STATEMENT
The authors are not aware of any affiliations, memberships, funding, or financial holdings that
might be perceived as affecting the objectivity of this review.
ACKNOWLEDGMENTS
This work was supported by the Boyce Thompson Institute and a National Science Foundation
grant (IOS0818071) to J.Y.L., by a Grant-in-Aid for Scientific Research of Japan (Grant 21027031)
to T.D., and by the Spanish Ministry of Science and Innovation (BIO2008/00505/) and the EU
Marie Curie Initial Training Networks (ITN) FP7-PEOPLE-2007 to A.C.-D.
LITERATURE CITED
Aloni R. 1987. Differentiation of vascular tissues. Annu. Rev. Plant Physiol. 38:179–204
Asami T, Min YK, Nagata N, Yamagishi K, Takatsuto S, et al. 2000. Characterization of brassinazole, a
triazole-type brassinosteroid biosynthesis inhibitor. Plant Physiol. 123:93–100
Baima S, Nobili F, Sessa G, Lucchetti S, Ruberti I, Morelli G. 1995. The expression of the Athb-8 homeobox
gene is restricted to provascular cells in Arabidopsis thaliana. Development 121:4171–82
Bainbridge K, Guyomarc’h S, Bayer E, Swarup R, Bennett M, et al. 2008. Auxin influx carriers stabilize
phyllotactic patterning. Genes Dev. 22:810–23
Bauby H, Divol F, Truernit E, Grandjean O, Palauqui JC. 2007. Protophloem differentiation in early Arabidopsis thaliana development. Plant Cell Physiol. 48:97–109
Baum SF, Dubrovsky JG, Rost TL. 2002. Apical organization and maturation of the cortex and vascular
cylinder in Arabidopsis thaliana (Brassicaceae) roots. Am. J. Bot. 89:908–20
Bayer EM, Smith RS, Mandel T, Nakayama N, Sauer M, et al. 2009. Integration of transport-based models
for phyllotaxis and midvein formation. Genes Dev. 23:373–84
Benitez-Alfonso Y, Cilia M, San Roman A, Thomas C, Maule A, et al. 2009. Control of Arabidopsis meristem
development by thioredoxin-dependent regulation of intercellular transport. Proc. Natl. Acad. Sci. USA
106:3615–20
Benkova E, Michniewicz M, Sauer M, Teichmann T, Seifertova D, et al. 2003. Local, efflux-dependent auxin
gradients as a common module for plant organ formation. Cell 115:591–602
Bennett MJ, Marchant A, Green HG, May ST, Ward SP, et al. 1996. Arabidopsis AUX1 gene: a permease-like
regulator of root gravitropism. Science 273:948–50
Berleth T, Jurgens G. 1993. The role of the monopteros gene in organising the basal body region of the
Arabidopsis embryo. Development 118:575–87
Berleth T, Mattsson J, Hardtke CS. 2000. Vascular continuity and auxin signals. Trends Plant Sci. 5:387–93
630
Caño-Delgado
· ·
Lee
Demura
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
by Universitat Autonoma de Barcelona on 12/09/13. For personal use only.
CB26CH24-Cano-Delgado
ARI
3 September 2010
20:17
Birnbaum K, Jung JW, Wang JY, Lambert GM, Hirst JA, et al. 2005. Cell type-specific expression profiling
in plants via cell sorting of protoplasts from fluorescent reporter lines. Nat. Meth. 2:615–19
Birnbaum K, Shasha DE, Wang JY, Jung JW, Lambert GM, et al. 2003. A gene expression map of the
Arabidopsis root. Science 302:1956–60
Bonke M, Thitamadee S, Mähönen AP, Hauser M-T, Helariutta Y. 2003. APL regulates vascular tissue
identity in Arabidopsis. Nature 426:181–86
Brady SM, Orlando DA, Lee J-Y, Wang JY, Koch J, et al. 2007. A high-resolution root spatiotemporal map
reveals dominant expression patterns. Science 318:801–6
Busse JS, Evert RF. 1999a. Pattern of differentiation of the first vascular elements in the embryo and seedling
of Arabidopsis thaliana. Int. J. Plant Sci. 160:1–13
Busse JS, Evert RF. 1999b. Vascular differentiation and transition in the seedling of Arabidopsis thaliana
(Brassicaceae). Int. J. Plant Sci. 160:241–51
Caño-Delgado A, Yin Y, Yu C, Vafeados D, Mora-Garcia S, et al. 2004. BRL1 and BRL3 are novel brassinosteroid receptors that function in vascular differentiation in Arabidopsis. Development 131:5341–51
Caño-Delgado AI, Metzlaff K, Bevan MW. 2000. The eli1 mutation reveals a link between cell expansion and
secondary cell wall formation in Arabidopsis thaliana. Development 127:3395–405
Carland F, Nelson T. 2009. CVP2- and CVL1-mediated phosphoinositide signaling as a regulator of the ARF
GAP SFC/VAN3 in establishment of foliar vein patterns. Plant J. 59:895–907
Carland FM, Fujioka S, Takatsuto S, Yoshida S, Nelson T. 2002. The identification of CVP1 reveals a role
for sterols in vascular patterning. Plant Cell 14:2045–58
Carland FM, Nelson T. 2004. COTYLEDON VASCULAR PATTERN2–mediated inositol (1,4,5) triphosphate signal transduction is essential for closed venation patterns of Arabidopsis foliar organs. Plant Cell
16:1263–75
Carlsbecker A, Lee J-Y, Roberts CJ, Dettmer J, Lehesranta S, et al. 2010. Cell signalling by microRNA165/6
directs gene dose-dependent root cell fate. Nature 465:316–21
Ceserani T, Trofka A, Gandotra N, Nelson T. 2009. VH1/BRL2 receptor-like kinase interacts with vascularspecific adaptor proteins VIT and VIK to influence leaf venation. Plant J. 57:1000–14
Cheng Y, Dai X, Zhao Y. 2006. Auxin biosynthesis by the YUCCA flavin monooxygenases controls the
formation of floral organs and vascular tissues in Arabidopsis. Genes Dev. 20:1790–99
Choe S, Fujioka S, Noguchi T, Takatsuto S, Yoshida S, Feldmann KA. 2001. Overexpression of DWARF4
in the brassinosteroid biosynthetic pathway results in increased vegetative growth and seed yield in
Arabidopsis. Plant J. 26:573–82
Ckurshumova W, Koizumi K, Chatfield SP, Sanchez-Buelna SU, Gangaeva AE, et al. 2009. Tissue-specific
GAL4 expression patterns as a resource enabling targeted gene expression, cell type-specific transcript
profiling and gene function characterization in the Arabidopsis vascular system. Plant Cell Physiol. 50:141–
50
Clay NK, Nelson T. 2002. VH1, a provascular cell-specific receptor kinase that influences leaf cell patterns
in Arabidopsis. Plant Cell 14:2707–22
Clouse SD, Langford M, McMorris TC. 1996. A brassinosteroid-insensitive mutant in Arabidopsis thaliana
exhibits multiple defects in growth and development. Plant Physiol. 111:671–78
Clutter ME. 1960. Hormonal induction of vascular tissue in tobacco pith in vitro. Science 132:548–49
de Reuille PB, Bohn-Courseau I, Ljung K, Morin H, Carraro N, et al. 2006. Computer simulations reveal
properties of the cell-cell signaling network at the shoot apex in Arabidopsis. Proc. Natl. Acad. Sci. USA
103:1627–32
Demura T, Fukuda H. 2007. Transcriptional regulation in wood formation. Trends Plant Sci. 12:64–70
Demura T, Tashiro G, Horiguchi G, Kishimoto N, Kubo M, et al. 2002. Visualization by comprehensive
microarray analysis of gene expression programs during transdifferentiation of mesophyll cells into xylem
cells. Proc. Natl. Acad. Sci. 99:15794–99
Deyholos M, Cordner G, Beebe D, Sieburth L. 2000. The SCARFACE gene is required for cotyledon and
leaf vein patterning. Development 127:3205–13
Dodsworth S. 2009. A diverse and intricate signaling network regulates stem cell fate in the shoot apical
meristem. Dev. Biol. 336:1–9
www.annualreviews.org • Plant Vascular Patterning
631
ARI
3 September 2010
20:17
Donner TJ, Sherr I, Scarpella E. 2009. Regulation of preprocambial cell state acquisition by auxin signaling
in Arabidopsis leaves. Development 136:3235–46
Du J, Mansfield SD, Groover AT. 2009. The Populus homeobox gene ARBORKNOX2 regulates cell differentiation during secondary growth. Plant J. 60:1000–14
Elo A, Immanen J, Nieminen K, Helariutta Y. 2009. Stem cell function during plant vascular development.
Semin. Cell Dev. Biol. 20:1097–106
Emery JF, Floyd SK, Alvarez J, Eshed Y, Hawker NP, et al. 2003. Radial patterning of Arabidopsis shoots by
class III HD-ZIP and KANADI genes. Curr. Biol. 13:1768–74
Endo S, Pesquet E, Tashiro G, Kuriyama H, Goffner D, et al. 2008. Transient transformation and RNA
silencing in Zinnia tracheary element differentiating cell cultures. Plant J. 53:864–75
Endo S, Pesquet E, Yamaguchi M, Tashiro G, Sato M, et al. 2009. Identifying new components participating
in the secondary cell wall formation of vessel elements in Zinnia and Arabidopsis. Plant Cell 21:1155–65
Engstrom EM, Izhaki A, Bowman JL. 2004. Promoter bashing, microRNAs, and Knox genes. New insights,
regulators, and targets-of-regulation in the establishment of lateral organ polarity in Arabidopsis. Plant
Physiol. 135:685–94
Esau K. 1965. Vascular Differentiation in Plants. New York: Holt, Rinehart, and Winston, 160 pp.
Esau K. 1977. Anatomy of Seed Plants. New York: Wiley
Eshed Y, Baum SF, Perea JV, Bowman JL. 2001. Establishment of polarity in lateral organs of plants. Curr.
Biol. 11:1251–60
Etchells JP, Turner SR. 2010. The PXY-CLE41 receptor ligand pair defines a multifunctional pathway that
controls the rate and orientation of vascular cell division. Development 137:767–74
Fisher K, Turner S. 2007. PXY, a receptor-like kinase essential for maintaining polarity during plant vasculartissue development. Curr. Biol. 17:1061–66
Fosket DE, Torrey JG. 1969. Hormonal control of cell proliferation and xylem differentiation in cultured
tissues of Glycine max var. Biloxi. Plant Physiol. 44:871–80
Fukuda H. 1997. Tracheary element differentiation. Plant Cell 9:1147–56
Fukuda H. 2004. Signals that control plant vascular cell differentiation. Nat. Rev. Mol. Cell Biol. 5:379–91
Fukuda H, Komamine A. 1980. Establishment of an experimental system for the study of tracheary element
differentiation from single cells isolated from the mesophyll of Zinnia elegans. Plant Physiol. 65:57–60
Funk V, Kositsup B, Zhao C, Beers EP. 2002. The Arabidopsis xylem peptidase XCP1 is a tracheary element
vacuolar protein that may be a papain ortholog. Plant Physiol. 128:84–94
Galbraith DW, Birnbaum K. 2006. Global studies of cell type-specific gene expression in plants. Annu. Rev.
Plant Biol. 57:451–75
Galweiler L, Guan C, Muller A, Wisman E, Mendgen K, et al. 1998. Regulation of polar auxin transport by
AtPIN1 in Arabidopsis vascular tissue. Science 282:2226–30
Geldner N, Anders N, Wolters H, Keicher J, Kornberger W, et al. 2003. The Arabidopsis GNOM ARF-GEF
mediates endosomal recycling, auxin transport, and auxin-dependent plant growth. Cell 112:219–30
Geldner N, Friml J, Stierhof YD, Jurgens G, Palme K. 2001. Auxin transport inhibitors block PIN1 cycling
and vesicle trafficking. Nature 413:425–28
Goicoechea M, Lacombe E, Legay S, Mihaljevic S, Rech P, et al. 2005. EgMYB2, a new transcriptional
activator from Eucalyptus xylem, regulates secondary cell wall formation and lignin biosynthesis. Plant J.
43:553–67
Grieneisen VA, Xu J, Maree AF, Hogeweg P, Scheres B. 2007. Auxin transport is sufficient to generate a
maximum and gradient guiding root growth. Nature 449:1008–13
Groover A, Mansfield S, DiFazio S, Dupper G, Fontana J, et al. 2006. The Populus homeobox gene
ARBORKNOX1 reveals overlapping mechanisms regulating the shoot apical meristem and the vascular cambium. Plant Mol. Biol. 61:917–32
Hardtke CS, Berleth T. 1998. The Arabidopsis gene MONOPTEROS encodes a transcription factor mediating
embryo axis formation and vascular development. EMBO J. 17:1405–11
Haseloff J. 1999. GFP variants for multispectral imaging of living cells. Methods Cell Biol. 58:139–51
Haseloff J, Siemering KR, Prasher DC, Hodge S. 1997. Removal of a cryptic intron and subcellular localization
of green fluorescent protein are required to mark transgenic Arabidopsis plants brightly. Proc. Natl. Acad.
Sci. USA 94:2122–27
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
by Universitat Autonoma de Barcelona on 12/09/13. For personal use only.
CB26CH24-Cano-Delgado
632
Caño-Delgado
· ·
Lee
Demura
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
by Universitat Autonoma de Barcelona on 12/09/13. For personal use only.
CB26CH24-Cano-Delgado
ARI
3 September 2010
20:17
Helariutta Y, Fukaki H, Wysocka-Diller J, Nakajima K, Jung J, et al. 2000. The SHORT-ROOT gene
controls radial patterning of the Arabidopsis root through radial signaling. Cell 101:555–67
Hirakawa Y, Shinohara H, Kondo Y, Inoue A, Nakanomyo I, et al. 2008. Non-cell-autonomous control of
vascular stem cell fate by a CLE peptide/receptor system. Proc. Natl. Acad. Sci. USA 105:15208–13
Husbands AY, Chitwood DH, Plavskin Y, Timmermans MCP. 2009. Signals and prepatterns: new insights
into organ polarity in plants. Genes Dev. 23:1986–97
Hwang I, Sheen J. 2001. Two-component circuitry in Arabidopsis cytokinin signal transduction. Nature
413:383–89
Ibañes M, Fàbregas N, Chory J, Caño-Delgado AI. 2009. Brassinosteroid signaling and auxin transport are
required to establish the periodic pattern of Arabidopsis shoot vascular bundles. Proc. Natl. Acad. Sci. USA
106:13630–35
Imlau A, Truernit E, Sauer N. 1999. Cell-to-cell and long-distance trafficking of the green fluorescent protein
in the phloem and symplastic unloading of the protein into sink tissues. Plant Cell 11:309–22
Itoh J-I, Hibara K-I, Sato Y, Nagato Y. 2008. Developmental role and auxin responsiveness of class III
homeodomain leucine zipper gene family members in rice. Plant Physiol. 147:1960–75
Ji J, Strable J, Shimizu R, Koenig D, Sinha N, Scanlon MJ. 2010. WOX4 promotes procambial development.
Plant Physiol. 152:1346–56
Jiao Y, Tausta SL, Gandotra N, Sun N, Liu T, et al. 2009. A transcriptome atlas of rice cell types uncovers
cellular, functional and developmental hierarchies. Nat. Genet. 41:258–63
Jonsson H, Heisler MG, Shapiro BE, Meyerowitz EM, Mjolsness E. 2006. An auxin-driven polarized transport
model for phyllotaxis. Proc. Natl. Acad. Sci. USA 103:1633–38
Juarez MT, Kui JS, Thomas J, Heller BA, Timmermans MCP. 2004. microRNA-mediated repression of rolled
leaf1 specifies maize leaf polarity. Nature 428:84–88
Kawaoka A, Kaothien P, Yoshida K, Endo S, Yamada K, Ebinuma H. 2000. Functional analysis of tobacco
LIM protein Ntlim1 involved in lignin biosynthesis. Plant J. 22:289–301
Kim J, Jung JH, Reyes JL, Kim YS, Kim SY, et al. 2005. microRNA-directed cleavage of ATHB15 mRNA
regulates vascular development in Arabidopsis inflorescence stems. Plant J. 42:84–94
Kinoshita T, Caño-Delgado A, Seto H, Hiranuma S, Fujioka S, et al. 2005. Binding of brassinosteroids to the
extracellular domain of plant receptor kinase BRI1. Nature 433:167–71
Ko JH, Yang SH, Park AH, Lerouxel O, Han KH. 2007. ANAC012, a member of the plant-specific NAC
transcription factor family, negatively regulates xylary fiber development in Arabidopsis thaliana. Plant J.
50:1035–48
Koizumi K, Naramoto S, Sawa S, Yahara N, Ueda T, et al. 2005. VAN3 ARF-GAP-mediated vesicle transport
is involved in leaf vascular network formation. Development 132:1699–711
Kramer EM. 2004. PIN and AUX/LAX proteins: their role in auxin accumulation. Trends Plant Sci. 9:578–82
Kramer EM. 2009. Auxin-regulated cell polarity: an inside job? Trends Plant Sci. 14:242–47
Kramer EM, Lewandowski M, Beri S, Bernard J, Borkowski M, et al. 2008. Auxin gradients are associated
with polarity changes in trees. Science 320:1610
Kubo M, Udagawa M, Nishikubo N, Horiguchi G, Yamaguchi M, et al. 2005. Transcription switches for
protoxylem and metaxylem vessel formation. Genes Dev. 19:1855–60
Kwaaitaal MACJ, de Vries SC. 2007. The SERK1 gene is expressed in procambium and immature vascular
cells. J. Exp. Bot. 58:2887–96
Lee J-Y, Colinas J, Wang JY, Mace D, Ohler U, Benfey PN. 2006. Transcriptional and posttranscriptional
regulation of transcription factor expression in Arabidopsis roots. Proc. Natl. Acad. Sci. USA 103:6055–60
Lee J-Y, Levesque M, Benfey PN. 2005. High-throughput RNA isolation technologies. New tools for highresolution gene expression profiling in plant systems. Plant Physiol. 138:585–90
Legay S, Lacombe E, Goicoechea M, Brière C, Séguin A, et al. 2007. Molecular characterization of EgMYB1,
a putative transcriptional repressor of the lignin biosynthetic pathway. Plant Sci. 173:542–49
Levesque MP, Vernoux T, Busch W, Cui H, Wang JY, et al. 2006. Whole-genome analysis of the SHORTROOT developmental pathway in Arabidopsis. PLoS Biol. 4:e143
Li J, Chory J. 1997. A putative leucine-rich repeat receptor kinase involved in brassinosteroid signal transduction. Cell 90:929–38
www.annualreviews.org • Plant Vascular Patterning
633
ARI
3 September 2010
20:17
Li J, Wen J, Lease KA, Doke JT, Tax FE, Walker JC. 2002. BAK1, an Arabidopsis LRR receptor-like protein
kinase, interacts with BRI1 and modulates brassinosteroid signaling. Cell 110:213–22
Long J, Moan E, Medford J, Barton M. 1996. A member of the KNOTTED class of homeodomain proteins
encoded by the STM gene of Arabidopsis. Nature 379:66–69
Mace DL, Lee J-Y, Twigg RW, Colinas J, Benfey PN, Ohler U. 2006. Quantification of transcription factor
expression from Arabidopsis images. Bioinformatics 22:e323–31
Mähönen AP, Bishopp A, Higuchi M, Nieminen KM, Kinoshita K, et al. 2006a. Cytokinin signaling and its
inhibitor AHP6 regulate cell fate during vascular development. Science 311:94–98
Mähönen AP, Bonke M, Kauppinen L, Riikonen M, Benfey PN, Helariutta Y. 2000. A novel two-component
hybrid molecule regulates vascular morphogenesis of the Arabidopsis root. Genes Dev. 14:2938–43
Mähönen AP, Higuchi M, Tormakangas K, Miyawaki K, Pischke MS, et al. 2006b. Cytokinins regulate a
bidirectional phosphorelay network in Arabidopsis. Curr. Biol. 16:1116–22
Marchant A, Kargul J, May ST, Muller P, Delbarre A, et al. 1999. AUX1 regulates root gravitropism in
Arabidopsis by facilitating auxin uptake within root apical tissues. EMBO J. 18:2066–73
Matsumoto-Kitano M, Kusumoto T, Tarkowski P, Kinoshita-Tsujimura K, Václavı́ková K, et al. 2008. Cytokinins are central regulators of cambial activity. Proc. Natl. Acad. Sci. USA 105:20027–31
Mattsson J, Ckurshumova W, Berleth T. 2003. Auxin signaling in Arabidopsis leaf vascular development. Plant
Physiol. 131:1327–39
Mattsson J, Sung ZR, Berleth T. 1999. Responses of plant vascular systems to auxin transport inhibition.
Development 126:2979–91
McCarthy RL, Zhong R, Ye ZH. 2009. MYB83 is a direct target of SND1 and acts redundantly with MYB46
in the regulation of secondary cell wall biosynthesis in Arabidopsis. Plant Cell Physiol. 50:1950–64
McConnell JR, Emery J, Eshed Y, Bao N, Bowman J, Barton MK. 2001. Role of PHABULOSA and
PHAVOLUTA in determining radial patterning in shoots. Nature 411:709–13
McHale NA, Koning RE. 2004. MicroRNA-directed cleavage of Nicotiana sylvestris PHAVOLUTA mRNA
regulates the vascular cambium and structure of apical meristems. Plant Cell 16:1730–40
Meinhardt H. 1982. Models of Biological Pattern Formation. New York: Academic.
Milioni D, Sado PE, Stacey NJ, Domingo C, Roberts K, McCann MC. 2001. Differential expression of cellwall-related genes during the formation of tracheary elements in the Zinnia mesophyll cell system. Plant
Mol. Biol. 47:221–38
Millar DJ, Whitelegge JP, Bindschedler LV, Rayon C, Boudet AM, et al. 2009. The cell wall and secretory
proteome of a tobacco cell line synthesising secondary wall. Proteomics 9:2355–72
Mitchison GJ. 1981. The polar transport of auxin and vein pattern in plants. Philos. Trans. R. Soc. Lond. Ser. B
295:461–71
Mitsuda N, Iwase A, Yamamoto H, Yoshida M, Seki M, et al. 2007. NAC transcription factors, NST1 and
NST3, are key regulators of the formation of secondary walls in woody tissues of Arabidopsis. Plant Cell
19:270–80
Mitsuda N, Seki M, Shinozaki K, Ohme-Takagi M. 2005. The NAC transcription factors NST1 and NST2
of Arabidopsis regulate secondary wall thickenings and are required for anther dehiscence. Plant Cell
17:2993–3006
Miyazawa Y, Nakajima N, Abe T, Sakai A, Fujioka S, et al. 2003. Activation of cell proliferation by brassinolide
application in tobacco BY-2 cells: effects of brassinolide on cell multiplication, cell-cycle-related gene
expression, and organellar DNA contents. J. Exp. Bot. 54:2669–78
Mũniz L, Minguet EG, Singh SK, Pesquet E, Vera-Sirera F, et al. 2008. ACAULIS5 controls Arabidopsis
xylem specification through the prevention of premature cell death. Development 135:2573–82
Mustroph A, Zanetti ME, Jang CJ, Holtan HE, Repetti PP, et al. 2009. Profiling translatomes of discrete cell
populations resolves altered cellular priorities during hypoxia in Arabidopsis. Proc. Natl. Acad. Sci. USA
106:18843–48
Nakajima K, Sena G, Nawy T, Benfey PN. 2001. Intercellular movement of the putative transcription factor
SHR in root patterning. Nature 413:307–11
Naramoto S, Sawa S, Koizumi K, Uemura T, Ueda T, et al. 2009. Phosphoinositide-dependent regulation of
VAN3 ARF-GAP localization and activity essential for vascular tissue continuity in plants. Development
136:1529–38
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
by Universitat Autonoma de Barcelona on 12/09/13. For personal use only.
CB26CH24-Cano-Delgado
634
Caño-Delgado
· ·
Lee
Demura
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
by Universitat Autonoma de Barcelona on 12/09/13. For personal use only.
CB26CH24-Cano-Delgado
ARI
3 September 2010
20:17
Nawy T, Lee J-Y, Colinas J, Wang JY, Thongrod SC, et al. 2005. Transcriptional profile of the Arabidopsis
root quiescent center. Plant Cell 17:1908–25
Nelson T, Dengler N. 1997. Leaf vascular pattern formation. Plant Cell 9:1121–35
Nelson T, Tausta SL, Gandotra N, Liu T. 2006. Laser microdissection of plant tissue: what you see is what
you get. Annu. Rev. Plant Biol. 57:181–201
Nieminen K, Immanen J, Laxell M, Kauppinen L, Tarkowski P, et al. 2008. Cytokinin signaling regulates
cambial development in poplar. Proc. Natl. Acad. Sci. USA 105:20032–37
Oda Y, Mimura T, Hasezawa S. 2005. Regulation of secondary cell wall development by cortical microtubules
during tracheary element differentiation in Arabidopsis cell suspensions. Plant Physiol. 137:1027–36
Ohashi-Ito K, Bergmann DC. 2007. Regulation of the Arabidopsis root vascular initial population by Lonesome
Highway. Development 134:2959–68
Ohashi-Ito K, Demura T, Fukuda H. 2002. Promotion of transcript accumulation of novel Zinnia immature
xylem-specific HD-Zip III homeobox genes by brassinosteroids. Plant Cell Physiol. 43:1146–53
Ohashi-Ito K, Fukuda H. 2003. HD-Zip III homeobox genes that include a novel member, ZeHB-13
(Zinnia)/ATHB-15 (Arabidopsis), are involved in procambium and xylem cell differentiation. Plant Cell
Physiol. 44:1350–58
Ohashi-Ito K, Kubo M, Demura T, Fukuda H. 2005. Class III homeodomain leucine-zipper proteins regulate
xylem cell differentiation. Plant Cell Physiol. 46:1646–56
Okada K, Ueda J, Komaki MK, Bell CJ, Shimura Y. 1991. Requirement of the auxin polar transport system
in early stages of Arabidopsis floral bud formation. Plant Cell 3:677–84
Parker G, Schofield R, Sundberg B, Turner S. 2003. Isolation of COV1, a gene involved in the regulation of
vascular patterning in the stem of Arabidopsis. Development 130:2139–48
Petrasek J, Friml J. 2009. Auxin transport routes in plant development. Development 136:2675–88
Pineau C, Freydier A, Ranocha P, Jauneau A, Turner S, et al. 2005. hca: an Arabidopsis mutant exhibiting
unusual cambial activity and altered vascular patterning. Plant J. 44:271–89
Prigge MJ, Otsuga D, Alonso JM, Ecker JR, Drews GN, Clark SE. 2005. Class III homeodomain-leucine
zipper gene family members have overlapping, antagonistic, and distinct roles in Arabidopsis development.
Plant Cell 17:61–76
Prusinkiewicz P, Crawford S, Smith RS, Ljung K, Bennett T, et al. 2009. Control of bud activation by an
auxin transport switch. Proc. Natl. Acad. Sci. USA 106:17431–36
Reinhardt D, Pesce ER, Stieger P, Mandel T, Baltensperger K, et al. 2003. Regulation of phyllotaxis by polar
auxin transport. Nature 426:255–60
Rolland-Lagan AG, Prusinkiewicz P. 2005. Reviewing models of auxin canalization in the context of leaf vein
pattern formation in Arabidopsis. Plant J. 44:854–65
Russinova E, Borst JW, Kwaaitaal M, Caño-Delgado A, Yin Y, et al. 2004. Heterodimerization and endocytosis
of Arabidopsis brassinosteroid receptors BRI1 and AtSERK3 (BAK1). Plant Cell 16:3216–29
Sachs T. 1969. Polarity and induction of organized vascular tissues. Ann. Bot. 33:263–75
Sachs T, Woolhouse HW. 1981. The control of the patterned differentiation of vascular tissues. In Advances
in Botanical Research, ed. HW Woolhouse, pp. 151–262. London: Academic
Sauer M, Balla J, Luschnig C, Wisniewska J, Reinohl V, et al. 2006. Canalization of auxin flow by Aux/IAAARF-dependent feedback regulation of PIN polarity. Genes Dev. 20:2902–11
Scarpella E, Francis P, Berleth T. 2004. Stage-specific markers define early steps of procambium development in Arabidopsis leaves and correlate termination of vein formation with mesophyll differentiation.
Development 131:3445–55
Scarpella E, Marcos D, Friml J, Berleth T. 2006. Control of leaf vascular patterning by polar auxin transport.
Genes Dev. 20:1015–27
Scheres B, Di Laurenzio L, Willemsen V, Hauser MT, Janmaat K, et al. 1995. Mutations affecting the radial
organisation of the Arabidopsis root display specific defects throughout the embryonic axis. Development
121:53–62
Schrader J, Moyle R, Bhalerao R, Hertzberg M, Lundeberg J, et al. 2004a. Cambial meristem dormancy in
trees involves extensive remodelling of the transcriptome. Plant J. 40:173–87
www.annualreviews.org • Plant Vascular Patterning
635
ARI
3 September 2010
20:17
Schrader J, Nilsson J, Mellerowicz E, Berglund A, Nilsson P, et al. 2004b. A high-resolution transcript profile
across the wood-forming meristem of poplar identifies potential regulators of cambial stem cell identity.
Plant Cell 16:2278–92
Sieburth LE, Deyholos MK. 2006. Vascular development: the long and winding road. Curr. Opin. Plant Biol.
9:48–54
Sieburth LE, Muday GK, King EJ, Benton G, Kim S, et al. 2006. SCARFACE encodes an ARF-GAP that is
required for normal auxin efflux and vein patterning in Arabidopsis. Plant Cell 18:1396–411
Smith RS, Bayer EM. 2009. Auxin transport-feedback models of patterning in plants. Plant Cell Environ.
32:1258–71
Smith RS, Guyomarc’h S, Mandel T, Reinhardt D, Kuhlemeier C, Prusinkiewicz P. 2006. A plausible model
of phyllotaxis. Proc. Natl. Acad. Sci. USA 103:1301–6
Soyano T, Thitamadee S, Machida Y, Chua NH. 2008. ASYMMETRIC LEAVES2-LIKE19/LATERAL
ORGAN BOUNDARIES DOMAIN30 and ASL20/LBD18 regulate tracheary element differentiation in
Arabidopsis. Plant Cell 20:3359–73
Spokevicius AV, Van Beveren K, Leitch MA, Bossinger G. 2005. Agrobacterium-mediated in vitro transformation of wood-producing stem segments in eucalyptus. Plant Cell Rep. 23:617–24
Sundberg MD. 1983. Vascular development in the transition region of Populus deltoides Bartr. Ex Marsh
seedlings. Am. J. Bot. 70:735–43
Swarup K, Benkova E, Swarup R, Casimiro I, Peret B, et al. 2008. The auxin influx carrier LAX3 promotes
lateral root emergence. Nat. Cell Biol. 10:946–54
Swarup R, Friml J, Marchant A, Ljung K, Sandberg G, et al. 2001. Localization of the auxin permease AUX1
suggests two functionally distinct hormone transport pathways operate in the Arabidopsis root apex. Genes
Dev. 15:2648–53
Swarup R, Kramer EM, Perry P, Knox K, Leyser HM, et al. 2005. Root gravitropism requires lateral root cap
and epidermal cells for transport and response to a mobile auxin signal. Nat. Cell Biol. 7:1057–65
Szekeres M, Nemeth K, Koncz-Kalman Z, Mathur J, Kauschmann A, et al. 1996. Brassinosteroids rescue the
deficiency of CYP90, a cytochrome P450, controlling cell elongation and de-etiolation in Arabidopsis. Cell
85:171–82
Taylor G. 2002. Populus: Arabidopsis for forestry. Do we need a model tree? Ann. Bot. 90:681–89
Turner S, Gallois P, Brown D. 2007. Tracheary element differentiation. Annu. Rev. Plant Biol. 58:407–33
Turner SR, Somerville CR. 1997. Collapsed xylem phenotype of Arabidopsis identifies mutants deficient in
cellulose deposition in the secondary cell wall. Plant Cell 9:689–701
Tuskan GA, DiFazio S, Jansson S, Bohlmann J, Grigoriev I, et al. 2006. The genome of black cottonwood,
Populus trichocarpa (Torr. & Gray). Science 313:1596–604
Uggla C, Mellerowicz EJ, Sundberg B. 1998. Indole-3-acetic acid controls cambial growth in Scots pine by
positional signaling. Plant Physiol. 117:113–21
Uggla C, Moritz T, Sandberg G, Sundberg B. 1996. Auxin as a positional signal in pattern formation in plants.
Proc. Natl. Acad. Sci. USA 93:9282–86
Vanneste S, Friml J. 2009. Auxin: a trigger for change in plant development. Cell 136:1005–16
Vert G, Chory J. 2006. Downstream nuclear events in brassinosteroid signaling. Nature 441:96–100
Wagner A, Ralph J, Akiyama T, Flint H, Phillips L, et al. 2007. Exploring lignification in conifers by silencing
hydroxycinnamoyl-CoA:shikimate hydroxycinnamoyltransferase in Pinus radiata. Proc. Natl. Acad. Sci.
USA 104:11856–61
Wang ZY, Nakano T, Gendron J, He J, Chen M, et al. 2002. Nuclear-localized BZR1 mediates brassinosteroidinduced growth and feedback suppression of brassinosteroid biosynthesis. Dev Cell 2:505–13
Wang ZY, Seto H, Fujioka S, Yoshida S, Chory J. 2001. BRI1 is a critical component of a plasma-membrane
receptor for plant steroids. Nature 410:380–83
Wenzel CL, Hester Q, Mattsson J. 2008. Identification of genes expressed in vascular tissues using NPAinduced vascular overgrowth in Arabidopsis. Plant Cell Physiol. 49:457–68
Whitford R, Fernandez A, De Groodt R, Ortega E, Hilson P. 2008. Plant CLE peptides from two distinct
functional classes synergistically induce division of vascular cells. Proc. Natl. Acad. Sci. USA 105:18625–30
Yamaguchi M, Kubo M, Fukuda H, Demura T. 2008. Vascular-related NAC-DOMAIN7 is involved in the
differentiation of all types of xylem vessels in Arabidopsis roots and shoots. Plant J. 55:652–64
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
by Universitat Autonoma de Barcelona on 12/09/13. For personal use only.
CB26CH24-Cano-Delgado
636
Caño-Delgado
· ·
Lee
Demura
Annu. Rev. Cell Dev. Biol. 2010.26:605-637. Downloaded from www.annualreviews.org
by Universitat Autonoma de Barcelona on 12/09/13. For personal use only.
CB26CH24-Cano-Delgado
ARI
3 September 2010
20:17
Yamamoto R, Demura T, Fukuda H. 1997. Brassinosteroids induce entry into the final stage of tracheary
element differentiation in cultured Zinnia cells. Plant Cell Physiol. 38:980–83
Yamamoto R, Fujioka S, Demura T, Takatsuto S, Yoshida S, Fukuda H. 2001. Brassinosteroid levels increase
drastically prior to morphogenesis of tracheary elements. Plant Physiol. 125:556–63
Yamamoto R, Fujioka S, Iwamoto K, Demura T, Takatsuto S, et al. 2007. Co-regulation of brassinosteroid
biosynthesis-related genes during xylem cell differentiation. Plant Cell Physiol. 48:74–83
Ye Z-H. 2002. Vascular tissue differentiation and pattern formation in plants. Annu. Rev. Plant Biol. 53:183–202
Ye ZH, Varner JE. 1994. Expression of an auxin- and cytokinin-regulated gene in cambial region in Zinnia.
Proc. Natl. Acad. Sci. USA 91:6539–43
Yin Y, Wang ZY, Mora-Garcia S, Li J, Yoshida S, et al. 2002. BES1 accumulates in the nucleus in response
to brassinosteroids to regulate gene expression and promote stem elongation. Cell 109:181–91
Yokoyama A, Yamashino T, Amano Y, Tajima Y, Imamura A, et al. 2007. Type-B ARR transcription factors,
ARR10 and ARR12, are implicated in cytokinin-mediated regulation of protoxylem differentiation in
roots of Arabidopsis thaliana. Plant Cell Physiol. 48:84–96
Yoshida S, Iwamoto K, Demura T, Fukuda H. 2009. Comprehensive analysis of the regulatory roles of auxin
in early transdifferentiation into xylem cells. Plant Mol. Biol. 70:457–69
Zhao C, Avci U, Grant EH, Haigler CH, Beers EP. 2008. XND1, a member of the NAC domain family in
Arabidopsis thaliana, negatively regulates lignocellulose synthesis and programmed cell death in xylem.
Plant J. 53:425–36
Zhao C, Craig JC, Petzold HE, Dickerman AW, Beers EP. 2005. The xylem and phloem transcriptomes from
secondary tissues of the Arabidopsis root-hypocotyl. Plant Physiol. 138:803–18
Zhao C, Johnson BJ, Kositsup B, Beers EP. 2000. Exploiting secondary growth in Arabidopsis. Construction
of xylem and bark cDNA libraries and cloning of three xylem endopeptidases. Plant Physiol. 123:1185–96
Zhao Y, Christensen SK, Fankhauser C, Cashman JR, Cohen JD, et al. 2001. A role for flavin monooxygenaselike enzymes in auxin biosynthesis. Science 291:306–9
Zhong R, Demura T, Ye ZH. 2006. SND1, a NAC domain transcription factor, is a key regulator of secondary
wall synthesis in fibers of Arabidopsis. Plant Cell 18:3158–70
Zhong R, Richardson EA, Ye ZH. 2007a. The MYB46 transcription factor is a direct target of SND1 and
regulates secondary wall biosynthesis in Arabidopsis. Plant Cell 19:2776–92
Zhong R, Richardson EA, Ye ZH. 2007b. Two NAC domain transcription factors, SND1 and NST1, function
redundantly in regulation of secondary wall synthesis in fibers of Arabidopsis. Planta 225:1603–11
Zhong R, Ye Z-H. 2004. amphivasal vascular bundle 1, a gain-of-function mutation of the IFL1/REV gene, is
associated with alterations in the polarity of leaves, stems and carpels. Plant Cell Physiol. 45:369–85
Zhong R, Ye ZH. 2007. Regulation of HD-ZIP III genes by microRNA 165. Plant Signal Behav. 2:351–53
Zhou J, Lee C, Zhong R, Ye ZH. 2009. MYB58 and MYB63 are transcriptional activators of the lignin
biosynthetic pathway during secondary cell wall formation in Arabidopsis. Plant Cell 21:248–66
www.annualreviews.org • Plant Vascular Patterning
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Contents
Enzymes, Embryos, and Ancestors
John Gerhart p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 1
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Control of Mitotic Spindle Length
Gohta Goshima and Jonathan M. Scholey p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p21
Annual Review
of Cell and
Developmental
Biology
Volume 26, 2010
Trafficking to the Ciliary Membrane: How to Get Across
the Periciliary Diffusion Barrier?
Maxence V. Nachury, E. Scott Seeley, and Hua Jin p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p59
Transmembrane Signaling Proteoglycans
John R. Couchman p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p89
Membrane Fusion: Five Lipids, Four SNAREs, Three Chaperones,
Two Nucleotides, and a Rab, All Dancing in a Ring on Yeast Vacuoles
William Wickner p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 115
Tethering Factors as Organizers of Intracellular Vesicular Traffic
I-Mei Yu and Frederick M. Hughson p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 137
The Diverse Functions of Oxysterol-Binding Proteins
Sumana Raychaudhuri and William A. Prinz p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 157
Ubiquitination in Postsynaptic Function and Plasticity
Angela M. Mabb and Michael D. Ehlers p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 179
α-Synuclein: Membrane Interactions and Toxicity
in Parkinson’s Disease
Pavan K. Auluck, Gabriela Caraveo, and Susan Lindquist p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 211
Novel Research Horizons for Presenilins and γ-Secretases in Cell
Biology and Disease
Bart De Strooper and Wim Annaert p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 235
Modulation of Host Cell Function by Legionella pneumophila
Type IV Effectors
Andree Hubber and Craig R. Roy p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 261
A New Wave of Cellular Imaging
Derek Toomre and Joerg Bewersdorf p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 285
Mechanical Integration of Actin and Adhesion Dynamics
in Cell Migration
Margaret L. Gardel, Ian C. Schneider, Yvonne Aratyn-Schaus,
and Clare M. Waterman p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 315
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Cell Motility and Mechanics in Three-Dimensional Collagen Matrices
Frederick Grinnell and W. Matthew Petroll p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 335
Rolling Cell Adhesion
Rodger P. McEver and Cheng Zhu p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 363
Assembly of Fibronectin Extracellular Matrix
Purva Singh, Cara Carraher, and Jean E. Schwarzbauer p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 397
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Interactions Between Nuclei and the Cytoskeleton Are Mediated
by SUN-KASH Nuclear-Envelope Bridges
Daniel A. Starr and Heidi N. Fridolfsson p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 421
Plant Nuclear Hormone Receptors: A Role for Small Molecules
in Protein-Protein Interactions
Shelley Lumba, Sean R. Cutler, and Peter McCourt p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 445
Mammalian Su(var) Genes in Chromatin Control
Barna D. Fodor, Nicholas Shukeir, Gunter Reuter, and Thomas Jenuwein p p p p p p p p p p p p p p 471
Chromatin Regulatory Mechanisms in Pluripotency
Julie A. Lessard and Gerald R. Crabtree p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 503
Presentation Counts: Microenvironmental Regulation of Stem Cells by
Biophysical and Material Cues
Albert J. Keung, Sanjay Kumar, and David V. Schaffer p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 533
Paramutation and Development
Jay B. Hollick p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 557
Assembling Neural Crest Regulatory Circuits into
a Gene Regulatory Network
Paola Betancur, Marianne Bronner-Fraser, and Tatjana Sauka-Spengler p p p p p p p p p p p p p p p 581
Regulatory Mechanisms for Specification and Patterning of Plant
Vascular Tissues
Ana Caño-Delgado, Ji-Young Lee, and Taku Demura p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 605
Common Factors Regulating Patterning of the Nervous
and Vascular Systems
Mariana Melani and Brant M. Weinstein p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 639
Stem Cell Models of Cardiac Development and Disease
Kiran Musunuru, Ibrahim J. Domian, and Kenneth R. Chien p p p p p p p p p p p p p p p p p p p p p p p p p p 667
Stochastic Mechanisms of Cell Fate Specification that Yield Random
or Robust Outcomes
Robert J. Johnston, Jr. and Claude Desplan p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 689
A Decade of Systems Biology
Han-Yu Chuang, Matan Hofree, and Trey Ideker p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 721
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Contents