Download Drosophila D

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
page
16
page
17
page
18
page
19
page
20
page
21
page
22
page
23
page
24
page
25
page
26
page
27
page
28
page
29
page
30
page
31
page
32
page
33
page
34
page
35
page
36
page
37
page
38
page
39
page
40
page
41
Document related concepts

Development of the nervous system wikipedia , lookup

Transcript 
Drosophila dorsal/ventral axis detemination
How are different tissue types specified at
distinct positions on the embryonic dorsalventral axis?
Cell fate specification at the blastoderm stage
amnioserosa
dorsal
dorsal
ectoderm
neuroectoderm
mesoderm
ventral
fate map
mesoderm formation
Dorsal-Ventral fate map
Genes identified in a famous screen for Drosophila
mutants with embryo patterning defects
Torpedo
Gurken
Localized
maternal
mRNA sets
up anterior
and posterior
poles
Gurken protein specifies the Anterior-Posterior
axis of the Drosophila embryo during oogenesis
(Similar to EGF)
Gurken also signals dorsal pole formation during oogenesis
oocyte
nucleus
1-6
A
+
7
8
D
migration of
nucleus
10A
D
-
P
anterior
posterior
V
V
follicle cells
microtubules
8
10A
1-6
+
gurken expression
in the oocyte
gurken expression in the oocyte
Expression of the
Gurken Message
and Protein
Between the
Oocyte Nucleus
and the Dorsal
Anterior Cell
Membrane
Gurken signaling inhibits production of an extracellular
signal (Spätzle) by follicle cells
follicle cells
Torpedo = EGF receptor
(in follicle cells)
Gurken = Epidermal
Growth Factor (EGF)
Oocyte
pipe
expression
X
Ventral follicle
cell
Pipe (Golgi?)
X
Wind (ER?)
Nucleus
X
modified from van Eeden & St.Johnston
Maternal effect mutations in dorso-ventral patterning
Somatic (follicle cells)
nudel, pipe, wbl
ndl, pipe, wbl
dorsal RNA
gd, snk, ea - serine proteases
Spätzle
Toll protein
spz - ligand
Spätzle protein
Germline (nurse cells)
Toll
Dorsal protein
Tl - membrane receptor
Dorsal protein
tube - cytoplasmic protein
pelle - ser/thr protein kinase
cactus
amnio serosa
cact - cytoplasmic inhibitor
dorsal
ectoderm
of Dorsal nuclear
translocation
dorsal
neuroectoderm
dl - transcription factor
(morphogen)
mesoderm
Dl
nuclear protein
dorsal and cactus mutants (maternal germline effect)
dorsal
Wild type
dorsal
cactus
mutant
mutant
A7
A8
A6
A5
A4
A3
A2
T3
A1
T2
T1
ventral
dorsalized
ventralized
Translocation of Dorsal protein into ventral
nuclei but not lateral or dorsal nuclei
Wild type
toll mutant
cactus mutant
Generation of Dorsal-Ventral Polarity in Drosophila
Generation of Dorsal-Ventral Polarity in Drosophila
The Toll pathway in dorso-ventral pattern formation
Inject wild-type cytoplasm
into toll mutant eggs
toll mutant
ventral
dorsalized
local
rescue
Wild type
dorsal
ectoderm
dorsal
neuro-ectoderm
(denticle belts)
mesoderm
polarity reversal
Conserved pathway for
regulating nuclear
transport of
transcription factors in
Drosophila and
mammals
Cells with highest nuclear Dorsal levels become mesoderm
Zygotically expressed genes
Action of Dorsal protein in ventral cells
Action of Dorsal protein in ventral cells
High affinity for promoter,
Not much Dorsal needed to activate
Action of Dorsal protein in ventral cells
Lower affinity for promoter,
More Dorsal needed to activate
Zygotically expressed genes
Action of Dorsal protein in ventral cells
Snail repression of rhomboid
creates domains with distinct gene
expression patterns
Dorso-ventral pattern formation: summary
nudel, pipe,
windbeutel
dorsal RNA
Toll protein
Spätzle
protein
Dorsal protein
Dorsal protein
dpp
twist
oocyte nucleus dorsal
> repression of ventral fate
in dorsal follicle cells
ventral production of ligand
> activation of Toll receptor
> graded nuclear uptake
of Dorsal morphogen
> regulation of zygotic
target gene expression
> cell fates along DV axis
Use of a similar regulatory system to pattern insects and vertebrates
Patterns ectoderm in Drosophila
Patterns mesoderm in vertebrates
Gastrulation in Drosophila
Schematic
representation of
gastrulation in
Drosophila
Anterior-posterior patterning in Drosophila
The fly body plan:
each segment has a
unique identity
and produces
distinctive
structures
3 head
3 thorax
8 abdomen
Mutations affecting the antero-posterior axis
3 independent maternal systems: anterior, posterior, terminal
fate map
larva
active
systems
triple mutants
active
systems
A P T
wild-type
single mutants
anterior
bicoid
posterior
oskar
terminal
torso
- - -
double mutants
- P T
- P -
A - T
- - T
A P -
A - additive phenotypes
Maternal effect mutations
Zygotic effect mutations
bicoid mutant phenotype
Embryo from
wild-type
mother
Embryo from
bicoid mother
Anterior: bicoid is required for head and thorax
Wild type
bicoid mutant
blastoderm fate map
head
+ thorax
abdomen
abdomen
Bicoid mRNA localization in embryo
(tethered to microtubules)
Nuclei divide without cell division in Drosophila
to produce a syncytial blastoderm embryo
Fig. 9.1
Bicoid protein
gradient in
syncytial
blastoderm
embryo
- diffuses after
translation from
localized mRNA
- protein unstable
Related documents
Introduction to Anatomy & Physiology
Introduction to Anatomy & Physiology
BICH/GENE 431 KNOWLEDGE OBJECTIVES Chapter 19 – Gene
BICH/GENE 431 KNOWLEDGE OBJECTIVES Chapter 19 – Gene
Necessities for Life and Body Regions
Necessities for Life and Body Regions
Slide 1
Slide 1
Annelid lab info
Annelid lab info
dorsal
dorsal
Axial vs. Appendicular Skeleton
Axial vs. Appendicular Skeleton
PowerPoint Lecture - Dr. Stuart Sumida
PowerPoint Lecture - Dr. Stuart Sumida
Anatomical Terms of Location!
Anatomical Terms of Location!
dorsal
dorsal
in follicle cells
in follicle cells
Anatomy of the Nervous System
Anatomy of the Nervous System