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Transcript 
TOYOHASHI UNIVERSITY of TECHNOLOGY
Tempaku-cho, Toyohashi, Aichi, 441-8580 Japan
PHONE: +81-532-44-6577
FAX: +81-532-44-6557
E-mail: [email protected]
PRESS RELEASE
Source: Toyohashi University of Technology, Japan, Committee for Public Relations
Subject line: Evolution of a novel organelle in insects – a symbiotic bacterium has
integrated into aphids using a mechanism common to mitochondria and chloroplasts
(Toyohashi, Japan, 21st July 2014) A Toyohashi Tech researcher in cooperation with
researchers at RIKEN, Iwate Medical University, Tokyo Institute of Technology, and the
National Institute of Genetics, has revealed that aphids synthesize a protein from a gene
laterally acquired from bacteria, and the produced protein is transported to an obligate
intracellular bacterial symbiont. This is the first report of integration between animals and
bacteria to the extent of ‘organellogenesis’. This finding will lead to the development of
innovative biotechnologies, including the fusion of distantly related organisms, and will
enable highly selective pest control.
Mitochondria and chloroplasts are descendants of bacteria that were engulfed by common ancestors of
all eukaryotes and plants, respectively. During their evolution, many genes were transferred from
ancestral organelles and other bacteria to the host genome. This process required incorporating intact
genes into the host genome, acquiring the expression signals that enable their transcription in eukaryotic
hosts, and evolving a targeting system to transport and import their protein products into the
endosymbiotic organelles. The advent of this protein-targeting machinery is commonly assumed to be the
most crucial step, at which an endosymbiont becomes an organelle. Although bacterial lineages have
repeatedly evolved intimate symbioses with eukaryotic hosts, the establishment of the protein
translocation system has been shown only in the cases of bona fide organelles and a symbiosis in an
amoeba. Here, Atsushi Nakabachi at Toyohashi Tech and his colleagues report this type of evolution in
Animalia. Aphids, sap-sucking insects known as agricultural pests, harbor the obligate mutualistic
symbiont, Buchnera aphidicola (Gammaproteobacteria), within specialized cells called bacteriocytes.
Buchnera provides nutrients to the host aphids and has been transmitted through host generations for
more than 100 million years. The present study revealed that (i) protein is synthesized from the
aphid-encoded RlpA4 gene that was laterally acquired from a bacterium, (ii) the RlpA4 protein is
synthesized specifically in the bacteriocyte, and (iii) the synthesized protein is localized in Buchnera cells,
indicating that a translocation system has evolved to target the RlpA4 protein to Buchnera. These results
demonstrate that the intimate aphid-Buchnera symbiosis is achieved using a mechanism that is common
to the evolution of organelles, mitochondria and chloroplasts. This finding will lead to the development of
innovative biotechnologies, including the fusion of distantly related organisms, and will enable highly
selective pest control.
TOYOHASHI UNIVERSITY of TECHNOLOGY
Tempaku-cho, Toyohashi, Aichi, 441-8580 Japan
PHONE: +81-532-44-6577
FAX: +81-532-44-6557
E-mail: [email protected]
Reference:
Authors: Atsushi Nakabachi1,2, Kinji Ishida3, Yuichi Hongoh4, Moriya Ohkuma2, Shin-ya Miyagishima5
Title of original paper: Aphid Gene of Bacterial Origin Encodes a Protein Transported to an Obligate
Endosymbiont
Journal, volume, pages and year: Current Biology (Online published ahead of print, 21 July 2014)
Affiliation(s): 1Electronics-Inspired Interdisciplinary Research Institute (EIIRIS), Toyohashi University of
Technology, Toyohashi, Aichi, Japan, 2Japan Collection of Microorganisms, RIKEN BioResource Center,
Tsukuba, Ibaraki, Japan, 3The Center for EM & Bio-Imaging Research, Iwate Medical University, Shiwa,
Iwate, Japan, 4Graduate School of Bioscience and Biotechnology, Tokyo Institute of Technology, Meguro,
Tokyo, Japan, 5Center for Frontier Research, National Institute of Genetics, Mishima, Shizuoka, Japan
Website: http://www.eiiris.tut.ac.jp/
Bacteriocyte
Laterally-acquired gene
Figure
Buchnera
1.
Aphids
show
integration with bacteria to the
Nucleus
Protein
extent of ‘organellogenesis’
Nuclear genome
Reduced genome
A
B
N SP
ICK-I
DPBB
(kD)
30
B
G
H
E
ICK-II C
is
20
C
specifically
bacteriocyte,
F
expressed
and
the
in
the
protein
maternal
product
is
transported to Buchnera. (A) Domain structure of
e
mb
Figure 2. The aphid-encoded bacterial gene RlpA4
the aphid RlpA4 protein. (B) Detection of RlpA4
eb
protein using immunoblot analysis. B, maternal
bacteriocyte; G, midgut; H, head; E, embryo. (C to
200 ! m
E) Immunofluorescence localization of RlpA4
D
protein (green signal). (C) Localization of RlpA4 in
the aphid body. mb, maternal bacteriocyte; e,
n
20 ! m
embryo;
b
100 nm
eb,
embryonic
Localization
of
RlpA4
bacteriocyte.
n,
nucleus;
bacteriocyte.
in
b,
the
(D)
maternal
Buchnera. (E)
Localization of RlpA4 in the Buchnera cell. (F)
E
G
Host cell
Localization of RlpA4 in the Buchnera cell as
Laterally-acquired gene
observed
Protein
Nuclear genome
Host membrane
1!m
Reduced genome
immunoelectron
microscopy.
Arrows highlight some of the signals. Arrowheads
Nucleus
Endosymbiont
with
indicate the cell envelope of Buchnera. (G) The
mechanism shown to be common to the
aphid-Buchnera symbiosis and the evolution of
organelles.
TOYOHASHI UNIVERSITY of TECHNOLOGY
Tempaku-cho, Toyohashi, Aichi, 441-8580 Japan
PHONE: +81-532-44-6577
FAX: +81-532-44-6557
E-mail: [email protected]
Atsushi Nakabachi
Further information
Toyohashi University of Technology
1-1 Hibarigaoka, Tempaku
Toyohashi, Aichi Prefecture, 441-8580, JAPAN
Inquiries: Committee for Public Relations
E-mail: [email protected]
About Toyohashi University of Technology:
Founded in 1976 as a National University of Japan, Toyohashi University of Technology is a vibrant
modern institute with research activities reflecting the modern era of advanced electronics, engineering,
and life sciences.
Website: http://www.tut.ac.jp/english/
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