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Sebuah gen tunggal , doublesex , mengontrol sayap kupu-kupu di mimikri
Sebuah gen tunggal mengatur kompleks pola sayap , warna dan struktur yang diperlukan untuk mimikri dalam kupu-kupu Swallowtail , .... . Anehnya , gen dijelaskan , doublesex , sudah terkenal untuk peran yang penting dalam diferensiasi seksual pada serangga ......read more
A single gene,
doublesex, controls wing mimicry in butterflies
Date:
March 5, 2014
Source:
University of Chicago
Medical Center
Summary:
A single gene
regulates the complex wing patterns, colors and structures required for mimicry
in swallowtail butterflies, report scientists. Surprisingly, the gene
described, doublesex, is already well-known for its critical role in sexual
differentiation in insects.
.................
A single gene regulates
the complex wing patterns, colors and structures required for mimicry in
swallowtail butterflies, report scientists from the University of Chicago,
March 5 in Nature. Surprisingly,
the gene described, doublesex, is already well-known for its critical role in
sexual differentiation in insects.
"Conventional wisdom says that it should be multiple genes working
together to control the whole wing pattern of a butterfly," said Marcus
Kronforst, Neubauer Family Assistant Professor of Ecology & Evolution at
the University of Chicago and senior author of the study. "But in this
case, it's just this one. This single gene that controls sexual differentiation
has been co-opted to do a totally new job."
Studied as an example of natural selection for centuries, wing pattern
mimicry in butterflies enables non-toxic species to mimic the pattern, color
and shape of a toxic species' wings to deter predation. A single region of the
genome regulates this process in some swallowtail butterflies. Due to the
complexity of forms involved with mimicry, researchers have assumed this region
contained a "supergene" -- multiple tightly-linked genes, each
controlling a subset of the wing pattern. However, little was known about this
hypothesized mimicry supergene.
To identify its function, Kronforst and his team studied Papilio
polytes, an Asian swallowtail butterfly species that displays sex-limited
mimicry. Females possess one of four different wing patterns, three of which
mimic toxic species, while the remaining female form and all males remain
non-mimetic.
Through a genetic mapping process that involved mating butterflies of
differing wing patterns and comparing the genomes of around 500 offspring, the
team identified five possible genes involved in mimicry. They then sequenced
the genomes of 30 butterflies, evenly split between mimetic and non-mimetic,
and looked for correlations between these specific genes and wing pattern.
To their surprise, only one, doublesex, showed an association. Well
established as a gene that controls sexual differentiation in insects,
doublesex functions through alternative splicing. When copied into messenger
RNA, it is cut and rearranged into different isoforms, which then go on to
instruct cells whether they should be male or female.
Kronforst and his team found that doublesex is also alternatively spliced
into multiple isoforms in Papilio polytes. Two in particular were
expressed at extremely high levels in the wings of mimetic butterflies when
compared to non-mimetic females. Tracing the doublesex protein from caterpillar
to chrysalis to butterfly, the team found expression of doublesex overlaps
exactly with wing pattern.
"When you look at the wing tissue in a chrysalis five days after it
forms the pupa, it's just a floppy piece of white tissue," Kronforst said.
"But when you look at where doublesex is being manufactured on the wing,
it looks just like the future adult wing pattern."
How one gene controls so many different functions remains unclear.
Kronforst suggests that noncoding, regulatory DNA that controls when and where
doublesex is expressed may play a role. The team also found that in mimetic
butterflies, the doublesex gene is inverted on the genome. This inversion
eliminates the possibility of recombination -- alleles will remain distinct
from each other and accumulate differing mutations. This has led to structural
differences in the doublesex protein between mimetic and non-mimetic
butterflies. Because doublesex is a transcription factor and activates other
genes, the researchers believe these differences may also contribute to wing
pattern variation.
"We've illustrated the genetic basis of female-limited mimicry in
these butterflies," said Wei Zhang, PhD, postdoctoral fellow at the
University of Chicago and a lead study author. "But this is just the first
step. How doublesex became involved in this process is still uncertain, and
requires further study."
Study lead author Krushnamegh Kunte, PhD, of the National Center for
Biological Sciences in Bengaluru, India, and a former postdoctoral fellow in
the Kronforst lab, anticipates future research will determine if this type of
phenomenon will be found in other species. "Across animal species, we find
examples where polymorphisms occur in one sex or the other," he said.
"We're studying it in the context of mimicry, but it's possible that this
sex differentiation pathway that we found in butterflies could be a pathway
that's more broadly important for sex-limited polymorphism."
Story Source:
The above story is based on materials provided by University of Chicago Medical
Center. Note: Materials may be edited for content and length.
Journal Reference:
1. K. Kunte, W. Zhang, A. Tenger-Trolander,
D. H. Palmer, A. Martin, R. D. Reed, S. P. Mullen, M. R. Kronforst. doublesex
is a mimicry supergene. Nature, 2014; DOI: 10.1038/nature13112
