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Dalam pengembangan,
semua tentang waktu
In development, it's all about the timing
Date:
July 17,
2014
Source:
Cold Spring Harbor Laboratory
Summary:
Closely related organisms share most of their genes,
but these similarities belie major differences in behavior, intelligence, and
physical appearance. Scientists are beginning to appreciate that the timing of
the events that happen during development plays a decisive role in defining an
organism. Now, a team of scientists has identified LIN-42 as a key regulator of
developmental timing, governing a broad range of events throughout maturation.
.....................
Closely related organisms share most of their genes, but
these similarities belie major differences in behavior, intelligence, and
physical appearance. For example, we share nearly 99% of our genes with chimps,
our closest relatives on the great "tree of life." Still, the
differences between the two species are unmistakable. If not just genes, what
else accounts for the disparities? Scientists are beginning to appreciate that
the timing of the events that happen during development plays a decisive role
in defining an organism, which may help to explain how species evolve without
the creation of new genes.
Today, a
team of scientists at Cold Spring Harbor Laboratory (CSHL) has identified a key
regulator of developmental timing. Led by CSHL Assistant Professor Christopher
Hammell, the researchers describe how LIN-42, a gene that is found in animals
across the evolutionary tree, governs a broad range of events throughout
development.
"A great
deal of science is focused on understanding how a single gene functions in the
cell," says Hammell. "But we are learning that when a gene is active
is just as important as what it does."
An organism
develops in well-defined stages: nerves and muscles mature before reproductive
tissues, for example. The stages unfold sequentially, like movements in a
symphony. Played all at once, they would produce a terrible developmental
cacophony, but with proper timing, a natural harmony can emerge.
Developmental
stages are marked by the activation or repression of a specific and unique
complement of genes, like individual notes within movements of a song. The
order and duration of when these key developmental genes (or notes) are active
(or played) within a given cell is controlled by a class of molecules called
microRNAs (miRNAs). A single miRNA gene can control hundreds of other genes at
once. If a miRNA turns off these specific genes too early or too late, the
organism will suffer severe developmental defects. But little is known about
how the activities of these miRNAs are regulated.
In work
published in PLoS Genetics, Hammell and his team describe the genetic
approach they used to search for genes that control developmental timing
through miRNAs. The team uses a tiny roundworm, called C. elegans, as a
simple model for the events that occur during development, even in higher
organisms. These worms have a fixed number of cells and each cell division is
precisely timed. "It is the perfect model for our work," says Hammell.
"It enables us to understand exactly how a mutation affects development,
whether maturation is precocious or delayed, by directly observing defects in
the timing of gene expression."
The team's
search uncovered the gene LIN-42 as a crucial regulator of developmental timing
via its pervasive role in controlling miRNAs. "LIN-42 shares a significant
amount of similarity to the genes that control circadian rhythms in organisms
such as mice and humans," says Roberto Perales, PhD, one of the lead
authors of the study. "These are genes that control the timing of cellular
processes on a daily basis for you and me. In the worm, these same genes and
mechanisms control development, growth, and behavior and this system will
provide us with leverage to understand how all of these things are
coordinated."
Hammell and
his team found that LIN-42 controls the repression of numerous genes in
addition to miRNAs. They also discovered that levels of the protein encoded by
LIN-42 tend to oscillate over the course of development and form a part of a
developmental clock. "LIN-42 provides the organism with a kind of cadence
or temporal memory, so that it can remember that it has completed one
developmental step before it moves on to the next," says Hammell. "This
way, LIN-42 coordinates optimal levels of the genes required throughout
development."
Story
Source:
The above
story is based on materials provided by Cold Spring Harbor Laboratory. Note: Materials may be edited
for content and length.
Journal
Reference:
- Roberto Perales, Dana M. King, Cristina Aguirre-Chen, Christopher M. Hammell. LIN-42, the Caenorhabditis elegans PERIOD homolog, Negatively Regulates MicroRNA Transcription. PLoS Genetics, 2014; 10 (7): e1004486 DOI: 10.1371/journal.pgen.1004486
