Time-lapse videos and computer simulations provide the first concrete molecular
explanation of how a cell flexes tiny muscle-like structures to pinch itself
into two daughter cells at the end of each cell division, according to a report
in Science Express.
Cell biologists at Yale and physicists at Columbia teamed up to model and then
observe the way a cell assembles the “contractile ring,” the short-lived
force-producing structure that physically divides cells and is always located
precisely between the two daughter cell nuclei.
“This contractile ring is thought to operate like an old-fashioned purse
string,” says senior author Thomas D. Pollard, Sterling Professor and chair
of the Department of Molecular, Cellular & Developmental Biology at Yale. “It
constricts the cell membrane into a cleavage furrow that eventually pinches the
cell in two.”
Living cells divide into two daughter cells to reproduce themselves. In one-celled
organisms like yeast, each cell division yields a new creature. In humans and
other multicellular species, cell division helps an embryo grow into an adult.
In fully developed adults, it provides necessary replacements for cells that
are continuously dying in the course of natural wear and tear.
Scientists have long studied aspects of how cells actually make this division — the
structure of the cellular machinery, how it assembles and how the machine works.
Since the 1970s, it has been known that the contractile ring is made up of
muscle-like actin and myosin — contractile proteins that are involved
a process in some ways similar to the muscle contraction used to move arms
or legs. However, there was no plausible mechanism to explain how it worked.
“We found that fission yeast cells assemble their contractile ring using
a ‘search, capture, pull and release’ mechanism,” says Pollard. “This
is important because it shows for the first time how the contractile machinery
assembles and how all the pieces get to the right place to get the job done.”
Time-lapse imaging and computer modeling demonstrated that cells undergoing
mitosis set up small clusters of proteins, or nodes, on the inside of the cell
membrane around the equator of the cell. Proteins in these nodes begin to put
out a small number of filaments composed of the protein actin. The filaments
grow in random directions until they encounter another node, where myosin motors
in the contacted node pull on the actin filament, bringing the two nodes together.
However, the researchers found that each connection is broken in about 20 seconds.
Releasing the connections and initiating subsequent rounds of “search
and capture” appears essential to the assembly process, say the scientists.
The assembly involves many episodes of attractions between pairs of nodes proceeding
in parallel. Eventually the nodes form into a condensed contractile ring around
the equator, ready to pinch the mother into two daughters at a later stage.
“A novel and important aspect of this work was that we used computer simulations
at every step to test what is feasible physically and to guide our experiments,” says
author Ben O’Shaughnessy, professor of chemical engineering at Columbia. “The
simulations show that cells use reaction rates that are nearly ideal to make
this mechanism work on the time scale of the events in the cells.”
According to Pollard, “Future work will involve testing the concepts learned from fission yeast in other cells to learn
if the mechanism is universal. Since other cells, including human cells, depend
on similar proteins for cytokinesis [cell division], it is entirely possible that they use the same strategy.”
Other authors on the paper were Dimitrios Vavylonis at Columbia, Yale and Lehigh
University; Jian-Qui Wu and Steven Hao at Yale. The work was supported by research
grants from the National Institutes of Health.
— By Janet Rettig Emanuel
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