thescientist | Little things mean a lot. To any
biologist, this time-worn maxim is old news. But it’s worth revisiting.
As several articles in this issue of The Scientist illustrate, how researchers define and examine the “little things” does mean a lot.
Consider this month’s cover story, “Noncoding RNAs Not So Noncoding,”
by TS correspondent Ruth Williams. Combing the human genome for open
reading frames (ORFs), sequences bracketed by start and stop codons,
yielded a protein-coding count somewhere in the neighborhood of 24,000.
That left a lot of the genome relegated to the category of junk—or,
later, to the tens of thousands of mostly mysterious long noncoding RNAs
(lncRNAs). But because they had only been looking for ORFs that were
300 nucleotides or longer (i.e., coding for proteins at least 100 amino
acids long), genome probers missed so-called short ORFs (sORFs), which
encode small peptides. “Their diminutive size may have caused these
peptides to be overlooked, their sORFs to be buried in statistical
noise, and their RNAs to be miscategorized, but it does not prevent them
from serving important, often essential functions, as the micropeptides
characterized to date demonstrate,” writes Williams.
How little things work definitely informs another field of life science
research: synthetic biology. As the functions of genes and gene
networks are sussed out, bioengineers are using the information to
design small, synthetic gene circuits that enable them to better
understand natural networks. In “Synthetic Biology Comes into Its Own,”
Richard Muscat summarizes the strides made by synthetic biologists over
the last 15 years and offers an optimistic view of how such networks
may be put to use in the future. And to prove him right, just as we go
to press, a collaborative group led by one of syn bio’s founding
fathers, MIT’s James Collins, has devised a paper-based test for Zika virus exposure
that relies on a freeze-dried synthetic gene circuit that changes color
upon detection of RNAs in the viral genome. The results are ready in a
matter of hours, not the days or weeks current testing takes, and the
test can distinguish Zika from dengue virus. “What’s really exciting
here is you can leverage all this expertise that synthetic biologists
are gaining in constructing genetic networks and use it in a real-world
application that is important and can potentially transform how we do
diagnostics,” commented one researcher about the test.
0 comments:
Post a Comment