In a discovery that challenges long-held dogma in biology, researchers show that mammalian cells can convert RNA sequences back into DNA, a feat more common in viruses than eukaryotic cells.
From Thomas Jefferson University
June 11, 2021 -- Cells contain machinery
that duplicates DNA into a new set that goes into a newly formed cell. That
same class of machines, called polymerases, also build RNA messages, which are
like notes copied from the central DNA repository of recipes, so they can be
read more efficiently into proteins. But polymerases were thought to only work
in one direction DNA into DNA or RNA. This prevents RNA messages from being
rewritten back into the master recipe book of genomic DNA. Now, Thomas
Jefferson University researchers provide the first evidence that RNA segments
can be written back into DNA, which potentially challenges the central dogma in
biology and could have wide implications affecting many fields of biology.
"This work opens the door to many
other studies that will help us understand the significance of having a
mechanism for converting RNA messages into DNA in our own cells," says
Richard Pomerantz, PhD, associate professor of biochemistry and molecular
biology at Thomas Jefferson University. "The reality that a human
polymerase can do this with high efficiency, raises many questions." For
example, this finding suggests that RNA messages can be used as templates for
repairing or re-writing genomic DNA.
The work was published June 11th in the
journal Science Advances.
Together with first author Gurushankar
Chandramouly and other collaborators, Dr. Pomerantz's team started by
investigating one very unusual polymerase, called polymerase theta. Of the 14
DNA polymerases in mammalian cells, only three do the bulk of the work of
duplicating the entire genome to prepare for cell division. The remaining 11
are mostly involved in detecting and making repairs when there's a break or
error in the DNA strands. Polymerase theta repairs DNA, but is very error-prone
and makes many errors or mutations. The researchers therefore noticed that some
of polymerase theta's "bad" qualities were ones it shared with
another cellular machine, albeit one more common in viruses -- the reverse transcriptase.
Like Pol theta, HIV reverse transcriptase acts as a DNA polymerase, but can
also bind RNA and read RNA back into a DNA strand.
In a series of elegant experiments, the
researchers tested polymerase theta against the reverse transcriptase from HIV,
which is one of the best studied of its kind. They showed that polymerase theta
was capable of converting RNA messages into DNA, which it did as well as HIV
reverse transcriptase, and that it actually did a better job than when
duplicating DNA to DNA. Polymerase theta was more efficient and introduced
fewer errors when using an RNA template to write new DNA messages, than when
duplicating DNA into DNA, suggesting that this function could be its primary
purpose in the cell.
The group collaborated with Dr. Xiaojiang
S. Chen's lab at USC and used x-ray crystallography to define the structure and
found that this molecule was able to change shape in order to accommodate the
more bulky RNA molecule -- a feat unique among polymerases.
"Our research suggests that
polymerase theta's main function is to act as a reverse transcriptase,"
says Dr. Pomerantz. "In healthy cells, the purpose of this molecule may be
toward RNA-mediated DNA repair. In unhealthy cells, such as cancer cells,
polymerase theta is highly expressed and promotes cancer cell growth and drug
resistance. It will be exciting to further understand how polymerase theta's
activity on RNA contributes to DNA repair and cancer-cell proliferation."
https://www.sciencedaily.com/releases/2021/06/210611174037.htm
No comments:
Post a Comment