They may well be bases, but the
primacy of the DNA bases can hardly be in dispute. And it makes perfect sense that other bases
exist for special applications.
In the meantime we are slowly
winkling out the majesty of the DNA ruling our cells and body.
It has been a remarkable passage
to observe over the decades.
UNC researchers identify seventh and eighth bases of DNA
by Staff Writers
The finding could have important implications for stem cell research,
as it could provide researchers with new tools to erase previous methylation
patterns to reprogram adult cells. It could also inform cancer research, as it
could give scientists the opportunity to reactivate tumor suppressor genes that
had been silenced by DNA methylation.
For decades, scientists have known that DNA consists of four basic
units - adenine, guanine, thymine and cytosine. Those four bases have been
taught in science textbooks and have formed the basis of the growing knowledge
regarding how genes code for
life. Yet in recent history, scientists have expanded that list from four to
six.
Now, with a finding published online in the July 21, 2011, issue of the
journal Science, researchers from the UNC School
of Medicine have discovered the seventh and eighth bases of DNA.
These last two bases - called 5-formylcytosine and 5 carboxylcytosine -
are actually versions of cytosine that have been modified by Tet proteins,
molecular entities thought to play a role in DNA demethylation and stem cell
reprogramming.
Thus, the discovery could advance stem cell research by giving a
glimpse into the DNA changes - such as the removal of chemical groups through
demethylation - that could reprogram adult cells to make them act like stem
cells.
"Before we can grasp the magnitude of this discovery, we have to
figure out the function of these new bases," said senior study author Yi
Zhang, PhD, Kenan Distinguished Professor of biochemistry and biophysics at UNC
and an Investigator of the Howard Hughes Medical Institute.
"Because these bases represent an intermediate state in the
demethylation process, they could be important for cell fate reprogramming and cancer,
both of which involve DNA demethylation." Zhang is also a member of the UNC Lineberger
Comprehensive Cancer
Center .
Holden Thorp, UNC chancellor and Kenan Professor of Chemistry in the
College of Arts and Sciences, said Zhang's discovery was a significant
development that holds promise for a variety of areas.
"Research such as this, at the intersection of chemistry, biology,
physics and medicine, show the value of scientists like Yi Zhang who tackle
both practical problems and fundamental scientific mysteries," said Thorp.
"Having devoted a large part of my research career to
understanding the fundamental processes in nucleobase and nucleotide oxidation,
I'm particularly excited to see this signature result at Carolina . The concept of sequential
nucleobase oxidation as an epigenetic signal is tantalizing."
Much is known about the "fifth base," 5-methylcytosine, which
arises when a chemical tag or methyl group is tacked onto a cytosine. This
methylation is associated with gene silencing, as it causes the DNA's double helix to
fold even tighter upon itself.
Last year, Zhang's group reported that Tet proteins can convert 5
methylC (the fifth base) to 5 hydroxymethylC (the sixth base) in the first of a
four step reaction leading back to bare-boned cytosine. But try as they might,
the researchers could not continue the reaction on to the seventh and eighth
bases, called 5 formylC and 5 carboxyC.
The problem, they eventually found, was not that Tet wasn't taking that
second and third step, it was that their experimental assay wasn't sensitive
enough to detect it.
Once they realized the limitations of the assay, they redesigned it and
were in fact able to detect the two newest bases of DNA. The researchers then
examined embryonic stem cells as well as mouse organs and found that both bases
can be detected in genomic DNA.
The finding could have important implications for stem cell research,
as it could provide researchers with new tools to erase previous methylation
patterns to reprogram adult cells. It could also inform cancer research, as it
could give scientists the opportunity to reactivate tumor suppressor genes that
had been silenced by DNA methylation.
The research was funded by the Howard Hughes Medical Institute and
the National Institutes of Health. Study co-authors from UNC include Shinsuke
Ito, PhD; Li Shen, PhD; Susan C. Wu, PhD; Leonard B. Collins and James A.
Swenberg, PhD.
Hello,
ReplyDeleteThank you for commenting on your experiences here. The main role of DNA molecules is the long term storage of information, which is often compared to a set of blueprints, since it contains the instructions needed to construct other components...