The shape of DNA

From: Gina Miller (nanogirl@halcyon.com)
Date: Wed Jun 16 1999 - 15:36:36 MDT


Contact: Tom Rickey
trickey@admin.rochester.edu
716-275-7954
University of Rochester

For DNA, it's all about fitting In

Thousands of times each second along the seven feet of DNA in every cell in
our bodies, enzymes are busy moving along the molecule, ferrying the proper
chemical bases into the appropriate positions to make copies of the genetic
blueprint. This high-speed copying makes all life possible. The enzymes in
charge do an incredible job, getting the sequence in humans correct more
than 99.999 percent of the time.

How so? Scientists have long assumed that the demand for this high fidelity
comes from the chemical bonds called "hydrogen bonds"between the two rows of
bases of DNA. One nucleotide extends a chemical "handshake," and only its
appropriate partner can match up with it, forming a pair of bases that take
their place as one rung in the twisting ladder of the double helix.

But new evidence from the laboratory of Eric Kool at the University of
Rochester shows that the formation of hydrogen bonds is not as important as
scientists expected. Instead, shape is paramount; together a pair of bases
must fit into its assigned space in the larger DNA molecule so that it can
serve as a template for identical molecules. Their latest evidence appears
in the June 17 issue of Nature.

"This is the jigsaw-puzzle model of DNA," says Kool, professor of chemistry.
"The bases must fit together for a polymerase enzyme to copy them. Shape
brings fidelity to the process." The finding is a surprise to many
biochemists who have long focused on hydrogen bonds when trying to unravel
the operation of polymerase enzymes, which copy DNA.

The Nature paper is the latest in a series of publications and patents in
which Kool describes experiments with molecular mimics, synthetic molecules
his laboratory creates to substitute for the conventional bases (adenine,
cytosine, thymine, guanine) that form the DNA of all known life forms. In
the paper, Kool and former post-doctoral associate Tracy J. Matray, now at
Geron Corp., designed two radically different shapes for a base pair. With
funding from the National Institutes of Health and the U.S. Army, they
reduced one base to the smallest chemical entity"a proton"and provided it
with a partner that was nearly double the size of a normal base. Together
the two bases filled about the same space as a conventional pair, fitting
within the general structure of DNA, though neither looks anything like a
traditional base. It's a little bit like an odd couple that blends well into
a conventional neighborhood by canceling out each other's foibles.

"It's amazing that although these bases look totally foreign, as long as
they fit together properly, like two jigsaw puzzle pieces, enzymes perceive
them as part of a DNA molecule and copy them accordingly. Not only do you
not need hydrogen bonds to copy DNA, you don't even need the traditional
shape of the individual bases," says Kool.

One possible application of the current work, Kool says, is a test for
cancer-causing agents that cause mutations by knocking out a single base,
which is the most common form of mutation in our bodies. The double-size
molecule the team developed is such an effective molecular impostor that
polymerase enzymes insert it into any "abasic" site, where a single base is
missing, kind of like a party guest who is always looking for an empty
chair. The molecule, a pyrene nucleoside triphosphate, fluoresces brightly,
flagging mutations and sending an easily visible signal whenever a base is
missing.

Kool's vein of research on novel types of DNA and RNA has been adopted by
several other laboratories and has a variety of other applications. He has
developed "rolling circles" of DNA, providing an inexpensive way to produce
hundreds of copies of an RNA molecule by spinning them off like a mimeograph
machine. The laboratory has developed loops of DNA and RNA that form a
triple helix with single strands, enveloping them like a bun around a hot
dog and knocking them out. The loops are specially resistant to enzymes that
chew up DNA, and they've shown promise as antisense agents to knock out the
proteins involved in diseases like leukemia and HIV. The laboratory has also
made molecules that can hone in on different targets depending on chemical
conditions.

Another far-off application might be a type of artificial DNA, the creation
of several entirely new base pairs that would fit together like conventional
DNA and code for proteins much like regular DNA has done for millions of
years. Experimenting with alternate genetic codes might provide hints about
the type of life that might exist elsewhere in the universe. While such a
development sounds like the stuff of science fiction, Kool?s work provides
one step in that direction. He has already developed several synthetic
molecules that can squeeze into natural DNA, and he has overturned decades
of dogma by showing that hydrogen bonds are not as vital as shape to the
existence and reproduction of DNA.

"The unexpected flexibility of the structure of DNA raises interesting
questions about the primordial soup," says Kool. "Why does DNA have the
structure it has? How different can we make a molecule and still have it
behave like DNA, and still have life?"
Gina "Nanogirl" Miller
Nanotechnology Industries
Web:
http://www.nanoindustries.com
E-mail:
nanogirl@halcyon.com
Alternate E-mail
echoz@hotmail.com
"Nanotechnology: solutions for the future."



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