112 lines
6.9 KiB
Plaintext
112 lines
6.9 KiB
Plaintext
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| File Name : LASECANC.ASC | Online Date : 01/15/96 |
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| Contributed by : InterNet | Dir Category : BIOLOGY |
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| From : KeelyNet BBS | DataLine : (214) 324-3501 |
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| KeelyNet * PO BOX 870716 * Mesquite, Texas * USA * 75187 |
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| A FREE Alternative Sciences BBS sponsored by Vanguard Sciences |
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| InterNet email keelynet@ix.netcom.com (Jerry Decker) |
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| Files also available at Bill Beaty's http://www.eskimo.com/~billb |
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UV Laser Light Used Against Viruses, Cancer
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A chemist at Washington University in St. Louis literally has shone new light
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on a potential way to treat viral diseases and cancer. John-Stephen Taylor,
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Ph.D., Washington University associate professor of chemistry in Arts and
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Sciences, has created a modified piece of DNA that can be fragmented when
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exposed to ultraviolet light by laser. Once broken into two pieces, the longer
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piece of the modified DNA binds to a target site - a virus or cancer - and
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makes the target dysfunctional. The breakthrough provides scientists new ways
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to battle viruses and cancers and may change or even displace chemotherapy.
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DNA is a double-stranded helix molecule; located in the nucleus of every human
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cell, it contains cellular plans encoded in segments of DNA called genes.
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Messenger RNA is a single-stranded molecule responsible for carrying out the
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plans of DNA by directing the formation of proteins. Potential therapeutic
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uses for Taylor's building block are based on a strategy called antisense,
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whereby matching genetic sequences bind to specific messenger RNA molecules,
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inactivating their genetic message. Because the genetic instructions carr
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ied by Taylor's photocleavable building blocks can only be activated to bind
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in conjunction with light, the building block can be selectively activated in
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an area containing a cancer, thereby leaving good cells alone. Conventional
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chemotherapy, on the other hand, kills beneficial cells as well as cancer
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cells.
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Taylor incorporated the modified DNA piece, which he calls a photocleavable
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subunit, into another short piece of DNA by automated DNA synthesis. When
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light is shone on the DNA molecule bearing the photocleavable piece, the DNA
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strand falls apart into a long and a short fragment. The sequence of the long
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fragment is designed so that it matches a sequence in another DNA molecule to
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which it now binds, changing its genetic message.
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"We wanted to demonstrate how you can use such a photocleavable subunit to
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trigger something biologically useful," Taylor says. "We demonstrated that we
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could design a molecule that is otherwise incapable of binding to another DNA
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molecule but in the presence of light will break apart into two fragments, one
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of which is capable of binding to a matching sequence in a target DNA or RNA
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molecule."
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Taylor put the photocleavable subunit into a short piece of DNA, shone
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ultraviolet light on it and, using gel electrophoresis, a process that
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separates DNA fragments of differing sizes, watched the DNA break into the
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large and small fragment. The target site for the larger DNA fragment was a
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bacteriophage, a bacterial virus, of the often-used laboratory organism E.
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coli. The laser used operates at 10 pulses per second, and it took 80 pulses,
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or just 8 seconds, to cleave the DNA.
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"We showed in the absence of light, there is no binding of the DNA to the
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bacteriophage; with light, the DNA is cleaved and the shorter fragment
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dissociates from the larger fragment, which can now bind to the
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bacteriophage," Taylor says. "This is another tool that can be engineered into
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a molecule. In this case, light is the switch to activate binding to genetic
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material."
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Taylor published his results in the November 1995 issue of the Journal of the
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American Chemical Society. His research was supported by grants from the
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National Institutes of Health. Light already is used in a number of medical
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therapies. For instance, dermatologists use a technique called photophoresis
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for psoriasis and cancer treatments. And laser ablation burns away tissue in
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various diseases, including cataracts. But the photocleavable building blocks
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potentially offer a new dimension of precision to existing therapies and ones
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in the works.
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"Light is very useful biochemically," Taylor observes. "You can spatially
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locate it, point it to a specific site and turn it on and off. The whole point
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about light is it's a wonderful trigger because it can be literally turned on
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and off with the flick of a switch. With most drugs, once they're ingested,
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they go and react everywhere, with little control. Building in the
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photocleavable unit provides the means to activate the molecule in a specific
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location at a specific time."
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One of Taylor's areas of expertise in synthetic organic chemistry is
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ultraviolet light damage leading to skin cancer. Sponsored by the National
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Cancer Institute, Taylor's work involves synthesizing genetic damage produced
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by sunlight and then studying the photoproducts produced by the damage, the
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processes of genetic mutations, and potential ways to reverse the damage or
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prevent it.
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In 1986, he and his team discovered the Dewar photoproduct, one of the chief
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cancer-causing products resulting from UV damage that is implicated in the
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beginning of skin cancer. In his skin cancer work, Taylor has created building
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blocks for DNA photoproducts essentially to produce pure compounds to study
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the cancer process.
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His current work was sparked by an interest in understanding the DNA breaks
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caused by ionizing radiation where a particle has enough energy to remove an
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electron from an atom or molecule, and in the process produces an ion and a
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free electron. More graphically, this kind of radiation is marked by breaking
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both strands of the DNA helix molecule, allowing no chance for the DNA to
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repair itself. While this is one of the most destructive features of ionizing
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radiation, the double strand break also makes ionizing radiation a useful
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therapeutic tool in cancer treatment, for instance.
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Taylor's breakthrough makes it possible to use DNA strand cleavage to turn on
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and/or off potentially useful antisense drugs. "Our motivation for doing this
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work was to see if we could generate the kinds of DNA breaks produced by
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ionizing radiation and see if that destructive act can be used beneficially,"
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Taylor says. "There is lots of interest in the basic questions of what kinds
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of double-stranded DNA breaks are difficult or easy to repair and how are
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these problems solved? This is an invention that has perhaps many different
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uses. Certainly, it makes biochemists look at light in a different way."
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