 |
|
Scientists discover new chemical reaction for DNA production in bacteria and viruses
April 17, 2009A team of researchers has discovered a new chemical reaction for producing one of the four nucleotides, or building blocks, needed to build DNA. The reaction includes an unusual first step, or mechanism, and unlike other known reactions that produce the DNA building block, uses an enzyme that speeds up, or catalyzes, the reaction without bonding to any of the compounds, or substrates, in the reaction.
The chemical reaction discovered by the researchers uses an enzyme called flavin-dependent thymidylate synthase, or FDTS. The enzyme is coded by the thyX gene and has been found primarily in bacteria and viruses, including several human pathogens and biological warfare agents. In the future, scientists may use this knowledge for the development of new antibacterial and antiviral drugs.
Supported with partial funding from the National Science Foundation (NSF) and led by Amnon Kohen, an associate professor in the departments of chemistry and molecular and cellular biology at the University of Iowa, the team reports their findings in the April 16, 2009, issue of Nature, Letters section.
Prior to the team's discovery, it was thought that thymidylate synthase, or TS, was the primary enzyme catalyzing a reaction that produced one of the four DNA building blocks called deoxy-thymidine monophosphate.
The TS enzyme is coded by the thyA and TYMS genes and is present in most multi-cellular forms of life, including humans.
Both the new and classical enzymatic reactions complete a key step in producing the DNA building block by adding a methyl group--one carbon atom attached to three hydrogen atoms--to the building block's precursor molecule called deoxy-uridine monophosphate, or dUMP.
Even though both reactions accomplish this key step, the reaction mechanisms, or steps, catalyzed by the FDTS and TS enzymes are structurally different.
Kohen and his team identified these differences using a traditional chemical method labeled isotopic substitution and a contemporary form of mass spectrometry using electron spray ionization. In particular, the team identified that the first step of the FTDS-catalyzed reaction involves the transfer of a proton and two electrons, known as a hydride, from a flavin co-factor molecule to dUMP whereas the first step of the TS-catalyzed reaction involves an amino acid from the enzyme's active site forming a bond with dUMP.
"This work nicely illustrates how chemists using traditional techniques and contemporary instrumentation methods can make substantial contributions to important and interesting problems in biology," said Charles Pibel, a program director in NSF's Division of Chemistry.
Since the two chemical reaction mechanisms used for the production of the DNA building block, and therefore DNA, are structurally different in humans and bacteria and viruses, and the enzymes used to catalyze the chemical reactions are different, the researchers' findings may assist with the development of structure-based antibiotics and antiviral drugs that selectively inhibit the activity of FDTS enzymes with little effect on TS enzymes--thereby combating pathogens causing anthrax, tuberculosis, botulism, syphilis, pneumonia, Lyme disease and other human diseases without interfering with human DNA synthesis.
"The proposed new catalytic path of the FDTS enzyme appears to be so very different from that of the classical TS enzyme that we hope that specific inhibitors against it will have little effect on DNA production in humans and thus may lead to development of new drugs with low toxicity. Also, some aspects of the proposed chemistry are not common in enzymology or biological chemistry in general, making the future testing of this mechanism very interesting and of potential broader impact," said Kohen.
National Science Foundation
Prior to the team's discovery, it was thought that thymidylate synthase, or TS, was the primary enzyme catalyzing a reaction that produced one of the four DNA building blocks called deoxy-thymidine monophosphate.
The TS enzyme is coded by the thyA and TYMS genes and is present in most multi-cellular forms of life, including humans.
Both the new and classical enzymatic reactions complete a key step in producing the DNA building block by adding a methyl group--one carbon atom attached to three hydrogen atoms--to the building block's precursor molecule called deoxy-uridine monophosphate, or dUMP.
Even though both reactions accomplish this key step, the reaction mechanisms, or steps, catalyzed by the FDTS and TS enzymes are structurally different.
Kohen and his team identified these differences using a traditional chemical method labeled isotopic substitution and a contemporary form of mass spectrometry using electron spray ionization. In particular, the team identified that the first step of the FTDS-catalyzed reaction involves the transfer of a proton and two electrons, known as a hydride, from a flavin co-factor molecule to dUMP whereas the first step of the TS-catalyzed reaction involves an amino acid from the enzyme's active site forming a bond with dUMP.
"This work nicely illustrates how chemists using traditional techniques and contemporary instrumentation methods can make substantial contributions to important and interesting problems in biology," said Charles Pibel, a program director in NSF's Division of Chemistry.
Since the two chemical reaction mechanisms used for the production of the DNA building block, and therefore DNA, are structurally different in humans and bacteria and viruses, and the enzymes used to catalyze the chemical reactions are different, the researchers' findings may assist with the development of structure-based antibiotics and antiviral drugs that selectively inhibit the activity of FDTS enzymes with little effect on TS enzymes--thereby combating pathogens causing anthrax, tuberculosis, botulism, syphilis, pneumonia, Lyme disease and other human diseases without interfering with human DNA synthesis.
"The proposed new catalytic path of the FDTS enzyme appears to be so very different from that of the classical TS enzyme that we hope that specific inhibitors against it will have little effect on DNA production in humans and thus may lead to development of new drugs with low toxicity. Also, some aspects of the proposed chemistry are not common in enzymology or biological chemistry in general, making the future testing of this mechanism very interesting and of potential broader impact," said Kohen.
National Science Foundation
Chemical Reaction Current Events and Chemical Reaction News RSSEngineers image nanostructure of a solid acid catalyst and boost its catalytic activity
The catalytic processes that facilitate the production of many chemicals and fuels could become much more environmentally friendly thanks to a breakthrough achieved by researchers from Lehigh and Rice Universities.
Researchers discover RNA repair system in bacteria
In new papers appearing this month in Science and the Proceedings of the National Academy of Sciences, University of Illinois biochemistry professor Raven H. Huang and his colleagues describe the first RNA repair system to be discovered in bacteria.
New aluminum-water rocket propellant promising for future space missions
Researchers are developing a new type of rocket propellant made of a frozen mixture of water and "nanoscale aluminum" powder that is more environmentally friendly than conventional propellants and could be manufactured on the moon, Mars and other water-bearing bodies.
Licence to go where no chemist has gone before
Scientists at The University of Nottingham have overcome one of the significant research challenges facing electrochemists. For the first time they have found a way of probing right into the heart of an electrochemical reaction.
Shedding light on cancer cells
Scientists label cells with coloured or glowing chemicals to observe how basic cellular activities differ between healthy and cancerous cells. Existing techniques for labelling cells are either too slow or too toxic to perform on live cells.
New X-ray technique illuminates reactivity of environmental contaminants
A chemical reaction can occur in the blink of an eye.
Conflict between plant and animal hormones in the insect gut?
Cis-OPDA (12-oxophytodienoic acid) is a highly reactive plant hormone which simultaneously serves as a precursor molecule of the metabolic "master switch" jasmonic acid.
This idea doesn't stink: New tech cuts industrial odors, pollutants
A North Carolina State University researcher has devised a new technology that really does not stink. In fact, it could be the key to eliminating foul odors and air pollutants emitted by industrial chicken rendering facilities and - ultimately - large-scale swine feedlots.
Newly found DNA catalysts cleave DNA with water molecule
Better tools for manipulating DNA in the laboratory may soon be possible with newly discovered deoxyribozymes (catalytic DNA) capable of cleaving single-stranded DNA, researchers at the University of Illinois say.
Scripps Research scientists find early evolution maximized the 'spellchecking' of protein sequences
As letters of the alphabet spell out words, when amino acids are linked to one another in a particular order they "spell out" proteins.
More Chemical Reaction Current Events and Chemical Reaction News Articles
 |
Chemical Reaction Engineering, 3rd Edition by Octave Levenspiel (Author) Chemical reaction engineering is concerned with the exploitation of chemical reactions on a commercial scale. It's goal is the successful design and operation of chemical reactors. This text emphasizes qualitative arguments, simple design methods, graphical procedures, and frequent comparison of capabilities of the major reactor types. Simple ideas are treated first, and are then extended to the more complex. |
|
Bill Nye the Science Guy: Chemical Reactions Classroom Edition [Interactive DVD] Starring: Bill Nye the Science Guy Directed By: Erin Gottlieb & James McKenna With more than 16 Emmys® to its credit and legions of fans, it's easy to see why the Bill Nye the Science Guy Series is one of the most popular educational series of all time. Beloved by teachers and students alike, Bill Nye and his unique brand of Way Cool Science make complex science principles accessible for all learners. In Chemical Reactions, have a blast watching the explosive examples Bill Nye uses to explain how everything is made of chemicals. Correlated to National Science Education Standards for grades 4-8, this Classroom Edition DVD includes Public Performance Rights, exclusive interviews with Way Cool Scientists, and printable educator's guide complete with assessment tool. | |
 |
Chemical Reaction by The Chemical Brothers Includes Seven Tracks by the Chemical Brothers. |
|
Hua Xue Fan Ying Gong Cheng Yu Gong Yi = Chemical Reaction E by China Intl Book Trading Corp | |
 |
Scientific Explorer's Fizzy Foamy Science Kit of Safe Chemical Reactions by Scientific Explorer Enjoy mixing safe powders to create solutions that foam and fizz. Learn about fun chemistry ideas while developing important science skills. |
 |
SciEd Chemical Reactions Lab Investigation by Neo/Sci Corporation Chemistry Kit, Chemical Reactions Lab Investigation; Series inquiry-based experiments, students discover definition of chemical reaction and understand nature, mechanism, properties, applications in chemistry and biology |
 |
Chemical Reaction Agent Orange (Primary Contributor) |
|
Investigating Chemical Reactions (Discovery Channel School) Also With: Discovery Channel School (Primary Contributor) | |
 |
Elements of Chemical Reaction Engineering (4th Edition) by H. Scott Fogler (Author) Great structure to ensure principles are clearly understood and can be appliedafter the completion of the book. This is achieved first through a discussion ofcritical thinking and how Socratic questioning is at the heart of criticalthinking, followed by examples of critical thinking questions, and then finallyexercises on critical thinking. Contains more coverage of industrial chemistrywith real reactors and real reactions and extends the wide range of applicationsto which chemical reaction engineering principles can be applied. Through theuse of an interactive CDROM that is shrunk wrapped with the text andcorresponding web page the book and resource material is designed to addressdifferent student learning styles according to the Felder-Solomon LearningStyle Index. (e.g.... |
 |
Historic Print (S): [Scientific apparatus used by Lavoisier in studying chemical reactions in combustion of by Olde Yankee Map and Photo Shoppe This is a museum quality, reproduction print on premium paper with archival/UV resistant inks. The framed work is single matted (ivory), under acrylic glass, with a hanging wire. Date: [published 1789] Subject: Notes: Illus. in: Traite elementaire de chimie / Antoine Laurent Lavoisier. Paris : Cuchet, 1789, plate 4. Published in: The tradition of science / Leonard C. Bruno. Washington, D.C. : Library of Congress, 1987, p. 187. Format: Scientific illustrations 1780-1790.Engravings 1780-1790. SOURCE: Library of Congress |
| © 2009 BrightSurf.com |