 |
|
Scientists discover a genetic code for organizing DNA within the nucleus
July 20, 2006DNA - the long, thin molecule that carries our hereditary material - is compressed around protein scaffolding in the cell nucleus into tiny spheres called nucleosomes. The bead-like nucleosomes are strung along the entire chromosome, which is itself folded and packaged to fit into the nucleus. What determines how, when and where a nucleosome will be positioned along the DNA sequence? Dr. Eran Segal and research student Yair Field of the Computer Science and Applied Mathematics Department at the Weizmann Institute of Science have succeeded, together with colleagues from Northwestern University in Chicago, in cracking the genetic code that sets the rules for where on the DNA strand the nucleosomes will be situated. Their findings appeared today in Nature.
The precise location of the nucleosomes along the DNA is known to play an important role in the cell's day to day function, since access to DNA wrapped in a nucleosome is blocked for many proteins, including those responsible for some of life's most basic processes. Among these barred proteins are factors that initiate DNA replication, transcription (the transfer of genetic information from DNA to RNA) and DNA repair. Thus, the positioning of nucleosomes defines the segments in which these processes can and can't take place. These limitations are considerable: Most of the DNA is packaged into nucleosomes. A single nucleosome contains about 150 genetic bases (the "letters" that make up a genetic sequence), while the free area between neighboring nucleosomes is only about 20 bases long. It is in these nucleosome-free regions that processes such as transcription can be initiated.
For many years, scientists have been unable to agree whether the placement of nucleosomes in live cells is controlled by the genetic sequence itself. Segal and his colleagues managed to prove that the DNA sequence indeed encodes "zoning" information on where to place nucleosomes. They also characterized this code and then, using the DNA sequence alone, were able to accurately predict a large number of nucleosome positions in yeast cells.
Segal and his colleagues accomplished this by examining around 200 different nucleosome sites on the DNA and asking whether their sequences have something in common. Mathematical analysis revealed similarities between the nucleosome-bound sequences and eventually uncovered a specific "code word." This "code word" consists of a periodic signal that appears every 10 bases on the sequence. The regular repetition of this signal helps the DNA segment to bend sharply into the spherical shape required to form a nucleosome. To identify this nucleosome positioning code, the research team used probabilistic models to characterize the sequences bound by nucleosomes, and they then developed a computer algorithm to predict the encoded organization of nucleosomes along an entire chromosome.
The team's findings provided insight into another mystery that has long been puzzling molecular biologists: How do cells direct transcription factors to their intended sites on the DNA, as opposed to the many similar but functionally irrelevant sites along the genomic sequence? The short binding sites themselves do not contain enough information for the transcription factors to discern between them. The scientists showed that basic information on the functional relevance of a binding site is at least partially encoded in the nucleosome positioning code: The intended sites are found in nucleosome-free segments, thereby allowing them to be accessed by the various transcription factors. In contrast, spurious binding sites with identical structures that could potentially sidetrack transcription factors are conveniently situated in segments that form nucleosomes, and are thus mostly inaccessible.
Since the proteins that form the core of the nucleosome are among the most evolutionarily conserved in nature, the scientists believe the genetic code they identified should also be conserved in many organisms, including humans. Several diseases, such as cancer, are typically accompanied or caused by mutations in the DNA and the way it organizes into chromosomes. Such mutational processes may be influenced by the relative accessibility of the DNA to various proteins and by the organization of the DNA in the cell nucleus. Therefore, the scientists believe that the nucleosome positioning code they discovered may aid scientists in the future in understanding the mechanisms underlying many diseases.
American Committee for the Weizmann Institute of Science
Segal and his colleagues accomplished this by examining around 200 different nucleosome sites on the DNA and asking whether their sequences have something in common. Mathematical analysis revealed similarities between the nucleosome-bound sequences and eventually uncovered a specific "code word." This "code word" consists of a periodic signal that appears every 10 bases on the sequence. The regular repetition of this signal helps the DNA segment to bend sharply into the spherical shape required to form a nucleosome. To identify this nucleosome positioning code, the research team used probabilistic models to characterize the sequences bound by nucleosomes, and they then developed a computer algorithm to predict the encoded organization of nucleosomes along an entire chromosome.
The team's findings provided insight into another mystery that has long been puzzling molecular biologists: How do cells direct transcription factors to their intended sites on the DNA, as opposed to the many similar but functionally irrelevant sites along the genomic sequence? The short binding sites themselves do not contain enough information for the transcription factors to discern between them. The scientists showed that basic information on the functional relevance of a binding site is at least partially encoded in the nucleosome positioning code: The intended sites are found in nucleosome-free segments, thereby allowing them to be accessed by the various transcription factors. In contrast, spurious binding sites with identical structures that could potentially sidetrack transcription factors are conveniently situated in segments that form nucleosomes, and are thus mostly inaccessible.
Since the proteins that form the core of the nucleosome are among the most evolutionarily conserved in nature, the scientists believe the genetic code they identified should also be conserved in many organisms, including humans. Several diseases, such as cancer, are typically accompanied or caused by mutations in the DNA and the way it organizes into chromosomes. Such mutational processes may be influenced by the relative accessibility of the DNA to various proteins and by the organization of the DNA in the cell nucleus. Therefore, the scientists believe that the nucleosome positioning code they discovered may aid scientists in the future in understanding the mechanisms underlying many diseases.
American Committee for the Weizmann Institute of Science
DNA Current Events and DNA News RSSDeciphering the regulatory code
Embryonic development is like a well-organised building project, with the embryo's DNA serving as the blueprint from which all construction details are derived.
Male sabertoothed cats were pussycats compared to macho lions
Despite their fearsome fangs, male sabertoothed cats may have been less aggressive than many of their feline cousins, says a new study of male-female size differences in extinct big cats.
Autism Consortium symposium draws record number of researchers, advocates, parents for autism update
The Autism Consortium, an innovative collaboration of researchers, clinicians, funders and families dedicated to catalyzing research and enhancing clinical care for autism spectrum disorders (ASDs), held its fourth annual symposium on October 28th, 2009, at Harvard Medical School in Boston.
Researchers identify drug candidate for treating spinal muscular atrophy
A chemical cousin of the common antibiotic tetracycline might be useful in treating spinal muscular atrophy (SMA), a currently incurable disease that is the leading genetic cause of death in infants.
Conserving historic apple trees
The apple trees of yesteryear are slowly disappearing. Many apple varieties common in the United States a century ago can no longer be found in today's orchards and nurseries.
Tiny injector to speed development of new, safer, cheaper drugs
It's no bigger than a stamp packet but it has the potential to allow rapid development of a new generation of drugs and genetic engineering organisms, and to better control in-vitro fertilization.
Taking aim at mysterious DNA structures in the battle against cancer
Designers of anti-cancer drugs are aiming their arrows at mysterious chunks of the genetic material DNA that may play a key role in preventing the growth and spread of cancer cells, according to an article in the current issue of Chemical & Engineering News, ACS' weekly newsmagazine.
Tags reveal white sharks have neighborhoods in the north Pacific, say Stanford researchers
The white shark may be the ultimate loner of the ocean, cruising thousands of miles in a solitary trek, but a team of researchers has discovered that the sharks have maintained such a consistent pattern of migration that over tens of thousands of years the white sharks in the northeastern Pacific Ocean have separated themselves into a population genetically distinct from sharks elsewhere in the world.
Clinical tests begin on medication to correct Fragile X defect
NIH-supported scientists at Seaside Therapeutics in Cambridge, Mass., are beginning a clinical trial of a potential medication designed to correct a central neurochemical defect underlying Fragile X syndrome, the most common inherited cause of intellectual disability.
A Potential Anti-cancer Agent
Pateamine A (PatA), a natural product first isolated from marine sponges, has attracted considerable attention as a potential anti-cancer agent, and now a new activity has been found for it, which may reveal yet another anti-cancer mechanism.
More DNA Current Events and DNA News Articles
 |
DNA: The Secret of Life by James D. Watson (Author) James Watson, the co-discoverer of the structure of DNA and author of the international bestseller "The Double Helix" tells the story of the amazing molecule since its discovery fifty years ago, following modern genetics from his own Nobel prize-winning work in the fifties to today's Dolly the sheep, designer babies and GM foods. Professor Watson introduces the science of modern genetics, along with its history and its implications, in this magnificent guide to one of the most triumphant achievements of human science. |
 |
Thames & Kosmos Genetics and DNA by Thames & Kosmos In depth investigation of genetics and DNA. Isolate the DNA from a tomato, learn about inheritance and how traits are expressed, build a DNA model, breed bacteria to experiment with genetic engineering. The full-color, 48-page manual guides your experiments. |
 |
DNA Science: A First Course, Second Edition by David Micklos (Author), Greg A. Freyer (Author) This is the second edition of a highly successful textbook (over 50,000 copies sold) in which a highly illustrated, narrative text is combined with easy–to–use thoroughly reliable laboratory protocols. It contains a fully up–to–date collection of 12 rigorously tested and reliable lab experiments in molecular biology, developed at the internationally renowned Dolan DNA Learning Center of Cold Spring Harbor Laboratory, which culminate in the construction and cloning of a recombinant DNA molecule. Proven through more than 10 years’ of teaching at research and nonresearch colleges and universities, junior colleges, community colleges, and advanced biology programs in high school, this book has been successfully integrated into introductory biology, general biology,... |
 |
DNA on DNA by DNA Previously released on CD by No More Records, now issued on a limited edition 2LP featuring newly-discovered songs exclusive to this LP: "Pompeii," "Shrinking Thing," "Drinking Water," plus two encores from DNA's final performance at CBGB's. Definitive collection of studio and live recordings by New York's seminal no wave band DNA. Surviving two line-ups over a brief period of four years; this highly influential, strikingly original and extremely under-recorded band left a huge void in its wake. Formed in 1978, Brazilian-raised singer/guitarist Arto Lindsay hastily assembled an international trio of non-musicians. Robin Crutchfield played keyboard and Japan's Ikue Mori played drums. DNA played their first gig within weeks and recorded their first 7" shortly afterwards. The ear of Brian... |
 |
Genes and DNA (Kingfisher Knowledge) by Richard Walker (Author), Steve Jones (Author) Genes & DNA explores modern genetics, from an investigation of genes and their function, to forensics, therapy, and cloning. |
 |
Science Wiz DNA Kit by Sciencewiz The central concepts of molecular biology becomes child's play in this set of camp favorites. 40 Page science book and materials with 8 Major Activities. Makes the DNA revolution accessible. Extract DNA from a fruit Probe and spool real DNA Build a double helix Solve a chromosome puzzle Is it a boy or a girl? Play the gene construction game Country of Origin: U.S.A., China & Hong Kong. |
 |
DNA & Genealogy by Colleen Fitzpatrick (Author), Andrew Yeiser (Author) DNA & Genealogy is more than a textbook on DNA analysis for genealogy. Beginner, intermediate, and advanced readers will all find this book fascinating. In addition to tutorials on the use of DNA for genealogy, DNA & Genealogy contains many unusual sidelights on "DNA in the News" and "Weird DNA". Do you know that there are people who have more than one DNA profile? Would you like to know about the DNA analysis of the Tyrolean Iceman? What about DNA and Exo-biology? DNA & Genealogy has all of this and much, much more. |
 |
Olay Regenerist Advanced Anti-Aging Dna Superstructure UV Cream SPF 25, 1.7-Ounce Box by Olay Introducing Olay Regenerist DNA Superstructure UV Cream. Helps block direct DNA damaging rays to help protect skin and maintain collagen's structural integrity. Hydrates to help rebuild cellular surface structure & restore firmness. This new anti-aging formula hydrates to help rebuild cellular surface structure and restore firmness, regenerating a more youthful appearance. SPF 25 helps block direct DNA damaging rays to help protect skin and maintain collagen's structural integrity. Powerful anti-oxidants help protect the skin's surface from free radical damage. Premium skin feel, suitable for daily use. Create the perfect skin care solution for you with the Regenerist line of advanced anti-aging products. Broad Spectrum SPF 25 UVA/UVB Sunscreen |
 |
DNA Starring: Tom Conti Also With: Samantha Bond (Performer) Forensics expert Joe Donovan uses science to snare killers—and save himself. Award-winning actor Tom Conti (Shirley Valentine; Reuben, Reuben) stars as Joe Donovan, an accomplished but troubled criminologist who returns from a mental breakdown to lead Manchester’s crack Forensic Investigations Unit. Called in to consult on a murder case that suspiciously resembles the one that drove him into near madness years ago, Donovan redeems his reputation and rediscovers his devotion to the job. Yet his professional dedication bleeds into his personal life, alienating his wife (Samantha Bond, Die Another Day, Tomorrow Never Dies) but appealing to his son (Ryan Cartwright, The Grimleys), who wants to follow in his father’s footsteps. Packed with fascinating procedural details and... |
 |
Signature in the Cell: DNA and the Evidence for Intelligent Design by Stephen C. Meyer (Author) One hundred fifty years ago, Charles Darwin revolutionized biology, but did he refute intelligent design (ID)? In Signature in the Cell, Stephen Meyer argues that he did not. Much confusion surrounds the theory of intelligent design. Frequently misrepresented by the media, politicians, and local school boards, intelligent design can be defended on purely scientific grounds in accordance with the same rigorous methods that apply to every proposed origin-of-life theory. Signature in the Cell is the first book to make a comprehensive case for intelligent design based upon DNA. Meyer embarks on an odyssey of discovery as he investigates current evolutionary theories and the evidence that ultimately led him to affirm intelligent design. Clearly defining what ID is and is... |
| © 2009 BrightSurf.com |