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Researcher Solves Mystery about Proteins that Package the Genome
October 08, 2009A Florida State University College of Medicine researcher has solved a century-old mystery about proteins that play a vital role in the transfer of the human genetic code from one cell to another. The discovery could lead to finding new ways to help the body fight a variety of diseases, including cancer.
For more than a hundred years, the best scientific evidence supported a belief that histones -- responsible for packaging DNA inside the nucleus of cells -- are highly stable proteins not rapidly degraded by the body. Yet, researchers have not previously been able to explain why free histones, if they are not degraded as other proteins are, do not accumulate in large amounts within human cells.
Akash Gunjan, an assistant professor in the department of biomedical sciences, has found evidence supporting his hypothesis that there actually are two pools of histones: one used in packaging DNA that is very stable and remains in the cell for more than a year in some cases and the other made in excess by the cells to ensure that enough histones are available for packaging the DNA. Not having enough histones results in cell death. Those excess histones, Gunjan suggests, are rapidly degraded as are other proteins.
The discovery is important because it sheds light on the way the body is able to regulate proteins for various complex tasks. Such knowledge may allow scientists to learn how to manipulate protein regulation to fight cancerous cells and thwart other disease processes. Gunjan and co-authors Rakesh Kumar Singh, Marie-Helene Miquel Kabbaj and Johanna Paik, all from the College of Medicine, published their findings in the journal Nature Cell Biology.
"This has major ramifications for all the different things the DNA does," Gunjan said. "Because if DNA contains genes and DNA is packaged around histones, then histones are at the most fundamental level regulating whether those genes are turned on or off."
If scientists are able to determine how genes for cancer and other diseases are turned on or off, it might lead to ways to help the body rid itself of or better control disease.
For decades scientists have been captivated by the way the body selectively uses proteins in essential functions, storing or disposing of them when they are not needed. For example, eating a hamburger requires a certain set of enzyme proteins for digestion. If the enzymes are not deactivated or degraded following digestion, the consequences would be disastrous.
"They'll start to digest things you do not want them to digest," Gunjan said. "After finishing your hamburger, if these enzymes started digesting proteins in your intestines, in your stomach wall and so on, that would not be a good thing."
To manage proteins when they are not needed, the body naturally degrades them through a process known as proteolysis. Histones in most cases, however, must be preserved for long periods of time because they make it possible to fold strands of DNA measuring about 3 feet in length within the microscopic nucleus of a typical human cell. Histones used in that process must be able to avoid degradation to preserve the body's ability to pass on its genetic code from cell to cell.
Histones, the first proteins to be purified, have been a topic of research by scientists for nearly 125 years. The mystery evolved as scientists discovered that cells have multiple copies of histone genes and make far more histones than what is needed for wrapping DNA, yet were unable to explain the apparent contradiction.
"On the one hand, you cannot find the excess histones," Gunjan said. "On the other hand, if you propose it gets degraded, then you try to measure its rate of degradation and you find that it hangs around for several months to more than a year."
Gunjan spent five years seeking answers to the mystery before his discovery of two separate pools of histones.
"Not only did we show for the first time that histones are unstable -- they get rapidly degraded -- we also showed this has important consequences for DNA damage and repair processes that have a major impact on cancer formation," Gunjan said.
Additionally, previous studies published by other researchers suggest that the newly discovered regulated histone proteolysis may make significant contributions to many diverse biological processes, from the resetting of epigenetic marks on histones that help regulate gene expression, to sperm formation.
"All of this together suggests this is a very important phenomenon," Gunjan said.
Florida State University
The discovery is important because it sheds light on the way the body is able to regulate proteins for various complex tasks. Such knowledge may allow scientists to learn how to manipulate protein regulation to fight cancerous cells and thwart other disease processes. Gunjan and co-authors Rakesh Kumar Singh, Marie-Helene Miquel Kabbaj and Johanna Paik, all from the College of Medicine, published their findings in the journal Nature Cell Biology.
"This has major ramifications for all the different things the DNA does," Gunjan said. "Because if DNA contains genes and DNA is packaged around histones, then histones are at the most fundamental level regulating whether those genes are turned on or off."
If scientists are able to determine how genes for cancer and other diseases are turned on or off, it might lead to ways to help the body rid itself of or better control disease.
For decades scientists have been captivated by the way the body selectively uses proteins in essential functions, storing or disposing of them when they are not needed. For example, eating a hamburger requires a certain set of enzyme proteins for digestion. If the enzymes are not deactivated or degraded following digestion, the consequences would be disastrous.
"They'll start to digest things you do not want them to digest," Gunjan said. "After finishing your hamburger, if these enzymes started digesting proteins in your intestines, in your stomach wall and so on, that would not be a good thing."
To manage proteins when they are not needed, the body naturally degrades them through a process known as proteolysis. Histones in most cases, however, must be preserved for long periods of time because they make it possible to fold strands of DNA measuring about 3 feet in length within the microscopic nucleus of a typical human cell. Histones used in that process must be able to avoid degradation to preserve the body's ability to pass on its genetic code from cell to cell.
Histones, the first proteins to be purified, have been a topic of research by scientists for nearly 125 years. The mystery evolved as scientists discovered that cells have multiple copies of histone genes and make far more histones than what is needed for wrapping DNA, yet were unable to explain the apparent contradiction.
"On the one hand, you cannot find the excess histones," Gunjan said. "On the other hand, if you propose it gets degraded, then you try to measure its rate of degradation and you find that it hangs around for several months to more than a year."
Gunjan spent five years seeking answers to the mystery before his discovery of two separate pools of histones.
"Not only did we show for the first time that histones are unstable -- they get rapidly degraded -- we also showed this has important consequences for DNA damage and repair processes that have a major impact on cancer formation," Gunjan said.
Additionally, previous studies published by other researchers suggest that the newly discovered regulated histone proteolysis may make significant contributions to many diverse biological processes, from the resetting of epigenetic marks on histones that help regulate gene expression, to sperm formation.
"All of this together suggests this is a very important phenomenon," Gunjan said.
Florida State University
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Histones and Other Basic Nuclear Proteins (Crc Series in the Biochemistry and Molecular Biology of the Cell Nucleus) by Gary S. Stein (Author), Janet L. Stein (Author) This comprehensive book is a compilation of Professor Lubomir S. Hnilica's twenty years of research experimentally addressing the chemistry and the biological functions of chromosomal proteins. The histones and other nuclear proteins found associated with DNA in a number of tissues and cell types are featured. Lubomir Hnilica played a major role in establishing the extent to which these basic chromosomal polypeptides are conserved and the manner in which they interact with DNA to modify chromatin structure. In addition, non-histone chromosomal protein research is explained, and his technique of applying several biochemical and immunological approaches to the characterization of this complex and heterogeneous class of chromosomal polypeptides is discussed. Highlighted is the use of... |
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The structure and biological function of histones (CRC uniscience series) by Lubomir S Hnilica (Author) | |
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Progress In Non Histone Protein Research by Bekhor (Author) | |
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Histone Deacetylases: Transcriptional Regulation and Other Cellular Functions (Cancer Drug Discovery and Development) by Eric Verdin (Editor) A panel of leading investigators summarizes and synthesizes the new discoveries in the rapidly evolving field of histone acetylation as a key regulatory mechanism for gene expression. The authors describe what has been learned about these proteins, including the identification of the enzymes, the elucidation of the enzymatic mechanisms of action, and the identification of their substrates and their partners. They also review the structures that have been solved for a number of enzymes-both alone and in complex with small molecule inhibitors-and the biological roles of the several histone deacetylases (HDAC) genes that have been knocked out in mice. |
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Sirtuins (histone deacetylases III) in the cellular response to DNA damage-Facts and hypotheses [An article from: DNA Repair] by M. Kruszewski (Author), I. Szumiel (Author) This digital document is a journal article from DNA Repair, published by Elsevier in . The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: Histone deacetylases (HDAC) are an important member of a group of enzymes that modify chromatin conformation. Homologues of the yeast gene SIR2 in mammalian cells code type III histone deacetylases (HDAC III, sirtuins), dependent on NAD^+ and inhibited by nicotinamide. In yeast cells, Sir2 participates in repression of transcriptional activity and in DNA double strand break repair. It is assumed that certain sirtuins may play a similar role in mammalian cells, by modifying chromatin structure and thus, altering the... |
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DNA-PK is responsible for enhanced phosphorylation of histone H2AX under hypertonic conditions [An article from: DNA Repair] by T. Reitsema (Author), D. Klokov (Author), J.P. Banath (Author), P.L. Olive (Author) This digital document is a journal article from DNA Repair, published by Elsevier in . The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: Exposure of cells to hypertonic medium after X-irradiation results in a 3-4-fold increase in the phosphorylation of histone H2AX (@cH2AX) at sites of radiation-induced DNA double-strand breaks. This increase was previously associated with salt-induced radiosensitization and inhibition of repair of DNA double-strand breaks. To examine possible mechanisms for the increase in foci size, chemical inhibitors of kinase and phosphatase activity and cell lines deficient in ATM and DNA-PK, two kinases known to phosphorylate H2AX, were... |
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Histone acetylation, chromatin remodelling, transcription and nucleotide excision repair in S. cerevisiae: studies with two model genes [An article from: DNA Repair] by Y. Teng (Author), Y. Yu (Author), J.A. Ferreiro (Author), R. Waters (Author) This digital document is a journal article from DNA Repair, published by Elsevier in . The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: We describe the technology and two model systems in yeast designed to study nucleotide excision repair (NER) in relation to transcription and chromatin modifications. We employed the MFA2 and MET16 genes as models. How transcription-coupled (TCR) and global genome repair (GGR) operate at the transcriptionally active and/or repressed S. cerevisiae MFA2 locus, and how this relates to nucleosome positioning are considered. We discuss the role of the Gcn5p histone acetyltransferase, also associated with MFA2's transcriptional... |
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DNA-PK phosphorylates histone H2AX during apoptotic DNA fragmentation in mammalian cells [An article from: DNA Repair] by B. Mukherjee (Author), C. Kessinger (Author), J. Kobayashi (Author), B. Chen (Author) This digital document is a journal article from DNA Repair, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: The phosphorylation of histone H2AX at serine 139 is one of the earliest responses of mammalian cells to ionizing radiation-induced DNA breaks. DNA breaks are also generated during the terminal stages of apoptosis when chromosomal DNA is cleaved into oligonucleosomal pieces. Apoptotic DNA fragmentation and the consequent chromatin condensation are important for efficient clearing of genomic DNA and nucleosomes and for protecting the organism from auto-immmunization and oncogenic transformation. In this study, we... |
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Histones and Other Nuclear Proteins by Harris Busch (Author) | |
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The Histone Code and Beyond: New Approaches to Cancer Therapy (Ernst Schering Foundation Symposium Proceedings) by S.L. Berger (Editor), O. Nakanishi (Editor), B. Haendler (Editor) Methylation of DNA at cytosine residues as well as post-translational modifications of histones, including phosphorylation, acetylation, methylation and ubiquitylation, contribute to the epigenetic information carried by chromatin. These changes play an important role in the regulation of gene expression by modulating the access of regulatory factors to the DNA. The use of a combination of biochemical, genetic and structural approaches has allowed demonstration of the role of chromatin structure in transcriptional control. The structure of nucleosomes has been elucidated and enzymes involved in DNA or histone modifications have been extensively characterized. Since deregulation of epigenetic marks has been reported in many cancers, a better understanding of the underlying molecular... |
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