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EuroDYNA takes lid off the genome
June 16, 2008European researchers have made significant progress unravelling how genes are governed and why this sometimes goes wrong in disease. The key lies in the dynamic ever-changing structure of the chromatin, which is the underlying complex of protein and DNA making up the chromosomes in which almost all genes are housed within the genome. The way this structure changes and responds to external signalling molecules within the cell determines how and when genes are expressed and also the mechanisms used to repair DNA damaged by a variety of internal and external insults, such as ultra violet radiation and free radical by-products of metabolism.
Understanding the structure of chromatin and its interactions with proteins and RNA within the cell was the goal of the European Science Foundation's (ESF) EuroDYNA programme, which held its last conference at the Wellcome Trust Conference Centre near Cambridge in May 2008. The study of genome structure involves interaction between various disciplines including cell biology, molecular physics, biomechanics and bioinformatics, as well as access to a wide range of expensive equipment such as electron microscopes, supercomputers, and scanners for simultaneous profiling of RNA expression across the whole genome. EuroDYNA helped broker these collaborations and enable projects to develop the critical mass needed to make real progress.
The expression of genes involves an apparatus comprised mostly of proteins for reading the DNA, leading to production of RNA. This RNA in turn is either transported within the cell to the protein factory called the ribosome, where the code is translated into proteins, or else it interacts with other genes to control their expression in turn. These processes are intimately related to the constantly changing physical and chemical structure of the chromatin. Furthermore the overall state of the genome evolves during the life cycle of the cell, leading to its duplication if and when the cell eventually divides. All these inter-related processes need to be understood in order to unravel the complex network of mechanisms controlling gene expression.
One of the big fundamental questions tackled within EuroDYNA concerned the detailed structure of how the DNA double helix is folded in the nucleus of higher organisms. Although the double helix structure was discovered by Crick and Watson in 1953, the way it folds and stretches such that it fits in the cell nucleus is only now becoming clear, as is its relevance both for cell replication and gene expression. At the EuroDYNA conference, John van Noort from Leiden University in the Netherlands reported that the DNA molecule, which in humans and most mammals is about two metres in length but only 2 nanometres in diameter, is coiled up like a spring in a solenoid structure. In such a folded structure it behaves according to the well known Hooke's law, stating that up to a certain point the extension is proportional to the force applied. It turns out chromatin is a very elastic molecular complex, capable of stretching to three times its normal rest length without breaking, according to van Noort. Even more remarkably - and here it differs from a familiar metal spring - even if stretched beyond three times its rest length, the chromatin solenoid is capable of repairing itself and regaining its former shape and elasticity.
Indeed the ability of DNA to repair itself is essential for the long term survival of the cell and ultimately of the whole organism. DNA damage occurs not just from factors outside the cell nucleus, but also during the process of cell division (mitosis). The overall objective is to hand down the correct genetic code to the daughter cells during mitosis, a process so important that a number of surveillance and repair systems have been put in place to ensure its completion. One of those systems is called PRR (Post Replicative Repair) and it is highly conserved among all organisms, from bacteria to eukarya. PRR was discovered in the 1970s, but here again the detailed mechanisms are only now being elicited. At the EuroDYNA conference, Simone Sabbioneda from the University of Sussex presented new findings about one of the key PRR mechanisms called Translesion DNA Synthesis (TLS). This project, like some of the others, involved direct observation of processes as they take place in living cells, in this case using a technique called Fluorescence Recovery after Photobleaching. This comprises an optical microscope combined with a probe to observe the radiation emitted (the fluorescence) by molecules within a cell in response to a laser source. Such work is yielding important clues on how the PRR pathways work, hoping to help in the long term campaign to find novel, more specific, treatments for cancer, without the side effects of current therapies based on surgery, radiotherapy, or chemotherapy.
One EuroDYNA project however yielded a more immediate insight into a treatment already used to alleviate the symptoms of another important disease, MS (multiple sclerosis). Pavel Kovarik from the University of Vienna's Department of Microbiology and Immunology noted that the only compound capable of alleviating MS symptoms was the protein interferon beta. This resembles the interferon produced naturally by the body in response to infection, but until now it has not been known how it relieves symptoms for MS sufferers. However Kovarik and colleagues have shown that interferon works by upregulating (increasing production of) members of the protein family Tristetraprolin (TTP), which have an anti-inflammatory affect by in turn inhibiting production of pro-inflammatory agents. "We have demonstrated a novel function for interferon," said Kovarik. By understanding how it works, there is the potential for delivering interferon beta more effectively for treating MS.
There were other projects within EuroDYNA with great therapeutic potential, many of which will continue, but which would benefit greatly from an extension to this highly successful programme.
European Science Foundation
One of the big fundamental questions tackled within EuroDYNA concerned the detailed structure of how the DNA double helix is folded in the nucleus of higher organisms. Although the double helix structure was discovered by Crick and Watson in 1953, the way it folds and stretches such that it fits in the cell nucleus is only now becoming clear, as is its relevance both for cell replication and gene expression. At the EuroDYNA conference, John van Noort from Leiden University in the Netherlands reported that the DNA molecule, which in humans and most mammals is about two metres in length but only 2 nanometres in diameter, is coiled up like a spring in a solenoid structure. In such a folded structure it behaves according to the well known Hooke's law, stating that up to a certain point the extension is proportional to the force applied. It turns out chromatin is a very elastic molecular complex, capable of stretching to three times its normal rest length without breaking, according to van Noort. Even more remarkably - and here it differs from a familiar metal spring - even if stretched beyond three times its rest length, the chromatin solenoid is capable of repairing itself and regaining its former shape and elasticity.
Indeed the ability of DNA to repair itself is essential for the long term survival of the cell and ultimately of the whole organism. DNA damage occurs not just from factors outside the cell nucleus, but also during the process of cell division (mitosis). The overall objective is to hand down the correct genetic code to the daughter cells during mitosis, a process so important that a number of surveillance and repair systems have been put in place to ensure its completion. One of those systems is called PRR (Post Replicative Repair) and it is highly conserved among all organisms, from bacteria to eukarya. PRR was discovered in the 1970s, but here again the detailed mechanisms are only now being elicited. At the EuroDYNA conference, Simone Sabbioneda from the University of Sussex presented new findings about one of the key PRR mechanisms called Translesion DNA Synthesis (TLS). This project, like some of the others, involved direct observation of processes as they take place in living cells, in this case using a technique called Fluorescence Recovery after Photobleaching. This comprises an optical microscope combined with a probe to observe the radiation emitted (the fluorescence) by molecules within a cell in response to a laser source. Such work is yielding important clues on how the PRR pathways work, hoping to help in the long term campaign to find novel, more specific, treatments for cancer, without the side effects of current therapies based on surgery, radiotherapy, or chemotherapy.
One EuroDYNA project however yielded a more immediate insight into a treatment already used to alleviate the symptoms of another important disease, MS (multiple sclerosis). Pavel Kovarik from the University of Vienna's Department of Microbiology and Immunology noted that the only compound capable of alleviating MS symptoms was the protein interferon beta. This resembles the interferon produced naturally by the body in response to infection, but until now it has not been known how it relieves symptoms for MS sufferers. However Kovarik and colleagues have shown that interferon works by upregulating (increasing production of) members of the protein family Tristetraprolin (TTP), which have an anti-inflammatory affect by in turn inhibiting production of pro-inflammatory agents. "We have demonstrated a novel function for interferon," said Kovarik. By understanding how it works, there is the potential for delivering interferon beta more effectively for treating MS.
There were other projects within EuroDYNA with great therapeutic potential, many of which will continue, but which would benefit greatly from an extension to this highly successful programme.
European Science Foundation
Chromatin Current Events and Chromatin News RSSGerton Lab determines the composition of centromeric chromatin
The Stowers Institute's Gerton Lab has provided new evidence to clarify the structure of nucleosomes containing Cse4, a centromere-specific histone protein required for proper kinetochore function, which plays a critical role in the process of mitosis. The work, conducted in yeast cells, was published in the most recent issue of Molecular Cell.
Researchers identify protein-telomere interactions that could be key in treating cancer
A team of researchers from The Wistar Institute have shown that a large non-coding RNA in mammals and yeast plays a central role in helping maintain telomeres, the tips of chromosomes that contain important genetic information and help regulate cell division.
Protein plays unexpected role protecting chromosome tips
A protein specialist that opens the genomic door for DNA repair and gene expression also turns out to be a multi-tasking workhorse that protects the tips of chromosomes and dabbles in a protein-destruction complex, a team lead by researchers at The University of Texas M. D. Anderson Cancer Center reports in the Aug. 13 edition of Molecular Cell.
Raising the alarm when DNA goes bad
Our genome is constantly under attack from things like UV light and toxins, which can damage or even break DNA strands and ultimately lead to cancer and other diseases.
Conaway Lab uncovers function of potential cancer-causing gene product
The Stowers Institute's Conaway Lab has uncovered a previously unknown function of a gene product called Amplified in Liver Cancer 1 (Alc1), which may play a role in the onset of cancer.
LincRNAs serve as genetic air-traffic controllers
Earlier this year, a scientific team from Beth Israel Deaconess Medical Center (BIDMC) and the Broad Institute identified a class of RNA genes known as large intervening non-coding RNAs or "lincRNAs," a discovery that has pushed the field forward in understanding the roles of these molecules in many biological processes, including stem cell pluripotency, cell cycle regulation, and the innate immune response.
BRIT1 allows DNA repair teams access to damaged sites
Like a mechanic popping the hood of a car to get at a faulty engine, a tumor-suppressing protein allows cellular repair mechanisms to pounce on damaged DNA by overcoming a barrier to DNA access.
Novel DNA vaccine leads to kidney damage prevention in systemic lupus erythematosus models
DNA vaccination using lupus autoantigens and interleukin-10 (IL-10, a cytokine that plays an important role in regulating the immune system) has potential as a novel therapy to induce antigen specific tolerance and may help to prevent kidney damage in patients with systemic lupus erythematosus (SLE).
USC researchers identify DNA mutation that occurs at beginning point of T-cell lymphoma
Researchers at the Keck School of Medicine of the University of Southern California (USC) have identified a key mechanism that causes chromosomes within blood cells to break-an occurrence that marks the first step in the development of human lymphoma.
Cocaine-linked genes enhance behavioral effects of addiction
New research sheds light on how cocaine regulates gene expression in a crucial reward region of the brain to elicit long-lasting changes in behavior.
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