Targeting astrocytes slows disease progression in ALS

Targeting astrocytes slows disease progression in ALS Sunday, 03 February 2008 In what the researchers say could be promising news in the quest to find a therapy to slow the progression of amyotrophic lateral sclerosis (ALS), or Lou Gehrig’s disease, scientists at the University of California, San Diego (UCSD) School of Medicine have shown that targeting neuronal support cells called astrocytes sharply slows disease progression in mice. The study, conducted in the laboratory of Don Cleveland, Ph.D., UCSD Professor of Medicine, Neurosciences and Cellular and Molecular Medicine and member of the Ludwig Institute for Cancer Research, will appear in the advance online publication on Nature Neuroscience's website on February 3rd. “Mutant genes that cause ALS are expressed widely, not just in the motor neurons,” Cleveland explained. “Targeting the partner cells like astrocytes, which live in a synergistic environment with the neuron cells, helps stop the ‘cascade of damage.’ Therapeutically, this is the big news.” ALS is a progressive disease that attacks the motor neurons, long and complex nerve cells that reach from the brain to the spinal cord and from the spinal cord to the muscles throughout the body, which act to control voluntary movement. Degeneration of the motor neurons in ALS leads to progressive loss of muscle control, paralysis and untimely death. Estimated to affect some 30,000 Americans, most people are diagnosed with ALS between the ages of 45 and 65. Typically, ALS patients live only one to five years after initial diagnosis. In findings published in Science in June 2006, Cleveland and his colleagues showed that in early stages of inherited ALS, small immune cells called microglia are damaged by mutations in the SOD1 protein, and that these immune cells then act to significantly accelerate the degeneration of the motor neurons. The new study demonstrates that much the same thing happens to astrocytes, support cells that are essential to neuronal function, and whose dysfunction is implicated in many diseases. The researchers speculate that the non-neuronal cells play a vital role in nourishing the motor neurons and in scavenging toxins from the cellular environment. As with microglia, the helper role of astrocytes is altered due to mutations in the SOD1 protein. “We tested what would happen if we removed the mutant gene from astrocytes in mouse models,” said Cleveland. “What happened was it doubled the lifespan of the mouse after the onset of ALS.” Astrocytes are key components in balancing the neurotransmitter signals that neurons use to communicate. To examine whether mutant SOD1 damage to the astrocytes contributes to disease progression in ALS, researchers in the Cleveland lab used a genetic trick to excise the mutant SOD1 gene, but only in astrocytes. Reduction of the disease-causing mutant SOD1 in astrocytes did not slow disease onset or early disease; however, the late stage of the disease was extended, nearly doubling the normal life expectancy of a mouse with ALS. “Silencing the mutant gene in the astrocytes not only helps protect the motor neuron, but delays activation of mutant microglia that act to accelerate the progression of ALS,” said Cleveland. The findings show that mutant astrocytes are likely to be viable targets to slow the rate of disease spread and extend the life of patients with ALS. Cleveland added that this may prove especially important news to researchers in California and elsewhere working with stem cells. “This gives scientists a good idea of what cells should be replaced using stem cell therapy. Astrocytes are very likely much easier to replace than the slow-growing motor neuron.” Additional contributors to the study include Koji Yamanaka, Seung Joo Chun and Severine Boillee, Ludwig Institute for Cancer Research and UCSD Department of Medicine and Neuroscience; Noriko Fujimore-Tonou and Hirofumi Yamashita, Yamanaka Research Unit, RIKEN Brain Science Institute, Saitama, Japan; David H. Gutmann, Department of Neurology, Washington University, St. Louis; Ryosuke Takahashi, Department of Neurology, Kyoto University, Japan; and Hidemi Misawa, Department of Pharmacology, Kyoritsu University of Pharmacy, Tokyo. ......... ZenMaster

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Carbohydrate Regulating Stem Cell Potency

Carbohydrate Regulating Stem Cell Potency Friday, 01 February 2008 Heparan sulfate, a carbohydrate molecule that coats certain proteins on the cell surface, is critical for the proper proliferation and potency of embryonic stem cells, researchers report. Stem cells’ tremendous therapeutic potential arises from their ability to continually self-renew and turn into any adult cell type. Researchers have long been trying to uncover the basis of these abilities, but while several proteins and growth factors are known to play a role both inside and outside the cell, the molecular mechanisms remain largely unknown. Many of the stem cell associated can attach to heparan sulphate (HS) molecules, so Shoko Nishihara and colleagues, Laboratory of Cell Biology, Department of Bioinformatics, Faculty of Engineering, Soka University, Tokyo, Japan, examined what would happen to mouse stem cells in cell culture if heparan sulphate production was reduced or blocked. They discovered that three of the major external factors promoting stem cell renewal (proteins called Wnt, FGF, and BMP) could not induce the proper signals inside the cell without HS. As a result, HS deficient cells grew more slowly, and also spontaneously differentiated into other cells more often, at rates that correlated with the level of inhibition. Nishihara and colleagues propose that heparan sulphate might be the cell-surface component that mediates the external and internal signals promoting stem cell renewal, and could be an important target for stem cell engineering.

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Caption: Model displays external factors that act to block stem cells from differentiating into different types of adult tissue. LIF activates STAT3 and blocks non-neural differentiation by induction of Myc, while BMP/Smad signalling through HS chains blocks neural differentiation by induction of Id. Wnt/b-catenin signalling through HS chains blocks primitive endodermal differentiation by induction of Nanog. FGF may contribute to proliferation through HS chains. HS chain dependent signalling by unknown factors may regulate proliferation and Oct3/4 expression. Credit: Shoko Nishihara.

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Reference:

Heparan Sulfate Regulates Self-renewal and Pluripotency of Embryonic Stem Cells J. Biol. Chem., Vol. 283, Issue 6, 3594-3606, February 8, 2008 ......... ZenMaster

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Human Genetic Recombination Studied II

Gene variants may help to distribute the work of evolution between men and women Thursday, 31 January 2008 Scientists from deCODE genetics today report the discovery of two common, single-letter variants in the sequence of the human genome (SNPs) that regulate one of the principle motors of evolution. Versions of the two SNPs, located on chromosome 4p16, have a genome-wide impact on the rate of recombination — the reshuffling of the genome that occurs in the formation of eggs and sperm. Recombination is largely responsible for generating human diversity, the novel configurations of the genome that enable the species to adapt and evolve in an ever-changing environment. Yet remarkably, the versions of the SNPs that increase recombination in men decrease it in women, and vice versa. This highly unusual characteristic may enable the variants to help to maintain a fundamental tension crucial for evolutionary success: promoting the generation of significant diversity within a portion of the population but keeping the pace of this change within certain bounds, maintaining it relatively constant overall and so supporting the stability of the genome and the cohesiveness of the species. “This is the latest in a series of landmark papers from deCODE in which we have utilized our unique capabilities in human genetics to elucidate some of the key mechanisms driving human evolution,” said Kari Stefansson, CEO of deCODE. “We are also excited that we can now immediately enable individuals to see if they carry such variants, by folding the findings announced today — and others we expect to publish in the near future — into our deCODEme™ personal genome analysis service.” The deCODE team identified the SNPs through a genome-wide analysis of more than 300,000 SNPs in approximately 20,000 participants in the company’s gene discovery programs. The SNPs, referred to as rs3796619 and rs1670533, are within the RNF212 gene, and are estimated to account for approximately 22% of paternal variability in recombination and 6.5% of maternal variability. Little is known about RNF212, though it is a mammalian homolog of a gene called ZHP-3 known to be crucial for the success of recombination in other organisms. The paper, entitled ‘Sequence Variants in the RNF212 Gene Associate with Genomewide Recombination Rate,’ is published today in the online edition of Science. deCODE has made a number of breakthrough discoveries in the understanding of recombination, fertility and human evolution. In 2002, deCODE published the most detailed recombination map to date of the genome, demonstrating that there are hotspots and coldspots for recombination in all chromosomes, and that these are very different in women and men. This map provided a template for completing the final assembly of the sequence of the human genome. deCODE scientists then showed that recombination rate varies between families and between women; that recombination rate increases with the age of the mother; and that higher recombination rate correlates with fertility, indicating that evolution appears to place a premium on the generation of human diversity. In 2005, deCODE identified a genetic variant that correlates with higher recombination rate, the first genetic variant ever demonstrated to be under positive evolutionary selection in human populations in real time. References for these and all deCODE’s major discoveries can be found at www.decode.com. About deCODE deCODE is a biopharmaceutical company applying its discoveries in human genetics to the development of drugs and diagnostics for common diseases. deCODE is a global leader in gene discovery — our population approach and resources have enabled us to isolate key genes contributing to major public health challenges from cardiovascular disease to cancer, genes that are providing us with drug targets rooted in the basic biology of disease. deCODE is also leveraging its expertise in human genetics and integrated drug discovery and development capabilities to offer innovative products and services in DNA-based diagnostics, bioinformatics, genotyping, structural biology, drug discovery and clinical development. deCODE is delivering on the promise of the new genetics. ......... ZenMaster

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