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New inhibitor has potential as cancer drug
October 23, 2007Laboratory experiments have previously shown that cancer cells overproduce an enzyme, heparanase, which splits the body's own polysaccharide heparan sulfate into shorter fragments. The amount of enzyme is related to the degree of malignancy. Today a study is being published in the journal Nature Chemical Biology in which Uppsala University researchers show, on the basis of animal models, that an inhibitor for heparanase would be extremely interesting as a drug candidate.
Heparan sulfate is a polysaccharide, that is, a chain of linked sugar units, with sulfate groups in different positions. These chains are found on the surface of practically every cell in the body. The sulfate groups enable binding to a number of proteins, such as inflammation proteins and growth factors. Heparan sulfate can thereby regulate different processes in the body, during embryonic development, for example, but also in various conditions of sickness. The capacity for protein-binding generally increases the more sulfate groups there are on the polysaccharide.
The enzyme heparanase splits heparan sulfate at certain points and converts the long chains into shorter fragments. Research at other laboratories has shown that cancer cells in many cases overproduce heparanase and that the amount of heparanase correlates with the degree of malignancy of the cancer cells and their capacity to metasthesize. The connection is believed to have multiple explanations. Heparanase helps cancer cells make their way through tissue barriers, but it also stimulates the heightened generation of blood vessels that is necessary for tumor growth. The fragments function as carriers of growth factors that can promote tumor growth in many ways.
In the current project the scientists introduced the gene for human heparanase into a mouse, so that the enzyme would be overproduced in several organs. Besides the expected splitting of heparan sulfate, they found that the metabolism of the polysaccharide was stimulated, but that the number of sulfate groups increased at the same time. The 'high-sulfated' fragments released by the enzyme evince dramatically increased binding to certain growth factors of potential importance to tumor growth. When they examined heparan sulfate from authentic cancer cells instead, or from cancer tissue that had overproduced heparanase, it was found that here too there was an increase in the number of sulfate groups compared with heparan sulfate from corresponding normal cells/tissues. The findings indicate that producing an inhibitor for heparanase is an urgent step in discovering new drugs for cancer.
Uppsala University
In the current project the scientists introduced the gene for human heparanase into a mouse, so that the enzyme would be overproduced in several organs. Besides the expected splitting of heparan sulfate, they found that the metabolism of the polysaccharide was stimulated, but that the number of sulfate groups increased at the same time. The 'high-sulfated' fragments released by the enzyme evince dramatically increased binding to certain growth factors of potential importance to tumor growth. When they examined heparan sulfate from authentic cancer cells instead, or from cancer tissue that had overproduced heparanase, it was found that here too there was an increase in the number of sulfate groups compared with heparan sulfate from corresponding normal cells/tissues. The findings indicate that producing an inhibitor for heparanase is an urgent step in discovering new drugs for cancer.
Uppsala University
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Chemistry and Biology of Heparin and Heparan Sulfate by Hari G. Garg (Editor), Robert J. Linhardt (Editor), Charles A. Hales (Editor) The chemistry, biochemistry and pharmacology of heparin and heparan sulfate have been and continue to be a major scientific undertaking - heparin and its derivative remain important drugs in clinical practice. Chemistry and Biology of Heparin and Heparan Sulfate provides readers with an insight into the chemistry, biology and clinical applications of heparin and heparan sulfate and examines their function in various physiological and pathological conditions. Providing a wealth of useful information, no other tome covers the diversity of topics in the field. Students, doctors, chemists, biochemists, and research scientists will find this book an invaluable source for updating their current knowledge of developments in this area. *... |
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Enzymes Involved in Heparan Sulfate Chain Elongation: Function of a Novel Family of Tumor Suppressors (Comprehensive Summaries of Uppsala Dissertations, 805) by Thomas Lind (Author) | |
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Cellular Regulation of Heparan Sulfate Structure and Function (Comprehensive Summaries of Uppsala Dissertations, 886) by Fariba Safaiyan (Author) | |
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Decoding Heparan Sulfate (Comprehensive Summaries of Uppsala Dissertations from the Faculty of Medicine, 1098) by Johan Kreuger (Author) | |
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Cell Surface Heparan Sulfate Proteoglycans As Co-Receptors for Fibroblast Growth Factor (Acta Biomedica Lovaniensia, 272) by Zhe Zhang (Author) |
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Modulation of the Interaction between Fibroblast Growth Factor-2 and Fibroblast Growth Factor Receptor-1 by Cell Surface Heparan Sulfate Proteoglycans by R. Steinfeld (Author) | |
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Heparan Sulfate Proteoglycans in Embryonic Development by X. Bai (Author) | |
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Molecular Genetic Analysis of the Glypicans, a Family of Cell Surface Heparan Sulfate Proteoglycans (Acta Biomedica Lovaniensia, 217) by Mark Veugelers (Author) | |
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Heparan Sulfate Proteoglycans in Malignant Cells by K. Nackaerts (Author) | |
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Chemistry And Biology Of Heparin And Heparan Sulfate by Robert J. Linhardt, Charles A. Hales Hari G. Garg (Author) |
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