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New angiogenesis finding may help fight cancer growth
September 29, 2006MADISON - A researcher at the University of Wisconsin-Madison School of Medicine and Public Health has discovered a new part of the complicated mechanism that governs the formation of blood vessels, or angiogenesis.
The finding may help halt tumor growth in cancer patients, says Emery Bresnick, the senior author on the study, a professor of pharmacology and member of the UW-Madison Paul P. Carbone Comprehensive Cancer Center.
The research, published in the Journal of Cell Biology on Sept. 25, is the first to connect a particular nervous-system chemical to the regulation of blood vessels.
Normally, blood vessels form when wounds heal and during menstruation, pregnancy and fetal development. But impaired blood-vessel development and function are also a major cause of blindness, and tumors rely on new blood vessels as they develop.
Like most critical body processes, angiogenesis is tightly controlled by multiple balancing mechanisms. When Bresnick and colleagues, including postdoctoral fellow Soumen Paul, began the new study, they were not looking into angiogenesis. Instead, they were studying a protein that regulates the maturation of blood cells, and noticed that it turns on a gene that makes a compound called neurokinin-B, or NK-B.
Aware that NK-B affects cells in the nervous system, Bresnick wondered, "Why would a protein involved in blood-cell formation turn on the gene for a compound that is supposedly involved in regulating the nervous system?"
The researchers searched for NK-B receptors-molecules that can "recognize" and respond to NK-B-and found great numbers of them on endothelial cells, which line the inside of blood vessels.
Endothelial cells form the internal structure of a blood vessel, and during angiogenesis, they migrate, starting an extension of the blood-vessel network. When Paul added NK-B to endothelial cells, "They lost the capacity to organize in three dimensions, to form the tubes that are the precursors to new blood vessels," Bresnick says. "Then we got excited."
Further tests showed that NK-B could inhibit angiogenesis in four ways. It prevents the production of vascular endothelial growth factor (VEGF), a key stimulator of blood-vessel formation, and also reduces the number of receptor molecules that respond to VEGF. NK-B also slows the movement of endothelial cells, which is necessary to form new vessels, and raises the level of a newly discovered angiogenesis inhibitor.
"It's premature to call it a master switch, but intriguingly, it regulates at least four different processes, each of which individually would be anti-angiogenic," says Bresnick.
Angiogenesis inhibitors, Bresnick observes, are a fast-growing field of medicine. This June, the Food and Drug Administration approved an angiogenesis inhibitor as the first drug that can restore some vision in the more severe ("wet") form of age-related macular degeneration (AMD). Wet AMD occurs when leaky blood vessels form in the retina. Along with a similar growth of new blood vessels in diabetes, it is the major cause of blindness in older adults.
But the "holy grail" of angiogenesis inhibition concerns cancer treatment. Before solid tumors start to grow, they must create a new blood supply, and since adults need angiogenesis only during pregnancy and to heal wounds, blocking angiogenesis could be a promising way to halt tumor growth. Also in June, the FDA approved a compound that inhibits VEGF for treating colon cancer, the second-leading cause of cancer death in the United States. The VEGF-inhibitor reduces the formation of blood vessels, helping starve tumors.
But angiogenesis regulation is a two-way street, and there are some diseases in which it might be desirable to stimulate angiogenesis. The new research shows that the NK-B system can work both ways: Reducing inhibition seems to increase angiogenesis.
"Activating the NK-B receptor blocked angiogenesis, and blocking the receptor stimulated angiogenesis," Bresnick says. In theory, selectively stimulating angiogenesis could help treat heart attacks by restoring blood flow to the heart, increasing the blood supply to threatened heart muscle.
NK-B also plays a role in a mysterious but common syndrome called preeclampsia, in which soaring blood pressure and low blood oxygen levels harm or even kill pregnant women and their babies. Philip Lowry, at the University of Reading in the United Kingdom, has found that NK-B levels spike in preeclampsia, and the new understanding of NK-B's role in angiogenesis suggests that faulty blood-vessel formation may be to blame.
Because NK-B prevents endothelial cells from organizing into blood vessels, Bresnick says, "Maybe excess levels of NK-B are responsible for or contribute to impaired vascular development/function and certain symptoms of preeclampsia." According to the Preeclampsia Foundation, the condition affects about 200,000 American women each year.
Many angiogenesis inhibitors are under study at this point, but finding a regulatory molecule that affects four separate mechanisms "makes for an interesting package," Bresnick says.
The Wisconsin Alumni Research Foundation has applied for a patent on the discovery, which, says Bresnick, reflected the work of "outstanding collaborators at the University of Wisconsin-Madison, who facilitated this multidisciplinary study and co-authored this paper." Authors included Patricia Keely in the Department of Pharmacology; John Fallon and Tim Gomez in the Department of Anatomy; and Sam Gellman in the Department of Chemistry.
Bresnick and his collaborators are looking further into how the molecule works in human cells and in mouse models of angiogenesis.
Eventually, after years of basic research and drug development, the multitalented compound NK-B could wind up playing a major role in treating cancer and other diseases where blood vessel formation goes awry, Bresnick says. "We have discovered a new peptide that clearly suppresses angiogenesis via a novel multi-component mechanism," he says. "A key question is whether we can exploit it to develop therapeutics."
University of Wisconsin-Madison
Normally, blood vessels form when wounds heal and during menstruation, pregnancy and fetal development. But impaired blood-vessel development and function are also a major cause of blindness, and tumors rely on new blood vessels as they develop.
Like most critical body processes, angiogenesis is tightly controlled by multiple balancing mechanisms. When Bresnick and colleagues, including postdoctoral fellow Soumen Paul, began the new study, they were not looking into angiogenesis. Instead, they were studying a protein that regulates the maturation of blood cells, and noticed that it turns on a gene that makes a compound called neurokinin-B, or NK-B.
Aware that NK-B affects cells in the nervous system, Bresnick wondered, "Why would a protein involved in blood-cell formation turn on the gene for a compound that is supposedly involved in regulating the nervous system?"
The researchers searched for NK-B receptors-molecules that can "recognize" and respond to NK-B-and found great numbers of them on endothelial cells, which line the inside of blood vessels.
Endothelial cells form the internal structure of a blood vessel, and during angiogenesis, they migrate, starting an extension of the blood-vessel network. When Paul added NK-B to endothelial cells, "They lost the capacity to organize in three dimensions, to form the tubes that are the precursors to new blood vessels," Bresnick says. "Then we got excited."
Further tests showed that NK-B could inhibit angiogenesis in four ways. It prevents the production of vascular endothelial growth factor (VEGF), a key stimulator of blood-vessel formation, and also reduces the number of receptor molecules that respond to VEGF. NK-B also slows the movement of endothelial cells, which is necessary to form new vessels, and raises the level of a newly discovered angiogenesis inhibitor.
"It's premature to call it a master switch, but intriguingly, it regulates at least four different processes, each of which individually would be anti-angiogenic," says Bresnick.
Angiogenesis inhibitors, Bresnick observes, are a fast-growing field of medicine. This June, the Food and Drug Administration approved an angiogenesis inhibitor as the first drug that can restore some vision in the more severe ("wet") form of age-related macular degeneration (AMD). Wet AMD occurs when leaky blood vessels form in the retina. Along with a similar growth of new blood vessels in diabetes, it is the major cause of blindness in older adults.
But the "holy grail" of angiogenesis inhibition concerns cancer treatment. Before solid tumors start to grow, they must create a new blood supply, and since adults need angiogenesis only during pregnancy and to heal wounds, blocking angiogenesis could be a promising way to halt tumor growth. Also in June, the FDA approved a compound that inhibits VEGF for treating colon cancer, the second-leading cause of cancer death in the United States. The VEGF-inhibitor reduces the formation of blood vessels, helping starve tumors.
But angiogenesis regulation is a two-way street, and there are some diseases in which it might be desirable to stimulate angiogenesis. The new research shows that the NK-B system can work both ways: Reducing inhibition seems to increase angiogenesis.
"Activating the NK-B receptor blocked angiogenesis, and blocking the receptor stimulated angiogenesis," Bresnick says. In theory, selectively stimulating angiogenesis could help treat heart attacks by restoring blood flow to the heart, increasing the blood supply to threatened heart muscle.
NK-B also plays a role in a mysterious but common syndrome called preeclampsia, in which soaring blood pressure and low blood oxygen levels harm or even kill pregnant women and their babies. Philip Lowry, at the University of Reading in the United Kingdom, has found that NK-B levels spike in preeclampsia, and the new understanding of NK-B's role in angiogenesis suggests that faulty blood-vessel formation may be to blame.
Because NK-B prevents endothelial cells from organizing into blood vessels, Bresnick says, "Maybe excess levels of NK-B are responsible for or contribute to impaired vascular development/function and certain symptoms of preeclampsia." According to the Preeclampsia Foundation, the condition affects about 200,000 American women each year.
Many angiogenesis inhibitors are under study at this point, but finding a regulatory molecule that affects four separate mechanisms "makes for an interesting package," Bresnick says.
The Wisconsin Alumni Research Foundation has applied for a patent on the discovery, which, says Bresnick, reflected the work of "outstanding collaborators at the University of Wisconsin-Madison, who facilitated this multidisciplinary study and co-authored this paper." Authors included Patricia Keely in the Department of Pharmacology; John Fallon and Tim Gomez in the Department of Anatomy; and Sam Gellman in the Department of Chemistry.
Bresnick and his collaborators are looking further into how the molecule works in human cells and in mouse models of angiogenesis.
Eventually, after years of basic research and drug development, the multitalented compound NK-B could wind up playing a major role in treating cancer and other diseases where blood vessel formation goes awry, Bresnick says. "We have discovered a new peptide that clearly suppresses angiogenesis via a novel multi-component mechanism," he says. "A key question is whether we can exploit it to develop therapeutics."
University of Wisconsin-Madison
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Angiogenesis: An Integrative Approach from Science to Medicine by William D. Figg (Author), William D. Figg (Editor), Judah Folkman (Editor) Dr. Judah Folkman, father of angiogenesis , (1933-2008) was the Director of the Vascular Biology Program, Andrus Professor of Pediatric Surgery, and Professor of Cell Biology at Harvard University's Boston Children's Hospital. In the 1971 issue of The New England Journal of Medicine, he proposed the theory that tumor growth is angiogenesis dependent. This premise was the basis of this field of research and has become the focus of scientists worldwide. Because of Folkman's discovery and research, the possibilities of antiangiogenic and angiogenic therapy have broadened beyond cancer to many noncancerous diseases. This book represents the first collection in a volume of which Dr. Folkman is co-editor. Dr. Folkman authored nearly 400 original papers and more than 100 book... |
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Angiogenesis Protocols (Methods in Molecular Biology) by Stewart Martin (Editor), Cliff Murray (Editor) As experimentation and clinical trials with first generation anti-angiogenic agents have yielded results and our understanding of the biology and physiology of blood and lymphatic vessels has increased, a new angiogenesis volume swiftly became a necessity. Angiogenesis Protocols, Second Edition remains true to its original vision of providing a single source for angiogenesis researchers, irrespective of levels of resource and expertise, by collecting a range of methods for cell isolation and assessing angiogenesis in vivo or in vitro. This information, however, is expanded to include chapters on circulating endothelial progenitor cells, angiogenic signalling pathways, imaging of angiogenesis, and measurement of tissue blood flow. Written in the Methods in Molecular Biology™ series... |
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Dr. Folkman's War: Angiogenesis and the Struggle to Defeat Cancer by Robert Cooke (Author), C. Everett Koop (Foreword) In 1961, twenty-eight-year-old Dr. Judah Folkman saw something while doing medical research in a United States navy lab that gave him the first glimmering of a wild, inspired hunch. What if cancerous tumors, in order to expand, needed to trigger the growth of new blood vessels to feed themselves? And if that was true, what if a way could be found to stop that growth? Could cancers be starved to death? Dr. Folkman had ample reason to be self confident — second in his class at Harvard Medical School, he was already considered one of the most promising doctors of his generation. But even he never guessed that his idea would eventually grow into a multibillion-dollar industry that is now racing through human trials with drugs that show unparalleled promise of being able to control... |
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Tumor Angiogenesis: Basic Mechanisms and Cancer Therapy by Dieter Marmé (Author), Dieter Marmé (Editor), Norbert Fusenig (Editor) Tumor angiogenesis is one of the most prominent mechanisms driving tumor development and progression. In the past 30 years some of the most important signaling pathways linking specific angiogenic activities of tumor cells to fatal reactions of the patient s vascular system have been elucidated. Crucial targets for therapeutic intervention have been identified and validated. Based on these achievements targeted drug development programs have been implemented to interfere with tumor angiogenesis as an attractive strategy in cancer treatment. The first targeted anti-angiogenic drugs have been approved for a variety of solid metastasizing cancers. Part 1 describes the basic mechanisms. Tumor-angiogenic signaling pathways are presented as new potential targets for... |
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Angiogenesis Assays: A Critical Appraisal of Current Techniques by Carolyn A Staton (Editor), Claire Lewis (Editor), Roy Bicknell (Editor) Angiogenesis, the development of new blood vessels from the existing vasculature, is essential for physiological growth and over 18,000 research articles have been published describing the role of angiogenesis in over 70 different diseases, including cancer, diabetic retinopathy, rheumatoid arthritis and psoriasis. One of the most important technical challenges in such studies has been finding suitable methods for assessing the effects of regulators of eh angiogenic response. While increasing numbers of angiogenesis assays are being described both in vitro and in vivo, it is often still necessary to use a combination of assays to identify the cellular and molecular events in angiogenesis and the full range of effects of a given test protein. Although the endothelial cell - its migration,... |
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Modern Concepts in Angiogenesis by Michael Simons (Author), Michael Simons (Editor), Gabor M. Rubanyi (Editor) This volume addresses current emerging concepts in the field of angiogenesis, including important angiogenesis modifiers which are essential in combination with growth factors (VEGF and FGF) for the physiological process and also for therapeutic applications. It covers many of the lesser discussed areas including blood vessel growth guidance (interactions with CNS) as well as emerging practical applications of these concepts. The book comprises in-depth reviews by leading experts in several major areas: recent basic science discoveries about angiogenesis modifiers (semaphorins, ephrins and nitric oxide, for which the Nobel Prize was awarded); arterial guidance; clinical applications of new angiogenic factors (HGF, HIF and eNOS); and basic and clinical advancement of anti-angiogenic... |
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Angiogenesis: From Basic Science to Clinical Applications by Napoleone Ferrara (Editor) Why a new book on angiogenesis and why now? For the first time concepts proposed over 30 years ago have found clinical validation. In the last two years the first antiangiogenic agents have been approved by the FDA for the treatment of cancer and age-related macular degeneration. Not surprisingly, this clinical success has raised a new set of basic and clinical questions that need to be addressed. Angiogenesis: From Basic Science to Clinical Applications presents the latest advances in basic science and reviews the status of the clinical applications of angiogenic growth factors and inhibitors. It explores current molecular and genetic findings on the regulation of angiogenesis, discusses the results of clinical trials and identifies the pathological conditions that are most likely to... |
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Angiogenesis and Direct Myocardial Revascularization (Contemporary Cardiology) by Roger J. Laham (Editor), Donald S. Baim (Editor) An interdisciplinary panel of pioneers and opinion leaders review the basic, preclinical, clinical, and developmental pathways to new treatment strategies, such as therapeutic angiogenesis and myogenesis. The authors take advantage of new biological understanding, novel therapeutic targets, multiple available and well-studied therapeutic strategies, and the necessary imaging techniques to measure outcomes. Their in-depth discussions cover the identification of new therapeutic targets and pathways, the investigation of transcriptional factors, master switch molecules, cell-based approaches, chemokines, a better understanding of the effects of aging, endothelial dysfunction, and hypercholesterolemia in response to angiogenic stimuli. Highlights include examination of drug delivery problems,... |
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New Frontiers in Angiogenesis by Reza Forough (Editor) New Frontiers in Angiogenesis is a fresh and unconventional look at the field of angiogenesis. It focuses on provocative and cutting-edge topics in the field of angiogenesis. Each chapter will take the reader along on a journey into uncharted territories of angiogenesis. The volume starts with a comprehensive overview of the field and continues with topics that have been minimally explored. The topics deal with dynamics of vasculogenesis using imaging techniques, bone marrow-derived endothelial cell precursors as potential therapeutic tools, regulation of post-angiogenic vessel regression, vascular mimicry, design and construction of artificial vessels, bioengineering of angiogenesis, and lymphangiogenesis recapitulating angiogenesis in health and disease states. Each chapter is... |
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Tumor Angiogenesis and Microcirculation (Basic and Clinical Oncology) by Voest/Damore (Author) Univ. Medical Center Utrecht, The Netherlands. Provides readers with a well-balanced overview of the current biological principles of angiogenesis and microcirculation and its relationship to tumor growth. Outlines methods for finding ways to inhibit circulation to tumors as a method of treatment, including recent achievements. |
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