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Adhesive Interactions in Normal and Transformed Cells describes the basic mechanisms of the ability of tissue cells to attach to each other and to the extracellular matrix. These adhesive interactions are pivotal regulators of main cellular functions, such as proliferation, survival and migration. The adhesive interactions are involved in embryonic development, regeneration, and also in inflammation and degeneration processes, which are at the basis of many diseases. Serious alterations in cell adhesion caused by the oncogenic transformation play a key role in cancer invasion and metastasis. This volume provides comprehensive information about structural, mechanistic and signaling aspects of adhesive interactions in both normal and cancer cells in comparison. Integration of such aspects of the adhesive process as structure, relation to cell systems of receptors and cytoskeleton, function, signaling pathways, and the alterations in tumor cells constitutes the strongest point of this work. The results of the long-time author’s research are included in the book. The author was one of pioneers, who used scanning electron microscopy (SEM) to study the cell surface morphology of normal cultured cells and the cells underwent the oncogenic transformation, processes of their attachment to and spreading on the surfaces of a solid substratum, and also surprising ability of the cells to respond to various geometric configurations of the substrata surfaces. Adhesive Interactions in Normal and Transformed Cells has both biological and medical aspects and, therefore, it can be interesting not only for cell biologists, developmental biologists and cancer researchers, but also for physicians. It is intended for researchers, postdocs, undergraduate and graduate students.
The aim of "The Adhesive Interaction of Cells" has been to assemble a series of reviews by leading international experts embracing many of the most important recent developments in this rapidly expanding field. The purpose of all biological research is to understand the form and function of living organisms and, by comprehending the normal, to find explanations and remedies for the abnormal and for disease conditions. The molecules involved in cell adhesion are of fundamental importance to the structure and function of all multicellular organisms. In this book, the contributors focus on the systems of vertebrates, especially mammals, since these are most relevant to human disease. It would have been equally possible to concentrate on developmental processes and adhesion in lower organisms. A major function of adhesion molecules is to bind cells to each other or to the extracellular matrix, but they are much more than "glue". Adhesions in animal tissues must be dynamic-forming, persisting, or declining in regulated fashion- to facilitate the mobility and turnover of tissue cells. Moreover, the majority of adhesion molecules are transmembrane molecules and thus provide links between the cells and their surroundings. This gives rise to another major function of adhesion molecules, the capacity to transduce signals across the hydrophobic barrier imposed by the plasma membrane. Such signal transduction is crucially important to many aspects of cellular function including the regulation of cell motility, gene expression, and differentiation. The work in this book progresses through four sections. Part I discusses the four major families of adhesion molecules themselves, the integrins (Green and Humphries), the cadherins (Stappert and Kemler), the selectins (Tedder et al.) and the immunoglobulin superfamily (Simmons); part 2 considers junctional complexes involved in cell interactions: focal adhesions and adherens junctions (Ben Ze'ev), desmosomes (Garrod et al.), and tight junctions (Citi and Cordenonsi). The signaling role of adhesion molecules is the focus of part 3, through integrins and the extracellular matrix (Edwards and Streuli), through platelet adhesion (Du and Ginsberg), and in the nervous system (Hemperley). In part 4, the aim is to show how adhesive phenomena contribute to important aspects of cell behavior and human health. Leukocyte trafficking (Haskard et al.), cancer metastasis (Marshall and Hart), cell migration (Paleck et al.), and implantation and placentation (Damsky et al.) are the topics considered in depth. The different sections are, of course, not mutually exclusive: it is both undesirable and impossible to separate structure from function when considering cell adhesion. Each chapter has its unique features, but some overlap is both invevitable and valuable since it provides different perspectives on closely related topics. We hope that the whole contributes a valuable and stimulating consideration of this important topic.
Cancer was thought to originate from alterations in intercellular signaling that resulted in the transformation of cells, their uncontrolled proliferation and metastasis. There is now an increasing body of evidence demonstrating that the surrounding matrix and cell-matrix interactions are also major players in this process. Cells adhere and receive signals from various extracellular matrices via transmembrane receptors, the best known of which are the heterodimeric glycoproteins, integrins.
Holland-Frei Cancer Medicine, Ninth Edition, offers a balanced view of the most current knowledge of cancer science and clinical oncology practice. This all-new edition is the consummate reference source for medical oncologists, radiation oncologists, internists, surgical oncologists, and others who treat cancer patients. A translational perspective throughout, integrating cancer biology with cancer management providing an in depth understanding of the disease An emphasis on multidisciplinary, research-driven patient care to improve outcomes and optimal use of all appropriate therapies Cutting-edge coverage of personalized cancer care, including molecular diagnostics and therapeutics Concise, readable, clinically relevant text with algorithms, guidelines and insight into the use of both conventional and novel drugs Includes free access to the Wiley Digital Edition providing search across the book, the full reference list with web links, illustrations and photographs, and post-publication updates
Genetic information determines the composition of molecules comprising cytoskeletal elements, membranes and receptors. The supramolecular arrangement of these components represents a self-assembly process controlled by physicochemical and mechanical interactions. This general hypothesis demarcates the aim of studying cellular mechanics. Description and evaluation of mechanical properties of cells and their organelles, as well as of the forces exerted by them, is the scope of this book on Cytomechanics. Emphasis is laid on the role of mechanical properties in the generation of shape and cytoplasmic motion, and on the basic principles and components determining mechanical properties.
Interactions of cells with their environment regulate important cellular functions and are required for the organization of cells into tissues and complex organisms. These interactions involve different types of adhesion receptors. Interactions with extracellular matrix (ECM) proteins are mainly mediated by the integrin family of adhesion molecules. Situations in which integrin-ECM interactions are deregulated cause diseases and play a crucial role in cancer cell invasion. Thus, the mechanisms underlying integrin-binding and regulation are of high interest, particularly at the molecular level. How can cell-ECM interactions be studied? While there are several methods to analyze cell adhesion, few provide quantitative data on adhesion forces. One group, single-cell force spectroscopy �ΕΠ�� ξραλϟζεζδπ αγϝδπζμλ αϟ ϟϝδ πζλϛιδ�ϐδιι ιδσδι αλγ ϐαλ ϟϝδοδεμοδ γζεεδοδλϟζαϟδ ϟϝδ αγϝδπζσδ νομνδοϟζδπ με ζλγζσζγραι ϐδιιπ� Μλδ ζκνιδκδλϟαϟζμλ με Π�ΕΠ ζπ βαπδγ μλ αϟμκζϐ εμοϐδ κζϐομπϐμνυ �ΑΕΚ�· ϟϝζπ ϟδϐϝλζξρδ ϝαπ βδδλ δκνιμυδγ ζλ ϟϝδ νοδπδλϟδγ ςμοθ� Αγσαλϟαϛδμρπιυ ΑΕΚ�Π�ΕΠ ϐμκβζλδπ ϝζϛϝ ϟδκνμοαι αλγ πναϟζαι ϐδιι καλζνριαϟζμλ� ϟϝδ αβζιζϟυ ϟμ κδαπροδ α ιαοϛδ οαλϛδ με αγϝδπζμλ εμοϐδπ αλγ πρεεζϐζδλϟιυ ϝζϛϝ�εμοϐδ οδπμιρϟζμλ ϟμ αιιμς ϟϝδ πϟργυ με πζλϛιδ�κμιδϐριδ βζλγζλϛ δσδλϟπ ζλ ϟϝδ ϐμλϟδτϟ με α ιζσζλϛ ϐδιι� Πζλϐδ ζλγζσζγραι αγϝδπζμλ οδϐδνϟμοπ ϐαλ βδ αλαιυφδγ ςζϟϝζλ ϟϝδζο νϝυπζμιμϛζϐαι δλσζομλκδλϟ� ΑΕΚ�Π�ΕΠ ζπ α νμςδοερι ϟμμι ϟμ πϟργυ ϟϝδ κδϐϝαλζπκπ ρλγδοιυζλϛ ζλϟδϛοζλ�οδϛριαϟζμλ� Ϟϝδ νοδπδλϟδγ ςμοθ ζπ πνιζϟ ζλϟμ πζτ ϐϝανϟδοπ� �ϝανϟδο μλδ ϛζσδπ βαϐθϛομρλγ ζλεμοκαϟζμλ αβμρϟ ϐδιι�Δ�Κ ζλϟδοαϐϟζμλπ� Ζλ ϐϝανϟδο ϟςμ� γζεεδοδλϟ αγϝδπζμλ αππαυπ αοδ ϐμκναοδγ αλγ ϐμλϟοαπϟδγ� Ϟϝδ ϟϝδμοδϟζϐαι Βδιι�Δσαλπ κμγδι ςϝζϐϝ ζπ ρπδγ ϟμ ζλϟδονοδϟ ζλϟδϛοζλ�κδγζαϟδγ ϐδιι αγϝδπζμλ ζπ γζπϐρππδγ ζλ ϐϝανϟδο ϟϝοδδ� Ϟϝδοδαεϟδο� ϟϝδ ϟϝοδδ νομηδϐϟπ ϟϝαϟ εμοκ ϟϝδ ϐμοδ με ϟϝδ ϟϝδπζπ αοδ γδϟαζιδγ ζλ ϐϝανϟδοπ εμρο ϟϝομρϛϝ πζτ� Ζλ ϟϝδ εζοπϟ νομηδϐϟ �ϐϝανϟδο ʹ�� �ł“�ø»�ζλϟδϛοζλ κδγζαϟδγ ϐδιι αγϝδπζμλ ϟμ ϐμιιαϛδλ ϟυνδ Ζ� ϟϝδ κμπ�
Sugar chains (glycans) are often attached to proteins and lipids and have multiple roles in the organization and function of all organisms. "Essentials of Glycobiology" describes their biogenesis and function and offers a useful gateway to the understanding of glycans.