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Author: Stefanie Whalen Mares Novak
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
In striated muscle, contractile activity is dependent on the coordination between the basic contractile unit called the sarcomere and complex cytoskeletal networks. For efficient contractile function, each component is highly regulated to ensure proper expression, assembly and localization within the cell. The molecular mechanisms that govern regulation in muscle cells are still being investigated. In this dissertation, two areas of regulation were investigated: 1) regulation of the heart's conduction system by the RNA-binding protein Fragile X (Chapter 2); and 2) regulation of the sarcomere’s thin filament system by the actin-binding proteins tropomodulin and leiomodin (Chapter 3). The function of Fragile X protein (FraX) in the heart is not well understood. In Drosophila, there is one functionally conserved FraX termed dFmr1, whereas in mammals there are three FraX members with predominate expression of FXR1 in striated muscle. We found that in Drosophila, dFmr1 is required cell autonomously in cardiac cells for regulating heart rate. In mice, cardiac specific loss of FXR1 results in enlarged ventricular lumens and a significant reduction in ejection fraction. Further analyses show FXR1 may influence cardiac membrane potential and calcium homeostasis. To better understand the role of FraX in disease, human and mouse models of dilated cardiomyopathy were examined. We show that FXR1 protein is upregulated and increased expression of FXR1 regulates gap junction remodeling contributing to ventricular tachycardia in mouse hearts. Overall our results support FraX’s essential role in regulating heart function. Another important factor in maintaining proper heart function is regulation of the basic contractile unit – the sarcomere. The actin-binding proteins tropomodulin (Tmod1-4) and leiomodin (Lmod1-3) are considered to be important regulators of the thin filament but their functional properties are still being studied. In striated muscle, Tmod1 and Lmod2 both assemble at the pointed ends of thin filaments but function differently – Tmod1 restricts while Lmod2 elongates thin filament lengths. Given slight differences in structure, we sought to determine the functional significance of their individual domains. For Tmod1, we verify that both tropomyosin-binding sites are necessary for pointed-end assembly and suggest another regulatory site is located within the C-terminal LRR domain. For Lmod2, we confirm the presence of only one functionally significant tropomyosin-binding site and the presence of an N-terminal actin-binding site that influences pointed-end assembly. We also show that tropomyosin-binding affinity of Tmod1 affects its localization, its actin-capping properties, and in skeletal muscle its ability to compete with Tmod3 and Tmod4 for pointed-end assembly. Moreover, we demonstrate endogenous phosphorylation of Tmod1 and Lmod2, suggesting a potential regulatory mechanism, as well as identify potential binding partners that may influence their function in the cell. In summary, the ability of the heart to function properly is dependent on its ability to create an electrical signal and transmit that signal between cells in order to generate muscle contraction. Taken together, these data indicate that FraX contributes to the regulation of membrane potential and gap junction properties, whereas Tmod and Lmod regulate the thin filament – both influencing muscle contraction.
Author: Stefanie Whalen Mares Novak
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
In striated muscle, contractile activity is dependent on the coordination between the basic contractile unit called the sarcomere and complex cytoskeletal networks. For efficient contractile function, each component is highly regulated to ensure proper expression, assembly and localization within the cell. The molecular mechanisms that govern regulation in muscle cells are still being investigated. In this dissertation, two areas of regulation were investigated: 1) regulation of the heart's conduction system by the RNA-binding protein Fragile X (Chapter 2); and 2) regulation of the sarcomere’s thin filament system by the actin-binding proteins tropomodulin and leiomodin (Chapter 3). The function of Fragile X protein (FraX) in the heart is not well understood. In Drosophila, there is one functionally conserved FraX termed dFmr1, whereas in mammals there are three FraX members with predominate expression of FXR1 in striated muscle. We found that in Drosophila, dFmr1 is required cell autonomously in cardiac cells for regulating heart rate. In mice, cardiac specific loss of FXR1 results in enlarged ventricular lumens and a significant reduction in ejection fraction. Further analyses show FXR1 may influence cardiac membrane potential and calcium homeostasis. To better understand the role of FraX in disease, human and mouse models of dilated cardiomyopathy were examined. We show that FXR1 protein is upregulated and increased expression of FXR1 regulates gap junction remodeling contributing to ventricular tachycardia in mouse hearts. Overall our results support FraX’s essential role in regulating heart function. Another important factor in maintaining proper heart function is regulation of the basic contractile unit – the sarcomere. The actin-binding proteins tropomodulin (Tmod1-4) and leiomodin (Lmod1-3) are considered to be important regulators of the thin filament but their functional properties are still being studied. In striated muscle, Tmod1 and Lmod2 both assemble at the pointed ends of thin filaments but function differently – Tmod1 restricts while Lmod2 elongates thin filament lengths. Given slight differences in structure, we sought to determine the functional significance of their individual domains. For Tmod1, we verify that both tropomyosin-binding sites are necessary for pointed-end assembly and suggest another regulatory site is located within the C-terminal LRR domain. For Lmod2, we confirm the presence of only one functionally significant tropomyosin-binding site and the presence of an N-terminal actin-binding site that influences pointed-end assembly. We also show that tropomyosin-binding affinity of Tmod1 affects its localization, its actin-capping properties, and in skeletal muscle its ability to compete with Tmod3 and Tmod4 for pointed-end assembly. Moreover, we demonstrate endogenous phosphorylation of Tmod1 and Lmod2, suggesting a potential regulatory mechanism, as well as identify potential binding partners that may influence their function in the cell. In summary, the ability of the heart to function properly is dependent on its ability to create an electrical signal and transmit that signal between cells in order to generate muscle contraction. Taken together, these data indicate that FraX contributes to the regulation of membrane potential and gap junction properties, whereas Tmod and Lmod regulate the thin filament – both influencing muscle contraction.
Author: Elisabeth Ehler
Publisher: Springer
ISBN: 3319152637
Category : Science
Languages : en
Pages : 320
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Book Description
This book presents a collection of expert reviews on different subcellular compartments of the cardiomyocyte, addressing fundamental questions such as how these compartments are assembled during development, how they are changed in and by disease and which signaling pathways have been implicated in these processes so far. As such, it offers the first overview of the cell biology of heart disease of its kind, addressing the needs of cell biology students specializing in vascular and cardiac biology, as well as those of cardiologists and researchers in the field of cell biology.
Author: R. Wayne Albers
Publisher: Academic Press
ISBN: 0080959016
Category : Science
Languages : en
Pages : 1121
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Book Description
Basic Neurochemistry, Eighth Edition, is the updated version of the outstanding and comprehensive classic text on neurochemistry. For more than forty years, this text has been the worldwide standard for information on the biochemistry of the nervous system, serving as a resource for postgraduate trainees and teachers in neurology, psychiatry, and basic neuroscience, as well as for medical, graduate, and postgraduate students and instructors in the neurosciences. The text has evolved, as intended, with the science. This new edition continues to cover the basics of neurochemistry as in the earlier editions, along with expanded and additional coverage of new research from intracellular trafficking, stem cells, adult neurogenesis, regeneration, and lipid messengers. It contains expanded coverage of all major neurodegenerative and psychiatric disorders, including the neurochemistry of addiction, pain, and hearing and balance; the neurobiology of learning and memory; sleep; myelin structure, development, and disease; autism; and neuroimmunology. Completely updated text with new authors and material, and many entirely new chapters Over 400 fully revised figures in splendid color 61 chapters covering the range of cellular, molecular and medical neuroscience Translational science boxes emphasizing the connections between basic and clinical neuroscience Companion website at http://elsevierdirect.com/companions/9780123749475
Author: Laurival Antonio De Luca Jr.
Publisher: CRC Press
ISBN: 1466506938
Category : Science
Languages : en
Pages : 340
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Book Description
A timely symposium entitled Body-Fluid Homeostasis: Transduction and Integration was held at Araraquara, São Paulo, Brazil in 2011. This meeting was convened as an official satellite of a joint gathering of the International Society for Autonomic Neuroscience (ISAN) and the American Autonomic Society (AAS) held in Buzios, Rio de Janeiro. Broad international participation at this event generated stimulating discussion among the invited speakers, leading to the publication of Neurobiology of Body Fluid Homeostasis: Transduction and Integration. Drawn from the proceedings and filled with rich examples of integrative neurobiology and regulatory physiology, this volume: Provides updated research using human and animal models for the control of bodily fluids, thirst, and salt appetite Explores neural and endocrine control of body fluid balance, arterial pressure, thermoregulation, and ingestive behavior Discusses recent developments in molecular genetics, cell biology, and behavioral plasticity Reviews key aspects of brain serotonin and steroid and peptide control of fluid consumption and arterial pressure The book highlights research conducted by leading scientists on signal transduction and sensory afferent mechanisms, molecular genetics, perinatal and adult long-term influences on regulation, central neural integrative circuitry, and autonomic/neuroendocrine effector systems. The findings discussed by the learned contributors are relevant for a basic understanding of disorders such as heat injury, hypertension, and excess salt intake. A unique reference on the neurobiology of body fluid homeostasis, this volume is certain to fuel additional research and stimulate further debate on the topic.
Author: Vahid Serpooshan
Publisher: Springer
ISBN: 3030200477
Category : Medical
Languages : en
Pages : 233
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Book Description
This book is a comprehensive and up-to-date resource on the use of regenerative medicine for the treatment of cardiovascular disease. It provides a much-needed review of the rapid development and evolution of bio-fabrication techniques to engineer cardiovascular tissues as well as their use in clinical settings. The book incorporates recent advances in the biology, biomaterial design, and manufacturing of bioengineered cardiovascular tissue with their clinical applications to bridge the basic sciences to current and future cardiovascular treatment. The book begins with an examination of state-of-the-art cellular, biomaterial, and macromolecular technologies for the repair and regeneration of diseased heart tissue. It discusses advances in nanotechnology and bioengineering of cardiac microtissues using acoustic assembly. Subsequent chapters explore the clinical applications and translational potential of current technologies such as cardiac patch-based treatments, cell-based regenerative therapies, and injectable hydrogels. The book examines how these methodologies are used to treat a variety of cardiovascular diseases including myocardial infarction, congenital heart disease, and ischemic heart injuries. Finally, the volume concludes with a summary of the most prominent challenges and perspectives on the field of cardiovascular tissue engineering and clinical cardiovascular regenerative medicine. Cardiovascular Regenerative Medicine is an essential resource for physicians, residents, fellows, and medical students in cardiology and cardiovascular regeneration as well as clinical and basic researchers in bioengineering, nanomaterial and technology, and cardiovascular biology.
Author: Institute of Medicine
Publisher: National Academies Press
ISBN: 0309214351
Category : Medical
Languages : en
Pages : 894
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Book Description
In 1900, for every 1,000 babies born in the United States, 100 would die before their first birthday, often due to infectious diseases. Today, vaccines exist for many viral and bacterial diseases. The National Childhood Vaccine Injury Act, passed in 1986, was intended to bolster vaccine research and development through the federal coordination of vaccine initiatives and to provide relief to vaccine manufacturers facing financial burdens. The legislation also intended to address concerns about the safety of vaccines by instituting a compensation program, setting up a passive surveillance system for vaccine adverse events, and by providing information to consumers. A key component of the legislation required the U.S. Department of Health and Human Services to collaborate with the Institute of Medicine to assess concerns about the safety of vaccines and potential adverse events, especially in children. Adverse Effects of Vaccines reviews the epidemiological, clinical, and biological evidence regarding adverse health events associated with specific vaccines covered by the National Vaccine Injury Compensation Program (VICP), including the varicella zoster vaccine, influenza vaccines, the hepatitis B vaccine, and the human papillomavirus vaccine, among others. For each possible adverse event, the report reviews peer-reviewed primary studies, summarizes their findings, and evaluates the epidemiological, clinical, and biological evidence. It finds that while no vaccine is 100 percent safe, very few adverse events are shown to be caused by vaccines. In addition, the evidence shows that vaccines do not cause several conditions. For example, the MMR vaccine is not associated with autism or childhood diabetes. Also, the DTaP vaccine is not associated with diabetes and the influenza vaccine given as a shot does not exacerbate asthma. Adverse Effects of Vaccines will be of special interest to the National Vaccine Program Office, the VICP, the Centers for Disease Control and Prevention, vaccine safety researchers and manufacturers, parents, caregivers, and health professionals in the private and public sectors.
Author: Alexander Mauro
Publisher: Raven Press (ID)
ISBN:
Category : Medical
Languages : en
Pages : 582
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Book Description
Author: George Karpati
Publisher: Cambridge University Press
ISBN: 9780521650625
Category : Medical
Languages : en
Pages : 800
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Book Description
Rewritten and redesigned, this remains the one essential text on the diseases of skeletal muscle.
Author: Babbette LaMarca, Ph.D.
Publisher: Academic Press
ISBN: 0128131977
Category : Medical
Languages : en
Pages : 392
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Book Description
Sex Differences in Cardiovascular Physiology and Pathophysiology is a comprehensive look into the often overlooked and underappreciated fundamental sex differences between men and women and how those differences affect the cardiovascular system. It covers cardiovascular function, anatomy, cell signaling and the development of pathology. With contributions from world-renowned research investigators, this up-to-date reference compiles critical knowledge on cardiovascular sex differences, providing researchers and clinicians with a better understanding of the diagnosis, prevention and treatment of cardiovascular diseases in both men and women. Identifies the fundamental sex differences in the physiology and pathophysiology of the cardiovascular system Describes cell signaling pathways involved in sex-associated cardiovascular function and diseases Puts the sex differences in cardiovascular diseases in the forefront to improve cardiovascular prognoses
Author: Vladimir Parpura
Publisher: Springer Science & Business Media
ISBN: 0387794921
Category : Medical
Languages : en
Pages : 701
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Book Description
Astrocytes were the original neuroglia that Ramón y Cajal visualized in 1913 using a gold sublimate stain. This stain targeted intermediate filaments that we now know consist mainly of glial fibrillary acidic protein, a protein used today as an astrocytic marker. Cajal described the morphological diversity of these cells with some ast- cytes surrounding neurons, while the others are intimately associated with vasculature. We start the book by discussing the heterogeneity of astrocytes using contemporary tools and by calling into question the assumption by classical neuroscience that neurons and glia are derived from distinct pools of progenitor cells. Astrocytes have long been neglected as active participants in intercellular communication and information processing in the central nervous system, in part due to their lack of electrical excitability. The follow up chapters review the “nuts and bolts” of ast- cytic physiology; astrocytes possess a diverse assortment of ion channels, neu- transmitter receptors, and transport mechanisms that enable the astrocytes to respond to many of the same signals that act on neurons. Since astrocytes can detect chemical transmitters that are released from neurons and can release their own extracellular signals there is an increasing awareness that they play physiological roles in regulating neuronal activity and synaptic transmission. In addition to these physiological roles, it is becoming increasingly recognized that astrocytes play critical roles during pathophysiological states of the nervous system; these states include gliomas, Alexander disease, and epilepsy to mention a few.
