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In the past few years, the body of experimental work on the structure, function and assembly processes of mitochondria has expanded rapidly. No one person can believe himself or herself completely in control of the burgeoning literature without possessing serious omissions or blind spots. In the present monograph I have attempted a critical evaluation of the literature. I believe that the common thread of single authorship outweighs the shortcomings of one person presenting many disparate viewpo,ints. It is my hope that the end product represents a comprehensive and coordinated review of the subject matter to the present date. Although the bulk of this monograph was completed by October 1974, I have made some attempts to update several of the sections at later times. Albany, N. Y. , November 1975 H. TEDESCHI Contents A. Structure of Mitochondria 1. General Organization . a) Conventional Thin Section Electron Microscopy b) Negative Staining Techniques . 3 c) Freeze-Cleavage . . . . . . . 4 2. Special Organization and Inclusions 10 a) Prismatic or Atypical Cristae 10 b) Filaments and Tubules . . 11 c) Amorphous Inclusions 12 d) Intramitochondrial Granules 12 e) DNA Containing Fibers 14 3. Topography of the Mitochondrial Transducing Systems 15 B. The Assembly of Mitochondria 18 1. Mitochondrial DNA and Its Genetic Role 19 2. Transcription of the Mitochondrial DNA . 28 a) mRNA . . . . . . . . . . . . . . 30 b) The Machinery for Transcription and Translation 32 c) Turnover of Mitochondrial RNA 36 3. Protein Synthesis . . . . . . . . 37 a) Mitochondrial Protein Synthesis and Its Characteristics 37 b) Role of Mitochondrial Protein Synthesis . .
Mitochondria in Obesity and Type 2 Diabetes: Comprehensive Review on Mitochondrial Functioning and Involvement in Metabolic Diseases synthesizes discoveries from laboratories around the world, enhancing our understanding of the involvement of mitochondria in the etiology of diseases, such as obesity and type 2 diabetes. Chapters illustrate and provide an overview of key concepts on topics such as the role of mitochondria in adipose tissue, cancer, cardiovascular comorbidities, skeletal muscle, the liver, kidney, and more. This book is a must-have reference for students and educational teams in biology, physiology and medicine, and researchers.
This book focuses on the mechanical properties of cells, discussing the basic concepts and processes in the fields of immunology, biology, and biochemistry. It introduces and explains state-of-the-art biophysical methods and examines the role of mechanical properties in the cell/protein interaction with the connective tissue microenvironment. The book presents a unique perspective on cellular mechanics and biophysics by combining the mechanical, biological, physical, biochemical, medical, and immunological views, highlighting the importance of the mechanical properties of cells and biophysical measurement methods. The book guides readers through the complex and growing field of cellular mechanics and biophysics, connecting and discussing research findings from different fields such as biology, cell biology, immunology, physics, and medicine. Featuring suggestions for further reading throughout and addressing a wide selection of biophysical topics, this book is an indispensable guide for graduate and advanced undergraduate students in the fields of cellular mechanics and biophysics.
Mitochondria in plants, as in other eukaryotes, play an essential role in the cell as the major producers of ATP via oxidative phosphorylation. However, mitochondria also play crucial roles in many other aspects of plant development and performance, and possess an array of unique properties which allow them to interact with the specialized features of plant cell metabolism. The two main themes running through the book are the interconnection between gene regulation and protein function, and the integration of mitochondria with other components of plant cells. The book begins with an overview of the dynamics of mitochondrial structure, morphology and inheritance. It then discusses the biogenesis of mitochondria, the regulation of gene expression, the mitochondrial genome and its interaction with the nucleus, and the targeting of proteins to the organelle. This is followed by a discussion of the contributions that mutations, involving mitochondrial proteins, have made to our understanding of the way the organelle interacts with the rest of the plant cell, and the new field of proteomics and the discovery of new functions. Also covered are the pathways of electron transport, with special attention to the non-phosphorylating bypasses, metabolite transport, and specialized mitochondrial metabolism. In the end, the impact of oxidative stress on mitochondria and the defense mechanisms, that are employed to allow survival, are discussed. This book is for the use of advanced undergraduates, graduates, postgraduates, and beginning researchers in the areas of molecular and cellular biology, integrative biology, biochemistry, bioenergetics, proteomics and plant and agricultural sciences.
The Structure of Mitochondria provides an extensive account of the structure of mitochondria. This book illustrates the variety of mitochondrial structure revealed by electron microscopy of intact cells. Organized into nine chapters, this book begins with an overview of the application of electron microscopy to the study of the structure of cells and their mitochondria. This text then explains the short-term changes of the type revealed by phase contrast microscopy of living cells. Other chapters consider the rationale behind the procedures generally employed for the isolation of mitochondria and other sub-cellular components. This book discusses as well the important component of mitochondria. The final chapter describes the interesting similarities of mitochondria, chloroplasts, and bacteria and the bearing these have on the concept about the way in which the relationships between mitochondria and the rest of the eukaryotic cell have evolved. This book is a valuable resource for biologists, physiologists, and bacteriologists.
The recent emphasis in biomedical research on translational biology and personalized medicine is revolutionizing conceptual and experimental approaches to understanding and improving human health. Translational Biology in Medicine begins with an introduction to experimental model systems for disease, such as cell lines, primary cells, stem cells and animal models for disease, followed by a systematic description of genetic and genomic profiling and biomarker validation currently used in biomedical research. Examples of translation studies that have used these models and methods are presented, including studies in aging, tissue repair and chronic infection, each with an emphasis on how personalized medicine is transforming biomedicine. Bioethical considerations in translational study design and bioethical considerations in biomedical research are then covered, before concluding remarks, and a look towards the future of personalized medicine. - Describes cellular and animal model systems used in translational research - Discusses the use of blood, genetic and genomic biomarkers for disease - Presents translational studies in aging, tissue repair and infectious disease biomedicine
Autophagy: Cancer, Other Pathologies, Inflammation, Immunity, Infection, and Aging is an eleven volume series that discusses in detail all aspects of autophagy machinery in the context of health, cancer, and other pathologies. Autophagy maintains homeostasis during starvation or stress conditions by balancing the synthesis of cellular components and their deregulation by autophagy. This series discusses the characterization of autophagosome-enriched vaccines and its efficacy in cancer immunotherapy. Autophagy serves to maintain healthy cells, tissues, and organs, but also promotes cancer survival and growth of established tumors. Impaired or deregulated autophagy can also contribute to disease pathogenesis. Understanding the importance and necessity of the role of autophagy in health and disease is vital for the studies of cancer, aging, neurodegeneration, immunology, and infectious diseases. Comprehensive and forward-thinking, these books offer a valuable guide to cellular processes while also inciting researchers to explore their potentially important connections. - Presents the most advanced information regarding the role of the autophagic system in life and death - Examines whether autophagy acts fundamentally as a cell survivor or cell death pathway or both - Introduces new, more effective therapeutic strategies in the development of targeted drugs and programmed cell death, providing information that will aid in preventing detrimental inflammation - Features recent advancements in the molecular mechanisms underlying a large number of genetic and epigenetic diseases and abnormalities, including atherosclerosis and CNS tumors, and their development and treatment - Includes chapters authored by leaders in the field around the globe—the broadest, most expert coverage available
In the two decades since the last comprehensive work on plant peroxisomes appeared, the scientific approaches employed in the study of plant biology have changed beyond all recognition. The accelerating pace of plant research in the post-genomic era is leading us to appreciate that peroxisomes have many important roles in plant cells, including reserve mobilisation, nitrogen assimilation, defence against stress, and metabolism of plant hormones, which are vital for productivity and normal plant development. Many plant scientists are finding, and will no doubt continue to find, that their own area of research is connected in some way to peroxisomes. Written by the leading experts in the field, this book surveys peroxisomal metabolic pathways, protein targeting and biogenesis of the organelle and prospects for the manipulation of peroxisomal function for biotechnological purposes. It aims to draw together the current state of the art as a convenient starting point for anyone, student or researcher, who wishes to know about plant peroxisomes.
This book provides the first comprehensive coverage of the quickly evolving research field of membrane contact sites (MCS). A total of 16 chapters explain their organization and role and unveil the significance of MCS for various diseases. MCS, the intracellular structures where organellar membranes come in close contact with one another, mediate the exchange of proteins, lipids, and ions. Via these functions, MCS are critical for the survival and the growth of the cell. Owing to that central role in the functioning of cells, MCS dysfunctions lead to important defects of human physiology, influence viral and bacterial infection, and cause disease such as inflammation, type II diabetes, neurodegenerative disorders, and cancer. To approach such a multifaceted topic, this volume assembles a series of chapters dealing with the full array of research about MCS and their respective roles for diseases. Most chapters also introduce the history and the state of the art of MCS research, which will initiate discussion points for the respective types of MCS for years to come. This work will appeal to all cell biologists as well as researchers on diseases that are impacted by MCS dysfunction. Additionally, it will stimulate graduate students and postdocs who will energize, drive, and develop the research field in the near future.