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In Volume 25, leading experts present studies on the value of increased ascorbic acid intake and explore its specific contributions to human and animal health.
This new volume in the Subcellular Biochemistry series will focus on the biochemistry and cellular biology of aging processes in human cells. The chapters will be written by experts in their respective fields and will focus on a number of the current key areas of research in subcellular aging research. Main topics for discussion are mitochondrial aging, protein homeostasis and aging and the genetic processes that are involved in aging. There will also be chapters that are dedicated to the study of the roles of a variety of vitamins and minerals on aging and a number of other external factors (microbiological, ROS, inflammation, nutrition). This book will provide the reader with a state of the art overview of the subcellular aging field. This book will be published in cooperation with a second volume that will discuss the translation of the cell biology of aging to a more clinical setting and it is hoped that the combination of these two volumes will bring a deeper understanding of the links between the cell and the body during aging.
The transition from the quarterly Sub-Cellular Biochemistry to the annual SUBCELLULAR BIOCHEMISTRY is a good opportunity to restate the aims and scope of this publication. They were originally given (in Volume 1 No. 1) as follows: This review and essay journal . . . brings together work on a wide range of topics in sub-cellular biochemistry in the hope of stimulating progress towards an integrated view of the cell. It deals with the biochemistry and general biology of nuclei, mitochondria, lysosomes, peroxisomes, chloroplasts, cell membranes, ribosomes, cell sap, flagellae and other specialized cell components. In addition to articles dealing with conventional biochemical studies on sub-cellular struc tures, the journal publishes articles on the genetics, evolution and biogenesis of cell organelles, bioenergetics, membrane behaviour and the interaction between cell structures, particularly between nucleus and cytoplasm. The first four volumes (in the quarterly format) fulfilled many, but not all, of these stated aims, and it is hoped that further articles in the new annual series will soon fill any deficiencies in the range of topics covered. Over the years we have intentionally not interpreted the title of the publication in a too literal sense. Although we have included specific articles on individual subcellular fractions (and certainly hope to do so again) the publication is definitely not only concerned with studies on the biochemistry of isolated cell fractions. The primary target is the "integrated view of the cell.
The broad aim of SUBCELLULAR BIOCHEMISTRY is to present an inte grated view of the cell in which artificial barriers between disciplines are bro ken down. The contents of Volume 7 illustrate the interconnections between initially unrelated fields of study and show strikingly how advances along one front become possible because of parallel successes in another. Current research into cell organelles and membrane systems is not only concerned with the elucidation of their structure and function. It also asks such questions as: Which regions of the cell are concerned in the bioassembly of the organelle? How are organelle and membrane precursors transported from the site of syn thesis to the newly formed cell constituent? What genetic systems control the biosynthesis and assembly of cell components and how do these systems inter act? How did the various cell constituents evolve? How did the genetic and biosynthetic systems making the organelles themselves evolve? The search for the answer to such questions has placed organelle biochemistry on a different level than that of the more restricted studies of the 1950s and early 1960s and promises to produce some fascinating and surprising results. Volume 7 opens with a detailed chapter by A. A. Hadjiolov on the bio genesis of ribosomes of eukaryotes. The general arrangement of ribosomal genes is discussed, and there is a full account of their transcription.
This volume of the subcellular Biochemistry series will attempt to bridge the gap between the subcellular events that are related to aging as they were described in the first volume of this set of two books and the reality of aging as this is seen in clinical practice. All chapters will start from the biochemistry or cell biology, where the data is available and work up towards the understanding that we have of aging in the various areas that are related to the subject. Key focus points for this volume are nutrition, external factors and genetics on aging. There will also be chapters that will focus on various organs or tissues in which aging has been well studied, like the eyes, the muscles, the immune system and the bones. The aim of the book project and the book project that is published in concert with this volume is to bring the subcellular and clinical areas into closer contact.
The Biology of Euglena, Volume IV: Subcellular Biochemistry and Molecular Biology focuses on the subcellular biochemistry and molecular biology of eukaryotic microorganisms that belong to the genus Euglena, including Euglena gracilis. It investigates enzymes and their functional location in Euglena cells, along with subcellular particles, the nucleus, the mitochondria, the chloroplast protein synthesis and chloroplast DNA, and the microbodies and lysosomes of Euglena. Organized into eight chapters, this volume begins with an overview of techniques in determining the location of enzymes and in isolating organelles in Euglena. It then proceeds with a discussion of the nucleus, its ultrastructure and macromolecules, and chromatin organization. The next chapters examine the morphology and ultrastructure of mitochondria, the morphology and biogenesis of microbodies and lysosomes, the nuclear-cytoplasmic interaction, and the structure and physicochemical properties of chloroplast DNA. The last two chapters consider the ribosomal RNAs of Euglena and the organization and activities of cytoplasmic, mitochondrial, and chloroplast ribosomes and polyribosomes, along with its polyadenylated and messenger RNA. This book will be of interest to biochemists, molecular biologists, botanists, and plant geneticists.
This much-needed book is the first definitive volume on Euglena in twenty-fire years, offering information on its atypical biochemistry, cell and molecular biology, and potential biotechnology applications. This volume gathers together contributions from well-known experts, who in many cases played major roles in elucidating the phenomenon discussed. Presented in three parts, the first section of this comprehensive book describes novel biochemical pathways which in some instances have an atypical subcellular localization. The second section details atypical cellular mechanisms of organelle protein import, organelle nuclear genome interdependence, gene regulation and expression that provides insights into the evolutionary origins of eukaryotic cells. The final section discusses how biotechnologists have capitalized on the novel cellular and biochemical features of Euglena to produce value added products. Euglena: Biochemistry, Cell and Molecular Biology will provide essential reading for cell and molecular biologists with interests in evolution, novel biochemical pathways, organelle biogenesis and algal biotechnology. Readers will come away from this volume with a full understanding of the complexities of the Euglena as well as new realizations regarding the diversity of cellular processes yet to be discovered.
Eukaryotic cells are remarkably complex structures, containing a vast repertoire of macromolecules, organelles, and other compartments that orchestrate the tasks required for life. For in-depth studies of their function and composition, reliable methods for the isolation of specific subcellular structures are often required. This laboratory manual provides step-by-step protocols for the extraction of subcellular components from animal tissues, yeasts, plants, and cultured cells. Each chapter focuses on a particular eukaryotic organelle, vesicle, membrane, or macromolecular complex. Strategies for breaking cells while maintaining the structural and functional integrity of the component of interest, enriching for that component based on its physical and biochemical characteristics, and monitoring and ensuring the success of the purification procedure are provided. The contributors describe both traditional approaches (e.g., density gradient centrifugation) and innovative techniques (e.g., the use of SPIONs) for isolating subcellular constituents. This manual is therefore an essential laboratory resource for all cell biologists seeking a comprehensive collection of dependable subcellular fractionation methods.