Download Free Chemical Mechanisms In Bioenergetics Book in PDF and EPUB Free Download. You can read online Chemical Mechanisms In Bioenergetics and write the review.

Advanced Biochemistry: Mechanisms in Bioenergetics provides information pertinent to the fundamental aspects of the mechanisms in bioenergetics. This book covers a variety of topics, including the enzymatic mechanism of ATP formation and the regulatory mechanisms that control its metabolic utilization. Organized into three parts encompassing 18 lectures, this book begins with an overview of the process of converting nutrients into forms of useful energy, which is the essence of energy metabolism. This text then explores the properties that have a specific bearing on the problem of oxidative phosphorylation. Other lectures consider the phosphoroclastic reaction with pyruvate, which plays a curious and apparently specific role in nitrogen fixation. This book discusses as well the operation of control mechanisms of energy metabolism in intact cells. The final lecture analyzes the rate-limiting steps in carbohydrate metabolism of various cells and some of the metabolic factors that govern them. This book is a valuable resource for graduate students.
Principles of Bioenergetics summarizes one of the quickly growing branches of modern biochemistry. Bioenergetics concerns energy transductions occurring in living systems and this book pays special attention to molecular mechanisms of these processes. The main subject of the book is the "energy coupling membrane" which refers to inner membranes of intracellular organelles, for example, mitochondria and chloroplasts. Cellular cytoplasmic membranes where respiratory and photosynthetic energy transducers, as well as ion-transporting ATP-synthases (ATPases) are also part of this membrane. Significant attention is paid to the alternative function of mitochondria as generators of reactive oxygen species (ROS) that mediate programmed death of cells (apoptosis and necrosis) and organisms (phenoptosis). The latter process is considered as a key mechanism of aging which may be suppressed by mitochondria-targeted antioxidants.
A New Look at Mechanisms in Bioenergetics features eight lectures based on the Robbins Lectures given at Pomona College in April 1973. These lectures are based mainly on the author's own laboratory work and are intended for students of biology and biochemistry who want to devote their lives to research. Lecture 1 presents some of the general lessons learned from research in the field of bioenergetics. It also discusses methods for measuring oxidative phosphorylation and the resolution of soluble multienzyme systems. Lecture 2 explains the biochemical approach to the problem of photophosphorylation. Lecture 3 considers the intersection of oxidative phosphorylation and membranology. Lecture 4 discusses the coupling device and its partial reactions. Lecture 5 focuses on the oxidation chain in mitochondria. Lecture 6 discusses the resolution and reconstitution of oxidative phosphorylation. Lecture 7 examines the reconstitution of ion pumps. Finally, Lecture 8 covers oxidation control in glycolysis; the high aerobic glycolysis of tumor cells; ATPases in tumor cells; and the repair of ion pumps in tumor cells.
Comprehensive Biochemisty, Volume 22: Bioenergetics focuses on comprehensive biochemistry that provides a chemical approach to the understanding of the phenomena of life. This book is devoted to certain aspects of organic and physical chemistry, aspects considered pertinent to the interpretation of biochemical techniques, and chemistry of biological compounds and mechanisms. The topics discussed include the methods and scope of quantum biochemistry, long range dipole-dipole transfer, and characteristics of the charge-transfer absorption band. The dye-sensitized photoconductivity, facilitation of solute diffusion by catalytic carriers, and coupling of primary and secondary translocation are also covered in this publication. This volume is valuable to biochemists and researchers concerned with biogenetics.
Current Topics in Bioenergetics, Volume 13 presents the biophysical and biochemical approaches that are valuable in some systems and that may be readily be applied to others. This book discusses the function and structure relationship of energy-transducing membranes that has played an essential role in the progress and development in the field of bioenergetics. Organized into six chapters, this volume begins with an overview of the bioenergetics processes that require a molecular description of the structure and reaction mechanisms of the individual energy-transducing catalysts. This text then provides an understanding to the methodology for initiation of an electron paramagnetic resonance (EPR) investigation in this field of research. This book discusses as well the developments in spin label EPR techniques. The final chapter deals with immunological techniques that are used for studying the biochemistry and molecular biology of membrane proteins. This book is a valuable resource for physiologists, biologists, and biochemists.
An essential resource for biochemists, biophysicists and chemical biologists, providing a complete understanding of the molecular machines of bioenergetics.
Mechanisms in Bioenergetics covers the proceedings of the eighth conference on ""Mechanisms in Bioenergetics"" held in Pugnochiuso, Italy on May 1-4, 1972. This book is organized into three parts, encompassing 43 chapters that discuss bioenergetics in mitochondria, chloroplasts, chromatophores, and bacterial protoplast membranes. It summarizes the structure and dynamics of energy-transducing membranes, molecular basis of membrane transport, and energy coupling mechanisms. The first part of the book describes various aspects of structure and dynamics of energy transducing membranes. This includes their chemiosmotic coupling, reflection coefficients, structural transformation, redox properties, and circular dichroism studies. This is followed by considerable chapters discussing chemiosmotic theory of transport and metabolism, ion channel phosphorylation paths in cell membrane, and kinetics of metabolite anion uptake in mitochondria. Other topics covered are mitochondrial Ca2+-binding glycoprotein and sucrose-dependent sugar transport across artificial lipid membranes. This book also looks into the enzyme interaction in mitochondrial membrane. It also discusses the relation of hydrogen uptake to electron flow in photosynthetic bacteria and purine nucleotides and fatty acids in energy coupling. The concluding section deals with the mechanisms of energy coupling, including mechanism of respiration-driven proton, role of mitochondrial energy transfer factors, and energy in mitochondrial respiration. The behavior of cytochromes b and c of pigeon heart and in the energized mitochondrial membrane is also described. Finally, this book considers the effect of adenosine-containing compounds competitively inhibiting the mitochondrial transhydrogenase reaction. Researchers and students who are interested in bioenergetics and energy-transducing membranes will benefit from this book.