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This highly researched yeast, which represents a system used by cell biologists, geneticists and molecular biologists, has been given only minimal coverage in the literature. Its properties make it an excellent organism for DNA and related biotechnology reseach. This book, which is the first attempt to collate existing information in one source, will be an invaluable aid to those initiating projects with this organism.
The fission yeast Schizosaccharomyces pombe is the favoured tool of many productive research groups throughout the world, serving as a useful model for fundamental principles and mechanisms, such as genome organization, differential gene regulation, cell-cycle control, signal transduction, or cellular morphogenesis. This book collates the current state of knowledge derived from molecular studies in this simple eukaryotic microorganism. The entire sequence of its genome has been completed, emphasizing the comparative value and model status of this yeast. The individual chapters, highlighting up-to-date views on prominent aspects of molecular organization, were written by active research scientists, presenting the results of their investigations to other workers in neighbouring fields. This book intends to serve the fission yeast community as a handy source of reference for years to come. It will also be of particular value to the ever-increasing number of researchers starting to look into fission yeast affairs for comparative reasons from other platforms of molecular genetics and cell biology.
Fission yeast are unicellular, rod-shaped fungi that divide by medial fission. Studies using fission yeast were instrumental in identifying fundamental mechanisms that govern cell division, differentiation, and epigenetics, to name but a few. Their rapid growth rate, genetic malleability, and similarities to more complex eukaryotes continue to make them excellent subjects for many biochemical, molecular, and cell biological studies. This laboratory manual provides an authoritative collection of core experimental procedures that underpin modern fission yeast research. The contributors describe basic methods for culturing and genetically manipulating fission yeast, synchronization strategies for probing the cell cycle, technologies for assessing proteins, metabolites, and cell wall constituents, imaging methods to visualize subcellular structures and dynamics, and protocols for investigating chromatin and nucleic acid metabolism. Modifications to techniques commonly used in related species (e.g., budding yeast) are noted, as are useful resources for fission yeast researchers, including various databases and repositories. The well-studied fission yeast Schizosaccharomyces pombe is the focus throughout, but the emerging model S. japonicus-a larger, dimorphic species with several desirable characteristics-is also covered. This manual is an important reference for existing fission yeast laboratories and will serve as an essential start-up guide for those working with fission yeast for the first time.
This fully updated edition of the bestselling three-part Methods in Enzymology series, Guide to Yeast Genetics and Molecular Cell Biology is specifically designed to meet the needs of graduate students, postdoctoral students, and researchers by providing all the up-to-date methods necessary to study genes in yeast. Procedures are included that enable newcomers to set up a yeast laboratory and to master basic manipulations. This volume serves as an essential reference for any beginning or experienced researcher in the field. - Provides up-to-date methods necessary to study genes in yeast - Includes proceedures that enable newcomers to set up a yeast laboratory and to master basic manipulations - Serves as an essential reference for any beginning or experienced researcher in the field
Yeast genetics began with Winge's 1935 studies of S. cerevisiae in Copenhagen, and afterwards was pursued by Lindegren in the U.S. and Ephrussi in France. Genetic studies in S. pombe were pioneered by Leupold in the 1940s in Switzerland. Within four decades, not without controversies, both yeast species were recognized as essential models in eukaryotic molecular cell biology. In this remarkable volume, Hall and Linder have assembled the reminiscences of many early investigators whose pioneering studies in the years before 1975 brought yeast biology to its current maturity. These illustrated essays about the science, the events and the personalities involved capture a fascinating era, in the informal style made famous by Phage and the Origins of Molecular Biology. This is a book that all scientists interested in the development of modern genetics and molecular biology should have on their shelves.
A Top 25 CHOICE 2016 Title, and recipient of the CHOICE Outstanding Academic Title (OAT) Award. How much energy is released in ATP hydrolysis? How many mRNAs are in a cell? How genetically similar are two random people? What is faster, transcription or translation?Cell Biology by the Numbers explores these questions and dozens of others provid
Clathrin-mediated endocytosis (CME) is a ubiquitous internalization process in eukaryotic cells. It consists of the formation of an approximately 50-nm diameter vesicle out of a flat membrane. Genetics, biochemistry, and microscopy experiments performed in the last four decades have been instrumental to discover and characterize major endocytic proteins in yeast and mammals. However, due to the highly dynamic nature of the endocytic assembly and its small size, many questions remain unresolved: how are endocytic proteins organized spatially and dynamically? How are forces produced and how are their directions controlled? How do the biochemical activities of endocytic proteins and the membrane shape and mechanics regulate each other? These questions are virtually impossible to visualize or measure directly with conventional approaches but thanks to new quantitative biology methods, it is now possible to infer the mechanisms of endocytosis in exquisite detail. This book introduces quantitative microscopy and mathematical modeling approaches that have been used to count the copy number of endocytic proteins, infer their localization with nanometer precision, and infer molecular and physical mechanisms that are involved in the robust formation of endocytic vesicles.
Considerable advances have been made in our understanding of the eukaryotic cell cycle at the molecular level over the past two decades or so, particularly in yeast and in animal systems. However, only in the past three or four years has progress been made in plants at the molecular level. The present volume brings together molecular biologists, cell biologists and physiologists to discuss this recent progress and how it relates to our understanding of the regulation of plant growth and development. The opening paper summarises the progress which has been made with fission yeast. Subsequent papers explore what is known about cell cycle control at the molecular level in plants, and about cell cycle regulation in specific physiological systems, ending with summary papers on cell division in roots and shoots. The book comprises up-to-date findings on a fundamental aspect of plant growth and development, and as such will be of particular interest to advanced undergraduates, postgraduates and research scientists in the fields of molecular biology, cell biology and physiology.
Guide to Yeast Genetics and Molecular Biology presents, for the first time, a comprehensive compilation of the protocols and procedures that have made Saccharomyces cerevisiae such a facile system for all researchers in molecular and cell biology. Whether you are an established yeast biologist or a newcomer to the field, this volume contains all the up-to-date methods you will need to study "Your Favorite Gene" in yeast. Basic Methods in Yeast Genetics**Physical and genetic mapping**Making and recovering mutants**Cloning and Recombinant DNA Methods**High-efficiency transformation**Preparation of yeast artificial chromosome vectors**Basic Methods of Cell Biology**Immunomicroscopy**Protein targeting assays**Biochemistry of Gene Expression**Vectors for regulated expression**Isolation of labeled and unlabeled DNA, RNA, and protein