Secure CheckoutPersonal information is secured with SSL technology.
Free ShippingFree global shipping
No minimum order.
Basic Methods of Yeast Genetics: F. Sherman, Getting Started with Yeast. F. Sherman and J. Hicks, Micromanipulation and Dissection of Asci. F. Sherman and P. Wakem, Mapping Yeast Genes. S.L. Gerring, C. Connelly, and P. Hieter, Positional Mapping of Genes by Chromosome Blotting and Chromosome Fragmentation. G.F. Sprague, Jr., Assay of Yeast Mating Reaction. Y. Kassir and G. Simchen, Monitoring Meiosis and Sporulation in Saccharomyces cerevisiae. R.E. Esposito, M. Dresser, and M. Breitenbach, Identifying Sporulation Genes, Visualizing Synaptonemal Complexes, and Large-Scale Spore and Spore Wall Purification. I. Herskowitz and R.E. Jensen, Putting the HO Gene to Work: Practical Uses for Mating-Type Switching. B. Rockmill, E.J. Lambie, and G.S. Roeder, Spore Enrichment. T.D. Fox, L.S. Folley, J.J. Mulero, T.W. McMullin, P.E. Thorsness, L.O. Hedin, and M.C. Costanzo, Analysis and Manipulation of Yeast Mitochondrial Genes. Cloning and Recombinant DNA: P. Philippsen, A. Stotz, and C. Scherf, DNA of Saccharomyces cerevisiae. D.M. Becker and L. Guarente, High-Efficiency Transformation of Yeast by Electroporation. J.A. Heinemann and G.F. Sprague, Jr., Transmission of Plasmid DNA to Yeast by Conjugation with Bacteria. M.D. Rose and J.R. Broach, Cloning Genes by Complementation in Yeast. R.A. Young and R.W. Davis, Gene Isolation with ~glgt11 System. J. Rine, Gene Overexpression in Studies of Saccharomyces cerevisiae. D.T. Burke and M.V. Olson, Preparation of Clone Libraries in Yeast Artificial-Chromosome Vectors. Making Mutants: C.W. Lawrence, Classical Mutagenesis Techniques. R. Rothstein, Targeting, Disruption, Replacement, and Allele Rescue. Integrative DNA Transformation in Yeast. R.S. Sikorski and J.D. Boeke, In Vitro Mutagenesis and Plasmid Shuffling. From Cloned Gene to Mutant Yeast: J.N. Strathern and D.R. Higgins, Recovery of Plasmids from Yeast into Escherichia coli. M.F. Hoekstra, Shuttle Vectors. H.S. Seifert, J. Nickoloff, and F. Heffron, Shuttle Mutagenesis. Bacterial Transposons for Genetic Manipulations in Yeast: D.J. Garfinkel and J.N. Strathern, Ty Mutagenesis in Saccharomyces cerevisiae. R.P. Moerschell, G. Das, and F. Sherman, Transformation of Yeast Directly with Synthetic Oligonucleotides. Biochemistry of Gene Expression: J.C. Schneider and L. Guarente, Vectors for Expression of Cloned Genes in Yeast. Regulation, Overproduction, and Underproduction: M. Schena, D. Picard, and K.R. Yamamoto, Vectors for Constitutive and Inducible Gene Expression in Yeast. K. Kadohrer and H. Domdey, Preparation of High Molecular Weight RNA. J.A. Wise, Preparation and Analysis of Low Molecular Weight RNAs and Small Ribonucleoproteins. R. Parker, D. Herrick, S.W. Peltz, and A. Jacobson, Measurement of mRNA Decay Rates in Saccharomyces cerevisiae J.R. Warner, Labeling of RNA and Phosphoproteins in Saccharomyces cerevisiae. E.W. Jones, Tackling the Protease Problem in Saccharomyces cerevisiae. H.A. Rauaae, W.H. Mager, and R.J. Planta, Structural and Functional Analysis of Yeast Ribosomal Proteins. T.J. Koerner, J.E. Hill, A.M. Myers, and A. Tzagoloff, High-Expression Vectors with Multiple Cloning Sites for Construction of trpE Fusion Genes: pATH Vectors. D.T. Moir and L.S. Davidow, Production of Proteins by Secretion from Yeast. P.A. Kolodziej and R.A. Young, Epitope Tagging and Protein Surveillance. K. Struhl, Reverse Biochemistry: Methods and Applications for Synthesizing Yeast Proteins in Vitro M.J. Leibowitz, F.P. Barbone, and D.E. Georgopoulos, In Vitro Protein Synthesis. N.F. Lue, P.M. Flanagan, R.J. Kelleher III, A.M. Edwards, and R.D. Kornberg, RNA Polymerase II Transcription in Vitro. J.M. Huibregtse and D.R. Engelke, Direct Sequence and Footprint Analysis of Yeast DNA by Primer Extension. Cell Biology: J.R. Pringle, A.E.M. Adams, D.G. Drubin, and B.K. Haarer, Immunofluorescence Methods for Yeast. B. Byers and L. Goetsch, Preparation of Yeast Cells for Thin-Section Electron Microscopy. M.W. Clark, Immunogold Labeling of Yeast Ultrathin Sections. M.P. Yaffe, Analysis of Mitochondrial Function and Assembly. C.J. Roberts, C.K. Raymond, C.T. Yamashiro, and T.H. Stevens, Methods for Studying the Yeast Vacuole. A. Franzusoff, J. Rothblatt, and R. Schekman, Analysis of Polypeptide Transit through Yeast Secretory Pathway. P.D. Garcia, W. Hansen, and P. Walter, In Vitro Protein Translocation across Microsomal Membranes of Saccharomyces cerevisiae. P. Orlean, M.J. Kuranda, and C.F. Albright, Analysis of Glycoproteins from Saccharomyces cerevisiae. V. Dulic, M. Egerton, I. Elguindi, S. Raths, B. Singer, and H. Riezman, Yeast Endocytosis Assays. C.M. Nicolet and E.A. Craig, Inducing and Assaying Heat-Shock Response in Saccharomyces cerevisiae. M.W. Clark, Nucleolar-Specific Positive Stains for Optical and Electron Microscopy. A.E.M. Adams and J.R. Pringle, Staining of Actin with Fluorochrome-Conjugated Phalloidin. J.R. Pringle, Staining of Bud Scars and Other Cell Wall Chitin with Calcofluor. J.P. Aris and G. Blobel, Isolation of Yeast Nuclei. J.H. Shero, M. Koval, F. Spencer, R.E. Palmer, P. Hieter, and D. Koshland, Analysis of Chromosome Segregation in Saccharomyces cerevisiae. V. Berlin, J.A. Brill, J. Trueheart, J.D. Boeke, and G.R. Fink, Genetic Screens and Selections for Cell and Nuclear Fusion Mutants. Fission Yeast: S. Moreno, A. Klar, and P. Nurse, Molecular Genetic Analysis of Fission Yeast Schizosaccharomyces pombe. Appendix: R.K. Mortimer, D. Schild, C.R. Contopoulou, and J.A. Kans, Genetic and Physical Maps of Saccharomyces cerevisiae. Each chapter includes references. Author Index. Subject Index.
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
- Protein targeting assays
- Biochemistry of Gene Expression
- Vectors for regulated expression
- Isolation of labeled and unlabeled DNA, RNA, and protein
Biochemists, geneticists, molecular and cell biologists, microbiologists, biotechnologists, and graduate and postgraduate students in these disciplines.
- No. of pages:
- © Academic Press 1990
- 28th December 1990
- Academic Press
- eBook ISBN:
@from:Praise for the Volume @qu:"This book will be a valuable resource both for beginners and for current practitioners. It should enable newcomers to set up a yeast laboratory and master basic manipulations." @source:--CAMBRIDGE SCIENTIFIC ABSTRACTS @qu:"Because this book covers so much in what is a technique-rich area, no researcher in the field will want to be without it... This is an exceptional book. While it is indeed a guide to many techniques and methods, in the final analysis, it is more than that. It is also a proclamation that yeast biology is now in the main stream." @source:--ASM NEWS @from:Praise for the Series @qu:"The Methods in Enzymology series represents the gold-standard." @source:--NEUROSCIENCE @qu:"Incomparably useful." @source:--ANALYTICAL BIOCHEMISTRY @qu:"It is a true 'methods' series, including almost every detail from basic theory to sources of equipment and reagents, with timely documentation provided on each page." @source:--BIO/TECHNOLOGY @qu:"The series has been following the growing, changing and creation of new areas of science. It should be on the shelves of all libraries in the world as a whole collection." @source:--CHEMISTRY IN INDUSTRY @qu:"The appearance of another volume in that excellent series, Methods in Enzymology, is always a cause for appreciation for those who wish to successfully carry out a particular technique or prepare an enzyme or metabolic intermediate without the tiresome prospect of searching through unfamiliar literature and perhaps selecting an unproven method which is not easily reproduced." @source:--AMERICAN SOCIETY OF MICROBIOLOGY NEWS @qu:"If we had some way to find the work most often consulted in the laboratory, it could well be the multi-volume series Methods in Enzymology...a great work." @source:--ENZYMOLOGIA @qu:"A series that has established itself as a definitive reference for biochemists." @source:--JOURNAL OF CHROMATOGRAPHY
California Institute of Technology, Division of Biology, Pasadena, U.S.A.
The Salk Institute, La Jolla, CA, USA
University of California, San Francisco, U.S.A.
Whitehead Institute for Biomedical Research and Department of Biology, Massachusetts Institute of Technology, Cambridge, U.S.A.
Elsevier.com visitor survey
We are always looking for ways to improve customer experience on Elsevier.com.
We would like to ask you for a moment of your time to fill in a short questionnaire, at the end of your visit.
If you decide to participate, a new browser tab will open so you can complete the survey after you have completed your visit to this website.
Thanks in advance for your time.