Gene knockout protocols

Following the completion of the mouse and human genome sequences, a major challengeisthefunctionalcharacterizationofeverymammaliangeneandthedeciph- ing of their molecular interaction network. The mouse offers many advantages for the use of genetics to study human biology and disease, unmatched among other m- mals. Its development, body plan, physiology, behavior, and diseases have much in common, based on the fact that 99% of the human genes have a mouse ortholog. The investigation of gene function using mouse models is based on many years of tech- logical development. In the two decades since gene targeting in murine embryonic stem (ES) cells was first described by Mario Capecchi and colleagues, more than 3000 predesigned mouse mutants have been developed. To date, a variety of mouse mutagenesis techniques, either gene- or phenotype-driven, are used as systematic approaches. The availability of the genome sequence supports gene-driven approaches such as gene-trap and targeted mutagenesis in ES cells, allowing efficient and precise gene disruption. In combination with the use of site-specific DNA recombinases, in particular the Cre/loxP system, gene disruptioncan be directed to specific cell types in conditionalmousemutants. Furthermore,chemicalandtransposonmutagenesisofthe mouse genome enables us to perform phenotype-driven screens for the unbiased identification of phenotype-genotype correlations involved in models of human d- ease. Over the next several years, the mouse genome will be systematically altered, and the techniques for achieving predesigned manipulations will be constantly developed further and improved. The second edition of Gene Knockout Protocols brings together distinguished c- tributorswithextensiveexperienceinthegenetargetingandmousegeneticsfields.

Chapter 1 Overview on Mouse Mutagenesis Ralf Kuhn and Wolfgang Wurst Section I. Gene Modification in ES Cells Chapter 2 Construction of Gene Targeting Vectors by Recombineering Song-Choon Lee, Wei Wang, and Pentao Liu Chapter 3 Gene Trap Vectors and Mutagenesis Silke De-Zolt, Joachim Altschmied,, Patricia Ruiz, Harald von Melchner, and Frank Schnutgen Chapter 4 Chromosome Engineering in ES Cells Louise van der Weyden, Charles Shaw-Smith, and Allan Bradley Chapter 5 Gene Modification in Embryonic Stem Cells by Single-Stranded DNA Oligonucleotides Marieke Aarts, Marleen Dekker, Rob Dekker, Sandra de Vries, Anja van der Wal, Eva Wielders, and Hein te Riele Chapter 6 Generation of shRNA Transgenic Mice Christiane Hitz, Patricia Steuber-Buchberger,Sabit Delic, Wolfgang Wurst, and Ralf Kuhn Chapter 7 Mutagenesis of Mouse Embryonic Stem Cells with Ethylmethanesulfonate Robert Munroe and John Schimenti Section II. Stem Cell Manipulation Chapter 8 Gene Targeting in Mouse Embryonic Stem Cells Lino Tessarollo, Mary Ellen Palko, Keiko Akagi, and Vincenzo Coppola Chapter 9 Manipulating Mouse Embryonic Stem Cells Eileen Southon and Lino Tessarollo Chapter 10 ES Cell Line Establishment Heidrun Kern and Branko Zevnik Chapter 11 Generation of Double Knockout Embryonic Stem Cells Eva Wielders, Marleen Dekker, and Hein te Riele Chapter 12 Differentiation Analysis of Pluripotent Mouse Embryonic Stem (ES) Cells in vitro Insa S. Schroeder, Cornelia Wiese, Thuy T.Truong, Alexandra Rolletschek, and Anna M. Wobus Chapter 13 Cloning of ES cells and Mice by Nuclear Transfer Sayaka Wakayama, Satoshi Kishigami, and Teruhiko Wakayama Section III. Genetically Engineered Mice Chapter 14 Isolation, Microinjection, and Transfer of Mouse Blastocysts Susan W. Reid and Lino Tessarollo Chapter 15 Aggregation Chimeras: Combining ES Cells, Diploid and Tetraploid Embryos Mika Tanaka, Anna-Katerina Hadjantonakis, Kristina Vintersten, and Andras Nagy Chapter 16 VelociMouse: Fully ES Cell-Derived F0 Generation Mice Obtained from the Injection of ES Cells into 8-Cell Stage Embryos Thomas M. DeChiara, William T. Poueymirou, Wojtek Auerbach, David Frendewey, George D. Yancopoulos, and David M. Valenzuela Chapter 17 Generation of Cre Recombinase Expressing Transgenic Mice Using Bacterial Artificial Chromosomes Jan Rodriguez Parkitna, David Engblom, and Gunther Schutz Chapter 18 Inducible Cre Mice Susanne Feil, Nadejda Valtcheva, and Robert Feil Chapter 19 Creation and Use of a Cre Recombinase Transgenic Database Andras Nagy, Lynn Mar, and Graham Watts Chapter 20 Transposon Mutagenesis in Mice David A. Largaespada Chapter 21 Lentiviral Transgenesis Alexander Pfeifer and Andreas Hofmann Chapter 22 Sperm Cryopreservation and In Vitro Fertilization Susan Marschall, Auke Boersma, and Martin Hrabe de Angelis Section IV. Phenotype Analysis Chapter 23 Influence of Genetic Background on Genetically Engineered Mouse Phenotypes Thomas