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Transgenic Animal Technology. A Laboratory Handbook PDF

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Transgenic Animal Technology Transgenic Animal Technology A Laboratory Handbook Third Edition Edited by Carl A. Pinkert The University of Alabama Tuscaloosa, AL, USA AMSTERDAM(cid:1)BOSTON(cid:1)HEIDELBERG(cid:1)LONDON(cid:1)NEWYORK(cid:1)OXFORD PARIS(cid:1)SANDIEGO(cid:1)SANFRANCISCO(cid:1)SINGAPORE(cid:1)SYDNEY(cid:1)TOKYO Elsevier 32JamestownRoad,LondonNW17BY 225WymanStreet,Waltham,MA02451,USA Thirdedition2014 Copyright©2014,2002,1994ElsevierInc.Allrightsreserved Nopartofthispublicationmaybereproducedortransmittedinanyformorbyanymeans, electronicormechanical,includingphotocopying,recording,oranyinformationstorage andretrievalsystem,withoutpermissioninwritingfromthepublisher.Detailsonhowto seekpermission,furtherinformationaboutthePublisher’spermissionspoliciesandour arrangementwithorganizationssuchastheCopyrightClearanceCenterandtheCopyright LicensingAgency,canbefoundatourwebsite:www.elsevier.com/permissions. Thisbookandtheindividualcontributionscontainedinitareprotectedundercopyright bythePublisher(otherthanasmaybenotedherein). Notices Knowledgeandbestpracticeinthisfieldareconstantlychanging.Asnewresearch andexperiencebroadenourunderstanding,changesinresearchmethods,professional practices,ormedicaltreatmentmaybecomenecessary. Practitionersandresearchersmustalwaysrelyontheirownexperienceandknowledgein evaluatingandusinganyinformation,methods,compounds,orexperimentsdescribedherein. Inusingsuchinformationormethodstheyshouldbemindfuloftheirownsafetyandthe safetyofothers,includingpartiesforwhomtheyhaveaprofessionalresponsibility. Tothefullestextentofthelaw,neitherthePublishernortheauthors,contributors,or editors,assumeanyliabilityforanyinjuryand/ordamagetopersonsorpropertyasa matterofproductsliability,negligenceorotherwise,orfromanyuseoroperationofany methods,products,instructions,orideascontainedinthematerialherein. BritishLibraryCataloguing-in-PublicationData AcataloguerecordforthisbookisavailablefromtheBritishLibrary LibraryofCongressCataloging-in-PublicationData AcatalogrecordforthisbookisavailablefromtheLibraryofCongress ISBN:978-0-12-410490-7 ForinformationonallElsevierpublications visitoutwebsiteatstore.elsevier.com ThisbookhasbeenmanufacturedusingPrintOnDemandtechnology.Eachcopyis producedtoorderandislimitedtoblackink.Theonlineversionofthisbookwillshow colorfigureswhereappropriate. List of Contributors Satoshi Akagi Animal Breeding and Reproduction Research Division, Institute of Livestock and Grassland Science, National Agriculture and Food Research Organization,Tsukuba,Ibaraki,Japan Anna V. Anagnostopoulos Mouse Genome Informatics, The Jackson Laboratory, BarHarbor,ME Benjamin P. Beaton Division of Animal Sciences, University of Missouri, Columbia,MO CoryF.Brayton JohnsHopkinsUniversity,Baltimore,MD SteveBrown MRCMammalianGeneticsUnit,Harwell,Oxford,UK Anthony W.S. Chan Yerkes National Primate Research Center, Department of Human Genetics, Department of Pediatrics, Emory University School of Medicine, EmoryUniversity,Atlanta,GA TomDoetschman UniversityofArizona,Tucson,AZ Rex A. Dunham School of Fisheries, Aquaculture, and Aquatic Sciences, Auburn University,Auburn,AL David A. Dunn Department of Biological Sciences, State University of New York atOswego,Oswego,NY Janan T. Eppig Mouse Genome Informatics, The Jackson Laboratory, Bar Harbor,ME Almudena Ferna´ndez National Centre for Biotechnology (CNB-CSIC), DepartmentofMolecularandCellularBiology,Madrid,Spain Tatiana Flisikowska Livestock Biotechnology, Technische Universita¨t Mu¨nchen, Freising,Germany xiv ListofContributors Vasiliy Galat Department of Pediatrics, Northwestern University Medical School and Developmental Biology Program, Ann & Robert H. Lurie Children’s Hospital ofChicagoResearchCenter,Chicago,IL Robert A. Godke Embryo Biotechnology Laboratory, Department of Animal Science,LouisianaStateUniversity,BatonRouge,LA Philip Iannaccone Department of Pediatrics, Northwestern University Medical School and Developmental Biology Program, Ann & Robert H. Lurie Children’s HospitalofChicagoResearchCenter,Chicago,IL Michael H. Irwin Department of Pathobiology, College of Veterinary Medicine, AuburnUniversity,Auburn,AL Larry W. Johnson Department of Genetics, The University of Alabama at Birmingham,Birmingham,AL Yoko Kato Laboratory of Animal Reproduction, College of Agriculture, Kinki University,Nakamachi,Nara,Japan Teoan Kim Department of Physiology, Catholic University of Daegu School of Medicine,Daegu,RepublicofKorea Alexander Kind Livestock Biotechnology, Technische Universita¨t Mu¨nchen, Freising,Germany BonChulKoo DepartmentofPhysiology,CatholicUniversityofDaeguSchoolof Medicine,Daegu,RepublicofKorea Mo Sun Kwon Department of Physiology, Catholic University of Daegu School ofMedicine,Daegu,RepublicofKorea DanielJ.Ledbetter DepartmentofBiology,UniversityofKentucky,Lexington,KY MichaelJ.Martin SpringPointProject,Minneapolis,MN Kazutsugu Matsukawa Multidisciplinary Science Cluster, Life and Environmental MedicineScienceUnit,KochiUniversity,Nankoku,Kochi,Kerala,India Colin McKerlie The Hospital for Sick Children and University of Toronto, Toronto,ON,Canada Llu´ıs Montoliu National Centre for Biotechnology (CNB-CSIC), Department of MolecularandCellularBiology,Madrid,Spain ListofContributors xv Paul E. Mozdziak Prestage Department of Poultry Science College of Agriculture andLifeSciencesNorthCarolinaStateUniversityRaleigh,NCUSA Akira Onishi Transgenic Pig Research Unit, Genetically Modified Organism ResearchCenter,NationalInstituteofAgrobiologicalSciences,Tsukuba,Ibaraki,Japan PaulA. Overbeek Department of Molecular and Cellular Biology, Baylor College ofMedicine,Houston,TX James N. Petitte Prestage Department of Poultry Science College of Agriculture andLifeSciencesNorthCarolinaStateUniversityRaleigh,NCUSA L.PhilipSanford UniversityofIowa,IowaCity,IA Jorge A. Piedrahita Department of Molecular Biomedical Sciences, North CarolinaStateUniversity,Raleigh,NC CarlA.Pinkert Department of Biological Sciences, College ofArts andSciences, TheUniversityofAlabama,Tuscaloosa,AL Wendy K. Pogozelski Department of Chemistry, State University of New York at Geneseo,Geneseo,NY H. Greg Polites Sanofi R1D Tucson, Sanofi Tucson Research Center, Oro Valley,AZ Edmund B. Rucker III Department of Biology, University of Kentucky, Lexington,KY Marina Sansinena Embryo Biotechnology Laboratory, Department of Animal Science,LouisianaStateUniversity,BatonRouge,LA Angelika Schnieke Livestock Biotechnology, Technische Universita¨t Mu¨nchen, Freising,Germany Kumiko Takeda National Agricultural and Food Research Organization, NARO InstituteofLivestockandGrasslandScience,Tsukuba,Japan James A. Thomson Plant Gene Expression Center, USDA-University of California, Berkeley,Albany,CA Ian A. Trounce Center for Eye Research Australia, University of Melbourne, Department of Ophthalmology, Royal Victorian Eye and Ear Hospital, East Melbourne,Australia xvi ListofContributors Yukio Tsunoda Laboratory of Animal Reproduction, College of Agriculture, KinkiUniversity,Nakamachi,Nara,Japan Cristina Vicente-Garc´ıa National Centre for Biotechnology (CNB-CSIC), DepartmentofMolecularandCellularBiology,Madrid,Spain Kevin D. Wells Division of Animal Sciences, National Swine Resource and ResearchCenter,UniversityofMissouri,Columbia,MO Richard N. Winn Warnell School of Forest Resources, University of Georgia, Athens,GA CurtisR.Youngs DepartmentofAnimalScience,IowaStateUniversity,Ames,IA Preface In discussions regarding the third edition of “Transgenic Animal Technology: A Laboratory Handbook,” we wrestled with the changing tide of technologies and a revision of the title for 2014. It has, after all, been over two decades since the origi- naltitlewasestablished.Wastransgenicnowalimitingterm?Weretheembryologi- cal, animal husbandry, reproductive biology, and molecular techniques something that should be highlighted in some bolder fashion? Yet it remained true that transgenic animal technologies and the ability to introduce and modify functional genes in animal models continue to represent powerful, dynamic, and evolving tools for dissecting complex biological processes. The questions to be addressed span the scientific spectrum from biomedical and biological applications to production agriculture. And yes, as transgenic methodologies continue to evolve, they have dra- matically influencedacrosssection ofdisciplinesandarerecognizedasinstrumental inexpandingourunderstandingofgeneexpression,regulation,andfunction. There are many general reviews on the topic of animal transgenesis and genetic engineering that are indeed very useful and timely. However, aside from the man- uals devoted to mouse embryology, a single text illustrating the methodologies employed by leading laboratories in their respective disciplines had not previously been compiled priortothefirsteditionofthistext.Thisthirdeditioncovers techni- cal aspects of gene transfer in animals—from molecular methods to whole animal considerations across a host of species. Consequently, we kept the title and focus for this handbook, and it is envisioned as a bridge for researchers and a tool to facilitate training of studentsand techniciansinthe development and use ofnumer- oustransgenicanimal modelsystems. Clearly, much has changed from a technological perspective since the first two editions in 1994 and 2002. With this in mind, I would like to acknowledge all of the contributing authors both past and present, as well as those individuals in my laboratory who have assisted over the course of these three editions. In preparation of the three editions, a number of colleagues have graciously provided assistance in reviewing specific chapters and in some cases providing additional data for consideration prior to publication, for which we are all most grateful. I would also like to acknowledge all of my mentors, colleagues, and those who came through my laboratory over the years. Lastly, I am appreciative of the consideration and help provided by Halima Williams, Radhakrishnan Lakshmanan and their colleaguesatElsevierforfacilitatingpublicationofthisthirdedition. CarlA.Pinkert Tuscaloosa,Alabama 1 Introduction to Transgenic Animal Technology Carl A. Pinkert DepartmentofBiologicalSciences,CollegeofArtsandSciences,TheUniversity ofAlabama,Tuscaloosa,AL I. Introduction The last three decades witnessed a rapid advance of the application of genetic engineeringtechniquesforincreasinglycomplexorganisms,fromsingle-cellmicrobial and eukaryotic culture systems to multicellular whole-animal systems. The whole animal is generally recognized as an essential tool for biomedical and biological research,aswellasforpharmaceuticaldevelopmentandtoxicological/safetyscreening technologies. Moreover, an understanding of the developmental and tissue-specific regulationofgeneexpressionisachievedonlythroughinvivowhole-animalstudies. Today, particularly with gene editing technologies on the rise, transgenic animals (andanimalbiotechnologies)continuetoembodyoneofthemostpotentandexciting researchtoolsinthebiologicalsciences.Transgenicanimalsrepresentuniquemodels thatarecustomtailoredtoaddress specificbiologicalquestions.Hence,theabilityto introduce functional genes into animals provides a very powerful tool for dissecting complex biological processes and systems. Gene transfer is of particular value in those animal species where long life cycles reduce the value of classical breeding practices for rapid genetic modification. Foridentificationofinterestingnewmodels, geneticscreeningandcharacterizationofchancemutationsremainalongandarduous task. Furthermore,classicalgenetic monitoringcannotadequatelyengineera specific genetictraitinadirectedfashion. II. Historical Background In the early 1980s, only a handful of laboratories possessed the technology neces- sary to produce transgenic animals. With this in mind, this text is envisioned as a bridge to the development of various transgenic animal models. Hopefully, through the first two editions the curiosity and interests of researchers in diverse research fields were influenced productively. The gene transfer technology that is currently utilized across vertebrate species was pioneered using mouse and domestic animal models. Today, the mouse continues to serve as a starting point TransgenicAnimalTechnology.DOI:http://dx.doi.org/10.1016/B978-0-12-410490-7.00001-3 ©2014ElsevierInc.Allrightsreserved. 4 TransgenicAnimalTechnology for implementing a variety of gene transfer procedures and is the standard for optimizing experimental efficiencies for many species. Inherent species differ- ences are frequently discounted by researchers who are planning studies with a more applicable species model. However, when one attempts to compare experi- mental results generated in mice to those obtained in other species, not surpris- ingly many differences become readily apparent. Therefore, an objective of this textwillbetoaddresstheadaptationofrelevantprotocols. When initiating work related to gene transfer, it is important to look at the rapid advancement of a technology that is still primitive by many standards. From an historical perspective, one readily contemplates potential technologies and methods that lie just ahead. Whereas modern recombinant DNA techniques are of primary importance, the techniques of early mammalian embryologists were crucial to the development of gene transfer technology. While we can look at well over three decades of transgenic animal production, the preliminary experiments leading to this text go back millennia to the first efforts to artificially regulate or synchronize embryo development. Amazingly, it has been more than a century since the first successful embryo transfer experiments, dating back to the efforts first published in the 1880s and to Heape’s success in 1891 (Heape, 1891). By the time the studies by Hammond were reported in the late 1940s, culture systems were developed that sustained ova throughseveral cleavagedivisions.Suchmethods provideda means to systematicallyinvestigateanddevelopproceduresforavarietyofeggmanipulations. These early studies led to experiments that ranged from mixing of mouse embryos andproductionofchimericanimals,tothetransferofinnercellmasscellsandterato- carcinomacells,tonucleartransferandthefirstinjectionsofnucleicacidsintodevel- opingova.Withouttheabilitytocultureormaintainovainvitro,suchmanipulations ortherequisiteinsightswouldnotbepossible(BrinsterandPalmiter,1986). Gurdon (1977) transferred mRNA and DNA into Xenopus eggs and observed thatthetransferrednucleicacidscouldfunctioninanappropriatemanner.Thiswas followed by a report by Brinster et al. (1980) of similar studies in a mammalian system, using fertilized mouse ova in initial experiments. Here, using rabbit globin mRNA,anappropriatetranslationalproductwasobtained. Major turning points in science continue to accelerate at an incredible pace. The technology available in 1994 had developed considerably and, as predicted, a number of areas from both the first and second editions of this text are clearly antiquated or obsolete today. It is amazing to look back at the major events related to genetic engineering of animals and how our ability to manipulate both the nuclearandmitochondrialgenomeshascomesofar. The production of transgenic mice has been hailed as a seminal event in the development of animal biotechnology. In reviewing the early events leading to thefirstgeneticallyengineeredmice,itisfascinatingtonotethattheentireproce- dure for DNA microinjection was described nearly 50 years ago. While some progress seems extremely rapid, it is still difficult to believe that, following the first published report of a microinjection method in 1966 (Lin, 1966; Figures 1.1 and 1.2), it would be another 15 years before transgenic animals were created. The pioneering laboratories that reported success at gene transfer would

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Transgenic animal technologies and the ability to introduce functional genes into animals have revolutionized our ability to address complex biomedical and biological questions. This well-illustrated handbook covers the technical aspects of gene transfer - from molecular methods to whole animal cons
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