,,-----------------, --~--~--,--.- ----~"--'" GENE CLONING AND DNA ANAL I An Introduction A, ROW Faculty of Life Sciences University of Manchester UK Fifth Edition '~( I~I Blackwell Publishing 'f) 2001 bv BlackWell Ltd 1;;; 2006 T:A. Brown Blackwell Publishing Editorial offices: " Blackwell Publishing Ltd, 9600 Road, Oxford OX4 2DQ, UK Tel: ~A4 (0)1865 776868 Blackwell Publishmg Inc .. 350 Main Malden. MA 02148-5020, USA Tel: +} '781 388 8250 Blackwell Publishing Asia Pty Ltd, 550 Swanston Street, Carltor:, Victoria Australia TeL +61 (Oj3 8359 1011 The right of the Author to be identified the Author of this Work has been accord-anee 'xith the and Patents Act 1988, All rights reserved, No may be reproduced, stored in a retrieval or transmitted, in !lny or electronic, mechanical, nnm(1rr,fWlTW otherwise, except as permitted Designs and Patents prior of the publisher. First, second and third edilions by Chapman & Hall 1S98 6r, o19t9 0L o1Q! G.:; E "thomes (Pubiishers'l t"ff{()MA,., Fourth edition Blackwell Sci. ",Ii Fifth edition '\' , • ~ N r, . " 8 H H. • A , RUAS", j., lSBN-13: 978-14C51-1121-8 a: .... ISB!'J-lO: 1-4051-1121-6 ).AT E, ". ...-. "" ,.-, ..... '\'q'~ ", EsstON NO •. J,;,;:;,.: ... u"'~"""u Da\[1 lIiIil~~'~' an lIltmduction ! T,A. Brown. - 5th ed, em, DNA - Analysis. 572.8' - dc22 2005006606 A catalogue record for this litlr,;; is available from British Library Set iIi JO!D Plfim:;s by SN? Best-set Typesetter Ltd" Print;:;d and bound ill Singapore by Markollo PrilH Ivredia Pte Ltd The publisher'~ polk\' i~ to use permanent from mills that operate a sustainable policy, and which has r.(;:en manufactured nrf)"p,<.prI using acid-free and elementary chlorine·frc·" practices, Fnrthermore, the ensures that the text paper and cover board used have md acceptable C1iviron:me,nt,~1 accreditation standards, For t<.lIther Illfurmation on BJack\vell 1>,,1'_1;,1-:_ visit our website: wW'\Y.blackwellpubJishing,com 7 _7R g-me tM"W1f ..... Contents Preface to the Fifth Edition, xv Preface to the Fourth Edition, xvi Preface to the Third Edition, xvii Preface to the Second Edition, xviii Preface to the First Edition, xx p.~~t '1: ; The Basic Principles of Gene ClonEng and " . ! t . DNA. A~lysis~ 1 ,:,; . 1 ,~TJ1yGene Cloning and DNA Analysis are Important, 3 1.1 The early development of genetics, 3 1.2 The advent of gene cloning and the polymerase chain reaction, 4 1.3 What is gene cloning? 5 1.4 What is PCR? 6 1.5 Why gene cloning and PCR are so important, 8 1.5.1 Gene isolation by cloning, 8 1.5.2 Gene isolation by PCR, 9 1.6 How to find your way through this book, 12 2 Vectors for Gene Cloning: Plasmids and Bacteriophages, 14 2.1 Plasmids. 14 2.1.1 Basic features of plasmids, 14 2.1.2 Size and copy number, 16 2.1.3 Conjugation and compatibility, 17 2.1.4 Plasmid classification, 18 2.1.5 Plasmids in organisms other than bacteria, 19 2.2 Bacteriophages, 19 2.2.1 Basic features of bacteriophages, 19 2.2.2 Lysogenic phages, 20 v t'ir Contents Preface to the Fifth Edition, xv Preface to the Fourth Edition, xvi Preface to the Third Edition, xvii Preface to the Second Edition, xviii Preface to the First Edition, xx t I '( t P~tt '1: The Basic Principles of Gene C~onB!l'!g and DNA" " ~A n., a lysis, 1 ; ~- ,; ; 1 ,yvliyGene Cloning and DNA Analysis are Important, 3 1.1 The early development of genetics, 3 1.2 The advent of gene cloning and the polymerase chain reaction, 4 1.3 What is gene cloning? 5 1,4 What is PCR? 6 1.5 Why gene cloning and PCR are so important, 8 1.5.1 Gene isolation by cloning. 8 1.5.2 Gene isolation by PCR 9 How to find your way through this book, 12 2 Vectors for Gene Cloning: Plasmids and Bacteriophages, 14 2.1 Plasmids, 14 2,1.1 Basic features of plasmids, 14 2,1.2 Size and copy number, 16 2.1.3 Conjugation and compatibility, 17 2.1.4 Plasmid classification,18 2.1.5 Plasmids in organisms other than bacteria, 19 2.2 Bacteriophages, 19 2.2,1 Basic features of bacteriophages, 19 2.2.2 Lysogenic phages, 20 v Contents 4.2.2 Type II restriction endonucleases cut DNA at specific nucleotide sequences, 64 4.2.3 Blunt ends and sticky ends, 64 4.2.4 The frequency of recognition sequences in a DNA molecule, 65 Performing a restriction digest in the laboratory, 68 4.2.6 Analysing the result of restriction endonuclease cleavage, 70 Separation of molecules by,gel electrophoresis, 70 Visualizing DNA molecules by staining a gel, 70 Visualizing DNA molecules by autoradiography, 72 4.2.7 Estimation of the sizes of DNA molecules, 74 4.2.8 :\lapping the positions of different restriction sites in a DNA molecule. 76 4.3 Ligation joining DNA molecules together, 78 4.3.1 The mode of action of DNA ligase, 78 4.3.2 Sticky ends increase the efficiency of ligation, 78 4.3.3 Putting sticky ends onto a blunt-ended molecule, 80 Linkers, 80 Adaptors, 80 Producing sticky ends by homopolymer tailing, 84 5 Introduction of DNA into Living Cells, 87 , Transformation the uptake of DNA by bacterial cells, 90 5.1.1 Not all species of bacteria are equally efficient at DNA uptake, 90 Preparation of competent E. coli cells, 90 5.1.3 Selection for transformed cells, 91 5.2 Identification of recombinants, 93 5.2.1 Recombinant selection with pBR322 insertional inactivation of an antibiotic resistance gene, 93 5.2.2 Insertional inactivation does not always involve antibiotic resistance, 95 5.3 Introduction of phage DNA into bacterial cells, 97 5.3.1 Transfection,98 5.3.2 In vitro packaging of A cloning vectors, 98 5.3.3 Phage infection is visualized as plaques on an agar medium, 99 5.4 Identification of recombinant phages, 101 5.4.1 Insertional inactivation of a lacZ' gene carried by the phage vector, 101 5.4.2 Insertional inactivation of the AcI 101 vii Contents 5.4.3 Selection using the Spi phenotype, 103 5.4.4 Selection on the basis of 'A genome size, 103 5.5 Introduction of DNA into non-bacterial cells, 103 5.5.1 Transformation of individual cells, 103 5.5.2 Transformation of whole organisms, 106 6 Cloning Vectors for E. coli. 107 6.1 Cloning vectors based on E. coli plasmids, 108 6.1.1 1be nomenclature of plasmid cloning vectors, 108 6.1.2 The useful properties of pBR322, 108 6.1.3 The pedigree of pBR322, 109 6.1.4 More sophisticated E. coli plasmid cloning vectors, 109 pUC8 - a Lac selection plasmid, 111 pGEM3Z in vitro transcription of cloned DNA, 113 6.2 Cloning vectors based on M13 bacteriophage, 114 6.2.1 Development of the M13 cloning vectors, 115 M13mp7 - symmetrical cloning sites, 115 More complex M13 vectors, 118 6.2.2 Hybrid plasmid-M13 vectors, 120 6.3 Cloning vectors based on A bacteriophage, 120 6.3.1 Segments of the A genome can be deleted without impairing viability, 122 6.3.2 Natural selection can be used to isolate modified A that lack certain restriction sites, 123 6.3.3 Insertion and replacement vectors, 123 Insertion vectors, 123 Replacement vectors, 124 6.3.4 Cloning experiments with Ainsertion or replacement vectors. 126 6.3.5 Long DNA fragments can be cloned using a cosmid, 127 6.4 A and other high capacity vectors enable genomic libraries to be constructed, 129 6.5 Vectors for other bacteria. 130 7 Cloning Vectors for Eukaryotes, 132 7.1 Vectors for yeast and other fungi, 132 7.1.1 Selectable markers for the 2 J.lm plasmid, 132 7.1.2 Vectors based on the 2 J.lm plasmid yeast episomal plasmids, 133 7.1.3 A YEp may insert into yeast chromosomal DNA, 135 7.1.4 Other types of yeast cloning vector, 135 7.1.5 Artificial chromosomes can be used to clone long pieces of DNA in yeast, 138 viii •__=2.'.7_7.·.·._______________________________ .._.. . .. l .tA.. .._ ....A..V.W.i NAYI_.__l* .!~-.,....."".,.-£.~- Contents The structure and use of a YAC vector. 138 Applications for YAC vectors, 140 7.1.6 Vectors for other yeasts and fungi, 140 7.2 Cloning vectors for higher plants, 141 7.2.1 Agrobacterium rumefaciens nature's smallest genetic engineer, 141 Using the Ti plasmid to introduce new genes into a plant cell, 142 Production of transformedpl'<lnts with the Ti plasmid, 145 The Ri plasmid, 145 Limitations of cloning with Agrobacterium plasmids, 146 7.2.2 Cloning genes in plants by direct gene transfer, 147 Direct gene transfer into the nucleus, 147 Transfer of genes into the chloroplast genome, 149 7.2.3 Attempts to use plant viruses as cloning vectors, 150 Caulimovirus vectors, 150 Geminivirus vectors. 150 7.3 Cloning vectors for animals, 151 7.3.1 Cloning vectors for insects, 151 P elements as cloning vectors for Drosophila, 151 Cloning vectors based on insect viruses, 153 7.3.2 Cloning in mammals, 153 Cloning vectors for mammals, 153 Gene cloning without a vector, 155 8 How to Obtain a Clone of a Specific Gene, 158 8.1 The problem of selection, 158 8.1.1 There are two basic strategies for obtaining the clone you want, 158 8.2 Direct selection. 159 8.2.1 Marker rescue extends the scope of direct selection, 161 8.2.2 The scope and limitations of marker rescue. 163 8.3 Identification of a clone from a gene library, 163 8.3.1 Gene libraries. 163 8.3.2 l'·Jot all genes are expressed at the same time, 164 8.3.3 mRNA can be cloned as complementary DNA, 166 8,4 Methods for clone identification. 166 8.4.1 Complementary nucleic acid strands hybridize to each other, 166 8.4.2 Colony and plaque hybridization probing, 168 8.4.3 Examples of the practical use of hybridization probing, 172 ix Contents Abundancy probing to analyse a cDNA library, 172 Oligonucleotide probes for genes whose translation products have been characterized, 172 Heterologous probing allows related genes to be identified, 176 8,4,4 Identification methods based on detection of the translation product of the cloned gene, 177 Antibodies are required for immunological detection methods, 177 Using a purified antibody to detect protein in recombinant colonies, 178 'The problem of gene expression, 178 9 The Polymerase Chain Reaction, 181 9.1 The polymerase chain reaction in outline, 181 9.2 PCR in more detail, 184 9.2.1 Designing the oligonucleotide primers for a PCR, 184 9.2.2 Working out the correct temperatures to use, 186 9.2.3 After the PCR: studying PCR products, 189 Gel electrophoresis of PCR products, 189 Cloning PCR products, 190 9.3 Problems with the error rate of Taq polymerase, 193 Part The Applications of Gene Cloning and DNA A.nalysis in Research, 197 10 Studying Gene Location and Structure, 199 10.1 How to study the location of a gene, 199 10.1.1 Locating the position of a gene on a small DNA molecule, 199 10.1.2 Locating the position of a gene on a large DNA molecule, 202 Separating chromosomes by gel electrophoresis, 203 In situ hybridization to visualize the position of a gene on a eukaryotic chromosome, 205 10.2 DNA sequencing - working out the structure of a gene, 207 10.2.1 The Sanger-Coulson method chain-terminating nucleotides, 207 The primer, 207 Synthesis of the complementary strand, 207 Four separate reactions result in four families of terminated strands, 209 Reading the DNA sequence from the autoradiograph, 209 x