Leading drosophilists describe in step-by-step detail all the essential techniques for studying Drosophila chromosomes and suggest new avenues for scientific exploration. The chapters emphasize specimen preparation (from dissection to mounting) and cover both polytene and mitotic/meiotic chromosomes in depth. Each fully tested and readily reproducible protocol offers a background introduction, equipment and reagent lists, and tips on troubleshooting and avoiding pitfalls. A cutting-edge FISH and immunolocalization technique will be important for discovering how DNA sequence influences higher-order chromosome architecture and ultimately gene expression.

The first edition of this book, published in 1999 and called DNA Repair Protocols: Eukaryotic Systems, brought together laboratory-based methods for studying DNA damage and repair in diverse eukaryotes: namely, two kinds of yeast, a nematode, a fruit fly, a toad, three different plants, and human and murine cells. This second edition of DNA Repair Protocols covers mammalian cells only and hence its new subtitle, Mammalian Systems. There are two reasons for this fresh emphasis, both of them pragmatic: to cater to the interests of what is now a largely mammalocentric DNA repair field, and to expedite editing and prod- tion of this volume. Although DNA Repair Protocols: Mammalian Systems is a smaller book than its predecessor, it actually contains a greater variety of methods. Fourteen of the book's thirty-two chapters are entirely new and areas of redundancy present in the first edition have been eliminated here (for example, now just two chapters describe assays for nucleotide excision repair [NER], rather than seven). All eighteen returning chapters have been revised, many of them ext- sively. In order to maintain a coherent arrangement of topics, the four-part p- titioning seen in the first edition was dispensed with and chapters concerned with ionizing radiation damage and DNA strand breakage and repair were re- cated to near the front of the book. Finally, an abstract now heads each chapter.

The field of eukaryotic DNA repair is enjoying a period of remarkable growth and discovery, fueled by technological advances in molecular bi- ogy, protein biochemistry, and genetics. Notable achievements include the molecular cloning of multiple genes associated with classical human repair disorders, such as xeroderma pigmentosum, Cockayne syndrome, and ataxia telangiectasia; elucidation of the core reaction of nucleotide excision repair (NER); the discovery that certain NER proteins participate not only in repair, but also in transcription; recognition of the crucial role played by mismatch repair processes in maintenance of genome stability and avoidance of cancer; the findings that the tumor suppressor protein p53 is mutated in many types of cancer, and has a key role in directing potentially malignant, genotoxin-d- aged cells towards an apoptotic fate; and the discovery and elaboration of DNA damage (and replication) checkpoints, which placed repair phenomen- ogy firmly within a cell-cycle context. Of course, much remains to be learned about DNA repair. To that end, DNA Repair Protocols: Eukaryotic Systems is about the tools and techniques that have helped propel the DNA repair field into the mainstream of biological research. DNA Repair Protocols: Eukaryotic Systems provides detailed, step-- step instructions for studying manifold aspects of the eukaryotic response to genomic injury. The majority of chapters describe methods for analyzing DNA repair processes in mammalian cells. However, many of those techniques can be applied with only minor modification to other systems, and vice versa.

The field of eukaryotic DNA repair is enjoying a period of remarkable growth and discovery, fueled by technological advances in molecular biol- ogy, protein biochemistry, and genetics. Notahle achievements include the molecular cloning of multiple genes associated with classical human repair disorders, such as xeroderma pigmentosum, Cockayne syndrome, and ataxia telangiectasia; elucidation of the core reaction of nucleotide excision repair (NER); the discovery that certain NER proteins participate not only in repair, but also in transcription; recognition of the crucial role played by mismatch repair processes in maintenance of genome stability and avoidance of cancer; the findings that the tumor suppressor protein p53 is mutated in many types of cancer, and has a key role in directing potentially malignant, genotoxin-dam- aged cells towards an apoptotic fate; and the discovery and elaboration of DNA darnage (and replication) checkpoints, which placed repair phenomenol- ogy firmly within a cell-cycle context. Of course, much remains to be learned about DNA repair. Tothat end, DNA Repair Protocols: Eukaryotic Systems is about the tools and techniques that have helped propel the DNA repair field into the mainstream of biological research. DNA Repair Protoco/s: Eukaryotic Systems provides detailed, step-by- step instructions for studying manifold aspects of the eukaryotic response to genomic injury. The majority of chapters describe methods for analyzing DNA repair processes in mammalian cells. However, many ofthose techniques can be applied with only minor modification to other systems, and vice versa.

The field of eukaryotic DNA repair is enjoying a period of remarkable growth and discovery, fueled by technological advances in molecular bi- ogy, protein biochemistry, and genetics. Notable achievements include the molecular cloning of multiple genes associated with classical human repair disorders, such as xeroderma pigmentosum, Cockayne syndrome, and ataxia telangiectasia; elucidation of the core reaction of nucleotide excision repair (NER); the discovery that certain NER proteins participate not only in repair, but also in transcription; recognition of the crucial role played by mismatch repair processes in maintenance of genome stability and avoidance of cancer; the findings that the tumor suppressor protein p53 is mutated in many types of cancer, and has a key role in directing potentially malignant, genotoxin-d- aged cells towards an apoptotic fate; and the discovery and elaboration of DNA damage (and replication) checkpoints, which placed repair phenomen- ogy firmly within a cell-cycle context. Of course, much remains to be learned about DNA repair. To that end, DNA Repair Protocols: Eukaryotic Systems is about the tools and techniques that have helped propel the DNA repair field into the mainstream of biological research. DNA Repair Protocols: Eukaryotic Systems provides detailed, step-- step instructions for studying manifold aspects of the eukaryotic response to genomic injury. The majority of chapters describe methods for analyzing DNA repair processes in mammalian cells. However, many of those techniques can be applied with only minor modification to other systems, and vice versa.

The first edition of this book, published in 1999 and called DNA Repair Protocols: Eukaryotic Systems, brought together laboratory-based methods for studying DNA damage and repair in diverse eukaryotes: namely, two kinds of yeast, a nematode, a fruit fly, a toad, three different plants, and human and murine cells. This second edition of DNA Repair Protocols covers mammalian cells only and hence its new subtitle, Mammalian Systems. There are two reasons for this fresh emphasis, both of them pragmatic: to cater to the interests of what is now a largely mammalocentric DNA repair field, and to expedite editing and prod- tion of this volume. Although DNA Repair Protocols: Mammalian Systems is a smaller book than its predecessor, it actually contains a greater variety of methods. Fourteen of the book's thirty-two chapters are entirely new and areas of redundancy present in the first edition have been eliminated here (for example, now just two chapters describe assays for nucleotide excision repair [NER], rather than seven). All eighteen returning chapters have been revised, many of them ext- sively. In order to maintain a coherent arrangement of topics, the four-part p- titioning seen in the first edition was dispensed with and chapters concerned with ionizing radiation damage and DNA strand breakage and repair were re- cated to near the front of the book. Finally, an abstract now heads each chapter.

The field of eukaryotic DNA repair is enjoying a period of remarkable growth and discovery, fueled by technological advances in molecular biol- ogy, protein biochemistry, and genetics. Notahle achievements include the molecular cloning of multiple genes associated with classical human repair disorders, such as xeroderma pigmentosum, Cockayne syndrome, and ataxia telangiectasia; elucidation of the core reaction of nucleotide excision repair (NER); the discovery that certain NER proteins participate not only in repair, but also in transcription; recognition of the crucial role played by mismatch repair processes in maintenance of genome stability and avoidance of cancer; the findings that the tumor suppressor protein p53 is mutated in many types of cancer, and has a key role in directing potentially malignant, genotoxin-dam- aged cells towards an apoptotic fate; and the discovery and elaboration of DNA darnage (and replication) checkpoints, which placed repair phenomenol- ogy firmly within a cell-cycle context. Of course, much remains to be learned about DNA repair. Tothat end, DNA Repair Protocols: Eukaryotic Systems is about the tools and techniques that have helped propel the DNA repair field into the mainstream of biological research. DNA Repair Protoco/s: Eukaryotic Systems provides detailed, step-by- step instructions for studying manifold aspects of the eukaryotic response to genomic injury. The majority of chapters describe methods for analyzing DNA repair processes in mammalian cells. However, many ofthose techniques can be applied with only minor modification to other systems, and vice versa.