With its author team of prominent scientists who are also highly accomplished educators, An Introduction to Genetic Analysis again combines exceptional currency, expansive updating of its acclaimed problem sets, and a variety of new ways to learn genetics. Historical experiments have also been woven into the text to help students understand how discoveries are .
This textbook can also be packaged with SaplingPlus; an online learning platform that combines heavily research based pre-lectures with the robust Sapling homework system, in which every problem has targeted feedback, hints, and a fully worked and explained solution. An experienced author team brings together a unique set of expertise and perspectives to help master concepts and succeed in developing problem-solving .
1 The Genetics Revolution in the Life Sciences
2 Single-Gene Inheritance
3 Independent Assortment of Genes
4 Mapping Eukaryote Chromosomes by Recombination
5 Gene Interaction6 The Genetics of Bacteria and Their Viruses
7 DNA: Structure and Replication
8 RNA: Transcription and Processing
9 Proteins and Their Synthesis
10 Gene Isolation and Manipulation
11 Regulation of Gene Expression in Bacteria and Their Viruses
12 Regulation of Transcription in Eukaryotes
13 The Genetic Control of Development
14 Genomes and Genomics
15 Mutation, Repair, and Recombination16 The Dynamic Genome: Transposable Elements
17 Large-Scale Chromosomal Changes
18 Population Genetics
19 The Inheritance of Complex Traits
20 Evolution of Genes, Traits, and Species
With its author team of prominent scientists who are also highly accomplished educators, An Introduction to Genetic Analysis again combines exceptional currency, expansive updating of its acclaimed problem sets, and a variety of new ways to learn genetics. Historical experiments have also been woven into the text to help students understand how discoveries are .
This textbook can also be packaged with SaplingPlus; an online learning platform that combines heavily research based pre-lectures with the robust Sapling homework system, in which every problem has targeted feedback, hints, and a fully worked and explained solution. An experienced author team brings together a unique set of expertise and perspectives to help master concepts and succeed in developing problem-solving .
1 The Genetics Revolution in the Life Sciences
2 Single-Gene Inheritance
3 Independent Assortment of Genes
4 Mapping Eukaryote Chromosomes by Recombination
5 Gene Interaction6 The Genetics of Bacteria and Their Viruses
7 DNA: Structure and Replication
8 RNA: Transcription and Processing
9 Proteins and Their Synthesis
10 Gene Isolation and Manipulation
11 Regulation of Gene Expression in Bacteria and Their Viruses
12 Regulation of Transcription in Eukaryotes
13 The Genetic Control of Development
14 Genomes and Genomics
15 Mutation, Repair, and Recombination16 The Dynamic Genome: Transposable Elements
17 Large-Scale Chromosomal Changes
18 Population Genetics
19 The Inheritance of Complex Traits
20 Evolution of Genes, Traits, and Species
1 The Genetics Revolution in the Life Sciences
2 Single-Gene Inheritance
3 Independent Assortment of Genes
4 Mapping Eukaryote Chromosomes by Recombination
5 Gene Interaction6 The Genetics of
Bacteria and Their Viruses
7 DNA: Structure and Replication
8 RNA: Transcription and Processing
9 Proteins and Their Synthesis
10 Gene Isolation and Manipulation11 Regulation of Gene
Expression in Bacteria and Their Viruses
12 Regulation of Transcription in Eukaryotes
13 The Genetic Control of Development
14 Genomes and Genomics
15 Mutation, Repair, and Recombination16 The Dynamic
Genome: Transposable Elements
17 Large-Scale Chromosomal Changes
18 Population Genetics
19 The Inheritance of Complex Traits
20 Evolution of Genes, Traits, and Species
Anthony J. F. Griffiths is a Professor of Botany, Emeritus, at the
University of British Columbia. His research focuses on
developmental genetics using the model fungus Neurospora crassa. He
has served as president of the Genetics Society of Canada and two
terms as Secretary-General of the International Genetics
Federation. He was recently awarded the Fellow Medal of the
International Mycological Association.
John F. Doebley is a Professor of Genetics and Chair of the
Department of Genetics at the University of Wisconsin–Madison. He
studies the genetics of crop domestication using the methods of
population and quantitative genetics. He was elected to the
National Academy of Sciences in 2003 and served as the president of
the American Genetic Association in 2005. In 2015, he was awarded
the Gregor Mendel Medal by the British Genetics Society. He teaches
general genetics at the University of Wisconsin.
Catherine L. Peichel is a Professor of Evolutionary Ecology at the
University of Bern, Switzerland. She studies the genetic,
developmental and genomic mechanisms that underlie evolutionary
processes using stickleback fish as a model system. Dr. Peichel was
named a Fellow of the John Simon Guggenheim Memorial Foundation in
2013 and served as President of the American Genetic Association in
2015. She teaches evolutionary biology at the University of
Bern.
David A. Wassarman is a Professor of Medical Genetics at the
University of Wisconsin-Madison. His research focuses on the
genetics of neurodegenerative diseases using Drosophila
melanogaster. In 1997, he was awarded the Presidential Early Career
Award for Scientists and Engineers. He teaches molecular genetics
at the University of Wisconsin-Madison.
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