| Description |
1 online resource : illustrations (some color) |
| Series |
Entomology monographs |
|
Entomology monographs.
|
| Contents |
Intro -- Preface -- References -- Acknowledgments -- Contents -- Chapter 1: Introduction to the World of Carabus -- 1.1 Diversity and Phylogeny of Carabinae and Carabus -- 1.2 Molecular Phylogeny and Divergence History -- 1.3 The Origin and Timing of the Carabus Radiation -- 1.4 Life History Patterns -- 1.4.1 Seasonal Life Cycle -- 1.4.2 Diets -- 1.4.3 Life History Evolution -- References -- Chapter 2: Ohomopterus: A Species Radiation with Diversification of Key Traits for Mechanical Reproductive Isolation -- 2.1 The Beginning of Ohomopterus Study -- 2.2 Resolving Phylogenetic Relationships Among Species -- 2.3 The Phylogeny of Ohomopterus Based on Genome-Wide Data -- 2.4 Phylogenetic Position of Ohomopterus in the Genus Carabus -- References -- Chapter 3: Biology of Ohomopterus -- 3.1 Seasonal Life Cycle of Ohomopterus -- 3.2 Life Cycle Control -- 3.3 Mating, Oviposition and Larval Development -- 3.4 Adult Population: Survival Pattern and Life Span -- 3.5 Variations in Seasonal Life Cycle -- 3.6 Predation on Earthworms by Larvae -- References -- Chapter 4: Species Assemblages -- 4.1 Number of Co-occurring Species -- 4.2 Body Size-Structured Species Assemblages Across Geographic Gradients -- 4.3 Body Size Ratios of Sympatric Species -- 4.4 The Processes Leading to Body Size-Structured Assemblages -- 4.5 The Nature of Interspecific Interactions and Consequences for Species Assembly -- 4.6 Ohomopterus in Carabus Species Assemblage: Differentiation of Ecological Niches Among Subgenera -- References -- Chapter 5: Natural Hybridization and Reproductive Isolation -- 5.1 Hybrid Zones of Ohomopterus Species -- 5.2 Experimental Hybridization -- 5.3 Reproductive Isolation Between Parapatric Species -- 5.4 Role of Cuticular Hydrocarbons in Species Recognition -- 5.5 Mechanical Reproductive Isolation by Body Size Differences |
|
5.6 Reproductive Isolation Mechanisms: Genital Mismatch -- 5.7 How Body Size and Genital Size Differences Affect Reproductive Isolation: Inference Based on the Analysis of Mitochondrial Introgression Patterns -- 5.8 Impact of Incomplete Reproductive Isolation on Species Distribution -- References -- Chapter 6: Evolutionary History of Ohomopterus -- 6.1 Fossils of Ohomopterus -- 6.2 Molecular Phylogeny, Divergence Time and Speciation Rate -- 6.3 Historical Biogeography Inferred from the Molecular Phylogeny -- 6.4 Divergence and Hybridization in the iwawakianus-insulicola Group -- 6.5 Mitochondrial Phylogeography and Introgressive Hybridization -- 6.6 Range Expansion and Mitochondrial Introgression -- 6.7 Divergence Times of Island Populations Surrounding the Main Islands of Japan -- References -- Chapter 7: Evolution of a Key Trait for Species Diversity: Body Size -- 7.1 Intraspecific Variation in Body Size Along the Habitat Temperature Gradient -- 7.2 Differentiation of Body Size Between Closely Related Lineages -- 7.3 Complex Evolutionary Factors for Body Size in Carabus japonicus -- 7.3.1 Body Size Variation Related to Competitive Release -- 7.3.2 Altitudinal Differences in the Availability of Prey Earthworms -- 7.3.3 Geographic Variation in Prey Earthworm Community Structure -- 7.3.4 Effects of Multiple Factors on Carabus Body Sizes -- 7.4 Genetic Basis of Body Size Variation in Carabus japonicus -- 7.5 Body Size Variation in Other Endemic Carabus Groups in Japan -- 7.6 Body Size Divergence and Species Coexistence: Implications from Comparisons Among Carabus Groups -- References -- Chapter 8: Evolution of a Key Trait for Species Diversity: Genital Morphology -- 8.1 Divergence of Genital Morphology and Coevolution Between the Sexes -- 8.1.1 Driving Forces of Genital Evolution and Coevolution Between the Sexes: General Theories |
|
8.2 Selective Forces Driving Genital Evolution in Ohomopterus -- 8.2.1 Basic Functions of Male and Female Genital Parts in Ohomopterus -- 8.2.2 Sperm Competition -- 8.2.3 Comparative Study Suggests the Role of Sperm Competition -- 8.2.4 Is There a Selective Advantage to Longer Copulatory Pieces? -- 8.2.5 Sexual Conflict May Have Promoted Genital Elongation -- 8.2.6 Exaggeration of Genitalia via Reinforcement Selection? Revival of the Lock-and-Key -- 8.2.7 Overview: Various Factors Affecting the Evolution of Genital Morphology -- 8.3 Genetic Background of Species-Specific Genital Morphology -- 8.3.1 Quantitative Genetic Analysis -- 8.3.2 QTL Mapping Study -- 8.3.3 Search for Genomic Regions Divergent Between the Species -- 8.3.4 Comparison of Gene Expression Between Two Species -- 8.3.5 Correlated Evolution of Male and Female Genitalia -- 8.3.6 Pattern of Genomic Divergence Among Genitally Divergent Species -- 8.3.7 Parallel Sequence Divergences Associated with the Divergence of Genital Morphology -- 8.4 Could Genital Evolution Promote Speciation and Species Diversification? -- 8.5 Ongoing and Future Studies in Genital Evolution -- References -- Chapter 9: Overview: How Does Species Richness Increase? -- 9.1 Species Diversification and Assembly Formation in Ohomopterus -- 9.2 Mechanisms of Species Coexistence: The Primary Role of Character Divergence in Reproductive Isolation -- 9.3 Coupled Divergent Evolution of Key Traits for Reproductive Isolation -- 9.4 Conclusions -- References -- Index |
| Summary |
This book presents the whole picture of the ecological and evolutionary study on the ground beetle group, the subgenus Ohomopterus of the genus Carabus, endemic to Japan. This flightless beetle group consists of many geographic races. They show divergence in key traits for reproductive isolation-body size and genital morphology, which leads to coexistence of two or more species. This beetle group provides an important material to study how a lineage of organisms diversify and form multi-species assemblage, and thereby multiply their species richness. The book introduces novel genomic approaches to resolve questions about evolution of Ohomopterus. The readers will find that this story of evolution in Carabus beetles revealed by recent approaches is much different from what was told in previous literature. Exploring different cases across a wide range of lineages is important in constructing a synthetic theory of species radiation and richness, including speciation and species coexistence. This study on Ohomopterus beetles contributes to the ongoing discussion to understand how and why species multiply and how species richness increases in one area of our planet. Teiji Sota, Professor, Department of Zoology, Graduate School of Science, Kyoto University |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Online resource; title from PDF title page (SpringerLink, viewed December 7, 2021) |
| Subject |
Carabus -- Evolution -- Japan
|
|
Carabus -- Variation -- Japan
|
|
Mussols.
|
|
Evolució (Biologia)
|
|
Biologia molecular.
|
|
Japan
|
| Genre/Form |
Llibres electrònics.
|
| Form |
Electronic book
|
| ISBN |
9789811666995 |
|
9811666997 |
|
