Molecular genetics in fisheries /
Bruno Augusto Amato Borges.
- xiii, 221 pages : color illustrations ; 24 cm.
Includes bibliographical references and index.
Diversity and biology of fishes -- Molecular genetics -- Fish genetics -- Genetics and fish breeding -- Molecular markers in fish -- Catfish hybrid technology -- Transgenic fish research -- Securing the future of seafood through genetics and genomic application -- Conservation biology of fisheries science -- The future of fisheries science.
"Since the emergence of starch gel electrophoresis around four decades ago, genetic polymorphism has gradually intensified in fish studies. Basically, this polymorphism has been utilized as a marker to make broader inferences about the genetic quality of the research, rather than just including the polymorphic locus itself. Although the introductory research included proteins such as hemoglobin and transferrin, it immediately changed to using enzymatic proteins (isoenzymes). Over the past decade, people have been expanding their attention to coordinate DNA assessment, first with mitochondrial DNA, and then with the establishment of molecular methods, namely nuclear DNA. This volume suggests that mechanical advances in new genetic technology usually come from natural aquatic system inspections other than fish, despite the fact that this usually requires specialized adaptations to support fish stocks. Fish geneticists need updated information about genetic improvements in model organisms. Sometimes, this method may be misleading but research in fish (such as salmon) can be used in genetic sequencing detection for more reliable outcomes. Since the original study around 20 years ago, the use of genetic methods to solve the problems of ecology and evolutionary research in fish has expanded incredibly. Significant advances in genetic hypotheses, and the availability of genetic markers, cost adequacy, and goals that are critical to the particularly rapid progress in the last decade. The genetic investigation of elasmobranchs has direct significance and has been applied to fishery management and conservation matters, such as defining fish species from their fins. In the future, the use of modern genetic mapping technologies will grow, which shall accelerate the development of genetic data and the improvement of new markers at a lower cost, preparing for the transition from quality inspections to genome-scale inspections. This volume examines different areas of the submolecular genetic quality of the elasmobranch branch related to fisheries and protection, with particular emphasis on (species distinction evidence, systematic geography, heritability population size, submolecular development rate and reproduction strategy). Also, the application of genome assets (computational genome sequencing), depending on the rise in the number of sub-molecular markers and the development of high-density genetic maps, sequencing methods can be applied to provide equipment for the genetic development of fish species. In this volume, the quality of various genetic markers and their applications in various aquaculture topics are discussed. Mendelian's genetic predisposition derives genetic standards by noting individual aggregates that appear due to proper breeding analysis. The coordination of data and strategies obtained through advances in molecular science promotes another aspect of genetic quality, that is, sub-molecular genetic quality, which focuses on exploring all parts of genetic quality, such as its structure and capabilities"-- Back cover.