Insect Pheromone Biochemistry and Molecular Biology (2nd Ed.)
Coordonnateurs : Blomquist Gary, Vogt Richard
1. Production and Reception of Insect Pheromones – Introduction and Overview 2. Lepidoptera: Female Sex pheromone biosynthesis and its hormonal regulation 3. Yeast/plants: production of insect pheromones 4. Pheromone production in bark beetles 5. Drosophila: pheromone production 6. Pheromone mediated social regulation in honey bees (Apis mellifera) 7. Hydrocarbon pheromone production in the housefly and other insects 8. Pheromone Production in Nasonia 9. Hemiptera/stink bugs: pheromone production 10. The neuroethology of labeled lines in insect olfactory systems 11. Pheromone Detection and Responses in Bombyx mori 12. Molecular Mechanisms of pheromone detection 13. Insect Odorant Receptors: Function and Regulation 14. Biophysics of Lepidoptera Pheromone Receptors 15. Olfactory genomics within the Lepidoptera 16. lfactory Genomics of Eusociality within the Hymenoptera 17. Olfactory Genomics of the Coleoptera 18. Mechanisms and dynamics of insect odorant-binding proteins 19. Odor Degrading Enzymes and Signal Termination 20. Olfactory Genomics and Biotechnology in Insect Control 21. Reflections on antennal proteins
Researchers and practitioners in insect physiology, biochemistry and molecular biology entomology, or chemical ecology
Richard Vogt is currently a Distinguished Professor Emeritus in the Department of Biological Sciences at the University of South Carolina. He received his PhD in Zoology from the University of Washington. Dr. Vogt served on the editorial board of Insect Biochemistry and Molecular Biology from 2002 to 2014. He has contributed to hundreds of journal articles and book chapters, including co-editing Insect Pheromone Biochemistry and Molecular Biology in 2003 with Dr. Gary Blomquist.
- Offers a historical and contemporary perspective, with a focus on advances over the last 15 years
- Discusses the molecular and regulatory mechanisms underlying pheromone production/detection, as well as the evolution of these processes across the insects
- Led by editors with broad expertise in the metabolic pathways of pheromone production and the biochemical and genetic processes of pheromone detection
Date de parution : 09-2020
Ouvrage de 750 p.
19x23.3 cm
Mots-clés :
Acetyltransferase; Adaptation; Alcohol oxidase/aldehyde decarbonylase; Aldehyde-oxidase; Alpha helical fold; Alpha oscillations; Beetle; Behavior; Biosensor; Biosynthesis; Bombykol; Bombyx mori; Brood pheromones; C-terminal segment; Calcium; Carboxylesterase; Chain shortening enzymes; Chemical ecology; Chemoreceptor; Chemosensory sensillum; Circadian rhythms; Clocks; Coleoptera; Conifer; Cytochrome P450; Cytochromes P450; Damping function; Deception; Dendroctonus; Desaturase; Detection; Detoxification; Diptera; Disulfide bridges; Drone pheromones; Drosophila; Ecology; Elongation; Epoxide hydrolase; Epoxides; Epoxy derivatives; Eusocial; Evolution; Exploitation; Expression pattern; Fatty acid biosynthesis; Fatty acid metabolism; Fatty acid synthase; Fatty acyl-CoA reductase; Fermentation; Food; Functional studies; GPCRs; Genetic regulation; Genomics; Glutathione-S-transferase; Gustation; Heliothines; Heterologous expression; Honey bee; Hormones; Hydrocarbon biosynthesis; Hydrocarbons; Insect; Insect olfaction; Ion channel; Ips; Isopentenyl diphosphate synthases; Isoprenyl diphosphate synthase; Lepidoptera; Ligand association and dissociation; Manduca sexta; Mate recognition; Mating disruptants; Metabotropic transduction; Mevalonate pathway; Molecular chemoreception; NGS; Nasonia; Neurobiology; Neurotransmitters; Numerous projects; OBP; Odorant binding protein; Odorant clearance; Odorant inactivation; Odorant receptor; Odorant-degrading enzyme; Oenocytes; Olfaction; Olfactory evolution; Olfactory sensory neuron; Omics; Orco; Ostrinia; Oxidase; PBAN; PBP; PDE; Pentatomid
