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Annotation Begun from the keynote addresses at the third International Organization for Biological Control (IOBC) Symposium, this book discusses new issues for each of the major approaches in applied biological control. These include the use of molecular genetics to trace the origin of target pests in classical biological control; the potential of mass-reared, transgenic agents in augmentative biological control; and the compatibility of transgenic crops and natural enemies in conservational biological control.
Written by experts in the fields of insect pest genetics, the genetics of biological control organisms, and the application of biological control, this book provides the first up-to-date summary of the genetic literature on the genetics of arthropod biological control agents. It identifies successful programs and also gaps and needs in research, research constraints, and possible research approaches in this important field of pest control. The power and applicability of new genetic and molecular biology methods have created new and exciting possibilities to greatly improve the effectiveness of traditional biological control programs. This book provides essential information about the state-of-the-art application of these new methods. It explains how biological control procedures can be improved, covers methods for selecting pesticide-resistant strains of natural enemies, and looks at methods for maintaining genetic diversity and quality control during the rearing of biological control agents in the laboratory. The book also provides information regarding the application of powerful PCR methods for taxonomic identification of strains and species of biocontrol agents.
Annotation. This book has been developed from the keynote addresses delivered at the third IOBC International Symposium (co-organized with CILBA) that was held in Montpellier in October 2002, to address recent developments in genetics and evolutionary biology as applied to biological control. Chapters are organized around the following themes: Genetic structure of pest and natural enemy populations Molecular diagnostic tools in biological control Tracing the origin of pests and natural enemies Predicting evolutionary change in pests and natural enemies Compatibility of transgenic crops and natural enemies Genetic manipulation of natural enemies. The authors identify new issues for each of the major approaches in applied biological control. These include the (1) use of molecular genetics to trace the origin of target pests in classical biological control, (2) potential of mass-reared, transgenic agents in augmentative biological control, and (3) compatibility of transgenic crops and natural enemies in conservational biological control.
This book enhances our understanding of biological control, integrating historical analysis, theoretical models and case studies in an ecological framework.
The revised edition of the highly successful Nelson Advanced Science Biology series for A Level Biology and Human Biology - Genetics, Evolution and Biodiversity provides full content coverage of Unit 5 of the AS and A2 specifications.
Far from being passive elements in the landscape, plants have developed many sophisticated chemical and mechanical means of deterring organisms that seek to prey on them. This volume draws together research from ecology, evolution, agronomy, and plant pathology to produce an ecological genetics perspective on plant resistance in both natural and agricultural systems. By emphasizing the ecological and evolutionary basis of resistance, the book makes an important contribution to the study of how phytophages and plants coevolve. Plant Resistance to Herbivores and Pathogens not only reviews the literature pertaining to plant resistance from a number of traditionally separate fields but also examines significant questions that will drive future research. Among the topics explored are selection for resistance in plants and for virulence in phytophages; methods for studying natural variation in plant resistance; the factors that maintain intraspecific variation in resistance; and the ecological consequences of within-population genetic variation for herbivorous insects and fungal pathogens. "A comprehensive review of the theory and information on a large, rapidly growing, and important subject."—Douglas J. Futuyma, State University of New York, Stony Brook
These proceedings contain the full-length papers and abstracts of papers presented at the symposium. Subjects covered include: ecology and modelling in biological control of weeds; benefits, risks and cost analysis of biological weed control; target and biological control agent selection; pre-release specificity and efficacy testing; regulations and public awareness; evolutionary processes; opportunities and constraints for the biological control of weeds in Europe; release activities and post-release evaluations; and management specifics, integration, restoration and implementation.
Genomic Control Process explores the biological phenomena around genomic regulatory systems that control and shape animal development processes, and which determine the nature of evolutionary processes that affect body plan. Unifying and simplifying the descriptions of development and evolution by focusing on the causality in these processes, it provides a comprehensive method of considering genomic control across diverse biological processes. This book is essential for graduate researchers in genomics, systems biology and molecular biology seeking to understand deep biological processes which regulate the structure of animals during development. - Covers a vast area of current biological research to produce a genome oriented regulatory bioscience of animal life - Places gene regulation, embryonic and postembryonic development, and evolution of the body plan in a unified conceptual framework - Provides the conceptual keys to interpret a broad developmental and evolutionary landscape with precise experimental illustrations drawn from contemporary literature - Includes a range of material, from developmental phenomenology to quantitative and logic models, from phylogenetics to the molecular biology of gene regulation, from animal models of all kinds to evidence of every relevant type - Demonstrates the causal power of system-level understanding of genomic control process - Conceptually organizes a constellation of complex and diverse biological phenomena - Investigates fundamental developmental control system logic in diverse circumstances and expresses these in conceptual models - Explores mechanistic evolutionary processes, illuminating the evolutionary consequences of developmental control systems as they are encoded in the genome
The global spread of plant species by humans is both a fascinating large scale experiment and, in many cases, a major perturbation to native plant communities. Many of the most destructive weeds today have been intentionally introduced to new environments where they have had unexpected and detrimental impacts. This 2003 book considers the problem of invasive introduced plants from historical, ecological and sociological perspectives. We consider such questions as 'What makes a community invasible?', 'What makes a plant an invader?' and 'Can we restore plant communities after invasion?' Written with advanced students and land managers in mind, this book contains practical explanations, case studies and an introduction to basic techniques for evaluating the impacts of invasive plants. An underlying theme is that experimental and quantitative evaluation of potential problems is necessary, and solutions must consider the evolutionary and ecological constraints acting on species interactions in newly invaded communities.
In this dissertation I expand upon our knowledge in regards to the utility of population genetic approaches to be used for the study of the evolution of introduced biological control agents and their target pests. If biological control methods are to provide sustainable pest management services then more long-term studies will be necessary, and these studies should also include the use of population genetic approaches. For existing biological control programs, post-release population genetic studies could be initiated using museum voucher specimens for baseline data. In Chapter 2, I explored what factors influence our ability to extract usable genomic material from dried museum specimens, and whether we could use non-destructive techniques for parasitic hymenoptera. I found that the age of the specimen was the most important determinant for the amplification of PCR products, with nuclear loci having a higher probability of amplification from older specimens than mitochondrial loci. With these sequence results I was able to differentiate voucher specimens of different strains of the biological control agent Trioxys pallidus and I was able to confirm the identification of an unknown parasitoid reared from the invasive light brown apple moth. For population genetic surveys to be conducted more frequently in biological control programs, some of the barriers to developing molecular markers that are variable enough for these types of surveys need to be overcome. One barrier is the time required to develop polymorphic microsatellite markers. Therefore, in Chapter 3, I developed a novel bioinformatics pipeline that searches through next-generation sequence (NGS) data and uses the raw sequencing reads to identify polymorphic loci. Using this approach I was able to rapidly develop microsatellite markers for two of my study species (T. pallidus and Chromaphis juglandicola). For both species more than 60% of the target markers amplified and were found to be polymorphic, compared to previous approaches where the success rates were much lower (published studies often show rates between 1 and 20%). I then examined evolutionary factors that may affect the sustainability of two classical biological control programs; 1) the biological control of walnut aphids, and 2) the biological control of invasive knotweeds. The walnut aphid biological control program is a textbook successful biological control program, but has shown recent evidence of localized breakdowns, whereas the biological control program for invasive knotweeds is currently under review in the United States and Canada. In Chapter 4, I explored whether hybridization between introduced "strains" of T. pallidus is responsible for recent breakdowns in this control program. In that study I found low levels of hybridization - thus it is unlikely hybridization is playing an important role in these breakdowns - as well as evidence that two of the strains may actually be cryptic species; one being a specialist and another being a generalist. In Chapter 5, I explored whether the geographic mosaic theory of coevolution might help explain these localized breakdowns. In that chapter I found evidence for a geographic mosaic in the walnut aphid biological control program, and commented on how components of the geographic mosaic theory of coevolution can help us predict what systems we might expect localized breakdowns to occur in. In Chapter 6, I explored whether endosymbionts might play a role in shaping the host-associations of two strains of the candidate biological control agent for invasive knotweeds. I found that while strains of the psyllid Aphalara itadori showed no barriers to hybridization of their nuclear genomes, there were curious patterns of horizontal transmission of their primary endosymbiont. I also found that one haplotype of the secondary endosymbiont Sodalis sp. dramatically changed in frequency during the hybrid crosses reared on giant knotweed. When compared with previous studies of this species, the results I observe suggest that endosymbionts may play an important role in the differing fitness levels of these two strains. In conclusion, population genetic approaches provide valuable tools for the study of post-release dynamics in biological control settings. While biological control programs promise to be useful study systems for evolutionary interactions, post-release studies will allow for that promise to come to fruition. In my future research endeavors I would like to continue to monitor the effects of hybridization and the frequency of geographic mosaics of coevolution in biological control settings. In addition, I would like to conduct post-release population genetic studies of both previous successful introductions and programs that resulted in failures. I believe these post-release studies will allow us to better determine what evolutionary factors affect the sustainability of biological control services and will allow for better management practices.