Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 A brief history of Lepidoptera as model systems
- 2 Genetics of the silkworm: revisiting an ancient model system
- 3 Mobile elements of lepidopteran genomes
- 4 Lepidopteran phytogeny and applications to comparative studies of development
- 5 A summary of lepidopteran embryogenesis and experimental embryology
- 6 Roles of homeotic genes in the Bombyx body plan
- 7 Chorion genes: an overview of their structure, function, and transcriptional regulation
- 8 Chorion genes: molecular models of evolution
- 9 Regulation of the silk protein genes and the homeobox genes in silk gland development
- 10 Control of transcription of Bombyx mori RNA polymerase III
- 11 Hormonal regulation of gene expression during lepidopteran development
- 12 Lepidoptera as model systems for studies of hormone action on the central nervous system
- 13 Molecular genetics of moth olfaction: a model for cellular identity and temporal assembly of the nervous system
- 14 Molecular biology of the immune response
- 15 Engineered baculoviruses: molecular tools for lepidopteran developmental biology and physiology and potential agents for insect pest control
- 16 Epilogue: Lepidopterans as model systems – questions and prospects
- References
- Index
14 - Molecular biology of the immune response
Published online by Cambridge University Press: 23 November 2009
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 A brief history of Lepidoptera as model systems
- 2 Genetics of the silkworm: revisiting an ancient model system
- 3 Mobile elements of lepidopteran genomes
- 4 Lepidopteran phytogeny and applications to comparative studies of development
- 5 A summary of lepidopteran embryogenesis and experimental embryology
- 6 Roles of homeotic genes in the Bombyx body plan
- 7 Chorion genes: an overview of their structure, function, and transcriptional regulation
- 8 Chorion genes: molecular models of evolution
- 9 Regulation of the silk protein genes and the homeobox genes in silk gland development
- 10 Control of transcription of Bombyx mori RNA polymerase III
- 11 Hormonal regulation of gene expression during lepidopteran development
- 12 Lepidoptera as model systems for studies of hormone action on the central nervous system
- 13 Molecular genetics of moth olfaction: a model for cellular identity and temporal assembly of the nervous system
- 14 Molecular biology of the immune response
- 15 Engineered baculoviruses: molecular tools for lepidopteran developmental biology and physiology and potential agents for insect pest control
- 16 Epilogue: Lepidopterans as model systems – questions and prospects
- References
- Index
Summary
Introduction
The cell populations that compose all multicellular organisms share the need to sense their environment and survey features of their cellular neighbors. These surveillance functions serve to ensure appropriate cell sorting and cellular association during embryonic development and metamorphosis, trigger repair processes that eliminate damaged or dysfunctional cells, and detect the presence of foreign (nonself) cells and elicit appropriate responses to eliminate the intruders. Collectively, the surveillance and effector mechanisms that serve the latter repair and defense functions are referred to as the organism's immune system.
We are most familiar with the antibody-based immune systems of vertebrates. These systems are capable of efficiently detecting “foreignness”, either in the form of nonself cells, aberrant self-cells or nonself macromolecules. They also provide for specific memory of previous encounters with nonself (immunization) so that a faster and more aggressive defensive response may be mobilized in the event of a secondary encounter. It is widely believed that among all living organisms, only the small group of animals that synthesize immunoglobulins (vertebrates) are capable of mounting a classic immune response in the presence of nonself challenges.
Recently, evidence has begun to accumulate that demonstrates that a variety of nonvertebrate organisms are capable of detecting foreign cells and foreign macromolecules, of eliciting effective and specific defensive responses to these challenges, and of acquiring “primed” states in which they are capable of surviving challenges that otherwise would be lethal to a “naive” individual.
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- Information
- Molecular Model Systems in the Lepidoptera , pp. 369 - 396Publisher: Cambridge University PressPrint publication year: 1995
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