Microbial Symbionts of Insects: Genetic Organization, Adaptive Role, and Evolution

The microorganisms forming symbioses with insects play an important role in nutrition, development and evolution of their hosts. They make it possible for their hosts to use poorly digestible nutrients, to resist the biotic and abiotic stresses, and to regulate the metamorphosis. The microsymbionts...

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Bibliographic Details
Published in:Microbiology (New York) 2018-03, Vol.87 (2), p.151-163
Main Authors: Provorov, N. A., Onishchuk, O. P.
Format: Article
Language:English
Subjects:
Biological control
Biomedical and Life Sciences
Chromosomes
Disease transmission
Evolution
Evolutionary genetics
Genetic analysis
Genetic drift
Genomes
Glands
Hemolymph
Insects
Intracellular
Life Sciences
Medical Microbiology
Metamorphosis
Microbiology
Mutation
Nutrients
Organelles
Pests
Pollinators
Reviews
Symbionts
Symbiosis
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Summary:The microorganisms forming symbioses with insects play an important role in nutrition, development and evolution of their hosts. They make it possible for their hosts to use poorly digestible nutrients, to resist the biotic and abiotic stresses, and to regulate the metamorphosis. The microsymbionts of insects may be facultative (genetically specialized for symbiosis but retaining the capacity for autonomous existence; they are usually located extracellularly, in the gut, hemolymph, or salivary glands of the host) or obligatory (incapable of autonomous existence due to the loss of large parts of their genomes; they are usually located inside specialized host cells). The intracellular symbionts (endocytobionts) are capable of vertical transmission during the host reproduction, which determines the loss of many housekeeping genes, including the genes for replication, transcription and translation. In some obligatory symbionts, amplification of genes performing the functions useful for the hosts, such as the synthesis of essential amino acids, was found. These symbionts exhibit increased rates of accumulation of mutations, including non-synonymous nucleotide substitutions, reflecting suppression of the purifying selection and activation of genetic drift stimulating the genome reduction. Transfer of some genes from endocytobionts to the nuclear chromosomes of insects enables them to implement the novel metabolic functions, including assimilation of rare nutrients. The obligatory intracellular insect symbionts may be used as models to reconstruct the early stages of evolution of cellular organelles, which involve reduction of essential genes and the loss of genetic individuality of the symbionts, i.e., the ability for self-maintenance and expression of their residual genomes. Genetic analysis of insect microsymbionts extends the opportunities for their practical application associated with biological control of harmful insects (herbivorous, bloodsucking) and stimulation of the beneficial ones (honey collectors, pollinators, antagonists of pests).
ISSN:0026-2617
1608-3237
DOI:10.1134/S002626171802011X