Stages of aestivation as a physiological state and the related biochemical composition in the grain chinch bug (Macchiademus diplopterus)

The grain chinch bug (Macchiademus diplopterus Distant) is a phytosanitary pest, endemic to the Western Cape in South Africa. At the start of the aestivation phase of their lifecycle, grain chinch bugs seek sheltering sites, which potentially include fruit and fruit trees if orchards are near host p...

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Bibliographic Details
Published in:Physiological entomology 2024-03, Vol.49 (1), p.1-13
Main Authors: Smit, R., Neven, L. G., Johnson, S. A.
Format: Article
Language:English
Subjects:
Abundance
Aestivation
Biochemical composition
Blissus leucopterus leucopterus
Contaminants
Energy metabolism
Fruit trees
Fruits
Heat shock
Heat shock proteins
Host plants
Insects
Macromolecules
metabolic reserves
Metabolism
Pests
Physiology
Proteins
proteomics
Thermal stress
thermo‐tolerance
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Summary:The grain chinch bug (Macchiademus diplopterus Distant) is a phytosanitary pest, endemic to the Western Cape in South Africa. At the start of the aestivation phase of their lifecycle, grain chinch bugs seek sheltering sites, which potentially include fruit and fruit trees if orchards are near host plants. Aestivating grain chinch bug on export fruit is considered contaminant or hitchhiker phytosanitary pests. Previous studies have indicated that the grain chinch bug has the ability to become more tolerant of thermal stresses as they progress through their aestivation cycle. To examine the potential physiological changes that occur during aestivation, molecular (soluble protein identification) and biochemical (macromolecule) analyses were performed on the insects before entering aestivation, as well as early, mid, mid‐late and late aestivation periods. Analyses provided useful information on the abundance and identity of individual soluble proteins and concentration of macromolecules, indicating whether compounds are up‐ or down‐regulated throughout the aestivation cycle. The focus of this investigation was to examine the influence of heat shock proteins and proteins involved in energy production and metabolism throughout the aestivation period. Results provide insight into the thermo‐tolerance capabilities or mechanisms of the grain chinch bug. The significant decrease in the number of individual proteins identified in samples before aestivation compared to early aestivation indicated the insects' progression into a hypometabolic state. During the early, mid and mid‐late aestivation periods (from December to May), large volumes of fruit are exported from South Africa. An increase in abundance of proteins, such as smHsp20, Hsp10, 70, 80 and 90, occurred during the mid/mid‐late aestivation period compared with the early period. This indicated the potential role of heat shock proteins in the insect's ability to increase its thermo‐tolerance at a later stage within the aestivation cycle. Aestivating M. diploterus has shown an increase in thermal tolerance as it progresses into and through its aestivation cycle (from November to June). Examination of physiological changes for survival was investigated by examining the insects' biochemical compositional changes as well as heat shock protein changes that occur over time. The results indicated that adaption and changes in macromolecule composition and specific individual proteins support the hypometabolic aestivat
ISSN:0307-6962
1365-3032
DOI:10.1111/phen.12420