Microbial Community Structure and Metabolic Function in the Venom Glands of the Predatory Stink Bug, Picromerus lewisi (Hemiptera: Pentatomidae)

The predatory stink bug, (Hemiptera: Pentatomidae), is an important and valuable natural enemy of insect pests in their ecosystems. While insects are known to harbor symbiotic microorganisms, and these microbial symbionts play a crucial role in various aspects of the host's biology, there is a...

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Bibliographic Details
Published in:Insects (Basel, Switzerland) Switzerland), 2024-09, Vol.15 (9), p.727
Main Authors: Li, Jinmeng, Tian, Xu, Hsiang, Tom, Yang, Yuting, Shi, Caihua, Wang, Hancheng, Li, Wenhong
Format: Article
Language:English
Subjects:
Agroforestry
Aspergillus
Bacteria
Biological effects
carbon source metabolism
Carbon sources
Cladosporium
Community structure
Composition
Endophytes
Enterococcus
Exocrine glands
Functional groups
Fungi
Fusarium
Glands
Harbor facilities
Hemiptera
high-throughput sequencing
Identification and classification
In vitro methods and tests
Insects
Investigations
Lactococcus
Metabolism
Metabolites
Microbiomes
Microbiota
microorganism
Microorganisms
Natural enemies
Nematodes
Next-generation sequencing
Parasites
Pathogens
Penicillium
Pentatomidae
Pest control
Pests
Phenotyping
Physiological aspects
Physiology
Picromerus lewisi
Predators
Serratia
Species diversity
Species richness
Stink bugs
Structure-function relationships
Symbionts
Technology assessment
Testing
Venom
Venom gland
Vishniacozyma
Wolbachia
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Summary:The predatory stink bug, (Hemiptera: Pentatomidae), is an important and valuable natural enemy of insect pests in their ecosystems. While insects are known to harbor symbiotic microorganisms, and these microbial symbionts play a crucial role in various aspects of the host's biology, there is a paucity of knowledge regarding the microbiota present in the venom glands of . This study investigated the venom glands of adult bugs using both traditional in vitro isolation and cultural methods, as well as Illumina high-throughput sequencing technology. Additionally, the carbon metabolism of the venom gland's microorganisms was analyzed using Biolog ECO metabolic phenotyping technology. The results showed 10 different culturable bacteria where the dominant ones were spp. and . With high-throughput sequencing, the main bacterial phyla in the microbial community of the venom glands of were Proteobacteria (78.1%) and Firmicutes (20.3%), with the dominant bacterial genera being , , , and . At the fungal community level, Ascomycota accounted for the largest proportion (64.1%), followed by Basidiomycota (27.6%), with , , , , , and as the most highly represented fungal genera. The bacterial and fungal community structure of the venom glands of exhibited high species richness and diversity, along with a strong metabolism of 22 carbon sources. Functional prediction indicated that the primary dominant function of venom-gland bacteria was metabolism. The dominant eco-functional groups of the fungal community included undefined saprotroph, fungal parasite-undefined saprotroph, unassigned, endophyte-plant pathogen, plant pathogen-soil saprotroph-wood saprotroph, animal pathogen-endophyte-plant pathogen-wood saprotroph, plant pathogen, and animal pathogen-endophyte-epiphyte-plant pathogen-undefined saprotroph. These results provide a comprehensive characterization of the venom-gland microbiota of and demonstrate the stability (over one week) of the microbial community within the venom glands. This study represents the first report on the characterization of microbial composition from the venom glands of captive-reared individuals. The insights gained from this study are invaluable for future investigations into 's development and the possible interactions between 's microbiota and some Lepidopteran pests.
ISSN:2075-4450
2075-4450
DOI:10.3390/insects15090727