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Microbial diversity and functional potential of the Halobates melleus (Heteroptera: Gerridae) microbiome from the Red Sea coastline
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Microbial diversity and functional potential of the Halobates melleus (Heteroptera: Gerridae) microbiome from the Red Sea coastline
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Journal Article
Microbial diversity and functional potential of the Halobates melleus (Heteroptera: Gerridae) microbiome from the Red Sea coastline
2025
Overview
Background
Halobates
, commonly known as sea skaters, are predatory Hemipterans uniquely adapted to tropical marine environments. Their ability to thrive in oligotrophic and environmentally extreme habitats, such as the open ocean surface and marine coastal areas, suggests the evolution of specialised adaptations, possibly including symbiotic associations with microorganisms that can support nutrition, niche adaptation, and stress resilience. To explore this hypothesis, we analysed the bacterial communities associated with
Halobates melleus
, a species inhabiting the Red Sea coastal mangroves in Saudi Arabia.
Results
Amplicon sequencing of the 16S rRNA gene and metagenomic analyses of composite body and gut samples from adult
H. melleus
revealed a population-level bacterial community dominated by
Wolbachia
and
Spiroplasma
, consistent with patterns observed in several terrestrial predatory insects. Members of
Providencia
and
Swaminathania
were also detected, along with other minor taxa that may represent transient environmental commensals. The identified bacteria encoded genes for the biosynthesis of essential vitamins and prosthetic groups, such as riboflavin and heme—compounds typically not synthesised de novo by insects—as well as amino acids, likely contributing to the host’s nutritional requirements. Notably, the
Wolbachia
metagenome-assembled genome from
H. melleus
clustered within the supergroup B, showing high genetic similarity to strains from phylogenetically distant Dipteran and Lepidopteran hosts that nonetheless inhabit common ecological niches, i.e., mangrove and tropical environments. This extends the known ecological breadth of
Wolbachia
symbioses to marine insects, underscoring their evolutionary and environmental versatility.
Conclusion
Our findings highlight the potential nutritional and metabolic roles of the
Halobates
-associated bacterial microbiome, particularly members of the
Wolbachia
genus. This emphasises the importance of microbial symbionts in the ecological success and adaptation of marine insects, offering a perspective complementary to previously studied terrestrial insect microbiomes.
Publisher
BioMed Central,BioMed Central Ltd,Springer Nature B.V,BMC
Subject
