Abstract
Insects have established mutualistic symbiotic interactions with microorganisms that are beneficial to both host and symbiont. Many insects have exploited these symbioses to diversify and expand their ecological ranges. In the Hemiptera (i.e., aphids, cicadas, and true bugs), symbioses have established and evolved with obligatory essential microorganisms (primary symbionts) and with facultative beneficial symbionts (secondary symbionts). Primary symbionts are usually intracellular microorganisms found in insects with specialized diets such as obligate hematophagy or phytophagy. Most Heteroptera (true bugs), however, have gastrointestinal (GI) tract extracellular symbionts with functions analogous to primary endosymbionts. The triatomines, are vectors of the human parasite, Trypanosoma cruzi. A description of their small GI tract microbiota richness was based on a few culturable microorganisms first described almost a century ago. A growing literature describes more complex interactions between triatomines and bacteria with properties characteristic of both primary and secondary symbionts. In this review, we provide an evolutionary perspective of beneficial symbioses in the Hemiptera, illustrating the context that may drive the evolution of symbioses in triatomines. We highlight the diversity of the triatomine microbiota, bacterial taxa with potential to be beneficial symbionts, the unique characteristics of triatomine-bacteria symbioses, and the interactions among trypanosomes, microbiota, and triatomines.
Highlights
Insects live in complex environments in which they interact with millions of fungi, bacteria, viruses, and parasites
When T. infestans is infected with B. triatomae and R. prolixus with T. rangeli [221], they experience symptoms similar to aposymbiotic insects
Triatomines have associations with extracellular intestinal beneficial symbionts, in contrast with other obligate hematophagous arthropods that rely on intracellular primary symbionts
Summary
Insects live in complex environments in which they interact with millions of fungi, bacteria, viruses, and parasites. Whereas nymphs of hemimetabolous insects may carry their microbiota from early nymphal stages through to the adult stages [8,9], the transformation from larva–pupa–adult in holometabolous insects involves the breakdown of the larval GI tract and the construction of the adult GI tract During this metamorphosis, there is a high expression of antimicrobial compounds that eliminate most gut bacterial symbionts [8,10,11], and can lead to the establishment of a different microbiome in adults [12]. This review will focus on recent advancements in our knowledge of the microbiome and microbiota of triatomines (Hemiptera) These insects have been studied extensively and are considered as models for studies on basic insect physiology [19,20,21], and many triatomines are vectors of the protozoan Trypanosoma cruzi, which causes Chagas disease in humans and kills over 15,000 people annually [22]
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