Abstract

Insect microbiomes influence many fundamental host traits, including functions of practical significance such as their capacity as vectors to transmit parasites and pathogens. The knowledge on the diversity and development of the gut microbiomes in various blood feeding insects is thus crucial not only for theoretical purposes, but also for the development of better disease control strategies. In Triatominae (Heteroptera: Reduviidae), the blood feeding vectors of Chagas disease in South America and parts of North America, the investigation of the microbiomes is in its infancy. The few studies done on microbiomes of South American Triatominae species indicate a relatively low taxonomic diversity and a high host specificity. We designed a comparative survey to serve several purposes: (I) to obtain a better insight into the overall microbiome diversity in different species, (II) to check the long term stability of the interspecific differences, (III) to describe the ontogenetic changes of the microbiome, and (IV) to determine the potential correlation between microbiome composition and presence of Trypanosoma cruzi, the causative agent of Chagas disease. Using 16S amplicons of two abundant species from the southern US, and four laboratory reared colonies, we showed that the microbiome composition is determined by host species, rather than locality or environment. The OTUs (Operational Taxonomic Units) determination confirms a low microbiome diversity, with 12-17 main OTUs detected in wild populations of T. sanguisuga and T. protracta. Among the dominant bacterial taxa are Acinetobacter and Proteiniphilum but also the symbiotic bacterium Arsenophonus triatominarum, previously believed to only live intracellularly. The possibility of ontogenetic microbiome changes was evaluated in all six developmental stages and feces of the laboratory reared model Rhodnius prolixus. We detected considerable changes along the host's ontogeny, including clear trends in the abundance variation of the three dominant bacteria, namely Enterococcus, Acinetobacter, and Arsenophonus. Finally, we screened the samples for the presence of Trypanosoma cruzi. Comparing the parasite presence with the microbiome composition, we assessed the possible significance of the latter in the epidemiology of the disease. Particularly, we found a trend toward more diverse microbiomes in Trypanosoma cruzi positive T. protracta specimens.

Highlights

  • Insect microbiomes are recognized as a major factor determining host fitness and various phenotypic traits, including vectorial capacity in blood feeding species (Klepzig et al, 2009; Minard et al, 2013; Oliver and Martinez, 2014)

  • Since it has been shown in some other arthropods that the microbiome composition can change during the host ontogeny, we used an available R. prolixus colony to directly characterize the ontogenetic development of the microbial communities across different developmental stages in a closely related and ecologically similar model

  • It is difficult to make any general comparison of the pattern we found in Triatominae to other arthropods, since only few other groups have been analyzed to date

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Summary

Introduction

Insect microbiomes are recognized as a major factor determining host fitness and various phenotypic traits, including vectorial capacity in blood feeding species (Klepzig et al, 2009; Minard et al, 2013; Oliver and Martinez, 2014). While vector control strategies are naturally venturing into the microbiome concept (Crotti et al, 2012; Saldaña et al, 2017), for some insect vectors and the allied pathogens the research focus has not yet fully passed the borders of epidemiological, surveillance, and medical studies One such example are kissing bugs of the subfamily Triatominae (Hemiptera: Reduviidae) and Trypanosoma cruzi, the protozoan parasite responsible for Chagas disease. R. prolixus has served as a model organism to study insect physiology, immunity, metabolism, and development (Nunes-da-Fonseca et al, 2017) Such a status has promoted a high availability of information on this Triatominae species, including a whole genome sequence (Mesquita et al, 2015), and has contributed to unraveling its role as the vector for Trypanosoma cruzi

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