Distribution of triatomine species in domestic and peridomestic environments in central coastal Ecuador

Grijalva, Mario J.; Villacís, Anita G.; Moncayo, Ana L.; Ocaña-Mayorga, Sofía; Yumiseva, César A.; Baus, Esteban G.

doi:10.1371/journal.pntd.0005970

Cited by 28 publications

(33 citation statements)

References 30 publications

(70 reference statements)

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“…These root causes are in part behavioral. Practices in the communities make homes conducive to triatomine infestation, including the accumulation of materials in the home, such as extra clothing or building supplies, which creates hiding places for triatomines during the day, and the accumulation of foodstuffs that attract rodents and small animals that can act as hosts for triatomines [14][15][16]. Animal husbandry practices, such as keeping chicken nests against the walls of the home, keeping Guinea pigs in the house or allowing pigs and goats to move from the wild to the peridomicile to the home [15], attract triatomines.…”

Section: Introductionmentioning

confidence: 99%

Determinants of intentions to prevent triatomine infestation based on the health belief model: An application in rural southern Ecuador

et al. 2020

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Introduction Control of triatomine infestation is a key strategy for the prevention of Chagas disease (CD). To promote this strategy, it is important to know which antecedents to behavioral change are the best to emphasize when promoting prevention. Objective The aim of this study was to determine predictors for intention to prevent home infestation based on the Health Belief Model (HBM), a commonly used health intervention planning theory. Materials & methods A cross-sectional study was conducted with 112 heads of household in six communities with endemic and high rates of triatomine infestation in Loja province, Ecuador. The data was collected by a questionnaire including perceived severity, susceptibility, benefits to action, barriers to action, and self-efficacy. These data were also used to predict actual infestation of homes. Results Community members reported strong intentions to prevent home infestation. HBM constructs predicted about 14% of the observed variance in intentions. Perceived susceptibility and severity did not predict behavioral intention well; perceived barriers to small-scale action that reduce likelihood of infestation and self-efficacy in participating in surveillance systems

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Section: Introductionmentioning

confidence: 99%

Determinants of intentions to prevent triatomine infestation based on the health belief model: An application in rural southern Ecuador

et al. 2020

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“…aequatorialis palms of Manabí and houses of northwestern Peru (department of Cajamarca, Mashcon-Marañón basin) were supplied by J Jurberg (LNIRTT) (S1 Table). We conducted a detailed review of external morphological and chromatic characters central to classical triatomine-bug taxonomy [1,41], and placed the results in the broader context of what we know about the systematics, biogeography, and ecology of R. ecuadoriensis [1,2,8,18,[25][26][27][28][29][30][31][32][33][34][35][36]38,39]. In particular, we emphasize that northern populations exploit palm-crown microhabitats just like most Rhodnius species do [2,29], whereas wild southern-Andean populations are associated with vertebrate tree-nests in dry ecoregions where palms are either rare or absent [2,8,[25][26][27][28][29][30][31][32][33][34].…”

Section: Origins Of Bugs and Qualitative Phenotype Assessmentmentioning

confidence: 99%

“…The natural habitats of Peruvian populations remain largely unknown, with a few records suggesting association with vertebrate nests/refuges in hollow trees and perhaps cacti [2,26,27,34]. In addition, some R. ecuadoriensis populations have adapted to live in and around houses in coastal Ecuador and, especially, in the dry valleys of southwestern Ecuador and northwestern Peru -where the bugs contribute to endemic Chagas disease [24][25][26][35][36][37][38][39]. Our comparative phenotypic and genetic analyses reveal that phenotypic divergence and convergence can both occur within a single nominal triatomine-bug species, and suggest that microhabitat adaptations likely play a crucial role in this phenomenon.…”

Section: Introductionmentioning

confidence: 99%

Under pressure: phenotypic divergence and convergence associated with microhabitat adaptations in Triatominae

Abad‐Franch

Monteiro

Pavan

et al. 2020

Preprint

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BackgroundTriatomine bugs, the vectors of Chagas disease, associate with vertebrate hosts in highly diverse ecotopes. When these blood-sucking bugs adapt to new microhabitats, their phenotypes may change. Although understanding phenotypic variation is key to the study of adaptive evolution and central to phenotype-based taxonomy, the drivers of phenotypic change and diversity in triatomines remain poorly understood.Methods/FindingsWe combined a detailed phenotypic appraisal (including morphology and morphometrics) with mitochondrial cytb and nuclear ITS2 DNA-sequence analyses to study Rhodnius ecuadoriensis populations from across the species’ range. We found three major, naked-eye phenotypic variants. Southern-Andean bugs (SW Ecuador/NW Peru) from house and vertebrate-nest microhabitats are typical, light-colored, small bugs with short heads/wings. Northern-Andean bugs (W Ecuador wet-forest palms) are dark, large bugs with long heads/wings. Finally, northern-lowland bugs (coastal Ecuador dry-forest palms) are light-colored and medium-sized. Wing and (size-free) head shapes are similar across Ecuadorian populations, regardless of habitat or naked-eye phenotype, but distinct in Peruvian bugs. Bayesian phylogenetic and multispecies-coalescent DNA-sequence analyses strongly suggest that Ecuadorian and Peruvian populations are two independently-evolving lineages, with little within-lineage structuring/differentiation.ConclusionsWe report sharp naked-eye phenotypic divergence of genetically similar Ecuadorian R. ecuadoriensis (house/nest southern-Andean vs. palm-dwelling northern bugs; and palm-dwelling Andean vs. lowland); and sharp naked-eye phenotypic similarity of typical, yet genetically distinct, southern-Andean bugs from house and nest (but not palm) microhabitats (SW Ecuador vs. NW Peru). This remarkable phenotypic diversity within a single nominal species likely stems from microhabitat adaptations possibly involving predator-driven selective pressure (yielding substrate-matching camouflage coloration) and a shift from palm-crown to vertebrate-nest microhabitats (yielding smaller bodies and shorter heads and wings). These findings shed new light on the origins of phenotypic diversity in triatomines, warn against excess reliance on phenotype-based triatomine-bug taxonomy, and confirm the Triatominae as an informative model-system for the study of phenotypic change under ecological pressure.Author summaryTriatomine bugs feed on the blood of vertebrates including humans and transmit the parasite that causes Chagas disease. The bugs, of which 150+ species are known, are highly diverse in size, shape, and color. Some species look so similar that they are commonly confused, whereas a few same-species populations look so different that they were thought to be separate species. Despite the crucial role of naked-eye phenotypes in triatomine-bug identification and classification (which are essential for vector control-surveillance), the origins of this variation remain unclear. Here, we describe a striking case of phenotypic divergence, with genetically similar bugs looking very different from one another, and phenotypic convergence, with bugs from two genetically distinct populations (likely on their way to speciation) looking very similar – and all within a single nominal species, Rhodnius ecuadoriensis. Phenotypically divergent populations occupy different ecological regions (wet vs. dry) and microhabitats (palm-crowns vs. vertebrate nests), whereas convergent populations occupy man-made and nest (but not palm) microhabitats. These findings suggest that triatomines can ‘respond’ to ecological novelty by changing their external, naked-eye phenotypes as they adapt to new microhabitats. We therefore warn that phenotypic traits such as overall size or color may confound triatomine-bug species identification and classification.

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“…Here we use a target-group background (TGB) approach by choosing 67 background data that exhibits similar sampling bias as the occurrence data [31]. This 68 approach can reduce the bias introduced by preferential sampling of the presence 69 locations. It was successfully used to map geographical distributions of malaria hosts 70 and vectors [32] and predict infection risk zones of yellow fever [33].…”

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confidence: 99%

“…There are locally important species for which maps could not be produced because they 273 are only found within areas where the relevant surveillance records are not publicly 274 available or because their range is limited so only small numbers of observations exist. 275 For example, Rhodnius ecuadoriensis is an important vector in Ecuador [69] but the 276 databases used in this study only provided 11 and 23 records, respectively, for known 277 collection dates after the year 2000.…”

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Modelling geospatial distributions of the triatomine vectors of Trypanosoma cruzi in Latin America

Bender

Python

Lindsay

et al. 2019

Preprint

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Approximately 150 triatomine species are known to be infected with the Chagas parasite, Trypanosoma cruzi, but they differ in the risk they pose to human populations. The largest risk comes from species that have a domestic life cycle and these species have been targeted by indoor residual spraying campaigns, which have been successful in many locations. It is now important to consider residual transmission that may be linked to persistent populations of dominant vectors, or to secondary or minor vectors. The aim of this project was to define the geographical distributions of the community of triatomine species in Latin America. Presence-only data with over 12, 000 observations of triatomine vectors were extracted from a public database and target-group background data were generated to account for sampling bias in the presence data. Geostatistical regression was then applied to estimate species distributions and fine-scale distribution maps were generated for thirty triatomine vector species. The results for Panstrongylus geniculatus, P. megistus, Triatoma barberi, T. brasiliensis, and T. pseudomaculata are presented in detail and the model validation results for each of the 30 species are presented in full. The predictive maps for all species are made publicly available so that they can be used to assess the communities of vectors present within different regions of the endemic zone. The maps are presented alongside key indicators for the capacity of each species to transmit T. cruzi to humans. These indicators include infection prevalence, evidence for human blood meals, and colonisation or invasion of homes. A summary of these indicators shows that the majority of the 30 species mapped by this study have the potential to transmit T. cruzi to humans. Author summaryThe Pan American Health Organisation's Strategy and Plan of Action for Chagas Disease Prevention, Control and Care highlights the importance of eliminating those triatomine vector species that colonise homes, and has had great success in many locations. Since indoor residual spraying campaigns have targeted these species, their importance relative to other vectors has diminished and their geographical distributions August 16, 2019 1/18 may also have changed. It is now vital to consider the full community of vector species, including previously dominant vectors as well as secondary or minor vector species, in order to target residual transmission to humans. Our aim was to define the geographical distributions of the most commonly reported triatomine species in Latin America. We extracted reports of triatomine vector species observed at specific locations from a public database and we used a geostatistical model to generate fine-scale predictive maps for thirty triatomine vector species. We present these maps alongside a summary of key indicators related to the capacity of each species to transmit the Chagas parasite to humans. We show that most of the 30 species that we have mapped pose a potential threat to human populations.

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Distribution of triatomine species in domestic and peridomestic environments in central coastal Ecuador

Cited by 28 publications

References 30 publications

Determinants of intentions to prevent triatomine infestation based on the health belief model: An application in rural southern Ecuador

Determinants of intentions to prevent triatomine infestation based on the health belief model: An application in rural southern Ecuador

Under pressure: phenotypic divergence and convergence associated with microhabitat adaptations in Triatominae

Modelling geospatial distributions of the triatomine vectors of Trypanosoma cruzi in Latin America

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