Your search keyword '"Nyasembe VO"' showing total 2 results

1. Host plant forensics and olfactory-based detection in Afro-tropical mosquito disease vectors.

Author

Nyasembe VO, Tchouassi DP, Pirk CWW, Sole CL, and Torto B

Subjects

Acyclic Monoterpenes, Aedes physiology, Aldehydes, Alkenes, Animals, Anopheles physiology, DNA, Plant, Dengue transmission, Dengue virology, Dengue Virus, Feeding Behavior psychology, Female, Genes, Plant genetics, Host-Parasite Interactions physiology, Kenya, Malaria transmission, Male, Monoterpenes, Plants classification, Plants genetics, Rift Valley Fever transmission, Sesquiterpenes, Behavior, Animal physiology, Disease Vectors, Mosquito Vectors physiology, Odorants, Plant Extracts chemistry, Plants chemistry, Smell

Abstract

The global spread of vector-borne diseases remains a worrying public health threat, raising the need for development of new combat strategies for vector control. Knowledge of vector ecology can be exploited in this regard, including plant feeding; a critical resource that mosquitoes of both sexes rely on for survival and other metabolic processes. However, the identity of plant species mosquitoes feed on in nature remains largely unknown. By testing the hypothesis about selectivity in plant feeding, we employed a DNA-based approach targeting trnH-psbA and matK genes and identified host plants of field-collected Afro-tropical mosquito vectors of dengue, Rift Valley fever and malaria being among the most important mosquito-borne diseases in East Africa. These included three plant species for Aedes aegypti (dengue), two for both Aedes mcintoshi and Aedes ochraceus (Rift Valley fever) and five for Anopheles gambiae (malaria). Since plant feeding is mediated by olfactory cues, we further sought to identify specific odor signatures that may modulate host plant location. Using coupled gas chromatography (GC)-electroantennographic detection, GC/mass spectrometry and electroantennogram analyses, we identified a total of 21 antennally-active components variably detected by Ae. aegypti, Ae. mcintoshi and An. gambiae from their respective host plants. Whereas Ae. aegypti predominantly detected benzenoids, Ae. mcintoshi detected mainly aldehydes while An. gambiae detected sesquiterpenes and alkenes. Interestingly, the monoterpenes β-myrcene and (E)-β-ocimene were consistently detected by all the mosquito species and present in all the identified host plants, suggesting that they may serve as signature cues in plant location. This study highlights the utility of molecular approaches in identifying specific vector-plant associations, which can be exploited in maximizing control strategies such as such as attractive toxic sugar bait and odor-bait technology.

Published

2018

2. Development and assessment of plant-based synthetic odor baits for surveillance and control of malaria vectors.

Author

Nyasembe VO, Tchouassi DP, Kirwa HK, Foster WA, Teal PE, Borgemeister C, and Torto B

Subjects

Acyclic Monoterpenes, Aldehydes, Alkenes, Animals, Bicyclic Monoterpenes, Bridged Bicyclo Compounds, Chemotactic Factors pharmacology, Cyclohexanols, Cyclohexenes, Female, Insect Vectors drug effects, Kenya, Likelihood Functions, Limonene, Male, Monoterpenes, Sesquiterpenes, Terpenes, Trityl Compounds, Chemotactic Factors metabolism, Insect Control methods, Insect Vectors physiology, Malaria prevention & control, Odorants analysis, Public Health Surveillance methods

Abstract

Background: Recent malaria vector control measures have considerably reduced indoor biting mosquito populations. However, reducing the outdoor biting populations remains a challenge because of the unavailability of appropriate lures to achieve this. This study sought to test the efficacy of plant-based synthetic odor baits in trapping outdoor populations of malaria vectors., Methodology and Principal Finding: Three plant-based lures ((E)-linalool oxide [LO], (E)-linalool oxide and (E)-β-ocimene [LO + OC], and a six-component blend comprising (E)-linalool oxide, (E)-β-ocimene, hexanal, β-pinene, limonene, and (E)-β-farnesene [Blend C]), were tested alongside an animal/human-based synthetic lure (comprising heptanal, octanal, nonanal, and decanal [Blend F]) and worn socks in a malaria endemic zone in the western part of Kenya. Mosquito Magnet-X (MM-X) and lightless Centre for Disease Control (CDC) light traps were used. Odor-baited traps were compared with traps baited with either solvent alone or solvent + carbon dioxide (controls) for 18 days in a series of randomized incomplete-block designs of days × sites × treatments. The interactive effect of plant and animal/human odor was also tested by combining LO with either Blend F or worn socks. Our results show that irrespective of trap type, traps baited with synthetic plant odors compared favorably to the same traps baited with synthetic animal odors and worn socks in trapping malaria vectors, relative to the controls. Combining LO and worn socks enhanced trap captures of Anopheles species while LO + Blend F recorded reduced trap capture. Carbon dioxide enhanced total trap capture of both plant- and animal/human-derived odors. However, significantly higher proportions of male and engorged female Anopheles gambiae s.l. were caught when the odor treatments did not include carbon dioxide., Conclusion and Significance: The results highlight the potential of plant-based odors and specifically linalool oxide, with or without carbon dioxide, for surveillance and mass trapping of malaria vectors.

Published

2014