Biology of insecticide resistance in the African malaria vector Anopheles Funestus (Diptera: Culicidae)

Okoye, Patricia Nkem

15 October 2008

The emergence of pyrethroid resistant Anopheles funestus (a major African vector) in malaria affected parts of KwaZuluNatal, South Africa was correlated with the malaria epidemic of 1996 2000. This finding prompted the necessity of incorporating insecticide resistance management strategies into formal malaria control policy in South Africa. Resistance management strategies often rely on the assumption of reduced fitness associated with insecticide resistance and are based on the principle that resistance genes will tend to drift out of vector populations in the absence of insecticide selection pressure. This study aimed to determine whether a fitness cost is associated with pyrethroid resistance as well as to determine the stability and mode of inheritance of the resistance genes in a pyrethroid resistant (FUMOZR) strain of An. funestus. It also aimed to sequence and analyze a segment of the sodium channel gene for any kdrtype mutation(s) that may be associated with pyrethroid resistance. The final aim was to determine the resistance mechanisms involved in a Ghanaian field population of An. funestus resistant to DDT and pyrethroids. Results obtained suggest that pyrethroid resistance in southern African An. funestus did not incur any loss of fitness. FUMOZR had a reproductive advantage over a pyrethroid susceptible An. funestus strain (FANG) in terms of higher fertility, proportion of females laying eggs and eggtoadult survivorship, and a lower sterility Click to buy NOW! PDFXCHANGE www.docutrack. com Click to buy NOW! PDFXCHANGE www.docutrack. com iv rate. However, FUMOZR had a slower developmental time from egg hatch to adult emergence than FANG. Results of crosses and backcrosses carried out between FUMOZR and FANG were consistent with a monofactorial and autosomal mode of inheritance in which the resistant genes presented as incompletely dominant. The resistant gene was found to be stable over several generations in the absence of insecticide selection pressure. Analysis of the genomic and mRNA sequences of the IIS5 IIS6 segment of the sodium channel gene showed a high sequence identity between FUMOZR and FANG suggesting that the two strains are genetically similar. The kdrtype mutation was absent from this region supporting previous evidence that the resistance mechanism is primarily metabolic. Bioassay data showed that a Ghanaian field population of An. funestus from Obuasi, Ghana, was resistant to DDT and pyrethroids. Molecular analysis of the IIS5 IIS6 segment of the sodium channel gene showed an absence of kdrtype mutations previously associated with insecticide resistance. Biochemical analysis suggests that resistance is metabolically mediated primarily by elevated levels of and esterases with monooxygenases and GSTs playing a lesser role. The presence of an altered acetylcholinesterase conferring carbamate resistance was also evident in the population. These results have implications for the management of resistance in malaria control programmes in Africa.

Anopheles Funestus

Pyrethoids

Sodium channel gene

Insecticide resistance and vector status of Anopheles funestus and An. gambiae populations at a sugar estate in Mozambique

Kloke, Ronald Graham

12 April 2010

MSc (Med), Faculty of Health Sciences, University of the Witwatersrand, 2009 / Malaria is on the increase in Mozambique since 2001 and impacts primarily on children < 5 years of age. Insecticide resistance in the malaria vector mosquitoes is on the increase in Mozambique and Africa and is cause for serious concern. Maragra sugar estate is situated in close proximity to the nKomati river floodplain in a rural area in Mozambique and requires intense irrigation for cane growing and as a result provides extensive breeding sites for An. funestus and other mosquitoes. In the areas surrounding the estate there are two important vectors of malaria, Anopheles funestus group and An. gambiae complex. There is intense malaria transmission in the areas surrounding the sugar estate and the last entomological study on the vectors in the Manhica area was done in 1998. It was becoming increasingly urgent to identify to species level the vectors in this area and to monitor the insecticide resistance status of these vectors. Due to leakage (theft) of insecticides and a change by the National Malaria Control Programme (NMCP) to an insecticide to which the predominant vector is resistant, an entomological survey was carried out in this area from January 2009 to March 2009 to ascertain by Polymerase chain reaction (PCR) what species of malaria vectors were present inside and outside of the Maragra vector control area, their population levels and their vectorial status in these two areas. Insecticide resistance studies by insecticide exposure and the synergist piperonyl butoxide (pbo) were carried out using the World Health Organisation (WHO) bioassay method on collected An. funestus mosquitoes. This was done to establish this species resistance status to the four classes of insecticides recommended by the WHO for malaria vector control. The collections of An. arabiensis and An. merus that were identified were too few to carry out insecticide resistance tests on these two species. Enzyme linked v immuno-sorbent assay (ELISA) tests were undertaken to establish the vectorial capacity of Anopheles funestus and An. gambiae complex in this area. The predominant malaria vector species in this area is An. funestus s.s., with the secondary vector being An. arabiensis. An. funestus has a high vectorial capacity in this area and found to have a Plasmodium falciparum sporozoite rate of 6.02%. This is an increase in the sporozoite rate of 1.2% from 1998 when the last survey in this regard was carried out. Coupled with this increase is an increase in the An. funestus populations in this area since this time. One An. gambiae complex sample was found to be positive but the species is not known as this particular sample did not amplify on PCR. Anopheles funestus is highly resistant to synthetic pyrethroids and exhibits a lower level of resistance to bendiocarb, a carbamate insecticide in use at Maragra sugar estate. The synergist pbo mediates the resistance mechanism in both these insecticides indicating that the metabolic resistance mechanism present in this mosquito is strongly mediated by monooxygenase detoxification. The role of the medical entomologist is increasingly necessary and important in the monitoring of this resistance phenomenon in malaria vector mosquitoes, as is the role of the vector control programme manager in implementing and managing vector control programmes. The implication of cane sugar farming and its impact on vector production and malaria transmission is discussed. Insecticide resistance and the change by the NMCP to a synthetic pyrethroid to which the predominant vector of malaria is resistant is discussed.

insecticide

malaria

Mozambique

Anopheles funestus

Anopheles gambiae

Role of monooxygenases in insecticide resistant anopheles funestus(diptera: culicidae)

Amenya, Dolphine Achieng'

26 February 2007

Student Number : 0318930A - PhD thesis - School of Animal, Plant and Environmental Studies - Faculty of Science / The widespread use of pyrethroid insecticides has led to the emergence of significant insecticide resistance in various parts of the world. An unprecedented increase in the number of annual malaria cases reported in Kwazulu Natal, South Africa in 1999 to 2000 was attributed to the re-emergence of pyrethroid-resistant Anopheles funestus Giles. Resistance was metabolic-based with increased monooxygenase (P450) metabolising the pyrethroid insecticides. This emphased the need to understand the molecular mechanisms conferring pyrethroid resistance in An. funestus. The present study aimed to firstly isolate P450 genes in An. funestus and secondly, to identify P450 gene over-expressed in a resistant (FUMOZ-R) strain compared to a susceptible (FANG) strain. A third aim was to construct an An. funestus cDNA library to lay the foundation for future studies on P450 monooxygenses. Degenerate primers based on conserved regions of three An. gambiae P450 families were used to amplify cDNAs from An. funestus. Eleven CYP4, four CYP6 and five CYP9 partial genes were isolated and sequenced. BLAST results revealed that An. funestus P450s have a high sequence similarity to An. gambiae with above 75% identity at the amino acid level. The exception was CYP9J14. The An. gambiae P450 with the closest similarity to CYP9J14 exhibited only 55% identity suggesting a recent duplication event in CYP9J14. Molecular phylogenetic analysis also supported this hypothesis. Intron positions were highly conserved between the two species. Expression studies using blot analysis implicated CYP6P9, an ortholog of CYP6P3 in An. gambiae, as the over-expressed P450. Dot blot analysis revealed a 500-fold expression higher in FUMOZ-R strain compared with FANG strain. Semiquantitative PCR revealed that CYP6P9 was developmentally regulated. Expression was not detected in eggs and was higher in larvae compared to pupae. Quantitative real time PCR showed that CYP6P9 expression was 4.5-fold higher in 3-day old FUMOZ-R males than females and 3.5-fold higher in the 14-day old males than 14- day old females. Statistically, this difference was not significant suggesting that CYP6P9 expression is not sex specific. The An. funestus cDNA library construction in λTriplEx2 vector was successful with a titre of 4.9 x108 pfu/ml and a transformation efficiency of 98%.

Malaria vector

Insecticide resistance

Monoxygenases

Anopheles funestus

Comparative insecticide resistance intensity studies between the pyrethroid resistant wild Zambian and the laboratory reared Mozambique Anopheles funestus

Segoea, Godira

January 2015

Malaria continues to be a significant cause of morbidity and mortality in the developing world with Africa being the most affected. Malaria vector control with chemical insecticides is the primary intervention to curb transmission. However, the success of chemical based interventions is threatened by the escalating development of insecticide resistance in the major anopheline mosquito vectors.

resistance intensities

deltamethrin

bendiocarb

Anopheles funestus

Anopheles arabiensis

Identification and characterization of microRNAs and their putative target genes in Anopheles funestus s.s

Ali, Mushal Allam Mohamed Alhaj

January 2013

Philosophiae Doctor - PhD / The discovery of microRNAs (miRNAs) is one of the most exciting scientific breakthroughs in the last decade. miRNAs are short RNA molecules that do not encode proteins but instead, regulate gene expression. Over the past several years, thousands of miRNAs have been identified in various insect genomes through cloning and sequencing, and even by computational prediction. However, information concerning possible roles of miRNAs in mosquitoes is limited. Within this context, we report here the first systematic analysis of these tiny RNAs and their target mRNAs in one of the principal African malaria vectors, Anopheles funestus s.s. Firstly, to extend the known repertoire of miRNAs expressed in this insect, the small RNAs from the four developmental stages (egg, larvae, pupae and the adult females), were sequenced using next generation sequencing technology. A total of 98 miRNAs were identified, which included 65 known Anopheles miRNAs, 25 miRNAs conserved in other insects and 8 novel miRNAs that had not been reported in any species. We further characterized new variants for miR-2 and miR-927 and stem-loop precursors for miR-286 and miR-2944. The analysis showed that many miRNAs have stage-specific expression, and co-transcribed and co-regulated during development. Secondly, for a better understanding of the molecular details of the miRNAs function, we identified the target genes for the Anopheles miRNAs using a novel approach that identifies overlap genes among three target prediction tools followed by filtering genes based on functional enrichment of GO terms and KEGG pathways. We found that most of the miRNAs are metabolic regulators. Moreover, the results suggest implication of some miRNAs not only in the development but also in insect-parasite interaction. Finally, we developed the InsecTar database (http://insectar.sanbi.ac.za) for miRNA targets in the three mosquito species; Anopheles gambiae, Aedes aegypti, and Culex quinquefasciatus, which incorporates prediction and the functional analysis of these target genes. The proposed database will undoubtedly assist to explore the roles of these regulatory molecules in insects. This type of analysis is a key step towards improving our understanding of the complexity and regulationmode of miRNAs in mosquitoes. Moreover, this study opens the door for exploration of miRNA in regulation of critical physiological functions specific to vector arthropods which may lead to novel approaches to combat mosquito-borne infectious diseases.

MicroRNA

Non-Coding RNA

MicroRNA Target

InsecTar

Database

Anopheles funestus

Anopheles gambiae

Culex quinquefasciatus

Aedes aegypti

Mosquitoes

Vectors

Insect

Malaria