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Spatial and temporal variation in the kdr allele L1014S in Anopheles gambiae s.s. and phenotypic variability in susceptibility to insecticides in Western Kenya

Abstract

Background

Malaria vector control in Africa depends upon effective insecticides in bed nets and indoor residual sprays. This study investigated the extent of insecticide resistance in Anopheles gambiae s.l., Anopheles gambiae s.s. and Anopheles arabiensis in western Kenya where ownership of insecticide-treated bed nets has risen steadily from the late 1990s to 2010. Temporal and spatial variation in the frequency of a knock down resistance (kdr) allele in A. gambiae s.s. was quantified, as was variation in phenotypic resistance among geographic populations of A. gambiae s.l.

Methods

To investigate temporal variation in kdr frequency, individual specimens of A. gambiae s.s. from two sentinel sites were genotyped using RT-PCR from 1996-2010. Spatial variation in kdr frequency, species composition, and resistance status were investigated in additional populations of A. gambiae s.l. sampled in western Kenya in 2009 and 2010. Specimens were genotyped for kdr as above and identified to species via conventional PCR. Field-collected larvae were reared to adulthood and tested for insecticide resistance using WHO bioassays.

Results

Anopheles gambiae s.s. showed a dramatic increase in kdr frequency from 1996 - 2010, coincident with the scale up of insecticide-treated nets. By 2009-2010, the kdr L1014S allele was nearly fixed in the A. gambiae s.s. population, but was absent in A. arabiensis. Near Lake Victoria, A. arabiensis was dominant in samples, while at sites north of the lake A. gambiae s.s was more common but declined relative to A. arabiensis from 2009 to 2010. Bioassays demonstrated that A. gambiae s.s. had moderate phenotypic levels of resistance to DDT, permethrin and deltamethrin while A. arabiensis was susceptible to all insecticides tested.

Conclusions

The kdr L1014S allele has approached fixation in A. gambiae s.s. populations of western Kenya, and these same populations exhibit varying degrees of phenotypic resistance to DDT and pyrethroid insecticides. The near absence of A. gambiae s.s. from populations along the lakeshore and the apparent decline in other populations suggest that insecticide-treated nets remain effective against this mosquito despite the increase in kdr allele frequency. The persistence of A. arabiensis, despite little or no detectable insecticide resistance, is likely due to behavioural traits such as outdoor feeding and/or feeding on non-human hosts by which this species avoids interaction with insecticide-treated nets.

Background

Malaria vector control programmes in sub-Saharan Africa continue to rely heavily on indoor residual spraying (IRS) or insecticide-treated nets (ITNs), both of which depend on vector susceptibility to the insecticides used. ITNs are a common component of malaria control programs, largely due to their ease of implementation, cost effectiveness [1–3], and record of success across transmission settings [4]. As a consequence, ITNs have been heavily promoted by the public-health community; and as of 2010, it was estimated that 42% of households owned at least one ITN across 44 countries in sub-Saharan Africa [5]. These advances in vector control, combined with effective new anti-malarial drugs, have renewed optimism for regional elimination [6, 7].

Few insecticides are available for use in malaria vector control and only pyrethroid compounds are considered safe for the treatment of ITNs [8]. Therefore, the continued success of ITNs and essentially the current vector-control paradigm depend on continued mosquito susceptibility to a single class of insecticides. Two mechanisms of insecticide resistance, which may co-occur, are commonly measured: (1) metabolic resistance and (2) target-site insensitivity [9]. The former results from the over expression or amplification of genes coding for enzymes that either biochemically alter the insecticidal compound making it less toxic to the mosquito (e.g. P450 monooxygenases), or sequester the compound preventing reactions detrimental to normal physiology (e.g. esterases) [9, 10]. In contrast, target-site insensitivity involves one or more mutations that make the physiologic target of an insecticide less reactive to the chemical [11]. Target-site insensitivity in the malaria vector Anopheles gambiae s.s. (hereafter referred to as A. gambiae) includes two kdr mutations (for knock-down resistance) which result in an amino acid substitution in the S6 hydrophobic segment of domain II in the voltage-gated sodium channel of neuronal membranes [9, 11]. Both mutations reduce susceptibility to DDT and to the pyrethroid class of insecticides and occur at different nucleotides of the same amino acid (residue 1014). In wild-type mosquitoes, this residue codes for leucine (TTA), while in mutant mosquitoes single nucleotide changes result in either a phenylalanine (TTT) or serine (TCA) substitution [12, 13]. The former is commonly referred to as West African kdr, or L1014F; while the latter is called East African kdr, or L1014S. Molecular data suggest that each mutation has risen independently at least twice in A. gambiae[14], and, although the names of each allele suggest distinct geographic distributions, co-occurrence has been reported in multiple countries including Uganda, Gabon, Cameroon, Equatorial Guinea, and Angola [15]. L1014F is thought to confer a greater degree of insensitivity to pyrethroid insecticides than L1014S [11], although bioassay data comparing each mutation within the same genetic background do not exist. Nevertheless, it has been speculated that selection for L1014F should be stronger than for L1014S, a hypothesis supported by recent molecular data showing that signatures of selective sweeps (i.e. reduced nucleotide variability) are more extensive around L1014F than L1014S mutations in the genomes of wild-caught mosquitoes [16]. A third mechanism of resistance--behavioural--is poorly understood and difficult to measure, although the excitatory effects of DDT in IRS and permethrin in certain ITN formulations suggest that a primary mode of action of these two chemicals is on vector behaviour and not survival [17–20].

When monitoring or investigating insecticide resistance in vector populations, at least three approaches can be taken, each with advantages and disadvantages: (1) measures of phenotypic resistance provide a direct indication of how resistance mechanisms impact vector control activities but require access to testing kits, insecticide impregnated papers, rearing facilities, and large numbers of mosquitoes, any of which may be limiting; (2) frequencies of target site mutations (e.g. kdr) are easier to measure, but it is unclear how much this mechanism contributes to resistant phenotypes; (3) measures of metabolic resistance (e.g. biochemical assays or gene expression arrays) are likely to be strong indicators of phenotypic resistance but are technically challenging.

Malaria vectors in western Kenya, where the present study was conducted, include two sibling species of the A. gambiae species complex, A. gambiae and Anopheles arabiensis, as well as Anopheles funestus s.s. Historically, A. gambiae has been the primary vector in the study area, but this species has declined proportionately to A. arabiensis (a secondary vector), possibly due to greater effectiveness of ITNs against the former, more anthropophilic species [21]. Development of insecticide resistance in the local A. gambiae population could reverse this trend and might reduce effectiveness of the malaria control program in the region.

Two of the study sites included in the present study are within or adjacent to areas included in a small ITN trial conducted in 1990 and a large-scale trial conducted from 1996 to 1999. The former involved just six villages [22], while the latter covered a 500 km2 area that encompassed 221 villages [23]. In the smaller trial, A. gambiae mosquitoes collected from villages with permethrin-treated nets and curtains showed increased tolerance to permethrin after one year, leading to establishment of a laboratory strain with reduced sensitivity to permethrin [24]. However, this tolerance did not persist in field populations, and required constant selection in the laboratory to maintain the phenotype [25]. The tolerant field population had increased activity of metabolic enzymes as well as a novel mutation in the sodium channel gene (i.e. kdr L1014S) [13, 26]. Studies of insecticide resistance following the larger ITN trial have varied with respect to both levels of phenotypic resistance and frequency of the kdr L1014S mutation. In 2004, Stump et al. [27] reported that kdr frequency was 8.0% in A. gambiae and had only risen slightly since 1987. A more recent study reported a range of 0.5% to 15.0% among sites in western Kenya for A. gambiae and 0.9% for A. arabiensis, but "conservative" population estimates for the former were given as 1.0% or less when accounting for relatedness of the specimens [28]. That study also reported an increase in monooxygenase activity in field-collected specimens. Another recent study reported a kdr L1014S frequency of 25.4% in a sub-population of A. gambiae from western Kenya [29]. WHO bioassays, however, provided no evidence of phenotypic resistance. Whether genotypic or phenotypic insecticide resistance is evolving in the A. gambiae population in direct response to the rapid rise in use of ITNs in western Kenya, in parallel with the profound changes in species composition of the A. gambiae complex there [21], is currently unknown. Therefore, the objective of this study was to quantify temporal variation in kdr L1014S frequency in populations of A. gambiae (1996 - 2010) from two areas of western Kenya having markedly different histories of ITN distribution and use; and to assess the spatial variation in frequency of the kdr L1014S allele, species composition, and phenotypic resistance among populations of A. gambiae s.l. sampled from multiple sites in western Kenya.

Methods

Temporal variation in kdr allele frequency

Adult and larval A. gambiae s.l. were sampled in the communities of Asembo from 1996 to 2010 and Seme from 2000 to 2008. These adjacent communities are situated 40-50 km west of the city of Kisumu along the northern shore of the Winam Gulf of Lake Victoria (Figure 1B), and are described in detail elsewhere [21, 30, 31]. The malaria vector populations in Asembo have been broadly exposed to pyrethroid insecticides in ITNs for about 13 years, beginning with Asembo's involvement in a village randomized, controlled trial of permethrin-treated bed nets in 1997. Initially, half of the villages in Asembo were provided permethrin-treated bed nets. Nets were re-treated with permethrin at approximately six-month intervals [23]. From 1999-2003, all villages were provided permethrin-treated bed nets and free house-to-house re-treatment [30]. Beginning in 2003, permethrin was replaced with alphacypermethrin (40 mg/m2) at 9 to 11 month intervals until the end of 2006. In early 2007, nets were treated with a KO Tab 1-2-3 wash resistant retreatment kit containing deltamethrin at a dose of 25 mg/m2[32]. Thereafter, residents were responsible for insecticide retreatment of their nets.

Figure 1
figure 1

Map of study area. A. Map of Kenya showing where studies were conducted in western Kenya, indicated by the box. B. Map showing sampling locations in western Kenya study area, near Kisumu, Kenya's third largest city.

At the conclusion of the large-scale trial in Asembo in 2000, entomological studies began in Seme, located on Asembo's eastern border [21, 31]. Seme did not participate in or receive ITNs as part of the cluster randomized trial that was conducted in Asembo. Net ownership in Seme began to rise only after the Kenya Ministry of Health and other partners increased access to ITNs through free and subsidized distributions beginning in 2004. ITNs were initially available to pregnant women and children <5 years old at a subsidized price at government-run health clinics. In 2006, ITNs were distributed free to children <5 years of age as part of a mass campaign [33] and the subsidy for ITNs distributed at government clinics was significantly increased. By 2009, ITNs were distributed at clinics to pregnant women and children <1 year of age free of charge.

Mosquito sampling methods have been described previously [21]. Sampling commenced in 1996 when adult female A. gambiae s.l. mosquitoes were collected from bed-net traps. From 1997 to 1999, mosquitoes were collected using pyrethrum spray catches (PSCs) inside houses in Asembo using 0.025% pyrethrum and 0.1% piperonyl butoxide mixed in kerosene. Houses for sampling were identified by selection from a geographic information system database [21, 31, 34]. From 2003-2008, mosquitoes were collected along transects running east to west during and immediately after the rainy season of each year (typically, April to July). From 2007 to 2010, adult samples were supplemented with larvae sampled from aquatic habitats along the same transect [21]. All larva-positive habitats encountered were exhaustively sampled for L3 and L4 stage larvae to obtain specimens for genotyping and bioassays as needed. Larvae and adults were morphologically identified to the A. gambiae complex, and categorized by stage; adults were categorized by sex, and by abdominal status if an adult female. Mosquitoes were desiccated in anhydrous calcium sulfate or silica gel for 48 hours. Following desiccation, samples were stored at room temperature until DNA extraction (see below).

Geographic variation in kdr allele

In 2009 and 2010, the geographic scope of the study was expanded to estimate the frequency of the kdr L1014S allele in A. gambiae and A. arabiensis regionally in western Kenya to include Budalangi (2010 only), Kisian, Kakamega, Bungoma (2009 only), Malaba, and Busia in Nyanza and Western provinces (Figure 1A, B). Adult and larval stages of A. gambiae s.l. were sampled and processed from these other sites using similar procedures as for Asembo and Seme.

Species identification and genotyping

DNA was extracted from A. gambiae s.l. larvae and adults following the protocol of Collins et al[35]. For adult males and larvae, whole bodies were ground in the initial step. For fed and half-gravid females, DNA was extracted from legs and wings only, while extraction from unfed and gravid females utilized legs, wings, and abdomens. Conventional polymerase chain reaction (PCR) was used to distinguish between the two sibling species of the A. gambiae species complex native to western Kenya, A. gambiae and A. arabiensis[36]. Real-time polymerase chain reaction (RT-PCR) was used to determine kdr genotype at amino acid position 1014 of the voltage-gated sodium channel. Following a modified version of the protocol by Bass et al. [37] , samples were genotyped using probes for the wild type (5'-CTTACGACTAAATTTC-3', labeled with HEX) and L1014S (5'-ACGACTGAATTTC-3', labeled with 6-FAM) alleles. A subset of samples was also genotyped for the L1014F allele (5'-ACGACAAAATTTC-3', labeled with 6-FAM). RT-PCR reactions were run on a Stratagene MxPro 3000 machine using a 96-well format. Each reaction included 5.0 μl of 2× Taqman RT-PCR master mix (Applied Biosystems), 0.2 μM kdr forward primer (5'-GCTGCGAGTTGTAGAGATGCG-3'), 0.2 μM kdr reverse primer (5'-GCTTACTGGTTTGGTCGGCATGT-3'), the wild type and L1014S probes at respective concentrations of 0.2 μM and 0.15 μM, ~50 ng DNA template, and sterile water in a final volume of 10 μl. Each 96-well plate included positive controls for all three genotypes in triplicate along with a no-template negative control. PCR conditions included an initial melting step at 95°C for 10 minutes followed by 45 cycles of 95° for 25 seconds and 64°C for 1 minute. Reaction curves for each set of reactions were visualized using Stratagene MxPro QPCR software and genotypes were scored by eye. Absence of alleles was confirmed by the text reports generated by the Stratagene MxPro QPCR software.

Sporozoite infection association with kdr

To test the hypothesis that mosquitoes with the kdr L1014S allele are longer lived, more fit, and therefore more likely to acquire a malaria infection in the context of high ITN coverage, a case-control study was conducted using specimens collected in Asembo and Gem, an area just to the north of Asembo and to the northwest of Seme, from 2003 through 2007. Mosquitoes were collected monthly using light traps set overnight next to persons sleeping under bed nets. Female A. gambiae s.l. were tested for the presence of Plasmodium falciparum sporozoites using the antigen-capture ELISA method of Wirtz et al[38]. All ELISA positive A. gambiae s.l. were identified to species by PCR, and each A. gambiae was analysed for the L1014S allele as described above. For each ELISA positive A. gambiae, three ELISA-negative A. gambiae mosquitoes collected in the same village in the same month were randomly selected as controls for a matched analysis, and were genotyped for the kdr allele as well.

Bioassays

To assess insecticide resistance phenotypically, field-collected A. gambiae s.l. mosquitoes were assayed for susceptibility to various insecticides using WHO tube tests [39]. Mosquitoes were collected from study sites as larvae and transported to an insectary, where they were reared in spring water and fed daily a mixture of finely ground fish food and brewer's yeast. Upon pupation, individuals were transferred to cages (40 cm3 metal frames covered with untreated mosquito netting) and allowed to emerge. Upon emergence, all adults were held for 2-5 days and provided sugar solution until used in bioassays. Insecticide impregnated papers for five insecticides were obtained from WHO at standard concentrations for determining resistance in field populations [39]: bendiocarb (0.1%), DDT (4%), deltamethrin (0.05%), malathion (5%), and permethrin (0.75%). Bioassays performed in early 2009 only used DDT, deltamethrin, and permethrin, while those performed in late 2009 and 2010 used all five insecticides. Due to variation in larval numbers, as well as time to pupation and emergence, the number of replicates per insecticide and number of mosquitoes per assay varied. The number of individuals used in any single assay ranged from 8 - 20 and the minimum number of replicates was three. For each bioassay, the plastic tube from the test kit was lined with the appropriate test paper and mosquitoes were transferred from a holding cage to the tube via an aspirator. Following transfer, tubes were placed horizontally on a flat surface to ensure maximal contact with the impregnated papers. Exposure for each replicate was 60 minutes for all insecticides, after which individuals were transferred to cohort cages (approximately 1 L volume) and allowed to recover. During recovery, mosquitoes were provided with sugar solution and maintained at 25˚C and relative humidity ≥ 80%. Mortality was scored at 24 hours post-bioassay. Following the late 2009 and 2010 bioassays, DNA was extracted from assayed individuals and used to determine kdr L1014S genotype and species identification as described above.

Data analysis

For analysis of changes in the frequency of the kdr L1014S allele over time, samples collected from each year and location were treated as separate populations. The frequency of L1014S homozygotes was analysed using multiple logistic regression in Stata (v. 11.0) with the dependent variable being the loge(odds of kdr L1014S homozygosity), modeled as a function of year and location. The frequency of kdr L1014S homozygotes, rather than frequency of kdr L1014S alleles, was selected as the dependent variable because the kdr mutation is only partially recessive and functionally more significant in the homozygous state [13, 16]. For the 2009 and 2010 samples, the frequency of kdr L1014S homozygotes was modeled in a similar manner but with sub-population and month of collection as the independent variables.

Similarly, for analysis of spatial variability, samples collected in 2009-10 were analysed separately by location, as were samples from the same location collected at different times of the year. However, because previous population-genetic studies of A. gambiae suggest that western Kenya has a single, panmictic population [40], the 2009 and 2010 location-specific samples are referred to as sub-populations throughout to acknowledge their genetic non-independence. For each sub-population, genotype frequencies were compared to Hardy-Weinberg expectations using the program Genepop (v. 4.0), Option 1 (Hardy-Weinberg Exact Tests), Sub-option 3 (Probability test) [41]. Genepop was also used to estimate Wright's inbreeding coefficient (FIS) using the method of Weir and Cockerham [42]; and for sub-populations out of Hardy-Weinberg equilibrium, these values were used to test for heterozygote deficiency and excess (Genepop O ption 1, Sub-options 1 and 2, respectively) using the U test as described in Raymond and Rousset [41]. A Bonferroni correction was applied to the level of significance for each procedure to adjust for multiple tests. To determine if mosquitoes with the kdr genotype were more likely to be infected with P. falciparum sporozoites, PROC LOGISTIC in SAS was used to model sporozoite infection status against kdr genotype.

Data from bioassays were pooled for each sub-population and insecticide, and mortality was calculated as the percentage of individuals that died within 24 hours of exposure. For bioassays performed in 2009, variation in survival was assessed using multiple logistic regression with the dependent variable being the loge(odds of survival) modelled as a function of sub-population and insecticide. Following regression, estimates of binomial 95% percent confidence intervals were used to compare bioassay outcomes between insecticides within a given sub-population. Further, levels of resistance were classified according to WHO guidelines [39]. Those with an overall mortality ≥ 98% were considered susceptible, those with mortality <98% but ≥ 80% were considered potentially resistant, and those with mortality <80% were strongly suspected to be resistant.

Results

Temporal variation in kdr genotype frequencies and species composition

A total of 799 samples of A. gambiae were genotyped for the kdr L1014S mutation in sub-populations from Asembo (1996-2010) and Seme (2000-2008). Results showed a sharp increase in homozygote frequencies from complete absence in both locations initially to 80.5% for Seme in 2008 and 91.7% for Asembo in 2010 (Table 1, Figure 2). Logistic regression indicated that the proportion of kdr L1014S homozygotes increased significantly by year for both Asembo (O.R. = 2.108, 95% CI = 1.81 - 2.45, P < 0.001) and Seme (2.547, 95% CI = 2.04 - 3.17, P < 0.001). Exact tests for Hardy-Weinberg equilibrium for each year and location showed that genotype frequencies differed significantly from expectation only in 2008 after correcting for multiple tests (Table 1). The West African allele (1014F) was not detected in any genotyped A. gambiae individuals (n = 88) from Asembo and Seme in 2008. A single A. arabiensis from Busia that was homozygous for the kdr 1014S allele was detected in 44 A. arabiensis from Bungoma, Busia, Kakamega, and Kisian in 2009 and 2010.

Table 1 Genotype frequencies for kdr 1014S in Anopheles gambiae s.s. according location and date of sample collection.
Figure 2
figure 2

Frequency of the kdr L1014S allele in Anopheles gambiae s.s. (top) and bed net ownership (bottom) by year in Asembo and Seme, western Kenya. Bed net ownership is the percentage of households that own at least one bed net, including both treated conventional nets and long-lasting impregnated nets.

Geographic variation in kdr genotype frequencies and species composition

3,172 specimens were identified to species within the A. gambiae complex from seven sites from 2009 and 2010. The proportion of the sibling species A. gambiae and A. arabiensis varied among sampling location but patterns were similar between 2009 and 2010 (Table 2, Figure 3A, B). In 2009, the percentage of A. gambiae was highest in Busia (89.7%) and Malaba (91.2%), close to the border with Uganda, and lowest at sites to the southeast near Lake Victoria, namely Kisian (12.8%) and Asembo/Seme (11.8%). In 2010, the percentage of A. gambiae were similarly lowest at Kisian (9.5%) and Asembo/Seme (2.8%), but were highest in Bungoma (88.9%) rather than Busia (50.4%). Overall, the percentage of A. arabiensis in all samples was higher in 2010 compared to 2009.

Table 2 Species composition in combined samples of Anopheles gambiae s.l. from sites in western Kenya collected in 2009 and 2010.
Figure 3
figure 3

Proportion of A. gambiae s.s. and A. arabiensis at sites in western Kenya in 2009 (A) and 2010 (B); Proportion of kdr genotypes observed in A. gambiae s.s. at sites in western Kenya in 2009 (C) and 2010 (D).

A total of 1,532 A. gambiae were genotyped for the kdr L1014S allele from samples taken in 2009 and 2010 in Busia, Malaba, Bungoma, Kakamega, and Kisian (Table 1). The frequency of kdr L1014S homozygotes in A. gambiae was high at all sites, and did not differ by location for either year (P = 0.254) (Table 1, Figure 3C, D). Within locations, homozygote frequency only differed between collections for one site, Busia in 2009 (O.R. = 2.67, 95% CI = 1.51 - 4.73, P < 0.01, Table 1). When including this site in the analysis, all locations had kdr L1014S homozygote frequencies of 79% or greater; but when excluding the Busia sample from April of 2009, homozygote frequencies were all greater than 90%. There was no statistical difference in genotype frequencies between larval and adult samples (O.R. = 1.15, 95% CI = 0.73 - 1.84, P = 0.537). Estimates of Wright's inbreeding coefficient (FIS) for both the time-series and 2009/2010 sub-populations indicated that genotype frequencies out of Hardy-Weinberg equilibrium tended toward heterozygote deficiency (Table 1).

Sporozoite infection

Between 2003 and 2007, a total of 43 A. gambiae mosquitoes were found to be infected with P. falciparum by sporozoite ELISA. These were genotyped for kdr L1014S along with 129 control mosquitoes. Among the sporozoite positive mosquitoes, 11.6% were homozygous for the kdr L1014S allele. Among sporozoite negative mosquitoes, 5.4% were homozygous for the kdr L1014S allele (Table 3). However, these percentages were not significantly different (P = 0.177).

Table 3 kdr L1014S genotype frequencies of A. gambia e s.s. from 2003-2007 in association with sporozoite infection.

Bioassays

A total of 3,432 individual A. gambiae s.l. were tested in phenotypic assays in 2009, and 1,027 individuals in 2010. Samples varied in their phenotypic susceptibility to different insecticides in standardized WHO bioassays. Of the three compounds tested in 2009, mosquitoes (grouped only within species complex) were generally most susceptible to deltamethrin, least susceptible to DDT, and intermediate in susceptibility to permethrin (Table 4). However, in late 2009/2010, there was more variability in the response to different insecticides with resistance highest to deltamethrin in A. gambiae from Bungoma. In Busia, the highest degree of resistance was to permethrin. Susceptibility to malathion was nearly 100% in all populations. There were marked differences among species, with A. arabiensis being susceptible to all insecticides, and A. gambiae having reduced susceptibility to most insecticides.

Table 4 Percent mortality in WHO bioassays 24 hours after exposure to discriminating concentrations of insecticide.

Discussion

Three processes have marked the dynamics of the Anopheles gambiae species complex in western Kenya during the course of national scale-up of ITNs: (1) a decline in density of indoor resting mosquitoes [31, 43], (2) a shift from a predominance of A. gambiae to A. arabiensis in adult and larval stages [21], and (3) a decrease in longevity of adult females, but no change in host preference patterns [21]. These changes correlate with a sustained reduction in the malaria burden in the human population [30]. The rapid rise in the frequency of the kdr L1014S allele to near fixation in A. gambiae as reported here, could herald a reversal of these positive outcomes. The marked rise in frequency of the kdr L1014S allele over 13 years in Asembo and Seme suggests that A. gambiae has been undergoing strong selection for resistance to the pyrethroid insecticides used in ITNs distributed there. Allele frequencies ranged from 2.5% to 3.8% in A. gambiae in western Kenya in 1987 [27]. The kdr allele frequency we report from Asembo for 1996 (5.3%, n = 95) is nearly identical to that of Stump et al[27] for the same year. Therefore, when ITNs were distributed in Asembo for the intervention trial in 1996, alleles for kdr-mediated resistance were already present in the A. gambiae population. Although direct comparisons with other populations are confounded by many factors, the rise in the L1014S allele observed in western Kenya was nearly as rapid as that observed for the L1014F allele in Ghana [16].

The rise in the mutation's frequency followed similar trajectories in Asembo and Seme despite substantial differences in net coverage between the areas for a decade (Figure 2). Net ownership rose modestly in Seme from 2000 to 2003 and then substantially increased with subsidized distribution of ITNs to pregnant women and children <5 years of age from government health facilities beginning in 2004, followed by a mass campaign in 2006 [21, 33]. The similar patterns of emergence of resistance likely reflect details of migration and selection pressure not measured in our study. While A. gambiae came into ever increasing contact with pyrethroids in Asembo over the past 13 years, selection pressures outside of Asembo due to either malaria control or agricultural pesticide use are unknown.

Other studies have also reported increases in frequency of the kdr L1014S allele in A. gambiae from Burundi [44] and Uganda [45] associated with vector control using pyrethroid insecticides; while studies in Niger [46] and Equatorial Guinea [47] have observed sharp rises in the kdr L1014F allele in response to ITNs and IRS, respectively. In Burundi and Rwanda, the rise in the kdr L1014S allele was ascribed to use of insecticides as indoor residual sprays to control adult stages of malaria vectors. However, in Burundi, the allele frequency actually increased in an unsprayed control area as well as in the sprayed area. In Uganda, there were marked regional variations in allele frequency without clear correlation with intensity of use of IRS or ITNs, and allele frequency and phenotypic resistance were noted particularly in areas with a history of cotton agriculture where insecticide use is often intense [45].

In other settings, agricultural use of insecticides has been cited as the primary cause of the emergence of insecticide resistance in A. gambiae s.l. populations in sub-Saharan Africa [48–50]. Anopheles gambiae s.l. larvae may face strong selection pressure for resistance to insecticides if exposed in breeding sites located near cultivated fields where insecticides are applied to control agricultural pests. In a cotton-growing region of northern Cameroon, investigators sampled mosquito larvae from breeding sites within cotton fields at different times during the rainy season [51]. Bioassays of emerged adults revealed that vector susceptibility to DDT and permethrin decreased over time in accordance with a spraying schedule in the cotton fields that included two applications of an organochlorine compound (endosulfan) followed by a pyrethroid/organophosphate mixture (cypermethrin/profenofos). In Burkina Faso, the spatial heterogeneity of kdr L1014F was associated with cotton agriculture; the mutation was present at 16 of 21 sites and ranged in frequency from 4.7% to 97.0% with the highest frequencies occurring in the so-called "cotton belt" [52]. Although data are lacking, current agricultural use of pesticides in western Kenya is likely low owing to the prevalence of subsistence agriculture. However, use of permethrin for cattle dips is common, and the region produces some cash crops (sugar cane and cotton) that may require insecticide use. In addition, the low level of resistance to bendiocarb implies that agricultural use of insecticides may play a role in the evolution of resistance in malaria vectors in western Kenya. However, the strong temporal association reported here between net ownership and kdr L1014S frequency (Figure 2) suggests that ITNs have been the most important selection pressure in this study population.

Given the trends in net ownership and kdr L1014S frequency in Seme, it is not surprising that similarly high homozygote frequencies were found in samples of A. gambiae throughout western Kenya in 2009 and 2010. One unexpected finding is the apparently greater magnitude of phenotypic resistance near the Ugandan border, as well as the dramatic differences in species composition near Lake Victoria compared to sites further north. Due to the decline in A. gambiae along the lakeshore, inadequate numbers of this species were available for testing in phenotypic assays. It is, therefore, possible that phenotypic resistance in A. gambiae along the lakeshore is similar to that of sites further away and the few mosquitoes that were tested (<5 per insecticide) suggest that this is the case. Therefore, the question is why A. gambiae remains the predominant species in sites located further from the lakeshore. The current hypothesis is that ITNs have not been in place sufficiently long in Busia, Malaba, Bungoma, and Kakamega to drive down local abundance of A. gambiae. Qualitative comparisons of the ratio of A. arabiensis to A. gambiae amongst all these sites suggests that the former species is rising in frequency in the sites away from the lake shore as it has at sites near the lake [21]. Indeed, the presence of A. arabiensis at Bungoma and Kakamega, both sites at relatively high altitudes where A. gambiae has traditionally been the only species in the complex present, is particularly striking [53]. However, because historical data on net ownership in these areas are lacking, baseline levels prior to the national scale-up of ITN are unknown. In Asembo and Seme, the change from sub-populations dominated by A. gambiae to those dominated by A. arabiensis took about a decade and occurred in Asembo first, as would be expected if ITNs were the primary cause [21]. This hypothesis is one that could be tested by monitoring both ITN coverage and species composition over the next several years in the region.

One trend that was consistent throughout all populations examined was the high degree of susceptibility of A. arabiensis to all insecticides but moderate to high resistance to pyrethroids in A. gambiae. The persistence of a species with little to no pyrethroid resistance (A. arabiensis) compared to a species with moderate to high levels of pyrethroid resistance (A. gambiae) in an area with high ITN coverage is somewhat counterintuitive. However, it is likely explained by the behaviour of A. arabiensis which often feeds outdoors and on cattle and may avoid the insecticide on nets. Anopheles arabiensis populations are therefore able to persist, apparently with little to no selection from the pyrethroid insecticides on nets [21]. Anopheles gambiae populations, despite having some resistance to pyrethroid insecticides, are still in decline possibly due to irritancy of the insecticide on the nets or the physical barrier imposed by the nets. These observations also suggest there is a limit to the degree of resistance conferred by the molecular and biochemical mechanisms currently present in western Kenya. Similar observations were made in the early 1990s during a small scale study of permethrin-treated nets where resistance was detected within a year of implementation [24], but reached a plateau and even regressed after three years [25]. However, other resistance mechanisms, possibly coupled with secondary compensatory mutations, may lead to further increases in pyrethroid resistance which could lead to a resurgence of A. gambiae. Despite the rapid decline in A. gambiae along the lakeshore, malaria transmission-presumably maintained by A. arabiensis--remains high with parasite prevalence in children over 45% (M. Hamel, unpublished data). As ITNs and IRS are increasingly scaled up throughout Africa, behavioural avoidance of these interventions may become increasingly important and tools to address species or populations exhibiting these traits are urgently needed.

Although pyrethroid resistance has been reported locally or regionally in many parts of sub-Saharan Africa, the impact of resistance on vector control is not always consistent between locations. In West Africa, for example, ITNs treated with the pyrethroid lambdacyhalothrin remained effective in reducing malaria prevalence in the face of kdr L1014F resistance in Cote d'Ivoire [54]. In contrast, the failure of IRS using pyrethroids in Bioko Island was associated with a high frequency of the kdr L1014F allele [47], while in Benin, N'Guessan et al[55] reported significantly reduced effectiveness of both ITNs and IRS in a region where kdr 1014F frequency was 83%. Data from western Kenya suggest that the rise of the kdr allele has had limited impact on the effectiveness of ITNs at least at sites along the lakeshore. Annual malaria surveys in Asembo indicated a decline in the prevalence of malaria until 2008. However, prevalence rose in 2009 and remained high in 2010 (M. Hamel, unpublished data). While the rise in malaria coincided with the period when the kdr allele was peaking in A. gambiae, entomologic data suggest that increasing pyrethroid resistance in this species is not the reason for increasing malaria in Asembo. The shift from a population dominated by A. gambiae to A. arabiensis along with the analysis of sporozoite rates by kdr genotype indicates that the rise of the kdr L1014S allele has not compromised the efficacy of ITNs along the Lake Victoria basin. On the other hand, the persistence of A. gambiae in sites further from the lakeshore where detectable levels of phenotypic resistance were observed is more worrisome. Nevertheless, the decline in A. gambiae relative to A. arabiensis from 2009 to 2010 in these sites where A. arabiensis has traditionally been rare or absent suggests that the hypothesis that these areas are more recent recipients of ITNs is correct and further increases in ITN coverage may continue to suppress A. gambiae populations to the levels observed along the lakeshore. However, the possibility that further increases in insecticide resistance, possibly attributable to changes in metabolic enzymes associated with pyrethroid resistance, are spreading east cannot be discounted. Continued surveillance of these populations is needed to monitor for additional changes in insecticide resistance and to assess its impact on the effectiveness of ITNs.

Conclusions

While the continuing effectiveness of ITNs against A. gambiae populations along the Lake Victoria basin is encouraging, the dramatic rise of the kdr L1014S allele and the detection of phenotypic resistance to pyrethroid insecticides in this region is alarming. Control failure due to insecticide resistance can arise rapidly, as has been observed in IRS programs in South Africa [56] and Equatorial Guinea [47]. However, it is possible that low levels of insecticide resistance existed undetected in these areas and only became apparent when IRS was no longer effective. Anopheles gambiae populations in western Kenya may be primed for further increases in pyrethroid resistance to a point where ITNs begin to lose their effectiveness. Monitoring is, therefore, imperative to quantify changes in insecticide resistance and to elucidate the specific resistance mechanisms operating in the populations, so that mitigation strategies can be implemented if and when pyrethroid resistance compromises the effectiveness of ITNs.

References

  1. Becker-Dreps SI, Biddle AK, Pettifor A, Musuamba G, Imbie DN, Meshnick S, Behets F: Cost-effectiveness of adding bed net distribution for malaria prevention to antenatal services in Kinshasa, Democratic Republic of the Congo. Am J Trop Med Hyg. 2009, 81: 496-502.

    PubMed  Google Scholar 

  2. Mueller DH, Wiseman V, Bakusa D, Morgah K, Dare A, Tchamdja P: Cost-effectiveness analysis of insecticide-treated net distribution as part of the Togo integrated child health campaign. Malar J. 2008, 7: 73-

    Article  PubMed Central  PubMed  Google Scholar 

  3. Yukich JO, Zerom M, Ghebremeskel T, Tediosi F, Lengeler C: Costs and cost-effectiveness of vector control in Eritrea using insecticide-treated bed nets. Malar J. 2009, 8: 51-

    Article  PubMed Central  PubMed  Google Scholar 

  4. Lengeler C: Insecticide-treated bednets and curtains for preventing malaria. Cochrane Database Syst Rev. 2004, 2004: CD000363-

    Google Scholar 

  5. W.H.O.: World Malaria Report, 2010. 2010, Geneva, Switzerland

    Google Scholar 

  6. Feachem RG, Phillips AA: Malaria: 2 years in the fast lane. Lancet. 2009, 373: 1409-1411.

    Article  PubMed  Google Scholar 

  7. Greenwood BM: Control to elimination: Implications for malaria research. Trends Parasitol. 2008, 24: 449-454.

    Article  PubMed  Google Scholar 

  8. W.H.O.: Pesticides and their application for the control of vectors and pests of public health importance. Department of Control of Neglected Tropical Diseases, WHO Pesticide Evaluation Scheme. Edited by: 6. 2006, Geneva, Switzerland: World Health Organization

    Google Scholar 

  9. Hemingway J, Hawkes NJ, McCarroll L, Ranson H: The molecular basis of insecticide resistance in mosquitoes. Insect Biochem Mol Biol. 2004, 34: 653-665.

    Article  CAS  PubMed  Google Scholar 

  10. Li X, Schuler MA, Berenbaum MR: Molecular mechanisms of metabolic resistance to synthetic and natural xenobiotics. Annu Rev Entomol. 2007, 52: 231-253.

    Article  PubMed  Google Scholar 

  11. Soderlund DM, Knipple DC: The molecular biology of knockdown resistance to pyrethroid insecticides. Insect Biochem Mol Biol. 2003, 33: 563-577.

    Article  CAS  PubMed  Google Scholar 

  12. Martinez-Torres D, Chandre F, Williamson MS, Darriet F, Berge JB, Devonshire AL: Molecular characterization of pyrethroid knockdown resistance (kdr) in the major malaria vector Anopheles gambiae s.s. Insect Mol Biol. 1998, 7: 179-184.

    Article  CAS  PubMed  Google Scholar 

  13. Ranson H, Jensen B, Vulule JM, Wang X, Hemingway J, Collins FH: Identification of a point mutation in the voltage-gated sodium channel gene of Kenyan Anopheles gambiae associated with resistance to DDT and pyrethroids. Insect Mol Biol. 2000, 9: 491-497.

    Article  CAS  PubMed  Google Scholar 

  14. Pinto J, Lynd A, Vicente JL, Santolamazza F, Randle NP, Gentile G, Moreno M, Simard F, Charlwood JD, do Rosário VE, Caccone A, Della Torre A, Donnelly MJ: Multiple origins of knockdown resistance mutations in the afrotropical mosquito vector Anopheles gambiae. PLoS One. 2007, 2: e1243-

    Article  PubMed Central  PubMed  Google Scholar 

  15. Santolamazza F, Calzetta M, Etang J, Barrese E, Dia I, Caccone A, Donnelly MJ, Petrarca V, Simard F, Pinto J, della Torre A: Distribution of knock-down resistance mutations in Anopheles gambiae molecular forms in west and west-central Africa. Malar J. 2008, 7: 74-

    Article  PubMed Central  PubMed  Google Scholar 

  16. Lynd A, Weetman D, Barbosa S, Egyir-Yawson A, Mitchell S, Pinto J, Hastings I, Donnelly MJ: Field, genetic and modeling approaches show strong positive selection acting upon an insecticide resistance mutation in Anopheles gambiae s.s. Mol Biol Evol. 2010, 27: 1117-1125.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  17. Busvine JR: Experiments concerned with the development of World Health Organization test for resistance in adult mosquitoes. Indian J Malariol. 1958, 12: 279-286.

    CAS  PubMed  Google Scholar 

  18. Lockwood JA, Sparks TC, Story RN: Evolution of insect resistance to insecticides: A reevaluation of the roles of physiology and behavior. Bull Entomol Soc Am. 1984, 30: 41-51.

    Google Scholar 

  19. Roberts DR, Andre RG: Insecticide resistant issues in vectors. Am J Trop Med Hyg. 1994, 50 (Suppl): 21-34.

    CAS  PubMed  Google Scholar 

  20. Siegert PY, Walker ED, Miller JR: Differential behavioral responses of Anopheles gambiae (Diptera: Culicidae) modulate mortality caused by pyrethroid-treated bed nets. J Econ Entomol. 2009, 102: 2061-2071.

    Article  CAS  PubMed  Google Scholar 

  21. Bayoh MN, Mathias DK, Odiere MR, Mutuku FM, Kamau L, Gimnig JE, Vulule JM, Hawley WA, Hamel MJ, Walker ED:Anopheles gambiae: historical population decline associated with regional distribution of insecticide-treated bed nets in western Nyanza Province, Kenya. Malar J. 2010, 9: 62-

    Article  PubMed Central  PubMed  Google Scholar 

  22. Beach RF, Ruebush TK, Sexton JD, Hightower A, Roberts J: Evaluation of permethrin-impregnated bed-nets and curtains during seasonal periods of intense malaria transmission in western Kenya. Am J Trop Med Hyg. 1993, 49: 230-300.

    Google Scholar 

  23. Phillips-Howard PA, ter Kuile FO, Nahlen BL, Alaii JA, Gimnig JE, Kolczak MS, Terlouw DJ, Kariuki SK, Shi YP, Kachur SP, Hightower AW, Vulule JM, Hawley WA: The efficacy of permethrin-treated bednets on child mortality and morbidity in western Kenya. II: Study design and methods. Am J Trop Med Hyg. 2003, 68: 10-15.

    PubMed  Google Scholar 

  24. Vulule JM, Beach RF, Atieli FK, Roberts JM, Mount DL, Mwangi RW: Reduced susceptibility of Anopheles gambiae to permethrin associated with the use of permethrin-impregnated bednets and curtains in Kenya. Med Vet Entomol. 1994, 8: 71-75.

    Article  CAS  PubMed  Google Scholar 

  25. Vulule JM, Beach RF, Atieli FK, Mount DL, Roberts JM, Mwangi RW: Long-term use of permethrin impregnated nets does not increase Anopheles gambiae permethrin tolerance. Med Vet Entomol. 1996, 10: 71-79.

    Article  CAS  PubMed  Google Scholar 

  26. Vulule JM, Beach RF, Atieli FK, McAllister JC, Brogdon WG, Roberts JM, Mwangi RW, Hawley WA: Elevated oxidase and esterase levels associated with permethrin tolerance in Anopheles gambiae from Kenyan villages using permethrin-impregnated nets. Med Vet Entomol. 1999, 13: 239-244.

    Article  CAS  PubMed  Google Scholar 

  27. Stump AD, Atieli FK, Vulule JM, Besansky NJ: Dynamics of the pyrethroid knockdown resistance allele in Western Kenya populations of Anopheles gambiae in response to insecticide-treated bed net trial. Am J Trop Med Hyg. 2004, 70: 591-596.

    CAS  PubMed  Google Scholar 

  28. Chen H, Githeko AK, Githure JI, Mutunga J, Zhou G, Yan G: Monooxygenase levels and knockdown resistance (kdr) allele frequencies in Anopheles gambiae and Anopheles arabiensis in Kenya. J Med Entomol. 2008, 45: 242-250.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  29. Kamau L, Agai D, Matoke D, Wachira L, Gikandi G, Vulule JM: Status of insecticide susceptibility in Anopheles gambiae sensu lato and Anopheles funestus mosquitoes from western Kenya. J Insect Sci. 2008, 8: 11-

    Article  PubMed Central  PubMed  Google Scholar 

  30. Lindblade KA, Eisele TP, Gimnig JE, Alaii JA, Odhiambo F, ter Kuile FO, Hawley WA, Wannemuehler KA, Phillips-Howard PA, Rosen DH, Nahlen BL, Terlouw DJ, Adazu K, Vulule JM, Slutsker L: Sustainability of reductions in malaria transmission and infant mortality in western Kenya with use of insecticide-treated bednets: 4 to 6 years of follow-up. JAMA. 2004, 291: 2571-2580.

    Article  CAS  PubMed  Google Scholar 

  31. Lindblade KA, Gimnig JE, Kamau L, Hawley WA, Odhiambo F, Olang G, ter Kuile FO, Vulule JM, Slutsker L: Impact of sustained use of insecticide-treated bednets on malaria vector species distribution and culicine mosquitoes. J Med Entomol. 2006, 43: 428-432.

    Article  CAS  PubMed  Google Scholar 

  32. Yates A, N'Guessan R, Kaur H, Akogbéto M, Rowland M: Evaluation of KO-Tab 1-2-3: a wash-resistant 'dip-it-yourself' insecticide formulation for long-lasting treatment of mosquito nets. Malar J. 2005, 4: 52-

    Article  PubMed Central  PubMed  Google Scholar 

  33. Hightower A, Kiptui R, Manya A, Wolkon A, Vanden Eng JL, Hamel M, Noor A, Sharif SK, Buluma R, Vulule J, Laserson K, Slutsker L, Akhwale W: Bed net ownership in Kenya: the impact of 3.4 million free bed nets. Malar J. 2010, 9: 183-

    Article  PubMed Central  PubMed  Google Scholar 

  34. Hightower AW, Ombok M, Otieno R, Odhiambo R, Oloo AJ, Lal AA, Nahlen BL, Hawley WA: A geographic information system applied to a malaria field study in western Kenya. Am J Trop Med Hyg. 1998, 58: 266-272.

    CAS  PubMed  Google Scholar 

  35. Collins FH, Mendez MA, Rasmussen MO, Mehaffey PC, Besansky NJ, Finnerty V: A ribosomal RNA gene probe differentiates member species of the Anopheles gambiae complex. Am J Trop Med Hyg. 1987, 37: 37-41.

    CAS  PubMed  Google Scholar 

  36. Scott JA, Brogdon WG, Collins FH: Identification of single specimens of the Anopheles gambiae complex by the polymerase chain-reaction. Am J Trop Med Hyg. 1993, 49: 520-529.

    CAS  PubMed  Google Scholar 

  37. Bass C, Nikou D, Donnelly MJ, Williamson MS, Ranson H, Ball A, Vontas J, Field LM: Detection of knockdown resistance (kdr) mutations in Anopheles gambiae: A comparison of two new high-throughput assays with existing methods. Malar J. 2007, 6: 111-

    Article  PubMed Central  PubMed  Google Scholar 

  38. Wirtz RA, Zavala F, Charoenvit Y, Campbell GH, Burkot TR, Schneider I, Esser KM, Beaudoin RL, Andre RG: Comparative testing of monoclonal antibodies against Plasmodium falciparum sporozoites for ELISA development. Bull WHO. 1987, 65: 39-45.

    PubMed Central  CAS  PubMed  Google Scholar 

  39. W.H.O.: Test procedures for insecticide resistance monitoring in malaria vectors: bio-efficacy and persistence of insecticides on treated surfaces. 1998, Geneva, Switzerland: World Health Organization

    Google Scholar 

  40. Lehmann T, Besansky NJ, Hawley WA, Fahey TG, Kamau L, Collins FH: Microgeographic structure of Anopheles gambiae in western Kenya based on mtDNA and microsatellite loci. Mol Ecol. 1997, 6: 243-253.

    Article  CAS  PubMed  Google Scholar 

  41. Raymond M, Rousset F: Genepop (version-1.2) - Population-genetics software for exact tests and ecumenicism. J Hered. 1995, 86: 248-249.

    Google Scholar 

  42. Weir BS, Cockerham CC: Estimating F-statistics for the analysis of population structure. Evolution. 1984, 38: 1358-1370.

    Article  Google Scholar 

  43. Gimnig JE, Vulule JM, Lo TQ, Kamau L, Kolczak MS, Phillips-Howard PA, Mathenge EM, ter Kuile FO, Nahlen BL, Hightower AW, Hawley WA: Impact of permethrin-treated bednets on entomological indices in an area of intense year-round malaria transmission. Am J Trop Med Hyg. 2003, 68 (suppl): 16-22.

    PubMed  Google Scholar 

  44. Protopopoff N, Verhaeghen K, Van Bortel W, Roelants P, Marcotty T, Baza D, D'Alessandro U, Coosemans M: A significant increase in kdr in Anopheles gambiae is associated with an intensive vector control intervention in Burundi highlands. Trop Med Int Health. 2008, 13: 1479-1487.

    Article  PubMed  Google Scholar 

  45. Verhaeghen K, Van Bortel W, Roelants P, Okello PE, Talisuna A, Coosemans M: Spatio-temporal patterns in kdr frequency in permethrin and DDT resistant Anopheles gambiae s.s. from Uganda. Am J Trop Med Hyg. 2010, 82: 566-573.

    Article  PubMed Central  PubMed  Google Scholar 

  46. Czeher C, Labbo R, Arzika I, Duchemin J: Evidence of increasing leu-phe knockdown resistance mutation in Anopheles gambiae from Niger following a nationwide long-lasting insecticide-treated nets implementation. Malar J. 2008, 7: 189-

    Article  PubMed Central  PubMed  Google Scholar 

  47. Sharp BL, Ridl FC, Govender D, Kuklinski J, Kleinschmidt I: Malaria vector control by indoor residual insecticide spraying on the tropical island of Bioko, Equatorial Guinea. Malar J. 2007, 6: 52-

    Article  PubMed Central  PubMed  Google Scholar 

  48. Diabate A, Baldet T, Chandre F, Akogbeto M, Guiguemde TR, Darriet F, Brengues C, Guillet P, Hemingway J, Small GJ, Hougard JM: The role of agricultural use of insecticides in resistance to pyrethroids in Anopheles gambiae s.l. in Burkina Faso. Am J Trop Med Hyg. 67: 617-622. 200

  49. Lines JD: Do agricultural insecticides select for insecticide resistance in mosquitoes? A look at the evidence. Parasitol Today. 1988, 4: S17-S20.

    Article  CAS  PubMed  Google Scholar 

  50. Müller P, Chouaïbou M, Pignatelli P, Etang J, Walker ED, Donnelly MJ, Simard F, H R: Pyrethroid tolerance is associated with elevated expression of antioxidants and agricultural practice in Anopheles arabiensis sampled from an area of cotton fields in Northern Cameroon. Mol Ecol. 2008, 17: 1145-1155.

    Article  PubMed  Google Scholar 

  51. Chouaibou M, Etang J, Brevault T, Nwane P, Hinzoumbe CK, Mimpfoundi R, Simard F: Dynamics of insecticide resistance in the malaria vector Anopheles gambiae s.l. from an area of extensive cotton cultivation in northern Cameroon. Trop Med Int Health. 2008, 13: 476-486.

    Article  CAS  PubMed  Google Scholar 

  52. Dabire KR, Diabate A, Namountougou M, Toe KH, Ouari A, Kengne P, Bass C, Baldet T: Distribution of pyrethroid and DDT resistance and the L1014F kdr mutation in Anopheles gambiae s.l. from Burkina Faso (west Africa). Trans R Soc Trop Med Hyg. 2009, 103: 1113-1120.

    Article  CAS  PubMed  Google Scholar 

  53. Shililu JI, Maier WA, Seitz HM, Orago AS: Seasonal density, sporozoite rates and entomological inoculation rates of Anopheles gambiae and Anopheles funestus in a high-altitude sugarcane growing zone in Western Kenya. Trop Med Int Health. 1998, 3: 706-710.

    Article  CAS  PubMed  Google Scholar 

  54. Henry MC, Assi SB, Rogier C, Dossou-Yovo J, Chandre F, Guillet P, Carnevale P: Protective efficacy of lambda-cyhalothrin treated nets in Anopheles gambiae pyrethroid resistance areas of Cote d'Ivoire. Am J Trop Med Hyg. 2005, 73: 859-864.

    CAS  PubMed  Google Scholar 

  55. N'Guessan R, Corbel V, Akogbéto M, Rowland M: Reduced efficacy of insecticide-treated nets and indoor residual spraying for malaria control in pyrethroid resistance area, Benin. Emerging Infect Dis. 2007, 13: 199-206.

    Article  PubMed Central  PubMed  Google Scholar 

  56. Hargreaves K, Koekemoer LL, Brooke BD, Hunt RH, Mthembu J, Coetzee M:Anopheles funestus resistant to pyrethroid insecticides in South Africa. Med Vet Entomol. 2000, 14: 181-189.

    Article  CAS  PubMed  Google Scholar 

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Acknowledgements

We gratefully acknowledge the field and laboratory work of Samson Otieno, Ben Oloo, Richard Owera, Richard Nyawalo, Laban Adero, Walter Nyawade, George Masula, Richard Amito, Gideon Nyansikera and Joseph Nduati. We also would like to thank Doug Norris for comments on an earlier version of the manuscript. This study was supported by grants from the Bill and Melinda Gates Foundation and the National Science Foundation (NSF grant EF-072377). Field work was also supported with funding from the US President's Malaria Initiative. DKM was partially supported by a postdoctoral fellowship from the American Society for Microbiology. The findings and conclusions in this manuscript are those of the authors and do not necessarily represent the views of the Centers for Disease Control and Prevention. This paper is published with the permission of the director of the Kenya Medical Research Institute.

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DKM, MNB, JMV, MJH, WAH, EDW and JEG designed the study and wrote the manuscript. DKM, EO, DM, LK performed species identification and RT-PCR analysis of A. gambiae kdr genotypes. EO, FA, MO and GO conducted and analysed the phenotypic bioassay data. DKM, EO, EDW and JEG analysed the data. All authors read and approved the final manuscript.

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Mathias, D.K., Ochomo, E., Atieli, F. et al. Spatial and temporal variation in the kdr allele L1014S in Anopheles gambiae s.s. and phenotypic variability in susceptibility to insecticides in Western Kenya. Malar J 10, 10 (2011). https://doi.org/10.1186/1475-2875-10-10

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