Role of Anopheles (Cellia) rufipes (Gough, 1910) and other local anophelines in human malaria transmission in the northern savannah of Cameroon: a cross-sectional survey

Background As part of a study to determine the impact of insecticide resistance on the effectiveness of long-lasting insecticide treated nets (LLINs) in the north of Cameroon, the unexpectedly high density and anthropophilic behaviour of Anopheles rufipes lead us to investigate this species bionomics and role in human malaria parasite transmission. Methods For four consecutive years (2011–2014), annual cross-sectional sampling of adult mosquitoes was conducted during the peak malaria season (September-October) in three health districts in northern Cameroon. Mosquitoes sampled by human landing catch and pyrethrum spray catch methods were morphologically identified, their ovaries dissected for parity determination and Anopheles gambiae siblings were identified by molecular assay. Infection with P. falciparum and blood meal source in residual fauna of indoor resting anopheline mosquitoes were determined by enzyme-linked-immunosorbent assays. Results Anopheles gambiae (sensu lato) (s.l.) comprised 18.4% of mosquitoes collected with An. arabiensis representing 66.27% of the sibling species. The proportion of An. rufipes (2.7%) collected was high with a human-biting rate ranging between 0.441 and 11.083 bites/person/night (b/p/n) and an anthropophagic rate of 15.36%. Although overall the members of An. gambiae complex were responsible for most of the transmission with entomological inoculation rates (EIR) reaching 1.221 infective bites/person/night (ib/p/n), An. arabiensis and An. coluzzii were the most implicated. The roles of An. funestus, An. pharoensis and An. paludis were minor. Plasmodium falciparum circumsporozoite protein rate in Anopheles rufipes varied from 0.6 to 5.7% with EIR values between 0.010 and 0.481 ib/p/n. Conclusions The study highlights the epidemiological role of An. rufipes alongside the members of the An. gambiae complex, and several other sympatric species in human malaria transmission during the wet season in northern Cameroon. For the first time in Cameroon, An. rufipes has been shown to be an important local malaria vector, emphasising the need to review the malaria entomological profile across the country as pre-requisite to effective vector management strategies.


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Conclusions: The study highlights the epidemiological role of An. rufipes alongside the members of the An. gambiae complex, and several other sympatric species in human malaria transmission during the wet season in northern Cameroon. For the first time in Cameroon, An. rufipes has been shown to be an important local malaria vector, emphasising the need to review the malaria entomological profile across the country as pre-requisite to effective vector management strategies.

Background
The discovery at the turn of the nineteenth century that malaria was transmitted by mosquitoes initiated an outburst of interest in the description and implication of various species in malaria transmission [1]. Human plasmodial species are transmitted by mosquitoes of the genus Anopheles, which includes 465 formally recognised species [2]. Amongst these, over 140 species have been identified in Africa [3,4], of which less than 20 have been shown to support the development and propagation of human Plasmodium species [5]. However, their relative contribution to malaria transmission greatly varies depending on their behaviour (host seeking, feeding and resting) and densities as influenced by environmental conditions. These differences in Anopheles behaviour and density, along with vector longevity, are key factors driving malaria transmission and epidemiological patterns observed across Africa [6,7]. Therefore, in areas with numerous potential vectors, an in-depth understanding of vectors dynamics is fundamental to designing interventions tailored to the local eco-epidemiological situation [8,9]. The malaria vectorial system in Cameroon is very complex. To date, over 50 Anopheles species have been described which are heterogeneously distributed across the eco-epidemiological zones of the country. Fifteen species have been demonstrated to support the development and spread of human Plasmodium spp.: An. gambiae Giles, 1902; An. funestus Giles, 1900; An. arabiensis Patton, 1905; An. nili (Theobald, 1904) and An. moucheti Evans, 1925 are classified as major vectors [10]. The other species amongst which are An. pharoensis and An. paludis play only a minor localised secondary role in transmission [11][12][13][14], and they may help to augment or extend the malaria transmission period [15,16]. For the first time we report the importance of An. rufipes (Gough, 1910), as vector of human Plasmodium in Cameroon. Although a few studies have attempted to associate An. rufipes with human malaria transmission [17,18], this species has generally been reported to be zoophilic [3,4] with high densities in ricegrowing areas [19,20]. Even though this species has often been collected landing on human volunteers in several studies in Cameroon [21][22][23], its role in malaria transmission has never been investigated.

Study site and design
For four consecutive years (2011-2014), annual crosssectional sampling of adult Anopheles mosquitoes was conducted in Northern Cameroon during the peak malaria season (September-October) in the health districts (HD) of Pitoa (9°23'0"N, 13°32'0"E), Garoua (9°18'0"N, 13°2 4' 0" E) and Oulo Mayo (9°7'34"N, 13°37'20"E) (Fig. 1). A total of 38 villages (12, 17 and 9 villages from each HD, respectively) were included in the assessment. Pitoa is a peri-urban area with about 108,611 inhabitants. The main economic activity is farming with major crops cultivated being rice, cotton, millet, sorghum and maize. On the other hand, Garoua is an urban area with a population of around 316,957 with rural suburbs that depend almost entirely on agriculture for subsistence. Mayo Oulo is predominantly rural, highland area with around 91,501 inhabitants. Unlike in the suburbs of Garoua where typically corn, tomatoes and eggplant are grown, in Mayo Oulo major crops cultivated are maize, beans and peanuts. All three areas have a Sahelian-type climate with an annual average rainfall of 700-1,000 mm and annual average temperature of 26-33°C. Anopheles gambiae (s.l.) is the major malaria vector along with typical sahelian vectors including An. funestus and An. pharoensis, and Plasmodium falciparum is the most prevalent malaria parasite species [24,25].

Field sampling of adult mosquitoes
Mosquitoes were sampled using both the human landing catch (HLC) and pyrethrum spray collection (PSC) methods. Mosquito collections took place concurrently in all 38 villages within the three HDs. HLCs were performed for two consecutive nights from 18:00-06:00 h. Mosquitoes were collected indoors and outdoors in three randomly selected houses (at least 50 m apart) in each village each night with rotation between houses at different locations. A team of four trained volunteers per house (two working during the first half of the night and the others during the second half of the night) made the collection, with one sitting inside the house and the other on the veranda collected female mosquitoes as they landed on exposed lower limbs. The mosquitoes were sorted by genus and the anophelines identified morphologically using the morphological identification keys of Gillies & de Meillon [3] and Gillies & Coetzee [4]. The ovaries of a proportion of unfed mosquitoes were dissected for parity determination [26]. All dissected and those undissected mosquitoes were individually stored in tubes containing silica gel for subsequent laboratory analyses. PSCs for indoor resting mosquitoes were performed once in the morning (06:00-08:00 h) as described by Service et al. [27], and the mosquitoes were identified morphologically with their physiological status recorded. Specimens were individually stored desiccated in tubes for later laboratory analyses.

Laboratory analysis of Anopheles spp. mosquitoes
A portion of specimens from each collection method belonging to the Anopheles gambiae complex were further identified using molecular assays. DNA from the legs and wings of each individual specimen was extracted [28] and PCR amplification was conducted to determine species [29]. The head and thorax portion of each Anopheles female collected was separated from the rest of the body, homogenized in grinding buffer (0.5% Casein, 0.1 N NaOH, 1 × PBS) and examined for the presence of Plasmodium falciparum circumsporozoite protein (CSP) by enzyme-linked-immunosorbent assay (ELISA) [30,31]. This was to avoid cross reactivity with animal blood as reported previously [32]. To minimize false positive CSP ELISA, only high absorbance readings were considered (mean plus three standard deviations of negative controls). Blood-fed females resting indoors were screened for the source of blood meal by ELISA as described by Beier et al. [33] and modified by Lardeux et al. [34]. Monoclonal antibodies against human, cow, pig and sheep blood were used.

Data analysis
Man biting rate (ma) was calculated as the average number of bites from Anopheles species received per person per night of collection. Infection Rate (IR) was calculated as the proportion of Anopheles species tested positive for P. falciparum CSP by ELISA, while the Human Blood Index (HBI) represented the proportion of Anopheles species identified by ELISA to have fed on human blood. The Entomological Inoculation Rate (EIR) was determined as the product of the Infection Rate (IR) and the man biting rate (ma). Data were analysed using SPSS Statistics 17.0. A Chi-square test was used to determine variable significance and the threshold for statistical significance was set at P < 0.05.

Night biting rate and biting cycles
The human-biting rates varied by species and health district. While peak biting rates for An. gambiae (s.l.) were recorded in Garoua and Pitoa health districts, in Mayo Oulo An. rufipes had the highest biting rates in 2012 and 2013 at 11.083 b/p/n and 7.852 b/p/n respectively ( Table 2). The human-biting rate of An. funestus, An. pharoensis and An. paludis were higher in Pitoa HD compared to Garoua and Mayo Oulo HD. There was no preference to the place of bite for the main Anopheles species as they could bite indoor as well as outdoor (Fig. 3).
Comparative analysis of the biting trends by hour of the night between An. rufipes and the major vector An. gambiae (s.l.) showed great variation in the peak aggressivitiy between the health districts ( Fig. 4). While  (Table 3). With regard to the health district, although generally the highest parity rates were observed in Pitoa, the difference in parity rate between HDs and anopheline species was not significant (χ 2 = 6.62, df = 8, P = 0.58). However, there was a significant difference in An. gambiae (s.l.) parity rates between the health districts (χ 2 = 8.42, df = 2, P = 0.0145), which could directly impact on their relative contribution to transmission in the HDs.

Human blood index (HBI)
In total, the blood meal source of 472 (53.15%) out of the 888 blood-fed Anopheles species tested were confirmed. Of these, 21.62% were solely of human origin, 15.99% were from cow and 1.80% from pig. However, there were cases of mixed blood from varied sources such as cow and sheep (8.33%), human and pig (2.48%), and cow, pig and sheep (1.35%). Amongst the members of An. gambiae complex, Anopheles gambiae was observed to feed essentially on human blood, while An. arabiensis and An. coluzzii, alongside other species like An. funestus and An. rufipes fed both on humans and a wide range of domestic animals. About 47% of the source of blood meal from fed Anopheles species was not identified, probably due to the lack of monoclonal antibodies to test for blood meals from several other animal species commonly found in those

Infectivity and entomological inoculation rate (EIR)
Details of the EIR by vector species and health district are presented in Tables 4 and 5. Overall, the CSP rates varied from 0.8 to 9.1% (    Note: The difference in parity rate between health districts and anopheline species was not significant (χ 2 = 6.62, df = 8, P = 0.58) Abbreviation: CI confidence interval and Pitoa (χ 2 = 0.014, df = 3, P > 0.05). However, An. gambiae contributed to transmission mainly in 2011 in Mayo Oulo with an EIR of 0.019 ib/p/n and in 2013 in Garoua with an EIR of 0.01 ib/p/n (Table 5).

Discussion
The identification and incrimination of vectors in malaria transmission as well as their relative contribution to transmission is critical for the implementation of an efficient malaria control strategy. Some control programmes like the Garki project, failed because of the erroneous identification of the vectors involved in malaria transmission, and insecticide resistance in An. arabiensis in Nigeria [35,36]. To date, malariologists have paid little or no attention in most areas to An. rufipes as this species has generally exhibited high zoophilic tendencies. Elsewhere, the abundance of this species was found to peak particularly at the end of the rainy season  in rice-growing areas, with very short periods of malaria outbreak resulting [17][18][19][20]. Anopheles rufipes breed commonly in small collections of water such as residual puddles in river beds, hoof prints of cattle, swamps and rice irrigation schemes, with the larvae staying close to the borders and among vegetation. This is important as cattle rearing and rice cultivation and irrigation are common practices in the study sites, which usually experience floods with long retention of surface water during the wet season. As part of a study to determine the impact of insecticide resistance on the effectiveness of vector control tools like the LLIN in the north of Cameroon, the observed unexpectedly high density and anthropophilic behaviour of this species incited our curiosity to investigate its role in P. falciparum transmission. For the first time in Cameroon, An. rufipes has been identified as an important local vector of P. falciparum.
A few earlier studies have described this species as weakly anthropophilic [18] and potentially involved in malaria transmission [3,37,38]. More recently in Burkina Faso, Plasmodium was detected in An. rufipes oocyts, further implicating it as a potential vector of human malaria parasites [39]. Thus, An. rufipes may be a more important and wider spread vector than previously thought and therefore this is important for malaria elimination strategies.  In Cameroon, five major malaria vectors (An. gambiae, An. funestus, An. arabiensis, An. nili and An. moucheti) have been described [10] with nine secondary vectors of local importance (An. paludis, An. carnevalei, An. coustani, An. marshallii, An. ziemanni, An. pharoensis, An. hancocki, An. wellcomei and An. ovengensis). Anopheles rufipes is now added to this plethora of vectors, further complicating the malaria vectorial system in the country. In the past, the role of this species in malaria transmission was largely neglected due its strong zoophilic tendency which leads to claims of its lack of importance. Moreover, An. rufipes had high parous rate wherever it was collected, suggesting the propensity to survive longer and being able to maintain and even extend P. falciparum transmission beyond the normal duration.
The vast plethora of Anopheles species observed in this study could be linked to the diversity of existing biotopes that enhance the proliferation of such species within the health districts. Anopheles arabiensis, An. coluzzii and An. gambiae (s.s.) were the An. gambiae (s.l.) siblings found with An. arabiensis being the most frequently encountered species. The relative abundance of An. gambiae (s.s.) and An. arabiensis varied across the years and by health districts with twice as many An. arabiensis. This is unlike observations by Robert et al. [40] in southern Burkina where the density of An. gambiae (s.s.) was nine-fold greater than that of An. arabiensis among residual endophilic mosquitoes. This difference however, might be due to differences in the microenvironments and the methods of collection. Both species are typical malaria vectors of the sahelian zone [41], with their densities peaking especially during the rainy season. As observed with An. rufipes in this study, species like An. pharoensis, An. funestus and An. coustani have been shown to contribute significantly to malaria transmission [23]. For An. funestus, the density remained relatively constant irrespective of the season [42]. Akin to studies conducted in Burkina Faso, An. rufipes constituted a significant proportion of the anophelines collected in this study [39]. This however differs markedly with observations from the HLC collections in the coastal areas and northern regions of Cameroon [21,22] and Chad [43], where An. rufipes density was low. The vast number of prolific breeding sites (rice fields, river banks and pools) during the study periods may explain the high density of An. rufipes [19,20].
With regard to the biting rates of the anophelines, except in Mayo Oulo where the highest An. rufipes densities were recorded in 2012 and 2013, An. gambiae (s.l.) generally had the highest biting rates throughout the study ( Table 2). Analyses of the blood meal sources among the members of the An. gambiae complex revealed An. gambiae despite its low density compared to An. coluzzii and An. arabiensis, to be the most anthropophagic. Amongst the vectors for which the blood meal source was confirmed, they were observed to feed mainly on cow, which is the most widely domesticated animal in this part of the country. Anopheles rufipes was observed to feed on both humans and animals confirming the species opportunistic behaviour or may be simply due to the imposing environmental conditions. Livestock rearing is a common practice with animals like dog, chicken, horse, goat and donkey in addition to those analyzed. Unlike previous reports on An. funestus being the most anthropophagic Anopheles species [33,[44][45][46][47] its human blood index in this study was very low. This may be due to the presence of a variety of domestic animals that provide an alternative source for blood-feeding or due to the occurrence of other members of the An. funestus group of species. In fact, Anopheles funestus (s.l.) comprises at least nine species that are morphologically identical [3] [48]. Despite the fact that many authors reported a high infection rate of An. funestus during dry season [3,49], Antonio-Nkondjio et al. [22] observed a pronounced anthropohilic behaviour of An. funestus during the wet season while this species was exclusively zoophilic during the dry season. Other earlier studies [50,51] also reported besides An. funestus (s.s.) the presence of Anopheles leesoni Evans and Anopheles rivulorum-like in tributaries of the Benoue River in the northern region of Cameroon. Based on these observations and the current HBI results, there is the likelihood of the existence of some zoophilic members of An. funestus group in this area. Therefore, it would be important that subsequent studies in this area should consider the identification of the members of the An. funestus group of species and their contribution to human malaria transmission.
On a general note, in addition to the Anopheles species displaying endophagic and exophagic tendencies, the parity rates were observably high in all HDs. Thus, despite the high LLIN coverage in the study localities [52], the malaria vectors survive long enough to sustain malaria transmission locally.
The infection rates varied enormously between the health districts. Overall, seven Anopheles species (An. arabiensis, An. coluzzii, An. gambiae, An. funestus, An. pharoensis, An. rufipes and An. paludis) were found infected with P. falciparum. Even though the CSP rates were higher than those obtained elsewhere under similar eco-epidemiological conditions [22], measures were taken to minimize false positive CS ELISA in these areas with an extensive animal reservoir flow for blood-feeding. Thus, only high absorbance readings (mean plus three standard deviations of negative controls) were considered. Nevertheless, this CSP-ELISA may overestimate the infection rate and all positive samples need to be confirmed with PCR [53]. Relatively low malaria transmission intensity was observed throughout the years in all health districts. The observed EIR estimate of 0.014 to 1.221 infective bites/person/night was consistent with other records in the sahelian zone [25]. However, the transmission intensity during the study was pronounced in the irrigated rice paddies of Pitoa, which is not uncommon to other such irrigation schemes that generate a variety of entomological and epidemiological situations with permanent water bodies that are prolific for Anopheles breeding and consequently increasing the risk of malaria in surrounding population [54].

Conclusions
The study highlights the epidemiological role of An. rufipes alongside the members of the Anopheles gambiae complex, and several other sympatric species in human malaria transmission during the wet season in northern Cameroon. Thus, for the first time in Cameroon, the role of An. rufipes as an important local malaria vector has been made evident. The study also portrays the need to carry out further studies to document the implication of this species and other presumably non-malaria vectors in human malaria transmission in other parts and to review and update the malaria entomological profile in the country and the Afrotropical region.