Review of the Biology of Anopheles squamosus, an Understudied Malaria Vector in Africa

Valerie T Nguyen; Dalia Dryden; Brooke A Broder; Ayaan Tadimarri; Primrose Tanachaiwiwat; Derrick K Mathias; Panpim Thongsripong; Lawrence E. Reeves; Reneé L.M.N. Ali; Mary E. Gebhardt; Kochelani Saili; Limonty Simubali; Edgar Simulundu; Douglas E. Norris; Yoosook Lee

doi:10.20944/preprints202412.0903.v1

Submitted:

09 December 2024

Posted:

10 December 2024

You are already at the latest version

Abstract

With ongoing global efforts to eliminate malaria, many countries have entered a pre-elimination stage, in which populations of the primary mosquito vector are reduced and the rates of malaria transmission are low. Efforts to eliminate malaria have changed the dynamics of disease trans-mission, causing a shift in anopheline community composition in some regions. One of the most abundant species of Anopheles found in pre-elimination areas, such as southern Africa, is Anopheles squamosus. Though An. squamosus has been documented across the African continent, limited in-formation is available about their biology. The aim of this review is to compile the information available for An. squamosus biology, ecology, distribution, behavior, and potential role in disease transmission. The review of current literature suggested that An. squamosus is abundant throughout the African continent. Studies indicate that this species occupies the same range and exhibits similar behaviors to primary malaria vectors in southern and eastern African countries like Zambia. Anopheles squamosus continues to be an understudied species that has circumvented disease control measures. Further studies are needed to develop resources to accurately identify this species from morphologically cryptic, closely related species and to effectively assess its role in malaria parasite transmission.

Keywords:

Zambia

;

Anopheles

;

distribution

;

host association

;

vector

;

malaria

Subject:

Biology and Life Sciences - Insect Science

1. Introduction

According to the World Health Organization (WHO), there were approximately 249 million malaria cases in the 85 countries where the disease is endemic and an estimated 608,000 deaths in 2022 [1]. The WHO has supported efforts to reduce the global burden of malaria by developing a framework for working toward elimination. The current Global technical strategy for malaria 2016–2030 (GTS) target is reducing malaria incidence and mortality rates by 90% and eliminating malaria in at least 35 countries by 2030 [2]. Between 2011 and 2021, there was an annual average reduction of malaria incidence of 25.4% [3]. However, this decrease was heterogeneous both within and across countries, and there was a 5% global increase in malaria incidence rates between 2019 and 2020, likely due in part to disruptions during the COVID-19 pandemic [4].

With global efforts to reduce the burden of malaria, several African countries reached the pre-elimination stages of malaria transmission [5,6,7,8]. The pre-elimination status is defined by a population with either a rapid diagnostic test (RDT) positivity rate below 5% annually or a parasite positivity rate lower than 5% among those with a fever [9]. The decrease in global malaria cases has been largely attributed in part to vector control that utilizes tools such as insecticide-treated bed nets (ITN) and indoor residual spraying (IRS), which target indoor-foraging (endophagic) and indoor-resting (endophilic) mosquitoes [10,11]. As a result of the implementation of these control methods, many of the principal vector species of malaria, such as Anopheles gambiae sensu lato (s.l.), have been declining in abundance in some countries [12,13,14].

Identification of the knowledge gaps must be done to adequately assess vector-borne pathogens across the African continent. There is a need for improved infrastructure, an understanding of the ecology of vector species and the environmental conditions that impact them, to assess their role in disease transmission [15,16,17]. For example, in Zambia, the need for vector ecology studies could be alleviated by improving the understanding of human-vector contact frequency, which is pivotal to assessing disease transmission in vector-borne systems and planning mitigation measures [15]. To adequately assess trends in vector-borne diseases in Africa, there must be an effort to increase the capacity for research on vector-borne zoonotic diseases by enhancing the interdisciplinary focus of research and building stronger communications between countries [18].

Despite these achievements and the identification of areas for improvement, the final elimination of malaria from many of these locations (e.g., southern Zambia, northeastern South Africa, Botswana, and Namibia) is now proving to be frustratingly difficult, and such locations remain static in the pre-elimination stage. Tenacious residual malaria infections persist in these pre-elimination zones despite access to rapid diagnostics and treatment, comprehensive IRS campaigns, and the widespread distribution of ITNs [9]. Despite the prolonged extirpation or decline of major vector species, persistent residual malaria has prompted many involved in malaria control to suspect that understudied secondary vector species contribute to the remaining malaria transmission in pre-elimination zones [19,20]. These residual malaria cases highlight that existing vector control tools that have focused on the major vector species alone are not sufficient to eliminate malaria from some regions [21].

Species often considered secondary vectors have been implicated in malaria transmission in pre-elimination zones and are often understudied. Examples include An. vaneedeni and An. parensis (members of the An. funestus group) in southern Africa and An. coustani and An. ziemanni in central Africa [22,23,24,25]. An expanding body of work has implicated An. squamosus, An. rufipes, and An. coustani in malaria transmission in Zambia, especially in pre-elimination settings [12,20,26,27,28]. Anopheles collections in Zambia revealed morphological misidentification and underrepresentation of many anopheline species in sequence databases, which confounds efforts to confirm the identity of potential malaria vector species [29]. Therefore, continued development of methodologies that allow more accurate species identification of these understudied malaria vector populations is critical for understanding malaria transmission in the pre-elimination setting and elucidating the potential role of the understudied secondary vectors in residual malaria cases.

Studies of malaria transmission dynamics in pre-elimination settings are particularly relevant to discussions of gene drive and other novel vector control strategies. For example, the ITN, one of the most successful malaria control tools, was devised with the understanding that the primary malaria vector bite humans at night indoors while people are sleeping [30]. Other Anopheles species that bite humans outdoors could circumvent control measures like ITNs. Other regions in Africa will inevitably reach the malaria pre-elimination phase at some future time through the implementation of available and perhaps new control strategies. Understanding the behavior and ecology of understudied malaria vectors will be critical in advancing comprehensive malaria control strategies targeting multiple vector species that can lead to malaria elimination.

Anopheles squamosus is a secondary vector species of malaria that can be found across sub-Saharan Africa [31]. This species is currently understudied because the species is believed to forage outdoors (exophagic) and to be primarily associated with non-human animal hosts (zoophilic) [20]. These are based on limited studies and created a perception that it does not pose a threat to public health. However, studies have shown that An. squamosus will opportunistically feed on humans and can be present around human dwellings [17,20]. Moreover, this species has been found naturally infected with Plasmodium falciparum, a causative agent of human malaria, and is abundantly collected during mosquito surveys [26,32].

Another barrier to studying An. squamosus is the morphological identification and separation of this species from other difficult to distinguish African anophelines. Many other anophelines, like An. gambiae s.l., exist as complexes of morphologically similar species with members exhibiting variable vector capability [26,33], insecticide resistance [34], and host association [35,36]. Therefore, the ability to distinguish exact species within an anopheline group is critical for assessing malaria risk associated and planning effective interventions targeted to the particular species of concern. As adults, An. squamosus is morphologically identical to An. cydippis [37], and there are at least five chromosomal forms based on chromosome that may correspond to cryptic species under the name An. squamosus [58]. Unless genetic methods are used to distinguish these taxa, any study of these species is based on an uncertain amalgamation of these cryptic species.

Creating further challenges to study this and other understudied malaria vectors is the diversity and morphological similarity among Afrotropical anophelines [58]. Distinguishing African anophelines from one another often requires specimens with morphological characters intact, which can challenging because of the methods and logistics of field collections [26,33,34,35,36].

Existing knowledge of An. squamosus is scattered across multiple articles published over decades, some of which are not digitized or available online, which posed a challenge to accessing and compiling what is known about this species. As of September 2024, only 53 results are found when searching "Anopheles squamosus" in PubMed. The objective of this review is to present a summary of the literature recovered on the identification, distribution, ecology and biology of this species. In addition, it aims to shed light on the knowledge gaps regarding An. squamosus as an understudied malaria vector and to inspire future research on this and other understudied Anopheles species in Africa.

2. Materials and Methods

We conducted literature searches for An. squamosus using online search engines including PubMed, Science Direct, Google Scholar, and the National Center for Biotechnology Information (NCBI) nucleotide database. Terms that were searched ranged from broad terms, such as “Anopheles,” to specific terms such as “Anopheles squamosus.” In each search engine, the following search terms were used: “Anopheles,” “Anopheles squamosus,” “Anopheles squamosus AND Plasmodium falciparum,” along with other variations to find instances of where An. squamosus was mentioned. We investigated the literature and extracted all available records of An. squamosus and other Anopheles spp. found together with An. squamosus in an Excel spreadsheet (See Supplementary Material Table S1). Additional species occurrence records were also retrieved from the Africa Vector Database [38]. For categorizing each country to subregions in a continent, we used the geographic regional groups according to UN M49 Standard country and area codes for statistical use [39]. For example, UN M49 Standard classifies Africa into 4 subgroups, namely Eastern, Middle, Southern, and Western Africa.

The distribution map of An. squamosus was created using QGIS software version 3.30.2 [40]. The basemap of African continent topography in the public domain was obtained from Natural Earth Tiles [41].

Representative images of An. squamosus morphology were created using adult female specimens collected along the outer perimeter of a goat pen using mouth aspirations at the Hanatanga Village in the Ngolwe zone of southern Zambia (16° 12' 26.766" S; 27° 0' 1.554" E) in January 2024. Collected An. squamous were frozen at 0 °C overnight and mounted to a glass microscope slide within 24 hours. The mounted mosquito was photographed with a Canon 5D SR digital SLR camera using a focus-stacking system that consisted of a 5x or 10x Mitutoyo infinity-corrected microscope objective attached to a Canon 200mm L prime lens. The camera and lens were mounted onto an automated StackShot rail (Cognisys Inc., Traverse City, MI). The camera was moved so that the mosquito specimen was just out of focus, then the camera was moved in steps of either 7µm (5x) or 15µm (10x), with one photograph taken between each step, until the mosquito was out of focus in the opposite direction. The raw images were stacked (i.e., the in-focus areas of each image were digitally merged to create one image with the entire specimen in focus) using Helicon Focus (v 8.2.13) program and then edited to clean the background using Adobe Photoshop (v 25.5.1).

3. Results

3.1. Anopheles Squamosus Identification

In 1901, Theobald described An. squamosus as "a very pronounced scaly species, not like any other Anopheles I have ever seen" [31]. As an adult, An. squamosus can be identified by several key features from other Anopheles, except for An. cydippis, as described in several morphological identification keys [42,43,44]. The first distinguishing feature is the presence of laterally projecting tufts of abdominal scales (Figure 1B). Anopheles squamosus is described by Evans [42] as being predominantly black with contrasting pure white scales, females having shaggy palpi with four narrow bands that are white, black, or bronzy-brown dorsal scales, and their last dorsal segment having numerous white scales (Figure 1A).

A study to assess the accuracy of identifying anopheline species found that only 37% of adult An. squamosus were identified correctly by morphology [24]. Distinguishing this species must be done in their 4th instar larval stage or through molecular tools. However, utilizing larval keys to differentiate An. squamosus from An. cydippis is challenging.

Currently, An, squamosus makes up only 0.6% of the literature on anopheline species when searching PubMed, Science Direct, and Google Scholar. In addition, there is a major lack of genomic resources for this species within NCBI, with only 210 genetic sequences as of September 2024. Furthermore, no cytochrome C oxidase subunit I (COI) sequences of An. cydippis are available, and the internal transcribed spacer 2 (ITS2) assay used by many researchers to distinguish cryptic anopheline species does not reliably amplify An. squamosus/An. cydippis DNA [32].

3.2. Anopheles Squamosus Distribution

In 1901 The current literature describing the distribution of these species varies throughout historical documentation. Theobald [31] describes this species as being native to the Middle African region in 1907. Evans [42] states that the distribution of An. squamosus is broad, covering Western, Eastern, and Southern Africa in 1927. Similarly, De Meillon [45] describes its distribution as widespread and practically across the whole continent in 1951. The literature review from this study suggested that An. squamosus is widespread across the African continent, consistent with the findings of De Meillon [45]. This species has been documented in 41 African countries across entomological surveys since 1898, as described in the Africa Vector Database and by other anopheline distribution descriptions (Table 1) [38]. The Africa Vector Database contains an inventory of anopheline species in Africa between 1898 and 2016 created by Kenyan Medical Research Institute and Wellcome Trust collaborators to document anopheline species occurrence. The data compiled from this database in addition to literature published after 2016, identified 1,331 unique geographic coordinate points where An. squamosus presence has been reported [12,17,26,27,28,38,46,47,48,49,50,51,52,53,54,55] (Figure 2).

The first documented capture of this species occurred in 1898 in Sierra Leone (Western Africa). Two years later, it was documented in eastern Africa, 5,765 km away. By 1904, An. squamosus has been documented in Africa's Eastern, Middle, Southern, and Western regions. Identifying this species at distance points over a short period indicates that this species was widespread throughout Africa before 1898. The known distribution of An. squamosus based on these data reaches its northern limit at Adrar, Mauritania (20.511°N, -13.049°E) [38] and extends as far south as Northern Cape, South Africa (-30.452°S, 21.228°E) [33]. Its most eastern occurrence has been documented in the Sava region of Madagascar (-15.2428°S, 50.4434°W) [38] and the furthest western report was from Thies, Senegal (14.801°N, -16.926°E) [38].

Kuznetsov [56] described the only detection of An. squamosus outside of the African continent in the country of Yemen. This observation occurred in 1965 during larval sampling in the coastal plain of Tihama in quick-drying pools that are not ideal for the complete lifecycle of anopheline species. A total of 380 larvae were documented in this survey, with one larva being identified as An. squamosus. Since this documentation, there has not been another published occurrence of An. squamosus outside of Africa. It remains to be determined if this species is reproductively established in Yemen and other western Asian countries.

Anopheles squamosus can be found in abundance throughout much of the known distribution. Anopheline surveillance was informative at providing a snapshot of the community composition of potential vectors inhabiting a given location. Across 25 studies in nine countries (Ethiopia, Kenya, Madagascar, Malawi, Mozambique, Rwanda, Senegal, South Africa, and Zambia) primarily in eastern and southern Africa, An. squamosus comprised as low as 0.1% and as high as 68.0% of adult anopheline trap captures (Figure 3, Table 2) [17,20,23,24,27,32,33,35,36,46,48,49,51,52,57,58,59,60,61,62,63,64,65,66]. These studies consisted of both indoor and outdoor surveys using various methods of collection (human-baited traps, animal-baited traps, CDC light traps).

The widespread distribution of An. squamosus is similar to that of the primary malaria vectors in Africa, such as those in the An. gambiae and An. funestus groups [38]. Based on the data in the African Vectors Database, An. squamosus was captured most often alongside species in the An. gambiae complex, An. coustani, and An. funestus complex [38]. The occurrence of An. squamosus in regions where other vectors actively transmit malaria suggests that this vector has potential exposure to circulating parasites and may sustain malaria transmission when primary vectors are reduced or eliminated.

3.2.1. Larval Biology of Anopheles squamosus

Identification of larval habitats for An. squamosus is essential, as they can be morphologically distinguished from An. cydippis in this life stage [32]. In addition, control of malaria vectors in the larval stage can be more effective in certain settings due to their inability to escape the habitats [54,69,70]. Since indoor targeted malaria control for adult anophelines is ineffective against exophagic vectors, targeting these species' larval stages could be an effective alternative control strategy.

Anopheles squamosus larvae were recorded in naturally occurring (ponds, rivers, and lagoons) and human-created (rice fields, irrigation drains, and tire tracks) bodies of water [65]. They were often associated with six other African anopheline species in these larval habitats (An. gambiae s.l., An. funestus s.l., An. coustani, An. cinereus, An. demeilloni, and An. pharoensis) [48,71]. In swamps of Ethiopia, they have been found to coexist in high numbers with An. pharoensis [59]. The highest contributing factors for the presence of An. squamosus larvae are high vegetation and algae [59]. There is also a positive correlation of An. squamosus with shallow depths of water [48]. In Ethiopia, Kenea et al. [59] found that An. squamosus larvae were located further away from human dwellings. In contrast, Adugna et al. [48] reported a positive correlation of An. squamosus larval habitats being closer to human dwellings. The studies on larval habitats and species associations were spatio-temporally sparse and only completed in eastern Africa. Therefore, the reported findings and any conclusions drawn from them are extremely limited.

There is very little known on the microbial tolerance of An. squamosus. Anopheles squamosus larvae have been observed to be more tolerant than An. gambiae complex when exposed to fungal biocontrol agents such as Coelomomyces [71]. Coelomomyces fungus can infect mosquito larvae and prevent pupation while other organisms remain unaffected [72]. Muspratt found that Coelomomyces fungus was highly effective for controlling An. gambiae larvae (>95% mortality) [71]. However, when An. squamosus was exposed to the same Coelomomyces fungus, there was a very low percentage (8% infection rate) of larvae infected with the biocontrol agent [71]. This suggests that An. squamosus may behave differently from principal malaria vector species when exposed to such biological control agents, and studies of immune response based on the well-studied principal malaria vectors may not translate to other anopheline species. There are no other studies testing additional microbial larvicides on An. squamosus reported as of September 2024.

3.2.2. Adult Anopheles squamosus Behavior

Understanding vector behavior is critical for disease control, as these vector behaviors can be interrupted to effectively reduce pathogen transmission [73,74]. Approximately 30 to 40 of the 430 described Anopheles species are currently known to be vectors of human pathogens [75]. A key behavioral trait that primary human malaria vectors exhibit is the propensity to feed on people indoors at night [73,76]. Targeting this behavior using ITN and IRS campaigns has drastically reduced malaria cases in many areas [23,30]. However, this has caused changes in the behaviors of primary vectors in some countries and shifts in the anopheline community composition in others [12,77,78,79].

Knowledge on the behavior of adult An. squamosus is scarce and can be attributed to the lack of research focused on this species. This species is commonly associated with livestock and considered zoophilic, which has made it less of a concern for human health initiatives [20]. In low transmission areas of Mozambique, An. squamosus will predominantly exhibit exophagic behavior [23], and they were reported foraging in the early evening in one study in Zambia [20].

Despite the notion that An. squamosus adults express exophagic behavior, this species has been recorded in indoor settings. In high transmission areas in Mozambique, up to 68.4% of An. squamosus were captured host-seeking indoors, predominantly in the evening before human occupants went to bed and while they were in bed [23]. The close proximity of An. squamosus to humans can increase instances of malaria transmission due to their potential ability to vector human Plasmodium parasites [80]. This species has been captured using CDC light traps, human landing catches (HLC), human-baited traps, and livestock-baited traps. Seven trapping studies were identified during our literature review that collected An. squamous or An. cydippis indoors. Across these studies, up to 41% of trap captures consisted of species identified as An. squamosus [23,27,32,47,48,57,58] with an average of 14.7% of indoor trap captures identified as An. squamosus.

Historically, this species has been considered zoophilic [31], as Anopheles squamosus has demonstrated a preference for feeding on non-human hosts if they are present [20]. However, there is evidence that feeding behavior for An. squamosus varies depending on its location. Across several studies, there were observed differences in HLC in different countries, which may be attributed to the availability of alternate hosts [17,24,47,58,66]. The recorded host species for An. squamosus include sheep, cow, pigeon, chicken, goat, dog, pig, and human [20,26,27,33,48,49]. From five host association studies between 2011 and 2022, where 670 specimens were collected, the host most often found for An. squamosus was cow (n=250), followed by goat (n=158), non-human (n=65), pig (n=60), cow and goat (50), cow and human (n=40), human (n=26), cow and pig (n=12), dog (n=5), human and animal (n=3), and chicken (n=1) (Table 3) [20,26,27,48,49]. From these studies, a total of 10.3% of the blood meals contained human blood, indicating that this species readily feeds on humans across habitats. In Macha, Zambia, An. squamosus had a higher rate of reported anthropophily when compared to Cameroon, Kenya, and Senegal based on indoor CDC light trap collections [20].

3.3. Anopheles squamosus Contribution to Pathogen Transmission

Anopheles squamosus has been implicated as a potential pathogen vector in Zambia, Madagascar, Mozambique, Namibia, Mali, Kenya, and Tanzania (Table 4) [20,23,38,60,61,65,81,82]. Though it is considered a secondary vector species of certain human diseases, such as malaria, secondary vector species may become primary vectors under certain conditions [83]. Distinguishing features of a primary malaria vector include their relative abundance, a high propensity to feed on humans, and sporozoite rate [84]. Most of the published studies on An. squamosus is focused on Zambia and Madagascar. Despite being identified across sub-Saharan Africa, pathogen transmission is unique to a location, as environmental and socio-economic factors impact transmission, which can vary from country to country [85].

Anopheles squamosus has been found infected with human Plasmodium sporozoites in Kenya, Mali, Mozambique, Madagascar, Tanzania, and Zambia [23,26,27,38,78]. Reported infection rates are variable due to sample size, however, these reports verify that An. squamosus feeds on humans frequently enough to be infected with infectious human-only parasites. The first detection of Plasmodium sporozoites in An. squamosus was in Tanzania in 1964, where a single mosquito was infected with the parasite [87]. In a study in Mozambique, An. squamosus had the highest Plasmodium sporozoite infection rate of 5.8%, more than An. parensis, An. arabiensis, and An. funestus [23]. In a trapping study in Zambia, all three captured An. squamosus samples were found to be infected with P. falciparum [27]. In Madagascar, two distinct strains of P. vivax, another causative agent of human malaria, were identified in An. squamosus [49].

Rift Valley fever virus (RVFV) is a virus that causes a mosquito-borne viral zoonosis affecting humans and livestock. RVFV can cause severe disease in animals, while severe symptoms in humans are rare [90,91]. Aedes mosquitoes are recognized as the primary vector for RVFV, however, Anopheles and Culex mosquitoes are considered secondary vectors [90]. Some anopheline species can maintain RVFV and transmit it to their offspring [60] and in Madagascar, RVFV was detected in five pools of An. squamosus, suggesting this species could be a host of RVFV [60].

Bluetongue disease, caused by bluetongue virus (BTV), is transmitted predominantly by Culicoides biting midges among ruminant animals. It causes a wide array of symptoms for ruminant animals but distinctly causes severe swelling of the tongue [92]. A survey of mosquitoes in Madagascar identified a pool of An. squamosus that tested positive for BTV [89]. Though it does not indicate that this species is a competent vector of BTV it demonstrates that these mosquitoes can acquire the virus from infected animals. Further research will be needed to determine any role for An. squamosus in maintenance and transmission of BTV.

4. Discussion

Anopheles squamosus has been documented in 43 of the 54 currently recognized African countries, with many studies reporting a robust number of this species. These collection records indicate that this species was likely widespread and well-established long before their first documentation in the early 1900s. The broad distribution of An. squamosus is similar to other primary malaria vectors in Africa, such as An. gambiae, An. arabiensis, and An. funestus, suggesting that An. squamosus has a reasonable chance of coming into contact with human hosts and infectious parasites. In Zambia, this species exhibited a high human blood index, even in the presence of livestock [20]. In addition, they have been found infected with human Plasmodium sporozoites [28,88]. These combinations of factors suggest that An. squamosus may play a more significant role in malaria transmission than previously recognized.

Anopheles squamosus poses a challenge for malaria transmission [19,87,93]. due to its exophilic nature, which allows them to evade indoor-based malaria intervention methods such as ITN and IRS. As a result, humans are more likely to encounter An. squamosus and other secondary vector species in outdoor settings when outdoor-based interventions are not put in place [30,77]. For example, in Mozambique, there was an increase in outdoor An. squamosus population numbers [23] after an increase in IRS campaigns. This suggests a potential behavioral adaptation or shift in mosquito community populations in response to indoor malaria control. Therefore, targeted control of primary endophagic vectors through ITN and IRS has the potential to shift vector status in favor of exophagic vectors like An. squamosus [94]. This highlights the need for comprehensive control approaches that address both indoor and outdoor transmission risks.

The public health significance of An. squamosus cannot be understated, as it has also been identified as a potential vector of RVFV, and BTV due to zoophilic behavior. For An. squamosus, records indicate a high vector abundance, a propensity to feed on humans, and positive Plasmodium sporozoite rates, thus indicating that this species is a competent vector for malaria.

Despite its significant role in malaria transmission, there is a lack of reliable molecular identification tools such as internal transcribed spacer (ITS) polymerase chain reaction (PCR) for An. squamosus. The current molecular identification of An. squamosus based on Sanger sequencing of Cytochrome Oxidase I is not ideal for routine surveillance. Since An. squamosus is morphologically identical to An. cydippis in their adult life stages, distinguishing between these cryptic species becomes challenging without robust molecular species identification tools [95]. This represents the key barrier to gaining further understanding of the biology and behavior of this species. Therefore, there is a pressing research need for building more genomic resources to improve our understanding of and enhance surveillance for An. squamosus.

Past studies that identify An. squamosus on morphology alone may not be accurate [29]. In our effort to create a reliable distribution map, we attempted to separate records verified only by morphological examination from records confirmed by both morphological and molecular methods. However, the lack of detailed metadate for many of the records and publications prevented accurate categorization. This further emphasizes the need for cost-effective tools that will help enhance species identification, allowing further investigations to inform the role of An. squamosus in pathogen transmission and development of disease mitigation strategies.

5. Conclusion

Anopheles squamosus is a widespread mosquito species found abundantly across the African continent. Despite implication in malaria transmission and potentially vectoring other diseases impacting human and animal health, research and information on this species remains scarce. Historically, An. squamosus was regarded as an exophagic and zoophilic species and as a result, they were not viewed as a threat to public health. However, our review indicates that this species occupies the same range and exhibits similar behaviors to primary malaria vectors, as they have been implicated on feeding on humans in indoor settings and found to be infected with human Plasmodium parasites. Anopheles squamosus continues to be a cryptic species that has circumvented disease control measures. Addressing these challenges requires further research to gain more information on their biology and behavior, ultimately enabling development of comprehensive vector control strategy that will lead to malaria elimination.

Supplementary Materials

The following supporting information can be downloaded at the website of this paper posted on Preprints.org. Table S1: Records of Anopheles squamosus occurrences.

Author Contributions

Conceptualization, V.T.N. and Y.L.; investigation, V.T.N., D.D.S., B.B.A., T.A., T.P., M.E.G, D.E.N., K.S., L.S., E.S., L.E.R., and Y.L.; data curation, V.T.N., D.D.S., B.B.A., T.A., and T.P.; formal analysis, V.T.N.; resources, E.S., D.E.N., and Y.L.; validation, D.K.M., P.T., L.E.R., A.R., M.E.G., K.S., E.S., R.A., D.E.N., and Y.L.; writing—original draft preparation, V.T.N. and Y.L..; writing—review and editing, V.T.N., D.K.M., P.T., L.E.R., R.A., M.E.G., K.S., E.S., D.E.N., and Y.L.; visualization, V.T.N..; supervision, D.K.M, P.T., and Y.L.; project administration, Y.L.; funding acquisition, V.T.N. and Y.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research was supported by grants from the United States National Institute of Health as part of the International Centers of Excellence for Malaria Research (2U19AI089680), Small Grant Program (R03AI178041), and T32 Institutional Training Grant (T32AI0074717). Additional support was provided by the United States Department of Agriculture National Institute of Food and Agriculture multistate Hatch project (1025565), the Bloomberg Philanthropies, the Johns Hopkins Malaria Research Institute, the College of Agricultural and Life Sciences Dean’s Award at the University of Florida, and Global Fellows Program at the University of Florida International Center.

Data Availability Statement

No new data were created in this study. The original contributions presented in this study are included in the article/supplementary material. Further inquiries can be directed to the corresponding author(s).

Acknowledgments

We thank Dr. Phillimon Ndubani, as well as his incredible staff members at the Macha Research Trust for facilitating our mosquito collection to obtain high quality images of our study species. We thank Dr. Ana L. Romero-Weaver at the University of Florida for reviewing our manuscript. We thank Dr. Liliana Cano and Dr. Bianca Burini at the University of Florida for serving as faculty advisors on our committee.

Conflicts of Interest

The authors declare no conflicts of interest. The funders did not have a specific role in the conceptualization, design, data collection, analysis, decision to publish, or preparation of the manuscript. The findings and conclusions in this article are those of the author(s) and do not necessarily represent the views of the funding agencies.

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Figure 1. Stacked focus image of An. squamosus taken by Dr. Lawrence Reeves and processed by Valerie T. Nguyen. (a) Lateral view of a blood-fed, (b) Abdomen tufts, and (c) wing of An. squamosus female.

Figure 2. Anopheles squamosus distribution across Africa and West Asia. Highlighted countries are documented presence of An. squamosus collected from WRBU and Kyalo et al. [38] and countries where Plasmodium spp. has been identified in the species. The points on the map indicate coordinate data where An. squamosus has been captured.

Figure 3. Proportion of An. squamosus captured across 25 anopheline trapping studies conducted between 1980 and 2022. The basemap of African continent topography is obtained from Natural Earth Tiles [41].

Table 1. Geographic region, country and year of first documented occurrence of An. squamosus. The geographic regions are according to UN M49 Standard country and area codes for statistical use [39].

Geographic region	Country	First documented occurrence
Eastern Africa	Eritrea	1941
	Ethiopia	1920
	Burundi	1935
	Kenya	1900
	Madagascar	1902
	Malawi	2012
	Mozambique	1901
	Rwanda	1933
	Somalia	1951
	South Sudan	1903
	Tanzania	1902
	Uganda	1907
	Zambia	1941
	Zimbabwe	1901
Middle Africa	Angola	1904
	Cameroon	1907
	Central African Republic	1950
	Chad	1950
	Congo	1943
	Democratic Republic of the Congo	1902
Northern Africa	Sudan	1903
Southern Africa	Botswana	1961
	Eswatini	1974
	Namibia	1950
	South Africa	1905
Western Africa	Benin	1950
	Burkina Faso	1948
	Cote d'Ivoire	1950
	Gambia	1902
	Ghana	1911
	Guinea	1950
	Guinea Bissau	1946
	Liberia	1902
	Mali	1909
	Mauritania	1945
	Niger	1961
	Nigeria	1909
	Senegal	1908
	Sierra Leone	1898
	Togo	1902
Western Asia	Yemen	1965

Table 2. Mean percent of An. squamosus collected in anopheline trapping studies grouped by country. Geographic regions are according to UN M49 Standard country and area codes for statistical use [39].

Geographic region	Country	Mean % An. squamosus	% An. squamosus range	References
Eastern Africa	Ethiopia	7.0	0.34 – 27.2	[17,48,51,59]
	Kenya	38.8	0.26 – 68.0	[35,64,67]
	Madagascar	68.0	2.76 – 97.4	[49,58,60,63,65,68]
	Malawi	9.5		[52]
	Mozambique	8.7	2.3 – 32	[23]
	Rwanda	0.004		[66]
	Zambia	10.0	0.5 – 41.4	[45]
Southern Africa	South Africa	18.8	0.12 – 100	[33,46,62]
Western Africa	Senegal	0.1		[36]

Table 3. Identified bloodmeals across five studies between 2011 – 2022.

Identified Blood Meal	Sample size	Proportion (%)	References
Chicken	1	0.1	[49]
Human and Animal	3	0.5	[27]
Dog	5	0.8	[27]
Cow and Pig	12	1.8	[49]
Human	26	3.9	[27,49]
Cow and Human	40	6.0	[48,49]
Cow and Goat	50	7.5	[27]
Pig	60	9.0	[20,27]
Non-human	65	9.7	[27]
Goat	158	23.6	[20,27,32]
Cow	250	37.3	[20,27,32,48]
Total	670

Table 4. Diseases An. squamosus has been implicated as a potential vector of.

Disease/Pathogen	Detection Method	Country	References
Malaria	ELISA, Salivary gland dissection	Kenya, Madagascar, Mali, Mozambique, Namibia, Tanzania, Zambia	[23,27,38,86,87,88]
Rift Valley fever	PCR	Madagascar	[60]
Bluetongue	Indirect Immunofluorescence assay	Madagascar	[89]

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