Mitochondrial genome sequences reveal deep divergences among Anopheles punctulatus sibling species in Papua New Guinea

Anopheles mosquitoes are distributed worldwide, with the exception of Antarctica, and feed on a variety of hosts from birds to mammals ([1] and references therein). Within the Anopheles genus, 70 of over 500 species are able to transmit human malaria[2]. These include the well-known species Anopheles gambiae, Anopheles arabiensis and Anopheles funestus that are the main vectors of malaria in Africa, Anopheles darlingi and Anopheles albitarsis in South America, Anopheles dirus and Anopheles minimus in Southeast Asia (SEA) and Anopheles punctulatus in Southwest Pacific (SW Pacific).

Despite their medical importance, the current understanding of the Anopheles phylogeny – the relationship among species as well as the times they diverged from each other – remains limited. Studies of this nature are complicated in Anopheles by the existence of species complexes (including morphologically identical sibling species)[3‐6] and incipient species[7‐9], as well as by the paucity of genetic data for most species besides An. gambiae. The current hypothesis of Anopheles evolution, mostly based on the extant geographic distribution of Anopheles mosquitoes, proposes that Anopheles originated in western Gondwana during the Cretaceous. They subsequently migrated across the world aided by land connections and radiated into multiple species adapted to unique habitats and climatic conditions[10, 11]. However, the timing and routes of these dispersions are unknown and the relationships among current species remain poorly understood. Determining the evolutionary relationships among Anopheles species has important clinical and vector control implications as it could clarify whether traits required for transmission of human blood-borne pathogens, avoidance of long-lasting insecticide-treated nets or insecticide resistance evolved only once in an ancestral population or, alternatively, whether different species acquired these traits independently.

The focus of this study is on members of the Anopheles punctulatus (AP) group, the principal vectors of malaria in Papua New Guinea (PNG), the Solomon Islands, Vanuatu, and northern Australia[12, 13]. Historically, the AP group was separated into four species based on morphological differences in the proboscis and wings: An. punctulatus, Anopheles koliensis, Anopheles farauti, and Anopheles clowi[12]. Later studies involving cross-mating[14‐16], allozyme analyses[17] and DNA sequence analysis[18‐22] provided evidence suggesting further differentiation of the AP group into 13 species, most of them morphologically indistinguishable. At least five of these species - An. punctulatus s.s, An. koliensis, An. farauti s.s (previously An. farauti 1), Anopheles hinesorum (previously An. farauti 2), and An. farauti 4 - have been described as competent vectors of malaria[23, 24]. Phylogenetic studies of this group have focused on DNA sequences of ribosomal RNAs[25, 26], mitochondrial genes[27, 28], ribosomal ITS2[19], and voltage-gated sodium channel gene[29]. However, the genetic information generated in these studies has not allowed robust determination of the AP group phylogeny and has often yielded conflicting results[19, 27]. In addition, no study has yet evaluated the relationships between AP sibling species and other Anopheles species from neighbouring regions, such as species from SEA. As Beebe and Cooper have described this group of Anopheles sibling species as ‘unspecialized’, there is some reason to hypothesize that AP group members have evolved to acquire a broad range of feeding strategies to ensure survival[30].

Here, the evolutionary history of the AP group of PNG is investigated by sequencing the mitochondrial (mt) genome of 14 individual mosquitoes from the AP group and neighbouring An. dirus complex. Next generation sequencing technologies were used to generate mt genome sequences and de novo assemble each individual sequence. The concatenated sequence of all mitochondrial protein coding genes (10,770 bp) was used to reconstruct robust phylogenies and estimate divergence times among available Anopheles mt genomes. The implications of this study’s findings are discussed with regard to the evolutionary history of anophelines in general and the origin of the AP group.

The predominant hypothesis regarding the origin of Anopheles mosquitoes predicts that they originated in western Gondwana[10, 11] and that, by 95 mya, Anopheles had migrated into Africa. Ancestral Anopheles are predicted to have then colonized Europe and North America (via land bridges), and migrated through Asia into the SW Pacific. The topology of the tree in Figure 2 is globally consistent with this hypothesis. However, the position of North American mosquitoes (An. quadrimaculatus) relative to African and other non-American Anopheles remains unclear. In particular the lack of mt genomes from European Anopheles mt genomes preclude determining whether African Anopheles are ancestral to European and North-American Anopheles or, alternatively, whether North-American Anopheles derive directly from South-American Anopheles. Additional sampling of mt genomes would provide better resolution of Anopheles early dispersal routes.

Regarding SEA and the SW Pacific, it is generally believed that Anopheles from the SW Pacific derives from SEA mosquitoes[10, 26, 27]. The results of this study suggest that the AP group is most closely related to the An. dirus complex of SEA, consistent with an origin of the AP group in SEA. However, currently it cannot be determined whether SW Pacific and Australian Anopheles originate from an SEA ancestor as currently hypothesized or, alternatively, whether SW Pacific and SEA Anopheles have an Australian origin. The molecular dates in this study, suggest that the ancestor of the AP group was present in PNG between 25 and 54 mya but does not allow rejecting either of these scenarios. Plate tectonic models show that the Australia/PNG plate, that separated from Gondwana during the Cretaceous, moved from a southern position in the Eocene to its current position near SEA[54]. While the upper limit of the age of the AP ancestor (54 mya) corresponds to a time when the distance between PNG and SEA would not have allowed migration between these regions, the lower limit (~25 mya) corresponds to a time when the Australian plate had moved close enough to the Asian plate to enable possible migration of species between the two regions[55]. Inclusion of additional mt genome sequences, in particular from Anopheles complexes restricted to Australia (e.g., Anopheles annulipes) may allow better understanding of these early dispersal routes in SEA and SW Pacific.

The monophyly of AP mosquitoes (Figure 1) suggests that they colonized PNG through a single migration event followed by speciation (as opposed to multiple migrations of pre-established species). This study suggests that the different AP sibling species diverged from each other 25–54 mya, much earlier than proposed in previous studies of the AP group[26, 28]. This deep divergence among AP mosquitoes is unlikely to be caused by a single species that could have diverged from the other sibling species in SEA and colonized PNG later. In fact, most of the AP sibling species are equally divergent from each other, suggesting rapid radiations of AP sibling species upon arrival in the SW Pacific area. Since this analysis relies on a single non-recombining locus, it cannot rule out the possibility that the estimates are influenced by the action of natural selection. However, when only Anopheles mt genomes are analysed, there is little evidence for deviation from a clock-like model of evolution, which suggests that nucleotide substitutions occur at a similar rate on each lineage. Therefore, if natural selection is driving the evolution of the mt genome in Anopheles, it is likely to have acted in a similar manner on all lineages and consequently is unlikely to bias the molecular dates significantly. An additional possible complication is that the phylogenetic tree inferred from mt sequences differs from the actual species tree: since these analyses are based on a single locus, one cannot rule out that incomplete lineage sorting and introgression lead to a phylogenetic reconstruction that does not represent the true evolutionary pathways of the species studied[56, 57]. The long internal branches separating species coupled with the very short branches separating individuals from the same species indicate that incomplete sorting of ancestral polymorphisms is unlikely to affect this phylogeny[58]. Ruling out introgression is difficult without genetic data on multiple unlinked loci (i.e., nuclear), which are complicated to generate due to the lack of a good reference genome sequence (An. gambiae being too divergent), the high divergence among AP species at the nuclear level and the high level of genetic diversity within species. However, there is little evidence of gene flow among AP mosquitoes (but see also Ambrose[28]) and early forced mating studies suggested that most hybrids are non-viable or sterile[15]. Overall, these observations suggest that, for this dataset, the mt gene tree likely recapitulates the actual species tree.

Absolute dates estimated from molecular data should be consider cautiously, especially since these estimates rely on a single calibration point. Note however that the divergence estimates between An. quadrimaculatus and non-American Anopheles, as well as, between An. farauti s.s. and An. hinesorum, are similar to those of previous studies[11, 28, 37]. When the estimated mutation rate for insect mtDNA was used[52], the divergence dates obtained were significantly younger than those obtained using a calibration point [see Additional file5]. This mutation rate, while widely used (see e.g.[28]) was originally calculated using closely related species (the maximum divergence time used in the study was ~3 mya) and, Brower noted, probably overestimated the actual mutation rate. A slower mutation rate would push estimated divergence dates back in time, closer to the estimates obtained using calibration points. Note that even considering these younger divergence dates, the MRCA of AP mosquitoes would still considerably predate the arrival of humans in PNG (see below). Irrespective of the absolute dates, it is interesting to note that the AP group is significantly older than the only other Anopheles group for which several mt genome sequences are available, the An. albitarsis complex (Figure 3). Indeed, the MRCA of the AP group is estimated to be approximately four times older (25–54 mya) than the An. albitarsis complex MRCA (6–24 mya) and almost half as old as the MRCA of all Anopheles mosquitoes. Based on these findings, it can be speculated that after arriving in PNG 25 to 54 mya, the ancestors of AP group became isolated on different islands as sea levels fluctuated and their distribution only overlapped later, when the sea level decreased to merge different islands into current-day PNG.

Given the old divergence times among most AP sibling species, one would expect that most AP species today are reproductively isolated and that hybridization is unlikely to occur in nature, with the possible exception of An. farauti s.s and An. hinesorum that only diverged 5 to 17 mya (see also[28]). This potential reproductive isolation among AP sibling species is supported by early cross-mating experiments suggesting that F1 hybrids between any combination of An. farauti s.s, An. hinesorum, An. koliensis and An. punctulatus s.s are non-viable or sterile in laboratory[15]. These results have important implications for vector control in the SW Pacific. For example, control of malaria by releasing genetically modified-, sterile-, male mosquitoes as was recently proposed[59] would require, in PNG, independent engineering of mosquitoes from, at least, five highly divergent species to significantly impact the populations of the main malaria vectors. In addition, if AP sibling species are reproductively isolated from each other, insecticide resistance arising in one species is unlikely to spread quickly across all AP mosquitoes, but instead resistance mutations would have to occur independently in each species[29]. Further investigations are required to definitively rule out the existence of gene flow among most AP sibling species, as well as to confirm the observation of putative mt genome introgression between An. farauti s.s and An. hinesorum recently described in Southern New Guinea[28].

The ancient divergences among Anopheles species, including among AP from SW Pacific, also raises questions for the evolution of traits related to human malaria transmission. Transmission of plasmodium parasites to humans is facilitated by the anthropophilic behaviour of some Anopheles species. Such behaviour includes usage of human-made habitats as breeding sites and preferential feeding on human blood. Some Anopheles mosquitoes, including most populations of An. gambiae, are highly specialized feeders and rely preferentially on humans for their blood meal[60]. Others are considered more “opportunistic” or “generalist” and the source of their blood meal varies according to several factors including host density (for review see[61]). There are limited data on the feeding preference and behaviour of AP mosquitoes. Early studies of AP mosquitoes seem to indicate a relatively unspecialized feeding behaviour[62, 63].

On the other hand, recent studies by Cooper and colleagues have shown that at least two populations of An. hinesorum show strong feeding preferences and specifically avoid biting humans[22, 28]. Frequency of utilization of human-made habitats for breeding also varies among the AP sibling species[22]. The phylogenetic study described here suggests that the AP sibling species diverged from each other long before humans arrived in PNG, probably ~50,000 years ago[64]. In fact, the molecular dates place the divergence time of AP mosquitoes before the emergence of the Hominidae (or great ape) family[65, 66]. This indicates that any adaptations to humans (for blood meal or larval habitats) would have occurred independently in each AP sibling species, rather than being inherited from a common ancestor, and suggests that co-occurrences of malaria-related traits in Anopheles are the results of convergent evolution[67, 68].

The ancient divergence among AP sibling species, coupled with the recent arrival of humans in PNG, indicates that AP mosquitoes were present in PNG long before humans colonized the island. This observation suggests that the AP mosquitoes have independently evolved to adapt their behaviour to humans. While further studies are needed to better characterize the behaviour of AP mosquitoes, these findings emphasize the potential of the AP group to serve as a model for studying the evolution of vector competence and potentially for identifying the genetic basis of the ability to transmit human malaria.