Abstract
Human malaria, which remains a major public health problem, is transmitted by a subset of Anopheles mosquitoes belonging to only three out of eight subgenera: Anopheles, Cellia and Nyssorhynchus. Unlike almost every other insect species, males of some Anopheles species produce steroid hormones which are transferred to females during copulation to influence their reproduction. Steroids are consequently a potential target for malaria vector control. Here, we analysed the evolution of sexually-transferred steroids and their effects on female reproductive traits across Anopheles by using a set of 16 mosquito species (five Anopheles, eight Cellia, and three Nyssorhynchus), including malaria vector and non-vector species. We show that male steroid production and transfer are specific to the Cellia and therefore represent a synapomorphy of this subgenus. Furthermore, we show that mating-induced effects in females are variable across species and differences are not correlated with sexually-transferred steroids or with Anopheles ability to transmit human malaria. Overall, our findings highlight that Anopheles mosquitoes have evolved different reproductive strategies, independently of being a malaria vector or not.
Similar content being viewed by others
Introduction
Anopheles mosquitoes are mostly known for their ability to transmit malaria parasites to humans with more than 200 million cases reported and an estimated 445000 deaths in 20161. Among 475 species named in this genus, 41 have been classified as dominant vector species (DVS) of human malaria2,3,4,5. The Anopheles genus is further subdivided into eight subgenera of which three (Anopheles, Cellia, and Nyssorhynchus) contain all known DVS of human malaria4. The first essential condition to be a vector of human malaria is that the mosquito, after ingestion of infected blood, is permissive to the development of the parasite until the production of the infective sporozoites, a feature termed “vector competence”. The efficiency of malaria transmission by Anopheles mosquitoes in natural settings, named “vectorial capacity”, depends on vector competence but also on many other factors including the size of mosquito populations. Therefore mosquito reproduction and fecundity can affect malaria transmission by Anopheles.
Unlike vertebrates, it was considered that insect adult males do not produce significant amounts of steroid hormones until it was shown that males of Anopheles gambiae, the main vector of human malaria in Africa, produce and transfer high quantities of 20-hydroxyecdysone (20E) to females during copulation6. As ovarian steroids produced after blood feeding trigger egg development7,8, sexual transfer of steroids by males likely represents a nuptial gift that affects female reproduction in the malaria vector. Consistent with this, sexually-transferred steroids were shown to induce refractoriness to further copulation and to stimulate oviposition in An. gambiae females9. Interestingly, a further study examining 20E production by males in nine species and the effect of mating in three of them suggested that sexually-transferred steroids and associated mating-induced phenotypes (refractoriness to mating, increased egg development and oviposition) may have shaped the ability of DVS to transmit human malaria10. In the present work, we investigated the evolutionary history of male steroid production using a large set of mosquito species belonging to the three Anopheles subgenera (five Anopheles, eight Cellia, three Nyssorhynchus) that contain all known DVS of human malaria. We further analysed post-mating effects on female reproductive traits whether or not the cognate males produce steroids. Our results show that i) production of steroids in male mosquitoes is restricted to the Cellia subgenus, and ii) the effects of mating on female reproductive potential vary across species of the three Anopheles subgenera and this is not correlated with male steroid production. Overall our data highlight that Anopheles mosquitoes have evolved different reproductive strategies independently of sexually-transferred steroids and of their ability to transmit malaria.
Results
Male steroid production is specific to the Cellia subgenus
We measured steroid titers in sexually mature virgin males from 19 different mosquito species. These mosquito species were selected within two Culicidae subfamilies, Anophelinae and Culicinae. Within the Anophelinae subfamily, 16 species distributed all over the world were chosen to cover three different subgenera (i.e. Cellia, Nyssorhynchus and Anopheles) of the Anopheles genus (Fig. 1A). In the Culicinae subfamily, Aedes aegypti, Aedes albopictus and Culex pipiens that are vectors of arboviruses were also analysed. As shown on Fig. 1B (right panel), male 20E production occurs only within the Cellia subgenus (Anophelinae) and is absent in the Culicinae. Interestingly, Anopheles quadriannulatus whose males produce similar levels of steroids compared to Anopheles stephensi is not a malaria vector unlike An. stephensi and other Cellia species investigated in the present study. Indeed, its refractoriness or low susceptibility to the human malaria parasite has been experimentally determined11,12, confirming epidemiological data13. Conversely, production of 20E was not detected in male mosquitoes from the two other Anopheles subgenera, Anopheles and Nyssorhynchus of which all tested members are registered as DVS and/or experimentally shown to be highly susceptible to Plasmodium falciparum14,15.
To uncover the evolutionary history and divergence time of male steroid production in mosquitoes, we analysed the phylogenetic relationships of the selected species. To this end, we used DNA sequences of partial regions of the coding sequence of mitochondrial genes (COI, COII, ND5 and CYTB) and nuclear genes (g6pd and white as well as ribosomal subunits 18S and 28S) from the 19 mosquito species plus Chagasia bathana (Anophelinae subfamily, Chagasia genera) as outgroup for Anopheles mosquitoes16. Phylogenetic analysis of the data set was performed by Bayesian inference (Fig. 1B left panel) and by maximum likelihood (Supplementary Fig. 1). Phylogenetic relationships inferred from these analyses resulted in different topologies mainly at the subgenus level and with varying node support values. In both analyses, the members of each subgenus formed monophyletic groups and the branching orders within the subgenus Cellia was identical. Our results are in agreement with those obtained by Sallum et al.17 with the Cellia clade being the outgroup of the subgenera Anopheles and Nyssorhynchus in the Bayesian approach while in the maximum likelihood approach, Nyssorhynchus is the outgroup of Anopheles and Cellia, also in agreement with recently published phylogenies2,18,19. The Anopheles subgenus has also been found by others to be a basal lineage to Cellia and Nyssorhynchus20. Thus, relationships between the different subgenera Cellia, Nyssorhynchus and Anopheles, are still not entirely resolved. The difficulty in determining the relationships among these subgenera might be due to limits and bias in gene and taxon sampling, but also to the different methods used4,16. This could also be due to the fact that the radiation of Anopheles and Cellia species happened roughly at the same time18,20.
From the Bayesian phylogenetic analysis and using fossil data, we obtained species divergence time estimates, which largely conform to recent phylogenies18,20,21 (Supplementary Table 1). The age of the last common ancestor of Anopheles genus is about 84.1 Ma (112.7–55.8, 95% highest posterior density [HPD] interval) and the most ancestral node within the Cellia subgenus is dated to 69.2 Ma (93.0–45.6, 95% HPD interval) (Fig. 1B, Supplementary Table 1). As males from all Cellia species tested so far have the ability to produce 20E while males from all species belonging to the other subgenera do not, according to the “law of parsimony” steroid production by mosquito males probably originated once in the ancestral Cellia lineage, at about 84.1–69.2 Ma (112.7–45.6, 95% HPD interval), i.e. during the late Cretaceous. Thus, steroid production by mosquito males is most probably a shared derived character from the last common ancestor of Cellia mosquitoes and represents as such a synapomorphy of this subgenus. As 20E production in males is private to the Cellia subgenus, which in addition forms a monophyletic group in the two phylogenetic approaches, the conflicting distribution of the outgroup lineages (Anopheles and Nyssorhynchus) does not alter the conclusion that steroid production by males most probably originated after the split between Cellia and these two other subgenera.
An. stephensi males transfer steroid to females upon mating (Supplementary Fig. 2) as do An. gambiae males6 and males of other Cellia species such as Anopheles arabiensis and Anopheles dirus10. This strongly suggests that transfer of steroids to females during mating is part of the “male 20E production” synapomorphy of Cellia mosquitoes. Our geographical mapping of nearly all contemporary mosquito species belonging to the Cellia subgenus (224 species) against the ones of Anopheles subgenus (184 species) (Fig. 2) suggests that the common ancestor of the Cellia subgenus diverged after separation of South America and Africa in agreement with previous observations4,22. This biogeographic calibration is consistent with divergence times obtained from our phylogenetic analysis placing the origin of steroid production by males of the Cellia subgenus around 84.1–69.2 Ma (112.7–45.6, 95% HPD interval), i.e. after the separation of South America and Africa, which started at least 100 Ma ago with no land bridge for about 80 to 50 Ma23,24.
Mating-induced effects do not correlate with sexually-transferred steroids
In female mosquitoes, each ovary is composed of 50 to 500 units called ovarioles that develop synchronously. At the time of adult emergence, each ovariole consists of a germarium and one follicle, called the primary follicle (see Fig. 3A). In some species, a secondary follicle is also present. Formation and detachment of follicles at this stage is thought to be controlled by steroids produced during the pupal stage. During two to three days after emergence and under the action of Juvenile Hormone (JH), primary follicles mature to a resting-stage in which they remain until females take a first blood meal. After blood meal ingestion, ovarian steroids trigger vitellogenesis of the primary follicles and egg development as well as the detachment from the germaria of new follicles, either secondary follicles if not yet present at emergence or tertiary follicles if secondary ones were already detached. Secondary follicles then grow to the previtellogenic resting stage, and develop after a second blood meal25.
To get a deeper understanding of the effect(s) of sexually-transferred steroids in Cellia female mosquitoes, we investigated the influence of mating on two events happening during the ovarian cycles which are known to be regulated by 20E. Firstly, injections of steroid hormones trigger follicle formation and detachment from the germarium in An. stephensi and Ae. aegypti26,27. Secondly, ovarian steroids produced upon blood feeding stimulate vitellogenesis and egg development7,8,25,27,28. We therefore compared follicle detachment (in females at the previtellogenic resting stage) and egg development (in blood fed females) between virgin and mated females from 12 Anopheles species (8 Cellia, 3 Anopheles and 1 Nyssorhynchus). As expected, mating induces the separation of the secondary ovarian follicle from the germarium in An. stephensi (Fig. 3, see also confocal pictures Supplementary Fig. 3), a Cellia species whose males produce and transfer steroids during mating. Mating also induces the separation of the secondary follicle in Anopheles minimus and Anopheles merus, although to a lesser extent. However, no secondary follicle detachment was observed after mating in An. dirus, a species for which none of the virgin females has the secondary follicle already detached. While multiple injections of steroids trigger the formation and detachment of the secondary and tertiary follicles within the same ovariole, in non-blood fed Ae. aegypti26, mating does not trigger detachment of tertiary follicles in Cellia species whose secondary follicles are already fully detached in virgin females (Anopheles farauti, An. gambiae, An. arabiensis and An. quadriannulatus). Mating also induces secondary follicle detachment in some species whose males do not produce steroids (Anopheles atroparvus and Anopheles freeborni), but not in others, even in species showing partial detachment of the secondary follicle in virgin females (Anopheles quadrimaculatus and Anopheles albimanus).
Similarly, mating increases the number of developing eggs in some mosquito species but not in others (Fig. 4). There is no correlation with the cognate male producing steroids, nor with the ability of virgin females to produce a low or a high number of eggs upon blood feeding (Fig. 4 and Table 1). As an example, mating increases egg development in An. albimanus (Nyssorhynchus), whose males do not produce steroids, but not in An. gambiae nor in An. arabiensis (Cellia). These results are in discrepancy with previous studies reporting that mating increases egg development in An. gambiae and An. arabiensis10,29 but not in An. albimanus10,30. These differences across studies are not due to the origin of the blood ingested by the females (animal or human) as similar results were obtained with An. albimanus and An. gambiae fed on mouse or human blood (Supplementary Fig. 4). Importantly, in Cellia species, the occurrence or absence of mating-induced phenotypes in females are not linked to the different quantities of steroids produced by the cognate males (Fig. 1 and Table 1) and likely transferred to females during mating as determined for An. gambiae, An. stephensi, An. arabiensis and An. dirus (Supplementary Fig. 2)6,10. Indeed, as depicted in Table 1, mating triggers both secondary follicle detachment and a rise in the number of developed eggs in An. stephensi, or only an increase in egg development in An. dirus, while this does not hold for An. gambiae and An. arabiensis, two species whose males produce and transfer higher amounts of steroids than An. stephensi and An. dirus.
Discussion
Since the discovery that Anopheles gambiae males were “unique” among insects by producing and transferring 20E to females6, steroids and steroid-signalling pathways became potential targets for malaria vector control31,32. Indeed, it was suggested that some post-mating responses such as refractoriness to further mating and increase in egg development only exist in Anopheles species whose males produce and transfer steroids to females and that may be linked to the ability of these mosquitoes to transmit human malaria10. However, a deep understanding of the selective forces driving reproductive strategy diversity and their functional consequences are critical for designing strategies for management of insect pests. Here, by analysing the evolution of steroid production and transfer by male mosquitoes, we reveal that this physiological trait is specific to the Cellia subgenus. The Anopheles species previously identified as transferring steroids indeed belong to the Cellia subgenus only. However, the analysis of a limited number of species could not reveal this synapomorphy10. Furthermore, by using a larger set of mosquito species we demonstrate that there is no strict correlation between the evolution of sexually-transferred 20E and the evolution of malaria transmission to humans (Table 1). Consistent with this, while we show that male steroid production and subsequent transfer to females is likely to have evolved only once in the common ancestor of the Cellia species, phylogenetic analyses on malaria mosquitoes support a convergent evolution with independent and repeated acquisitions of vectorial capacities in Anopheles mosquitoes even though losses also occurred33,34,35. Nevertheless, as sexually-transferred steroids influence egg production in some species, we cannot exclude they could impact malaria transmission by these species. This is also true for species not transferring steroids and for which mating influences egg production even though it is not yet known which sexually-transferred molecule mediates these effects.
While post-mating responses are rather conserved among insects, they are triggered by species-specific genes and signalling pathways due to the rapid evolution of insect reproductive systems36. For instance, Ae. aegypti males transfer JH to females upon copulation to trigger physiological and behavioural changes in mated females, whereas Drosophila flies transfer male accessory gland peptides such as Sex Peptide37,38. However, few data were available for Anopheles mosquitoes and it has been suggested that mating-induced changes, mediated by male steroids, do not exist in species whose males do not produce and transfer steroids. Importantly, our analysis demonstrates that identical post-mating responses increasing fecundity occur in Cellia species, but also in mosquito species whose males do not produce and transfer steroids such as in species of the Anopheles and Nyssorhynchus subgenera (Table 1). Injection of 20E into virgin females induces refractoriness to further mating in An. gambiae and An. arabiensis but not in An. albimanus which do not produce male 20E, linking male 20E transfer with monogamy (insemination by a single male) in the former species9,10. Similarly to the post-mating responses analysed in this study, monogamy is common in Anopheles mosquitoes, whether males produce steroids or not39,40,41,42. It is therefore likely that mosquitoes belonging to the Anopheles and Nyssorhynchus subgenera transfer other and not yet identified molecule(s) to directly or indirectly increase egg development, stimulate follicle detachment and induce refractoriness to further mating in mated females as sexually-transferred steroids do in Cellia species. For instance, it could be possible that in these species not transferring steroids, mating triggers the females to produce their own steroid hormones, which in turn would have the same effects as the sexually-transferred ones in Cellia species. As JH is transferred to females during mating in Ae. aegypti mosquitoes but also in the Lepidoptera Heliothis virescens43, sexual transfer of steroid hormones in other mosquito subgenera, genera or even insect orders not yet tested cannot even be excluded.
Overall, our data demonstrate that mating-induced phenotypes are variable among Anopheles species. These differences are independent of male ability to produce and transfer steroids to females and are not correlated with malaria vectorial capacity. In agreement with this, a recent study found that molecular pathways triggered by male 20E are different in An. gambiae and An. coluzzii females, members of the Anopheles gambiae complex that recently diverged and live in sympatry in many places in Africa44. While previous reports demonstrated that mating increases egg development in An. gambiae and An. arabiensis but not in An. albimanus10,29,30, our results show the opposite, i.e. mating increases egg development in An. albimanus but not in An. gambiae and An. arabiensis. These different results obtained for the same species across laboratories show that mating-induced phenotypes are possibly variable even among strains as already described for some Aedes species45,46. In the same way An. coluzzii males produce higher amounts of 20E under wet versus dry conditions47. It cannot therefore be excluded that male steroids transferred upon mating benefit reproduction of some Cellia species but only under certain environmental conditions. Different ecological pressures such as nutrition resources might also favour the maintenance and importance of sexually-transferred steroids, as shown for nuptial gifts in Ae. aegypti48,49,50. The reproductive capacity of mosquito females is affected by their nutrition at both the larval and adult stages. In An. gambiae (Cellia), An. stephensi (Cellia), An. albimanus (Nyssorhynchus) and An. quadrimaculatus (Anopheles), reserves acquired during larval development are lower and females invest less of their blood meal resources in oogenesis than in Ae. aegypti. Moreover, starvation during larval stages decreases female body size, which in turn decreases the volume of ingested blood and then the number of matured eggs51. As a consequence, wild female Anopheles are likely to seek multiple blood meals during a single gonotrophic cycle, especially the first one52. It is therefore possible that steroids transferred during mating in Cellia, as well as unidentified molecule(s) in Nyssorhynchus and Anopheles subgenera, constitute an adaptation within the Anopheles genera to enhance fertility and reduce the multiple seeking behaviour in case of poor larval reserves.
Apart from follicle detachment, increase in egg development and induction of refractoriness to mating, numerous other functions of steroids have been described in adult insects53,54,55,56. Thus, sexually-transferred steroids could mediate different functions with more or less direct benefit for the reproduction of Cellia females, due to the rapid evolution of reproductive systems between species. Sexually-transferred steroids could be preferentially used to control one or another female reproductive trait, and differently according to various reproductive strategies among species. If this is the case, this could explain why we could not see any effect of mating on follicle detachment and egg development in some species such as An. gambiae and An. farauti, or only an effect on egg development but not on follicle detachment such as in An. dirus. For this latter species, it cannot be excluded as well that another signal, such as the blood meal, is also required to trigger secondary follicle detachment. It is unlikely that the occurrence or absence of mating-induced effects are due to the quantity of steroids being transferred as for instance, males of An. gambiae produce and transfer to females much more steroids compared to An. dirus.
It remains open as what were the evolutionary forces that have initially promoted the acquisition and radiation of this presumably costly male steroid production and sexual gift to females in Cellia mosquitoes around 84.1–69.2 Ma. At this time, two main paleogeological events that had impacts on environmental conditions may have led to pressures driving the evolution of steroid production and transfer by males in Cellia species: (i) the Gondwana break up at 100 Ma with separation of South America and Africa57; (ii) the Cretaceous-Paleogene extinction event at 65.5 Ma58,59. Because such geographical isolation and environmental stresses are believed to drive traits contributing to animal species survival, it is likely that transfer of steroids by males to females have favoured Cellia species populations at this critical time.
Material and Methods
Mosquito species and rearing
Ecdysteroid production by sexually mature males was analysed in 19 mosquito species. Sixteen (16) species belong to the subfamily Anophelinae (An. arabiensis, An. dirus, An. farauti, An. gambiae form M, An. merus, An. minimus, An. quadriannulatus, An. stephensi, An. albimanus, An. albitarsis, An. aquasalis, An. atroparvus, An. freeborni, An. plumbeus, An. pseudopunctipennis and An. quadrimaculatus) and three species belong to the subfamily Culicinae (Ae. aegypti, Ae. albopictus and Cx. pipiens). Information on species is given in Supplementary Information. Mosquito larvae were reared at 27 °C in deionized water supplemented with minerals and fed on TetraMin Baby-E fish food from the day of hatching to the fourth larval instar supplemented with pieces of cat food. Male and female adults were maintained at 27 °C, under 68% relative humidity and a 12/12 h light/dark cycle, and provided free access to a 10% wt/vol sucrose solution for the first five days post-emergence (PE). Female mosquitoes (first gonotrophic cycle) were allowed to feed for 30 min on the blood of an anesthetized mouse or rabbit depending on mosquito species preference (see Supplementary Table 2). An. plumbeus L4 larvae and pupae were harvested from a natural pond in Switzerland and reared up to the adult stage at the Institut Pasteur. Mature males of An. albitarsis and An. aquasalis were kindly prepared and provided by D. Valle and L. Moreira (Fiocruz, Brazil) and An. pseudopunctipennis by F. Lardeux (IRD, Bolivia).
Mosquito sampling, ecdysteroid extraction and quantification
To measure ecdysteroid titers in virgin adult males and females, males and females were separated on the day of adult emergence, transferred individually 5 days later in methanol and stored at −20 °C until ecdysteroid extraction. For the transfer experiments, An. stephensi males and females were separated on the day of adult emergence for 5 days to allow male sexual maturation. Mating experiments and sampling were performed as described in6. Total ecdysteroids from individual whole mosquitoes were extracted with methanol and re-dissolved in enzyme immuno assay (EIA) buffer. Empty tubes were treated similarly in parallel to be used as a negative control (referred as extraction blank). Ecdysteroids were quantified by EIA, with 20-hydroxyecdysone-2-succinate coupled to peroxydase as a tracer (dilution 1:100,000) and the L2 antiserum (gift from M. De Reggi (Marseille, France); dilution 1:100,000). Calibration curves were generated with ecdysone (E; 3,6–500 pg/tube) diluted in EIA buffer, and titers were expressed as E equivalents. Under these conditions, detection limit is 2 pg E equivalents. All measurements were performed in duplicate and the results are expressed as mean values ± SEM of several (n = 20 at least) independent samples and have been repeated on two independent cohorts of mosquitoes. Samples at or above the highest value of the calibration curve were diluted and quantified again. The intra- and inter-assay variation coefficients were 3,9% and 5,6%, respectively. For steroid titers in whole males from different species, data were subjected to statistical analysis using Kruskall-Wallis test for nonparametric data followed by Dunn’s post-hoc test (control group: extraction blank). The indicated p values are those obtained with Dunn’s test. For the transfer experiment in An. stephensi, results were subjected to statistical analysis using the Mann-Whitney test.
Taxon sampling and DNA sequencing for phylogenetic analysis
We chose 20 Culicidae species for phylogenetic and comparative analysis. We selected 16 species of the genus Anopheles (Anophelinae subfamily) of which An. arabiensis, An. dirus, An. farauti, An. gambiae, An. merus, An. minimus, An. stephensi, An. quadriannulatus, An. atroparvus, An. freeborni, An. plumbeus, An. pseudopunctipennis, An. quadrimaculatus, An. albimanus, An. albitarsis, and An. aquasalis. As outgroups, we chose Chagasia bathana (Anophelinae subfamily, Chagasia genus), and 3 mosquito species belonging to the subfamily Culicinae with Ae. aegypti, Ae. albopictus (Aedes genus) and Cx. pipiens (Culex genus). Sequence data were generated for An. aquasalis, An. atroparvus, An. merus and An. plumbeus. Genomic DNA was obtained from single individuals using the DNeasy Blood and tissue kit (QIAGEN). A common set of molecular markers were chosen based on the availability of sequence data for Ch. bathana. Partial genomic regions of four nuclear genes (g6pd, white, 18S and 28S) and four mitochondrial genes (COI, COII, ND5 and CYTB) were amplified by PCR with gene-specific or degenerate primers (sequences in Supplementary Table 3). For PCR amplifications, we used 0.4 µM oligonucleotides, 1 U GoTaq® DNA Polymerase (Promega) per 35 µl reaction volume, 2 mM MgCl2, and 200 µM dNTP and reactions were carried out using standard thermocycle conditions. PCR products were purified and Sanger-sequenced with gene-specific primers or with T7, SP6 universal primers at Cogenics (www.cogenics.com, Beckman Coulter, GenBank Accession Numbers in Supplementary Table 4). Sequence data of the remaining species were obtained from GenBank and VectorBase (Supplementary Table 4). Sequences were examined and aligned with Geneious 6.1.3 (Biomatters). Our dataset was not complete, we did not find or generate sequence data for 10 / 160 (8 genes X 20 species) gene specific sequences and among the rest 15 / 150 of sequences were only partially covering the locus. The missing sequence data represent 5.6% of the total dataset and was annotated as a “?” (missing value) in the alignments for phylogenetic analysis. Introns were removed from g6pd and white sequences and the extremities of all protein coding sequences were trimmed to be in codon frame. Alignments for protein coding genes were re-aligned with the Geneious translation alignment program. In addition to gene specific alignments a concatenated dataset was generated in the following order: COI-COII-ND5-CYTB-18S-28S-g6pd-white. The number of informative sites was calculated using MEGA460.
Phylogenetic analysis
We used DNA sequences of partial regions of the coding sequence of mitochondrial genes (COI, COII, ND5 and CYTB) and nuclear ones (18S, 28S, g6pd and white) from the 19 mosquito species plus Chagasia bathana. Phylogenetic analysis of the concatenated, five-partition data set was performed by maximum likelihood and by Bayesian inference. Details of phylogenetic analysis are given in Supplementary Information.
Cellia and Anopheles species distribution mapping
Total numbers of mosquito species belonging to the Cellia or Anopheles subgenera per country were taken from the Walter Reed Biosystematics Unit (WRBU, http://www.wrbu.org/). Data were further represented on maps created with R61 using the “sp” package62.
Analysis of the secondary follicle detachment in virgin and mated non-blood fed females
Males and females were separated upon emergence to keep females virgin. A portion of females were put in a cage with males to obtain mated females. After 7 days (time at which all species were at the previtellogenic resting stage, i.e. being competent to develop eggs in response to a blood meal), female ovaries were dissected, and the spermatheca of mated females checked for presence of spermatozoa. Ovaries from each female were then mounted on a slide in mounting media and observation of the secondary follicle detachment was performed using a transmitted light microscope. 30 to 60 females were analysed per species and per condition. Data were subjected to Chi-square test. For An. stephensi, ovaries from either virgin or mated females were fixed with 4% paraformaldehyde, washed 3 times with PBS-0.05% Tween 20 (PBS-T) and stained with DAPI. After 4 washes with PBS-T, ovaries were mounted on a slide in mounting media. Pictures were taken using a SP5 Leica confocal microscope.
Analysis of egg development in virgin and mated blood fed females
Virgin and mated females were prepared as described above. A portion of females were put in a cage with males to obtain mated females. On 7 days PE, females were allowed to blood feed on anesthetized mouse or rabbit (Supplementary Table 2). An. gambiae and An. albimanus females were also fed with fresh human blood (ICAReB Platform, Center for Translational Research, Institut Pasteur, Paris, France) for comparison with mouse-fed mosquitoes. Ovaries were dissected 48 hours after blood feeding, and the total number of eggs in virgin and mated females was counted. Mated status was verified by observing spermatozoa in the spermatheca and only females with a filled spermatheca were taken into account. 30 to 60 females were dissected per species and per condition. Data were subjected to Mann-Whitney non-parametric test.
Ethical compliance
This study complied with all relevant ethical guidelines and regulations. Project (n° 2013-0132) approved by the Ministère de l’Enseignement Supérieur et de la Recherche – Direction Générale pour la Recherche et l’Innovation – Secrétariat « Autorisation de projet » − 1, rue Descartes, 75231 PARIS cedex 5. Human blood was obtained from ICAReB Platform, Center for Translational Research, Institut Pasteur, Paris, France.
Data Availability
The sequence data reported in this paper are tabulated in the Supplementary Information and archived at Genbank.
References
WHO. World Malaria Report 2017 160 (Geneva: World Health Organization, 2017).
Harbach, R. E. & Kitching, I. J. The phylogeny of Anophelinae revisited: inferences about the origin and classification of Anopheles (Diptera: Culicidae). Zool. Scripta 45, 34–47 (2016).
Hay, S. I. et al. Developing global maps of the dominant Anopheles vectors of human malaria. PLoS Med. 7, e1000209, https://doi.org/10.1371/journal.pmed.1000209 (2010).
Harbach, R. E. In Anopheles mosquitoes - New insights into malaria vectors (ed. Sylvie Manguin) Ch. 1, 3–55 (InTech, 2013).
Harbach, R. E. Anopheles Meigen, 1818. Mosquito Taxonomic Inventory (2018).
Pondeville, E., Maria, A., Jacques, J. C., Bourgouin, C. & Dauphin-Villemant, C. Anopheles gambiae males produce and transfer the vitellogenic steroid hormone 20-hydroxyecdysone to females during mating. Proc. Natl. Acad. Sci. USA 105, 19631–19636, https://doi.org/10.1073/pnas.0809264105 (2008).
Raikhel, A. S., Brown, M. R. & Belles, X. In Comprehensive Molecular Insect Science Vol. 3 (eds Gilbert, L. I., Iatrou, K. & Gill, S. S.) Ch. 3.9, 433–491 (2005).
Swevers, L., Raikhel, A. S., Sappington, T. W., Shirk, P. & Iatrou, K. In Comprehensive Molecular Insect Science Vol. 1 (eds Gilbert, L. I., Iatrou, K. & Gill, S. S.) Ch. 1.3, 87–155 (2005).
Gabrieli, P. et al. Sexual transfer of the steroid hormone 20E induces the postmating switch in Anopheles gambiae. Proc. Natl. Acad. Sci. USA 111, 16353–16358, https://doi.org/10.1073/pnas.1410488111 (2014).
Mitchell, S. N. et al. Mosquito biology. Evolution of sexual traits influencing vectorial capacity in anopheline mosquitoes. Science 347, 985–988, https://doi.org/10.1126/science.1259435 (2015).
Takken, W. et al. Susceptibility of Anopheles quadriannulatus Theobald (Diptera: Culicidae) to Plasmodium falciparum. Trans. R. Soc. Trop. Med. Hyg. 93, 578–580 (1999).
Habtewold, T., Povelones, M., Blagborough, A. M. & Christophides, G. K. Transmission blocking immunity in the malaria non-vector mosquito Anopheles quadriannulatus species A. PLoS pathog. 4, e1000070, https://doi.org/10.1371/journal.ppat.1000070 (2008).
Sinka, M. E. et al. The dominant Anopheles vectors of human malaria in Africa, Europe and the Middle East: occurrence data, distribution maps and bionomic precis. Parasit. vectors 3, 117, https://doi.org/10.1186/1756-3305-3-117 (2010).
Sinka, M. E. et al. A global map of dominant malaria vectors. Parasit. vectors 5, 69, https://doi.org/10.1186/1756-3305-5-69 (2012).
Schaffner, F. et al. Anopheles plumbeus (Diptera: Culicidae) in Europe: a mere nuisance mosquito or potential malaria vector? Malar. J. 11, 393, https://doi.org/10.1186/1475-2875-11-393 (2012).
Harbach, R. E. The Culicidae (Diptera): a review of taxonomy, classification and phylogeny. Zootaxa 1668, 591–638 (2007).
Sallum, M. A. M. et al. Phylogeny of Anophelinae (Diptera: Culicidae) based on nuclear ribosomal and mitochondrial DNA sequences. Syst. Entomol. 27, 361–382 (2002).
Neafsey, D. E. et al. Mosquito genomics. Highly evolvable malaria vectors: the genomes of 16 Anopheles mosquitoes. Science 347, 1258522, https://doi.org/10.1126/science.1258522 (2015).
Wei, Y. et al. Comparative physical genome mapping of malaria vectors Anopheles sinensis and Anopheles gambiae. Malar. J. 16, 235, https://doi.org/10.1186/s12936-017-1888-7 (2017).
Freitas, L. A. et al. Diversification of the Genus Anopheles and a Neotropical Clade from the Late Cretaceous. PloS one 10, e0134462, https://doi.org/10.1371/journal.pone.0134462 (2015).
Moreno, M. et al. Complete mtDNA genomes of Anopheles darlingi and an approach to anopheline divergence time. Malar. J. 9, 127, https://doi.org/10.1186/1475-2875-9-127 (2010).
Krzywinski, J., Grushko, O. G. & Besansky, N. J. Analysis of the complete mitochondrial DNA from Anopheles funestus: an improved dipteran mitochondrial genome annotation and a temporal dimension of mosquito evolution. Mol. Phylogenet. Evol. 39, 417–423, https://doi.org/10.1016/j.ympev.2006.01.006 (2006).
Scotese, C. R. A continental drift flipbook. J. Geol. 112, (729–741 (2004).
de Oliveira, B. F., Molina, C. E. & Marroig, G. In Developments in Primatology: Progress and Prospects (eds Garber, P. A. et al.) Ch. 3, 55–68 (Springer New York 2009).
Clements, A. N. Vol. 1 509 (Chapman & Hall, 1992).
Beckemeyer, E. F. & Lea, A. O. Induction of follicle separation in the mosquito by physiological amounts of ecdysterone. Science 209, 819–821, https://doi.org/10.1126/science.209.4458.819 (1980).
Redfern, C. P. F. 20-hydroxyecdysone and ovarian development in Anopheles stephensi. J. Insect. Physiol. 28, 97–109 (1982).
Lu, Y. H. & Hagedorn, H. H. Egg development in the mosquito Anopheles albimanus. Int. J. Invertebr. Repr. Dev. 9, 79–94 (1986).
Baldini, F. et al. The interaction between a sexually transferred steroid hormone and a female protein regulates oogenesis in the malaria mosquito Anopheles gambiae. PLoS biology 11, e1001695, https://doi.org/10.1371/journal.pbio.1001695 (2013).
Lounibos, L. P. Variable egg development among Anopheles (Nyssorhynchus): control by mating? Physiol. Entomol. 19, 51–57 (1994).
Childs, L. M. et al. Disrupting Mosquito Reproduction and Parasite Development for Malaria Control. PLoS pathog. 12, e1006060, https://doi.org/10.1371/journal.ppat.1006060 (2016).
Mitchell, S. N. & Catteruccia, F. Anopheline Reproductive Biology: Impacts on Vectorial Capacity and Potential Avenues for Malaria Control. Cold Spring Harbor perspectives in medicine 7, https://doi.org/10.1101/cshperspect.a025593 (2017).
Kamali, M. et al. Multigene phylogenetics reveals temporal diversification of major African malaria vectors. PloS one 9, e93580, https://doi.org/10.1371/journal.pone.0093580 (2014).
Kamali, M., Xia, A., Tu, Z. & Sharakhov, I. V. A new chromosomal phylogeny supports the repeated origin of vectorial capacity in malaria mosquitoes of the Anopheles gambiae complex. PLoS pathog. 8, e1002960, https://doi.org/10.1371/journal.ppat.1002960 (2012).
Marshall, J. C., Powell, J. R. & Caccone, A. Short report: Phylogenetic relationships of the anthropophilic Plasmodium falciparum malaria vectors in Africa. Am. J. Trop. Med. Hyg. 73, 749–752 (2005).
Swanson, W. J. & Vacquier, V. D. The rapid evolution of reproductive proteins. Nature reviews. Genetics 3, 137–144, https://doi.org/10.1038/nrg733 (2002).
Clifton, M. E. & Noriega, F. G. The fate of follicles after a blood meal is dependent on previtellogenic nutrition and juvenile hormone in Aedes aegypti. J Insect Physiol 58, 1007–1019, https://doi.org/10.1016/j.jinsphys.2012.05.005 (2012).
Chapman, T. & Davies, S. J. Functions and analysis of the seminal fluid proteins of male Drosophila melanogaster fruit flies. Peptides 25, 1477–1490, https://doi.org/10.1016/j.peptides.2003.10.023 (2004).
Villarreal, C., Fuentes-Maldonado, G., Rodriguez, M. H. & Yuval, B. Low rates of multiple fertilization in parous Anopheles albimanus. J. Am. Mosq. Control Assoc. 10, 67–69 (1994).
Yuval, B. & Fritz, G. N. Multiple mating in female mosquitoes — evidence from a field population of Anopheles freeborni (Diptera: Culicidae). Bull. Entomol. Res. 84, 137–140 (1994).
Arnqvist, G. Comparative evidence for the evolution of genitalia by sexual selection. Nature 393, 784–786 (1998).
Tripet, F., Toure, Y. T., Dolo, G. & Lanzaro, G. C. Frequency of multiple inseminations in field-collected Anopheles gambiae females revealed by DNA analysis of transferred sperm. Am. J. Trop. Med. Hyg. 68, 1–5 (2003).
Park, Y. I., Shu, S., Ramaswamy, S. B. & Srinivasan, A. Mating in Heliothis virescens: transfer of juvenile hormone during copulation by male to female and stimulation of biosynthesis of endogenous juvenile hormone. Arch. Insect. Biochem. Physiol. 38, 100–107, doi:10.1002/(SICI)1520-6327(1998)38:2<100::AID-ARCH6>3.0.CO;2-X (1998).
Thailayil, J. et al. Analysis of natural female post-mating responses of Anopheles gambiae and Anopheles coluzzii unravels similarities and differences in their reproductive ecology. Scientific Reports 8, 6594, https://doi.org/10.1038/s41598-018-24923-w (2018).
O’Meara, G. F. & Evans, D. C. Autogeny in saltmarsh mosquitoes induced by a substance from the male accessory gland. Nature 267, 342–344 (1977).
Gillett, J. D. Genetic differences affecting egg-laying in the mosquito Aedes (Stegomyia) aegypti (Linnaeus). Ann. Trop. Med. Parasitol. 50, 362–374 (1956).
Mamai, W. et al. Metabolomic and ecdysteroid variations in Anopheles gambiae s.l. mosquitoes exposed to the stressful conditions of the dry season in Burkina Faso, West Africa. Physiological and biochemical zoology: PBZ 87, 486–497, https://doi.org/10.1086/675697 (2014).
Gwynne, D. T. & Simmons, L. W. Nature 346, 172–174 (1990).
Gwynne, D. T. Sexual conflict over nuptial gifts in insects. Annu. Rev. Entomol. 53, 83–101, https://doi.org/10.1146/annurev.ento.53.103106.093423 (2008).
Klowden, M. J. & Chambers, G. M. Male accessory gland substances activate egg development in nutritionally stressed Aedes aegypti mosquitoes. J. Insect. Physiol. 37, 721–726 (1991).
Briegel, H. Fecundity, metabolism, and body size in Anopheles (Diptera: Culicidae), vectors of malaria. J Med Entomol 27, 839–850 (1990).
Briegel, H. & Horler, E. Multiple blood meals as a reproductive strategy in Anopheles (Diptera: Culicidae). J Med Entomol 30, 975–985 (1993).
Raikhel, A. S. & Lea, A. O. Control of follicular epithelium development and vitelline envelope formation in the mosquito; role of juvenile hormone and 20-hydroxyecdysone. Tissue Cell 23, 577–591 (1991).
Terashima, J. & Bownes, M. E75A and E75B have opposite effects on the apoptosis/development choice of the Drosophila egg chamber. Cell. Death Differ. 13, 454–464, https://doi.org/10.1038/sj.cdd.4401745 (2006).
Konig, A., Yatsenko, A. S., Weiss, M. & Shcherbata, H. R. Ecdysteroids affect Drosophila ovarian stem cell niche formation and early germline differentiation. EMBO J. 30, 1549–1562, https://doi.org/10.1038/emboj.2011.73 (2011).
Domanitskaya, E., Anllo, L. & Schupbach, T. Phantom, a cytochrome P450 enzyme essential for ecdysone biosynthesis, plays a critical role in the control of border cell migration in. Drosophila. Dev. Biol. 386, 408–418, https://doi.org/10.1016/j.ydbio.2013.12.013 (2014).
Reyment, R. A. & Dingle, R. V. Palaeogeography of Africa during the Cretaceous period. Palaeogeogr. Palaeoclimatol. Palaeoecol. 59, 93–116 (1987).
Schulte, P. et al. The Chicxulub asteroid impact and mass extinction at the Cretaceous-Paleogene boundary. Science 327, 1214–1218, https://doi.org/10.1126/science.1177265 (2010).
Novacek, M. J. 100 Million year of land vertebrate evolution: the early Cretaceous-early Tertiary transition. Ann. Mo. Bot. Gard. 86, 230–258 (1999).
Tamura, K., Dudley, J., Nei, M. & Kumar, S. MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol. Biol. Evol. 24, 1596–1599, https://doi.org/10.1093/molbev/msm092 (2007).
RCoreTeam. (R Foundation for Statistical Computing, Vienna, Austria, 2016).
Bivand, S., Pebesma, E. & Gomez-Rubio, V. Applied Spatial Data Analysis with R. Vol. Second edition (Springer, 2013).
Acknowledgements
We are grateful to L. Lambrechts, S. Blandin and J.-P. Parvy for comments on the manuscript. We acknowledge D. Streicker, E. Hutchinson and M. Palmarini for discussions. We acknowledge M.-T. Lecoq, S. Touron and C. Thouvenot for mosquito rearing, A-B. Failloux for providing Ae. aegypti and Ae. albopictus eggs, M. Weill (ISEM, Montpellier, France) for providing Cx. pipiens eggs, T. Bukhari for providing An. arabiensis samples, D. Valle and L. Moreira (FIOCRUZ, Brazil) for providing An. aquasalis and An. albitarsis samples, as well as F. Lardeux (IRD, Centre de Bolivie, La Paz, Bolivia) for providing An. pseudopunctipennis samples. We thank E. Perret (Dynamic Imaging Platform, Institut Pasteur) for her assistance with confocal microscopy. The following reagents were obtained through BEI resources, NIAID, NIH: eggs of An. albimanus STECLA (MRA-126), An. arabiensis DONGOLA (MRA-856), An. quadrimaculatus ORLANDO (MRA-139), An. quadriannulatus SANGWE (MRA-1155), An. merus OPHANSI (MRA-803), An. minimus MINIMUS1 (MRA-729), An. dirus WRAIR2 (MRA-700), An. farauti s.s. FAR1 (MRA-489), An. atroparvus EBRO (MRA-493) and An. freeborni F1 (MRA-130). Support to E.P. was from an ANR-07-MIME-O25-01 award to C.B. and by the UK Medical Research Council to E.P. (MC_UU_12014/8), to C.B. from award no. ANR-10-LABX-62-IBEID. M.L. was hosted by V. Courtier-Orgogozo, financed by a FRM postdoctoral fellowship SPF20121226328 and by the CNRS.
Author information
Authors and Affiliations
Contributions
E.P. and C.B. conceptualised and supervised the project as well as the experimental design; E.P., N.P., M.L., F.C., F.S., C.D.-V. and E.B. performed the experiments; E.P., N.P., M.L., E.B. and C.B. contributed to data interpretation; E.P., N.P., M.L., F.S. and E.B. contributed to figure preparation; E.P. and C.B. wrote the manuscript; M.L., F.S., E.B. commented on the final manuscript.
Corresponding authors
Ethics declarations
Competing Interests
The authors declare no competing interests.
Additional information
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Pondeville, E., Puchot, N., Lang, M. et al. Evolution of sexually-transferred steroids and mating-induced phenotypes in Anopheles mosquitoes. Sci Rep 9, 4669 (2019). https://doi.org/10.1038/s41598-019-41094-4
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-019-41094-4
- Springer Nature Limited
This article is cited by
-
Mating-regulated atrial proteases control reinsemination rates in Anopheles gambiae females
Scientific Reports (2020)
-
JNK signaling regulates oviposition in the malaria vector Anopheles gambiae
Scientific Reports (2020)