Mike A. Osta

Evolutionary dynamics of immune-related genes and pathways in disease-vector mosquitoes

Mosquitoes are vectors of parasitic and viral diseases of immense importance for public health. The acquisition of the genome sequence of the yellow fever and Dengue vector, Aedes aegypti (Aa), has enabled a comparative phylogenomic analysis of the insect immune repertoire: in Aa, the malaria vector Anopheles gambiae (Ag), and the fruit fly Drosophila melanogaster (Dm). Analysis of immune signaling pathways and response modules reveals both conservative and rapidly evolving features associated with different functional gene categories and particular aspects of immune reactions. These dynamics reflect in part continuous readjustment between accommodation and rejection of pathogens and suggest how innate immunity may have evolved.

A genetic module regulates the melanization response of Anopheles to Plasmodium

Two modes of refractoriness to Plasmodium, ookinete lysis and melanization, are known in the malaria vector, Anopheles gambiae. Melanization, a potent insect immune response, is manifested in a genetically selected refractory strain and in susceptible mosquitoes that are depleted of specific C‐type lectins (CTLs). Here we use a systematic in vivo RNA interference‐mediated reverse genetic screen and other recent results to define a melanization‐regulating genetic module or network. It encompasses at least 14 genes, including those that encode five Easter‐like clip domain serine proteases and four Masquerade‐like serine protease homologues of the mosquito CLIPB and CLIPA subfamilies respectively. We show that several but not all CLIPB genes promote Plasmodium melanization, exhibiting partial functional overlap and synergy. We also report that several CLIPA genes have contrasting roles: CLIPA8 is essential for parasite melanization, while three other CLIPAs are novel synergistic inhibitors of this response. Importantly, the roles of certain CLIPAs and CLIPBs are strain specific, indicating that this network may differ between strains. Finally, we provide evidence that in susceptible mosquitoes melanization induced by knockdown of either CTL4 or CLIPA2/CLIPA5 directly kills ookinetes, in contrast to refractory mosquitoes where it merely disposes of dead parasites.

Anopheles and Plasmodium: from laboratory models to natural systems in the field.

Parasites that cause malaria must complete a complex life cycle in Anopheles vector mosquitoes in order to be transmitted from human to human. Previous gene‐silencing studies have shown the influence of mosquito immunity in controlling the development of Plasmodium. Thus, parasite survival to the oocyst stage increased when the parasite antagonist gene LRIM1 (leucine‐rich repeat immune protein 1) of the mosquito was silenced, but decreased when the C‐type lectin agonist gene CTL4 or CTLMA2 (CTL mannose binding 2) was silenced. However, such effects were shown for infections of the human mosquito vector Anopheles gambiae with the rodent parasite Plasmodium berghei. Here, we report the first results of A. gambiae gene silencing on infection by sympatric field isolates of the principal human pathogen P. falciparum. In contrast with the results obtained with the rodent parasite, silencing of the same three genes had no effect on human parasite development. These results highlight the importance of following up discoveries in laboratory model systems with studies on natural parasite–mosquito interactions.

Innate immunity in the malaria vector Anopheles gambiae:comparative and functional genomics

SUMMARY The resurgence of malaria is at least partly attributed to the absence of an effective vaccine, parasite resistance to antimalarial drugs and resistance to insecticides of the anopheline mosquito vectors. Novel strategies are needed to combat the disease on three fronts: protection (vaccines), prophylaxis/treatment (antimalarial drugs) and transmission blocking. The latter entails either killing the mosquitoes (insecticides), preventing mosquito biting (bednets and repellents), blocking parasite development in the vector (transmission blocking vaccines), genetic manipulation or chemical incapacitation of the vector. During the past decade, mosquito research has been energized by several breakthroughs, including the successful transformation of anopheline vectors, analysis of gene function by RNAi, genome-wide expression profiling using DNA microarrays and, most importantly, sequencing of the Anopheles gambiae genome. These breakthroughs helped unravel some of the mechanisms underlying the dynamic interactions between the parasite and the vector and shed light on the mosquito innate immune system as a set of potential targets to block parasite development. In this context, putative pattern recognition receptors of the mosquito that act as positive and negative regulators of parasite development have been identified recently. Characterizing these molecules and others of similar function, and identifying their ligands on the parasite surface, will provide clues on the nature of the interactions that define an efficient parasite–vector system and open up unprecedented opportunities to control the vectorial capacity of anopheline mosquitoes.

The Roles of Two Clip Domain Serine Proteases in Innate Immune Responses of the Malaria Vector Anopheles gambiae

The malaria vector Anopheles gambiae is capable of multiple immune responses against Plasmodium ookinetes. Accumulating evidence in several insect species suggests the involvement of serine protease cascades in the initiation and coordination of immune responses. We report molecular and reverse genetic characterization of two mosquito clip domain serine proteases, CLIPB14 and CLIPB15, which share structural similarity to proteases involved in prophenoloxidase activation in other insects. Both CLIPs are expressed in mosquito hemocytes and are transcriptionally induced by bacterial and Plasmodium challenges. Functional studies applying RNA interference revealed that both CLIPs are involved in the killing of Plasmodium ookinetes in Anopheles. Studies on parasite melanization demonstrated an additional role for CLIPB14 in the prophenoloxidase cascade. We further report that both CLIPs participate in defense toward Gram-negative bacteria. Our findings strongly suggest that clip domain serine proteases serve multiple functions and play distinctive roles in several immune pathways of A. gambiae.

The melanization reaction is not required for survival of Anopheles gambiae mosquitoes after bacterial infections.

The melanization reaction of insects requires activation of pro-phenoloxidase by a proteolytic cascade leading to melanin production. Studies in adult mosquitoes have shown that bacteria are efficiently melanized in the hemocoel, but the contribution of melanization to survival after bacterial infections has not been established. Here we show that the Anopheles gambiae noncatalytic serine protease CLIPA8, an essential factor for Plasmodium ookinete melanization, is also required for melanization of bacteria in adult mosquitoes. CLIPA8 silencing by RNA interference inhibits pro-phenoloxidase activation and melanization of bacteria in the hemolymph following microbial challenge. However, CLIPA8 is not required for wound melanization nor for melanotic pseudotumor formation in serpin2 knockdown mosquitoes, suggesting a specific role for pathogen melanization. Surprisingly, CLIPA8 knockdown mosquitoes are as resistant to bacterial challenge as controls, indicating that melanization is not essential for defense against bacteria and questions its precise role in mosquito immunity.

Two C-type Lectins Cooperate to Defend Anopheles gambiae against Gram-negative Bacteria

C-type lectins (CTLs) are a family of proteins that share a common structural motif, the carbohydrate recognition domain, and may act as receptors in pathogen recognition. Indeed, some vertebrate CTLs, particularly the collectins, are unequivocally implicated in the innate immune response to certain microbes. Although studies in insects and other invertebrates have described CTL activation of effector immune responses in vitro, the contribution of these CTLs to immune defenses in vivo is still poorly understood. Here we report that two CTLs, CTL4 and CTLMA2, which were shown previously to inhibit Plasmodium berghei ookinete melanization in the malaria vector Anopheles gambiae, are transcriptionally induced by bacterial challenge. Using in vivo reverse genetic analysis, we show that both CTLs are required for the clearance of Escherichia coli, but not Staphylococcus aureus, from adult female mosquitoes. Silencing either CTL dramatically reduces mosquito survival to Gram-negative but not to Gram-positive bacterial infections, suggesting a role in defense against Gram-negative bacteria. Furthermore, molecular characterization reveals that both CTLs are secreted into the mosquito hemolymph mainly in the form of a disulfide-linked heterodimer. This association explains the similar roles of these CTLs in bacterial defense as well as in the melanization response to P. berghei ookinetes. Apparently, CTL4 and CTLMA2 serve pleiotropic functions in the innate immune response of A. gambiae.

The CLIP-Domain Serine Protease Homolog SPCLIP1 Regulates Complement Recruitment to Microbial Surfaces in the Malaria Mosquito Anopheles gambiae

The complement C3-like protein TEP1 of the mosquito Anopheles gambiae is required for defense against malaria parasites and bacteria. Two forms of TEP1 are present in the mosquito hemolymph, the full-length TEP1-F and the proteolytically processed TEP1cut that is part of a complex including the leucine-rich repeat proteins LRIM1 and APL1C. Here we show that the non-catalytic serine protease SPCLIP1 is a key regulator of the complement-like pathway. SPCLIP1 is required for accumulation of TEP1 on microbial surfaces, a reaction that leads to lysis of malaria parasites or triggers activation of a cascade culminating with melanization of malaria parasites and bacteria. We also demonstrate that the two forms of TEP1 have distinct roles in the complement-like pathway and provide the first evidence for a complement convertase-like cascade in insects analogous to that in vertebrates. Our findings establish that core principles of complement activation are conserved throughout the evolution of animals.

A Serine Protease Homolog Negatively Regulates TEP1 Consumption in Systemic Infections of the Malaria Vector Anopheles gambiae

Clip domain serine protease homologs are widely distributed in insect genomes and play important roles in regulating insect immune responses, yet their exact functions remain poorly understood. Here, we show that CLIPA2, a clip domain serine protease homolog of Anopheles gambiae, regulates the consumption of the mosquito complement-like protein TEP1 during systemic bacterial infections. We provide evidence that CLIPA2 localizes to microbial surfaces in a TEP1-dependent manner whereby it negatively regulates the activity of a putative TEP1 convertase, which converts the full-length TEP1-F form into active TEP1cut. CLIPA2 silencing triggers an exacerbated TEP1-mediated response that significantly enhances mosquito resistance to infections with a broad class of microorganisms including Plasmodium berghei, Escherichia coli and the entomopathogenic fungus Beauveria bassiana. We also provide further evidence for the existence of a functional link between TEP1 and activation of hemolymph prophenoloxidase during systemic infections. Interestingly, the enhanced TEP1-mediated immune response in CLIPA2 knockdown mosquitoes correlated with a significant reduction in fecundity, corroborating the existence of a trade-off between immunity and reproduction. In sum, CLIPA2 is an integral regulatory component of the mosquito complement-like pathway which functions to prevent an overwhelming response by the host in response to systemic infections.

Functional Interaction between Apolipophorins and Complement Regulate the Mosquito Immune Response to Systemic Infections.

The complement-like protein thioester-containing protein 1 (TEP1) is the hallmark effector molecule against Plasmodium ookinetes in the malaria vector Anopheles gambiae. We have previously shown that the knockdown of the noncatalytic clip domain serine protease CLIPA2 increased TEP1-mediated killing rendering mosquitoes more resistant to Plasmodium, bacterial and fungal infections. Here, CLIPA2 coimmunoprecipitation from the hemolymph of Beauveria bassiana-infected mosquitoes followed by mass spectrometry and functional genetic analysis led to the identification of the Apolipophorin-II/I gene, encoding the two lipid carrier proteins Apo-I and II, as a novel negative regulator of TEP1-mediated immune response during mosquito systemic infections. Apo-II/I exhibits a similar RNAi phenotype as CLIPA2 in mosquito bioassays characterized by increased resistance to B. bassiana and Escherichia coli infections. We provide evidence that this enhanced resistance to systemic infections is TEP1 dependent. Interestingly, silencing Apo-II/I but not CLIPA2 upregulated the expression of TEP1 following systemic infections with E. coli and B. bassiana in a c-Jun N-terminal kinase pathway-dependent manner. Our results suggest that mosquito Apo-II/I plays an important immune regulatory role during systemic infections and provide novel insight into the functional interplay between lipid metabolism and immune gene regulation.