Project description:Mosquito saliva facilitates blood feeding through the anti-haemostatic, anti-inflammatory and immunomodulatory properties of its proteins. However, the potential contribution of non-coding RNAs to host manipulation is still poorly understood. We analysed small RNAs from Aedes aegypti saliva and salivary glands and show here that chikungunya virus-infection triggers both the siRNA and piRNA antiviral pathways with limited effects on miRNA expression profiles. Saliva appears enriched in specific miRNA subsets and its miRNA content is well conserved among mosquitoes and ticks, clearly pointing to a non-random sorting and occurrence. Finally, we provide evidence that miRNAs from Ae. aegypti saliva may target human immune and inflammatory pathways, as indicated by prediction analysis and searching for experimentally validated targets of identical human miRNAs. Overall, we believe these observations convincingly support a scenario where both proteins and miRNAs from mosquito saliva are injected into vertebrates during blood feeding and contribute to the complex vector-host-pathogen interactions.

Project description:Background: Anopheles culicifacies is a rural vector of malaria in tropical and sub tropical South East Asian region. The salivary gland of the mosquito is the target for sporozoite interaction, blood feeding behavior, haemostasis and vector-parasite interactions. Malaria parasite matures inside the salivary gland, gain competence and transmitted to the host along with the saliva during biting. The importance of the proteins expressed in salivary gland is the first step in understanding the physiology of blood feeding and may provide insights into vector- parasite interactions. Since, no genomic or transcriptomics information is available of Anopheles culicifacies, therefore locally expressed functional proteins in salivary glands are of much importance. . Method: In this study, 1DE protein and in solution digestion was combined with tandem mass spectrometry (nano LC-MS/MS) and computational bioinformatics for data mining was employed to study the proteome profile of salivary glands of sugar fed An. culicifacies mosquito species. Functional annotation of all the identified proteins was carried out using gene ontology tools, CELLO and SMART analysis software. Results: Total 102 proteins were identified and analysed by SEQUEST algorithm against mosquito protein database from Uniprot/NCBI. Out of which 81 proteins were identified using gel free approach and 21 proteins using in-gel approach and 15 were common among these two approaches. All the identified proteins were categorized in to 23 groups of biological processes using GO tool. 7 proteins were depicted to be secretary in nature by investigating the signal peptide present. Potential proteins with unknown function were predicted by analyzing their functional association with other characterized proteins by STRING algorithm and were categorized in cell adhesion, cytoskeleton and membrane trafficking networks. Conclusion: Our study elucidates the first proteomic dataset of An. culicifacies salivary gland proteins. Functional annotation of salivary proteins and complementary gene ontology assignments in An. culicifacies species may contribute towards understanding the complex physiology of the tissues in this species. This proteome baseline data may facilitate the discernment of salivary glands and parasite correlation during blood feeding. Furthermore, this mass spectrometry based proteomic data may also provide insights into the elucidation of role of differential functional proteins present in refractory An. culicifacies mosquito and may be useful for development of effective malaria control strategies.

Project description:Here, we challenged rabbits with repeated feeding of Ixodes ricinus adults and observed the formation of specific antibodies against several tick salivary proteins. To identify the salivary antigens, isolated immunoglobulins from repeatedly infested rabbits were utilised for a pull-down from the saliva of pilocarpine-treated ticks. Eluted antigens were separated on 1D SDS-PAGE and analysed by peptide mass fingerprinting. To increase the authenticity of immunogens identified, we also performed, for the first time, de novo assembly of the sialome from I. ricinus females fed for six days, a timepoint used for pilocarpine-salivation.

Project description:Blood feeding is an integral process of the malaria vector Anopheles required for its physiological functions and its propagation. During blood feeding, presence of the malaria parasite, Plasmodium in the blood induces several host effector molecules including microRNAs which play important roles in the development and maturation of the parasite within the mosquito. The present study was undertaken to elucidate the dynamic expression of miRNAs during gonotrophic cycle and parasite development in Anopheles stephensi.For this purpose, miRNA microarray was done in sugar fed, 42 hours post blood fed and 42 hours post infected blood fed female mosquitoes to identify regulated miRNAs under these conditions.

Project description:Blood feeding is an integral process of the malaria vector Anopheles required for its physiological functions and its propagation. During blood feeding, presence of the malaria parasite, Plasmodium in the blood induces several host effector molecules including microRNAs which play important roles in the development and maturation of the parasite within the mosquito. The present study was undertaken to elucidate the dynamic expression of miRNAs during gonotrophic cycle and parasite development in Anopheles stephensi.For this purpose, small RNA sequencing was done in sugar fed, 42 hours and 5 days post blood fed and infected blood fed female mosquitoes to identify regulated miRNAs under these conditions.

Project description:Ascertain the transcriptional response of the major malaria vector Anopheles coluzzii to aging over 4 time points.

Project description:Salivary gland proteins of Anopheles mosquitoes offer attractive targets to understand interactions with sporozoites, blood feeding behavior, homeostasis and immunological evaluation of malaria vectors and parasite interactions. To date limited studies have been carried out to elucidate salivary proteins of An. stephensi salivary glands. The aim of the present study was to provide detailed analytical attributives of functional salivary gland proteins of urban malaria vector An. stephensi. A proteomic approach combining one-dimensional electrophoresis (1DE), ion trap liquid chromatography mass spectrometry (LC/MS/MS) and computational bioinformatic analysis was adopted to provide the first direct insight into identification and functional characterization of known salivary proteins and novel salivary proteins of An. stephensi. Computational studies by online servers namely, Mascot and OMSSA algorithms identified a total of 36 known salivary proteins and 123 novel proteins analysed by LC/MS/MS. This first report describes a baseline proteomic catalogue of 159 salivary proteins belonging to various categories of signal transduction, regulation of blood coagulation cascade, and various immune and energy pathways of An. stephensi sialo-transcriptome by mass spectrometry. Our results may serve as basis to provide a putative functional role of proteins into concept of blood feeding, biting behavior and other aspects of vector-parasite host interactions for parasite development in anopheline mosquitoes.

Project description:Ascertain the transcriptional response of the major malaria vector Anopheles coluzzii to the pyrethroid deltamethrin over ten time points.

Project description:We developed a new simple method to assess the composition of proteins in the Ornithodoros moubata saliva. To collect naturally expectorated saliva from the ticks, we employed an artificial membrane feeding technique using a simple, chemically defined diet and submitted the collected native saliva samples for liquid chromatography-mass spectrometry (LC-MS) analysis. These experiments were conducted with groups of uninfected ticks as well as with B. duttonii infected ticks. The ticks exhibited a fair feeding response to the tested diet, engorgement rates reaching between 60-100% of ticks per feeding chamber. LC-MS analysis identified a total of 17 and 15 proteins in saliva samples from the uninfected and infected ticks respectively. Importantly, the analysis was sensitive enough to detect up to 9 different proteins in the saliva containing diet upon which as few as 6 nymphal ticks fed. Some of the proteins identified are well known for their immunomodulatory activity in a vertebrate host, whereas others were structural or “housekeeping” proteins and their finding in the naturally expectorated saliva confirms that they can be secreted and having some roles at the tick-host interface. Most notably, some of the proteins that have long been suspected as important for vector-pathogen interactions of Borrelia spirochetes were detected only in the samples from infected ticks, suggesting that their expression was altered by the persistent colonization of the tick’s salivary glands by spirochetes. The simple method described herein is an important addition to the toolbox available to study the vector-host-pathogen interactions in the rapidly feeding soft ticks.

Project description:In addressing R. microplus - A. marginale interactions, we propose and test three linked hypotheses. The first is that the tick gene response is organ specific: the midgut gene regulation is unique during feeding and during acquisition of A. marginale as compared to the salivary gland. This distinction is relevant as the two organs serve very different roles in the transmission biology of A. marginale with early survival and replication within the midgut epithelium, composed of highly phagocytic cells, required for initial colonization while a second round of replication in the salivary gland acini, composed of highly secretory cells, is required for transmission of an infectious dose in the saliva. Importantly, both the midgut epithelium and salivary glands have been identified as separate and distinct barriers for transmission of A. marginale and thus represent two potential sites where transmission could be blocked. The second hypothesis to be tested is that the salivary gland transcriptome is temporally dynamic. Initiation of tick attachment and feeding involves secretion of a virtual pharmacopeia including lytic enzymes, anticoagulants, and inhibitors of the mammalian innate immune and nocioceptive systems. Concomitantly, the acini provide an environment where A. marginale replicates >100 fold and are secreted into the saliva. Prior studies show that duration of feeding is a critical component of transmission efficiency, with increased efficiency positively correlated with time of tick feeding. The third hypothesis to be tested is that A. marginale colonization does not significantly modulate the tick midgut and salivary gland transcriptome. This hypothesis is based on observations by ourselves and others that tick infection does not impart a significant fitness cost on the vector. This is in contrast to other bacterial and protozoal pathogens that have dramatic effects on success of tick attachment, engorgement, and survival. A. marginale, similar to other tick-borne pathogens in the Family Anaplasmataceeae, is believed to have evolved from an arthropod-specific bacterium with relatively late adaptation to specific niches in mammalian hosts. Consequently, we predict that A. marginale is well adapted to its tick vector and utilizes the normal signaling pathways of the feeding tick with few, if any, effects on the midgut and salivary gland transcriptome. In this manuscript, we report the testing of these three hypotheses and present the results in context of the vector-pathogen-mammalian host interaction at the time of transmission. A Roche NimbleGen high-density gene expression microarray was custom designed based on the expressed sequence tag (EST) database, B. microplus Gene Index Version 2 (BmiGI V2) for R. microplus. The expression level of 14,447 R. microplus genes was analyzed from total RNA extracted from 10 different tick tissue samples; 30 arrays were included since triplicates of each different sample were analyzed as follow: unfed (midgut and salivary glands), blood feeding (2 days midgut and 2, 6 and 9 days salivary glands), A. marginale-infected blood feeding (2 days midgut and 2, 6 and 9 days salivary glands).