Project description:A general understanding of redox homeostasis in An. gambiae midgut epithelial cells under different oxidative conditions during P. falciparum ookinete invasion is missing. We used an ex vivo midgut culture model to understand AgTrx-1 protein expression pattern in An. gambiae midguts under oxidative stress of the ROS inducer, tert-butyl hydroperoxide (tBHP). We then quantified the midgut proteomic expression profile to understand organ-level regulation of the response to oxidative stress. An. gambiae midguts under low (50M) and high (200M) tBHP concentrations were enriched in ribosomal proteins (RPs), consistent with cells undergoing ribosomal/nucleolar stress. Nevertheless, these midguts were also enriched in peptidases, integral membrane proteins, and cytochrome P450s indicating cells that are undergoing protein processing and folding through post-translational modification (PTMs), and detoxification of toxic compounds through active efflux. This response to oxidative stress was strikingly dissimilar to that observed from previous studies with another dipteran, Drosophila following oxidative stress induction. Our data indicates that the response to tBHP induced oxidative stress is mild and suggests that the associated antioxidant response is similar to what is observed during midgut invasion of P. falciparum okinete. Furthermore, our data shows that ribosomal/nucleolar stress is crucial in the regulation of oxidative stress in An. gambiae midguts. Given this importance, its possible to develop mechanisms to perturb this ribosomal/nucleolar stress response in An. gambiae resulting into unmanageable levels of oxidative stress exposure to Plasmodium parasite in the midgut, yet still allowing the mosquito to survive the perturbation. Unmanageable levels of oxidative stress could result to harmful effect to the Plasmodium and eventually its death resulting into halting of its transmission.

Project description:Malaria is caused by Plasmodium parasites, which are transmitted via the bites of infected Anopheline mosquitoes. Midgut invasion is a major bottleneck for Plasmodium development inside the mosquito vectors as a rapidly responding immune system recognizes ookinetes and recruits killing factors from the midgut and surrounding tissues, dramatically reducing the population of invading ookinetes before they can successfully traverse the midgut epithelium. Understanding molecular details of the parasite-vector interactions requires precise measurement of nascent protein synthesis in the mosquito during Plasmodium infection. Current expression profiling primarily monitors alterations in steady-state levels of mRNA, but does not address the equally critical issue of whether the proteins encoded by the mRNAs are actually synthesized. In this study, we used sucrose density gradient centrifugation to isolate actively translating Anopheles gambiae mRNAs based upon their association with polyribosomes (polysomes). The proportion of individual gene transcripts associated with polysomes, which is determined by RNA deep sequencing, reflects mRNA translational status. This approach led to identification of 1017 mosquito transcripts that were primarily regulated at the translational level after ingestion of Plasmodium falciparum-infected blood. Caspar, a negative regulator of the NF-kappaB transcription factor Rel2, appears to be substantially activated at the translational levels during Plasmodium infection. In addition, transcripts of Dcr1, Dcr2 and Drosha, which are involved in small RNA biosynthesis, exhibited enhanced associations with polysomes after P. falciparum challenge. This observation suggests that mosquito microRNAs may play an important role in reactions against Plasmodium invasion. We analyzed both total cellular mRNAs and mRNAs that are associated with polysomes to simultaneously monitor transcriptomes and nascent protein synthesis in the mosquito. This approach provides more accurate information regarding the rate of protein synthesis, and identifies some mosquito factors that might have gone unrecognized because expression of these proteins is regulated mainly at the translational level rather than at the transcriptional level after mosquitoes ingest a Plasmodium-infected blood meal. Midguts from female Anopheles gambiae mosquitoes were dissected at around 24 h after ingestion of P. falciparum-infected blood. Mosquitoes fed on uninfected blood were used as control. A portion of the midguts were used for isolation of total cellular RNA. Extracts of the remaining midguts were fractionated over sucrose density gradients, and fifteen fractions were collected from the top of each gradient. Non-polysomal fractions, as well as polysomal fractions were combined, respectively, to obtain two RNA pools per gradient for three independent experiments. The first, last and the sample between non-polysomal and polysomal, were all discarded to ensure pure pools from each set. A fourth experiment was conducted where the polysomal and non-polysomal samples were not pooled, to be used later for qRT-PCR. The mRNA levels of individual mosquito genes in polysome (PS) fractions, nonpolysome (NP) fractions and unfractionated steady-state (total) RNA were determined using high throughput RNA deep sequencing. Each RNA pool generated 2.1-9.8 million raw read . Signal intensities of transcripts from each PS pool were compared to those of transcripts from a matching NP pool. To quantify the translational status of individual mRNA species, we define the relative PS loading [PL=P/(P+NP)] as the extent of mRNA association with polysomes. PL values were compared between the mosquitoes fed on P. falciparum-infected or -uninfected blood.

Project description:Transmission of malaria is dependent on the successful completion of the Plasmodium lifecycle in the Anopheles vector. Major obstacles are encountered in the midgut tissue, where most parasites are killed by the mosquito’s immune system. In the present study, DNA microarray analyses have been used to compare Anopheles gambiae responses to invasion of the midgut epithelium by the ookinete stage of the human pathogen Plasmodium falciparum and the rodent experimental model pathogen P. berghei. Invasion by P. berghei had a more profound impact on the mosquito transcriptome, including a variety of functional gene classes, while P. falciparum elicited a broader immune response at the gene transcript level. Ingestion of human malaria-infected blood lacking invasive ookinetes also induced a variety of immune genes, including several anti-Plasmodium factors. Keywords: Anopheles gambiae, Plasmodium falciparum, ookinete, invasion, innate immunity

Project description:Transmission of malaria is dependent on the successful completion of the Plasmodium lifecycle in the Anopheles vector. Major obstacles are encountered in the midgut tissue, where most parasites are killed by the mosquito’s immune system. In the present study, DNA microarray analyses have been used to compare Anopheles gambiae responses to invasion of the midgut epithelium by the ookinete stage of the human pathogen Plasmodium falciparum and the rodent experimental model pathogen P. berghei. Invasion by P. berghei had a more profound impact on the mosquito transcriptome, including a variety of functional gene classes, while P. falciparum elicited a broader immune response at the gene transcript level. Ingestion of human malaria-infected blood lacking invasive ookinetes also induced a variety of immune genes, including several anti-Plasmodium factors. By comparing gene expression patterns between carcassess or guts of mosquitoes that fed on a P. falciparum or P. berghei wt and mosquitoes that fed on invasion incapable strains we gain information on the A. gambiae transcriptional responses to the invading ookinete at 24 hours after feeding. By comparing gene expression patterns between carcassess or guts of mosquitoes that fed on a P. falciparum ookinete invasion incapable strain and mosquitoes that fed on non-infected blood we gain information on the A. gambiae transcriptional responses to malaria infected blood in absence of ookinete invasion at 24 hours after feeding. By comparing gene expression patterns between mosquitoes at 4 hours after being injected with either E. coli or S. aureus and mosquitoes injected with sterile PBS we gain information on the mosquito's transcriptional response to these bacterial challenges.

Project description:Malaria inflicts the highest rate of morbidity and mortality among the vector-borne diseases. The dramatic bottleneck of parasite numbers that occurs in the gut of the obligatory mosquito vector provides a promising target for novel control strategies. Using single-cell transcriptomics, we analyzed Plasmodium falciparum development in the mosquito gut, from unfertilized female gametes through the first 20 hours post blood feeding, including the zygote and ookinete stages. This study revealed the temporal gene expression of the ApiAP2 family of transcription factors, and of parasite stress genes in response to the harsh environment of the mosquito midgut. Further, employing structural protein prediction analyses we found several upregulated genes predicted to encode intrinsically disordered proteins (IDPs), a category of proteins known for their importance in regulation of transcription, translation and protein-protein interactions. IDPs are known for their antigenic properties and may serve as suitable targets for antibody or peptide-based transmission suppression strategies. In total, this study uncovers the P. falciparum transcriptome from early-to-late parasite development in the mosquito midgut, inside its natural vector, which provides an important resource for future malaria transmission-blocking initiatives. Single-cell data can be visualized interactively via https://mubasher-mohammed.shinyapps.io/shinyapp/ In-house bash, R code scripts and data that were implemented in this study are available on GitHub https://github.com/ANKARKLEVLAB/Single-cell-P.falciparum-midgut .

Project description:We conducted a genome wide survey of mosquito gene expression profiles in 4 different tissues of adult Anopheles gambiae mosquitoes. The tissues included the head, the midgut, the carcass (corresponding to the remainder of the mosquito after decapitation and midgut removal) and ovaries. Ovaries were collected from adult female mosquitoes, which had been bloodfed 48h prior to dissection. To investigate mosquito expression in those tissues, we performed competitive two-dye hybridizations of experimental and standard reference RNA samples to MMC1 microarrays. MMC1 microarrays contain approximately 20,000 EST clones. Standard reference RNA was produced in vitro from the spotted ESTs and was utilized to provide consistent, non-zero reference values for almost all probes of the array. For the experiment, two biological replicates, corresponding to mosquito generations 1 and 3 (generation 2 was discarded due to probable labelling errors) and one technical (dye-swap) replicate was conducted.

Project description:PP1 is a conserved eukaryotic serine/threonine phosphatase that regulates many aspects of mitosis and meiosis, often working in concert with other phosphatases, such as CDC14 and CDC25. The proliferative stages of the parasite life cycle include sexual development within the mosquito vector, with male gamete formation characterized by an atypical rapid mitosis, consisting of three rounds of DNA synthesis, successive spindle formation with clustered kinetochores, and a meiotic stage during zygote to ookinete development following fertilization. It is unclear how PP1 is involved in these unusual processes. Using real-time live-cell imaging, conditional gene knockdown, RNA-seq and proteomic approaches, we show that Plasmodium PP1 is involved in both chromosome segregation during mitotic exit, and potentially establishment of cell polarity during zygote development in the mosquito midgut, suggesting that chemical inhibitors of PP1 may be explored for blocking parasite transmission

Project description:Morphogenesis of many protozoans depends on a polarized establishment of cortical cytoskeleton possessing the subpellicular microtubules (SPMTs), which are apically nucleated and anchored by the apical polar ring (APR). In the malaria parasite Plasmodium, APR can be observed when a round zygote differentiates to a crescent motile ookinete for mosquito midgut infection. So far, the fine structure and molecular components of APR as well as the underlying mechanism of APR-mediated apical positioning of SPMTs are largely unknown. Here, we report that a previously undescribed MT-binding protein APR2 localizes at APR and associates directly with apical SPMTs throughout ookinete morphogenesis. We resolve an unprecedented APR structure composed of a top ring plus approximate 60 radiating spines, with each spine fitting with an individual SPMT. APR2 disruption impairs ookinete morphological development and gliding motility, leading to failure of mosquito transmission of Plasmodium. The APR2-deficient ookinetes display defective apical anchorage of APR and SPMT due to the impaired integrity of APR. Using proximity labeling with APR2 as bait, we obtain a Plasmodium ookinete APR proteome for the first time and validate 10 new APR proteins. Among the proteins, APRp2 and APRp4, directly interacting with APR2, also mediate the apical anchorage of SPMTs. This study sheds light on the molecular basis of APR in the organization of SPMTs essential for ookinete morphogenesis and mosquito transmission of Plasmodium.

Project description:Overall, the study aims at obtaining a comprehensive picture of the African malaria mosquito, Anopheles gambiae, transcriptome using high-coverage RNA-seq of sexed whole-insect samples collected at different developmental time points. This experiment focuses on transcriptomes of 4 h, 10 h and 20 h old male and female pupae.

Project description:Salivary glands are the only mosquito tissue invaded by Plasmodium sporozoites being a key stage for the effective parasite transmission and maturation, making knowledge regarding Anopheles sialome highly relevant to understand this process. In this study, we report for the first time a transcriptomic analysis using RNA-seq of An. gambiae infected by P. berghei.