Abstract
Malaria parasites transmitted by mosquito bite are remarkably efficient in establishing human infections. The infection process requires roughly 30 minutes and is highly complex as quiescent sporozoites injected with mosquito saliva must be rapidly activated in the skin, migrate through the body, and infect the liver. This process is poorly understood for Plasmodium vivax due to low infectivity in the in vitro models. To study this skin-to-liver-stage of malaria, we used quantitative bioassays coupled with transcriptomics to evaluate parasite changes linked with mammalian microenvironmental factors. Our in vitro phenotyping and RNA-seq analyses revealed key microenvironmental relationships with distinct biological functions. Most notable, preservation of sporozoite quiescence by exposure to insect-like factors coupled with strategic activation limits untimely activation of invasion-associated genes to dramatically increase hepatocyte invasion rates. We also report the first transcriptomic analysis of the P. vivax sporozoite interaction in salivary glands identifying 118 infection-related differentially-regulated Anopheles dirus genes. These results provide important new insights in malaria parasite biology and identify priority targets for antimalarial therapeutic interventions to block P. vivax infection.
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Introduction
Malaria infections are initiated when a Plasmodium-infected Anopheles mosquito bites a mammalian host, injecting saliva-laden sporozoites into the skin1,2,3,4,5. Before transmission, salivary gland sporozoites can remain in a quiescent state for days to weeks under ideal environmental conditions. However, once sporozoites are injected into the skin, a just-in-time activation of molecular processes and induction of gene expression stimulates a remarkably efficient process whereby sporozoites make a ‘mad dash’ to reach the liver and infect hepatocytes6. The initial sporozoite activation appears to be linked to the drastic changes in the newly encountered microenvironment, such as change in pH, temperature, amino acids, and serum proteins, especially albumin7,8,9. However, replicating the in vivo infection processes in the laboratory is inherently difficult as studies typically begin with isolation of sporozoites through dissection of salivary glands thus resulting in dramatically reduced sporozoite infection rates in cultured hepatocytes compared to infections initiated by direct mosquito bite10.
Activation in the skin represents the initial phase of the malaria infection process and it is thought that sporozoites are progressively activated by refined cellular mechanisms to recognize and then respond to extrinsic microenvironmental factors for motile migration, cell traversal, and ultimately hepatocyte invasion11,12,13. A better understanding of the molecular activations that occur during infection should help improve in vitro systems to more closely reflect in vivo outcomes. Sporozoite motility in the skin is important for parasites to rapidly enter human blood vessels enabling transport to the liver sinusoid by blood circulation. Once in the liver, sporozoites rely on cell traversal to passage through and eventually invade a host hepatocyte14,15. While entry into the circulatory system can be immediate, studies have shown accumulation of sporozoites at the injection site for up to 42 hours with almost half of the inoculation present after 3 hours1,2,16. Consistent with the just-in-time requirement for sporozoite activation, prolonged in vitro exposure of Plasmodium falciparum sporozoites to human body temperature, serum proteins, primary human hepatocytes (PHHs), or human skin keratinocytes have been shown to prematurely transform sporozoites to early liver-stage parasites leading to reduction in sporozoites infectivity9,17.
Plasmodium vivax, the focus of this study, is less well-characterized but is the widest geographically-distributed malaria parasite placing over 2.85 billion people at risk of infection18,19,20,21. Unlike other human malarias, P. vivax has a unique fundamental biological feature where the parasite can remain clinically dormant as a hypnozoite inside the liver until unknown reactivation mechanisms cause relapse to blood-stage22,23. Recently, there has been a renewed interest in P. vivax due to reports of P. vivax dominance in areas previously dominant for P. falciparum and the prevalence of both asymptomatic and sub-microscopic parasite carriers24,25,26,27. However, the inability to maintain continuous in vitro blood-stage culture in the laboratory causes sporozoites usage for studies on P. vivax vector interactions and liver-stage biology to primarily rely on resource-intensive mosquito infections from clinical isolates. Therefore, a critical need exists to improve efficiency of sporozoite usage to support studies on the unique biology of this neglected malaria parasite, especially to develop new interventions to prevent relapse from dormant liver-stage parasites.
There are more than 400 anopheline mosquito species in the world with over 40 known as dominant vectors for malaria-causing Plasmodium species28. Anopheles mosquito vectors are more permissive to P. vivax gametocyte infection than P. falciparum showing highly effective transmission rates in far more diverse climates20,29. In continental Southeast (SE) Asia, 19 dominant vector species are present, where Anopheles dirus sensu lato (s.l.) (Dirus Complex), An. minimus s.l. (Minimus Complex), and An. sundaicus s.l. (Sundaicus Complex) present as the three most competent malaria vectors. Within the Dirus complex, An. dirus (An. dirus sensu stricto) is historically the dominant malaria vector in Thailand, Laos, Cambodia, and Myanmar feeding primarily on humans with suitable adaption to human-induced environmental changes30. New approaches for entomological malaria transmission metrics are needed for elimination, particularly in regions with diverse vectors and low parasite densities31. Identifying P. vivax or vector-specific biomarkers in mosquito saliva would improve estimates of transmission variables, and such biomarkers may also serve as targets for transmission interruption32,33.
In this study, we report progressive gene activation in P. vivax sporozoites in response to microenvironmental stimuli that mimic host factors encountered when transitioning from mosquito to mammal. Effects on sporozoites by modification of the microenvironment were assessed using biometric measurements from in vitro functional assays targeting sporozoite motility and invasion of PHHs. These functional assays paired with RNA-seq reveal changes in gene expression associated with sporozoite infectivity and initiation of early liver-stage parasite development. Most importantly, we demonstrate that strategic manipulation of the sporozoite microenvironment can significantly enhance sporozoite in vitro infectivity for cultured hepatocytes. Furthermore, using our salivary gland isolation techniques we identified transcriptional signatures in the An. dirus mosquito harboring P. vivax sporozoites implicating dynamic biological variables that may affect transmission of P. vivax. Overall, this study reveals rapid transcriptional changes in P. vivax sporozoites in response to host-like stimuli as well as in the An. dirus mosquito vector that are important regulators affecting infectivity and transmission.
Results
Selection of media and study design to emulate insect and human host-like microenvironment
The microenvironment composition was selected based on media components previously determined to resemble mosquito and human host-like environments that salivary gland sporozoites encounter upon transmission34,35. Schneider’s insect media (pH 7) was used to mimic the mosquito microenvironment whereas incomplete RPMI 1640 media with the addition of 3% (w/v) of bovine serum albumin (BSA) represented the human microenvironment (Supplementary Table S1). Our study design focused on the serum protein albumin as it is the most abundant (>50%) of total serum proteins and has important roles in transport as well as modulating osmotic pressure36. Additionally, previous studies have shown that addition of albumin significantly contributes to sporozoite activation8,35. Further, we used BSA rather than human serum albumin as they are chemically similar, and to avoid serum-donor bias and non-specific protein binding. In total, four different buffered media compositions were tested including RPMI (B1), RPMI + 3% BSA (B2), Schneider’s (B3), and Schneider’s + 3% BSA (B4) (Fig. 1a).
In order to recapitulate the sporozoite’s transitional journey from vector to host, our study design considered initial time zero (0 h) immediately after salivary gland isolation (manual dissection) with subsequent 4 h post-dissection incubations at two different temperatures, room temperature (RT) or 37 °C (Fig. 1a). We hypothesized that the prolonged 4 h post-dissection sampling would capture sporozoite gene expression specific to the microenvironment in which the sporozoite was maintained. For instance, transformation into early liver-stage parasites when held in a human-like microenvironment, as previously shown in Kaiser et al.17, or preservation of a quiescent transcriptional state when maintained in an insect-like microenvironment. Additionally, the 4 h post-dissection samples at RT or 37 °C were used to investigate the effect on the sporozoite when exposed to temporal temperature shift. Further, our salivary gland isolations typically consisted of 10–20 mosquitoes per microenvironment condition and required no additional sporozoite purification, reducing sample manipulation. Lastly, P. vivax salivary gland sporozoites (PvSGSs) in the various microenvironment conditions were phenotypically assessed at each time point using in vitro assays measuring percent gliding motility and invasion rate of PHHs (Fig. 1a).
All P. vivax patient isolate-derived samples (48 total) were analyzed for expression of genes showing low experimental variation indicated between replicates (Supplementary Fig. S1a). These samples collected for RNA-seq included 5 biological replicates (patient isolates) for 0 h post-dissection, 3 biological replicates at 4 h post-dissection kept at RT, and 4 biological replicates at 4 h post-dissection kept at 37 °C. The quantified transcript abundance of PvSGS-infected samples showed a mean of 14% ± 9% (± standard deviation.) mapped to P. vivax reference genome P01 (PlasmoDB, version 34), a mean of 50% ± 12% mapped to the WRAIR2 An. dirus reference genome (Vectorbase, VB-2018-02, AdirW1.7), and a mean of 36% ± 5% of unmapped reads (mean transcript count ≥20 FPKM) (Supplementary Fig. S1b). We achieved very high coverage of the P. vivax genome, where approximately 10–30% of the total reads (on average half a million malarial parasite reads per sample) are mapped back to the P. vivax reference sequences covering over 4000 genes with high confidence, confirming the high-quality preparation of our samples. Furthermore, an average of 70% of RNA transcripts detected from PvSGS samples and uninfected salivary gland controls mapped to An. dirus reference genome with, >93% of transcripts mapped to salivary gland-associated genes previously identified from an An. gambiae proteomic study37 (Supplementary Fig. S1c).
Sporozoite transcriptome signatures linked to host microenvironments
Initially, sporozoite transcripts were identified through a comprehensive comparison of our sporozoites transcriptome to datasets previously published for P. vivax blood-stages38. We identified 3,510 up-regulated genes and 1,923 down-regulated genes in the sporozoite stage compared to blood-stages, of which 903 genes were identified as specific to sporozoites (Supplementary Fig. S2 and Supplementary Data S2). As a comparison of sporozoite to blood-stage gene expression across species, we additionally examined previously generated sporozoites transcriptome data from P. falciparum39,40, P. vivax41, and P. yoelii42 (Fig. 1b). The datasets were re-normalized to a scale from 1 to 100, and similarity was calculated using a non-parametric method (Kendall’s Tau). There are overall similarities between sporozoites data across different species with a conserved set of highly expressed genes, such as Cell Traversal protein for Ookinetes and Sporozoites (CelTOS) and Circumsporozoite Protein (CSP) (Fig. 1c). The overall correlation of transcriptome expression is stronger between the same stage of different species (i.e., sporozoite vs. sporozoite) than the correlation between different stages of the same species (i.e. oocyst or hypnozoite) (Fig. 1b).
Coupling our in vitro sporozoite bioassays allowed us to categorize sporozoite genes into three phenotype conditions: (i) quiescent; (ii) invasion-activated; and (iii) early liver-stage (Fig. 2a and Supplementary Data S3). Genes preferentially expressed in salivary glands at RT in insect media without mammalian serum components (BSA) defined the quiescent phenotype. These quiescent-state genes were identified as genes most highly expressed in unperturbed PvSGSs by multiple pairwise comparisons of different microenvironment activators between the key insect-like and mammalian-like variables, including temperature (37 °C vs RT °C, log2FC < −1, P (p value) ≤ 0.05) (Supplementary Data S4) and insect or mammalian media (with or without BSA, log2FC < −2, P ≤ 0.05) (Supplementary Data S5). High transcript abundance implicated gliding motility proteins such as TRAP-like protein (TLP) and others (e.g., ROM1) as representative of the quiescent stage. Invasion-activated genes, which were genes preferentially expressed in the early phase (4 h vs. 0 h, log2FC < −2, P ≤ 0.05, Supplementary Data S6) and induced by BSA, included > 100 invasion- and motility-related genes (RPMI +3% BSA, 0 h vs. RPMI +3% BSA, 4 h, 37 °C, log2FC < −2, P ≤ 0.05, Supplementary Data S7). Many leading and attempted vaccine candidates are included in the invasion group, such as CelTOS, Apical Membrane Antigen 1 (AMA1) and Thrombospondin-related Adhesive Protein (TRAP). Finally, the early liver-stage is represented by genes with enriched expression at core human body temperature 37 °C (4 h, 37 °C vs. 4 h, RT, log2FC > 2, P ≤ 0.05, Supplementary Data S8). The early liver-stage is also the largest group, representing a major transcriptome shift when the motile parasite transitions to the intracellular microenvironment and initiates liver-stage parasite development. As expected for intracellular developmental requirements, several hundred up-regulated genes are related to protein biosynthesis, fatty acid synthesis, and mitochondrial function. To analyze these important parameters in our experimental setup, i.e. elapsed time (0 h and 4 h), host temperature shifts (RT and 37 °C), and host chemical environment change (with and without BSA), we calculated the overall transcriptome shift as indicated by Pearson’s r between different experimental conditions. We used the transcriptomes of freshly-dissected sporozoites (0 h post-dissection) as a baseline of comparison and calculated the similarities between 4 h post-dissection with varying BSA and 37 °C conditions. We found a large overall change of transcriptome induced by temperature, with an r decrease to 0.2, when the parasite is maintained at 37 °C. The most significant transcriptome change occurred when both BSA and 37 °C are combined, with an r decrease of 0.3 to 0.5 (Fig. 2b).
An insect-like microenvironment improves sporozoite vitality and hepatocyte invasion
To define the most suitable conditions to sustain viability and infectivity of freshly-dissected PvSGSs, pH and time were experimentally assessed using dissection into Schneider’s insect media in comparison to RPMI. For all experiments, sporozoite viability and infectivity were measured using in vitro assays of sporozoite invasion of cultured PHHs and quantification of development of liver-stage parasites after 6–8 days post-infection. Collection of freshly dissected PvSGSs into Schneider’s, pH 4 adversely affected sporozoite viability, resulting in no hepatocyte invasion and liver-stage parasite development, whereas Schneider’s, pH 7 resulted in the highest rates of PHH infection and liver-stage parasite development (3-fold higher than RPMI) (Supplementary Fig. S3a). When collected PvSGSs were maintained for 24 hours (at 4 °C or RT), only PvSGSs in Schneider’s, pH 7 or Schneider’s +3% BSA, pH 7 retained the ability to invade hepatocytes showing a ~2-fold increase in liver-stage parasites when the PvSGSs were maintained at RT (Supplementary Fig. 3b). These studies demonstrated that sporozoites-infected salivary glands collected into Schneider’s, pH 7 are most efficient for hepatocyte infection, and these conditions are capable of maintaining sporozoite viability for at least 24 hours. The media Schneider’s, pH7 was thus selected as the insect-like environment for our RNA-seq study and is referred to as “Schneider’s” hereafter.
The PvSGSs samples collected for RNA-seq were also simultaneously subjected to bioassays measuring sporozoite motility and invasion of PHHs. We found PvSGSs exposed to Schneider’s insect media showed a prolonged gliding motility phenotype across all time points (>60%) in comparison to RPMI which had a large reduction to <10% gliding after time 0 (Fig. 3a–e and Supplementary Fig. S4). Also, significant differences in infectivity and liver-stage parasite development resulted from exposure to the different microenvironments (Fig. 4a–d). Of highest importance, PvSGSs dissected into Schneider’s with subsequent addition of serum-containing hepatocyte culture media (HCM) at the time of hepatocyte infection produced superior PHH infection rates with complete development of day 8 liver-stage schizonts and hypnozoites. At 0 h post-dissection, PvSGSs collected in Schneider’s were inoculated in PHHs at 5 × 103 sporozoites per well generating an average of 269 ± 91 liver-stage parasites per well of a 384-well plate, which is greater than a 2-fold increase over collection media RPMI of 115 ± 30 liver-stage parasites (Fig. 4b). Similarly, at 4 h post-dissection, 37 °C only PvSGSs in Schneider’s and Schneider’s + BSA mediums successfully infected PHHs (Fig. 4d). Immunofluorescence staining of the parasitophorous vacuole membrane (PVM) biomarker Upregulated in Infective Sporozoites 4 (UIS4) and active glycolysis biomarker Glyceraldehyde 3-Phosphate Dehydrogenase (GAPDH) were used to identify liver-stage parasites and distinguish between developing schizonts and hypnozoites (Fig. 4e–f)43. All liver-stage parasites were imaged, classified, and quantified on a high-content imaging system (Operetta, Perkin Elmer) following an established methodology previously described44.
Identification of genes involved in sporozoite quiescent state
To discover the molecular metabolic activities of the sporozoite quiescent state, differentially expressed genes were identified between insect-like sporozoites at 0 h, (Schneider’s, RT) with environmentally activated sporozoites (4 h post-dissection, RPMI + 3% BSA, 37 °C). Transcriptome profiling revealed 197 genes down-regulated upon entry into the human-like environment with the highest annotated differentially expressed genes summarized in Table 1. Of the 197 differentially expressed genes, 74 are unknown with the remaining 123 having annotated sporozoite-associated roles (Supplementary Data S3). Familiar annotated proteins expressed include the cell traversal proteins Gamete Egress and Sporozoite Traversal protein (GEST), Sporozoite Protein Essential for Cell Traversal 1 (SPECT1), CelTOS, and the motility/invasion related proteins Thrombospondin-Related Adhesive Protein (TRAP), TRAP-like Protein (TLP,) Thrombospondin-Related Sporozoite Protein (TRSP), CSP, Secreted Protein with Altered Thrombospondin Repeat domain (SPATR), and profilin (PFN). Notably, our differential-expression analysis revealed genes involved in intracellular calcium signaling cascades, including Calcium-Dependent Protein Kinase (CDPK) 4, centrin (CEN) 2, and CDPK6, indicating proteins are maintained by sporozoites prior to stimulation from the mammalian host (Fig. 2c) (FPKM ≥ 20, log2FC ≥ 1, P ≤ 0.05). Further, our results implicate genes with unexplored but hypothesized roles in sporozoites such as the recently characterized proteolytic cascade in P. falciparum blood-stage involving Plasmepsin X (PMX), subtilisin 2 (SUB2), and AMA1 used for invasion (FPKM ≥ 20, log2FC ≥ 1, P ≤ 0.05)45. In total, we identified 74 genes with unknown functions that we predict may have a role in the sporozoite pre-invasive, quiescent state. Among the top most highly expressed were PVP01_0943600, PVP01_0210600, and PVP01_0319000 (FPKM ≥ 20, log2FC ≥ 2, P ≤ 0.05) (Supplementary Data S3).
The function of the Plasmodium apicoplast is indispensable for the parasites survival, but the organelle’s function is not fully defined. The Suf family is one of the four known pathways for Fe-S cluster biogenesis and is believed to provide the Fe-S clusters to many proteins functional in the apicoplast, including proteins involved in the isoprenoids biosynthesis pathway. Our analysis indicated an increased abundance of apicoplast genes, suggesting the organelle may have a role in both quiescent sporozoites (SufE) and early liver-stage parasite formation. To validate RNA-seq data, four genes of the Suf family (SufE, SufA, SufS, SufC) and the most conserved protein of the isoprenoid pathway (IspD)46 were analyzed by qPCR (n = 2) which confirmed SufE and SufS are actively expressed (Supplementary Fig. S5a). Further, high-resolution fluorescent microscopy of P. vivax sporozoites using mouse immune sera raised against proteins SufS and SufE stained positive for SufS in a single sporozoite organelle, similarly to an Acyl Carrier Protein (ACP) control with known localization to the apicoplast. Alternatively, SufE had a diffused staining pattern with localization in multiple sporozoite organelles (Supplementary Fig. S5b). These data indicate the potential importance of this pathway during sporozoite and liver-stages, warranting further investigation.
Lastly, to provide biological insight into processes involved in sporozoite quiescence, we performed an enrichment analysis of the identified differentially expressed genes using respective functional annotation in the Gene Ontology (GO) and KEGG databases (Fig. 2d)47,48. In total, 4 cellular-components GO-terms were enriched: cell surface (n = 12), microneme (n = 8), cell periphery (n = 6), and osmiophilic body (n = 3) (P ≤ 0.05) (Fig. 2d). Further, >40% of differentially expressed genes were enriched in molecular functions involving catalytic activity, including transferase activity (n = 30), metal ion binding (n = 20), protein kinase (n = 10), oxidoreductase activity (n = 10), lyase activity (n = 6), iron-sulfur cluster binding (n = 4), and anion transmembrane transport activity (n = 2) (P ≤ 0.05) (Fig. 2d). Biological process GO-terms including locomotion (n = 7), phosphorylation (n = 12), macromolecule modification (n = 22) were enriched (P ≤ 0.05) (Fig. 2d). Moreover, 8 genes were found to participate in carbon-fixation pathways in prokaryotes (ec00720) and the citrate cycle (TCA) (ec00020).
Quiescent sporozoites are activated by human serum components
The PvSGSs samples from 0 h were used to compare all buffered mediums to identify PvSGS genes triggered by induction to the mammalian-like environment. A total of 16 up-regulated genes were differentially expressed upon BSA activation summarized in Table 2. The results showed 11 annotated genes with the intracellular calcium cascade modulator CDPK1 most highly expressed followed by sporozoite surface protein 3 (SSP3), ADP-ribosylation factor GTPase-activating protein (APH), sporozoite surface protein essential for liver stage development (SPELD), syntaxin (SYN17), ADP-ribosylation factor GTPase-activating protein (ARFGAP), and rho GTPase-activating protein (PVP01_0806900) (FPKM ≥ 20, log2FC ≥ 1, P ≤ 0.05). Our bioassays suggest phenotypic associations with these differentially expressed genes, showing a mean of 96% ± 2% PvSGSs gliding in RPMI + 3% BSA compared to 78% ± 22% in RPMI at 0 h post-dissection, 37 °C (P < 0.0001) (Fig. 3a,e). Furthermore, BSA activation extends PvSGSs gliding motility at both RT and 37 °C (65% ± 43% and 60% ± 48%). In comparison, virtually no gliding was evident in RPMI (9% ± 11% and 0.5% ± 0.9%); apparent arrest of sporozoite migration and transformation into liver-stage parasites were marked by early PVM formation (Fig. 3b,d,e and Supplementary Fig. S3). Importantly, activation of PvSGSs by the mammalian environment or with addition of BSA impeded sporozoite ability to invade PHHs as shown by a drastic reduction in liver-stage parasite developmental rates (Fig. 4a–d). At 0 h post-dissection, PvSGSs collected in RPMI + 3% BSA or Schneider’s + 3% BSA had an average of 75 ± 10 or 77 ± 11 liver-stage parasites per well, respectively (Fig. 4b).
Specific human factors induce sporozoite transition into an early liver-stage parasite
After a sporozoite invades the host hepatocyte, formation of a PVM ensues for transition into a highly metabolically-active intracellular liver-stage parasite preparing for rapid replication. To explore the early liver-stage parasite transcriptomic profile, an analysis of differentially expressed genes was performed using our PvSGSs exposed to the mammalian-like environment (4 h post-dissection, 37 °C). We identified 518 differentially expressed genes noting 30 highly abundant annotated differentially expressed genes in Table 3 (Supplementary Data S3). Interestingly, the ookinete surface protein p25 (Pvs25), potentially a false-positive, followed by the Parasitophorous Vacuole protein 1 (PV1) showed the highest differential expression with temperature change and BSA induction. Another intriguing find was the expression of Sortilin, recently characterized in P. falciparum asexual blood-stage as a transmembrane protein involved in protein trafficking to rhoptries of the apical complex, suggesting a role in the sporozoites secretory system during and after host hepatocyte invasion49,50. Additional genes implicated in initial liver-stage parasite development include Liver Stage Associated Protein 1 (LSAP1), Sporozoite Invasion-Associated Protein 2 (SIAP2) and four PVM-associated genes (PVP01_0504800, PVP01_1271000, PVP01_073480, PVP01_0602100) termed Early-Transcribed Membrane Proteins (ETRAMPs), and UIS4. Activation of sporozoite intracellular calcium signaling cascades in response to the mammalian microenvironment was evident with increased abundance of calmodulin, CDPK7, protein kinase 4 (PK4), and Receptor of Activated Protein C Kinase 1 (RACK1). Our results also support recent reports that heat shock proteins (HSP) are critical for liver-stage parasite development as HSP70, HSP70-2, HSP90, and PVP01_1405400 were amongst the highest differentially expressed genes51. In order to rapidly transition between pivotal life-cycle stages, Plasmodium uses translational repression to regulate pre-transcribed mRNA stockpiles that encode required proteins. Our analysis of differentially expressed genes revealed high expression of known translational regulators ALBA-152, ALBA-2, and ALBA-453 indicating these genes as potential global regulators of developing liver-stage parasites (FPKM ≥ 20, log2FC ≥ 2, P ≤ 0.05).
A GO enrichment analysis indicated differentially expressed genes in the sporozoite transition into early liver-stage parasites are enriched in biological processes including translation (n = 74), ribosome biogenesis (n = 14), cellular macromolecular complex assembly (n = 14), and chromosome organization (n = 6) (P ≤ 0.05) (Fig. 2e). In terms of cellular components, a majority of genes are associated with the ribosome (n = 64), nucleus (n = 46), and cytosol (n = 56) (P ≤ 0.05) (Fig. 2e). Significantly enriched molecular functions GO-terms included nucleic acid-binding (n = 93), RNA-binding (n = 46), and structural constituent of ribosome (n = 62) (P ≤ 0.05) (Fig. 2e). Of the KEGG pathways, 4 genes were identified in the pentose phosphate pathway (ec00030), as well as 4 genes involved in carbon fixation in photosynthetic organisms (ec00710).
Characterization of the Anopheles dirus salivary gland transcriptome
Experimental PvSGS-infected An. dirus samples and uninfected An. dirus salivary gland controls were analyzed for expression of genes on day 14 (post-blood meal). Transcriptome analysis showed similar expression levels for salivary gland proteins in all samples including salivary gland protein 6 (SGP6), D7 long-form salivary protein, salivary gland protein 1-like, and TRIO salivary gland protein (Supplementary Data S9). The top expressed known gene encoded was anopheline antiplatelet protein (AAPP), which is secreted by blood-feeding females to block platelet adhesion to collagen and prevent aggregation54. To explore the transcriptome of PvSGS-infected An. dirus salivary glands, differentially expressed genes were compared between infected and uninfected salivary glands. The results showed 71 genes up-regulated and 47 genes down-regulated differentially expressed genes, but only 43% of these differentially expressed genes have a known function (uninfected vs infected, log2FC ≥ 2 or ≤−2, P ≤ 0.05) (Fig. 5, Table 4, Supplementary Data S10). The top three genes with significantly excess abundance were uncharacterized (ADIR008862, ADIR014872, and ADIR010223) while the most highly-expressed known genes (ADIR007940 and ADIR007941) are members of the HSP20/alpha-crystallin family which have not been previously reported. As expected, results showed high induction of immune response-related genes, such as the anti-microbial proteins (AMPs): gambicin, defensin, cecropin, attacin, and leucine-rich immune protein (LRIM1) (Fig. 5)55. Further assignment of biological relevance using Gene Ontology (GO) analysis revealed differences in gene expression of biological processes where infected salivary glands showed an increase of protein catabolism, apoptosis inhibition, structural composition, and olfaction. On the other hand, down-regulation was observed in genes relating to proton and amino acid transport, protein synthesis, and DNA repair (Fig. 5, Table 4)56. Interestingly, enrichment in gene expression for uninfected mosquitoes showed increased expression of three genes (ADIR014650, ADIR003224, and ADIR004887) annotated as salivary gland proteins with significantly lower levels of expression in PvSGS-infected salivary gland samples (Supplementary Data S10).
Discussion
Transmission of Plasmodium sporozoites from mosquito to human involves a transition between two highly distinctive environments, insect to mammal, requiring rapid adjustment for parasite survival. Inside the mosquito’s salivary gland, the sporozoite exists in a quiescent state primed for introduction to the mammalian host but not yet activated. Upon inoculation, sporozoites must immediately react to changes in their microenvironment, especially temperature and serum components, to initiate gliding motility and migration to the liver. In conjunction with this activation, changes in gene expression reflect future developmental requirements for sporozoite cell traversal and then parasite development within hepatocytes. In this study, we used microenvironments with extrinsic stimuli to mimic in vitro infection process to define key relationships with distinct biological functions. Most notable, post-dissection preservation of quiescence by placing sporozoites in an insect-like microenvironment and delaying strategic activation until inoculating hepatocyte cultures prevented untimely activation of invasion-associated genes to dramatically increase invasion rates into primary human hepatocytes. Additional studies will be needed to determine the specific components that modulate sporozoite activation.
Our experimental method allowed us to examine factors of the different biotic microenvironments in multiple pair-wise comparisons (insect vs mammal, BSA vs no BSA), time (0 h vs 4 h), and temperature (RT vs 37 °C) where differential expression revealed 3 phenotypic states (i) quiescent; (ii) invasion-activated; and (iii) early liver-stage. We found that across different Plasmodium species the sporozoite transcriptome have strong similarities with a conserved set of highly expressed genes such as CelTOS, CSP, and TRAP (Fig. 1b,c). However, this study is the first to differentiate between activated vs non-activated sporozoites in relation to key host physiological triggers accompanied with complete transcriptomic analysis (Fig. 2) and quantitative phenotypic assessment (Figs 3, 4). Previous studies in rodent malaria’s and P. falciparum have under-explored the host physiological effects on sporozoites, required laborious purification, and are unable to link expression with in vitro phenotypes39,40,42. Within the last decade, several blood-stage P. vivax sequencing projects in genomics57,58, transcriptomics38,59,60, and proteomics61,62 have advanced our insight of parasite biology63, however, P. vivax sporozoite biology is underrepresented with only one recent publication on the P. vivax sporozoite proteome63,64. Our analysis provides more understanding of transitional host effects as the first published P. vivax sporozoite RNA-seq study and addresses how to improve in vitro infectivity and intracellular development of primary human hepatocytes.
The RNA-seq analysis revealed 197 genes expressed by quiescent PvSGSs maintained in an insect-like environment including genes associated in motility (TLP, TRAP, profilin, CLAMP), cell traversal (GEST, CelTOS, SPECT1), and host invasion (CSP, SIAP1, SPATR). Further, our analysis suggests genes with roles in blood-stage motility and invasion such as Plasmepsin X45 and merozoite TRAP-like protein (MTRAP)65,66 to potentially have uncharacterized functions in sporozoites or early liver-stage parasites. In agreement with the RNA-seq results, our bioassays revealed the most notable finding that PvSGSs collected in Schneider’s insect media remain quiescent until activation by exposure to hepatocyte culture media (Fig. 3a–b). Strategic activation by serum-containing media just before PHH inoculation increases (>2-fold) the hepatocyte invasion rates in comparison to the mammalian-based media, RPMI. Previous studies have demonstrated that sporozoites are activated by serum albumin7,8, other small ligands67,68, or temperature9 to cause an intracellular calcium flux followed by exocytosis69. In agreement, our results demonstrate increased expression of 16 genes including calmodulin, CDPK1, SSP3, SPELD, and regulatory proteins when sporozoites are activated by BSA. CDPK1 orchestrates many processes required for invasion of host cells, including microneme release and activation of actin-myosin motor in PvSGSs70, while SSP3 and SPELD are sporozoite surface proteins with functions in motility71 and liver-stage parasite maturation72. Based on these results it is evident that premature activation of PvSGSs in mammalian-based mediums mistimes the just-in-time cascade of events leading to reduced sporozoite viability and infectivity.
The transcriptome shift from PvSGSs into early liver-stage parasites, mimicked experimentally by exposure to BSA and human body temperature, identified 517 genes with different levels of expression in the transition. Our GO and KEGG enrichment analysis associated the genes with translation and DNA replication with implications in glycolysis and pentose phosphate pathways. As expected, the differentially expressed genes included many liver-stage-associated genes previously determined to be essential for establishment and development (PV1, ETRAMPs, LSAP1)73. Much speculation exists of what genes are present in early liver-stage parasite development where our results more conclusively reveal through the up-regulation of genes involved in the secretory pathway, such as Sortilin, and regulatory processes of gene expression, such as translational repressors ALBA 1, 2, and 4. Furthermore, we attempted to discern the role of the Plasmodium apicoplast in sporozoites as the organelle is vital for the parasites survival due to the prokaryotic type metabolic pathways functional within. The importance of Fe-S cluster biogenesis has been deemed essential for the apicoplast maintenance in the erythrocytic stages of P. falciparum74,75 and in oocyst development of P. berghei76 but yet to be studied in the pre-erythrocytic stages. Our RNA-seq analysis and qRT-PCR determines that initial components of the Suf pathway (Suf S and E) are actively up-regulated in infectious sporozoites and early liver-stage parasites where diffused immunofluorescence staining of SufE alludes to the possibility of multiple roles for the protein as previously reported in Arabidopsis thaliana77. Lastly, our analysis helps prioritize development of new vaccine candidates, such as SIAP2, by its link to hepatocyte invasion and subsequent development9,78,79, and new drug targets in signaling cascade, such as calmodulin, CPDK7, PK, and RACK1.
We offer the first RNA-seq analysis of uninfected and Plasmodium-infected An. dirus, a major SE Asia vector for malaria. While the mosquito salivary gland main purpose is to produce saliva and digestive enzymes to breakdown ingested nutrients, it must tolerate the presence of PvSGS for extended periods in order for transmission to be successful. Our study indicates the presence of the parasite has a profound effect on the An. dirus with induction of innate immune responses genes to P. vivax infections similar to other studies55,80,81,82,83,84,85; however, we identified many genes not yet associated with Plasmodium infections, including the odorant binding protein (OBP) ADIR010042, the serine protease (SP24D) ADIR007695, and the small heat shock associated proteins (alpha-crystallin B chain) ADIR007940 and ADIR007941. Heat shock proteins are essential to mosquito survival and induced by biotic factors such as temperature or colonized parasite86,87,88. Presumably, higher expression in P. vivax-infected mosquitoes may contribute to the sporozoites need to mediate stress and thermotolerance when transitioning between hosts during multiple mosquito blood meals. Further, HSP20 has specifically been implemented in regulation of sporozoite adhesion and locomotion89. Additionally, we found down-regulation of three salivary gland proteins (ADIR014650, ADIR003224, and ADIR004887) in P. vivax-infected salivary glands previously unreported. The parasite manipulation of salivary gland proteins may be a strategy used to bypass the activation of the host innate immune response and avoid detection. Overall, our identification of novel mosquito biomarkers can increase understanding of transmission, improve metrics for measuring transmission, and act as targets for transmission blocking.
Research of P. vivax usually lags significantly behind that of P. falciparum primarily due to the inability to continuously culture P. vivax in the laboratory. However, our research in this study with P. vivax sporozoites provide innovative changes to broadly enhance malaria sporozoite research. Our experimental analyses of P. vivax sporozoites revealed that the microenvironmental changes associated with transition from mosquito into human host trigger distinct processes for initial activation, hepatocyte infection, and liver-stage parasite development. Importantly, distinct calcium-dependent protein kinase signaling pathways associated with these phases of infection represent attractive new drug targets that might be capable of halting migrating sporozoites before they can infect and hide within the liver. Additionally, we offer the first study on mosquito salivary gland gene and proteins involved in P. vivax infection and transmission. Altogether our study represents an important advance in understanding mosquito transmission and the key processes regulating sporozoite infectivity of P. vivax.
Methods
Ethical statement
The Human Subjects protocols for this study was approved by the Institutional Ethics Committee of the Thai Ministry of Public Health and the Human Subjects Research Review Board of the U.S. Army (WRAIR#1949). The protocols conformed to the Helsinki Declaration on ethical principles for medical research involving human subjects (version 2002) and informed written consent was obtained for all volunteers.
Mosquito colonization, rearing and P. vivax infection
For colonization, 3–5-day old adult An. dirus was provided blood meals preserved using citrate phosphate dextrose adenine (CPDA-1) via an artificial membrane feeder containing human blood (Interstate Blood Bank, Inc., Memphis, TN), as previously described90. After blood-feeding, females were manually mated, eggs obtained, and larvae and adults maintained as described earlier91. The blood-fed adults were maintained in the AFRIMS insectary at 25 °C ± 1 °C and 80% relative humidity until transport to the Mae Sod Malaria Clinic, Mae Sod District (Thailand Ministry of Public Health. A 5% solution (v/v) of commercially produced multivitamin syrup (MULTILIM, Atlantic Pharmaceutical Co., Bangkok, Thailand) that included 5% sucrose (LIN, TTR Group, Col, Uthai Thani, Thailand) was as a food source and changed daily92.
The P. vivax -infected blood was obtained from Thai patients who reported to medical clinics along the Thai–Myanmar border with signs and symptoms of malaria infection and confirmation of vivax malaria parasites in the blood. Thick and thin blood smears were prepared and then examined microscopically for P. vivax parasites and gametocyte densities calculated per 200 white blood cells. In total, 20 ml of venous blood was collected in a heparinized tube and maintained at a constant temperature of 37 °C using a water bath circulation system. After starvation for 8 h, 5–7-day old An. dirus females were allowed to blood-feed for 30 min using an artificial membrane feeder. Unfed and partially fed mosquitoes were removed, counted, and discarded in accordance with standard protocols. Engorged mosquitoes were then secured in a container and transported to the AFRIMS insectary where they remained until use at AFRIMS or shipment to USF (Tampa, FL). The adults were maintained at temperature and humidity as described earlier and provided with 10% multivitamin sugar solution that was changed daily to reduce fungal and bacteria growth. P. vivax infected An. dirus mosquitoes were shipped to USF for experiments RNA-seq experiments (n = 1) and preliminary experimental optimization (Supplementary Fig. S3).
Preparation of sporozoite dissection collection media
The experimental design included exposure of fresh sporozoites to a mammalian-based media (RPMI), an insect-based media (Schneider’s), and an addition of BSA to media at a 3% w/v concentration mimicking the level in human plasma. RPMI used was pre-made with addition of 50 mg ml−1 hypoxanthine, 25 mM HEPES, and L-glutamine (Cat. No. CUS-0645, KD medical, Columbia, MD, U.S.A). Schneider’s powder without sodium bicarbonate or calcium chloride (Cat. No. S9895, Sigma-Aldrich, St. Louis, MO, U.S.A.) was reconstituted following manufacture’s protocol in cell culture water (Corning, New York, NY, U.S.A.) with gently stirring until solution was clear and then pH altered near neutral (7.0–7.3) using 1 M NaOH. Complete list of media components is in Supplementary Table S1. The microenvironments were termed as the following: B1 = RPMI, B2 = RPMI + 3% BSA, B3 = Schneider’s, B4 = Schneider’s + 3% BSA. Time points were termed as the following: 0 h refers to time after dissection was finished and sporozoites were taken off ice (4 °C) where 4 h refers to time after dissection was finished and sporozoites are incubated at respective temperatures. Temperature differences at 4 h post-dissection occurred at either room temperature (RT) or 37 °C, 5% CO2. The 4 h RT with 37 °C induction refers to a 30 min incubation (the amount of time to run the gliding assay) of 4 h RT samples with 37 °C, 5% CO2 incubation.
Dissection of P. vivax salivary gland sporozoites
For all experiments, salivary glands were dissected from An. dirus mosquitoes 14–16 days post–infectious blood meal. Mosquitoes were immobilized by cold incubation (−20 °C, 5 min), transferred to ice (4 °C), and individually washed in a 3-step wash: 70% ethanol, 0.5 mg ml−1 penicillin-streptomycin and 1 mg ml−1 of neomycin (PSN), and 2.5 µg ml−1 FungizoneTM diluted in 1× Dulbecco’s Phosphate Buffered Solution (DPBS). Intact, clean salivary glands were collected into 100 μl of collection media with dissection time under an hour. Salivary glands were centrifuged (1600 G, 3 min) with gland disruption using plastic pestle and manually pipetting then counted using a hemocytometer. A total of 200,000–2,000,000 sporozoites were collected per condition for RNA-seq.
Sporozoite gliding motility assay
The gliding motility assay used was described in a previous study34. Briefly, 20,000–40,000 sporozoites were allowed to glide for 30 min in respective media at either room temperature (23 °C) or 37 °C on a glass coverslip coated with 10 µg ml−1 of P. vivax anti-CSP monoclonal antibodies (mAB) 2F2 (subtype VK210) or 2E10.E11 (subtype VK247) (BEI Resources, NIAID, NIH)93. Subsequently, sporozoites were fixed with 4% paraformaldehyde (PFA) for 10 minutes and blocked with 1% bovine serum albumin (BSA) in 1× phosphate buffered saline (PBS) overnight at 4 °C. Sporozoites were stained with 10 µg ml−1 of mAB as primary antibody for 1 hour at room temperature followed by staining with 10 µg ml−1 secondary goat anti-mouse Alexa Fluor® 488 conjugate (2 µg ml−1, 1:1,000-fold dilution; Molecular Probes, ThermoFisher, Waltham, MA, U.S.A.). The coverslip was washed thrice to remove unbound antibodies and mounted inverted on a drop of Fluoromont G. Illuminated anti-CSP trails were quantified and imaged by fluorescence microscopy (20x, 1.4 NA or 100×, 1.4 NA, DeltaVision Core system, GE Healthcare Life Sciences, Piscataway Township, NJ, U.S.A.) where positive gliding was defined by a trail ≥ 3 μm. Percent gliding was calculated by total gliding sporozoites divided by total sporozoites (gliding and non-gliding) for 10 fields of view (20x, 1.4 NA) or for a total of 1,000 sporozoites.
Infection of primary human hepatocytes with P. vivax sporozoites
Cryopreserved primary human hepatocytes (Cat. No. M00995-P and F00995-P, Bioreclamation IVT, Inc, Baltimore, MD, U.S.A.) were previously evaluated for P. vivax invasion where donor lots NLX (Supplementary Fig. S3) or PDC (Fig. 4) were used for PHH invasion experiments. In brief, selected wells of a commercial 384-well plate (Cat No. 781091, Greiner, Monroe, NC, U.S.A.) were coated with rat tail collagen I (Corning, New York, NY, U.S.A) diluted to a final concentration of 5 µg collagen per cm2 in 0.02 M acetic acid and incubated at 37 °C overnight to ensure adsorption. Next day, wells were washed twice with 1× DPBS and once with InVitroGroTM CP Medium (Bioreclamation IVT, Inc, Baltimore, MD, U.S.A.) referred to as hepatocyte culture media (HCM). Cryopreserved PHH were thawed following manufacturer’s instructions with post–thaw viability measured by trypan blue exclusion with > 5 million viable cells per vial and diluted in HCM supplemented with a final concentration of 50 µg ml−1 penicillin-streptomycin, 100 µg ml−1 of neomycin, and 10 µg ml−1 of gentamicin (HCM+) to a concentration of 900 cells per μl. The cell mixture was seeded as a confluent monolayer with a total of 18,000 cells per well in a 384-well plate then incubated at 37 °C, 5% CO2. Following 2 days post–seed, each well received a complete media change (40–50 µl) with HCM+ then ready for sporozoite infection.
After dissection, sporozoites were counted using a hemocytometer and diluted accordingly in experimental medium (Fig. 4a) or HCM+ (Fig. 4b–d), respectively. After dilution, 5.0 × 103 (Fig. 4a–d) or 1.8 × 104 (Supplementary Fig. S3a,b) sporozoites from each condition were added to hepatocyte-seeded wells with experimental replicates (n = 5 or 6), the plate centrifuged (200 G, 5 min), and allowed to invade for 24 hours at 37 °C, 5% CO2 before washing with HCM+ (40–50 µl). Media was changed every 2 days using HCM+ until fixation at 6–8 days post-infection. To fix cells, 4% PFA was incubated for 10 min at room temperature and washed twice with 1× DPBS then stored at 4 °C until temperature-controlled shipment to USF.
Microscopy and image analysis of P. vivax liver-stage parasites
In brief, a standard immunofluorescence assay (IFA) protocol was used to stain and quantify P. vivax liver-stage parasites. Wells were incubated in blocking buffer (0.03% TritonX-100, 1% (w/v) BSA in 1× DPBS) with rabbit anti-UIS-4 polyclonal antibody or mouse anti-ACP antibody at 1:1,000-fold dilution (kindly provided by Center for Infectious Disease Research, WA, U.S.A) and mouse anti-GAPDH monoclonal antibody at 1:50,000-fold dilution (The European Malaria Reagent Repository, Cat. No. 7.2) overnight at 4 °C43,94. After, wells were washed thrice with 1× DPBS and incubated for 1 hour at room temperature with secondary goat anti-mouse or anti-rabbit Alexa Fluor® 488 or 568 conjugate at 1:1,000-fold dilution (2 µg ml−1; Cat. No. A11001, A11034, A11004, A11011, Molecular Probes, ThermoFisher, Waltham, MA, U.S.A.) antibody and Hoechst at 1:1,000-fold dilution (10 µg ml−1) then washed thrice and filled with 1× DPBS until imaging and for long-term storage. Liver-stage parasite imaging, identification, and quantification was performed on the Operetta Imaging System with Harmony software 4.1 (20x, 0.4 NA; Perkin Elmer, Waltham, MA, U.S.A.) following previously described protocol44. Each individual well of a 384-well plate had 35 fields of view collected, capturing anti-UIS4 signal using FITC channel and hepatocyte nuclei using DAPI channel. Predetermined image analysis parameters were set to collect the total liver-stage parasite population. Large, developing liver-stage schizonts and small, dormant hypnozoites were distinguished based upon fluorescent intensity, area, and roundness. Statistical analysis of PHH invasion assays were performed using Prism 7 (Graphpad, La Jolla, CA, U.S.A.).
High-resolution IFA images of the P. vivax liver-stage parasites were captured with a 100x oil objective, 1.4 NA on a DeltaVision Core system (GE Healthcare Life Sciences, Piscataway Township, NJ, U.S.A.). The same IFA protocol was followed as described above. Mouse immune sera samples collected from mice raised against protein to SufE and SufS were diluted in blocking buffer at 1:50 or 1:200 (kindly provided by V.S. and G.S.S., Z.P. and S.G). All high-resolution images were deconvoluted using the softWoRx® image analysis package (GE Healthcare Life Sciences, Piscataway Township, NJ, U.S.A.) and merged z-stacks with added scale bars were processed in (ImageJ)95. Images captured with secondary antibody Alexa Fluor® 568 were re-colored to magenta using FIJI in order to meet publication image standards.
Library preparation and RNA-sequencing of sporozoites and uninfected mosquitoes
The P. vivax sporozoite samples and uninfected salivary glands were extracted and purified from TRIzol using Direct-zolTM RNA miniprep kit (Zymo Research, Irvine, CA, U.S.A.). Sample protein concentration and quality were then measured on a Nanodrop (ThermoFisher, Waltham, MA, U.S.A.). 0.5 μg–1.0 μg total RNA of each sample was used for library preparation. Libraries were prepared by using TruSeq Stranded mRNA Preparation Kit v2 (Illumina, San Diego, CA, U.S.A.) following manufacturer’s recommendations. Library quantification was conducted by qPCR and TapeStation (Agilent Technologies, Santa Clara, CA, U.S.A.) measurements. Libraries were subsequently pooled and sequenced across 4 or 12 lanes of a MiSeq at a read length of 100 bp paired end using 300 cycle V2 MiSeq reagent kit (Illumina, San Diego, CA, U.S.A.).
Mapping, data processing, and transcriptome profiles
The sequencing raw reads from each sporozoite sample were aligned to the P. vivax reference genome P0158 of PlasmoDB version 3496. The sequencing raw reads from each infected and uninfected An. dirus salivary gland samples were aligned to the An. dirus WRAIR2 reference genome of VectorBase release VB-2018-02 (AdirW1.7)56. A maximum of one mismatch per read was allowed. The mapped reads from TopHat97 were used to assemble known transcripts from the reference and their abundances were estimated using Cufflinks98. The expression level of each gene was normalized as Fragments Per Kilobase of exon per Million (FPKM) mapped reads for each condition. All the RNA sequencing raw reads have been deposited into NCBI’s Gene Expression Omnibus which are accessible through GEO Series accession number GSE117538.
Differential gene expression analysis
The difference of gene expression levels across the different time points and buffered media conditions were determined from fragment counts using EdgeR99 in R software100. The aligned read pairs from sorted bam files were counted against P. vivax P01 (PlasmoDB v34) and An. dirus WRAIR2 (AdirW1.7) gene annotations using featureCounts application of the Subread suite101, defining features at the gene-level. TMM (trimmed mean of M-values) normalization100 of the counts was performed across the five runs and three biological replicates to eliminate compositional biases between the samples. For each pairwise comparison (Supplementary Dataset S4–S9) performed, a gene was inferred differentially expressed if the FPKM ≥ 20, log2FC of the mean FPKM across biological replicates is greater 2 or less than −2, P ≤ 0.05 and FDR (False Detection Rate) < 0.1.
Gene Ontology (GO) term enrichment analysis
Predetermined gene lists from each pairwise differential gene expression comparison were used to test the enrichment of specific GO term in each group. The GO enrichment analysis of the molecular function, cellular component, and biological processes were conducted using the Gene Ontology (GO) tool on PlasmoDB96 (www.plasmodb.org) and analyzed using a P of ≤0.05 cutoff. REVIGO program102 was used to reduce the redundancy in GO terms. GO terms with a frequency ≥20% were reported and fold enrichment was used to generate figures.
Gene expression comparison of human and mosquito stages of P. vivax
Gene expression comparison between recently published P. vivax blood-stage38 and our current sporozoite stage transcriptomic data, to understand potential underlying variations and identify sporozoite specific genes (Supplementary Dataset S3, Supplementary Fig. S2). Raw reads from sporozoite samples are re-aligned98 to P. vivax reference genome Sal1 of PlasmoDB version 12 to be consistent with blood-stage RNA-seq data. Peak gene expression across the sporozoite (buffered media and time point) and blood (time point) samples are respectively profiled along with peak expression point, to classify the genes and rank genes based on sporozoite stage expression.
Quantitative real time RT-PCR (qRT-PCR)
Total RNA was extracted from samples preserved in Trizol as described above. After giving DNase I (Invitrogen, Carlsbad, CA, U.S.A.) treatment, the total RNA (about 50–100 ng) was subjected to first-strand cDNA synthesis using the Superscript II Reverse Transcriptase kit (Invitrogen, Carlsbad, CA, U.S.A.) and gene-specific primers following manufacturer’s protocol. The resulting cDNA was diluted 1:5 with nuclease-free water. For real time analysis, the primers were designed based on mRNA of desired genes available from PlasmoDB (Supplementary Table S2) using freely available software GeneRunner and cross verified using Primer Blast (NCBI). Real-time PCR analysis was performed on Agilent Technologies Stratagene Mx3005P System using the Brilliant II SYBR Green QPCR Master Mix with low ROX (Agilent Technologies, Santa Clara, CA, U.S.A.). Briefly, the PCR reaction consisted of 12.5 µl of Brilliant II SYBR Green QPCR Master Mix, 10 µmole of forward and reverse primers and 2 µl of diluted cDNA in a total volume of 25 µl. PCR cycling conditions were performed using the default conditions of the Mx3005P Software: 95 °C, 10 minutes followed by 40 cycles of 94 °C, 30 seconds; 55 °C, 1 minute; and 72 °C, 30 seconds. The housekeeping P. vivax gene, seryl-tRNA- synthetase, known to be transcribed stably throughout different erythrocytic stages was used as an endogenous control (normalizer) for every run. Two buffered media compositions (RPMI + 3% BSA, Schneider’s) were used from 2 biological samples and run in triplicates for the following timepoints, 0 h post-dissection and 4 h post-dissection, 37 °C. For data analysis, the normalized quantity of each target gene was expressed as the ratio of the relative amount of target gene over the quantity of the housekeeping gene. Then, log2FC was used calculated from qPCR data (Schneider’s, 0 h post-dissection vs. RPMI + 3% BSA, 4 h post-dissection, 37 °C) with results compared to the RNA-seq generated FPKM (Supplementary Fig. S5a).
Statistical analysis
All graph bars are represented by means with standard deviation (s.d.). Significance of mean was assessed by two-way ANOVA with Tukey’s multiple comparisons (Figs 3 and 4) When standard deviation is reported, n represents biological replicates and experimental replicates per biological replicate. When p value is reported, P is used for representation.
Disclaimer
Material has been reviewed by the Walter Reed Army Institute of Research. There is no objection to its presentation and/or publication. The opinions or assertions contained herein are the private views of the authors, and are not to be construed as official, or as reflecting true views of the Department of the Army or the Department of Defense. The investigators have adhered to the policies for protection of human subjects as prescribed in AR 70–25.
Data availability
The data that support the findings of this study are available from the corresponding author upon request.
References
Amino, R. et al. Quantitative imaging of Plasmodium transmission from mosquito to mammal. Nature medicine 12, 220–224, https://doi.org/10.1038/nm1350 (2006).
Sidjanski, S. & Vanderberg, J. P. Delayed migration of Plasmodium sporozoites from the mosquito bite site to the blood. The American journal of tropical medicine and hygiene 57, 426–429 (1997).
Vanderberg, J. P. & Frevert, U. Intravital microscopy demonstrating antibody-mediated immobilisation of Plasmodium berghei sporozoites injected into skin by mosquitoes. International journal for parasitology 34, 991–996, https://doi.org/10.1016/j.ijpara.2004.05.005 (2004).
Medica, D. L. & Sinnis, P. Quantitative dynamics of Plasmodium yoelii sporozoite transmission by infected anopheline mosquitoes. Infection and immunity 73, 4363–4369, https://doi.org/10.1128/IAI.73.7.4363-4369.2005 (2005).
Matsuoka, H., Yoshida, S., Hirai, M. & Ishii, A. A rodent malaria, Plasmodium berghei, is experimentally transmitted to mice by merely probing of infective mosquito, Anopheles stephensi. Parasitology international 51, 17–23 (2002).
Frischknecht, F. & Matuschewski, K. Plasmodium Sporozoite Biology. Cold Spring Harb Perspect Med 7, https://doi.org/10.1101/cshperspect.a025478 (2017).
Vanderberg, J. P. Studies on the motility of Plasmodium sporozoites. J Protozool 21, 527–537 (1974).
Kebaier, C. & Vanderberg, J. P. Initiation of Plasmodium sporozoite motility by albumin is associated with induction of intracellular signalling. International journal for parasitology 40, 25–33, https://doi.org/10.1016/j.ijpara.2009.06.011 (2010).
Siau, A. et al. Temperature shift and host cell contact up-regulate sporozoite expression of Plasmodium falciparum genes involved in hepatocyte infection. PLoS pathogens 4, e1000121, https://doi.org/10.1371/journal.ppat.1000121 (2008).
Frevert, U. et al. Intravital observation of Plasmodium berghei sporozoite infection of the liver. PLoS Biol 3, e192, https://doi.org/10.1371/journal.pbio.0030192 (2005).
Mota, M. M. et al. Migration of Plasmodium sporozoites through cells before infection. Science 291, 141–144, https://doi.org/10.1126/science.291.5501.141 (2001).
Kumar, K. A. et al. Exposure of Plasmodium sporozoites to the intracellular concentration of potassium enhances infectivity and reduces cell passage activity. Molecular and biochemical parasitology 156, 32–40, https://doi.org/10.1016/j.molbiopara.2007.07.004 (2007).
Sinnis, P. & Coppi, A. A long and winding road: the Plasmodium sporozoite’s journey in the mammalian host. Parasitology international 56, 171–178, https://doi.org/10.1016/j.parint.2007.04.002 (2007).
Silvie, O., Franetich, J. F., Renia, L. & Mazier, D. Malaria sporozoite: migrating for a living. Trends Mol Med 10, 97–100; discussion 100–101 (2004).
Ejigiri, I. & Sinnis, P. Plasmodium sporozoite-host interactions from the dermis to the hepatocyte. Current opinion in microbiology 12, 401–407, https://doi.org/10.1016/j.mib.2009.06.006 (2009).
Yamauchi, L. M., Coppi, A., Snounou, G. & Sinnis, P. Plasmodium sporozoites trickle out of the injection site. Cell Microbiol 9, 1215–1222, https://doi.org/10.1111/j.1462-5822.2006.00861.x (2007).
Kaiser, K., Camargo, N. & Kappe, S. H. Transformation of sporozoites into early exoerythrocytic malaria parasites does not require host cells. J Exp Med 197, 1045–1050, https://doi.org/10.1084/jem.20022100 (2003).
Price, R. N. et al. Vivax malaria: neglected and not benign. The American journal of tropical medicine and hygiene 77, 79–87 (2007).
Guerra, C. A. et al. The international limits and population at risk of Plasmodium vivax transmission in 2009. PLoS neglected tropical diseases 4, e774, https://doi.org/10.1371/journal.pntd.0000774 (2010).
Battle, K. E. et al. The global public health significance of Plasmodium vivax. Adv Parasitol 80, 1–111, https://doi.org/10.1016/B978-0-12-397900-1.00001-3 (2012).
Howes, R. E. et al. Global Epidemiology of Plasmodium vivax. The American journal of tropical medicine and hygiene, https://doi.org/10.4269/ajtmh.16-0141 (2016).
Mueller, I. et al. Key gaps in the knowledge of Plasmodium vivax, a neglected human malaria parasite. The Lancet. Infectious diseases 9, 555–566, https://doi.org/10.1016/S1473-3099(09)70177-X (2009).
Krotoski, W. A. et al. Observations on early and late post-sporozoite tissue stages in primate malaria. II. The hypnozoite of Plasmodium cynomolgi bastianellii from 3 to 105 days after infection, and detection of 36- to 40-hour pre-erythrocytic forms. The American journal of tropical medicine and hygiene 31, 211–225 (1982).
Rovira-Vallbona, E. et al. Predominance of asymptomatic and sub-microscopic infections characterizes the Plasmodium gametocyte reservoir in the Peruvian Amazon. PLoS neglected tropical diseases 11, e0005674, https://doi.org/10.1371/journal.pntd.0005674 (2017).
Hussain, M. M., Sohail, M., Abhishek, K. & Raziuddin, M. Investigation on Plasmodium falciparum and Plasmodium vivax infection influencing host haematological factors in tribal dominant and malaria endemic population of Jharkhand. Saudi J Biol Sci 20, 195–203, https://doi.org/10.1016/j.sjbs.2013.01.003 (2013).
Rosenberg, R. Plasmodium vivax in Africa: hidden in plain sight? Trends in parasitology 23, 193–196, https://doi.org/10.1016/j.pt.2007.02.009 (2007).
Gething, P. W. et al. A long neglected world malaria map: Plasmodium vivax endemicity in 2010. PLoS neglected tropical diseases 6, e1814, https://doi.org/10.1371/journal.pntd.0001814 (2012).
Sinka, M. E. et al. The dominant Anopheles vectors of human malaria in the Asia-Pacific region: occurrence data, distribution maps and bionomic precis. Parasit Vectors 4, 89, https://doi.org/10.1186/1756-3305-4-89 (2011).
Collins, W. E. et al. Experimental infection of Anopheles farauti with different species of Plasmodium. The Journal of parasitology 88, 295–298, https://doi.org/10.1645/0022-3395(2002)088[0295:EIOAFW]2.0.CO;2 (2002).
Tainchum, K., Kongmee, M., Manguin, S., Bangs, M. J. & Chareonviriyaphap, T. Anopheles species diversity and distribution of the malaria vectors of Thailand. Trends in parasitology 31, 109–119, https://doi.org/10.1016/j.pt.2015.01.004 (2015).
Rabinovich, R. N. et al. malERA: An updated research agenda for malaria elimination and eradication. PLoS medicine 14, e1002456, https://doi.org/10.1371/journal.pmed.1002456 (2017).
Londono-Renteria, B. et al. An. gambiae gSG6-P1 evaluation as a proxy for human-vector contact in the Americas: a pilot study. Parasit Vectors 8, 533, https://doi.org/10.1186/s13071-015-1160-3 (2015).
Armiyanti, Y. et al. Detection of immunogenic proteins from Anopheles sundaicus salivary glands in the human serum. Rev Soc Bras Med Trop 48, 410–416, https://doi.org/10.1590/0037-8682-0185-2015 (2015).
Lupton, E. J. et al. Enhancing longevity of Plasmodium vivax and P. falciparum sporozoites after dissection from mosquito salivary glands. Parasitology international 64, 211–218, https://doi.org/10.1016/j.parint.2014.11.016 (2015).
Hegge, S., Kudryashev, M., Barniol, L. & Frischknecht, F. Key factors regulating Plasmodium berghei sporozoite survival and transformation revealed by an automated visual assay. The FASEB Journal 24, 5003–5012, https://doi.org/10.1096/fj.10-164814 (2010).
Bock, J. Serum protein concentration and relative albumin percentage in normal individuals. Acta Physiol Scand 18, 231–237, https://doi.org/10.1111/j.1748-1716.1949.tb00615.x (1949).
Chaerkady, R. et al. A proteogenomic analysis of Anopheles gambiae using high-resolution Fourier transform mass spectrometry. Genome Res 21, 1872–1881, https://doi.org/10.1101/gr.127951.111 (2011).
Zhu, L. et al. New insights into the Plasmodium vivax transcriptome using RNA-Seq. Scientific reports 6 (2016).
Zanghì, G. et al. A Specific PfEMP1 Is Expressed in P. falciparum Sporozoites and Plays a Role in Hepatocyte Infection. Cell reports 22, 2951–2963 (2018).
Gómez-Díaz, E. et al. Epigenetic regulation of Plasmodium falciparum clonally variant gene expression during development in Anopheles gambiae. Scientific reports 7, 40655 (2017).
Gural, N. et al. In vitro culture, drug sensitivity, and transcriptome of Plasmodium vivax hypnozoites. Cell host & microbe 23, 395–406 (2018). e394.
Lindner, S. E. et al. Perturbations of Plasmodium Puf2 expression and RNA‐seq of Puf2‐deficient sporozoites reveal a critical role in maintaining RNA homeostasis and parasite transmissibility. Cellular microbiology 15, 1266–1283 (2013).
Mikolajczak, S. A. et al. Plasmodium vivax liver stage development and hypnozoite persistence in human liver-chimeric mice. Cell host & microbe 17, 526–535, https://doi.org/10.1016/j.chom.2015.02.011 (2015).
Roth, A. et al. A comprehensive model for assessment of liver stage therapies targeting Plasmodium vivax and Plasmodium falciparum. Nat Commun 9, 1837, https://doi.org/10.1038/s41467-018-04221-9 (2018).
Nasamu, A. S. et al. Plasmepsins IX and X are essential and druggable mediators of malaria parasite egress and invasion. Science 358, 518–522, https://doi.org/10.1126/science.aan1478 (2017).
Saggu, G. S., Garg, S., Pala, Z. R., Kochar, S. K. & Saxena, V. Deciphering the role of IspD (2Cmethylderythritol 4phosphate cytidyltransferase) enzyme as a potential therapeutic drug target against Plasmodium vivax. Gene. https://doi.org/10.1016/j.gene.2018.06.084 (2018).
Ashburner, M. et al. Gene ontology: tool for the unification of biology. The Gene Ontology Consortium. Nat Genet 25, 25–29, https://doi.org/10.1038/75556 (2000).
Gene Ontology, C. et al. Gene Ontology annotations and resources. Nucleic Acids Res 41, D530–535, https://doi.org/10.1093/nar/gks1050 (2013).
Hallee, S., Boddey, J. A., Cowman, A. F. & Richard, D. Evidence that the Plasmodium falciparum Protein Sortilin Potentially Acts as an Escorter for the Trafficking of the Rhoptry-Associated Membrane Antigen to the Rhoptries. mSphere 3, https://doi.org/10.1128/mSphere.00551-17 (2018).
Krai, P., Dalal, S. & Klemba, M. Evidence for a Golgi-to-endosome protein sorting pathway in Plasmodium falciparum. PloS one 9, e89771, https://doi.org/10.1371/journal.pone.0089771 (2014).
Posfai, D. et al. Identification of Hsp90 inhibitors with anti-Plasmodium activity. Antimicrob Agents Chemother. https://doi.org/10.1128/AAC.01799-17 (2018).
Vembar, S. S., Droll, D. & Scherf, A. Translational regulation in blood stages of the malaria parasite Plasmodium spp.: systems-wide studies pave the way. Wiley Interdiscip Rev RNA 7, 772–792, https://doi.org/10.1002/wrna.1365 (2016).
Munoz, E. E. et al. ALBA4 modulates its stage-specific interactions and specific mRNA fates during Plasmodium yoelii growth and transmission. Mol Microbiol 106, 266–284, https://doi.org/10.1111/mmi.13762 (2017).
Hayashi, H. et al. Anopheline anti-platelet protein from a malaria vector mosquito has anti-thrombotic effects in vivo without compromising hemostasis. Thromb Res 129, 169–175, https://doi.org/10.1016/j.thromres.2011.09.015 (2012).
Yi, H. Y., Chowdhury, M., Huang, Y. D. & Yu, X. Q. Insect antimicrobial peptides and their applications. Appl Microbiol Biotechnol 98, 5807–5822, https://doi.org/10.1007/s00253-014-5792-6 (2014).
Giraldo-Calderon, G. I. et al. VectorBase: an updated bioinformatics resource for invertebrate vectors and other organisms related with human diseases. Nucleic Acids Res 43, D707–713, https://doi.org/10.1093/nar/gku1117 (2015).
Carlton, J. M. et al. Comparative genomics of the neglected human malaria parasite Plasmodium vivax. Nature 455, 757 (2008).
Auburn, S. et al. A new Plasmodium vivax reference sequence with improved assembly of the subtelomeres reveals an abundance of pir genes. Wellcome open research 1 (2016).
Kim, A. et al. Characterization of P. vivax blood stage transcriptomes from field isolates reveals similarities among infections and complex gene isoforms. Scientific reports 7, 7761 (2017).
Bozdech, Z. et al. The transcriptome of Plasmodium vivax reveals divergence and diversity of transcriptional regulation in malaria parasites. Proceedings of the National Academy of Sciences 105, 16290–16295 (2008).
Acharya, P. et al. Clinical proteomics of the neglected human malarial parasite Plasmodium vivax. PloS one 6, e26623 (2011).
Anderson, D. et al. Plasmodium vivax trophozoite-stage proteomes. Journal of proteomics 115, 157–176 (2015).
Bourgard, C., Albrecht, L., Kayano, A., Sunnerhagen, P. & Costa, F. T. M. Plasmodium vivax Biology: Insights Provided by Genomics, Transcriptomics and Proteomics. Front Cell Infect Microbiol 8, 34, https://doi.org/10.3389/fcimb.2018.00034 (2018).
Swearingen, K. E. et al. Proteogenomic analysis of the total and surface-exposed proteomes of Plasmodium vivax salivary gland sporozoites. PLoS neglected tropical diseases 11, e0005791, https://doi.org/10.1371/journal.pntd.0005791 (2017).
Boucher, L. E., Hopp, C. S., Muthinja, J. M., Frischknecht, F. & Bosch, J. Discovery of Plasmodium (M)TRAP-Aldolase Interaction Stabilizers Interfering with Sporozoite Motility and Invasion. ACS Infect Dis 4, 620–634, https://doi.org/10.1021/acsinfecdis.7b00225 (2018).
Kehrer, J., Frischknecht, F. & Mair, G. R. Proteomic Analysis of the Plasmodium berghei Gametocyte Egressome and Vesicular bioID of Osmiophilic Body Proteins Identifies Merozoite TRAP-like Protein (MTRAP) as an Essential Factor for Parasite Transmission. Molecular & cellular proteomics: MCP 15, 2852–2862, https://doi.org/10.1074/mcp.M116.058263 (2016).
Perschmann, N., Hellmann, J. K., Frischknecht, F. & Spatz, J. P. Induction of malaria parasite migration by synthetically tunable microenvironments. Nano Lett 11, 4468–4474, https://doi.org/10.1021/nl202788r (2011).
Hellmann, J. K., Perschmann, N., Spatz, J. P. & Frischknecht, F. Tunable substrates unveil chemical complementation of a genetic cell migration defect. Adv Healthc Mater 2, 1162–1169, https://doi.org/10.1002/adhm.201200426 (2013).
Carey, A. F. et al. Calcium dynamics of Plasmodium berghei sporozoite motility. Cell Microbiol 16, 768–783, https://doi.org/10.1111/cmi.12289 (2014).
Bansal, A. et al. Characterization of Plasmodium falciparum calcium-dependent protein kinase 1 (PfCDPK1) and its role in microneme secretion during erythrocyte invasion. J Biol Chem 288, 1590–1602, https://doi.org/10.1074/jbc.M112.411934 (2013).
Harupa, A. et al. SSP3 is a novel Plasmodium yoelii sporozoite surface protein with a role in gliding motility. Infection and immunity 82, 4643–4653, https://doi.org/10.1128/IAI.01800-14 (2014).
Al-Nihmi, F. M. et al. A Novel and Conserved Plasmodium Sporozoite Membrane Protein SPELD is Required for Maturation of Exo-erythrocytic Forms. Scientific reports 7, 40407, https://doi.org/10.1038/srep40407 (2017).
Silvie, O., Briquet, S., Muller, K., Manzoni, G. & Matuschewski, K. Post-transcriptional silencing of UIS4 in Plasmodium berghei sporozoites is important for host switch. Mol Microbiol 91, 1200–1213, https://doi.org/10.1111/mmi.12528 (2014).
Gisselberg, J. E., Dellibovi-Ragheb, T. A., Matthews, K. A., Bosch, G. & Prigge, S. T. The suf iron-sulfur cluster synthesis pathway is required for apicoplast maintenance in malaria parasites. PLoS pathogens 9, e1003655, https://doi.org/10.1371/journal.ppat.1003655 (2013).
Dellibovi-Ragheb, T. A., Gisselberg, J. E. & Prigge, S. T. Parasites FeS up: iron-sulfur cluster biogenesis in eukaryotic pathogens. PLoS pathogens 9, e1003227, https://doi.org/10.1371/journal.ppat.1003227 (2013).
Haussig, J. M., Matuschewski, K. & Kooij, T. W. Identification of vital and dispensable sulfur utilization factors in the Plasmodium apicoplast. PloS one 9, e89718, https://doi.org/10.1371/journal.pone.0089718 (2014).
M, N. M. et al. Characterization of Arabidopsis thaliana SufE2 and SufE3: functions in chloroplast iron-sulfur cluster assembly and Nad synthesis. J Biol Chem 282, 18254–18264, https://doi.org/10.1074/jbc.M701428200 (2007).
Arevalo-Pinzon, G., Curtidor, H., Munoz, M., Patarroyo, M. A. & Patarroyo, M. E. Synthetic peptides from two Pf sporozoite invasion-associated proteins specifically interact with HeLa and HepG2 cells. Peptides 32, 1902–1908, https://doi.org/10.1016/j.peptides.2011.08.008 (2011).
Garzon-Ospina, D., Buitrago, S. P., Ramos, A. E. & Patarroyo, M. A. Identifying Potential Plasmodium vivax Sporozoite Stage Vaccine Candidates: An Analysis of Genetic Diversity and Natural Selection. Front Genet 9, 10, https://doi.org/10.3389/fgene.2018.00010 (2018).
Gwadz, R. W. et al. Effects of magainins and cecropins on the sporogonic development of malaria parasites in mosquitoes. Infection and immunity 57, 2628–2633 (1989).
Clayton, A. M., Dong, Y. & Dimopoulos, G. The Anopheles innate immune system in the defense against malaria infection. J Innate Immun 6, 169–181, https://doi.org/10.1159/000353602 (2014).
Habtewold, T., Groom, Z. & Christophides, G. K. Immune resistance and tolerance strategies in malaria vector and non-vector mosquitoes. Parasit Vectors 10, 186, https://doi.org/10.1186/s13071-017-2109-5 (2017).
Couto, J. et al. Solute carriers affect Anopheles stephensi survival and Plasmodium berghei infection in the salivary glands. Scientific reports 7, 6141, https://doi.org/10.1038/s41598-017-06317-6 (2017).
Cao, X., Gulati, M. & Jiang, H. Serine protease-related proteins in the malaria mosquito, Anopheles gambiae. Insect Biochem Mol Biol 88, 48–62, https://doi.org/10.1016/j.ibmb.2017.07.008 (2017).
Simoes, M. L., Mlambo, G., Tripathi, A., Dong, Y. & Dimopoulos, G. Immune Regulation of Plasmodium Is Anopheles Species Specific and Infection Intensity Dependent. MBio 8, https://doi.org/10.1128/mBio.01631-17 (2017).
Zhang, G., Storey, J. M. & Storey, K. B. Chaperone proteins and winter survival by a freeze tolerant insect. J Insect Physiol 57, 1115–1122, https://doi.org/10.1016/j.jinsphys.2011.02.016 (2011).
Benoit, J. B., Lopez-Martinez, G., Phillips, Z. P., Patrick, K. R. & Denlinger, D. L. Heat shock proteins contribute to mosquito dehydration tolerance. J Insect Physiol 56, 151–156, https://doi.org/10.1016/j.jinsphys.2009.09.012 (2010).
Benoit, J. B. et al. Drinking a hot blood meal elicits a protective heat shock response in mosquitoes. Proc Natl Acad Sci USA 108, 8026–8029, https://doi.org/10.1073/pnas.1105195108 (2011).
Montagna, G. N., Matuschewski, K. & Buscaglia, C. A. Small heat shock proteins in cellular adhesion and migration: evidence from Plasmodium genetics. Cell Adh Migr 6, 78–84, https://doi.org/10.4161/cam.20101 (2012).
Rutledge, L. C., Ward, R. A. & Gould, D. J. Studies on the feeding response of mosquitoes to nutritive solutions in a new membrane feeder. Mosquito News 24, 407–419 (1964).
Ow Yang, C. K., Sta Maria, F. L., Wharton, R. W. & Organization, W. H. Maintenance of a laboratory colony of Anopheles maculatus Theobald by artificial mating. 34–35 (1963).
Phasomkusolsil, S. et al. Colonization and maintenance of Anopheles kleini and Anopheles sinensis from the Republic of Korea. J Am Mosq Control Assoc 30, 1–6, https://doi.org/10.2987/13-6390.1 (2014).
Nardin, E. H. et al. Circumsporozoite proteins of human malaria parasites Plasmodium falciparum and Plasmodium vivax. J Exp Med 156, 20–30 (1982).
Hall, R. et al. Antigens of the erythrocytes stages of the human malaria parasite Plasmodium falciparum detected by monoclonal antibodies. Molecular and biochemical parasitology 7, 247–265 (1983).
Schindelin, J. et al. Fiji: an open-source platform for biological-image analysis. Nature methods 9, 676–682, https://doi.org/10.1038/nmeth.2019 (2012).
Bahl, A. et al. PlasmoDB: the Plasmodium genome resource. A database integrating experimental and computational data. Nucleic Acids Res 31, 212–215 (2003).
Kim, D. et al. TopHat2: accurate alignment of transcriptomes in the presence of insertions, deletions and gene fusions. Genome biology 14, R36, https://doi.org/10.1186/gb-2013-14-4-r36 (2013).
Trapnell, C. et al. Differential gene and transcript expression analysis of RNA-seq experiments with TopHat and Cufflinks. Nat Protoc 7, 562–578, https://doi.org/10.1038/nprot.2012.016 (2012).
Robinson, M. D., McCarthy, D. J. & Smyth, G. K. edgeR: a Bioconductor package for differential expression analysis of digital gene expression data. Bioinformatics 26, 139–140 (2010).
Team, R. C. R: A language and environment for statistical computing. (2013).
Liao, Y., Smyth, G. K. & Shi, W. FeatureCounts: an efficient general purpose program for assigning sequence reads to genomic features. Bioinformatics 30, 923–930 (2013).
Supek, F., Bošnjak, M., Škunca, N. & Šmuc, T. REVIGO summarizes and visualizes long lists of gene ontology terms. PloS one 6, e21800 (2011).
Acknowledgements
The authors would like to thank the P. vivax infected patients and residents of Tak Province, Thailand for their generosity for participation in the study. We thank AFRIMS Entomology, particularly Waranya Buadok, Rochanawan Sootichote, and Amnart Kayha from the Malaria Section, and Insectary for mosquito breeding, blood feeding, and maintenance. The monoclonal antibody 7.2 (anti-GAPDH) was obtained from The European Malaria Reagent Repository (http://www.malariaresearch.eu). We thank Stefan Kappe and Sebastian Mikolajczak for providing the polyclonal antibody UIS4. We thank Jenna Oberstaller for constructive discussions. Funding support was provided by Bill and Melinda Gates Foundation (OPP1023643 to J.H.A.), Department of Science & Technology, India (SB/YS/LS-275-2013 to S.G.), University Grants Commission Fellowship, India (S.R.F. to G.S.S.), Council of Scientific Research, India (S.R.F. to Z.R.P.), 2017 ASM-IUSSTF Research Professorship (to V.S.), University Grants Commission, India (42-182/2013 to V.S.), and University of South Florida College of Public Health Graduate Fellowship (to A.R.).
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Study design and development: A.R., J.H.A., S.R.A., R.H.Y.J.; P. vivax sample collection, mosquito and sporozoite production: R.U., S.D.; Sporozoite dissection/isolation, hepatocyte experiments, immunofluorescence assays, high-content imaging, and data analysis: A.R.; Sporozoite gliding assays and analysis: A.R., R.G., S.L.; DNA/RNA isolation, library preparation, and RNA-seq runs: X.L., M.Z., A.R.; RNA-seq data analysis and interpretation: S.R.A., R.H.Y.J., A.R., J.H.A.; Generated Suf protein and sera: V.S., S.G., Z.R.P., G.S.S.; Performed qPCR and data analysis: V.S., S.G.; Manuscript preparation-original: A.R.; Manuscript additional preparation: J.H.A., R.H.Y.J., S.R.A., V.S. All authors contributed to final, submitted manuscript.
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Roth, A., Adapa, S.R., Zhang, M. et al. Unraveling the Plasmodium vivax sporozoite transcriptional journey from mosquito vector to human host. Sci Rep 8, 12183 (2018). https://doi.org/10.1038/s41598-018-30713-1
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DOI: https://doi.org/10.1038/s41598-018-30713-1
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