Project description:Gametogenesis is essential for malaria parasite transmission, but the molecular mechanism of this process remains to be refined. Here, we identified a G-protein-coupled receptor 180 (GPR180) that plays a critical role in signal transduction during gametogenesis in Plasmodium. In the rodent parasite P. berghei, PbGPR180 was expressed during asexual and sexual development, with more prominent expression in gametocytes and ookinetes. While PbGPR180 was predominantly localized to cytoplasmic puncta in asexual stages and gametocytes, it became associated with the plasma membrane in female gametes and ookinetes. Knockout of pbgpr180 (Δpbgpr180) had no noticeable effect on asexual development or gametocytogenesis but impaired gamete formation and reduced transmission of the parasites to mosquitoes. Transcriptome analysis of the Δpbgpr180 gametocytes revealed a large proportion of the dysregulated genes with assigned functions in cyclic nucleotide signaling transduction, especially the cGMP-PKG-Ca2+ signaling cascade. Deletion of pbgpr180 resulted in a delay and reduction in cytosolic Ca2+ mobilization during the induction of gametogenesis. In addition, the intracellular cGMP level was significantly reduced in the Δpbgpr180 gametocytes, suggesting that PbGPR180 functions upstream of the cGMP-PKG-Ca2+ signaling pathway. In line with this function, PbGPR180 protein was found to interact with several transmembrane transporter proteins and a small GTPase, Rab6, in activated gametocytes. Allele replacement of pbgpr180 with the P. vivax ortholog pvgpr180 showed equal competence of the transgenic parasite in sexual development, suggesting functional conservation of this gene in Plasmodium spp . These results indicate that GPR180 is involved in cGMP-PKG-Ca2+ signal transduction to regulate gametogenesis in malaria parasites.

Project description:Protein phosphorylation plays a critical role during the development of malaria parasites. Here, we performed a functional analysis of the Plasmodium berghei Ser/Thr protein phosphatase 6 (PbPP6), which was associated with the plasma membrane of macrogametes and ookinetes. Compared to wild-type P. berghei, genetic disruption/deletion of the pbpp6 gene (∆pbpp6) reduced the asexual growth of the parasites and prolonged the survival of ∆pbpp6-infected mice. The ∆pbpp6 parasites showed impaired gametogenesis, particularly affecting male gametogenesis, which substantially decreased ookinete formation and transmission to mosquitoes. RNA-seq assays revealed that pbpp6 disruption led to over 11-fold down-regulation of the nek3 gene, a regulator of MAPK2 in the PKG-Ca2+ signaling cascade during male gametogenesis. Several PDEs (α, γ, δ) were also affected, indicating that PbPP6 plays a role in the cGMP-PKG-Ca2+ signaling pathway. Additionally, we observed altered expression of messenger ribonucleoproteins in the Δpbpp6 parasites, which may affect translational repression of stored mRNAs in female gametocytes and post-fertilization development in mosquitoes. Consistent with the dysregulated GO terms related to the cGMP-PKG-Ca2+ signaling cascade observed in RNA-seq analysis, the activated gametocytes of ∆pbpp6 exhibited significantly reduced levels of intracellular cGMP, cytosolic Ca2+ mobilization, and DNA replication. Phosphoproteomic analysis detected increased phosphorylation at the Ser508 site of guanylyl cyclase alpha (GCα), suggesting that PbPP6 regulates cGMP-PKG-Ca2+ signaling cascades by modulating the activity of GCα during gametogenesis. This study highlights the potential of targeting PP6 to disrupt malaria transmission.

Project description:Protein phosphorylation plays a critical role during the development of malaria parasites. Here, we performed a functional analysis of the Plasmodium berghei Ser/Thr protein phosphatase 6 (PbPP6), which was associated with the plasma membrane of macrogametes and ookinetes. Compared to wild-type P. berghei, genetic disruption/deletion of the pbpp6 gene (∆pbpp6) reduced the asexual growth of the parasites and prolonged the survival of ∆pbpp6-infected mice. The ∆pbpp6 parasites showed impaired gametogenesis, particularly affecting male gametogenesis, which substantially decreased ookinete formation and transmission to mosquitoes. RNA-seq assays revealed that pbpp6 disruption led to over 11-fold down-regulation of the nek3 gene, a regulator of MAPK2 in the PKG-Ca2+ signaling cascade during male gametogenesis. Several PDEs (α, γ, δ) were also affected, indicating that PbPP6 plays a role in the cGMP-PKG-Ca2+ signaling pathway. Additionally, we observed altered expression of messenger ribonucleoproteins in the Δpbpp6 parasites, which may affect translational repression of stored mRNAs in female gametocytes and post-fertilization development in mosquitoes. Consistent with the dysregulated GO terms related to the cGMP-PKG-Ca2+ signaling cascade observed in RNA-seq analysis, the activated gametocytes of ∆pbpp6 exhibited significantly reduced levels of intracellular cGMP, cytosolic Ca2+ mobilization, and DNA replication. Phosphoproteomic analysis detected increased phosphorylation at the Ser508 site of guanylyl cyclase alpha (GCα), suggesting that PbPP6 regulates cGMP-PKG-Ca2+ signaling cascades by modulating the activity of GCα during gametogenesis. This study highlights the potential of targeting PP6 to disrupt malaria transmission.

Project description:Gametogenesis is essential for malaria parasite transmission, but the molecular mechanism of this process remains to be refined. Here, we identified a G-protein-coupled receptor 180 (GPR180) that plays a critical role in signal transduction during gametogenesis in Plasmodium. P. berghei GPR180 was predominantly expressed in gametocytes and ookinetes and associated with the plasma membrane in female gametes and ookinetes. Knockout of pbgpr180 (Δpbgpr180) had no noticeable effect on blood-stage development but impaired gamete formation and reduced transmission of the parasites to mosquitoes. Transcriptome analysis revealed that a large proportion of the dysregulated genes in the Δpbgpr180 gametocytes had assigned functions in cyclic nucleotide signaling transduction. In the Δpbgpr180 gametocytes, the intracellular cGMP level was significantly reduced, and the cytosolic Ca2+ mobilization showed a delay and a reduction in the magnitude during gametocyte activation. These results suggest that PbGPR180 functions upstream of the cGMP-protein kinase G-Ca2+ signaling pathway. In line with this functional prediction, the PbGPR180 protein was found to interact with several transmembrane transporter proteins and the small GTPase Rab6 in activated gametocytes. Allele replacement of pbgpr180 with the P. vivax ortholog pvgpr180 showed equal competence of the transgenic parasite in sexual development, suggesting functional conservation of this gene in Plasmodium spp. Furthermore, an anti-PbGPR180 monoclonal antibody and the anti-PvGPR180 serum possessed robust transmission-blocking activities. These results indicate that GPR180 is involved in signal transduction during gametogenesis in malaria parasites and is a promising target for blocking parasite transmission.

Project description:In malaria parasites, all cGMP-dependent signalling is mediated through a single cGMP-dependent protein kinase (PKG). A major function of PKG is to control calcium signals essential for the parasite to exit red blood cells or for transmission to the mosquito vector. However, how PKG controls these signals in the absence of known second messenger-dependent calcium channels or scaffolding proteins remains a mystery. Here we identify a tightly-associated PKG partner protein in both Plasmodium falciparum asexual blood stages and P. berghei gametocytes. Named ICM1, the partner is a polytopic membrane protein with homology to transporters and calcium channels, raising the possibility of a direct functional link between PKG and calcium homeostasis. Phosphoproteomic analyses in both Plasmodium species highlight a densely phosphorylated region of ICM1 with multiple phosphorylation events dependent upon PKG activity. Stage-specific depletion of ICM1 in P. berghei blocks gametogenesis due to the inability of mutant parasites to mobilise intracellular calcium upon PKG activation, whilst conditional disruption of P. falciparum ICM1 results in reduced cGMP-dependent calcium mobilisation associated with defective egress and invasion. Our findings provide new insights into the atypical calcium homeostasis in malaria parasites essential for pathology and disease transmission.

Project description:In malaria parasites, cGMP signalling is mediated by a single cGMP-dependent protein kinase (PKG). One of the major functions of PKG is to control calcium signals essential for the parasite to exit red blood cells or for the transmission of the gametocyte stages to the mosquito. However, how PKG controls these signals in the absence of known second messenger-dependent calcium channels or scaffolding proteins remains a mystery. Here we use pull-down approaches to identify a PKG partner protein in both Plasmodium falciparum schizonts and P. berghei gametocytes. This partner, named ICM1, is a polytopic membrane protein with homologies to transporters and calcium channels, raising the possibility of a direct functional link between PKG and calcium homeostasis. Phosphoproteomic analyses in both Plasmodium species highlight a densely phosphorylated region of ICM1 with multiple phosphorylation events dependent on PKG activity. Conditional disruption of the P. falciparum ICM1 gene results in reduced cGMP-dependent calcium mobilisation associated with defective egress and invasion. Stage-specific depletion of ICM1 in P. berghei gametocytes blocks gametogenesis due to the inability of mutant parasites to mobilise intracellular calcium upon PKG activation. These results provide us with new insights into the atypical calcium homeostasis in malaria parasites

Project description:In malaria parasites, cGMP signalling is mediated by a single cGMP-dependent protein kinase (PKG) . One of the major functions of PKG is to control calcium signals essential for the parasite to exit red blood cells or for the transmission of the gametocyte stages to the mosquito . However, how PKG controls these signals in the absence of known second messenger-dependent calcium channels or scaffolding proteins remains a mystery. Here we use pull-down approaches to identify a PKG partner protein in both Plasmodium falciparum schizonts and P. berghei gametocytes. This partner, named ICM1, is a polytopic membrane protein with homologies to transporters and calcium channels, raising the possibility of a direct functional link between PKG and calcium homeostasis. Phosphoproteomic analyses in both Plasmodium species highlight a densely phosphorylated region of ICM1 with multiple phosphorylation events dependent on PKG activity. Conditional disruption of the P. falciparum ICM1 gene results in reduced cGMP-dependent calcium mobilisation associated with defective egress and invasion. Stage-specific depletion of ICM1 in P. berghei gametocytes blocks gametogenesis due to the inability of mutant parasites to mobilise intracellular calcium upon PKG activation. These results provide us with new insights into the atypical calcium homeostasis in malaria parasites.

Project description:Protein phosphorylation plays a critical role during the development of malaria parasites. Here, we performed a functional analysis of a Plasmodium berghei Ser/Thr protein phosphatase 6 (PbPP6), which was associated with the plasma membrane of macrogametes and ookinetes. Compared with the wild-type P. berghei, genetic disruption/deletion of the pbpp6 gene (∆pbpp6) reduced the asexual growth of the parasites and prolonged the survival of ∆pbpp6-infected mice. The ∆pbpp6 parasites displayed impaired gametogenesis, with a more significant effect on male gametogenesis, which substantially decreased ookinete formation and transmission to mosquitoes. RNA-seq assays revealed that pbpp6 deletion led to over 11-fold down-regulation of the nek3 gene, a regulator of MAPK2 downstream of protein kinase G (PKG)-dependent Ca2+ signaling cascade in male gametogenesis, suggesting that PbPP6 plays a role in the Ca2+ signaling pathway. Meanwhile, we observed altered expression of messenger ribonucleoproteins in the Δpbpp6 parasites, which may affect translational repression of stored mRNAs in female gametocytes and post-fertilization development in mosquitoes. A phospho-proteomic analysis detected increased phosphorylation at the Ser375 site of the phosphoinositide metabolism kinase PIP5K, a target of the PKG. In addition, the Thr699 site of PKG is also a putative target of PbPP6, suggesting that PbPP6 may be involved in a PKG-mediated transcending signaling network to control the sexual development of the malaria parasite. Our study highlighted the significance of protein phosphorylation in sexual development and Plasmodium phosphatases as potential targets for disrupting malaria transmission.

Project description:Gametocytogenesis and gametogenesis in malaria parasites are complex processes of cell differentiation and development likely involving many gene products. Gametocytes develop in the blood of the vertebrate host but mature gametocytes are not activated until taken up by the mosquito vector. Several distinct mutants have been described that block gametogenesis but the detailed molecular causes for the mutant phenotypes are not understood. To investigate whether a block in gametogenesis also results in a changed transcriptional profile, we studied two gene deletions mutants; act2(-) lacking stage-specific actin II and CDPK4(-) lacking calcium-dependent protein kinase 4. Whole-genome microarray analysis was performed from RNA of mature gametocytes to compare the transcriptomes of the mutants with wild-type Plasmodium berghei. The microarray analysis identified ~12% of all genes being differentially expressed in either or both mutants compared to normal gametocytes, as defined by at least two-fold change in transcript abundance. A large proportion of differentially expressed genes in both mutants overlapped consistent with the developmental gametocyte arrest. Distinct profiles in each mutant were also observed. Microarray experiments were performed as dual-color hybridizations on Agilent-024169 custom whole genome Plasmodium berghei 44K arrays. To compensate for dye-specific effects, a dye-reversal color-swap was applied.

Project description:Plasmodium falciparum is a unicellular parasite responsible for the majority of 440,000 death due to malaria every year. Due to their essential role for malaria transmission, gametocytes represent prime targets for transmission-blocking strategies intended to prevent spread of the deadly disease. In this study, we explored the signaling pathways leading to gametogenesis and identified a hitherto unknown protein, which structurally belongs to the class of seven-helix proteins and which thus was termed 7-helix-1. The protein is specifically expressed in female gametocytes and gene disruption leads to impaired gamete formation and thus reduced transmission of malaria parasites to mosquitoes. The loss of 7-helix-1 caused significant changes in the expression of components of the molecular machinery needed by eukaryotic cells to synthesize proteins. We thus propose that 7-helix-1 is a key regulator needed to coordinate the increased need of proteins at the onset of gametogenesis.