Project description:Merozoite invasion of host red blood cells (RBCs) is essential for survival of the human malaria parasite Plasmodium falciparum. Proteins involved with RBC binding and invasion are secreted from dual-club shaped organelles at the apical tip of the merozoite called the rhoptries. Here we characterise P. falciparum Cytosolically Exposed Rhoptry Leaflet Interacting protein 2 (PfCERLI2), as a rhoptry bulb protein that is essential for merozoite invasion. Phylogenetic analyses show that cerli2 arose through an ancestral gene duplication of cerli1, a related cytosolically exposed rhoptry bulb protein. We show that PfCERLI2 is essential for blood-stage growth and localises to the cytosolic face of the rhoptry bulb. Inducible knockdown of PfCERLI2 led to a proportion of merozoites failing to invade after formation of the tight junction. PfCERLI2 knockdown was associated with inhibition of rhoptry antigen processing and a significant elongation of the rhoptries, suggesting that the inability of merozoites to invade is caused by aberrant rhoptry function due to PfCERLI2 deficiency. These findings identify PfCERLI2 as a protein that has key roles in rhoptry biology during merozoite invasion.

Project description:Ubiquitylation is a common post translational modification of eukaryotic proteins. Protein ubiquitylation increases in the transition from intracellular schizont to extracellular merozoite in the asexual blood stage cycle of the human malaria parasite, Plasmodium falciparum (Pf). Here, we identify specific ubiquitylation sites of protein substrates in three intracellular parasite stages and extracellular merozoites; a total of 1464 sites in 546 proteins were identified. 469 ubiquitylated proteins were identified in merozoites compared with only 160 in the preceding intracellular schizont stage, indicating a large increase in protein ubiquitylation associated with merozoite maturation. Following merozoite invasion of erythrocytes, few ubiquitylated proteins were detected in the first intracellular ring stage but as parasites matured through trophozoite to schizont stages the extent of ubiquitylation increased. We identified commonly used ubiquitylation motifs and groups of ubiquitylated proteins in specific areas of cellular function, for example merozoite pellicle proteins involved in erythrocyte invasion, exported proteins, and histones. To investigate the importance of ubiquitylation we screened ubiquitin pathway inhibitors in a parasite growth assay and identified the ubiquitin activating enzyme (UBA1 or E1) inhibitor, MLN7243 (TAK-243) to be particularly effective. This small molecule was shown to be a potent inhibitor of recombinant PfUBA1, and a structural homology model of MLN7243 bound to the parasite enzyme highlights avenues for the development of P. falciparum specific inhibitors. We constructed a genetically modified parasite with a rapamycin-inducible functional deletion of uba1; addition of either MLN7243 or rapamycin to the recombinant parasite line resulted in the same phenotype, with parasite development blocked at the schizont stage. These results indicate that the intracellular target of MLN7243 is UBA1, and this activity is essential for the final differentiation of schizonts to merozoites. The ubiquitylation of many merozoite proteins and their disappearance in ring stages are consistent with the idea that ubiquitylation leads to their destruction via the proteasome once their function is complete following invasion, which would allow amino acid recycling in the period prior to the parasite’s elaboration of a new food vacuole.

Project description:Cyclic nucleotide signalling is a major regulator of malaria parasite differentiation. Specific phosphodiesterase (PDE) enzymes are known to control cGMP levels in the parasite, but the mechanisms by with cAMP is regulated remain enigmatic. Here we show that P. falciparum PDEbeta translocates via the ER to an apical location and finally to the plasma membrane of merozoites within the segmented schizont. PDEbeta is essential for blood stage replication, with conditional gene disruption causing a profound invasion phenotype and rapid death of those merozoites that are able to invade a host erythrocyte. Importantly we also demonstrate that PDEbeta is able to hydrolyse both cAMP and cGMP. Loss of PDEbeta activity results in significantly elevated levels of cAMP which correlate temporally with the observed reduction in merozoite invasion. Quantitative phosphoproteomic analysis revealed a >2-fold increase in phosphorylation for >250 phosphosites following silencing of PfPDEbeta. These included a highly significant increase in phosphorylation at PKA substrate consensus sequences. Our results suggest that dysregulated phosphorylation of MyoA S19 and AMA1 S610 likely contributes to the PfPDEbeta knockout invasion phenotype, that PKG activity governs cAMP levels and PKA activation prior to merozoite egress, and that PfPDEbeta has an essential function in regulation cAMP levels in early intra-erythrocytic development in P. falciparum.

Project description:Background: Considerable work has been carried out to understand the biology of the intermediate stages, the tachyzoite and bradyzoite, of Toxoplasma gondii in large part due to the accessible culturing methods for these stages. However, culturing methods for stages beyond the bradyzoite, including the merozoite and sexual stages, have not been developed hindering the ability to study a large portion of the parasite’s life cycle. We begin to unravel the molecular aspects of the merozoite stage focusing on gene expression. Results: To initiate this, we harvested merozoite parasites and hybridized mRNA to the Affymetrix Toxoplasma GeneChip. We analyzed the merozoite data in context of the life cycle by combining it with a previously published study that generated array data for the oocyst, tachyzoite, and bradyzoite stages (Fritz HM et al. PLoS One, 2012). Principal component analysis highlights the unique profile of the merozoite samples, placing them approximately half-way on a continuum between the tachyzoite/bradyzoite and oocyst samples. Prior studies have shown that antibodies to surface antigen p30 (SAG1) and many dense granule proteins do not label merozoites, and our microarray data confirms that these genes are not expressed at this stage. Also, the expression for many rhoptry and microneme proteins is drastically reduced while the expression for many surface antigens is increased at the merozoite stage. Gene Ontology and KEGG analysis reveals that genes involved in transcription/translation and many metabolic pathways are upregulated at the merozoite stage, highlighting unique growth requirements of this stage. We also show that an upstream promoter region of a merozoite specific gene is sufficient to control stage specific expression at the merozoite stage. Conclusion: The merozoite represents the first developmental stage within the gut of the definitive host. Determining the correct conditions that coax the parasite into the merozoite stage in vitro may allow the parasite to complete sexual development. The data presented here describe the global gene expression profile of merozoite stage and the creation of transgenic parasite strains that will be useful in unlocking how the parasite senses and responds to the felid gut environment to initiate coccidian development. The ToxoGeneChip microarray was used to measure both tachyzoite and merozoite mRNA expression in the type II TgNmBr1 strain.

Project description:Plasmodium falciparum causes the most severe form of malaria in humans. The protozoan parasite develops within erythrocytes to mature schizonts, that contain more than 16 merozoites, which egress and invade fresh erythrocytes. The aspartic protease plasmepsin X (PMX), processes proteins and proteases essential for merozoite egress from the schizont and invasion of the host erythrocyte, including the leading vaccine candidate PfRh5. PfRh5 is anchored to the merozoite surface through a 5-membered complex (PCRCR), consisting of Plasmodium thrombospondin-related apical merozoite protein (PTRAMP), cysteine-rich small secreted protein (CSS), Rh5-interacting protein (PfRipr) and cysteine-rich protective antigen (CyRPA). We show that PCRCR is processed by PMX in micronemes to remove the N-terminal prodomain and this activates the function of the complex unmasking a form that can bind basigin on the erythrocyte membrane and mediate merozoite invasion. The ability to activate PCRCR at a specific time in merozoite invasion ensures invasion inhibitory epitopes are exposed to the immune system for a minimal time but also mask potential deleterious effects of its function until they are required. These results provide an important understanding of the essential roles of PMX and the fine regulation of PCRCR function in P. falciparum biology.

Project description:Obligate intracellular parasites must efficiently invade host cells in order to mature and be transmitted. For the malaria parasite Plasmodium falciparum, invasion of host red blood cells (RBCs) is essential. Here we describe a parasite-specific transcription factor belonging to the Apicomplexan Apetala 2 (ApiAP2) family that is responsible for regulating the expression of a subset of merozoite genes involved in RBC invasion (PfAP2-I). Our genome-wide analysis by ChIP-seq shows that PfAP2-I interacts with a specific DNA motif in the promoters of these genes. msp5 transcription levels decrease when the PfAP2-I DNA-binding motif is mutated in PfAP2-I-GFP parasites, showing that PfAP2-I must bind the DNA motif in order for msp5 to be transcribed.

Project description:Obligate intracellular parasites must efficiently invade host cells in order to mature and be transmitted. For the malaria parasite Plasmodium falciparum, invasion of host red blood cells (RBCs) is essential. Here we describe a parasite-specific transcription factor belonging to the Apicomplexan Apetala 2 (ApiAP2) family that is responsible for regulating the expression of a subset of merozoite genes involved in RBC invasion (PfAP2-I). Our genome-wide analysis by ChIP-seq shows that PfAP2-I interacts with a specific DNA motif in the promoters of these genes. msp5 transcription levels decrease when the PfAP2-I DNA-binding motif is mutated in PfAP2-I-GFP parasites, showing that PfAP2-I must bind the DNA motif in order for msp5 to be transcribed.

Project description:Red blood cell (RBC) invasion by Plasmodium merozoites requires multiple steps that are regulated by signalling pathways. However, the signalling pathways in merozoites that regulate microneme secretion and RBC invasion are not completely understood. Exposure of P. falciparum merozoites to a low potassium (K+) ionic environment as found in blood plasma has been shown to lead to a rise in cytosolic calcium (Ca2+), which triggers microneme secretion. Here, we present a phosphoproteome analysis of extracellular merozoites revealing 3700 phosphorylation sites of which 1705 were not previously known. Upon investigation of phosphorylation changes in merozoites subjected to different ionic environments (high K+/ low K+) we identified 394 protein phosphorylation sites out of which changes in 143 were Ca2+-dependent. We observed that the catalytic and regulatory subunits of protein kinase A (PfPKAc and PfPKAr), calcium-dependent protein kinase 1 (PfCDPK1) and scaffold protein Pf14-3-3I form a phosphorylation-dependent multiprotein complex when merozoites are exposed to the low K+ signal. Moreover, disruption of this complex using phospho-peptides, or small molecule inhibitors blocks microneme secretion and RBC invasion. This study sheds light on the regulatory mechanisms used by merozoites to invade RBCs and identifies new targets for development of drugs against malaria.

Project description:Sporozoites and merozoites share a number of proteins that are expressed by both stages, including the Apical Membrane Antigen 1 (AMA1) and the Rhoptry Neck Proteins (RONs). Although AMA1 and RONs are essential for merozoite invasion of erythrocytes during asexual blood stage replication of the malaria parasite, their precise function in sporozoites is unclear. Here we performed RFP-trap immunoprecipitation experiments using lysates from transgenic sporozoites expressing RON4 fused to mCherry. RON4, RON2, RON5 and AMA1 were the main proteins identified by mass spectrometry among co-precipitated proteins, showing that AMA1-RON interactions are conserved in salivary gland sporozoites.

Project description:Gene expression in malaria parasites is subject to various layers of regulation, including histone post-translational modifications (PTMs). Gene regulatory mechanisms have been extensively studied during the main developmental stages of Plasmodium parasites inside erythrocytes, from the ring stage following invasion to the schizont stage leading up to egress. However, gene regulation in merozoites that mediate the transition from one host cell to the next is an understudied area of parasite biology. Here, we sought to characterize gene expression and the corresponding histone PTM landscape during this stage of the parasite lifecycle through RNA-seq and ChIP-seq on P. falciparum blood stage schizonts, merozoites, and rings, as well as P. berghei liver stage merozoites. In both hepatic and erythrocytic merozoites, we identified a subset of genes with a unique histone PTM profile characterized by depletion of H3K4me3 in their promoter regions. These genes were upregulated in merozoites and rings, had roles in protein export, translation, and host cell remodeling, and shared a DNA motif. These results indicate that similar regulatory mechanisms may underlie merozoite formation in the liver and blood stages. We also observed that H3K4me2 was deposited in gene bodies of gene families encoding variant surface antigens in erythrocytic merozoites, which may facilitate switching of gene expression between different members of these families. Finally, H3K18me and H2K27me were uncoupled from gene expression and were enriched around the centromeres in erythrocytic merozoites, suggesting roles in the maintenance of chromosomal organization during schizogony. Together, our results demonstrate that extensive changes in gene expression and histone landscape occur during the schizont-to-ring transition to facilitate productive erythrocyte infection. The dynamic remodeling of the transcriptional program in hepatic and erythrocytic merozoites makes this stage attractive as a target for novel anti-malarial approaches that may have activity against both the liver and blood stages.