Project description:Malaria-causing Plasmodium vivax parasites can linger in the human liver for weeks to years, and then reactivate to cause recurrent blood-stage infection. While an important target for malaria eradication, little is known about the molecular features of the replicative and non-replicative states of intracellular P. vivax parasites, or their human host-cell dependencies and the host responses to them. Here, we leverage a bioengineered human microliver platform to culture patient-derived P. vivax parasites in primary human hepatocytes and conduct transcriptional profiling. By coupling enrichment strategies with bulk and single-cell analyses, we captured both parasite and host transcripts in individual hepatocytes throughout the infection course. We define host- and state-dependent transcriptional signatures and identify previously unappreciated populations of replicative and non-replicative parasites, sharing features with sexual transmissive forms. We find that infection suppresses transcription of key hepatocyte function genes, and that P. vivax elicits an innate immune response that can be manipulated to control infection. Our work provides an extendible framework and resource for understanding host-parasite interactions and reveals new insights into the biology of P. vivax dormancy and transmission.
Project description:Malaria-causing Plasmodium vivax parasites can linger in the human liver for weeks to years, and then reactivate to cause recurrent blood-stage infection. While an important target for malaria eradication, little is known about the molecular features of the replicative and non-replicative states of intracellular P. vivax parasites, or their human host-cell dependencies and the host responses to them. Here, we leverage a bioengineered human microliver platform to culture patient-derived P. vivax parasites in primary human hepatocytes and conduct transcriptional profiling. By coupling enrichment strategies with bulk and single-cell analyses, we captured both parasite and host transcripts in individual hepatocytes throughout the infection course. We define host- and state-dependent transcriptional signatures and identify previously unappreciated populations of replicative and non-replicative parasites, sharing features with sexual transmissive forms. We find that infection suppresses transcription of key hepatocyte function genes, and that P. vivax elicits an innate immune response that can be manipulated to control infection. Our work provides an extendible framework and resource for understanding host-parasite interactions and reveals new insights into the biology of P. vivax dormancy and transmission.
Project description:A major obstacle in deciphering the hepatic stage of the malaria parasite has been the challenges associated with culturing the infected hepatocytes through the entire liver stage cycle, including that of the dormant form known as hypnozoites. Primary hepatocytes lose their specialized functions in long-term in vitro culture. Hepatocyte infection represents the first step for clinically silent infection and development of malaria parasite Plasmodium in the liver. Thus this liver stage is an ideal target for development of novel antimalarial drugs and vaccine. However, drug discovery against Plasmodium liver stage is severely hampered by the poor understanding of host-cell and parasites interactions during the liver stage infection and development. In this study, we have performed tandem mass tags (TMT) labelling based quantitative proteomic analysis in simian primary hepatocytes cultured in three different systems of susceptibility to plasmodium infection. Our results represent the first documentation of potentially essential molecular markers including asialoglycoprotein receptor (ASGPR), apolipoproteins, squalene synthase and scavenger receptor B1 (SR-BI) required for productive infection and full development in relapsing Plasmodium species. The identification of these candidate proteins for constructive infection and development of Plasmodium in malaria paves the way to explore them as therapeutic targets.
Project description:Single-cell RNA-sequencing is revolutionising our understanding of seemingly homogeneous cell populations but has not yet been widely applied to single-celled organisms. Transcriptional variation in unicellular malaria parasites from the Plasmodium genus is associated with critical phenotypes including red blood cell invasion and immune evasion, yet transcriptional variation at an individual parasite level has not been examined in depth. Here, we describe the adaptation of a single-cell RNA-sequencing (scRNA-seq) protocol to deconvolute transcriptional variation for more than 500 individual parasites of both rodent and human malaria comprising asexual and sexual life-cycle stages. We uncover previously hidden discrete transcriptional signatures during the pathogenic part of the life cycle, suggesting that expression over development is not as continuous as commonly thought. In transmission stages, we find novel, sex-specific roles for differential expression of contingency gene families that are usually associated with immune evasion and pathogenesis.
Project description:Background: Host iron deficiency is protective against severe malaria as the human malaria parasite Plasmodium falciparum depends on free iron from its host to proliferate. Due to the absence of transferrin, ferritin, ferroportin, and a functional heme oxygenase, the parasite’s essential pathways of iron acquisition, storage, export, and detoxification differ from those in humans and may thus be excellent targets for therapeutic development. However, the proteins involved in these processes in P. falciparum remain largely unknown. Experimental design: To identify iron-regulated mechanisms and putative iron transporters in the human malaria parasite Plasmodium falciparum 3D7, we carried out whole-transcriptome profiling using bulk RNA-sequencing. The parasites were cultured either using erythrocytes from a donors with high, medium (healthy) or low iron status (experiment 1); or with red blood cells from another healthy donor in the presence or absence of 0.7 µM hepcidin, a specific ferroportin inhibitor and iron-regulatory hormone (experiment 2). This concentration of hepcidin was reported to reduce binding of ferrous iron to ferroportin by 50% in vitro (39). Samples from three biological replicates each were harvested at the ring and trophozoite stage (6 – 9 and 26 – 29 hours post invasion, hpi) during the second intra-erythrocytic developmental cycle under the conditions specified.
Project description:Malaria, caused by Plasmodium parasites is responsible for the illness of millions of individuals each year. Plasmodium sporozoites inoculated by mosquitoes migrate to the liver and infect hepatocytes prior to release of merozoites that initiate symptomatic blood-stage malaria. Parasites are thought to be restricted to hepatocytes throughout this obligate liver-stage of replication and differentiation. In contrast to this notion, we found that a subset of hepatic dendritic CD11c+ cells co-expressing F4/80, CD103, CD207 and CSF1R, acquired a substantial parasite burden during the liver-stage of malaria, but only after initial hepatocyte infection. These CD11c+ cells found in the infected liver and liver-draining lymph nodes exhibited transcriptionally and phenotypically enhanced antigen-presentation functions; and primed protective CD8 T cell responses against Plasmodium liver-stage restricted antigens. Our findings uncover a novel aspect of Plasmodium biology as well as the fundamental mechanism by which CD8 T cell responses are primed against liver-stage malaria.