Project description:Artemisinin resistance in Plasmodium falciparum, clinically presented as prolonged parasite clearance half-life, has been associated with a mutation in the NLI-interacting factor-like phosphatase PfNIF4, in addition to the mutations in the Kelch13 protein as the major determinant. We found that PfNIF4 predominant expression at the schizont stage and localized in the nuclei of the parasite. To elucidate the functions of PfNIF4 in P. falciparum, we performed PfNIF4 knockdown (KD) using the inducible ribozyme system. PfNIF4 KD attenuated merozoite invasion and affected gametocytogenesis. PfNIF4 KD parasites also showed significantly increased in vitro susceptibility to artemisinins. Transcriptomic analysis revealed that PfNIF4 KD led to significant changes in the expression of approximately 10-25% of parasite genes during the IDC. At the schizont stage, down-regulated genes were significantly enriched in the invasion-related terms, while at the trophozoite and schizont stages, pathways associated with artemisinin resistance (e.g., mitochondrial function, membrane, and Kelch13 interactome) were also down-regulated. Consistent with PfNIF4 being a protein phosphatase, PfNIF4 KD resulted in an overall up-regulation of the phosphoproteome of infected erythrocytes. Specifically, we observed increased phosphorylation of Ser2/5 of the tandem repeats in the Rpb1 C-terminal domain (CTD) of RNA polymerase II (RNAPII) upon PfNIF4 KD. Furthermore, using the TurboID-based proteomic approach, we identified that PfNIF4 interacted with the RNA polymerase II (RNAPII) components, AP2-domain transcription factors, and chromatin-modifiers and binders. These findings suggest that PfNIF4 may act as the RNAPII CTD phosphatase, regulating the expression of general and parasite-specific cellular pathways during the blood-stage development.

Project description:Artemisinin resistance in Plasmodium falciparum, clinically presented as prolonged parasite clearance half-life, has been associated with a mutation in the NLI-interacting factor-like phosphatase PfNIF4, in addition to the mutations in the Kelch13 protein as the major determinant. We found that PfNIF4 predominant expression at the schizont stage and localized in the nuclei of the parasite. To elucidate the functions of PfNIF4 in P. falciparum, we performed PfNIF4 knockdown (KD) using the inducible ribozyme system. PfNIF4 KD attenuated merozoite invasion and affected gametocytogenesis. PfNIF4 KD parasites also showed significantly increased in vitro susceptibility to artemisinins. Transcriptomic analysis revealed that PfNIF4 KD led to significant changes in the expression of approximately 10-25% of parasite genes during the IDC. At the schizont stage, down-regulated genes were significantly enriched in the invasion-related terms, while at the trophozoite and schizont stages, pathways associated with artemisinin resistance (e.g., mitochondrial function, membrane, and Kelch13 interactome) were also down-regulated. Consistent with PfNIF4 being a protein phosphatase, PfNIF4 KD resulted in an overall up-regulation of the phosphoproteome of infected erythrocytes. Specifically, we observed increased phosphorylation of Ser2/5 of the tandem repeats in the Rpb1 C-terminal domain (CTD) of RNA polymerase II (RNAPII) upon PfNIF4 KD. Furthermore, using the TurboID-based proteomic approach, we identified that PfNIF4 interacted with the RNA polymerase II (RNAPII) components, AP2-domain transcription factors, and chromatin-modifiers and binders. These findings suggest that PfNIF4 may act as the RNAPII CTD phosphatase, regulating the expression of general and parasite-specific cellular pathways during the blood-stage development.

Project description:Artemisinin resistance in Plasmodium falciparum, clinically presented as prolonged parasite clearance half-life, has been associated with a mutation in the NLI-interacting factor-like phosphatase PfNIF4, in addition to the mutations in the Kelch13 protein as the major determinant. We found that PfNIF4 predominant expression at the schizont stage and localized in the nuclei of the parasite. To elucidate the functions of PfNIF4 in P. falciparum, we performed PfNIF4 knockdown (KD) using the inducible ribozyme system. PfNIF4 KD attenuated merozoite invasion and affected gametocytogenesis. PfNIF4 KD parasites also showed significantly increased in vitro susceptibility to artemisinins. Transcriptomic analysis revealed that PfNIF4 KD led to significant changes in the expression of approximately 10-25% of parasite genes during the IDC. At the schizont stage, down-regulated genes were significantly enriched in the invasion-related terms, while at the trophozoite and schizont stages, pathways associated with artemisinin resistance (e.g., mitochondrial function, membrane, and Kelch13 interactome) were also down-regulated. Consistent with PfNIF4 being a protein phosphatase, PfNIF4 KD resulted in an overall up-regulation of the phosphoproteome of infected erythrocytes. Specifically, we observed increased phosphorylation of Ser2/5 of the tandem repeats in the Rpb1 C-terminal domain (CTD) of RNA polymerase II (RNAPII) upon PfNIF4 KD. Furthermore, using the TurboID-based proteomic approach, we identified that PfNIF4 interacted with the RNA polymerase II (RNAPII) components, AP2-domain transcription factors, and chromatin-modifiers and binders. These findings suggest that PfNIF4 may act as the RNAPII CTD phosphatase, regulating the expression of general and parasite-specific cellular pathways during the blood-stage development.

Project description:We exploited the phosphorylation state of the RNAPII CTD to assess the transcriptional status of most P. falciparum genes across the IDC. We raised highly specific monoclonal antibodies against three forms of the parasite CTD, namely unphosphorylated, Ser5-P and Ser2/5-P, and used these in ChIP-on-chip type experiments to map the genome-wide recruitment and activity of RNAPII.

Project description:We exploited the phosphorylation state of the RNAPII CTD to assess the transcriptional status of most P. falciparum genes across the IDC. We raised highly specific monoclonal antibodies against three forms of the parasite CTD, namely unphosphorylated, Ser5-P and Ser2/5-P, and used these in ChIP-on-chip type experiments to map the genome-wide recruitment and activity of RNAPII. We raised and used 3 different anti-RNAPII antibodies in ChIP-on-chip analysis to map the position and status of RNAPII across the entire P. falciparum genome over the 48 h of the IDC at 8 h intervals resulting in TP1-6. Total 4 antibodies were used for ChIP-chip analysis for six time points each done in triplicates, except one antibody 8WG16 which was done in duplicate. We also used 8WG16, commercial RNAPII antibody in similar study done in duplicates.

Project description:Plasmodium falciparum, the most pathogenic human malaria parasite, infects millions of human beings and causes a serious public health threat. Currently, the most potent anti-malarial drugs are artemisinin and its derivatives1,2. Artemisinin is a sesquiterpene lactone with an endoperoxide bridge3. The activation of artemisinin requires the cleavage of the endoperoxide bridge in the presence of iron sources4. Once activated, artemisinins are converted into highly reactive carbon-centered radicals5,6 that attack macromolecules through alkylation and propagate a series of damages, eventually leading to parasite death7,8. Even though several parasite proteins have been reported as the targets of artemisinin9,10, the exact mechanism of artemisinin action is still controversial and its high potency and specificity against the malaria parasite could not be fully accounted. Here, we have developed an unbiased chemical proteomics approach to directly probe the mechanism of action of artemisinin in P. falciparum in situ. An alkyne-tagged artemisinin analogue coupled with biotin enables selective purification and identification of 124 artemisinin covalent-binding protein targets, many of which are involved in essential biological processes of the parasite. In vitro assays confirm the specific artemisinin binding and inhibition of selected targets. Such a broad targeting spectrum disrupts the biochemical landscape of the parasite and causes its death. Furthermore, using the alkyne-tagged artemisinin coupled with a fluorescent dye to monitor its protein binding, we showed that heme, rather than free ferrous iron, is predominantly responsible for artemisinin activation. The extremely high level of heme released from the hemoglobin digestion by the parasite make artemisinin exceptionally potent against late-stage parasites (trophozoite and schizont stages) compared to parasites at early ring stage, which have low level of heme, mainly from endogenous synthesis. The ‘blood eating’ nature of the parasite with the release of large amounts of heme confers artemisinin with extremely high specificity against the parasites, with minimum side effects towards healthy red blood cells. Taken together, our results established a unifying model to explain the action and specificity of artemisinin in parasite killing. Our findings could facilitate the development of better alternative strategies to treat malaria in times of emerging artemisinin resistance11,12.

Project description:Proteome of the human malaria parasite Plasmodium falciparum at schizont life cycle stage during blood stage development

Project description:We identified unconventional histone lysine trimethylation mark in the nucleosome core at H3K64 position in human malaria parasite Plasmodium falciparum. Global ChIP analysis was performed using anti-H3K64me3 specific antibody for three major blood stages, i.e. ring, trophozoite and schizont stages to identify the genomic position of the H3K64me3. The sheared chromatin was prepared from highly synchronous P. falciparum culture and subjected for ChIP followed by library preparation from the ChIP DNA and were subjected to sequencing using the HiSeq Illumina platform. H3K64me3 binding sites were determined after sequence alignment and normalization with input sequence. Interestingly, there was a significant reduction in the number of peaks on different chromosomes during multinucleated schizont stage as compared to ring and trophozoite stage. Collectively, this is first study to show that H3K64me3 function as repressor methyl mark during ring and trophozoite stages to regulate the expression of schizont specific export family of proteins in P. falciparum.

Project description:Background: Plasmodium falciparum causes the majority of malaria mortality worldwide, and the disease occurs during the asexual red blood cell (RBC) stage of infection. In the absence of an effective and available vaccine, and with increasing drug resistance, asexual RBC stage parasites are an important research focus. In recent years, mass spectrometry-based proteomics using Data Dependent Acquisition (DDA) has been extensively used to understand the biochemical processes within the parasite. However, DDA is problematic for the detection of low abundance proteins, protein coverage, and has poor run-to-run reproducibility. Results: Here, we present a comprehensive P. falciparum-infected RBC (iRBC) spectral library to measure the abundance of 44,449 peptides from 3,113 P. falciparum and 1,617 RBC proteins using a Data Independent Acquisition (DIA) approach. The spectral library includes proteins expressed in the three morphologically distinct RBC stages (ring, trophozoite, schizont), the RBC compartment of trophozoite-iRBCs, and the cytosolic fractions from uninfected RBCs (uRBC). This spectral library contains 87% of P. falciparum proteins with previously blood-stage protein-level evidence as well as 692 previously unidentified proteins. The P. falciparum spectral library was successfully applied to generate semi-quantitative proteomics datasets that characterise the three distinct asexual parasite stages in RBCs, and compare artemisinin resistant (Cam3.IIR539T) and sensitive (Cam3.IIrev) parasites. Conclusion: A reproducible, high-coverage proteomics spectral library and analysis method has been generated for investigating sets of proteins expressed in the iRBC stage of P. falciparum malaria. This will provide a foundation for an improved understanding of parasite biology, pathogenesis, drug mechanisms and vaccine candidate discovery for malaria.

Project description:Background: Plasmodium falciparum causes the majority of malaria mortality worldwide, and the disease occurs during the asexual red blood cell (RBC) stage of infection. In the absence of an effective and available vaccine, and with increasing drug resistance, asexual RBC stage parasites are an important research focus. In recent years, mass spectrometry-based proteomics using Data Dependent Acquisition (DDA) has been extensively used to understand the biochemical processes within the parasite. However, DDA is problematic for the detection of low abundance proteins, protein coverage, and has poor run-to-run reproducibility. Results: Here, we present a comprehensive P. falciparum-infected RBC (iRBC) spectral library to measure the abundance of 44,449 peptides from 3,113 P. falciparum and 1,617 RBC proteins using a Data Independent Acquisition (DIA) approach. The spectral library includes proteins expressed in the three morphologically distinct RBC stages (ring, trophozoite, schizont), the RBC compartment of trophozoite-iRBCs, and the cytosolic fractions from uninfected RBCs (uRBC). This spectral library contains 87% of P. falciparum proteins with previously blood-stage protein-level evidence as well as 692 previously unidentified proteins. The P. falciparum spectral library was successfully applied to generate semi-quantitative proteomics datasets that characterise the three distinct asexual parasite stages in RBCs, and compare artemisinin resistant (Cam3.IIR539T) and sensitive (Cam3.IIrev) parasites. Conclusion: A reproducible, high-coverage proteomics spectral library and analysis method has been generated for investigating sets of proteins expressed in the iRBC stage of P. falciparum malaria. This will provide a foundation for an improved understanding of parasite biology, pathogenesis, drug mechanisms and vaccine candidate discovery for malaria.