Project description:The mutually exclusive expression of virulence genes is critical for the immune evasion and pathogenesis of malaria parasites, Plasmodium falciparum, in human host. The three-dimensional genome structure has emerged as a new factor involved in transcriptional regulation of virulence gene families in the parasites. However, the mechanism controlling this epigenetic regulation pathway remains elusive. Here, we have identified the highly conserved high mobility group protein HMGB1 as a critical architectural regulator in establishment of high-order genome structure via interaction with centromeres in P. falciparum. Genetic manipulation of Pfhmgb1 gene and Hi-C analysis showed that the boundary of telomere and centromere clusters in an opposite spatial relationship in the nucleus was disrupted upon hmgb1 knockout. The collapse of euchromatic centromere cluster from nuclear periphery towards the opposite heterochromatic telomere cluster triggered relocation of the original active var gene, which resulted in complete silence of the entire repertoire of var gene family. ChIP-seq and fluorescence assay analysis confirmed the specific interaction between PfHMGB1 and centromeres. Meanwhile, as in other eukaryotes, PfHMGB1 was also widely present on the promoter regions of a variety of genes and co-regulated transcription, including other non-var variant gene families, suggesting multiple dimensions of epigenetic gene regulation by PfHMGB1. Finally, the natural genome organization could be reconstructed by hmgb1 gene complementation, which rescued the mutually exclusive expression of virulence genes. Taken together, our work provides new insight into the evolution of biological functions of the HMG architectural superfamily in eukaryotes.

Project description:The mutually exclusive expression of virulence genes is critical for the immune evasion and pathogenesis of malaria parasites, Plasmodium falciparum, in human host. The three-dimensional genome structure has emerged as a new factor involved in transcriptional regulation of virulence gene families in the parasites. However, the mechanism controlling this epigenetic regulation pathway remains elusive. Here, we have identified the highly conserved high mobility group protein HMGB1 as a critical architectural regulator in establishment of high-order genome structure via interaction with centromeres in P. falciparum. Genetic manipulation of Pfhmgb1 gene and Hi-C analysis showed that the boundary of telomere and centromere clusters in an opposite spatial relationship in the nucleus was disrupted upon hmgb1 knockout. The collapse of euchromatic centromere cluster from nuclear periphery towards the opposite heterochromatic telomere cluster triggered relocation of the original active var gene, which resulted in complete silence of the entire repertoire of var gene family. ChIP-seq and fluorescence assay analysis confirmed the specific interaction between PfHMGB1 and centromeres. Meanwhile, as in other eukaryotes, PfHMGB1 was also widely present on the promoter regions of a variety of genes and co-regulated transcription, including other non-var variant gene families, suggesting multiple dimensions of epigenetic gene regulation by PfHMGB1. Finally, the natural genome organization could be reconstructed by hmgb1 gene complementation, which rescued the mutually exclusive expression of virulence genes. Taken together, our work provides new insight into the evolution of biological functions of the HMG architectural superfamily in eukaryotes.

Project description:The mutually exclusive expression of virulence genes is critical for the immune evasion and pathogenesis of malaria parasites, Plasmodium falciparum, in human host. The three-dimensional genome structure has emerged as a new factor involved in transcriptional regulation of virulence gene families in the parasites. However, the mechanism controlling this epigenetic regulation pathway remains elusive. Here, we have identified the highly conserved high mobility group protein HMGB1 as a critical architectural regulator in establishment of high-order genome structure via interaction with centromeres in P. falciparum. Genetic manipulation of Pfhmgb1 gene and Hi-C analysis showed that the boundary of telomere and centromere clusters in an opposite spatial relationship in the nucleus was disrupted upon hmgb1 knockout. The collapse of euchromatic centromere cluster from nuclear periphery towards the opposite heterochromatic telomere cluster triggered relocation of the original active var gene, which resulted in complete silence of the entire repertoire of var gene family. ChIP-seq and fluorescence assay analysis confirmed the specific interaction between PfHMGB1 and centromeres. Meanwhile, as in other eukaryotes, PfHMGB1 was also widely present on the promoter regions of a variety of genes and co-regulated transcription, including other non-var variant gene families, suggesting multiple dimensions of epigenetic gene regulation by PfHMGB1. Finally, the natural genome organization could be reconstructed by hmgb1 gene complementation, which rescued the mutually exclusive expression of virulence genes. Taken together, our work provides new insight into the evolution of biological functions of the HMG architectural superfamily in eukaryotes.

Project description:The P. falciparum genome is equipped with several subtelomeric gene families that are implicated in parasite virulence and immune evasion. The members of these gene families are uniformly positioned within heterochromatic domains of the genome and are thus subject to variegated expression. The best-studied example is that of the var gene family encoding the major parasite virulence factor P. falciparum erythrocyte membrane protein 1 (PfEMP1). Transcriptional regulation of other subtelomeric gene families and their role in parasite biology is much less understood. Here, we investigated the mode of transcriptional control of var, rif, stevor, phist and pfmc-2tm families by comparative genome-wide transcriptional profiling of transgenic parasite lines. Our results establish a clear functional distinction between var and non-var transcriptional control mechanisms. Unlike var promoters, we find that promoters of non-var families are not silenced by default. Moreover, we show that mutually exclusive transcription is unique to the var gene family.

Project description:The P. falciparum genome is equipped with several subtelomeric gene families that are implicated in parasite virulence and immune evasion. The members of these gene families are uniformly positioned within heterochromatic domains of the genome and are thus subject to variegated expression. The best-studied example is that of the var gene family encoding the major parasite virulence factor P. falciparum erythrocyte membrane protein 1 (PfEMP1). Transcriptional regulation of other subtelomeric gene families and their role in parasite biology is much less understood. Here, we investigated the mode of transcriptional control of var, rif, stevor, phist and pfmc-2tm families by comparative genome-wide transcriptional profiling of transgenic parasite lines. Our results establish a clear functional distinction between var and non-var transcriptional control mechanisms. Unlike var promoters, we find that promoters of non-var families are not silenced by default. Moreover, we show that mutually exclusive transcription is unique to the var gene family. 3D7 wild-type parasites were transfected with constructs carrying eight different promoters that drive expression of the drug-selectable marker hdhfr-gfp. Thereof seven promoters are members of the multigene families upsA var, upsB var, upsC var, rif, stevor, phistb and pfmc-2tm. The cam promoter was used as transfection-based control and also a wild-type 3D7 cell line was included as control. These nine cell lines were subjected to genome-wide transcriptional profiling. Parasites were synchronized to obtain an 8 hour growth window and were harvested at four consecutive timepoints (TP): TP1 (6-14 hours post-invasion (hpi)); TP2 (14-22 hpi); TP3 (22-30 hpi); TP4 (30-38 hpi) to monitor intra- and inter-family specific linkage of multigene family expression.

Project description:The var multigene family encodes clonally variant surface antigens that are key to immune evasion and pathogenesis in the human malaria parasite, Plasmodium falciparum. Epigenetics and nuclear organization regulate the var gene family in a system of mutually exclusive expression; however, few factors have been shown to play a direct role in these processes. Thus, we adapted a CRISPR-based immunoprecipitation-mass spectrometry approach for identification of novel factors associated with var genes in their natural chromatin context. A tagged, catalytically inactive Cas9 (“dCas9”) was targeted to the promoters or introns of a subset of var genes and subjected to immunoprecipitation followed by label-free LC-MS/MS. A non-targeted dCas9 served as a control.

Project description:Epigenetic regulation of mutually exclusive transcription within the var gene family is important for infection and pathogenesis of the malaria parasite Plasmodium falciparum. var genes are kept transcriptionally silent via heterochromatic clusters located at the nuclear periphery; however, only a few proteins have been shown to play a direct role in var gene transcriptional regulation. Importantly, the chromatin components that contribute to var gene nuclear organization remain unknown. Here, we adapted a CRISPR-based immunoprecipitation-mass spectrometry approach for de novo identification of factors associated with specific transcriptional regulatory sequences of var genes. Tagged, catalytically inactive Cas9 (“dCas9”) was targeted to var gene promoters or introns, cross-linked, and immunoprecipitated with all DNA, proteins, and RNA associated with the targeted locus. Chromatin immunoprecipitation followed by sequencing demonstrated that genome-wide dCas9 binding was specific and robust. Proteomics analysis of dCas9-immunoprecipitates identified specific proteins for each target region, including known and novel factors such as DNA binding proteins, chromatin remodelers, and structural proteins. We also demonstrate the ability to immunoprecipitate RNA that is closely associated to the targeted locus. Our CRISPR/dCas9 study establishes a new tool for targeted purification of specific genomic loci and advances understanding of virulence gene regulation in the human malaria parasite.

Project description:The variant antigen, Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1), expressed on the surface of P. falciparum infected Red Blood Cells (iRBCs) is a critical virulence factor for malaria. Each parasite encodes 60 antigenically distinct var genes encoding PfEMP1s, but during infection the clonal parasite population expresses only one gene at a time before switching to the expression of a new variant antigen as an immune evasion mechanism to avoid the host’s antibody responses. The mechanism by which 59 of the 60 var genes are silenced remains largely unknown. We used microarrays to detail the global programme changes of gene expression caused by each gene knockout with a particular view towards which gene knockout results in transcriptional upregulation of the entire var gene family.

Project description:ChIP-seq experiments were performed for the putative Telomere Repeat-binding Zinc finger protein (PfTRZ) in the malaria parasite Plasmodium falciparum strain 3D7. The gene encoding this factor (PF3D7_1209300) was endogenously tagged with either a GFP- or a 3xHA-tag and these transgenic parasite lines were used in ChIP-sequencing experiments. Sequencing of the ChIP and input libraries showed enrichment of PfTRZ at all telomere-repeat containing chromosome ends (reference genome Plasmodium falciparum 3D7 from PlasmoDB version 6.1) as well as in all upsB var promoters.In addition,PfTRZ was enriched at seven additional, intra-chromosomal sites and called in the PfTRZ-HA ChIP-seq only.

Project description:Centromere identity is defined and maintained epigenetically by the presence of the histone variant CENP-A. How centromeric CENP-A position is specified and precisely maintained through DNA replication is not fully understood. The recently released Telomere-to-Telomere (T2T-CHM13) genome assembly containing the first complete human centromere sequences provides a new resource for examining CENP-A position. Mapping CENP-A position in clones of the same cell line to T2T-CHM13 identified highly similar CENP-A position following multiple cell divisions. In contrast, centromeric CENP-A epialleles were evident at several centromeres of different human cell lines, demonstrating the location of CENP-A enrichment and site of kinetochore recruitment varies among human cells. Across the cell cycle, CENP-A molecules deposited in G1 phase are maintained at their precise position through DNA replication. Thus, despite CENP-A dilution during DNA replication, CENP-A is precisely reloaded onto the same sequences within the daughter centromeres, maintaining unique centromere identity among human cells.