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:Purpose: this study is to analyze the change of overall transctiption after disruption of Protein Arginine Methyltranferase 5 (PRMT5) in Plasmodium falciparum. Methods: In this study, the transcriptomes of a PfPRMT5 gene knockout (KO) parasite line with its wildtype control were analyzed a custom-desinged Agilent microarray.Total RNA were harvested from the asexual parasites at four stages (ring, early trophozoite, late trophozoite, and schizont)(12h, 24h, 36h, and 46h post-invasion) using the Quick-RNA MiniPrep kit (Zymo Research).

Project description:Two decades after the first Plasmodium transfection, attempts have been made to disrupt more than 3,151 genes in malaria parasites, across five Plasmodium species. While results from rodent malaria transfections have been curated and systematised, empowering large-scale analysis, phenotypic data from human malaria parasite transfections currently exists as individual reports scattered across a the literature. To facilitate systematic analysis of published experimental genetic data across Plasmodium species, we have built PhenoPlasm ( http://www.phenoplasm.org), a database of phenotypes generated by transfection experiments in all Plasmodium parasites. The site provides a simple interface linking citation-backed Plasmodium reverse-genetic phenotypes to gene IDs. The database has been populated with phenotypic data on 367 P. falciparum genes, curated from 176 individual publications, as well as existing data on rodent Plasmodium species from RMgmDB and PlasmoGEM. This is the first time that all available data on P. falciparum transfection experiments has been brought together in a single place. These data are presented using ortholog mapping to allow a researcher interested in a gene in one species to see results across other Plasmodium species. The collaborative nature of the database enables any researcher to add new phenotypes as they are discovered. As an example of database utility, we use the currently available datasets to identify RAP (RNA-binding domain abundant in Apicomplexa)-domain containing proteins as crucial to parasite survival.

Project description:BackgroundPlasmodium parasites undergo several major developmental transitions during their complex lifecycle, which are enabled by precisely ordered gene expression programs. Transcriptomes from the 48-h blood stages of the major human malaria parasite Plasmodium falciparum have been described using cDNA microarrays and RNA-seq, but these assays have not always performed well within non-coding regions, where the AT-content is often 90-95%.ResultsWe developed a directional, amplification-free RNA-seq protocol (DAFT-seq) to reduce bias against AT-rich cDNA, which we have applied to three strains of P. falciparum (3D7, HB3 and IT). While strain-specific differences were detected, overall there is strong conservation between the transcriptional profiles. For the 3D7 reference strain, transcription was detected from 89% of the genome, with over 78% of the genome transcribed into mRNAs. We also find that transcription from bidirectional promoters frequently results in non-coding, antisense transcripts. These datasets allowed us to refine the 5' and 3' untranslated regions (UTRs), which can be variable, long (>?1000?nt), and often overlap those of adjacent transcripts.ConclusionsThe approaches applied in this study allow a refined description of the transcriptional landscape of P. falciparum and demonstrate that very little of the densely packed P. falciparum genome is inactive or redundant. By capturing the 5' and 3' ends of mRNAs, we reveal both constant and dynamic use of transcriptional start sites across the intraerythrocytic developmental cycle that will be useful in guiding the definition of regulatory regions for use in future experimental gene expression studies.

Project description:The exosome complex plays a central role in RNA metabolism, and each of its core subunits is essential for viability in yeast However, comprehensive studies of exosome substrates and functional analyses of its subunits in multi.CELlular eukaryotes are lacking Here we show that, in sharp contrast to yeast and metazoan exosome complexes, individual subunits of the plant exosome core are functionally specialized Using whole-genome oligonucleotide tiling microarray analyses of csl4 null mutant plants and conditional genetic depletions of RRP4 and RRP41, we uncovered unexpected functional plasticity in the plant exosome core as well as generated a set of high-resolution genome-wide maps of Arabidopsis exosome targets These analyses provide evidence for widespread polyadenylation- and exosome-mediated RNA quality control in plants and reveal novel aspects of stable structural RNA metabolism Finally, numerous novel exosome substrates were discovered, including a select subset of mRNAs, miRNA processing intermediates, and hundreds of noncoding RNAs, the vast majority of which have not been previously described This large collection of RNAs belong to a Òdeeply hiddenÓ layer of the transcriptome that is tightly repressed and can only be visualized upon inhibition of exosome activity These first genome-wide maps of exosome substrates will aid in illuminating new fundamental components and regulatory mechanisms of eukaryotic transcriptomes Keywords: Strand-specific gene expression analysis using whole-genome oligonucleotide tiling microarray analyses of three exosome subunits, using csl4 null mutant plants and conditional genetic depletions of RRP4 and RRP41.

Project description:Purpose: this study is to analyze the change of RNA splicing events after disruption of Protein Arginine Methyltranferase 5 (PRMT5) in Plasmodium falciparum. Methods: In this study, the transcriptomes of a PfPRMT5 gene knockout (KO) parasite line with its wildtype control were analyzed by RNAseq.Total RNA were harvested from the asexual parasites at four stages (ring, early trophozoite, late trophozoite, and schizont)(12h, 24h, 36h, and 46h post-invasion) using the Quick-RNA MiniPrep kit (Zymo Research). RNA sequencing libraries were prepared using the KAPA stranded RNA-seq library preparation kit (Roche) with 500 ng RNA from each sample. Illumina adapter sequence removal and quality trimming of reads were performed using Trimmomatic. Only reads that had a minimum length of 50 base pairs were retained. Reads were then mapped to the P. falciparum 3D7 strain reference genome with HISAT2. Results: This RNAseq analysis with strand-specific mRNA libraries from both ΔPfPRMT5 and WT lines showed that >90% of sequencing reads were of high quality for mapping to the P. falciparum genome with nearly 40 times of coverage. This allows us to analyze the change of alternative splicing events (alternative 5' splice site, alternative 3' splice site, retained intron and skipped exon). 800, 1056, 479, and 1158 alternative splicing events (alternative 5' splice site, alternative 3' splice site, retained intron and skipped exon) were altered in the DPfPRMT5 parasite line as compared to the WT line at four development stages, respectively (unpublished data). Conclusions: Collectively, this RNAseq provide a dataset for analysis of abnormal RNA splicing events in the ΔPfPRMT5 parasites.

Project description:Gene expression in Plasmodium falciparum is tightly regulated to ensure successful propagation of the parasite throughout its complex life cycle. The earliest transcriptomics studies in P. falciparum suggested a cascade of transcriptional activity over the course of the 48-hour intraerythrocytic developmental cycle (IDC); however, the just-in-time transcriptional model has recently been challenged by findings that show the importance of post-transcriptional regulation. To further explore the role of transcriptional regulation, we performed the first genome-wide nascent RNA profiling in P. falciparum. Our findings indicate that the majority of genes are transcribed simultaneously during the trophozoite stage of the IDC and that only a small subset of genes is subject to differential transcriptional timing. RNA polymerase II is engaged with promoter regions prior to this transcriptional burst, suggesting that Pol II pausing plays a dominant role in gene regulation. In addition, we found that the overall transcriptional program during gametocyte differentiation is surprisingly similar to the IDC, with the exception of relatively small subsets of genes. Results from this study suggest that further characterization of the molecular players that regulate stage-specific gene expression and Pol II pausing will contribute to our continuous search for novel antimalarial drug targets.

Project description:To facilitate pre-eythrocytic malaria vaccine and drug target identification, a comprehensive transcriptome analysis of the parasites liver stages (LS) was undertaken. Green fluorescent protein-tagged Plasmodium yoelii (PyGFP) was used to isolate LS-infected hepatocytes from the rodent host. Genome-wide LS gene expression was profiled and compared to other parasite life cycle stages. The analysis reveals ~2000 genes active during LS development. Keywords: Stage comparison, time course

Project description:Choline analogs represent a novel class of antimalarial compounds with strong potency against drug-sensitive and resistant P. falciparum. Although, these drugs are presumed to target proteins within lipid biosynthesis pathways; their complete mechanism of action and the parasite’s compensatory response remain to be elucidated. We have applied transcriptional profiling to characterize the global response to the choline analog T4 during the P. falciparum intraerythrocytic life cycle Keywords: Trascriptome analysis of Plasmodium falciparum in response to external stimuli using the affymetrix platform GPL3575

Project description:We report the results of a genome-wide analysis of transcription in Arabidopsis thaliana after treatment with Pseudomonas syringae pathovar tomato. Our time course RNA-Seq experiment uses over 500 million read pairs to provide a detailed characterization of the response to infection in both susceptible and resistant hosts. The set of observed differentially expressed genes is consistent with previous studies, confirming and extending existing findings about genes likely to play an important role in the defense response to Pseudomonas syringae. The high coverage of the Arabidopsis transcriptome resulted in the discovery of a surprisingly large number of alternative splicing (AS) events--more than 44% of multi-exon genes showed evidence for novel AS in at least one of the probed conditions. This demonstrates that the Arabidopsis transcriptome annotation is still highly incomplete, and that AS events are more abundant than expected. To further refine our predictions, we identified genes with statistically significant changes in the ratios of alternative isoforms between treatments. This set includes several genes previously known to be alternatively spliced or expressed during the defense response, and it may serve as a pool of candidate genes for regulated alternative splicing with possible biological relevance for the defense response against invasive pathogens.