Monoallelic expression of the var multigene family enables immune evasion of the malaria parasite Plasmodium falciparum in its human host. At a given time only a single member of the 60-member var gene family is expressed at a discrete perinuclear region called the ‘var expression site’. However, the mechanism of var gene counting remains ill-defined. We hypothesize that activation factors associating specifically with the expression site play a key role in this process. Here, we investigate the role of a GC-rich non-coding RNA (ncRNA) gene family composed of 15 highly homologous members. GC-rich genes are positioned adjacent to var genes in chromosome-central gene clusters but are absent near subtelomeric var genes. Fluorescence in situ hybridization demonstrates that GC-rich ncRNA localizes to the perinuclear expression site of central and subtelomeric var genes in trans. Importantly, overexpression of distinct GC-rich ncRNA members disrupts the gene counting process at the single cell level and results in activation of a specific subset of var genes in distinct clones. We identify the first trans-acting factor targeted to the elusive perinuclear var expression site and open up new avenues to investigate ncRNA function in antigenic variation of malaria and other protozoan pathogens.
The human malaria parasite Plasmodium falciparum uses mutually exclusive expression of the PfEMP1-encoding var gene family to evade the host immune system. Despite progress in the molecular understanding of the default silencing mechanism, the activation mechanism of the uniquely expressed var member remains elusive. A GC-rich noncoding RNA (ncRNA) gene family has coevolved with Plasmodium species that express var genes. Here, we show that this ncRNA family is transcribed in a clonally variant manner, with predominant transcription of a single member occurring when the ncRNA is located adjacent to and upstream of an active var gene. We developed a specific CRISPR interference (CRISPRi) strategy that allowed for the transcriptional repression of all GC-rich members. A lack of GC-rich ncRNA transcription led to the downregulation of the entire var gene family in ring-stage parasites. Strikingly, in mature blood-stage parasites, the GC-rich ncRNA CRISPRi affected the transcription patterns of other clonally variant gene families, including the downregulation of all Pfmc-2TM members. We provide evidence for the key role of GC-rich ncRNA transcription in var gene activation and discovered a molecular link between the transcriptional control of various clonally variant multigene families involved in parasite virulence. This work opens new avenues for elucidating the molecular processes that control immune evasion and pathogenesis in P. falciparum. IMPORTANCE Plasmodium falciparum is the deadliest malaria parasite species, accounting for the vast majority of disease cases and deaths. The virulence of this parasite is reliant upon the mutually exclusive expression of cytoadherence proteins encoded by the 60-member var gene family. Antigenic variation of this multigene family serves as an immune evasion mechanism, ultimately leading to chronic infection and pathogenesis. Understanding the regulation mechanism of antigenic variation is key to developing new therapeutic and control strategies. Our study uncovers a novel layer in the epigenetic regulation of transcription of this family of virulence genes by means of a multigene-targeting CRISPR interference approach.
Non-coding RNAs (ncRNAs) are emerging regulators of immune evasion and transmission ofPlasmodium falciparum. RUF6 is an ncRNA gene family that is transcribed by RNA polymerase III but actively regulates the Pol II–transcribedvarvirulence gene family. Understanding how RUF6 ncRNA connects to downstream effectors is lacking. We developed an RNA-directed proteomic discovery (ChIRP-MS) protocol to identify in vivo RUF6 ncRNA–protein interactions. The RUF6 ncRNA interactome was purified with biotinylated antisense oligonucleotides. Quantitative label-free mass spectrometry identified several unique proteins linked to gene transcription including RNA Pol II subunits, nucleosome assembly proteins, and a homologue of DEAD box helicase 5 (DDX5). Affinity purification of Pf-DDX5 identified proteins originally found by our RUF6-ChIRP protocol, validating the technique’s robustness for identifying ncRNA interactomes inP. falciparum. Inducible displacement of nuclear Pf-DDX5 resulted in significant down-regulation of the activevargene. Our work identifies a RUF6 ncRNA–protein complex that interacts with RNA Pol II to sustain thevargene expression, including a helicase that may resolve G-quadruplex secondary structures invargenes to facilitate transcriptional activation and progression.
Many neurodegenerative disorders display protein aggregation as a hallmark, Huntingtin and TDP-43 aggregates being characteristic of Huntington disease and amyotrophic lateral sclerosis, respectively. However, whether these aggregates cause the diseases, are secondary by-products, or even have protective effects, is a matter of debate. Mutations in both human proteins can modulate the structure, number and type of aggregates, as well as their toxicity. To study the role of protein aggregates in cellular fitness, we have expressed in a highly tractable unicellular model different variants of Huntingtin and TDP-43. They each display specific patterns of aggregation and toxicity, even though in both cases proteins have to be very highly expressed to affect cell fitness. The aggregation properties of Huntingtin, but not of TDP-43, are affected by chaperones such as Hsp104 and the Hsp40 couple Mas5, suggesting that the TDP-43, but not Huntingtin, derivatives have intrinsic aggregation propensity. Importantly, expression of the aggregating form of Huntingtin causes a significant extension of fission yeast lifespan, probably as a consequence of kidnapping chaperones required for maintaining stress responses off. Our study demonstrates that in general these prion-like proteins do not cause toxicity under normal conditions, and in fact they can protect cells through indirect mechanisms which up-regulate cellular defense pathways.
Malaria pathogenesis is linked to parasite sequestration in critical target organs and is regulated seasonally in malaria-endemic regions, suggesting environmental sensing might regulate disease severity. How this occurs at the molecular level and the contributing host and parasite factors remain unclear. Here, we report that P. falciparum RNA polymerase III (RNA Pol III) transcription is downregulated in field isolates from asymptomatic patients. By using in vitro cultured parasites, we identified an RNA Pol III-dependent mechanism that governs expression of a major virulence factor in response to external stimuli. We establish a link between P. falciparum cytoadhesion and a Pol III-transcribed non-coding RNA family. Furthermore, we identify P. falciparum Maf1 as a critical regulator of Pol III transcription for cellular homeostasis and in adaptive responsive to external stimuli. Our results identify an RNA Pol III-dependent reduction in parasite cytoadherence capacity and link this process to asymptomatic malaria infection.
Heterochromatin is essential in all eukaryotes to maintain genome integrity, long-term gene repression and to help chromosome segregation during mitosis. However, heterochromatin regions must be restricted by boundary elements to avoid its spreading over actively transcribed loci. In Plasmodium falciparum, facultative heterochromatin is important to regulate parasite virulence, antigenic variation and transmission. However, the underlying molecular mechanisms regulating repressive regions remain unknown. To investigate this topic, we chose the ap2-g gene, which forms a strictly delimited and independent heterochromatin island. Using electrophoretic motility shift assay (EMSA) we identified an ap2-g exon element at the 3' end binding nuclear protein complexes. Upon replacement of this region by a gfp gene, we observed a shift in the heterochromatin boundary resulting in HP1 (Heterochromatin Protein 1) spreading over ~2 additional kb downstream. We used this DNA element to purify candidate proteins followed by proteomic analysis. The identified complexes were found to be enriched in RNA-binding proteins, pointing to a potential role of RNA in the regulation of the ap2-g 3' heterochromatin boundary. Our results provide insight into the unexplored topic of heterochromatin biology in P. falciparum and identify a DNA element within the master regulator of sexual commitment modulating heterochromatin spreading.
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