During its red blood cell stage, the malaria parasite Plasmodium falciparum can switch its variant surface proteins (P. falciparum erythrocyte membrane protein 1) to evade the host immune response. The var gene family encodes P. falciparum erythrocyte membrane protein 1, different versions of which have unique binding specificities to various human endothelial surface molecules. Individual parasites each contain Ϸ60 var genes at various locations within their chromosomes; however, parasite isolates contain different complements of var genes, thus, the gene family is enormous with a virtually unlimited number of members. A single var gene is expressed by each parasite in a mutually exclusive manner. We report that control of var gene transcription and antigenic variation is associated with a chromatin memory that includes methylation of histone H3 at lysine K9 as an epigenetic mark. We also discuss how gene transcription memory may affect the mechanism of pathogenesis and immune evasion.antigenic variation ͉ chromatin ͉ monoallelic expression ͉ histone modification
A fundamental yet poorly understood aspect of gene regulation in eukaryotic organisms is the mechanisms that control allelic exclusion and mutually exclusive gene expression. In the malaria parasite Plasmodium falciparum, this process regulates expression of the var gene family-a large, hypervariable repertoire of genes that are responsible for the ability of the parasite to evade the host immune system and for pathogenesis of the disease. A central problem in understanding this process concerns the mechanisms that limit expression to a single gene at a time. Here, we describe results that provide information on the mechanisms that control silencing and single gene expression and differentiate between several models that have recently been proposed. The results provide the first evidence, to our knowledge, supporting the existence of a postulated var-specific, subnuclear expression site and also reinforce the conclusion that var gene regulation is based on cooperative interactions between the two promoters of each var gene. Keywords: malaria; antigenic variation; allelic exclusion; silencing; transcription EMBO reports (2007) 8, 959-965.
Antigenic variation by the malaria parasite Plasmodium falciparum results from switches in expression between members of the multicopy var gene family. These genes encode the variant surface protein PfEMP-1, the primary determinant of the antigenic and cytoadherent properties of infected erythrocytes. Only a single var gene is expressed at a time while the remaining members of the family remain transcriptionally silent. How mutually exclusive var gene expression is regulated is poorly understood; however, it is generally thought to involve alterations in chromatin assembly and modification, resulting in a type of cellular memory. Recently, several aspects of the chromatin structure surrounding var genes have been described, in particular the histone modifications associated with the active and silent states of the genes as well as their subnuclear localization. Here, we demonstrate that this chromatin structure also includes the incorporation of long sense and antisense noncoding RNAs. These sterile transcripts initiate from a bidirectional promoter located within a conserved intron found in all var genes that was previously implicated in var gene silencing. Mapping of the 59 and 39 ends of the sterile transcripts indicates that they are nonpolyadenylated. RNA fluorescent in situ hybridization (RNA-FISH) analysis detects both the sense and antisense noncoding RNAs in distinct spots within the nucleus similar to the pattern described for the var genes themselves. Further, analysis by RNA chromatin immunoprecipitation (ChIP) indicates that the noncoding RNAs are physically associated with chromatin. These sterile transcripts therefore might act in a manner analogous to noncoding RNAs associated with silent, condensed chromatin found in other eukaryotic systems.
Non-coding RNAs (ncRNAs) play an important role in a variety of nuclear processes, including genetic imprinting, RNA interference-mediated transcriptional repression, and dosage compensation. These transcripts are thought to influence chromosome organization and, in some cases, gene expression by directing the assembly of specific chromatin modifications to targeted regions of the genome. In the malaria parasite Plasmodium falciparum, little is known about the regulation of nuclear organization or gene expression, although a notable scarcity of identifiable transcription factors encoded in its genome has led to speculation that this organism may be unusually reliant on chromatin modifications as a mechanism for regulating gene expression. To study the mechanisms that regulate chromatin structure in malaria parasites, we examined the role of ncRNAs in the assembly of chromatin at the centromeres of P. falciparum. We show that centromeric regions within the Plasmodium genome contain bidirectional promoter activity driving the expression of short ncRNAs that are localized within the nucleus and appear to associate with the centromeres themselves, strongly suggesting that they are central characters in the maintenance and function of centromeric chromatin. These observations support the hypothesis that ncRNAs play an important role in the proper organizational assembly of chromatin in P. falciparum, perhaps compensating for a lack of both regulatory transcription factors and RNA interference machinery.Recent years have seen many reports of non-coding RNAs (ncRNAs) 4 and their involvement in chromatin assembly in eukaryotes. RNAs are non-coding if they are not translated into protein, and most do not have any substantial open reading frames. Examples of ncRNAs and their roles in chromatin assembly and modification are found in organisms as varied as dinoflagellates (1) and yeast, fruit flies, mice, and humans (2) and thus are likely conserved throughout a broad range of eukaryotic evolution. The most closely studied systems that employ ncRNAs to direct chromatin assembly and modification include examples of genetic imprinting (3), RNAi-based transcriptional repression (4), and dosage compensation in both mammals and fruit flies (5, 6). Although different aspects of these RNAs have been characterized, exactly how they execute their tasks is still a mystery. Several studies support the hypothesis that these nuclear, cis-acting ncRNAs act by recruiting chromatin-modifying enzymes to specific chromosomal regions, thereby influencing genome organization or gene expression. The centromeres of eukaryotic chromosomes are examples of chromosomal elements that assemble a unique, specific chromatin architecture that is necessary for proper chromosome segregation during replication. Studies of ncRNAs found at the centromeres of various organisms underscore the influence these RNAs have on chromatin structure and function. There is strong evidence that epigenetic marks on chromatin, and not DNA sequence, are the basis for centrom...
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