The nucleosome landscape of<i>Plasmodium falciparum</i>reveals chromatin architecture and dynamics of regulatory sequences

Kensche, Philip; Hoeijmakers, Wieteke A. M.; Toenhake, Christa Geeke; Bras, Maaike; Chappell, Lia; Berriman, Matthew; Bártfai, Richárd

doi:10.1093/nar/gkv1214

Cited by 80 publications

(287 citation statements)

References 59 publications

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“…However, these results are based on highly over-digested chromatin and it is known that MNase exhibits a strong preference for AT-rich sequences [40]. A recent genome wide study shows that nucleosomes in the intergenic regions are not depleted, but potentially disappear by over-digestion of chromatin with MNase [16]. Analyzing the new, low digested dataset, still revealed higher nucleosome occupancy at GC-rich sequences (S4D and S4E Fig).…”

Section: Resultsmentioning

confidence: 99%

“…Next, we had a closer look at the available high throughput sequencing data and re-analyzed the datasets studying the accessibility of chromatin (Data sets used: SRX013309 [14], SRX013302 [14], SRX885811-SRX885819 [16]). Ponts and colleagues performed FAIRE assays [39] to reveal the accessible genomic regions, relative to their MNase resistant nucleosomal fraction.…”

Section: Resultsmentioning

confidence: 99%

“…Also for plasmodium it was shown that proper promoter functioning and regulation of var gene expression requires the presence of positioned nucleosomes [10–13]. High-throughput sequencing analyses of nucleosome positions and chromatin structure analyses in different life cycle stages correlate changes in chromatin structure with the regulation of gene expression [14–16]. Interestingly, the chromatin structure of P .…”

Section: Introductionmentioning

confidence: 99%

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Plasmodium falciparum Nucleosomes Exhibit Reduced Stability and Lost Sequence Dependent Nucleosome Positioning

et al. 2016

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The packaging and organization of genomic DNA into chromatin represents an additional regulatory layer of gene expression, with specific nucleosome positions that restrict the accessibility of regulatory DNA elements. The mechanisms that position nucleosomes in vivo are thought to depend on the biophysical properties of the histones, sequence patterns, like phased di-nucleotide repeats and the architecture of the histone octamer that folds DNA in 1.65 tight turns. Comparative studies of human and P. falciparum histones reveal that the latter have a strongly reduced ability to recognize internal sequence dependent nucleosome positioning signals. In contrast, the nucleosomes are positioned by AT-repeat sequences flanking nucleosomes in vivo and in vitro. Further, the strong sequence variations in the plasmodium histones, compared to other mammalian histones, do not present adaptations to its AT-rich genome. Human and parasite histones bind with higher affinity to GC-rich DNA and with lower affinity to AT-rich DNA. However, the plasmodium nucleosomes are overall less stable, with increased temperature induced mobility, decreased salt stability of the histones H2A and H2B and considerable reduced binding affinity to GC-rich DNA, as compared with the human nucleosomes. In addition, we show that plasmodium histone octamers form the shortest known nucleosome repeat length (155bp) in vitro and in vivo. Our data suggest that the biochemical properties of the parasite histones are distinct from the typical characteristics of other eukaryotic histones and these properties reflect the increased accessibility of the P. falciparum genome.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Plasmodium falciparum Nucleosomes Exhibit Reduced Stability and Lost Sequence Dependent Nucleosome Positioning

et al. 2016

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“…Regulation of gene expression in eukaryotic cells can be achieved at the transcriptional level using both genetic and epigenetic mechanisms. Moreover, it is likely that the activity of transcription factors and DNA binding proteins, combined and acting in coordination with modulated chromatin organizations such as nucleosome positioning, essentially controls gene expression at different parasite life cycle stages [7]. In addition, gene expression can also be regulated at the post-transcriptional and translational levels.…”

Section: Introductionmentioning

confidence: 99%

“…equi AP2 domains remain unknown, and they will need to be defined experimentally. Remarkably, the specificity of binding of some AP2 proteins to certain short DNA target motifs (usually six to seven base-pairs long) appears to be quite conserved among distinct Plasmodium species and, furthermore, among other related apicomplexans [7, 25]. These findings suggest that Plasmodium binding specificity data together with bioinformatics analysis on the 5′ upstream gene coding regions could guide the design of future experiments aimed at establishing the DNA binding specificities of the AP2 proteins in the three parasites examined in this study.…”

Section: Introductionmentioning

confidence: 99%

Comparative Bioinformatics Analysis of Transcription Factor Genes Indicates Conservation of Key Regulatory Domains among Babesia bovis, Babesia microti, and Theileria equi

2016

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Apicomplexa tick-borne hemoparasites, including Babesia bovis, Babesia microti, and Theileria equi are responsible for bovine and human babesiosis and equine theileriosis, respectively. These parasites of vast medical, epidemiological, and economic impact have complex life cycles in their vertebrate and tick hosts. Large gaps in knowledge concerning the mechanisms used by these parasites for gene regulation remain. Regulatory genes coding for DNA binding proteins such as members of the Api-AP2, HMG, and Myb families are known to play crucial roles as transcription factors. Although the repertoire of Api-AP2 has been defined and a HMG gene was previously identified in the B. bovis genome, these regulatory genes have not been described in detail in B. microti and T. equi. In this study, comparative bioinformatics was used to: (i) identify and map genes encoding for these transcription factors among three parasites’ genomes; (ii) identify a previously unreported HMG gene in B. microti; (iii) define a repertoire of eight conserved Myb genes; and (iv) identify AP2 correlates among B. bovis and the better-studied Plasmodium parasites. Searching the available transcriptome of B. bovis defined patterns of transcription of these three gene families in B. bovis erythrocyte stage parasites. Sequence comparisons show conservation of functional domains and general architecture in the AP2, Myb, and HMG proteins, which may be significant for the regulation of common critical parasite life cycle transitions in B. bovis, B. microti, and T. equi. A detailed understanding of the role of gene families encoding DNA binding proteins will provide new tools for unraveling regulatory mechanisms involved in B. bovis, B. microti, and T. equi life cycles and environmental adaptive responses and potentially contributes to the development of novel convergent strategies for improved control of babesiosis and equine piroplasmosis.

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Epigenetic Players of Chromatin Structure Regulation in Plasmodium falciparum

Jabeena

Rajavelu

2019

ChemBioChem

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The protozoan parasite Plasmodium has evolved to survive in different hosts and environments. The diverse strategies of adaptation to different niches involve differential gene expression mechanisms mediated by chromatin plasticity that are poorly characterized in Plasmodium. The parasite employs a wide variety of regulatory mechanisms to complete their life cycle and survive inside hosts. Among them, epigenetic‐mediated mechanisms have been implicated for controlling chromatin organization, gene regulation, morphological differentiation, and antigenic variation. The differential gene expression in parasite is largely dependent on the nature of the chromatin structure. The histone core methylation marks and methyl mark readers contribute to chromatin dynamics. Here, we review the recent developments on various epigenetic marks and its enzymes in the Plasmodium falciparum, how these marks play a key role in the regulation of transcriptional activity of variable genes and coordinate the differential gene expression. We also discuss the possible roles of these epigenetic marks in chromatin structure regulation and plasticity at various stages of its development.

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The nucleosome landscape ofPlasmodium falciparumreveals chromatin architecture and dynamics of regulatory sequences

Cited by 80 publications

References 59 publications

Plasmodium falciparum Nucleosomes Exhibit Reduced Stability and Lost Sequence Dependent Nucleosome Positioning

Plasmodium falciparum Nucleosomes Exhibit Reduced Stability and Lost Sequence Dependent Nucleosome Positioning

Comparative Bioinformatics Analysis of Transcription Factor Genes Indicates Conservation of Key Regulatory Domains among Babesia bovis, Babesia microti, and Theileria equi

Epigenetic Players of Chromatin Structure Regulation in Plasmodium falciparum

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