New Histone H4 variant and H2B variant Exhibits Distinct Genomic Locations, Chromatin Affinities, and Dynamics Throughout Life Cycle and Cell Cycle of Trypanosoma cruzi
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Histone variants play crucial roles in chromatin organization and transcriptional regulation in eukaryotes. Unusually, trypanosomatids display histone variants for all histones, although a functional homolog of histone H4 variant (H4.V) had not yet been described in Trypanosoma cruzi . In this study, we identified a H4.V in T. cruzi that is encoded by a single-copy gene located apart from the typical tandem arrays of canonical histone H4. Functional characterization using ChIP-seq assays revealed that H4.V is located at telomeric regions, demarcates convergent strand-switch regions (cSSRs), and determines new transcription termination sites at codirectional PTUs interrupted by tDNA loci. Throughout the cell cycle, H4.V transcript levels remain stable, while protein abundance increases in G2/M, as shown by immunofluorescence and image flow cytometry. In contrast, the histone H2B variant (H2B.V) transcripts peak at S-phase, and protein abundance accumulates progressively. H4.V is more abundant in the nuclei of metacyclic trypomastigotes but barely detectable in amastigotes and bloodstream trypomastigotes. In contrast, H2B.V shows a punctate nuclear pattern and is present in all life stages, with the highest levels also observed in metacyclics. During metacyclogenesis, both variants show a progressive increase in expression, particularly H4.V, suggesting a role in parasite differentiation. Ultimately, salt extraction experiments demonstrated differing chromatin binding affinities across life stages for both variants, with H4.V displaying a more permanent chromatin association than H2B.V, indicating that H4.V may be associated with a more compact chromatin state. Our data reveal H4.V as a novel histone variant in T. cruzi , characterized by unique genomic localization, expression profiles, and chromatin-binding dynamics in contrast to H2B.V, underscoring its potential function as an epigenetic marker in transcriptional regulation and adaptation to diverse host environments.
Author summary
Chromatin is composed of a group of proteins called histones that are involved in compacting DNA and thereby affecting many DNA-associated mechanisms, such as replication and transcription. Histone variants share distinct primary sequences from the canonical ones and display different roles and genomic locations. While variants of histone H3 and H2A are common in all eukaryotes, variants of H2B and H4 are unusual, except in trypanosomatids, a group of parasites that cause human and veterinary diseases. Among them, Trypanosoma cruzi , the causative agent of Chagas disease, exhibits variants for three core histones, but a variant of histone H4 (H4.V) had not been described. Here, we identify H4.V and demonstrate its preferential deposition at telomeres, convergent strand-switch regions (cSSRs), and codirectional polycistronic transcription units (PTUs) interrupted by tDNA loci, likely marking transcription termination sites. Both variants are enriched in the nuclei of metacyclic trypomastigotes; however, H4.V is barely detectable in amastigotes and bloodstream trypomastigotes, while H2B.V is consistently present in all forms. Additionally, each variant shows distinct chromatin-binding affinities across life stages, with H4.V potentially linked to a more compact chromatin state. Our findings reveal a novel histone variant with unique dynamics and epigenetic roles distinct from H2B.V in T. cruzi .
