Systematic histone mutagenesis reveals nucleosome-dependent maintenance of three-dimensional chromosome architecture and virulence in Cryptococcus neoformans

BackgroundGenomic stability is maintained through the coordinated regulation of DNA repair, dNTP pool balance, and histone dynamics--the three pillars of the DNA damage response. Because histones constitute the fundamental 3D physical scaffold of the genome, their precise regulation is essential for the spatial organization that dictates environmental fitness. In the radiotolerant pathogen Cryptococcus neoformans, the Rad53-Bdr1 pathway is a central DDR mediator; however, the mechanisms linking this checkpoint to histone dynamics remain poorly understood. Because conventional one-dimensional analyses cannot capture how spatial chromatin folding shapes transcriptional reprogramming, we integrated high-throughput chromosome conformation capture (Hi-C) with transcriptomic profiling to address this gap. ResultsWe demonstrate that HTA1 and HTB1, encoding H2A and H2B, are essential for viability, whereas H3 and H4 paralogs exhibit functional redundancy. Although most core histones are regulated by Rad53, HHT1 and variant HTZ1 are expressed independently of the Rad53. Notably, loss of the H3 paralog HHT2 induces growth defects under diverse stress conditions. Integrated RNA sequencing and Hi-C analyses reveal that HHT2 deletion drives transcriptional reprogramming of stress-responsive genes, coinciding with large-scale chromatin rearrangements such as A/B compartment switching and topologically associating domain boundary shifts. Furthermore, HHT2 loss impairs virulence factor formation and attenuates virulence. ConclusionOur findings identify core histones as essential architects of the 3D genome in C. neoformans. By establishing a causal link between chromatin structural collapse and transcriptional reprogramming, this study highlights 3D genome architecture as a decisive physical switch linking nucleosome-level dynamics to global transcriptional programs required for environmental survival.