Abstract
The importance of genome organization at the supranucleosomal scale in the control of gene expression is increasingly recognized today. In mammals, Topologically Associating Domains (TADs) and the active/inactive chromosomal compartments are two of the main nuclear structures that contribute to this organization level. However, recent works reviewed here indicate that, at specific loci, chromatin interactions with nuclear bodies could also be crucial to regulate genome functions, in particular transcription. They moreover suggest that these nuclear bodies are membrane-less organelles dynamically self-assembled and disassembled through mechanisms of phase separation. We have recently developed a novel genome-wide experimental method, High-salt Recovered Sequences sequencing (HRS-seq), which allows the identification of chromatin regions associated with large ribonucleoprotein (RNP) complexes and nuclear bodies. We argue that the physical nature of such RNP complexes and nuclear bodies appears to be central in their ability to promote efficient interactions between distant genomic regions. The development of novel experimental approaches, including our HRS-seq method, is opening new avenues to understand how self-assembly of phase-separated nuclear bodies possibly contributes to mammalian genome organization and gene expression.
Highlights
Several physical properties of nuclear organization are critical for regulating mammalian gene expression
Such a paradoxical achievement of a compact but dynamic genome is solved by packaging the genome into the chromatin nucleofilament, and through a complex compartmentalization of the nucleus that contributes to the functional genome organization at the supranucleosomal scale
The functional role of 3D genome organization has become an important component in the study of mammalian gene expression [1]
Summary
Several physical properties of nuclear organization are critical for regulating mammalian gene expression. The genome is highly compacted to fit into the limited space of the cell nucleus while, at the same time, it remains fully accessible to multiple interactions involving cis- and trans-acting genomic elements and RNA/protein factors. Such a paradoxical achievement of a compact but dynamic genome is solved by packaging the genome into the chromatin nucleofilament, and through a complex compartmentalization of the nucleus that contributes to the functional genome organization at the supranucleosomal scale (i.e., encompassing few tenths of kb to few Mb of DNA).
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