Live-Cell Chromosome Dynamics and Outcome of X Chromosome Pairing Events during ES Cell Differentiation

SummaryRandom X inactivation represents a paradigm for monoallelic gene regulation during early ES cell differentiation. In mice, the choice of X chromosome to inactivate in XX cells is ensured by monoallelic regulation of Xist RNA via its antisense transcription unit Tsix/Xite. Homologous pairing events have been proposed to underlie asymmetric Tsix expression, but direct evidence has been lacking owing to their dynamic and transient nature. Here we investigate the live-cell dynamics and outcome of Tsix pairing in differentiating mouse ES cells. We find an overall increase in genome dynamics including the Xics during early differentiation. During pairing, however, Xic loci show markedly reduced movements. Upon separation, Tsix expression becomes transiently monoallelic, providing a window of opportunity for monoallelic Xist upregulation. Our findings reveal the spatiotemporal choreography of the X chromosomes during early differentiation and indicate a direct role for pairing in facilitating symmetry-breaking and monoallelic regulation of Xist during random X inactivation

CARACTERISATION DES ANOMALIES 1Q12-23 ASSOCIEES A LA PROGRESSION TUMORALE DANS LES LYMPHOMES MALINS NON-HODGKINIENS ET LE MYELOME MULTIPLE

GRENOBLE1-BU Sciences (384212103) / SudocSudocFranceF

A novel role for Xist RNA in the formation of a repressive nuclear compartment into which genes are recruited when silenced

During early mammalian female development, one of the two X chromosomes becomes inactivated. Although X-chromosome coating by Xist RNA is essential for the initiation of X inactivation, little is known about how this signal is transformed into transcriptional silencing. Here we show that exclusion of RNA Polymerase II and transcription factors from the Xist RNA-coated X chromosome represents the earliest event following Xist RNA accumulation described so far in differentiating embryonic stem (ES) cells. Paradoxically, exclusion of the transcription machinery occurs before gene silencing is complete. However, examination of the three-dimensional organization of X-linked genes reveals that, when transcribed, they are always located at the periphery of, or outside, the Xist RNA domain, in contact with the transcription machinery. Upon silencing, genes shift to a more internal location, within the Xist RNA compartment devoid of transcription factors. Surprisingly, the appearance of this compartment is not dependent on the A-repeats of the Xist transcript, which are essential for gene silencing. However, the A-repeats are required for the relocation of genes into the Xist RNA silent domain. We propose that Xist RNA has multiple functions: A-repeat-independent creation of a transcriptionally silent nuclear compartment; and A-repeat-dependent induction of gene repression, which is associated with their translocation into this silent domain

Heterochromatin Reorganization during Early Mouse Development Requires a Single-Stranded Noncoding Transcript

The equalization of pericentric heterochromatin from distinct parental origins following fertilization is essential for genome function and development. The recent implication of noncoding transcripts in this process raises questions regarding the connection between RNA and the nuclear organization of distinct chromatin environments. Our study addresses the interrelationship between replication and transcription of the two parental pericentric heterochromatin (PHC) domains and their reorganization during early embryonic development. We demonstrate that the replication of PHC is dispensable for its clustering at the late two-cell stage. In contrast, using parthenogenetic embryos, we show that pericentric transcripts are essential for this reorganization independent of the chromatin marks associated with the PHC domains. Finally, our discovery that only reverse pericentric transcripts are required for both the nuclear reorganization of PHC and development beyond the two-cell stage challenges current views on heterochromatin organization

Two HIRA-dependent pathways mediate H3.3 de novo deposition and recycling during transcription

International audienceNucleosomes represent a challenge in regard to transcription. Histone eviction enables RNA polymerase II (RNAPII) progression through DNA, but compromises chromatin integrity. Here, we used the SNAP-tag system to distinguish new and old histones and monitor chromatin reassembly coupled to transcription in human cells. We uncovered a transcription-dependent loss of old histone variants H3.1 and H3.3. At transcriptionally active domains, H3.3 enrichment reflected both old H3.3 retention and new deposition. Mechanistically, we found that the histone regulator A (HIRA) chaperone is critical to processing both new and old H3.3 via different pathways. De novo H3.3 deposition is totally dependent on HIRA trimerization as well as on its partner ubinuclein 1 (UBN1), while antisilencing function 1 (ASF1) interaction with HIRA can be bypassed. By contrast, recycling of H3.3 requires HIRA but proceeds independently of UBN1 or HIRA trimerization and shows absolute dependency on ASF1–HIRA interaction. We propose a model whereby HIRA coordinates these distinct pathways during transcription to fine-tune chromatin states