Barry Kesner

High-resolution Xist binding maps reveal two-step spreading during X-chromosome inactivation

The Xist long noncoding RNA (lncRNA) is essential for X-chromosome inactivation (XCI), the process by which mammals compensate for unequal numbers of sex chromosomes. During XCI, Xist coats the future inactive X chromosome (Xi) and recruits Polycomb repressive complex 2 (PRC2) to the X-inactivation centre (Xic). How Xist spreads silencing on a 150-megabases scale is unclear. Here we generate high-resolution maps of Xist binding on the X chromosome across a developmental time course using CHART-seq. In female cells undergoing XCI de novo, Xist follows a two-step mechanism, initially targeting gene-rich islands before spreading to intervening gene-poor domains. Xist is depleted from genes that escape XCI but may concentrate near escapee boundaries. Xist binding is linearly proportional to PRC2 density and H3 lysine 27 trimethylation (H3K27me3), indicating co-migration of Xist and PRC2. Interestingly, when Xist is acutely stripped off from the Xi in post-XCI cells, Xist recovers quickly within both gene-rich and gene-poor domains on a timescale of hours instead of days, indicating a previously primed Xi chromatin state. We conclude that Xist spreading takes distinct stage-specific forms. During initial establishment, Xist follows a two-step mechanism, but during maintenance, Xist spreads rapidly to both gene-rich and gene-poor regions.

A comprehensive Xist interactome reveals cohesin repulsion and an RNA-directed chromosome conformation

Protein partners for chromosome silencing Female mammals have two X chromosomes, one of which is almost completely shut down during development. The long noncoding Xist RNA plays a role in this process. To understand how a whole chromosome can be stably inactivated, Minajigi et al. identified many of the proteins that bind to the Xist RNA, which include cohesins. Paradoxically, the interaction between Xist and cohesin subunits resulted in repulsion of cohesin complexes from the inactive X chromosome, changing the three-dimensional shape of the whole chromosome. Science, this issue 10.1126/science.aab2276 A screen for factors that bind directly to RNA reveals the proteins that interact with the long noncoding RNA Xist. INTRODUCTION The mammal has evolved an epigenetic mechanism to silence one of two X chromosomes in the XX female to equalize gene dosages with the XY male. Once established, the inactivated X chromosome (Xi) is extremely stable and is maintained through the lifetime of the female mammal. The principal regulator, Xist, is a long noncoding RNA that orchestrates the silencing process along the Xi. Xist is believed to operate as a scaffold to recruit and spread repressive complexes, such as Polycomb Repressive Complex 2, along the X chromosome. The identities of crucial interacting factors, however, have remained largely unknown. RATIONALE Although the Xi’s epigenetic stability is a necessary homeostatic property, an ability to unlock this epigenetic state is of great current interest. The X chromosome is home to nearly 1000 genes, at least 50 of which have been implicated in X-linked diseases, such as Rett syndrome and fragile X syndrome. The Xi is therefore a reservoir of functional genes that could be tapped to replace expression of a disease allele on the active X (Xa). A major gap in current understanding is the lack of a comprehensive Xist interactome. Progress toward a full interactome would advance knowledge of epigenetic regulation by long noncoding RNA and potentially inform treatment of X-linked diseases. RESULTS We have developed an RNA-centric proteomic method called iDRiP (identification of direct RNA-interacting proteins). Using iDRiP, we identified 80 to 200 proteins in the Xist interactome. The interactors fall into several functional categories, including cohesins, condensins, topoisomerases, RNA helicases, chromatin remodelers, histone modifiers, DNA methyltransferases, nucleoskeletal factors, and nuclear matrix proteins. Targeted inhibition demonstrates that Xi silencing can be destabilized by disrupting multiple components of the interactome, consistent with the idea that these factors synergistically repress Xi transcription. Triple-drug treatments lead to a net increase of Xi expression and up-regulation of ~100 to 200 Xi genes. We then carry out a focused study of X-linked cohesin sites. Chromatin immunoprecipitation sequencing analysis demonstrates three types of cohesin sites on the X chromosome: Xi-specific sites, Xa-specific sites, and biallelic sites. We find that the Xa-specific binding sites represent a default state. Ablating Xist results in restoration of Xa-specific sites on the Xi. These findings demonstrate that, while Xist attracts repressive complexes to the Xi, it actively repels chromosomal architectural factors such as the cohesins from the Xi. Finally, we examine how Xist and the repulsion of cohesins affect Xi chromosome structure. In wild-type cells, the Xa is characterized by ~112 topologically associated domains (TADs) and the Xi by two megadomains. Intriguingly, loss of Xist and restoration of cohesin binding result in a reversion of the Xi to an Xa-like chromosome conformation. Hi-C analysis shows that TADs return to the Xi in a manner correlated with the reappearance of cohesins and with a transcriptionally permissive state. CONCLUSION Our study unveils many layers of Xi repression and demonstrates a central role for RNA in the topological organization of mammalian chromosomes. Our study also supports a model in which Xist RNA simultaneously acts as (i) a scaffold for the recruitment of repressive complexes to establish and maintain the inactive state and (ii) a repulsion mechanism to extrude architectural factors such as cohesins to avoid acquisition of a transcription-favorable chromatin conformation. Finally, our findings indicate that the stability of the Xi can be perturbed by targeted inhibition of multiple components of the Xist interactome. An operational model for how Xist RNA orchestrates the Xi state. Xist is a multitasking RNA that brings many layers of repression to the Xi. Although Xist RNA recruits repressive complexes (such as PRC1, PRC2, DNMT1, macroH2A, and SmcHD1) to establish and maintain the inactive state, it also actively repels activating factors and architectural proteins (such as the cohesins and CTCF) to avoid acquisition of a transcription-favorable chromatin conformation. The inactive X chromosome (Xi) serves as a model to understand gene silencing on a global scale. Here, we perform “identification of direct RNA interacting proteins” (iDRiP) to isolate a comprehensive protein interactome for Xist, an RNA required for Xi silencing. We discover multiple classes of interactors—including cohesins, condensins, topoisomerases, RNA helicases, chromatin remodelers, and modifiers—that synergistically repress Xi transcription. Inhibiting two or three interactors destabilizes silencing. Although Xist attracts some interactors, it repels architectural factors. Xist evicts cohesins from the Xi and directs an Xi-specific chromosome conformation. Upon deleting Xist, the Xi acquires the cohesin-binding and chromosomal architecture of the active X. Our study unveils many layers of Xi repression and demonstrates a central role for RNA in the topological organization of mammalian chromosomes.

N-terminal strands of filamin Ig domains act as a conformational switch under biological forces.

Conformational changes of filamin A under stress have been postulated to play crucial roles in signaling pathways of cell responses. Direct observation of conformational changes under stress is beyond the resolution of current experimental techniques. On the other hand, computational studies are mainly limited to either traditional molecular dynamics simulations of short durations and high forces or simulations of simplified models. Here we perform all‐atom discrete molecular dynamics (DMD) simulations to study thermally and force‐induced unfolding of filamin A. The high conformational sampling efficiency of DMD allows us to observe force‐induced unfolding of filamin A Ig domains under physiological forces. The computationally identified critical unfolding forces agree well with experimental measurements. Despite a large heterogeneity in the population of force‐induced intermediate states, we find a common initial unfolding intermediate in all the Ig domains of filamin, where the N‐terminal strand unfolds. We also study the thermal unfolding of several filamin Ig‐like domains. We find that thermally induced unfolding features an early‐stage intermediate state similar to the one observed in force‐induced unfolding and characterized by the N‐terminal strand being unfurled. We propose that the N‐terminal strand may act as a conformational switch that unfolds under physiological forces leading to exposure of cryptic binding sites, removal of native binding sites, and modulating the quaternary structure of domains. Proteins 2010.

A high-throughput small molecule screen identifies synergism between DNA methylation and Aurora kinase pathways for X reactivation

Significance In mammalian female cells, nearly all genes are silenced on one of two X chromosomes. Heterozygous females with “dominant” X-linked diseases, such as Rett syndrome, may benefit from pharmacological reactivation of the silent, healthy allele in affected organs. Toward establishing proof of concept, here we carry out a primed screen of a large library of small molecules for compounds that can reactivate expression from the inactive X (Xi). We identify a combination of compounds that inhibits the DNA methylation and Aurora kinase pathways and demonstrate that the two pathways act synergistically to repress genes on the Xi, including genes involved in X-linked disease. X-chromosome inactivation is a mechanism of dosage compensation in which one of the two X chromosomes in female mammals is transcriptionally silenced. Once established, silencing of the inactive X (Xi) is robust and difficult to reverse pharmacologically. However, the Xi is a reservoir of >1,000 functional genes that could be potentially tapped to treat X-linked disease. To identify compounds that could reactivate the Xi, here we screened ∼367,000 small molecules in an automated high-content screen using an Xi-linked GFP reporter in mouse fibroblasts. Given the robust nature of silencing, we sensitized the screen by “priming” cells with the DNA methyltransferase inhibitor, 5-aza-2′-deoxycytidine (5azadC). Compounds that elicited GFP activity include VX680, MLN8237, and 5azadC, which are known to target the Aurora kinase and DNA methylation pathways. We demonstrate that the combinations of VX680 and 5azadC, as well as MLN8237 and 5azadC, synergistically up-regulate genes on the Xi. Thus, our work identifies a synergism between the DNA methylation and Aurora kinase pathways as being one of interest for possible pharmacological reactivation of the Xi.