FACT maintains chromatin architecture and thereby stimulates RNA polymerase II pausing during transcription in vivo

Is Enhancer Function Driven by Protein-Protein Interactions? From Bacteria to Leukemia

The precise regulation of the transcription of genes is essential for normal development and for the maintenance of life. Aberrant gene expression changes drive many human diseases. Despite this, we still do not completely understand how precise gene regulation is controlled in living systems. Enhancers are key regulatory elements that enable cells to specifically activate genes in response to environmental cues, or in a stage or tissue-specific manner. Any model of enhancer activity needs to answer two main questions: (1) how enhancers are able to identify and act on specific genes and (2) how enhancers influence transcription. To address these points, we first outline some of the basic principles that can be established from simpler prokaryotic systems, then discuss recent work on aberrant enhancer activity in leukemia. We argue that highly specific protein-protein interactions are a key driver of enhancer-promoter proximity, allowing enhancer-bound factors to directly act on RNA polymerase and activate transcription.

Multiple structures of RNA polymerase II isolated from human nuclei by ChIP-CryoEM analysis

RNA polymerase II (RNAPII) is a central transcription enzyme that exists as multiple forms with or without accessory factors, and transcribes the genomic DNA packaged in chromatin. To understand how RNAPII functions in the human genome, we isolate transcribing RNAPII complexes from human nuclei by chromatin immunopurification, and determine the cryo-electron microscopy structures of RNAPII elongation complexes (ECs) associated with genomic DNA in distinct forms, without or with the elongation factors SPT4/5, ELOF1, and SPT6. This ChIP-cryoEM method also reveals the two EC-nucleosome complexes corresponding nucleosome disassembly/reassembly processes. In the structure of EC-downstream nucleosome, EC paused at superhelical location (SHL) -5 in the nucleosome, suggesting that SHL(-5) pausing occurs in a sequence-independent manner during nucleosome disassembly. In the structure of the EC-upstream nucleosome, EC directly contacts the nucleosome through the nucleosomal DNA-RPB4/7 stalk and the H2A-H2B dimer-RPB2 wall interactions, suggesting that EC may be paused during nucleosome reassembly. These representative EC structures transcribing the human genome provide mechanistic insights into understanding RNAPII transcription on chromatin.

NDF/GLYR1 Promotes RNA Polymerase II Processivity via Pol II Binding and Nucleosome Destabilization

The Nucleosome Destabilizing Factor (NDF) facilitates transcription through chromatin, but its precise mechanism remains incompletely understood. Here, we identify a critical region (amino acids 140-160) within NDF that specifically interacts with phosphorylated RPB1, the largest subunit of elongating RNA Polymerase II (Pol II). Mutations in this region disrupt Pol II interaction and impair Pol II elongation both in vitro and in cells, yet do not affect NDF's ability to destabilize nucleosomes, establishing a functional separation between these two activities. Cellular studies reveal that NDF knockout cells display faster Pol II elongation rates but produce fewer nascent transcripts, demonstrating NDF's primary role in maintaining transcriptional processivity throughout gene bodies. Our findings demonstrate that NDF uses distinct mechanisms to ensure productive transcription elongation rather than simply enhancing elongation speed, offering new insights into how transcription efficiency is maintained in chromatin.

Chromatin-bound U2AF2 splicing factor ensures exon inclusion

Most mRNA splicing occurs co-transcriptionally, but it is unclear how splicing factors accurately select exons for inclusion. Using CUT&RUN profiling in K562 cells, we demonstrate that three splicing factors-SF3B1, U2AF1, and U2AF2-bind near active promoters of intron-containing and intronless genes, implying their association with the general transcriptional machinery. RNase A treatment reduces factor binding at promoters, indicating that these proteins interact with nascent transcripts. Strikingly, the U2AF2 protein also accumulates throughout intron-containing gene bodies and requires histone H3-lysine36 trimethylation but not nascent transcripts or persistent RNA polymerase II. Chromatin-bound U2AF2 preferentially binds to exons of highly expressed, exon-dense genes, with greater occupancy at exons skipped after U2AF2 knockdown, suggesting that U2AF2 enhances exon selection accuracy. U2AF2-targeted genes include those encoding splicing factors, where it improves splicing accuracy and efficiency. Our findings provide a mechanistic basis for the homeostatic regulation of efficient co-transcriptional splicing by chromatin-bound U2AF2.

FACT weakens the nucleosomal barrier to transcription and preserves its integrity by forming a hexasome-like intermediate

Transcription of yeast RNA polymerase II through nucleosomes requires the assistance of the histone chaperone FACT (facilitates chromatin transcription). Yet, how FACT modulates the nucleosomal mechanical barrier to affect the polymerase's elongation dynamics is poorly understood. Using high-resolution single-molecule optical tweezers, we show that FACT greatly decreases the magnitude of the barrier by favoring the unwrapping of DNA from the distal H2A-H2B dimer, which, in turn, weakens the contacts near the dyad, significantly reducing the enzyme's crossing time. We show that barrier crossing depends on the asymmetric flexibility of the nucleosome arms, an asymmetry we find across the genome. Mechanical unwrapping of Cy3-H2A nucleosomes reveals that FACT reduces their unwrapping force and stabilizes a hexasome-like intermediate that retains both labeled dimers during successive unwrapping cycles. This intermediate is also observed after transcription. In conclusion, FACT facilitates nucleosomal transcription by weakening the barrier and actively assisting the maintenance of nucleosomal integrity after enzyme passage.

Interactions with multiple inner kinetochore proteins determine mitotic localization of FACT

The FAcilitates Chromatin Transcription (FACT) complex is a dimeric histone chaperone that operates on chromatin during transcription and replication. FACT also interacts with a specialized centromeric nucleosome containing the histone H3 variant centromere protein A (CENP-A) and with CENP-TW, two subunits of the constitutive centromere-associated network (CCAN), a 16-protein complex associated with CENP-A. The significance of these interactions remains elusive. Here, we show that FACT has multiple additional binding sites on CCAN. The interaction with CCAN is strongly stimulated by casein kinase II phosphorylation of FACT. Mitotic localization of FACT to kinetochores is strictly dependent on specific CCAN subcomplexes. Conversely, CENP-TW requires FACT for stable localization. Unexpectedly, we also find that DNA readily displaces FACT from CCAN, supporting the speculation that FACT becomes recruited through a pool of CCAN that is not stably integrated into chromatin. Collectively, our results point to a potential role of FACT in chaperoning CCAN during transcription or in the stabilization of CCAN at the centromere during the cell cycle.

ZmSSRP1 facilitates the progression of RNA polymerase II and is essential for kernel development in maize

Transcript elongation controlled by RNA polymerase II (RNAP II) represents a key regulatory event in numerous cellular processes. However, the precise mechanisms underlying the regulation of RNAP II distribution and progression in plants remain largely elusive. Here, we positionally cloned the causal mutation in the defective kernel 59 (dek59) maize (Zea mays) mutant and demonstrated that Dek59 encodes Structure-Specific Recognition Protein 1 (ZmSSRP1), a subunit of the FAcilitates Chromatin Transcription (FACT) complex that regulates RNAP II. Using genome-wide mapping assays, we determined that ZmSSRP1-binding sites co-localize with those of RNAP II phosphorylated at its serine 2 residue (Ser2P) and are highly enriched within actively transcribed genes. Mutation of ZmSSRP1 resulted in Ser2P accumulation around the +1 nucleosome of genes, affecting gene expression in a gene length-dependent manner. The reduced amount of RNAP II in the dek59 mutant was rescued to wild-type-like levels by inhibiting the proteasome, indicating that arrested RNAP II degradation is proteasome-dependent. These findings reveal the indispensable role of ZmSSRP1 in regulating RNAP II-mediated transcription, which is critical for the proper expression of thousands of genes during maize seed development.

Structural insights into promoter-proximal pausing of RNA polymerase II at +1 nucleosome

The metazoan transcription elongation complex (EC) of RNA polymerase II (RNAPII) generally stalls between the transcription start site and the first (+1) nucleosome. This promoter-proximal pausing involves negative elongation factor (NELF), 5,6-dichloro-1-β-d-ribobenzimidazole sensitivity-inducing factor (DSIF), and transcription elongation factor IIS (TFIIS) and is critical for subsequent productive transcription elongation. However, the detailed pausing mechanism and the involvement of the +1 nucleosome remain enigmatic. Here, we report cryo-electron microscopy structures of ECs stalled on nucleosomal DNA. In the absence of TFIIS, the EC is backtracked/arrested due to conflicts between NELF and the nucleosome. We identified two alternative binding modes of NELF, one of which reveals a critical contact with the downstream DNA through the conserved NELF-E basic helix. Upon binding with TFIIS, the EC progressed to the nucleosome to establish a paused EC with a partially unwrapped nucleosome. This paused EC strongly restricts EC progression further downstream. These structures illuminate the mechanism of RNAPII pausing/stalling at the +1 nucleosome.

Chromatin Transcription Elongation - A Structural Perspective

In eukaryotic cells, transcription by RNA polymerase II occurs in the context of chromatin, requiring the transcription machinery to navigate through nucleosomes as it traverses gene bodies. Recent advances in structural biology have provided unprecedented insights into the mechanisms underlying transcription elongation. This review presents a structural perspective on transcription through chromatin, focusing on the latest findings from high-resolution structures of transcribing RNA polymerase II-nucleosome complexes. I discuss how RNA polymerase II, in concert with elongation factors such as SPT4/5, SPT6, ELOF1, and the PAF1 complex, engages with and transcribes through nucleosomes. The review examines the stepwise unwrapping of nucleosomal DNA as polymerase advances, the roles of elongation factors in facilitating this process, and the mechanisms of nucleosome retention and transfer during transcription. This structural perspective provides a foundation for understanding the intricate interplay between the transcription machinery and chromatin, offering insights into how cells balance the need for genetic accessibility with the maintenance of genome stability and epigenetic regulation.

Pause Patrol: Negative Elongation Factor's Role in Promoter-Proximal Pausing and Beyond

RNA polymerase (Pol) II is highly regulated to ensure appropriate gene expression. Early transcription elongation is associated with transient pausing of RNA Pol II in the promoter-proximal region. In multicellular organisms, this pausing is stabilized by the association of transcription elongation factors DRB-sensitivity inducing factor (DSIF) and Negative Elongation Factor (NELF). DSIF is a broadly conserved transcription elongation factor whereas NELF is mostly restricted to the metazoan lineage. Mounting evidence suggests that NELF association with RNA Pol II serves as checkpoint for either release into rapid and productive transcription elongation or premature termination at promoter-proximal pause sites. Here we summarize NELF's roles in promoter-proximal pausing, transcription termination, DNA repair, and signaling based on decades of cell biological, biochemical, and structural work and describe areas for future research.

The histone chaperone Spt6 controls chromatin structure through its conserved N-terminal domain

The disassembly and reassembly of nucleosomes by histone chaperones is an essential activity during eukaryotic transcription elongation. This highly conserved process maintains chromatin integrity by transiently removing nucleosomes as barriers and then restoring them in the wake of transcription. While transcription elongation requires multiple histone chaperones, there is little understanding of how most of them function and why so many are required. Here, we show that the histone chaperone Spt6 acts through its acidic, intrinsically disordered N-terminal domain (NTD) to bind histones and control chromatin structure. The Spt6 NTD is essential for viability and its histone binding activity is conserved between yeast and humans. The essential nature of the Spt6 NTD can be bypassed by changes in another histone chaperone, FACT, revealing a close functional connection between the two. Our results have led to a mechanistic model for dynamic cooperation between multiple histone chaperones during transcription elongation.

Chromatin Buffers Torsional Stress During Transcription

Transcription through chromatin under torsion represents a fundamental problem in biology. Pol II must overcome nucleosome obstacles and, because of the DNA helical structure, must also rotate relative to the DNA, generating torsional stress. However, there is a limited understanding of how Pol II transcribes through nucleosomes while supercoiling DNA. In this work, we developed methods to visualize Pol II rotation of DNA during transcription and determine how torsion slows down the transcription rate. We found that Pol II stalls at ± 9 pN·nm torque, nearly sufficient to melt DNA. The stalling is due to extensive backtracking, and the presence of TFIIS increases the stall torque to + 13 pN·nm, making Pol II a powerful rotary motor. This increased torsional capacity greatly enhances Pol II's ability to transcribe through a nucleosome. Intriguingly, when Pol II encounters a nucleosome, nucleosome passage becomes more efficient on a chromatin substrate than on a single-nucleosome substrate, demonstrating that chromatin efficiently buffers torsional stress via its torsional mechanical properties. Furthermore, topoisomerase II relaxation of torsional stress significantly enhances transcription, allowing Pol II to elongate through multiple nucleosomes. Our results demonstrate that chromatin greatly reduces torsional stress on transcription, revealing a novel role of chromatin beyond the more conventional view of it being just a roadblock to transcription.

Transcription elongation factor ELOF1 is required for efficient somatic hypermutation and class switch recombination

Somatic hypermutation (SHM) and class switch recombination (CSR) diversify immunoglobulin (Ig) genes and are initiated by the activation induced deaminase (AID), a single-stranded DNA cytidine deaminase that is thought to engage its substrate in the context of RNA polymerase II (RNAPII) transcription. Through a loss of function genetic screen, we identified numerous potential factors involved in SHM including ELOF1, a component of the RNAPII elongation complex that has been shown to function in DNA repair and transcription elongation. Loss of ELOF1 strongly compromises SHM, CSR, and AID targeting and alters RNAPII transcription by reducing RNAPII pausing downstream of transcription start sites and levels of serine 5 but not serine 2 phosphorylated RNAPII throughout transcribed genes. ELOF1 must bind to RNAPII to be a proximity partner for AID and to function in SHM and CSR. We propose that ELOF1 helps create the appropriate stalled RNAPII substrate on which AID acts.

The relationship between nucleosome positioning and higher-order genome folding

Eukaryotic genomes are organized into 3D structures, which range from small-scale nucleosome arrays to large-scale chromatin domains. These structures have an important role in the regulation of transcription and other nuclear processes. Despite advances in our understanding of the properties, functions, and underlying mechanisms of genome structures, there are many open questions about the interplay between these structures across scales. In particular, it is not well understood if and how 1D features of nucleosome arrays influence large-scale 3D genome folding patterns. In this review, we discuss recent studies that address these questions and summarize our current understanding of the relationship between nucleosome positioning and higher-order genome folding.