Explore the vast range of titles available.

PRC2 promotes methylation of H3K27, a modification that recruits PRC1, which in turn deposits H2A ubiquitin marks. Müller and colleagues use biochemistry approaches to show that H2Aub recruits Jarid–Aebp2–containing PRC2 to promote H3K27 trimethylation on H2Aub nucleosomes, thus forming a positive feedback loop to establish repressed chromatin domains. A key step in gene repression by Polycomb is trimethylation of histone H3 K27 by PCR2 to form H3K27me3. H3K27me3 provides a binding surface for PRC1. We show that monoubiquitination of histone H2A by PRC1-type complexes to form H2Aub creates a binding site for Jarid2–Aebp2–containing PRC2 and promotes H3K27 trimethylation on H2Aub nucleosomes. Jarid2, Aebp2 and H2Aub thus constitute components of a positive feedback loop establishing H3K27me3 chromatin domains.

Histone modification: tail spin Brdt1 is a bromodomain-containing chromatin protein that can compact hyperacetylated chromatin and has important functions during spermiogenesis. Here, the crystal structure of a bromodomain of Brdt1 bound to an acetylated histone H4 tail reveals a combinatorial mode of binding to post-translational modifications where a single effector module engages two marks on a histone tail. The recognition of histone post-translational modifications by effector modules such as bromodomains is a key step in many chromatin-related processes. Although effector-mediated recognition of single post-translation modifications is well characterized, combinatorial readout of histones bearing multiple modifications is poorly understood. Here, a distinct mechanism of combinatorial readout for the mouse TAF1 homologue Brdt, a testis-specific member of the BET protein family, is reported. A key step in many chromatin-related processes is the recognition of histone post-translational modifications by effector modules such as bromodomains and chromo-like domains of the Royal family 1 , 2 . Whereas effector-mediated recognition of single post-translational modifications is well characterized 3 , how the cell achieves combinatorial readout of histones bearing multiple modifications is poorly understood. One mechanism involves multivalent binding by linked effector modules 4 . For example, the tandem bromodomains of human TATA-binding protein-associated factor-1 (TAF1) bind better to a diacetylated histone H4 tail than to monoacetylated tails, a cooperative effect attributed to each bromodomain engaging one acetyl-lysine mark 5 . Here we report a distinct mechanism of combinatorial readout for the mouse TAF1 homologue Brdt, a testis-specific member of the BET protein family 6 . Brdt associates with hyperacetylated histone H4 (ref. 7 ) and is implicated in the marked chromatin remodelling that follows histone hyperacetylation during spermiogenesis, the stage of spermatogenesis in which post-meiotic germ cells mature into fully differentiated sperm 7 , 8 , 9 , 10 . Notably, we find that a single bromodomain (BD1) of Brdt is responsible for selectively recognizing histone H4 tails bearing two or more acetylation marks. The crystal structure of BD1 bound to a diacetylated H4 tail shows how two acetyl-lysine residues cooperate to interact with one binding pocket. Structure-based mutagenesis that reduces the selectivity of BD1 towards diacetylated tails destabilizes the association of Brdt with acetylated chromatin in vivo . Structural analysis suggests that other chromatin-associated proteins may be capable of a similar mode of ligand recognition, including yeast Bdf1, human TAF1 and human CBP/p300 (also known as CREBBP and EP300, respectively). Our findings describe a new mechanism for the combinatorial readout of histone modifications in which a single effector module engages two marks on a histone tail as a composite binding epitope.

RNA polymerase III (Pol III) synthesizes transfer RNAs and other short, essential RNAs. Human Pol III misregulation is linked to tumor transformation, neurodegenerative and developmental disorders, and increased sensitivity to viral infections. Here, we present cryo-electron microscopy structures at 2.8 to 3.3 Å resolution of transcribing and unbound human Pol III. We observe insertion of the TFIIS-like subunit RPC10 into the polymerase funnel, providing insights into how RPC10 triggers transcription termination. Our structures resolve elements absent from Saccharomyces cerevisiae Pol III such as the winged-helix domains of RPC5 and an iron–sulfur cluster, which tethers the heterotrimer subcomplex to the core. The cancer-associated RPC7α isoform binds the polymerase clamp, potentially interfering with Pol III inhibition by tumor suppressor MAF1, which may explain why overexpressed RPC7α enhances tumor transformation. Finally, the human Pol III structure allows mapping of disease-related mutations and may contribute to the development of inhibitors that selectively target Pol III for therapeutic interventions. Cryo-EM structures of human Pol III in both apo- and elongating states reveal metazoan-specific differences in the regulation of transcription termination and identify mutations relevant to human disease.

RNA polymerase III (Pol III), the largest eukaryote polymerase yet characterized, transcribes structured small non-coding RNAs; here cryo-electron microscopy structures of budding yeast Pol III allow building of an atomic-level model of the complete 17-subunit complex, both unbound and while elongating RNA. Transcription of genes encoding small structured RNAs such as transfer RNAs, spliceosomal U6 small nuclear RNA and ribosomal 5S RNA is carried out by RNA polymerase III (Pol III), the largest yet structurally least characterized eukaryotic RNA polymerase. Here we present the cryo-electron microscopy structures of the Saccharomyces cerevisiae Pol III elongating complex at 3.9 Å resolution and the apo Pol III enzyme in two different conformations at 4.6 and 4.7 Å resolution, respectively, which allow the building of a 17-subunit atomic model of Pol III. The reconstructions reveal the precise orientation of the C82–C34–C31 heterotrimer in close proximity to the stalk. The C53–C37 heterodimer positions residues involved in transcription termination close to the non-template DNA strand. In the apo Pol III structures, the stalk adopts different orientations coupled with closed and open conformations of the clamp. Our results provide novel insights into Pol III-specific transcription and the adaptation of Pol III towards its small transcriptional targets. High-resolution structures of Pol III RNA polymerase III (Pol III) transcribes structured small non-coding RNAs such as tRNAs and spliceosomal RNAs. It is the largest eukaryote polymerase, yet the least characterized structurally. Here Christoph Müller and colleagues determine the cryo-electron microscopy structures of budding yeast Pol III and build an atomic-level model of the complete 17-subunit complex, in both unbound and elongating conformations. The results allow a detailed comparison with the Pol I and Pol II enzymes and explain the adaptation of this polymerase towards its specific targets.

Nuclear pore complexes (NPCs) fuse the inner and outer membranes of the nuclear envelope. They comprise hundreds of nucleoporins (Nups) that assemble into multiple subcomplexes and form large central channels for nucleocytoplasmic exchange 1 , 2 . How this architecture facilitates messenger RNA export, NPC biogenesis and turnover remains poorly understood. Here we combine in situ structural biology and integrative modelling with correlative light and electron microscopy and molecular perturbation to structurally analyse NPCs in intact Saccharomyces cerevisiae cells within the context of nuclear envelope remodelling. We find an in situ conformation and configuration of the Nup subcomplexes that was unexpected from the results of previous in vitro analyses. The configuration of the Nup159 complex appears critical to spatially accommodate its function as an mRNA export platform, and as a mediator of NPC turnover. The omega-shaped nuclear envelope herniae that accumulate in nup116Δ cells 3 conceal partially assembled NPCs lacking multiple subcomplexes, including the Nup159 complex. Under conditions of starvation, herniae of a second type are formed that cytoplasmically expose NPCs. These results point to a model of NPC turnover in which NPC-containing vesicles bud off from the nuclear envelope before degradation by the autophagy machinery. Our study emphasizes the importance of investigating the structure–function relationship of macromolecular complexes in their cellular context. In-cell structural studies in Saccharomyces cerevisiae reveal that the configuration of the Nup159 complex is a key determinant of the mRNA export function of the nuclear pore complex, and suggest a model in which nuclear pore complexes are degraded via the autophagy machinery.

DNMT1 is an essential DNA methyltransferase that catalyzes the transfer of methyl groups to CpG islands in DNA and generates a prominent epigenetic mark. The catalytic activity of DNMT1 relies on its conformational plasticity and ability to change conformation from an auto-inhibited to an activated state. Here, we present four cryo-EM reconstructions of apo DNMT1 and DNTM1: non-productive DNA, DNTM1: H3Ub2-peptide, DNTM1: productive DNA complexes. Our structures demonstrate the flexibility of DNMT1’s N-terminal regulatory domains during the transition from an apo ‘auto-inhibited’ to a DNA-bound ‘non-productive’ and finally a DNA-bound ‘productive’ state of DNMT1. Furthermore, we address the regulation of DNMT1’s methyltransferase activity by a DNMT1-selective small-molecule inhibitor and ubiquitinated histone H3. We observe that DNMT1 binds DNA in a ‘non-productive’ state despite the presence of the inhibitor and present the cryo-EM reconstruction of full-length DNMT1 in complex with a di-ubiquitinated H3 peptide analogue. Taken together, our results provide structural insights into the reaction cycle of DNMT1.

Protein biosynthesis depends on the availability of ribosomes, which in turn relies on ribosomal RNA production. In eukaryotes, this process is carried out by RNA polymerase I (Pol I), a 14-subunit enzyme, the activity of which is a major determinant of cell growth. Here we present the crystal structure of Pol I from Saccharomyces cerevisiae at 3.0 Å resolution. The Pol I structure shows a compact core with a wide DNA-binding cleft and a tightly anchored stalk. An extended loop mimics the DNA backbone in the cleft and may be involved in regulating Pol I transcription. Subunit A12.2 extends from the A190 jaw to the active site and inserts a transcription elongation factor TFIIS-like zinc ribbon into the nucleotide triphosphate entry pore, providing insight into the role of A12.2 in RNA cleavage and Pol I insensitivity to α-amanitin. The A49–A34.5 heterodimer embraces subunit A135 through extended arms, thereby contacting and potentially regulating subunit A12.2. RNA polymerase (Pol) I transcribes ribosomal RNA that is critically required for ribosome assembly, and the enzyme is a major determinant of protein biosynthesis and cell growth; here the crystal structure of the complete 14-subunit Pol I from yeast is determined, providing insights into its unique architecture and the possible functional roles of its components. Pol I structure determined RNA polymerase I (Pol I) transcribes ribosomal RNA which is critically required for ribosome assembly, and the enzyme is therefore a major determinant of protein biosynthesis and cell growth. Mis-regulation of Pol I has been associated with several types of cancer, and Pol I is an emerging target for anticancer drugs. In this issue of Nature , two groups, working independently, present the X-ray crystal structure of the complete 14-subunit Pol I from yeast, determined at 3.0 Å and 2.8 Å resolution. The basic architecture of Pol I resembles those of Pol II and Pol III, but its DNA-binding cleft adopts a wider conformation than seen in the other RNA polymerases, and other unique features also provide insights into the functional roles of its components.

RNA polymerase III (Pol III) and transcription factor IIIB (TFIIIB) assemble together on different promoter types to initiate the transcription of small, structured RNAs. Here we present structures of Pol III preinitiation complexes, comprising the 17-subunit Pol III and the heterotrimeric transcription factor TFIIIB, bound to a natural promoter in different functional states. Electron cryo-microscopy reconstructions, varying from 3.7 Å to 5.5 Å resolution, include two early intermediates in which the DNA duplex is closed, an open DNA complex, and an initially transcribing complex with RNA in the active site. Our structures reveal an extremely tight, multivalent interaction between TFIIIB and promoter DNA, and explain how TFIIIB recruits Pol III. Together, TFIIIB and Pol III subunit C37 activate the intrinsic transcription factor-like activity of the Pol III-specific heterotrimer to initiate the melting of double-stranded DNA, in a mechanism similar to that of the Pol II system. Cryo-EM structures of Pol III preinitiation complexes are presented, comprising Pol III and the transcription factor TFIIIB bound to a natural promoter in different functional states. Structures of RNA polymerase III pre-initiation complex RNA polymerase III (Pol III) catalyses the transcription of short RNAs, including transfer RNAs and the 5S ribosomal RNA, which are essential for protein synthesis during cell growth. Pol III is predominantly regulated at the level of transcription initiation, and dysregulated Pol III activity is linked to diseases including cancer. Two independent studies in this issue, by Alessandro Vannini and colleagues and Christoph Müller and colleagues, describe electron cryo-microscopy structures of the yeast Pol III preinitiation complex, comprising the full 17-subunit Pol III and the three TFIIIB subunits (TBP, Brf1 and Bdp1) bound to promoter DNA in various functional states. The structures reveal the detailed mechanisms that underlie how Pol III is recruited to its target promoters and how promoter DNA is opened to form a stable transcription bubble, and also allow a comparison with the structures of Pol I and Pol II preinitiation complexes.

RNA polymerase I (Pol I) specifically synthesizes ribosomal RNA. Pol I upregulation is linked to cancer, while mutations in the Pol I machinery lead to developmental disorders. Here we report the cryo-EM structure of elongating human Pol I at 2.7 Å resolution. In the exit tunnel, we observe a double-stranded RNA helix that may support Pol I processivity. Our structure confirms that human Pol I consists of 13 subunits with only one subunit forming the Pol I stalk. Additionally, the structure of human Pol I in complex with the initiation factor RRN3 at 3.1 Å resolution reveals stalk flipping upon RRN3 binding. We also observe an inactivated state of human Pol I bound to an open DNA scaffold at 3.3 Å resolution. Lastly, the high-resolution structure of human Pol I allows mapping of disease-related mutations that can aid understanding of disease etiology. Here the authors structurally investigate elongating human RNA polymerase I at 2.7 Å using cryo-electron microscopy, as well as an RNA polymerase I open complex at 3.3 Å and bound to initiation factor RRN3 at 3.2 Å.

Understanding the structural biology of the insulin receptor and how it signals is of key importance in the development of insulin analogs to treat diabetes. We report here a cryo-electron microscopy structure of a single insulin bound to a physiologically relevant, high-affinity version of the receptor ectodomain, the latter generated through attachment of C-terminal leucine zipper elements to overcome the conformational flexibility associated with ectodomain truncation. The resolution of the cryo-electron microscopy maps is 3.2 Å in the insulin-binding region and 4.2 Å in the membrane-proximal region. The structure reveals how the membrane proximal domains of the receptor come together to effect signalling and how insulin’s negative cooperativity of binding likely arises. Our structure further provides insight into the high affinity of certain super-mitogenic insulins. Together, these findings provide a new platform for insulin analog investigation and design. The insulin receptor plays a key role in many physiological processes, yet how insulin effects receptor signaling at the structural level remains incomplete. Here the authors present a high-resolution cryo-EM structure of a high-affinity form of the insulin-bound insulin receptor ectodomain that sheds light on the mechanism of signal transduction.