Nature Structural & Molecular Biology

Microtubules are dynamic polymers assembled from {beta}-tubulin dimers. Mammals have multiple and {beta}-tubulin isoforms. Despite a high degree of conservation, microtubules assembled from different tubulin isoforms have unique dynamic properties. How isoform sequence variation affects polymerization interfaces and nucleotide dependent conformational changes in microtubules is still not well understood. Here we report 2.9[A] resolution cryo-EM structures of human 1B/{beta}I+{beta}IVb microtubules in the GDP state, and a GTP-like state, bound to GMPCPP. Our structures show that, similar to microtubules assembled from other mammalian isoforms, transition from the GTP to the GDP states in 1B/{beta}I+{beta}IVb microtubules results in strengthening of the longitudinal interface and an overall compaction of the axial dimer repeat distance in the lattice. Interestingly, we find that -tail residues link longitudinally adjacent tubulin dimers through interactions with two conserved arginine residues in {beta}-tubulin that are mutated in human disease. Comparative analysis of tubulin isoforms shows minimal isoform-specific effects at the longitudinal interface or the -tubulin lateral interface, but a high concentration of sequence variability in the second shell of residues away from the {beta}-tubulin lateral interface which can modulate polymerization interfaces and thus impact microtubule dynamics.

Ubiquitination of histone H2A at lysine 119 residue (H2AK119ub) plays critical roles in a wide range of physiological processes, including Polycomb gene silencing 1,2, replication 3-5, DNA damage repair 6-10, X inactivation 11,12, and heterochromatin organization 13,14. However, the underlying mechanism and structural basis of H2AK119ub remains largely elusive. In this study, we report that H2AK119ub nucleosomes have a unique composition, containing histone variants H2BC1 and H2AZ.2, and importantly, this composition is required for H2AK119ub and Polycomb gene silencing. Using the UAB domain of RSF1, we purified H2AK119ub nucleosomes to a sufficient amount and purity. Mass spectrometry analyses revealed that H2AK119ub nucleosomes contain the histone variants H2BC1 and H2AZ.2. A cryo-EM study resolved the structure of native H2AK119ub nucleosomes to a 2.6A resolution, confirming H2BC1 in one subgroup of H2AK119ub nucleosomes. Tandem GST-UAB pulldown, Flag-H2AZ.2, and HA-H2BC1 immunoprecipitation revealed that H2AK119ub nucleosomes could be separated into distinct subgroups, suggesting their composition heterogeneity and potential dynamic organization. Knockout or knockdown of H2BC1 or H2AZ.2 reduced cellular H2AK119ub levels, establishing H2BC1 and H2AZ.2 as critical determinants of H2AK119ub. Furthermore, genomic binding profiles of H2BC1 and H2AZ.2 overlapped significantly with H2AK119ub binding, with the most significant overlapping in the gene body and intergenic regions. Finally, assays in developing embryos reveal an interaction of H2AZ.2, H2BC1, and RING1A in vivo. Thus, this study revealed, for the first time, that the H2AK119ub nucleosome has a unique composition, and this composition is required for H2AK119ub and Polycomb gene silencing.

H2A.Z is a conserved histone variant that is localized to specific genomic regions where it plays important roles in transcription, DNA repair, and replication. Central to the biochemistry of human H2A.Z are the SRCAP and TIP60 chromatin remodelers, homologs of yeast SWR1 which catalyzes ATP-dependent H2A.Z exchange. Here, we use cryo-electron microscopy to resolve six structural states of the native SRCAP complex, uncovering conformational intermediates interpreted as a stepwise path to full nucleosome engagement. We also resolve the structure of the native TIP60 complex which consists of a structured core from which flexibly tethered chromatin binding domains emerge. Despite the shared subunit composition, the core of TIP60 displays divergent architectures from SRCAP that structurally disfavor nucleosome engagement, suggesting a distinct biochemical function.

Methylation of histone H3 at lysine 36 (H3K36me3) marks active chromatin. The mark is interpreted by epigenetic readers that assist transcription and safeguard the integrity of the chromatin fiber. The chromodomain protein MSL3 binds H3K36me3 to target X-chromosomal genes in male Drosophila for dosage compensation. The PWWP-domain protein JASPer recruits the JIL1 kinase to active chromatin on all chromosomes. Unexpectedly, depletion of K36me3 had variable, locus-specific effects on the interactions of those readers. This observation motivated a systematic and comprehensive study of K36 methylation in a defined cellular model. Contrasting prevailing models, we found that K36me1, K36me2 and K36me3 each represent independent chromatin states. A gene-centric view of the changing K36 methylation landscape upon depletion of the three methyltransferases Set2, NSD and Ash1 revealed local, context-specific methylation signatures. Set2 catalyzes K36me3 predominantly at transcriptionally active euchromatin. NSD places K36me2/3 at defined loci within pericentric heterochromatin and on weakly transcribed euchromatic genes. Ash1 deposits K36me1 at regions with enhancer signatures. The genome-wide mapping of MSL3 and JASPer suggested that they bind K36me2 in addition to K36me3, which was confirmed by direct affinity measurement. This dual specificity attracts the readers to a broader range of chromosomal locations and increases the robustness of their actions.

Epigenetic inheritance requires the transfer of parental histones to newly synthesized DNA during eukaryotic chromosome replication, yet the structural mechanisms underlying replisome engagement with nucleosomes remain unclear. Here we establish an in vitro chromatin replication system and report four cryo-EM structures of the human replisome in complex with a parental nucleosome. The structures capture distinct states of nucleosomal DNA unwrapping and nucleosome integrity during nucleosome disassembly by the encroaching replisome.

The Fanconi Anemia (FA) pathway is essential for the repair of DNA interstrand crosslinks (ICLs). The pathway is activated when a replication fork stalls because of an ICL or other replication stress. A central event in pathway activation is the mono-ubiquitination of the FANCI-FANCD2 (ID) complex by the FA Core complex, a ubiquitin ligase of nine subunits. Here we describe the cryo-EM structures of the 1.1 MDa FA Core at 3.1 angstroms, except for the FANCA subunit at 3.4, and of the complex containing Core, ID and the UBE2T ubiquitin conjugating enzyme at 4.2 angstroms. The Core has unusual stoichiometry with two copies of FANCB, FAAP100, FANCA, FAAP20, FANCG, FANCL, but only a single copy of FANCC, FANCE and FANCF. This is due to homodimers of FANCA and FANCB having incompatible 2-fold symmetry, resulting in an overall asymmetric assembly of the other subunits. The asymmetry is crucial, as it prevents the binding of a second FANC-C-E-F sub-complex that inhibits UBE2T recruitment by FANCL, and instead creates an ID binding site. The single active FANCL-UBE2T binds next to the FANCD2 ubiquitination site, prying open the FANCI-FANCD2 interface within which the ubiquitination sites are buried. These structures and biochemical data indicate a single active site ubiquitinates FANCD2 and FANCI sequentially, shedding light on a central event in the FA pathway.

The endoplasmic reticulum (ER) unfolded protein response (UPR) is tuned by the balance between unfolded proteins and chaperones. While reserve chaperones are known to suppress the UPR transducers via their stress-sensing luminal domains, the underlying structural mechanisms remain unclear. Cellular and biophysical analyses established that the ER chaperone AGR2 forms a repressive complex with the luminal domain of the UPR transducer IRE1{beta}. Structural prediction, X-ray crystallography and NMR spectroscopy identify critical interactions between an AGR2 monomer and a regulatory loop in IRE1{beta}s luminal domain. However, in the repressive complex it is an AGR2 dimer that binds IRE1{beta}. Cryo-EM reconstruction reveals a mechanism of unanticipated simplicity: one AGR2 protomer engages the regulatory loop, while the second asymmetrically binds IRE1{beta}s luminal domains C-terminus, blocking IRE1{beta}-activating dimerization. Molecular dynamic simulations indicate that the second, disruptive AGR2 protomer exploits rare fluctuations in the IRE1{beta} dimer that expose its binding site. Thus, AGR2 actively disrupts IRE1{beta} dimers to suppress the UPR, while chaperone clients compete for AGR2 to trigger UPR signalling

In Saccharomyces cerevisiae, prolonged cellular stress induces some introns to accumulate post-splicing as stable, linear, spliceosome-protected RNAs1. These stable introns are defined by having short distances from their branchpoint (BP) sequences to their 3'-splice sites (3'SSs). Stable introns sequester splicing components, thereby reducing splicing activity and affecting cell growth in the stressed conditions. The mechanism by which these normally ephemeral products of pre-mRNA splicing persist cannot be explained by the current understanding of the splicing pathway, which derives primarily from studies of unstressed cells and their extracts2,3. Here, we determined the cryo-electron microscopy (cryo-EM) structure of a stable-intron complex purified from saturated-culture conditions. This structure and experimental follow-up show that a Bact-like spliceosome protects stable introns from degradation, and that the short BP-3'SS distances of stable introns render this conformation of the spliceosome resistant to remodelling by helicases. Spliceosomes can also assemble onto artificial introns that have the same sequences as authentic stable introns but do not rely on splicing for their biogenesis, which demonstrates that spliceosomes arrive at this Bact-like conformation by reassembling onto linear introns after their excision from pre-mRNAs. This reassembly activity is maintained in both stressed and unstressed cells. Thus, most yeast introns compete with pre-mRNAs for access to the splicing machinery, and budding yeast has co-opted this activity to adapt to environmental insults.

Acetylation of histones is a key post-translational modification that guides gene expression regulation. In yeast, the class I histone deacetylase containing Rpd3S complex plays a critical role in the suppression of spurious transcription by removing histone acetylation from actively transcribed genes. The Saccharomyces cerevisiae Rpd3S complex has five subunits (Rpd3, Sin3, Rco1, Eaf3, and Ume1) but its subunit stoichiometry and how the complex engages nucleosomes to achieve substrate specificity remains elusive. Here we report the cryo-EM structure of the complete Rpd3S complex bound to a nucleosome. Sin3 and two copies of subunits Rco1 and Eaf3 encircle the deacetylase subunit Rpd3 and coordinate the binding of Ume1. The Rpd3S complex binds both trimethylated H3 tails at position lysine 36 and makes multiple additional contacts with the nucleo-somal DNA, the H2A-H2B acidic patch, and histone H3. Direct regulation via the Sin3 subunit coordinates binding of the acetylated histone substrate to achieve substrate specificity.

Most TGF{beta} family ligands exist as procomplexes consisting of a prodomain noncovalently bound to a growth factor (GF); Whereas some prodomains confer latency, the Anti-Mullerian Hormone (AMH) prodomain maintains a remarkably high affinity for the GF yet remains active. Using single particle EM methods, we show the AMH prodomain consists of two subdomains: a vestigial TGF{beta} prodomain-like fold and a novel, helical bundle GF-binding domain, the result of an exon insertion 450 million years ago, that engages both receptor epitopes. When associated with the prodomain, the AMH GF is distorted into a strained, open conformation whose closure upon bivalent binding of AMHR2 displaces the prodomain through a conformational shift mechanism to allow for signaling.

De novo cytosine methylation is essential for mammalian development and is deposited by DNMT3A and DNMT3B. In cells, DNA methylation occurs in the context of chromatin, where nucleosomes are connected by DNA linkers. Here, we report Cryo-EM structures of DNMT3A2/3B3 bound to di-nucleosomes with different linker lengths. We show that DNMT3A2/3B3 preferentially binds di-nucleosomes separated by short DNA linkers by inducing large-scale changes to the di-nucleosome structure, enabling each DNMT3B3 subunit to bind each nucleosome. Linker length and the position of cytosines within the linker control DNA methylation, indicating that a significant fraction of linkers in chromatin are naturally resistant to DNMT3A2/3B3 activity. Finally, DNMT3A2/3B3 scans for H3K36me2-3 modifications, explaining how H3K36 methylation simulates DNMT3A2 activity. Our structure is the first example of a DNA methyltransferase interacting with higher-order nucleosome substrates and provides new insights on how DNA methylation takes place in chromatin.

Linker histones are essential for chromatin compaction, yet how they contribute to higher-order fiber assembly remains poorly understood. Here, we determined cryo-electron microscopy structures of Arabidopsis dodeca-nucleosome fibers containing distinct H2A/H3 variants and linker histone H1.3, revealing a noncanonical binding mode that a laterally positioned H1.3 connects the acidic patch of one nucleosome and the DNA of the neighboring nucleosome, thereby scaffolding dinucleosomes into two-start chromatin fibers. This noncanonical binding mode is structurally conserved when H1.3 is replaced by Gallus gallus H5. Furthermore, incorporation of H2A.W and H3.3 further induces back-to-back fiber dimerization. Cryo-electron tomography and in vivo cross-linking mass spectrometry analyses support the physiological relevance of H1 lateral engagement. Our findings establish that linker histones act as active architectural scaffolds in higher-order chromatin organization.

During normal levels of exertion, many cardiac muscle myosin heads are sequestered in an off-state even during systolic contraction to save energy and for precise regulation. They can be converted to an on-state when exertion is increased. Hypercontractility caused by hypertrophic cardiomyopathy (HCM) myosin mutations is often the result of shifting the equilibrium toward more heads in the on-state. The off-state is equated with a folded-back structure known as the interacting head motif (IHM), which is a regulatory feature of all muscle myosins and class-2 non-muscle myosins. We report here the human {beta}-cardiac myosin IHM structure to 3.6 [A] resolution. The structure shows that the interfaces are hot spots of HCM mutations and reveals details of the significant interactions. Importantly, the structures of cardiac and smooth muscle myosin IHMs are dramatically different. This challenges the concept that the IHM structure is conserved in all muscle types and opens new perspectives in the understanding of muscle physiology. The cardiac IHM structure has been the missing puzzle piece to fully understand the development of inherited cardiomyopathies. This work will pave the way for the development of new molecules able to stabilize or destabilize the IHM in a personalized medicine approach. *This manuscript was submitted to Nature Communications in August 2022 and dealt efficiently by the editors. All reviewers received this version of the manuscript before 9208 August 2022. They also received coordinates and maps of our high resolution structure on the 18208 August 2022. Due to slowness of at least one reviewer, this contribution was delayed for acceptance by Nature Communications and we are now depositing in bioRxiv the originally submitted version written in July 2022 for everyone to see. Indeed, two bioRxiv contributions at lower resolution but adding similar concepts on thick filament regulation were deposited this week in bioRxiv, one of the contributions having had access to our coordinates. We hope that our data at high resolution will be helpful for all readers that appreciate that high resolution information is required to build accurate atomic models and discuss implications for sarcomere regulation and the effects of cardiomyopathy mutations on heart muscle function.

TASK channels are unusual members of the two-pore domain potassium (K2P) channel family, with unique and unexplained physiological and pharmacological characteristics. TASKs are found in neurons1,2, cardiomyocytes3-5 and vascular smooth muscle cells6 where they are involved in regulation of heart rate7, pulmonary artery tone6,8, sleep/wake cycles9 and responses to volatile anaesthetics9-12. K2P channels regulate the resting membrane potential, providing background K+ currents controlled by numerous physiological stimuli13,14. Unlike other K2P channels, TASK channels have the capacity to bind inhibitors with high affinity, exceptional selectivity and very slow compound washout rates. These characteristics make the TASK channels some of the the most easily druggable potassium channels, and indeed TASK-1 inhibitors are currently in clinical trials for obstructive sleep apnea (OSA) and atrial fibrillation (Afib)15 (The DOCTOS and SANDMAN Trials). Generally, potassium channels have an intramembrane vestibule with a selectivity filter above and a gate with four parallel helices below. However, K2P channels studied to date all lack a lower gate. Here we present the structure of TASK-1, revealing a unique lower gate created by interaction of the two crossed C-terminal M4 transmembrane helices at the vestibule entrance, which we designate as an \"X-gate\". This structure is formed by six residues (V243LRFMT248) that are essential for responses to volatile anaesthetics11, neuro-transmitters16 and G-protein coupled receptors16. Interestingly, mutations within the X-gate and surrounding regions drastically affect both open probability and activation by anaesthetics. Structures of TASK-1 with two novel, high-affinity blockers, shows both inhibitors bound below the selectivity filter, trapped in the vestibule by the X-gate, thus explaining their exceptionally low wash-out rates. Thus, the presence of the X-gate in TASK channels explains many aspects of their unusual physiological and pharmacological behaviour, which is invaluable for future development and optimization of TASK modulators for treatment of heart, lung and sleep disorders.

Many regulatory PPP1R subunits join few catalytic PP1c subunits to mediate phosphoserine and phosphothreonine dephosphorylation in metazoans. Regulatory subunits are known to engage PP1cs surface, locally affecting flexible phosphopeptides access to the active site. However, catalytic efficiency of holophosphatases towards their natively-folded phosphoprotein substrates is largely unexplained. Here we present a Cryo-EM structure of the tripartite PP1c/PPP1R15A/G-actin holophosphatase that terminates signalling in the Integrated Stress Response (ISR) in pre-dephosphorylation complex with its substrate, translation initiation factor 2 (eIF2). G-actins role in eIF2 dephosphorylation is supported crystallographically by the structure of the binary PPP1R15A-G-actin complex, and by biochemical and genetic confirmation of the essential role of PPP1R15A-G-actin contacts to eIF2P dephosphorylation. In the pre-dephosphorylation CryoEM complex, G-actin aligns the catalytic and regulatory subunits, creating a composite surface that engages eIF2s N-terminal domain to position the distant phosphoserine-51 at the active site. eIF2 residues specifying affinity for the holophosphatase are confirmed here to make critical contacts with the eIF2 kinase PERK. Thus, a convergent process of higher-order substrate recognition specifies functionally-antagonistic phosphorylation and dephosphorylation in the ISR.

Pioneer transcription factors are vital for cell fate changes. PU.1 and C/EBP work together to regulate hematopoietic stem cell differentiation. However, how they recognize in vivo nucleosomal DNA targets remain elusive. Here we report the structures of the nucleosome containing the mouse genomic CX3CR1 enhancer DNA and its complexes with PU.1 alone and with both PU.1 and the C/EBP DNA binding domain. Our structures reveal that PU.1 binds the DNA motif at the exit linker, shifting 17 bp of DNA into the core region through interactions with H2A, unwrapping [~]20 bp of nucleosomal DNA. C/EBP binding, aided by PU.1s repositioning, unwraps [~]25 bp entry DNA. The PU.1 Q218H mutation, linked to acute myeloid leukemia, disrupts PU.1-H2A interactions. PU.1 and C/EBP jointly displace linker histone H1 and open the H1-condensed nucleosome array. Our study unveils how two pioneer factors can work cooperatively to open closed chromatin by altering DNA positioning in the nucleosome.

The super family 2 (SF2) helicase XPD is a central component of the general transcription factor II H (TFIIH) which is essential for transcription and nucleotide excision DNA repair (NER)1. Within these two processes XPDs helicase function is vital for NER but not for transcription initiation, where XPD only acts as a scaffold for other factors 2. We deciphered one of the most enigmatic steps in XPD helicase action: the active separation of dsDNA and its stalling upon approaching an interstrand crosslink, one of the most severe DNA damages in the cell, using cryo EM. Furthermore, the structure clearly shows how dsDNA is separated and reveals a highly unusual involvement of the Arch domain in active dsDNA separation. Combined with mutagenesis and biochemical analyses, we identify distinct functional residues important for helicase activity. Surprisingly, those areas also affect core TFIIH translocase activity, revealing a yet unencountered function of XPD within the TFIIH scaffold. Importantly, our structure provides a basis for XPD damage recognition and further suggests how the NER bubble could be formed, leading to a model for the location of the XPG nuclease relative to the excised damage.

The efficient formation of native protein complexes is essential for cellular function. Across all kingdoms of life, protein complexes frequently assemble co-translationally, either when one subunit is fully synthesized before interaction with nascent partner subunits (co-post) or when multiple nascent subunits interact co-translationally (co-co), with homomeric proteins particularly enriched among co-co assembling complexes. However, it is unknown whether co-co assembly of homomers occurs on the same mRNA in cis or across neighboring mRNAs in trans, and how ribosomes spatially organize to enable co-co assembly. Using E. coli homodimeric protein PheA as a proof-of-concept model, we show by ribosome profiling and cryo-EM structural analysis that it employs the co-co assembly route. Co-co assembly of PheA is facilitated by the proximity of polypeptide exit tunnels, but does not rely on fixed ribosomal orientations. Surprisingly, we identified trans-assembly as potentially the primary mode of PheA co-co assembly, generating large polysomal networks for PheA synthesis. Cis-assembly of PheA was less frequent and occurred mainly between non-adjacent ribosomes on the mRNA due to spatial restraints imposed by the arrangement of directly neighboring ribosomes in polysomes. These findings reveal fundamental principles of how cells structurally organise protein complex formation during translation.

The Hsp90 molecular chaperone collaborates with the phosphorylated Cdc37 cochaperone to maintain kinase proteostasis through the folding and activation of its many client kinases. As with many kinases, the Hsp90 client kinase CRaf is activated by phosphorylation at specific regulatory sites. The cochaperone phosphatase PP5 dephosphorylates CRaf but also Cdc37 in an Hsp90-dependent manner. Although dephosphorylating Cdc37 has been proposed as a mechanism for releasing Hsp90-bound kinases, here we show that Hsp90 bound kinases sterically inhibit Cdc37 dephosphorylation indicating kinase release must occur before Cdc37 dephosphorylation. The cryo-EM structure of PP5 in complex with Hsp90:Cdc37:CRaf reveals how Hsp90 both activates PP5 and scaffolds its association with the bound CRaf to dephosphorylate a site at the C-terminus of the kinase domain. Thus, we directly show how Hsp90s role in maintaining protein homeostasis goes beyond folding and activation to include post translationally modifying its client kinases.

Human RAD521,2 is a multifunctional DNA repair protein involved in several cellular events that support genome stability including protection of stalled DNA replication forks from excessive degradation3-7. In its gatekeeper role, RAD52 binds to and stabilizes stalled replication forks during replication stress protecting them from reversal by SMARCAL15. The structural and molecular mechanism of the RAD52-mediated fork protection remains elusive. Here, using P1 nuclease sensitivity, biochemical and single-molecule analyses we show that RAD52 dynamically remodels replication forks through its strand exchange activity. The presence of the ssDNA binding protein RPA at the fork modulates the kinetics of the strand exchange without impeding the reaction outcome. Mass photometry and single-particle cryo-electron microscopy show that the replication fork promotes a unique nucleoprotein structure containing head-to-head arrangement of two undecameric RAD52 rings with an extended positively charged surface that accommodates all three arms of the replication fork. We propose that the formation and continuity of this surface is important for the strand exchange reaction and for competition with SMARCAL1. One Sentence SummaryUsing cryo-EM, biochemical and single-molecule approaches we show that the structure of stalled DNA replication fork promotes a unique two-ring organization of human RAD52 protein which remodels the fork via DNA strand exchange.