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The SARS-CoV-2 non-structural protein 1 (Nsp1), also referred to as the host shutoff factor, suppresses host innate immune functions. By combining cryo-electron microscopy and biochemistry, we show that SARS-CoV-2 Nsp1 binds to the human 40S subunit in ribosomal complexes, including the 43S pre-initiation complex and the non-translating 80S ribosome. The protein inserts its C-terminal domain into the mRNA channel, where it interferes with mRNA binding. We observe translation inhibition in the presence of Nsp1 in an in vitro translation system and in human cells. Based on the high-resolution structure of the 40S–Nsp1 complex, we identify residues of Nsp1 crucial for mediating translation inhibition. We further show that the full-length 5′ untranslated region of the genomic viral mRNA stimulates translation in vitro, suggesting that SARS-CoV-2 combines global inhibition of translation by Nsp1 with efficient translation of the viral mRNA to allow expression of viral genes.Cryo-EM structural analysis reveals the mechanism by which the SARS-CoV-2 protein Nsp1 inhibits global translation.

Co-translational protein targeting to membranes is a universally conserved process. Central steps include cargo recognition by the signal recognition particle and handover to the Sec translocon. Here we present snapshots of key co-translational-targeting complexes solved by cryo-electron microscopy at near-atomic resolution, establishing the molecular contacts between the Escherichia coli translating ribosome, the signal recognition particle and the translocon. Our results reveal the conformational changes that regulate the latching of the signal sequence, the release of the heterodimeric domains of the signal recognition particle and its receptor, and the handover of the signal sequence to the translocon. We also observe that the signal recognition particle and the translocon insert-specific structural elements into the ribosomal tunnel to remodel it, possibly to sense nascent chains. Our work provides structural evidence for a conformational state of the signal recognition particle and its receptor primed for translocon binding to the ribosome–nascent chain complex. The co-translational insertion of proteins into membranes requires interaction between a ribosome-bound signal recognition particle (SRP) and a membrane-bound translocon. Here the authors use cryo-EM and single particle reconstructions to obtain a comprehensive view of the co-translational protein targeting process.

Proteasomes are present in eukaryotes, archaea and Actinobacteria, including the human pathogen Mycobacterium tuberculosis , where proteasomal degradation supports persistence inside the host. In mycobacteria and other members of Actinobacteria, prokaryotic ubiquitin-like protein (Pup) serves as a degradation tag post-translationally conjugated to target proteins for their recruitment to the mycobacterial proteasome ATPase (Mpa). Here, we use single-particle cryo-electron microscopy to determine the structure of Mpa in complex with the 20S core particle at an early stage of pupylated substrate recruitment, shedding light on the mechanism of substrate translocation. Two conformational states of Mpa show how substrate is translocated stepwise towards the degradation chamber of the proteasome core particle. We also demonstrate, in vitro and in vivo, the importance of a structural feature in Mpa that allows formation of alternating charge-complementary interactions with the proteasome resulting in radial, rail-guided movements during the ATPase conformational cycle. Pup is the bacterial analog of ubiquitin for targeting proteins to the proteasome. Here, the authors use cryoEM to visualize structures of the Mycobacterium tuberculosis proteasome translocating a Pup-tagged substrate.

Ribosomes synthesizing membrane or secretory proteins are targeted to the endoplasmic reticulum (ER) in eukaryotic cells by the signal recognition particle (SRP). Upon reaching the ER, the SRP interacts with its receptor to promote transfer of the signal sequence to the protein-conducting channel or translocon. Kobayashi et al. studied the ribosomal complex that forms on the ER, in which the SRP and its receptor interact to transfer the newly synthesized protein to the translocon. The observed organization of the assembly reveals the roles of multiple eukaryotic-specific protein components present in the SRP and its receptor in stabilizing the conformation that facilitates signal sequence handover. Science , this issue p. 323 Eukaryotic-specific signal recognition particle and receptor components stabilize the ribosomal endoplasmic reticulum–targeting complex. Signal recognition particle (SRP) targets proteins to the endoplasmic reticulum (ER). SRP recognizes the ribosome synthesizing a signal sequence and delivers it to the SRP receptor (SR) on the ER membrane followed by the transfer of the signal sequence to the translocon. Here, we present the cryo–electron microscopy structure of the mammalian translating ribosome in complex with SRP and SR in a conformation preceding signal sequence handover. The structure visualizes all eukaryotic-specific SRP and SR proteins and reveals their roles in stabilizing this conformation by forming a large protein assembly at the distal site of SRP RNA. We provide biochemical evidence that the guanosine triphosphate hydrolysis of SRP·SR is delayed at this stage, possibly to provide a time window for signal sequence handover to the translocon.

Cell survival under nutrient-deprived conditions relies on cells’ ability to adapt their organelles and rewire their metabolic pathways. In yeast, glucose depletion induces a stress response mediated by mitochondrial fragmentation and sequestration of cytosolic ribosomes on mitochondria. This cellular adaptation promotes survival under harsh environmental conditions; however, the underlying mechanism of this response remains unknown. Here, we demonstrate that upon glucose depletion protein synthesis is halted. Cryo-electron microscopy structure of the ribosomes show that they are devoid of both tRNA and mRNA, and a subset of the particles depicted a conformational change in rRNA H69 that could prevent tRNA binding. Our in situ structural analyses reveal that the hibernating ribosomes tether to fragmented mitochondria and establish eukaryotic-specific, higher-order storage structures by assembling into oligomeric arrays on the mitochondrial surface. Notably, we show that hibernating ribosomes exclusively bind to the outer mitochondrial membrane via the small ribosomal subunit during cellular stress. We identify the ribosomal protein Cpc2/RACK1 as the molecule mediating ribosomal tethering to mitochondria. This study unveils the molecular mechanism connecting mitochondrial stress with the shutdown of protein synthesis and broadens our understanding of cellular responses to nutrient scarcity and cell quiescence. Cells adapt to low glucose by halting protein synthesis and altering organelle shape. Here the authors showed that hibernating ribosomes tether to mitochondria and form arrays on the membrane, acting as a pro-survival mechanism in dormant yeast cells.

Our understanding of protein synthesis has been conceptualised around the structure and function of the bacterial ribosome. This complex macromolecular machine is the target of important antimicrobial drugs, an integral line of defence against infectious diseases. Here, we describe how open access to cryo-electron microscopy facilities combined with bespoke user support enabled structural determination of the translating ribosome from Escherichia coli at 1.55 Å resolution. The obtained structures allow for direct determination of the rRNA sequence to identify ribosome polymorphism sites in the E. coli strain used in this study and enable interpretation of the ribosomal active and peripheral sites at unprecedented resolution. This includes scarcely populated chimeric hybrid states of the ribosome engaged in several tRNA translocation steps resolved at ~2 Å resolution. The current map not only improves our understanding of protein synthesis but also allows for more precise structure-based drug design of antibiotics to tackle rising bacterial resistance. Developments in cryo-EM sample preparation and data collection are pivotal for structure determination. Fromm et al. present a 1.55 Å structure of the translating bacterial ribosome that provides new insights on its function and may allow for more precise structure-based drug design.

During co-translational protein targeting, the signal recognition particle (SRP) binds to the translating ribosome displaying the signal sequence to deliver it to the SRP receptor (SR) on the membrane, where the signal peptide is transferred to the translocon. Using electron cryo-microscopy, we have determined the structure of a quaternary complex of the translating Escherichia coli ribosome, the SRP–SR in the ‘activated’ state and the translocon. Our structure, supported by biochemical experiments, reveals that the SRP RNA adopts a kinked and untwisted conformation to allow repositioning of the ‘activated’ SRP–SR complex on the ribosome. In addition, we observe the translocon positioned through interactions with the SR in the vicinity of the ribosome exit tunnel where the signal sequence is extending beyond its hydrophobic binding groove of the SRP M domain towards the translocon. Our study provides new insights into the mechanism of signal sequence transfer from the SRP to the translocon. Membrane proteins are inserted co-transnationally through the association between ribosome, the signal recognition particle and its receptor, and the membrane-bound translocon. Here the authors present a cryo-EM reconstruction of this quaternary complex in the activated state and propose a model for signal sequence transfer to the translocon.

Membrane scaffold protein-based nanodiscs have facilitated unprecedented structural and biophysical analysis of membrane proteins in a near-native lipid environment. However, successful reconstitution of membrane proteins in nanodiscs requires prior solubilization and purification in detergents, which may impact their physiological structure and function. Furthermore, the detergent-mediated reconstitution of nanodiscs is unlikely to recapitulate the precise composition or asymmetry of native membranes. To circumvent this fundamental limitation of traditional nanodisc technology, we herein describe the development of membrane-solubilizing peptides to directly extract membrane proteins from native cell membranes into nanoscale discoids. By systematically protein engineering and screening, we create a class of chemically modified Apolipoprotein-A1 mimetic peptides to enable the formation of detergent-free nanodiscs with high efficiency. Nanodiscs generated with these engineered membrane scaffold peptides are suitable for obtaining high-resolution structures using single-particle cryo-EM with native lipids. To further highlight the versatility of our approach, we directly extract a sampling of membrane signaling proteins with their surrounding native membranes for biochemical and biophysical interrogations. To bypass the limitations of detergents, Ren et al. developed peptide scaffolds that extract membrane proteins directly into lipid nanodiscs, preserving the native environment for structural and functional studies of previously inaccessible membrane protein complexes

AbstractObjectiveTo systematically document the patterns of war related injuries in Gaza, Palestine.DesignSurvey study of international healthcare workers, August 2024 to February 2025.SettingGaza, Palestine.Participants78 international healthcare workers deployed to Gaza.Main outcome measuresThe main outcome was the type of injuries observed by international healthcare workers during the conflict in Gaza. A Delphi informed survey was distributed through non-governmental organisation rosters and secure WhatsApp and email groups. Respondents completed the survey using contemporaneous logbooks and shift records.ResultsThe survey collected data on 12 anatomical regions, mechanisms of trauma, and general medical conditions. 78 healthcare workers reported 23 726 trauma related injuries and 6960 injuries related to weapons. The most common traumatic injuries were burns (n=4348, 18.3%), lower limb injuries (n=4258, 17.9%), and upper limb injuries (n=3534, 14.9%). Explosive injuries accounted for most of the weapon related trauma (n=4635, 66.6%), predominantly affecting the head (n=1289, 27.8%), whereas firearm injuries disproportionately affected the lower limbs (n=526, 22.6%). Healthcare workers reported 4188 people with chronic disease across 11 domains requiring long term treatment.ConclusionHealthcare workers deployed to Gaza reported an injury phenotype defined by extensive polytrauma (≥2 anatomical regions), complex blast injuries from high yield explosives, firearm related injuries to upper and lower limbs, and severe disruption to primary care and the treatment of chronic diseases. The results provide actionable insights to tailor humanitarian response and highlight the urgent need for structured, resilient clinical surveillance systems.Editor’s noteThis paper is based on research from an active war zone, where conventional research methods may be impossible to apply.

Asynchronously cycling cells pose a challenge to the accurate characterization of phase-specific gene expression. Current strategies, including RNAseq, survey the steady state gene expression across the cell cycle and are inherently limited by their inability to resolve dynamic gene regulatory networks. Single cell RNAseq (scRNAseq) can identify different cell cycle transcriptomes if enough cycling cells are present, however some cells are not amenable to scRNAseq. Therefore, we merged two powerful strategies, the CDT1 and GMNN degrons used in Fluorescent Ubiquitination-based Cell Cycle Indicator (FUCCI) cell cycle sensors and the ribosomal protein epitope tagging used in RiboTrap/Tag technologies to isolate cell cycle phase-specific mRNA for sequencing. The resulting cell cycle dependent, tagged ribosomal proteins (ccTaggedRP) were differentially expressed during the cell cycle, had similar subcellular locations as endogenous ribosomal proteins, incorporated into ribosomes and polysomes, and facilitated the recovery of cell cycle phase-specific RNA for sequencing. ccTaggedRP has broad applications to investigate phase-specific gene expression in complex cell populations.