The rockefeller university

A primary goal in the development of an AIDS vaccine is the elicitation of broadly neutralizing antibodies (bNAbs) that protect against diverse HIV-1 strains. To this aim, germline-targeting immunogens have been developed to activate bNAb precursors and initiate the induction of bNAbs. While most preclinical germline-targeting HIV-1 vaccine candidates only include a single bNAb precursor epitope, an effective HIV-1 vaccine will likely require bNAbs that target multiple epitopes on Env. Here, we report a newly designed germline-targeting Env SOSIP trimer, named 3nv.2, that presents three bNAb epitopes on Env: the CD4bs, V3, and V2 epitopes. 3nv.2 forms a stable trimeric Env and binds to bNAb precursors from each of the desired epitopes. Immunization experiments in rhesus macaques and mice demonstrate 3nv.2 elicits the combined effects of its parent immunogens. Our results provide proof of concept for using a germline-targeting immunogen presenting three or more bNAb epitopes and a framework to develop improved next-generation HIV-1 vaccine candidates.

Biomolecular condensates are key features of intracellular compartmentalization(1,2). As the most prominent nuclear condensate in eukaryotes, the nucleolus is a multiphase liquid-like structure in which ribosomal RNAs (rRNAs) are transcribed and processed, undergoing multiple maturation steps to form the small (SSU) and large (LSU) ribosomal subunits(3-5). However, how rRNA processing is coupled to the layered organization of the nucleolus is poorly understood owing to a lack of tools to precisely monitor and perturb nucleolar rRNA processing dynamics. Here we developed two complementary approaches to spatiotemporally map rRNA processing and engineer de novo nucleoli. Using sequencing in parallel with imaging, we found that rRNA processing steps are spatially segregated, with sequential maturation of rRNA required for its outward movement through nucleolar phases. By generating synthetic nucleoli in cells using an engineered rDNA plasmid system, we show that defects in SSU processing can alter the ordering of nucleolar phases, resulting in inside-out nucleoli and preventing rRNA outflux, while LSU precursors are necessary to build the outermost layer of the nucleolus. These findings demonstrate how rRNA is both a scaffold and substrate for the nucleolus, with rRNA acting as a programmable blueprint for the multiphase architecture that facilitates assembly of an essential molecular machine.

Lipids are essential components of cancer cells due to their structural and signalling roles1. To meet metabolic demands, many cancers take up extracellular lipids2, 3, 4-5; however, how these lipids contribute to cancer growth and progression remains poorly understood. Here, using functional genetic screens, we identify uptake of lipoproteins-the primary mechanism for lipid transport in circulation-as a key determinant of ferroptosis sensitivity in cancer. Lipoprotein supplementation robustly inhibits ferroptosis across diverse cancer types, primarily through the delivery of alpha-tocopherol (alpha-toc), the most abundant form of vitamin E in human lipoproteins. Mechanistically, cancer cells take up lipoproteins through a pathway dependent on sulfated glycosaminoglycans (GAGs) linked to cell-surface proteoglycans. Disrupting GAG biosynthesis or acutely degrading surface GAGs reduces lipoprotein uptake, sensitizes cancer cells to ferroptosis and impairs tumour growth in mice. Notably, human clear cell renal cell carcinomas-a lipid-rich malignancy-exhibit elevated levels of chondroitin sulfate and increased lipoprotein-derived alpha-toc compared with normal kidney tissue. Together, our study establishes lipoprotein uptake as a critical anti-ferroptotic mechanism in cancer and implicates GAG biosynthesis as a therapeutic target.

Retrons are a retroelement class found in diverse prokaryotes that can be adapted to augment CRISPR-Cas9 genome engineering technology to efficiently rewrite short stretches of genetic information in bacteria and yeast. However, efficiency in human cells has been limited by unknown factors. We identified non-coding RNA (ncRNA) instability and impaired Cas9 activity due to 5 ' sgRNA extension as key contributors to low retron editor efficiency in human cells. We re-engineered the Eco1 ncRNA to incorporate an exoribonuclease-resistant RNA pseudoknot from the Zika virus 3 ' UTR and devised an RNA processing strategy using Csy4 ribonuclease to minimize 5 ' sgRNA extension. This strategy increased steady-state ncRNA levels and rescued sgRNA activity, leading to increased templated repair. This work reveals a previously unappreciated role for ncRNA stability in retron editor efficiency in human cells and presents an enhanced Eco1 retron editor capable of precise genome editing in human cells from a single integrated lentivirus and, in the context of the nCas9 H840A nickase, without creating double-strand breaks.

YnaI is a member of the family of bacterial MscS (mechanosensitive channel of small conductance)-like channels. Channel gating upon hypoosmotic stress and the role of lipids in this process have been extensively studied for MscS, but are less well understood for YnaI, which features two additional transmembrane helices. Here, we combined cryogenic electron microscopy, molecular dynamics simulations and patch-clamp electrophysiology to advance our understanding of YnaI. The two additional helices move the lipid-filled hydrophobic pockets in YnaI further away from the lipid bilayer and change the function of the pocket lipids from being a critical gating element in MscS to being more of a structural element in YnaI. Unlike MscS, YnaI shows pronounced gating hysteresis and remains open to a substantially lower membrane tension than is needed to initially open the channel. Thus, at near-lytic membrane tension, both MscL and YnaI will open, but while MscL has a large pore and must close quickly to minimize loss of essential metabolites, YnaI only conducts ions and can thus remain open for longer to continue to facilitate pressure equilibration across the membrane.

The Nidovirus RdRp-associated nucleotidyltransferase (NiRAN) domain initiates mRNA capping in coronaviruses through a GDP-polyribonucleotidyltransferase reaction, with RNA covalently linked to nsp9. GDP is the preferred substrate for this reaction, but the NiRAN domain can also utilize GTP to produce an authentic 5 ' RNA cap structure, though the GTP-mediated mechanism is unclear. Yan and colleagues claimed to have delineated the reaction mechanism from the analysis of a cryoelectron microscopy (cryo-EM) structure of a trapped catalytic intermediate of the SARS-CoV-2 NiRAN domain with a beta-gamma-non-hydrolyzable GTP analog (GMPPNP) and RNA-nsp9 (PDB: 8GWE). We show that the cryo-EM data used to derive PDB: 8GWE do not support the presence of GMPPNP in the NiRAN active site, and the resulting atomic model is incompatible with fundamental chemical principles. We conclude that Yan and colleagues' conclusions are not experimentally supported and the mechanism for GTP-mediated RNA capping by the SARS-CoV-2 NiRAN domain remains unresolved. This Matters Arising paper is in response to Yan et al. (2022), published in Cell. See also the response by Huang et al. (2025), published in this issue.

Spatial refugia offered by structurally complex habitats mitigate high rates of predation for many aquatic and terrestrial prey species. These refuges are particularly important for small juvenile marine invertebrates, for which predation often represents the greatest cause of mortality. When the availability or quality of habitat landscapes and refugia are diminished by natural or anthropogenic forces, prey populations face further risk. In this study, we examined the utilization of alternative types of submerged aquatic vegetation (SAV) by juvenile bay scallops, Argopecten irradians, in a system where their historical habitat of eelgrass, Zostera marina, has largely disappeared. We found that scallops settled on and remained attached, above the bottom, to 9 species of macroalgae, 6 of which were fine filamentous or fleshy red algae. Macroalgae thus serve as suitable substrates for scallop larval settlement and early juvenile life, clearly important to successful population rebuilding that occurred following commencement of our restoration efforts. However, the much smaller maximum observed size (2-9 mm) and calculated duration of attachment (5-27 days) of scallops in the canopy of red macroalgae were considerably lower than those previously reported for eelgrass and the green macroalgae Codium fragile. With scallops dropping sooner to the bottom from red macroalgae, at smaller sizes, they are accessible to greater numbers of predator species/sizes and higher rates of predation (as shown in supporting laboratory experiments). Furthermore, this transition occurs well before scallops have undergone an ontogenetic shift to evasive swimming or have grown to reach a refuge in larger size. Fine filamentous red macroalgae, in which juvenile scallops demonstrated the highest frequency of attachment in this study and among the shortest duration in the canopy, now predominate in many areas of the Peconic Bays, New York, where eelgrass was formerly widespread. This apparent habitat degradation/replacement is thus acting to compress the length of time scallops are able to utilize a spatial refuge from predation at a critical life history stage, with potential cascading ontogenetic impacts on the use of a subsequent behavioral refuge and possible negative demographic consequences. Few prior studies have revealed such clear impacts of this kind resulting from habitat loss.

The Christchurch mutation (R136S) in the APOE3 (E3S/S) gene is associated with attenuated tau load and cognitive decline despite the presence of a causal PSEN1 mutation and high amyloid burden in the carrier. However, the molecular mechanisms enabling the E3S/S mutation to mitigate tau-induced neurodegeneration remain unclear. Here, we replaced mouse Apoe with wild-type human APOE3 or APOE3S/S on a tauopathy background. The R136S mutation decreased tau load and protected against tau-induced synaptic loss, myelin loss, and reduction in hippocampal theta and gamma power. Additionally, the R136S mutation reduced interferon responses to tau pathology in both mouse and human microglia, suppressing cGAS-STING pathway activation. Treating E3 tauopathy mice with a cGAS inhibitor protected against tau-induced synaptic loss and induced transcriptomic alterations similar to the R136S mutation across brain cell types. Thus, suppression of the microglial cGAS-STING-interferon (IFN) pathway plays a central role in mediating the protective effects of R136S against tauopathy.

The original 100.3 Mb reference genome for Caenorhabditis elegans, generated from the wild-type laboratory strain N2, has been crucial for analysis of C. elegans since 1998 and has been considered complete since 2005. Unexpectedly, this long-standing reference was shown to be incomplete in 2019 by a genome assembly from the N2-derived strain VC2010. Moreover, genetically divergent versions of N2 have arisen over decades of research and hindered reproducibility of C. elegans genetics and genomics. Here we provide a 106.4 Mb gap-free, telomere-to-telomere genome assembly of C. elegans, generated from CGC1, an isogenic derivative of the N2 strain. We use improved long-read sequencing and manual assembly of 43 recalcitrant genomic regions to overcome deficiencies of prior N2 and VC2010 assemblies and to assemble tandem repeat loci, including a 772 kb sequence for the 45S rRNA genes. Although many differences from earlier assemblies come from repeat regions, unique additions to the genome are also found. Of 19,972 protein-coding genes in the N2 assembly, 19,790 (99.1%) encode products that are unchanged in the CGC1 assembly. The CGC1 assembly also may encode 183 new protein-coding and 163 new ncRNA genes. CGC1 thus provides both a completely defined reference genome and corresponding isogenic wild-type strain for C. elegans, allowing unique opportunities for model and systems biology.