The rockefeller university

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.

Nguni sheep (Ovis aries) are indigenous to the Southern Africa region and common within the smallholder and poor resources farming systems. They are well adapted to different agroecological regions. However, limited genomic resources such as high-quality reference genomes have hindered our understanding of its adaptation and establishment of an effective breeding program. To address this, we assembled a chromosomal-level genome of Nguni sheep using a combination of PacBio HiFi reads and Omni-C reads. The genome size was estimated to be 2.9 Gb with a contig/scaffold N50 74 Mb and 99.6 Mb and a genome completeness of 96.1%, as estimated by the Benchmarking Universal Single-Copy Orthologs (BUSCO) program. The final genome encompassed a total of 25,926 protein-coding genes. The findings of this study provide a valuable genomic resource for understanding the adaptability of the Nguni sheep and the establishment of effective breeding programs.

Hearing hinges upon the ear's ability to enhance its responsiveness by means of an energy-expending active process that amplifies the very mechanical inputs that it detects. This process is defined by four properties that, although seemingly unrelated, consistently occur together: amplification, sharp frequency tuning, compressive nonlinearity, and spontaneous otoacoustic emission. In nonmammal tetrapods, the active process is evident in individual hair cells. The hair bundles of the bullfrog, for example, exhibit all four attributes by operating near a Hopf bifurcation-a critical regime in which these properties naturally coalesce. In mammals, however, the delicate nature of the cochlea has restricted the evidence for an active process to studies in vivo, where it is generally attributed to the collective effort of the outer hair cells that energize the traveling wave along the cochlear spiral. As a result, the cellular mechanisms that underlie the properties of mammalian hearing remain contested, with uncertainty about whether criticality plays a role in the cochlea's active process. Here we show that, when placed in a recording chamber that closely mimics the in vivo physiological environment, a segment of the mammalian cochlea ex vivo displays the features of the active process-amplification, frequency tuning, compressive nonlinearity, and the generation of distortion products. We show that this process operates locally, independently of traveling waves, and that the sensory epithelium achieves active amplification by operating near criticality at a Hopf bifurcation. The results reveal the existence of a unified biophysical principle that underlies auditory processing across species and even phyla.

Type 2 immunity is orchestrated by IL-4 and IL-13 signaling, initiated by binding to receptors that are specific to each cytokine or to the shared heterodimeric receptor comprising the IL-4R alpha and IL-13R alpha 1 subunits. Here, we report that sexually dimorphic IL13RA1 transcription is regulated by estrogen and characterize an IL-13R alpha 1 isoform (referred to here as IL-13R alpha 1-LOR1a) created through facultative splicing to an alternative terminal exon composed of primate-specific retrotransposable elements (RTEs). At the mRNA level, RTE exonization replaces regulatory sequences in the canonical 3 ' untranslated region (3 ' UTR) implicated in IL13RA1 mRNA stability. Moreover, alternative splicing removes critical domains in the cytoplasmic tail, rendering the IL-13R alpha 1-LOR1a isoform partially signaling defective at the protein level. When coexpressed, the IL-13R alpha 1-LOR1a isoform antagonizes the function of the canonical receptor, reducing cellular responsiveness to IL-4 and IL-13. Thus, the balance of the two IL13RA1 isoforms appears to fine-tune type 2 cytokine signaling and downstream immune responses.

Reference genomes from representative species across families provide the critical infrastructure for research and conservation. The Cetacean Genomes Project (CGP) began in early 2020 to facilitate the generation of near error-free, chromosome-resolved reference genomes for all cetacean species. Towards that goal, and using the methods, goals and genome assembly quality standards of the Vertebrate Genomes Project (VGP), we generated 13 new reference genomes across eight of the 14 cetacean families. Additionally, we summarize the genome assembly characteristics for 18 species, including these newly-generated and five published genome assemblies that meet the completeness and quality standards. We infer ancestral linkage groups (ALG) for cetaceans, showing that the ancestral karyotype of 22 ALGs is largely conserved in extant species, except for Ziphiidae, and for Balaenidae and Kogiidae, which exhibit similar independent fusions. Gene annotation, characterization of historical demography, heterozygosity and runs of homozygosity (ROH) reveal important information for conservation applications. By comparing the new reference genomes to previous draft assemblies, we show that the reference genomes have enhanced characteristics that will support and promote scientific research. Specifically, the genomes improve resolution and characterization of repetitive elements, provide validation (or exclusion) of genes linked to complex traits, and allow more complete characterization of gene regions such as the highly complex Major Histocompatibility Complex (MHC) Class I and II gene clusters that are important for population health.

Hepatic mitochondria play critical roles in sustaining systemic nutrient balance, nitrogen detoxification, and cellular bioenergetics. These functions depend on tightly regulated mitochondrial processes, including amino acid catabolism, ammonia clearance via the urea cycle, and transport through specialized solute carriers. Genetic disruptions in these pathways underlie a range of inborn errors of metabolism, often resulting in systemic toxicity and neurological dysfunction. Here, we review the physiological functions of hepatic mitochondrial amino acid metabolism, with a focus on subcellular compartmentalization, disease mechanisms, and therapeutic strategies. We discuss how emerging genetic and metabolic interventions-including dietary modulation, cofactor replacement, and gene therapy-are reshaping treatment of liver-based metabolic disorders. Understanding these pathways offers mechanistic insights into metabolic homeostasis and reveals actionable vulnerabilities in metabolic disease and cancer.