We introduce a high-affinity split-HaloTag comprised of a short peptide tag (Hpep, 14 residues) and a large, inactive fragment (cpHaloΔ3). Hpep binds to cpHaloΔ3 spontaneously with nanomolar affinity, enabling subsequent labeling with fluorescent HaloTag ligands. The small size of Hpep facilitates cloning-free endogenous protein tagging using CRISPR/Cas9 and the complementation of Hpep-tagged proteins can be achieved in live cells through co-expression with cpHaloΔ3 and in fixed cells through incubation with cpHaloΔ3. The approach is compatible with advanced microscopy techniques such as expansion microscopy and live-cell STED imaging. Additionally, variants of Hpep that modulate the spectral properties of labeled fluorophores enable simultaneous imaging of two different Hpep-tagged proteins via fluorescence lifetime microscopy. In summary, our high-affinity split-HaloTag is a robust and versatile tool for live-cell imaging and diverse applications in chemical biology.

Parkinson’s disease (PD) is a progressive neurodegenerative disorder characterised by the loss of dopaminergic neurons, driven by complex molecular mechanisms that are not fully understood. To address this issue, we have developed a novel high-content phenotypic screening platform using human induced pluripotent stem cell-derived dopaminergic neurons to investigate the PINK1-PARKIN mitophagy pathway, a critical process in PD pathogenesis. Utilising high throughput, 384 well arrayed CRISPR-CAS9 genetic manipulation and high-content immunofluorescence imaging complemented with machine learning analysis, we examined ubiquitin (Ub) pSer65 levels. Ub pSer65, a potential PD clinical biomarker, is a key marker of mitophagy initiation in dopaminergic neurons upon mitophagy initiation using exogenous stimuli to mimic the disease relevant environment. The CRISPR-CAS9 knockout (KO) screen revealed two distinct phenotypic classes: essential genes causing cell death upon deletion, and genes modulating Ub pSer65 levels. Notably, KO of PINK1, PARKIN , and TOM7 genes decreased Ub pSer65 upregulation during mitophagy activation, confirming their established roles in the pathway and validating the suitability of the platform for target identification. This innovative platform provides a precise tool to further interrogate PD-associated genes, offering insights into mitophagy-related pathogenic mechanisms and identification of potential therapeutic targets. By bridging functional genomics with disease-specific neuronal models, this approach presents a promising strategy for advancing PD research and developing targeted interventions. To our knowledge, this is the first reported use of a human, translationally relevant cell model to study genetic perturbation within a disease relevant phenotype.

GBA1 is a risk gene for multiple neurodegenerative diseases, including Lewy Body Dementia and Parkinson’s disease, and biallelic pathogenic variants in the gene result in the lysosomal storage disorder Gaucher disease. GBA1 encodes the enzyme glucocerebrosidase (GCase), and alterations in the gene result in reduced enzymatic activity, which affects lysosome function downstream. Induced pluripotent stem cells (iPSCs) are a useful tool for testing the functional consequences of gene variants in an isogenic setting. Additionally, they can be used to perform multiomic studies to explore biological effects independent of disease mechanisms. Using CRISPR-edited isogenic KOLF2.1J iPSC lines containing pathogenic GBA1 variants D409H (p.D448H), D409V (p.D448V) and GBA1 knockout line generated by the iPSC Neurodegenerative Disease Initiative (iNDI), we examined potential molecular mechanisms and downstream consequences of GCase reduction. In this study, we confirm that this isogenic series behaves as expected for loss of function variants, despite the known difficulties with GBA1 editing. We identified that there are limited overlapping results across cell types suggesting potential different downstream effects caused by GBA1 variants. Additionally, we note that RNA-based quantitation may not be the best method to characterize GCase mechanisms, but protein and metabolomic analyses may be used to evaluate differences across genotypes.

The Spindle Assembly Checkpoint (SAC) plays critical roles in regulating mitotic fidelity and progression. Here, we utilized a SAC-deficient cell line lacking the full-length Cdc20 translational protein isoform (Cdc20 ΔFL) to define its differential genetic interactions using CRISPR/Cas9-based gene targeting. Cdc20 ΔFL cells display synthetic lethal relationships with gene targets required for proper chromosome segregation, highlighting the critical role of the SAC in error surveillance. Surprisingly, we found that the checkpoint component Mad2 becomes dispensable for viability in Cdc20 ΔFL cells. Prior work suggested that Mad2 acts as an essential mitotic “timer” to control mitotic duration in unperturbed cells. Instead, our functional analysis indicates that the mitotic timer depends on the interdependent and overlapping actions of: (1) Mad2 inhibition of APC/C-Cdc20, (2) Cdk1-mediated phosphorylation of Cdc20, and (3) total Cdc20 protein levels. Simultaneously perturbing these pathways results in near immediate mitotic exit and catastrophic chromosome mis-segregation.

ABSTRACT Delivery of gene therapy vectors targeted to any somatic cell remains a key barrier for the development of genetic medicines. While rodent models provide insights into vector biodistribution and cellular tropism, their anatomical and physiological differences from humans limit their translational potential and studies in large animal models are often required. In this study, we developed a swine reporter model (SRM-1) to evaluate both viral and nonviral vector delivery in a large animal system. The SRM-1 model harbors a Cre- and CRISPR-activated tdTomato reporter at the Rosa26 locus that allows for tracing of cell-specific delivery and expression of gene therapy vectors in vivo . To evaluate this model, we administered adeno-associated virus serotype 9 (AAV9) and lipid nanoparticles (LNPs) carrying mRNA systemically and found successful in vivo reporter activation across a variety of tissues. Intracerebroventricular (ICV) administration of LNP-Cre mRNA was also performed and demonstrated localized activation in cortical brain cells. In addition to biodistribution studies, this model has utility for testing safety and clinically relevant administration methods, surgical and non-surgical, of delivery vectors. Our findings support the SRM-1 model as a valuable tool for advancing gene therapies from preclinical testing to clinical application.

ABSTRACT RNA-based vaccines offer a superior efficacious and economic approach over traditional vaccines. However, current dose requirement and short half-life of conventional modified mRNA (modRNA) may hinder the development of more effective vaccines. Self-amplifying mRNA (saRNA) is a modality that has the potential to address these limitations by reducing delivery dosage and enhancing the duration of expression over modRNA. Despite marked success in preclinical studies, saRNA vaccines have thus far underperformed in most clinical trials. We hypothesized that non-optimal human cellular context limits saRNA expression, and that elucidating the factors underlying saRNA expression would be key in developing saRNA as a viable therapeutic modality. To identify factors involved in the regulation of saRNA, we performed a quasi-genome-wide CRISPR knockout screen, which revealed that saRNA expression in human cells is linked to mitochondrial function and governed by ACSL4. We validated these findings through pharmacological intervention and single gene editing, demonstrating that ACSL4-mediated regulation is unique to saRNA and does not impact modRNA. Moreover, we show that modulating ACSL4 leads to improved saRNA expression across multiple cell types. We demonstrate for the first time that mitochondrial function and ACSL4 play key roles in saRNA expression, providing insight for the development and implementation of saRNA as a therapeutic modality.

Genome-wide CRISPR-Cas9 knockout screens is often used to evaluate gene functions experimentally. Nevertheless, the efficacy of individual sgRNAs that target unique gene varies and is hard to integrate. In this study, tensor decomposition (TD) was used to integrate multiple sgRNAs as well as sgRNA profiles simultaneously. As a result, TD can discriminate between essential and non-essential genes with the competitive performances of one of SOTA, JACKS, which previously outperformed various SOTA. In addition to this, in spite of that TD is nothing but the simple linear algebra, TD can achieve the performance even without control samples without which JACKS even cannot be performed. Moreover, since raw and logarithmic values can achieve the similar performances through TD for the largest dataset among those tested, taking logarithmic values as has been done frequently is questioned. In conclusion, TD is the ever first method that can integrate multiple sgRNAs and profiles simultaneously and can achieve comparative performances with JACKS, one of SOTA.

Mapping protein–protein interactions (PPIs) in living systems is critical for understanding dynamic biological processes. While proximity-labeling enzymes like LOV-TurboID and APEX2 are widely used, their dependence on external light, reactive chemicals, or large fusion domains limits in vivo applications, especially in deep tissues. Here, we introduce LucID (Light-free Unifying Catalytic Integrated Domain) – a compact, self-contained proximity-labeling system that functions independently of light or external ROS. LucID was engineered by embedding a minimal catalytic motif derived from TurboID into a NanoLuc scaffold, preserving bioluminescence while enabling spatially confined biotinylation. Upon luciferin addition, LucID leverages BRET (bioluminescence resonance energy transfer) to uncage the catalytic site and activate biotin transfer. With a molecular weight of approximately 23.7 kDa (40% smaller than TurboID), LucID is optimized for delivery via mRNA-LNP platforms. Its modularity and light-independent activation make it a unique tool for real-time interactome mapping in live cells and deep tissues. LucID introduces a new paradigm in proximity labeling: compact, luminescent, and chemically programmable. By integrating catalytic motifs into a light-producing scaffold, LucID enables temporally precise, spatially confined interactome mapping in challenging biological contexts. This innovation holds promise for single-cell proteomics, in vivo interaction studies, and next-generation bioimaging tools. Graphical Abstract | LucID enables light-free, ultra-compact biotinylation via BRET-triggered ROS uncaging LucID is a next-generation proximity labeling tool that combines NanoLuc bioluminescence, engineered TurboID motifs, and a ROS-cleavable thioketal cage to perform spatially precise biotinylation without external light. Upon luciferin addition, BRET triggers localized ROS generation, rapidly cleaving the cage (2.4–3.6 ns) and activating the catalytic site. This compact, self-contained platform enables deep-tissue labeling with high temporal control, making it ideal for in vivo proteomics, CRISPR fusions, and light-inaccessible systems.LucID is a next-generation proximity labeling tool that combines NanoLuc bioluminescence, engineered TurboID motifs, and a ROS-cleavable thioketal cage to perform spatially precise biotinylation without external light. Upon luciferin addition, BRET triggers localized ROS generation, rapidly cleaving the cage (2.4–3.6 ns) and activating the catalytic site. This compact, self-contained platform enables deep-tissue labeling with high temporal control, making it ideal for in vivo proteomics, CRISPR fusions, and light-inaccessible systems.

In Drosophila melanogaster females, as in most organisms, the segregation of meiotic chromosomes depends on the proper distribution of crossovers along paired maternal and paternal chromosomes. In most cases, crossovers require the synaptonemal complex (SC), a conserved multi-protein structure that forms between homologous chromosomes in meiotic prophase I. Recent studies leveraging hypomorphic alleles suggest that the SC plays a more direct role in the distribution of crossover events. However, identifying additional hypomorphic mutations that avoid catastrophic phenotypes by partially disrupting the SC has been challenging. Here, to create a new hypomorphic allele of the D. melanogaster SC gene corolla , we used CRISPR/Cas9 to replace it with the coding sequence of its Drosophila mauritiana ortholog, yielding corolla mau . Since the amino acid sequence of SC proteins is rapidly diverging while maintaining the general tripartite structure of the SC, we hypothesized that this replacement would enable the assembly of the SC but show defects in crossover distribution. Indeed, at 25 °C corolla mau homozygous females exhibited full-length SC with defects in SC maintenance and crossover formation, resulting in moderate levels of chromosome missegregation. At 18 °C, SC maintenance was rescued, and recombination rates were improved, although they remained significantly lower than observed in wild type. Importantly, these phenotypes are less severe than observed in corolla null mutant flies, suggesting corolla mau is a hypomorphic allele. Unexpectedly, in homozygotes we also observed unique polycomplexes composed of the SC proteins Corolla and Corona but lacking the transverse filament protein C(3)G. Overall, we report a novel hypomorphic allele of corolla that will enable future studies on the role of the SC in crossover distribution. Further, the unique polycomplexes found in mutant flies may provide new insights into SC protein-protein interactions and SC architecture. Author Summary In many species, the success of sexual reproduction relies on a protein structure called the synaptonemal complex (SC). The SC forms between the maternal and paternal copies of chromosomes and functions to ensure crossing over. Most prior studies have used SC mutants that have grave defects, preventing the study of nuances in SC function. Here, we replace one of the SC genes in Drosophila melanogaster with the ortholog of a close relative, creating a new allele that displays a partial loss-of-function phenotype. At the standard rearing temperature, flies homozygous for this allele exhibit SC maintenance defects, a reduced number of crossover events, and aberrant chromosome segregation. In flies reared at a lower temperature, SC maintenance is rescued but the defects in recombination and chromosome segregation persist. We also found a unique SC protein aggregate in these flies. Altogether, this new mutant reflects a novel approach to study the structure and function of the SC.

CRISPR screening is a powerful approach to identify genetic perturbations that impact viral infection. However, most virus-focused CRISPR screens utilize selection strategies that limit the ability to identify genes important for infection. Here, we developed a novel CRISPR screening pipeline to identify cellular determinants of Human Cytomegalovirus infection based on virally induced remodeling of cellular antibody affinity (VIRCAA), which is scalable for large libraries and can identify cellular genes that impact HCMV infection at different life cycle stages. We utilized this pipeline to interrogate proteomic and transcriptomic data sets associated with the HCMV UL26 protein, which blocks anti-viral signaling during infection. We find that JUNB drives anti-viral gene expression, induces protein ISGylation, and suppresses diverse viral infections. Further, UL26 proximally interacts with JUNB and suppresses JUNB’s nuclear condensation and JUNB-mediated contraction of viral DNA replication compartments. These results highlight the VIRCAA pipeline’s utility for identifying important determinants of viral infection.

ABSTRACT Hyperactive enzymes drive the pathology of several diseases, and classically, “occupancy-driven” drugs (e.g., active site or allosteric inhibitors) are used to target these enzymes. However, the stoichiometric nature of such inhibitors and the emergence of resistance highlight the need for new modalities. Here, we report a Phosphorylation-Inducing Chimeric Small molecule (PHICS) that rewires the hyperactivity of an oncogenic kinase, BCR-ABL, to phosphorylate its active site residue. Molecular dynamics simulations suggest this phosphorylation inhibits BCR-ABL by inducing electrostatic rearrangements of its active site. This “event-driven” mechanism selectively induces apoptosis of BCR-ABL-dependent cancer cells at substoichiometric concentrations (vs. stoichiometric concentrations of occupancy-driven drugs). Furthermore, PHICS is effective on other oncogenic ABL fusions or clinically observed resistance mutations, including to occupancy-driven drugs with the same binding site as PHICS, pointing to the orthogonality of their resistance mechanisms. These studies lay the foundation for electric-field and “event-driven” modalities to control hyperactive enzymes with orthogonal resistance mechanisms to occupancy-driven modalities.

Interactions between microbes and their mobile genetic elements (MGEs), including viruses and plasmids, are critical drivers of microbiome structures and processes. CRISPR-Cas systems are known to be important regulators of these host-MGE interactions, but a global understanding of CRISPR-Cas diversity, activity, and roles across Earth’s biomes is still lacking. Here, we use an optimized computational approach to search short-read data and collect ∼800 million CRISPR spacers across ∼450,000 public metagenomes. Comparing spacers across samples and taxa revealed a high population diversity for CRISPR loci overall, with typically only a small subset of spacers detected as prevalent and conserved within a microbial population. From this extensive CRISPR spacer dataset, we identified 1.18 billion hits between 41 million spacers and 2.5 million viruses and plasmids. Prevalent and conserved spacers were over-represented in these MGE-matching spacers, and CRISPR spacers frequently matched multiple MGEs, consistent with a positive selection pressure associated with MGE targeting. Focusing on the role of CRISPR as anti-phage defense, we observed surprising cases of viruses targeted by microbes not expected to be viable hosts. These were more frequent for viruses encoding a diversification mechanism (DGR) for their host attachment proteins, and associated with a reduced rate of escape mutations. This suggests that broad spacer targeting may derive from the recurring entry of a virus genome into a non-host microbial cell, leading to some viruses being targeted by taxonomically diverse microbes well outside of their actual host range. Taken together, this petabase-scale exploration of CRISPR arrays in nature outlines the extensive diversity of CRISPR array loci across microbiomes. It highlights several key genomic and ecological parameters driving the activity of CRISPR arrays that are likely influencing strain-level diversification and selection processes within microbial populations.

Summary CRISPR-Cas systems confer prokaryotic adaptive immunity by integrating foreign DNA (prespacers) into host arrays. Type II-A systems employ Cas9 for protospacer adjacent motif (PAM) recognition and coordinate with Csn2 and the Cas1-Cas2 integrase during spacer acquisition, yet their structural basis remains unresolved. Here, we report cryo-EM structures of the Enterococcus faecalis Cas9-Csn2-Cas1-Cas2 supercomplex in apo and DNA-bound states. The apo-state structure (Cas9 2 -Csn2 8 -Cas1 8 -Cas2 4 ) adopts a resting conformation, with Cas9 locked in a nuclease-inactive state and Cas1-Cas2 sterically blocked from prespacer loading. Upon DNA engagement, Cas9 undergoes a conformational transition, forming a prespacer catching complex that threads the DNA through Csn2’s central channel. This architecture enables Cas9 to interrogate the PAM sequence while sliding along the DNA, with Cas9 and Csn2 jointly define a 30-bp DNA segment which matches the prespacer length. Subsequent dissociation of Cas9 triggers a structural reconfiguration of the Csn2-Cas1-Cas2 assembly. The PAM-proximal DNA becomes accessible, and Cas1-Cas2 relocates to bind to the exposed DNA, enabling further prespacer processing and directional integration. These findings reveal how Cas9 collaborates with Csn2 and Cas1-Cas2 to couple PAM recognition with prespacer selection, resolving the dynamic structural transitions that ensure fidelity during type II-A CRISPR adaptation.

SUMMARY During CRISPR-Cas adaptation, prokaryotic cells become immunized by the insertion of foreign DNA fragments, termed spacers, into the host genome to serve as templates for RNA-guided immunity. Spacer acquisition relies on the Cas1-Cas2 integrase and accessory proteins like Cas4, which select DNA sequences flanked by the protospacer adjacent motif (PAM) and insert them into the CRISPR array. It has been shown that in type II-A systems selection of PAM-proximal prespacers is mediated by the effector nuclease Cas9, which forms a ‘supercomplex’ with the Cas1-Cas2 integrase and the Csn2 protein. However, the supercomplex structure and the role of the ring-like Csn2 protein remain unknown. Here, we present cryo-electron microscopy structures of the type II-A prespacer selection supercomplex in the DNA-scanning and two different PAM-bound configurations. Our study uncovers the mechanism of Cas9-mediated prespacer selection in type II-A CRISPR-Cas systems, and reveals the role of the accessory protein Csn2, which serves as a platform for the assembly of Cas9 and Cas1-Cas2 integrase on prespacer DNA, reminiscent of the sliding clamp in DNA replication. Repurposing of Cas9 by the CRISPR adaptation machinery for prespacer selection characterized here demonstrates Cas9 plasticity and expands our knowledge of the Cas9 biology.

Tuberculosis, caused by Mycobacterium tuberculosis (Mtb), remains a leading cause of mortality worldwide. Proteins involved in lipid metabolism, such as the monoacylglycerol lipase Rv0183, play critical roles during both the active and dormant phases of Mtb and present novel targets for therapeutic intervention. Through high-throughput screening at the European Lead Factory, we identified a novel chemotype characterized by a hydroxypyrrolidine ring, which demonstrated potent inhibition of Rv0183 and promising results in whole cell bacterial studies. Subsequent co-crystallization studies of this chemotype with Rv0183 revealed non-covalent interactions within the lipase’s binding pocket, elucidating the inhibitory mechanism. Comparative analysis, augmented by AI-driven 3D-point-cloud approaches, distinguished Rv0183’s ligand-binding cavity from that of human monoacylglycerol lipase, implying the possibility for species-selective inhibition. This selectivity was further supported by molecular docking simulations which validated the experimental binding affinities and predicted strong, specific binding modes. Our study presents not only the structural basis for the inhibition of Rv0183 by these novel hydroxypyrrolidine-based inhibitors but also demonstrates the utility of integrating computational and empirical methods to achieve species-specific targeting. This approach could minimize off-target effects in humans, marking a significant step toward developing more effective antitubercular therapies. The potential to selectively inhibit Mtb in its dormant state could lead to treatments that prevent the persistence and resurgence of the disease, addressing a crucial gap in the fight against tuberculosis.

Multi-omics technologies allow for a detailed characterization of cell types and states across multiple omics layers, helping to identify features that differentiate biological conditions, such as chemical or CRISPR-based perturbations. However, current tools employing variational inference on single-cell datasets, including methods for paired and mosaic integration, transfer learning, and modality imputation, typically act as black boxes. This lack of interpretability makes it challenging to evaluate whether biological variation is preserved, which can compromise downstream analyses. Here, we introduce NetworkVI, a sparse deep generative model designed for the integration and interpretation of multimodal single-cell data. NetworkVI utilizes biological prior knowledge as an inductive bias, specifically it relies on gene-gene interactions inferred from topologically associated domains and structured ontologies like the Gene Ontology to aggregate gene embeddings to cell embeddings, enhancing the interpretability at the gene and subcellular level. While achieving state-of-the-art data integration, modality imputation, and cell label transfer via query-to-reference mapping benchmarks across bimodal and trimodal datasets, NetworkVI additionally excels in providing biologically meaningful modality- and cell type-specific interpretations. NetworkVI aids researchers in identifying associations between genes and biological processes and uncovers immune evasion mechanisms in a Perturb CITE-seq dataset of melanoma cells. NetworkVI will support researchers in interpreting cellular disease mechanisms, guiding biomarker discovery, and ultimately aiding the development of targeted therapies in large-scale single-cell multimodal atlases. NetworkVI is available at http://github.com/LArnoldt/networkVI .

Bacterial pathogens commonly become drug resistant via horizontal acquisition of antimicrobial resistance genes (ARGs), which are often encoded on mobile genetic elements (MGEs). Although bacterial defence systems are typically considered barriers to horizontal gene transfer (HGT), previous studies revealed that bacteria with more restriction-modification (RM) systems (the most abundant bacterial defences) frequently carry more MGEs. It was suggested that this counterintuitive relationship might result from stronger selection for RM systems when exposure to costly MGEs increases. Here, we test this hypothesis using a combination of modelling and bioinformatics analysis of >40,000 bacterial genomes to better understand how eco-evolutionary feedbacks between selection for RM and acquisition of MGEs shape bacterial genome evolution. Our model predicts negative associations between HGT and RM, but only if RM diversity is high. By contrast, at low RM diversity, eco-evolutionary feedbacks drive the emergence of positive associations between HGT and RM. Consistent with these predictions, we identified negative relationships between acquired ARG counts and RM counts across species but positive relationships within individual species. Collectively, our work helps to understand how RM systems shape patterns of HGT of ARGs, which may offer opportunities for targeted surveillance of strains at higher risk of horizontally acquiring novel drug resistance alleles.

SUMMARY Cas1 and Cas2 are the hallmark proteins of prokaryotic adaptive immunity. However, these two proteins are often fused to other proteins and the functional association of these fusions often remain poorly understood. Here we purify Cas1 and the Cas2/3 fusion protein from Pseudomonas aeruginosa . We determine multiple structures of the Cas1-2/3 complex at distinct stages of CRISPR adaptation. Collectively, these structures reveal a prominent, positively charged channel on one face of the integration complex that captures short fragments of foreign DNA. Foreign DNA binding triggers conformational changes in Cas2/3 that expose new DNA binding surfaces necessary for homing the DNA-bound integrase to specific CRISPR loci. The length of the foreign DNA substrate determines if Cas1-2/3 docks completely onto the CRISPR repeat to successfully catalyze two sequential transesterification reactions required for integration. Taken together, these structures clarify how the Cas1-2/3 proteins orchestrate foreign DNA capture, site-specific delivery, and integration of new DNA into the bacterial genome. GRAPHICAL ABSTRACT HIGHLIGHTS - A positively charged channel on the Cas1-2/3 complex captures fragments of DNA - A loop in the RecA1 domain controls access to the Cas3 nuclease active site - Foreign DNA binding allosterically regulates access to additional DNA binding sites - Distortion of the CRISPR repeat sequence licenses complete foreign DNA integration

In Parkinson’s disease and other synucleinopathies, α-synuclein (α-Syn) misfolds and forms Ser 129 – phosphorylated aggregates (pSyn 129 ). The factors controlling this process are largely unknown. Here, we used arrayed CRISPR-mediated gene activation and ablation to discover new pSyn 129 modulators. Using quadruple-guide RNAs (qgRNAs) and Cas9, or an inactive Cas9 version fused to a synthetic transactivator, we ablated 2304 and activated 2428 human genes related to mitochondrial, trafficking and motility function in HEK293 cells. After exposure of cells to α-Syn fibrils, pSyn 129 signals were recorded by high-throughput fluorescent microscopy and aggregates were identified by image analysis. We found that pSyn 129 was increased by activating the mitochondrial protein OXR1, which decreased ATP levels and altered the mitochondrial membrane potential. Instead, pSyn 129 was reduced by ablation of the endoplasmic reticulum (ER)-associated protein EMC4, which enhanced ER-driven autophagic flux and lysosomal clearance. OXR1 activation preferentially modulated cellular reactions to fibrils derived from multiple system atrophy (MSA) patients, whereas EMC4 ablation broadly reduced pSyn 129 across diverse α-Syn polymorphs. These findings were confirmed in human iPSC-derived cortical and dopaminergic neurons, where OXR1 preferentially promoted somatic aggregation and EMC4 reduced both somatic and neuritic aggregates. These results uncover previously unrecognized roles for OXR1 and EMC4 in α-Syn aggregation, thereby broadening our mechanistic understanding of synucleinopathies.

Protein tyrosine kinases activate signaling pathways by catalyzing the phosphorylation of tyrosine residues in their substrates. Mounting evidence suggests that, in addition to recognizing phosphorylated tyrosine (pTyr) residues through specific phosphobinding modules, many protein kinases selectively recognize pTyr directly adjacent to the tyrosine residue they phosphorylate and catalyze the formation of twin pTyr-pTyr sites. Here, we demonstrate the importance of this phosphopriming-driven twin pTyr signaling in promoting cell cycle progression through the cell cycle-inhibitory protein p27 Kip1 . We identify, structurally resolve, and tune two distinct molecular determinants driving the selective recognition of pTyr directly N- and C-terminal to the target phospho-acceptor tyrosine site. We further show structural and biochemical conservation in this recognition, and identify cancer-associated alterations to these determinants that are unable to recognize phosphoprimed substrates. Finally, using an in vivo mouse model of leukemia we show that Bcr-Abl mutants unable to recognize phosphoprimed substrates paradoxically result in enhanced tumor development and progression. These data indicate that Bcr-Abl, like other proto-oncogenes such as Ras or Myc, engages both pro- and anti-oncogenic programs – but in the case of Bcr-Abl, this is accomplished through a mechanism involving traditional and phosphoprimed substrate recognition.

Single-guide RNA lentiviral infection with Cas9 protein electroporation (SLICE) enables CRISPR screening in primary cell types that require transient Cas9 expression yet is limited by scalability and robustness. Here, we introduce dual-guide RNA infection with Cas9 electroporation (DICE), which expresses two guides from the same lentiviral construct that target the same gene. In genome-wide screens, DICE outperformed SLICE in defining essential genes and modulators of PD-L1 expression in IFN gamma activated THP1 cells. Collectively, these data demonstrate that DICE can be utilized for reduced-scale CRISPR screens in cell types with transient Cas9 protein expression without sacrificing screening quality.

ABSTRACT Bacterial transcription initiation is a tightly regulated process that canonically relies on sequence-specific promoter recognition by dedicated sigma (σ) factors, leading to functional DNA engagement by RNA polymerase (RNAP) 1 . Although the seven σ factors in E. coli have been extensively characterized 2 , Bacteroidetes species encode dozens of specialized, extracytoplasmic function σ factors (σ E ) whose precise roles are unknown, pointing to additional layers of regulatory potential 3 . Here we uncover an unprecedented mechanism of RNA-guided gene activation involving the coordinated action of σ E factor in complex with nuclease-dead Cas12f (dCas12f). We screened a large set of genetically-linked dCas12f and σ E homologs in E. coli using RIP-seq and ChIP-seq experiments, revealing systems that exhibited robust guide RNA enrichment and DNA target binding with a minimal 5ʹ-G target-adjacent motif (TAM). Recruitment of σ E was dependent on dCas12f and guide RNA (gRNA), suggesting direct protein-protein interactions, and co-expression experiments demonstrated that the dCas12f-gRNA-σ E ternary complex was competent for programmable recruitment of the RNAP holoenzyme. Remarkably, dCas12f-RNA-σ E complexes drove potent gene expression in the absence of any requisite promoter motifs, with de novo transcription start sites defined exclusively by the relative distance from the dCas12f-mediated R-loop. Our findings highlight a new paradigm of RNA-guided transcription (RGT) that embodies natural features reminiscent of CRISPRa technology developed by humans 4,5 .

ABSTRACT RNA-guided proteins have emerged as critical transcriptional regulators in both natural and engineered biological systems by modulating RNA polymerase (RNAP) and its associated factors 1-5 . In bacteria, diverse clades of repurposed TnpB and CRISPR-associated proteins repress gene expression by blocking transcription initiation or elongation, enabling non-canonical modes of regulatory control and adaptive immunity 1,6,7 . Intriguingly, a distinct class of nuclease-dead Cas12f homologs (dCas12f) instead activates gene expression through its association with unique extracytoplasmic function sigma factors (σ E ) 8 , though the molecular basis has remained elusive. Here we reveal a novel mode of RNA-guided transcription initiation by determining cryo-electron microscopy structures of the dCas12f-σ E system from Flagellimonas taeanensis . We captured multiple conformational and compositional states, including the DNA-bound dCas12f-σ E -RNAP holoenzyme complex, revealing how RNA-guided DNA binding leads to σ E -RNAP recruitment and nascent mRNA synthesis at a precisely defined distance downstream of the R-loop. Rather than following the classical paradigm of σ E -dependent promoter recognition, these studies show that recognition of the −35 element is largely supplanted by CRISPR-Cas targeting, while the melted −10 element is stabilized through unusual stacking interactions rather than insertion into the typical recognition pocket. Collectively, this work provides high-resolution insights into an unexpected mechanism of RNA-guided transcription, expanding our understanding of bacterial gene regulation and opening new avenues for programmable transcriptional control.

ABSTRACT Oxytocin receptors (OTR) within the extended amygdala and nucleus accumbens have been implicated in modulating social behaviors, particularly following stress. The effects of OTR could be mediated by modulating the activity of pre-synaptic axon terminals or via post-synaptic neurons or glia. Using a viral-mediated CRISPR/Cas9 gene editing system in California mice ( Peromyscus californicus ), we selectively knocked down OTR in the anteromedial bed nucleus of the stria terminalis (BNST) or the nucleus accumbens (NAc) to examine their roles modulating social approach and vigilance behaviors. Knockdown of OTR in the BNST attenuated stress-induced decreases of social approach and increases of social vigilance behaviors in adult female California mice, similar to prior pharmacological studies. These effects were more prominent in the large arena social interaction where mice could control proximity to a social target with a barrier (wire cage). In a small arena interaction test where focal mice freely interacted with target mice, effects of BNST OTR knockdown were muted. This suggests that within the BNST OTR are more important for modulating behavioral responses to more distal stimuli versus more proximal social contexts. In mice with OTR knockdown in the NAc, few behavioral changes were observed which is consistent with previous findings of the importance of presynaptic OTR, which were unaffected by our gene editing strategy, driving social approach behaviors in the NAc. Interestingly, BNST OTR knockdown increased exploratory behavior toward a non-social stimulus after stress, pointing to a potentially broader role for BNST OTR function. Our findings highlight the region- and context-specific functions of OTR in social behavior and the advantages of using a selective gene-editing tool to dissect the neural circuits that influence social and stress-related responses.

Abstract The fall armyworm (FAW), Spodoptera frugiperda , is an invasive and polyphagous pest that has become a major threat to tropical crops due to its rapid dissemination, broad host range, and increasing insecticide resistance. This research approaches the molecular basis of resistance by combining comparative transcriptomics with RNA interference (RNAi) to discover and functionally validate critical detoxification genes. We identified significant up-regulation of cytochrome P450 monooxygenases (CYP321A1 and CYP9A4), glutathione S-transferases (GSTE6 and GSTE2) and carboxylesterase (CCE2) in resistant populations. Suppression of these genes through RNAi resulted in greater susceptibility to insecticides and lower larval survival. Delivery of the chitosan nanoparticle using dsRNA also improved stability and knockdown in a field context. Phylogenetic analysis revealed that these resistance genes are well conserved among the most important lepidopteran pests, indicating potential for a broader efficacy of RNAi as a pest management strategy. It may establish RNAi- and CRISPR-based molecular biocontrol systems in tropical IPMs, with significant benefits for sustainable agriculture and biodiversity conservation.