Protein knockdown using an improved auxin-inducible degron (AID2) technology has proven to be a powerful tool for studying protein function. The current approach requires the fusion of target proteins with a degron tag, a process typically achieved through CRISPR knock-in. However, knock-in remains challenging in non-model organisms and humans, limiting the broader applicability of AID2. To overcome this limitation, we developed a single-chain antibody AID2 (scAb-AID2) system. This approach employs an adaptor composed of a single-chain antibody fused with a degron, which recognises a target protein and induces rapid degradation in the presence of the inducer 5-Ph-IAA. We demonstrated that scAb-AID2, in combination with an anti-GFP nanobody, degraded GFP-fused proteins in human cells and C. elegans . Furthermore, we showed that endogenous p53 and H/K-RAS were conditionally degraded in cells expressing an adaptor encoding an anti-p53 nanobody and -RAS monobody, respectively, and led to aphidicolin sensitivity in cell culture and growth inhibition in mouse xenografts. This study paves the way for broader application of AID2-based target depletion in model and non-model organisms and for advancing therapeutic strategies.

Coding and enhancer variants of the RET receptor tyrosine kinase gene contribute to ∼50% of Hirschsprung disease (HSCR) risk, a congenital disorder of disrupted enteric nervous system (ENS) development. The greatest contribution of this risk is from a common variant (rs2435357) in an ENS-active, SOX10-bound RET enhancer (MCS+9.7) that reduces RET gene expression in vivo and triggers expression changes in other ENS genes in the human fetal gut. To uncover the cellular basis of RET -mediated aganglionosis, we used CRISPR/Cas9 to delete (Δ) the homologous mouse enhancer (mcs+9.7). We used single cell RNA sequencing and high-resolution immunofluorescence to demonstrate four significant features of the developing E14.5 gut of Δmcs+9.7/Δmcs+9.7 embryos: (1) a small (5%) yet significant reduction in Ret gene expression in only two major cell types – early differentiating neurons and fate-restricted inhibitory motor neurons; (2) no significant cellular loss in the ENS; and, (3) loss of expression of 19 cell cycle regulator genes suggesting a proliferative defect. To identify the Ret functional threshold for normal ENS development, we also generated, in combination with the Ret CFP null allele, (4) Δmcs+9.7/CFP double heterozygote mice which reduced Ret gene expression in the ENS to 42% with severe loss of inhibitory motor neurons, an effect restricted to the hindgut and driven by proliferative loss. Thus, Ret gene expression drives proliferation of ENS progenitor cells and hindgut-specific inhibitory motor neuron development, and that HSCR aganglionosis arises from a cascade of cellular defects triggered by >50% loss of Ret function.

Background Alpha-1 antitrypsin deficiency (A1ATD) is a hereditary recessive disorder caused by mutations in the SERPINA1 gene. It is a clinically under-recognised disease characterised by low circulating A1AT levels and intracellular accumulation of misfolded A1AT in hepatocytes. Deposition of excessive abnormal A1AT in the liver leads to liver failure, yet no specific treatments are available due to the lack of physiologically relevant disease modelling platforms. Methods We have hypothesised that human induced pluripotent stem cell (iPSC)-derived hepatocytes can provide an efficient platform to study A1ATD. Using CRISPR/Cas9, we have generated wild-type and A1ATD iPSC-derived hepatocytes (Opti-HEP) from healthy and A1ATD donors and developed a bioassay that mimics the accumulation of misfolded A1AT in the liver. Responses to the reference drug carbamazepine (CBZ), known to reduce intracellular misfolded A1AT levels, and RNA-based therapeutics were subsequently investigated. Results All lines successfully differentiated into hepatocytes as measured by comparable key hepatic and disease markers to those seen in primary human hepatocytes. The diseased lines displayed increased intracellular accumulation of misfolded A1AT compared to isogenic controls. Diseased cell lines showed significant decreases in intracellular accumulation of polymeric A1AT following transfection with RNA-based therapeutics, but a differential response upon treatment with CBZ. Conclusion We have developed a specific and robust in vitro model of A1ATD that recapitulates disease pathophysiology and responds to small molecule-based treatments and advanced therapeutic strategies. These data demonstrate the suitability of this model for large-scale efficacy screening studies for the treatment of A1ATD and help pave the way towards the development of novel therapies.

Plant volatiles shape plant-plant interactions by acting as defense regulators and response factors. While plant volatile biosynthesis is well understood, how their emission is regulated remains largely elusive. Here, we show that small peptide signaling regulates induced volatile release in maize. Following herbivore attack, green leaf volatiles such as ( Z )-3-hexenyl acetate (HAC) are released and induce terpene and indole emissions from neighboring plants. This process is accompanied by reduced expression of the ZmCLE1E9 gene and the ZmBAM1A, ZmBAM1B and ZmBAM3C receptor genes in HAC-exposed plants. Exogenous ZmCLE1E9 peptide inhibits HAC-triggered volatile release by limiting stomatal aperture. This inhibition disappears in the Zmbam1a/Zmbam1b/Zmbam3c triple mutant. Molecular docking supports ZmCLE1E9 and ZmBAMs as ligand-receptor pairs. Furthermore, Zmcle1e9 and Zmbams triple mutants show increased volatile emissions upon HAC exposure. In summary, we show that upon HAC perception, maize plants enhance their capacity to release terpenes and indole via the suppression of CLE1E9 signaling. This behavior allows maize plants to rapidly deploy volatile cues in response to stress volatiles and thus shape the infochemical dynamics of multitrophic environments.

ABSTRACT GABBR1 and GABBR2 are widely expressed in the brain and genetic inhibition of their function leads to widespread neurologic dysfunction and premature death in mice. Given that GABBR1 and GABBR2 heterodimerize to form a functional receptor, global knockout of GABBR1 or GABBR2 results in a similar phenotype, characterized by spontaneous epileptiform activity, hyperlocomotor activity, hyperalgesia, impaired memory and premature death. It is now known that both GABBR1 and GABBR2 are expressed in a variety of tissues outside the nervous system and that GABA-B receptors can heterodimerize with other class C GPCRs, including the extracellular calcium-sensing receptor (CaSR). Studies in vitro have demonstrated that interactions with GABBR1 and GABBR2 can alter CaSR signaling in human embryonic kidney cells and breast cancer cells. The neurologic consequences of global loss of function of GABBR1 or GABBR2 has made it difficult to study the effects of loss of GABBR function in other organs. While a conditional knockout for GABBR1 is available, the GABBR2 gene had not been “floxed”. We have used CRISPR to insert loxP sites into the GABBR2 locus in mice. These mice are normal at baseline but when bred with mice expressing Cre-recombinase under the control of the ubiquitously expressed Actin gene promoter, they recapitulate the phenotype of global GABBR2 knockout mice. Phenotypic changes through the brain, including the cortex, hippocampus and cerebellum. Evidence of abnormal neuronal function, increase cell death, and changes in neuronal architecture are seen throughout the brain of CRISPR knockout mice. These mice should be useful tools to study cell type-specific loss of GABBR2 function in the brain and other organs.

Spatial restriction of Aurora B to centromeres during prometaphase and metaphase enables it to phosphorylate proteins necessary for spindle assembly checkpoint signalling and biorientation of chromosomes on the mitotic spindle. Aurora B binding to T3-phosphorylated histone H3 (H3pT3) nucleosomes requires a multivalent targeting module, the chromosomal passenger complex (CPC), consisting of survivin, borealin, and INCENP. To shed light on how these components mediate CPC localisation during prometaphase and metaphase, we determined the structure of the CPC targeting module in complex with haspin-phosphorylated H3pT3-nucleosomes by cryo-electron microscopy. This structure shows how the N-terminus of borealin and the survivin BIR domain act as pivot and flexible tethering points, respectively, to increase CPC affinity for H3pT3 nucleosomes without limiting it to a specific orientation. We demonstrate that this flexible, yet constrained pivot-tether arrangement is important for the control of spindle assembly checkpoint signalling by Aurora B.

ABSTRACT The diversity of genes implicated in autism spectrum disorder (ASD) creates challenges for identifying core pathophysiological mechanisms. Aggregation of seven different classes of genetic variants implicated in ASD, in a database we call Consensus-ASD , reveals shared features across distinct types of ASD variants. Functional interrogation of 19 ASD genes and 9 neighboring long non-coding RNAs (lncRNAs) using CRISPR-Cas13 strikingly revealed differential gene expression profiles that were significantly enriched for other ASD genes. Furthermore, construction of a gene regulatory network (GRN) enabled the identification of central regulators that exhibit convergently altered activity upon ASD gene disruption. Thus, this study reveals how perturbing distinct ASD-associated genes can lead to shared, broad dysregulation of GRNs with critical relevance to ASD. This provides a crucial framework for understanding how diverse genes, including lncRNAs, can play convergent roles in key neurodevelopmental processes and ultimately contribute to ASD.

Summary Autoimmunity develops as a result of a breakdown in immune tolerance and activation of autoreactive immune cells. Most of the common autoimmune diseases are polygenic 1 suggesting dysregulation in multiple signalling pathways. By contrast, in monogenic Inborn Errors of Immunity (IEI), which also can result in autoimmunity, the disease is triggered by a single genetic defect. Therefore, the discovery of causative mutations in IEI allows tracing the molecular mechanisms leading to autoimmunity in humans from a defect in the function of a specific gene to patients’ clinical and immunological phenotype. Here, we discovered an IEI patient with systemic autoimmunity caused by a private homozygous protein-truncating mutation in gene ZC3H12A leading to deficiency of Regnase-1, a regulatory RNase 2–5 . Flow cytometry, bulk T cell transcriptome analysis and single-cell RNA sequencing demonstrated expansion of γδ T cells expressing VCAM-1 and IFNγ genes. We show that Regnase-1 directly targets 3’UTR of VCAM1 and the coding sequence of IFNG mRNAs. These findings highlight a new autoimmunity mechanism in humans, where Regnase-1 deficiency causes expansion of VCAM1 + IFNG + T cells and their interaction with integrin α4β1-expressing B cells, which showed upregulation of IFN-response genes and activation, leading to systemic autoimmunity. Furthermore, we show that VCAM1+ T cells are present in organs of donors and are expanded in the blood of patients with systemic lupus erythematosus, a common autoimmune disease characterised by systemic autoimmunity.

ABSTRACT Primary human cells cultured in organoid format have great promise as potential regenerative cellular therapies. However, their immunogenicity and mutational profile remain unresolved, impeding effective long-term translation to the clinic. In this study we report, for the first time, the generation of human leukocyte antigen (HLA)-I and HLA-II knock-out expandable human primary cholangiocyte organoids (PCOs) using CRISPR-Cas9 as a potential ‘universal’ low-immunogenic therapy for bile duct disorders. HLA-edited PCOs (ePCOs) displayed the same phenotypical and functional characteristics as parental un-edited PCOs. Despite minimal off-target edits, single-molecule DNA-sequencing demonstrated that ePCOs and PCOs acquire substantial mutations in culture at similar rates but without evident selection for cancer-driver mutations. ePCOs induced reduced T cell-mediated immunity and a donor-dependent NK cell cytotoxicity in vitro and evaded cytotoxic responses with increased graft survival in humanized mice in vivo . Our findings have important implications for assessment of safety and immunogenicity of organoid cellular therapies.

Base-editing technologies, particularly cytosine base editors (CBEs), allow precise gene modification without introducing double-strand breaks; however, unintended RNA off-target effects remain a critical concern and are under-studied. To address this gap, we developed PiCTURE, a standardized computational pipeline for detecting and quantifying transcriptome-wide CBE-induced RNA off-target events. PiCTURE identifies both canonical ACW (W = A or T/U) motif-dependent and non-canonical RNA off-targets, revealing a broader WCW motif that underlies many unanticipated edits. Additionally, we developed two machine learning models based on the DNABERT-2 language model, termed STL and SNL, which outperformed motif-only approaches in terms of accuracy, precision, recall, and F1 score. To demonstrate the practical application of our predictive model for CBE-induced RNA off-target risk, we integrated PiCTURE outputs with the PROTECTiO pipeline and estimated RNA off-target risk for each transcript showing tissue-specific expression. The analysis revealed differences among tissues: while the brain and ovaries exhibited relatively low off-target burden, the colon and lungs displayed relatively high risks. Our study provides a comprehensive frame-work for RNA off-target profiling, emphasizing the importance of advanced machine learning-based classifiers in CBE safety evaluations and offering valuable insights for the development of safer genome-editing therapies.

ABSTRACT Patients with Acute Myeloid Leukemia (AML) subtypes, acute erythroleukemia and acute megakaryocytic leukemia (M6 and M7 AMLs, respectively) have a median survival of only a few months with no targeted effective treatment. Our gene expression analysis using the Cancer Cell Line Encyclopedia and CRISPR screen from DepMap showed that M6/M7 AMLs have high levels of the transcription factor GATA1 and depend on GATA1 for survival. While GATA1 was shown to support AML cell proliferation and resistance to chemotherapy, GATA1 has long been considered “undruggable”. Here, we identify the small molecule N-(4-hydroxyphenyl)retinamide (4-HPR, Fenretinide) as a novel GATA1 targeting agent in M6 and M7 AML cells, with nM to low μM concentrations of 4-HPR causing loss of GATA1. In M6 AML OCIM1 cells, knock-down of GATA1 induced cytotoxicity similarly to low doses 4-HPR while overexpression of GATA1 significantly protected cells from 4-HPR-induced cytotoxicity. In M6 AML cells, 4-HPR synergized with the current standard-of-care (SOC), Azacytidine plus Venetoclax, overcoming cell resistance to the drugs. As single-agent, 4-HPR outperformed SOC. 4-HPR is a synthetic derivative of vitamin A, and numerous clinical trials have supported its safe profile in cancer patients; therefore, targeted use of 4-HPR against M6 and M7 AMLs may represent a novel therapeutic breakthrough. Key Points - Fenretinide (4-HPR) targets the transcription factor GATA1, which was previously thought to be “undruggable” and induces GATA1 loss. - M6 and M7 Acute Myeloid Leukemias (AML) have enriched expression of GATA1 and they can be considered GATA1 positive. - Loss of GATA1 contributes significantly to 4-HPR cytotoxicity in M6 OCIM1 cells. - 4-HPR treatment overcomes chemotherapeutic resistance in M6 Acute Myeloid Leukemia cells, synergizes with standard-of-care and outperforms standard-of-care as a single agent.

ABSTRACT Fast twitch, type II muscle fibers are particularly prone to degradation in skeletal muscle pathologies, such as sarcopenia and muscular dystrophies. We previously showed that endogenous activation of the exercise-induced long noncoding RNA CYTOR promotes fast-twitch myogenesis. In the present study, we identify an independent pro-myogenic element within human CYTOR and optimize its RNA delivery. In human primary myoblasts exogenous, vector-based CYTOR exon 2 recapitulates the effect of full-length CYTOR by enhancing fast-twitch myogenic differentiation. Furthermore, chemically modified CYTOR exon 2 RNA ΨU (N1-me-PseudoU, 7-methyl guanosine 5’Cap, polyA tail) enhanced RNA stability and reduced the immunogenic response to CYTOR exon 2 RNA. We demonstrate that viral- or chemically optimized RNA-mediated CYTOR exon 2 administration enhances the commitment towards myogenic maturation in Duchenne muscular dystrophy-derived primary myoblasts, induced myogenic progenitor cells and mouse embryonic stem cells. Furthermore, chemically optimized CYTOR exon 2 improves key disease characteristics in dystrophic myotubes, including calcium handling and mitochondrial bioenergetics. In summary, our findings identify CYTOR exon 2 as the pro-myogenic domain of CYTOR that can be delivered in a disease context using chemical modifications. This is of particular importance given the susceptibility of type II muscle fibers in different muscle pathologies such as aging and dystrophies, and the reported oncogenic effect of CYTOR exon 1. Our study, therefore, highlights the potential of identifying functional domains in noncoding RNAs. Delivery, or targeting of such RNA domains could constitute next-generation RNA therapeutics.

The nucleoli are subdomains of the nucleus that form around actively transcribed ribosomal RNA (rRNA) genes. The highly repetitive and transcribed nature of the rRNA genes (rDNA) by RNA polymerase I (Pol I) poses a challenge for DNA repair and replication machineries. Here, we profile the nucleolar proteome and the chromatin landscape of stalled replication sites upon rDNA damage to characterize the early steps of nucleolar DNA damage response (nDDR). We observed early dynamics in nucleolar-nucleoplasmic proteome localization and identified nucleolar replication stress signatures involving chromatin remodeling networks, transcription-replication conflicts and DNA repair. Our findings define localized surveillance mechanisms that activate the nDDR. Further, we identified that upon rDNA damage, nucleolar RNA Polymerase (Pol) II binds to intergenic rDNA sequences and generates R-loops (DNA:RNA hybrid structures) that are essential for recruiting nDDR factors. Using a boutique CRISPR-Cas9 synthetic lethal screen of DNA repair factors with inhibitors of RNA Pol I transcription, we identified an unexpected protective role for the DNA translocase RAD54L in nDDR. Loss of Rad54L increases nucleolar R-loops and rDNA damage leading to defects in nucleolar structure and enhanced sensitivity to PARP and RNA Pol I inhibitors. Altogether, our study uncovers localized surveillance networks within the nucleolus that respond to rDNA damage. These insights expand our understanding of the molecular mechanisms governing nDDR and opens new avenues for developing nDDR-targeting therapies.

Plants employ diverse strategies to cope with different types of heat stress. The response to short-term acute heat stress differs significantly from that to moderate heat stress followed by severe stress events. After experiencing moderate heat stress, plants exhibit a more robust response to subsequent severe stress, a phenomenon known as thermopriming or acquired thermotolerance. Thermopriming creates a memory by maintaining the heat stress (HS) memory-related genes in an alert state. In this work, we investigated the role of Arabidopsis Universal Stress Protein 1 (USP1) in plant heat stress responses. CRISPR-Cas9 generated knockout usp1 mutant lines showed no morphological changes during development and normal growth conditions. However, usp1 mutant plants showed enhanced levels of apoplast hydrogen peroxide and superoxide reactive oxygen species accumulation upon heat stress. Transcriptome analyses revealed that genes related to protein folding, electron transport, and oxidative phosphorylation are strongly upregulated in usp1 mutant plants. USP1 is essential for acquired thermotolerance, as usp1 mutants are compromised in heat stress memory but show normal responses to acute heat stress similar to hsfa2 mutants. Biochemical assays showed that USP1 functions as a molecular chaperone, protecting the transcription factor HSFA2 from heat-induced denaturation. Moreover, usp1 mutant plants show decreased transcript levels of heat stress response genes and reduced H3K4me3 enrichment at memory gene loci. These data show that USP1 plays an important role as a chaperone of HSFA2 in mediating plant heat stress memory.

Lacticaseibacillus rhamnosus GG (LGG) is one of the most studied probiotic strains and is widely used in both food and therapeutic industries. With its safe and health-beneficial properties, LGG is an ideal candidate for genome modification to enhance its functionalities for food, industrial and pharmaceutical applications. However, precise and efficient genome engineering tools for LGG are unavailable. In this study, we developed a novel genome engineering tool for LGG based on its endogenous type II-A CRISPR-Cas9 system. By employing a validated protospacer adjacent motif (PAM), a customized single guide RNA (sgRNA) expression cassette and a homologous repair template, we successfully reprogrammed the native CRISPR-Cas9 system for targeted genome modifications. Using this method, we successfully constructed a fucose-negative LGG incapable of growing on L-fucose and a lactose-positive LGG. The lactose-positive LGG exhibited significantly improved growth in milk compared to its parental strain LGG, which is unable to ferment lactose, attributed to its ability to metabolize lactose efficiently. Moreover, this strain showed robust growth during yogurt fermentation and maintained viability during cold storage for at least three weeks. These findings highlight the potential of the lactose-positive LGG as an improved culture for dairy industry and a functional probiotic for food and therapeutic applications. Importance A precise and efficient genome editing tool is essential for unlocking the full potential of Lacticaseibacillus rhamnosus GG (LGG), the most extensively studied probiotic strain. This study established the first high-efficiency genome editing platform for LGG by harnessing the endogenous type II-A CRISPR-Cas9 system. Using this tool, we achieved targeted gene modifications, without introducing scars, heterologous DNA, or antibiotic resistance genes. The engineered lactose-positive LGG strain demonstrated improved growth in lactose-containing dairy products and robust performance during yogurt fermentation, highlighting its industrial and therapeutic value. This platform not only advances the development of enhanced probiotic strains but also establishes LGG as a versatile vehicle for synthetic biology and biotechnological applications.

Bacteria of the genus Bifidobacterium are pivotal for human health, especially in early life, where they dominate the gut microbiome in healthy infants. Bacteriophages, viruses of bacteria, are drivers of gut bacterial composition in the human gut and could affect bifidobacterial abundance. Here, we use a bioinformatics approach to explore the direct interactions occurring between human-associated Bifidobacterium spp. and prophages, as evidenced by their genomes. A total of 1,086 bifidobacterial genomes were analysed in this study, revealing complex systems to prevent viral invasion. Despite their characteristically small genomes, Bifidobacterium strains harboured more than double the number of defence systems as most bacteria. In total, 34 defence system types and 56 subtypes were detected, including several different CRISPR-Cas systems with spacers that targeted almost three-quarters of bifidobacteria-derived prophages. We identified at least one prophage which met our stringent quality control measures in ~63% of strains, with phages exhibiting high genomic diversity and evidence of historical recombination. Additionally, prophages were found to encode various anti-defence systems, such as anti-CRISPR genes and restriction modification resistance mechanisms. In summary, our investigation reveals "arms race" dynamics drive genomic diversity in both bifidobacteria and their phages.

Congenital heart defects (CHDs) occur in about 1% of live births and are the leading cause of infant death due to birth defects. While there have been remarkable efforts to pursue large-scale whole-exome and genome sequencing studies on CHD patient cohorts, it is estimated that these approaches have thus far accounted for only about 50% of the genetic contribution to CHDs. We sought to take a new approach to identify genetic causes of CHDs. By combining analyses of genes that are under strong selective constraint along with published embryonic heart transcriptomes, we identified over 200 new candidate genes for CHDs. We utilized protein-protein interaction (PPI) network analysis to identify a functionally-related subnetwork consisting of known CHD genes as well as genes encoding proteasome factors, in particular POMP , PSMA6 , PSMA7 , PSMD3 , and PSMD6 . We used CRISPR screening in zebrafish embryos to preliminarily identify roles for the PPI subnetwork genes in heart development. We then used CRISPR to create new mutant zebrafish strains for two of the proteasome genes in the subnetwork: pomp and psmd6 . Phenotypic analyses confirm critical roles for pomp and psmd6 in heart development. In particular, we find defects in myocardial cell shapes and in outflow tract development in pomp and psmd6 mutant zebrafish embryos, and these phenotypes have been observed in other zebrafish CHD-gene mutants. Our study provides a novel systems genetics approach to further our understanding of the genetic causes of human CHDs. Author Summary Congenital heart defects (CHDs) are birth defects resulting in the abnormal structure and function of the heart. Genetic mutations are a significant cause of CHDs. Many studies have used genome sequencing of CHD patients and their families to gain knowledge of the mutations that cause CHDs. However, these studies have only found about 50 percent of the genes involved in CHDs. Here, we take a new approach to identifying genes that are required for heart development and that may cause CHDs, generating a list of over 200 candidate genes. Using multiple data systems, including human exome sequences, mouse transcriptomes, and protein-protein interactions, we identify a small group of related potential CHD genes that includes multiple genes encoding proteasome factors. These factors are known to be important for assembling the proteasome, a large molecular machine that eliminates unneeded or damaged proteins from the cell, but which has not been shown to contribute to CHD. We use a CRISPR-based approach in zebrafish to specifically eliminate some of these candidate genes and reveal new roles for proteasome genes in heart development. We show that loss of proteasome gene functions leads to zebrafish heart defects that resemble those seen in other zebrafish CHD-gene mutants. This study shows that a proteasome gene family contributes to heart development, advancing our understanding of the causes of CHDs. By increasing our understanding of the genetic causes of CHDs, our work should lead to better screening, more accurate diagnoses, and, ultimately, better treatments for these disorders.

The evolutionary arms race between bacteriophages and their bacterial hosts has driven the evolution of sophisticated adaptive immune systems, such as CRISPR-Cas, as a crucial defense mechanism. While bacteriophages have developed various anti-CRISPR strategies to counteract these immune systems, the role of bacterial host factors in enhancing CRISPR-Cas functions has been relatively unexplored. In this study, we employ an artificial intelligence (AI)-driven approach to systematically analyze potential interactions between Escherichia coli ( E. coli ) proteins and fifteen previously uncharacterized Cas12 proteins, generating 65,715 predicted binary complex structures. Our findings reveal a previously unknown dimension of CRISPR immunity, demonstrating that the host’s ubiquitous redox enzyme, thioredoxin (TrxA), significantly enhances the DNA cleavage efficiency of a phage-encoded, miniature Cas12 nuclease (termed ‘Cas12 hacker’). This synergistic relationship represents a strategic inversion, where a bacteriophage hijacks a host protein to reinforce its own genome degradation machinery, possibly targeting rival nucleic acids. Through comprehensive biochemical characterizations, structural analyses of the Cas12 hacker-TrxA-sgRNA-dsDNA quaternary complex, and in vivo bacterial defense assays, we uncover an intricate association in which thioredoxin binds to and activates the Cas12 hacker nuclease, intensifying its DNA cleavage capacity and bolstering CRISPR immunity. Our findings expand the understanding of the molecular interactions underlying host-phage conflicts and highlight the potential for harnessing endogenous host factors to enhance the capabilities of CRISPR-based genetic engineering tools.

A 2-year-old Large White research gilt was presented to the Comparative Theriogenology service at WSU for infertility. She was produced from the transfer of genetically modified embryos obtained by in vitro fertilization (IVF) that had been treated with CRISPR-Cas9 reagents to mutate the NANOS2 gene. Since birth, the gilt showed a so-called “skyhook” vulva and abnormal estrous cycles. She was artificially inseminated multiple times, starting at 5 months of age, with semen from a proven boar, but never conceived. On transabdominal ultrasonography of the reproductive tract, a unilateral ovotestis was suspected. An exploratory laparotomy was performed and confirmed the presence of ovarian and testicular tissue on her right gonad. The diagnosis was confirmed by histology following unilateral gonadectomy. The cytogenic evaluation revealed the gilt to be XX, 38; SRY-negative. The gilt showed estrus signs 4 months after surgery, and artificial insemination was performed, which resulted in a pregnancy. She delivered six piglets. Necropsy was performed following humane euthanasia. Several abnormalities of the reproductive tract were discovered, including a unilateral mucometra due to a complete septum preventing communication between the right uterine horn and the body of the uterus. This case is novel because it demonstrates that surgical removal is an effective treatment for fertility in SRY-negative XX DSD gilts with partial masculiniza-tion, posing the presence of a normal ovary and a developed oviduct and uterine horn.

ABSTRACT Background/Purpose Desmoplakin (DSP) mutations are linked to familial cardiomyopathies with a very high arrhythmogenic propensity. While autosomal recessive inheritance forms manifest in the cardio-cutaneous Carvajal syndrome, the dominant-inheritance variants associate to DSP-cardiomyopathy (DSP-CM). This latter is a subtype of Arrhythmogenic Cardiomyopathy characterized by frequent myocarditis-like episodes, dominant left ventricular (LV) remodeling, recurrent premature ventricular contractions and life-threatening arrhythmias, frequently preceding LV dysfunction and dilation. Notably, DSP-CM evades the diagnostic identifiers of Arrhythmogenic Cardiomyopathy, further complicating risk-stratification and prediction. At the time being, the pathogenetic mechanisms underlying DSP-related cardiomyopathies are largely obscure and their elucidation is urgently required. Methods To this end, we employed CRISPR-Cas9 to generate a novel knock-in mouse model harboring a point mutation at the murine ortholog of human Serine-299, a mutation site previously identified in a family affected by left dominant-Arrhythmogenic Cardiomyopathy. In both heterozygotes and homozygotes, cardiac function was assessed by echocardiography and telemetry-ECG, at different ages. Results were correlated with heart structure, which was assessed by ultrastructural, histopathological and molecular/biochemical assays. The effects of moderate exercise on disease manifestations were tested. Results The homo- and hetero-zygous expression of mutant Dsp S311A allele replicated the human cardiac phenotypes of Carvajal syndrome and DSP-CM, respectively. Indeed, Dsp S311A/S311A mice featured precocious dilated cardiomyopathy with biventricular fibrotic remodeling, aneurisms, systolic dysfunction, increased arrhythmic vulnerability, sudden death and, remarkably, cutaneous defects. Differently, Dsp WT/S311A mice did not show evident cutaneous alterations, and myocardial remodeling and contractile dysfunction developed later and were associated to increased cell death, inflammatory response and patchy fibrosis predominantly in the LV. Notably, as observed in certain patient subgroups, Dsp WT/S311A mice had electrophysiological alterations (i.e. QRS prolongation, distal conduction defects and sustained ventricular arrhythmias) prior to developing contractile dysfunction. Furthermore, in both genotypes, exercise accelerated myocardial remodeling and increased the incidence of arrhythmic mortality. Conclusions Our novel Dsp S311A mice recapitulate the clinical and pathological features of the respective dominant (i.e. DSP-CM) and recessive (i.e. Carvajal syndrome) forms of DSP-related cardiomyopathies. Thus, Dsp S311A mice are a novel experimental model of human diseases, suited to test therapeutic interventions aimed at reducing the burden of stress-dependent SD.

Nearly all mitochondrial proteins are imported into mitochondria from the cytosol. How nascent mitochondrial precursors acquire and sustain import-competence in the cytosol under normal and stress conditions is incompletely understood. Here, we show that under normal conditions, the Hsc70 and Hsp90 systems interact with and redundantly minimize precursor degradation. During acute import stress, Hsp90 buffers precursor degradation, preserving proteins in an import-competent state until stress resolution. Unexpectedly, buffering by Hsp90 relies critically on a mitochondrial targeting signal (MTS), the absence of which greatly decreases precursor-Hsp90 interaction. Site-specific photo-crosslinking and biochemical reconstitution showed how the MTS directly engages co-chaperones of Hsc70 (St13 and Stip1) and Hsp90 (p23 and Cdc37) to facilitate chaperone retention on the mature domain. Thus, the MTS has a previously unappreciated role in regulating chaperone dynamics on mitochondrial precursors to buffer their degradation and maintain import competence, functions that may facilitate restoration of mitochondrial homeostasis after acute import stress. Significance statement Mitochondrial proteins encoded by the nuclear genome are synthesized in the cytosol before their subsequent import into mitochondria. The factors that recognize mitochondrial precursors in the cytosol to maintain their import-competence are incompletely defined. Using a systematic site-specific photo-crosslinking strategy, the authors find that the mitochondrial targeting signal (MTS) is directly recognized by co-chaperones of Hsc70 and Hsp90. The co-chaperones facilitate recruitment, retention, and remodeling of these general chaperones on the nascent precursor protein. Chaperone retention becomes particularly important during mitochondrial stress, when precursors must avoid degradation during a prolonged period in the cytosol.

Many cancers use an alternative lengthening of telomeres (ALT) pathway for telomere maintenance. ALT telomeric DNA synthesis occurs in ALT telomere-associated PML bodies (APBs). However, the mechanisms by which APBs form are not well understood. Here, we monitored the formation of APBs with time-lapse imaging employing CRISPR knock-in to track the promyelocytic leukemia (PML) protein at endogenous levels. We found APBs form via two pathways: telomeres recruit PML proteins to nucleate PML bodies de novo, or telomeres fuse with preformed PML bodies. Both nucleation and fusion of APBs require interactions between SUMO and SUMO interaction motifs (SIMs). Moreover, APB nucleation is associated with higher levels of SUMOs and SUMO-mediated recruitment of DNA helicase BLM, resulting in more robust telomeric DNA synthesis. Finally, further boosting SUMO levels at telomeres enhances APB nucleation, BLM enrichment, and telomeric DNA synthesis. Thus, high SUMO levels at telomeres promote APB formation via nucleation, resulting in stronger ALT activity.

Experimental studies suggest that the probiotic yeast Saccharomyces boulardii can mitigate the symptoms of inflammatory bowel disease. However, these results are equivocal and S boulardii probiotic therapy has not gained widespread acceptance in clinical practice. To assess whether the therapeutic properties of S boulardii might be improved upon, we engineered S boulardii to overproduce and secrete spermidine, a pro-regenerative natural metabolite. We employed CRISPR gene deletion and transposon-mediated gene integration to manipulate expression of key enzymes in the polyamine synthetic and transport pathways. We tested the engineered yeast by oral gavage of mice treated with azoxymethane and dextran sulfate sodium to induce chronic colitis and colon cancer. We demonstrate that oral delivery of spermidine-secreting S boulardii in mice populates the gastrointestinal tract with viable spermidine-secreting S boulardii cells and raises free spermidine levels in the gastrointestinal tract. Strikingly, spermidine-secreting S boulardii strains were significantly more effective than wild-type S boulardii in reducing dextran sulfate sodium-induced colitis as well as colitis-associated colon cancer in mice. These results suggest that in situ spermidine secretion by engineered synthetic biotic yeast strains may be an effective and low-cost therapy to mitigate inflammatory bowel disease and colon cancer.

Background FZD8 could be a promising therapeutic target in osteoporosis (OP), although the signal transduction mechanism in OP regarding FZD8 has not been completely elucidated. Aims We used the CRISPR/Cas9 technique to develop an Fzd8 -knockout mouse model to study whether Fzd8 inactivation results in genetic changes with potential correlations to OP. Materials and Methods Genotypes of distinguished classified knockout mice, i.e., heterozygous, homozygous, and wild-type were identified through PCR. Applying the murine model, third generation mice were used for the downstream experiments. We investigated the potential relevance of differentially expressed genes (DEGs) in OP. Results We found that osteoclasts significantly increased in Fzd8 -knockout homozygous mice, compared to wild-type mice, while osteoblasts reduced significantly. Before transcription, heterozygous and homozygous mice possessed DEGs related to exons SNP, which are associated with exons CNV. After transcription, DEGs related to exons SNP in heterozygous and homozygous mice were observed, some of which are potentially associated with OP based on pathway and gene set enrichment analyses. Conclusions Our Fzd8- knockout murine model showed that there were significant alternations in Fzd10 and Lta gene expressions and Itgb3 and RANK protein expressions among the wild-type and homozygous mice, which are significantly associated with bone remodeling. Our results revealed that FZD8 could be a therapeutic target in OP. This study elucidates the molecular mechanisms in OP, providing evidence-based data for OP drug development and treatment.

The impact of cancer driving mutations in regulating immunosurveillance throughout tumor development remains poorly understood. To better understand the contribution of tumor genotype to immunosurveillance, we generated and validated lentiviral vectors that create an epi-allelic series of increasingly immunogenic neoantigens. This vector system is compatible with autochthonous Cre-regulated cancer models, CRISPR/Cas9-mediated somatic genome editing, and tumor barcoding. Here, we show that in the context of KRAS-driven lung cancer and strong neoantigen expression, tumor suppressor genotype dictates the degree of immune cell recruitment, positive selection of tumors with neoantigen silencing, and tumor outgrowth. By quantifying the impact of 11 commonly inactivated tumor suppressor genes on tumor growth across neoantigenic contexts, we show that the growth promoting effects of tumor suppressor gene inactivation correlate with increasing sensitivity to immunosurveillance. Importantly, specific genotypes dramatically increase or decrease sensitivity to immunosurveillance independently of their growth promoting effects. We propose a model of immunoediting in which tumor suppressor gene inactivation works in tandem with neoantigen expression to shape tumor immunosurveillance and immunoediting such that the same neoantigens uniquely modulate tumor immunoediting depending on the genetic context. One Sentence Summary Here we uncover an under-appreciated role for tumor suppressor gene inactivation in shaping immunoediting upon neoantigen expression.