Double Knockout Mice Research Articles

Concomitant suppression of COX-1 and COX-2 is insufficient to induce enteropathy associated with chronic NSAID use.

Nonsteroidal anti-inflammatory drugs (NSAIDs) are the most widely used medications for the management of chronic pain; however, they are associated with gastrointestinal (GI) adverse events. Although many mechanisms have been suggested, NSAID-induced enteropathy has been thought to be primarily due to inhibition of both cyclooxygenases (COX) -1 and -2, which results in suppression of prostaglandin synthesis. Here we report that concomitant postnatal deletion of Cox-1 and -2 over 10 months failed to cause intestinal injury in mice unless they were treated with naproxen or its structural analog, phenylpropionic acid, which is not a COX inhibitor. Cox double knockout mice exhibit a distinct gut microbiome composition, and cohousing them with controls rescues their dysbiosis and delays the onset of NSAID-induced GI bleeding. Suppression of bile acid synthesis is also protective. In both the UK Biobank and All of Us human cohorts, coadministration of antibiotics with NSAIDs is associated with an increased frequency of GI bleeding. These results show that prostaglandin suppression plays a trivial role in NSAID-induced enteropathy. However, Cox deletion causes dysbiosis of the gut microbiome that amplifies the enteropathic response to NSAIDs.

Endogenous Glucagon-Like Peptide-1 Receptor and Glucose-Dependent Insulinotropic Polypeptide Receptor Signaling Inhibits Aeroallergen-Induced Innate Airway Inflammation.

Anti-inflammatory effects of incretin signaling through the glucagon-like peptide-1 receptor (GLP-1R) and the glucose-dependent insulinotropic polypeptide receptor (GIPR) in mice have been reported. Therefore, we hypothesized that signaling through the endogenous GLP-1R and the GIPR individually decreases allergic airway inflammation and that the combination of GLP-1R and GIPR signaling together additively inhibits allergen-induced lung and airway inflammation. WT (C57BL/6J), GLP-1R knockout (KO), GIPR KO, and GLP-1R/GIPR double KO (DKO) mice were challenged intranasally with Alternaria alternata extract (Alt-Ext) or vehicle to evaluate the impact of signaling through these receptors on the innate allergen-induced inflammatory response that is primarily driven by group 2 innate lymphoid cells (ILC2). Alt-Ext-induced IL-33 release in the bronchoalveolar lavage fluid (BALF) was not different between the mouse strains, but thymic stromal lymphopoietin (TSLP) was significantly increased in GLP-1R/GIPR DKO mice challenged with Alt-Ext compared to the other strains. Furthermore, Alt-Ext-induced protein expression of IL-5, IL-13, CCL11, and CCL24 in the lung homogenates, the number of eosinophils, lymphocytes, and neutrophils in the BALF, and the number of lung GATA3+ ILC2 were significantly increased in GLP-1R/GIPR DKO mice compared to the other 3 strains. Furthermore, ICAM-1 expression on lung epithelial cells was increased in GLP-1R/GIPR DKO mice challenged with Alt-Ext compared to the other 3 strains. Deficiency of both GLP-1R and GIPR signaling together increased TSLP release, ILC2 activation, and early type 2 innate immune responses to aeroallergen exposure. Combined GLP-1R and GIPR signaling should be explored for the treatment of asthma.

CD59 double knockout mice express a CD59ba hybrid fusion protein that mediates insulin secretion.

CD59 is a cell-surface inhibitor of the terminal step in the complement cascade. However, in addition to its complement inhibitory function, a non-canonical role of CD59 in pancreatic beta cells has been identified. Two recently discovered intracellular alternative splice forms of CD59, IRIS-1 and IRIS-2, are involved in insulin exocytosis through interactions with SNARE-complex components. In mice, the CD59 gene has undergone duplication and to further explore the role of CD59 in insulin secretion, blood glucose homeostasis was studied in a CD59 double knockout (CD59abKO) mouse model. However, no phenotypic deviation related to insulin secretion or blood glucose homeostasis was observed for the CD59abKO mice. Instead, a CD59ba hybrid transcript formed as a consequence of the mutation induced to generate the model was identified. This hybrid transcript is expressed in pancreatic islets of the CD59abKO mice and is comprised of the remaining exons of the two CD59 genes spliced together. Similar to canonical CD59, the CD59ba hybrid was found to be glycosylated and present on the cell surface when exogenously expressed in INS-1 832/13 cells. Furthermore, INS-1 832/13 cells over-expressing the mouse CD59ba hybrid retained normal insulin secretion following siRNA-mediated knockdown of canonical CD59. Hence, although the CD59ba hybrid has lost the complement inhibitory function, the intracellular insulin secretory function remains. These results provide further information concerning the structural requirements of CD59 in its intracellular role relative to its role as a complement inhibitor. It also highlights the importance of carefully assessing plausible consequences of induced mutations in research models.

Abstract 4137713: Epsin-Mediated PCSK9-LDLR Interaction: A New Therapeutic Target for Atherosclerosis

Introduction: Atherosclerosis, a leading cause of cardiovascular diseases, causes about 17.9 million deaths annually. It is driven by high levels of LDL cholesterol (LDL-C). The liver's LDL receptor (LDLR) removes LDL-C from the bloodstream, but its degradation by PCSK9 exacerbates the condition. Epsin, an endocytic adaptor protein crucial for clathrin-mediated endocytosis, plays a significant role in atherosclerosis, particularly lipid metabolism. Hypothesis: We propose that hepatic epsins significantly contribute to atherosclerosis by facilitating the PCSK9-induced degradation of LDLR, thus impeding LDL-C clearance. Objectives: This study aims to investigate hepatic epsins' role in PCSK9-mediated LDLR degradation and its effects on LDL-C levels and atherosclerosis development. Using bioinformatics, we will analyze enriched pathways and networks to study epsins modulation, which will be validated through biochemical assays and in vivo experiments. Methods: Liver-specific double knockout (DKO) mice lacking epsin1 and epsin2 were created on an ApoE -/- background. Atherosclerosis was induced using a Western diet (WD), and blood cholesterol and triglyceride levels were monitored. We employed high-resolution single-cell RNA sequencing (scRNA-seq) to analyze cellular transitions, intercellular interactions, and Gene Ontology pathway enrichment within hepatocyte-derived data. Results: RNA velocity reveals the transition from lipogenic Alb hi Hepatocytes to glucogenic Hnf4a hi Hepatocytes in Liver-DKO mice on an ApoE -/- background on a WD. Liver-DKO mice on an ApoE -/- background on a WD exhibited significantly reduced atherogenesis and lower blood cholesterol and triglyceride levels compared with wild-type on an ApoE -/- background on a WD. Gene Ontology enrichment analysis showed elevated pathways for LDL particle clearance and enhanced LDLR-cholesterol communication scores in Liver-DKO mice, suggesting improved LDL-C clearance. Nanoparticle-encapsulated siRNAs targeting liver epsins effectively inhibited atherosclerosis. Conclusion: Epsin depletion in the liver upregulated LDLR protein levels, and PCSK9-triggered LDLR degradation was abolished, preventing atheroma progression. Targeting liver epsins presents a novel therapeutic strategy for atherosclerosis, supported by network analysis and predictive modeling for effective interventions.

Abstract 4113300: Targeting Liver Epsins Ameliorates Dyslipidemia in Atherosclerosis

Rationale: Low density cholesterol receptor (LDLR) in the liver is critical for the clearance of low-density lipoprotein cholesterol (LDL-C) in the blood. In atherogenic conditions, proprotein convertase subtilisin/kexin 9 (PCSK9) binds to LDLR on the surface of hepatocytes, preventing its recycling and enhancing its degradation in lysosomes, resulting in reduced LDL-C clearance. Our recent studies demonstrate that epsins, a family of ubiquitin-binding endocytic adaptors, are critical regulators of atherogenicity. Given the fundamental contribution of circulating LDL-C to atherosclerosis, we hypothesize that liver epsins promote atherosclerosis by controlling PCSK9-triggered LDLR endocytosis and degradation. Objective: We will determine the role of liver epsins in promoting PCSK9-mediated LDLR degradation and hindering LDL-C clearance to propel atherosclerosis. Methods and Results: We generated double knockout mice using albumin Cre in which both genes of epsin, namely, epsin 1 and epsin 2, are specifically deleted in the liver (Liver-DKO) on an ApoE -/- background. We discovered that western diet (WD)-induced atherogenesis was greatly inhibited, along with diminished blood cholesterol and triglyceride levels. Mechanistically, using scRNA-seq analysis on hepatocyte-derived data revealed elevated pathway involved in LDL particle clearance under WD treatment in ApoE -/- /Liver-DKO, which was coupled with diminished plasma LDL-C levels. Further analysis using the MEBOCOST algorithm revealed enhanced communication score between LDLR and cholesterol, suggesting elevated LDL-C clearance in the ApoE -/- Liver-DKO mice. In addition, we showed that loss of epsins in the liver upregulates of LDLR protein level. We further showed that epsins bind LDLR via the ubiquitin-interacting motif (UIM), and PCSK9-triggered LDLR degradation was abolished by depletion of epsins, preventing atheroma progression. Finally, our therapeutic strategy, which involved targeting liver epsins with nanoparticle-encapsulated siRNAs, was highly efficacious at inhibiting dyslipidemia and impeding atherosclerosis. Conclusions: Liver epsins promote atherogenesis by mediating PCSK9-triggered degradation of LDLR, thus raising the circulating LDL-C levels. Targeting epsins in the liver may serve as a novel therapeutic strategy to treat atherosclerosis by suppression of PCSK9-mediated LDLR degradation.

CNSC-36. REGULATION OF CELL FATE IN PAEDIATRIC HIGH-GRADE GLIOMA BY THE HOMEOBOX TRANSCRIPTION FACTOR DLX2

Abstract Paediatric high-grade gliomas (pHGG) are nearly uniformly fatal cancers that arise predominantly in children and adolescents and encompass Diffuse Midline Glioma (DMG) and Diffuse Hemispheric Glioma (DHG). Most patients harbour mutations in histone variants H3.1 or H3.3, resulting in global epigenetic dysregulation and a stalled oligodendroglial progenitor (OPC) or GABAergic interneuron progenitor (IP) fate for DMG and DHG, respectively. DLX2, a homeobox transcription factor, represses OPC fate and promotes IP cell fate and migration during early neurogenesis. Our lab has shown that Dlx2 binds to and regulates the promoters of Gad1/Gad2, as well as early (Olig2, Nkx2.2) and late (Myt1, Plp1) genes required for OPC differentiation in vivo. Co-expression of Dlx2 with these target sequences reduces reporter gene expression in vitro and Dlx1/2 double knockout mice exhibit increased expression of these OPC markers in vivo. Transient overexpression of a Dlx2-GFP construct in murine DMG cells led to significant IP marker increase (Gad1/2), decrease of OPC markers (Olig2, Nkx2.2) and global restoration of H3K27me3. Additionally, decreased proliferation, colony growth, invasion and migration were observed in vitro. To translate these findings in human pHGG, analysis of a bulk RNA-seq database of 62 patient-derived pHGG cell lines revealed an inverse relationship between DLX2 and OLIG2. DLX2 was knocked out of DLX2high/OLIG2low DHG cell lines using CRISPR-Cas9, and overexpressed in DLX2low/OLIG2high DMG cell lines using a DLX2-mCherry overexpression construct. Evaluation of cell fate markers and epigenetic marks will be presented. Changes in migration, invasion, and proliferation in vitro will also be presented, in addition to changes in tumour growth using a neonatal xenograft murine model in vivo. Manipulation of DLX2 in pHGG provides a model for investigating the link between the factors that control cell fate decisions in the developing brain and the aberrant differentiation state in pHGG.

PINK1-mediated mitophagy attenuates pathological cardiac hypertrophy by suppressing the mtDNA release-activated cGAS-STING pathway.

Sterile inflammation is implicated in the development of heart failure (HF). Mitochondria plays important roles in triggering and maintaining inflammation. Mitophagy is important for regulation of mitochondrial quality and maintenance of cardiac function under pressure overload. The association of mitophagy with inflammation in HF is largely unclear. As PINK1 is a central mediator of mitophagy, our objective was to investigate its involvement in cardiac hypertrophy, and the effect of PINK1-mediated mitophagy on cGAS-STING activation during cardiac hypertrophy. PINK1 knockout and cardiac-specific PINK1-overexpressing transgenic mice were created and subsequently subjected to transverse aortic constriction (TAC) surgery. In order to explore whether PINK1 regulates STING-mediated inflammation during HF, PINK1/STING (stimulator of interferon genes) double-knockout mice were created. Pressure overload was induced by TAC. Our findings indicate a significantly decline in PINK1 expression in TAC-induced hypertrophy. Cardiac hypertrophic stimuli caused the release of mitochondrial DNA (mtDNA) into the cytosol, activating the cGAS-STING signaling, which in turn initiated cardiac inflammation and promoted the progression of cardiac hypertrophy. PINK1 deficiency inhibited mitophagy activity, promoted mtDNA release, and then drove the overactivation of cGAS-STING signaling, exacerbating cardiac hypertrophy. Conversely, cardiac-specific PINK1 overexpression protected against hypertrophy thorough inhibition of the cGAS-STING signaling. Double-knockout mice revealed that the effects of PINK1 on hypertrophy were dependent on STING. Our findings suggest that PINK1-mediated mitophagy plays a protective role in pressure overload-induced cardiac hypertrophy via inhibiting the mtDNA-cGAS-STING pathway.

Protease-activated receptor 2 (PAR2) inhibition reduces complement-associated cardiac remodelling in obesity-related heart failure

Abstract Background and Aims Obesity is considered a major risk factor for the development of heart failure (HF) due to lipid accumulation, oxidative stress and inflammation which results in cardiac remodeling. Protease activated receptor 2 (PAR2) has been linked to various cardiovascular and inflammatory diseases. The role of PAR2 has not yet been studied in obesity-related HF. Methods In the experimental mouse study, we used 1-year-old ApoE knockout (ApoE-/-) and ApoE PAR2 double knockout (ApoE-/-PAR2-/-) mice with a C57BL/6J background on a high fat (HF) diet (n=5/ group). Cell culture experiments were performed with human primary cardiac fibroblasts and HepG2 hepatocytes. Patients (n=50) included in the clinical study had a BMI > 25kg/m², symptoms of heart failure (HF), coronary angiography (CA) that excluded coronary artery disease (CAD) and endomyocardial biopsy (EMB) that confirmed the absence of active myocarditis or primary cardiac amyloidosis. Patients were divided into PAR2low (n=22) and PAR2high (n=22) based on the median PAR2 expression measured via qPCR in the EMB of the cohort, and six patients served as healthy controls. Results Evaluation of endomyocardial biopsies (EMB) from overweight/ obese non-ischemic cardiomyopathy (NICM) patients with heart failure (HF) (n=44) revealed that a reduced cardiac PAR2 expression is associated with less cardiac C3 (p≤0.054), C4 (p≤0.041) and C5 gene expression (p≤0.045), as well as plasma levels of complement C3 (1.1g/l± 0.7 vs 2.1g/l±0.2; p≤0.016) and C5b-9 (303.4ng/ml± 215.7 vs 992.7ng/ml± 756.2; p≤0.0002) and as a result, better systolic function i.e. LVEF (46.1%±17.1 vs 36.8%±15.2; p≤0.046) and LV GLS (-14.9%± 5.7 vs -9.5%± 4.6; p≤0.009), less cardiac remodeling and damage. Correspondingly, aged ApoE-/-PAR2-/-mice on a Western diet showed less hepatic and cardiac complement expression (i.e. C1q, C3, C4, C5, C9), cardiac C3 deposition (p≤0.047) and C5b-9 plasma levels (p≤0.049), as well as less cardiac necrosis (p≤0.046) and lower BNP (p≤0.016) than ApoE-/-. PAR2 overexpression in human cardiac fibroblasts (HCFs) independently enhanced and PAR2 antagonism reduced interferon γ (IFNγ)-mediated STAT1-dependent complement C3, C4 and C5 expression. Conclusions Protease-activated receptor 2 regulates complement-mediated cardiac damage and remodeling in HF. The PAR2-IFNγ/STAT1/C3-C4-C5 complement-axis might be a promising prognostic and therapeutic approach to identify and treat high-risk cases of HF in overweight/obese patients.

Association of ethanolamine desaturase TMEM189-plasmalogen axis with the stability of atherosclerotic plaque and cardiovascular events after acute coronary syndrome

Abstract Background Patients with acute coronary syndrome (ACS) are still at high risk of recurring major adverse cardiovascular events (MACE). Disorders of lipid metabolism play an important role in the pathogenesis and progression of ACS. However, whether there are lipid components that can play an early warning role on the recurrence of MACE in patients with ACS and its potential mechanism is not yet known. Purpose To explore the changes of lipid profile before recurrent MACE in ACS patients, screen lipid molecules related to recurrent MACE, and explore their effects on pathological changes of atherosclerotic plaque. Methods We selected 44 Chinese ACS patients from the ‘Peking and Rotterdam on Mission to Reduce Coronary Artery Disease’ (PRoMISS) study. Among them, patients with recurrent MACE within 1 year after first onset of ACS were defined as MACE group, and the control group was recruited through 1:1 matching. The lipid profile of patients was analyzed by liquid chromatography-mass spectrometry. The effects of the screened potential lipid biomarkers and their synthesis enzymes were evaluated by real-time PCR, Western blot, IHC staining and ELISA. The enzyme knockout mice and ApoE knockout mice were hybridized and bred to obtain double gene knockout mice to determine whether the enzyme deficiency affects atherosclerotic plaque. Results Lipomic analysis showed that in the MACE group, plasmalogens and their 12 subtypes continued to decrease three months before the MACE recurrence. The most critical ethanolamine desaturase in the synthesis pathway of plasmalogen, transmembrane protein 189 (TMEM189) was also significantly lower in the MACE group than in the control group, and the level of TMEM189 was positively correlated with plasmalogen. Analysis of single-cell RNA sequencing results in human carotid artery plaques shows that TMEM189 is enriched in endothelial cells and smooth muscle cells (VSMC). In VSMC, treatment with oxLDL reduced TMEM189 expression. Overexpression of TMEM189 significantly improved oxLDL induced reduction in collagen synthesis, expression of alpha-smooth muscle actin (alpha-SMA) and smooth muscle protein 22 (SM22). Overexpression of TMEM189 in VSMC, significantly reduced the content of plasmalogens in the cells. After 12 weeks of feeding with high-fat and high-cholesterol diet, it was found that the content of smooth muscle cells and vulnerability index in the aortic plaque in TMEM189 -/-ApoE -/- mice were significantly decreased than in ApoE -/- mice. Conclusions Before the recurrence of MACE in ACS patients, the synthesis pathway of plasmalogen was gradually damaged, and the reduction of plasmalogen was a potential marker for predicting the recurrence of MACE in ACS patients. The deficiency of TMEM189 - plasmalogen axis aggravates atherosclerosis, it can regulate the phenotype transformation of smooth muscle cells, inhibit their collagen synthesis, and thus affect plaque stability.

The orchestration of coding and non-coding genes at the CDH13 locus in coronary artery disease

Abstract Background The CDH13 locus was associated with coronary artery disease (CAD) by genome-wide association studies (GWAS). However, the causal gene(s) and underlying disease mechanisms at this locus remain undetermined. Purpose We intended to pinpoint and functionally validate the causal coding and non-coding genes at the CDH13 locus and delineate the underlying mechanisms for CAD. Methods and results We conducted the transcriptome-wide association analysis (TWAS) using nine types of CAD-relevant tissues from Stockholm-Tartu Atherosclerosis Reverse Network Engineering Task (STARNET) and Genotyped Tissue Expression (GTEx) projects and identified CDH13 (T-cadherin) and four long non-coding RNA (lncRNA) genes as candidate causal genes at The CDH13 locus. One of the antisense(AS) lncRNAs, CDH13-AS2, was predicted to bind on the 3’ untranslated region (UTR) of CDH13 using LncRRIsearch and RNAup servers. The binding interaction was validated by dCas13-medicated RNA immunoprecipitation. Weighted correlation network analysis (WGCNA) using transcriptomic data from CAD-relevant tissues of ~600 human subjects suggested a positive expression correlation between CDH13 and CDH13-AS2 in artery tissues. CRISPR/Cas9-based knockout (KO) of CDH13 or CDH13-AS2 in human umbilical vein endothelial cells (HUVECs) indicated synergistically atherogenic phenotypes, including reduced proliferation and migration, and increased apoptosis and monocyte adhesion. The data matched with the downregulation of CDH13 in artery samples of atherosclerosis patients. The cellular phenotypes were also in line with our in vivo data of Cdh13 and Apoe double-KO (Cdh13-/-/Apoe-/-) mice, which showed increased aortic lesion areas when fed on a high-fat diet compared to Apoe-/- mice. Furthermore, prediction using TargetScan, miRWalk, and scanMiRApp databases identified the potential binding of several EC-expression microRNAs (mir) on 3’UTR of CDH13. Several disease-associated variants were mapped to the predicted binding sites of a few microRNAs, including mir-let7, mir-30, and mir-125. The dual luciferase-based RNA interference (RNAi) assay confirmed the binding of mir-let7 on 3’UTR of CDH13. Transcriptional activation of CDH13-AS2 by the enzymatically inactivated Cas9 (dCas9) system diminished the binding of mir-let7 and increased CDH13 expression. Conclusions At the CDH13 locus, CDH13 and CDH13-AS2 are two causal genes, whose downregulation likely contributes to CAD. CDH13-AS2 bound and stabilized CDH13 partially by preventing mir-let7 mediated degradation of CDH13 mRNA, suggesting therapeutic potentials.

Irx3/5 define the cochlear sensory domain and regulate vestibular and cochlear sensory patterning in the mammalian inner ear.

The mammalian inner ear houses the vestibular and cochlear sensory organs dedicated to sensing balance and sound, respectively. These distinct sensory organs arise from a common prosensory region, but the mechanisms underlying their divergence remain elusive. Here, we showed that two evolutionarily conserved homeobox genes, Irx3 and Irx5 , are required for the patterning and segregation of the saccular and cochlear sensory domains, as well as for the formation of auditory sensory cells. Irx3/5 were highly expressed in the cochlea, their deletion resulted in a significantly shortened cochlea with a loss of the ductus reuniens that bridged the vestibule and cochlea. Remarkably, ectopic vestibular hair cells replaced the cochlear non-sensory structure, the Greater Epithelial Ridge. Moreover, most auditory sensory cells in the cochlea were transformed into hair cells of vestibular identity, with only a residual organ of Corti remaining in the mid-apical region of Irx3/5 double knockout mice. Conditional temporal knockouts further revealed that Irx3/5 are essential for controlling cochlear sensory domain formation before embryonic day 14. Our findings demonstrate that Irx3/5 regulate the patterning of vestibular and cochlear sensory cells, providing insights into the separation of vestibular and cochlear sensory organs during mammalian inner ear development.

MBNL deficiency in motor neurons disrupts neuromuscular junction maintenance and gait coordination.

Muscleblind-like proteins (MBNLs) are a family of RNA-binding proteins that play essential roles in the regulation of RNA metabolism. Beyond their canonical role in RNA regulation, MBNL proteins have emerged as key players in the pathogenesis of Myotonic Dystrophy type 1 (DM1). In DM1, sequestration of MBNL proteins by expansion of the CUG repeat RNA leads to functional depletion of MBNL, resulting in deregulated alternative splicing and aberrant RNA processing, which underlie the clinical features of the disease. While attention to MBNL proteins has focused on their functions in skeletal muscle, new evidence suggests that their importance extends to motor neurons (MNs), pivotal cellular components in the control of motor skills and movement. To address this question, we generated conditional double knockout mice in which Mbnl1 and Mbnl2 were specifically deleted in motor neurons (MN-dKO). Adult MN-dKO mice develop gait coordination deficits associated with structural and ultrastructural defects in the neuromuscular junction, indicating that MBNL activity in MNs is crucial for the maintenance of the neuromuscular junction. In addition, transcriptome analysis performed on the spinal cord of MN-dKO mice identified mis-splicing events in genes associated with synaptic transmission and neuromuscular junction homeostasis. In summary, our results highlight the complex roles and regulatory mechanisms of MBNL proteins in MNs for muscle function and locomotion. This work provides valuable insights into fundamental aspects of RNA biology and offers promising avenues for therapeutic intervention in DM1 as well as a range of diseases associated with RNA dysregulation.

Deficiency of GPR10 and NPFFR2 receptors leads to sex-specific prediabetic syndrome and late-onset obesity in mice.

GPR10 and neuropeptide FF receptor 2 (NPFFR2) play important role in the regulation of food intake and energy homeostasis. Understanding the interaction between these receptors and their specific ligands, such as prolactin-releasing peptide, is essential for developing stable peptide analogs with potential for treating obesity. By breeding and characterizing double knockout (dKO) mice fed standard or high-fat diet (HFD), we provide insights into the metabolic regulation associated with the GPR10 and NPFFR2 deficiency. Both WT and dKO mice were subjected to behavioral tests and an oral glucose tolerance test. Moreover, dual-energy X-ray absorptiometry (DEXA) followed by indirect calorimetry were performed to characterize dKO mice. dKO mice of both sexes, when exposed to an HFD, showed reduced glucose tolerance, hyperinsulinemia, and insulin resistance compared with controls. Moreover, they displayed increased liver weight with worsened hepatic steatosis. Mice displayed significantly increased body weight, which was more pronounced in dKO males and caused by higher caloric intake on a standard diet, while dKO females displayed obesity characterized by increased white adipose tissue and enhanced hepatic lipid accumulation on an HFD. Moreover, dKO females exhibited anxiety-like behavior in the open field test. dKO mice on a standard diet had a lower respiratory quotient, with no significant changes in energy expenditure. These results provide insights into alterations associated with disrupted GPR10 and NPFFR2 signaling, contributing to the development of potential anti-obesity treatment.

Latexin deficiency limits foam cell formation and ameliorates atherosclerosis by promoting macrophage phenotype differentiation

Latexin (LXN) is abundant in macrophages and plays critical roles in inflammation. Much is known about macrophages in atherosclerosis, the role of macrophage LXN in atherosclerosis has remained elusive. Here, the expression of LXN in human and mouse atherosclerotic lesions was examined by immunofluorescence and immunohistochemistry. LXN knockout and LXN/ApoE double-knockout mice were generated to evaluate the functions of LXN in atherosclerosis. Bone marrow transplantation (BMT) experimentation was carried out to determine whether macrophage LXN regulates atherosclerosis. We found that LXN is enriched in human and murine atherosclerotic lesions, mainly localized to macrophages. LXN deletion ameliorated atherosclerosis in ApoE-/- mice. BMT demonstrate that deletion of LXN in bone marrow protects ApoE-/- mice against atherosclerosis. Mechanistically, we found that LXN targets and inhibits JAK1 in macrophages. LXN deficiency stimulates the JAK1/STAT3/ABC transporter pathway, thereby enhancing the anti-inflammatory and anti-oxidant phenotype, cholesterol efflux, subsequently minimizing foam cell formation and atherosclerosis. Gene therapy by treatment of atherosclerotic mice with adeno-associated virus harbouring LXN-depleting shRNA attenuated the disease phenotype. In summary, our study provides new clues for the role of LXN in the pathological regulation of atherosclerosis, and determines that LXN is a target for preventing atherosclerosis, which may be a potential new anti-atherosclerosis therapeutic target.

YTHDC1-mediated microRNA maturation is essential for hematopoietic stem cells maintenance

YTHDC1, a reader of N6-methyladenosine (m6A) modifications on RNA, is posited to exert significant influence over RNA metabolism. Despite its recognized importance, the precise function and underlying mechanisms of YTHDC1 in the preservation of normal hematopoietic stem cell (HSCs) homeostasis remain elusive. Here, we investigated the role of YTHDC1 in normal hematopoiesis and HSCs maintenance in vivo. Utilizing conditional Ythdc1 knockout mice and Ythdc1/Mettl3 double knockout mice, we demonstrated that YTHDC1 is required for HSCs maintenance and self-renewal by regulating microRNA maturation. YTHDC1 deficiency resulted in HSCs apoptosis. Furthermore, we uncovered that YTHDC1 interacts with HP1BP3, a nuclear RNA binding protein involved in microRNA maturation. Deletion of YTHDC1 brought about significant alterations in microRNA levels. However, over-expression of mir-125b, mir-99b, and let-7e partially rescued the functional defect of YTHDC1-null HSCs. Taken together, these findings indicated that the nuclear protein YTHDC1-HP1BP3-microRNA maturation axis is essential for the long-term maintenance of HSCs.

Limited Alleviation of Lysosomal Acid Lipase Deficiency by Deletion of Matrix Metalloproteinase 12.

Lysosomal acid lipase (LAL) is the only known enzyme that degrades cholesteryl esters and triglycerides at an acidic pH. In LAL deficiency (LAL-D), dysregulated expression of matrix metalloproteinase 12 (MMP-12) has been described. The overexpression of MMP-12 in myeloid lineage cells causes an immune cell dysfunction resembling that of Lal knockout (Lal KO) mice. Both models develop progressive lymphocyte dysfunction and expansion of myeloid-derived suppressor (CD11b+ Gr-1+) cells. To study whether MMP-12 might be a detrimental contributor to the pathology of LAL-D, we have generated Lal/Mmp12 double knockout (DKO) mice. The phenotype of Lal/Mmp12 DKO mice closely resembled that of Lal KO mice, while the weight and morphology of the thymus were improved in Lal/Mmp12 DKO mice. Cytological examination of blood smears showed a mildly reversed lymphoid-to-myeloid shift in DKO mice. Despite significant decreases in CD11b+ Ly6G+ cells in the peripheral blood, bone marrow, and spleen of Lal/Mmp12 DKO mice, the hematopoietic bone marrow progenitor compartment and markers for neutrophil chemotaxis were unchanged. Since the overall severity of LAL-D remains unaffected by the deletion of Mmp12, we conclude that MMP-12 does not represent a viable target for treating the inflammatory pathology in LAL-D.

ASGR1 Deficiency Inhibits Atherosclerosis in Western Diet-Fed ApoE-/- Mice by Regulating Lipoprotein Metabolism and Promoting Cholesterol Efflux.

Atherosclerosis is the most common cause of cardiovascular diseases. Clinical studies indicate that loss-of-function ASGR1 (asialoglycoprotein receptor 1) is significantly associated with lower plasma cholesterol levels and reduces cardiovascular disease risk. However, the effect of ASGR1 on atherosclerosis remains incompletely understood; whether inhibition of ASGR1 causes liver injury remains controversial. Here, we comprehensively investigated the effects and the underlying molecular mechanisms of ASGR1 deficiency and overexpression on atherosclerosis and liver injury in mice. We engineered Asgr1 knockout mice (Asgr1-/-), Asgr1 and ApoE double-knockout mice (Asgr1-/-ApoE-/-), and ASGR1-overexpressing mice on an ApoE-/- background and then fed them different diets to assess the role of ASGR1 in atherosclerosis and liver injury. After being fed a Western diet for 12 weeks, Asgr1-/-ApoE-/- mice exhibited significantly decreased atherosclerotic lesion areas in the aorta and aortic root sections, reduced plasma VLDL (very-low-density lipoprotein) cholesterol and LDL (low-density lipoprotein) cholesterol levels, decreased VLDL production, and increased fecal cholesterol contents. Conversely, ASGR1 overexpression in ApoE-/- mice increased atherosclerotic lesions in the aorta and aortic root sections, augmented plasma VLDL cholesterol and LDL cholesterol levels and VLDL production, and decreased fecal cholesterol contents. Mechanistically, ASGR1 deficiency reduced VLDL production by inhibiting the expression of MTTP (microsomal triglyceride transfer protein) and ANGPTL3 (angiopoietin-like protein 3)/ANGPTL8 (angiopoietin-like protein 8) but increasing LPL (lipoprotein lipase) activity, increased LDL uptake by increasing LDLR (LDL receptor) expression, and promoted cholesterol efflux through increasing expression of LXRα (liver X receptor-α), ABCA1 (ATP-binding cassette subfamily A member 1), ABCG5 (ATP-binding cassette subfamily G member 5), and CYP7A1 (cytochrome P450 family 7 subfamily A member 1). These underlying alterations were confirmed in ASGR1-overexpressing ApoE-/- mice. In addition, ASGR1 deficiency exacerbated liver injury in Western diet-induced Asgr1-/-ApoE-/- mice and high-fat diet-induced but not normal laboratory diet-induced and high-fat and high-cholesterol diet-induced Asgr1-/- mice, while its overexpression mitigated liver injury in Western diet-induced ASGR1-overexpressing ApoE-/- mice. Inhibition of ASGR1 inhibits atherosclerosis in Western diet-fed ApoE-/- mice, suggesting that inhibiting ASGR1 may serve as a novel therapeutic strategy to treat atherosclerosis and cardiovascular diseases.

An in vitro and in vivo efficacy evaluation of gene therapy candidate SBT101 in mouse models of adrenomyeloneuropathy and in NHPs

Adrenomyeloneuropathy is a progressive neurodegenerative disease caused by pathogenic variants in the ABCD1 gene, resulting in very-long-chain fatty acid (VLCFA) accumulation that leads to dying-back axonopathy. Our candidate gene therapy, SBT101 (AAV9-human ABCD1 [hABCD1]), aims to ameliorate pathology by delivering functional copies of hABCD1 to the spinal cord. Transduced cells produce functional ABCD1 protein, thereby repairing the underlying biochemical defect. Invitro and invivo mouse studies were conducted to assess the biochemical and functional efficacy of SBT101 and show effective delivery to target tissues involved in the disease pathology: spinal cord and dorsal root ganglia. Administration of SBT101 to mixed glial cell cultures from Abcd1-Null mice, and to male Abcd1 knockout (Abcd1 -/y ) and double-knockout (Abcd1 -/y /Abcd2 -/- ) mice led to increased hABCD1 production and reduced VLCFA. Double-knockout mice also exhibited improved grip strength. Furthermore, we conducted biodistribution and safety assessments in nonhuman primates. Six-hour intrathecal lumbar infusions demonstrated effective transduction throughout target tissues,supporting the clinical feasibility of the procedure. SBT101 was well tolerated, with no observed SBT101-relatedmortality or clinical signs. These findings not only providepreclinical efficacy data for SBT101 but also inform clinically relevant SBT101 dose selection for patients with adrenomyeloneuropathy.

Bone quality relies on hyaluronan synthesis – Insights from mice with complete knockout of hyaluronan synthase expression

Bone consists of a complex mineralised matrix that is maintained by a controlled equilibrium of synthesis and resorption by different cell types. Hyaluronan (HA) is an important glycosaminoglycan in many tissues including bone.Previously, the importance of HA synthesis for bone development during embryogenesis has been shown. We therefore investigated whether HA synthesis is involved in adult bone turnover and whether abrogation of HA synthesis in adult mice would alter bone quality.To achieve complete abrogation of HA synthesis in adult mice, we generated a novel Has-total knockout (Has-tKO) mouse model in which a constitutive knockout of Has1 and Has3 was combined with an inducible, Ubc-Cre-driven Has2 knockout.By comparing bone tissue from wild-type, Has1,3 double knockout and Has-tKO mice, we demonstrate that Has2-derived HA mainly contributes to the HA content in bone. Furthermore, Has-tKO mice show a significant decrease of bone integrity in trabecular and cortical bone, as shown by µ-CT analysis. These effects are detectable as early as five weeks after induced Has2 deletion, irrespective of sex and progress with age.Mesenchymal stem cells (MSC) during osteogenic differentiation in vitro showed that Has2 expression is increased while Has3 expression is decreased during differentiation. Furthermore, the complete abrogation of HA synthesis results in significantly reduced osteogenic differentiation as indicated by reduced marker gene expression (Runx-2, Tnalp, Osterix) as well as alizarin red staining. RNAseq analysis revealed that MSC from Has-tKO are characterised by decreased expression of genes annotated for bone and organ development, whereas expression of genes associated with chemokine related interactions and cytokine signalling is increased.Taken together, we present a novel mouse model with complete deletion of HA synthases in adult mice which has the potential to study HA function in different organs and during age-related HA reduction. With respect to bone, HA synthesis is important for maintaining bone integrity, presumably based on the strong effect of HA on osteogenic differentiation.

Comprehensive model for simultaneous monitoring of primary tumor to metastatic cancer utilizing Prkdc and Il2rg double knockout mice

Liver cancer is the second leading cause of cancer-related deaths worldwide, motivating major scientific efforts to understand and treat this cancer type. Over 30% of patients with liver cancer progress to metastasis, which reduces the survival rate. Extensive studies on primary tumors have been conducted to improve the prognosis. However, there is a lack of appropriate and accessible models for studying the progression and metastasis of liver cancer. Moreover, conventional metastasis models do not reproduce metastasis as it occurs in patients. To address this lack of an appropriate model for the monitoring of cancer progression and evaluation of anticancer drugs, we established a spontaneous metastatic xenograft model using NSG mice subcutaneously transplanted with SK-Hep-1 cells. Compared to the conventional experimental metastasis model (intravenous transplantation), in which only lung metastasis was observed, the established spontaneous metastatic xenograft model was superior, as it showed both a primary tumor and metastatic patterns similar to those observed in human patients. Additionally, this model was successfully used to assess the antimetastatic efficacy of sorafenib. In conclusion, our results demonstrate that the established spontaneous metastatic xenograft model better reflects liver cancer metastasis and can be utilized to assess the efficacy of anticancer drugs for liver cancer.