Project description:RNF213 is a large, poorly characterized interferon-induced protein. Mutations in RNF213 are associated with predisposition for Moyamoya disease (MMD), a rare cerebrovascular disorder. Recently, RNF213 was found to have broad antimicrobial activity in vitro and in vivo, yet the molecular mechanisms behind this function remain unclear. Using mass spectrometry-based proteomics and validation by real-time PCR we here report that knockdown of RNF213 leads to transcriptional upregulation of MVP and downregulation of CYR61, in line with reported pro- and anti-bacterial activities of these proteins. Knockdown of RNF213 also results in downregulation of DDAH1, which we discover to exert anti-microbial activity against Listeria monocytogenes infection. DDAH1 regulates production nitric oxide (NO), a molecule with both vascular and antimicrobial effects. We show that NO production is reduced in macrophages from RNF213 KO mice, suggesting that RNF213 controls Listeria infection through regulation of DDAH1 transcription and production of NO. Our findings propose a potential mechanism for the antilisterial activity of RNF213 and highlight NO as a potential link between RNF213-mediated immune responses and the development of MMD.

Project description:Alternative splicing analysis of laser micro-dissected lung dysplasia RNA samples Lung dysplasia is a precancerous condition with high risk of malignant transformation. Little is known about alternative spliced (AS) genes in dysplasia. We therefore investigated laser micro-dissected microscopic foci of non-contaminant dysplasia and/or lung adenocarcinoma of c-Raf transgenic mice and searched genome wide for AS genes using exon arrays. Notably, bioinformatics defined 34 and 36 AS genes in the comparison dysplasia versus transgenic unaltered and non-transgenic lung tissue while the comparison adenocarcinoma versus transgenic unaltered and non-transgenic lung tissue revealed 54 and 56 genes, respectively. So far only 6 of these were reported for lung cancer. Importantly, dysplasia related AS genes were also regulated in lung cancer to suggest a role in disease onset. Next to exon skipping/inclusion alternative splicing at the 3M-bM-^@M-^Y and 5M-bM-^@M-^Y was common and included genes of the splicing regulatory pathway. Disease dependent changes of variant transcripts were confirmed by RT-PCR while Western blotting identified alternative splicing to modulate protein levels of AS genes. For the AS genes Add3, Cast, Osbpl6, Nedd4l, Numb, Picalm and Slk transcript and protein level agreed well, whereas for Arhgef11, Clstn1, Dlg1, Dock9, Mbnl2, Mfge8, Npnt, Pdlim5, Ppp2r5c, Tjp1 notable differences in the abundance of variant transcripts were observed by RT-PCR and gel electrophoresis. Moreover, expression of individual variants differed between dysplasia and carcinoma to suggest their disease dependent regulation. Western blotting of IQGAP1, MYO6, PTPRM, RABGAP1L and RAD50 confirmed significant regulation of isoforms in lung cancer as compared to non-transgenic, transgenic unaltered and dysplastic lung tissue. For 46 AS genes expression of the non-variant protein was reported in human lung cancer (www.proteinatlas.org) and for 13 of these, cancer related AS events are known. Overall, new insight into lung dysplasia was obtained with 43 new cancer related AS genes to aid diagnosis and molecular intervention strategies. We analyzed and compared dysplastic (n=4) and adenocarcinoma (n=4) lesions and with transgenic but unaltered (n=4) and non-transgenic (n=5) lung tissue obtained from SPC/c-Raf transgenic mice with aid of laser micro dissection pressure catapulted (LMPC) technique. Dysplasia is a pre-neoplastic condition and developed at 5 month of age in the proposed mouse model. LMPC provides precise microscopic lesion collection without contamination. The RNA samples were analyzed using the Affymetrix Mouse Exon 1.0 ST platform. Alternative splicing was analyzed using Biotique XRAY tool. No technical replicates were performed.

Project description:RNF213 is the major susceptibility factor for Moyamoya disease, a progressive cerebrovascular disorder that often leads to brain stroke in adults and children. Characterization of disease-associated mutations has been complicated by the enormous size of RNF213. Here we present the cryo-EM structure of mouse RNF213. The structure reveals the intricate fold of the 584 kDa protein, comprising an N-terminal stalk, a dynein-like core with six ATPase units, and a multidomain E3 module. Collaboration with UbcH7, a cysteine-reactive E2, points to an unexplored ubiquitin-transfer mechanism that proceeds in a RING-independent manner. Moreover, we show that pathologic MMD mutations cluster in the composite E3 domain, likely interfering with substrate ubiquitination. In conclusion, the structure of RNF213 uncovers a distinct type of an E3 enzyme, highlighting the growing mechanistic diversity in ubiquitination cascades. Our results also provide the molecular framework for investigating the emerging role of RNF213 in lipid metabolism, hypoxia, and angiogenesis.

Project description:Alternative splicing analysis of laser micro-dissected lung dysplasia RNA samples Lung dysplasia is a precancerous condition with high risk of malignant transformation. Little is known about alternative spliced (AS) genes in dysplasia. We therefore investigated laser micro-dissected microscopic foci of non-contaminant dysplasia and/or lung adenocarcinoma of c-Raf transgenic mice and searched genome wide for AS genes using exon arrays. Notably, bioinformatics defined 34 and 36 AS genes in the comparison dysplasia versus transgenic unaltered and non-transgenic lung tissue while the comparison adenocarcinoma versus transgenic unaltered and non-transgenic lung tissue revealed 54 and 56 genes, respectively. So far only 6 of these were reported for lung cancer. Importantly, dysplasia related AS genes were also regulated in lung cancer to suggest a role in disease onset. Next to exon skipping/inclusion alternative splicing at the 3’ and 5’ was common and included genes of the splicing regulatory pathway. Disease dependent changes of variant transcripts were confirmed by RT-PCR while Western blotting identified alternative splicing to modulate protein levels of AS genes. For the AS genes Add3, Cast, Osbpl6, Nedd4l, Numb, Picalm and Slk transcript and protein level agreed well, whereas for Arhgef11, Clstn1, Dlg1, Dock9, Mbnl2, Mfge8, Npnt, Pdlim5, Ppp2r5c, Tjp1 notable differences in the abundance of variant transcripts were observed by RT-PCR and gel electrophoresis. Moreover, expression of individual variants differed between dysplasia and carcinoma to suggest their disease dependent regulation. Western blotting of IQGAP1, MYO6, PTPRM, RABGAP1L and RAD50 confirmed significant regulation of isoforms in lung cancer as compared to non-transgenic, transgenic unaltered and dysplastic lung tissue. For 46 AS genes expression of the non-variant protein was reported in human lung cancer (www.proteinatlas.org) and for 13 of these, cancer related AS events are known. Overall, new insight into lung dysplasia was obtained with 43 new cancer related AS genes to aid diagnosis and molecular intervention strategies.

Project description:Transcriptome analysis of vascular smooth muscle cells differentiated from iPS-derived neural crest stem cells in Moyamoya disease Moyamoya disease (MMD) is a rare cerebrovascular disorder characterized by steno-occlusive changes in the cerebral arteries at the base of the brain with unknown etiology, although histopathological features have demonstrated as fibrocellular thickening of the intima and medial thinning on the steno-occlusive arteries. However, the pathophysiology of proliferating cells in the thickened intima is still obscure. Furthermore, biological features of the vascular smooth muscle cells are unclear in MMD. Here, we aimed to analyze whole genome gene expression profile in VSMC using induced pluripotent stem (iPS) cell line. We generated iPS cell line from the blood of MMD with RNF213 R4810K risk allele (rs112735431) or healthy control without the risk allele. VSMCs were differentiated from iPS-derived neural crest stem cells. As a result, we successfully established cranio-cervical region specific VSMC confirmed by immunocytochemistry. Biological cellular features, including cellular proliferation, migration, and contraction ability were similar in VSMCs between MMD and control. Genome-wide gene expression analysis showed similar transcriptome profile in the VSMCs between MMD and control. Differential gene expression analysis in MMD-VSMC revealed 6 differentially expressed genes (4 upregulated, 2 down regulated in MMD), including decorin (DCN, upregulated in MMD), playing an inhibitory role in angiogenesis. In conclusion, VSMCs are not impaired in cellular function with similar transcriptome profile in MMD compared to healthy control. Since many previous studies have shown impaired EC features in MMD, our study suggests EC may play more role in the vascular pathogenesis in MMD rather than VSMC.

Project description:We aim to investigate circulating genome-wide microRNA (miRome) profiles in Moyamoya disease (MMD)-discordant monozygotic (MZ) twins with the RNF213 founder mutation (rs112735431).A disease discordant monozygotic twin-based study design may unmask potential confounders from previously published circulating microRNA signature in MMD. Circulating genome-wide microRNA (miRNome) profiling was performed in MMD-discordant monozygotic twins, non-twin-MMD patients, and non-MMD healthy volunteers by microarray followed by qPCRvalidation, using blood samples. Differential plasma-microRNAs were further quantified in endothelial cells differentiated from iPS cell lines (iPSECs) derived from another independent non-twin cohort. Lastly, their target gene expression in the iPSECs was analyzed. Microarray detected 309 plasma-microRNAs in MMD-discordant monozygotic twins that were also detected in the non-twin cohort. Principal component analysis of the plasma-microRNA expression level demonstrated distinct 2 groups separated by MMD and healthy control in the twin- and non-twin cohorts. Of these, differential up-regulations of hsa-miR-6722-3p/-328-3p were validated in the plasma of MMD (Imposed threshold: absolute log2 expression fold change (logFC) > 0.26 for the twin cohort; absolute logFC > 0.26, p < 0.05, and q < 0.15 for the non-twin cohort). In MMD derived iPSECs, hsa-miR-6722-3p/-328-3p showed a trend of up-regulation with a 3.0- or higher expression fold change. Bioinformatics analysis revealed that 41 target genes of miR- 6722-3p/-328-3p were significantly down-regulated in MMD derived iPSECs and were involved in STAT3, IGF-1-, and PTEN-signaling, suggesting a potential microRNA- gene expression interaction between circulating plasma and endothelial cells. In conclusion, our MMD-discordant monozygotic twin-based study confirmed a novel circulating microRNA signature in MMD as a potential diagnostic biomarker minimally confounded by genetic heterogeneity. The novel circulating microRNA signature can contribute for the future functional microRNA analysis to find new diagnostic and therapeutic target of MMD.

Project description:The tumor microenvironment (TME) typically includes hypoxic regions. Hypoxic cancer cells are resistant to many anti-neoplastic therapies and can seed recurrence; consequently, understanding how they survive could yield new therapeutic strategies. In response to decreasing oxygen, cells are known to successively activate hypoxia-inducible factor 1-alpha (HIF1alpha), endoplasmic reticulum (ER) stress, and AMP-dependent protein kinase (AMPK). We previously identified an additional pathway in which the protein-tyrosine phosphatase PTP1B (encoded by PTPN1) prevents the death of HER2+ breast cancer cells exposed to severe hypoxia (O2<1%) by inhibiting RNF213, a large (~600 kDa) E3 ubiquitin ligase containing two functional AAA-ATPase domains and two ubiquitin ligase domains (RING and RZ) that also is implicated in Moyamoya disease (MMD), lipotoxicity, and innate immunity. These findings provided a potential explanation for earlier observations that Ptpn1-/- mice are resistant to Neu (rodent HER2)-induced breast cancer, but how PTP1B regulates RNF213, the identity(ies) of RNF213 targets, the mechanism of cell death, and the relevance to other RNF213 actions remained unclear. Via proximity-based proteomics, we identified the CYLD-SPATA2 complex, a major negative regulator of NF-kappaB activation, as an RNF213 substrate critical for hypoxia-induced cell death. Here we show that PTP1B and ABL1/2 reciprocally control the phosphorylation of RNF213 on Tyrosine-1275. Phosphorylation of this site promotes RNF213 oligomerization, resulting in RZ domain activation, LUBAC complex-dependent ubiquitylation and degradation of the CYLD/SPATA2 deubiquitinase complex, and NF-kappaB activation. NF-kappaB induces NLRP3 inflammasome priming, and concomitant hypoxia-induced ER stress triggers inflammasome activation, resulting in pyroptotic cell death. Mutagenesis experiments show that the RNF213 RING negatively regulates the RZ domain, and RING domain mutants, including those associated with MMD, catalyze LUBAC-independent CYLD/SPATA2 degradation. Our results identify a novel PTP1B/RNF213/CYLD/SPATA2 pathway responsible for the pyroptotic death of hypoxic tumor cells, reveal new insights into RNF213 regulation, and have potentially important implications for the pathogenesis of MMD, atherosclerosis, and inflammatory and auto-immune disorders. The mass spectrometry raw files for the phosphorylation identification and proximity labeling results are included here.

Project description:Genetic variants in LZTR1 are associated with the development of Noonan syndrome. Here, we analyzed the proteome of cultured cardiomyocytes derived from hiPSCs with a pathological homozygous LZTR1 variant L580P in comparison to heterozygous and homozygous CRISPR/Cas9-corrected iPSC lines.

Project description:Truncating variants in titin can cause dilated cardiomyopathy, however, the role of missense titin variants is less clear. In humans the heterozygous titin A178D variant is associated with dilated cardiomyopathy with left ventricular non-compaction. Using CRISPR-Cas9 mediated homology-directed repair the A178D titin variant was introduced into a mouse model. Homozygous A178D mice showed features of dilated cardiomyopathy. Total RNA was extracted from the left ventricles of WT and homozygous A178D littermate control mice and RNA-sequencing performed. Different patterns of gene expression were identified in wildtype and homozygous A178D left ventricles.

Project description:Knockin mice were created that contained a point mutation that elminated the requisite GT in the 5' donor site of each of the NCoRω or NCoRδ splice variants, thus preventing splicing at that site and forcing splicing of the reciprocal splice variant.