Project description:Multisystem smooth muscle dysfunction syndrome (MSMDS) is a smooth muscle myopathy with major dysfunction in multiple organ systems. Described cases have been exclusively associated with recurrent missense variants at amino acid position 179 in the ACTA2 gene. We describe a patient with multiple major manifestations of MSMDS including steno-occlusive cerebrovascular arteriopathy, prune belly syndrome, gastrointestinal dysmotility, bladder dysfunction, and pupillary hyporeactivity without variation in ACTA2. Whole genome sequencing revealed a single nucleotide variant contained within the seed sequence of MIR145, which encodes the smooth muscle associated microRNA; hsa-miR-145-5p. RNA expression analysis on patient-derived fibroblasts was consistent with actin cytoskeletal dysfunction, and mutant miR-145-5p was unable to mediate cytoskeletal modulation of smooth muscle cells. MSMDS can be caused by a loss-of-function mutation in the smooth muscle differentiation factor, miR-145-5p, the first described non-coding genetic vasculopathy.

Project description:BACKGROUND: Vascular smooth muscle cells (vSMCs), the predominant cell type in the aortic wall, play a crucial role in maintaining aortic integrity, blood pressure, and cardiovascular function. vSMC contractility and function depend on smooth muscle alpha-actin 2 (ACTA2). The pathogenic variant ACTA2 c.536G>A (p. R179H) causes multisystemic smooth muscle dysfunction syndrome (MSMDS), a severe disorder marked by widespread smooth muscle abnormalities, resulting in life-threatening aortic disease and high risk early mortality from aneurysms or stroke. No effective treatments exist for MSMDS. METHODS: To develop a comprehensive therapy for MSMDS, we utilized CRISPR-Cas9 adenine base editing to correct the ACTA2 R179H mutation. We generated isogenic human induced pluripotent stem cell (iPSC) lines and humanized mice carrying this pathogenic missense mutation. iPSC-SMCs were evaluated for key functional characteristics, including proliferation, migration, and contractility. The adenine base editor (ABE) ABE8e-SpCas9-VRQR under control of either a SMC-specific promoter or a CMV promoter, and an optimized single guide RNA (sgRNA) under control of U6 promoter were delivered intravenously to humanized R179H mice using adeno-associated virus serotype 9 (AAV9) and phenotypic outcomes were evaluated. RESULTS: The R179H mutation causes a dramatic phenotypic switch in human iPSC-SMCs from a contractile to a synthetic state, a transition associated with aneurysm formation. Base editing prevented this pathogenic phenotypic switch and restored normal SMC function. In humanized mice, the ACTA2R179H/+ mutation caused widespread smooth muscle dysfunction, manifesting as decreased blood pressure, aortic dilation and dissection, bladder enlargement, gut dilation, and hydronephrosis. In vivo base editing rescued these pathological abnormalities, normalizing smooth muscle function. CONCLUSIONS: This study demonstrates the effectiveness of adenine base editing to treat MSMDS and restore aortic smooth muscle function. By correcting the ACTA2 R179H mutation, the pathogenic phenotypic shift in SMCs was prevented, key aortic smooth muscle functions were restored, and life-threatening aortic dilation and dissection were mitigated in humanized mice. These findings underscore the promise of gene-editing therapies in addressing the underlying genetic causes of smooth muscle disorders and offer a potential transformative treatment for patients facing severe vascular complications.

Project description:In response to myocardial infarction (MI), quiescent cardiac fibroblasts differentiate into myofibroblasts mediating tissue repair in the infarcted area. One of the most widely accepted markers of myofibroblast differentiation is the expression of Acta2 which encodes smooth muscle alpha-actin (SMαA) that is assembled into stress fibers. However, the requirement of Acta2/ SMαA in the myofibroblast differentiation of cardiac fibroblasts and its role in post-MI cardiac repair remained largely unknown. To answer these questions, we generated a tamoxifen-inducible cardiac fibroblast-specific Acta2 knockout mouse line. Surprisingly, mice that lacked Acta2 in cardiac fibroblasts had a normal survival rate after MI. Moreover, Acta2 deletion did not affect the function or overall histology of infarcted hearts. No difference was detected in the proliferation, migration, or contractility between WT and Acta2-null cardiac myofibroblasts. It was identified that Acta2-null cardiac myofibroblasts had a normal total filamentous actin level and total actin level. Acta2 deletion caused a significant compensatory increase in the transcription level of non- Acta2 actin isoforms, especially Actg2 and Acta1, 2 other muscle actin isoforms. Moreover, in myofibroblasts the transcription levels of cytoplasmic actin isoforms were significantly higher than those of muscle actin isoforms. In addition, we found that myocardin-related transcription factor-A is critical for myofibroblast differentiation but is not required for the compensatory effects of non-Acta2 isoforms. In conclusion, the deletion of Acta2 does not prevent the myofibroblast differentiation of cardiac fibroblasts or affect the post-MI cardiac repair, and the increased expression and stress fiber formation of non-SMαA actin isoforms and the functional redundancy between actin isoforms are able to compensate for the loss of Acta2 in cardiac myofibroblasts.

Project description:Myotonic dystrophy type 1 (DM1) is the most common adult-onset muscular dystrophy and severely affects multiple organ systems, including the brain, heart, skeletal muscle, and gastrointestinal (GI) tract. Despite 80% of individuals with DM1 experiencing GI dysfunction that affects their daily life, the mechanisms of GI dysmotility in DM1 remain an understudied aspect of the disease. DM1 is caused by a CTG repeat expansion in the DMPK gene that, when expressed as an expanded CUG repeat RNA, sequesters and reduces the activity of the muscleblind-like (MBNL) RNA-binding protein family. We developed a mouse line with conditional, smooth muscle-specific knockout of Mbnl1 and Mbnl2 to model and investigate myogenic mechanisms contributing to GI dysmotility in DM1. Mice with Mbnl knockout exhibited delayed GI transit of small and large bowel in vivo and increased smooth muscle contractile tone of jejunum and colon segments ex vivo. Smooth muscle from jejunum and colon showed no histopathologic changes and contained increased phosphorylation of the 20 kDa myosin light chain (Mlc20), consistent with increased contraction. RNA sequencing of mouse and human DM1 GI samples enriched for smooth muscle revealed conserved misregulated alternative splicing of transcripts associated with the regulation of Mlc20 phosphorylation and smooth muscle contraction. These findings demonstrate that Mbnl KO disrupts the regulation of contraction dynamics and causes GI smooth muscle hyperactivity, suggesting that therapeutics that reduce GI contractile activity may help alleviate DM1 GI symptoms.

Project description:Smooth muscle cells exist in many different locations within the body, including blood vessels and airways. The heterogeneity of smooth muscle cells has been related to their embryological origins and could have implications in many diseases, including atherosclerosis, pulmonary hypertension, and asthma. Here we aimed to study the heterogeneity of Acta2+ cells in the mouse lung and to identify specific markers for Acta2+ sub-populations. We used a mouse line containing an Acta2hrGFP/Cspg4dsRed reporter and performed single cell RNA sequencing of Acta2+ cells isolated from adult mouse lungs. We identified 3 main distinct clusters, corresponding to airway smooth muscle (ASM), vascular smooth muscle (VSM) and mesenchymal alveolar niche cells (MANCs), and extracted specific gene signatures for each of these cell types. Our dataset and gene signatures help address the heterogeneity of Acta2+ lineages in the lung and will be of use for future studies focusing on smooth muscle cells in the lung and in other organs.

Project description:Single-cell RNA datasets for aortic tissue from 8-week-old inducible smooth muscle cell-specific knock-in of Acta2 R179C mutation vs. littermate controls and aortic aneurysm tissue from a human patient carrying an ACTA2 R179H variant vs. a pediatric organ donor healthy control.

Project description:Functional gastrointestinal disorders (FGIDs) affect ∼40% of the global population and are frequently characterized by colonic dysmotility. Symptomatic manifestations of colonic dysmotility significantly reduce quality of life in inflammatory bowel disease (IBD), diabetes, and Gulf War Illness (GWI). Current in vitro models lack the integration of functional physiology with immune and neuronal complexity required to establish causal links between neuroinflammation and dysmotility. Here, an immune-competent bioengineered colon assembloid is introduced that integrates multiple cell types of the external colonic wall, along with functional readouts of motility. Within bioengineered colon assembloids, various inflammatory insults resulted in enteric neuroinflammation, cascading to changes in colonic motility. Key mechanisms of dysmotility following inflammatory insult within the bioengineered colon assembloids included impaired neuronal regeneration, and aberrant smooth muscle remodeling. The bioengineered colon assembloid model mimicked diverse aspects of enteric neuroinflammation. Ultimately, the platform offers a physiologically relevant avenue to interrogate neuroimmune crosstalk and dissect mechanisms of colonic dysmotility, paving the way to new therapeutic strategies to improve colonic motility.

Project description:Genomic editing of a pathogenic mutation in ACTA2 rescues multisystemic smooth muscle dysfunction syndrome

Project description:Lung smooth muscle cells are including bronchiolar and vascular smooth muscle cells. In order to get adult lung smooth muscle cells, we use transgenic mouse line with smooth muscle actin creERT2, which is a transgenic cre recombinase in Acta2 (contractile smooth muscle cell gene). This mouse line also contains a CAG promoter-driven red fluorescent protein variant (tdTomato) - all inserted into the ROSA26 locus. This mouse line express robust tdTomato fluorescence following cre-mediated recombination after Tamoxifen injection.

Project description:Background/ Aim: Diabetes has substantive co-occurrence with disorders of gut-brain interactions (DGBIs). The pathophysiological and molecular mechanisms linking diabetes and DGBIs are unclear. miRNAs are key regulators of diabetes and gut dysmotility. We investigated whether impaired gut barrier function regulated by a key miRNA, miR-10b-5p, links diabetes and gut dysmotility. Methods: We created a new mouse line using the Mb3Cas12a/Mb3Cpf1 endonuclease to knock out mir-10b globally. Loss of function studies were conducted to characterize diabetes, gut dysmotility, and gut barrier dysfunction phenotypes in these mice. Gain of function studies were conducted by injecting these mice with a miR-10b-5p mimic. Further, we performed miRNA-sequencing analysis from colonic mucosa from mir-10b KO, WT, and miR-10b-5p mimic injected mice to confirm 1) deficiency of miR-10b-5p in KO mice, and 2) restoration of miR-10b-5p expression after the mimic injection. Results: Congenital loss of mir-10b in mice led to the development of hyperglycemia, gut dysmotility, and gut barrier dysfunction. We found increased gut permeability and reduced expression of the tight junction protein Zonula occludens-1 (ZO-1), in the colon of mir-10b KO mice. We further confirmed that patients with diabetes or IBS-C, a known DGBI that is linked to leaky gut, had significantly reduced miR-10b-5p expression. Injection of a miR-10b-5p mimic in mir-10b KO mice rescued these molecular alterations and phenotypes. Conclusion: Our study uncovered a potential pathophysiologic mechanism of gut barrier dysfunction that links both the diabetes and gut dysmotility phenotypes in mice lacking miR-10b-5p. Treatment with a miR-10b-5p mimic reversed the leaky gut, diabetic, and gut dysmotility phenotypes, highlighting the translational potential of miR-10b-5p mimic.