Project description:Venous neointimal hyperplasia, characterized by the abnormal proliferation of smooth muscle cells (SMCs), represents a critical contributor to vascular stenosis and therapeutic failure in vascular interventions. Here, we identified a novel role of spatiotemporal nucleolar expression of DExH-box helicase 9 (DHX9) and its binding partner, the long non-coding RNA (lncRNA) MIAT in venous neointimal pathogenesis. In normal SMCs, DHX9 transiently localized to nucleoli during the early S phase. Pathologically, endogenous-activated MIAT facilitated nucleolar DHX9 location and its interaction with PARP1. Activated-MIAT induced mitotic spindle pole location of DHX9 which was destroyed by PARP inhibitor. MIAT also drove SMCs proliferation by accelerating cell cycle progression. While depleting MIAT or DHX9 led to remarkable nucleolar subphase disruption, mitotic breakage-fusion-bridge, and DNA damage. Of note, nucleolar-associated morphology phenotypes analyzed with deep learning are determined to be valuable biomarkers for assessing cellular status and disease progress. MIAT was repressed in cultured human veins, reducing SMCs proliferation and vascular intimal hyperplasia. These results establish the MIAT-DHX9 axis as the central regulator of venous SMCs in arteriovenous fistula and venous graft models. Our study may provide a new avenue to destroy the pathologic spatiotemporal function of DHX9 by targeting MIAT in intimal hyperplasia.

Project description:MIAT-DHX9 spatiotemporal expression drives venous neointimal hyperplasia through nucleolar homeostasis and mitotic progression.

Project description:MIAT-DHX9 spatiotemporal expression drives venous neointimal hyperplasia through nucleolar homeostasis and mitotic progression

Project description:PGC1α regulates the mitochondrial metabolism response to cyclic stretch, which inhibits neointimal hyperplasia microscopy revealed that intimal injury disrupted the balance of vascular energy metabolism and impaired the mitochondrial ultrastructure in vivo. The human carotid plaque and femoral artery plaque samples also exhibited alterations in mitochondrial morphology. Vascular smooth muscle cells (VSMCs) are the main components of neointimal hyperplasia and are subjected to cyclic stretch resulting from pulsatile pressure. In this study, we found that the application of cyclic stretch in vitro increased VSMC mitochondrial mass and function. In addition, peroxisome proliferator-activated receptor gamma coactivator-1α (PGC1α) played an important role in regulating VSMC mitochondrial function in response to physiological stretch via the phosphorylation of Smad3. Increasing the activation of PGC1α by ZLN005 treatment effectively inhibited VSMC hyperproliferation after intimal injury in vivo. These results suggested that the regulation of PGC1α by p-Smad3 in response to physiological cyclic stretch may effectively alleviate neointimal hyperplasia by promoting mitochondrial function. PGC1α may be a potential therapeutic target for the prevention and treatment of neointimal hyperplasia.

Project description:Fractalkine Antibody Attenuates Venous Neointimal Hyperplasia of Arteriovenous Fistula in Mice model

Project description:1α,25-Dihydroxyvitamin D3 encapsulated in Nanoparticles Prevents Venous Neointimal Hyperplasia and Stenosis in Porcine Arteriovenous Fistulas

Project description:Vascular smooth muscle cells (VSMCs) possess significant phenotypic plasticity, shifting between a contractile phenotype and a synthetic state for vascular repair/remodelling. Dysregulated VSMC transformation, marked by excessive proliferation and migration, primarily drives intimal hyperplasia. N6-methyladenosine (m6A), the most prevalent RNA modification in eukaryotes, plays a critical role in gene expression regulation; however, its impact on VSMC plasticity is not fully understood. This research investigates the alterations in m6A modification and its regulatory factors during VSMC phenotypic shifts and their influence on intimal hyperplasia. We demonstrate that METTL14, crucial for m6A deposition, significantly promotes VSMC dedifferentiation. METTL14 expression, initially negligible, is elevated in synthetic VSMC cultures, post-injury neointimal VSMCs, and human restenotic arteries. Reducing Mettl14 levels in mouse primary VSMCs decreases pro- synthetic genes, suppressing their proliferation and migration. m6A-RIP-seq profiling shows key VSMC gene networks undergo altered m6A regulation in Mettl14-deficient cells. Mettl14 enhances Klf4 and Serpine1 expression through increased m6A deposition. Local Mettl14 knockdown significantly curbs neointimal formation post-arterial injury, and reducing Mettl14 in hyperplastic arteries halts further neointimal development. We found that Mettl14 is a pivotal regulator of VSMC dedifferentiation, influencing Klf4- and Serpine1- mediated phenotypic conversion. Inhibiting Mettl14 is a viable strategy for preventing restenosis and halting restenotic occlusions

Project description:Vascular smooth muscle cells (VSMCs) possess significant phenotypic plasticity, shifting between a contractile phenotype and a synthetic state for vascular repair/remodelling. Dysregulated VSMC transformation, marked by excessive proliferation and migration, primarily drives intimal hyperplasia. N6-methyladenosine (m6A), the most prevalent RNA modification in eukaryotes, plays a critical role in gene expression regulation; however, its impact on VSMC plasticity is not fully understood. This research investigates the alterations in m6A modification and its regulatory factors during VSMC phenotypic shifts and their influence on intimal hyperplasia. We demonstrate that METTL14, crucial for m6A deposition, significantly promotes VSMC dedifferentiation. METTL14 expression, initially negligible, is elevated in synthetic VSMC cultures, post-injury neointimal VSMCs, and human restenotic arteries. Reducing Mettl14 levels in mouse primary VSMCs decreases pro- synthetic genes, suppressing their proliferation and migration. m6A-RIP-seq profiling shows key VSMC gene networks undergo altered m6A regulation in Mettl14-deficient cells. Mettl14 enhances Klf4 and Serpine1 expression through increased m6A deposition. Local Mettl14 knockdown significantly curbs neointimal formation post-arterial injury, and reducing Mettl14 in hyperplastic arteries halts further neointimal development. We found that Mettl14 is a pivotal regulator of VSMC dedifferentiation, influencing Klf4- and Serpine1- mediated phenotypic conversion. Inhibiting Mettl14 is a viable strategy for preventing restenosis and halting restenotic occlusions

Project description:The role of different cells in intimal hyperplasia remains unintelligible. To characterize the cells in intimal hyperplasia, we performed single-cell RNA sequencing of whole remodeled vessel cells from C57BL/6J mice with a murine model of intimal hyperplasia at an early (IH 2w) or late stage (IH 4w). The single-cell RNA-seq analyses revealed the heterogeneity of cells in vascular remodeling.

Project description:Restenosis is an inescapable problem when patients underwent percutaneous transluminal angioplasty because of intimal hyperplasia. Human umbilical cord mesenchymal stem cells derived exosomes (HucMSC-Exo) have been proved to promote reendothelialization to restrain the process of intimal hyperplasia. However, aberrant vascular smooth muscle cell (VSMC) proliferation, migration and dedifferentiation play more important roles in intimal hyperplasia, the effects and mechanisms of HucMSC-Exo upon VSMC are elusive