Objective Abnormal proliferation and migration of vascular smooth muscle cells (SMCs) are the key events in the progression of neointima formation in response to vascular injury. The goal of this study is to investigate the functional role of a potent oncogene YAP in smooth muscle phenotypic modulation in vitro and in vivo. Methods and Results In vitro in cell culture and in vivo in both mouse and rat arterial injury models YAP expression is significantly induced and correlated with the vascular SMC synthetic phenotype. Over-expression of YAP promotes SMC migration and proliferation while attenuating smooth muscle contractile gene expression. Conversely, knocking-down endogenous YAP in SMCs up-regulates smooth muscle gene expression but attenuates SMC proliferation and migration. Consistent with this, knocking-down YAP expression in a rat carotid balloon injury model and genetic deletion of YAP specifically in vascular SMCs in mouse after carotid artery ligation injury attenuates injury-induced smooth muscle phenotypic switch and neointima formation. Conclusions YAP plays a novel integrative role in smooth muscle phenotypic modulation by inhibiting smooth muscle-specific gene expression while promoting smooth muscle proliferation and migration in vitro and in vivo. Blocking the induction of YAP would be a potential therapeutic approach for ameliorating vascular occlusive diseases.
Cellular response to genotoxic stress is a very complex process, and it usually starts with the "sensing" or "detection" of the DNA damage, followed by a series of events that include signal transduction and activation of transcription factors. The activated transcription factors induce expressions of many genes which are involved in cellular functions such as DNA repair, cell cycle arrest, and cell death. There have been extensive studies from multiple disciplines exploring the mechanisms of cellular genotoxic responses, which have resulted in the identification of many cellular components involved in this process, including the mitogen-activated protein kinases (MAPKs) cascade. Although the initial activation of protein kinase cascade is not fully understood, human protein kinases ATM (ataxia-telangiectasia, mutated) and ATR (ATM and Rad3-related) are emerging as potential sensors of DNA damage. Current progresses in ATM/ATR research and related signaling pathways are discussed in this review, in an effort to facilitate a better understanding of genotoxic stress response.
Angiogenin undergoes nuclear translocation in endothelial and smooth muscle cells where it accumulates in the nucleolus and binds to DNA. Nuclear translocation of angiogenin is necessary for its biological activity and is mediated by an endocytotic pathway that is independent of the microtubule system and lysosomal processing. Because the nucleolus is a subnuclear organelle containing clusters of transcriptionally active ribosomal RNA genes, we studied the binding of angiogenin to the intergenic spacer of the ribosomal RNA gene where many of the transcription regulatory elements are located. Here we report that angiogenin binds to CT repeats that are abundant in the nontranscribed region of the ribosomal RNA gene. An angiogenin-binding DNA sequence (CTCTCTCTCTCTCTCTCCCTC) has been identified and designated angiogenin-binding element (ABE). ABE binds angiogenin specifically and exhibits angiogenin-dependent promoter activity in a luciferase reporter system. CT repeats, or inverted GA box, which are abundantly distributed in the eukaryotic genome and are often located in the 5'-flanking region, have been implicated in regulating gene expression. We have previously shown that angiogenin stimulates rRNA synthesis. The present results suggest that the nuclear function of angiogenin may not only be related to rRNA production but also play a role in regulating expression of genes containing CT repeats.
N6‐methyladenosine (m6A) mRNA methylation has emerged as an important player in many biological processes by regulating gene expression. However, its roles in intestinal stem cell (ISC) homeostasis remain largely unknown. Here, we report that YTHDF1, an m6A reader, is highly expressed in ISCs and its expression is upregulated by Wnt signaling at the translational level. Whereas YTHDF1 is dispensable for normal intestinal development in mice, genetic ablation of Ythdf1 dramatically blocks Wnt‐driven regeneration and tumorigenesis with reduced ISC stemness. Mechanistically, YTHDF1 facilitates the translation of Wnt signaling effectors including TCF7L2/TCF4, while this process is enhanced during Wnt activation to augment β‐catenin activity. Targeting YTHDF1 in ISCs of established tumors leads to tumor shrinkage and prolonged survival. Collectively, our studies unveil YTHDF1 as an amplifier of Wnt/β‐catenin signaling at the translational level, which is required for the maintenance of ISCs during regeneration and tumorigenesis.
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