Periodontitis imparting the increased risk of atherosclerotic cardiovascular diseases is partially due to the immune subversion of the oral pathogen, particularly the Porphyromonas gingivalis (P. gingivalis), by inducing apoptosis. However, it remains obscure whether accumulated apoptotic cells in P. gingivalis-accelerated plaque formation are associated with impaired macrophage clearance. Here, we show that smooth muscle cells (SMCs) have a greater susceptibility to P. gingivalis-induced apoptosis than endothelial cells through TLR2 pathway activation. Meanwhile, large amounts of miR-143/145 in P.gingivalis-infected SMCs are extracellularly released and captured by macrophages. Then, these miR-143/145 are translocated into the nucleus to promote Siglec-G transcription, which represses macrophage efferocytosis. By constructing three genetic mouse models, we further confirm the in vivo roles of TLR2 and miR-143/145 in P. gingivalis-accelerated atherosclerosis. Therapeutically, we develop P.gingivalis-pretreated macrophage membranes to coat metronidazole and anti-Siglec-G antibodies for treating atherosclerosis and periodontitis simultaneously. Our findings extend the knowledge of the mechanism and therapeutic strategy in oral pathogen-associated systemic diseases.
Animals ; Mice ; Endothelial Cells ; Toll-Like Receptor 2 ; Macrophages ; Apoptosis ; Atherosclerosis ; Myocytes, Smooth Muscle ; MicroRNAs

OBJECTIVE: To explore whether the differentiation of vascular stem cells (VSC) into smooth muscle cells (SMC) in aortic dissection (AD) is dysregulated, and to verify the role of Notch3 pathway in this process. METHODS: Aortic tissues were obtained from AD patients undergoing aortic vascular replacement and heart transplant donors at Department of Cardiovascular Surgery, Guangdong Provincial People's Hospital Affiliated to Southern Medical University. VSC were isolated by enzymatic digestion and c-kit immunomagnetic beads. The cells were divided into normal donor-derived VSC group (Ctrl-VSC group) and AD-derived VSC group (AD-VSC group). The presence of VSC in the aortic adventitia was detected by immunohistochemical staining, and VSC was identified by stem cell function identification kit. The differentiation model of VSC into SMC established in vitro was induced by transforming growth factor-β1 (10 μg/L) for 7 days. They were divided into normal donor VSC-SMC group (Ctrl-VSC-SMC group), AD VSC-SMC group (AD-VSC-SMC group) and AD VSC-SMC+Notch3 inhibitor DAPT group (AD-VSC-SMC+DAPT group,DAPT 20 μmol/L was added during differentiation induction). The expression of contractile marker Calponin 1 (CNN1) in SMC derived from aortic media and VSC were detected by immunofluorescence staining. The protein expressions of contractile markers α-smooth muscle actin (α-SMA), CNN1 as well as Notch3 intracellular domain (NICD3) in SMC derived from aortic media and VSC were detected by Western blotting. RESULTS: Immunohistochemical staining showed there was a population of c-kit-positive VSC in the adventitia of aortic vessels, and VSC from both normal donors and AD patients had the ability to differentiate into adipocytes and chondrocytes. Compared with normal donor vascular tissue, the expressions of SMC markers α-SMA and CNN1 of tunica media contraction in AD were down-regulated (α-SMA/β-actin: 0.40±0.12 vs. 1.00±0.11, CNN1/β-actin: 0.78±0.07 vs. 1.00±0.14, both P < 0.05), while the protein expression of NICD3 was up-regulated (NICD3/GAPDH: 2.22±0.57 vs. 1.00±0.15, P < 0.05). Compared with Ctrl-VSC-SMC group, the expressions of contractile SMC markers α-SMA and CNN1 were down-regulated in AD-VSC-SMC group (α-SMA/β-actin: 0.35±0.13 vs. 1.00±0.20, CNN1/β-actin: 0.78±0.06 vs. 1.00±0.07, both P < 0.05), the protein expression of NICD3 was up-regulated (NICD3/GAPDH: 22.32±1.22 vs. 1.00±0.06, P < 0.01). Compared with AD-VSC-SMC group, the expressions of contractile SMC markers α-SMA, CNN1 were up-regulated in AD-VSC-SMC+DAPT group (α-SMA/β-actin: 1.70±0.07 vs. 1.00±0.15, CNN1/β-actin: 1.62±0.03 vs. 1.00±0.02, both P < 0.05). CONCLUSIONS Dysregulation of VSC differentiation into SMC occurs in AD, while inhibition of Notch3 pathway activation can restore the expression of contractile proteins in VSC-derived SMC in AD.
Humans ; Actins ; Platelet Aggregation Inhibitors ; Signal Transduction ; Aortic Dissection ; Cell Differentiation ; Myocytes, Smooth Muscle ; Stem Cells

Muscle, Smooth, Vascular ; RNA, Long Noncoding/genetics* ; Cell Proliferation/genetics* ; Myocytes, Smooth Muscle ; Cells, Cultured

Phenotypic transformation of pulmonary artery smooth muscle cells (PASMCs) is a key factor in pulmonary vascular remodeling. Inhibiting or reversing phenotypic transformation can inhibit pulmonary vascular remodeling and control the progression of hypoxic pulmonary hypertension. Recent studies have shown that hypoxia causes intracellular peroxide metabolism to induce oxidative stress, induces multi-pathway signal transduction, including those related to autophagy, endoplasmic reticulum stress and mitochondrial dysfunction, and also induces non-coding RNA regulation of cell marker protein expression, resulting in PASMCs phenotypic transformation. This article reviews recent research progress on mechanisms of hypoxia-induced phenotypic transformation of PASMCs, which may be helpful for finding targets to inhibit phenotypic transformation and to improve pulmonary vascular remodeling diseases such as hypoxia-induced pulmonary hypertension.
Humans ; Pulmonary Artery ; Hypertension, Pulmonary ; Vascular Remodeling/genetics* ; Hypoxia/genetics* ; Myocytes, Smooth Muscle ; Cell Proliferation/physiology* ; Cells, Cultured ; Cell Hypoxia/genetics*

OBJECTIVES: To study the effect of platelet-derived growth factor-BB (PDGF-BB) on pulmonary vascular remodeling in neonatal rats with hypoxic pulmonary hypertension (HPH). METHODS: A total of 128 neonatal rats were randomly divided into four groups: PDGF-BB+HPH, HPH, PDGF-BB+normal oxygen, and normal oxygen (n=32 each). The rats in the PDGF-BB+HPH and PDGF-BB+normal oxygen groups were given an injection of 13 μL 6×10¹⁰ PFU/mL adenovirus with PDGF-BB genevia the caudal vein. After 24 hours of adenovirus transfection, the rats in the HPH and PDGF-BB+HPH groups were used to establish a neonatal rat model of HPH. Right ventricular systolic pressure (RVSP) was measured on days 3, 7, 14, and 21 of hypoxia. Hematoxylin-eosin staining was used to observe pulmonary vascular morphological changes under an optical microscope, and vascular remodeling parameters (MA% and MT%) were also measured. Immunohistochemistry was used to measure the expression levels of PDGF-BB and proliferating cell nuclear antigen (PCNA) in lung tissue. RESULTS: The rats in the PDGF-BB+HPH and HPH groups had a significantly higher RVSP than those of the same age in the normal oxygen group at each time point (P<0.05). The rats in the PDGF-BB+HPH group showed vascular remodeling on day 3 of hypoxia, while those in the HPH showed vascular remodeling on day 7 of hypoxia. On day 3 of hypoxia, the PDGF-BB+HPH group had significantly higher MA% and MT% than the HPH, PDGF-BB+normal oxygen, and normal oxygen groups (P<0.05). On days 7, 14, and 21 of hypoxia, the PDGF-BB+HPH and HPH groups had significantly higher MA% and MT% than the PDGF-BB+normal oxygen and normal oxygen groups (P<0.05). The PDGF-BB+HPH and HPH groups had significantly higher expression levels of PDGF-BB and PCNA than the normal oxygen group at all time points (P<0.05). On days 3, 7, and 14 of hypoxia, the PDGF-BB+HPH group had significantly higher expression levels of PDGF-BB and PCNA than the HPH group (P<0.05), while the PDGF-BB+normal oxygen group had significantly higher expression levels of PDGF-BB and PCNA than the normal oxygen group (P<0.05). CONCLUSIONS Exogenous administration of PDGF-BB in neonatal rats with HPH may upregulate the expression of PCNA, promote pulmonary vascular remodeling, and increase pulmonary artery pressure.
Rats ; Animals ; Hypertension, Pulmonary ; Becaplermin ; Animals, Newborn ; Proliferating Cell Nuclear Antigen ; Vascular Remodeling ; Pulmonary Artery/metabolism* ; Hypoxia ; Oxygen ; Cell Proliferation ; Myocytes, Smooth Muscle/metabolism*

Animals ; Coronary Vessels ; Diabetes Mellitus ; Muscle, Smooth, Vascular ; Myocytes, Smooth Muscle ; Rats

This study investigated the effect of salidroside on phenotypic transformation of rat pulmonary artery smooth muscle cells(PASMCs) induced by hypoxia. Rat pulmonary arteries were isolated by tissue digestion and PASMCs were cultured. The OD values of cells treated with salidroside at different concentrations for 48 hours were measured by cell counting kit-8(CCK-8) to determine the appropriate concentration range of salidroside. The cells were divided into a normal(normoxia) group, a model(hypoxia) group, and three hypoxia + salidroside groups(40, 60, and 80 μg·mL~(-1)). Quantitative real-time PCR(qRT-PCR) was used to detect the mRNA expression of cell contractile markers in each group, such as α-smooth muscle actin(α-SMA), smooth muscle 22(SM22), and calcium-binding protein(calponin), and synthetic marker vimentin. The expression levels of cell phenotypic markers and proliferating cell nuclear antigen(PCNA) were detected by Western blot. The proliferation of cells in each group was detected by the 5-ethynyl-2'-deoxyuridine(EdU) assay. Cell migration was measured by Transwell assay. As revealed by results, compared with the normal group, the model group showed decreased mRNA and protein expression of contractile phenotypic markers of PASMCs and increased mRNA and protein expression of synthetic markers. Compared with the conditions in the model group, salidroside could down-regulate the mRNA and protein expression of synthetic markers in PASMCs and up-regulated the mRNA and protein expression of contractile phenotypic markers. Compared with the normal group, the model group showed potentiated proliferation and migration. Compared with the model group, the hypoxia + salidroside groups showed blunted proliferation and migration of cells after phenotypic transformation. The results suggest that salidroside can inhibit the expression of synthetic markers in PASMCs and promote the expression of contractile markers to inhibit the hypoxia-induced phenotypic transformation of PASMCs. The mechanism of salidroside in inhibiting the proliferation and migration of PASMCs is related to the inhibition of the phenotypic transformation of PASMCs.
Animals ; Cell Proliferation ; Cells, Cultured ; Glucosides ; Hypoxia ; Myocytes, Smooth Muscle ; Phenols ; Pulmonary Artery ; Rats

Vascular calcification is an active and complex pathological process regulated by several factors. Vascular calcification is closely related to the incidence and mortality of the cardiovascular disease, chronic kidney disease and other diseases, which affects multiple organs and systems, thus affecting people's health. Therefore, more and more attention is paid to vascular calcification. At present, the pathogenesis and clinical practice of vascular calcification have been continuously improved, which mainly includes calcium and phosphorus imbalance theory, vascular smooth muscle cell transdifferentiation theory, bone homeostasis imbalance theory, epigenetic regulation theory, inflammation theory, extracellular matrix theory, new cell fate theory and so on. However, there are still many unsolved problems. Since the occurrence and development of vascular calcification affect multiple organs and systems, this expert consensus gathered clinicians and basic research experts engaged in the study of vascular calcification in order to summarize the progress of various disciplines related to vascular calcification in recent years. The purpose of this consensus is to systematically summarize the latest research progress, treatment consensus and controversy of vascular calcification from the aspects of epidemiology, pathogenesis, prevention and treatment, so as to provide theoretical basis and clinical enlightenment for in-depth research in this field.
Humans ; Consensus ; Epigenesis, Genetic ; Vascular Calcification/pathology* ; Cardiovascular Diseases ; Myocytes, Smooth Muscle

Vascular calcification, the deposition of calcium in the arterial wall, is often linked to increased stiffness of the vascular wall. Vascular calcification is one of the important factors for high morbidity and mortality of cardiovascular and cerebrovascular diseases, as well as an important biomarker in atherosclerotic cardiovascular events, stroke and peripheral vascular diseases. The mechanism of vascular calcification has not been fully elucidated. Recently, non-coding RNAs have been found to play an important role in the process of vascular calcification. In this paper, the main types of non-coding RNAs and their roles involved in vascular smooth muscle cell calcification are reviewed, including the changes of osteoblast-related proteins, calcification signaling pathways and intracellular Ca²⁺.
Humans ; Muscle, Smooth, Vascular/metabolism* ; Vascular Calcification/metabolism* ; Myocytes, Smooth Muscle/metabolism*

Vascular calcification is the crucial factor of high cardiovascular disease morbidity and mortality in patients with chronic kidney disease (CKD), which causes a huge medical and economic burden. It is urgent to explore its pathogenesis and intervention methods. CKD-associated vascular calcification is an ectopic osteogenesis process actively regulated by multiple cells. Vascular smooth muscle cells (VSMCs) undergo osteogenic differentiation in a pro-calcification environment, and secrete matrix vesicles to form calcium and phosphorus crystal deposition sites, which are key events in the development of CKD-associated vascular calcification. This article reviews the new mechanism and technology of CKD-associated vascular calcification and discusses the role of the myokine Irisin in CKD-associated vascular calcification.
Humans ; Osteogenesis ; Renal Insufficiency, Chronic ; Vascular Calcification/pathology* ; Proteins ; Cardiovascular Diseases/complications* ; Disease Progression ; Myocytes, Smooth Muscle