Card9 deficiency accelerates experimental atherosclerosis (original) (raw)
Related papers
Journal of Clinical Medicine
Background: Besides its well-known functions in hemostasis, thrombin plays a role in various non-hemostatic biological and pathophysiologic processes. We examined the potential of thrombin to promote premature atrial endothelial cells (ECs) senescence. Methods and Results: Primary ECs were isolated from porcine atrial tissue. Endothelial senescence was assessed by measuring beta-galactosidase (SA-β-gal) activity using flow cytometry, oxidative stress using the redox-sensitive probe dihydroethidium, protein level by Western blot, and matrix metalloproteinases (MMPs) activity using zymography. Atrial endothelial senescence was induced by thrombin at clinically relevant concentrations. Thrombin induced the up-regulation of p53, a key regulator in cellular senescence and of p21 and p16, two cyclin-dependent kinase inhibitors. Nicotinamide adenine dinucleotide phosphate NADPH oxidase, cyclooxygenases and the mitochondrial respiration complex contributed to oxidative stress and senescence...
Ageing Research Reviews, 2021
Cellular senescence is a state of growth arrest that occurs after cells encounter various stresses. Senescence contributes to tumour suppression, embryonic development, and wound healing. It impacts on the pathology of various diseases by secreting inflammatory chemokines, immune modulators and other bioactive factors. These secretory biosignatures ultimately cause inflammation, tissue fibrosis, immunosenescence and many ageingrelated diseases such as atrial fibrillation (AF). Because the molecular mechanisms underpinning AF development remain unclear, current treatments are suboptimal and have serious side effects. In this review, we summarize recent results describing the role of senescence in AF. We propose that senescence factors induce AF and have a causative role. Hence, targeting senescence and its secretory phenotype may attenuate AF.
Journal of Clinical Medicine
Background: Whilst the link between aging and thrombogenicity in atrial fibrillation (AF) is well established, the cellular underlying mechanisms are unknown. In AF, the role of senescence in tissue remodeling and prothrombotic state remains unclear. Aims: We investigated the link between AF and senescence by comparing the expression of senescence markers (p53 and p16), with prothrombotic and inflammatory proteins in right atrial appendages from patients in AF and sinus rhythm (SR). Methods: The right atrial appendages of 147 patients undergoing open-heart surgery were harvested. Twenty-one non-valvular AF patients, including paroxysmal (PAF) or permanent AF (PmAF), were matched with 21 SR patients according to CHA2DS2-VASc score and treatment. Protein expression was assessed by tissue lysates Western blot analysis. Results: The expression of p53, p16, and tissue factor (TF) was significantly increased in AF compared to SR (0.91 ± 0.31 vs. 0.58 ± 0.31, p = 0.001; 0.76 ± 0.32 vs. 0.3...
Current Pharmaceutical Design, 2013
The aging process is associated with a loss of complexity in the dynamics of physiological systems that reduce the ability to adapt to stress, causing frailty and/or age-related diseases. At the cellular level, proliferative and/or oxidative-stress induced cell senescence associated with a pro-inflammatory state may greatly contribute to age-associated impaired tissue and organ functions. Senescence of endothelial and cardiac cells observed over normal aging, appear to be accelerated in age-related diseases and in particular, in cardiovascular disease (CVD). Although the molecular mechanisms of cellular senescence have been extensively studied, a complete understanding of their role in CVD is still limited. Cardiac, endothelial (EC), vascular smooth muscle (VSMC), leukocytic and stem cells (endothelial progenitor cells (EPC), embryonic stem cells (ESC) and haematopoietic stem cells (HSC)) may play a pivotal role on the maintenance and regeneration of cardiovascular tissue. Age-associated changes of such cells may enhance the risk of developing CVD. The purpose of this review is to illustrate how cellular senescence may affect tissue repair and maintenance toward CVD, focusing on the role played by telomere length and microRNA expression. Finally, interventions aimed at improving the age-related decline in vascular cells during aging and disease, as well as strategies to harness the regenerative capacity of stem cells in CVD will be discussed.
Journal of Personalized Medicine
Atherosclerosis is probably one of the paradigms of disease linked to aging. Underlying the physiopathology of atherosclerosis are cellular senescence, oxidative stress, and inflammation. These factors are increased in the elderly and from chronic disease patients. Elevated levels of oxidative stress affect cellular function and metabolism, inducing senescence. This senescence modifies the cell phenotype into a senescent secretory phenotype. This phenotype activates immune cells, leading to chronic systemic inflammation. Moreover, due to their secretory phenotype, senescence cells present an increased release of highlighted extracellular vesicles that will change nearby/neighborhood cells and paracrine signaling. For this reason, searching for specific senescent cell biomarkers and therapies against the development/killing of senescent cells has become relevant. Recently, senomorphic and senolityc drugs have become relevant in slowing down or eliminating senescence cells. However, e...
Endothelial Progenitor Cells Dysfunction and Senescence: Contribution to Oxidative Stress
Current Cardiology Reviews, 2008
The identification of endothelial progenitor cells (EPCs) has led to a significant paradigm in the field of vascular biology and opened a door to the development of new therapeutic approaches. Based on the current evidence, it appears that EPCs may make both direct contribution to neovascularization and indirectly promote the angiogenic function of local endothelial cells via secretion of angiogenic factors. This concept of arterial wall repair mediated by bone marrow (BM)-derived EPCs provided an alternative to the local "response to injury hypothesis" for development of atherosclerotic inflammation. Increased oxidant stress has been proposed as a molecular mechanism for endothelial dysfunction, in part by reducing nitric oxide (NO) bioavailability. EPCs function may also be highly dependent on a well-controlled oxidant stress because EPCs NO bioavailability (which is highly sensitive to oxidant stress) is critical for their in vivo function. The critical question is whether oxidant damage directly leads to an impairment in EPCs function. It was revealed that activation of angiotensin II (Ang II) type 1 receptor stimulates nicotinamide-adenine dinucleotide phosphate (NADPH) oxidase in the vascular endothelium and leads to production of reactive oxygen species. We observed that Ang II accelerates both BM-and peripheral blood (PB)-derived EPCs senescence by a gp91phox-mediated increase of oxidative stress, resulting in EPCs dysfunction. Consistently, both Ang II receptor 1 blockers (ARBs) and angiotensin converting enzyme (ACE) inhibitors have been reported to increase the number of EPCs in patients with cardiovascular disease. In this review, we describe current understanding of the contributions of oxidative stress in cardiovascular disease, focusing on the potential mechanisms of EPCs senescence.
Cardiac Senescence Is Associated with Enhanced Expression of Angiotensin II Receptor Subtypes 1
Endocrinology, 1998
Recent studies have pointed out the differential role of angiotensin II (Ang II) receptor subtypes, AT1 and AT2, in cardiac hypertrophy and fibrosis during pathological cardiac growth. Because senescence is characterized by an important cardiovascular remodeling, we examined the age-related expression of cardiac Ang II receptors in rats. AT1 and AT2 receptor subtype messenger RNA (mRNA) levels were quantitated by RT-PCR. In parallel, specific Ang II densities were determined in competition binding experiments using specific antagonists. AT1a and AT1b mRNA levels were markedly up-regulated (5.6-fold) in the left ventricle of 24-month-old rats compared with 3-month-old rats, but not in the right ventricle. In contrast, AT2 gene expression was increased in both ventricles of senescent rats (4.2- and 2.8-fold in the left and right ventricles, respectively). Similarly, AT1 and AT2 gene expression was increased 2.3- and 2-fold, respectively, in freshly isolated cardiomyocytes from aged rats. Furthermore, AT1 and AT2 specific binding was increased in the aged left ventricular myocardium. Even though the mechanistic pathway of this up-regulation of Ang II receptor subtype gene expression might be intrinsic to developmental gene reprogramming, the up-regulation of AT1 mRNA accumulation in the left ventricle during aging could also be secondary to age-related hemodynamic changes, whereas increased AT2 gene expression in both ventricles may depend upon hormonal and humoral factors.
Clinical Interventions in Aging
The true onset of atherosclerosis remains one of the biggest challenges for cardiologists. Is atheroma plaque development considered the earliest step of vascular aging? If so, when it starts? Before or after birth? If it starts before birth or early during childhood, it seems that Thomas Sydenham was right: "A man is as old as his arteries." Except disorganization of elastic fibers, less is known about the morphology of vascular aging and also about the molecular events influencing the age of arteries, arterial stiffness, and their role in the appearance of future complications. Cellular and molecular events responsible for the switch from physiologic to pathologic aging of human arteries are less known. Epigenetic, genetic, and environmental influences at the onset of early vascular aging (EVA) should specifically influence the process. This paper briefly reviews the controversial data regarding vascular aging with an emphasis on the less known facts about the morphology of EVA.
Cellular senescence and cardiovascular diseases: moving to the “heart” of the problem
Physiological Reviews
Cardiovascular diseases (CVDs) constitute the prime cause of global mortality, with an immense impact on patient quality of life and disability. Clinical evidence has revealed a strong connection between cellular senescence and worse cardiac outcomes in the majority of CVDs concerning both ischemic and nonischemic cardiomyopathies. Cellular senescence is characterized by cell cycle arrest accompanied by alterations in several metabolic pathways, resulting in morphological and functional changes. Metabolic rewiring of senescent cells results in marked paracrine activity, through a unique secretome, often exerting deleterious effects on neighboring cells. Here, we recapitulate the hallmarks and key molecular pathways involved in cellular senescence in the cardiac context and summarize the different roles of senescence in the majority of CVDs. In the last few years, the possibility of eliminating senescent cells in various pathological conditions has been increasingly explored, giving ...
Clinical Interventions in Aging, 2017
The true onset of atherosclerosis remains one of the biggest challenges for cardiologists. Is atheroma plaque development considered the earliest step of vascular aging? If so, when it starts? Before or after birth? If it starts before birth or early during childhood, it seems that Thomas Sydenham was right: "A man is as old as his arteries." Except disorganization of elastic fibers, less is known about the morphology of vascular aging and also about the molecular events influencing the age of arteries, arterial stiffness, and their role in the appearance of future complications. Cellular and molecular events responsible for the switch from physiologic to pathologic aging of human arteries are less known. Epigenetic, genetic, and environmental influences at the onset of early vascular aging (EVA) should specifically influence the process. This paper briefly reviews the controversial data regarding vascular aging with an emphasis on the less known facts about the morphology of EVA.