Extracellular matrix (ECM) is known to provide signals controlling cell shape, migration, proliferation, differentiation, morphogenesis, and survival. Recent data shows that some of these signals are derived from biologically active cryptic sites within matrix molecules (matricryptic sites) that are revealed after structural or conformational alteration of these molecules. We propose the name, matricryptins, for enzymatic fragments of ECM containing exposed matricryptic sites. Mechanisms regulating the exposure of matricryptic sites within ECM molecules include the major mechanism of enzymatic breakdown as well as others including ECM protein multimerization, adsorption to other molecules, cell-mediated mechanical forces, and ECM denaturation. Such matrix alterations occur during or as a result of tissue injury, and thus, the appearance of matricryptic sites within an injury site may provide important new signals to regulate the repair process. Here, we review the data supporting this concept and provide insight into why the increased exposure of matricryptic sites may be an important regulatory step in tissue responses to injury.
Rationale: Increased aortic stiffness, an important feature of many vascular diseases, eg, aging, hypertension, atherosclerosis, and aortic aneurysms, is assumed because of changes in extracellular matrix (ECM).Objective: We tested the hypothesis that the mechanisms also involve intrinsic stiffening of vascular smooth muscle cells (VSMCs). Methods and Results:
The smooth muscle of arterioles responds to an increase in intraluminal pressure with vasoconstriction and with vasodilation when pressure is decreased. Such myogenic vasoconstriction provides a level of basal tone that enables arterioles to appropriately adjust diameter in response to neurohumoral stimuli. Key in this process of mechanotransduction is the role of changes in intracellular Ca(2+). However, it is becoming clear that considerable complexity exists in the spatiotemporal characteristics of the Ca(2+) signal and that changes in intracellular Ca(2+) may play roles other than direct effects on the contractile process via activation of myosin light-chain phosphorylation. The involvement of Ca(2+) may extend to modulation of ion channels and release of Ca(2+) from the sarcoplasmic reticulum, alterations in Ca(2+) sensitivity, and coupling between cells within the vessel wall. The purpose of this brief review is to summarize the current literature relating to Ca(2+) and the arteriolar myogenic response. Consideration is given to coupling of Ca(2+) changes to the mechanical stimuli, sources of Ca(2+), involvement of ion channels, and spatiotemporal aspects of intracellular Ca(2+) signaling.
By definition, the myogenic response is the contraction of a blood vessel that occurs when intravascular pressure is elevated and, conversely, the vasodilation that follows a reduction in pressure. Over the last several decades numerous investigators have demonstrated the importance of the myogenic response in the local regulations of blood flow, capillary pressure, and in the generation of basal vascular tone. Despite the considerable information obtained from these investigations, information about the cellular mechanisms that underlie this response has been slow to accumulate. Because of the physiological significance of the myogenic response, its mechanistic basis represents an important subject for research. Currently, there are several broad hypotheses concerning the sequence of events that couple changes in intravascular pressure or stretch with alterations in vascular smooth muscle activation. These hypotheses include 1) altered membrane properties leading to activation of ion channels; 2) modulation of biochemical cell-signaling pathways within vascular smooth muscle; 3) length-dependent changes in contractile protein function; and 4) endothelial-dependent modulation of vascular smooth muscle tone. This review summarizes current work relative to each of these hypotheses and describes a possible sequence of events to account for myogenic activation of vascular smooth muscle.
Rationale Enhanced activation of the mineralocorticoid receptors (MR) in cardiovascular tissues increases oxidative stress, maladaptive immune responses and inflammation with associated functional vascular abnormalities. We previously demonstrated that consumption of a Western Diet (WD) for 16 weeks results in aortic stiffening, and that these abnormalities were prevented by systemic MR blockade in female mice. However, the cell specific role of endothelial MR (ECMR) in these maladaptive vascular effects has not been explored. Objective We hypothesized that specific deletion of the ECMR would prevent WD-induced increases in endothelial sodium channel (ENaC) activation, reductions in bioavailable nitric oxide (NO), increased vascular remodeling and associated increases in vascular stiffness in females. Methods and Results Four week-old female ECMR knockout and wild type mice were fed either mouse chow or WD for 16 weeks. WD feeding resulted in aortic stiffness and endothelial dysfunction as determined in vivo by pulse wave velocity (PWV) and ex vivo by atomic force microscopy, and wire and pressure myography. The WD-induced aortic stiffness was associated with enhanced ENaC activation, attenuated endothelial NO synthase (eNOS) activation, increased oxidative stress, a pro-inflammatory immune response and fibrosis. Conversely, cell specific ECMR deficiency prevented WD-induced aortic fibrosis and stiffness in conjunction with reductions in ENaC activation, oxidative stress and macrophage pro-inflammatory polarization, restoration of eNOS activation. Conclusions Increased ECMR signaling associated with consumption of a WD plays a key role in endothelial ENaC activation, reduced NO production, oxidative stress, and inflammation that lead to aortic remodeling and stiffness in female mice.
The diameter of resistance arteries has a profound effect on the distribution of microvascular blood flow and the control of systemic blood pressure. Here, we review mechanisms that contribute to the regulation of resistance artery diameter, both acutely and chronically, their temporal characteristics, and their interdependence. Furthermore, we hypothesize the existence of a remodeling continuum that allows for the vascular wall to rapidly modify its structural characteristics, specifically through the re-positioning of vascular smooth muscle cells.Importantly, the concepts presented more closely link acute vasoregulatory responses with adaptive changes in vessel wall structure. These rapid structural adaptations provide resistance vessels the ability to maintain a desired diameter under presumed optimal energetic and mechanical conditions.1548-9213/09 8.00
Women are especially predisposed to development of arterial stiffening secondary to obesity due to consumption of excessive calories. Enhanced activation of vascular mineralocorticoid receptors impairs insulin signaling, induces oxidative stress, inflammation and maladaptive immune responses. We tested whether a sub-pressor dose of mineralocorticoid receptor antagonist, spironolactone (1 mg•kg−1•day−1) prevents aortic and femoral artery stiffening in female C57BL/6J mice fed a high fat/high sugar western diet (WD) for four months (i.e., from 4–20 weeks of age). Aortic and femoral artery stiffness were assessed using ultrasound, pressurized vessel preparations and atomic force microscopy. WD induced weight gain and insulin resistance compared to control diet-fed mice and these abnormalities were unaffected by spironolactone. Blood pressures and heart rates were normal and unaffected by diet or spironolactone. Spironolactone prevented WD-induced stiffening of aorta and femoral artery as well as endothelial and vascular smooth muscle cells within aortic explants. Spironolactone prevented WD-induced impaired aortic protein kinase B/endothelial nitric oxide synthase signaling, as well as, impaired endothelium-dependent and –independent vasodilation. Spironolactone ameliorated WD-induced aortic medial thickening and fibrosis and the associated activation of the pro-growth extracellular receptor kinase 1/2 pathway. Finally, preservation of normal arterial stiffness with spironolactone in WD-fed mice was associated with attenuated systemic and vascular inflammation and an anti-inflammatory shift in vascular immune cell marker genes. Low-dose spironolactone may represent a novel prevention strategy to attenuate vascular inflammation, oxidative stress, and growth pathway signaling and remodeling to prevent development of arterial stiffening secondary to consumption of a WD.
Vasoactive effects of soluble matrix proteins and integrin-binding peptides on arterioles are mediated by αvβ3 and α5β1 integrins. To examine the underlying mechanisms, we measured L-type Ca2+ channel current in arteriolar smooth muscle cells in response to integrin ligands. Whole-cell, inward Ba2+ currents were inhibited after application of soluble cyclic RGD peptide, vitronectin (VN), fibronectin (FN), either of two anti–β3 integrin antibodies, or monovalent β3 antibody. With VN or β3 antibody coated onto microbeads and presented as an insoluble ligand, current was also inhibited. In contrast, beads coated with FN or α5 antibody produced significant enhancement of current after bead attachment. Soluble α5 antibody had no effect on current but blocked the increase in current evoked by FN-coated beads and enhanced current when applied in combination with an appropriate IgG. The data suggest that αvβ3 and α5β1 integrins are differentially linked through intracellular signaling pathways to the L-type Ca2+ channel and thereby alter control of Ca2+ influx in vascular smooth muscle. This would account for the vasoactive effects of integrin ligands on arterioles and provide a potential mechanism for wound recognition during tissue injury.
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