David Gregg

Aging, Progenitor Cell Exhaustion, and Atherosclerosis

Background—Atherosclerosis is largely attributed to chronic vascular injury, as occurs with excess cholesterol; however, the effect of concomitant vascular aging remains unexplained. We hypothesize that the effect of time in atherosclerosis progression is related to obsolescence of endogenous progenitor cells that normally repair and rejuvenate the arteries. Methods and Results—Here we show that chronic treatment with bone marrow–derived progenitor cells from young nonatherosclerotic ApoE−/− mice prevents atherosclerosis progression in ApoE−/− recipients despite persistent hypercholesterolemia. In contrast, treatment with bone marrow cells from older ApoE−/− mice with atherosclerosis is much less effective. Cells with vascular progenitor potential are decreased in the bone marrow of aging ApoE−/− mice, but cells injected from donor mice engraft on recipient arteries in areas at risk for atherosclerotic injury. Conclusions—Our data indicate that progressive progenitor cell deficits may contribute to the development of atherosclerosis.

Thrombospondin 2 Regulates Cell Proliferation Induced by Rac1 Redox-Dependent Signaling

ABSTRACT Thrombospondin 2 (TSP2) is a matricellular protein controlling the apoptosis-proliferation balance in endothelial cells. Little is known about its transcriptional regulation compared with that of TSP1. We found that overexpression of a constitutively active mutant of Rac (RacV12) specifically increases TSP2 mRNA levels without affecting TSP1 in human aortic endothelial cells (HAEC). Moreover, TSP2 induction by RacV12 is dependent upon reactive oxygen species (ROS) production, as gp91ds-tat peptide, an inhibitor of NADPH oxidase, and the flavoprotein inhibitor diphenylene iodinium (DPI) block TSP2 synthesis. Furthermore, we found that increasing RacV12 expression results in a biphasic proliferative curve, with proliferation initially increasing as RacV12 expression increases and then returning to levels less than that of control cells at higher expression. This growth inhibition is mediated by TSP2, as either DPI treatment, which blocks TSP2 synthesis, or pan-TSP blocking antibodies restore the proliferative ability of HAEC with high expression. Mechanistically, we show that the effect of TSP2 on cell proliferation is independent of the antiangiogenic TSP2 Hep1 sequence, which is capable of altering actin cytoskeletal reorganization but not proliferation in our experimental conditions. Finally, we show in vivo that Rac-induced TSP2 expression is observed in the aorta of transgenic mice selectively expressing RacV12 in smooth muscle cells. These results identify Rac-induced ROS as a new pathway involved in the regulation of TSP2 expression.

Integrins and Coagulation: A Role for ROS/Redox Signaling?

Integrin regulation and signaling play a central role in the hemostasis process, particularly at the level of endothelial cells by regulating the contractility and barrier function of these cells and in platelets by controlling adhesion and aggregation at the site of cell injury. Reactive oxygen species (ROS) have emerged as an important mediator both transducing the signals associated with integrin activation and modulating integrin function. Ligation of integrins in endothelial cells and platelets induces activation of the Ras/mitogen-activated protein kinase, nuclear factor-kappaB, and phosphatidylinositol 3-kinase and Rho-GTPases pathways. Following vessel-wall injury and associated with activation and recruitment of platelets, there is a production of ROS concomitant with the stimulation of the blood coagulation. Moreover, ROS are capable of inducing conformational changes in integrins to change their binding affinity and function. This review will explore how ROS have emerged as an important modulator of integrins in coagulation through both outside-in (integrins stimulating ROS production to effect intracellular events) and inside-out signaling (intracellular ROS altering integrin function).

Platelets and Cardiovascular Disease

Platelets are specialized disk-shaped cells in the blood stream that are involved in the formation of blood clots that play an important role in heart attacks, strokes, and peripheral vascular disease. In most people, the more than 200 million platelets in a milliliter of blood act as tiny building blocks to form the basis of a clot to stop bleeding from cuts or injuries. Platelets can detect a disruption in the lining of a blood vessel and react to build a wall to stop bleeding (Figure 1). Figure 1. Platelets form a platelet plug to stop bleeding from an injured blood vessel. In cardiovascular disease, abnormal clotting occurs that can result in heart attacks or stroke. Blood vessels injured by smoking, cholesterol, or high blood pressure develop cholesterol-rich build-ups (plaques) that line the blood vessel; these plaques can rupture and cause the platelets to form a clot. Even though no bleeding is occurring, platelets sense the plaque rupture and are confused, thinking that an injury has taken place that will cause bleeding. Instead of sealing the vessel to prevent bleeding as would occur with a cut, a clot forms in an intact blood vessel, causing a blockage of blood flow (Figure 2). Without …

Rac-Dependent Monocyte Chemoattractant Protein-1 Production Is Induced by Nutrient Deprivation

Abstract— Under ischemic conditions, the vessel wall recruits inflammatory cells. Human aortic endothelial cells (HAECs) exposed to hypoxia followed by reoxygenation produce monocyte chemoattractant protein-1 (MCP-1); however, most experiments have been performed in the presence of nutrient deprivation (ND). We hypothesized that ND rather than hypoxia mediates endothelial MCP-1 production during ischemia, and that the small GTP-binding protein Rac1 and reactive oxygen species (ROS) are involved in this process. ND was generated by shifting HAECs from 10% to 1% FBS. Superoxide production by HAECs was increased 6 to 24 hours after ND, peaking at 18 hours. MCP-1 production was increased over a similar time frame, but peaked later at 24 hours. These effects were blocked by treatment with antioxidants such as superoxide dismutase mimetic and N-acetylcysteine (NAC), or NADPH oxidase inhibitors, DPI and gp91ds-tat. Superoxide and MCP-1 production were enhanced by RacV12 (constitutively active) in the absence of ND, and were inhibited by RacN17 (dominant-negative) adenoviral transduction under ND, suggesting that the small G-protein Rac1 is required. In conclusion, ND, an important component of ischemia, is sufficient to induce MCP-1 production by HAECs, and such production requires a functional Rac1, redox-dependent pathway.