Paul R. Standley

Cyclic stretch regulates autocrine IGF-I in vascular smooth muscle cells: implications in vascular hyperplasia

Vascular smooth muscle cells (VSMC) subjected to acute or chronic stretch display enhanced growth rates in vitro and in vivo. Clinical examples of vascular hyperplasia (e.g., systolic hypertension and postinjury restenosis) suggest that local insulin-like growth factor I (IGF-I) expression is enhanced. Therefore, we investigated the role of in vitro cyclic stretch on rat VSMC IGF-I secretion and cellular growth. In serum-free medium, cyclic stretch (1 Hz at 120% resting length for 48 h) stimulated thymidine incorporation approximately 40% above that seen in nonstretched cells. Graded stretch magnitude (100-125% resting length) yielded graded increases in VSMC growth. Exogenous IGF-I increased growth of serum-starved, nonstretched VSMC in a dose-dependent manner, with maximal growth seen with 10(-7) M. IGF-I secretion from stretched cells was 20- to 30-fold greater than from those cells cultured in a static environment. Stretch-induced increases in growth were completely blocked on addition of anti-IGF-I and partially blocked with platelet-derived growth factor (PDGF) antibodies and with a tyrosine kinase inhibitor (tyrphostin-1). Finally, blockade of stretch-activated cation channels with GdCl3 profoundly inhibited stretch-induced growth. We conclude that stretch increases VSMC IGF-I secretion and that such autocrine IGF-I is required for stretch-induced growth. PDGF and stretch-sensitive cation channels are likely additional components of a complex pathway that regulates stretch-induced VSMC seen in systolic hypertension and postinjury restenosis.Vascular smooth muscle cells (VSMC) subjected to acute or chronic stretch display enhanced growth rates in vitro and in vivo. Clinical examples of vascular hyperplasia (e.g., systolic hypertension and postinjury restenosis) suggest that local insulin-like growth factor I (IGF-I) expression is enhanced. Therefore, we investigated the role of in vitro cyclic stretch on rat VSMC IGF-I secretion and cellular growth. In serum-free medium, cyclic stretch (1 Hz at 120% resting length for 48 h) stimulated thymidine incorporation ∼40% above that seen in nonstretched cells. Graded stretch magnitude (100-125% resting length) yielded graded increases in VSMC growth. Exogenous IGF-I increased growth of serum-starved, nonstretched VSMC in a dose-dependent manner, with maximal growth seen with 10-7 M. IGF-I secretion from stretched cells was 20- to 30-fold greater than from those cells cultured in a static environment. Stretch-induced increases in growth were completely blocked on addition of anti-IGF-I and partially blocked with platelet-derived growth factor (PDGF) antibodies and with a tyrosine kinase inhibitor (tyrphostin-1). Finally, blockade of stretch-activated cation channels with GdCl3 profoundly inhibited stretch-induced growth. We conclude that stretch increases VSMC IGF-I secretion and that such autocrine IGF-I is required for stretch-induced growth. PDGF and stretch-sensitive cation channels are likely additional components of a complex pathway that regulates stretch-induced VSMC seen in systolic hypertension and postinjury restenosis.

Identification of a functional Na+/Mg2+ exchanger in human trophoblast cells

BACKGROUND Ionized magnesium levels are elevated in fetal blood compared with maternal blood, suggesting that the placenta may possess an active transport mechanism for magnesium. In the present study, we sought to determine the existence of an active transport mechanism for magnesium in the placenta using cultured trophoblast cells. METHODS Using choriocarcinoma cells as a model system, we attempted to demonstrate the presence of a functional Na+/Mg2+ exchanger. Human choriocarcinoma JEG-3 cells cultured on glass coverslips were loaded with MAG-Fura 2-AM (5 micromol/L x 30 min) to spectrofluorometrically assess kinetics of intracellular magnesium ([Mg2+]i). Cells were superfused with various concentrations of Na+, Mg2+, Ca2+ and imipramine, a blocker of erythrocyte Na/Mg exchange. [Mg2+]i calibration was determined via Triton X-100 and EDTA. RESULTS Sequential lowering of extracellular Na+ caused progressively larger, transient increases in [Mg2+]i. These transient changes in [Mg2+]i were completely dependent on [Mg]o but was independent of extracellular calcium ([Ca]o). Although acute imipramine did not alter basal [Mg2+]i, imipramine eliminated the return-to-basal phase of the [Mg2+]i transient induced by low sodium medium. Increasing extracellular magnesium ([Mg]o) caused stepwise increases in [Mg2+]i. CONCLUSIONS The JEG-3 cells appear to possess a functional Na/Mg exchanger that functions to maintain low [Mg2+]i in cytotrophoblast cells. In addition, [Mg2+]i is acutely regulated by [Mg]o. Because placental trophoblasts are sites of maternal-fetal ion exchange, and [Mg]o is altered in preeclampsia, derangements in or modulation of this exchanger may contribute to complications of pregnancy such as pregnancy-induced hypertension, pre-eclampsia, and preterm labor.

Cyclic strain upregulates VEGF and attenuates proliferation of vascular smooth muscle cells

ObjectiveVascular smooth muscle cell (VSMC) hypertrophy and proliferation occur in response to strain-induced local and systemic inflammatory cytokines and growth factors which may contribute to hypertension, atherosclerosis, and restenosis. We hypothesize VSMC strain, modeling normotensive arterial pressure waveforms in vitro, results in attenuated proliferative and increased hypertrophic responses 48 hrs post-strain.MethodsUsing Flexcell Bioflex Systems we determined the morphological, hyperplastic and hypertrophic responses of non-strained and biomechanically strained cultured rat A7R5 VSMC. We measured secretion of nitric oxide, key cytokine/growth factors and intracellular mediators involved in VSMC proliferation via fluorescence spectroscopy and protein microarrays. We also investigated the potential roles of VEGF on VSMC strain-induced proliferation.ResultsProtein microarrays revealed significant increases in VEGF secretion in response to 18 hours mechanical strain, a result that ELISA data corroborated. Apoptosis-inducing nitric oxide (NO) levels also increased 43% 48 hrs post-strain. Non-strained cells incubated with exogenous VEGF did not reproduce the antimitogenic effect. However, anti-VEGF reversed the antimitogenic effect of mechanical strain. Antibody microarrays of strained VSMC lysates revealed MEK1, MEK2, phospo-MEK1T385, T291, T298, phospho-Erk1/2T202+Y204/T185+T187, and PKC isoforms expression were universally increased, suggesting a proliferative/inflammatory signaling state. Conversely, VSMC strain decreased expression levels of Cdk1, Cdk2, Cdk4, and Cdk6 by 25-50% suggesting a partially inhibited proliferative signaling cascade.ConclusionsSubjecting VSMC to cyclic biomechanical strain in vitro promotes cell hypertrophy while attenuating cellular proliferation. We also report an upregulation of MEK and ERK activation suggestive of a proliferative phenotype. Hhowever, the proliferative response appears to be aborogated by enhanced antimitogenic cytokine VEGF, NO secretion and downregulation of Cdk expression. Although exogenous VEGF alone is not sufficient to promote the quiescent VSMC phenotype, we provide evidence suggesting that strain is a necessary component to induce VSMC response to the antimitogenic effects of VEGF. Taken together these data indicate that VEGF plays a critical role in mechanical strain-induced VSMC proliferation and vessel wall remodeling. Whether VEGF and/or NO inhibit signaling distal to Erk 1/2 is currently under investigation.

Prevention of ischemic heart failure by exercise in spontaneously diabetic BB Wor rats subjected to insulin withdrawal

Poor metabolic control resulting from insulin withdrawal in chronic type 1 diabetic rats results in ischemic heart failure. In the present study, we determined whether heart failure occurs in acute type 1 diabetic rats following insulin withdrawal and if prior exercise training can prevent this dysfunction. Four-week-old diabetic prone BB Wor rats were either sedentary or moderately exercised by daily treadmill running. Training was discontinued at the onset of diabetes. Isolated working rat heart function was then assessed in the following groups: diabetic resistant, uncontrolled sedentary diabetic (USD), controlled sedentary diabetic (CSD), uncontrolled trained diabetic (UTD), and controlled trained diabetic (CTD) rats. To induce an uncontrolled state, insulin treatment was withheld for 24 hours. During increased metabolic demand and reperfusion following ischemia, heart rate, contractility, and cardiac output were depressed in hearts from USD animals. Treatment with insulin prevented the depressions in cardiac performance from occurring. Hearts from UTD rats perfused under these conditions showed comparable cardiac function to that seen in the controlled state. This occurred despite poor metabolic control, reflected by elevated levels of plasma glucose and free fatty acids. Our results indicate that metabolic deteriorations in acute diabetes result in ischemic heart failure. However, this cardiac dysfunction can be prevented with exercise training.

Altered insulin-like growth factor-1 and nitric oxide sensitivities in hypertension contribute to vascular hyperplasia

Vascular medial thickening, a hallmark of hypertension, is associated with vascular smooth muscle cell (VSMC) hypertrophy and hyperplasia. Although the precise mechanisms responsible are elusive, we have shown that strain induced regulation of autocrine insulin-like growth factor-1 (IGF-1) and nitric oxide (NO) reciprocally modulate VSMC proliferation. Therefore, we investigated potential IGF-1 and NO abnormalities in young (10-week-old) spontaneously hypertensive rats (SHR) and Wistar-Kyoto rats (WKY) and their respective VSMC ex vivo. The SHR had increased mean arterial pressure (173 +/- 2 v 128 +/- 3 mm Hg, n = 24, P <.05) but similar pulse pressures (31 +/- 2 v 30 +/- 3 mm Hg; P >.05) v WKY. The SHR exhibited increased aortic wall thickness in comparison with WKY (523 +/- 16 v 355 +/- 17 micro m; P <.05). No differences were seen in plasma combined NO(2) and NO(3) (NO(x)) (0.48 +/- 0.11 mmol/L for WKY v 0.58 +/- 0.18 mmol/L for SHR) or plasma IGF-1 (1007 +/- 28 ng/mL for WKY v 953 +/- 26 ng/mL for SHR). Aortic VSMC from SHR displayed enhanced proliferation in comparison with WKY (P <.05). Underlying this enhanced proliferation was altered SHR VSMC sensitivity to the antiproliferative NO donor 2,2[Hydroxynitrosohydrazono] bis-ethanimine (DETA-NO) (ID(50): 270 +/- 20 mmol/L for SHR; 150 +/- 11 mmol/L for WKY; P <.05). Basal cyclic guanosine monophosphate (cGMP) secretion from SHR VSMC was 65-fold greater than that seen from WKY (P <.001). In response to DETA-NO, cGMP secretion from SHR VSMC increased modestly (1.5-fold; P <.01), whereas treatment of WKY VSMC resulted in a 26-fold (P <.001) increase in cGMP. The SHR VSMC did not respond to exogenous IGF-1, whereas WKY VSMC exhibited a dose dependent increase in proliferation with IGF-1 (10(-10) to 10(-7) mol/L). These data suggest that VSMC hyperplasia in early hypertension is not reflected by imbalances in plasma IGF-1 or NO. Rather, altered SHR VSMC sensitivity to NO is likely responsible in part for the observed hyperproliferation seen in early stages of hypertension.