Allison W. Miller

Endothelial dysfunction precedes hypertension in diet-induced insulin resistance

The insulin-resistant (IR) syndrome may be an impetus for the development of hypertension (HTN). Unfortunately, the mechanism by which this could occur is unclear. Our laboratory and others have described impaired endothelium-mediated relaxation in IR, mildly hypertensive rats. The purpose of the current study is to determine if HTN is most likely a cause or result of impaired endothelial function. Sprague-Dawley rats were randomized to receive a fructose-rich diet for 3, 7, 10, 14, 18, or 28 days or were placed in a control group. The control group received rat chow. After diet treatment, animals were instrumented with arterial cannulas, and while awake and unrestrained, their blood pressure (BP) was measured. Subsequently, endothelium-mediated relaxation to acetylcholine was determined (in vitro) by measuring intraluminal diameter of phenylephrine-preconstricted mesenteric arteries ( approximately 250 microM). Serum insulin levels were significantly elevated in all groups receiving fructose feeding compared with control, whereas there were no differences in serum glucose levels between groups. Impairment of endothelium-mediated relaxation starts by day 14 [mean percent maximal relaxation (Emax): 69 +/- 10% of baseline] and becomes significant by day 18 (Emax: 52 +/- 11% of baseline; P < 0.01). However, the mean BP (mmHg) does not become significantly elevated until day 28 [BP: 132 +/- 1 (day 28) vs. 116 +/- 3 (control); P < 0.05]. These findings demonstrate that both IR and endothelial dysfunction occur before HTN in this model and suggest that endothelial dysfunction may be a mechanism linking insulin resistance and essential HTN.The insulin-resistant (IR) syndrome may be an impetus for the development of hypertension (HTN). Unfortunately, the mechanism by which this could occur is unclear. Our laboratory and others have described impaired endothelium-mediated relaxation in IR, mildly hypertensive rats. The purpose of the current study is to determine if HTN is most likely a cause or result of impaired endothelial function. Sprague-Dawley rats were randomized to receive a fructose-rich diet for 3, 7, 10, 14, 18, or 28 days or were placed in a control group. The control group received rat chow. After diet treatment, animals were instrumented with arterial cannulas, and while awake and unrestrained, their blood pressure (BP) was measured. Subsequently, endothelium-mediated relaxation to acetylcholine was determined (in vitro) by measuring intraluminal diameter of phenylephrine-preconstricted mesenteric arteries (∼250 μM). Serum insulin levels were significantly elevated in all groups receiving fructose feeding compared with control, whereas there were no differences in serum glucose levels between groups. Impairment of endothelium-mediated relaxation starts by day 14 [mean percent maximal relaxation (Emax): 69 ± 10% of baseline] and becomes significant by day 18 (Emax: 52 ± 11% of baseline; P < 0.01). However, the mean BP (mmHg) does not become significantly elevated until day 28 [BP: 132 ± 1 ( day 28) vs. 116 ± 3 (control); P < 0.05]. These findings demonstrate that both IR and endothelial dysfunction occur before HTN in this model and suggest that endothelial dysfunction may be a mechanism linking insulin resistance and essential HTN.

Heart mitochondria contain functional ATP-dependent K+ channels

Recent observations challenged the functional importance or even the existence of mitochondrial ATP-dependent K+ (mitoK(ATP)) channels. In the present study, we determined the presence of K(ATP)-channel subunits in mouse heart mitochondria, and investigated whether known openers or blockers of the channel can alter mitochondrial membrane potential. Investigation of the channel composition was performed with antibodies against K(ATP)-channel subunits, namely the sulfonylurea receptor (SUR1 or SUR2) and the inwardly rectifying K+ channel (Kir6.1 or Kir6.2). Specific Kir6.1 and Kir6.2 proteins were found in the mitochondria by western blotting and immunogold electron microscopy. Neither SUR1 nor SUR2 was present in the mitochondria. In contrast, a mitochondrially enriched low molecular weight SUR2-like band was found at approximately 25 kDa. Mitochondrial-transport tags were identified in the sequences of Kir6.1 and Kir6.2, but not in SUR1 or SUR2. The fluorescent BODIPY-glibenclamide labeling of mitochondria indicated direct sulfonylurea binding. Pharmacological characterization of mitoK(ATP) was performed in isolated respiring heart mitochondria. Fluorescent confocal imaging with the membrane potential-sensitive dye MitoFluorRed showed that glibenclamide application changed membrane potential, while the specific mitoK(ATP)-channel openers, diazoxide or BMS-191095, reversed the effect. Mitochondrially formed peroxynitrite is a physiological opener of the channel. We conclude that a functional K(ATP) channel is present in heart mitochondria, which can be opened by diazoxide or BMS-191095. The channel can be composed of Kir6.1 and Kir6.2 subunits and does not contain either SUR1 or SUR2.

Potassium Channel Dysfunction in Cerebral Arteries of Insulin-Resistant Rats Is Mediated by Reactive Oxygen Species

Background and Purpose— Insulin resistance (IR) increases the risk of stroke in humans. One possible underlying factor is cerebrovascular dysfunction resulting from altered K+ channel function. Thus, the goal of this study was to examine K+ channel–mediated relaxation in IR cerebral arteries. Methods— Experiments were performed on pressurized isolated middle cerebral arteries (MCAs) from fructose-fed IR and control rats. Results— Dilator responses to iloprost, which are BKCa channel mediated, were reduced in the IR compared with control arteries (19±2% versus 33±2% at 10−6 mol/L). Similarly, relaxation to the KATP opener pinacidil was diminished in the IR MCAs (17±2%) compared with controls (38±2% at 10−5 mol/L). IR also reduced the KATP channel–dependent component in calcitonin gene-related peptide–induced dilation; however, the magnitude of the relaxation remained unchanged in IR because of a nonspecified K+ channel–mediated compensatory mechanism. In contrast, Kir channel–mediated relaxation elicited by increases in extracellular [K+] (4 to 12 mmol/L) was similar in the control and IR arteries. Blockade of the Kir and Kv channels with Ba2+ and 4-aminopyridine, respectively, constricted the MCAs in both experimental groups with no significant difference. Pretreatment of arteries with superoxide dismutase (200 U/mL) plus catalase (150 U/mL) restored the dilatory responses to iloprost and pinacidil in the IR arteries. Immunoblots showed that the expressions of the pore-forming subunits of the examined K+ channels are not altered by IR. Conclusions— IR induces a type-specific K+ channel dysfunction mediated by reactive oxygen species. The alteration of KATP and BKCa channel–dependent vascular responses may be responsible for the increased risk of cerebrovascular events in IR.

EDHF-mediated relaxation is impaired in fructose-fed rats.

Insulin resistance (IR) is associated with endothelial dysfunction. A defect in endothelium-dependent relaxation via outward potassium conductance has been observed in mesenteric arteries from IR rats. The purpose of this study was to assess whether this defect in endothelium-dependent relaxation was due to impaired endothelium-derived hyperpolarizing factor (EDHF) and to determine which specific potassium channel(s) are involved in relaxation. This was accomplished by using specific potassium channel inhibitors in the presence of nitric oxide synthase and cyclooxygenase inhibition. In addition, we sought to assess the function of smooth muscle cell adenosine triphosphate (ATP)-dependent potassium (K(ATP)) channels. Sprague-Dawley rats were randomized to control or IR. To determine EDHF-mediated relaxation, acetylcholine (ACh)-induced (10(-9)-10(-5) M) relaxation was measured (in vitro) in mesenteric arteries in the presence of indomethacin (10(-5) M) and N-nitro-L-arginine (L-NNA) (10(-4) M). Subsequently the combination of charybdotoxin (CTX) (0.1 microM) and apamin (0.5 microM) or glibenclamide (Glib) (10 microM) was added to the bath to inhibit KCa or K(ATP), respectively. In separate experiments, relaxation to pinacidil (10(-13)-10(-5) M), a K(ATP) activator, was assessed in vessels with intact endothelium, endothelium denuded, or with L-NNA. Maximal relaxation to ACh in the presence of L-NNA and indomethacin was 68+/-6% for control and 12+/-3% for IR (p<0.01). The addition of CTX + apamin almost abolished EDHF-mediated relaxation in control (Emax, 8+/-5% vs. 68+/-6%; p<0.01), whereas Glib had little affect. Neither CTX + apamin nor Glib had any affect on IR. Additionally, IR arteries were less sensitive to pinacidil than were controls (EC50, 1.5+/-0.9 microM vs. 5x10(-4)+/-3x10(-4) microM, respectively; p<0.01). Endothelial removal or L-NNA pretreatment of control arteries decreased the response to pinacidil similar to IR, whereas IR vessels were unaffected. EDHF-mediated relaxation is impaired in IR arteries. In addition, the K(Ca) channel appears to be imperative for activity of EDHF in rat small mesenteric arteries. Moreover, activation of K(ATP) channels by pinacidil is impaired in IR, and this appears to be a result of endothelial dysfunction.

Enhanced Endothelin Activity Prevents Vasodilation to Insulin in Insulin Resistance

Although insulin-mediated vasodilation is impaired in insulin resistance, the mechanisms of this are unknown. We investigated factors mediating vasoactive responses to insulin in control and insulin-resistant rats. Responses to insulin in small mesenteric arteries from control and insulin-resistant rats were investigated after blocking endothelin-A receptors, cyclooxygenase, nitric oxide synthase, and potassium channels. In addition, insulin’s effect on prostacyclin production in small mesenteric blood vessels was assessed by enzyme immunoassay. Insulin induced a concentration-dependent vasodilation in control arteries that was absent in arteries from insulin-resistant rats. However, in the presence of BQ610, an endothelin-A receptor antagonist, the response to insulin was normalized in insulin-resistant arteries. In control arteries, insulin-induced vasodilation was completely inhibited by indomethacin, meclofenamate, glibenclamide, or potassium chloride. In contrast, neither n-nitro-l-arginine nor the combination of charybdotoxin and apamin altered vasodilation to insulin. In insulin-resistant arteries in the presence of BQ610, vasodilation was also inhibited by indomethacin, glibenclamide, and potassium chloride. Insulin increased prostacyclin production in small mesenteric blood vessels from both groups of rats to a similar degree. Insulin-induced vasodilation in small rat mesenteric arteries is mediated through prostacyclin- and ATP-dependent potassium channels. However, insulin-resistant arteries do not vasodilate to insulin unless endothelin-A receptors are blocked. Thus, impaired relaxation to insulin in insulin-resistant rats is due to enhanced vasoconstriction by endothelin, which offsets a normal vasodilatory response to insulin.

Impaired Endothelium-Mediated Relaxation in Coronary Arteries from Insulin-Resistant Rats1

Objective: The insulin resistance syndrome is associated with atherosclerosis and cardiovascular events; however, the underlying mechanism of vascular dysfunction is unknown. The purpose of the current study was to assess endothelium- and smooth-muscle-mediated vasodilation in isolated coronary arteries from insulin-resistant rats and to determine whether insulin resistance alters the activity of the specific endothelium-derived relaxing factors. Methods: Male Sprague-Dawley rats were randomized to insulin resistance or control. Insulin resistance was induced by a fructose-rich diet. After 4 weeks of diet, coronary arteries were removed and vascular function was assessed in vitro using videomicroscopy. Acetylcholine (10–9–3 × 10–5 M)- or sodium-nitroprusside (10–9–3 × 10–4 M)-induced relaxations were determined. To evaluate the role of the specific endothelium-derived relaxing factors, several inhibitors were used, including N-nitro-L-arginine (LNNA), charybdotoxin/apamin (CTX/apamin), and indomethacin. Results: Studies with nitroprusside showed that smooth-muscle-dependent relaxation did not differ between insulin resistance and control groups. In contrast, maximal relaxation (Emax) to acetylcholine was decreased in the insulin resistance group (56 ± 7%) versus control (93 ± 3%). LNNA pretreatment further impaired Emax in the IR group from 56 ± 7 to 17 ± 2% (p < 0.01). In control, Emax was only slightly impaired by LNNA (93 ± 3 to 63 ± 6%; p < 0.05). The addition of CTX/apamin also decreased relaxation in the control group (93 ± 3 to 47 ± 7%; p < 0.05), whereas relaxation in insulin-resistant rats was not affected (45 ± 5% with CTX/apamin vs. 56 ± 7% with acetylcholine alone, NS). Pretreatment with indomethacin did not affect relaxation in either group, while pretreatment with the combination of LNNA and CTX/ apamin completely abolished relaxation in both groups. Conclusions: Endothelium-dependent relaxation is impaired in small coronary arteries from insulin-resistant rats. The mechanism of this defect is related to a decrease in an endothelium-dependent, nitric oxide/prostanoid-independent relaxing factor or endothelium-derived hyperpolarizing factor.

Impaired vagal reflex activity in insulin-resistant rats.

Insulin resistance, without frank diabetes, is associated with sudden cardiac death. We postulated that a potential mechanism for this association is autonomic dysfunction. Male Sprague-Dawley rats were randomized into one of two groups: (a) insulin resistant (IR; n = 15), or (b) control (n = 11). Animals were made insulin resistant with a fructose-rich diet, whereas control animals received standard rat chow. Four weeks after randomization, arterial pressure and baroreceptor reflex were assessed. Baroreflex sensitivity was defined as the heart-rate response to acute blood pressure changes caused by nitroprusside (0.5-18 micrograms) or phenylephrine (0.2-3 micrograms). To determine the role of vagal stimulation specifically, each animal was randomized to receive atropine sulfate (1 mg/kg) or vehicle (normal saline) before administration of phenylephrine. Mean arterial pressure and fasting insulin concentrations were increased in the insulin-resistant group, whereas there were no differences in body weight, fasting glucose concentrations, or resting heart rate. Phenylephrine increased arterial blood pressure to a maximum of 54 +/- 2 mm Hg for control and 45 +/- 6 mm Hg for IR, p = 0.7. The maximal heart-rate change response to the increased blood pressure was markedly blunted in IR as compared with control (-88 +/- 12 beats/min for IR vs. -238 +/- 18 beats/min for control; p < 0.001). Thus the baroreflex sensitivity (BRS) was threefold less in IR versus the control group (-1.8 +/- 0.2 vs. -4.6 +/- 0.7 beats/min/mm Hg; p = 0.001). Pretreatment with atropine sulfate decreased the BRS in both groups, eliminating the difference between groups (-0.96 +/- 0.5 beats/min/mm Hg for control and -0.56 +/- 0.3 beats/min/mm Hg for IR; p = 0.2). Thus atropine sulfate caused the phenylephrine-induced heart rate and arterial blood pressure response to be equal between groups. On the other hand, BRS to nitroprusside-induced blood pressure changes were similar between groups. Insulin resistance, without the confounding factors of obesity, diabetes, and significant hypertension, is associated with a large reduction in vagal activity, which occurs via attenuation in reflex activity. In contrast, the insulin-resistant syndrome does not affect baroreflex sensitivity via sympathetic reflex.

Mechanisms of Impaired Endothelial Function Associated with Insulin Resistance

Background: The insulin-resistant (IR) syndrome is causally related to hypertension and cardiovascular events; however, the underlying mechanism remains elusive. The current study was designed to determine (1) whether the IR syndrome causes vascular dysfunction and (2) whether insulin resistance alters the activity of the individual endothelium-derived relaxing factors. Methods and Results: Insulin resistance was induced in Sprague-Dawley rats by a 4-week fructose-rich diet. Subsequently, mesenteric arteries (~250 μM) were removed from control and 1R rats, and intraluminal diameter was used to assess vascular response to pharmaco logical probes. Studies with sodium nitroprusside showed that vascular relaxation did not differ between IR and control groups. In contrast, maximal vascular relaxation to acetylcho line (10 -9 to 10-4 mol/L) in phenylephrinc preconstricted arteries was decreased in the IR group (44 ± 4%) versus control (89 ± 5%) (P < .01). N-nitro-L-arginine (LNNA) pretreat ment further impaired acetylcholine-induced maximal relaxation in the IR group from 44 ± 4% to 12 ± 3%; P < .01. In control rats, maximal relaxation was only slightly impaired by the addition of LNNA (89 ± 5% to 68 ± 6%; P <.05). The addition of indomethacin to ace tylcholine did not affect maximal relaxation in either group. When potassium chloride (KCl) was used for preconstriction, relaxation to acetylcholine in the IR group was similar to that found with phenylephrine preconstriction (41 ± 4% v 44 ± 4%, respectively); how ever, KCl preconstriction significantly decreased acetylcholine-induced relaxation in con trol rats (89 ± 5% to 43 ± 5%; P > .01). Conclusion: Insulin resistance impairs endothelium-dependent relaxation in small mesen teric arteries. It appears that insulin resistance transforms the primary relaxant factor from endothelial-derived hyperpolarizing factor to nitric oxide. These findings suggest that hyper tension and atherosclerosis associated with the IR syndrome are caused, at least in part, by endothelial dysfunction.

Cytochrome P450 Activity and Endothelial Dysfunction in Insulin Resistance

Impaired endothelium-dependent relaxation attributable to nitric oxide/prostacyclin-independent factor (endothelium-dependent hyperpolarizing factor; EDHF) has been demonstrated in the small mesenteric arteries of insulin-resistant rats. The purpose of this study was to determine if modulation of the cytochrome P450 enzyme system would restore EDHF-mediated relaxation in insulin-resistant rats. Sprague-Dawley rats were randomized to control (n = 32) or insulin-resistant (n = 32) groups. Each group was further randomized to treatment (n = 48) or placebo (n = 16). Miconazole (3 days) and phenobarbital (3 and 14 days) achieved cytochrome P450 inhibition and induction, respectively. Following drug treatment, mean arterial pressure was measured and vascular function was assessed in small mesenteric arteries in vitro. Specifically, acetylcholine-induced relaxation alone and in the presence of indomethacin plus N-nitro-L-arginine (LNNA) or KCl was determined. Miconazole reduced the maximal relaxation in response to acetylcholine in control rats. Similarly, in the presence of LNNA plus indomethacin, acetylcholine-induced relaxation was impaired in the miconazole-treated control group versus the placebo group, whereas relaxation in the presence of KCl was unchanged. Miconazole did not affect relaxation in insulin-resistant arteries. In contrast, 3- and 14-day treatment with phenobarbital significantly improved acetylcholine-induced relaxation in insulin-resistant arteries. Likewise, acetylcholine-mediated relaxation in the presence of LNNA plus indomethacin was also improved after phenobarbital treatment, while relaxation in the presence of KCl was unchanged. Phenobarbital treatment did not affect the control group. Miconazole treatment increased the mean arterial pressure in control rats, while 14-day phenobarbital treatment normalized the mean arterial pressure in insulin-resistant rats. Cytochrome P450 induction results in the restoration of EDHF-mediated relaxation in small mesenteric arteries and the normalization of mean arterial pressure in insulin-resistant rats. Thus, endothelial dysfunction secondary to insulin resistance can be reversed by the induction of cytochrome P450.

Heat shock protein expression in cerebral vessels after subarachnoid hemorrhage.

OBJECTIVE The mechanisms of cerebral vasospasm after subarachnoid hemorrhage (SAH) remain controversial. Recent data have implicated two small heat shock proteins (HSPs), namely HSP20 and HSP27, in the regulation of vascular tone. Increases in the phosphorylation of HSP20 are associated with vasorelaxation, and increases in the phosphorylation of HSP27 are associated with impaired vasorelaxation. Therefore, we hypothesized that alterations in the expression and/or phosphorylation of these two small HSPs might play a role in cerebral vasospasm after SAH. METHODS A rat model of endovascular perforation was used to induce SAH. Middle cerebral arteries were harvested from control animals, sham-treated animals, and animals with SAH, 48 hours after SAH induction. Dose-response curves for endothelium-independent (sodium nitroprusside, 10(-8) to 10(-4) mol/L) and endothelium-dependent (bradykinin, 10(-10) to 10(-5) mol/L) relaxing agents were recorded ex vivo. Physiological responses were correlated with the expression and phosphorylation of HSP20 and HSP27 by using one- and two-dimensional immunoblots. RESULTS There was impaired endothelium-independent and endothelium-dependent relaxation in cerebral vessels after SAH. These changes were associated with decreased expression of both total and phosphorylated HSP20 and increases in the amount of phosphorylated HSP27. CONCLUSION In this model, impaired relaxation of cerebral vessels after SAH was associated with increases in the amount of phosphorylated HSP27 and decreases in the expression and phosphorylation of HSP20. These data are consistent with alterations in the expression and phosphorylation of these small HSPs in other models of vasospasm.