Zhi Ming

HISS-dependent insulin resistance (HDIR) in aged rats is associated with adiposity, progresses to syndrome X, and is attenuated by a unique antioxidant cocktail

The hypotheses were: HISS-dependent insulin resistance (HDIR) accounts for insulin resistance that occurs with aging; HDIR is the initiating metabolic defect that leads progressively to type 2 diabetes and the metabolic syndrome; a synergistic antioxidant cocktail in chow confers protection against HDIR, subsequent symptoms of diabetes, and the metabolic syndrome. Male Sprague Dawley rats were tested at 9, 26, and 52 weeks to determine their dynamic response to insulin, the HISS (hepatic insulin sensitizing substance)-dependent component of insulin action, and the HISS-independent (direct) insulin action using a dynamic insulin sensitivity test. In young rats, the HISS component accounted for 52.3+/-2.1% of the response to a bolus of insulin (50mU/kg) which decreased to 29.8+/-3.4% at 6 months and 17.0+/-2.7% at 12 months. HISS action correlated negatively with whole body adiposity and all regional fat depots (r(2) = 0.67-0.87). The antioxidants (vitamin C, vitamin E, and S-adenosylmethionine) conferred protection of HISS action, fat mass at all sites, blood pressure, postprandial insulin and glucose. Data are consistent with the hypotheses. Early detection and therapy directed towards treatment of HDIR offers a novel therapeutic target.

Nitric oxide mediates hepatic arterial vascular escape from norepinephrine-induced constriction

The involvement of nitric oxide (NO) in the vascular escape from norepinephrine (NE)-induced vasoconstriction was investigated in the hepatic arterial vasculature of anesthetized cats. The hepatic artery was perfused by free blood flow or pump-controlled constant-flow, and NE (0.15 and 0.3 microg x kg(-1) x min(-1), respectively) was infused through the portal vein. In the free-flow perfusion model, the NE-induced hepatic vasoconstriction recovered from the maximum point of the constriction, resulting in 36.6 +/- 5. 9% vascular escape. Blockade of NO formation with N(omega)-nitro-L-arginine methyl ester (L-NAME, 2.5 mg/kg ipv) potentiated NE-induced maximum vasoconstriction, and the potentiation was reversed by L-arginine (75 mg/kg ipv). Furthermore, NE-induced vasoconstriction became more stable after L-NAME, resulting in an inhibition of vascular escape (7.5 +/- 3.3%), and the inhibition was reversed by L-arginine (23.0 +/- 6.4%). Similar potentiation of NE-induced vasoconstriction and inhibition of hepatic vascular escape by L-NAME (40.4 +/- 4.3% control vs. 10.2 +/- 3.7% post-L-NAME escape) and the reversal by L-arginine were also observed in the constant-flow perfusion model. The data suggest that NO is the major endogenous mediator involved in the hepatic vascular escape from NE-induced vasoconstriction.The involvement of nitric oxide (NO) in the vascular escape from norepinephrine (NE)-induced vasoconstriction was investigated in the hepatic arterial vasculature of anesthetized cats. The hepatic artery was perfused by free blood flow or pump-controlled constant-flow, and NE (0.15 and 0.3 μg ⋅ kg-1 ⋅ min-1, respectively) was infused through the portal vein. In the free-flow perfusion model, the NE-induced hepatic vasoconstriction recovered from the maximum point of the constriction, resulting in 36.6 ± 5.9% vascular escape. Blockade of NO formation with N ω-nitro-l-arginine methyl ester (l-NAME, 2.5 mg/kg ipv) potentiated NE-induced maximum vasoconstriction, and the potentiation was reversed byl-arginine (75 mg/kg ipv). Furthermore, NE-induced vasoconstriction became more stable after l-NAME, resulting in an inhibition of vascular escape (7.5 ± 3.3%), and the inhibition was reversed by l-arginine (23.0 ± 6.4%). Similar potentiation of NE-induced vasoconstriction and inhibition of hepatic vascular escape by l-NAME (40.4 ± 4.3% control vs. 10.2 ± 3.7% post-l-NAME escape) and the reversal byl-arginine were also observed in the constant-flow perfusion model. The data suggest that NO is the major endogenous mediator involved in the hepatic vascular escape from NE-induced vasoconstriction.

Intrahepatic adenosine triggers a hepatorenal reflex to regulate renal sodium and water excretion

The mechanism for water and sodium retention in liver cirrhosis is related to the disturbance in hepatic portal circulation. We hypothesize that the increases in intraportal adenosine, which occur when the portal blood flow decreases, may trigger the hepatorenal reflex to inhibit renal water and sodium excretion. In anesthetized rats, intravenous vs. intraportal adenosine-induced effect on renal water and sodium excretion was compared in normal animals and animals with hepatic or renal denervation, and in the presence of an adenosine receptor antagonist. Compared to saline infusion, intraportal adenosine (0.02 mg kg(-1) min(-1) for 1 h) infusion decreased urine flow by 51.3% (11.7 +/- 2.3 vs. 5.7 +/- 0.5 microl min(-1)) for the first 30 min and by 49% (22.8 +/- 5.4 vs. 11.6 +/- 1.5 microl min(-1)) for the second 30-min duration. Urinary sodium excretion was also decreased. Intraportal administration of an adenosine receptor antagonist (8-phenyltheophylline (8-PT), 3 mg kg(-1) bolus injection followed by 0.05 mg kg(-1) min(-1) continuous infusion), as well as liver or kidney denervation, abolished adenosine-induced inhibition. In contrast, intravenous adenosine infusion had no influence on either urine flow or sodium excretion. The data indicated that selectively increased intraportal adenosine inhibited renal water and sodium excretion. The water and sodium retention commonly seen in the hepatorenal syndrome may be related to intraportal adenosine accumulation due to the decrease in intraportal portal flow.

Absence of meal-induced insulin sensitization (AMIS) in aging rats is associated with cardiac dysfunction that is protected by antioxidants

We have previously demonstrated that progressive development of absence of meal-induced insulin sensitization (AMIS) leads to postprandial hyperglycemia, compensatory hyperinsulinemia, resultant hyperlipidemia, increased oxidative stress, and obesity, progressing to syndrome X in aging rats. The present study tested the hypothesis that progressive development of AMIS in aging rats further resulted in deterioration in cardiac performance. Anesthetized male Sprague-Dawley rats were tested at 9, 26, and 52 wk to determine their dynamic response to insulin and cardiac function. Dynamic insulin sensitivity was determined before and after atropine to quantitate hepatic insulin sensitizing substance (HISS)-dependent and -independent insulin action. Cardiac performance was evaluated using a Millar pressure-volume conductance catheter system. AMIS developed with age, as demonstrated by significant decrease in HISS-dependent insulin action, and this syndrome was increased by sucrose supplementation and inhibited by the antioxidant treatment. Associated with progressive development of AMIS, aging rats showed impaired cardiac performance, including the reduction in cardiac index, heart rate, dP/dt(max), dP/dt(min), ejection fraction and decreased slope of left ventricular end-systolic pressure-volume relationship, and increased relaxation time constant of left ventricular pressure as well as increased left ventricular end-diastolic pressure. Total peripheral vascular resistance also increased with age. Sucrose supplementation and antioxidant treatment, respectively, potentiated and attenuated cardiac dysfunction associated with age. In addition, poor cardiac performance correlated closely with the development of AMIS. These results indicate that AMIS is the first metabolic defect that leads to homeostatic disturbances and dysfunctions, including cardiovascular diseases.

Nitric oxide inhibits norepinephrine-induced hepatic vascular responses but potentiates hepatic glucose output.

We previously reported that sympathetic nerve-induced vasoconstriction in the intestine resulted in shear stress induced release of nitric oxide (NO) that led to presynaptic inhibition of transmitter release. In contrast, studies in the liver suggested a postsynaptic inhibition of vascular responses, thus leading to the hypothesis tested here that maintained catecholamine release in the liver would result in maintained metabolic catecholamine action in the face of inhibition of vascular responses. In rats, norepinephrine (NE) induced elevations in arterial glucose content were inhibited by NO synthase antagonism (N(omega)-nitro-L-arginine methyl ester (L-NAME), 10 mg/kg, intraportal) but potentiated by NO donor administration (3-morpholinosydnonimine (SIN-1), 0.2 mg/kg, intraportal). The potentiated effect of SIN-1 was abolished by indomethacin (7.5 mg/kg, intraportal). To confirm the hepatic site of metabolic effect, cats were used so that blood flow and hepatic glucose balance could be determined. SIN-1 potentiated NE-induced glucose output from the liver from 5.0 +/- 0.4 to 7.2 +/- 0.6 mg x min(-1) x kg(-1). The potentiation was blocked by methylene blue, a guanylate cyclase inhibitor. Contrary to the glucose response, L-NAME potentiated but SIN-1 attenuated NE-induced portal vasoconstriction. Thus NO is shown to produce differential modulation of vascular and metabolic effects of NE. Vasoconstriction of the hepatic vasculature is inhibited by NO, whereas the glycogenolytic response to NE is potentiated, responses that are probably mediated by prostaglandin.

HISS, not insulin, causes vasodilation in response to administered insulin

Meal-induced sensitization to the dynamic actions of insulin results from the peripheral actions of a hormone released by the liver (hepatic insulin sensitizing substance or HISS). Absence of meal-induced insulin sensitization results in the pathologies associated with cardiometabolic risk. Using three protocols that have previously demonstrated HISS metabolic action, we tested the hypothesis that HISS accounts for the vasodilation that has been associated with insulin. The dynamic metabolic actions of insulin and HISS were determined using a euglycemic clamp in response to a bolus of 100 mU/kg insulin in pentobarbital-anesthetized Sprague-Dawley rats. Hindlimb blood flow was measured with an ultrasound flow probe on the aorta above the bifurcation of the iliac arteries. Fed rats showed tightly coupled metabolic and vascular responses, which were completed by 35 min after insulin administration. Blocking HISS release, with the use of atropine or hepatic surgical denervation, eliminated the HISS-dependent metabolic and vascular responses to insulin administration. Physiological suppression of HISS release occurs with fasting. In 24-h fasted rats, HISS metabolic and vascular actions were absent, and atropine had no effect on either action. Fed rats with liver denervation did not release HISS, but intraportal venous infusion of acetylcholine, to mimic the permissive parasympathetic nerve signal, restored the ability of insulin to cause HISS release and restored both the metabolic and vascular actions. These studies report vascular actions of HISS for the first time and demonstrate that HISS, not insulin action, results in the peripheral vasodilation generally attributed to insulin.

Contribution of hepatic adenosine A1 receptors to renal dysfunction associated with acute liver injury in rats

Acute liver injury is associated with renal insufficiency, whose mechanism may be related to activation of the hepatorenal reflex. We previously showed that intrahepatic adenosine is involved in activation of the hepatorenal reflex to restrict urine production in both healthy rats and in rats with cirrhosis. The aim of the present study was to test the hypothesis that activation of intrahepatic adenosine receptors is involved in the pathogenesis of the renal insufficiency seen in acute liver injury. Acute liver injury was induced by intraperitoneal injection of thioacetamide (TAA, 500 mg/kg) in rats. The animals were instrumented 24 hours later to monitor systemic, hepatic, and renal circulation and urine production. Severe liver injury developed following TAA insult, which was associated with renal insufficiency, as demonstrated by decreased (∼25%) renal arterial blood flow, a lower (∼30%) glomerular filtration rate, and decreased urine production. Further, the increase in urine production following volume expansion challenge was inhibited. Intraportal, but not intravenous, administration of a nonselective adenosine receptor antagonist, 8‐phenyltheophylline, improved urine production. To specify receptor subtype, the effects of 8‐cyclopentyl‐1,3‐dipropylxanthine (DPCPX, an adenosine A1 receptor antagonist) and 3,7‐dimethyl‐1‐propargylxanthine (DMPX, an adenosine A2 receptor antagonist) were compared. Intraportal but not intravenous administration of DPCPX greatly improved impaired renal function induced by acute liver injury, and this beneficial effect was blunted in rats with liver denervation. In contrast, neither intraportal nor intravenous administration of DMPX showed significant improvement in renal function. In conclusion, an activated hepatorenal reflex, triggered by intrahepatic adenosine A1 receptors, contributed to the pathogenesis of the water and sodium retention associated with acute liver injury. (HEPATOLOGY 2006;44:813–822.)

Shear stress-induced nitric oxide antagonizes adenosine effects on intestinal metabolism

The influence of nitric oxide (NO) on adenosine-induced metabolic effects was studied in the intestine. Blood flow supplied an in situ- isolated segment of small intestine in anesthetized cats via the superior mesenteric artery (SMA) and was controlled by a vascular circuit. The SMA and portal samples were taken for analysis of oxygen and lactate. Adenosine (0.4 mg ⋅ kg-1 ⋅ min-1, intra-SMA) reduced oxygen consumption by 25.1 ± 2.9 from 73.1 ± 10.8 μmol ⋅ min-1 ⋅ 100 g-1 and increased lactate production by 13.3 ± 3.0 from 12.8 ± 4.6 μmol ⋅ min-1 ⋅ 100 g tissue-1 during constant-flow (CF, decreased shear stress) but not during constant-pressure (CP, increased shear stress) perfusion. Blockade of NO synthase using N ω-nitro-l-arginine methyl ester did not affect the metabolic effects of adenosine during CF but eliminated the differences seen between CP and CF perfusion. A NO donor, 3-morpholinosydnonimine, attenuated the metabolic effects of adenosine during CF perfusion. The results suggested that shear-induced NO antagonized metabolic effects of adenosine but that the inhibition of vascular effects by NO was not shear dependent since it occurred in both CP and CF perfusion.The influence of nitric oxide (NO) on adenosine-induced metabolic effects was studied in the intestine. Blood flow supplied an in situ- isolated segment of small intestine in anesthetized cats via the superior mesenteric artery (SMA) and was controlled by a vascular circuit. The SMA and portal samples were taken for analysis of oxygen and lactate. Adenosine (0.4 mg. kg-1. min-1, intra-SMA) reduced oxygen consumption by 25.1 +/- 2.9 from 73.1 +/- 10.8 micromol. min-1. 100 g-1 and increased lactate production by 13.3 +/- 3.0 from 12.8 +/- 4.6 micromol. min-1. 100 g tissue-1 during constant-flow (CF, decreased shear stress) but not during constant-pressure (CP, increased shear stress) perfusion. Blockade of NO synthase using Nomega-nitro-L-arginine methyl ester did not affect the metabolic effects of adenosine during CF but eliminated the differences seen between CP and CF perfusion. A NO donor, 3-morpholinosydnonimine, attenuated the metabolic effects of adenosine during CF perfusion. The results suggested that shear-induced NO antagonized metabolic effects of adenosine but that the inhibition of vascular effects by NO was not shear dependent since it occurred in both CP and CF perfusion.

Hepatic Hemodynamics in Portal Hypertension

This chapter will discuss some consequences of the hepatic hemodynamic disturbances that accompany portal hypertension. Fibrosis or other mechanisms that lead to a restriction of blood flow through the liver have enormous consequences to the entire cardiovascular system, endocrine processing system, and metabolic homeostasis in general. Many systems have evolved to compensate for the disturbances that result from portal hypertension but some regulatory systems result in a worsening of homeostasis as a result of confusion at the afferent end of the signaling process. For example, does the liver respond to a decrease in portal blood flow the same if the decrease is caused by vasoconstriction of the superior mesenteric artery and subsequent reduction in intestinal blood flow as it does if blood flow to the hepatic parenchymal cells is reduced because of portacaval shunt formation? This chapter represents a conceptual focus on our own areas of expertise with no attempt to provide a detailed literature review. Although the references arc few, more detailed references are available in the cited reviews and original articles. The approach taken is to evaluate the effects of increases and decreases in intra-hepatic portal flow on four vital hepatic areas: the hepatic blood reservoir, hepatic arterial blood flow, the hepatorenal reflex, and liver cell mass.

Fatty Liver and Fatty Heart-Where do They Stand in the AMIS Syndrome?

Meal-induced insulin sensitization (MIS) refers to the augmented glucose uptake response to insulin following a meal. Absence of MIS (AMIS) causes significant decrease in post-meal glucose disposal leading to postprandial hyperglycemia, hyperinsulinemia, hyperlipidemia, adiposity, increased free radical stress, and a cluster of progressive metabolic, vascular, and cardiac dysfunctions referred to as the AMIS syndrome. We tested the hypothesis that fat accumulation in the liver and heart is part of the AMIS syndrome. Questions examined in the study: (1) Is prediabetic fat accumulation in the heart and liver a component of the AMIS syndrome? (2) Is fatty liver a cause or consequence of peripheral insulin resistance? (3) Is early cardiac dysfunction in the AMIS syndrome attributable to fat accumulation in the heart? and (4) Can the synergistic antioxidant cocktail SAMEC (S-adenosylmethionine, vitamin E, and vitamin C), known to benefit MIS, affect cardiac and hepatic triglyceride levels? Four animal models of AMIS were used in aged male Sprague-Dawley rats (52 weeks ± sucrose ± SAMEC), compared with young controls (nine weeks). Fat accumulation in the heart was not significant and therefore cannot account for the early cardiac dysfunction. Hepatic triglycerides increased only in the most severe AMIS model but the small changes correlated with the much more rapidly developing peripheral adiposity. Systemic adiposity represents an early stage, whereas accumulation of cardiac and hepatic triglycerides represents a late stage of the prediabetic AMIS syndrome. Fat accumulation in the liver is a consequence, not a cause, of AMIS. SAMEC protected against the sucrose effects on whole body adiposity and hepatic lipid accumulation.