Effect of heat shock protein 70 expression induced by glutamine on vascular hyporeactivity in rats caused by LPS

AIM: To observe the effect of heat shock protein 70(HSP70) expression induced by glutamine on Escherichia coli lipopolysaccharides(LPS)-induced vascular hyporeactivity in rats.METHODS: Twenty four healthy male Sprague-Dawley rats were randomly divided into: the control group (n=8);LPS shock group (n=8);glutamine(Gln) treated group (Gln 0.75 g·kg-1 iv,n=8).6 h after LPS shock,phenylephrine (PE,0.5-2.5 μg·kg-1 ) was applied intravenously to all groups and the percentage increase in mean arterial pressure(MAP) was detected,respectively.The concentration-response curves of aorta rings were obtained by cumulative addition of phenylephrine (PE),and PE Emax,EC50 were calculated.The blood concentration of malondialdehyde (MDA),TNF-α and IL-6 were assayed in all groups 30 min and 360 min after LPS shock,respectively.The expressions of HSP70 from heart and aorta were also assayed after 6 h LPS shock.RESULTS: The MAP level induced by PE significantly decreased by 51.4% in LPS shock group compared with the control (P<0.05).However,PE induced MAP level increased by 17.5% in Gln group compared with LPS shock group (P<0.05).Emax and EC50 to PE were significant reduced in LPS shock group compared with control group (P<0.05),but significantly improved in Gln group (P<0.05).The expressions of HSP70 from heart and aorta were much higher in Gln group than those in LPS shock group (P<0.05).The blood concentrations of TNF-α,IL-6 and MDA were much lower in Gln group than those in LPS shock group.CONCLUSION: Glutamine effectively improves α-adrenergic receptor-mediated vascular reactivity through inducing the expression of HSP 70,reducing inflammatory cytokine release and peroxide biosynthesis in LPS shock.These results suggest that glutamine have potential beneficial therapeutic effect for septic shock patients.     

Jagged1 knocking down in endothelial cells accelerates PDGF induced proliferation and migration of vascular smooth muscle cells in rats

AIM: To investigate the effect of Jagged1 expression in endothelial cells (EC) on platelet derived growth factor (PDGF) induced proliferation and migration of vascular smooth muscle cells (VSMC) in rat.METHODS: Rat aorta EC was inoculated in the lower chamber and VSMC were in the upper chamber of the cell coculture system. Three groups were divided: control, sicontrol and siJagged1. The EC Jagged1 protein expression was assayed by Western blotting to evaluate small RNA interfering (RNAi) efficiency. After the cells were cocultured with PDGF for 24 h, the proliferation and migration of VSMC were respectively evaluated by ［3H］-TdR incorporation and migrating cells counting. Protein expression of α-SM-actin in VSMC was assayed by Western blotting. RESULTS: The Jagged1 protein expression in EC was significantly lower in siJagged1 group than that in control group (0.26±0.02 vs 0.67±0.02, P<0.05), and no statistic significance was observed between control and sicontrol groups. The VSMC ［3H］-TdR incorporation and migration were higher in PDGF +siJagged1 group than those in PDGF group {［3H］-TdR incorporation (23 074±2 702) counts·min-1·well-1 vs (16 442±1 803)counts·min-1·well-1, n=5, P<0.05; migration (27±4) cells/field vs (15±3)cells/field, n=5, P<0.05}. The α-SM-actin protein in VSMC was lower in PDGF + siJagged1 group than that in PDGF group (0.25±0.06 vs 0.49±0.04, n=3, P<0.05).CONCLUSION: Jagged1 knock down in rat EC accelerates PDGF induced proliferation and migration of VSMC. These results suggest that Jagged1 expression in EC plays an important role in maintaining VSMC contract phenotype and inhibiting VSMC overgrowth after arterial injury.     

Evaluation of the inflammatory response in two-hit acute lung injury model of rats using ［8F］ FDG microPET

AIM: To investigate whether two-hit acute lung injury (ALI) model is better than one-hit, and to evaluate the inflammatory response in the lungs during these models by using ［8F］FDG microPET. METHODS: Thirty three, adult, male Sprague-Dawley rats weighing 180-210 g were used and divided into 4 groups. Rats in LPS group (n=10) and LPS-HCl group (n=10) were challenged with intraperitoneal administration of LPS at the dose of 5 mg/kg, while rats in NS group (n=3) and HCl group (n=10) received normal saline solution intraperitoneally at the dose of 1 mL/kg, after 16 h, all animals were anesthetized with an intraperitoneal injection of sodium pentobarbital (40 mg/kg) and placed in a 60°inclined position, the femoral artery was cannulated and connected to a pressure transducer to record the arterial pressure on a polygraph recorder, the trachea was surgically exposed. Rats in HCl group and LPS-HCl group received direct intratracheal injection of HCl (pH=1.2) at the dose of 0.5 mL/kg while rats in NS group and LPS group received the same volume of normal saline solution. Blood gas samples (each 0.3 mL) were obtained at 30, 90 and 240 min after the instillation and replaced by the same volume of saline solution, the samples were analyzed using a blood gas analyzer. 240 min after HCl or NS administration, the rats underwent a microPET scanning, then, all the rats were sacrificed and the lungs were obtained for histological analysis. RESULTS: Blood gas analysis showed that rats in LPS-HCl group had higher PaO2 and lower PaCO2 than the other groups. MAP decreased markedly in LPS-HCl group, while MAP in other groups remained stable. The results of microPET showed that the ratio of ROI between the right lung and the muscle tissue of the right arm in LPS-HCl group was 9.00±1.41, and was significantly higher than that in LPS group (4.01±0.60) and HCl group (3.33±0.55). Histological examination showed that the mean lung injury score in LPS-HCl group was 12.70±0.95, while that was 8.40±1.26 in HCl group and 7.00±0.82 in LPS group, and there were significant differences (both P<0.01). CONCLUSION: LPS pretreatment significantly magnifies and prolongs the inflammatory response to the subsequent acid instillation in both lungs. When compared with “one-hit”, “two-hit” is easier to induce the ALI, and ［8F］FDG microPET is a useful tool to evaluate the inflammatory reaction during ALI.     

iNOS-GC-cGMP signaling activation might be involved in vascular hyporeactivity in endotoxemic rats

AIM: To evaluate the activation of inducible nitric oxide synthase (iNOS)-guanylate cyclase(GC)-cyclic guanosine monophosphate(cGMP) signaling on vascular hyporeactivity in endotoxemic rats. METHODS: Twenty-four SD rats were randomly divided into 4 groups as follows: sham operation group (sham group), lipopolysaccharide group(LPS group), LPS+polymyxin B group (LPS+PMX-B group) and polymyxin B group (PMX-B group). Cannulation of the carotid artery was performed to record mean arterial blood pressure (MABP). The levels of plasma NO, iNOS and TNF-α were detected. The tension of the thoracic aortic rings was measured by a biological analytical system. RESULTS: Compared with sham group, MABP in LPS group was significantly lower (P<0.01), whereas MABP in LPS+PMX-B group was significantly higher than that in LPS group (P<0.05), and no statistical difference of MABP between PMX-B group and sham group was observed (P>0.05). The plasma levels of NO and iNOS in LPS group were significantly higher than those in sham group and LPS+PMX-B group (P<0.01). The contraction of isolated thoracic aortic rings stimulated by phenylephrine and the relaxation response by acetylcholine in LPS group were significantly lower than those in sham group (P<0.01), whereas those in LPS+PMX-B group were significantly improved (P<0.01). The vascular hyporeactivity to vasoconstrictors was completely reversed by pretreatment either with aminoguanidine, a selective iNOS inhibitor, or with methylene blue, an inhibitor of NO-sensitive GC. CONCLUSION: The iNOS-GC-cGMP signaling activation might be involved in vascular hyporeactivity in LPS-induced endotoxemic rats. Polymyxin B partly reverses the vascular hyporeactivity to vasoconstrictors by reducing the level of serum TNF-α, which may be mediated by the iNOS-GC-cGMP signal pathways to attenuate the overexpression of iNOS and NO production.     

Effects of salvianolic acid B on the energy metabolism and hydrocephalus in mice with cerebral ischemia

AIM: To explore the effects of salvianolic acid B (SalB) on the energy metabolism and hydrocephalus in mice with cerebral ischemia.METHODS: NIH mice were randomly divided into four groups: sham-operated group,cerebral ischemia group,SalB-treated group and nimodipine-treated group.The brain tissue energy charge (EC),phosphocreatine (PCr),the activity of ATPase,excitability amino acid (EAA) content and water content of brain were measured when cerebral ischemia for 30 min.RESULTS: EC (0.520±0.034),PCr content ［(98.344±13.249) μmol/g］,the activity of Na⁺-K⁺-ATPase ［(0.593±0.013)×10³ U/g］ and Ca²⁺-ATPase ［(0.484±0.053)×10³ U/g］ in SalB-treated group were significantly higher than those in cerebral ischemia group {EC (0.465±0.037),PCr content ［(81.614±9.919) μmol/g］ ,the activity of Na⁺-K⁺-ATPase ［(0.244±0.065)×10³ U/g］,the activity of Ca²⁺-ATPase ［(0.321±0.086)×10³ U/g］} (P<0.01).The glutamate (Glu) content ［(0.405±0.110) μmol/g］,aspartate (Asp) content ［(0.141±0.020) μmol/g］ and water content of brain ［(38.1±0.1)%］ in SalB-treated group were markedly lower than those in cerebral ischemia group ［ Glu content (0.550±0.140) μmol/g,Asp content (0.287±0.050) μmol/g,water content of brain (44.1±0.1)%］ (P<0.05,P<0.01).CONCLUSION: The increase in cerebral energy metabolism and the activity of ATPase,and decrease in EAA content in brain tissue are the mechanism of SalB alleviating hydrocephalus at the early stage of cerebral ischemia in mice.     

Effects of pentoxifylline on ventricular remodeling and cardiac function of dilated cardiomyopathy rats

AIM: To explore the effects of pentoxifylline (PTX) on ventricular remodeling and cardiac function in dilated cardiomyopathy (DCM) rats.METHODS: Lewis rats were randomly allocated to a myocin-induced dilated cardiomyopathy (DCM) group receiving saline (n=10), a DCM group receiving PTX (PTX group; 25 mg·kg^-1·d^-1, ip, for 30 days, n=10) or healthy control group (n=10). The levels of tumor necrosis factor-α (TNF-α), interleukin-6 (IL-6) and IL-10 in the blood plasma were analyzed by ELISA. The extent of fibrosis was estimated using Massons staining and immunohistochemistry analyses. Cardiac structure and function were measured by echocardiography.RESULTS: PTX decreased plasma levels of TNF-α and IL-6, and increased IL-10 level in DCM animals compared with DCM group ［TNF-α: (7.21±0.24) μg/L vs (19.30±1.31) μg/L, P<0.01; IL-6: (119.60±36.58) ng/L vs (189.50±13.25) ng/L, P<0.05; IL-10: (41.26±3.27) μg/L vs (32.45±4.32) μg/L, P<0.05］. Collagen volume fraction (CVF), perivascular collagen area (PVCA) and collagen Ⅰ/Ⅲ ratio were lower in PTX group than those in DCM group ［CVF: (16.45±3.01)% vs (23.33±4.43)%, P<0.05; PVCA: 4.58±2.10 vs 13.74±4.29, P<0.05; Ⅰ/Ⅲ ratio: 2.84±0.67 vs 4.22±0.54, P<0.01］. Left ventricular end-diastolic dimension reduced ［(6.11±0.51) mm vs (6.46±0.28) mm, P<0.05］ and left ventricular ejection fraction elevated ［(77.29±5.20)% vs (62.73±10.11)%, P<0.01］ by PTX compared with DCM.CONCLUSION: PTX modulates plasma levels of inflammatory cytokines, delays the ventricle remodeling and improves the heart function in DCM rats.     

Changes of hydrogen sulfide content in plasma and tissues of rats with LPS-induced shock

AIM: To investigate the changes and significance of hydrogen sulfide (H2S) in both plasma and various tissues, including liver, kidney, heart, lung and arteriae aorta, in rats with LPS-induced shock. METHODS: A rat model of shock induced by injection of lipopolysaccharide (LPS) was developed. Male Wistar rats were divided into four groups: control group, LPS group, LPS+NaHS (H2S donor) group and LPS+ propargylglycine (PPG, metabolic enzyme inhibitor of H2S) group. The mean arterial pressure (MAP) of rats within 240 min was observed，and H2S contents were determined. The structures of various tissues were observed. RESULTS: Administration of LPS to male Wistar rats caused a sustained fall in MAP, various tissue injuries and a significant increase in H2S contents in plasma as well as liver, kidney, heart, lung and arteriae aorta within 240 min（all P<0.05）. Treatment with metabolic enzyme inhibitor of H2S, propargylglycine, was shown to reduce H2S content elevation in plasma as well as liver, kidney, heart, lung, and arteriae aorta, and ameliorate the hypotension and tissue injuries caused by LPS（all P<0.05）. However, treatment with H2S donor-NaHS was shown to increase H2S content elevation in plasma as well as liver, kidney, heart, lung and arteriae aorta, and aggravate the hypotension and tissue injuries caused by LPS（all P<0.05）. Endogenous H2S contents in both plasma and various tissues were negatively correlated with MAP（all P<0.05）.CONCLUSION: H2S may be a new endogenous mediator and play a role in the pathogenesis of endotoxic shock.     

Development and evaluation for volume overload-induced and pressure overload-induced cardiac hypertrophy in rats

AIM: To compare the evaluations for the structure and function of the hypertrophic hearts induced by volume overload or pressure overload in rats. METHODS: Volume overload-induced cardiac hypertrophy was established by abdominal aortacaval fistula (ACF) and pressure overload-induced cardiac hypertrophy was developed by constriction of aorta (CA). The cardiac structure and function were analyzed by echocardiography, hemodynamic determination, heart weight measurement and histological examination. RESULTS: Heart weight of rats in all the operated groups was increased compared to the sham-operated groups. In 1-week ACF group, the internal diameter ［(0.67±0.03)cm vs (0.60±0.02)cm, P<0.01］ and volume of left ventricle increased ［(0.69±0.10)mL vs (0.50±0.04)mL, P<0.01］，relative wall thickness (RWT) decreased (0.46±0.05 vs 0.55±0.05, P<0.01), compared with the sham-operated group. In 1-week CA group, interventricular septal thickness ［(0.20±0.03)cm vs (0.16±0.02)cm, P<0.05］, left ventricular posterior wall thickness ［(0.20±0.03)cm vs (0.16±0.02)cm, P<0.01］, RWT (0.71±0.17 vs 0.56±0.12, P<0.05) and +dp/dtmax (4 886±1 304 vs 3 674±325, P<0.05) were all increased compared with the sham-operated group. In 2-week-groups, these parameters changed more significiantly. CONCLUSION: Cardiac structure and function could be evaluated by echocardiography and hemodynamic determination. RWT is a sensitive index for the cardiac hypertrophy induced by both volume overload and pressure overload.     

Relationship between 3-nitrotyrosine and myocardial cell apoptosis in rat diabetic cardiomyopathy

AIM: To explore the relationship between 3-nitrotyrosine (3-NT) level in hearts or blood and myocardial cell apoptosis in rat diabetic cardiomyopathy (DCM). METHODS: Sixty Sprague-Dawley (SD) rats (male, 8-week-old) were randomly divided into 4 groups: normal group, diabetic cardiomyopathy group (DCM group), diabetic rats treated with valsartan (40 mg·kg^-1·d^-1, D+V group) and DCM rats treated with valsartan (40 mg·kg^-1·d^-1, DCM+V group). Apoptotic index (AI) of rat cardiac myocytes was examined by TUNEL. The expression index (EI) of 3-NT in rat cardiac myocytes was examined by immunohistochemistry. The 3-NT concentration in rat serum was examined by ELISA. RESULTS: (1) Significant differences of the heart weight indexes among the 4 groups were observed (P<0.01). The heart weight indexes in DCM group and DCM+V group were higher than those in normal group and D+V group (P<0.01). (2) The EI of 3-NT in the cardiac myocytes was positively correlated with the AI of the cardiac myocytes in the same group (P<0.01), but the concentration of 3-NT in blood had no correlation with the AI of cardiac myocytes (P>0.05). (3) The difference of AI of cardiac myocytes among the 4 groups had statistical significance (P<0.01). The arrangement from high to low of AI was DCM group > D+V group and DCM+V group > N group (P<0.05). (4) The EI of 3-NT in DCM group was the highest as compared to other groups (P<0.05). (5) No statistical difference of 3-NT concentration in blood among the 4 groups was observed (P>0.05). CONCLUSION: (1) The expression of 3-NT in DCM myocardial tissues in SD rats is significantly increased and closely correlated with the apoptosis in myocardial cells. Valsartan inhibits 3-NT expression in DCM myocardial cells, thus inhibits the DCM myocardium apoptosis. (2) The 3-NT level in blood can not be true for reflection of 3-NT expression in DCM myocardial tissues and its effect on myocardial cell apoptosis.     

Effect of rosiglitazone on myocardial energy substrate utilization in type 2 diabetic rats

AIM: To study the effect of rosiglitazone (RSG) to improve insulin sensitivity on myocardial energy substrate utilization as well as the cardiac function in a rat model of type 2 diabetes mellitus. METHODS: Sprague-Dawley rats were conducted into three groups: chow-fed rats were fed with normal chow (12% of calories as fat); fat-fed/STZ rats were fed with high-fat diet (40% of calories as fat) for 4 weeks and then injected with streptozotocin 35 mg/kg intraperitoneal; fat-fed/STZ/RSG rats were fat-fed/STZ rats treated with rosiglitazone (3 mg·kg-1·d-1) for 2 weeks. A cannula connected to a passive transducer was inserted the heart for the measurement of the cardiac function including heart rate (HR), left ventricular end-diastolic pressure (EDP) and ±dp/dtmax. Then the isolated hearts were mounted onto a Langendorff perfusion apparatus to perfuse with Krebs-Henseleit buffer in the presence of 5 mmol/L glucose and 0.4 mmol/L ［3H］ labelled palmitate. Glucose uptake and ［3H2O］ collection were measured to evaluate the rate of carbohydrate and fatty acid oxidation. RESULTS: Compared with the chow-fed rats, fat-fed/STZ rats had a significantly depression of glucose uptake in the hearts ［(54.7±6.2 vs 69.0±5.7) μmol·g-1 dry weight, P<0.01］ after 30 min perfusion. The oxidation of glucose and palmitate were 18% and 82%, respectively. Paralleling the reduction was a change of EDP ［(14.3±1.8 vs 10.5±1.1) mmHg, P<0.05］ and -dp/dt ［(550±57 vs 650±42) mmHg/s, P<0.01］, indicating a impaired left ventricular diastolic function. In the hearts subjected to fat-fed/STZ group, rosiglitazone treated for 2 weeks resulted in a elevated level of glucose uptake ［(63.5±6.4 vs 54.7±6.2) μmol·g-1 dry weight, P<0.05］. A protective role of the ventricular function ［EDP decreased from （14.8±1.9） to （11.0±0.8） mmHg/s and -dp/dtmax increased from （558±60） to （629±51） mmHg/s, P<0.05］ were observed. CONCLUSIONS: Our study indicates that there is a depression of glucose oxidation and at increase in fatty acid oxidation in type 2 diabetic hearts. Elevation of insulin sensitivity using rosiglitazone increases the myocardial glucose metabolism and shows a benefitial result to heart functions.