Chronic steatosis aggravates cold-storage induced acute ischemic injury in rat donor livers through the perturbation of lipophagy

In this study, we explored the effects of cold ischemia on chronic steatosis and lipid signaling in vivo. Sprague Dawley (SD) rat models of chronic steatosis were established. Pathological observations and liver indices were assessed through hematoxylin-eosin (HE)- and Oil Red O staining. Autophagy and metabolism in adipose tissue were analyzed under post-ischemia and hypoxic conditions via western blotting and immunofluorescent analysis.We found that cold ischemia treatment exacerbated hepatic steatosis and reduced lipid phagocytosis. This manifested as a loss of Microtubule-associated protein 1A/1B-light chain 3 (LC3) and Perilipin 2 (PLIN2), and lower levels of autophagy. Cold ischemia also inhibited lipophagy in transplanted rat livers, most notably in moderate-to-severe steatosis models. Ischemia and hypoxia inhibited lipid phagocytosis and increased lipid accumulation.Collectively, these data show that chronic steatosis aggravates cold storage induced acute ischemic injury in rat donor livers through the inhibition of lipophagy. Moderate-to-severe steatosis therefore influences the postoperative recovery of liver transplant recipients, which should be immediately transplanted to reduce the risk of cold ischemia.     

Activation of glycogenolysis in perfused rat livers by glucagon and metabolic inhibitors

The activation of hepatic glycogenolysis by glucagon and metabolic inhibitors was studied in isolated perfused livers from fed rats. Glucose production rates and phosphorylase activity were increased by all these agents. If iodoacetate (1 mM) and cyanide (1 mM) were infused simultaneously, glycogenolysis was activated to the same extent as by glucagon (1 nM). The effects of the hormone were additive to those of cyanide, but not to those of iodoacetate. When glycogen breakdown was maximally activated by cyanide plus glucagon, additional iodoacetate was inhibitory. The glucagon-induced release of cyclic AMP into the perfusate was partially suppressed by iodoacetate. The inhibitors caused various degrees of depletion of the tissue ATP content and parallel augmentation of the AMP levels. ADP rose to a lesser extent. Indirect evidence suggested that of a progressive lowering of the cellular ATP levels was accompanied by an inhibition of enzyme dephosphorylation as well as of phosphorylation processes. However, dephosphorylation appeared to be more sensitive to changes of the energy balance, resulting in an activation of phosphorylase in response to the metabolic inhibitors.     

Electrical bioimpedance measurement during hypothermic rat kidney preservation for assessing ischemic injury

Non-heart-beating donors sustain an ischemic insult of unknown severity and duration, which can compromise the viability of the graft. This preliminary study aimed to assess whether electrical bioimpedance monitoring of cold preserved organs could be useful to identify kidneys that have suffered previous warm ischemia (WI). Two rat groups were studied during 24 h of preservation in University of Wisconsin solution (UW): a control cold ischemia group and another group subjected previously to 45 min of WI. Multi-frequency bioimpedance was monitored during preservation by means of a miniaturized silicon probe and the results were modeled according to the Cole equation. Tissular ATP content, lactate dehydrogenase in UW solution and histological injury were assessed. Renal function and cell injury, evaluated during 3 h of ex vivo reperfusion using the isolated perfused rat kidney model, demonstrated differences between groups. Bioimpedance results showed that the time constant and the high frequency resistivity parameters derived from the Cole equation were able to discriminate between groups at the beginning of the preservation (Deltatau approximately 78%, DeltaRinfinity approximately 36%), but these differences tended to converge as preservation time advanced. Nevertheless, another of the Cole parameters, alpha, showed increasing significant differences until 24 h of preservation (Deltaalpha approximately 15%).     

Effects of delta-sleep-inducing peptide during ischemic injury of the rat brain

An anti-ischemic effect of the delta-sleep-inducing peptide (DSIP) was found in rats. The DSIP effect was more obvious than that of the MK-801. The data obtained is discussed considering a possible use of the DSIP for brain stroke prophylaxis.     

Attenuation of irreversible rat heart injury by reperfusion with metabolic protectors

The effects of intravenous infusion of potassium-magnesium aspartate (K-Mg-Asp), a glucoseinsulin-potassium cocktail (GIK), a combination of glucose, insulin and potassium aspartate (GIKAsp), and insulin (I) alone on metabolism of the risk area (AR) and cardiomyocyte membrane damage have been investigated in rats during reperfusion after myocardial regional ischemia. Acute myocardial infarction (MI) was induced by a 40-min occlusion of the anterior descending coronary artery followed by a 60-min reperfusion. During reperfusion, K-Mg-Asp, GIK, GIKAsp, I or the physiological solution (control) was infused into the jugular vein at a rate of 1 ml/kg/h. After reperfusion, the MI sizes were significantly lower than in control and reduced in the following order: K-Mg-Asp > GIKAsp > I > GIK. By the end of reperfusion with metabolic protectors, ATP and phosphocreatine levels in the AR were 2–2.5 times higher that in the control (56.3 ± 3.4 and 81.8 ± 7.9% of the initial values, respectively). The losses of aspartate and glutamate pool and lactate and glucose accumulation in AR were significantly lower in the experimental groups than in control. At the end of the reperfusion, the total creatine content in the AR decreased to 32.3 ± 2.3% of the initial value in control, but restored after perfusion with GIK, I and K-Mg-Asp to 78.0 ± 5.7, 76.7 ± 5.5, and 62.4 ± 5.6% (of the initial value), respectively. The recovery of most parameters of aerobic metabolism and cell membrane integrity was maximal in the GIK and I groups and insignificantly lower after reperfusion with K-Mg-Asp.The metabolic efficacy of these protectors corresponded to MI size limitation induced by their infusion. The results suggest that myocardial reperfusion with GIK, I and K-Mg-Asp is a promising adjunctive therapy in patients with acute MI.     

Phosphatidylinositol 3-kinase-dependent signaling modulates taurochenodeoxycholic acid-induced liver injury and cholestasis in perfused rat livers

Taurochenodeoxycholic acid (TCDCA), but not glycochenodeoxycholic acid (GCDCA), activates a phosphatidylinositol 3-kinase (PI3-K)-mediated survival pathway in vitro. Here, the effects of PI3-K inhibition on TCDCA- and GCDCA-induced hepatocellular injury, apoptosis, and bile secretion were examined in the intact liver. In isolated perfused rat livers, bile flow was determined gravimetrically. Hepatovenous lactate dehydrogenase and alanine aminotransferase efflux as markers of liver integrity and biliary secretion of 2,4-dinitrophenyl-S-glutathione (DNP-GS) were determined photometrically. Apoptosis was assessed by immunohistochemistry of active caspase-3 and cytokeratin 18 in liver tissue. Phosphorylation of protein kinase B (PKB/Akt) as a readout of PI3-K activity was determined by immunoblot analysis. Bile acid concentrations were determined by gas chromatography. TCDCA (25 muM) induced moderate liver injury by hepatocellular apoptosis and distinctly reduced bile flow and DNP-GS secretion. In contrast, GCDCA (25 muM) induced severe liver injury by extensive hepatocyte apoptosis. TCDCA strongly activated PI3-K, whereas GCDCA did not markedly affect PI3-K activity. Inhibition of PI3-K by 100 nM wortmannin enhanced TCDCA-induced liver injury and apoptosis and tended to aggravate the cholestatic effect of TCDCA. In contrast, wortmannin reduced GCDCA-induced liver injury and apoptosis. Bile acid uptake tended to be reduced by wortmannin. The cholestatic effect of GCDCA was aggravated by wortmannin. Inhibition of PI3-K markedly aggravated TCDCA-induced but not GCDCA-induced liver damage and hepatocyte apoptosis. Thus TCDCA appears to block its inherent toxicity by a PI3-K-dependent survival pathway in the intact liver.     

Ischemic adaptation of the rat brain as a method for protection of endothelium from ischemic reperfusion injury

This study represents results of investigation carried out to determine the endothelium-protective effect of early and late phases of brain ischemic preconditioning as well as local and remote adaptation. The experiments were performed on adult male rats. Prolonged 30-min four vessels brain ischemia followed by 120-min reperfusion on carotid arteries, was performed (control group). Early and late local ischemic preconditioning was due to both 5-min ischemia and 30-min and 48 h reperfusion respectively on carotid arteries. Remote ischemic preconditioning was caused by 30-min ischemia and also by 15-min and 48 h reperfusion, respectively (early and late phases of adaptation) on femoral artery before prolonged brain ischemia described above. To estimate the role of nitric oxide in ischemic adaptation, mechanisms involved both nonselective blocker of NO-synthesis (N omega-nitro-L-arginine) in the time of early adaptation phase and the relatively selective iNOS inhibitor S-methylisothiourea sulfate, given before sustained brain ischemia, on the late preconditioning. Registration of brain blood flow was made by ultrasonic high-frequency Doppler device. Degree of brain edema was studied and evaluation of desquamated endothelial cells in blood was carried out. Early and late phases of local ischemic preconditioning were found to improve the brain blood flow and level of circulatory endothelial cells as well as to reduce degree of edema. The endothelium-protective effect of remote ischemic preconditioning has been proved in this study only on the late phase. Nitric oxygen was found to be important endothelium-protective factor in ischemic preconditioning.     

Mechanisms for progenitor cell-mediated repair for ischemic heart injury

Recent studies have shown that treatments involving injection of stem cells into animals with damaged cardiac tissue result in improved cardiac functionality. Clinical trials have reported conflicting results concerning the recellularization of post-infarct collagen scars. No clear mechanism has so far emerged to fully explain how injected stem cells, specifically the commonly used mesenchymal stem cells (MSC) and endothelial precursor cells (EPC), help heal a damaged heart. Clearly, these injected stem cells must survive and thrive in the hypoxic environment that results after injury for any significant repair to occur. Here we discuss how ischemic preconditioning may lead to increased tolerance of stem cells to these harsh conditions and increase their survival and clinical potential after injection. As injected cells must reach the site in numbers large enough for repair to be functionally significant, homing mechanisms involved in stem cell migration are also discussed. We review the mechanisms of action stem cells may employ once they arrive at their target destination. These possible mechanisms include that the injected stem cells (1) secrete growth factors, (2) differentiate into cardiomyocytes to recellularize damaged tissue and strengthen the post-infarct scar, (3) transdifferentiate the host cells into cardiomyocytes, and (4) induce neovascularization. Finally, we discuss that tissue engineering may provide a standardized platform technology to produce clinically applicable stem cell products with these desired mechanistic capacities.     

Melatonin scavenges hydroxyl radical and protects isolated rat hearts from ischemic reperfusion injury

During postischemic reperfusion, free radicals are produced and have deleterious effects in isolated rat hearts. We investigated whether melatonin (MEL) reduces the production of hydroxyl radical (*OH) in the effluent and aids in recovery of left ventricular (LV) function. Hearts were subjected to 30 min of ischemia followed by 30 min of reperfusion. Salicylic acid (SAL) was used as the probe for *OH, and its derivatives 2,5- and 2,3-dihydroxybenzoic acid (DHBA) were quantified using HPLC. In addition, thiobarbituric acid reactive substances (TBARS) in the myocardium was measured. Plateaus in the measurement of 2,5- and 2,3-DHBA were seen from 3 to 8 min after reperfusion in each group. The group that received 100 microM MEL+ SAL had significantly reduced amounts of 2,5- and 2,3-DHBA by multiple folds, compared to the SAL group. TBARS was significantly decreased in the 100 microM MEL group (1.20+/-0.36 vs 1.85+/-0.10 micromol/g of drug-free group, p<0.001). More importantly, the 100 microM MEL group significantly recovered in LV function (LV developed pressure, +dp/dt, and -dp/dt; 63.0%, 60.3%, and 59.4% in the 100 microM MEL group; 30.2%, 29.7%, and 31.5% in the drug-free group, respectively; p<0.05). Duration of ventricular tachycardia or ventricular fibrillation significantly decreased in the 100 microM MEL group (100 microM MEL, 159+/-67 sec; drug-free, 1244+/-233 sec; p<0.05). As a result of scavenging *OH and reducing the extent of lipid peroxidation, MEL is an effective agent for protection against postischemic reperfusion injury.     

Antagonists of calmodulin delay injury development in the severely ischemic perfused working rat heart

The effects of calmodulin antagonists trifluoperazine (TFP) and calmidazolium (CMZ) and of ethmozine (a phenothiazine without anticalmodulin activity) on the postischemic recovery in the perfused working rat hearts were studied. In the hearts subjected to 25 min zero-flow ischemia coronary flow, cardiac output, MVO2 and external work recovered to about 50% of the preischemic values during 40 min of reperfusion. TFP (5 x 10(-7) M and 10(-6) M) or CMZ (10(-7) M) improved the functional recovery to 75-94% whereas 5 x 10(-7) M ethmozine was not effective. In all experimental groups a prolongation of the ischemic period caused a progressive deterioration of the functional recovery while the total postischemic LDH release showed an initial gradual rise followed by a later decay. TFP and CMZ prolonged the time-to-half decay of the hemodynamic functions (tHF50) by 4-7 min and the time-to-peak of total LDH release (tLDHmax) by 5-10 min. In the hearts subjected to 0.2 ml/min low-flow ischemia tHF50 and tLDHmax were increased to 40 min, CMZ prolonged these times by further 5-10 min. Thus, TFP and CMZ delayed the development of the myocardial ischemic injury. Although other interpretations are possible, our data are consistent with the hypothesis that calmodulin-sensitive process is involved in the ischemic damage of the myocardium.     

A combination of ischemic preconditioning and allopurinol protects against ischemic injury through a nitric oxide-dependent mechanism

This study examined the cytoprotective mechanisms of a combination of ischemic preconditioning (IPC) and allopurinol against liver injury caused by ischemia/reperfusion (I/R). Allopurinol (50 mg/kg) was intraperitoneally administered 18 and 1 h before sustained ischemia. A rat liver was preconditioned by 10 min of ischemia, followed by 10 min of reperfusion, and then subjected to 90 min of ischemia, followed by 5 h of reperfusion. Rats were pretreated with adenosine deaminase (ADA), 3,7-dimethyl-1-[2-propargyl]-xanthine (DMPX), and N-nitro-l-arginine methyl ester (l-NAME) before IPC. Hepatic nitrite and nitrate and eNOS protein expression levels were increased by the combination of IPC and allopurinol. This increase was attenuated by ADA, DMPX, and l-NAME. I/R induced an increase in alanine aminotransferase activity, whereas it decreased the hepatic glutathione level. A combination of IPC and allopurinol attenuated these changes, which were abolished by ADA, DMPX, and l-NAME. The increase in the liver wet weight-to-dry weight ratio after I/R was attenuated by the combination of IPC and allopurinol. In contrast, hepatic bile flow was decreased after I/R, which was attenuated by the combination of IPC and allopurinol. These changes were restored by l-NAME. I/R induced a decrease in the level of mitochondrial dehydrogenase, whereas it increased mitochondrial swelling. A combination of IPC and allopurinol attenuated these changes, which were restored by ADA, DMPX, and l-NAME. Our findings suggest that a combination of IPC and allopurinol reduces post-ischemic hepatic injury by enhancing NO generation.     

Mechanisms mediating metabolic abnormalities in the livers of Ehrlich ascites tumor-bearing mice

Previously we reported that intermittent intraperitoneal administration of ornithine decarboxylase-inducing factor (ODC factor), interleukin 1alpha (IL-1alpha), and tumor-necrosis factor-alpha (TNF-alpha) to normal mice induced biological changes in the hosts which included changes in the pattern of expression of pyruvate kinase (PK) isozymes in the liver and hypertrophy of the spleen. In the study reported here, we investigated the chronic and combined effects of these factors on hepatic enzymes using alzet microosmotic pumps implanted in the subcutis of the backs or abdominal cavities of mice. Continuous administration of ODC factor and recombinant human IL-1alpha (rhIL-1alpha) reduced the activity of L-type PK, which is a glycolysis-related enzyme in the liver, and induced the activity of M2-type PK, a known marker of liver dedifferentiation. Serine dehydratase (SDH) and tyrosine aminotransferase (TAT), enzymes associated with amino acid metabolism, were not significantly influenced at the examined concentration. The simultaneous continuous infusion of ODC factor and rhIL-1alpha or rhTNF-alpha caused alterations in the patterns of expression of PK isozyme activity profiles and reduced overall PK activity. SDH and TAT activities were also significantly induced. Moreover, mice treated with these combined factors displayed many other metabolic changes normally associated with cancer cachexia. These findings suggest that the tumor-derived ODC factor and cytokines such as IL-1alpha and TNF-alpha might function synergistically in the metabolic perturbations observed in Ehrlich ascites tumor bearers.     

A study of metabolic cooperation with rat peritoneal macrophages

Rat peritoneal macrophages were studied for their ability to undergo metabolic cooperation. Macrophages were unable to cooperate with human fibroblasts. This was true for macrophages which had been activated in vivo as well as for macrophages treated with various agents in vitro. Macrophages were also unable to undergo metabolic cooperation with rat fibroblasts or with other macrophages. In contrast, rat reticular cells, mesothelial cells, and fibroblasts were able to cooperate with human fibroblasts.     

Kinetics of lipid peroxidation in isolated surviving rat livers

The kinetics of accumulation of lipid peroxidation products (hydroperoxides as primary products and malonic dialdehyde and fluorescent pigments as secondary ones) was investigated in an isolated non-perfused and preliminarily perfused liver during aerobic incubation. In the course of surviving there takes place an intensive accumulation of primary, secondary and final products of lipid peroxidation whose kinetics is of an extreme character. The rate of this process in a non-perfused liver is considerably higher than in a preliminarily perfused liver.