Biphasic mechanism for hypothermic induced loss of protein synthesis in hepatocytes.

BACKGROUND: A complication in liver transplantation is increased clotting times due to inhibition of protein synthesis resulting from prolonged hypothermic preservation. Protein synthesis is also blocked in cold preserved hepatocytes. In this study, the mechanism of inhibition of protein synthesis in cold preserved hepatocytes was investigated. METHODS: Hepatocytes prepared from rat liver were cold preserved in University of Wisconsin solution for 4, 24, and 48 hr. Protein synthesis was measured as incorporation of radiolabeled leucine into acid precipitable proteins. Hepatocytes were treated with antioxidants (dithiothreitol, trolox or deferoxamine, nitric oxide synthase inhibitor (N(G)-monomethyl-L-arginine monoacetate), steroids (dexamethasone or methylprednisolone), methods to keep adenosine triphosphate high (aerobic storage), and cytoskeletal disrupting agents (cytochalasin D or colchicine). RESULTS: There was a 26% decrease in protein synthesis after only 4 hr of cold storage and a further 25% decrease at 24 hr. Antioxidants, elevated adenosine triphosphate, and N(G)-monomethyl-L-arginine monoacetate did not affect the rate of loss of protein synthesis. Protein synthesis was not due to inhibition of amino acid transport or lack of amino acids in the storage medium. Steroid pretreatment of hepatocytes had no effect on the loss of protein synthesis occurring in the first 4 hr of storage but did suppress the loss occurring during the next 44 hr of storage. Cytoskeletal disrupting agents, added to freshly isolated cells, inhibited protein synthesis. CONCLUSION: The mechanism of loss of protein synthesis in cold preserved liver cells is not mediated by: (1) oxygen free radical generation or improved by antioxidant therapy, (2) nitric oxide generation in hepatocytes, (3) an adenosine triphosphate-sensitive destruction of cell viability, and (4) decreased permeability of amino acids or loss of amino acids from the cells. Loss of protein synthesis due to hypothermic storage appears biphasic. The first phase, occurring within 4 hr of storage, may be the result of the effects of hypothermia on the cell cytoskeletal system and may be untreatable. The second phase, which occurs during the next 24 to 48 hr is sensitive to steroid pretreatment. This phase may be amenable to improved preservation methodology. Improved preservation of the liver may require the use of steroids to conserve protein synthetic capabilities.

Cold storage sensitizes hepatocytes to oxidative stress injury.

Liver cold storage leads to oxygen free radical production and reperfusion injury. Antioxidants are effective in suppression reperfusion injury in rat livers when used in the reperfusion medium. However, in clinical liver transplantation their effectiveness is not clear, which may be due to the way they are used (in the recipient). In this study we compare the effectiveness of antioxidants when used in the reperfusion medium versus the cold storage solution in isolated hepatocytes and the isolated perfused liver. Hepatocytes were cold stored in UW solution for 24 h. Oxidative stress, induced by t-butyl hydroperoxide (tBHP), was measured in the presence of one of five different antioxidants--deferoxamine (DFO), dithiothreitol (DTT), trolox, tocopherol, dimethylthiourea (DMTU)--in the reperfusion buffer or UW solution. Efficacy was judged by reduction in membrane damage (LDH release) during rewarming. Also, rat livers were cold stored for 48 h in UW solution (+/- antioxidant) and reperfused (+/- antioxidants). Efficacy was judged by the effect on enzyme release and bile production. Cold storage of hepatocytes for 24 h sensitized them to oxidative stress. The concentration of tBHP required to induce maximal cell death (80%-90% LDH release) was reduced from 1.3 mM (fresh cells) to 0.37 mM (LD-50 values). All antioxidants except DMTU suppressed oxyradical-induced LDH release when used in the reperfusion medium, but only DFO was effective when used in the UW solution. In the isolated perfused liver, DFO, DTT, and trolox were effective and suppressed enzyme release when added to the reperfusion buffer, but none were effective when used in the UW solution. We conclude that cold storage sensitizes liver cells to oxidative stress. The most effective antioxidant was the iron chealator, DFO, which was effective in the reperfusion buffer (isolated perfused sliver or hepatocytes) but not in the UW solution when tested in the isolated perfused liver. Suppression of reperfusion injury in liver transplantation could be obtained by antioxidant therapy. However, it is unclear how best to deliver the antioxidants to the site of oxyradical generation.

Comparison of isolated hepatocytes and tissue slices for study of liver hypothermic preservation/reperfusion injury.

Simple models are needed that effectively test the variables that may be important in liver preservation. Two such models are isolated hepatocytes and tissue slices. In this study the effects of hypothermic preservation on the viability of hepatocytes (HC) and tissue slices (TS) from rat livers were measured by LDH leakage after cold storage and rewarming. We compared how glycine, calcium, and fasting, shown previously to affect preservation injury in hepatocytes, affected both HC and TS viability. Hepatocytes were cold-stored in University of Wisconsin organ preservation solution for up to 48 h and rewarmed in Krebs-Henseleit Bicarbonate (KHB) for 120 min. Tissue slices were studied in two ways. Either livers were cold-stored intact and then tissue slices (TS-A) prepared and rewarmed in KHB, or tissue slices were prepared from the fresh liver, cold-stored, and then rewarmed (TS-B). The latter method may be similar to cold storage of HC. Freshly prepared samples (HC, TS-A, or TS-B) showed < 15% LDH leakage during the rewarming phase. Cold storage for 24 h resulted in < 30% LDH leakage in all preparations. After 48 h cold storage there was a significant increase in LDH leakage (HC, 65.1 +/- 5.1%; TS-A, 52.9 +/- 0.8%, TS-B, 53.6 +/- 2.6%). Glycine (3 mM) or calcium (1.5 mM) included in the KHB significantly reduced LDH leakage from 48 h cold-stored HC to 20.7 +/- 1.8 and 26.3 +/- 2.4%, respectively. These agents caused a smaller decrease in LDH release from tissue slices (around 40%). Hepatocytes appear more susceptible to preservation/reperfusion damage than the more structurally intact tissue slices as suggested by the greater release of LDH. Another difference was that the agents which improved preservation quality of HC were not as effective in TS. Hepatocytes may be more vulnerable to preservation/reperfusion damage because of the harsh methods used in their preparation. The damage induced during preparation appears amenable to suppression by glycine or calcium. Tissue slices, which are intact pieces of liver tissue, may be more suitable for studies related to development of better methods for liver preservation. The intact cells in TS have not been exposed to harsh conditions and maintain a more natural cell-cell relationship.

Effect of fasting on hepatocytes cold stored in University of Wisconsin solution for 24 hours.

Although there have been improvements in liver preservation, liver dysfunction still remains a serious consequence of liver transplantation. This may be related to cold ischemic injury since the incidence of dysfunction increases with longer preservation times. However, even some livers preserved for short periods of time (less than 15 hr) develop liver dysfunction. One possible cause may be the lack of adequate nutritional support, and the donor may be exposed to prolonged periods of hyponutrition. In this study, we have compared the effects of fasting on functions of hepatocytes isolated from the rat. Hepatocytes were cold stored in University of Wisconsin solution for 24 hr and analyzed at the end of preservation as well as at the end of rewarming in Krebs-Henseleit buffer for 120 min. The glycogen content of fed cells was 1.57 mumol/mg protein and this was reduced by 95% in cells from fasted rats. After cold storage and rewarming, hepatocytes from fasted rats lost 84.2 +/- 2.5% of the total cellular lactate dehydrogenase versus only 32.7 +/- 3.8% (P < 0.001) in cells from fed rats. Also, ATP and reduced glutathione content of fasted cells were significantly reduced, free fatty acids were higher (P = 0.0154), and protein synthesis was reduced to 41% of controls (versus only 88% in fed cells), although there were no differences in phospholipid content. When hepatocytes from fasted rats were rewarmed in Krebs-Henseleit buffer containing fructose (10 mM), lactate dehydrogenase release was reduced from 80% to 34.4 +/- 0.2% and ATP content was significantly higher with fructose than without. Hepatocytes from fasted rats, therefore, are more sensitive to cold ischemic injury than cells from fed rats. The increased sensitivity appears related to the lack of glycogen as a source of substrates for metabolism during rewarming. This is supported by the fact that addition of fructose, which is metabolized readily by hepatocytes through glycolysis, suppressed rewarming injury to cells from fasted rats. The nutritional status of the donor, therefore, may play a pivotal role in the results of liver preservation and transplantation. Effective donor nutritional management may reduce the incidence of liver dysfunction after transplantation.

Glycine protects hepatocytes from injury caused by anoxia, cold ischemia and mitochondrial inhibitors, but not injury caused by calcium ionophores or oxidative stress.

Isolated hepatocytes, suspended in an organ preservation solution, can be preserved at 4 degrees C for up to 6 days. After preservation, normothermic-normoxic incubation causes loss of hepatocyte viability. The addition of 3 mmol/L glycine to the rewarming medium prevents the loss of viability. In this study we investigated the cytoprotective effects of glycine under many conditions known to cause hepatocellular injury to understand the mechanism of cold-induced injury in the liver. Hepatocytes were suspended in modified Krebs-Henseleit buffer with or without 3 mmol/L glycine and exposed to agents or conditions known to induce cell death. Hepatocyte viability was assessed by measuring the percentage of lactate dehydrogenase leakage from the cells and the concentration of ATP during incubation at 37 degrees C under room air for up to 90 min. Mitochondrial inhibitors (potassium cyanide and carbonyl cyanide m-chlorophenylhydrazone); calcium ionophores (ionomycin and A23187); an oxidizing agent, tert-butyl hydroperoxide; and anoxia were all used to cause cell injury. Hepatocytes were also isolated from fasted rats and hypothermically preserved as another model of cell death. Other amino acids were also tested in the hypothermic preservation model to study the specificity of the amino acid requirement for prevention of lactate dehydrogenase leakage. Of the amino acids tested, only alanine (10 mmol/L) and the combination of alanine (3 mmol/L) and serine (3 mmol/L) were as effective as glycine in preventing lactate dehydrogenase release in the hypothermic preservation model.(ABSTRACT TRUNCATED AT 250 WORDS)

Urea and protein synthesis in cold-preserved isolated rat hepatocytes.

We used an isolated-hepatocyte model to study how hypothermic storage (simulating liver preservation) affects metabolism after prolonged preservation. Rat hepatocytes were stored in the University of Wisconsin solution for up to 72 hr. After each day of storage, protein synthesis, urea synthesis, ATP content and lactate dehydrogenase release were determined in rewarmed (37 degrees C) and oxygenated hepatocytes. Protein synthesis ([3H]-leucine incorporation into protein) was depressed by 16% +/- 4%, 54% +/- 6% and 69% +/- 4% after 24 hr, 48 hr and 72 hr, respectively. Urea synthesis, ATP synthesis and lactate dehydrogenase release were similar to those in control hepatocytes (no preservation). Fasting of the rats before isolation of hepatocytes caused more rapid loss of protein-synthesis capabilities (59% in 24 hr) with no significant loss of lactate dehydrogenase, urea synthesis or ATP synthesis. Hepatocyte viability (lactate dehydrogenase release) as judged by membrane permeability, ATP synthesis and potassium content can be maintained after up to 6 days of cold storage. However, protein synthesis is depressed after only 48 hr of cold storage. Thus hypothermic storage of the liver causes a change in the metabolic capabilities of the hepatocytes, and the timing of the loss of protein synthesis is similar to the limits of successful cold storage of the whole liver (48 hr). Thus a limit to long-term storage of the liver may be related to loss of protein synthesis. In liver transplantation, one indication of poor preservation is a decrease in serum albumin and clotting factors with increased tissue edema and bleeding diathesis.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of cold storage on tissue and cellular glutathione.

One of the mechanisms thought to cause injury in preserved organs is the formation of oxygen free radicals. The cell is protected from oxidative stress by many defense mechanisms. A major defense mechanism involves glutathione and glutathione-dependent enzymes. During organ preservation by simple cold storage the loss of glutathione may sensitize the organ to free radical damage after transplantation. In this study we show that glutathione is depleted from the rabbit liver, kidney, and heart cold-stored (5 degrees C) for up to 72 h in the UW solution without glutathione. In the first 24 h kidney glutathione decreased to 84 +/- 3% of control values, liver glutathione decreased to 49 +/- 3% of control values, and heart glutathione decreased to 73 +/- 3% of control values. After 48 h of storage the kidney and liver lost an additional 30 and 20%, respectively, whereas heart glutathione changed very little. By 72 h all three organs had lost more than 50% of the glutathione found in freshly obtained tissue. To determine if glutathione added to the UW solution can effectively prevent this loss of glutathione during preservation, hepatocytes were cold-stored for up to 72 h in a preservation solution with and without glutathione. We found that adding glutathione to the preservation solution slowed the rate of loss of glutathione from the cells. These data suggest that at hypothermia the cell may be permeable to GSH. Methods to suppress the loss of glutathione during preservation of organs may be an important factor in suppressing oxygen free radical injury.

Hypothermic preservation of hepatocytes. III. Effects of resuspension media on viability after up to 7 days of storage.

Hepatocyte suspensions provide a rapid method to determine how hypothermic storage affects liver cell metabolism and viability. Using these studies, improved methods of hypothermic liver preservation for transplantation may be developed. In this study, rat hepatocytes were cold-stored for up to 7 days in University of Wisconsin liver preservation solution. At the end of each day of storage hepatocytes were resuspended in Krebs-Henseleit buffer or tissue-culture medium (Liebovitz-15; Fischer's; modified Fischer's, which was similar to Fischer's but with glycine and cysteine added; or Waymouth's medium). Hepatocyte viability was assessed by rewarming and oxygenating the suspensions and measuring the percentage of leakage of lactate dehydrogenase from the cells, the cellular concentration of potassium and the stimulation of respiration by succinate, all measures of plasma membrane integrity. Additionally, concentrations of ATP and glutathione after rewarming and reoxygenation in the various resuspension media were measured. Hepatocyte permeability to lactate dehydrogenase did not increase during cold storage of 1 to 7 days (7.2% +/- 2% leakage), indicating that most of the hepatocytes remained viable during cold storage. However, when rewarmed, loss of viability (leakage of lactate dehydrogenase) was dependent on the composition of the resuspension media. In Krebs-Henseleit buffer, viability was reduced after 2 and 3 days of storage (lactate dehydrogenase leakage on rewarming = 70% to 90%). Leakage of lactate dehydrogenase was reduced significantly after resuspension in tissue-culture media. After 6 days of storage, lactate dehydrogenase leakage from hepatocytes stored in Liebovitz- 15 or modified Fischer's was only about 30%.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of polyethylene glycol on lipid peroxidation in cold-stored rat hepatocytes.

A mechanism suggested to cause injury to preserved organs is the generation of oxygen free radicals either during the cold-storage period or after transplantation (reperfusion). Oxygen free radicals can cause peroxidation of lipids and alter the structural and functional properties of the cell membranes. Methods to suppress generation of oxygen free radicals of suppression of lipid peroxidation may lead to improved methods of organ preservation. In this study we determined how cold storage of rat hepatocytes affected lipid peroxidation by measuring thiobarbituric acid reactive products (malondialdehyde, MDA). Hepatocytes were stored in the UW solution +/- glutathione (GSH) or +/- polyethylene glycol (PEG) for up to 96 h and rewarmed (resuspended in a physiologically balanced saline solution and incubated at 37 degrees C under an atmosphere of oxygen) after each day of storage. Hepatocytes rewarmed after storage in the UW solution not containing PEG or GSH showed a nearly linear increase in MDA production with time of storage and contained 1.618 +/- 0.731 nmol MDA/mg protein after 96 h. When the storage solution contained PEG and GSH there was no significant increase in MDA production after up to 72 h of storage and at 96 h MDA was 0.827 +/- 0.564 nmol/mg protein. When freshly isolated hepatocytes were incubated (37 degrees C) in the presence of iron (160 microM) MDA formation was maximally stimulated (3.314 +/- 0.941 nmol/mg protein). When hepatocytes were stored in the presence of PEG there was a decrease in the capability of iron to maximally stimulate lipid peroxidation. The decrease in iron-stimulated MDA production was dependent upon the time of storage in PEG (1.773 nmol/mg protein at 24 h and 0.752 nmol/mg protein at 48 h).(ABSTRACT TRUNCATED AT 250 WORDS)

Glycine prevention of cold ischemic injury in isolated hepatocytes.

Isolated hepatocytes suspended in a liver preservation solution (University of Wisconsin (UW) solution) and exposed to cold (5 degrees C) ischemia lose viability (LDH release) after 3 (76.5 +/- 2.6% extracellular LDH) and 4 days (90.3 +/- 5.7% extracellular LDH) storage when rewarmed (37 degrees C) in Krebs-Henseleit buffer. However, if 3 mM glycine is added to Krebs-Henseleit buffer the loss of LDH on rewarming was suppressed (% LDH = 24.4 +/- 2.2% and 33.2 +/- 3.0%, at 3 and 4 days, respectively). The protection by glycine could also be obtained by storing the hepatocytes in the UW solution containing 15 mM glycine and rewarming in the absence of glycine in Krebs-Henseleit buffer. There did not appear to be a relationship between the protection by glycine and glutathione concentration of the hepatocytes as shown by the lack of effect of a glutathione synthetase inhibitor (butathionine sulfoximine) on the protective effects of glycine. Other amino acids did not provide protection to hepatocytes exposed to cold ischemia. The mechanism of action of glycine is not known, but this compound may be important in improving cold storage of livers for transplantation.

Important components of the UW solution.

The UW solution for preservation of the liver, kidney, and pancreas contains a number of components, and the importance of each of these has not been fully resolved. In the studies reported here the importance of glutathione and adenosine is demonstrated in isolated cell models (rabbit renal tubules and rat liver hepatocytes) of hypothermic preservation and reperfusion and in dog renal transplantation. Glutathione in the UW solution is necessary for the preservation of the capability of the cell to regenerate ATP and maintain membrane integrity. Adenosine in the UW solution provides the preserved cell with substrates for the regeneration of ATP during the reperfusion period following cold storage. The omission of GHS from the UW solution results in poorer renal function in the 48 hr dog kidney preservation-transplant model. The role of other components of the UW solution is discussed including lactobionic acid; other impermeants; and the colloid, hydroxyethyl starch. It is concluded that the development of improved preservation solutions will require a more detailed understanding of the mechanism of injury due to cold storage and, once obtained, solutions more complex than the UW solution may be required for improved long-term storage of organs.

Preservation of the canine liver for 24-48 hours using simple cold storage with UW solution.

The results of a series of 29 orthotopic liver transplants in the dog are described. The livers were preserved in a new cold storage fluid, UW solution, and were successfully transplanted after periods of storage of 24, 30, 36, and 48 hr. All six animals transplanted after 24 hr survived beyond 5 days after transplantation and had excellent graft function. Four of six survived for at least 5 days after 30 hr of cold storage, and five of five after 36 hr. Five of six consecutive dogs that received transplants that had been cold-stored for 48 hr survived for 5 or more days. This solution represents a substantial advance over all existing cold storage solutions for liver preservation.