Phosphorylation and redox states in ischemic liver

Differential activation of some transcription factors during rat liver ischemia, reperfusion, and heat shock

Cells respond to external stimuli by changes in gene expression that are largely dependent on transcription factors (TFs). We studied the behavior of some TFs in rat liver during ischemia, postischemic reperfusion, and heat shock. Knowledge of the conditions at the end of ischemia is essential to understand changes occurring at reperfusion. The TFs investigated are known to be typically responsive to heat shock (HSF), hypoxia (HIF-1), pro- and antioxidant conditions (AP-1), or to various environmental changes (HNF-1 and ATF/CREB family). The most relevant new information includes the following: 1) Liver ischemia activates extremely rapidly the DNA binding capacity of HSF, soon followed by analogous activation of HIF-1 and AP-1. 2) After a certain lag time from the activation of HIF-1, mRNAs accumulate for two glycolytic enzymes, in particular Aldolase A and Heme Oxygenase 1, which contain HIF-1 sequences in their promoters. 3) Reperfusion, which is known to further increase the binding of HSF and to induce NFkappaB binding, abrogates or decreases the binding of HIF-1 and AP-1, stimulated by ischemia, and activates the binding of ATF/CREB. Later on, a second peak of AP-1 binding is induced. 4) Heat shock activates both ischemia-responsive and reperfusion-responsive TFs. 5) Preliminary experiments of supergelshift reveal that the activation of AP-1 at reperfusion or upon heat shock may result from the different involvement of the component subunits.

A new gastric juice peptide, BPC. An overview of the stomach-stress-organoprotection hypothesis and beneficial effects of BPC

The possibility that the stomach, affected by general stress, might initiate a counter-response has not until recently been considered in theories of stress. We suggest that the stomach, as the most sensitive part of the gastrointestinal tract and the largest neuroendocrine organ in the body, is crucial for the initiation of a full stress response against all noxious stress pathology. The end result would be a strong protection of all organs invaded by 'stress'. Consistent with this assumption, this coping response is best explained in terms of 'organoprotection'. Endogenous organoprotectors (eg prostaglandins, somatostatin, dopamine) are proposed as mediators. Such an endogenous counteraction could even be afforded by their suitable application. A new gastric juice peptide, M(r) 40,000, named BPC, was recently isolated. Herein, a 15 amino acid fragment (BPC 157), thought to be essential for its activity, has been fully characterized and investigated. As has been demonstrated for many organoprotective agents using different models of various tissue lesions, despite the poorly understood final mechanism, practically all organ systems appear to benefit from BPC activity. These effects have been achieved in many species using very low dosages (mostly microgram and ng/kg range) after ip, ig, and intramucosal (local) application. The effect was apparent already after one application. Long lasting activity was also demonstrated. BPC was highly effective when applied simultaneously with noxious agents or in already pathological, as well as chronical, conditions. Therefore, it seems that BPC treatment does not share any of the so far known limitations for 'conventional organoprotectors'. No influence on different basal parameters and no toxicity were observed. These findings provide a breakthrough in stress theory. BPC, as a possible endogenous free radical scavenger and organoprotection mediator, could be a useful prototype of a new class of drugs, organoprotective agents.

Biochemistry of alcoholic liver disease

The biochemistry of alcohol liver disease as it relates to clinical medicine and experimental alcohol liver disease is presented. Clinical features are emphasized in the diagnosis of alcohol liver disease, particularly as it relates to staging the disease and predictors of prognosis. Currently, it is true that the biochemical diagnosis of alcohol liver disease is at best very limited in terms of the sensitivity tests and specificity of the test. It is particularly difficult to detect alcohol liver disease biochemically in the early stages when steatohepatitis is not severe. Consequently, 50% of the patients have already developed cirrhosis at the time they are diagnosed clinically. In this review indicators of malnutrition are emphasized because they have the strongest implications regarding survival during the acute hospitalization stage of the disease. They are also the best indicators of response to therapy during the recovery phase. With respect to experimental work on the pathogenesis of alcohol liver disease, it appears that necrosis is due to the inability to increase blood flow to compensate for increased oxygen utilization. The hypothesis that mitochondrial damage is the cause of liver cell damage is regarded as less important in the pathogenesis of necrosis. The shift in the redox state during alcohol metabolism accounts for the fatty change noted in the central lobular area of the liver in animals fed alcohol. Apparently, there is strong experimental evidence that highly reactive intermediates are important in the pathogenesis of liver damage due to the induction of the isozyme cytochrome P450 IIE1 by alcohol ingestion. This mechanism is enhanced by a diet high in polyunsaturated fatty acids.

Involvement of oxygen in harvesting injury of the liver. An experimental study including substrate free organ persufflation to evaluate a specific therapeutic approach

The present study was undertaken to assess the role of oxygen free radicals relating to cell damage upon reoxygenation of the ischemically altered isolated rat liver. Livers were excised and flushed via the portal vein with Ringer's solution and Euro-Collins solution, to which superoxide dismutase (SOD) was added in the experimental group. After warm ischemia at 37 degrees C and cold storage at 4 degrees C, the livers were reperfused via the portal vein with carbogen-saturated Krebs-Henseleit solution. Other livers were subjected to a retrograde persufflation via the infrahepatic caval vein with either oxygen or nitrogen and then rinsed with Ringer's solution. During reperfusion, SOD-treated livers showed markedly reduced vascular resistance, lower enzyme release and enhanced VO2 accordingly, energy charge at the end of reperfusion was significantly higher in the treated group. With reference to the tissue content of malondialdehyde, SOD-treated livers showed significantly less damage than the corroboration for these data. Enzyme activities in the eluate were significantly reduced under anoxic conditions as well as in the presence of SOD. We conclude from these data that oxygen free radicals do exert a detrimental impact on the reoxygenated liver, which could be specifically suppressed by application of exogenous SOD.

Adenosine partially prevents cirrhosis induced by carbon tetrachloride in rats

Adenosine administration was tested in rats with carbon tetrachloride-induced hepatic fibrosis and was able to partially prevent the enlargement of liver and spleen induced by the toxin. This amelioration of the hepatomegaly was accompanied by a 50% reduction of the liver collagen deposition and preservation of content of glycosaminoglycans. A stimulated hepatic collagenase activity is apparently the mechanism for reduction of collagen accumulation. These effects were associated with a striking improvement in liver function. Adenosine treatment did not modify the late hepatotoxic effect of the carbon tetrachloride; however, the stimulatory effect of the nucleoside on energy state appeared to counteract the drastic decreases in adenine nucleotides, ATP, ATP/ADP ratio and energy charge elicited by the hepatotoxin. Moreover, a possible beneficial action of enhanced hepatic oxygenation caused by the vasodilator properties of adenosine cannot be ruled out. Regardless of the mechanism, adenosine seems to change the cellular response to the injury induced by the hepatotoxin.

Prevention of impaired liver metabolism due to ischemia in rats. Efficacy of defibrotide administration

The effect of defibrotide treatment in protecting liver metabolism from ischemic damage was studied. The drug was administered to male Wistar rats as a bolus (30 mg/kg body weight) at the beginning of 60 min ischemia and then continuously during 60 min of postischemic reperfusion at a dose of 30 mg/kg body weight. This dose was previously identified as useful to protect against myocardial ischemia induced in the cat. ATP and ADP intrahepatic levels were significantly higher in drug-treated rats than in untreated animals. The liver cytoplasmic NAD+/NADH ratio in defibrotide-treated rats was no different from that observed in sham-operated rats. The mitochondrial NAD+/NADH ratio in the liver was also improved by defibrotide treatment. Our data suggest that defibrotide may exert protective activity on hepatocytes useful for inducing a rapid restoration of their metabolism. Such a restoration is possibly related to improvement of microcirculation through an increase in prostaglandin I2 production or oxygen delivery due to drug administration.

Biochemical basis for alcohol-induced liver injury

Chronic ethanol ingestion leads to hepatocellular injury and alcoholic liver disease (ALD) only if multiple factors combine to favor centrilobular hepatocellular hypoxia. It is hypothesized that these factors include a shift in the redox state, the induction of the microsomal ethanol oxidizing system (MEOS), a high blood alcohol level (BAL), a high polyunsaturated fat diet and episodic decreased O2 supply to the liver. The shift in the redox state favors a low cellular pH, decreased fatty acid oxidation and increased triglyceride formation. The increased MEOS activity increases O2 consumption and portal-central O2 gradient as well as favors acetaldehyde toxic effects including retention of hepatic lipids and export proteins causing cell swelling. The resultant increase in the concentration of acetaldehyde and lactate may stimulate fibrosis as they stimulate collagen synthesis in vitro. The resultant fatty liver narrows the sinusoids slowing sinusoid blood flow. The combination of events reduces available O2 leading to decreased levels of ATP and cellular pH making the liver vulnerable to episodes of systemic hypoxia. The role of membrane changes are reviewed, i.e., 1) membrane fluidity as related to changes in the species of phospholipids, 2) mitochondrial function as related to the changes in the lipid environment of the electron transport chain, and 3) linoleic acid-prostaglandin metabolism. Acute ethanol in vitro has been shown to affect liver cell metabolism regulation by triggering and increasing protein phosphorylation through the Ca2+-phospholipase C pathway. A high fat diet enhances the liver injury caused by chronic ethanol ingestion.

Short-term changes in blood ketone body ratios in the phase immediately after hepatic artery embolization: their clinical significance

Changes in arterial and hepatic venous blood ketone bodies were investigated following transcatheter hepatic artery embolization (THAE) in patients with hepatocellular carcinoma. Acetoacetate/ beta-hydroxybutyrate ratio (ketone body ratio) in arterial blood was positively correlated with those of hepatic venous blood (r = 0.960, p less than 0.001), which reflects the mitochondrial redox potential in the embolized lobe. Nine cirrhotic patients were classified into three groups according to the changes in arterial blood ketone body ratio following THAE: Type A without decrease to below 0.7; Type B with a transient decrease to below 0.7, followed by its restoration within 5 hours; and Type C with decrease to below 0.7 without recovery within 5 hours. There were no serious complications in Type A and B patients. By contrast, severe sepsis and hepatic failure developed in Type C patients, possibly due to the extended embolization of both lobes. It is suggested that THAE can be successfully performed even in severely cirrhotic patients, as long as the embolized area is restricted to one lobe. In addition, changes in arterial blood ketone body ratios can give early information about the likely consequences of the THAE procedure just performed.

Synthesis of heat shock proteins in rat liver after ischemia and hyperthermia

Ischemia of rat liver is followed by recovery or cell death. Since heat shock proteins may be essential to cell survival under stress, we determined levels of heat shock proteins in liver after different periods of blood deprivation and correlated the results with cellular recovery. Cell-free synthesis by poly (A+)-mRNA and polysomes revealed 70 and 89 kd proteins which appear similar to proteins produced by the liver of rats with amphetamine-induced hyperthermia. The 70 and 89 kd proteins increased in the liver of rats which recovered from ischemia.

Structural alterations of the inner mitochondrial membrane in ischemic liver cell injury

Mitoplasts were prepared from 3-h ischemic livers in an attempt to define the structural alterations in the inner membrane that may account for the functional deficiencies of ischemic mitochondria. Mitoplasts from both control and ischemic livers had similar specific activities of cytochrome oxidase and succinate-cytochrome c reductase. With both preparations, the specific activity of rotenone-insensitive NADH-cytochrome c reductase was 10-fold lower than in the mitochondria from which they were prepared. Ischemic mitoplasts had no respiratory control with ADP, and had a slightly reduced phospholipid to protein ratio and an increased cholesterol to protein ratio. As a result, the cholesterol to phospholipid molar ratio was increased from the control of 0.04 to 0.08. There were also differences in the content of individual phospholipid species. Phosphatidylcholine increased by 15%, while cardiolipin decreased by 60%. There were increases in sphingomyelin and in the lysophospholipids of phosphatidylcholine, ethanolamine, and cardiolipin. Pretreatment with chlorpromazine did not prevent these changes. Linoleic acid was decreased by 35% in ischemic phospholipids, and the content of free fatty acids was increased 4-fold. Electron spin resonance spectroscopy of mitoplasts spin labeled with either 5- or 12-doxyl stearic acid revealed an increased molecular order (decreased fluidity) of ischemic inner mitochondrial membranes consistent with the increased cholesterol to phospholipid ratio. The data indicate activation of a phospholipase A in ischemic mitochondria with the resulting accumulation of products of lipid hydrolysis. This conclusion further emphasizes the close similarity between the structural and functional consequences of ischemia in the intact animal and the effect on isolated mitochondria of the activation of the endogenous phospholipase A. In both cases the major functional alterations are attributable to changes in the permeability of the inner mitochondrial membrane induced by the accumulation of lysophospholipids.

The effect of cyclosporine on nucleotide content of rat lymphocytes

In vivo administration of cyclosporin A (CyA) was found to determine some variations in nucleotide content of rat lymphocytes. ATP levels were reduced by CyA treatment, and the effect was more evident in peripheral blood than in spleen lymphocytes. In contrast, cAMP values were increased upon pharmacologic treatment with the same major evidence at the blood lymphocyte level. Intralymphocytic phosphodiesterase enzyme activity became detectable during CyA administration, whereas the intracellular redox state (NAD+/NADH ratios) did not vary significantly. These results were amplified by increasing CyA concentration.

Effects of succinate on amino acid incorporation into protein during chemical carcinogenesis

The starting point of this study is the observation that succinate, the well-known Krebs cycle intermediate, strongly inhibits the incorporation of amino acids into protein of tissue slices. The results presented in this paper show that this somewhat peculiar succinate effect, which is present in regenerating liver and in a well-differentiated hepatoma and absent in two anaplastic hepatomas, is well-marked in all stages of hepatic carcinogenesis by N,N'-dimethyl-4-aminoazobenzene. A working hypothesis is that the inhibition by succinate of the amino acid incorporation into protein is mediated by a shift of the redox level in the cell toward a more reduced condition.

Metabolic studies of postischemic acute renal failure in the rat

Postischemic acute renal failure was induced by 1 hr of clamping of the renal vasculature. Adenine nucleotide (ATP, ADP, AMP) and lactate (Lac) levels were measured after 0, 0.25, 1, 6, 24, and 48 hr of reflow to determine the time necessary for recovery to control levels. After 1 hr of ischemia with no reflow, [ATP] was 18% and [Lac] was 10-fold control levels. Control levels were restored after 24 hr of reflow. Variable ischemic times (5, 15, 30, 60, 90, and 120 min) followed by (1) no reflow or (2) 24 hr of reflow were also studied. [ATP] decreased to 25 and 13% of controls after 5 and 120 min of ischemia, respectively, and [Lac] increased to 5- and 13-fold controls after 5 and 120 min. Five to ninety minutes of ischemia followed by 24 hr of reflow resulted in a trend toward restoration of ATP and Lac levels; whereas, 120 min of ischemia followed by 24 hr of reflow resulted in death. The results indicate that: (1) In vivo ischemia results in a drastic and rapid shift in the ATP-ADP-AMP equilibrium; (2) the absolute concentration of ATP is not a reliable criterion of cell viability, but the ability to resynthesize ATP may be determinant in the reversibility of the lesion; (3) 1 hr of ischemia is reversible with respect to restoration of [ATP] and [Lac], but 24 hr of reflow are needed for restoration; and (4) ischemia for 90 min results in a metabolic derangement which is partially reversible in that metabolite levels are partially restored after 24 hr of reflow. However, 90 min of vascular clamping is not functionally reversible since the majority of animals exhibit severe azotemia and do not survive.

Relationship of deranged energy metabolism in liver and kidney to arterial ketone body ratio following liver ischemia in rats

Changes in energy metabolism in the liver and kidney in liver ischemia induced in rats were simultaneously studied, in terms of energy charge (EC) and mitochondrial oxidoreduction state. Mean arterial blood pressure, glucose and lactate, total ketone bodies (acetoacetate + beta-hydroxybutyrate) and the ketone body ratio in arterial blood (KBR) were also investigated. During and after liver ischemia, both organs showed similar patterns of reversibility, and KBR, which reflects the mitochondrial oxidoreduction state, correlated well with EC, in both organs. Referring to the mortality and changes in substrates above mentioned, KBR is a pertinent parameter for detection of viability following induced liver ischemia. It was also suggested that KBR may indicate a regulating role by the liver, in kidney energy metabolism.

Anti-ribosomal ribonucleoprotein autoantibodies in systemic lupus erythematosus

Sera from systemic lupus erythematosus (SLE) patients giving a fluorescent ribosomal pattern on tissue and cell preparations also showed precipitating autoantibodies against purified rat liver ribosomes. Ribosomal antigen is also present in rabbit thymus cellular extract (RTE), since the same sera gave precipitin lines against RTE in identity with ribosomes. Immunofluorescent staining was completely inhibited by serum absorption with ribosomes or with RTE. However ribosomal RNA and RNase or trypsin-treated ribosomes failed to react with these autoantibodies as demonstrated in immunoabsorption and immunodiffusion studies. These data suggest that these sera contain autoantibodies directed against some antigenic site composed of a portion of both RNA and ribosomal protein. Ribosomal autoantibodies were detectable at a low frequency in SLE patients characterized by an active disease and renal involvement.

Effects of liver ischemia on degradation of different classes of hepatic proteins

The effects of liver ischemia on hepatic protein degradation were studied in rats. In one series of experiments degradation was measured in incubated liver slices as release of trichloroacetic acid soluble radioactivity from proteins prelabelled with L-(14C)-leucine during 4 h (short-lived proteins) or during 24 h (long-lived proteins). In another series of experiments protein degradation was determined in vivo by measuring decay of radioactivity in hepatic proteins prelabelled with (14C)-sodium bicarbonate administered intraperitoneally 4 h or 24 h before induction of liver ischemia. Degradation of short-lived proteins was reduced by 50% both in vitro and in vivo during liver ischemia while breakdown of long-lived proteins was unchanged. Thus, short-lived and long-lived proteins were differently affected by liver ischemia. These results are consistent with the concept of distinct proteolytic pathways for different classes of proteins.

Cell repair after liver injury: an analysis of some metabolic conditions required for the stimulation of RNA synthesis in postischemic liver nuclei

Nuclei isolated from liver cells recovering from reversible (non-necrogenic) ischemia show an increased RNA synthesis. The postischemic effect is not abolished by previous adrenalectomy and occurs in fasted as well as in fed animals. Treatment with cycloheximide, at a dose that severely inhibits protein synthesis without primary effects on RNA synthesis, suppresses the postischemic stimulation of RNA synthesis even if cycloheximide is administered when stimulation is already well developed. Postischemic liver nuclei respond only weakly to the additional stimulation of RNA synthesis caused by the presence of cytosol and albumin in the incubation medium.

Role of lipid peroxidation in tissue injury after hepatic ischemia

Ischemia and anoxia are associated with decreased concentrations of cellular antioxidants. The hypothesis that recirculation of oxygenated blood to previously ischemic tissue may result in enhanced free-radical reactions leading to lipid peroxidation and tissue damage was investigated. Elevated hepatic conjugated diene concentrations were detected 60 min after treatment of rats with carbon tetrachloride, a positive control, but were not found after 90 min ischemia or at 5 or 60 min after reperfusion of ischemic tissue. These findings suggest that lipid peroxidation may not be an early event in ischemia-induced necrosis but do not rule out a role of other free-radical reactions in the pathogenesis of ischemic necrosis.

Improved blood flow and protein synthesis in the postischemic liver following infusion of dopamine

To study the effects of dopamine on hepatic blood flow and protein synthesis in a condition with reduced liver blood flow, dopamine (5 micrograms X kg-1 X min-1) or saline was infused intravenously following a period of liver ischemia in rats. Hepatic blood flow was measured by xenon washout technique and protein synthesis by leucine incorporation into proteins in incubated liver slices. Blood flow and protein synthesis in the postischemic liver were restituted faster and more completely in dopamine-treated rats suggesting that dopamine infusion can be of beneficial effect on liver metabolism in situations with reduced hepatic blood flow.

Liver damage in rats during acute carbon monoxide poisoning

Plasma leucine aminopeptidase (LAP) levels and respiration rates of isolated liver mitochondria were studied in carbon monoxide (CO)-poisoned rats sampled at respiratory arrest. An increase in LAP levels paralleled a decrease in the respiratory control ratio and the ADP/O ratio. The results suggest that the damage to mitochondria closely correlates with the liver damage in rats during acute CO poisoning.

Deterioration of rat liver mitochondria under conditions of metabolite deprivation

In a previous study [Parce, Cunningham & Waite (1978) Biochemistry 17, 1634-1639] changes in mitochondrial phospholipid metabolism and energy-linked functions were monitored as coupled mitochondria were aged in iso-osmotic sucrose solution at 18 degrees C. The sequence of events that occur in mitochondrial deterioration under the above conditions have been established more completely. Total adenine nucleotides are depleted early in the aging process, and their loss parallels the decline in respiratory control. Related to the loss of total adenine nucleotides is a dramatic decrease in ADP and ATP translocation (uptake). The decline of respiratory control is due primarily to a decrease in State-3 respiration; loss of this respiratory activity can be related to the decline in ADP translocation. Mitochondrial ATPase activity does not increase significantly until State-4 respiration has increased appreciably. At the time of loss of respiratory control the ATPase activity increases to equal the uncoupler-stimulated activity. The H+/O ratio and P/O ratios do not decrease appreciably until respiratory control is lost. Similarly, permeability of the membrane to the passive diffusion of protons increases only after respiratory control is lost. There observations reinforce our earlier conclusion that there are two main phases in mitochondrial aging. The first phase is characterized by loss of the ability to translocate adenine nucleotides. The second phase is characterized by a decline in the ability of the mitochondrion to conserve energy (i.e. maintain a respiration-driven proton gradient) and to synthesize ATP.

Inhibition of protein synthesis in ischaemic liver from phenobarbitone-treated rat

Both ribosomal factors and cytosolic inhibitors are involved in the reduction of the rate of protein synthesis which occurs in the ischaemic hepatocyte from control and phenobarbitone-treated livers. Of these 2 factors it is the latter which seems to play a major role in determining the irreversible impairment of protein synthesis. Phenobarbitone administration has no effect on the rate of protein synthesis of ischaemic and post-ischaemic hepatocyte.

RNA synthesis by nuclei and nucleoli from ischemic liver cells

Nuclei and nucleoli were isolated from rat livers subjected to an interruption of the blood supply for periods of different duration, as well as after restoration of the blood supply. They were assayed for RNA synthesis under conditions of diverse ionic strengths, and in the presence of an exogenous template, such as poly d (A-T), and actinomycin to inactivate the endogenous template; alpha-amanitin was made used of to distinguish polymerase I and polymerase II dependent RNA synthesis. Nuclei and nucleoli from ischemic livers showed a severe impairment of RNA synthesis, which is likely to be due to decreased initiation frequency of the engaged polymerases, while free polymerases were essentially unchanged. Both form I and II polymerase were equally involved. After restoration of the blood supply RNA synthesis recovered with an overshooting well above normal levels of activity, lasting for at least 24 hours. Increased RNA synthesis was not followed by thymidine incorporation into DNA.

Different response of hepatic energy change and adenine nucleotide concentrations to hemorrhagic shock

The adenine nucleotide and mitochondrial metabolisms of the liver were studied in hemorrhagic shock of rats. In reversible shock, the energy charge (ATP+1/2ADP/ATP+ADP+AMP) levels fell more rapidly than the total adenine nucleotide concentrations and decreased to 64% of controls 2 hours after shock. However, the oxidative phosphorylation of isolated mitochondira was only slightly inhibited. The energy charge levels were restored to normal values immediately when the shed blood was reinfused, while the concentrations of adenine nucleotides increased gradually and reached normal at 2 hours later. In irreversible shock which took up 70% or more of the withdrawn blood to maintain pressure of 40mm. Hg, the energy charge, adenine nucleotide concentrations and mitochondrial oxidative phosphorylation decreased considerably and were not restored by the reinfusion of the remainder of shed blood. It is suggested that the energy charge can respond rapidly to changes in an available oxygen and the adenine nucleotide concentrations and that an impairment of mitochondrial oxidative phosphorylation plays an important role in leading to irreversible hemorrhagic shock.

Breakdown of 5'-adenine nucleotides in ischaemic renal cortex estimated by oxypurine excretion during perfusion

The catabolism of 5'-adenine nucleotides in the cortex of the rabbit kidney was studied during normothermic and hypothermic ischaemia. Changes were found in the cortical content of ATP, ADP, AMP, and SAN (the sum of 5'-adenine nucleotides) during ischaemia; those changes were delayed by hypothermia. The loss of SAN was found to be significantly correlated to the duration of normothermic as well as hypothermic ischaemia. The oxypurines hypoxanthine and xanthine and the nucleoside inosine were shown to be the final products of the catabolism of 5'-adenine nucleotides. An accumulation of hypoxanthine-xanthine and inosine in the tissue and a corresponding excretion in the perfusion fluid occurred simultaneously with the catabolism of 5'-adenine nucleotides, in equivalent amounts. It is concluded that determination of the amount of oxypurines excreted during kidney preservation is an indirect measure of the loss of SAN in the tissue, and a reflection of the changes in the metabolic state.

The effect of phenobarbitone on protein synthesis by liver polyribosomes in fed and starved rats

1. The effect of phenobarbitone on the rate of protein synthesis and on the sedimentation patterns of various liver subcellular fractions containing ribosomes was studied in rats. 2. Phenobarbitone treatment increased the incorporation of [114C]leucine into protein by all preparations, provided they had not been subjected to preliminary treatment with Sephadex G-25. The phenobarbitone-induced effect on incorporation was associated with a gain in liver weight and a higher degree of polyribosomal aggregation. 3. Preparations that were treated with Sephadex G-25 incorporated more radioactivity into protein, but did not show the response to phenobarbitone treatment. 4. When the influence of starvation and phenobarbitone was studied separately on membrane-bound and membrane-free polyribosomes, it was shown that whereas both classes of polyribosomes were affected by starvation, apparently only the former class was susceptible to phenobarbitone stimulation of protein synthesis. 5. The decreased capacity for protein synthesis of polyribosomes from starved rats was independent of their association with the membranes of the endoplasmic reticulum, but resulted from polyribosomal disaggregation, from an intrinsic defect of the polyribosomes themselves and from changes in composition of the cell cap. 6. The results are discussed in relation to the problem of the control of protein biosynthesis and of the functional separation of membrane-bound and membrane-free polyribosomes.