Zonation of the action of ethanol on gluconeogenesis and ketogenesis studied in the bivascularly perfused rat liver

Zonation of the actions of ethanol on gluconeogenesis and ketogenesis from lactate were investigated in the bivascularly perfused rat liver. Livers from fasted rats were perfused bivascularly in the antegrade and retrograde modes. Ethanol and lactate were infused into the hepatic artery (antegrade and retrograde) and portal vein. A previously described quantitative analysis that takes into account the microcirculatory characteristics of the rat liver was extended to the analysis of zone-specific effects of inhibitors. Confirming previous reports, gluconeogenesis and the corresponding oxygen uptake increment due to saturable lactate infusions were more pronounced in the periportal region. Arterially infused ethanol inhibited gluconeogenesis more strongly in the periportal region (inhibition constant = 3.99 ± 0.22 mM) when compared to downstream localized regions (inhibition constant = 8.64 ± 2.73 mM). The decrease in oxygen uptake caused by ethanol was also more pronounced in the periportal zone. Lactate decreased ketogenesis dependent on endogenous substrates in both regions, periportal and perivenous, but more strongly in the former. Ethanol further inhibited ketogenesis, but only in the periportal zone. Stimulation was found for the perivenous zone. The predominance of most ethanol effects in the periportal region of the liver is probably related to the fact that its transformation is also clearly predominant in this region, as demonstrated in a previous study. The differential effect on ketogenesis, on the other hand, suggest that the net effects of ethanol are the consequence of a summation of several partial effects with different intensities along the hepatic acini.     

The metabolism of fructose in the bivascularly perfused rat liver.

The metabolism of fructose was investigated in the bivascularly and hemoglobin-free perfused rat liver. Anterograde and retrograde perfusions were performed. In anterograde perfusion, fructose was infused at identical rates (19 mumols min-1 g-1) via the portal vein (all liver cells) or the hepatic artery (predominantly perivenous cells); in retrograde perfusion fructose was infused via the hepatic vein (all liver cells) or the hepatic artery (only periportal cells). The cellular water spaces accessible via the hepatic artery were measured by means of the multiple-indicator dilution technique. The following results were obtained. (i) Fructose was metabolized to glucose, lactate and pyruvate even when this substrate was infused via the hepatic artery in retrograde perfusion; oxygen consumption was also increased. (ii) When referred to the water spaces accessible to fructose via the hepatic artery in each perfusion mode, the rate of glycolysis was 0.99 +/- 0.14 mumols min-1 ml-1 in the retrograde mode; and, 2.05 +/- 0.19 mumols min-1 ml-1 in the anterograde mode (P = 0.002). (iii) The extra oxygen uptake due to fructose infusion via the hepatic artery was 1.09 +/- 0.16 mumols min-1 ml-1 in the retrograde mode; and, 0.51 +/- 0.08 mumols min-1 ml-1 in the anterograde mode (P = 0.005). (iv) Glucose production from fructose via the hepatic artery was 2.18 +/- 0.18 mumols min-1 ml-1 in the retrograde mode; and, 1.83 +/- 0.16 mumols min-1 ml-1 in the anterograde mode (P = 0.18). (v) Glucose production and extra oxygen uptake due to fructose infusion did not correlate by a single factor in all perfusion modes. It was concluded that: (a) rates of glycolysis are lower in the periportal area, confirming previous views; (b) extra oxygen uptake due to fructose infusion is higher in the periportal area; (c) a predominance of glucose production in the periportal area could not be demonstrated; and (d) extra oxygen uptake due to fructose infusion is not a precise indicator for glucose synthesis.     

Liver parenchyma heterogeneity in the response to extracellular NAD+

The perfused rat liver responds intensely to NAD+ infusion (20-100 microM). Increases in portal perfusion pressure and glycogenolysis and transient inhibition of oxygen consumption are some of the effects that were observed. The aim of the present work was to investigate the distribution of the response to extracellular NAD+ along the hepatic acinus. The bivascularly perfused rat liver was used. Various combinations of perfusion directions (antegrade and retrograde) and infusion routes (portal vein, hepatic vein and hepatic artery) were used in order to supply NAD+ to different regions of the liver parenchyma, also taking advantage of the fact that its extracellular transformation generates steep concentration gradients. Oxygen uptake was stimulated by NAD+ in retrograde perfusion (irrespective of the infusion route) and transiently inhibited in antegrade perfusion. This indicates that the signal causing oxygen uptake inhibition is generated in the periportal area. The signal responsible for oxygen uptake stimulation is homogenously distributed. Stimulation of glucose release was more intense when NAD+ was infused into the portal vein or into the hepatic artery, indicating that stimulation of glycogenolysis predominates in the periportal area. The increases in perfusion pressure were more pronounced when the periportal area was supplied with NAD+ suggesting that the vasoconstrictive elements responding to NAD+ predominate in this region. The response to extracellular NAD+ is thus unequally distributed in the liver. As a paracrine agent, NAD+ is likely to be released locally. It can be concluded that its effects will be different depending on the area where it is released.     

Hepatic heterogeneity in the response to ATP studied in the bivascularly perfused rat liver

The zonation of the purinergic action of ATP in the hepatic parenchyma was investigated in the bivascularly perfused rat liver by means of anterograde and retrograde perfusion. Livers from fed rats were used, and ATP was infused according to four different experimental protocols: (A) anterograde perfusion and ATP infusion via the portal vein; (B) anterograde perfusion and ATP via the hepatic artery; (C) retrograde perfusion and ATP via the hepatic vein; (D) retrograde perfusion and ATP via the hepatic artery. The following metabolic parameters were measured: glucose release, lactate production and oxygen consumption. The hemodynamic effects were evaluated by measuring the sinusoidal mean transit times by means of the indicator-dilution technique. ATP was infused during 20 min at four different rates (between 0.06-0.77 µmol min_-1 g liver_-1; 20-200 µM) in each of the four experimental protocols.The results that were obtained allow several conclusions with respect to the localization of the effects of ATP along the hepatic acini: (1) In retrograde perfusion the sinusoidal mean transit times were approximately twice those observed in anterograde perfusion. ATP increased the sinusoidal mean transit times only in retrograde perfusion (protocols C and D). The effect was more pronounced with protocol D. These results allow the conclusion that the responsive vasoconstrictive elements are localized in a pre-sinusoidal region; (2) All hepatic cells, periportal as well as perivenous, were able to metabolize ATP, so that concentration gradients were generated with all experimental protocols. Extraction of ATP was more pronounced in retrograde perfusion, an observation that can be attributed, partly at least, to the longer sinusoidal transit times. In anterograde perfusion, the extraction of ATP was time-dependent, a phenomenon that cannot be satisfactorily explained with the available data; (3) ATP produced a transient initial inhibition of oxygen uptake when protocols A and B were employed. These protocols are the only ones in which the cells situated shortly after the intrasinusoidal confluence of the portal vein and the hepatic artery were effectively supplied with ATP. The decrease in oxygen consumption was more pronounced at low ATP infusions when protocol B was employed. These observations allow the conclusion that the former phenomenon is localized mainly in cells situated shortly after the intrasinusoidal confluence of the portal vein and hepatic artery. Oxygen consumption in all other cells, especially the proximal periportal ones, is increased by ATP; (4) In agreement with previous data found in the literature, glycogenolysis stimulation by ATP was more pronounced in the periportal region. The cells that respond more intensively are not the proximal periportal ones, but those situated in the region of the intrasinusoidal confluence of the portal vein and the hepatic artery.     

Bivascular liver perfusion in the anterograde and retrograde modes: Zonation of the response to inhibitors of oxidative phosphorylation

The action of cyanide (500 μM ), 2,4-dinitrophenol (50 μM ) and atractyloside (100 μM ) on glycogen catabolism and oxygen uptake was investigated in the bivascularly perfused liver of fed rats. Cyanide, 2,4-dinitrophenol and atractyloside were infused at identical rates into the hepatic artery in either the anterograde or retrograde perfusion. The accessible aqueous cell spaces were determined by means of the multiple-indicator dilution technique. Glucose release, oxygen uptake and glycolysis were measured as metabolic parameters. Oxygen uptake changes per unit cell space caused by atractyloside (inhibition) and 2,4-dinitrophenol (stimulation) were equal in the retrograde perfusion (periportal cells) and the anterograde perfusion (space enriched in perivenous cells); the decreases caused by cyanide were higher in the retrograde perfusion. Glucose release from periportal cells was not increased upon inhibition of oxidative phosphorylation, a phenomenon which was independent of the mechanism of action of the inhibitor. There were nearly identical changes in glycolysis in the periportal and perivenous cells. It was concluded that: (1) oxygen concentration in the perfused rat liver, if maintained above 100 μM , had little influence on the zonation of the respiratory activity; (2) in spite of the lower activities of the key enzymes of glycolysis in the periportal hepatocytes, as assayed under standard conditions, these cells were as effective as the perivenous ones in generating ATP in the cytosol when oxidative phosphorylation was impaired; (3) the key enzymes of glycogenolysis and glycolysis in periportal and perivenous cells responded differently to changes in the energy charge.     

The zonation of liver and the distribution of fructose 2,6-bisphosphate in rat liver

Livers of starved rats refed for 2 h were perfused in situ by a modification of the dual digitonin pulse technique of Quistorff and Grunnet (Quistorff, B., and Grunnet, N. (1987) Biochem. J. 243, 87-95). A pulse of digitonin (2 mg/ml) was infused first antegrade through the portal vein followed retrograde through the vena cava, or in reverse order, 13 mg of digitonin per zone. Microscopic examination showed that this procedure permeabilized the periportal and perivenous zones of the liver without overlap, with a narrow unaffected band of hepatocytes between the zones. The distribution pattern between periportal and perivenous zones ratio for alanine transaminase, lactate hydrogenase, fructose-1,6-bisphosphatase, and phosphoenolpyruvate carboxykinase ranged from 1.5 to 3. Glucokinase activity was higher in the perivenous zone (periportal/perivenous ratio of 0.7) and glutamine synthetase was exclusively present in that zone. Fructose 2,6-bisphosphate concentration was nearly equal in the two zones.     

Zonation of the metabolic action of vasopressin in the bivascularly perfused rat liver

Predominance of the vasopressin binding capacity in the hepatic perivenous area leads to the hypothesis that the metabolic effects of the hormone should also be more pronounced in this area. Until now this question has been approached solely by experiments with isolated hepatocytes where an apparent absence of metabolic zonation was found. We have reexamined this question using the bivascularly perfused liver. In this system periportal cells can be reached in a selective manner with substrates and effectors via the hepatic artery when retrograde perfusion (hepatic vein --> portal vein) is done. The action of vasopressin (1-10 nM) on glycogenolysis, initial calcium efflux, glycolysis and oxygen uptake were measured. The results revealed that the action of vasopressin in the liver is heterogeneously distributed. Glycogenolysis stimulation and initial calcium efflux were predominant in the perivenous area, irrespective of the vasopressin concentration. Oxygen uptake was stimulated in the perivenous area; in the periportal area it ranged from inhibition at low vasopressin concentrations to stimulation at high ones. Lactate production was generally greater in the perivenous zone, whereas the opposite occurred with pyruvate production. Analysis of these and other results suggests that at least three factors are contributing to the heterogenic response of the liver parenchyma to vasopressin: a) receptor density, which tends to favour the perivenous zone; b) cell-to-cell interactions, which tend to favour situations where the perivenous zone is amply supplied with vasopressin; and c) the different response capacities of perivenous and periportal cells.     

Hepatocyte heterogeneity in glutamine and ammonia metabolism and the role of an intercellular glutamine cycle during ureogenesis in perfused rat liver

1. The metabolism of glutamine and ammonia was studied in isolated perfused rat liver in relation to its dependence on the direction of perfusion by comparing the physiological antegrade (portal to caval vein) to the retrograde direction (caval to portal vein). 2. Added ammonium ions are mainly converted to urea in antegrade and to glutamine in retrograde perfusions. In the absence of added ammonia, endogenously arising ammonium ions are converted to glutamine in antegrade, but are washed out in retrograde perfusions. When glutamine synthetase is inhibited by methionine sulfoximine, direction of perfusion has no effect on urea synthesis from added or endogenous ammonia. 3. 14CO2 production from [1-14C]glutamine is higher in antegrade than in retrograde perfusions as a consequence of label dilution during retrograde perfusions. 4. The results are explained by substrate and enzyme activity gradients along the liver lobule under conditions of limiting ammonia supply for glutamine and urea synthesis, and they are consistent with a perivenous localization of glutamine synthetase and a predominantly periportal localization of glutaminase and urea synthesis. Further, the data indicate a predominantly periportal localization of endogenous ammonia production. The results provide a basis for an intercellular (as opposed to intracellular) glutamine cycling and its role under different metabolic conditions.     

Regional heterogeneities in the production of uric acid from adenosine in the bivascularly perfused rat liver

The heterogeneity of the liver parenchyma in relation to uric acid production from adenosine was investigated using the bivascularly perfused rat liver in the anterograde and retrograde modes. Adenosine was infused in livers from fed rats during 20 min at four different concentrations (20, 50, 100 and 200 M) according to four experimental protocols as follows: (A) anterograde perfusion, with adenosine infusion into the portal vein; (B) anterograde perfusion, with adenosine in the hepatic artery, (C) retrograde perfusion, with adenosine in the hepatic vein; (D) retrograde perfusion, with adenosine in the hepatic artery. With protocols A, B, and D uric acid production from adenosine was always characterized by initial bursts followed by progressive decreases toward smaller steady-states. With protocol C the initial burst was present only when 200 M adenosine was infused. The initial bursts in uric acid production were accompanied by simultaneous increases in the ratio of uric acid production/adenosine uptake rate. These initial bursts are thus representing increments in the production of uric acid that are not corresponded by similar increments in the metabolic uptake rates of adenosine. Global analysis of uric acid production revealed that the final steady-state rates were approximately equal for all infusion rates with protocols A, B and C, but smaller with protocol D. This difference, however, can be explained in terms of the differences in accessible cellular spaces, which are much smaller when protocol D is employed. When the analysis was performed in terms of the extra amounts of uric acid produced during the infusion of adenosine, where the initial bursts are also taken into account, different dose-response curves were found for each experimental protocol. These differences cannot be explained in terms of the accessible cell spaces and they are likely to reflect regional heterogeneities. From the various dose-response curves and from the known characteristics of the microcirculation of the rat liver it can be concluded that the initial bursts in uric acid production are generated in periportal hepatocytes. The reason for this heterogeneity could be related to the metabolic effects of adenosine, especially to oxygen uptake inhibition, which is likely to produce changes in the ATP/AMP ratios.     

Metabolism of cysteinyl leukotrienes in non-recirculating rat liver perfusion. Hepatocyte heterogeneity in uptake and biliary excretion

1. The uptake, metabolism and biliary excretion of the cysteinyl leukotrienes LTC4, LTD4 and LTE4, were studied in a non-recirculating rat liver perfusion system at constant flow in both antegrade (from the portal to the caval vein) and retrograde (from the caval to the portal vein) perfusion directions. During a 5-min infusion of [3H]LTC4, [3H]LTD4 and [3H]LTE4 (10 nmol/l each) in antegrade perfusions single-pass extractions of radioactivity from the perfusate were 66%, 81% and 83%, respectively. Corresponding values for LTC4 and LTD4 in retrograde perfusions were 83% and 93%, respectively, indicating a more efficient uptake of cysteinyl leukotrienes in retrograde than in antegrade perfusions. The concentrations of unmetabolized leukotrienes in the effluent perfusate were 8-12% in antegrade and 2-4% in retrograde perfusions. [14C]Taurocholate extraction from the perfusate was inhibited by LTC4 by only 3%, suggesting that an opening of portal-venous/hepatic-venous shunts does not explain the effects of perfusion direction on hepatic LTC4 uptake. 2. Following infusion of [3H]LTC4 and [3H]LTD4, in the antegrade perfusion direction, about 80% and 87%, respectively, of the radiolabel taken up by the liver was excreted into bile. In retrograde perfusions, however, only 40% and 57%, respectively, was excreted into bile and the remainder was slowly redistributed into the perfusate, indicating that leukotrienes were taken up into a hepatic compartment with less effective biliary elimination or converted to metabolites escaping biliary excretion. The metabolite pattern found in bile was not affected by the direction of perfusion. Biliary products of LTC4 were polar metabolites (31-38%), LTD4 (27-30%), LTE4 (about 1%) and N-acetyl-LTE4 (3-4%) in addition to unmodified LTC4 (17-18%). 3. LTC4 was identified as a major metabolite of [3H]LTD4 in bile, amounting to about 20% of the total radioactivity excreted into bile. This is probably due to a gamma-glutamyltransferase-catalyzed glutamyl transfer from glutathione in the biliary compartment, as demonstrated in in vitro experiments. The presence of sinusoidal gamma-glutamyltransferase activity in perfused rat liver was shown in experiments on the hydrolysis of infused gamma-glutamyl-p-nitroanilide. 90% inhibition of this enzyme activity by AT-125 did not affect the metabolism of LTC4. 4. When [3H]LTE4 was infused in the antegrade perfusion direction, biliary metabolites comprised N-acetyl-LTE4 (24%) and polar components (60%).(ABSTRACT TRUNCATED AT 400 WORDS)     

Differential effect of glucagon on gluconeogenesis in periportal and pericentral regions of the liver lobule.

The effect of glucagon on gluconeogenesis was measured in periportal and pericentral regions of the liver lobule by monitoring changes in rates of O2 uptake on the surface of the perfused liver with miniature O2 electrodes after infusion of lactate. When lactate (2 mM) was infused into livers from starved rats perfused in the anterograde direction, O2 uptake was increased 2.5-fold more in periportal than in pericentral regions, reflecting increased energy demands for glucose synthesis. Under these conditions, glucagon infusion in the presence of lactate increased O2 uptake exclusively in periportal regions of the liver lobule. Thus, when perfusion is in the physiological anterograde direction, the metabolic actions of glucagon predominate in periportal regions of the liver lobule under gluconeogenic conditions in the starved state. When livers were perfused in the retrograde direction, however, glucagon stimulated O2 uptake exclusively in pericentral regions. Thus glucagon only stimulates gluconeogenesis in 'upstream' regions of the liver lobule irrespective of the direction of flow.     

High zone-selectivity of cell permeabilization following digitonin-pulse perfusion of rat liver. A re-interpretation of the microcirculatory zones

The plasma membrane permeabilization obtained by exposure of hepatocytes to digitonin is utilized in the so-called digitonin-pulse perfusion of rat liver (Quistorff and Grunnet 1987). Brief pulses of digitonin applied with antegrade and retrograde perfusion of the liver caused selective elution of cytosolic enzymes and metabolites from the periportal and the perivenous zone of the same liver. In the present study a light microscopical examination of the liver fixed immediately after the digitonin pulse confirmed the very high zonal selectivity of the method inferred from the marker enzyme pattern of the eluates: Only cells around the port of entry of digitonin were affected and the borderline between affected and non-affected cells was always sharp. The typical periportal lesion was triangular in shape, enclosing the portal space, while the perivenous lesion was roughly circular, concentric with the hepatic vein. Assuming that the digitonin lesion reflects the microcirculatory flow pattern these findings seem to be at variance with the acinar model of Rappaport (Rappaport et al. 1954). The lesion in the lobuli near the surface of the liver as reflected by the discoloration pattern observed on the surface was the same as the lesion of deeper lobuli. The conducting vessels of the liver were only insignificantly affected by digitonin. At the cellular level only the sinusoidal luminal surface of the hepatocytes was affected. The cytoplasmic matrix of the cells including glycogen appeared thinned. All cell types of the liver parenchyma seemed to be equally affected by the digitonin treatment.     

High zone-selectivity of cell permeabilization following digitonin-pulse perfusion of rat liver

Summary The plasma membrane permeabilization obtained by exposure of hepatocytes to digitonin is utilized in the so-called digitonin-pulse perfusion of rat liver (Quistorff and Grunnet 1987). Brief pulses of digitonin applied with antegrade and retrograde perfusion of the liver caused selective elution of cytosolic enzymes and metabolites from the periportal and the perivenous zone of the same liver. In the present study a light microscopical examination of the liver fixed immediately after the digitonin pulse confirmed the very high zonal selectivity of the method inferred from the marker enzyme pattern of the eluates: Only cells around the port of entry of digitonin were affected and the borderline between affected and non-affected cells was always sharp. The typical periportal lesion was triangular in shape, enclosing the portal space, while the perivenous lesion was roughly circular, concentric with the hepatic vein. Assuming that the digitonin lesion reflects the microcirculatory flow pattern these findings seem to be at variance with the acinar model of Rappaport (Rappaport et al. 1954). The lesion in the lobuli near the surface of the liver as reflected by the discoloration pattern observed on the surface was the same as the lesion of deeper lobuli. The conducting vessels of the liver were only insignificantly affected by digitonin. At the cellular level only the sinusoidal luminal surface of the hepatocytes was affected. The cytoplasmic matrix of the cells including glycogen appeared thinned. All cell types of the liver parenchyma seemed to be equally affected by the digitonin treatment.     

Gluconeogenesis from fructose predominates in periportal regions of the liver lobule

Gluconeogenesis from fructose was studied in periportal and pericentral regions of the liver lobule in perfused livers from fasted, phenobarbital-treated rats. When fructose was infused in increasing concentrations from 0.25 to 4 mM, corresponding stepwise increases in glucose formation by the perfused liver were observed as expected. Rates of glucose and lactate production from 4 mM fructose were around 100 and 75 mumol/g/h, respectively. Rates of fructose uptake were around 190 mumol/g/h when 4 mM fructose was infused. 3-Mercaptopicolinate, an inhibitor of phosphoenolpyruvate carboxykinase, decreased glucose formation from fructose maximally by 20% suggesting that a fraction of the lactate formed from fructose is used for glucose synthesis. A good correlation (r = 0.92) between extra oxygen consumed and glucose produced from fructose was observed. At low fructose concentrations (less than 0.5 mM), the extra oxygen uptake was much greater than could be accounted for by glucose synthesis possibly reflecting fructose 1-phosphate accumulation. Furthermore, fructose diminished ATP/ADP ratios from about 4.0 to 2.0 in periportal and pericentral regions of the liver lobule indicating that the initial phosphorylation of fructose via fructokinase occurs in both regions of the liver lobule. Basal rates of oxygen uptake measured with miniature oxygen electrodes were 2- to 3-fold higher in periportal than in pericentral regions of the liver lobule during perfusions in the anterograde direction. Infusion of fructose increased oxygen uptake by 65 mumol/g/h in periportal areas but had no effect in pericentral regions of the liver lobule indicating higher local rates of gluconeogenesis in hepatocytes located around the portal vein. When perfusion was in the retrograde direction, however, glucose was synthesized nearly exclusively from fructose in upstream, pericentral regions. Thus, gluconeogenesis from fructose is confined to oxygen-rich upstream regions of the liver lobule in the perfused liver.     

Differential effects of human anaphylatoxin C3a on glucose output and flow in rat liver during orthograde and retrograde perfusion: the periportal scavenger cell hypothesis

1) During orthograde perfusion of rat liver human anaphylatoxin C3a caused an increase in glucose and lactate output and reduction of flow. These effects could be enhanced nearly twofold by co-infusion of the carboxypeptidase inhibitor MERGETPA, which reduced inactivation of C3a to C3adesArg. 2) During retrograde perfusion C3a caused a two- to threefold larger increase in glucose and lactate output and reduction of flow than in orthograde perfusions. These actions tended to be slightly enhanced by MERGETPA. 3) The elimination of C3a plus C3adesArg immunoreactivity during a single liver passage was around 67%, irrespective of the perfusion direction and the presence of the carboxypeptidase inhibitor MERGETPA; however, less C3adesArg and more intact C3a appeared in the perfusate in the presence of MERGETPA in orthograde and retrogade perfusions. It is concluded that rat liver inactivated human anaphylatoxin C3a by conversion to C3adesArg and moreover eliminated it by an additional process. The inactivation to C3adesArg seemed to be located predominantly in the proximal periportal region of the liver sinusoid, since C3a was less effective in orthograde perfusions, when C3a first passed the proximal periportal region before reaching the predominant mass of parenchyma as its site of action, than in retrograde perfusions, when it first passed the perivenous area. These data may be evidence for a periportal scavenger mechanism, by which the liver protects itself from systemically released mediators of inflammation that interfere with the local regulation of liver metabolism and hemodynamics.     

Gluconeogenesis predominates in periportal regions of the liver lobule

Rates of gluconeogenesis from lactate were calculated in periportal and pericentral regions of the liver lobule in perfused rat livers from increases in O2 uptake due to lactate. When lactate (0.1-2.0 mM) was infused into livers from fasted rats perfused in either anterograde or the retrograde direction, a good correlation (r = 0.97) between rates of glucose production and extra O2 uptake by the liver was observed as expected. Rates of oxygen uptake were determined subsequently in periportal and pericentral regions of the liver lobule by placing miniature oxygen electrodes on the liver surface and measuring the local change in oxygen concentration when the flow was stopped. Basal rates of oxygen uptake of 142 +/- 11 and 60 +/- 4 mumol X g-1 X h-1 were calculated for periportal and pericentral regions, respectively. Infusion of 2 mM lactate increased oxygen uptake by 71 mumol X g-1 X h-1 in periportal regions and by 29 mumol X g-1 X h-1 in pericentral areas of the liver lobule. Since the stoichiometry between glucose production and extra oxygen uptake is well-established, rates of glucose production in periportal and pericentral regions of the liver lobule were calculated from local changes in rates of oxygen uptake for the first time. Maximal rates of glucose production from lactate (2 mM) were 60 +/- 7 and 25 +/- 4 mumol X g-1 X h-1 in periportal and pericentral zones of the liver lobule, respectively. The lactate concentrations required for half-maximal glucose synthesis were similar (0.4-0.5 mM) in both regions of the liver lobule in the presence or absence of epinephrine (0.1 microM). In the presence of epinephrine, maximal rates of glucose production from lactate were 79 +/- 5 and 59 +/- 3 mumol X g-1 X h-1 in periportal and pericentral regions, respectively. Thus, gluconeogenesis from lactate predominates in periportal areas of the liver lobule during perfusion in the anterograde direction; however, the stimulation by added epinephrine was greatest in pericentral areas. Differences in local rates of glucose synthesis may be due to ATP availability, as a good correlation between basal rates of O2 uptake and rates of gluconeogenesis were observed in both regions of the liver lobule in the presence and absence of epinephrine. In marked contrast, when livers were perfused in the retrograde direction, glucose production was 28 +/- 5 mumol X g-1 X h-1 in periportal areas and 74 +/- 6 mumol X g-1 X h-1 in pericentral regions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Hepatocyte heterogeneity in response to extracellular ATP

1. The metabolic and hemodynamic effects of extracellular ATP in perfused rat liver were compared during physiologically antegrade (portal to hepatic vein) and retrograde (hepatic to portal vein) perfusion. ATP in concentrations up to 100 microM was completely hydrolyzed during a single liver passage regardless of the perfusion direction. 2. The ATP(20 microM)-induced increases of glucose output, perfusion pressure and ammonium ion release seen during antegrade perfusions were diminished by 85-95% when the perfusion was in the retrograde direction, whereas the amount of Ca2+ mobilized from the liver was decreased by only 60%. The maximal rate of initial K+ uptake following ATP was dependent on the amount of Ca2+ mobilized regardless of the direction of perfusion. In the presence of UMP (1 mM), an inhibitor of ATP hydrolysis by membrane-bound nucleotide pyrophosphatase, the effect of the direction of perfusion on the glycogenolytic response to ATP (20 microM) was largely diminished. 3. For a maximal response of glucose output, Ca2+ release and perfusion pressure to extracellular ATP, concentrations of about 20 microM, 50 microM and 100 microM were required during antegrade perfusion, respectively. These maximal responses could also be obtained during retrograde perfusion, but higher ATP concentrations were required (120 microM, 80 microM, above 200 microM, respectively). 4. 14CO2 production from [1-14C]glutamate which occurs predominantly in the perivenous hepatocytes capable of glutamine synthesis was stimulated by extracellular ATP (20 microM); it was only slightly affected by the direction of perfusion. In antegrade perfusions, ATP (20 microM) increased 14CO2 production from 88 to 162 nmol g-1 min-1, compared to an increase from 91 to 148 nmol g-1 min-1 in retrograde perfusion. 5. The data are interpreted to suggest that (a) extracellular ATP is predominantly hydrolyzed by a small hepatocyte population located at the perivenous outflow of the acinus; (b) glycogenolysis to glucose is predominantly localized in the periportal area; (c) contractile elements (sphincters) exist near the inflow of the sinusoidal bed; (d) a considerable portion of the Ca2+ mobilized by ATP is derived from liver cells that do not contribute to hepatic glucose output.     

Heterogeneous distribution of ATP citrate lyase in rat-liver parenchyma. Microradiochemical determination in microdissected periportal and perivenous liver tissue

1. A radiochemical microtest was established for the determination of ATP citrate lyase in tissue samples of 0.2-1.0 micrograms dry weight. The specificity of this test system was guaranteed by its coenzyme A dependence as well as by inhibition of the activity measured in presence of a specific antibody. 2. Using this test system ATP citrate lyase activity was determined in microdissected periportal and perivenous liver tissue of fed, fasted and refed animals. The perivenous activity was 1.8-fold and 2.4-fold higher than the periportal one in fed male and female rats respectively. 3. The perivenous to periportal gradient was decreased during starvation-dependent reduction of the ATP citrate lyase activity. On the other hand it was not only restored but enhanced up to 2.8 after refeeding-dependent enhancement of the enzyme activity. 4. The predominance of the ATP citrate lyase activity in the perivenous, mainly glycolytic zone supports the hypothesis of the coordinate zonation of the carbohydrate and the lipid metabolism in the liver parenchyma.     

Glycogen synthesis from pyruvate in the periportal and from glucose in the perivenous zone in perfused livers from fasted rats

The isolated liver of 24 h fasted rats was perfused in a non-recirculating manner in the orthograde or retrograde direction with media containing glucose and/or gluconeogenic precursors. Glycogen formation was determined biochemically and demonstrated histochemically. With glucose as the only exogenous substrate glycogen was formed exclusively in the perivenous area during both orthograde and retrograde perfusion. With gluconeogenic precursors as the exogenous substrates glycogen was deposited in the periportal zone during orthograde perfusion and in the intermediate zone during retrograde perfusion. Supply of glucose and gluconeogenic substrates initiated glycogen synthesis only in the upstream region, i.e. in the periportal zone during orthograde and in the perivenous zone during retrograde perfusion. This localization of glycogen synthesis was probably due to an unavoidable, insufficient oxygen supply of the respective downstream area. In general, the results confirm the hypothesis that periportal and perivenous glycogen was synthesized from different substrates.     

Mechanism of the stimulatory effect of fructose on ethanol oxidation in perfused rat liver.

The stimulatory effect of fructose on ethanol oxidation was studied in livers from fasted rats perfused with Krebs-Henseleit-bicarbonate buffer in a non-recirculating system. Two series of experiments were performed: (A) ethanol was infused with stepwise increasing concentrations (0.1-20 mM) in the presence of 4 mM fructose; (B) fructose was infused with stepwise increasing concentrations (0.5-10 mM) in the presence of 2 mM ethanol. From measured metabolic rates the following parameters were calculated: energy-rich phosphates consumed for fructose metabolism which were provided from oxidative phosphorylation (delta approximately P); reducing equivalents derived from stimulated ethanol utilization which were disposed by mitochondrial oxidation (delta2H). Under the various conditions studied a linear relationship between these parameters was observed. The ratio delta approximately P/delta2H was about 2.0. It is suggested that fructose stimulates ethanol oxidation indirectly by increasing the energy consumption of the liver due to the production of glucose from fructose. Consequetnly, the rate of oxidative phosphorylation is increased and, therefore, the capacity of the respiratory chain for oxidizing reducing equivalents derived from ethanol is enhanced. The data support the more general hypothesis that the rate of ethanol oxidation depend upon the rate of hepatic energy consumption in a given metabolic state.