Tissue and subcellular distribution of glucokinase in rat liver and their changes during fasting-refeeding

The distribution of glucokinase in rat liver under both normal feeding and fasting-refeeding conditions was investigated immunohistochemically. Under normal feeding conditions, glucokinase immunoreactivity was observed in both nuclei and cytoplasm of parenchymal cells. The nuclei were stained intensely and evenly, whereas the cytoplasm showed weak immunoreactivity of different degrees of staining intensity depending on the location of the cells. The cytoplasm of perivenous hepatocytes was stained more intensely, though not so much more, than that of periportal hepatocytes. The cytoplasm of hepatocytes surrounding the terminal hepatic venule (THV), of hepatocytes surrounding the portal triad, and of some other hepatocytes showed a stronger immunoreactivity than that of residual hepatocytes. The nuclear immunoreactivity in hepatocytes surrounding the portal triad and in some other hepatocytes was weak or absent, and positive immunoreactivity was detected at the plasma membrane of some of these cells. After 72 h of fasting, glucokinase immunoreactivity was markedly decreased in all hepatocytes. After the start of refeeding, the cytoplasmic immunoreactivity began to increase first in the parenchymal cells surrounding the THV and extended to those in the intermediate zone followed by those in the periportal zone. In contrast, the increase in nuclear immunoreactivity started in hepatocytes situated in the intermediate zone adjacent to the perivenous zone and then extended to those in the perivenous zone followed by those in the periportal zone. Hepatocytes surrounding either THV or portal triad showed a distinctive change in immunoreactivity during the refeeding period. After 10 h of refeeding, strong immunoreactivity was observed in both the cytoplasm and the nuclei of all hepatocytes, and appreciable glucokinase immunoreactivity was detected at the plasma membrane of some hepatocytes. These findings are discussed from the standpoint of a functional role of glucokinase in hepatic glucose metabolism.     

肝细胞的异质性：葡萄糖和酮体在大鼠肝脏的代谢

用大鼠肝脏门静脉或肝静脉周围的肝细胞来研究葡萄糖和酮体生成的区域分布。肝细胞通过毛地黄皂苷－胶原酶灌流技术分离。门静脉周围肝细胞的γ谷氨酰转肽酶的活性比肝静脉周围肝细胞高２．４倍;而谷氨酰胺合成酶的活性则相反,肝静脉周围肝细胞高出５６倍。门静脉周围肝细胞的内源性葡萄糖合成比肝静脉周围肝细胞高１．５７倍。给予刺激葡萄糖异生的底物,门静脉周围肝细胞的葡萄糖合成则增加１．７－２．１倍。肝静脉周围肝细胞的内源性酮体生成比门静脉周围肝细胞高１．３倍。给予能明显刺激酮体生成的辛酸盐,肝静脉周围肝细胞的酮体生成仅略为增加。我们的结果证实,在基础和刺激的条件下,葡萄糖的异生在门静脉周围肝细胞中优先,而酮体生成仅在肝静脉周围肝细胞占微弱的优势。     

Zonation of fatty acid metabolism in rat liver.

Fatty acid metabolism was studied in periportal and perivenous hepatocytes isolated by the method of Chen & Katz [Biochem. J. (1988) 255, 99-104]. The rate of fatty acid synthesis and the activity of acetyl-CoA carboxylase were markedly enhanced in perivenous hepatocytes as compared with periportal cells. However, the response of these two parameters to short-term modulation by cellular effectors such as the hormones insulin and glucagon, the phorbol ester 4 beta-phorbol 12 beta-myristate 13 alpha-acetate and the xenobiotics ethanol and acetaldehyde was similar in the two zones of the liver. In addition, perivenous hepatocytes showed a higher capacity of esterification of exogenous fatty acids into both cellular and very-low-density-lipoprotein lipids. Nevertheless, no difference between the two cell sub-populations seemed to exist in relation to the secretion of very-low-density lipoproteins. On the other hand, the rate of fatty acid oxidation was increased in periportal cells. This could be accounted for by a higher activity of carnitine palmitoyltransferase I and a lower sensitivity of this enzyme to inhibition by malonyl-CoA in the periportal zone. No differences were observed between periportal and perivenous hepatocytes in relation to the short-term response of fatty acid oxidation and carnitine palmitoyltransferase I activity to the cellular modulators mentioned above. In conclusion, our results show that: (i) lipogenesis is achieved at higher rates in the perivenous zone of the liver, whereas the fatty-acid-oxidative process occurs with a certain preference in the periportal area of this organ; (ii) the short-term response of the different fatty-acid-metabolizing pathways to cellular effectors is quantitatively similar in the two zones of the liver.     

Distribution of pyruvate kinase type L and M2 in microdissected periportal and perivenous rat liver tissue with different dietary states

Pyruvate kinase type L and M2 activities were measured in microdissected periportal and perivenous liver tissue from rats in different dietary states. A specific antibody against pyruvate kinase type L was used to distinguish the two isoenzymes. Using separated cells it was found that the L-isoenzyme was essentially restricted to the parenchymal and the M2-isoenzyme to the non-parenchymal cells. Pyruvate kinase type L activity in the perivenous zone was about twice as high as in the periportal zone in both male and female fed rats. Starvation for 48 h led to a decrease of the overall activity and to a lower perivenous-periportal gradient. After refeeding for 48 h the overall activity and the gradient were increased to above the normal level. Pyruvate kinase type M2 was homogenously distributed within the liver acinus. After 48 h starvation no change in the overall activity nor in the zonal distribution was observed. Refed rats exhibited a slightly reduced overall activity. Since the hepatocytes contain the total regulatory L- but no M2-pyruvate kinase the heterogeneous distribution of the L-isoenzyme under different dietary states supports the model of metabolic zonation of liver parenchyma with glycolysis predominantly in the perivenous zone.     

Measurement of NADPH-ferrihemoprotein reductase content in sections of liver

We developed a method for measuring the content of NADPH-ferrihemoprotein reductase in sections of liver. First, reductase in sections of rat liver was detected with the indirect immunoperoxidase reaction. Subsequently, specific absorbances were measured in the stained sections by microphotometry. Then, the resulting specific absorbances were converted into the reductase content in the sections using an apparent extinction coefficient obtained from a nitrocellulose binding assay. The average of the reductase content in hepatocytes in periportal, intermediate, and perivenous zones thus measured was consistent with the value in liver homogenates estimated by enzyme-linked immunosorbent assay. Therefore, the present method gave accurate measurement of the reductase content in the sections. Perivenous hepatocytes contained 1.5 times as much reductase (1.15 nmol/g liver, mean for five animals) as that in periportal hepatocytes (0.74 nmol/g liver). The reductase content in hepatocytes in the intermediate zone (0.93 nmol/g liver) was intermediate between values of the periportal and perivenous hepatocytes.     

The compartmentation of glycolytic and gluconeogenic enzymes in rat kidney and liver and its significance to renal and hepatic metabolism

Summary An indirect immunoperoxidase procedure has been used to demonstrate sites of glycolysis and gluconeogenesis in normal rat kidney and liver. In kidney, the gluconeogenic enzyme fructose 1,6-biphosphatase was restricted to the proximal tubular epithelium, while the glycolytic enzyme hexokinase predominated in more distal segments. Intense staining for the biphosphatase in proximal convoluted tubular brush borders suggests that reabsorbed substrates may be used directly at this site in renal gluconeogenesis. In view of the high phosphofructokinase and pyruvate kinase activities present in collecting ducts, their relatively low hexokinase activities and their relatively pale immunostaining for hexokinase indicate that glycolytic substrates which feed into the pathway subsequent to the initial phosphorylation step, rather than glucose, may be the major energy source for the rat renal papilla.Immunostaining in the liver was consistent with the metabolic zonation of liver parenchyma, in that glucokinase occurred mainly in perivenous regions and fructose 1,6-bisphosphatase in periportal areas. The presence of such metabolic zonation is difficult to reconcile with the widely held view that the majority of hepatic glucogen is derived directly from glucose. A model for hepatic glycogen synthesis is proposed which links the concept of parenchymal zonal heterogeneity with recent biochemical evidence concerning the glucose paradox and with microscopical studies on the dynamics of glycogen deposition after refeeding.     

Clofibrate induces carnitine acyltransferases in periportal and perivenous zones of rat liver and does not disturb the acinar zonation of gluconeogenesis

Clofibrate induces hypertrophy and hyperplasia and marked changes in the activities of various enzymes in rat liver. We examined the effects of treatment of rats with clofibrate on enzyme induction and on rates of metabolic flux in hepatocytes isolated from the periportal and perivenous zones of the liver. Clofibrate induced the activities of carnitine acetyltransferase (90-fold), carnitine palmitoyltransferase (3-fold) and NADP-linked malic enzyme (3-fold) to the same level in periportal as in perivenous hepatocytes, suggesting that these enzymes were induced uniformly throughout the liver acinus. Increased rates of palmitate metabolism and ketogenesis after clofibrate treatment were associated with: a more oxidised mitochondrial redox state; diminished responsiveness to glucagon and loss of periportal/perivenous zonation. Despite the marked liver enlargement and hyperplasia caused by clofibrate, the normal periportal/perivenous zonation of alanine aminotransferase and gluconeogenesis was preserved in livers of clofibrate-treated rats, indicating that clofibrate-induced hyperplasia does not disrupt the normal acinar zonation of these metabolic functions.     

Methods for the study of liver cell heterogeneity

A large number of histological, histochemical and biochemical techniques are available for studying liver cell heterogeneity. Structural differences are recognized by morphometric analyses of electron micrographs. The zonal heterogeneity of enzyme activities can be demonstrated by histochemistry and more precisely by ultramicrobiochemical assays in microdissected periportal and perivenous tissue. Immunohistochemistry is useful for quantifying and localizing proteins, especially isoenzymes, without depending on their biological activity. The zonal quantification of specific mRNA can be achieved by in situ hybridization. The different structural and enzymic equipment of periportal and perivenous tissue found by these techniques has led to the concept of metabolic zonation. This hypothesis can be confirmed by determination of metabolic rates in perfused liver after selective zonal damage, in separated periportal and perivenous hepatocytes as well as in periportal and perivenous tissue of perfused liver by non-invasive techniques.     

Insulin resistance in the liver: Deficiency or excess of insulin?

In insulin-resistant states (obesity, pre-diabetes, and type 2 diabetes), hepatic production of glucose and lipid synthesis are heightened in concert, implying that insulin deficiency and insulin excess coexists in this setting. The fact that insulin may be inadequate or excessive at any one point in differing organs and tissues has many biologic ramifications. In this context the concept of metabolic compartmentalization in the liver is offered herein as one perspective of this paradox. In particular, we focus on the hypothesis that insulin resistance accentuates differences in periportal and perivenous hepatocytes, namely periportal glucose production and perivenous lipid synthesis. Subsequently, excessive production of glucose and accumulation of lipids could be expected in the livers of patients with obesity and insulin resistance. Overall, in this review, we provide our integrative perspective regarding how excessive production of glucose in periportal hepatocytes and accumulation of lipids in perivenous hepatocytes interact in insulin resistant states.     

Coexpression of periportal and perivenous enzymes in rat hepatocytes after experimental bile duct ligation: Comparison with intrasplenically transplanted hepatocytes

The coexpression of normally periportal and perivenous markers has been described in heterotopically transplanted hepatocytes. To determine whether such a coexpression might also occur in hepatocytes retaining their original intrahepatic location, we compared in bileduct-ligated livers and intrasplenically transplanted hepatocytes, the expression and distribution of the predominantly periportal glucose-6-phosphatase, succinate dehydrogenase, and lactate dehydrogenase, the predominantly perivenous glutamate dehydrogenase, NADPH-dehydrogenase, and -hydroxybutyrate dehydrogenase, and the strictly perivenous glutamine synthetase. The coexpression of high levels of the two periportal markers glucose-6-phosphatase and lactate dehydrogenase and of the perivenous marker NADPH dehydrogenase was observed in two situations: in clusters of hepatocytes isolated within the ductular proliferation in bile-duct-ligated livers and the majority of intrasplenically transplanted hepatocytes. The expression of glutamine synthetase was different according to the site. The protein was observed in certain intrasplenically transplanted hepatocytes bordering the splenic vessels but was never detected in hepatocyte clusters found in bile-duct-ligated livers. Our study therefore suggests that the coexpression of periportal and perivenous markers in the same hepatocytes is likely to be a non-specific consequence of the loss of the normal connections of hepatocytes with the normal liver microcirculation.     

Heterogeneous expression of glutamine synthetase mRNA in rat liver parenchyma revealed by in situ hybridization and Northern blot analysis of RNA from periportal and perivenous hepatocytes

Using radiolabeled specific cDNA glutamine synthetase mRNA could be detected by in situ hybridization exclusively within those few perivenous hepatocytes which stained immunocytochemically for glutamine synthetase. This localization of glutamine synthetase mRNA was recently reported by Moorman et al. [(1988) J. Histochem. Cytochem. 36, 751-755]. Biotinylated cDNA was not suitable for mRNA detection because of a very high background staining under the conditions of in situ hybridization. Dot blot and Northern blot analysis of RNA isolated from periportal and perivenous subfractions of hepatocytes also demonstrated the exclusive perivenous localization of two hybridizable glutamine synthetase mRNAs of length 2.8 and 1.6 kilobases. These results indicate that the unique heterogeneity of glutamine synthetase in rat liver parenchyma is controlled at the pretranslational level.     

Hypophysectomy does not alter the acinar zonation of gluconeogenesis or the mitochondrial redox state in rat liver.

The biochemical and functional heterogeneity of hepatocytes in different zones of the liver acinus may be related to the concentrations of hormones within the liver acinus. We examined the effects of hypophysectomy, which causes marked changes in plasma hormone levels and in activities of hepatic enzymes that are normally heterogeneously distributed, on the degree of metabolic zonation within the liver acinus. In hypophysectomized rats the activity of alanine aminotransferase was increased, but its normal zonation (predominance in the periportal zone) was preserved. The activity in cultured periportal and perivenous hepatocytes was increased by dexamethasone, but not by glucagon. Periportal hepatocytes from hypophysectomized rats expressed higher rates of gluconeogenesis in culture than did perivenous hepatocytes, irrespective of the absence or presence of dexamethasone, glucagon or insulin. Similar differences in rates of ketogenesis and in the mitochondrial redox state in response to glucagon were observed between periportal and perivenous hepatocytes from hypophysectomized rats as between cell populations from normal rats. Although hypophysectomy causes marked changes in hepatic enzyme activities, it does not alter the degree of zonation of alanine aminotransferase, gluconeogenesis or the mitochondrial redox state within the liver acinus.     

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.     

Zonation of cytochrome P450 isozyme expression and induction in rat liver.

The regional expression of six different cytochrome P450 (CYP) forms in rat liver under constitutive and induced conditions was compared using immunological techniques. Immunostaining of consecutive thin sections from control liver revealed that the same hepatocytes, forming a 6-8 cells thick layer surrounding the terminal hepatic venules, were stained for CYP2B1/2, CYP2E1 and CYP3A1. Staining of CYP2A1 extended further into the midzonal region, whereas all cells of the acinus stained for CYPEtOH2. These results were supported by Western blot analysis of cell lysates from the periportal or perivenous region obtained by zone-restricted digitonin treatment during in situ perfusion. The data suggest three distinct patterns of constitutive P450 expression: perivenous-restricted (CYP2B1/2, CYP2E1 and CYP3A1); perivenous-dominated (CYP2A1) and panacinar (CYPEtOH2). Chronic exposure to ethanol caused induction of CYP2E1 in the same cells already being constitutively expressed, whereas CYPEtOH2 was more induced in the periportal area. The relative induction of CYP2B1/2, CYP3A1 and CYPEtOH2 after treatment with phenobarbital was stronger in periportal hepatocytes, resulting in levelling out of the initial perivenous dominance of CYP2B1/2 and CYP3A1, whereas CYPEtOH2 became periportal-dominated. Acetone induced CYP2E1, CYP2C11 and CYP3A1 selectively in the perivenous area. These studies indicate that a particular P450 isozyme is generally induced in the same cells where it is constitutively expressed, and that this regional selectivity is independent of the kind of inducer. The data suggest that, during maturation, the hepatocytes acquire various phenotypes in the periportal and perivenous region, to respond differently to endogenous and exogenous signals in the control of P450 expression.     

Modulation by oxygen of zonal gene expression in liver studied in primary rat hepatocyte cultures

The different endowment with key enzymes and thus different metabolic capacities of periportal and perivenous cell types led to the model of "metabolic zonation." The periportal and perivenous hepatocytes receive different signals owing to the decrease of substrate concentrations including O2 and hormone levels during passage of blood through the liver sinusoids. These different signal patterns should be important for the short-term regulation of metabolism and also for the long-term induction and maintenance of the different enzyme pathways by control of gene expression. The periportal to perivenous drop in oxygen tension was considered to be a key regulator in the zonated expression of carbohydrate-metabolizing enzymes. In primary hepatocyte cultures, glucagon activated the phosphoenolpyruvate carboxykinase (PCK) gene to higher levels under arterial than under venous oxygen. The insulin-dependent activation of the glucokinase (GK) gene was reciprocally modulated by oxygen. Exogenously added hydrogen peroxide mimicked the effects of arterial oxygen on both the glucagon-dependent PCK gene and the insulin-dependent GK activation. Therefore, the oxygen sensor could be a hydrogen peroxide-producing oxidase which could contain a heme group for "measuring" the O2 tension. This notion was corroborated by the finding that CO mimicked the positive effect of O2 on PCK gene activation. Transfection of PCK promoter-CAT gene constructs into primary hepatocytes showed that the oxygen modulation of the PCK gene activation occurred in the region -281/+69. The modulation by O2 was not mediated by isolated cAMP-responsive elements. Nuclear protein extracts prepared from hepatocytes cultured under venous Po2 as compared to arterial Po2 showed an enhanced binding activity to the promoter fragment -149/-43. Oxidative conditions such as H2O2 reduced the DNA-binding activity, thus supporting the role of H2O2 as a mediator in the O2 response of the PCK and GK genes.     

Gluconeogenesis in periportal and perivenous hepatocytes of rat liver, isolated by a new high-yield digitonin/collagenase perfusion technique.

A technique is described which allows preparations of hepatocytes, enriched in either periportal or perivenous hepatocytes ('PP-cells' and 'PV-cells' respectively), in a yield of about 30-50% compared with control cell preparations. The liver is first perfused for 40-60s with digitonin (4 mg/ml) to destroy selectively either the periportal or the perivenous part of the microcirculatory unit, and then the remaining hepatocytes are isolated by the ordinary collagenase perfusion technique. In periportal cells the activities of alanine aminotransferase and pyruvate kinase were 29.4 and 18.7 mumol/min per mg of DNA respectively. The rate of gluconeogenesis was 0.402 mumol/min per mg of DNA. In perivenous cells the corresponding values were 9.55, 22.1 and 0.244 mumol/min per mg of DNA respectively. These data support the concept of a zonation of glucose metabolism within the microcirculatory unit of the liver, with the afferent part (periportal zone) having a 2-fold, more active gluconeogenesis than the efferent part (perivenous zone).     

Expression of hepatic mitochondrial carbonic anhydrase V

We have raised specific (rabbit anti-rat) polyclonal antibodies to hepatic mitochondrial carbonic anhydrase V (CA V) and used them to assay the amounts of protein expressed in liver mitochondria isolated from term-foetal, control or diabetic adult rats and in perivenous and periportal rat hepatocytes. The levels of CA V expressed in mitochondria isolated from the livers of adult male and female rats are similar and increase (about 2-fold) in mitochondria from adult diabetic rats when compared to those isolated from the livers of control rats. The level of enzyme in adult liver was higher than in the livers of term-foetal rats. CA V is expressed in both perivenous and periportal hepatocytes, but the level of expression is greater (approx. 40%) in perivenous cells. The implications and significance of these findings are discussed with reference to the roles and properties of the other carbonic anhydrase isoenzymes and the metabolic function of the mitochondrial isoenzyme.     

Distribution of hepatic glutaminase activity and mRNA in perivenous and periportal rat hepatocytes.

Perivenous and periportal hepatocytes were isolated by the digitonin/collagenase perfusion technique. The specific activity of phosphate-activated glutaminase was 2.33-fold higher in periportal cells than in perivenous cells. Similarly, the relative abundance of glutaminase mRNA was 2.6-fold higher in samples from periportal cells. The distribution of glutaminase activity and mRNA was compared with those for glutamine synthetase (predominantly perivenous) and phosphoenolpyruvate carboxykinase (predominantly periportal). The results suggest that phosphate-activated glutaminase is predominantly expressed in the periportal zone of the liver acinus.     

Induction in primary culture of 'gluconeogenic' and 'glycolytic' hepatocytes resembling periportal and perivenous cells

Adult rat hepatocytes were kept in primary culture for 48 h under different hormonal conditions to induce an enzyme pattern which with respect to carbohydrate metabolism approximated that of periportal and perivenous hepatocytes in vivo. 1. Glucagon-treated cells compared with control cells possessed a lower activity of glucokinase, a 4.5-fold higher activity of phosphoenolpyruvate carboxykinase and unchanged levels of glucose-6-phosphatase, phosphofructokinase, fructose-bisphosphatase and pyruvate kinase; they resembled in a first approximation the periportal cell type and are called for simplicity 'periportal'. Inversely, insulin-treated cells compared with control cells contained a 2.2-fold higher activity of glucokinase, a slightly decreased activity of phosphoenolpyruvate carboxykinase, increased activities of phosphofructokinase and pyruvate kinase and unaltered levels of glucose-6-phosphatase and fructose-bisphosphatase; they resembled perivenous cells and are called simply 'perivenous'. Gluconeogenesis and glycolysis were studied under various substrate and hormone concentrations. 2. Physiological concentrations of glucose (5 mM) and lactate (2 mM) gave about 80% saturation of gluconeogenesis from lactate and less than 15% saturation of glycolysis at a simultaneous 40% inhibition of the glycolytic rate by lactate. 3. Comparison of the two cell types showed that under identical assay conditions (5 mM glucose, 2 mM lactate, 0.5 nM insulin, 0.1 muM dexamethasone) gluconeogenesis was 1.5-fold faster in the 'periportal' cells and glycolysis was 2.4-fold faster in the 'perivenous' cells. 4. Metabolic rates were under short-term hormonal control. Insulin increased glycolysis three fold in both cell types with a half-maximal effect at about 0.4 nM, but did not influence the gluconeogenic rate. Glucagon inhibited glycolysis by 70% with a half-maximal effect at about 0.1 nM. Gluconeogenesis was stimulated by glucagon (half-maximal dose: 0.5 nM) 1.8-fold only in 'periportal' cells containing high phosphoenolpyruvate carboxykinase activity, not in the 'perivenous' cells with a low level of this enzyme. 5. A comparison of the two cell types showed that with maximally stimulating hormone concentrations gluconeogenesis was threefold faster in 'periportal' cells and glycolysis was eightfold faster in 'perivenous' cells. The results support the view that periportal and perivenous hepatocytes in vivo catalyse gluconeogenesis and glycolysis at inverse rates.