Periportal expression of the serine dehydratase gene in rat liver

Summary The mRNA for rat liver serine dehydratase, a gluconeogenic enzyme, exhibits a circadian rhythm with a maximum at the onset of darkness marking the end of the fasting period and a minimum at the onset of light that marks the end of the feeding period, when rats have free access to food and water.In situ hybridization with an antisense cRNA probe revealed that serine dehydratase mRNA was localized in the periportal area of rat liver parenchyma in the evening, whereas it was scarce in the liver in the morning. The predominant localization of serine dehydratase mRNA in the periportal area also occurred in livers of rats that underwent laparotomy, glucagon and dexamethasone administration, and streptozotocin-induced diabetes mellitus, all of which are known to induce serine dehydratase mRNA levels remarkably. Immunostaining revealed that the localization of serine dehydratase protein agreed with that of succinate dehydrogenase, another enzyme known to be predominant in the periportal zone. Thus, the periportal serine dehydratase gene expression strongly supports the idea of metabolic zonation that gluconeogenesis from amino acids occurs preferentially in the periportal parenchyma of rat liver.     

Predominant periportal expression of the phosphoenolpyruvate carboxykinase and tyrosine aminotransferase genes in rat liver

Summary The zonal distribution of phosphoenolpyruvate carboxykinase (PCK) and tyrosine aminotransferase (TAT) mRNA in liver was studied by in situ hybridization with radiolabelled cRNA probes and the abundance of PCK and TAT mRNA was quantified by Northern blot analysis of total RNA with biotinylated cRNA probes. Livers were taken from rats during a normal 12 h day/night rhythm, when they had access to food only during the dark period from 7 pm to 7 am, or during refeeding, when they had access to food after having been starved for 60 h. 1. Daily feeding rhythm: High levels of PCK mRNA were distributed mainly in the periportal and intermediate zone during the fasting period at noon and 6 pm. Feeding caused a rapid decrease in PCK mRNA level and a restriction of PCK mRNA localization to the periportal area within the first 2 h. No further alterations were observed during the following hours of the feeding period. TAT mRNA was distributed also in the periportal and intermediate zone during the fasting period. Feeding first reduced the mRNA level without changing the distribution pattern. Then towards the end of the feeding period TAt mRNA increased again to half-maximal levels and became restricted mainly to the periportal area. 2. Starvation-refeeding cycle: High amounts of PCK mRNA as well as of TAT mRNA were localized predominantly in the periportal and intermediate zone after 60 h of starvation. PCK and TAT mRNA both decreased markedly during the first 2 h of refeeding and then remained almost constant. Whereas the alterations in the overall abundance of the two mRNAs were similar, the distribution patterns of both mRNAs differed. While PCK mRNA became more and more restricted to a small area of periportal cells towards the end of refeeding, TAT mRNA was first evenly distributed in the periportal and perivenous area with higher amounts in the intermediate zone and then again was predominantly located in the periportal area. The present data indicate that the predominant periportal localization of PCK and TAT activity and enzyme protein is regulated mainly at the pretranslational level.     

Predominant periportal expression of the phosphoenolpyruvate carboxykinase and tyrosine aminotransferase genes in rat liver. Dynamics during the daily feeding rhythm and starvation-refeeding cycle demonstrated by in situ hybridization

The zonal distribution of phosphoenolpyruvate carboxykinase (PCK) and tyrosine aminotransferase (TAT) mRNA in liver was studied by in situ hybridization with radiolabelled cRNA probes and the abundance of PCK and TAT mRNA was quantified by Northern blot analysis of total RNA with biotinylated cRNA probes. Livers were taken from rats during a normal 12 h day/night rhythm, when they had access to food only during the dark period from 7 pm to 7 am, or during refeeding, when they had access to food after having been starved for 60 h. 1. Daily feeding rhythm: High levels of PCK mRNA were distributed mainly in the periportal and intermediate zone during the fasting period at noon and 6 pm. Feeding caused a rapid decrease in PCK mRNA level and a restriction of PCK mRNA localization to the periportal area within the first 2 h. No further alterations were observed during the following hours of the feeding period. TAT mRNA was distributed also in the periportal and intermediate zone during the fasting period. Feeding first reduced the mRNA level without changing the distribution pattern. Then towards the end of the feeding period TAT mRNA increased again to half-maximal levels and became restricted mainly to the periportal area. 2. Starvation-refeeding cycle: High amounts of PCK mRNA as well as of TAT mRNA were localized predominantly in the periportal and intermediate zone after 60 h of starvation. PCK and TAT mRNA both decreased markedly during the first 2 h of refeeding and then remained almost constant.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of the ontogeny of rat liver metallothionein mRNA by zinc

To investigate the role of metals in the regulation of the ontogenic expression of rat liver metallothionein (MT) mRNA, the concentrations of zinc, MT and MT mRNA were determined in livers of fetal and newborn rats from dams which were fed with a control or zinc-deficient or copper-deficient or iron-deficient diet from day 12 of gestation. The liver samples were analyzed for MT-mRNA levels using a mouse MT-I cRNA probe. Although the newborn hepatic levels of each metal (zinc or copper or iron) was specifically reduced corresponding to the respective mineral deficiencies, the hepatic concentrations of total MT and MT-I mRNA were significantly decreased only in pups born from zinc-deficient dams. Injection of the zinc-deficient newborn pups with 20 mg Zn as ZnSO4/kg restored with MT-I mRNA levels to slightly above control values within 5 h of injection. The hepatic zinc, MT and MT-I mRNA levels were observed to increase significantly in control fetal rat liver on days 17-21 of gestation but there were little changes in either zinc or MT in fetal livers from zinc-deficient dams during the late gestational period. The MT-I mRNA level also did not show an increase on days 18 and 20 of gestation in zinc-deficient fetal liver as compared to controls. These results demonstrate a direct role of zinc in hepatic MT gene expression in rat liver during late gestation. Immunohistochemical localization of MT using a specific antibody to rat liver MT showed that the staining for MT in zinc-deficient pup liver was mainly in the cytosol in contrast to the significant nuclear MT staining observed in control newborn rat liver. The results suggest that maternal zinc deficiency has a marked effect not only in decreasing the levels of hepatic MT and MT-I mRNA but also in the localization of MT in newborn rat liver.     

Metabolic effects of developmental, tissue-, and cell-specific expression of a chimeric phosphoenolpyruvate carboxykinase (GTP)/bovine growth hormone gene in transgenic mice.

Transgenic mice were used to investigate sequences within the promoter of the gene for the cytosolic form of phosphoenolpyruvate carboxykinase (GTP) from the rat (EC 4.1.1.32) (PEPCK) which are involved in tissue-specific and developmental regulation of gene expression. Segments of the PEPCK promoter between -2000 and -109 were linked to the structural gene for bovine growth hormone (bGH) and introduced into the germ line of mice by microinjection. Bovine growth hormone mRNA was found in tissues that express the endogenous PEPCK gene, mainly in the liver but to a lesser extent in the kidney, adipose tissue, small intestine, and mammary gland. In the liver the chimeric PEPCK/bGH(460) gene was expressed in periportal cells, which is consistent with the zonation of endogenous PEPCK. The PEPCK/bGH gene was not transcribed in the livers of fetal mice until immediately before birth; at birth the concentration of bGH mRNA increased 200-fold. Our results indicate that the region of the PEPCK promoter from -460 to +73 base pairs contains regulatory sequences required for tissue-specific and developmental regulation of PEPCK gene expression. Mice transgenic for PEPCK/bGH(460) were not hyperglycemic or hyperinsulinemic in response to elevated bGH, as were transgenic mice with the MT/bGH gene. The number of insulin receptors in skeletal muscle was no different in mice transgenic for MT/bGH when compared with mice transgenic for PEPCK/bGH(460) and control animals. However, mRNA abundance for the insulin-sensitive glucose transporter in skeletal muscle was decreased in mice transgenic for the MT/bGH gene. The differences in glucose homeostasis noted with the two types of transgenic mice may be the result of the relative site of expression, the different developmental pattern, or hormonal regulation of expression of the bGH gene.     

Zonal expression of the glucokinase gene in rat liver. Dynamics during the daily feeding rhythm and starvation-refeeding cycle demonstrated by in situ hybridization

The abundance and zonal distribution of glucokinase (GK) mRNA were studied in rat liver during a normal 12 h day/12 h night rhythm (dark from 1900 to 0700 hours) and during refeeding after 60 h of starvation. Zonation of GK gene expression was examined by in situ hybridization with a radiolabelled cRNA probe and GK mRNA abundance was determined by Northern blot analysis with a digoxigenin-labelled cRNA probe. GK mRNA appeared to be almost homogeneously distributed throughout the whole daily feeding cycle; yet it was predominantly localized in the perivenous and intermediate zone during refeeding after 60 h of starvation. During the daily feeding rhythm, the total amount of GK mRNA increased quickly with the beginning of the feeding period at 1900 hours reaching a maximum at midnight and then decreased continuously to a basal level at noon. Virtually no GK mRNA was detected after 60 h of starvation. Refeeding caused a rapid increase in GK mRNA to a maximum at 2400 hours followed by a decrease to approximately two-thirds of the maximum value at 0700 hours. If the homogeneous distribution of GK mRNA during the daily feeding rhythm was real rather than apparent because of too low a sensitivity of the cRNA probe, the present results suggest that during the normal circadian cycle the mainly perivenous distribution of GK enzyme activity and protein is regulated preferentially at a translational level. The findings clearly show that during refeeding after 60 h of starvation the GK distribution is controlled predominantly at a pretranslational level.     

Diet- and hormone-induced reversal of the carbamoylphosphate synthetase mRNA gradient in the rat liver lobulus

A hybridocytochemical analysis of adult liver from normal control and from hormonally and dietary-treated rats was carried out, using radioactively-labelled probes for the mRNAs of glutamine synthetase (GS), carbamoylphosphate synthetase (CPS) and phosphoenolpyruvate carboxykinase (PEPCK). In line with previous findings, GS mRNA is exclusively expressed in a small pericentral compartment, CPS mRNA exclusively in a contiguous large periportal compartment and PEPCK mRNA across the entire porto-central distance. The density of labelling in CPS and PEPCK mRNA-positive hepatocytes decreases in a porto-central direction. Starvation resulted in a reversal of the gradient of CPS mRNA within its periportal compartment; glucose refeeding counteracted this effect. Livers of glucocorticosteroid-treated, starved or diabetic rats also revealed a reversal of the normal gradient of CPS mRNA, but now across the entire porto-central distance. The patterns of expression of GS and PEPCK mRNA remained essentially unchanged, notwithstanding substantial changes in the levels of expression. It is concluded that blood-borne factors constitute the major determinants for the expression patterns of CPS mRNA within the context of the architecture of the liver lobulus.     

Lithium inhibits hepatic gluconeogenesis and phosphoenolpyruvate carboxykinase gene expression.

Incubation of isolated hepatocytes from fasted rats with 20 mM LiCl for 1 h decreased glucose production from lactate, pyruvate, and alanine. In addition, phosphoenolpyruvate carboxykinase (PEPCK) gene expression in FTO-2B rat hepatoma cells was inhibited by treatment with LiCl. Lithium was also able to counteract the increased PEPCK mRNA levels caused by both Bt2cAMP and dexamethasone, in a concentration-dependent manner. A chimeric gene containing the PEPCK promoter (-550 to +73) linked to the amino-3-glycosyl phosphotransferase (neo) structural gene was transduced into FTO-2B cells using a Moloney murine leukemia virus-based retrovirus. In these infected cells, 20 mM LiCl decreased both the concentration of neo mRNA transcribed from the PEPCK-neo chimeric gene and mRNA from the endogenous PEPCK gene. Lithium also inhibited the stimulatory effect of Bt2cAMP and dexamethasone on both genes. The stability of neo mRNA was not altered by lithium, since in cells infected with retrovirus containing only the neo gene transcribed via the retroviral 5'-LTR and treated with 20 mM LiCl, no change in neo mRNA levels was observed. The intraperitoneal administration of LiCl to rats caused a decrease in hepatic PEPCK mRNA, indicating that lithium could also modify gene expression in vivo. The effects of lithium were not due to an increase in the concentration of insulin in the blood but were correlated with an increase in hepatic glycogen and fructose 2,6-bisphosphate levels. These results indicate that lithium ions, at concentrations normally used therapeutically for depression in humans, can inhibit glucose synthesis in the liver by a mechanism which can selectively modify the expression of hepatic phosphoenolpyruvate carboxykinase.     

Transforming growth factor β1 increases the phosphoenolpyruvate carboxykinase mRNA level in cultured rat hepatocytes

Transforming growth factor β1 (TGFβ1) elevated the phosphoenolpyruvate carboxykinase (PEPCK) mRNA abundance in primary cultures of rat hepatocytes. Although this increase was not as large as the rise in PEPCK gene expression induced by the cAMP-elevating agents glucagon or isoproterenol, the effect of TGFβ1 was several-fold and concentration-dependent, with ED₅₀ at about 2.5 pM, which is in the same concentration range as the previously found growth-inhibitory effect of TGFβ. The data show that the level of mRNA for PEPCK, an enzyme typically expressed in the liver, can be regulated in the same direction by TGFβ1 and cAMP.     

trans activation of rat phosphoenolpyruvate carboxykinase (GTP) gene expression by micro-coinjection of rat liver mRNA in Xenopus laevis oocytes.

To study the liver-specific trans activation of the rat phosphoenolpyruvate carboxykinase (PEPCK) gene, the PEPCK promoter was linked to a reporter gene and was microinjected into Xenopus laevis oocytes alone or in conjunction with rat liver poly(A)+ RNA. The rat liver mRNA markedly enhanced the expression of the PEPCK-chimeric construct. This effect appeared to be sequence specific, as it was dependent on the presence of the intact promoter. Moreover, the RNA effect was limited to mRNA preparations from PEPCK-expressing tissues only. Finally, microinjection of size-fractionated liver mRNA revealed that the trans-acting factor(s) is encoded by RNA of 1,600 to 2,000 nucleotides, providing a direct bioassay for the gene(s) involved in this tissue-specific trans-activation process.     

The interplay of ubiquitous DNA-binding factors, availability of binding sites in the chromatin, and DNA methylation in the differential regulation of phosphoenolpyruvate carboxykinase gene expression.

We have identified DNA elements in the phosphoenolpyruvate carboxykinase (PEPCK) gene promoter which are bound 'in vivo' by proteins under conditions of basal level gene expression and have evaluated several hypothesis to account for the tissue specific expression of the gene. In vitro DNase I footprinting demonstrated that factors which bind to basal expression elements of the PEPCK promoter, the BSE/CRE and NFI/CCAAT sites, are also present in HTC and XC cells which do not express the PEPCK gene. 'In vivo' DNase I footprinting demonstrated that the BSE/CRE, NFI/CCAAT, and three additional sites are bound by protein in H4IIE cells which express the PEPCK gene but not in the HTC or XC cells. No evidence for a repressor protein or for phased nucleosome binding to the PEPCK promoter in HTC or XC cells could be detected. Genomic sequencing was used to determine if differential methylation of the PEPCK promoter could account for the lack of factor binding in HTC and XC nuclei. None of the 14 cytosine residues in CpG dinucleotides was methylated in H4IIE or rat liver DNA, all were methylated in rat sperm DNA, and 6 were methylated in HTC DNA; including the cytosine at position--90 within the BSE/CRE. Only one cytosine residue, at position--90, was methylated in XC DNA. Treatment of XC cells with 5-azacytidine resulted in loss of methylation at the--90 position yet this was insufficient to allow synthesis of a detectable amount of PEPCK mRNA.