Thrombin activates the hypoxia-inducible factor-1 signaling pathway in vascular smooth muscle cells: Role of the p22(phox)-containing NADPH oxidase.

The heterodimeric transcription factor hypoxia-inducible factor-1 (HIF-1) is activated under hypoxic conditions, resulting in the upregulation of its target genes plasminogen activator inhibitor-1 (PAI-1) and vascular endothelial growth factor (VEGF). PAI-1 and VEGF are also induced in response to vascular injury, which is characterized by the activation of platelets and the coagulation cascade as well as the generation of reactive oxygen species (ROS). However, it is not known whether HIF-1 is also stimulated by thrombotic factors. We investigated the role of thrombin, platelet-associated growth factors, and ROS derived from the p22(phox)-containing NADPH oxidase in the activation of HIF-1 and the induction of its target genes PAI-1 and VEGF in human vascular smooth muscle cells (VSMCs). Thrombin, platelet-derived growth factor-AB (PDGF-AB), and transforming growth factor-beta(1) (TGF-beta(1)) upregulated HIF-1alpha protein in cultured and native VSMCs. This response was accompanied by nuclear accumulation of HIF-1alpha as well as by increased HIF-1 DNA-binding and reporter gene activity. The thrombin-induced expression of HIF-1alpha, PAI-1, and VEGF was attenuated by antioxidant treatment as well as by transfection of p22(phox) antisense oligonucleotides. Inhibition of p38 mitogen-activated protein kinase and phosphatidylinositol-3-kinase significantly decreased thrombin-induced HIF-1alpha, PAI-1, and VEGF expression. These findings demonstrate that the HIF-1 signaling pathway can be stimulated by thrombin and platelet-associated growth factors and that a redox-sensitive cascade activated by ROS derived from the p22(phox)-containing NADPH oxidase is crucially involved in this response.

Effects of contextual information and stimulus ambiguity on overt visual sampling behavior.

The sampling of our visual environment through saccadic eye movements is an essential function of the brain, allowing us to overcome the limits of peripheral vision. Understanding which parts of a scene attract overt visual attention is subject to intense research, and considerable progress has been made in unraveling the underlying cortical mechanisms. In contrast to spatial aspects, however, relatively little is understood about temporal aspects of overt visual sampling. At every fixation, the oculomotor system faces the decision whether to keep exploring different aspects of an object or scene or whether to remain fixated to allow for in-depth cortical processing - a situation that can be understood in terms of an exploration-exploitation dilemma. To improve our understanding of the factors involved in these decisions, we here investigate how the level of visual information, experimentally manipulated by scene context and stimulus ambiguity, changes the sampling behavior preceding the recognition of centrally presented ambiguous and disambiguated objects. Behaviorally, we find that context, although only presented until the first voluntary saccade, biases the perceptual outcome and significantly reduces reaction times. Importantly, we find that increased information about an object significantly alters its visual exploration, as evident through increased fixation durations and reduced saccade amplitudes. These results demonstrate that the initial sampling of an object, preceding its recognition, is subject to change based on the amount of information available in the system: increased evidence for its identity biases the exploration-exploitation strategy towards in-depth analyses.

Cross-talk between the signals hypoxia and glucose at the glucose response element of the L-type pyruvate kinase gene.

The signals oxygen and glucose play an important role in metabolism, angiogenesis, tumorigenesis, and embryonic development. Little is known about an interaction of these two signals. We demonstrate here the cross-talk between oxygen and glucose in the regulation of L-type pyruvate kinase (L-PK) gene expression in the liver. In the liver the periportal to perivenous drop in O(2) tension was proposed to be an endocrine key regulator for the zonated gene expression. In primary rat hepatocyte cultures the expression of the L-PK gene on mRNA and on protein level was induced by venous pO(2), whereas its glucose-dependent induction occurred predominantly under arterial pO(2). It was shown by transient transfection of L-PK promoter luciferase and glucose response element (Glc(PK)RE) SV40 promoter luciferase gene constructs that the modulation by O(2) of the glucose-dependent induction occurred at the Glc(PK)RE in the L-PK gene promoter. The reduction of the glucose-dependent induction of the L-PK gene expression under venous pO(2) appeared to be mediated via an interference between hypoxia inducible factor-1 (HIF-1) and upstream stimulating factor at the Glc(PK)RE. The glucose response element also functioned as an hypoxia response element which was confirmed in cotransfection assays with Glc(PK)RE luciferase gene constructs and HIF-1alpha expression vectors. Furthermore, it was found by gel shift and supershift assay that HIF-1alpha and USF-1 or USF-2 could bind to the Glc(PK)RE. Our findings implicate that the cross-talk between oxygen and glucose might have a fundamental role in the regulation of several physiological and pathophysiological processes.

Periportal localization of glucagon receptor mRNA in rat liver and regulation of its expression by glucose and oxygen in hepatocyte cultures.

Glucagon is the major hormone activating glycogenolysis and gluconeogenesis both localized in the periportal, more aerobic zone of the liver. Accordingly, the glucagon receptor (GcgR) mRNA was found to be predominantly expressed in this area. In hepatocyte cultures high glucose concentrations as reached after a meal induced GcgR mRNA under arterial but not venous pO2. The induction by glucose was partially antagonized by insulin and unaffected by glucagon. The modulation by 02 of the glucose-dependent induction would contribute to the zonated expression of GcgR mRNA.

Modulation of the glucagon-dependent activation of the phosphoenolpyruvate carboxykinase gene by oxygen in rat hepatocyte cultures. Evidence for a heme protein as oxygen sensor.

The glucagon-dependent activation of the phosphoenolpyruvate carboxykinase (PCK) gene is modulated by oxygen. It was proposed that heme proteins might function as O2 sensors; their actions are impaired after replacement of the central Fe2+ ion by Co2+ and inhibition of heme synthesis by succinylacetone (SA). Therefore, the effects of CoCl2 and SA, alone and in combination, on the glucagon-dependent induction of PCK activity and PCK mRNA were investigated at different physiological oxygen tensions in primary rat hepatocyte cultures. The cells were exposed to 50 microM CoCl2 and/or 2 mM SA from 4-24 h. After addition of fresh media without CoCl2 or SA, PCK was induced with 1 nM glucagon. PCK activity and PCK mRNA were elevated to 100% at 16% O2 and to about 65% at 8% O2. CoCl2 reduced these increases to about 45% at 16% O2 and to about 35% at 8% O2. SA lowered the inductions to about 50% and 40% each at 16% and 8% O2. CoCl2 plus SA diminished the elevations to about 5% at both oxygen tensions. In the presence of CoCl2 and/or SA, ornithine decarboxylase induction by insulin was not impaired; lactate dehydrogenase did not leak from the cells, which in electron microscopical inspections had normal cell structures. These findings support the hypothesis that a heme protein is involved in the activation of the PCK gene and that it acts as an O2 sensor.

Regulation of the gluconeogenic phosphoenolpyruvate carboxykinase and glycolytic aldolase A gene expression by O2 in rat hepatocyte cultures. Involvement of hydrogen peroxide as mediator in the response to O2.

Heme proteins acting as oxidases which produce H2O2 have been proposed to function as O2 sensors. In order to find out whether the modulation by O2 of PCK gene activation and the stimulation of the ALD A gene by venous O2 operate via H2O2, the effects of different concentrations of H2O2 and catalase as H2O2 scavenger were studied in rat hepatocyte cultures under different O2 tensions. Primary hepatocytes were treated with 0.1 nM glucagon, 50 microM H2O2 and/or 100 micrograms/ml catalase each at arterial O2 or venous pO2. PCK mRNA was induced by glucagon maximally under arterial O2 and only half maximally under venous O2. ALD A mRNA was induced only by venous O2. H2O2 enhanced the induction of PCK mRNA to similar levels under venous O2 tensions and the induction of ALD A mRNA under both O2 was completely inhibited. Addition of catalase antagonized the actions of H2O2 completely. These findings support the hypothesis that an H2O2-generating heme protein is involved in the O2 sensing system regulating gluconeogenic and glycolytic gene expression in response to O2.

Differential effects of hypoxia on untreated and NGF treated PC12 cells.

Perinatal hypoxia is known to induce long-lasting changes in the central dopaminergic system. In order to understand the cellular mechanism of these changes, we studied the effects of hypoxia on the levels of dopamine (DA) and tyrosine hydroxylase (TH) mRNA in untreated and NGF treated PC12 cells. On the second day after plating (DAP), cells were exposed to a hypoxic episode (pO2 = 10-20 mm Hg, 24 h), and the levels of DA and TH mRNA were examined on DAP 4 and DAP 8. In untreated cells, hypoxia induced a two fold increase both in DA and TH mRNA levels on DAP 4 which normalized up to DAP 8. This increase correlated with an activation of the hypoxia inducible factor (HIF-1alpha), measured with a reporter gene. In contrast, NGF treated cells responded to hypoxia with an increase of DA level on DAP 8. In these cells neither an increase of the HIF-1alpha activity measured immediately after hypoxia nor a significant increase of the TH mRNA level on DAP 8 were found. The findings indicate that NGF shifts the hypoxia induced changes of DA levels from a short-term to a long-term mode. The long-term increase of dopamine levels is the most likely result of changes connected with cell growth and differentiation and not the result of a long-term TH mRNA level increase.

Expression of hypoxia-inducible factor-1 in the cochlea of newborn rats.

Hypoxia/ischemia is a major pathogenetic factor in the development of hearing loss. An important transcription factor involved in the signaling and adaptation to hypoxia/ischemia is the hypoxia-inducible factor-1 (HIF-1). To study HIF-1 expression we used an in vitro hypoxia model of explant and dissociated cultures of the stria vascularis, the organ of Corti with limbus and the modiolus from the cochlea of 3-5-day-old Wistar rats. Hypoxia differentially increased HIF-1 activity as measured by a reporter gene. Twenty-four hour hypoxia increased HIF-1 activity 14.1+/-3.5-fold in the modiolus, 9.4+/-3.0-fold in the organ of Corti with limbus, and 6.4+/-1.5-fold in the stria vascularis. The HIF-1alpha mRNA level was measured by quantitative reverse transcription polymerase chain reaction and showed a lower expression in the modiolus (1.3+/-0.2 pg/microg RNA) than in both the organ of Corti with limbus and the stria vascularis (2.7-3.2+/-1.3, P<0.01). Hypoxia had no effect on the HIF-1alpha mRNA levels. The region-specific regulation of HIF-1 expression on the transcriptional and posttranslational levels may expand the possibilities for adaptation of the cochlea to hypoxia.

Expression patterns of erythropoietin and its receptor in the developing midbrain.

The expression patterns of erythropoietin (EPO) and its receptor (EPOR) were investigated in the midbrain and in adjacent parts of the synencephalon and hindbrain of embryonic C57Bl mice. On embryonic (E) day 8 (E8), virtually all neuroepithelial cells expressed EPOR. After neural tube closure, subsets of these cells downregulated EPOR. In contrast, radial glial cells were EPOR-immunolabeled from E11 onwards. Simultaneously, subpopulations of early developing neurons upregulated EPO and expressed HIF-1, known to transcriptionally activate EPO. Three-dimensional reconstructions revealed subpopulations of EPO-expressing neurons: (1) in the trigeminal mesencephalic nucleus (TMN), (2) at the rostral transition of the midbrain and synencephalon, (3) in the basal plate of the midbrain, (4) in the trigeminal motor nucleus, and (5) in the trigeminal principal sensory nucleus. In the rostral midbrain and synencephalon, EPO-immunoreactive neurons were attached to EPOR-expressing radial glial cells. The identity of radial glial cells was proven by their immunoreactivity for antibodies against astrocyte-specific glutamate transporter, brain lipid-binding protein, and nestin. From E12.5 onwards EPOR was downregulated in radial glial cells. Viable neurons of the TMN continued to express EPO and upregulated EPOR. Our findings provide new evidence that components of the EPO system are present in distinct locations of the embryonic brain and, by interactions between neurons and radial glial cells as well as among clustered TMN neurons, may contribute to its morphogenesis. Whether the observed expression patterns of EPO and EPOR may reflect EPO-mediated trophic and/or antiapoptotic effects on neurons is discussed.

Hypoxia-induced long-term increase of dopamine and tyrosine hydroxylase mRNA levels.

The aim of the present study was to determine hypoxia-induced changes in the long-term expression of tyrosine hydroxylase (TH) mRNA and the steady-state dopamine (DA) levels in rat mesencephalic cell cultures. The cultures were exposed to hypoxia during the early developmental period, and DA content and TH mRNA expression were determined on day in vitro (DIV) 14. Hypoxic exposure of 5-day-old cultures resulted in increased DA (control 89.9+/-8.9, hypoxia 135.8+/-23.7 pg/microg protein) and TH mRNA (control 37.3+/-4.7, hypoxia 143.1+/-49.4 pg/microg RNA) levels. To analyze the involvement of hypoxia-inducible factor-1 (HIF-1) in these changes, we studied its activation using reporter gene. Hypoxia caused a 3-fold increase in HIF-1 activity. Our data suggest that hypoxia/ischemia during the putative critical developmental period of neurons may determine the tyrosine hydroxylase gene expression and, consequently, the development of the dopaminergic system.

Oxygen: modulator of physiological and pathophysiological processes in the liver.

Oxygen has important functions as substrate for biochemical reactions and as modulator of gene expression. In the liver, the physiologically occurring oxygen gradient is a major effector of metabolic zonation. In addition, cross-talks between the O2 signaling and nutrient signaling chains initiate a dynamic zonation pattern. Under pathological situations, hypoxia appears to be a major determinant for liver diseases and cancer. Thereby transcription factors of the HIF family are activated whereas USF proteins have the potential to counteract HIFs. In addition, feedback mechanisms between hypoxia, HIF and the IGF axes appear to exist. Thus, the knowledge of these mechanisms may help to initiate new therapies in diseases with disturbed O2 availability.

[Influence of ischemia/hypoxia on the HIF-1 activity and expression of hypoxia-dependent genes in the cochlea of the newborn rat]. / Einfluss von Ischämie/Hypoxie auf die HIF-1-Aktivität und Expression von hypoxieabhängigen Genen in der Kochlea der neugeborenen Ratte.

BACKGROUND: Transcription factor HIF-1 (hypoxia-inducible factor-1) regulates the expression of genes which are involved in glucose supply, growth, metabolism, redox reactions and blood supply. Hypoxia and ischemia play an important role in the pathogenesis of tinnitus and hearing loss. Therefore, HIF-1 activity and the expression of HIF-1 dependent genes in the cochlea were examined under ischemic and hypoxic conditions. MATERIAL AND METHODS: For the HIF-1 analysis, single-cell cultures of the organ of Corti (OC), stria vascularis (SV) and modiolus (MOD) were used. mRNA expression was analyzed in the organotypic culture using a microarray technique (RN U34-chip, Affymetrix). RESULTS: Ischemia (hypoxia without glucose) and pure hypoxia increase the HIF-1 activity identically, with the highest increase found in MOD and OC. The HIF-1 alpha mRNA levels were found to be higher in SV than in the OC and MOD. During culturing, there is a clear increase in HIF-1 alpha mRNA and the expression of a number of HIF-1 dependent genes, such as Gapdh/glyceraldehyde-3-phosphate dehydrogenase, Slc2a1/solute carrier family 2 (facilitated glucose transporter), member 1, Tf/transferrin and Tfrc/transferrin receptor, in all three regions. In SV, MOD and OC, increase in the expression of Hmox1/hemoxygenase 1, Nos2/nitric oxide synthase, inducible and Tfrc is particularly high. Hypoxia (5 h) results in an increased expression of Igf2/Insulin-like growth factor 2. CONCLUSION: The present data underline the contribution of radical forming processes to the pathogenesis of inner ear diseases. For experimental research, it is important to note that organotypic culture may be coupled with hypoxia.

Zonation of parenchymal and nonparenchymal metabolism in liver.

The enormous number of different liver functions are carried out by parenchymal and four main types of nonparenchymal cells, either alone or in cooperation. Although the liver tissue is uniform on the level of histology, it is heterogenous on the level of morphometry and histochemistry. This heterogeneity is related to the blood supply; cells located in the upstream or periportal zone differ from those in the downstream or perivenous zone in their equipment with key enzymes, translocators, receptors, and subcellular structures and therefore have different functional capacities. This is the basis of the model of metabolic zonation, according to which glucose release from glycogen and via gluconeogenesis, amino acid utilization and ammonia detoxification, protective metabolism, bile formation, and the synthesis of certain plasma proteins such as albumin and fibrinogen occur mainly in the periportal area, whereas glucose utilization, xenobiotic metabolism, and the formation of other plasma proteins such as alpha 1-antitrypsin or alpha-fetoprotein occur predominantly in the perivenous zone. The mor- phologic and functional heterogeneity is the result of zonal differences in the activation of the cellular genome caused by gradients in oxygen, substrate, hormone, and mediator levels, in innervation, as well as in cell-to-cell and cell-to-biomatrix interactions.

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.

Role of oxygen in the zonation of carbohydrate metabolism and gene expression in liver.

Hepatocytes around the afferent (periportal) vessels differ from those around the efferent (perivenous) vessels in their contents of key enzymes, and therefore have different metabolic capacities. Thus, the model of "metabolic zonation" proposes that the periportal cells produce glucose via glycogenolysis and gluconeogenesis and that the perivenous cells utilize glucose via glycogen synthesis and glycolysis. The periportal and perivenous cells receive different signal patterns, because substrates including oxygen and hormones are degraded and products and mediators are formed during passage of blood through the liver. The different signal patterns should be important for both short-term regulation of metabolic rates and for long-term induction and maintenance of the enzyme equipments by control of gene expression. From the periportal to the perivenous zone, the concentration of the signal oxygen falls corresponding to a drop from about 13 (arterial) to 9 (mixed periportal) and then to 4 (hepatovenous) volume% gas atmosphere. For short-term regulation of metabolism, in perivenous-like cells net glucose production measured over a period of two hours was observed below 2%, net glycogen synthesis above 4%, and net lactate utilization above 6% oxygen. In periportal-like cells net glucose formation and net lactate utilization increased sharply from anoxia to 6% oxygen and then only moderately. For long-term regulation of gene expression, the glucagon (cAMP)-dependent activation of the PCK gene was modulated by oxygen. The transcriptional rate, the abundance of mRNA and the enzyme activity were increased to higher levels under arterial rather than under venous oxygen. Conversely, the insulin-dependent activation of the glucokinase gene was negatively modulated by oxygen. A heme protein appeared to be involved in oxygen sensing, since CO mimicked the effects of oxygen on the PCK gene. Hydrogen peroxide was produced by hepatocytes as a function of oxygen tension; exogenously added, it mimicked the effects of oxygen on PCK gene induction. Therefore, the heme protein containing an oxygen sensor could be a peroxide producing oxidase. It is not known at present whether the same oxygen sensor is also involved in the short-term regulation by oxygen of hepatic carbohydrate metabolism. Transfection of PCK promoter-CAT gene constructs into primary hepatocytes showed that oxygen modulated PCK gene activation in the region of -277/+73. This modulation was not mediated by isolated cAMP responsive elements.

Diminution of the O2 responsiveness of the glucagon-dependent activation of the phosphoenolpyruvate carboxykinase gene in rat hepatocytes by long-term culture at venous PO2.

The glucagon-dependent activation of the phosphoenolpyruvate carboxykinase (PCK) gene within two hours is modulated by O2 in rat hepatocytes. It was the aim of the present study to test if this short-term modulation by O2 of the glucagon induction might be influenced by long-term culture of hepatocytes for 24 hours under different O2 tensions prior to glucagon induction. Cells were precultured for 24 hours at arterial O2 (16% O2) or venous O2 (8% O2), then induced within two to four hours with 1 nM glucagon each at arterial or venous O2. In arterial O2 precultured cells PCK mRNA and activity were induced to 100% at arterial O2 and to about 60% at venous O2. In venous O2 precultured cells PCK mRNA and activity were induced only to about 70% at arterial O2 and to about 60% at venous O2. Transfected PCK promoter (-2500)-CAT constructs were activated by glucagon with the same long-term modulatory effects of oxygen as the endogenous PCK gene. Gel mobility shift assays with nuclear extracts prepared from hepatocytes and a PCK promoter fragment ranging from -149 to -42 bp revealed one complex with a higher DNA binding activity when extracts of cells precultured for 24 hours under venous O2 as compared to arterial O2 were used. Therefore, the short-term modulation by O2 of PCK gene activation by glucagon was widely lost during preculture at low O2. This diminution of O2 sensitivity of PCK induction may be due to a nuclear protein or proteins which are induced by perivenous O2 tensions and bind to the PCK promoter.

Perivenous localization of insulin receptor protein in rat liver, and regulation of its expression by glucose and oxygen in hepatocyte cultures.

Insulin stimulates glucose utilization in the liver, which occurs mainly in the less aerobic, perivenous, zone. Accordingly, the insulin receptor protein was predominantly expressed in this area, although the insulin receptor mRNA was homogeneously distributed. In hepatocyte cultures venous O(2) partial pressure (pO(2)) induced insulin receptor protein expression. High glucose concentrations enhanced insulin receptor protein under arterial and venous pO(2). The induction of insulin receptor protein by venous pO(2) would explain its zonated expression.

Induction of the plasminogen activator inhibitor-1 gene expression by mild hypoxia via a hypoxia response element binding the hypoxia-inducible factor-1 in rat hepatocytes.

Plasminogen activator inhibitor-1 (PAI-1) is the primary physiological inhibitor of both tissue-type and urokinase-type plasminogen activators. The balance between plasminogen activators and PAI-1 plays an important role in several physiological and pathophysiological processes such as atherosclerosis or thrombosis. Because these conditions are associated with hypoxia, it was the aim of the present study to investigate the influence of low O(2) tension on the expression of PAI-1 mRNA and protein using primary cultured rat hepatocytes as a model system. We found that PAI-1 mRNA and protein were induced by mild hypoxia (8% O(2)). The hypoxia-dependent PAI-1 mRNA induction was transcriptionally regulated because it was inhibited by actinomycin D (ActD). Luciferase (LUC) reporter gene constructs driven by about 800 bp of the 5'-flanking region of the rat PAI-1 gene were transiently transfected into primary rat hepatocytes; mild hypoxia caused a 3-fold induction, which was mediated by the PAI-1 promoter region -175/-158 containing 2 putative hypoxia response elements (HRE) binding the hypoxia-inducible factor (HIF-1). Mutation of the HRE-1 (-175/-168) or HRE-2 (-165/-158) also abolished the induction by mild hypoxia. Cotransfection of a HIF-1alpha vector and the PAI-1-LUC constructs, as well as gel shift assays, showed that the HRE-2 of the PAI-1 promoter was most critical for induction by hypoxia and HIF-1 binding. Thus, PAI-1 induction by mild hypoxia via a HIF-1 binding HRE in the rat PAI-1 promoter appears to be the mechanism causing the increase in PAI-1 in many clinical conditions associated with O(2) deficiency.

Identification of an oxygen-responsive element in the 5'-flanking sequence of the rat cytosolic phosphoenolpyruvate carboxykinase-1 gene, modulating its glucagon-dependent activation.

The glucagon-stimulated transcription of the cytosolic phosphoenolpyruvate carboxykinase-1 (PCK1) gene is mediated by cAMP and positively modulated by oxygen in primary hepatocytes. Rat hepatocytes were transfected with constructs containing the first 2500, 493 or 281 bp of the PCK1 5'-flanking region in front of the chloramphenicol acetyltransferase (CAT) reporter gene. With all three constructs glucagon induced CAT activity with decreasing efficiency maximally under arterial pO2 and to about 65% under venous pO2. Rat hepatocytes were then transfected with constructs containing the first 493 bp of the PCK1 5'-flanking region in front of the luciferase (LUC) reporter gene, which were block-mutated at the CRE1 (cAMP-response element-1; -93/-86), putative CRE2 (-146/-139), promoter element (P) 1 (-118/-104), P2 (-193/-181) or P4 (-291/-273) sites. Glucagon induced LUC activity strongly when the P1 and P2 sites were mutated and weakly when the P4 site was mutated; induction of the P1, P2 and P4 mutants was positively modulated by the pO2. Glucagon also induced LUC activity strongly when the putative CRE2 site was altered; however, induction of the CRE2 mutant was not modulated by the pO2. Glucagon did not induce LUC activity when the CRE1 site was modified. These experiments suggested that the CRE1 but not the putative CRE2 was an essential site necessary for the cAMP-mediated PCK1 gene activation by glucagon and that the putative CRE2 site was involved in the oxygen-dependent modulation of PCK1 gene activation. To confirm these conclusions rat hepatocytes were transfected with simian virus 40 (SV40)-promoter-driven LUC-gene constructs containing three CRE1 sequences (-95/-84), three CRE2 sequences (-148/-137) or three CRE1 sequences plus two CRE2 sequences of the PCK1 gene in front of the SV40 promoter. Glucagon induced LUC activity markedly when the CRE1, but not when the CRE2, sites were in front of the SV40-LUC gene; however, induction of the (CRE1)3SV40-LUC constructs was not modulated by the pO2. Glucagon also induced LUC activity very strongly when the CRE1 and CRE2 sites were combined; induction of the (CRE1)3(CRE2)2SV40-LUC constructs was positively modulated by the pO2. These findings corroborated that sequences of the putative CRE2 site were responsible for the modulation by oxygen of the CRE1-dependent induction by glucagon of PCK1 gene transcription.