Liver Transcription Research Articles

Hepatocyte Nuclear Factor 1 and the Glucocorticoid Receptor Synergistically Activate Transcription of the Rat Insulin-like Growth Factor Binding Protein-1 Gene

The insulin-like growth factor (IGF) binding proteins (IGFBPs) are a family of proteins that bind IGF-I and IGF-II and modulate their biological activities. IGFBP-1 is distinctive among the IGFBPs in its rapid regulation in response to metabolic and hormonal changes. The synthetic glucocorticoid, dexamethasone, increases IGFBP-1 mRNA abundance and gene transcription in rat liver and in H4-II-E rat hepatoma cells. A glucocorticoid response element (GRE) located at nucleotide (nt) −91/−77 is required for dexamethasone to stimulate rat IGFBP-1 promoter activity in transient transfection assays in H4-II-E cells. In addition to the GRE, three accessory regulatory sites [a putative hepatocyte nuclear factor-1 (HNF-1) site (nt −62/−50), an insulin-response element (nt− 108/−99), and an upstream site (nt −252/−236)] are involved in dexamethasone stimulation under some, but not all, circumstances. The present study begins to address the mechanism by which transcription factors bound to the putative HNF-1 site act synergistically with the glucocorticoid receptor (GR) bound to the GRE. In gel shift assays, HNF-1α and HNF-1β in H4-II-E extracts bind to the palindromic HNF-1 site. Both half-sites are required. Overexpression of HNF-1β enhances dexamethasone-stimulated promoter activity. Both the HNF-1 site and the GRE must be intact for stimulation to occur. By contrast, overexpression of HNF-1α does not enhance dexamethasone-stimulated promoter activity, although, as also observed with overexpression of HNF-1β, it inhibits basal promoter activity. Thus, the synergistic effects of HNF-1β and the GR on dexamethasone-stimulated promoter activity require that they are bound to the HNF-1 site and the GRE, respectively, and may involve protein-protein interactions between the transcription factors, or between them and the basal transcription machinery or a steroid receptor coactivator. Synergy between the ubiquitously expressed GR and HNF-1, which is developmentally regulated and expressed in a limited number of tissues, provides a possible mechanism for tissue- and development-specific regulation of glucocorticoid action.

Hepatocyte nuclear factor 1 and the glucocorticoid receptor synergistically activate transcription of the rat insulin-like growth factor binding protein-1 gene.

The insulin-like growth factor (IGF) binding proteins (IGFBPs) are a family of proteins that bind IGF-I and IGF-II and modulate their biological activities. IGFBP-1 is distinctive among the IGFBPs in its rapid regulation in response to metabolic and hormonal changes. The synthetic glucocorticoid, dexamethasone, increases IGFBP-1 mRNA abundance and gene transcription in rat liver and in H4-II-E rat hepatoma cells. A glucocorticoid response element (GRE) located at nucleotide (nt) -91/-77 is required for dexamethasone to stimulate rat IGFBP-1 promoter activity in transient transfection assays in H4-II-E cells. In addition to the GRE, three accessory regulatory sites [a putative hepatocyte nuclear factor-1 (HNF-1) site (nt -62/-50), an insulin-response element (nt -108/-99), and an upstream site (nt -252/-236)] are involved in dexamethasone stimulation under some, but not all, circumstances. The present study begins to address the mechanism by which transcription factors bound to the putative HNF-1 site act synergistically with the glucocorticoid receptor (GR) bound to the GRE. In gel shift assays, HNF-1alpha and HNF-1beta in H4-II-E extracts bind to the palindromic HNF-1 site. Both half-sites are required. Overexpression of HNF-1beta enhances dexamethasone-stimulated promoter activity. Both the HNF-1 site and the GRE must be intact for stimulation to occur. By contrast, overexpression of HNF-1alpha does not enhance dexamethasone-stimulated promoter activity, although, as also observed with overexpression of HNF-1beta, it inhibits basal promoter activity. Thus, the synergistic effects of HNF-1beta and the GR on dexamethasone-stimulated promoter activity require that they are bound to the HNF-1 site and the GRE, respectively, and may involve protein-protein interactions between the transcription factors, or between them and the basal transcription machinery or a steroid receptor coactivator. Synergy between the ubiquitously expressed GR and HNF-1, which is developmentally regulated and expressed in a limited number of tissues, provides a possible mechanism for tissue- and development-specific regulation of glucocorticoid action.

Upstream Stimulatory Factor-2 (USF2) Activity Is Required for Glucose Stimulation of L-Pyruvate Kinase Promoter Activity in Single Living Islet β-Cells

Elevated glucose concentrations stimulate L-pyruvate kinase (L-PK) gene transcription in liver and islet beta-cells. A glucose response element termed the L4 box (two noncanonical E-boxes located -165 and -154 base pairs upstream of the transcriptional start point) has previously been defined within the proximal promoter region of the gene. However, the identity of the transacting factor(s) which binds to this site remains unclear. We have used photon counting digital imaging of firefly luciferase activity to monitor promoter activity continuously in single living islet beta and derived INS-1 cells, and to analyze the molecular basis of the regulation by glucose. L-PK promoter activity, normalized to cytomegalovirus promoter activity using the distinct Renilla reniformis luciferase, was >/=6-fold higher in cells cultured at 16 mM glucose or above compared with cells cultured at 3 mM glucose. Microinjection of antibodies against the ubiquitous transcription factor USF2 inhibited L-PK promoter activity in beta- and INS-1 cells incubated at 30 mM glucose by 71-87%. Anti-USF2 antibodies had a much smaller effect on promoter activity in INS-1 cells cultured at 3 mM glucose, and on the activity of a modified promoter construct lacking an L4 box. These data support the view that glucose enhances L-PK gene transcription in beta-cells by modifying the transactivational capacity of USF2 bound to the upstream L4 box.

Transcription in the liver

Transcription in the liver

Effects of cyclic and continuous parenteral nutrition on albumin gene transcription in rat liver

To evaluate schedule-dependent effects of parenteral nutrition on albumin gene expression and regulation, mRNA levels for albumin and its promoter-binding nuclear factors in the liver were measured in rats receiving cyclic or continuous parenteral nutrition. Rats were divided into three groups: the control group (n = 5) received a nonpurified diet, the continuous parenteral nutrition group (n = 5) received a continuous infusion of a defined parenteral nutrition formula, and the cyclic parenteral nutrition group (n = 5) received a cyclic (between 2000 and 0800) infusion of the same formula. After 7 d, rats were killed to obtain serum and liver. The serum albumin concentrations were 44 +/- 3 g/L in the controls, 31 +/- 2 g/L in the continuous parenteral nutrition group, and 33 +/- 3 g/L in the cyclic parenteral nutrition group. The mRNA for albumin and D site binding protein (DBP) was more abundant and mRNA for CCAAT/enhancer binding protein beta (C/EBP beta) was less abundant in the cyclic parenteral nutrition group than in the continuous parenteral nutrition group. Gel-shift assay for D site and gel-shift Western blotting of DBP carried out using another three rats in each group revealed an increase of DBP in rats receiving cyclic parenteral nutrition compared with continuous parenteral nutrition. In conclusion, although parenteral nutrition decreases serum albumin concentrations, cyclic parenteral nutrition maintains transcription of the albumin gene to a greater extent than does continuous parenteral nutrition. Cyclic parenteral nutrition, in contrast with continuous parenteral nutrition, sustains the mRNA and concentrations of DBP.

Regulation of signal transducer and activator of transcription (STAT) 5b activation by the temporal pattern of growth hormone stimulation.

Plasma GH profiles, intermittent in adult male and continuous in adult female rats, respectively, activate unique patterns of gene transcription in male and female rat liver. Pulsatile, but not continuous, GH exposure activates liver STAT5 (signal transducer and activator of transcription-5) by tyrosine phosphorylation, leading to nuclear translocation, and is proposed to play a key role in GH pulse-regulated male-specific liver gene expression. The mechanisms underlying the GH pattern dependence of STAT5 activation are presently investigated using a rat hepatocyte-derived cell line. Rat GH stimulated tyrosine phosphorylation followed by serine or threonine phosphorylation, leading to activation of the DNA-binding activity of STAT5b, the major STAT5 form present in these cells. Maximal STAT5b activation required a full 20 min at a receptor-saturating GH concentration of 50 ng/ml, suggesting that hormone binding leading to receptor dimerization is a relatively slow process. Repeat cycles of GH pulsation led to repeat cycles of STAT5b activation followed by deactivation, similar to rat liver in vivo. Full responsiveness to succeeding GH pulses required a minimum GH off-time of > or = 2.5 h, but was independent of new protein synthesis. Continuous GH exposure led to down-regulation of activated STAT5b, consistent with the desensitization of this GH pulse-activated pathway observed in female rat liver. The rapid deactivation of STAT5b after termination of a GH pulse involved phosphotyrosine dephosphorylation as a key first step and could be blocked by pervanadate, a phosphotyrosine phosphatase inhibitor. Unexpectedly, serine/threonine kinase inhibitors also inhibited STAT5b deactivation. These studies establish that STAT5b is responsive to the temporal pattern of GH stimulation and demonstrate a role for both a tyrosine phosphatase and a serine/threonine kinase in resetting this JAK/STAT signaling apparatus so that it may respond to subsequent rounds of GH pulse activation.

Interaction of a Novel Sex-dependent, Growth Hormone-regulated Liver Nuclear Factor with CYP2C12 Promoter

CYP2C12 is a steroid hydroxylase cytochrome P450 whose female-specific expression in adult rat liver is transcriptionally activated by the continuous plasma growth hormone (GH) profile characteristic of adult female rats. DNase I footprinting and gel mobility shift analysis of the 5'-flank of the CYP2C12 gene were carried out to identify cis-acting elements and trans-acting factors that may contribute to the GH-regulated, sex-dependent transcription of this P450 gene. DNase I footprinting analysis revealed sex- and GH-regulated DNase I hypersensitivity sites at the boundaries of several protein binding sites detected along a 1560-nucleotide upstream segment of CYP2C12. Five distinct sites bound a novel continuous GH-regulated nuclear factor, GHNF, which is enriched in adult female and continuous GH-treated male liver nuclear extracts compared to untreated male liver nuclear extracts. Two other footprinted sites correspond to binding sites for the liver transcription factors C/EBP and albumin D element-binding protein and a third to an HNF1 binding site. A specific binding site for GHNF was also found in the 5'-proximal promoter of CYP2C11, an adult male-specific liver P450 gene, suggesting that GHNF may contribute to the down-regulation of that gene by continuous GH. GHNF was distinguished from the nuclear factors that bind to a GH response element upstream of the rat Spi 2.1 gene and is also distinct from the GH-activatable latent cytoplasmic transcription factors STAT 1, STAT 3, and STAT 5. These findings support the hypothesis that continuous GH-activated transcription of CYP2C12 in adult female rat liver (a) involves the activation of a novel GH-regulated nuclear factor which binds to multiple sites along the 5'-flank of this cytochrome P450 gene, and (b) proceeds via a signaling pathway distinct from the GH pulse-activated STAT5 pathway proposed to induce CYP2C11 and other male-expressed liver genes.

Dexamethasone stimulation of rat insulin-like growth factor binding protein-1 promoter activity involves multiple cis-elements.

Insulin-like growth factor binding protein-1 (IGFBP-1) modulates the mitogenic actions of IGF-I and IGF-II. Dexamethasone increases IGFBP-1 mRNA abundance and gene transcription in rat liver and in H4-II-E rat hepatoma cells. A glucocorticoid response element (GRE) located at nucleotide (nt) -91/-77 is required for dexamethasone to stimulate rat IGFBP-1 promoter activity in transient transfection assays in H4-II-E cells. Mutagenesis of nt -108/-99 (the M4 region of the insulin response element), however, decreased dexamethasone-stimulated promoter activity despite the presence of an intact GRE, suggesting that regulatory sites in addition to the GRE were required for optimal dexamethasone stimulation. To identify these sites, we introduced 5'-deletion and substitution mutations into rat IGFBP-1 promoter fragments coupled to a luciferase reporter gene and transfected these constructs into H4-II-E cells. Three sites are required for optimal basal promoter activity: a site (nt -62/-50) that binds the liver-enriched transcription factor, hepatocyte nuclear factor-1 (HNF-1), the M4 site, and a putative binding site for transcription factor AP-2 (nt -293/-286). The HNF-1 and M4 sites and an upstream site (nt -252/-236) are also involved in dexamethasone stimulation under some, but not all, circumstances. Mutation of either the HNF-1 site or the M4 site decreased dexamethasone stimulation by more than 80% in constructs whose 5'-end was at nt -92, -135, or -235 but not if the 5' -end was at nt -278 or -327. These results suggest that the nt -278/-236 region can compensate for the loss of the HNF-1 site or the M4 site but that the HNF-1 and M4 sites do not compensate for each other in constructs whose 5'-end was at nt -135 or -235, which lack the nt -278/-236 region. The site within the nt -278/-236 region was localized to nt -252/-236 by deoxyribonuclease I protection and transfection assays. Thus, several cis-elements in the rat IGFBP-1 promoter cooperate, in varying combinations, with the low-affinity GRE to allow optimal dexamethasone-stimulated promoter activity.

Vitamin K-Dependent Carboxylase: mRNA Distribution and Effects of Vitamin K-Deficiency and Warfarin Treatment

A cDNA encoding vitamin K-dependent γ-glutamyl carboxylase was cloned from a human Hep G2 cDNA library. The RNA transcript of the enzyme was found to be widely distributed in various human and rat tissues with liver showing the highest level. The carboxylase transcription in liver was not affected in rats treated with a single dose of warfarin (10 mg/kg) when measured up to 48 hours after the dose, though, at 12 hours, carboxylase activity measured in liver microsomes was elevated 5.4 fold over controls (p<0.001). In rats fasted for 72 hours there was no affect on transcription in the liver while hepatic carboxylase activity increased 4.1 fold (p<0.001). These data suggest that the increase in activity of the liver carboxylase in warfarin treated or fasted rats was not regulated by transcription but more likely was due to a posttranscriptional mechanism.

Nutritional regulation of gene expression of insulin-like growth factor-binding proteins and the acid-labile subunit in various tissues of rats

The plasma concentration and liver mRNA content of IGF-I are regulated by the quantity and quality of dietary proteins. To determine whether the synthesis of IGF-binding proteins (BPs) is also affected by protein nutrition, we assessed plasma concentration, tissue mRNA content and liver transcription rate of each BP after rats were fed either a 12% casein or a protein-free diet for 1 week. Protein deprivation reduced the plasma concentration of IGFBP-3 and IGFBP-4 and increased that of IGFBP-1 and IGFBP-2. The mRNA content in tissues and liver transcription rates of IGFBP-3 and IGFBP-4 did not change in response to protein deprivation although their plasma concentrations decreased. The increased plasma IGFBP-1 and IGFBP-2 concentrations were explained by the increased mRNA content and transcription rate of their genes in the liver. Although IGFBP-1 mRNA was increased by protein deprivation not only in liver but also in kidney, IGFBP-2 mRNA was increased only in liver and did not increase in any other tissue examined. In addition, the liver mRNA content of the acid-labile subunit, which can form a ternary complex with IGFs and IGFBP-3, was not affected by protein deprivation. These results show that tissue-specific synthesis of each BP is regulated in a distinct way in response to protein deprivation.

Effects of Insulin, Epinephrine, and Glucose on Regulation of Transcription of the Serine Dehydratase Gene in Newborn Dogs

Our previous investigations showed that hyperinsulinemia incompletely suppressed the transcription of the gene encodingl-serine dehydratase (SDH) (EC 4.2.1.13), a gluconeogenic enzyme, in newborn dogs. To test another hypothesis that insulin resistance in newborn mammals may be partially due to counterregulatory factors, such as epinephrine, euglycemic hyperinsulinemic clamps, hyperglycemic hyperinsulinemic clamps, and hyperglycemic hyperinsulinemic hyperepinephrinemic clamps were performed in newborn dogs in the present study. The infusion rates of insulin and epinephrine were 30 mU/kg/min and 150 ng/kg/min, respectively; the glucose infusion rate was adjustable. The SDH mRNA levels in kidney and liver of newborn dogs were quantitatively analyzed by using rat SDH cDNA probe and by a personal densitometer. The results showed that insulin, glucose, and epinephrine did not change the kidney SDH mRNA level; hyperinsulinemia and hyperglycemia reduced the liver SDH mRNA level by 8.5 and 29.2%, respectively; in the presence of hyperglycemia and hyperinsulinemia, epinephrine was able to increase the liver SDH mRNA by 27.8%, almost offsetting the reduction of the liver SDH mRNA level induced by the combination of insulin and glucose. We conclude that the enhanced regulatory effect of epinephrine counteracting insulin on SDH gene transcription in liver of newborn dogs may be one of the mechanisms responsible for the neonatal insulin resistance which contributes to neonatal hyperglycemia.

Dietary Calorie Restriction in Mice Induces Carbamyl Phosphate Synthetase I Gene Transcription Tissue Specifically

Dietary calorie restriction (CR) delays age-related physiologic changes, increases maximum life span, and reduces cancer incidence. Here, we present the novel finding that chronic reduction of dietary calories by 50% without changing the intake of dietary protein induced the activity of mouse hepatic carbamyl phosphate synthetase I (CpsI) 5-fold. In liver, CpsI protein, mRNA, and gene transcription were each stimulated by approximately 3-fold. Thus, CR increased both the rate of gene transcription and the specific activity of the enzyme. Short-term feeding studies demonstrated that higher cpsI expression was due to CR and not consumption of more dietary protein. Intestinal CpsI activity was stimulated 2-fold, while its mRNA level did not change, suggesting enzyme activity or translation efficiency was stimulated. CpsI catalyzes the conversion of metabolic ammonia to carbamyl phosphate, the rate-limiting step in urea biosynthesis. cpsI induction suggests there is a shift in the metabolism of calorie-restricted animals toward protein catabolism. CpsI induction likely facilitates metabolic detoxification of ammonia, a strong neurotoxin. Enhanced protein turnover and metabolic detoxification may extend life span. Physiologic similarities between calorie-restricted and hibernating animals suggest the effects of CR may be part of a spectrum of adaptive responses that include hibernation.

Antioxidant enzyme gene transcription in copper-deficient rat liver

Antioxidant enzymes, Cu/Zn- and Mn-superoxide dismutase, catalase, and glutathione peroxidase, constitute an important defense mechanism against cytotoxicity of reactive oxygen species. Copper is essential for the activity of Cu/Zn-superoxide dismutase. Oxidative stress, therefore, is expected in organs of rats fed copper-deficient diet due to reduced Cu/Zn-superoxide dismutase activity. Our previous studies have shown that the expression of antioxidant enzymes was altered in copper-deficient rat liver. The present report was undertaken to study further the transcription of these enzymes in liver nuclei of rats made copper-deficient for 4 weeks. While copper deficiency decreased the copper in liver by about 80%, it did not alter the copper content in liver nuclei. In spite of a 100% elevation in nuclear iron concentration, liver nuclei from copper-deficient rats showed normal appearance. The transcriptional rates for Cu/Zn-superoxide dismutase, glutathione peroxidase, and glyceraldehyde-3-phosphate dehydrogenase were not altered by dietary copper deprivation. In contrast, transcriptional rates for Mn-superoxide dismutase and β-actin were increased but that for catalase was reduced in the nuclei isolated from the copperdeficient rat liver. These results suggest that oxidative stress, resulting from copper deficiency, differentially modulates the gene transcription for the antioxidant enzymes in rat liver.

DNA elements and protein factors involved in the transcription of the beta 2-adrenergic receptor gene in rat liver. The negative regulatory role of C/EBP alpha.

Primer extension and RNase protection analyses of the rat beta 2-adrenergic receptor (beta 2AR) gene identify two transcription start points at -64 and -220 nt, respectively. Transient transfections of putative promoter/pCAT constructs into DDT1 MF-2 cells indicate that fragments -36 to -100 (PI) and -186 to -312 (P2) are sufficient to promote transcription, whereas -911 to -1122 contains a negative regulatory element(s). RNase protection analysis of the 3' untranslated region (3'-UTR) indicates the presence of two transcripts with 3'-UTR of 111 and 604 nt exclusive of the poly(A+) tails. Northern blots of beta 2AR mRNA using full-length and partial cDNA probes indicate that a major 2.2 kb and a minor 1.6 kb species arise from the use of alternative promoters as well as different polyadenylation signals. DNase I footprinting and DNA mobility shift assays (DMSA) using rat liver nuclear extracts identify a number of transcription factors binding to sequence elements within or upstream from P1 and P2, including Spl, CRE, CPl, AP-2, NF-1, NF-kappa B, and C/EBP. Supershift assays using antibodies against C/EBP alpha and C/EBP beta and mutational analyses indicate that the protein binding to the C/EBP consensus recognition site at -925 to -933 is C/EBP alpha. The activity of promoter/CAT constructs containing the C/EBP recognition site is significantly decreased by cotransfection of C/EBP alpha but not C/EBP alpha but not C/EBP beta into either DDT1 MF-2 cells or primary rat hepatocytes. Partial hepatectomy causes a transient decrease in C/EBP alpha, as measured by DMSA, and an increase in beta 2 AR mRNA levels and rate of transcription in the remnant liver. Thus, derepression via C/EBP alpha is likely involved in the up-regulation of beta 2AR in the regenerating rat liver.

Nucleotide Structure and Characterization of the Murine Blood Coagulation Factor VII Gene

The gene encoding murine coagulation factor VII (fVII) has been cloned. Seven introns and eight exons are present, with the introns positioned as splice junctions between the major domain units of the protein. A total of 11,748 bp of the gene was sequenced, and included 1,077 bp of a 5'-flanking region, in which several high probability binding sites for liver transcription factors were present, as well as a CCAAT sequence and possible GC boxes. Primer extension analysis revealed that the major transcription start site was positioned only 9 residues upstream of the ATG initiation codon, thus providing a very short 5'-untranslated region of the gene. The sequence of the CAP site in the murine fVII gene matched exactly the consensus eukaryotic sequence. A total of 1,484 bp of 3'-flanking nucleotides included a probable polyadenylation site (ATTAAA) and an appropriately positioned downstream consensus sequence (AGTGTTTC) for the efficient formation of a 3' terminus of mRNA. These results indicate that all elements are present for liver-based transcription of the gene for murine factor VII. The sequence and restriction endonuclease map of this gene will facilitate construction of fVII deficient mice and mice containing mutant fVII genes.

Cloning and Characterization of the Mouse Glucokinase Gene Locus and Identification of Distal Liver-Specific DNase I Hypersensitive Sites

We cloned and characterized an 83-kb fragment of mouse genomic DNA containing the entire glucokinase (GK) gene. The 11 exons of the gene span a total distance of 49 kb, with exons 1β and 1L being separated by 35 kb. A total of 25,266 bp of DNA sequence information was determined: from ∼−9.2 to ∼+15 kb (24,195 bp), relative to the hepatocyte transcription start site, and from −335 to +736 bp (1071 bp), relative to the transcription start site in β cells. These sequences revealed that mouse GK is >94% identical to rat and human GK. Mouse hepatic GK mRNA is regulated by fasting and refeeding, as also occurs in the rat. Alignment of the upstream and downstream promoter regions of the mouse, rat, and human genes revealed several evolutionarily conserved regions that may contribute to transcriptional regulation. However, fusion gene studies in transgenic mice indicate that the conserved regions near the transcription start site in hepatocytes are themselves not sufficient for position-independent expression in liver. Analysis of the chromatin structure of a 48-kb region of the mouse gene using DNase I revealed eight liver-specific hypersensitive sites whose locations ranged from 0.1 to 36 kb upstream of the liver transcription start site. The availability of a single, contiguous DNA fragment containing the entire mouse GK gene should allow further studies of cell-spe- cific expression of GK to be performed.

IGF-I and serine protease inhibitor 2·1 nuclear transcript abundance in rat liver during protein restriction

Restriction of dietary protein consumption of young male rats results in decreased growth velocity and a reduction in the abundance of hepatic IGF-I mRNA. It is not known whether the reduction of IGF-I mRNA abundance in the liver of protein-restricted rats results from a decrease in IGF-I gene transcription. In the present study, three experiments were performed with 4-week-old male rats to examine the effect of protein restriction on IGF-I gene transcription in liver. In these experiments, we monitored IGF-I nuclear transcripts (pre-mRNA) within total cellular RNA using a ribonuclease protection assay. In the first experiment, a consistent decrease in IGF-I mRNA from animals fed isocaloric diets containing 20% (control), 12%, 8% and 4% protein (dietary effect, P < 0.001) was not paralleled by a decrease (P > 0.50) in IGF-I pre-mRNA. Two additional experiments examining the effect of 4% vs 20% protein diets yielded comparable results. Pooled results from these two studies (n = 12/treatment) demonstrated that a 64% reduction (P < 0.0001) in IGF-I mRNA abundance was not accompanied by a decrease in IGF-I pre-mRNA (1.17 vs 1.31 +/- 0.21 image density units for 4% and 20% protein treatments). Unlike IGF-I, the abundance of carbamyl phosphate synthetase-I (CPS-I) pre-mRNA and mRNA was comparably reduced (approximately 70%, P < 0.001), indicating that the decrease in mRNA of this urea cycle enzyme during protein restriction occurs predominantly by a transcriptional mechanism. A common feature of all experiments was a pronounced variability in the expression of hepatic IGF-I pre-mRNA among animals, which was not diet specific. To test whether the variability in IGF-I gene transcription was correlated with variability in the transcription of another gene that is regulated by GH, we quantified the abundance of nuclear transcripts for the serine protease inhibitor 2.1 (SPI 2.1) gene. A positive association (r = 0.81, P < 0.0001) between SPI 2.1 and IGF-I nuclear transcripts was demonstrated. The correlation between IGF-I and SPI 2.1 transcripts was specific, because the quantity of IGF-I and CPS-I nuclear transcripts was not correlated in this study. Although transcription of the IGF-I and SPI 2.1 genes was similar, the abundance of SPI 2.1 mRNA was not altered by protein deprivation.(ABSTRACT TRUNCATED AT 400 WORDS)

Regulation of Hepatic Genes and Liver Transcription Factors in Rat Hepatocytes by Extracellular Matrix

Culturing hepatocytes on different extracellular matrix (ECM) substrata including tissue culture plastic, type I collagen, Engelbreth-Holm-Swarm (EHS) gel and poly-N-p-vinylbenzyl-D-lactonamide (PVLA) regulated levels of mRNAs for cytoskeleton and liver-specific genes. In hepatocytes on EHS gel, the ratio of albumin/β-actin in mRNA levels was high and serially increased during the culture period, while the ratio was low and declined in cells on plastic substratum, collagen or PVLA. The changes in cellular levels of albumin mRNA which were regulated by ECM corresponded with those in two liver-specific transcription factors, hepatocyte nuclear factors-1 and -4, which control the transcription of liver-specific genes. These results suggest that cell-matrix interaction may determine and maintain the differentiated phenotype of hepatocytes by regulating liver-specific transcription factors.

A 700-bp fragment of the human antithrombin III promoter is sufficient to confer high, tissue-specific expression on human apolipoprotein A-II in transgenic mice

The human antithrombin III-encoding gene (h AT-III) promoter ( ph AT-III) was used to generate transgenic mice producing a human hepatic apolipoprotein, apolipoprotein A-II (hApoA-II). Integration of the transgene into the mouse genome resulted in the efficient production of hApoA-II in plasma, reaching up to 0.40 g/l in two transgenic lines. The human ApoA-II mRNA was detected at high levels, both in the liver and in the kidney of transgenic mice. The rat AT-III gene shows the same expression pattern. In contrast, as previously described, the same promoter permitted the expression of the SV40 large T antigen only in the liver of transgenic mice. In view of the extra-hepatic distribution of the ApoA-II mRNA, a preliminary characterization of the hAT-III proximal promoter ( phAT-III), driving the expression of the transgene, was realized. Using DNase I footprinting analysis with liver nuclear extracts, four protected regions (I–IV) were identified in the first 175 bp of the 5′ region of h AT-III. Electrophoretic mobility shift assays performed with liver and kidney nuclear extracts indicate that region III (nucleotides (nt) −67 to −90) interacts with the liverenriched HNF4 nuclear factor. Furthermore, our data suggest that region I (nt −123 to −138) interacts with the liverenriched HNF3 transcription factor family, both in liver and kidney. Taken together, these results demonstrate that ph AT-III is a useful tool to create transgenic mice producing high plasma levels of a human apolipoprotein due to expression of the transgene in liver and kidney. Interestingly, our data suggest that, in both organs, common pathways are involved in the control of ph AT-III activity

The three heavy-chain precursors for the inter-α-inhibitor family in mouse: new members of the multicopper oxidase protein group with differential transcription in liver and brain

The inter-alpha-inhibitor (I alpha I) family is comprised of the plasma protease inhibitors I alpha I, inter-alpha-like inhibitor (I alpha LI), pre-alpha-inhibitor (P alpha I) and bikunin. I alpha I, I alpha LI and P alpha I are distinct assemblies of bikunin with one of three heavy (H) chains designated H1, H2 and H3. These H chains and bikunin are respectively encoded by a set of three H genes and an alpha 1-microglobulin/bikunin precursor (AMBP) gene. All four gene products undergo maturation steps from precursor polypeptides. The full-length cDNAs for the H1-, H2- and H3-chain precursors were cloned from a mouse liver cDNA library and sequenced. Extensive searches of amino acid sequence similarities to other proteins in databanks revealed (i) a highly significant similarity of the C-terminal sequence in the three H-chain precursors to the multicopper-binding domain in the group of multicopper oxidase proteins and (ii) the presence of von Willebrand type-A domains in the mature H chains. Amino acid sequence comparisons between the three mouse H1-, H2- and H3-chain precursors and their human counterparts allowed us to appraise the timing and order of occurrence of the three H-chain genes from a shared ancestor during mammalian evolution. Owing to a multiple alignment of the six mouse and human nucleotide sequences for these H-chain precursors, a reverse transcriptase PCR assay with degenerate oligonucleotides was designed, allowing us to (i) present evidence that no mRNAs for further H genes exist in mouse liver and (ii) demonstrate a previously undescribed transcription of the H2- and H3-chain mRNAs in mouse brain, which contrasts with the expression of all four, H1, H2, H3 and AMBP, mRNAs in liver.