Expression of matrix metalloproteinase-2 and -9 and of tissue inhibitor of matrix metalloproteinase-1 in liver regeneration from oval cells in rat.

Oval cells participate in liver regeneration when hepatocyte replication is impaired. These precursor cells proliferate in periportal regions and organize in ductules. They are surrounded by a basement membrane, the degradation of which by matrix metalloproteinases (MMP) might trigger their terminal differentiation into hepatocytes. We studied the expression of MMP-2 and MMP-9 and that of one of their tissue inhibitors (TIMP-1) in a model of hepatic regeneration from precursor cells. Regeneration was induced by treating rats with 2-acetylaminofluorene followed by partial hepatectomy. MMP-2 and MMP-9 hepatic expression paralleled oval cell number with a peak at day 9-14 after hepatectomy. They were mainly detected in oval cells. TIMP-1 mRNA and oncostatin M receptor mRNA, a major regulator of TIMP-1 synthesis, markedly increased from day 1 after surgery until day 9 and then declined; they were mainly detected in interlobular bile duct cells and oval cells until day 14. In agreement with the in vivo data, the WB-F344 liver precursor cell line expressed MMP-2 and MMP-9, as well as TIMP-1 and oncostatin M receptor. These data suggest that (a) early increased TIMP-1 synthesis by biliary and oval cells favors basement membrane deposition around proliferating ductular structures through MMP inhibition, (b) delayed increased MMP expression, concomitant to decreased TIMP-1 synthesis, leads to basement membrane degradation, preceding oval cell differentiation, (c) the oncostatin M pathway might play a major role in increased TIMP-1 synthesis.

Differential expression of the rat gamma-glutamyl transpeptidase gene promoters along with differentiation of hepatoblasts into biliary or hepatocytic lineage.

gamma-Glutamyl transpeptidase (GGT), a major enzyme of glutathione (GSH) homeostasis, is often used as a biliary marker to follow the differentiation of hepatic precursor cells. The expression of the GGT gene is driven by different promoters and yields multiple mRNAs, depending on the cell type or the stage of differentiation. In the present study, we analyzed the GGT mRNA expression pattern by quantitative reverse transcriptase-polymerase chain reaction or by in situ hybridization i) in the liver, in vivo, at early stages of development; ii) in oval cells, which proliferate and differentiate into hepatocytes in response to galactosamine injury in vivo; and finally, iii) during hepatoblast differentiation, in vitro. We show that GGT gene transcription originates from promoters P3, P4, and P5 in rat hepatic precursor cells. Differentiation of these cells induces profound alterations in GGT gene expression, leading to extinction of promoters P4 and P5, when they differentiate into the hepatocytic pathway, and to extinction of promoters P3 and P5 when they differentiate into the biliary pathway. This diversity in GGT mRNA expression provides unique molecular probes to follow hepatic precursor cell differentiation. Furthermore, the identification of factors governing GGT P5 and P4 promoter expression should provide further insight into the molecular events that occur as the liver precursor cell differentiates into the hepatic lineages.

Gamma-glutamyl transpeptidase gene organization and expression: a comparative analysis in rat, mouse, pig and human species.

Gamma-glutamyl transpeptidase (GGT) is an enzyme located at the external surface of epithelial cells. It initiates extracellular glutathione (GSH) breakdown, provides cells with a local cysteine supply and contributes to maintain intracellular GSH level. GGT expression, highly sensitive to oxidative stress, is a part of the cell antioxidant defense mechanisms. We describe recent advances in GGT gene structure and expression knowledge and put emphasis on the complex transcriptional organization of that gene and its conservation among different species. GGT gene structure has been elucidated in rat and mouse where a single gene is transcribed from multiple promoters into several transcripts which finally yield a unique polypeptidic chain. Analysis of rat, mouse, human and pig cDNA and gene sequences reveals a large conservation of the transcriptional organization of that gene. This complex structure provides flexibility in GGT expression controlled at the promoter level, through multiple regulatory sites, and at RNA level by alternate 5' untranslated sequences which may create a diversity in the stability and translational efficiency of the different transcripts. In conclusion, transcription of the GGT gene from several promoters offers multiple DNA and RNA targets for various oxidative stimuli and contributes to a broad antioxidant cell defense through GGT induction and subsequent cysteine supply from extracellular glutathione.

The gamma-glutamyl transpeptidase gene is transcribed from a different promoter in rat hepatocytes and biliary cells.

Gamma-glutamyl transpeptidase (GGT) activity is commonly used to follow the differentiation of liver precursor cells into the biliary lineage. However, the GGT expression in immature hepatocytes or its induction in adult hepatocytes following diverse carcinogenic or noncarcinogenic treatments has questioned the reliability of GGT expression as a biliary marker. In the present study, we investigated the GGT gene expression from its five different promoters in the late fetal, neonatal, and adult rat liver by Northern blot, reverse transcription-polymerase chain reaction, and in situ hybridization analysis. We show that the GGT activity in the 18-day-old fetus results from the transcription of the gene from the promoter P3 in the hepatocytes. In contrast, the GGT promoter P4 activity appears to be specific of biliary cells in normal as well in cholestatic liver. Thus, sequences unique to the GGT transcripts initiated on these two alternate promoters provide unique molecular probes to discriminate between the biliary and the hepatocytic phenotypes in liver differentiation and cell lineage studies.

A specific distal promoter controls gamma-glutamyl transpeptidase gene expression in undifferentiated rat transformed liver cells.

In rat undifferentiated hepatoma cells, the gamma-glutamyl transpeptidase (GGT) gene is transcribed into a 2.3 and a 2.6 kb mRNA which, in contrast with other rat GGT transcripts, are not detected in more differentiated liver cells or adult tissues. Analysis of the cDNA sequences obtained from H5 hepatoma cells reveals that these two transcripts differ from other GGT mRNAs by a 312-nt unique untranslated leader sequence; this sequence maps on the gene in a single exon 10 kb upstream from the GGT promoter IV transcription start site. We established that the 2.6 kb mRNA V-1 and the 2.3 kb GGT mRNA V-2 derive, by alternate splicing, from a primary transcript initiated on a distal promoter on the rat GGT gene. This gene appears to be transcribed from five promoters, and the specific expression of this new distal promoter in undifferentiated hepatoma cells requires binding of activator protein-1 and hepatic nuclear factor 3 specific transcription factors to a composite cis-element in the proximal region of the promoter. The distal GGT promoter, specifically expressed in undifferentiated liver cells, might reflect the expression of that gene in liver precursor cells before they differentiate in the hepatocytic or biliary lineage.

Species differences in the localisation of gamma-glutamyl transpeptidase immunopositive cells at the blood-brain interface.

The expression of gamma-glutamyl transpeptidase (GGT) has been associated with the emergence of a functional blood-brain barrier. We have undertaken a precise localisation of this enzyme in the cerebral cortical vessels of different species, by immunocytochemistry using a polyclonal antibody and light and electron microscopy. GGT immunoreaction product was present on the luminal surface of endothelial cells in 1-day-old to 3-month-old rats, whereas in the mouse, monkey and human cortex, this protein was present in astrocytic endfeet around the vessels. No labelling was observed in the other cellular components of the vessel walls, such as pericytes, fibroblasts, smooth muscle cells and perivascular cells. The localisation of GGT in astrocytes in mice, monkeys and humans suggests that these cells could play a role in the detoxication of lipophilic xenobiotic substances that cross the endothelial barrier. In these species, astrocytes can be viewed as a second line of defense against xenobiotics, beyond the capillary endothelium.

Control of gamma-glutamyl transpeptidase expression by glucocorticoids in the rat pancreas. Correlation with granule formation.

Glucocorticoids are known to promote the formation of zymogen granules in acinar cells of the exocrine pancreas in vivo as well as in vitro. To gain insight into the mechanism of this regulation, we studied the effects of glucocorticoids on the synthesis of two components of the secretory granule membrane, the glycoprotein 2 (GP-2) and the gamma-glutamyl transpeptidase (GGT). It was demonstrated that following adrenalectomy, degranulation of pancreatic acinar cells is accompanied by a sharp decrease in GGT and GP-2 synthesis as measured by mRNA and protein accumulation. The decline of GGT synthesis was prevented by glucocorticoid replacement therapy, whereas GP-2 synthesis could be maintained with either glucocorticoid or estradiol treatment. These in vivo observations were corroborated and extended in an in vitro study using AR42J pancreatic cells. With this cell line, it was demonstrated that dexamethasone induces the formation of zymogen granules and the accumulation of a specific GGT transcript (mRNA III) by decreasing its degradation rate. At the same time, the GP-2 mRNA level was not modified by the hormonal treatment. These data demonstrate that glucocorticoids exert a positive control on the GGT expression in pancreatic cells at a post-transcriptional level. GGT, an enzyme of the glutathione metabolism, could play a significant role in protein packaging in secretory cells.

Three alternative promoters of the rat gamma-glutamyl transferase gene are active in developing lung and are differentially regulated by oxygen after birth.

The rat gamma-glutamyl transferase mRNA transcripts I, II, and III are derived from three alternative promoters, P(I), P(II), and P(III). In the adult only mRNA III is expressed in the lung. We show that mRNA III gene expression is developmentally regulated in the fetal lung; it is first expressed in gestation. In contrast to the adult lung, the fetal lung expresses mRNA I, II, and III. The switch from the fetal to the adult pattern of gammaGT mRNA expression begins within the first 24 h of birth and is complete by 10 d of age. gammaGT mRNA II disappears within 24 h, mRNA I disappears by 10 d leaving mRNA III as the sole transcript. Alveolar epithelial type 2 cells (AT2) isolated from the adult lung express only mRNA III. When cultured in 21% O2 mRNA III is maintained, but when cultured in 3% O2 the fetal pattern of mRNA I, II and III expression is induced. When AT2 cells in hypoxia are exposed to carbon monoxide, mRNA II is suppressed suggesting that a heme-binding protein (responsive to oxygen) may suppress mRNA II expression and may be responsible for the decrease in lung mRNA II seen after birth. A reporter gene under the control of DNA sequences from the gammaGT P(III) promoter is activated in transient transfection studies in response to hyperoxia, while a deletion construct retaining an antioxidant responsive element is not. Oxygen appears to regulate each of the alternative promoters of the gammaGT gene, such that P(II) is rapidly repressed by a heme-dependent mechanism, P(I), is more gradually repressed by a nonheme mechanism and P(III) is activated by a putative oxygen response element. We hypothesize that similar oxygen-dependent mechanisms regulate other genes in the developing lung at birth.

Expression of the rat gamma-glutamyl transpeptidase gene from a specific promoter in the small intestine and in hepatoma cells.

In the small intestine and in HTC hepatoma cells, the gamma-glutamyl transpeptidase (GGT) single-copy gene is transcribed into a 2.5 kb and a 2.2 kb mRNA. Cloning of the GGT cDNA sequences from HTC cells demonstrates that the 2.5 kb mRNA (mRNA(IV-1)) differs from the other rat GGT transcripts by a 371-base unique leader sequence which maps in the gene as 2 separate exons upstream of the 3 promoters which have been previously characterized. We established that the transcription of these two mRNAs is initiated on a new promoter (promoter IV) and occurs in the small intestine, in the epididymis, and in some hepatoma cells. The primary transcript initiated on GGT promoter IV is then alternatively spliced into the 2.5 kb mRNA(IV-1) or the 2.2 kb mRNA(IV-2) which is shorter in its 5'-untranslated sequence. The rat GGT gene exhibits a complex transcriptional organization leading to the transcription of five mRNAs from four independent promoters in a tissue-specific manner. The expression of the GGT promoter IV in the HTC hepatoma cells as well as in the small intestine could reveal that the HTC-transformed cells originate from liver precursor cells which still have the capacity to evolve toward different lineages. Thus, the GGT promoter IV will be valuable to isolate factors involved in the differentiation and carcinogenic processes.

Functional characterization of the rat gamma-glutamyl transpeptidase promoter that is expressed and regulated in the liver and hepatoma cells.

gamma-Glutamyl transpeptidase (GGT) is an enzyme encoded by multiple mRNAs (mRNAI to mRNAIV) that, in the rat, are transcribed from a single copy gene in a tissue-specific manner. In the liver, GGT expression is up-regulated in transformed cells, and this induction is the most widely used marker of liver cell transformation. We characterized the GGT mRNA species expressed in the liver (mRNAIII), and we report that this mRNA differs from the other GGT mRNA species by a 275-base alternate 5'-end sequence. Its transcription occurs on a specific promoter (promoter III) that maps on the GGT gene upstream of the two promoters coding for the GGT mRNAI and mRNAII. In hepatoma cells, mRNAIII expression is related to the differentiation state of the cells. We have shown that, in Reuber H-35-derived cell lines, the GGT mRNAIII is transcribed in cells that express a differentiated phenotype (Fao), but not in the dedifferentiated C2 and H5 variants. Moreover, we observed a reexpression of the GGT mRNAIII species in the C2 Rev7 variant, which has reverted from C2 toward a differentiated hepatocyte phenotype. In the proximal promoter III region, we identified a sequence that strongly enhances transcriptional activity in Fao and C2 Rev7 cells, but not in the dedifferentiated C2 variant. This motif interacts with nuclear proteins belonging to the NF-1 and NF-Y families that govern GGT promoter III expression in differentiated hepatoma cells.

Multiple forms of gamma-glutamyl transpeptidase messenger ribonucleic acid are expressed in the adult rat testis and epididymis.

The expression of gamma-glutamyl transpeptidase (GGT) mRNA in tissues of the adult rat male reproductive tract was examined. Northern blot analysis of total RNA revealed that GGT mRNA expression occurs primarily in the initial segment and caput epididymidis. Multiple GGT mRNAs of varying sizes were detected in the testis and in different regions of the epididymis: testis, 2.4 and 2.8 kb; efferent ducts, 2.2 and 2.5 kb; initial segment, 2.2, 2.4, and 2.5 kb; caput, 2.2, 2.4, and 2.5 kb; corpus, 2.2 and 2.5 kb; cauda, 2.2 and 2.5 kb; ductus deferens, 2.2 and 2.4 kb. Ribonuclease (RNase) H removal of the poly(A) tail from testicular and epididymal GGT mRNA revealed that multiple GGT mRNAs were not generated by differences in the length of the poly(A) tail. Northern blot analysis of poly(A)+ mRNA with four GGT mRNA 5' untranslated region (UTR)-specific cRNA probes showed that the multiple GGT mRNAs expressed in the testis and epididymis were due to differences in the lengths and nucleotide compositions of the 5' UTR. We hypothesize that transcription of multiple GGT mRNAs from different promoters on the single-copy GGT gene is the molecular basis that underlies the region-specific expression of GGT mRNAs along the rat male reproductive tract.

Immunocytochemical localization of gamma-glutamyltranspeptidase, GP-2 and amylase in the rat exocrine pancreas: the concept of zymogen granule membrane recycling after exocytosis.

We localized gamma-glutamyltranspeptidase (GGT) in the rat pancreas by immunocytochemistry using the protein A-gold technique. The enzyme was found in the apical and zymogen granule (ZG) membranes of the pancreatic acinar cell. With ZG at the onset of exocytosis, labeling was seen over membrane, whereas content was unreactive. In the acinar lumen, the enzyme was generally associated with small vesicles previously described as "pancreasomes." This observation corroborates a recent proposal that a membrane-shedding process is associated with exocytosis in the exocrine pancreas. It also implies that some elements of the ZG membrane are not recycled after exocytosis. The cellular distribution of GGT was compared with GP2, another glycoprotein component of the ZG membrane, and differences in localization indicate different fates for these two proteins. Indeed, GP2 shows a strong signal with the basolateral membrane, whereas in the case of GGT the signal is barely detectable. The reverse situation is observed on the apical plasma membrane, GGT producing a much stronger signal than GP2. The failure to detect GGT in lysosomal structures, combined with the fact that some endocytic-like vacuoles in the vicinity of the apical plasma membrane give a positive reaction, supports the view that some GGT molecules are recycled in the ZG membrane after exocytosis. Our observations clearly demonstrate that a fraction of the protein components of the ZG membrane are not recycled after exocytosis, raising new questions regarding the concept of membrane recycling associated with regulated secretion.

Identification of a second promoter which drives the expression of gamma-glutamyl transpeptidase in rat kidney and epididymis.

In rat, gamma-glutamyl transpeptidase (GGT) is encoded by multiple mRNAs (mRNAI, mRNAII, mRNAIII, and mRNAIV) that differ only in their 5' untranslated regions and are transcribed from a single-copy gene. Using oligonucleotides designed from the 5' untranslated sequences of the GGT mRNAII and mRNAIII, we amplified a 3.4-kb genomic sequence which contains the promoter region for mRNAII. The sequence flanking the two initiation start sites for mRNAII contains consensus motifs for several potential regulatory proteins and a TATA-like element at the expected position 26 bp upstream from the predominant start site. The sequence from positions -528 to +72 associated with the chloramphenicol acetyltransferase (CAT) reporter gene drives a promoter activity in LLC-PK1, a pig kidney cell line. Deletion analysis revealed that the region from nucleotides -528 to -322 mediates an activation of the promoter activity, whereas the sequence from -322 to -114 has a negative effect. Furthermore, the structural organization of the 5' end of the GGT gene reveals that the GGT mRNAIII is transcribed from a third promoter located upstream from the promoter II on the GGT gene. By Northern blot analysis, the promoter II was found to be expressed only in the kidney and in the epididymis. We also identified two new mRNA species which are expressed in the H5 hepatoma cells. Therefore, the GGT gene expression reveals a strong tissue- or cell-specific pattern which is based on the transcription of several mRNA species from multiple promoters.

Tissue-specific expression of multiple gamma-glutamyl transpeptidase mRNAs in rat epithelia.

gamma-Glutamyl transpeptidase (GGT) is an enzyme that plays a key role in interorgan glutathione transport. Three mRNAs (mRNAI, mRNAII, and mRNAIII) are known to encode the GGT precursor; they are initiated on three separate promoters on the single GGT gene. In this work, we identified by Northern blot and RNase H analysis a new GGT mRNA (mRNAIV). This mRNA differs from the others in its 5'-noncoding sequence. This mRNA species is the predominant GGT mRNA expressed in HTC hepatoma cells and in the small intestine in which its level increases from the base to the apex of the microvillus. The analysis of the GGT gene expression pattern in kidney, mammary gland, small intestine, liver, preneoplastic liver, and HTC hepatoma cells reveals a strong tissue or cell specificity. The mRNAIII was found in all the tissues and cells; in contrast, the expression of mRNAI, mRNAII, and mRNAIV is limited in normal tissues to the kidney and to the small intestine, the two tissues that display the highest enzyme activity. The synthesis of these three mRNAs is linked to the development of the kidney proximal tubule and to the differentiation of the enterocyte. The tissue and cell specificity of the GGT gene expression is based upon the use of multiple promoters that are controlled independently by specific cell factors.

Organization of the 5' end of the rat gamma-glutamyl transpeptidase gene: structure of a promoter active in the kidney.

Two gamma-glutamyl transpeptidase mRNAs (mRNAI and mRNAII), with alternate 5'-untranslated regions, are expressed in the rat kidney. Oligonucleotides were designed based upon these two alternate 5' sequences and used as primers to amplify GGT genomic DNA sequences. The genomic organization of the mRNAI and mRNAII 5'-untranslated sequences reveals that the mRNAs are encoded from two separate promoters which are 2.1 kbp apart on the single GGT gene. A 2775 base pair genomic sequence, which contains the proximal GGT promoter, was cloned from two overlapping amplified fragments. S1 mapping analysis shows that the kidney GGT mRNAI is transcribed from several start sites on this promoter which displays neither a classical TATA box nor Sp1 binding sites. Chimeric plasmids, including the GGT promoter region for mRNAI, associated with the chloramphenicol acetyltransferase (CAT) reporter gene, were transiently expressed in a kidney (LLCPK) and in a hepatoma (HTC) cell line. A sequence extending 308 bases upstream from the major GGT mRNAI start site drives a promoter activity which is 5-fold higher in LLCPK than in HTC cells and is sufficient to confer cell specificity to the GGT proximal promoter.

Regulation of mouse mammary-gland gamma-glutamyltranspeptidase mRNA during pregnancy, lactation and weaning.

The level of gamma-glutamyltranspeptidase (GGT) activity and of its mRNA were determined in the mouse mammary gland during pregnancy, lactation and weaning. The GGT activity, which is very low in the virgin-mouse mammary gland (5 munits/mg of protein), increases progressively during pregnancy (3-fold), reaches its maximum at the onset of lactation (8-fold) and returns rapidly to basal level at weaning. Although no GGT-specific mRNA is detected in the virgin-mouse mammary gland, a single faint band of 2.2 kb in size is found during pregnancy. During lactation, an additional mRNA of 2.4 kb in size appears, and the level of both mRNAs is higher. This high level of mRNA persists during weaning as well. Southern-blot analysis of mouse mammary-gland DNA provides convincing evidence that there is only one gene which codes for the two mRNAs. The present study provides the first evidence for a physiological regulation of the two GGT mRNAs in the same tissue.

Tissue-specific expression of two gamma-glutamyl transpeptidase mRNAs with alternative 5' ends encoded by a single copy gene in the rat.

Two different cDNAs have been isolated and characterized from a rat kidney cDNA library. The two cDNA sequences are identical in the coding region and in the 144 bases upstream from the initiation codon but have alternate sequences (154 and 138 bases) at their 5' ends. Primer extension analysis on kidney mRNA reveals that both cDNAs are full-length and correspond to two mRNAs of nearly the same size (2142 and 2127 bases). Synthesis of two mRNAs with alternative 5' ends can be explained only by initiation at two separate promoters on the single rat gamma-glutamyl transpeptidase (GGT) gene. The alternate 5' end nucleotide sequences were used as probes to detect the corresponding mRNAs in several rat tissues. In the kidney, the expression of both RNAs was detected by in situ hybridization in the distal part of the proximal convolutions of the renal tubule. Northern blot analysis of kidney mRNAs reveals that the expression of both mRNAs increases from birth to the adult stage. Neither of these two transcripts is expressed in the liver or in seminal vesicles in which a larger mRNA (2.4 kilobase pairs) is transcribed from the same gene. Thus, two GGT mRNAs, initiated on two separate promoters on the single GGT gene, are expressed in the rat in a tissue-specific manner and coordinately regulated.

gamma-Glutamyl transpeptidase: a single copy gene in the rat and a multigene family in the human genome.

gamma-Glutamyl transpeptidase (GGT) genomic sequences were isolated from rat and human libraries using a rat GGT cDNA as a cross-species hybridization probe. Characterization of the human GGT clones by restriction mapping clearly establishes that at least four different GGT genes or pseudogenes are present in the human genome. All the rat genomic clones cover a 12.5-kilobase sequence and exhibit a unique restriction pattern. A precise quantitation of the rat GGT gene copy number by Southern blot analysis demonstrates that this sequence is present as a single copy/rat haploid genome. Therefore, the GGT gene organization is different between rat and human species; this raises the possibility of different regulatory mechanisms in the two species.

Specific modulation by ethanol of the protein synthesis pattern in the C2 rat hepatoma cell line.

The effect of ethanol on protein synthesis in the C2 rat hepatoma cell line was analyzed by two-dimensional gel electrophoresis after the labeling with [35S]methionine of cells that were untreated or had been treated with 180 mM ethanol. In this cell line, this concentration of ethanol is known to induce gamma-glutamyl transpeptidase, a marker of alcoholism in man (Barouki et al., Hepatology 1983; 3: 323-329). In the present work we demonstrate that ethanol, besides causing a slight decrease in overall protein synthesis (less than 25%), primarily regulates the expression of two unique proteins among 1500 labeled products that were analyzed: one of these was induced and did not correspond to gamma-glutamyl transpeptidase, and one was repressed after 20 h of ethanol treatment. We conclude that the set of hepatic proteins altered by ethanol is likely to be very limited in number, which reflects the specificity of alcohol action on protein synthesis in the C2 cell line.