gamma-Glutamyl transferase (GGT) deficiency in the GGTenu1 mouse results from a single point mutation that leads to a stop codon in the first coding exon of GGT mRNA.

GGTenul, a recently described genetic murine model of gamma-glutamyl transferase (GGT) deficiency, was induced by the point mutagen N-ethyl-N-nitrosourea and is inherited as an autosomal recessive trait. The phenotype of systemic GGT deficiency suggested a mutation site within the cDNA coding region which is common in all GGT transcripts. To identify this site, total lung and kidney RNA was isolated from normal and mutant mice, amplified by RT-PCR using GGT-specific primers, cloned as two overlapping approximately 1 kb GGT cDNA fragments, sequenced and compared with that in the literature. A single base pair substitution was identified in the coding region at position 237, where thymidine became adenine, and this mutation replaced a leucine codon, TTG, with a termination codon, TAG. This mutation site was confirmed in mutant genomic DNA by PCR using primers that flanked the predicted site and spanned the intron between the common GGT non-coding exon and the first GGT coding exon. This PCR product was sequenced directly with the secondary 3' PCR primer, the mutation site identified and the protocol then utilized to genotype animals. In addition to this mutation, the steady-state level of GGT mRNA in mutant kidney is reduced 3-fold compared with the control. Heterodimeric GGT protein is not detectable by western blot in either whole kidney homogenate or a microsomal membrane fraction. The steady-state mRNA level of gamma-glutatmyl cysteinyl synthetase was unchanged in mutant mice compared with normal, but that of heme oxygenase-1 and Cu,Zn-SOD was induced 4- and 3-fold, respectively. Hence, the GGTenul mouse model of GGT deficiency results from a single point mutation in the first coding exon of GGT mRNA and the resulting impairment in glutathione turnover induces oxidative stress in the kidney.

The Bax inhibitor-1 gene is differentially regulated in adult testis and developing lung by two alternative TATA-less promoters.

We identified Bax inhibitor-1, BI-1, as a developmentally regulated gene product in perinatal lung using suppressive subtractive hybridization. BI-1 is a novel suppressor of apoptosis that was previously cloned as testis-enhanced gene transcript (TEGT). However, sequence analysis of lung BI-1 revealed unique nucleotides starting 29 bases upstream of the ATG initiation codon and extending to the 5' end of lung-derived BI-1 cDNA compared to the original transcript from the testis. Cloning and sequencing of the upstream region of the BI-1 gene revealed that these unique sequences originated from two alternative first exons, located in tandem and separated by approximately 600 bases. Neither was preceded by a TATA box in the usual position, and S1 nuclease mapping at each exon 1 revealed multiple transcription start points with a major site being overlapped by a consensus initiator element. Promoter activity from each region was documented by transient transfection analysis in vitro using DNA sequences ligated to a reporter gene. The proximal promoter, P1, may exhibit cell type-specific differences in fibroblasts versus epithelia, whereas the distal promoter, P2, may exhibit species-specific differences in rat versus human cells. RT-PCR analysis for expression in adult tissues using exon 1-specific 5' primers and common 3' primers revealed that P1 is tissue-specific; P2 is ubiquitously active. The developmental regulation of BI-1 in the late fetal and early postnatal lung is specific for P2, indicating that these two TATA-less promoters are differentially regulated in adult testis and developing lung. Since Bax inhibitor-1 functions as a suppressor of apoptosis, its expression could provide a survival advantage for select cell populations during the peak period of apoptosis that occurs at birth.

Atrial natriuretic peptide modulates alveolar type 2 cell adenylyl and guanylyl cyclases and inhibits surfactant secretion.

Alveolar epithelial type 2 (T2) cells isolated from the lungs of adult rats responded to exogenous atrial natriuretic peptide (ANP) by two signalling mechanisms. First, ANP induced a dose-dependent reduction of ligand-stimulated adenylyl cyclase activity and cAMP accumulation. This effect was inhibited by the addition of GDPbetaS or by pretreatment with pertussis toxin (PT), consistent with mediation by a Gi protein(s). PT-catalyzed [32P]ADP-ribosylation, immunoblots with specific antisera, and Northern blot analysis demonstrated that T2 cells contain the G-proteins Gi2 and Gi3 which could transduce this signal. ANP also promoted PT-insensitive, dose-dependent accumulation of cGMP, consistent with activation of a receptor guanylyl cyclase. Isoproterenol-stimulated phosphatidylcholine secretion was markedly attenuated by ANP, and this effect was inhibited by PT pretreatment, consistent with mediation by a Gi protein(s). These data indicate that in addition to the lung being a major clearance organ for circulating ANP, lung parenchymal cells are targets of ANP action.

Ontogeny of gamma-glutamyltransferase in the rat lung.

gamma-Glutamyltransferase (gamma-GT) is a key enzyme in the metabolism of glutathione and glutathione-substituted molecules. The gamma-GT gene is expressed in two epithelial cells of the adult lung, the bronchiolar Clara cell and the alveolar type II cell. Because pulmonary glutathione metabolism may be important in the perinatal period, we studied gamma-GT ontogeny in the developing rat lung. In the late fetal and early postnatal lung, gamma-GT mRNA was below detectable limits on Northern blots. Pulmonary gamma-GT protein and enzyme activity were present at low levels after fetal day 18. gamma-GT protein appeared as a high-molecular-mass band (>95 kDa), with small amounts of enzymatically active gamma-GT heterodimer. Between the 2nd and 3rd postnatal wk, pulmonary gamma-GT mRNA expression increased in association with an increase in gamma-GT protein and enzyme activity that reached adult lung levels. At this time, gamma-GT protein appeared predominantly in the heterodimeric form with small amounts of the >95-kDa protein. Immunocytochemistry revealed that, in the fetal and early postnatal lung, gamma-GT was expressed only in the alveolar type II cell, whereas the Clara cell became the major site of gamma-GT mRNA and protein expression by 2-3 wk and in the adult. Type II cells isolated from the fetal lung express gamma-GT mRNA and synthesize the >95-kDa form of gamma-GT in excess of the heterodimer. These studies demonstrate that the alveolar type II cell is the only cell producing gamma-GT in the newborn lung and that it synthesizes a form of gamma-GT that appears to differ from that produced at a later time point by the Clara cell.

Nitrogen dioxide exposure activates gamma-glutamyl transferase gene expression in rat lung.

Exposure to nitrogen dioxide (NO2) has been shown to activate glutathione metabolism in lung and lung lavage. Since GGT is a key enzyme in glutathione metabolism and we have previously characterized GGT expression in distal lung epithelium and in lung surfactant, we examined the NO2 exposed lung for induction of gamma-glutamyl transferase (GGT) mRNA, protein, and enzyme activity. We found that the GGT gene product is induced in lung by NO2. The GGT mRNA level in lung increases 2-fold within 6 hr and 3-fold after 24 hr of exposure to this oxidant gas, and this 3-fold elevation persists even after 14 days of exposure. The pattern of GGT mRNA expression switches from the single GGT mRNA III transcript in the normal lung to the dual expression of GGT mRNA I and mRNA III. Enzyme activity in whole lung increases 1.6- to 2.5-fold while extracellular surfactant-associated GGT activity accumulates 5.5-fold and GGT protein accumulates in lung surfactant. Induction of GGT mRNA and protein is evident in cells of the bronchioles by in situ hybridization and immunolocalization, respectively. In contrast, alveolar type 2 cells lack an in situ hybridization signal and exhibit a reduction in the intensity of immunostaining with prolonged exposure. Our studies show that NO2 induces GGT mRNA expression, including GGT mRNA1, in lung and GGT protein and enzyme activity in lung and lung lavage in response to the oxidative stress of NO2 inhalation.

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.

Synthesis and release of amphipathic gamma-glutamyl transferase by the pulmonary alveolar type 2 cell. Its redistribution throughout the gas exchange portion of the lung indicates a new role for surfactant.

gamma-Glutamyl transferase (gamma-GT) catalyzes a transpeptidation reaction which is involved in the metabolism of glutathione. Glutathione is abundant within the epithelial lining fluid of the lung. However, little is known about gamma-GT expression in the epithelial cells of the lung alveolus. Herein we show that the pulmonary alveolar epithelial type 2 cell expresses the gene for gamma-GT. We were unable to detect expression in the pulmonary alveolar epithelial type 1 cell or in the pulmonary alveolar macrophage. gamma-GT expression in the pulmonary alveolar epithelial type 2 cell is via mRNA III, a transcript that was initially cloned from the liver. This cell synthesizes gamma-GT protein and releases enzyme activity into a surfactant-associated pool within the lung alveolus. The specific activity of this surfactant-associated enzyme is almost 10-fold higher than that of whole lung. This activity results from amphipathic gamma-GT since it partitions with lung surfactant phospholipid and with the detergent phase of Triton X-114. Activity can be dissociated from each by papain proteolysis. These results demonstrate that gamma-GT is expressed in the differentiated pulmonary alveolar epithelial type 2 cell and that amphipathic gamma-GT protein is released by this cell along with lung surfactant. These results suggest that surfactant may serve an expanded role in lung cell biology as the vehicle for the redistribution of amphipathic signal anchored proteins throughout the gas exchange surface of the lung.