Retinoblastoma protein complexes with C/EBP proteins and activates C/EBP-mediated transcription.

The retinoblastoma protein (RB) recruits histone deacetylase (HDAC) to repress E2F-mediated transactivation that plays a critical role in cell cycle regulation. RB is also involved in activation of expression of a number of tissue specific- and differentiation-related genes. In this study, we examined the mechanism by which RB stimulated the expression of a differentiation-related gene, the surfactant protein D (SP-D), which plays important roles in innate host defense and the regulation of surfactant homeostasis. We demonstrated that RB specifically stimulated the activity of human SP-D gene promoter. The RB family member, p107 but not p130, also increased SP-D promoter activity. Activation by RB was mediated through a NF-IL6 (C/EBP beta) binding motif in the human SP-D promoter, and this sequence specifically bound to C/EBP alpha, C/EBP beta, and C/EBP delta. RB formed stable complexes with all three C/EBP family members. RB small pocket (amino acid residues 379-792), but not the C-pocket (amino acid residues 792-928), was necessary and sufficient for its interaction with C/EBP proteins. Furthermore, we demonstrated that the complexes containing RB and C/EBP proteins directly interacted with C-EBP binding site on DNA. These findings indicate that RB plays a positive, selective, and direct role in the C/EBP-dependent transcriptional regulation of human SP-D expression.

Loss of heterozygosity in epithelial cells obtained by bronchial brushing: clinical utility in lung cancer.

To determine whether loss of heterozygosity (LOH) could be a useful diagnostic test for lung cancer, we evaluated LOH in cells obtained from bronchial brushings. Cells from radiographically normal and abnormal lungs were obtained from 55 patients undergoing diagnostic bronchoscopy. Among 38 patients with lung cancer, LOH was present in at least one chromosomal locus in 79%, whereas cytology was positive for malignant cells in 37%. LOH was not restricted to the airway containing the tumor; fifty-three percent of the cancer patients had LOH in the contralateral lung, as did 59% of patients without lung cancer. There was an association between the extent of LOH and proximity to the cancer. The LOH score, which combined measures of fractional allelic loss and percentage of cells with allelic loss, was greater in subjects with positive cytology and on the side of the tumor. A LOH score >10 was positive in 58% of tumor-bearing lungs, in 13% of the contralateral lungs in cancer patients, and in no patients without cancer. Our results suggest that extensive and widespread allelic loss, as indicated by a high LOH score, may be diagnostic of lung cancer. Additional studies will be needed to clarify the clinical potential of using bronchial epithelial cell LOH as a biomarker and diagnostic test for lung cancer.

FGF-2 induces surfactant protein gene expression in foetal rat lung epithelial cells through a MAPK-independent pathway.

Fibroblast growth factors (FGFs) play important roles in diverse aspects of animal development including mammalian lung epithelial cell proliferation, differentiation, and branching morphogenesis. We developed an in vitro lung epithelial cell culture system to study functions and mechanisms of FGFs in regulating growth and differentiation of primary foetal rat lung epithelial cells. In comparison with other growth factors such as IGF-I, EGF, and HGF, FGFs were the most potent mitogens in stimulating lung epithelial cell proliferation. In the presence of FGF-1, 2, or 7, the primary lung epithelial cells could be propagated for generations and grown for more than two mo in vitro. Among the three FGFs tested, FGF-7 showed the strongest stimulation in cell growth. FGF-2, on the other hand, is the most effective inducer of lung epithelial cell-specific surfactant protein gene expression (SP-A, -B, and -C). FGF-2 upregulated SP-C expression in a dose-dependent manner. More interestingly, the induction of surfactant protein gene expression by FGF-2 appeared to be independent of MAPK pathway, since the SP-C expression was not inhibited but rather augmented by MEK1 inhibitor which inhibited MAPK activation and cell proliferation. Similar effects were observed for the expressions of surfactant protein genes SP-A and SP-B. In contrast to MAPK, FGF-2-induced SP-C expression was partially inhibited by PI 3-kinase inhibitor wortmannin. These data suggest dynamic roles and complex signalling mechanisms of FGFs in regulating lung epithelial cell proliferation and differentiation. While a MAPK-dependent pathway is essential for all three FGFs to stimulate cell proliferation, a MAPK-independent pathway may be responsible for the FGF-2-induced surfactant protein gene expression. PI 3-kinase may play an important role in mediating FGF-2-induced lung epithelial cell differentiation during development.

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.

FGF-1 and FGF-7 induce distinct patterns of growth and differentiation in embryonic lung epithelium.

Fibroblast growth factors (FGFs) and receptors (FGFRs) are expressed in the developing lung and appear to be major regulators of lung growth and differentiation. By using mesenchyme-free lung epithelial cultures we show that FGF-1 (aFGF) and FGF-7 (KGF) produce different effects in the developing lung. FGF-1 stimulates epithelial proliferation that results in bud formation (branching), while FGF-7 promotes epithelial proliferation that leads to formation of cyst-like structures. In addition, FGF-7 stimulates epithelial differentiation, stimulating expression of SP-A and SP-B mRNA throughout the explant, and inducing formation of focal areas of highly differentiated cells. The FGF-1 effects on differentiation are limited to induction of surfactant protein SP-B mRNA at the tips of the explant. The FGF-induced patterns of growth appear to correlate with the distribution of epithelial FGFRs mRNAs; FGFR-2 IIIb (KGFR) is diffusely expressed in the day 11 lung epithelium, while FGFR-4 appears in distal but not in proximal sites. We propose that cyst-like structures may result from FGF-7 binding to the uniformly distributed FGFR-2-IIIb. Lung bud formation may be regulated by FGF-1 and/or other ligands binding to FGFR-2 and a distally located FGFR, such as FGFR-4, leading to an increasing binding and activation of FGFRs at the tips of the explant. Thus, in the embryonic lung epithelium, growth effects of FGFs appear to be dependent on location of FGFRs, while effects on differentiation are ligand-dependent.

Epithelial marker genes are expressed in cultured embryonic rat lung and in vivo with similar spatial and temporal patterns.

Explants of embryonic lung are often used to characterize lung growth, bronchial tree pattern, and cell differentiation. Most investigators culture lungs for 3-7 days in defined media lacking, e.g., added growth factors or hormones. If growth and differentiation are comparable to that in vivo, these cultures show considerable promise for identifying developmental regulatory molecules and target genes, and for elucidating molecular responses. We used in situ hybridization and RT-PCR to compare times and sites of expression of mRNAs of six epithelial genes in cultured and uncultured fetal rat lungs. These genes, expressed in distal lung of adult rats, are surfactant proteins (SP) A, B, and C; LAR, a receptor-type tyrosine phosphatase; Clara cell secretory protein (CC10, CCSP); and T1alpha. SP-A, SF-B, LAR, and CC10 are expressed by both Clara and Type II cells in adult animals. SP-C and T1alpha are unique markers for Type II and Type I cells, respectively. SP-C, LAR, and T1alpha are expressed before the lung is explanted (Day 13.5); SP-A, -B, and CC10 mRNAs are first detected later. The onset of expression is similar in vivo and in vitro. Although the patterns of expression differ for each mRNA, their sites of expression in culture match those in vivo relative to the bronchial tree. The explanted embryonic lung appears to be an excellent experimental model.

Retinoic acid alters the expression of pattern-related genes in the developing rat lung.

Exogenous retinoids alter pattern formation and differentiation in many developing systems, such as limb, vertebrae, and central nervous system. Many of these effects are mediated by changes in expression of patterning genes such as Hox genes and Sonic hedgehog. We have previously shown that exogenous retinoic acid, administered to the embryonic rat lung in culture alters the structural pattern of the developing lung, suppressing formation of distal lung and favoring growth of proximal tubules. To determine whether these retinoic acid-induced changes in lung development were linked to alterations in pattern-related genes, we characterized the expression of Hoxa-2, Hoxb-6, and Sonic hedgehog mRNAs in vivo and in vitro, with or without 10(-5)M retinoic acid, by in situ hybridization and quantitative polymerase chain reaction. Each of these genes demonstrated unique timing and distribution of expression that was similar in vivo and in control cultured embryonic lungs. Hoxb-6 and Sonic hedgehog mRNAs both decreased during lung development in vivo or in vitro. From the patterns of mRNA expression we propose that Hoxb-6 is involved in distal airway branching while Hoxa-2 is involved in differentiation of proximal mesenchymal derivatives and vasculogenesis in the lung. RA upregulated all three genes, changing their developmental pattern of distribution and preventing the developmental decrease in Sonic hedgehog expression. We propose that RA acts to maintain high levels of expression of these and likely other pattern-related genes in a fashion that is characteristic of the immature lung, promoting continued formation of proximal lung structures and preventing formation of typical distal lung structures of the mature lung.

Type I receptor serine-threonine kinase preferentially expressed in pulmonary blood vessels.

Type II and type I receptor serine-threonine kinases (RSTK) are important components of the transmembrane signaling machinery that allow cells to respond to the transforming growth factor-beta (TGF-beta) superfamily of cytokines. We have cloned from rat lung and report here a 3,935-base pair (bp) cDNA encoding a type I RSTK previously identified as R-3 (rat) or ALK-1 (human). Northern blot analysis reveals that the R-3 mRNA is more abundant in lung than in other adult rat tissues. With the use of in situ hybridization, the R-3 transcripts are found exclusively in the pulmonary vessels of all sizes, as well as in aorta, vena cava, and certain blood vessels of kidney, spleen, heart and intestine. In most blood vessels, a higher level of gene expression is found in endothelium than in adjacent smooth muscle. The R-3 transcripts are also found in splenic macrophages, as well as within cells of marginal zone of the splenic lymphoid tissue. In fetal rat lung, the expression of R-3 transcripts differs from the expression patterns of two other type 1 RSTK. The R-3 is expressed in vessels; the activin type IB receptor (R-2) is preferentially expressed in putative developing airways, whereas the TGF-beta type I receptor (R-4) transcripts appear to be ubiquitous. Our data suggest that in vivo R-3 may propagate signaling of TGF-beta in selected cell types. The differential expression of multiple type I receptors within different cell lineages may therefore define cell specific responses to TGF-beta.

Two closely related receptor-type tyrosine phosphatases are differentially expressed during rat lung development.

Transmembrane protein tyrosine phosphatases (PTPases) comprise a newly identified class of receptor-like molecules. In most cases their ligands and the substrates they dephosphorylate are not known. In order to begin to explore the functions of the PTPases in cell physiology and in mammalian development, we examined the expression patterns of two closely related receptor-type tyrosine phosphatase genes, namely LAR and PTP delta, in fetal rat lung and in selected adult rat tissues. In the lung, in situ hybridization and immunohistochemistry show that the LAR mRNA and protein are expressed exclusively in the epithelium. In the early embryonic or fetal lung (day 13 to 18) LAR is expressed by all of the epithelial cells of the forming bronchial tree. This widespread pattern of expression is lost later in fetal life (day 21) as the lung matures and acquires the morphologic and biochemical features of the adult organ. LAR gene expression is then confined to two epithelial progenitor cells of the distal airways, namely the bronchiolar Clara cell and the alveolar type II cell. The LAR gene products were also found abundantly expressed in epithelial progenitor cells of adult esophagus, skin, and small intestine, all of which are continuously renewing epithelia. The rat PTP delta gene, on the other hand, is specifically expressed in the mesenchyme of the developing lung. The level of the PTP delta mRNA decreases as the lung matures. These results suggest that the two closely related receptor-type tyrosine phosphatases are differentially expressed in a tissue-specific fashion. They are expressed mostly in proliferating cells or in cells which have potential to proliferate.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of insulin-like growth factor receptors 1 and 2 in the developing lung and their relation to epithelial cell differentiation.

Insulin-like growth factors (IGFs) and their receptors have been implicated as regulators of cell differentiation and cell proliferation in a number of systems and have been shown to play an important role in embryonic development. In this study we examined expression of mRNA for IGF-I and IGF-II, IGF binding protein 2 (IGFBP-2), and IGF receptors 1 (IGFR-1) and 2 (IGFR-2) during fetal lung development and in early postnatal and adult lungs by the polymerase chain reaction (PCR). IGF-I mRNA was found in embryonic and postnatal lungs at all ages as was IGFBP-2, whereas IGF-II mRNA was present only in prenatal lungs. IGFR-1 was present in all but the adult lungs. Lung epithelial cells expressed IGFR-1 at 14 days' gestation but not at 18 days' gestation as measured by PCR and in situ hybridization. Alveolar epithelial cells re-expressed IGFR-1 mRNA in the early postnatal period but not in the adult lung. IGFR-2 was expressed by PCR and in situ hybridization in 14-day embryonic epithelium, was not present at 18 days or at birth, but was re-expressed at high levels in the early postnatal alveolar wall. Immunocytochemical localization of IGFR-2 confirmed its absence in the late fetal and newborn lung. It reappeared in alveoli, exclusively in type 1 cells, in early postnatal and adult lungs. These studies demonstrate the stage- and cell-specific appearance of IGF receptors in the developing and postnatal lung. They also establish IGFR-2 as a marker of the mature alveolar type 1 cell.(ABSTRACT TRUNCATED AT 250 WORDS)

Retinoic acid induces changes in the pattern of airway branching and alters epithelial cell differentiation in the developing lung in vitro.

Retinoids have been shown to influence pattern formation during development and regeneration in numerous systems such as limbs, vertebrae, and neural tube although there is little information about the effects of retinoids on pattern formation in visceral organs. We investigated the effects of exogenous retinoic acid on the in vitro pattern of airway branching and on lung epithelial cell differentiation. Histology, [3H]thymidine autoradiographies and reverse transcriptase/polymerase chain reaction (RT/PCR) amplification were used to assess the effects of retinoids and the expression of lung epithelial markers of differentiation. We found that retinoic acid interferes, in a dose-dependent fashion, with the expression of epithelial genes that are found in distal segments of the fetal lung (surfactant-associated proteins SP-A, SP-B, and SP-C). At high concentrations, retinoic acid (RA) dramatically altered the developmental pattern of the lung, favoring growth of structures that resemble proximal airways and concomitantly suppressing distal epithelial buds. We hypothesize that this in vitro "proximalizing" effect on the developing lung may be related to alterations in the expression of pattern-related genes.

Cloning, characterization, and development expression of a rat lung alveolar type I cell gene in embryonic endodermal and neural derivatives.

We report here the identification and characterization of a novel gene, T1 alpha, expressed in high abundance in adult rat lung, fetal lung, and early fetal brain. T1 alpha was identified by a monoclonal antibody previously shown to be specific for an antigen expressed by alveolar epithelial type I cells. The cDNA for T1 alpha is 1.85 kb and identifies a single mRNA species of the same size on Northern blots of adult rat lung. The longest open reading frame of the cDNA is 498 bases which would encode a protein of approximately 18 kDa. The protein has a putative membrane spanning domain near the C-terminus but lacks consensus sequences for N-glycosylation. Northern blots and RT-PCR show high expression of T1 alpha in adult lung, with marginally detectable expression in adult brain, intestine, and kidney. RT-PCR analysis shows expression of T1 alpha in freshly isolated type I cells (50-60% purity) but not in highly purified type II cells or other lung cells. We believe therefore that T1 alpha is primarily if not uniquely expressed in alveolar type I cells in the adult rat. Polyclonal antisera against a 16-amino-acid peptide identified in the deduced sequence reacts with the apical membranes of adult type I cells in lung tissue sections but does not label other cell types. The above antiserum as well as the original monoclonal antibody recognize a single approximately 18-kDa protein derived from bacterial expression of a construct containing the T1 alpha open reading frame. By RT-PCR T1 alpha is detected in rat lung from Day 13.5 onward, but is detected by in situ hybridization earlier in lung, brain and neural derivatives, and foregut. Expression is down-regulated in all but lung tissues as development proceeds.

Structural characterization and specificity of expression of E2F-5: a new member of the E2F family of transcription factors.

Members of the E2F gene family are transcription factors that have been implicated in the control of genes essential for cell cycle progression. Regulation of E2F function is finely tuned by the retinoblastoma tumor suppressor gene product and a small family of related "pocket proteins," with the participation of a number of cyclins and cyclin-dependent kinases. Perturbations of this regulatory network can lead to oncogenic transformation and, in certain systems, to the loss of the ability to maintain terminal differentiation. We describe here the cloning, structural characterization, and tissue expression pattern of a new member of the E2F family, E2F-5. We show that this protein is highly conserved between human and rat but exhibits considerable divergence from E2F-1, E2F-2, or E2F3. Together with the recently reported E2F-4, E2F-5 defines a new branch of the E2F family. The distribution of E2F-5 mRNA among adult rat tissues and the temporal pattern of its expression during the cell cycle of vascular smooth muscle cells are distinctly different from that of E2F-1. The structural divergence between the two branches of the E2F family may thus reflect participation in different regulatory networks.

Insulin-like growth factors, their binding proteins, and transforming growth factor-beta 1 in oxidant-arrested lung alveolar epithelial cells.

The epithelium of the pulmonary alveolus is a major target for oxidant injury, and its proper repair following injury is dependent on the proliferative response of its stem cells, the type 2 cells. We have recently shown that hyperoxia arrests proliferation of an immortalized type 2 cell line (SV40T-T2) and that expression of several growth-related genes, normally induced near the G1/S and boundary was altered with a block of translation of their mRNA. In the present study we examined the possible role of the insulin-like growth factor (IGF) system and of transforming growth factor-beta 1 (TGF-beta 1) in the arrest of proliferation induced by hyperoxia. We show that IGF-binding protein 2 (IGFBP-2) accumulates to higher levels in culture medium of SV40T-T2 cells whose proliferation has been arrested by hyperoxia. This proliferation arrest is associated with increased expression of IGFBP-2 mRNA and with induction of type 2 IGF receptor and IGF-II mRNAs. When O2-arrested cells were allowed to resume proliferation in normoxia, the level of expression of these genes rapidly decreased to control levels. We also, found that TGF-beta 1 was induced by O2 exposure, that TGF-beta 1 inhibited SV40T-T2 proliferation, and that TGF-beta 1 itself was a potent stimulator of IGFBP-2 expression. These studies suggest a regulatory link between components of the IGF system and TGF-beta 1 in hyperoxic control of cell proliferation of alveolar epithelial cells.

Type I collagen formation in rat type II alveolar cells immortalised by viral gene products.

BACKGROUND: Alveolar type II (T2) cells synthesise matrix proteins such as type IV collagen and fibronectin. In contrast, a fetal rat T2 cell line has been shown to synthesise type I and III collagen as well as type IV collagen. To study regulation of collagen production in T2 cells, neonatal T2 cells immortalised by adenoviral 12SE1A gene transfer were used. It was previously reported that this immortalised cell line (E1A-T2) retains epithelial features such as tight junctions and cytokeratins but also expresses mesenchymal features such as vimentin. METHODS: Collagen production was examined in E1A-T2 and primary neonatal T2 cells using polyacrylamide gel electrophoresis. Electron microscopy was used to examine collagen deposition in E1A-T2 cell culture. To define the mechanism by which alpha 1(I) type I collagen gene expression was activated in E1A-T2 cells, a deletional analysis of alpha 1(I) promoter constructs linked to the bacterial chloramphenicol acetyltransferase gene was performed. RESULTS: E1A-T2 cells produced large amounts of type I collagen with a predominance of alpha 1(I) homotrimers; alpha 2(I) peptides were detected only in the cell layer. In contrast, primary neonatal rat T2 cell cultures produced a trace amount of type I collagen. Production of alpha 1(I) peptide chains (per microgram DNA) in E1A-T2 cell cultures was 30 times higher than that observed in primary neonatal T2 cell cultures. Electron microscopy showed deposition of type I collagen fibrils in the extracellular matrix of E1A-T2 cell cultures. Transfection studies suggested at least two cis-acting elements which mediate increased alpha 1(I) gene expression in E1A-T2 cells. CONCLUSIONS: These studies indicate that the E1A-T2 cell line may be useful for studying type I collagen gene regulation in alveolar T2 cells. These findings also raise the possibility that viral activation of type I collagen genes in alveolar epithelium may be involved in certain forms of pulmonary fibrosis.

Effect of floating a gel matrix on mucin release in cultured airway epithelial cells.

Confluent cultures of primary hamster tracheal surface epithelial (HTSE) cells grown on a thick collagen gel are highly enriched with secretory cells and constitutively release mucins. In the present experiment, we examined the possible effect of mechanical strain of cultured HTSE cells on the release of mucin. The mechanical strain of cells was accomplished by several methods: 1) by floating the gel from the culture dish by rimming; 2) by treatment with EGTA which interrupts intercellular tight junctions; 3) by treatment with collagenase which disrupts the cell-matrix adhesion; and 4) by mechanically flexing the collagen gel matrix. All these conditions caused increases of mucin release without damage on the plasma membrane. We conclude that a number of mechanical strains which might alter cell shape can stimulate mucin release from cultured HTSE cells. Such a mechanism might be operative in the physiological regulation of airway goblet cell mucin secretion where mechanical strains may be induced on epithelial cells by underlying smooth muscles.

Inhibition of lung epithelial cell proliferation by hyperoxia. Posttranscriptional regulation of proliferation-related genes.

The alveolar surface of the lung is a major target for oxidant injury. After injury, repair of the alveolar epithelium is dependent on the ability of epithelial type 2 (T2) cells to proliferate. The regulation of T2 cell proliferation and the effect of reactive oxygen (O2) species on this lung cell proliferation have not been well defined. To investigate this process we focused on the regulation of two late cell cycle genes, histone and thymidine kinase, in T2 cells and fibroblasts exposed in vitro to varying periods of hyperoxia (95% O2). Hyperoxia for 24 to 48 h arrested cell proliferation in a SV40T-immortalized T2 cell line we have developed and in primary and SV40T-immortalized lung fibroblasts. Despite the cessation of proliferation, histone and TK mRNA continued to be expressed at high levels; mRNA half-lives were markedly prolonged but neither protein was translated. Thus proliferation arrest induced by hyperoxia was associated with posttranscriptional control of at least two late cell cycle-related genes. This form of proliferation arrest is also seen when primary and SV40T-T2 cells but not fibroblasts are serum deprived, suggesting that T2 cells in vitro may be uniquely sensitive to alterations in their redox state and that these alterations in turn affect translational control of a subset of proliferation-related genes.

A rat alveolar type II cell line developed by adenovirus 12SE1A gene transfer.

The regulation of pulmonary alveolar type II cell proliferation and differentiation is poorly understood and has been difficult to study, in part due to lack of proliferation, cellular heterogeneity, and phenotypic instability of type II cells in primary culture. To develop a stable population of homogeneous cells capable of proliferation, we transfected type II cells isolated from the lungs of neonatal rats with an immortalizing oncogene, adenovirus 12SE1A, using a retroviral vector. Individual clones were isolated, screened for cytokeratin expression, and further characterized. One of the 12SE1A expressing clones, E1A-T2, has epithelial features such as cytokeratin expression and tight junctions, and coexpresses vimentin. E1A-T2 rapidly proliferate when grown in 10% fetal bovine serum, and slow their growth at confluence. A labeling index of greater than 90% during a 24-h pulse of [3H]thymidine reflects a uniform population of proliferating cells. E1A-T2 can be grown and passed in 0.4% fetal bovine serum, suggesting the production of an autocrine growth factor(s). The type II cell Maclura pomifera agglutinin (MPA)-binding glycoprotein, MPA-gp200, appears to be expressed in an incompletely glycosylated form, whereas other features of differentiated type II cells, such as lamellar bodies, surfactant protein A, and a high percentage of saturated phosphatidylcholine, are absent. Homogeneous, clonally derived type II cell lines, such as E1A-T2 may retain sufficient type II cell features of interest to test new hypotheses relating to cell proliferation and differentiation otherwise not feasible using primary cultures of type II cells.

SV40T-immortalized lung alveolar epithelial cells display post-transcriptional regulation of proliferation-related genes.

To study the regulation of proliferation of lung alveolar epithelial type 2 cells, we have established a cell line derived from neonatal type 2 cells by transfection with the SV40 large T antigen gene. We find that this cell line, designated SV40-T2, displays the same post-transcriptional control of expression of proliferation-related genes, including c-myc, ornithine decarboxylase, thymidine kinase, and histone, that we have previously described in primary isolates of type 2 cells (Clement et al., Proc. Natl. Acad. Sci. USA 87, 318-322, 1990). Both proliferating and nonproliferating SV40-T2 cells express these genes at high levels, but their translation products are only detected in proliferating cells. Using the histone gene as an example, we have found that regulation of expression occurs at the level of transcription and of mRNA turnover, as previously described in other mammalian systems. However, in addition, regulation of expression also occurs at the level of translation of the histone mRNA, because its protein product is not detectable in nonproliferating SV40-T2 cells. We have analyzed the steps which are potentially involved in this translational regulation of histone gene expression in SV40-T2 cells. In both proliferating and nonproliferating cells, histone mRNA was found to be efficiently transported from the nucleus to the cytoplasm and to associate with the translationally active heavy polysomal fractions. These results indicate that control of histone gene expression (and perhaps that of other proliferation-related genes) in lung epithelial cells may involve either rapid and selective degradation of histone protein or binding factor(s) which modulate translational efficiency of histone mRNA.