The lung tumor promoter, butylated hydroxytoluene (BHT), causes chronic inflammation in promotion-sensitive BALB/cByJ mice but not in promotion-resistant CXB4 mice

An inflammatory response accompanies the reversible pneumotoxicity caused by butylated hydroxytoluene (BHT) administration to mice. Lung tumor formation is promoted by BHT administration following an initiating agent in BALB/cByJ mice, but not in CXB4 mice. To assess the contribution of inflammation to this differential susceptibility, we quantitatively characterized inflammation after one 150 mg/kg body weight, followed by three weekly 200 mg/kg ip injections of BHT into male mice of both strains. This examination included inflammatory cell infiltrate and protein contents in bronchoalveolar lavage (BAL) fluid, cyclooxygenase (COX)-1 and COX-2 expression in lung extracts, and PGE(2) and PGI(2) production by isolated bronchiolar Clara cells. BAL macrophage and lymphocyte numbers increased in BALB mice (P<0.0007 and 0.02, respectively), as did BAL protein content (P<0.05), COX-1 and COX-2 expression (P<0.05 for each), and PGI(2) production (P<0.05); conversely, these indices were not perturbed by BHT in CXB4 mice. BALB mice fed aspirin (400 mg/kg of chow) for two weeks prior to BHT treatment had reduced inflammatory cell infiltration. Our results support a hypothesis that resistance to BHT-induced inflammation in CXB4 mice accounts, at least in part, for the lack of effect of BHT on lung tumor multiplicity in this strain.

Cyclin D1 as a proliferative marker regulating retinoblastoma phosphorylation in mouse lung epithelial cells

Elevations in cyclin D1 content increase the phosphorylation status of retinoblastoma (Rb) protein to encourage cell cycle transit. We sought to determine if cyclin D1 content could be used as an index of cell proliferation in mouse lung epithelia following growth manipulations in vitro and in vivo. Rb protein concentration was high in 82-132 and LM2, two fast-growing neoplastic mouse lung epithelial cell lines. The hyperphosphorylated form of Rb predominated in these two cell lines, while Rb in slower-growing cell lines was predominantly hypophosphorylated. Consistent with this, more cyclin D1 protein was expressed in the fast-growing cell lines than in slower-growing cells. We therefore tested whether cyclin D1 content varied with growth status. The amount of cyclin D1 decreased upon serum removal coincident with growth inhibition and then increased upon serum re-addition which stimulated resumption of proliferation. This correlation between cyclin D1 content and growth status also occurred in vivo. Cyclin D1 content increased when lungs underwent compensatory hyperplasia following damage caused by butylated hydroxytoluene administration to mice and in lung tumor extracts as compared with extracts prepared from uninvolved tissue or control lungs. We conclude that elevated cyclin D1 levels account, at least in part, for the hyperphosphorylation of Rb in neoplastic lung cells, and are associated with enhanced lung growth in vitro and in vivo.

Primary lung tumors in mice as an aid for understanding, preventing, and treating human adenocarcinoma of the lung

Primary lung tumors in mice have morphologic, histogenic, and molecular features similar to human lung adenocarcinoma, and in particular, the bronchiolo-alveolar carcinoma subtype. Because of this, and because of the genetic homology between man and mouse and the ease of genetic manipulations in mice, this model system is receiving intense research attention. This review is intended to be informative to clinical investigators, and describes features of this model, how it is being used for translational research, and points out additional avenues of study that could have practical benefits, such as application for identifying novel therapeutic strategies.

Regulation of lung epithelial cell morphology by cAMP-dependent protein kinase type I isozyme

Cell shape is mediated in part by the actin cytoskeleton and the actin-binding protein vinculin. These proteins in turn are regulated by protein phosphorylation. We assessed the contribution of cAMP-dependent protein kinase A isozyme I (PKA I) to lung epithelial morphology using the E10/E9 sibling cell lines. PKA I concentration is high in flattened, nontumorigenic E10 cells but low in their round E9 transformants. PKA I activity was lowered in E10 cells by stable transfection with a dominant negative RIα mutant of the PKA I regulatory subunit and was raised in E9 cells by stable transfection with a wild-type Cα catalytic subunit construct. Reciprocal changes in morphology ensued. E10 cells became rounder and grew in colonies, their actin microfilaments were disrupted, and vinculin localization at cell-cell junctions was diminished. The converse occurred in E9 cells on elevating their PKA I content. Demonstration that PKA I is responsible for the dichotomy in these cellular behaviors suggests that manipulating PKA I concentrations in lung cancer would provide useful adjuvant therapy.

Defective gap junctional intercellular communication in lung cancer: loss of an important mediator of tissue homeostasis and phenotypic regulation

Gap junctions provide direct pathways for the exchange of molecules and ions between neighboring cells, a process known as gap junctional intercellular communication (GJIC). This GJIC is important for homeostasis and regulation of mitosis, differentiation, and apoptosis. Gap junctions are present in lung airway and alveolar epithelial cells and, in addition to the above roles, might coordinate ciliary beating and surfactant secretion. GJIC is decreased in human and mouse lung carcinoma cells because of reduced expression of the gap junction protein, connexin43 (Cx43), and defects in signal transduction pathways that mediate Cx43 function. This reduced GJIC is important in the behavior of lung carcinoma cells because forced expression of Cx43 in lung carcinoma cells inhibits their growth and tumorigenicity. In this report, we summarize our studies on the role of GJIC in lung neoplasia.

Butylated hydroxytoluene (BHT) induction of pulmonary inflammation: a role in tumor promotion

Chronic pulmonary inflammatory diseases predispose towards lung cancer by unknown mechanisms. Butylated hydroxytoluene (BHT) administration to mice causes lung injury and a subsequent inflammatory response, and when administered chronically to certain inbred strains following carcinogen treatment, increases lung tumor multiplicity. We hypothesize that inflammation promotes lung tumor growth in this model system and have begun to examine this hypothesis by assessing inflammatory parameters in inbred strains that vary in their susceptibility to promotion. Positive correlations were found between susceptibilities to tumor promotion and BHT induction of alveolar macrophage and lymphocyte infiltration into alveolar airspaces, and increased vascular permeability (P < .03, P < .04, and P < .005, respectively). The amounts of pulmonary cyclooxygenase (COX)-1 and COX-2 did not strongly correlate with promotion. Because persistent elevation of macrophage content is the hallmark of a chronic inflammatory response, the alveolar macrophage population was depleted by adding chlorine to the drinking water prior to carcinogenesis. This treatment reduced lung tumor multiplicity following 2-stage carcinogenesis (P < .05). These correlations between inflammatory and tumorigenic responses to BHT, along with decreased tumorigenesis after macrophage depletion, are consistent with a role of inflammation in promotion. Inflammatory mediators may provide targets for early diagnosis and chemoprevention.

Inactivation of both Rb and p53 pathways in mouse lung epithelial cell lines

Aberrant expression of key cell cycle regulatory genes is essential for the immortalization and transformation of cells in vitro. We examined 20 mouse lung epithelial cell lines (2 nontumorigenic, 5 nonmetastatic, and 13 metastatic) for mutations or alterations in the expression of key components of the Rb pathway (pRb and p16INK4a) and the p53 pathway (p53 and p19ARF). Seven cell lines had a mutation in exons 5 to 8 of p53. p19ARF was inactivated in the remaining 13 cell lines, primarily by homozygous deletion. Rb expression was present and unaltered in all cell lines, with both phosphorylated and unphosphorylated protein forms detectable. p16INK4a transcripts were undetectable in all cell lines tested except LM1. Loss of p16INK4a expression was a result of homozygous deletion in 11 out of 20 lung cell lines and promoter-exon 1 hypermethylation in 6 out of the remaining 8 cell lines. Other related components that were examined in this study included p21WAF1 and cyclin D1. Compared to normal lung tissue, p21WAF1 expression levels were reduced or undetectable in all cell lines, which did not correlate with loss of p53 function, but did correlate with inactivation of either p53 or p19ARF. Although cyclin D1 expression was variable between cell lines, transcript levels were decreased by at least 50% in the nontumorigenic lines C10 and E10 compared to the tumorigenic cell lines. These results demonstrate mutually exclusive relationships between p53 and p19ARF and between Rb and p16INK4a, but perhaps not between cyclin D1 and p16INK4a, and further describe the nature of involvement of both pathways in mouse lung tumorigenesis.

Studies using structural analogs and inbred strain differences to support a role for quinone methide metabolites of butylated hydroxytoluene (BHT) in mouse lung tumor promotion

Chronic treatment of BALB and GRS mice with BHT (2,6-di-tert-butyl-4-methylphenol) following a single urethane injection increases lung tumor multiplicity, but this does not occur in CXB4 mice. Previous data suggest that promotion requires the conversion of BHT to a tert-butyl-hydroxylated metabolite (BHTOH) in lung and the subsequent oxidation of this species to an electrophilic quinone methide. To obtain additional evidence for the importance of quinone methide formation, structural analogs that form less reactive quinone methides were tested and found to lack promoting activity in BHT-responsive mice. The possibility that promotion-unresponsive strains are unable to form BHTOH was tested by substituting this compound for BHT in the promotion protocol using CXB4 mice. No promotion occurred, and in-vitro work demonstrated that CXB4 mice are, in fact, capable of producing BHTOH and its quinone methide, albeit in smaller quantities. Incubations with BALB lung microsomes and radiolabeled substrates confirmed that more covalent binding to protein occurs with BHTOH than with BHT and, in addition, BHTOH quinone methide is considerably more toxic to mouse lung epithelial cells than BHT quinone methide. These data are consistent with the hypothesis that a two-step oxidation process, i.e. hydroxylation and quinone methide formation, is required for the promotion of mouse lung tumors by BHT.

Differential sensitivity to lung tumorigenesis following transplacental exposure of mice to polycyclic hydrocarbons, heterocyclic amines, and lung tumor promoters

Research conducted by this laboratory over the past decade has demonstrated the high susceptibility of the fetus to lung tumor formation following in utero exposure of the resistant C57BL/6 and DBA/2N strains of mice to 3-methylcholanthrene (MC). In this review, we describe our more recent studies on the effects of MC and cotreatment with the lung tumor promoter, butylated hydroxytoluene (BHT), on lung tumor formation in the intermediately susceptible BALB/c strain of mice, and the determination of the potential carcinogenicity of the heterocyclic amine, 2-amino-3-methylimidazo[4,5-f]quinoline (IQ) in resistant mouse strains. BALB/c mice showed a similar incidence of lung tumors, both in terms of percentage of mice with tumors and number of tumors per mouse, as found in the resistant [D2 x B6D2F1]F2 mice. Ki-ras point mutations were found in 56% (20/36) of BALB/c lung lesions compared with an incidence of 79% in [D2 x B6D2F1]F2 mice. BALB/c lung lesions demonstrated a similar association of Ki-ras mutations with tumor stage. Interestingly, a strain-dependent difference was observed in the mutational spectrum, where 62% and 38% of the lesions in BALB/c mice exhibited G-->C and G-->T transversions, respectively, in contrast with the 16% and 84% incidences observed in [D2 x B6D2F1]F2 mice. BHT had no statistically significant effect on tumor incidence, multiplicity, or Ki-ras mutational spectrum in BALB/c mice treated in utero with MC, although a trend toward increased tumor multiplicity was observed. Finally, experiments initiated to assess the transplacental carcinogenicity of IQ in D2B6F1 mice demonstrated that 1 year after birth, no macroscopically or microscopically visible liver, lung, or colon tumors were found in the transplacentally treated offspring, nor was induction of Cyp1a1, Cyp1b1, or glutathione S-transferases (GSTs) in fetal lung and liver tissues observed. This implies that at least under these experimental conditions, IQ may not be an important transplacental carcinogen. Overall, these data demonstrate that mutagenic damage to Ki-ras is a critical early event mediating murine lung tumorigenesis in both sensitive and resistant strains. Strain-dependent differences in the Ki-ras mutational spectrum may be associated with their differential susceptibility to lung tumor initiation.

Growth inhibition in G(1) and altered expression of cyclin D1 and p27(kip-1 )after forced connexin expression in lung and liver carcinoma cells

Gap junctional intercellular communication (GJIC) and connexin expression are frequently decreased in neoplasia and may contribute to defective growth control and loss of differentiated functions. GJIC, in E9 mouse lung carcinoma cells and WB-aB1 neoplastic rat liver epithelial cells, was elevated by forced expression of the gap junction proteins, connexin43 (Cx43) and connexin32 (Cx32), respectively. Transfection of Cx43 into E9 cells increased fluorescent dye-coupling in the transfected clones, E9-2 and E9-3, to levels comparable to the nontransformed sibling cell line, E10, from which E9 cells originated. Transduction of Cx32 into WB-aB1 cells also increased dye-coupling in the clone, WB-a/32-10, to a level that was comparable to the nontransformed sibling cell line, WB-F344. The cell cycle distribution was also affected as a result of forced connexin expression. The percentage of cells in G(1)-phase increased and the percentage in S-phase decreased in E9-2 and WB-a/32-10 cells as compared to E9 and WB-aB1 cells. Concomitantly, these cells exhibited changes in G(1)-phase cell cycle regulators. E9-2 and WB-a/32-10 cells expressed significantly less cyclin D1 and more p27(kip-1) protein than E9 and WB-aB1 cells. Other growth-related properties (expression of platelet-derived growth factor receptor-beta, epidermal growth factor receptor, protein kinase C-alpha, protein kinase A regulatory subunit-Ialpha, and production of nitric oxide in response to a cocktail of pro-inflammatory cytokines) were minimally altered or unaffected. Thus, enhancement of connexin expression and GJIC in neoplastic mouse lung and rat liver epithelial cells restored G(1) growth control. This was associated with decreased expression of cyclin D1 and increased expression of p27(kip-1), but not with changes in other growth-related functions.

Quantitative trait locus mapping of genes regulating pulmonary PKC activity and PKC-alpha content

Strain A/J mice, which are predisposed to experimentally induced asthma and adenocarcinoma, have the lowest pulmonary protein kinase (PK) C activity and content among 22 inbred mouse strains. PKC in neonatal A/J mice is similar to that in other strains, so this difference reflects strain-dependent postnatal regulation. PKC activity is 60% higher in C57BL/6J (B6) than in A/J lungs, and the protein and mRNA concentrations of PKC-alpha, the major pulmonary PKC isozyme, are two- to threefold higher in B6 mice. These differences result from more than a single gene as assessed in F(1), F(2), and backcross progeny of B6 and A/J parents. Quantitative trait locus (QTL) analysis of 23 AxB and BxA recombinant inbred strains derived from B6 and A/J progenitors indicates a major locus regulating lung PKC-alpha content that maps near the Pkcalpha structural gene on chromosome 11 (D11MIT333; likelihood ratio statistic = 12.5) and a major locus controlling PKC activity that maps on chromosome 3 (D3MIT19; likelihood ratio statistic = 15.4). The chromosome 11 QTL responsible for low PKC-alpha content falls within QTLs for susceptibilities to lung tumorigenesis and ozone-induced toxicity.

Differential expression and localization of the mRNA binding proteins, AU-rich element mRNA binding protein (AUF1) and Hu antigen R (HuR), in neoplastic lung tissue

Modulation of gene expression at the level of mRNA stability has emerged as an important regulatory paradigm. In this context, differential expression of numerous mRNAs in normal versus neoplastic tissues has been described. Altered expression of these genes, at least in part, has been demonstrated to be at the level of mRNA stability. Two ubiquitously expressed mRNA binding proteins have recently been implicated in the stabilization (Hu antigen R/HuR) or destabilization (AU-rich element mRNA binding protein [AUF1]/heterogeneous nuclear ribonucleoprotein D) of target mRNAs. Further, their functional activity appears to require cytoplasmic localization. In the present study, we demonstrate a strong correlation between increased cytoplasmic expression of both AUF1 and HuR with urethane-induced neoplasia and with butylated hydroxytoluene-induced compensatory hyperplasia in mouse lung tissue. In addition, when compared with slower growing cells, rapidly growing neoplastic lung epithelial cell lines expressed a consistently higher abundance of both AUF1 and HuR proteins. Moreover, in nontumorigenic cell lines, both AUF1 and HuR protein abundance decreased with confluence and growth arrest. In contrast, in spontaneous transformants, AUF1 and HuR abundance was unaffected by changes in cell density. We suggest that growth-regulated alterations in AUF1 and HuR abundance may have pleiotropic effects on the expression of a number of highly regulated mRNAs and that this significantly impacts the onset, maintenance, and progression of the neoplastic phenotype. Mol. Carcinog. 28:76-83, 2000.

High cyclooxygenase 1 (COX-1) and cyclooxygenase 2 (COX-2) contents in mouse lung tumors

Mouse lung tumorigenesis is a convenient model for examining all stages of lung adenocarcinoma (AC) progression. Because enhanced cyclooxygenase 2 (COX-2) expression has been observed in advanced human AC, we investigated the intracellular concentrations of the two cyclooxygenases, cyclooxygenase 1 (COX-1) and COX-2, at different times after carcinogen administration to A/J mice. The concentrations of both proteins were much higher in urethane-induced adenomas and carcinomas compared with control A/J mouse lung tissue (P < 0.03 and P < 0.01 in adenomas and AC, respectively, for COX-1; P < 0.003 and P < 0.004 in adenomas and AC, respectively, for COX-2). Small benign tumors that arose spontaneously in 13-month-old mice also stained for COX-1 and COX-2, showing that this elevated enzyme content does not depend on chemical induction. COX-1 and COX-2 immunostaining was observed in normal bronchiolar and alveolar epithelia, alveolar macrophages and bronchiolar smooth muscle. This is the first report of the cellular distribution of COX-1 and COX-2 in murine lungs and the first in any species to demonstrate their co-localization. COX content in isolated bronchiolar Clara cells, a putative cell of tumor origin, was equal to that found in tumors, suggesting that the high enzyme content in neoplasms is due to their proportionally high concentration of these tumor precursor cells. Different patterns of COX-1 and COX-2 expression were observed in tumors of different growth patterns; only occasional small foci stained in solid adenomas, while most cells in papillary adenomas were immunoreactive. This staining pattern was also seen in adenocarcinomas, but some of the papillary portions also included focally stained and unstained regions. The continued expression during neoplastic progression of these specialized enzymes present in normal cells of tumor origin suggests their function in maintenance of the neoplastic state.

Surfactant protein C expression in urethane-induced murine pulmonary tumors

Mice injected with urethane develop tumors with distinct histological patterns, which are classified as solid, papillary, or a mixture of these two patterns within the same tumor. Most investigators agree that solid tumors arise from alveolar type II cells, but the cellular origin of papillary tumors is less certain, being attributed to either type II cells or nonciliated bronchiolar epithelial (Clara) cells. To characterize the state of differentiation of these tumors more precisely and to provide additional information on gene expression, we used immunocytochemistry and/or in situ hybridization to determine the cellular localization of surfactant-associated proteins A (SP-A), SP-B, SP-C, and SP-D; Clara cell-associated protein CC-10; and thyroid transcription factor-1. In normal mouse lung, the messenger RNAs (mRNAs) for SP-A, SP-B, and SP-D were expressed in both type II cells and Clara cells. SP-C mRNA, however, was expressed only in type II cells, and CC-10 expression of mRNA was restricted to Clara cells. All tumors examined, both solid and papillary, expressed SP-A, SP-B, SP-C, SP-D, and thyroid transcription factor-1, but not CC-10. However, SP-C expression was slightly diminished in larger (older) papillary tumors. These results demonstrate that urethane-induced murine lung tumors express the type II cell phenotype.

Strain-dependent lung tumor formation in mice transplacentally exposed to 3-methylcholanthrene and post-natally exposed to butylated hydroxytoluene

The carcinogenic effects of in utero exposure to 3-methylcholanthrene (MC) have been demonstrated in the tumor-resistant C57BL/6 (B6) and DBA (D2) strains of mice. In this study, we determined the effects of in utero exposure to MC in BALB/c mice, a strain which demonstrates greater susceptibility to lung tumor induction, and compared our findings with those previously found in [D2xB6D2F(1)]F(2) mice. In addition, we assessed the molecular pathogenesis of the chemically induced tumors and examined the effects of the putative lung tumor promoter butylated hydroxytoluene (BHT) in BALB/c mice. BALB/c mice were treated on day 17 of gestation with 5, 15 or 45 mg/kg MC and 6 weeks after birth with BHT for 6 consecutive weeks. Mice were killed at 6 months of age. Ki-ras, p16Ink4a and p19ARF gene loci were amplified from paraffin-embedded lung tumor tissue and screened for the presence of point mutations via allele-specific oligonucleotide hybridization and single strand conformation polymorphism (SSCP) analyses. Ki-ras point mutations were found in 56% (20/36) of BALB/c lung tumors, with 33% (2/6) of the hyperplasias, 58% (10/19) of the adenomas and 73% (8/11) of the carcinomas exhibiting point mutations at this gene locus. Similar incidences of Ki-ras mutations were previously found following transplacental exposure of [D2xB6D2F(1)]F(2) mice to MC and treatment of adult A/J mice with urethane. Interestingly, a strain-dependent difference was observed in the mutational spectrum. Sixty-two and 38% of the lung lesions in BALB/c mice exhibited G-->C and G-->T transversions, respectively, in contrast to the 13 and 84% incidences previously observed in [D2xB6D2F(1)]F(2) mice. SSCP analysis of the tumor suppressor gene p16Ink4a showed a 6% incidence of point mutations, consistent with that found in [D2xB6D2F(1)]F(2) mice. No mutations were found in exon 1beta of the p19ARF gene of either strain. BHT, a lung tumor promoter in adult mice, had no statistically significant effects on either tumor incidence, tumor multiplicity or the mutational spectrum produced in the Ki-ras gene by in utero MC treatment. However, though not significant, there was an observable trend in increased tumor multiplicity in mice co-treated with BHT. These data demonstrate the transplacental carcinogenic effect of MC in BALB/c mice and show that mutagenic damage to Ki-ras is a critical early event mediating murine lung tumorigenesis in both the tumor-sensitive and tumor-resistant strains. Unlike what occurs when adult BALB/c mice are treated with MC, BHT does not appear to significantly promote the formation of lung tumors following transplacental exposure to MC, possibly due to the rapid growth and cell proliferation in the developing organism. Strain-dependent differences in the Ki-ras mutational spectrum may be associated with their differential susceptibility to lung tumor initiation.

Compensatory lung growth after partial pneumonectomy enhances lung tumorigenesis induced by 3-methylcholanthrene

In small mammals, partial pneumonectomy (PNX) elicits rapid hyperplastic compensatory growth of the remaining lung parenchyma to restore normal lung mass, structure, and function. In BALB mice subjected to PNX, compensatory lung growth is complete within 10 days. Because cellular hyperplasia contributes to the mechanism of tumor promotion by butylated hydroxytoluene (BHT), we hypothesized that hyperplastic compensatory lung growth would promote tumor formation in carcinogen-treated animals in a manner similar to that observed after BHT. In mice subjected to PNX, within 1 week of treatment with the carcinogen 3-methylcholanthrene (MCA; 10 microg/g body weight), lung tumor multiplicity was 3-7-fold higher in animals subjected to PNX than in mice subjected to a sham operation. The increase in tumor multiplicity occurred when PNX was performed 1, 3, and 6 days before or 1 day after MCA treatment. In the absence of PNX, lung tumor multiplicity in MCA-treated mice given one injection of BHT (200 mg/kg body weight) increased significantly (P < 0.01) as compared to that in mice given MCA alone. Tumor multiplicity continued to increase linearly (R2 = 0.99) with each subsequent BHT injection. Lung tumor multiplicity and tumor size in mice given one or two injections of BHT were comparable to those in animals subjected to PNX. These data demonstrate that post-PNX compensatory lung growth stimulates tumorigenesis in MCA-treated mice and provides a novel model for investigating tumor formation.

Reduced receptor expression for platelet-derived growth factor and epidermal growth factor in dividing mouse lung epithelial cells

The roles of growth factors in mouse lung neoplasia were investigated by examining receptors for platelet-derived growth factor (PDGF) and epidermal growth factor (EGF) in epithelial cell lines. Whereas nontumorigenic lung cells expressed mRNA and protein for PDGF receptor (PDGFR)-alpha, PDGFR-beta, and EGF receptor (EGFR), five of six neoplastic lines did not. Because this exceptional tumorigenic cell line grows slowly, we hypothesized that receptor levels increased with cell stasis. To test this hypothesis, serum concentrations were manipulated, and log-phase and post-confluent cells were compared. Consistent with our hypothesis, PDGFR-alpha and EGFR contents, but not PDGFR-beta contents, increased at stasis. Ki-ras mutation initiates lung tumorigenesis in mice, but activation of Ki-ras did not affect receptor expression. This was determined both by transfecting nontumorigenic cells with activated Ki-ras and neoplastic cells with a Ki-ras antisense construct and by diminishing Ki-ras activation by using a farnesyltransferase inhibitor. Stasis-associated upregulation of growth-factor receptor expression suggests a function in lung cell differentiation that is abrogated during neoplastic growth.

Calpain and calpastatin regulate neutrophil apoptosis

The average polymorphonuclear neutrophil (PMN) lives only a day and then dies by apoptosis. We previously found that the calcium-dependent protease calpain is required for apoptosis in several mouse models of cell death. Here we identify calpain, and its endogenous inhibitor calpastatin, as regulators of human neutrophil apoptosis. Cell death triggered by the translation inhibitor cycloheximide is calpain-dependent, as evidenced using either a calpain active site inhibitor (N-acetyl-leucyl-leucyl-norleucinal) or agents that target calpain's calcium binding sites (PD150606, PD151746). No significant effect on cycloheximide-triggered apoptosis was found by using inhibitors of the proteasome or of other papain-like cysteine proteases, providing further evidence that the active site calpain inhibitor prevents apoptosis via its action on calpain. In addition, we find that potentiation of calpain activity by depleting its endogenous inhibitor, calpastatin, is sufficient to cause apoptosis of neutrophils. Nevertheless, apoptosis signalled via the Fas antigen proceeds regardless of the presence of calpain inhibitor. These experiments support a growing body of work, indicating an upstream regulatory role for calpain in many, but not all, forms of apoptotic cell death. They also identify calpastatin as a participant in apoptotic cell death and suggest that for at least one cell type, a decrease in calpastatin is a sufficient stimulus to initiate calpain-dependent apoptosis.

Diminished CYP2E1 expression and formation of 2-S-glutathionyl acetate, a glutathione conjugate derived from 1,1-dichloroethylene epoxide, in murine lung tumors

We hypothesized that resistance of lung tumors to the cytotoxic effects of xenobiotics is associated with loss of cytochrome P-450 expression, leading to defective formation of reactive intermediates. To test this hypothesis, we investigated 1,1-dichloroethylene (DCE), a chemical that causes Clara cell damage, in a urethane-induced model of lung tumorigenesis. Lung metabolism of DCE yields 2-S-glutathionyl acetate (conjugate [C]), a glutathione conjugate derived from DCE-epoxide, believed to be the ultimate toxic species. We used immunohistochemistry to investigate CYP2E1 expression in nontumor- and tumor-bearing lung to identify cells capable of generating [C]. CYP2E1 and [C] were colocalized in adjacent tissue sections to determine coincidence between CYP2E1 and [C] in lung cells. CYP2E1 was highly localized to the bronchiolar epithelium of nontumor-bearing lung and in uninvolved tissue of tumor-bearing lung and was concentrated in the Clara cells. In contrast, tumor foci including hyperplasias, adenomas, and carcinomas were deficient in CYP2E1 in both untreated and DCE-treated mice. Immunoreactivity for [C] was also detected in the bronchiolar epithelium in nontumor-bearing lung and uninvolved tissue of tumor-bearing lung of DCE-treated mice and was reduced in hyperplasias, adenomas, or carcinomas. Thus, there was a coincidence between the sites of CYP2E1 expression and [C] formation. Conjugate [C] accumulated only in lung cells in which CYP2E1 was expressed. Histochemical staining for glutathione confirmed its presence in tumor foci. Thus, bioactivation and conjugation of DCE occur in structurally normal tissue from both nontumor- and tumor-bearing lung but was lost in tumor tissue, irrespective of the stage of tumor development.

At least four loci and gender are associated with susceptibility to the chemical induction of lung adenomas in A/J x BALB/c mice

Four putative quantitative trait loci (QTLs) that influence susceptibility to the induction of lung adenomas by urethane in an F2 cross between A/J and BALB/cOlaHsd have been mapped. Following microsatellite typing of mice with resistant and susceptible phenotypes at 97 microsatellite marker loci, a major locus was identified on chromosome 18 with a lod score of 15. This was responsible for an 8- to 10-fold increase in tumor multiplicity in males and females, respectively, having the AA and CC genotypes at the D18Mit188 marker locus. It mapped close to Dcc (deleted in colorectal cancer). A locus on chromosome 4 (lod score 6.5) had the resistant allele in strain A/J and the susceptible allele in BALB/c, with a 14-fold difference in tumor multiplicity between mice of the AA and CC genotypes. This mapped close to the Cdkn2a (cyclin-dependent kinase inhibitor 2A) locus, which is commonly deleted in mouse lung tumors. Two loci with smaller effects (lod scores 3.03 and 3.25) were identified on chromosomes 1 and 11. There was also significant sexual dimorphism in tumor multiplicity both among 151 F2 hybrids and among 52 mice resulting from a backcross to strain A/J, with males having higher tumor counts than females.

Selective induction of apoptosis in mouse and human lung epithelial cell lines by the tert-butyl hydroxylated metabolite of butylated hydroxytoluene: a proposed role in tumor promotion

Butylated hydroxytoluene (BHT) causes lung injury in mice and promotes tumor formation. Hydroxylation of a tert-butyl group on BHT to yield the metabolite, 6-tert-butyl-2-[2'-(2'-hydroxymethyl)-propyl]-4-methylphenol (BHTOH), may be required. BHTOH is more potent than BHT on an equimolar basis in causing lung damage, enhancing lung tumor development, killing isolated bronchiolar non-ciliated Clara cells, and inhibiting lung epithelial gap junctional intercellular communication. One mechanism proposed for tumor promoting agents is selective cytotoxicity; killing normal cells allows uninhibited clonal expansion of neighboring initiated cells. We compared the abilities of BHT, BHTOH, and other BHT metabolites to kill non-tumorigenic and tumorigenic mouse and human lung cell lines, and examined the contribution of apoptosis to this cytotoxicity. These cells lack the cytochrome P450 2B isozyme necessary for converting BHT to BHTOH. BHTOH and 4-hydroperoxy-4-methyl-2,6-di-tert-butyl-2,5-cyclohex-adienone+ ++ (BHTOOH) were most toxic, BHT and 2,6-di-tert-butyl-1,4-benzoquinone (BHTQu) were less potent, and 4-methyl BHT metabolites that are not pneumotoxic were ineffective. BHTOH most strongly induced apoptosis, based on nuclear condensation and transmission electron microscopy. Non-tumorigenic cells were as susceptible to cell death as the neoplastic cell lines when apoptosis and necrosis are not distinguished, but more sensitive to BHTOH-induced apoptosis. An apoptotic mechanism may underlie the lung tumor promoting actions of BHTOH.

Inhibition of 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone-induced mouse lung tumor formation by FGN-1 (sulindac sulfone)

The sulfone derivative of the non-steroidal anti-inflammatory drug (NSAID), sulindac, has been reported to inhibit mammary and colon tumor formation in rodent models of chemically-induced carcinogenesis. Unlike its parent compound, this metabolite lacks cyclo-oxygenase inhibitory activity. A tumor induction protocol, consisting of NNK administration in the drinking water over several weeks to model chronic human exposure, was used to test whether the sulfone (called FGN-1) could inhibit the formation of primary lung tumors in mice. A total of 150 female, AIN76A-fed, A/J mice received 9 mg of NNK each. Concentrations of FGN-1 that had been previously determined not to affect body weight gain were added to the food at levels of 0, 250, 500 and 750 mg/kg of diet (30 mice/group) starting 2 weeks before NNK administration and continuing for 22 weeks. At that time pleural surface tumors were counted. Tumor incidence decreased significantly from 96 % in the control diet and 93% in the 250 FGN-1 mg/kg diet to 63 and 67% in the 500 and 750 mg FGN-1/kg diet groups, respectively (P < 0.001 by chi-square analysis). Lung tumor multiplicity decreased from 18.1+/-3 tumors/ mouse (mean+/-SEM, control diet) to 12.3+/-3 (250), 5.3+/-1 (500) and 2.1+/-1 (750) (P < 0.0005 by post hoc ANOVA). In previous studies using this carcinogenesis protocol, the maximum tolerated dose of sulindac inhibited lung tumor multiplicity by no more than 50% with no effect on incidence. This dose-dependent reduction in tumorigenesis by a non-toxic dose of FGN-1 indicates a strong chemopreventive activity against experimental induction of lung carcinogenesis. The greater potency of the sulfone over sulindac and its lack of toxic side effects because of its inability to affect cyclo-oxygenase activity suggests that clinical testing in individuals at high risk for lung cancer should be considered.

Additional evidence that the K-ras protooncogene is a candidate for the major mouse pulmonary adenoma susceptibility (Pas-1) gene

A locus for mouse pulmonary adenoma susceptibility, Pas-1, has been mapped on distal chromosome 6, where the K-ras gene is located. Allele-specific activation and expression of the K-ras allele from the susceptible parent has been observed in lung tumors from F1 hybrid mice. We report here genetic mapping of lung tumor susceptibility genes in urethane-treated A x B and B x A recombinant inbred (RI) mice using microsatellite markers to seek further evidence for the K-ras gene as candidate for Pas-1. The K-ras genotype differs between the A/J and C57BL/6J progenitors of the RI strains, and distal chromosome 6 contained a major lung tumor susceptibility determinant in the RI mice. Additional evidence that Pas-1 is K-ras involved linkage analysis of (A/JOLaHsd x BALB/ cOLaHsd) F2 intercross mice whose parents shared the same K-ras genotype. In contrast to the results with the A x B and B x A RI strains, no distal chromosome 6 site was significantly associated with tumor development in these F2 mice. In addition to this major locus, linkage analysis of the RI mice revealed additional quantitative trait loci for susceptibility on chromosomes 10, 17, and 19. These loci may serve as modifiers of Pas-1. The relationship between the K-ras genotype and the frequency of K-ras mutations in urethane-induced lung tumors from the RI mice was also explored. All 18 tumor DNAs from RI mice with high susceptibility contained an AT-->TA transversion at the second base of K-ras codon 61. This was also true for DNAs from 27 of 27 (100%) tumors in mice with high intermediate susceptibility. In RI strains with a low intermediate susceptibility, the DNA from 39 of 47 (83%) tumors contained an AT-->TA transversion at codon 61, and only 13 of 21 (62%) tumors had this mutation in the most resistant group. This reflects a positive correlation between the frequency of K-ras mutations in lung tumors of A x B or B x A RI strains and their susceptibility to lung carcinogenesis. Since K-ras appears to be Pas-1, these results suggest that some RI mice that have the resistant K-ras or Pas-1 allele undergo tumor development by a K-ras-independent route.

Molecular comparison of human and mouse pulmonary adenocarcinomas

Mice develop lung tumors similar in their histogenesis and molecular features to peripheral adenocarcinomas in humans. The advantage of this model system is that events early in tumorigenesis can be delineated and their biological consequences tested by transgenic and knockout strategies. Both human and murine adenocarcinomas contain Kras mutations; in mice these occur within weeks following carcinogen administration. Decreased expression of similar tumor suppressor genes occur in both species due to mutation, deletion, altered DNA methylation, or unknown mechanisms. These genes include p15, p16, Rb, cyclin D1, p53, Apc, Mcc, and Gjal. Some genes have only been examined in one of these species, such as the deletions in chromosome 3p and the overexpression of bcl 2 in human adenocarcinoma. Not all molecular changes are identical to the two species, however. Quinone oxidoreductase (DT-diaphorase) levels rise in the human tumors but fall in the mouse; the extent of both changes is very dramatic. Similarly, EGF-receptor content often increases in human lung adenocarcinomas but decreases in the mouse tumors. In general, however, the nature of the molecular changes is quite similar.

Role of gap junctions in lung neoplasia

Reduced gap junctional intercellular communication (GJIC) has been noted in many types of neoplastic cells and may contribute to the neoplastic phenotype. This study assessed GJIC (by fluorescent dye-coupling) and gap junction protein (connexin) expression in mouse and human lung carcinoma cell lines and investigated whether reduced GJIC was involved in their neoplastic phenotype. Dye-coupling and connexin43 (Cx43) expression were much lower in most of the carcinoma lines (16 of 22) compared to nontransformed lung epithelial cells. Other connexins were not detected. A poorly communicating mouse lung carcinoma cell line (E9) was transfected with Cx43 or transduced with Cx32 and several stable clones were isolated that had 2- to 4-fold increased dye coupling. When evaluated for growth in vitro, the population doubling times were increased and the saturation densities were decreased in the clones. When assessed for tumorigenicity, the parental E9 cells formed tumors with a 100% incidence (6/6 mice), whereas the clones varied in tumorigenic response (0-88% incidence). The best communicating clone (E9-2) was not tumorigenic. The highly communicating Cx32 clone, E9/32-9, gave a tumor incidence of 88%. These results suggest that restoration of GJIC by forced connexin expression can reduce the growth and tumorigenicity of lung carcinoma cells in a connexin-specific manner.

Cytokine-induced nitric oxide formation in normal but not in neoplastic murine lung epithelial cell lines

Cytomix, a mixture of interferon-gamma, tumor necrosis factor-alpha, and interleukin-1beta, induces nitric oxide (NO) production in lung epithelial cell lines. It is not known whether neoplastic transformation alters a cell's ability to form NO in response to cytokines. The present study investigated NO formation in two murine lines of immortalized "normal" (nontumorigenic) lung epithelial cells of alveolar type II origin, E10 and C10, and their sibling spontaneous transformants, E9 and A5. Nontumorigenic cells elaborated much more NO after cytomix exposure than did their tumorigenic counterparts. NO production was prevented by inhibiting protein synthesis and NO synthase and attenuated by dexamethasone. Northern and Western blot analyses of inducible NO synthase (iNOS) demonstrated cytomix-induced induction of iNOS only in nontumorigenic cells. The deficiency in NO production in tumorigenic cells was not associated with reduced iNOS mRNA stability or with differences in cytomix-induced nuclear factor-kappaB activation. Although cytomix caused a greater production of NO in E10 cells than in E9 cells, the same treatment induced equivalent proliferation in both cell lines. These results indicate a specific deficiency in cytokine-induced NO synthesis in transformed murine lung epithelial cells relative to their normal progenitor cells and provide a model for investigating iNOS regulation.

Decreased expression of the adenomatous polyposis coli (Apc) and mutated in colorectal cancer (Mcc) genes in mouse lung neoplasia

A decrease in the intracellular concentrations of the transcripts for some tumor suppressor genes has been found during murine lung tumorigenesis; for p15INK4b and p16INK4a, this was due to homozygous deletions. We report here a decrease in the mRNA levels of the mutated in colorectal cancer (Mcc) and adenomatous polyposis coli (Apc) genes in mouse lung tumors and some neoplastic cell lines. This was assessed both by northern blotting and reverse transcriptase-polymerase chain reaction of RNA isolated from lung tumors that had been induced by urethane, N-nitrosodiethylamine, or 3-methylcholanthrene in (A/J x C57BL/6) F1 or A/J mice. A reduced amount of both Mcc and Apc messages was also seen when two neoplastic cell lines, a spontaneous transformant (E9) and a line derived from a chemically induced solid tumor (82-132), were compared with two independently derived nontumorigenic cell lines (E10 and C10); E9 was derived from E10, and all of these lines are probably of alveolar type 2 cell origin. A cell line derived from a chemically induced papillary lung tumor probably of bronchiolar Clara cell origin (LM2) had Mcc mRNA levels similar to those of C10 and E10 but reduced Apc mRNA levels. A line (p53-823) derived from a papillary tumor that arose in a mouse with a mutated p53 transgene had a reduced amount of the Mcc gene product only. These differential changes in the relative amounts of Apc and Mcc messages in LM2 and p53-823) cells may serve as useful models for studying the regulation of their expression. Both messages had half-lives of 6-9 h in normal E10 and neoplastic E9 cells, so decreased message stability does not account for these reductions. This is the first report of estimated degradation rates of these mRNAs. Apc and Mcc message content did not vary as a function of growth status of the cell lines. Single-strand conformation polymorphism analysis did not reveal mutations in Apc coding regions known to have a high mutation frequency in human colon tumors. Loss of heterozygosity of Apc and Mcc was not found in tumors that developed in the F1 mice, implying a lack of allelic deletions. These changes in tumor suppressor gene expression may contribute to the development and maintenance of neoplasia in lung epithelium.

Frequent reduction of gap junctional intercellular communication and connexin43 expression in human and mouse lung carcinoma cells

The reduced gap junctional intercellular communication (GJIC) and gap junction protein (connexin) expression that have been noted in many neoplastic cell types may contribute to the neoplastic phenotype. We assessed GJIC (by fluorescent dye micro-injection) and connexin expression (by Northern blotting, Western blotting and immunohistochemistry) in five mouse and 17 human lung carcinoma cell lines; both measures were lower in neoplastic cells compared to non-transformed lung epithelial cells. Other connexins were not detected in these cells. Co-culture experiments indicated that carcinoma cell lines able to transfer dye among themselves (homologous GJIC) had little capacity for dye-coupling with non-transformed cells (heterologous GJIC). Southern blot analyses indicated that reductions in GJIC and connexin43 expression were not due to deletions or rearrangements of this gene, but were more likely accounted for by transcriptional down-regulation and/or post-transcriptional factors. No correlations between GJIC and known oncogene and tumor suppressor gene alterations in the human lung carcinoma cells were apparent, suggesting that other mechanisms down-regulate GJIC in these cells. Since the neoplastic cell lines exhibited low GJIC (either homologous or heterologous), this characteristic may be involved in expression of the neoplastic phenotype.

Mouse lung epithelial cell lines--tools for the study of differentiation and the neoplastic phenotype

Several dozen lung epithelial cell lines have been established in culture over the past 20 years from normal lung explants and their spontaneous transformants, and from lung tumors that arose spontaneously or were induced with chemicals, viruses, or oncogenic transgenes. To provide information from which to choose appropriate lines for investigating problems in lung cell biology and pulmonary neoplasia, this review describes the origins of these lines and some of their characteristics. These include growth, morphology, tumorigenicity, ability to metastasize, xenobiotic metabolism, mutational status, signal transducing activities, cytogenetics, ability to form domes, and electric conductance. In addition to collecting this information in a single place for the first time, we describe previously unpublished apoptosis features of some of these lines. An increasing number of investigations are beginning to use these lines and this review contains references into 1997.

Butylated hydroxytoluene exposure is necessary to induce lung tumors in BALB mice treated with 3-methylcholanthrene

Chronic butylated hydroxytoluene (BHT) treatment after a single administration of a carcinogen increases lung tumor multiplicity in some inbred strains of mice. We report that BALB/cOla and BALB/cByJ mice given a low dose (10 microg/g of body weight) of 3-methylcholanthrene (MCA) develop no lung tumors unless this is followed by chronic BHT exposure. Slightly higher MCA doses (15 and 25 microg/g) induce low lung tumor multiplicities (0.6 and 1.9 tumors/mouse, respectively) that are increased 12-26-fold by chronic BHT administration. This low-dose MCA/BHT model in BALB mice will facilitate the identification of genes regulating susceptibility to lung tumor promotion and pulmonary chemopreventative agents that act at a postinitiation site.

Ki-ras and p53 mutations are early and late events, respectively, in urethane-induced pulmonary carcinogenesis in A/J mice

In the A/J strain of mice, urethane (ethyl carbamate) induces lung hyperplasia, adenoma, and adenocarcinoma in a time-dependent manner. These distinct morphological stages may correlate with sequential molecular genetic changes in this mouse model. To test this hypothesis, we investigated the presence of mutations involving Ki-ras and p53 in urethane-induced lung lesions in A/J mice at early and late stages of tumorigenesis. We precisely microdissected 40 lung lesions from paraffin-embedded sections. Ki-ras mutations around codon 61 and p53 mutations in exons 5-8 were identified by polymerase chain reaction-single-strand conformation polymorphism and DNA sequencing techniques. In 29 early-stage lung lesions classified as hyperplasias (seven) or adenomas (22), we observed 19 Ki-ras mutations (66%), including three silent mutations and one double mutation at different codons, and one silent p53 mutation (3.5%). In 11 late-stage adenomas, we identified nine activating Ki-ras mutations (82%) and four missense p53 mutations (36%). These results indicate that Ki-ras mutations arise early, whereas p53 mutations occur relatively late during the benign stages of urethane-induced lung carcinogenesis in A/J mice.

Homozygous codeletion and differential decreased expression of p15INK4b, p16INK4a-alpha and p16INK4a-beta in mouse lung tumor cells

The genes of murine cyclin D-dependent kinase inhibitors, p15INK4b and p16INK4a, are located in a region of chromosome 4 where overlapping deletions were found in lung adenocarcinomas. The p16INK4a gene uniquely consists of alternative first exons (E1alpha and E1beta), which are spliced to exon 2 in alternative reading frames to either encode p16INK4a (alpha form) or another potential tumor suppressor, p19ARF (beta form). We examined 99 lung adenocarcinomas of C3H/HeJ x A/J F1(C3AF1) and A/J x C3H/HeJ F1(AC3F1) mouse hybrids and 18 (13 metastatic, 5 nonmetastatic) tumorigenic mouse lung epithelial cell lines for p15INK4b and p16INK4a gene inactivation. Homozygous codeletion occurred in eight of the 13 (62%) metastatic, four of the five (80%) nonmetastatic cell lines, but in only six of 99 (6%) adenocarcinomas. Neither p15INK4b nor p16INK4a gene was individually deleted in any of the tumors or cell lines, and all deletions of the p16INK4a gene extended into exon 2, which would be expected to disrupt the functions of both p16INK4a and p19ARF. We also detected no intragenic mutations of either gene in 44 tumors that displayed loss of heterozygosity at the p16INK4a locus or in any of the cell lines. Transcript levels of p16INK4a-alpha, p16INK4a-beta and p15INK4b also were examined in each of the cell lines that retained copies of these genes. Whereas an immortal mouse lung epithelial cell line (E10) and two metastatic tumor cell lines (LM1 and E9) expressed p16INK4a-beta and p15INK4b mRNA, the alpha transcript of p16INK4a was detected in only the LM1 cell line. These results suggest that both p15INK4b and p16INK4a (alpha and beta) are targets of inactivation in mouse lung tumorigenesis.

Enhancement of gap junctional intercellular communication by dibutyryl cyclic AMP in lung epithelial cells

Reduced gap junctional intercellular communication (GJIC) occurs in neoplastic cells and contributes to their phenotype. Cyclic AMP agonists inhibit lung cancer cell growth and enhance GIIC in other cell types, but little is known about their effects on lung epithelial cell gap junctions. We have examined whether N6, 2'-O-dibutyryladenosine 3':5'-cyclic mono-phosphate (DBcAMP) affected GJIC, gap junction protein (connexin43) expression, and the growth of non-transformed and neoplastic mouse lung epithelial cells. DBcAMP (0.01.1 mM) stimulated GJIC (assayed by fluorescent dye microinjection) and connexin43 expression (assessed by Northern and Western blotting) and reduced their proliferation. These results suggest an association between cAMP growth inhibition and enhanced GJIC in lung epithelial cells.

Cytoskeletal architecture in mouse lung epithelial cells is regulated by protein-kinase C-alpha and calpain II

Brief exposure to 12-O-tetradecanoylphorbol 13-acetate (TPA) caused a uniformly flattened population of mouse lung epithelial cells to become more heterogeneous; some cells rounded up, and others detached to overlap with flatter cells. Actin stress fiber organization was disrupted, and F-actin accumulated in lemellipodia. Vinculin dissociated from the focal adhesion plaques to diffuse throughout the cytoplasm. Inhibition of protein kinase C (PKC) activity blocked these effects of TPA. After 8 h of TPA exposure, actin filaments reassembled and vinculin again localized to the cell periphery. Calpain inhibition attenuated the decrease of PKC-alpha protein and PKC activity from the membrane fraction, and prevented the redistribution of cytoskeletal elements. Talin immunostaining was widespread throughout control cells but was localized to the periphery 8 h after treatment with TPA or with inhibitors of PKC and calpain. Both vinculin and talin concentrations increased with prolonged TPA treatment. PKC-zeta and calpain II were not appreciably affected by TPA exposure. Translocation of PKC-alpha to the membrane, followed by its calpain-induced downmodulation, is apparently required for the reversible pattern of cytoskeletal changes caused by TPA.

Down-regulation by butylated hydroxytoluene of the number and function of gap junctions in epithelial cell lines derived from mouse lung and rat liver

The mouse pneumotoxicant and lung and liver tumor promoter butylated hydroxytoluene (BHT) was examined for its effects on gap junctional intercellular communication (GJIC) in mouse lung epithelial (C10) and rat liver epithelial (WB-F344) cell lines. GJIC, as measured by fluorescent dye microinjection, was inhibited in both types of cells by BHT in dose- and time-dependent fashions. Inhibition was detected in WB-F344 cells at BHT concentrations > or = 62.5 microM and in C10 cells at concentrations > or = 150 microM after 4 h treatment. Inhibition occurred within 15-30 min and was reversed by removing BHT from the culture medium. The highly toxic BHT metabolite 6-t-butyl-2-(hydroxy-t-butyl)-4-methylphenol (BHTOH) and the non-toxic BHT metabolite, 2,6-di-t-butyl-4-hydroxymethylphenol (BHTBzOH) were also tested. In both cell lines BHTOH was a more potent inhibitor of GJIC than BHT, whereas BHTBzOH was ineffective. The mechanisms of inhibition of GJIC by BHT were also examined. The initial rapid inhibition detected within 15-30 min may have been due to gap junction channel closure or blockage, since no changes in gap junction number, connexin (Cx) 43 levels or Cx43 phosphorylation were observed. By 2-4 h, however, gap junctions were internalized into the cytoplasm, the number of immunodetectable plasma membrane gap junctions was reduced and phosphorylated Cx43-P2 was decreased. Treatment of the cells for 24 h with 12-O-tetradecanoylphorbol-13-acetate (TPA) prevented inhibition of GJIC by TPA, but not by BHT. Western blot analyses of TPA-treated WB-F344 or C10 cells revealed the presence of a hyperphosphorylated form of Cx43 (Cx43-P3) and no reduction in Cx43-P2, in contrast to BHT-treated cells. These data suggest that BHT and TPA inhibit lung and liver epithelial cell GJIC through distinct mechanisms.

Very early changes in pulmonary protein kinase C-alpha and calpain II contents following injection of butylated hydroxytoluene (BHT) into mice

Butylated hydroxytoluene (BHT)-induced lung damage in mice is an excellent model system for studying mechanisms of chemically-induced, reversible alveolar injury. Changes in the pulmonary contents of protein kinase C (PKC) and the calcium-dependent protease, calpain, were previously noted during the repair phase following BHT-induced pneumotoxicity. Calpain is believed to initiate PKC down-regulation. PKC-alpha is the major PKC isozyme and calpain II the major calpain isozyme in mouse lung. We have now studied the time course of these enzymatic changes in detail. Pulmonary PKC-alpha concentrations decreased as early as 45 min after an i.p. injection of 200 mg/kg BHT. Calpain II levels rose within the first 40 min after BHT injection, and then declined below control levels. The rapidity of these changes implies a role of these enzymes in mediating the onset of injury. Lung damage and repair, as estimated by measuring the lung weight/body weight ratio, is maximal 6 days after administration of this dose of BHT. The extent of the decreased PKC-alpha and calpain II concentrations at this time was linearly related to the estimated degree of injury based on increased lung weight. This correlation suggests the value of monitoring these enzymes as putative early biomarkers of alveolar injury.

Decreased content of the IL1 alpha processing enzyme calpain in murine bone marrow-derived macrophages after treatment with the benzene metabolite hydroquinone

Benzene is an important industrial chemical known to produce hematotoxicity in mice and humans. Hydroquinone, a major metabolite of benzene, inhibits conversion of the precursor form of IL1 alpha (pre-IL1 alpha) to IL1 alpha in murine bone marrow-derived macrophages in vitro, and a similar effect can be demonstrated in vivo after treatment of mice with benzene. The protease which converts pre-IL1 alpha to IL1 alpha is calpain. We examined decreases in calpain content in bone marrow-derived macrophages as a possible mechanism underlying hydroquinone-induced decreases in pre-IL1 alpha conversion. Hydroquinone, at concentrations which were not overtly cytotoxic, decreased total calpain activity in macrophages by 10-30%. Using immunoblot analysis macrophage calpain II levels were shown to be decreased by approximately 50% after treatment with hydroquinone. Under the same conditions, no changes were observed in calpain I content using immunoblot analysis. These data show that decreased calpain II content represents a potential mechanism of hydroquinone-induced inhibition of pre-IL1 alpha processing, and may contribute to benzene-induced alterations in bone marrow stromal cell function and myelotoxicity.

At least four genes and sex are associated with susceptibility to urethane-induced pulmonary adenomas in mice

Susceptibility to urethane-induced lung adenomas in mice has a polygenic mode of inheritance, with no obvious discontinuity in lung tumour counts among 37 AXB recombinant inbred strains. However, mean tumour counts were markedly higher in strains carrying the A/J allele at the Kras2 and H2 complex than in those carrying the C57BL/ allele. In 162 F2 hybrids and small numbers of both backcrosses between strain A/J (susceptible) and C57/BL/6 (resistant) mice, five factors influencing susceptibility were identified. Variation due to the 'major' Kras2 locus (chromosome 6) accounted for 60% of the total variation. 'Minor' loci linked to microsatellite markers Tnfb (in the H2 complex), D9Mit11 and D19Mit16 (on chromosomes 17, 9 and 19, respectively) accounted for a further 13% of the variation, and males had more tumours than females with sex differences accounting for 2% of the variation. No significant association with 32 other loci was detected. On a square-root transformed scale, heterozygotes at all marker loci were of intermediate susceptibility compared with homozygotes. The three minor loci and sex only affected lung tumour counts when at least one susceptible Kras2 allele was present.

Strain-related differences in the pneumotoxic effects of chronically administered butylated hydroxytoluene on protein kinase C and calpain

BALB/cBy (BALB) and CXB H mice responded similarly to a single intraperitoneal injection of butylated hydroxytoluene (BHT). This transient pneumotoxicity was characterized by an elevated lung weight and alveolar damage. These changes were accompanied by alterations in the calcium second messenger pathway, namely, two- to five-fold decreases in the activities and pulmonary content of protein kinase C alpha (PKC alpha) and calcium-dependent protease isozyme II (calpain II). BALB and CXB H mice varied in their responsiveness to a chronic (4-6 weekly injections) BHT regimen. CXB H mice became tolerant to BHT and all of the above parameters had returned to control values when examined after the last injection. Chronic BHT administration also failed to enhance lung tumor multiplicity in CXB H mice when the first BHT injection was preceded by the carcinogen, urethane. In contrast, the additional BHT doses potentiated the pathological and biochemical alterations in BALB mice above that found with acute treatment. This included a chronic inflammatory response characterized by the presence of activated macrophages, and a lung tumor multiplicity that was 3-fold greater than in BALB mice receiving urethane alone. One BHT injection increased calpain II mRNA in both strains (1.5- to 3-fold); mRNA declined following multiple BHT injections in BALB mice, but remained elevated in CXB H mice. Studies with the cytochrome P450 inhibitor, piperonyl butoxide, indicated that metabolism of BHT was required for both its acute and chronic effects. We conclude the following: (i) Differences between inbred mice in their susceptibility to chronic pneumotoxicant exposure may exist even when they respond similarly to an acute exposure of the same agent; (ii) A chronic inflammatory state involving a high concentration of activated macrophages may play an important role in tumor enhancement by a non-carcinogen; (iii) The protein contents of PKC alpha and calpain II decrease during BHT-induced lung damage.

Calpain activation in apoptosis

Programmed cell death is an active process wherein the cell initiates a sequence of events culminating in the fragmentation of its DNA, nuclear collapse, and disintegration of the cell into small, membrane-bound apoptotic bodies. Examination of the death program in various models has shown common themes, including a rise in cytoplasmic calcium, cytoskeletal changes, and redistribution of membrane lipids. The calcium-dependent neutral protease calpain has putative roles in cytoskeletal and membrane changes in other cellular processes; this fact led us to test the role of calpain in a well-known model of apoptotic cell death, that of thymocytes after treatment with dexamethasone. Assays for calcium-dependent proteolysis in thymocyte extracts reveal a rise in activity with a peak at about 1 hr of incubation with dexamethasone, falling to background at approximately 2 hr. Western blots indicate autolytic cleavage of the proenzyme precursor to the calpain I isozyme, providing additional evidence for calpain activation. We have also found that apoptosis in thymocytes, whether induced by dexamethasone or by low-level irradiation, is blocked by specific inhibitors of calpain. Apoptosis of metamyelocytes incubated with cycloheximide is also blocked by calpain inhibitors. These studies suggest a required role for calpain in both "induction" and "release" models of apoptotic cell death.

Calpain-induced downregulation of activated protein kinase C-alpha affects lung epithelial cell morphology

A few minutes after mouse lung epithelial cell lines were treated with 12-O-tetradecanoylphorbol-13-acetate (TPA), the cells rounded up and pulled away from their neighbors. Several hours later, the cells flattened out to resume their original morphology. To begin to characterize the enzymology underlying these changes, the subcellular distribution and intracellular content of the TPA receptor, protein kinase C (PKC), and its putative endogenous regulator, the Ca(2+)-dependent protease, calpain, were investigated. Of eight PKC isozymes examined in several tumorigenic and nontumorigenic cell lines, all cells contained PKC-alpha, PKC-delta, and PKC-zeta. TPA rapidly (5 min) translocated PKC-alpha from the cytosol to the particulate fraction; PKC-alpha concentrations then decreased with continued TPA exposure. PKC-zeta levels and intracellular location were not affected. An inhibitor of PKC activity, GF 109203X, prevented the initial morphological change. The calpain II isozyme was also found in all cell lines, and its cellular content increased as a result of TPA treatment. Calpain inhibitor I did not affect the initial shape change but prevented subsequent flattening of the cells. We therefore conclude that PKC activation is required for the TPA-induced alterations in lung cell morphology and that calpain mediates the return to a flattened epithelial appearance.

Metabolic activation of butylated hydroxytoluene by mouse bronchiolar Clara cells

Metabolism of BHT (2,6-di-tert-butyl-4-methylphenol) is requisite for its pneumotoxic activities. Previous evidence using microsomal preparations from livers and lungs of mice indicated that cytochrome P450-catalyzed hydroxylation of a tertbutyl group to form 6-tert-butyl-2-(hydroxy-tert-butyl)-4-methylphenol (BHTOH) is the first step in the bioactivation of this compound. Subsequent oxidation of BHTOH produces the quinone methide 6-tert-butyl-2-(hydroxy-tert-butyl)-4-methylene-2,5-cyclohexadienone (BHTOH-QM), and this highly reactive electrophile may be directly responsible for the pulmonary effects of BHT. The present study assessed the ability of intact bronchiolar Clara cells isolated from mice, a major site of pulmonary xenobiotic metabolism, to convert BHT to BHTOH-QM. The data demonstrate that BHTOH is, in fact, the principal oxidation product in these cells, and that a substantial portion of this metabolite is oxidized further to the quinone methide. BHTOH was found to be considerably more toxic to Clara cells than BHT, and both toxicity and metabolism were simultaneously depressed by the cytochrome P450 inhibitor SKF 525-A. These results strongly support the hypothesis that BHTOH-QM is the active metabolite that generates acute pneumotoxicity and modulates lung tumor formation.

Serine/threonine protein kinases and calcium-dependent protease in senescent IMR-90 fibroblasts

Three enzymes relevant to signal transduction were compared in replicating, quiescent and senescent human diploid fibroblasts (HDF). These were Ca(2+)-dependent thiol protease (calpain), cAMP-dependent protein kinase (Pk-A), and calcium/phospholipid-dependent protein kinase C (Pk-C). The amounts of these enzymes in quiescent HDF were slightly greater or the same as in replicating HDF. In contrast, senescent HDF exhibited higher Pk-C, Pk-A and proteolytic activities than did either replicating or quiescent cells. While the elevated protein kinase activities could be accounted for by the larger size of senescent cells relative to younger cells, the increased calpain activity exceeded this size differential. Immunoblotting studies with antisera to both Pk-C and calpain demonstrated increased enzyme concentrations in parallel with the increased activities. Photolabeling cell extracts with an analog of cAMP, 8-N3-[32P]cAMP, provides an estimate of Pk-A concentration. By this criterion, senescent HDF have more Pk-A molecules than do young cells that are either replicating or quiescent. Only the type I isozyme of Pk-A (Pk-A-I) was observed in any of these cells. Photolabeling with 8-N3-[32P]cAMP demonstrated more degradative fragments of the Pk-A regulatory subunit (RI) in senescent cells also. This is a logical consequence of the increased calpain activity in senescent cells, since RI is a substrate for calpain. These results imply that senescent cells do not fail to enter S phase owing to inadequate concentrations of Pk-A or Pk-C. Rather, the increased quantities of these enzymes in senescent cells may reflect aberrations elsewhere along signal transduction pathways that coordinate cell size with cell proliferation.

Gap junctional intercellular communication in mouse lung epithelial cell lines: effects of cell transformation and tumor promoters

Gap junctional intercellular communication (GJIC) is reduced by neoplastic transformation and treatment with tumor promoters in many types of cells but few data exist for the lung. GJIC was therefore evaluated in non-transformed (C10) and transformed (E9, 82-132, and PCC4) mouse lung epithelial cell lines and in C10 cells treated with tumor promoters. GJIC was assessed by fluorescent dye microinjection (dye-coupling). Dye-coupling levels were highest in C10 cells (85-90% communicating cells) followed by 82-132 cells (40-50%), E9 cells (15-20%), and PCC4 cells (3-10%). Indirect immunofluorescent staining with anti-gap junction protein (connexin) antibodies revealed that C10 cells expressed gap junctions comprised of connexin43, but not connexin32 or connexin26. The tumor promoters, butylated hydroxytoluene (BHT), 12-O-tetradecanoylphorbol-13-acetate (TPA), and p,p'-dichlorodiphenyltrichloroethane (DDT), inhibited dye-coupling in C10 cells but phenobarbital (PB) did not. BHT promotes mouse lung tumor formation, PB does not, while the effects of TPA and DDT on lung tumor development have not been reported. These data indicate that cell transformation and certain tumor promoters reduce GJIC in mouse lung epithelial cells and demonstrate correlations between the in vitro inhibition of GJIC and lung tumor promotion.

Altered dexamethasone responsiveness and loss of growth control in tumorigenic mouse lung cell lines

Glucocorticoid hormones induce differentiation, inhibit proliferation, and, in mice, reduce carcinogen-induced tumorigenesis of lung epithelial cells. Therefore we examined dexamethasone effects on tumorigenic and non-tumorigenic mouse lung epithelial-derived cell lines. Non-tumorigenic cells were growth inhibited and exhibited CAT activity in pMMTV-CAT transfectants in response to dexamethasone. Tumorigenic cell lines exhibited a range of responses to dexamethasone. While one tumorigenic line was growth-inhibited and responsive in CAT assays, 2 other tumorigenic cell lines were unresponsive both in CAT and in growth assays. A fourth tumorigenic cell line exhibited intermediate sensitivity in CAT assays and was actually growth-enhanced by dexamethasone. Although no difference between cell lines was observed in the abundance of glucocorticoid receptor protein on Western blots, the least dexamethasone-responsive tumorigenic lines exhibited very little binding of 3H-dexamethasone. Clones of tumorigenic lines stably transfected with the rat glucocorticoid receptor gene were more dexamethasone-sensitive in CAT assays and were growth-inhibited by dexamethasone. These data suggest that the neoplastic progression of cell lines derived from mouse lung frequently involves the acquisition of diminished glucocorticoid responsiveness.