Transition from SCLC to NSCLC phenotype is accompanied by an increased TRE-binding activity and recruitment of specific AP-1 proteins.

Transitions from small cell (SCLC) to non-small cell lung cancer (NSCLC) cells have been documented both in vitro and in vivo and are thought to be an important step during tumor progression of human small cell lung cancer towards a treatment-resistant tumor state. We have screened NSCLC and SCLC cell lines for differences in the composition of nuclear transcription factors using consensus oligonucleotide sequences (SRE, Ets, TRE, CRE, B-motif, GAS, E-box). We found NSCLC cells to exhibit significantly higher AP-1 binding activity than SCLC cells consistent with the increased expression of CD44, an AP-1 target gene. To gain more insight into the molecular mechanisms underlying these differences, we analysed SCLC cell lines (NCI-N592 and NCI-H69) which were phenotypically transformed into NSCLC-type cells by transfection with activated H-ras and c-myc oncogenes. In these cells, ras-induced transition is accompanied by a strong induction of AP-1-binding activity along with increased expression of CD44 mRNA and protein. When analysing the composition of the AP-1 complex in more detail and comparing ras-induced versus phorbol ester-induced changes, we found Fra-1 to be the major component induced in ras-transfected but not in phorbol-ester treated or non-treated parental SCLC cells. This finding is paralleled by the observation that among the various members of the Fos and Jun family analysed (c-Fos, FosB, Fra-1, Fra-2, c-Jun, JunD, JunB) fra-1 is the only gene to be exclusively expressed in NSCLC cells but not in cells of SCLC origin. Our data, thus, point to a histiotype-related mechanism of recruitment among AP-1 proteins which may have bearings on the fate of lung cancer development.

Control of proteinase expression by phorbol-ester- and Fos-dependent pathways in human non-small-cell lung-cancer cells.

Activation of protein kinase C- (PKC) and Fos/Jun-dependent signal transduction pathways are thought to be major effects of oncogene action in different tumor systems including human non-small-cell lung carcinoma (NSCLC). We have previously shown that the phorbol ester analogue phorbol-myristate-acetate (PMA), which is a potent activator of PKC, can induce squamous-type cellular differentiation and the expression of proteinases, such as plasminogen activators and pro-cathepsin L, in several NSCLC cell lines. To investigate the PMA-dependent effect on proteinase secretion in more detail, we have now analysed the role of a downstream transmitter of PKC activity in this process, namely Fos, which is part of the AP-1 transcription factor in the nucleus. We transfected a cell line derived from an undifferentiated squamous-cell lung carcinoma with different chimeric fos-estrogen receptor constructs (fos-ER) which makes selective activation of this transcription factor possible. The resulting clones were treated either with PMA as activator of PKC, or with diethylstilbestrol (DES), an estrogen analogue binding to and thereby activating preformed Fos-ER molecules. We show that cells treated with either substance undergo similar phenotypic changes (change from cuboidal to spindle-cell type) and decrease their doubling rates and cloning efficiencies. This is paralleled by the induction of several proteinase genes such as t-PA, urokinase, and pro-cathepsins B and L. Contrary to activated PKC, Fos in this system seems to be unable to initiate terminal squamous-cell differentiation, as assessed by the production of cornified envelopes. It is, however, efficient in the stimulation of neutral or lysosomal proteinase secretion as determined by Western-blot analysis and zymography. This Fos-ER expressing system thus seems to be a valuable tool in the molecular dissection of pathways that lead to the activation and secretion of proteinases in NSCLC cells.