Nau Mm

jun-B inhibits and c-fos stimulates the transforming and trans-activating activities of c-jun

We have cloned the human jun-B gene and determined its sequence and transforming and trans-activating activities. jun-B is less potent that c-jun in transforming and immortalizing primary rat embryo cells in cooperation with activated ras (effects enhanced by c-fos and TPA); unlike c-jun, jun-B does not transform Rat-1A cells alone. However, cotransfection of c-jun and jun-B into primary rat embryo cells with c-Ha-ras results in a significant decrease in transformation compared with c-jun alone, an event reversed by TPA. Cotransfection of c-jun and jun-B with or without c-fos into F9 teratocarcinoma cells results in decreased trans-activation of AP-1 compared with either gene alone. Introduction of jun-B into primary rat c-jun/ras transformants or c-jun into jun-B/ras transformants also results in a decrease in trans-activation. These findings demonstrate that, whereas jun-B and c-jun each participate in AP-1 trans-activation and malignant transformation, interactions between them involve negative regulation.

Multiple mechanisms for transcriptional regulation of the myc gene family in small-cell lung cancer

The molecular mechanisms reported to regulate the expression of myc family genes are multiple and complex and include gene amplification, transcriptional activation, transcriptional attenuation, and mRNA stability. We have investigated which of these mechanisms are responsible for the extreme variation in myc gene family mRNA levels observed in human small-cell lung cancer cell lines. In addition to gene amplification, a block to nascent mRNA chain elongation, causing attenuation of transcription, is an important regulatory mechanism controlling the steady-state levels of c-myc and L-myc mRNA. The loss of transcriptional attenuation is correlated with overexpression of these two genes in cell lines which do not show gene amplification. Expression of c-myc mRNA appears to be dependent on promoter activity and attenuator function. In contrast, regulation of expression of the N-myc gene does not involve transcriptional attenuation; steady-state mRNA levels are correlated with promoter activity as well as gene amplification. We conclude that transcriptional regulation of each member of the myc gene family is accomplished by a different assortment of complex mechanisms, including gene copy number, promoter activation, and transcriptional attenuation. Interference at multiple points in this complex regulatory process appears to be an important mechanism by which small-cell lung cancer and other human tumors evade growth control.

Structure and expression of the human L-myc gene reveal a complex pattern of alternative mRNA processing.

We analyzed in detail the structure of the L-myc gene isolated from human placental DNA and characterized its expression in several small-cell lung cancer cell lines. The gene is composed of three exons and two introns spanning 6.6 kilobases in human DNA. Several distinct mRNA species are produced in all small-cell lung cancer cell lines that express L-myc. These transcripts are generated from a single gene by alternative splicing of introns 1 and 2 and by use of alternative polyadenylation signals. In some mRNAs there is a long open reading frame with a predicted translated protein of 364 residues. Amino acid sequence comparison with c-myc and N-myc demonstrated multiple discrete regions with extensive homology. In contrast, other mRNA transcripts, generated by alternative processing, could encode a truncated protein with a novel carboxy-terminal end.

Molecular Genetic Analysis Reveals Chromosomal Deletion, Gene Amplification, and Autocrine Growth Factor Production in the Pathogenesis of Human Lung Cancer

These studies of lung cancer suggest that a number of molecular mechanisms may be important in the pathogenesis of lung cancer, especially SCLC. An inherited predisposition to develop SCLC may correlate with a nonfunctional, recessive allele for a gene (McKusick #18228, McKusick 1986) that maps to chromosome region 3p(14-23). Individuals at risk would be heterozygous for this allele in their germ line, carrying one copy of a normal functional gene and one mutant, recessive allele. Exposure to carcinogens, in particular cigarette smoke, can produce somatic genetic changes such as chromosomal deletion or gene mutation in the functional allele of this gene, unmasking the nonfunctional allele. Loss of this normal gene may alter the regulation of cell growth, perhaps by allowing the deregulated expression of proto-oncogenes of the myc family, or autocrine growth factors such as GRP and/or its receptor. Alternatively, loss of this gene may result in the cell returning to a less differentiated developmental state where growth regulation is less stringent. Persons with this mutant gene should be at increased risk to develop SCLC, and further RFLP analysis of the 3p region in SCLC may allow identification of specific haplotypes with increased risk of developing lung cancer. If this notion is correct, one might expect to find an increased frequency of second tumors in lung cancer patients and the presence of similar chromosomal deletions in second tumors arising in SCLC patients. In this regard, cured lung cancer patients, including those with SCLC, have a tenfold increased risk of developing a second lung cancer (Fontana 1977; Cortese et al. 1983; Johnson et al. 1986b). In fact, a chromosome 3p deletion along with other chromosomal abnormalities was identified in acute erythroleukemia cells arising in a long-term survivor of SCLC (Bradley et al. 1982), implicating this same region in the pathogenesis of both tumors. Other predictions include the correction of at least a portion of the defect by introducing a normal chromosome 3 into SCLC cells. While c-myc is expressed in many fetal and adult tissues, high-level expression of N- and L-myc is very restricted as to tissue and stage in the developing mouse, with N-myc expressed in the fetal but not adult lung, whereas the lung was the only adult tissue where L-myc expression was detected (Zimmerman et al. 1986). Could these patterns provide a clue to the differential expression of c-, N-, and L-myc found in different lung cancers (Nau et al. 1986)?(ABSTRACT TRUNCATED AT 400 WORDS)

4 – Molecular Pathogenesis of Lung Cancer

Lung cancer is the largest cancer killer of men and women in the world. In addition to the progress made from antismoking primary prevention measures, new tools to help treat patients with lung cancer are emerging from the rapid advances in knowledge of the molecular pathogenesis of lung cancer. These tools include molecular and cellular biology and are starting to provide an insight into how the tumor cells, by altering oncogenes and tumor suppressor genes, achieves growth advantage, uncontrolled proliferation and metastatic behavior via disruption of key cell-cycle regulators and signal transduction cascades. These tools are being translated into clinical strategies to complement surgery, radiotherapy, and chemotherapy and also to assist in primary and secondary prevention efforts. From the current knowledge of the molecular pathogenesis of lung cancer we know that respiratory epithelial cells require many genetic alterations to become invasive and metastatic cancer.