The homeostatic mechanism for the respiratory system involves the tight control of expression of several gene products. One such gene is a member of the multi-substrate oxidase system called cytochrome P450 (P450). Pulmonary P450s may be involved in the tissue-specific detoxification, and/or bio-activation of chemical agents. Additionally, pulmonary cytochrome P450s, particularly the human iso-form 4B1, could play an important role in the development and homeostasis of the pulmonary tissue by removing androgens that cause deleterious effects on lung maturation. Human cytochrome P450 4B1 (CYP 4B1) is a predominant cytochrome P450 activity in the lung. CYP 4B1 protein is reported to bio-activate some pulmonary toxicants. Therefore it may mediate chemical-induced damage to that organ. However, the high expression levels of CYP 4B1 gene products in the lung (approximately 80% of the total P450 activity) may suggest the involvement of the iso-form in normal physiological functions for pulmonary tissue. On the other hand, the results of this and other laboratories have shown an apparent species-specific difference in the catalytic activity of 4B1 protein in man versus rodents. For instance, the rodent iso-form is potent at activating pro-carcinogens and devoid of androgen hydrolyzing activities towards androgen metabolism. The human 4B1 protein has higher 6-beta-testosterone hydroxylase activity while the rodent iso-form is devoid of this action. Furthermore, the manner in which the 4B1 gene is regulated appears to be species-specific. Therefore, my studies have been directed toward further defining the genetic mechanism of action that regulates the human 4B1 gene expression levels. My research objectives have been divided into three specific aims: to determine the presence or absence of cis-acting elements located in the 3.0 Kbp upstream fragment of the human 4B1 gene; to determine the DNA structure of the 4.5 Kbp fragment that overlaps and lies further upstream to the 3.0 Kbp regulatory region of the human 4B1 gene; and to determine the actions of a contiguous 6.5 Kbp fragment containing the entire putative upstream region of 4B1 gene on transcription of the luciferase reporter gene in human lung cells. The results of my studies show the presence of multiple promoter elements in addition to the TATA-box that are contained in the CYP 4B 13.0 Kbp upstream fragment. Nucleotide sequence analysis of the 4.5 Kbp upstream fragment that contains 1.0 Kbp overlapping fragment with the 3.0 Kbp fragment based on restriction mapping confirms that it is indeed part of the contiguous region of the CYP 4B1 gene. A number of consensus DNA regulatory motifs have been identified. (Abstract shortened by UMI.)

The Chinese hamster lung cell line DC-3F8/A55 has a 4,500-fold increase in resistance to methotrexate over the parental cell line DC-3F. Although DC- 3F8/A55 cells have a 4.5-fold increase in a mutant form of dihydrofolate reductase, this does not fully account for the high level of resistance to methotrexate. The purpose of this study is to determine the molecular basis for the inability of DC-3F8/A55 cells to accumulate methotrexate, and to identify the mechanism of transport of folate compounds in DC-3F8/A55 cells. This work has revealed that DC-3F8/A55 cells harbor a debilitating mutation to the reduced folate carrier gene, resulting in the loss of reduced folate carrier function. A nonsense mutation changes an arginine at amino acid 88 to a STOP codon, resulting in a non-functional protein. The parental cell line DC-3F is heterozygous at this locus, possessing one mutant and one wild-type allele of the RFC gene, thus retaining reduced folate carrier activity. These facts are supported by the kinetics of folate transport in both of these cell lines. The parental cell line DC-3F has a Kt for folinic acid of 10.69 +/- 0.67 muM and for methotrexate of 8.88 +/- 0.82 muM, values characteristic of a cell expressing a reduced folate carrier. DC-3F8/A55 cells were found to have a Kd for MTX of 3.16 +/- 1.03 nM, for folinic acid of 7.75 +/- 2.16 nM, and for folic acid of 1.42 +/- 0.54 nM. The high affinity of DC-3F8/A55 cells for folic acid, with a Kd for folic acid in the nM range, suggests that these cells are expressing a folate receptor. Northern blot analysis revealed a 1.6 kb transcript with low homology to FR-alpha and FR-gamma in DC-3F8/A55 cells. Overall, these studies suggest that the methotrexate transport-defective cell line DC-3F8/A55 expresses a previously unidentified folate receptor which may be a new member of the folate receptor family.