Aileen W. McLaren

Characterization of the Human Cytochrome P4502D6 Promoter A POTENTIAL ROLE FOR ANTAGONISTIC INTERACTIONS BETWEEN MEMBERS OF THE NUCLEAR RECEPTOR FAMILY

The functional mapping of the human cytochrome P4502D6 (CYP2D6) promoter in HepG2 cells revealed the presence of both positive and negative regulatory elements. One of these regulatory elements overlapped a sequence that is highly conserved in most members of the CYP2 family. This element, which consists of a degenerate AGGTCA direct repeat spaced by 1 base pair (DR1) and is known to be a target for members of the steroid receptor superfamily, was found to bind in vitro translated hepatocyte nuclear factor 4 (HNF4) in gel retardation analysis. Using HepG2 nuclear extracts, three protein-DNA complexes were formed on the DR1 element, one of which was confirmed to be dependent on the binding of HNF4. The other DR1 complexes were shown to be due to the interaction of the orphan receptor chicken ovalbumin upstream promoter transcription factor I (COUP-TFI). Experiments in COS-7 cells showed that HNF4 could activate the CYP2D6 promoter 30-fold. Surprisingly, mutation of the DR1 element produced a relatively minor 23% decrease in activity in HepG2 cells. Additionally, COUP-TFI was shown to inhibit HNF4 stimulation of the CYP2D6 promoter in COS-7 cells, suggesting that COUP-TFI could attenuate the effect of HNF4 in HepG2 cells. However, when HNF4 levels were increased in HepG2 cells by co-transfection, it resulted in the enhancement of CYP2D6 promoter activity, indicating that HNF4 could overcome the repressive effect of COUP-TFI. Therefore, the contribution of the DR1 element in controlling the transcription of the CYP2D6 gene depends on the balance between positively and negatively acting transcription factors.

Sp1-mediated transcriptional activation of the human Pi class glutathione S-transferase promoter.

Previous studies in this laboratory have identified an essential AP-1 recognition sequence (C1 region; −69 to −63) in the human Pi class glutathione S-transferase (GSTP1) promoter and a negatively acting regulatory element (−105 to −86) that acts to suppress GSTP1 transcription in the human mammary carcinoma cell line, MCF7(1). The data presented here further delineate the functional characteristics of the GSTP1 promoter by examining the significance of two potential binding sites for the transcription factor, Sp1 (−57 to −49 and −47 to −39). The introduction of mutations within these Sp1-like elements and the use of Sp1 antisera in electrophoretic mobility shift assays demonstrated that Sp1 was bound to this region of the GSTP1 promoter in three different cell lines, MCF7, VCREMS, and EJ. Moreover, these in vitro studies indicated that only one of the two putative Sp1 response elements was utilized. Transient transfection assays using GSTP1 promoter constructs that incorporated mutations of the Sp1 elements clearly demonstrated that binding of Sp1 to the GSTP1 promoter was absolutely required for optimal levels of GSTP1 transcription. In particular, disruption of the distal Sp1 recognition motif (−57 to −49) markedly reduced GSTP1 promoter activity in each cell line, thus indicating preferential binding of Sp1 to the distal site. However, insertion of the repressor binding site (−105 to −86) into these constructs suggested that Sp1 was not involved in mediating the suppressive effects of the GSTP1 transcriptional repressor in MCF7 cells, because inhibition of Sp1 binding did not alleviate repressor activity. Therefore, these studies provide strong evidence that Sp1 plays a central role in regulating basal levels of GSTP1 transcription.

Conditional Deletion of Cytochrome P450 Oxidoreductase in the Liver and Gastrointestinal Tract: A New Model for Studying the Functions of the P450 System

We have previously described a mouse model, where hepatic cytochrome P450 oxidoreductase (POR) expression has been deleted, resulting in almost complete ablation of hepatic P450 function [Hepatic P450 Reductase Null (HRN)]. HRN mice grow normally but develop fatty livers, and they have increased cytochrome P450 levels. Associated with the hepatic lipid accumulation are significant changes in the expression of genes controlling lipid homeostasis. We have characterized this model extensively and demonstrated its value in drug efficiency testing, in toxicokinetics, and in evaluating the role of the hepatic P450 system in drug pharmacokinetics. To extend the deletion of POR, and P450 inactivation, to other tissues, and to develop the utility of this model, we have generated a mouse where POR can be deleted conditionally in the liver and gastrointestinal tract using the rat cytochrome P450 CYP1A1 promoter to drive Cre recombinase expression. Administration of the CYP1A1 inducers tetrachlorodibenzo-p-dioxin or β-naphthoflavone resulted in both hepatic and gastrointestinal deletion of POR, whereas administration of 3-methylcholanthrene resulted specifically in loss of hepatic POR expression. In all cases, the resulting hepatic phenotype seemed identical to that of the HRN model, including increased cytochrome P450 expression. Hepatic deletion of POR and the subsequent increase in P450 expression were dependent on inducer dose, with maximal POR deletion occurring at a single dose of 3-methylcholanthrene of 40 mg/kg. This model provides a powerful approach for studying the functions of POR as well as in the evaluation of the role of hepatic and gastrointestinal P450s in drug deposition and chemical toxicity.

FUNCTIONAL CHARACTERIZATION OF THE TRANSCRIPTION SILENCER ELEMENT LOCATED WITHIN THE HUMAN PI CLASS GLUTATHIONE S-TRANSFERASE PROMOTER

We have previously demonstrated enhanced transcriptional activity of the human Pi class glutathione S-transferase (GSTP1) promoter in a multidrug-resistant derivative (VCREMS) of the human mammary carcinoma cell line, MCF7 (Moffat, G. J., McLaren, A. W., and Wolf, C. R. (1994) J. Biol. Chem. 269, 16397-16402). Furthermore, we have identified an essential sequence (C1; −70 to −59) within the GSTP1 promoter that bound a Jun-Fos heterodimer in VCREMS but not in MCF7 cells. These present studies have examined the negative regulatory element (−105 to −86), which acted to suppress GSTP1 transcription in MCF7 cells. Mutational analysis of this silencer element further defined the repressor binding site to be located between nucleotides −97 and −90. In vitro DNA binding assays suggested that the repressor exerted its action by causing displacement of the essential non-AP-1-like MCF7 C1 complex. However, the addition of MCF7 nuclear extract did not disrupt binding of the VCREMS Jun-Fos C1 complex to the GSTP1 promoter. Furthermore, upstream insertion of the GSTP1 silencer element failed to inhibit activity of a heterologous promoter in MCF7 cells. These results highlighted the cell and promoter specificity of the GSTP1 transcriptional repressor and implicated a functional requirement for contact between the repressor and C1 complex. In this regard, the introduction of half-helical turns between the silencer and the C1 element abrogated repressor activity, thus leading to the hypothesis that a direct interaction between the repressor and C1 complex was required to suppress GSTP1 transcription. Moreover, these findings suggest that cell-specific differences in the composition of the C1 nuclear complex may dictate repressor activity.

Knockout Mice in Xenobiotic Metabolism

Mice in which genes for drug metabolizing enzymes have been deleted or inactivated have great potential to further our understanding of the functions of these enzymes and their role in toxicology and disease. Our laboratory has worked for many years on the cellular adaptive response to stress and in particular in the involvement of these enzyme systems in the process of carcinogenesis. One of the major problems in working in this area is that of functional redundancy: many drug-metabolizing enzymes are members of multigene families, composed of structurally and functionally related proteins with wide and overlapping substrate specificities, such that the loss of a single enzyme may often be at least partially compensated for by another enzyme. This creates potential problems in the interpretation of phenotypes, and in delineation of the function of individual enzymes. Among phase I drug-metabolizing enzymes, several cytochrome P450 genes have been deleted over the past 10 years or so. Generally, these can be divided into two

In vivo regulation of human glutathione transferase GSTP by chemopreventive agents

Relatively little progress has been made in determining the in vivo regulation of glutathione S-transferase P (GSTP), particularly the human enzyme hGSTP1, despite being identified as a significant factor in carcinogenesis and development of drug resistance in tumor cell lines. Here, we report the characterization of a transgenic reporter mouse that reveals how hGSTP1 is regulated in vivo by chemopreventive agents. Basal expression was found in crypts and villi of the small and large intestine, bronchiolar epithelial cells, the epidermis and hair follicles, gall bladder epithelium, choroid plexus, and biliary epithelium. Expression was induced in different tissues by the antioxidant chemopreventive agents ethoxyquin and butylated hydroxyanisole. However, genetic deletion of the Nrf2 transcription factor, which directs central genetic programs of detoxification and protection against oxidative stress, increased rather than attenuated GSTP1 expression. In vitro investigations with mouse embryonic fibroblasts revealed factors, in addition to Nrf2, that control the expression of GSTP1, offering further insights into regulation. The new reporter mouse described here provides a useful tool to gain deeper insights into the mechanisms of action of chemopreventive compounds and other environmental agents.

Increased Skin Papilloma Formation in Mice Lacking Glutathione Transferase GSTP

The glutathione S-transferase GSTP is overexpressed in many human cancers and chemotherapy-resistant cancer cells, where there is evidence that GSTP may have additional functions beyond its known catalytic role. On the basis of evidence that Gstp-deficient mice have a comparatively higher susceptibility to skin carcinogenesis, we investigated whether this phenotype reflected an alteration in carcinogen detoxification or not. For this study, Gstp(-/-) mice were interbred with Tg.AC mice that harbor initiating H-ras mutations in the skin. Gstp(-/-)/Tg.AC mice exposed to the proinflammatory phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) exhibited higher tumor incidence and multiplicity with a significant thickening of skin after treatment, illustrating hyperproliferative growth. Unexpectedly, we observed no difference in cellular proliferation or apoptosis or in markers of oxidative stress, although higher levels of the inflammatory marker nitrotyrosine were found in Gstp(-/-)/Tg.AC mice. Instead, gene set enrichment analysis of microarray expression data obtained from skin revealed a more proapoptotic and proinflammatory environment shortly after TPA treatment. Within 4 weeks of TPA treatment, Gstp(-/-)/Tg.AC mice displayed altered lipid/sterol metabolism and Wnt signaling along with aberrant processes of cytoskeletal control and epidermal morphogenesis at both early and late times. In extending the evidence that GSTP has a vital role in normal homeostatic control and cancer prevention, they also strongly encourage the emerging concept that GSTP is a major determinant of the proinflammatory character of the tumor microenvironment. This study shows that the GSTP plays a major role in carcinogenesis distinct from its role in detoxification and provides evidence that the enzyme is a key determinant of the proinflammatory tumor environment.

Application of a novel regulatable Cre recombinase system to define the role of liver and gut metabolism in drug oral bioavailability.

The relative contribution of hepatic compared with intestinal oxidative metabolism is a crucial factor in drug oral bioavailability and therapeutic efficacy. Oxidative metabolism is mediated by the cytochrome P450 mono-oxygenase system to which cytochrome P450 reductase (POR) is the essential electron donor. In order to study the relative importance of these pathways in drug disposition, we have generated a novel mouse line where Cre recombinase is driven off the endogenous Cyp1a1 gene promoter; this line was then crossed on to a floxed POR mouse. A 40 mg/kg dose of the Cyp1a1 inducer 3-methylcholanthrene (3MC) eliminated POR expression in both liver and small intestine, whereas treatment at 4 mg/kg led to a more targeted deletion in the liver. Using this approach, we have studied the pharmacokinetics of three probe drugs – paroxetine, midazolam, nelfinavir – and show that intestinal metabolism is a determinant of oral bioavailability for the two latter compounds. The Endogenous Reductase Locus (ERL) mouse represents a significant advance on previous POR deletion models as it allows direct comparison of hepatic and intestinal effects on drug and xenobiotic clearance using lower doses of a single Cre inducing agent, and in addition minimizes any cytotoxic effects, which may compromise interpretation of the experimental data.