Alvin Gomez

Molecular genetics and epigenetics of the cytochrome P450 gene family and its relevance for cancer risk and treatment

The cytochromes P450 (CYPs) are very efficient catalysts of foreign compound metabolism and are responsible for the major part of metabolism of clinically important drugs. The enzymes are important in cancer since they (a) activate dietary and environmental components to ultimate carcinogens, (b) activate or inactivate drugs used for cancer treatment, and (c) are potential targets for anticancer therapy. The genes encoding the CYP enzymes active in drug metabolism are highly polymorphic, whereas those encoding metabolism of precarcinogens are relatively conserved. A vast amount of literature is present where investigators have tried to link genetic polymorphism in CYPs to cancer susceptibility, although not much conclusive data have hitherto been obtained, with exception of CYP2A6 polymorphism and tobacco induced cancer, to a great extent because of lack of important functional polymorphisms in the genes studied. With respect to anticancer treatment, the genetic CYP polymorphism is of greater importance, where treatment with tamoxifen, but also with cyclophosphamide and maybe thalidomide is influenced by CYP genetic variants. In the present review we present updates on CYP genetics, cancer risk and treatment and also epigenetic aspects of interindividual variability in CYP expression and the use of these enzymes as targets for cancer therapy. We conclude that the CYP polymorphism does not predict cancer susceptibility to any large extent but that this polymorphism might be an important factor for optimal cancer therapy using selected anticancer agents.

Expression of CYP2W1 in colon tumors: regulation by gene methylation.

INTRODUCTION CYP2W1 is a novel enzyme shown to be selectively expressed in rat fetal colon and in human colon cancer and has previously been suggested as a potential drug target for cancer therapy. Here, the expression and gene methylation of CYP2W1 were analyzed in human colon carcinoma cell lines, colon tumors and in corresponding normal colon tissue. METHODS CYP2W1 mRNA and protein expression in HepG2 and Caco-2TC7 cells and normal colon and colon tumor tissue samples were analyzed using real-time PCR and Western blotting. CYP2W1 gene methylation status in the same samples was analyzed using the sodium bisulfite sequencing method. RESULTS & DISCUSSION CYP2W1 mRNA was detected in all (n = 39) tumor samples analyzed. Moreover, in 60% (12/20) of the colon tumors, CYP2W1 mRNA levels were substantially higher than in corresponding normal tissues. CYP2W1 protein was detected in most of the colon tumor samples analyzed (n = 16), which appeared to be of two apparent phenotypes: those with five- to ten-fold induced CYP2W1 (approximately 50% of the tumors), and those with low expression, harboring similar or only slightly higher amounts of CYP2W1 as compared with surrounding control tissue. Methylation analysis of the CpG island in the exon 1-intron 1 junction of the CYP2W1 gene from both cell lines, tumors and normal tissues revealed that demethylated CpG dinucleotides appeared as a requirement for high CYP2W1 gene expression. CONCLUSION The expression of CYP2W1 is colon tumor-specific and is associated with methylation status of the CYP2W1 gene, suggesting a potential causal link between the gene hypomethylation and its enhanced expression.

Epigenetic and microRNA-dependent control of cytochrome P450 expression: a gap between DNA and protein

Although pharmacogenetics has been instrumental in describing interindividual variations in drug metabolism, epigenetic factors offer another blanket of information that could give a more vivid picture and help in developing a more personalized therapy. The dynamic aspect of epigenetics could likewise provide more definite answers to the role of changing environmental factors in drug response: the bridge that connects the environment to the genome. In this review we discuss known epigenetic and microRNA-dependent regulation of the human drug-metabolizing cytochromes P450 to help explain the unknown factors of variable drug response.

Allele-specific expression and gene methylation in the control of CYP1A2 mRNA level in human livers

The basis for interindividual variation in the CYP1A2 gene expression is not fully understood and the known genetic polymorphisms in the gene provide no explanation. We investigated whether the CYP1A2 gene expression is regulated by DNA methylation and displays allele-specific expression (ASE) using 65 human livers. Forty-eight percent of the livers displayed ASE not associated to the CYP1A2 mRNA levels. The extent of DNA methylation of a CpG island including 17 CpG sites, close to the translation start site, inversely correlated with hepatic CYP1A2 mRNA levels (P=0.018). The methylation of two separate core CpG sites was strongly associated with the CYP1A2 mRNA levels (P=0.005) and ASE phenotype (P=0.01), respectively. The CYP1A2 expression in hepatoma B16A2 cells was strongly induced by treatment with 5-aza-2′-deoxycytidine. In conclusion, the CYP1A2 gene expression is influenced by the extent of DNA methylation and displays ASE, mechanisms contributing to the large interindividual differences in CYP1A2 gene expression.

The past, present and future of pharmacoepigenomics.

A significant number of instances of interindividual variability in drug response, where a clear phenotypic consequence is evident in the population, have not yet been associated with variations in gene sequence. Epigenetics, along with, for example, drug interactions and disease, provides answers to some of these inconsistencies. The role of epigenetics in drug response has just started to be perceived, but its impending influence on drug metabolism and disposition promises to be important. Research in this area can provide us with novel mechanisms for this variation and also with novel biomarkers that can be useful for understanding drug response, as well as for the development of new drugs and which can, in addition, constitute predictive biomarkers for todays and tomorrows pharmacotherapy, yielding a substantial improvement in human health.

Colorectal cancer-specific cytochrome P450 2W1: intracellular localization, glycosylation, and catalytic activity.

Cytochrome P450 2W1 (CYP2W1) is expressed at high levels in colorectal cancer cells. Moreover, we have shown previously that a higher tumor expression is associated with less survival. In this study, we characterize post-translational modification, inverted endoplasmic reticulum (ER) topology, and catalytic activity of CYP2W1. The analysis of colorectal normal and cancer tissues and CYP2W1 overexpressing human embryonic kidney (HEK) 293 cells showed that a fraction of CYP2W1 is modified by N-glycosylation. Bioinformatic analysis identified Asn177 as the only possible glycosylation site of CYP2W1, which was supported by the inability of an N177A mutant to be glycosylated in HEK 293 cells. Analysis of the membrane topology indicated that unlike other cytochromes P450, CYP2W1 in HEK 293-transfected cells and in nontransfected Caco2TC7 and HepG2 cells is oriented toward the lumen of the ER, a topology making CYP2W1 available to the ER glycosylation machinery. Immunofluorescence microscopy and cell surface biotinylation experiments revealed approximately 8% of the CYP2W1 on the cell surface. Despite the reverse orientation of CYP2W1 in the ER membrane, apparently making functional interactions with NADPH-cytochrome P450 reductase impossible, CYP2W1 in HEK 293 cells was active in the metabolism of indoline substrates and was able to activate aflatoxin B1 into cytotoxic products. The study identifies for the first time a cytochrome P450 enzyme with a luminal ER orientation and still retaining catalytic activity. Together, these results suggest the possibility of using CYP2W1 as a drug target in the treatment of colon cancer using antibodies and/or specific CYP2W1 activated prodrugs.

Pharmacoepigenetic aspects of gene polymorphism on drug therapies: effects of DNA methylation on drug response

Our knowledge of epigenetics has increased in recent times and its role in various aspects of cellular physiology and disease cannot be overemphasized, even though many issues still need to be clarified. The role of epigenetics in drug therapy is one aspect that necessitates more work. Although a few epigenetic drugs are already being used clinically and others are being developed for such use, other aspects of drug therapy that are affected by epigenetic alterations need to be considered. We want to emphasize the role of environment as an important factor that modifies the epigenome, creating variation among individuals and that can ultimately affect how they respond to drug therapy. The numerous gene products that are being utilized as drug targets can likewise be affected epigenetically and would thus require special attention.