Victoria H. Brophy

Paraoxonase (PON1) Phenotype Is a Better Predictor of Vascular Disease Than Is PON1192 or PON155 Genotype

The paraoxonase (PON1) PON1-Q192R and PON1-L55M polymorphisms have been inconsistently associated with vascular disease. Plasma PON1 activity phenotypes vary markedly within genotypes and were, therefore, expected to add to the informativeness of genotype for predicting vascular disease. The case-control sample included 212 age- and race-matched men (mean age 66.4 years). The 106 carotid artery disease (CAAD) cases had >80% carotid stenosis, and the 106 controls had <15%. Two PON1 substrate hydrolysis rates (paraoxon [POase] and diazoxon [DZOase]) were significantly lower in cases than in controls and were significant predictors of CAAD by use of logistic regression (POase, P =0.005; DZOase, P =0.019). DZOase predicted vascular disease independently of lipoprotein profile, high density lipoprotein subfractions, apolipoprotein A-I, and smoking. PON1-192 and PON1-55 genotypes or haplotypes did not predict case-control status unless the activity phenotype was also included as a predictor by use of logistic regression. When phenotype was included as a predictor, PON1-192 and PON1-55 genotypes or combined haplotypes were significant predictors (P <0.05). In conclusion, examining PON1-192 and/or PON1-55 genotypes alone may mistakenly lead to the conclusion that there is no role of PON1 in CAAD. These results support the benefit of a “level crossing” approach that includes intervening phenotypes in the study of complexly inherited disease.

Vitamin C and E Intake Is Associated With Increased Paraoxonase Activity

Objective—Paraoxonase (PON1), an esterase physically associated with high density lipoprotein, has been shown to inhibit atherogenic low density lipoprotein and high density lipoprotein oxidation. PON1 activity appears to be primarily under genetic control with some environmental modification and is a predictor of vascular disease. Vitamins C and E, dietary antioxidants, scavenge free-oxygen radical products that may depress PON1 activity. Therefore, we evaluated the relationship between dietary vitamin C and E intake and PON1 activity. Methods and Results—The vitamin C and E intakes of male white subjects (n=189) were estimated by using a standardized food frequency survey. With covariates, vitamin C or E intakes were found to be significant positive predictors of PON1 activity for the hydrolysis of paraoxon and diazoxon with the use of linear regression. Smoking and use of statins were independent predictors of PON1 activity. Conclusions—PON1 activity, which is primarily genotype dependent, varies with antioxidant vitamins, cigarette smoking, and statin drug use. Because PON1 activity is a better predictor of vascular disease than is the currently described genetic variation in PON1, further studies of the environmental influences on PON1 activity and additional PON1 genetic variants are warranted.

Polymorphisms in the human paraoxonase (PON1) promoter

Paraoxonase (PON1) is a protein component of high-density lipoprotein (HDL) particles that protects against oxidative damage to both low-density lipoprotein and HDL and detoxifies organophosphorus pesticides and nerve agents. A wide range of expression levels of PON1 among individuals has been observed. We examined the promoter region of PON1 for genetic factors that might affect PON1 activity levels. We conducted a deletion analysis of the PON1 promoter region in transient transfection assays and found that cell-type specific promoter elements for liver and kidney are present in the first 200bp upstream of the coding sequence. Sequence analysis of DNA from a BAC clone and a YAC clone identified five polymorphisms in the first 1000 bases upstream of the coding region at positions -108, -126, -162, -832 and -909. Additionally, the promoter sequences of two individuals expressing high levels of PON1 and two individuals expressing low levels of PON1 were analysed. The two polymorphisms at -126 and -832 had no apparent effect on expression level in the reporter gene assay. The polymorphisms at position -909, -162 (a potential NF-I transcription factor binding site) and -108 (a potential SP1 binding site) each have approximately a two-fold effect on expression level. The expression level effects of the three polymorphisms appear not to be strictly additive and may depend on context effects.

Paraoxonase Activity, But Not Haplotype Utilizing the Linkage Disequilibrium Structure, Predicts Vascular Disease

Objective—The effects of paraoxonase (PON1) activity and of genetic variation in the PON1 promoter and coding region on carotid artery disease (CAAD) were investigated. Methods and Results—We identified functional promoter polymorphisms and examined their effects in a cohort with and without CAAD. We used the full sequences in 23 white subjects to determine the linkage disequilibrium (LD) structure of the PON1 region and to direct the grouping of haplotypes for disease association testing. There are several discrete regions of the PON1 gene with strong local LD, but the useful levels of LD do not extend across the entire gene. Indeed, PON1−162/−108/55/192 haplotype did not predict additional variation in PON1 activities compared with the 4 genotypes separately. PON1 hydrolysis activity predicted CAAD status, but this was not attributable to the promoter or coding region polymorphisms or haplotype or to the effects of smoking or statin use on PON1 activity. Conclusions—PON1 does not have LD across the gene, and use of haplotypes in association studies should consider the LD structure. PON1 activity predicts CAAD, yet 4 functional polymorphisms do not. Additional investigations of genetic and environmental factors that influence PON1 activity as a risk factor for vascular disease are warranted.

Analysis of paraoxonase (PON1) L55M status requires both genotype and phenotype.

Paraoxonase (PON1) is tightly associated with high-density lipoprotein particles and is believed to contribute to the prevention of atherosclerosis by metabolizing oxidized lipids. PON1 also hydrolyses the bioactive oxon forms of organophosphorus pesticides such as parathion, diazinon and chlorpyrifos. Two common polymorphisms have been identified in the coding sequence of human PON1: L55M and R192Q. Several previous studies have found that the presence of the PON1R192 allele raises the risk of cardiovascular disease while others found no correlation. The studies, however, have focused on the genotype of PON1 and not the expression level of the protein. We found that the PON1 expression level in plasma, as determined by the rates of paraoxon and diazoxon hydrolysis, varies widely among individuals and within a genotype. Previous studies found that individuals having Met at PON155 have lower levels of both PON1 mRNA and activity. In this study, we determined the plasma activity levels of PON1 and examined the relationships between PON155 genotype and PON1 level. As with PON1192, we found considerable overlap in activity among the PON155 genotypes. Of the 317 individuals whose PON1 status was determined in this study, 48.9% were PON1Q192 homozygotes. Analysis of the PON1QQ192 population showed that while the average PON1 activity (diazoxon hydrolysis) was 12266 U/L for PON1LL55 and 7777 U/L for PON1MM55, a given PONMM55 individual could have more than twice the activity of a PON1LL55 individual. PON1 status, which includes PON1 level as well as PON1192 genotype, may be a better predictor for cardiovascular disease or organophosphate susceptibility than PON1 genotype alone.

Identification of Cryptosporidium parvum Dihydrofolate Reductase Inhibitors by Complementation in Saccharomyces cerevisiae

ABSTRACT There is a pressing need for drugs effective against the opportunistic protozoan pathogen Cryptosporidium parvum. Folate metabolic enzymes and enzymes of the thymidylate cycle, particularly dihydrofolate reductase (DHFR), have been widely exploited as chemotherapeutic targets. Although many DHFR inhibitors have been synthesized, only a few have been tested against C. parvum. To expedite and facilitate the discovery of effective anti-Cryptosporidium antifolates, we have developed a rapid and facile method to screen potential inhibitors of C. parvum DHFR using the model eukaryote, Saccharomyces cerevisiae. We expressed the DHFR genes of C. parvum, Plasmodium falciparum, Toxoplasma gondii, Pneumocystis carinii, and humans in the same DHFR-deficient yeast strain and observed that each heterologous enzyme complemented the yeast DHFR deficiency. In this work we describe our use of the complementation system to screen known DHFR inhibitors and our discovery of several compounds that inhibited the growth of yeast reliant on the C. parvum enzyme. These same compounds were also potent or selective inhibitors of the purified recombinantC. parvum DHFR enzyme. Six novel lipophilic DHFR inhibitors potently inhibited the growth of yeast expressing C. parvumDHFR. However, the inhibition was nonselective, as these compounds also strongly inhibited the growth of yeast dependent on the human enzyme. Conversely, the antibacterial DHFR inhibitor trimethoprim and two close structural analogs were highly selective, but weak, inhibitors of yeast complemented by the C. parvum enzyme. Future chemical refinement of the potent and selective lead compounds identified in this study may allow the design of an efficacious antifolate drug for the treatment of cryptosporidiosis.

Efficacies of Lipophilic Inhibitors of Dihydrofolate Reductase against Parasitic Protozoa

ABSTRACT Competitive inhibitors of dihydrofolate reductase (DHFR) are used in chemotherapy or prophylaxis of many microbial pathogens, including the eukaryotic parasites Plasmodium falciparum andToxoplasma gondii. Unfortunately, point mutations in the DHFR gene can confer resistance to inhibitors specific to these pathogens. We have developed a rapid system for testing inhibitors of DHFRs from a variety of parasites. We replaced the DHFR gene from the budding yeast Saccharomyces cerevisiaewith the DHFR-coding region from humans, P. falciparum,T. gondii, Pneumocystis carinii, and bovine or human-derived Cryptosporidium parvum. We studied 84 dicyclic and tricyclic 2,4-diaminopyrimidine derivatives in this heterologous system and identified those most effective against the DHFR enzymes from each of the pathogens. Among these compounds, six tetrahydroquinazolines were effective inhibitors of every strain tested, but they also inhibited the human DHFR and were not selective for the parasites. However, two quinazolines and four tetrahydroquinazolines were both potent and selective inhibitors of the P. falciparum DHFR. These compounds show promise for development as antimalarial drugs.

Expression of CD14 corrects the slow response to lipopolysaccharide in the 1B8 mutant of the B cell lymphoma 70Z/3

Abstract B cells and macrophages both activate NF-κB/Rel in response to lipopolysaccharide (LPS), but differ in sensitivity to LPS and in downstream genes that are activated. CD14 is a high-affinity receptor for LPS found on macrophages, but not B cells. We expressed human CD14 (hCD14) in the mouse B lymphoma, 70Z/3, and a mutant, 1B8, which responds slowly to LPS, to test whether expression of hCD14 could correct or bypass the defect in 1B8 cells. We compared the timing and extent of known responses to LPS in 70Z/3 cells and the 1B8 mutants. The hCD14+ 1B8 and 70Z/3 cells responded more rapidly and were sensitive to 100-fold lower levels of LPS than their untransfected counterparts. Degradation of the IκB-α and -β molecules and translocation of the NF-κB/Rel complexes into the nucleus were more rapid and the steady-state levels of Igk mRNA and mIgM on the cell surface were markedly increased in cells that expressed hCD14. The LPS response of the hCD14+ 1B8 and 70Z/3 cells showed subtle differences. In the 1B8 hCD14 cells, the p50/p50 complexes were never abundant in nuclear extracts, and degradation of IκB-β was slower than in hCD14 70Z/3 cells. This partial correction of the 1B8 phenotype suggests that the defective component in 1B8 participates in the CD14 signaling pathway and could include the B-cell LPS receptor itself.