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Research Article

Materials and Methods Top

Subjects and recruitment

Pregnant women (n = 130) and their newborns (n = 130) were randomly selected from the CHAMACOS (Center for the Health Assessment of Mothers and Children of Salinas) cohort, a longitudinal birth cohort study of the effects of pesticides and other environmental exposures on the health of pregnant women and their children living in the Salinas Valley, California. Women were eligible for enrollment in the CHAMA-COS study if they were ≥ 18 years of age, < 20 weeks’ gestation at enrollment, English- or Spanish-speaking, Medi-Cal eligible, and planning to deliver at the Natividad Medical Center (Bradman et al. 2005; Eskenazi et al. 2003, 2004; Young et al. 2005). All women in the subcohort described here were representative of the CHAMACOS cohort; they were Latina by ethnicity, including 85% born in Mexico and the remainder in the United States. Most of the participants never smoked (> 92%), had relatively high pesticide exposures based on diethyl phosphate urinary metabolites (median, 20 nmol/L; range, 7–560 nmol/L), and worked in agriculture during pregnancy (39%). Fathers were more likely to smoke (11%) and work in agriculture (72%) than were mothers. Study protocols were approved by the University of California, Berkeley, and the University of Washington human-subject review committees in compliance with all applicable requirements. Written informed consent was provided by all subjects.

Biologic samples collection and processing

We collected blood from mothers at the time of their glucose tolerance test (26.1 ± 2.3 weeks) and in the hospital shortly before or after delivery. Blood samples were also collected from the umbilical cords by delivery room staff once the baby was safely delivered. Heparinized whole blood was centrifuged, divided into plasma, buffy coats, and red blood cells, and then stored at −80°C. BD Vacutainers (Becton Dickinson, Franklin Lakes, NJ) without anticoagulant were used to collect serum and clot. Processed plasma samples were stored at −80°C before being shipped on dry ice to the University of Washington, Seattle, for analysis of enzyme activity.

DNA was isolated from blood clots. Blood clots thawed in a 37°C water bath were first mechanically disrupted using ClotSpin tubes (Gentra Systems Inc., Minneapolis, MN). The Qiagen protocol (Qiagen Inc., Santa Clarita, CA) was slightly modified by prolonging the initial lysis and protease digestion step to overnight incubation. DNA concentration was measured using PicoGreen (Molecular Probes Inc., Eugene, OR), adjusted to 10 ng/μL, plated in 96-well plates, and stored at −80°C. Samples were transferred to 384-well plates for analysis of multiple SNPs, using robotic equipment to avoid manual pipetting errors and for time efficiency.

PON1 genotyping

Genotyping was conducted by the University of California, Berkeley, and Children’s Hospital Research Institute Genotyping Core. Taqman real-time polymerase chain reaction method was used for genotyping of the −162 _AG , 55 _LM , and 192 _QR polymorphisms. Briefly, primers for these SNPs were custom designed by Applied Biosystems Inc. (Foster City, CA). Amplifluor allele-specific primers were used for genotyping of −909 _CG and −108 _CT . Genotype calling was performed either manually using a spreadsheet (Chemicon AssayAuditor, for real-time data) or by automatic allele calling in SDS 2.1 (Applied Biosystems, for end-point data).

Quality assurance procedures included assessment of randomly distributed blank samples in each plate, duplicates of randomly selected samples with independently isolated DNA from the same subjects, and internal controls. Repeated analysis in several runs showed a high degree (96.5%) of concordance, and the most robust call was selected in the case of discordance (3.5%). Furthermore, the assays were repeated for all low-confidence samples until a reliable call was obtained, using a combination of the TaqMan and Amplifluor methods for a subset of samples. Additional analysis was performed independently at the University of Washington for 10% of the DNA samples for the 192 _QR polymorphism by standard polymerase chain reaction method (details given by Richter et al. 2004) with approximately 95% concordance; all discrepancies were resolved by repeated runs. Quality control software was used to check data for Mendelian errors, and if those were noted, the whole run was repeated.

Enzyme assays

Plasma was frozen at −80°C until analysis. We measured three PON1 enzyme activities in plasma from mothers and children, using paraoxonase (POase), chlorpyrifos oxonase (CPOase), and phenylacetate arylesterase (AREase) according to published protocols (Jarvik et al. 2003; Richter and Furlong 1999; Richter et al. 2004). We used PON1 plasma levels (AREase assay) to analyze the genetic effect because, unlike POase and CPOase levels, they are not affected by differential catalytic efficiency primarily controlled by the PON1 ₁₉₂ SNP and have been shown to correspond with PON1 levels determined by immunologic methods (Blatter-Garin et al. 1994; Furlong et al. 1993). Together, these three assays provide comprehensive information about PON1 enzyme activities regarding different substrates. Assessment of PON1 activities in mothers was first conducted for 25 pregnant women at two different time points, at 26 weeks and at delivery. PON1 activities were not statistically different between the two time points for all three PON1 enzyme assays (r = 0.77–1.0, p < 0.0001). Therefore, we performed analyses of AREase, POase, and CPOase in the remainder of 105 Latina mothers at one time point only—at 26 weeks’ gestation. Children in the study were of both sexes, and girls represented 54%. No sex differences in PON1 enzyme levels or genotypes were observed, as is consistent with the available PON1 literature (Costa et al. 2002).

Statistical analysis

Standard analyses for all genotype data included analysis for Hardy-Weinberg equilibrium, pairwise linkage disequilibrium (LD), and haplotype assignment using algorithms implemented in the publicly available Haploview software (Battett et al. 2005), including PYPOP (Lancaster et al. 2003), tagSNPs (Stram et al. 2003), and PHASE (Stephens et al. 2001, 2003). The LD statistic D′ was calculated for each pair of five PON1 SNPs, and R² values were used to describe the haplotype structure of the PON1 gene in our Latino cohort. PYPOP, tagSNPs, and PHASE software methods showed similar results. We used PHASE to generate the data reported in this article, because it has been shown to reduce error rates in haplotype reconstruction compared with the expectation maximization algorithm (Stephens and Donelly 2003).

Subjects were grouped according to their imputed diplotypes (Chen et al. 2005). When more than one diplotype was possible for an individual, only the most likely imputed haplotypes were used in this analysis. The distributions and descriptive statistics were established separately for each of the three PON1 enzyme assays in mothers and in their newborns for each of the five SNPs. The distributions of enzyme activities were approximately normal. Linear regression and backward regression models were used to determine whether the additional information for all five polymorphisms altered the effect of genotype on enzyme activity. Coefficients of determination (total R²) were calculated for the proportion of variability in PON1 plasma levels explained by the five SNP genotypes (used as ordinal variables) and by imputed haplotypes. Each haplotype with > 5% frequency was coded as a variable in the linear regression model, where the values 0, 1, or 2 denoted the presence of zero, one, or two copies of the haplotype for a subject. Haplotypes with < 5% frequency were pooled into one group for this analysis. All analyses were conducted in STATA software (version 8.0; StataCorp., College Station, TX) and SAS software (version 9.1; SAS Institute Inc., Cary, NC).

Results Top

PON1 polymorphisms

PON1 gene frequencies were established for two coding polymorphisms (PON1 ₁₉₂ and PON1 ₅₅ ) and three promoter region polymorphisms (PON1_{− 909} , PON1_{− 162} , PON1_{− 108} ) (Table 1). As expected, the five polymorphisms had similar allelic frequencies in 130 pregnant Latina women of Mexican descent and their newborns. All genotypes were consistent with Hardy-Weinberg equilibrium (data not shown). The SNPs at position PON1_{− 162} of the promoter region and PON1 ₅₅ in the coding region had lower variant allele frequencies (−162 A, 55 M) than did the major allele, whereas the other three polymorphisms (PON1_{− 909} , PON1_{− 108 ,} and PON1 ₁₉₂ ) had approximately equal presence of both alleles in this population. Specifically, the frequencies of PON1 ₁₉₂ alleles were Q = 0.46, R = 0.54 in mothers, and Q = 0.51, R = 0.49 in children, with overall population prevalence Q ~ R ~ 0.5. Frequencies for the major alleles of promoter polymorphisms PON1_G−909, PON1_G−162, and PON1_C−108 were, respectively, 0.52, 0.78, and 0.51 in mothers and 0.56, 0.81, and 0.55 in children, and the frequency of a major allele of the coding PON1 _L55 polymorphism equaled 0.82 in both age groups.

Results of linkage analysis between five PON1 polymorphisms were also similar for Latina mothers and their newborns (Table 2). We observed nearly complete LD among the three promoter polymorphisms (D′ = 0.8–1; p < 0.001). Strong LD (D′ = 0.87 and 0.94 in mothers and children, respectively; p < 0.001) was found between the two coding polymorphisms (PON1 ₁₉₂ and PON1 ₅₅ ). There was a more complex relationship between coding and promoter region polymorphisms: although PON1 ₅₅ had high LD with all three promoter polymorphisms (D′ = 0.74–1), only two (PON1_{− 108} and PON1_{− 909} ) of the three promoter SNPs were linked to PON1 ₁₉₂ (D′ = 0.22 and 0.19 in mothers, and D′ = 0.27 and 0.34 in children, respectively). These LDs were all modest but statistically significant. However, no linkage was demonstrated between SNPs at positions PON1 ₁₉₂ and PON1_{− 162} (D′ = 0.0 in mothers and 0.18 and children; p > 0.4).

Haplotype analysis

Haplotype analysis revealed a total of 32 different combinations of alleles (Table 3). However, their frequencies were noticeably different and fall into three distinct groups: a) a main group contributing approximately 93% of all haplotypes for this cohort, which is composed of seven haplotypes with individual frequencies ranging from 7 to 24%; b) a second group with individual frequencies ranging from 0.1 to 1.9%, which contributes 5.5–7.8% of all haplotypes in mothers and children; and c) a group of 17 rare haplotypes contributing a total of approximately 1% of haplotype variability.

PON1 enzyme activities

AREase levels allow for a comparison of PON1 levels across genotypes because the catalytic efficiency of hydrolysis of phenylacetate is not affected by the PON1 ₁₉₂ polymorphism (Tables 4, 5). The AREase activity in mothers ranged from 19.8 to 281.4 U/mL and in newborns, from 4.3 to 110.7 U/mL. The mean AREase values for mothers were similar across three PON1 ₁₉₂ genotypes (Q/Q = 151.9 U/mL; Q/R = 144.3 U/L; R/R = 152.2 U/L; p = 0.64). In cord samples, the Q192R polymorphism slightly influenced AREase levels with PON1 _R192 individuals having the highest average levels (Q/Q = 30.8 U/mL; Q/R = 35.8 U/mL; R/R = 42.9 U/mL), although the difference between genotypes was not statistically significant (p = 0.13).

AREase levels varied noticeably across C-108T genotypes in mothers (C/C = 163.6 U/mL; C/T = 147.1 U/mL; T/T = 134.8 U/mL; p = 0.04) with a larger gradient in newborns (C/C = 48.7 U/mL; C/T = 34.0 U/mL; T/T = 27.3 U/mL; p = 0.0003). AREase levels also differed by the L55M polymorphism in cord blood (p < 0.0001) but not in maternal blood (p = 0.44), with M/M homozygotes having the lowest levels in children (17.6 U/mL) and in mothers (135.6 U/mL). AREase levels were significantly higher in subjects with the G-909 and A-162 alleles in both mothers and children (p = 0.0003–0.03).

Mean POase and CPOase activities in mothers were significantly higher (1024.2 and 9358.3 U/L, respectively) than in newborns (315.1 and 2663.4 U/L, respectively) (Tables 4, 5). Both POase and CPOase activity levels demonstrated a strong association with the PON1 ₁₉₂ genotype. The lowest mean average POase activity was seen in 192 _QQ children (81.2 U/L) and the highest in 192 _RR mothers (1927.9 U/L), resulting in a 24-fold difference among these two genotype/age groups. Furthermore, the lowest overall POase level (10.3 U/L) was observed in the 192 _QQ newborn child, and the highest in 192 _RR adult (3014.2 U/L), bringing the overall difference among individuals from the same population to 300-fold. For CPOase, respective differences in enzyme activity between the lowest and highest levels in this cohort reached 70-fold. Both POase and CPOase activities also varied significantly by the other four PON1 polymorphisms, with the lowest values for −909_GG, −162_GG, −108_TT, and 55_MM homozygote groups (p < 0.001 in children; p < 0.03 in mothers).

Overall, PON1 activity levels in maternal blood were significantly higher than in cord blood for all enzyme assays and all genotypes (p < 0.001). Specifically, maternal POase, CPOase, and AREase levels were 3.3-fold, 3.6-fold, and 4.0-fold higher, respectively, than those in newborn. As expected, AREase, CPOase, and POase levels correlated well within PON1 ₁₉₂ genotypes. In mothers, the correlations between AREase and CPOase levels ranged between 0.62 and 0.74 in QQ, QR, and RR groups, and in newborns, these correlations were even stronger, 0.90–0.92 (all p-values < 0.0001 for both mothers and newborns). The correlations between AREase and POase, and between POase and CPOase were the highest in RR newborns (both 0.93) and mothers (0.7 and 0.95, respectively), and somewhat lower for other maternal and new-born PON1 ₁₉₂ genotype groups (all p-values less than 0.001). AREase activity was not compared with either CPOase or POase across genotypes because of the differential effects of the PON1 ₁₉₂ polymorphism on CPOase or POase activities. For example, the PON1 _Q192 alloform hydrolyzes paraoxon with a catalytic efficiency nine times lower than PON1 _R192 (Li et al. 2000).

Phenotypic effects of PON1 genotype and haplotype

We constructed linear regression models to determine the proportion of the variance of AREase explained by the five PON1 polymorphisms and the imputed haplotypes. The five PON1 genotype polymorphisms explained 8.1 and 23.1% of the variance of AREase in mothers and newborns, respectively. The coefficient of variation (R²) was similar for both promoter polymorphisms PON1_{− 909} and PON1_{− 162} in mothers (~5%) and children (~14%) after adjusting for PON1_{− 108} . PON1 haplotypes did not significantly improve the amount of variance explained (total R² = 8.8% for mothers, 26.3% for newborns). The genetic contribution to AREase levels was significantly higher in newborns than in their mothers (p < 0.01). Because POase and CPOase characterize PON1 catalytic efficiency and are primarily controlled by PON1 ₁₉₂ polymorphism, a comparison of haplotype and genotype effects by these two assays was not relevant.

Discussion Top

To our knowledge, this is the first study to report three PON1 enzyme activity levels in a large cohort of newborns and mothers from an agricultural cohort with relatively high levels of OP exposure. Two main PON1 factors are likely to contribute to the risk of adverse health effects of OP exposure: the level of enzyme (as measured by AREase assay) and the ability of this enzyme to detoxify OP metabolites (as measured in this study by CPOase assay, and primarily affected by PON1 ₁₉₂ ). Thus, newborn children in this cohort, based on their lower PON1 plasma levels and detoxifying activities, are likely to be significantly more susceptible to OP exposure than are their mothers. Similar to results of a study from Mexico (Rojas-Garcia et al. 2005), we found large interindividual variability in PON1 plasma levels in both mothers and children, with a 14-fold difference in AREase among mothers, a 25-fold difference in newborns, and an overall range of 65-fold in this cohort. Additionally, we observed a range of 70-fold for CPOase and 300-fold for POase. However, it is important to emphasize that POase variability does not reflect differential sensitivity to paraoxon exposure based on recent animal data (Li et al. 2000). On the other hand, PON1 levels and PON1 ₁₉₂ polymorphism are very important in determining sensitivity to chlorpyrifos and chlorpyrifos oxon exposure (Cole et al. 2005; Furlong et al. 2006). Further, AREase variability primarily defines sensitivity to diazoxon exposure (Furlong et al. 2006; Li et al. 2000). Moreover, given the wide range in enzyme levels, some of the mothers are predicted to have an elevated susceptibility because they have levels as low as most of the newborns.

In nine children followed longitudinally, PON1 reached plateaus comparable with mean adult levels between 6 and 24 months of age (Cole et al. 2003). Our finding that CHAMACOS mothers had approximately 4-fold higher AREase levels than did their newborns confirms previous observations of lower PON1 activities in small groups of neonates compared with adults (Augustinsson and Barr 1963; Ecobichon and Stephens 1973; Mueller et al. 1983). Our finding is also consistent with a recent report where neonates had 2.6- to 4.6-fold lower PON1 levels compared with mothers in three ethnic groups residing in New York (Chen et al. 2003). However, no previous study has reported either POase or CPOase variability in such a large cohort of newborns.

In Latino newborns of the CHAMACOS cohort, all three PON1 promoter polymorphisms as well as PON1 ₅₅ were significantly associated with AREase levels in children, and a greater proportion of the variance in AREase enzyme levels was explained by genetic polymorphisms in newborns than in mothers. The association of these polymorphisms and AREase levels is in agreement with another study of PON1 levels in newborns (Chen et al. 2005). There was a nearly complete LD among the three promoter region polymorphisms, as also observed in other studies (Brophy et al. 2001a; Chen et al. 2005; James et al. 2000; Rojas-Garcia et al. 2005). However, PON1 ₁₉₂ was not in LD with promoter SNP PON1_{− 162} and was in weak LD with the PON1_{− 108} and PON1_{− 909} . The lack of strong LD between PON1 ₁₉₂ and promoter polymorphisms is also in agreement with data from the Hispanic population in New York City (Chen et al. 2005). We found stronger LD between the two coding-region SNPs, PON1 ₁₉₂ and PON1 ₅₅ , in both mothers and children (D′ = 0.88 and 0.94, respectively) of the CHAMACOS cohort compared with Hispanics in New York City (Chen et al. 2005). The differences in linkage pattern may be attributed to variation among ethnic groups (Koda et al. 2004).

It has been reported that the association of the M55 allele with low PON1 levels is primarily attributable to LD with the inefficient T-108 allele (Brophy et al. 2001b). PON1 _M55 has also been reported to be somewhat less stable than PON1 _L55 , additionally affecting protein levels in plasma (James et al. 2000). This may explain why in CHAMACOS mothers, who have about a 4-fold higher AREase levels than the newborns, the effect of PON1 ₅₅ was not statistically significant.

Our analysis of five PON1 SNPs in a Latino population of Mexican descent living in California suggests that these SNPs may be located on separate haplotype blocks because we found nearly complete LD among the coding SNPs but not between PON1 ₁₉₂ and PON1_{− 162} The presence of several haplotypes blocks in the PON1 gene has been previously reported for other ethnic groups (International HapMap Consortium 2003; Koda et al. 2004). This underscores the importance of further analysis of PON1 genetic variability. The gene frequencies for specific alleles of PON1 genes vary by ethnicity, implying different population susceptibility to pesticides (Costa et al. 2002). The frequency of PON1 ₁₉₂ alleles in our Latina cohort of Mexican descent (Q = 0.5) was similar to those observed in Caribbean Hispanic mothers and neonates in New York City (both Q = 0.5) (Chen et al. 2003). PON1_{− 162} frequencies were also comparable in these two populations (~ 0.8). However, the frequencies for the PON1_{− 108} , PON1_{− 909} , and PON1 ₅₅ were noticeably different between Latinos from California and New York. The PON1 ₁₉₂ frequency in Hispanics from Washington State (Q = 0.6) was slightly higher than in New York and California (Brophy et al. 2002). In previous studies, the allele frequencies for PON1 ₁₉₂ polymorphism in Caucasians was Q = 0.7, whereas for African Americans and other groups of African descent, the PON1 ₁₉₂ frequencies are reversed, Q = 0.3 (Brophy et al. 2002).

Allebrandt et al. (2002) have compared a combination of the PON1 ₁₉₂ and PON ₁₅₅ allele frequencies across various ethnic groups. Using this approach, Mexican Latinos of the CHAMACOS cohort appear to be equally differentiated from Caucasians, Asians, and African Americans, which is consistent with their Native American background, whereas Caribbean Hispanics from New York (Chen et al. 2003) are closer to Africans and Caucasians (data not shown). This difference across ethnic groups corroborates genetic and historical information about these populations (Cavalli-Sforza et al. 1993).

An effect of both PON1 genotype and haplotypes on PON1 phenotype as measured by AREase was stronger in CHAMACOS newborns. This is in agreement with another study (Chen et al. 2005; Wetmur et al. 2005) that evaluated the relationship of five PON1 SNPs with enzyme activity in mothers and their newborns. It is also clear that polymorphisms characterized to date in the PON1 gene account for only a portion of the variability in PON1 levels observed among individuals. Additional research needs to be carried out to identify other factors (e.g., trans-acting factors, other PON1 polymorphisms including intronic and exonic splice enhancing sequences) that influence PON1 expression.

Individuals with low PON1 activity are hypothesized to be at higher risk for any adverse health effects of OP exposure. In the only study to date to directly examine this hypothesis, Berkowitz et al. (2004) reported that in residents of east Harlem (the same cohort described by Chen et al. 2003), low PON1 plasma levels were associated with smaller neonatal head circumference. Further, although prenatal levels of the urinary metabolite of chlorpyrifos—3,5,6-trichloro-2-pyridinol (TCP)—were not associated with any measure of fetal growth or length of gestation by itself, higher levels of TCP were associated with smaller head circumference in children whose mothers had low expression of PON1.

We previously reported in the CHAMA-COS cohort that OP exposure as measured by urinary dialkyl phosphate metabolite levels of the mother during pregnancy was associated with shorter gestational duration (Eskenazi et al. 2004) and poorer neonatal reflexes (Young et al. 2005). A recent publication links PON1 _RR and PON2 _CC genotypes in infants with increased risk of preterm delivery in China (Chen et al. 2004). In future analyses, we aim to expand the analyses of PON1 to the entire CHAMACOS cohort and to determine whether PON1 levels modify the previously observed relationship between OP exposure and gestational duration and neonatal development.

Figures and Tables Top

Table 1.

PON1 allelic frequencies in Latino mothers and their newborns.

Table 2.

Tests of PON1 LD in Latino mothers and children.

Table 3.

Haplotypes (%) of five PON1 polymorphisms in 130 Latino mothers and their newborns.

Table 4.

PON1 polymorphism frequencies and enzyme activities in Latina mothers (n = 130).

Table 5.

PON1 polymorphism frequencies and enzyme activities in Latino newborns (n = 130).

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