Skip to main content
Allergy, Asthma, and Clinical Immunology : Official Journal of the Canadian Society of Allergy and Clinical Immunology logoLink to Allergy, Asthma, and Clinical Immunology : Official Journal of the Canadian Society of Allergy and Clinical Immunology
. 2017 Feb 27;13:12. doi: 10.1186/s13223-017-0187-8

Dietary intake is associated with respiratory health outcomes and DNA methylation in children with asthma

L Montrose 1, T J Ward 2, E O Semmens 2, Y H Cho 2, B Brown 3, C W Noonan 2,
PMCID: PMC5327515  PMID: 28261276

Abstract

Background

Asthma is an increasingly common chronic disease among children, and data point toward a complex mechanism involving genetic, environmental and epigenetic factors. Epigenetic modifications such as DNA hypo- or hyper-methylation have been shown to occur in response to environmental exposures including dietary nutrients.

Methods

Within the context of the asthma randomized trial of indoor wood smoke (ARTIS) study, we investigated relationships between diet, asthma health measures, and DNA methylation. Asthma health measures included a quality of life instrument, diurnal peak flow variability (dPFV) and forced expiratory volume in the first second (FEV1). Dietary intake was assessed with a food frequency questionnaire. Methylation levels of LINE-1 repetitive element and two promoter CpG sites for interferon gamma (IFNγ, -186 and -54) from buccal cell DNA were measured using pyrosequencing assays.

Results

Data were collected on 32 children with asthma living in western Montana who were recruited to the ARTIS study. Selenium and several methyl donor dietary nutrients were positively associated with the asthma quality of life measure. Intake of methyl donating nutrients including folate was positively associated LINE-1 methylation and negatively associated with IFNγ CpG-186. Higher levels of LINE-1 methylation were associated with greater dPFV.

Conclusion

We identified several nutrients that were associated with improved quality of life measures among children with asthma. The IFNγ promoter CpG site -186 but not -54 was associated with the intake of selected dietary nutrients. However, in this small population of children with asthma, the IFNγ promoter CpG sites were not associated with respiratory health measures so it remains unclear through which epigenetic mechanism these nutrients are impacting the quality of life measure. These findings add to the evidence that dietary nutrients, particularly foods containing methyl donors, may be important for epigenetic regulation as it pertains to the control of asthma.

Trial registration ClincialTrials.gov NCT00807183. Registered 10 December 2008

Electronic supplementary material

The online version of this article (doi:10.1186/s13223-017-0187-8) contains supplementary material, which is available to authorized users.

Keywords: Asthma, Methylation, Spirometry, Diet, Nutrition, Children, Epigenetics, Quality of life

Background

Asthma is an environmentally triggered disease that affects nearly 26 million people in the United States [1]. Dietary intake represents a modifiable environmental exposure that could partially explain the current burden of chronic disease, including asthma, in industrialized countries [2]. Epidemiological studies suggest that dietary patterns are linked to the risk of developing asthma, however, the evidence from longitudinal birth cohorts has not clearly defined the importance of specific nutrients or fully elucidated the mechanistic pathways linking diet to chronic respiratory disease. Further, there have been few studies aimed at determining if nutrient intake contributes to asthma control in children. One potential mechanism whereby dietary intake affects respiratory health in children is through epigenetic modulation of immunoregulatory cytokines.

Significant observational data suggests that dietary status and intake of particular nutrients can affect respiratory health outcomes. Several recent studies have suggested that some dietary nutrients may be protective for respiratory health [312]. A recent review concluded that dietary intake in utero and throughout the lifecourse can influence respiratory health status, however definitively assessing causal relationships in human studies is a major challenge [13]. A cross-sectional study by Berthon et al. showed that among asthmatics, a high fat diet was associated with increased airway eosinophilic inflammation, and low fiber intake was associated with poor lung function [14]. Supplementation of dietary folic acid has been successful in the prevention of neural tube defects in the United States. However, longitudinal cohort studies have produced mixed results regarding maternal folic acid supplementation and asthma development [15, 16]. Antioxidants like selenium may play a role in respiratory health through systemic reduction of oxidative stress [17]. In a mouse model of allergic airway disease, a combinatory therapeutic that included selenium attenuated the physiologic airway damage that is typical of this model [18].

The rapidly evolving field of epigenetics has emerged as an appealing potential mechanistic bridge that could link environmental exposures to the development of asthma or the exacerbation of asthma-related symptoms [19]. The exact toxicoepigenetic mechanisms are far from elucidated, but landmark studies using the agouti mouse model have provided solid evidence that environmental exposures can affect phenotype through alterations in DNA methylation patterns [20]. Understanding how and when these mechanisms can impact asthma pathogenesis is paramount. In a mouse model of allergic airway disease, in utero dietary intake of methyl donating nutrients was associated with an enhanced disease phenotype as well as aberrant hypermethylation of runt-related transcription factor 3 (Runx3), a gene known to suppress allergic airway disease [21]. Although the perinatal exposure window may be especially important, data also suggest that environmental exposures could impact health via epigenetic mechanisms throughout the lifecourse. In humans, the production of regulatory T cells (Tregs), which are known to suppress immune responses, is controlled by transcription factor forkhead box p3 (FOXP3) [22]. Nadeau et al. demonstrated that patients with asthma in a polluted environment had a hypermethylated FOXP3 locus profile which was associated with impaired Treg function relative to patients with asthma in a less polluted area [23].

The relationship between dietary intake and epigenetic modifications is complex and compounded by sensitivity to timing of exposure (e.g. prenatal, postnatal, adolescent, or adult). Nevertheless, human and mouse data indicate several dietary nutrients play a role in epigenetic mechanisms [24], thus it is possible that nutrient intake is related to asthma pathogenesis through the epigenetic regulation of key genes. Asthma is phenotypically characterized by a shift toward type 2 T helper (Th2) polarization and consequently type 1 T helper (Th1) cell cytokines such as interferon gamma (IFNγ) play a critical role as counter regulators in the allergic asthma pathway [25, 26]. For example, in a follow-up study of adults recruited as children with a history of wheeze, those with persistent asthma were compared to those with resolved asthma to characterize the Th1/Th2 response following exposure to house dust mite allergen [27]. Smart et al. found that those with persistent asthma had much weaker Th1 responses and concluded that a measured decrease in IFNγ production in this group could be a major factor underpinning the presence of severe and chronic asthma symptoms. Meng et al. investigated the effect of diet on IFNγ production in humans and showed that cells extracted and purified from non-asthmatic adults produced differential amounts of IFNγ [28]. Interestingly, Meng found that the amounts of IFNγ were associated with intake of specific dietary variables and predicted upper respiratory tract infection incidence. Finally, a series of studies using either a ragweed or dust mite-sensitized mouse model of asthma showed that pre-treatment with a DNA adjuvant known to result in Th1 biased immune status with marked overproduction of IFNγ resulted in an ameliorated lung inflammatory phenotype [29, 30]. Thus IFNγ is a relevant candidate gene that plausibly exists in the mechanistic pathway linking dietary intake to respiratory health via epigenetic regulation of the Th1/Th2 cytokine balance.

Poor asthma control is associated with school absences, higher health care costs and worse long-term health outcomes. An understanding of the association between a child’s recent dietary history and respiratory health measures could lead to important intervention strategies to improve outcomes among children with asthma. In this study we aimed to evaluate the relationship between a priori selected nutrients and asthma health. Although the link between current dietary status and asthma health is not clear, evidence suggests a potential role for an epigenetic mechanism. In addition to a measure of global gene methylation, IFNγ was chosen as a candidate gene because of its well-established role in the Th1/Th2 balance.

Methods

Study overview

Participants were recruited from the asthma randomized trial of indoor wood smoke (ARTIS) study. The rationale and methods for the ARTIS study have been described previously [3133]. The ARTIS study included 114 children with asthma (ages 6–17) from 97 homes in Montana, Idaho, and Alaska. This parent study was designed to test an indoor air quality intervention, and homes were assigned to either a placebo arm or an air filter intervention. Two in-home data collection visits occurred in each of two consecutive winter periods with the intervention occurring between these winter periods. The subcohort recruited to participate in this diet and epigenetics study included 32 participants living in western Montana who had been recruited in the final 2 years of the 5-year ARTIS study. Additional file 1: Figure S1 indicates when spirometry measurements, buccal cells, and food frequency questionnaires (FFQ) were administered. For the purpose of the currently described study, only data that was collected in conjunction with a FFQ was considered. In Additional file 1: Figure S1, this would be visits B and D. Health outcomes measures included a quality of life instrument and self-monitoring of spirometry measures using a peak flow meter. Buccal cell samples were collected for evaluating epigenetic markers. Anthropometric measures determined by trained staff using a digital scale and stadiometer along with the participant’s gender and date of birth were used to calculate body mass index (BMI) percentile using the U.S. Centers for Disease Control and Prevention (CDC) calculator [34]. The study was approved by the University of Montana Institutional Review Board. In addition to the informed consent procedures for the parent study, children were separately assented to participate in this diet and epigenetics study and parents signed a parental permission and informed consent form.

Dietary nutrient collection

Dietary data was collected using the 2004 Block Kids FFQ (NutritionQuest, Berkeley, CA, USA) to characterize dietary intake among participants. This instrument has been validated in children, ages 6–17 years old [3538]. The questionnaire includes 77 food items. In addition to intake of standard nutrients, this instrument was used to estimate intake of micronutrients that participate in the one-carbon metabolism pathway (i.e. betaine, choline, folate, etc.). These nutrients are important for the generation of methyl groups and are therefore potentially relevant to DNA methylation markers. The questionnaire was administered to each participant by trained staff using serving size visual aides, and parents were asked to assist their child with portion size recognition and remembering foods they ate during the last week. Questionnaires were processed by NutritionQuest, and the resulting data were analyzed at the University of Montana.

Health outcome measures collected in parent study

The pediatric asthma quality of life questionnaire (PAQLQ) is a 23-item asthma-specific battery which provides domain scores for symptoms (10 items), activity limitation (5 items), and emotional function (8 items) [39]. The total PAQLQ score and each domain score are calculated as mean scores ranging from one to seven with seven as the optimal score. The PAQLQ has been validated as an evaluative tool to measure within participant changes over time due to treatment, and changes in this scale of 0.5 or more points are clinically significant [39].

Using the PiKo-1 m (Ferraris Respiratory, Ayer, MA, USA) participants performed a test twice daily, in the morning and in the evening, for a period of 2 weeks. These 2-week periods were initiated at the beginning of each air sampling event. For each test, the child’s parent records the observation as it appears on the meter and these observations are later checked for accuracy against the digital log of the instrument. The instrument records the best result for both peak expiratory flow (PEF) and forced expiratory volume in one second (FEV1). Outcomes from these measures include average morning PEF and FEV1, average evening PEF and FEV1, and diurnal PEF variability (dPFV).

Cell collection, DNA extraction, and pyrosequencing

Buccal cells were collected from the participant’s cheek by trained staff using a cytology brush and stored in Cell Lysis Solution (Qiagen, Valencia, CA, USA) at room temperature until all samples were collected. In compliance with this protocol, all samples were processed within 24 months from the day of collection. DNA from the buccal cells was extracted using Gentra Puregene Buccal Cell DNA Kit (Qiagen, Valencia, CA, USA) according to the manufacturer’s instructions. The quantity of the purified DNA was measured using a Nanodrop spectrophotometer (Thermo Scientific, Wilmington, DE) and then stored at −20 °C. DNA bisulfite treatment was carried out using the EZ DNA Methylation-Direct Kit (Zymo Research, Irvine, CA) according to the manufacturer’s instruction, and stored at −20 °C. Pyrosequencing assay was used to measure methylation levels of LINE-1 repetitive element and the promoter region of INFγ. Briefly, 50 µg of bisulfite-modified DNA was PCR amplified by polymerase chain reaction (PCR) using specific primers (Additional file 1: Table S1) and the PyroMark PCR kit (Qiagen, Valencia, CA, USA). After annealing, pyrosequencing was conducted using a Pyromark Q96 MD (Qiagen, Valencia, CA, USA). Samples were run in duplicate and only samples with a coefficient of variation less than 5% were used in the final analysis. Epitect (Qiagen, Valencia, CA, USA) bisulfite treated controls, which include a methylated and unmethylated human genome sample, along with a no template control were used on each plate.

Statistical analysis

All analyses were conducted using SAS v9.4 (Cary, NC, USA). To evaluate if cross sectional measurements of IFN CpG sites are correlated with each other and/or correlated with LINE1 global methylation we estimated Pearson correlation coefficients using the first available observation for each participant (n = 32). A subset of 17 macro- and micronutrients from the total 73 nutrient variables generated by the FFQ were chosen after a literature review of diet as it relates to asthma. Relationships between a priori selected dietary nutrients and both epigenetic markers and asthma outcomes were considered in separate models using all available and complete data, which included multiple visits for some participants. Their associations with continuous epigenetic markers (i.e. global and gene-specific methylation) and asthma measures were evaluated using generalized estimating equations (GEE), which account for correlations between repeated measures on the same participant. Tertiles of dietary nutrients were included in analyses as three-level indicator variables to investigate potentially non-linear relationships with epigenetic and asthma outcomes. Analyses were adjusted for age (continuous) and gender. Although this diet and epigenetics repeated measures study was not directly related to the indoor air quality intervention study, we included in our models indicators for pre- versus post-intervention winter and home intervention assignment (i.e., placebo versus air filter). Inclusion of the following potential confounders: presence of cat or dog in home (yes or no), family income (above or below $50,000) and parent education (college degree or no college degree) appreciably impacted parameter estimates. Therefore, the final model included age, gender, winter and intervention group assignment, presence of cat or dog, income and education. We investigated relationships between epigenetic markers and asthma measures in a similar manner. Due to the number of comparisons (n = 264), a false discovery rate correction [40] was applied and adjusted p-values (q-values) were calculated for each relationship where the GEE model was used. A threshold for significance was set at q < 0.20 which means we accept that 20% of the observed significant relationships (i.e. 3.4 out of 17) could be false positives.

Results

A subset of 32 children from the ARTIS cohort participated in this study of diet, asthma health and epigenetics and was included in the analyses described here. Diet data was collected once per winter in conjunction with buccal cells, PAQLQ and spirometry and therefore, only these ‘complete’ visits were considered in the analysis. Approximately 63% of subcohort, or 20 participants, had both a year one and year two ‘complete’ visit, while 12 participants only had one ‘complete’ visit, which occurred in either year one or year two, for a total of 52 observations. Reasons for these 12 participants having one rather than 2 years of data included missing data, participant not available during scheduled visit, or the participant chose to only participate in one year of the study. Moreover, in the final GEE models, which were adjusted for several covariates, one participant (two observations) was excluded because income and education data was missing, therefore the results from these models include 50 observations from 31 participants. Ages ranged from 8 to 17 years and 47% were male (Table 1). The study population was 94% non-Hispanic white. The mean (sd) BMI percentile was 70.6 (20.1) and 34% (n = 11) were above the 85th percentile, which is considered overweight according to the CDC [34]. Baseline asthma-related respiratory health values can be found in Table 1. Mean values for both dPFV and FEV1 were at the approximate threshold used to designate poor asthma control [41]. Mean (sd) LINE-1 methylation was 65.3% (3.4) with a range of 56.1–73.2%. Mean (sd) IFNγ CpG-54 was 79.6% (4.5) with a range of 68.6–92.4%. Mean (sd) IFNγ CpG-186 was 70.1% (6.6) with a range of 49.1–81.6%. IFNγ CpG-54 and IFNγ CpG-186 observations were moderately correlated with each other (r = 0.42; p = 0.02) as were IFNγ CpG-54 and LINE-1 methylation (r = 0.44; p = 0.01). IFNγ CpG-186 and LINE-1 methylation were not significantly correlated (r = 0.26; p = 0.15).

Table 1.

Selected characteristics of subset of ARTIS participants included in epigenetic study

N Mean SD Range
Age 32 12.8 2.5 8.0–17.0
Gender
 Male 15 (46%)
 Female 17 (53%)
Ethnicity
 Non-Hispanic 30 (94%)
BMI percentile 32 70.6 24.1 5.8–99.0
dPFV 32 20.0 14.0 2.0–66.0
% Predicted morning FEV1 32 81.7 19.7 26.9–112.9
% Predicted evening FEV1 32 82.3 19.3 19.3–110.1
PAQLQ 32 5.6 1.1 3.1–7.0
LINE-1 (%) 32 65.3 3.4 56.1–73.2
IFNγ-54 (%) 32 79.6 4.5 68.6–92.4
IFNγ-186 (%) 32 70.1 6.6 49.1–81.6

SD standard deviation, BMI body mass index, dPFV evening to morning peak flow variability, FEV 1 forced expiratory volume in 1 s, PAQLQ pediatric asthma quality of life questionnaire, IFNγ interferon gamma

Evaluating dietary nutrients with respect to respiratory health

When considered across categories of calculated intake, most dietary nutrients failed to show a consistent association with respiratory health measures, but several differences in PAQLQ scores were observed between participants in the highest third versus the lowest third of intake for some nutrients (Table 2). Phosphatidylcholine was the only selected nutrient that was associated with any of the three pulmonary function measure assessed. Children in the middle tertile relative to the lowest had 16.04% point (95% CI 3.31, 28.78; q = 0.16) higher % predicted evening FEV1. Intake of selenium and folate was associated with better PAQLQ scores. Specifically, participants with the highest tertile of selenium and folate intake had 1.4 unit (95% CI 0.90, 1.91; q = 0. 01) and 0.92 unit (95% CI 0.31, 1.53; q = 0.11) higher PAQLQ scores, respectively. Additionally, nutrients in the one-carbon metabolism cycle, phosphocholine (1.11 unit higher PAQLQ score; 95% CI 0.23, 1.98; q = 0.16) and betaine (0.98 unit higher PAQLQ score; 95% CI 0.30, 1.66; q = 0. 13) were positively associated with PAQLQ.

Table 2.

The relationship between select nutrients and asthma health measures by dietary tertiles in ARTIS where the lowest tertile of intake (T1) is the reference group

Asthma health measure dPFV % Predicted morning FEV1 % Predicted evening FEV1 PAQLQ
Dietary factor Estimate (95% CI) q-value Estimate (95% CI) q-value Estimate (95% CI) q-value Estimate (95% CI) q-value
Kilocalories
 T3:T1 −3.18 (−11.41, 5.06) 0.80 13.09 (−4.04, 30.22) 0.61 4.18 (−14.08, 22.44) 0.87 0.62 (−0.25, 1.48) 0.68
 T2:T1 −0.50 (−8.78, 7.78) 0.98 0.83 (−13.94, 15.60) 0.98 7.04 (−8.31, 22.40) 0.76 −0.34 (−1.20, 0.51) 0.79
Protein
 T3:T1 −6.96 (−20.40, 6.48) 0.72 19.26 (0.48, 38.05) 0.33 10.96 (−2.58, 24.51) 0.55 0.70 (−0.16, 1.56) 0.55
 T2:T1 −3.42 (−14.56, 7.73) 0.83 6.31 (−8.30, 20.92) 0.77 1.14 (−12.42, 14.70) 0.97 0.59 (−0.09, 1.27) 0.51
M-fats
 T3:T1 −2.87 (−10.62, 4.87) 0.81 11.64 (−6.82, 30.11) 0.71 8.55 (−10.72, 27.81) 0.77 0.39 (−0.31, 1.09) 0.71
 T2:T1 −0.57 (−8.81, 7.67) 0.98 3.89 (−9.58, 17.36) 0.83 3.26 (−9.25, 15.77) 0.85 0.52 (−0.03, 1.07) 0.41
S-fats
 T3:T1 −3.99 (−15.87, 7.89) 0.83 16.85 (1.36, 32.35) 0.29 11.73 (0.65, 22.82) 0.33 −0.16 (−0.82, 0.50) 0.87
 T2:T1 −6.56 (−16.72, 3.59) 0.70 16.67 (2.96, 30.37) 0.28 10.19 (−0.41, 20.80) 0.41 −0.05 (−0.77, 0.67) 0.98
Omega 3:6 ratio
 T3:T1 −1.25 (−10.54, 8.03) 0.92 2.42 (−11.59, 16.44) 0.90 −0.39 (−13.84, 13.07) 1.00 −0.13 (−1.18, 0.93) 0.92
 T2:T1 −1.29 (−12.09, 9.51) 0.92 5.40 (−4.00, 14.80) 0.71 1.46 (−6.18, 9.10) 0.90 0.11 (−0.54, 0.75) 0.90
Selenium
 T3:T1 5.44 (−2.98, 13.86) 0.70 6.63 (−6.31, 19.56) 0.73 6.37 (−6.57, 19.30) 0.74 1.40 (0.90, 1.91) 0.01*
 T2:T1 2.52 (−4.56, 9.59) 0.82 0.20 (−14.11, 14.51) 1.00 2.91 (−12.96, 18.77) 0.90 −0.56 (−1.59, 0.47) 0.71
Fiber
 T3:T1 −0.39 (−9.02, 8.25) 0.99 7.75 (−5.27, 20.78) 0.71 5.86 (−8.02, 19.74) 0.77 0.66 (−0.52, 1.84) 0.71
 T2:T1 0.63 (−9.85, 11.11) 0.98 −5.36 (−17.98, 7.27) 0.77 −3.60 (−15.79, 8.59) 0.83 0.32 (−0.38, 1.02) 0.76
Folate
 T3:T1 −3.43 (−14.76, 7.89) 0.83 10.07 (−7.95, 28.09) 0.71 3.75 (−10.53, 18.02) 0.85 0.92 (0.31, 1.53) 0.11*
 T2:T1 −3.03 (−14.23, 8.17) 0.85 −0.03 (−17.50, 17.44) 1.00 −0.24 (−13.99, 13.50) 1.00 −0.25 (−0.83, 0.35) 0.78
Methionine
 T3:T1 −4.83 (−13.90, 4.24) 0.72 14.81 (−0.25, 29.88) 0.36 11.07 (−4.02, 26.17) 0.65 0.52 (−0.37, 1.41) 0.71
 T2:T1 1.87 (−7.53, 11.28) 0.90 5.22 (−12.12, 22.57) 0.83 7.29 (−10.16, 24.73) 0.77 −0.06 (−1.58, 1.46) 0.99
Free choline
 T3:T1 2.44 (−4.68, 9.56) 0.83 11.20 (−6.45, 28.86) 0.70 7.69 (−10.98, 26.36) 0.78 0.00 (−1.34, 1.34) 1.00
 T2:T1 5.35 (−3.47, 14.17) 0.71 −2.64 (14.74, 9.47) 0.88 −0.21 (−13.39, 12.97) 1.00 −0.31 (−1.26, 0.64) 0.83
Glycpp-choline
 T3:T1 2.84 (−5.75, 11.42) 0.83 −3.05 (−18.17, 12.07) 0.89 −3.64 (−19.88, 12.61) 0.88 0.61 (−0.17, 1.39) 0.59
 T2:T1 −1.81 (−9.22, 5.59) 0.87 2.88 (−9.04, 14.80) 0.87 3.70 (−8.10, 15.50) 0.83 0.12 (−0.41, 0.65) 0.87
Pp-choline
 T3:T1 4.54 (−3.07, 12.15) 0.71 −2.95 (−12.99, 7.08) 0.83 −5.21 (−15.57, 5.14) 0.73 1.11 (0.23, 1.98) 0.16*
 T2:T1 −1.03 (−7.55, 5.50) 0.90 −10.81 (−27.27, 5.64) 0.69 −12.35 (−29.79, 5.09) 0.68 0.50 (−0.61, 1.60) 0.77
Ppt-choline
 T3:T1 0.36 (−6.86, 7.58) 0.98 11.60 (−1.45, 24.65) 0.48 −1.13 (−19.21, 16.94) 0.98 0.24 (−0.86, 1.35) 0.88
 T2:T1 5.71 (−2.92, 14.33) 0.69 −3.17 (−15.51, 9.17) 0.85 16.04 (3.31, 28.78) 0.16* −0.19 (−0.58, 0.21) 0.76
Total choline
 T3:T1 1.33 (−6.50, 9.16) 0.90 8.61 (−7.92, 25.14) 0.72 5.96 (−12.23, 24.15) 0.83 0.18 (−1.26, 1.61) 0.92
 T2:T1 3.76 (−4.42, 11.94) 0.76 −6.68 (−20.25, 6.90) 0.74 −2.06 (−16.74, 12.62) 0.92 −0.38 (−1.35, 0.59) 0.80
Betaine
 T3:T1 −2.62 (−9.35, 4.10) 0.80 12.85 (0.98, 24.72) 0.29 9.13 (−1.59, 19.85) 0.51 0.98 (0.30, 1.66) 0.13*
 T2:T1 4.20 (−6.18, 14.58) 0.79 −9.34 (−21.55, 2.86) 0.61 −9.10 (−19.78, 3.59) 0.68 0.21 (−0.56, 0.98) 0.85
Vitamin B-2
 T3:T1 −0.95 (−8.43, 6.54) 0.92 −4.74 (−18.10, 8.61) 0.82 3.81 (−10.97, 18.58) 0.85 0.40 (−0.66, 1.46) 0.80
 T2:T1 1.66 (−8.13, 11.44) 0.90 8.98 (−7.57, 25.52) 0.71 −4.04 (−17.65, 9.56) 0.83 −0.12 (1.12, 0.88) 0.92
Vitamin B-6
 T3:T1 2.53 (−5.37, 10.43) 0.83 4.19 (−10.21, 18.59) 0.83 0.26 (−13.43, 13.94) 1.00 0.46 (−0.21, 1.13) 0.69
 T2:T1 4.64 (−3.10, 12.38) 0.71 −4.96 (−20.50, 10.57) 0.83 0.81 (−14.85, 16.46) 0.98 −0.65 (−1.20, 0.00) 0.36
Vitamin B-12
 T3:T1 −0.02 (−8.26, 8.22) 1.00 6.42 (−8.93, 21.77) 0.77 1.70 (−11.74, 15.13) 0.92 0.79 (0.09, 1.50) 0.29
 T2:T1 1.53 (−7.17, 10.23) 0.90 −2.40 (−16.46, 11.66) 0.90 −3.38 (−16.85, 10.10) 0.86 0.29 (−0.53, 1.11) 0.82

M-fats monosaturated fats, S-fats saturated fats, Glycpp-choline glycerophosphocholine, Pp-choline phosphocholine, Ppt-choline phosphotidylcholine, dPFV evening to morning peak flow variability, FEV 1 forced expiratory volume in 1 s, PAQLQ pediatric asthma quality of life questionnaire

* q-value < 0.20

Evaluating dietary nutrients with respect to methylation outcomes

Intake of several nutrients was associated with LINE-1 methylation and methylation at CpG promoter site IFNγ-186, but not for IFNγ-54 (Table 3). Children in the highest tertile of kilocalories (3.2% points higher methylation; 95% CI 0.82, 5.58; q = 0.16) or the middle tertile of protein (2.67% points higher methylation; 95% CI 0.62, 4.71; q = 0.16) had higher LINE-1 methylation. Similarly, those in the highest tertile of methyl donating nutrients free choline (2.18% points higher methylation; 95% CI 0.54, 3.82; q = 0.16), total choline (2.60% points higher methylation; 95% CI 0.60, 4.60; q = 0.16) and folate (4.29% points higher methylation; 95% CI 2.25, 6.34; q = 0.01) also had higher LINE-1 methylation. Intake within the middle tertile of kilocalories (4.56% points lower methylation; 95% CI −7.44, −1.69; q = 0.09) and folate (4.05% points lower methylation; 95% CI −6.18, −1.19; q = 0.02) compared to the lowest was associated with less IFNγ-186 methylation. However, intake within middle tertile of monosaturated fat intake (6.88% points higher methylation; 95% CI 3.11, 10.62; q = 0.02) was associated with more IFNγ-186 methylation. Children in the highest tertile of betaine intake (4.34% points lower methylation; 95% CI −7.25, −1.42; q = 0.12) and both the middle and highest tertile of vitamin B6 intake (6.57% points lower methylation; 95% CI −10.65, −2.48; q = 0.09 and 6.63% points lower methylation; 95% CI −11.13, −2.14; q = 0.12, respectively) had less IFNγ CpG-186 methylation.

Table 3.

The relationship between select nutrients and DNA methylation markers by dietary tertiles in ARTIS, where the lowest tertile of intake (T1) is the reference group

Epigenetic measure IFNγ CpG-54 IFNγ CpG-186 LINE-1
Dietary factor Estimate (95% CI) q-value Estimate (95% CI) q-value Estimate (95% CI) q-value
Kilocalories
 T3:T1 0.46 (−2.46, 3.38) 0.90 −0.11 (−4.35, 4.13) 1.00 3.20 (0.82, 5.58) 0.16*
 T2:T1 −0.40 (−2.87, 2.07) 0.90 −4.56 (−7.44, −1.69) 0.09* 0.00 (−2.45, 2.46) 1.00
Protein
 T3:T1 2.60 (−0.90, 6.10) 0.65 −0.04 (−3.41, 3.32) 1.00 1.62 (−0.79, 4.03) 0.69
 T2:T1 2.17 (−0.46, 4.80) 0.55 2.02 (−1.24, 5.27) 0.71 2.67 (0.62, 4.71) 0.16*
M-fats
 T3:T1 −1.10 (−3.70, 1.51) 0.77 4.77 (−0.04, 9.57) 0.36 1.14 (−1.23, 3.51) 0.76
 T2:T1 −2.42 (−4.74, −0.11) 0.33 6.86 (3.11, 10.62) 0.02* 1.12 (−1.00, 3.24) 0.72
S-fats
T3:T1 −0.75 (−3.11, 1.61) 0.83 5.11 (−1.08, 11.31) 0.55 1.52 (−1.09, 4.13) 0.71
T2:T1 1.02 (−1.91, 3.96) 0.82 3.00 (−2.48, 8.48) 0.71 1.26 (−1.45, 3.97) 0.76
Omega 3:6 ratio
 T3:T1 1.44 (−1.23, 4.10) 0.71 2.29 (−1.85, 6.44) 0.71 −0.09 (−2.70, 2.52) 0.99
 T2:T1 3.72 (0.44, 7.01) 0.29 0.24 (−4.72, 5.20) 0.98 0.96 (−1.03, 2.95) 0.74
Selenium
 T3:T1 0.34 (−2.45, 3.13) 0.92 −1.40 (−5.17, 2.38) 0.81 2.32 (−0.15, 4.79) 0.45
 T2:T1 1.40 (−0.60, 3.40) 0.68 −2.38 (−5.01, 0.24) 0.45 −0.18 (−2.69, 2.33) 0.98
Fiber
 T3:T1 0.53 (−2.31, 3.37) 0.90 −4.67 (−9.09, −0.24) 0.33 1.89 (−1.02, 4.80) 0.69
 T2:T1 0.19 (−2.29, 2.68) 0.98 −2.52 (−6.54, 1.49) 0.71 −0.27 (−2.70, 2.16) 0.94
Folate
 T3:T1 2.93 (0.06, 5.80) 0.36 2.46 (−2.25, 7.17) 0.72 4.29 (2.25, 6.34) 0.01*
 T2:T1 1.95 (−0.03, 3.93) 0.36 −4.05 (−6.18, −1.91) 0.02* 0.46 (−1.24, 2.16) 0.85
Methionine
 T3:T1 0.63 (−2.42, 3.68) 0.89 −2.70 (−6.86, 1.45) 0.69 1.12 (−1.78, 4.03) 0.80
 T2:T1 0.43 (−2.25, 3.11) 0.90 −1.38 (−5.68, 2.92) 0.83 1.58 (−1.04, 4.21) 0.71
Free choline
 T3:T1 1.33 (−1.08, 3.74) 0.71 −2.61 (−5.84, 0.63) 0.55 2.18 (0.54, 3.82) 0.16*
 T2:T1 1.29 (−1.03, 3.60) 0.71 −3.28 (−6.33, −0.24) 0.29 0.01 (−1.82, 1.85) 1.00
Glycpp-choline
 T3:T1 0.44 (−2.23, 3.12) 0.90 −2.81 (−5.95, 0.33) 0.48 0.66 (−1.48, 2.80) 0.83
 T2:T1 1.68 (−0.54, 3.89) 0.65 −0.31 (−3.84, 3.22) 0.97 0.24 (−1.74, 2.21) 0.92
Pp-choline
 T3:T1 0.50 (−2.65, 3.65) 0.90 −1.77 (−5.27, 1.73) 0.73 0.41 (−1.43, 2.25) 0.88
 T2:T1 1.47 (−0.52, 3.46) 0.65 −1.54 (−5.83, 2.75) 0.82 −2.08 (−4.41, 0.24) 0.48
Ppt-choline
 T3:T1 1.49 (−1.08, 4.06) 0.71 −2.33 (−6.06, 1.39) 0.71 0.64 (−1.66, 2.94) 0.84
 T2:T1 −0.78 (−3.40, 1.84) 0.83 −1.55 (−6.86, 3.76) 0.83 −1.66 (−4.03, 0.71) 0.68
Total choline
 T3:T1 1.29 (−1.06, 3.64) 0.71 −3.47 (−6.68, −0.26) 0.29 2.60 (0.60, 4.60) 0.16*
 T2:T1 0.85 (−1.41, 3.11) 0.80 −3.58 (−6.59, −0.58) 0.28 0.42 (−1.88, 2.73) 0.90
Betaine
 T3:T1 −0.00 (−2.50, 2.49) 1.00 −4.34 (−7.25, −1.42) 0.12* 1.18 (−1.25, 3.62) 0.74
 T2:T1 1.52 (−1.21, 4.26) 0.71 1.28 (−4.28, 1.73) 0.77 1.65 (−0.61, 3.91) 0.65
Vitamin B-2
 T3:T1 0.62 (−2.44, 3.68) 0.89 −4.19 (−7.91, −0.48) 0.29 2.47 (−0.37, 5.32) 0.51
 T2:T1 1.41 (−0.74, 3.56) 0.69 −4.03 (−7.86, −0.20) 0.33 0.23 (−2.48, 2.94) 0.97
Vitamin B-6
 T3:T1 2.05 (−1.04, 5.14) 0.69 −6.63 (−11.13, −2.14) 0.12* 1.44 (−1.65, 4.52) 0.76
 T2:T1 0.66 (−1.80, 3.12) 0.85 −6.57 (−10.65, −2.48) 0.09* 0.13 (−2.39, 2.65) 0.98
Vitamin B-12
 T3:T1 1.12 (−2.31, 4.55) 0.83 −2.31 (−7.00, 2.39) 0.74 0.59 (−2.43, 3.60) 0.90
 T2:T1 2.21 (−0.48, 4.91) 0.55 1.84 (−2.37, 6.05) 0.77 0.87 (−2.09, 3.82) 0.83

M-fats monosaturated fats, S-fats saturated fats, Glycpp-choline glycerophosphocholine, Pp-choline phosphocholine, Ppt-choline phosphotidylcholine, IFNγ interferon gamma

* q-value <0.20

Evaluating DNA methylation with respect to respiratory health

We investigated the relationships between methylation markers and asthma-related respiratory health measurements (Table 4). A one-percentage point increase of LINE-1 methylation was associated with a 1.24 percentage point (95% CI 0.31, 2.16; q = 0.16) increase in dPFV. Neither IFNγ CpG-54 nor-186 methylation was associated with the respiratory health measures evaluated in this study.

Table 4.

The relationship between epigenetic measurements and asthma health outcomes in ARTIS

Epigenetic marker dPFV % Predicted morning FEV1 % Predicted evening FEV1 PAQLQ
Estimate (95% CI) q-value Estimate (95% CI) q-value Estimate (95% CI) q-value Estimate (95% CI) q-value
LINE-1 1.24 (0.31, 2.16) 0.16* −0.89 (−3.18, 1.41) 0.80 −1.19 (−3.41, 1.03) 0.72 0.04 (−0.11, 0.20) 0.84
IFNγ CpG-186 0.58 (0.06, 1.09) 0.29 −0.53 (−1.79, 0.72) 0.77 −0.57 (−1.62, 0.48) 0.72 0.03 (0.00, 0.07) 0.44
IFNγ CpG-54 0.22 (−0.74, 1.19) 0.87 −0.57 (−1.92, 0.77) 0.77 −0.84 (−2.10, 0.42) 0.69 0.02 (−0.07, 0.11) 0.85

dPFV evening to morning peak flow variability, FEV 1 forced expiratory volume in 1 s, PAQLQ pediatric asthma quality of life questionnaire, IFNγ interferon gamma

* q-value <0.20

Discussion

In this study of dietary nutrients, DNA methylation and asthma-related respiratory health outcomes, we observed positive associations between several nutrients related to one-carbon metabolism (e.g. folate, phosphocholine and betaine) and the PAQLQ score. These nutrients were not similarly associated with better self-monitored spirometry outcomes, suggesting that the nutrients may positively influence asthma quality of life through another mechanism. The composite PAQLQ score is comprised of symptom, activity and emotion domains; however, a post hoc analysis, which substituted individual domains for the composite PAQLQ in a model with dietary nutrients (i.e. those nutrients that had significant relationships with composite PAQLQ), revealed no difference for the impact of dietary intake on individual domains. Furthermore, the individual domains were highly correlated with one another (data not shown) and therefore it is unclear which of these domains may be more affected by diet.

Folate (or folic acid) is one of the most prominently studied methyl donors and is known to play a role in allergic asthma [42]. Many studies have investigated the efficacy of methyl donating nutrient supplementation to reduce the risk of asthma development. To date the results have been inconclusive (see reviews [2, 43]). Many of these supplementation studies have been either limited by ethical concerns or underpowered. We observed that folate intake was associated with a higher PAQLQ score in children with asthma. Based on the most recent reviews, the evidence suggests that early life exposure to folate has no major effects on asthma outcomes later in life [44]. However, relevant to our findings, few studies have investigated the relationship between folate intake and asthma measures in adolescent children with established asthma [45]. Folate deficiency has been associated with asthma-related symptoms and exacerbations [4648]. Folate and betaine are involved in DNA methylation through the formation of S-adenosylmethionine and homocysteine metabolism and therefore have the potential to affect gene expression, thereby influencing asthma pathogenesis [43]. In addition to methyl donors, selenium was also positively associated with PAQLQ score. Fabian et al. found that children with asthma compared to healthy control children had lower plasma levels of selenium and higher exhaled nitric oxide, a marker of poor lung health [49]. However, a group of Swedish researchers found no impact of selenium intake on allergic disease in young children [50]. The inconclusive results regarding the impact of selenium intake on allergic asthma could be attributed to the fact that while selenium does have antioxidant properties it also has the ability to upregulate some immune responses [17, 51]. In our analysis selenium status is associated with better asthma quality of life measures, however, this nutrient was not associated with LINE-1 or IFNγ methylation profiles.

Among the dietary nutrients investigated in this study only phosphatidylcholine was modestly associated with self-administered spirometry measures, specifically higher evening FEV1. Phosphatidylcholine is phospholipid and a major dietary source of choline, which is involved in one-carbon metabolism. Phospholipids can also impact T cell function in a number of ways including membrane fluidity and gene expression, which could have indirect immunomodulatory effects [52]. Therefore, our observation of a positive association between phosphatidylcholine and FEV1 in these children could be reflective of reduced lung inflammation. However, this association was not consistent across tertiles of phosphatidylcholine intake nor was there a consistent response across the different FEV1 measures, evening versus morning. These concerns together with the studies that have linked phosphatidylcholine to cardiovascular disease [53] and related inflammatory symptoms [54], suggest that the association between phosphatidylcholine intake and FEV1 should be interpreted with caution.

In addition to evaluating the relationship between nutritional intake and asthma health, a potential epigenetic mechanism was examined by determining if global methylation or IFNγ promoter methylation was associated with nutritional intake. Global methylation, though informative, is difficult to interpret in the context of respiratory health and may be even more complex in this cohort of children with asthma. Few studies have looked at buccal DNA LINE-1 global methylation in healthy children. A study of 57 healthy girls aged from 6 to 15 investigated LINE-1 global methylation in saliva samples and the average (SD) was 75.2 (3.4) [55]. The cells collected from buccal and saliva should be similar, however the mean LINE-1 methylation in our study overall was considerably lower, which could be attributed to asthma status. It is clear from the literature that intake of methyl donors can result in measureable changes to the mammalian epigenome [20]. Our study shows that dietary intake of folate, free choline, and total choline is positively associated with LINE-1 methylation. By convention, an increase in global methylation is thought to be protective, while a shift toward genome-wide hypomethylation is often associated with a poor health outcome or disease [56, 57]. Nevertheless, our data suggested that global methylation was positively associated with dPFV, an indicator of airway hyper-reactivity. This finding could be a characteristic of the study population, which had relatively low average global methylation. Further, DNA methylation is dynamic and global methylation is a reflection of the epigenetic changes occurring at many gene locations.

Our study specifically focused on IFNγ as a candidate gene, hypothesizing that this gene would lie in the mechanistic pathway linking dietary intake to asthma health outcomes in children. Previous studies have established that IFNγ CpG-54 and -186 (-53 and -190 are the corresponding murine CpGs) are relevant to allergic outcomes in animal models [58, 59] and humans [6062]. In the mouse, Jones et al. showed that these CpGs are functionally relevant (i.e., methylation status affects transcription of the IFNγ gene) and that de novo methylation of these sites plays a key role in Th2 polarization at least within the CD4+ T cells [63]. In an human asthma cohort, Lovinsky-Desir et al. showed that there are differential methylation profiles for these CpGs relative to age, sex and tissue type [64]. For example, when methylation profiles of buccal cells and CD4+ lymphocytes isolated from whole blood were compared, IFNγ CpG-186 was correlated for males but not females. Further, methylation values for IFNγ CpG-54 and -186 were correlated for children and adults in CD4+ lymphocytes but only for adults in buccal cells. White et al. investigated IFNγ promoter methylation profiles by in vitro polyclonal expansion of CD4+ and CD8+ T cells sorted from peripheral blood mononuclear cells [62]. When samples collected from adolescent children were stratified by atopic status, the authors found that, for CD8+ T cells under Th1 polarizing conditions, IFNγ CpG sites -54 and -186 were less methylated in the non-atopic children.

When evaluating the impact of diet on IFNγ promoter methylation, we found that only IFNγ CpG-186 methylation patterns were affected by selected nutrients. We observed that intake of kilocalories and three methyl donating nutrients was associated with less IFNγ CpG-186 methylation, while children who had higher intake of monosaturated fats had more IFNγ CpG-186 methylation. Based on the functional data available for this CpG site, which we note does not come from buccal cells, we speculate that a negative association between a dietary nutrient and methylation at this site could impact the Th1/Th2 balance by increasing the expression of IFNγ. Overall nutrient intake has previously been linked to IFNγ production [65]. However, overnutrition is not likely a preferable or effective asthma intervention especially due to the potential links between obesity, inflammation, and asthma. Monosaturated fat was the only nutrient we found to be positively associated with IFNγ-186 methylation. In a study of approximately 1200 adolescent children conducted in Taiwan, intake of monosaturated fats was inversely associated with risk of asthma [66]. By contrast, a study of nearly 4000 adult European participants found that intake of monosaturated fats was positively associated with allergic sensitization [67].

IFNγ CpG promoter methylation at site -54 and -186 was not associated with respiratory health measures or PAQLQ. This suggests that the positive relationship revealed between PAQLQ composite score and intake of selenium, folate, phosphocholine, and betaine may not be working directly through epigenetic modification of these specific sites as we had hypothesized.

Limitations and cautions

We evaluated several dietary macro- and micronutrients in this study, but these factors likely include only a portion of the exogenous factors that could influence DNA methylation in this population. While FFQs are an accepted and validated method for acquiring personal dietary information, we note that the portion sizes and specific foodstuffs were self-reported by the participants with assistance and input from parents. Though it is widely accepted, BMI may actually be a poor indicator for obesity in children and adolescents who have large, lean body mass from physical activity, high muscularity, or frame size. By focusing on select candidate DNA methylation markers, we recognize that numerous inflammatory pathways involving diet and asthma may not have been captured. We also are limited in our interpretation of the DNA methylation data because we did not measure IFNγ expression or protein levels in these samples. For example, we found some dietary factors to be negatively associated with DNA methylation, which could be informative for asthma intervention strategies, but such interpretations require further assessment as methylation changes do not necessarily translate to functional changes in the target tissue. Finally, although we accounted for false discoveries, we recognize that several statistical tests were performed and would expect some significant results due to chance alone. Thus these observations should be considered exploratory and requiring of further study in other populations.

Conclusions

Within this cohort of childhood asthmatics, we sought to identify dietary nutrients that may be beneficial for respiratory health. In addition we measured LINE-1 and IFNγ (CpG-54 and -186) methylation levels to identify pathways whereby diet influences the health among children with asthma. In this study, selenium and several nutrients involved in the one-carbon metabolism pathway were associated with improved asthma quality of life measures. Furthermore, these data showed that some dietary constituents were associated with both global and gene specific methylation in children with asthma. The two IFNγ CpG sites that were investigated appear to be uniquely affected by intake of micro- and macronutrients.

Authors’ contributions

LM aided in the design of the study, acquisition and analysis of data, and with drafting the manuscript. TW aided in the design of the study and with drafting the manuscript. ES contributed to the data analysis strategy and interpretation as well as with drafting the manuscript. YHC provided support for epigenetic assays and with manuscript revisions. BB aided in the design, collection, and analysis of diet related data as well as manuscript revisions. CN aided in the design of the study, data analysis strategy and interpretation, and with drafting the manuscript. All authors read and approved the final manuscript.

Acknowledgements

The authors would like to thank Dr. Jackie Goodrich and Virginia Kay for providing support for epigenetic assay development, Emily Weiler for field collection of data, Dr. Dana Dolinoy for mentorship and Carolyn Hester for aiding in study management and organization.

Competing interests

The authors declare that they have no competing interests.

Availability of data and materials

Please contact author for data requests.

Ethics approval and consent to participate

The study was approved by the University of Montana Institutional Review Board (protocol numbers 233_10 and 152_11). In addition to the informed consent procedures for the parent study, children were separately assented to participate in this diet and epigenetics study and parents signed a parental permission and informed consent form.

Funding

This research was supported by the National Institute of Environmental Health Sciences (1R01ES016336–01 and 3R01ES016336–02S1). Additional support was provided by a COBRE award (P20RR017670) and the National Institute of General Medical Sciences (P20GM103474 and 1U54GM104944). LM was partially supported by an NIH NRSA T32 training program Grant (#E2007062, PI: Rita Loch-Caruso). The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

Abbreviations

ARTIS

asthma randomized trial of indoor wood smoke

BMI

body mass index

CDC

U.S. Centers for Disease Control and Prevention

CI

confidence interval

CpG

regions of DNA where a cytosine nucleotide is followed by a guanine nucleotide

DNA

deoxyribonucleic acid

dPFV

diurnal peak flow variability

FEV1

forced expiratory volume in the first second

FFQ

food frequency questionnaires

FOXp3

transcription factor forkhead box p3

GEE

generalized estimating equations

glycpp-choline

glycerophosphocholine

IFNγ

interferon gamma

LINE-1

long interspersed nuclear elements

M-fats

monosaturated fats

NO2

nitrogen dioxide

PAQLQ

pediatric asthma quality of life questionnaire

PCR

polymerase chain reaction

PEF

peak expiratory flow

PM

particulate matter

PM2.5

fine PM or particles less than 2.5 micrometers in aerodynamic diameter

Pp-choline

phosphocholine

Ppt-choline

phosphotidylcholine

Runx3

runt-related transcription factor 3

S-fats

saturated fats

SD

standard deviation

Tregs

regulatory T cells

Th1

type 1 T helper

Th2

type 2 T helper

USEPA

U.S. Environmental Protection Agency

Additional file

13223_2017_187_MOESM1_ESM.docx (119.3KB, docx)

Additional file 1: Table S1. Primers and amplification conditions for PCR and pyrosequencing experiments. Figure S1. Description of ARTIS sub-study design.

Contributor Information

L. Montrose, Email: montluke@umich.edu

T. J. Ward, Email: Tony.Ward@mso.umt.edu

E. O. Semmens, Email: Erin.Semmens@mso.umt.edu

Y. H. Cho, Email: yoonhee.cho@mso.umt.edu

B. Brown, Email: Blakely.Brown@mso.umt.edu

C. W. Noonan, Phone: (406) 243-4957, Email: curtis.noonan@mso.umt.edu

References

  • 1.Akinbami LJ, et al. Trends in asthma prevalence, health care use, and mortality in the United States, 2001–2010. NCHS Data Brief. 2012;94:1–8. [PubMed] [Google Scholar]
  • 2.Han YY, et al. Diet and asthma: vitamins and methyl donors. Lancet Respir Med. 2013;1(10):813–822. doi: 10.1016/S2213-2600(13)70126-7. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 3.Thuesen BH, et al. Atopy, asthma, and lung function in relation to folate and vitamin B(12) in adults. Allergy. 2010;65(11):1446–1454. doi: 10.1111/j.1398-9995.2010.02378.x. [DOI] [PubMed] [Google Scholar]
  • 4.Mehta AK, et al. Choline attenuates immune inflammation and suppresses oxidative stress in patients with asthma. Immunobiology. 2010;215(7):527–534. doi: 10.1016/j.imbio.2009.09.004. [DOI] [PubMed] [Google Scholar]
  • 5.Barros R, et al. Adherence to the Mediterranean diet and fresh fruit intake are associated with improved asthma control. Allergy. 2008;63(7):917–923. doi: 10.1111/j.1398-9995.2008.01665.x. [DOI] [PubMed] [Google Scholar]
  • 6.Barros R, et al. Dietary intake of alpha-linolenic acid and low ratio of n-6:n-3 PUFA are associated with decreased exhaled NO and improved asthma control. Br J Nutr. 2011;106(3):441–450. doi: 10.1017/S0007114511000328. [DOI] [PubMed] [Google Scholar]
  • 7.Castro-Rodriguez JA, et al. Mediterranean diet as a protective factor for wheezing in preschool children. J Pediatr. 2008;152(6):823–828. doi: 10.1016/j.jpeds.2008.01.003. [DOI] [PubMed] [Google Scholar]
  • 8.Chatzi L, et al. Diet, wheeze, and atopy in school children in Menorca, Spain. Pediatr Allergy Immunol. 2007;18(6):480–485. doi: 10.1111/j.1399-3038.2007.00596.x. [DOI] [PubMed] [Google Scholar]
  • 9.Chatzi L, et al. Mediterranean diet in pregnancy is protective for wheeze and atopy in childhood. Thorax. 2008;63(6):507–513. doi: 10.1136/thx.2007.081745. [DOI] [PubMed] [Google Scholar]
  • 10.de Batlle J, et al. Mediterranean diet is associated with reduced asthma and rhinitis in Mexican children. Allergy. 2008;63(10):1310–1316. doi: 10.1111/j.1398-9995.2008.01722.x. [DOI] [PubMed] [Google Scholar]
  • 11.Garcia-Marcos L, et al. Relationship of asthma and rhinoconjunctivitis with obesity, exercise and Mediterranean diet in Spanish schoolchildren. Thorax. 2007;62(6):503–508. doi: 10.1136/thx.2006.060020. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 12.Romieu I, et al. Dietary intake, lung function and airway inflammation in Mexico City school children exposed to air pollutants. Respir Res. 2009;10:122. doi: 10.1186/1465-9921-10-122. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 13.Berthon BS, Wood LG. Nutrition and respiratory health-feature review. Nutrients. 2015;7(3):1618–1643. doi: 10.3390/nu7031618. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 14.Berthon BS, et al. Investigation of the association between dietary intake, disease severity and airway inflammation in asthma. Respirology. 2013;18(3):447–454. doi: 10.1111/resp.12015. [DOI] [PubMed] [Google Scholar]
  • 15.Cortessis VK, et al. Environmental epigenetics: prospects for studying epigenetic mediation of exposure–response relationships. Hum Genet. 2012;131(10):1565–1589. doi: 10.1007/s00439-012-1189-8. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 16.Lovinsky-Desir S, Miller RL. Epigenetics, asthma, and allergic diseases: a review of the latest advancements. Curr Allergy Asthma Rep. 2012;12(3):211–220. doi: 10.1007/s11882-012-0257-4. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 17.Norton RL, Hoffmann PR. Selenium and asthma. Mol Aspects Med. 2012;33(1):98–106. doi: 10.1016/j.mam.2011.10.003. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 18.Bansal P, et al. Intranasal administration of a combination of choline chloride, vitamin C, and selenium attenuates the allergic effect in a mouse model of airway disease. Free Radic Biol Med. 2014;73:358–365. doi: 10.1016/j.freeradbiomed.2014.05.018. [DOI] [PubMed] [Google Scholar]
  • 19.North ML, Ellis AK. The role of epigenetics in the developmental origins of allergic disease. Ann Allergy Asthma Immunol. 2011;106(5):355–361. doi: 10.1016/j.anai.2011.02.008. [DOI] [PubMed] [Google Scholar]
  • 20.Dolinoy DC. The agouti mouse model: an epigenetic biosensor for nutritional and environmental alterations on the fetal epigenome. Nutr Rev. 2008;66(Suppl 1):S7–S11. doi: 10.1111/j.1753-4887.2008.00056.x. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 21.Hollingsworth JW, et al. In utero supplementation with methyl donors enhances allergic airway disease in mice. J Clin Invest. 2008;118(10):3462–3469. doi: 10.1172/JCI34378. [DOI] [PMC free article] [PubMed] [Google Scholar] [Retracted]
  • 22.Lloyd CM, Hawrylowicz CM. Regulatory T cells in asthma. Immunity. 2009;31(3):438–449. doi: 10.1016/j.immuni.2009.08.007. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 23.Nadeau K, et al. Ambient air pollution impairs regulatory T-cell function in asthma. J Allergy Clin Immunol. 2010;126(4):845–852. doi: 10.1016/j.jaci.2010.08.008. [DOI] [PubMed] [Google Scholar]
  • 24.Friso S, et al. One-carbon metabolism and epigenetics. Mol Aspects Med. 2016. [DOI] [PubMed]
  • 25.Calderon C, et al. T-cell cytokine profiles are altered in childhood asthma exacerbation. Respirology. 2009;14(2):264–269. doi: 10.1111/j.1440-1843.2008.01464.x. [DOI] [PubMed] [Google Scholar]
  • 26.Crinnion WJ. Do environmental toxicants contribute to allergy and asthma? Altern Med Rev. 2012;17(1):6–18. [PubMed] [Google Scholar]
  • 27.Smart JM, et al. Polyclonal and allergen-induced cytokine responses in adults with asthma: resolution of asthma is associated with normalization of IFN-gamma responses. J Allergy Clin Immunol. 2002;110(3):450–456. doi: 10.1067/mai.2002.127283. [DOI] [PubMed] [Google Scholar]
  • 28.Meng H, et al. In vitro production of IL-6 and IFN-gamma is influenced by dietary variables and predicts upper respiratory tract infection incidence and severity respectively in young adults. Front Immunol. 2015;6:94. doi: 10.3389/fimmu.2015.00094. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 29.Mohammadi-Shahrokhi V, et al. Immunomodulatory effects of adjuvants CPG, MPLA, and BCG on the Derp2-induced acute asthma at early life in an animal model of BALB/c Mice. Inflammation. 2016. [DOI] [PubMed]
  • 30.Santeliz JV, et al. Amb a 1-linked CpG oligodeoxynucleotides reverse established airway hyperresponsiveness in a murine model of asthma. J Allergy Clin Immunol. 2002;109(3):455–462. doi: 10.1067/mai.2002.122156. [DOI] [PubMed] [Google Scholar]
  • 31.Noonan CW, Ward TJ. Asthma randomized trial of indoor wood smoke (ARTIS): rationale and methods. Contemp Clin Trials. 2012;33(5):1080–1087. doi: 10.1016/j.cct.2012.06.006. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 32.Ward TJ, et al. Efficacy of interventions targeting household air pollution from residential wood stoves. J Expo Sci Environ Epidemiol. 2017;27(1):64–71. doi: 10.1038/jes.2015.73. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 33.Semmens EO, et al. Indoor particulate matter in rural, wood stove heated homes. Environ Res. 2015;138:93–100. doi: 10.1016/j.envres.2015.02.005. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 34.BMI percentile calculator for child and teen. https://nccd.cdc.gov/dnpabmi/calculator.aspx. Accessed 1 Dec 2016.
  • 35.Block G, et al. Revision of dietary analysis software for the health habits and history questionnaire. Am J Epidemiol. 1994;139(12):1190–1196. doi: 10.1093/oxfordjournals.aje.a116965. [DOI] [PubMed] [Google Scholar]
  • 36.Block G, DiSogra C. WIC dietary assessment validation study. Final report. Alexandria: US Department of Agriculture, Food and Nutrition Service; 1995. [Google Scholar]
  • 37.Block G, et al. Comparison of two dietary questionnaires validated against multiple dietary records collected during a 1-year period. J Am Diet Assoc. 1992;92:686–693. [PubMed] [Google Scholar]
  • 38.Block G, et al. Validation of a self-administered diet history questionnaire using multiple diet records. J Clin Epidemiol. 1990;43(12):1327–1335. doi: 10.1016/0895-4356(90)90099-B. [DOI] [PubMed] [Google Scholar]
  • 39.Juniper EF, et al. Measuring quality of life in children with asthma. Qual Life Res. 1996;5(1):35–46. doi: 10.1007/BF00435967. [DOI] [PubMed] [Google Scholar]
  • 40.Benjamini Y, Hochberg Y. Controlling the false discovery rate—a practical and powerful approach to multiple testing. J R Stat Soc Series B-Methodol. 1995;57(1):289–300. [Google Scholar]
  • 41.Lung National Heart, Institute Blood. Expert panel report 3: guidelines for the diagnosis and management of asthma. Bethesda: National Heart Lung, and Blood Institute; 2007. [Google Scholar]
  • 42.Sharma S, Litonjua A. Asthma, allergy, and responses to methyl donor supplements and nutrients. J Allergy Clin Immunol. 2014;133(5):1246–1254. doi: 10.1016/j.jaci.2013.10.039. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 43.Blatter J, et al. Folate and asthma. Am J Respir Crit Care Med. 2013;188(1):12–17. doi: 10.1164/rccm.201302-0317PP. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 44.Crider KS, et al. Prenatal folic acid and risk of asthma in children: a systematic review and meta-analysis. Am J Clin Nutr. 2013;98(5):1272–1281. doi: 10.3945/ajcn.113.065623. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 45.Lin JH, et al. Relationships between folate and inflammatory features of asthma. J Allergy Clin Immunol. 2013;131(3):918–920. doi: 10.1016/j.jaci.2012.10.046. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 46.Matsui EC, Matsui W. Higher serum folate levels are associated with a lower risk of atopy and wheeze. J Allergy Clin Immunol. 2009;123(6):1253–1259. doi: 10.1016/j.jaci.2009.03.007. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 47.Farres MN, et al. Study of folate status among Egyptian asthmatics. Intern Med. 2011;50(3):205–211. doi: 10.2169/internalmedicine.50.4424. [DOI] [PubMed] [Google Scholar]
  • 48.Blatter J, et al. Folate deficiency, atopy, and severe asthma exacerbations in Puerto Rican children. Ann Am Thorac Soc. 2016;13(2):223–230. doi: 10.1513/AnnalsATS.201508-549OC. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 49.Fabian E, et al. Nutritional supplements and plasma antioxidants in childhood asthma. Wien Klin Wochenschr. 2013;125(11–12):309–315. doi: 10.1007/s00508-013-0359-6. [DOI] [PubMed] [Google Scholar]
  • 50.Rosenlund H, et al. Antioxidant intake and allergic disease in children. Clin Exp Allergy. 2012;42(10):1491–1500. doi: 10.1111/j.1365-2222.2012.04053.x. [DOI] [PubMed] [Google Scholar]
  • 51.Hoffmann PR. Selenium and asthma: a complex relationship. Allergy. 2008;63(7):854–856. doi: 10.1111/j.1398-9995.2008.01676.x. [DOI] [PubMed] [Google Scholar]
  • 52.Pollock AH, et al. Prolonged Intake of dietary lipids alters membrane structure and T cell responses in LDLr−/− Mice. J Immunol. 2016;196(10):3993–4002. doi: 10.4049/jimmunol.1501261. [DOI] [PubMed] [Google Scholar]
  • 53.Wang Z, et al. Gut flora metabolism of phosphatidylcholine promotes cardiovascular disease. Nature. 2011;472(7341):57–63. doi: 10.1038/nature09922. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 54.de Pablo MA, Puertollano MA, Alvarez de Cienfuegos G. Biological and clinical significance of lipids as modulators of immune system functions. Clin Diagn Lab Immunol. 2002;9(5):945–950. doi: 10.1128/CDLI.9.5.945-950.2002. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 55.Wu HC, et al. Correlation of DNA methylation levels in blood and saliva DNA in young girls of the LEGACY Girls study. Epigenetics. 2014;9(7):929–933. doi: 10.4161/epi.28902. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 56.Rozek LS, et al. Epigenetics: relevance and implications for public health. Annu Rev Public Health. 2014;35:105–122. doi: 10.1146/annurev-publhealth-032013-182513. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 57.Perera F, Herbstman J. Prenatal environmental exposures, epigenetics, and disease. Reprod Toxicol. 2011;31(3):363–373. doi: 10.1016/j.reprotox.2010.12.055. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 58.Liu J, et al. Combined inhaled diesel exhaust particles and allergen exposure alter methylation of T helper genes and IgE production in vivo. Toxicol Sci. 2008;102(1):76–81. doi: 10.1093/toxsci/kfm290. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 59.Brand S, et al. DNA methylation of TH1/TH2 cytokine genes affects sensitization and progress of experimental asthma. J Allergy Clin Immunol. 2012;29(6):1602–1610. doi: 10.1016/j.jaci.2011.12.963. [DOI] [PubMed] [Google Scholar]
  • 60.Runyon RS, et al. Asthma discordance in twins is linked to epigenetic modifications of T cells. PLoS ONE. 2012;7(11):e48796. doi: 10.1371/journal.pone.0048796. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 61.Kohli A, et al. Secondhand smoke in combination with ambient air pollution exposure is associated with increasedx CpG methylation and decreased expression of IFN-gamma in T effector cells and Foxp3 in T regulatory cells in children. Clin Epigenetics. 2012;4(1):17. doi: 10.1186/1868-7083-4-17. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 62.White GP, et al. CpG methylation patterns in the IFNgamma promoter in naive T cells: variations during Th1 and Th2 differentiation and between atopics and non-atopics. Pediatr Allergy Immunol. 2006;17(8):557–564. doi: 10.1111/j.1399-3038.2006.00465.x. [DOI] [PubMed] [Google Scholar]
  • 63.Jones B, Chen J. Inhibition of IFN-gamma transcription by site-specific methylation during T helper cell development. EMBO J. 2006;25(11):2443–2452. doi: 10.1038/sj.emboj.7601148. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 64.Lovinsky-Desir S, et al. DNA methylation of the allergy regulatory gene interferon gamma varies by age, sex, and tissue type in asthmatics. Clin Epigenetics. 2014;6(1):9. doi: 10.1186/1868-7083-6-9. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 65.van den Brink GR, et al. Feed a cold, starve a fever? Clin Diagn Lab Immunol. 2002;9(1):182–183. doi: 10.1128/CDLI.9.1.182-183.2002. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 66.Huang SL, Pan WH. Dietary fats and asthma in teenagers: analyses of the first Nutrition and Health Survey in Taiwan (NAHSIT) Clin Exp Allergy. 2001;31(12):1875–1880. doi: 10.1046/j.1365-2222.2001.01222.x. [DOI] [PubMed] [Google Scholar]
  • 67.Heinrich J, et al. Allergic sensitization and diet: ecological analysis in selected European cities. Eur Respir J. 2001;17(3):395–402. doi: 10.1183/09031936.01.17303950. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Please contact author for data requests.


Articles from Allergy, Asthma, and Clinical Immunology : Official Journal of the Canadian Society of Allergy and Clinical Immunology are provided here courtesy of BMC

RESOURCES