Study Participants

The Adult Health Study (AHS) cohort was established in 1958, and has enrolled 23,000 A-bomb survivors in Hiroshima and Nagasaki who undergo biennial health examinations at the outpatient clinics of the Radiation Effects Research Foundation (RERF) (20). Approximately 1,100 Hiroshima participants in the AHS were randomly selected to examine immunological phenotypes (21, 22). Of these participants, telomere length was measured for 792 survivors who donated blood samples in 2003–2009. We excluded 171 participants who had been diagnosed with cancer, due to the potential effects of cancer development or therapeutics on telomere length, as well as one participant who had a missing value for smoking, resulting in 620 participants for statistical analyses (Table 1). Radiation dose was the weighted absorbed bone marrow dose (Gy), based on the Dosimetry System 2002 and recent updates (23–25).

TABLE 1

Study Participants (N = 620)

This study was approved by the RERF Human Investigation Committee, and was conducted according to the principles expressed in the Declaration of Helsinki. All participants gave written informed consent before each examination.

Measurement of Specific Telomere Fluorescence by Flow-FISH

Peripheral blood mononuclear cell (PBMC) fractions were collected from the upper layer of the Ficoll-Hypaque gradient sedimentation of fresh heparinized blood samples. Granulocyte fractions were obtained by hemolysis of buffy coat blood cells collected from the lower layer of the blood sedimentation. Approximately 10 million PBMCs were stained with fluorescein isothiocyanate (FITC)-labeled anti-CD4 antibody (BD Biosciences, San Jose, CA), phycoerythrin (PE)-labeled anti-CD45RA antibody (Beckman Coulter^® Inc., Fullerton, CA) and PE-Cy5-labeled anti-CD8 (BD Biosciences). Naïve (CD4⁺CD45RA⁺) and memory (CD4⁺CD45RA^–) CD4 T cells and total CD8 T cells (CD8^bright) were sorted using a FACSVantage™ (BD Biosciences). The telomere lengths in these T-cell fractions and granulocytes were measured using fluorescence in situ hybridization (FISH) as previously described by Rufer et al (26), using 1 × 10⁵ cells of each of the cell fractions. In brief, this procedure involved DNA denaturation at 85°C for 10 min and hybridization at 20°C overnight in 70% formamide, 20 mM Tris-HCl and 0.1% bovine serum albumin solution with FITC-labeled telomere-specific (CCCTAA)₃ or telomere–unspecific (CCC ATA ACT AAA CAC: the alphoid sequences of the X chromosome) peptide nucleic acid (PNA) probes (Sawady Technology Inc., Tokyo, Japan). After treatment of the cells with RNase, the interphase cell fraction was determined by measuring the fluorescence of 7-aminoactinomycin-d that binds to cellular DNA. FITC fluorescent intensity and its distribution in the interphase cells were measured using a FACScan™ (BD Biosciences). Specific telomere fluorescence was determined by subtracting the mean fluorescent intensity with telomere-unspecific probes from that with telomere-specific probes. In addition, we confirmed the reproducibility of the flow-FISH method and found highly correlated results between this fluorescence-based measurement and a Southern blot method in our previous study (27).

Lifestyle Factors and Clinical Information

Lifestyle and clinical information were obtained as previously described (22). Information on alcohol consumption and smoking at the time of telomere measurement was obtained from questionnaires at the AHS health examinations in 2003–2009. Clinical information such as body mass index (BMI), total serum cholesterol, HDL cholesterol, low-density lipoprotein (LDL) cholesterol, hemoglobin A1c (HbA1c), C-reactive protein (CRP) levels and diseases was also obtained at these health examinations. The following conditions (according to ICD-10 codes) were classified and included in the statistical analyses: cancer (C00–C97, D00–D09), ischemic heart disease (I20–I25), type-2 diabetes (E11–E14, based on blood HbA1c and glucose levels as well as treatment information), fatty liver (K70.0 and K76.0, based on abdominal ultrasonography findings) and hypertension (I10–I15).

Statistical Data Analysis

The association between each telomere length measurement and radiation exposure was evaluated with multiple linear regression, taking the natural log-transformation of telomere length. Considering the highly right-skewed distribution of the radiation dose in A-bomb survivors, we evaluated the effects of high-dose points by comparing the regression results of natural log-transformed telomere length and original-scale radiation dose to the results of methods such as super smoothers in nonparametric smoothing, in which it was known that the results of the analysis would be robust to the effect of influential data points, and to the results of analyses based on log-transformed telomere length and log-transformed radiation dose. We took the logarithm of the radiation dose by adding a small number (added 0.005 Gy) to avoid taking log of zero. The analysis was adjusted for continuous variables of participant age at examination, alcohol consumption and quantity of smoking; an indicator variable of gender; and metabolic-condition-related continuous variables (BMI, HbA1c, total cholesterol, HDL cholesterol, LDL cholesterol and CRP) and indicator variables of diseases (ischemic heart disease, type-2 diabetes, fatty liver and hypertension) possibly related to telomere length. The scatter plots of each telomere length measurement for radiation dose as well as age showed high variability among individuals, and we used both linear terms as well as nonlinear terms of age and radiation dose to detect complex changes in telomere length as it relates to aging and radiation exposure in the model selection. The starting model consisted of the main effects of the linear terms of age and dose, the quadratic terms of age and dose, the cubic term of dose and all of the candidate covariates. The stepwise variable selection based on the Akaike Information Criterion (AIC) was then applied to evaluate the association with telomere lengths using the “step” function of R statistical software ( http://cran.r-project.org). Because we were investigating the existence of associations between the telomere length of each subset and the metabolic status of the participants, we selected the models with the minimum AIC of each end point and evaluated the association of radiation exposure with telomere lengths with adjustment of selected sets of variables. When none of the radiation terms was included in the model, association between telomere length and a linear term of radiation was shown. The model fits of polynomial functions of radiation dose for each end point were also compared by the AIC with that of the dose-response model commonly considered due to radiation-induced effects, such as sterilizing (or cell killing): (β₁ d + β₂ d²) e^γd, where d is the radiation dose, β₁ and β₂ are regression coefficients of linear and quadratic terms of radiation dose, respectively, and γ is the additional regression coefficient of the sterilizing effect of γ < 0. Additionally, mean telomere lengths were compared by radiation dose category (0–0.005 Gy, 0.005–0.5 Gy, 0.5–1 Gy and ≥1 Gy), adjusting for selected covariates in the model selection. The final parametric model was decided by the AIC and by comparing the shape of the parametric function of selected radiation terms to that of nonparametric estimates and also to the smoothing curve of residual plots of the final model without radiation terms. Then, super smoother was mainly used as a method of nonparametric smoothing to lessen the effect of influential points and outliers.

In addition, recent evidence from mouse studies suggests direct interactions between individual metabolic status and biological responses to radiation exposure (28, 29). Therefore, the difference in the association between radiation dose and telomere length with different values of metabolic conditions or diseases was investigated by testing the two-way multiplicative interaction of radiation terms and each metabolic indicator by adding those variables to the selected best models of each subset in the main effect investigation mentioned above. We also considered dividing the radiation dose range because we may not be able to ignore the possibility that different biological mechanisms may underlie some responses to high-dose radiation; i.e., the association was investigated separately for individuals with radiation exposure <0.5 and ≥0.5 Gy, at which lymphocyte apoptosis is generally induced. All of the tests were two-sided, and analyses were conducted using R software version 3.2.1.

Telomere Length and Aging

The basic characteristics of the study participants, a subset of the A-bomb survivor cohort, are shown in Table 1, and a representative flow cytometry pattern is shown in Fig. 1. We conducted multiple regression analyses using age at examination, gender, radiation dose, alcohol consumption and smoking along with metabolic conditions and diseases, to find potential factors that might influence telomere length in peripheral blood T-cell populations and granulocytes. To detect complex changes in telomere length related to aging and radiation exposure, we used not only linear terms but also nonlinear terms for age and radiation dose in the statistical models. The results showed that the coefficients of telomere length were negative for the linear term of age while positive for the quadratic term of age (age²) in all of the cell populations examined (Table 2). These results suggest that telomere length decreased with age, and did so at a slower rate at around 80 years of age (Fig. 2).

FIG. 1.

A representative flow cytometry pattern in flow-FISH. Panel A: Typical flow cytometry pattern of naïve (CD45RA⁺) CD4 T and memory (CD45RA^–) CD4 T cells in an A-bomb survivor. Panels B and C: Fluorescence intensity in each T-cell subset assessed by flow-FISH with telomere-unspecific (dashed lines) and telomere-specific probes (solid lines) in the same survivor.

TABLE 2

Regression Analyses of Telomere Length in Peripheral Blood Cell Populations

FIG. 2.

Telomere length with age in peripheral T-cell populations and granulocytes. Each dot represents a measured value of telomere length. Specific telomere fluorescence was determined by subtracting the mean fluorescent intensity with telomere-unspecific probes from that with telomere-specific probes, and was then natural log-transformed. The solid curves in each panel represent predicted values obtained from parametric regression models. The thin curves represent nonparametric smoothers of the residuals of the multivariable regression model as a function of age. These overlapping curves are estimated for individuals who were not exposed to A-bomb radiation and who had the median HbA1c value and no fatty liver.

Telomere Length and Radiation Exposure

Analysis of telomere length and radiation exposure indicated significant associations between telomere length and dose in naïve and memory CD4 and total CD8 T-cell populations, i.e., positive coefficients of telomere length for linear terms or a quadratic term of radiation dose (radiation dose²) and negative coefficients for cubic terms of radiation dose (radiation dose³; Table 2 and Fig. 3). Similar results were obtained in linear-quadratic models and nonlinear models, but the AIC of the final models showed a better fit than the other models (data not shown). In addition, comparison of the mean telomere length of radiation dose categories showed that there was a significant increase in the 0.5–1 Gy category (the mean telomere lengths in arbitrary units, a nonlogarithmic scale: 187.0, 145.7, 149.0) compared to the lowest dose category (0–0.005 Gy, the mean telomere lengths: 170.0, 122.3, 129.6) in naïve CD4, memory CD4 and CD8 T-cell populations (P = 0.04, P = 0.002, P = 0.03), respectively; there was a slight but statistically-insignificant decrease in the higher dose category (≥1 Gy, the mean telomere lengths: 183.2, 138.0, 144.3) compared to the 0.5–1 Gy category. Telomere lengths were not significantly different between the 0–0.005 and ≥1 Gy dose categories (data not shown). We further examined the relationship between telomere length and log-transformed radiation dose since, by taking the log of the radiation dose, the study participants were relatively equally distributed in terms of radiation dose, and it was possible that such log transformation of the dose might weaken the influence of the small number of higher dose individuals in the regression analysis. The nonparametric smoothing curves using super smoother of residuals obtained in regression models without radiation terms showed a steeper decreasing trend in the telomere length of three T-cell populations when the dose was greater than approximately 0.5–1 Gy (see the thin curves shown in Fig. 3). On the other hand, those decreasing trends were not statistically captured in the parametric modeling using a log-radiation dose. Based on the model selection, the parametric shape of regression results between the telomere length and log-radiation dose was as follows: a linear function of log dose in memory CD4 T cells (P = 0.02) with a positive coefficient of 0.02, and a quadratic term of log dose in CD8 T cells (P = 0.07) with a negative coefficient of −0.003. However, when we focused on a narrower domain of radiation dose by dividing the dose range into two; i.e., when individuals with <0.5 Gy and those with ≥0.5 Gy exposure were separately analyzed, inverse associations between telomere length and radiation dose were observed at doses of ≥0.5 Gy, using both original-scale and log-transformed radiation doses (Tables 3 and 4). These data suggest that there were tendencies for radiation-associated telomere shortening at doses higher than approximately 0.5 Gy, whereas telomeres could be elongated with exposure to lower doses of radiation. We observed no significant radiation effects on telomere length in granulocytes.

FIG. 3.

Telomere length with radiation dose in peripheral T-cell populations and granulocytes. Each dot represents a natural log-transformed measured value of telomere length. Solid curves represent predicted values obtained from parametric regression models. The thin curves represent nonparametric smoothers of each scatter plot between radiation and residuals of multivariable parametric regression. These overlapping curves are estimated for individuals who are 70 years old, with median HbA1c value and no fatty liver.

TABLE 3

Regression Analyses of Telomere Length for Two Separate Dose Ranges (Original-Scale Radiation Dose)

TABLE 4

Regression Analyses of Telomere Length for Two Separate Dose Ranges (Log-Transformed Radiation Dose)

Telomere Length and Metabolic Status

Metabolic parameters (BMI, total, HDL and LDL cholesterols, HbA1c and CRP) and diseases (ischemic heart disease, type-2 diabetes, fatty liver and hypertension) were included in the regression models as candidate factors related to telomere length. Most of these parameters were not significantly associated with telomere length in T-cell populations. However, we found significant inverse associations between telomere length and HbA1c or fatty liver development in both naïve and memory CD4 and total CD8 T-cell populations (Table 2). In addition, although we employed BMI imputation for individuals who had missing BMI data in the presented analyses, analyses excluding such individuals yielded similar results (data not shown).

Finally, we investigated the significance of interaction terms between radiation dose and each metabolic parameter or disease with telomere length in T-cell populations. The interaction term of CRP and linear radiation dose was found to be significantly associated with telomere length in naïve and memory CD4 T-cell populations (P = 0.03 and 0.036, Table 5) with negative coefficients in the nonlinear relationships between radiation and telomere length. The interaction terms were not statistically associated with telomere length when individuals with <0.5 and ≥0.5 Gy were separately analyzed. Furthermore, the interaction term of cubic radiation dose and HDL cholesterol was selected in the naïve and memory CD4 T-cell populations in the model selection (P = 0.07 and 0.06, respectively). When we looked only at those individuals exposed to ≥0.5 Gy radiation, the interaction term was statistically significant in naïve and memory CD4 T-cell populations (P = 0.008 and 0.029, respectively; Table 5), indicating that individuals who had a higher HDL cholesterol had a weaker decreasing trend of telomere length with radiation doses. Similar results were obtained for the interactions of radiation dose and CRP or HDL cholesterol using the log-transformed radiation dose (data not shown). Because we individually selected models to evaluate associations between radiation dose and telomere length, including interaction terms using the AIC, correction for multiple testing was not considered.

TABLE 5

Associations of Interaction Terms between Radiation Dose and Metabolic Indicators with Telomere Length