China has undergone increasing changes in the prevalence of obesity in recent decades. During the period of 1993 to 2009, the prevalence of obesity (body mass index (BMI) ≥27.5 kg/m2) increased from 4.0% to 10.7% in Chinese adults (Xi et al., Reference Xi, Liang, He, Reilly, Hu, Wang and Mi2012).
Obesity has been reported to be associated with various indicators of socioeconomic status, such as educational attainment, marital status, occupation, and income level (Gupta et al., Reference Gupta, Guptha, Gupta, Agrawal, Gaur and Deedwania2012; Silva, Reference Silva2013). Unlike income or occupation, educational levels are stable and can be assessed for all individuals, and are useful across the age spectrum (Tzotzas et al., Reference Tzotzas, Vlahavas, Papadopoulou, Kapantais, Kaklamanou and Hassapidou2010). Emerging evidence has shown that BMI differs by educational levels, with better educated individuals tending to have better health and a lower risk of obesity (Boing & Subramanian, Reference Boing and Subramanian2015; Hermann et al., Reference Hermann, Rohrmann, Linseisen, May, Kunst, Besson and Peeters2011). However, the relationship between educational level and obesity may vary in industrialized and developing countries. While a consistent inverse association between education and obesity was found especially for women in developed countries, there is less evidence from developing countries. In addition, marital status has also been reported to have mixed relationships with obesity. Although most studies tend to find that married people more often have a higher BMI than those living alone, important variations exist according to sex and ethnicity (Sobal et al., Reference Sobal, Rauschenbach and Frongillo2003; Sobal et al., Reference Sobal, Hanson and Frongillo2009).
Although a link between socioeconomic status and obesity status has been suggested, the relevant mechanism is still poorly understood. Socioeconomic status may influence BMI in a direct way since both men and women of a higher social class appear to be more concerned about their health (Wardle & Griffith, Reference Wardle and Griffith2001) and have more positive attitudes to healthy lifestyles (Wardle & Steptoe Reference Wardle and Steptoe2003). Another possible reason may be that people in a better socioeconomic environment might also have unobserved factors that are important for health. As shown by previous studies, many factors in childhood, such as poorer residential areas and social deprivation (Nau et al., Reference Nau, Schwartz, Bandeen-Roche, Liu, Pollak, Hirsch and Glass2015), have been found to be associated with obesity and are probably more prevalent in lower socioeconomic positions. Moreover, common genetic factors may affect both BMI and socioeconomic status. Previous studies have shown that BMI is highly heritable (Schousboe et al., Reference Schousboe, Willemsen, Kyvik, Mortensen, Boomsma, Cornes and Kaprio2003; Silventoinen et al., Reference Silventoinen, Jelenkovic, Sund, Yokoyama, Hur, Cozen and Kaprio2017), and there is also a genetic component underlying socioeconomic factors, such as educational attainment (Heath et al., Reference Heath, Berg, Eaves, Solaas, Corey, Sundet and Nance1985) and marital status (Johnson et al., Reference Johnson, McGue, Krueger and Bouchard2004). It is possible that some of the genetic factors predisposing to BMI may also account for genetic variation in these socioeconomic factors. Therefore, the crucial research question was whether the so-called gradients in health by socioeconomic factors are causal effects of these factors or the result of unobserved familial or genetic factors correlated with higher levels of social class. Better comprehension of the causal mechanisms underlying socioeconomic disparities in obesity would help to identify risk groups and formulate measures that might be used to reduce obesity among disadvantaged persons.
Twin design is seen as a useful method of controlling confounders in observational epidemiologic studies. Monozygotic (MZ) twins are perfectly matched for genetic and childhood family environmental factors, while dizygotic (DZ) twins share on average half of their genes and their entire family environment. As such, comparing twins within pairs can provide powerful control for genetic and shared environmental confounding factors that are typically different among unrelated individuals (McGue et al., Reference McGue, Osler and Christensen2010). Twin studies examining the relation between socioeconomic indicators with obesity or other health outcomes are sparse, and few have been conducted in Asian populations. In general, the current evidence has remained inconclusive. A study using a Finnish twin sample examining education-associated disparities in weight and weight gain indicated that common genetic factors affecting both educational attainment and body weight contributed to their associations (Silventoinen et al., Reference Silventoinen, Sarlio-Lahteenkorva, Koskenvuo, Lahelma and Kaprio2004). Another Australian twin study reported that the association between education and the probability of being overweight was significant in male twins, independent of genetic influence (Webbink et al., Reference Webbink, Martin and Visscher2010).
Since the association of socioeconomic status with obesity and the etiology behind this association are still poorly understood, we aimed to evaluate the associations of BMI, overweight, and obesity with socioeconomic status as indexed by educational level and marital status in 18- to 79-year-old adult twins from the Chinese National Twin Registry (CNTR). We also investigated whether shared genetic and environmental factors contributed to the socioeconomic disparities in BMI.
Methods
Study Sample
The data were derived from the CNTR. During 2011–2012, twin members were recruited for this study through in-person interview by means of a questionnaire in nine provinces or cities, including Jiangsu, Zhejiang, Sichuan, Heilongjiang, and Qinghai provinces, and the cities of Tianjin, Beijing, Qingdao, and Shanghai; detailed information about this twin registry is described elsewhere (Li et al., Reference Li, Gao, Yu, Lv, Cao, Zhan and Hu2013). All complete same-sex twin pairs aged between 18–79 years who replied to the questionnaires in 2011–2012 with information about education, marital status, and BMI were included in this study. Twin pairs were excluded from analyses if one of the co-twins was diagnosed with cardiovascular heart disease, stroke, type 2 diabetes, or cancer. Twins reared apart were excluded from analyses (reared apart was defined according to SATSA's definition as twins who had been reared apart for at least 1 year before the age of 11). Finally, 10,448 complete adult twin pairs were eligible for this study.
The determination of zygosity was based on age, sex, questions of appearance confused by strangers, and previously perceived zygosity from questionnaires. This method has been validated using DNA genotyping from 192 pairs of same-sex twins and found to have a mean area under curve (AUC) of 89.03% (Wang et al., Reference Wang, Gao, Yu, Cao, Lv, Wang and Li2015).
All participants provided informed consent and the Biomedical Ethics Committee at Peking University, Beijing, China approved the study protocol.
Measures
Explanatory variables
Data on education were self-reported. In the questionnaire, educational status was evaluated by asking the participants to declare their highest level of educational achievement. Educational level was grouped into three categories: (a) illiterate or primary education, (b) secondary education, and (c) tertiary education. Marital status was assessed by asking whether participants were unmarried, married, separated, divorced, or widowed.
Outcome variables
Self-reported height and weight were used to calculate BMI. Data on height and weight were required to be accurate to the nearest centimeter and kilogram, respectively. BMI was defined as weight in kilograms divided by height in meters squared. The reliability of self-reported height and weight was assessed in a subsample of twins who participated in a follow-up study in 2014 July, whose body weight and height were measured by healthcare professionals. Intraclass correlations for measured versus self-reported weight and height were 0.89 and 0.94 respectively, which suggested good reliability of self-reported BMI. BMI was categorized according to the Asian standards as underweight (<18.5 kg/m2), normal weight (18.5–23.9 kg/m2), overweight (24 to 27.9 kg/m2), and obese (≥28 kg/m2).
Assessment of covariates
Potential covariates included age (18–79 years), region (south including Jiangsu, Zhejiang, Sichuan and Qinghai province, and Shanghai City, north including Heilongjiang Province, Tianjin, Beijing, and Qingdao City), zygosity (MZ and DZ), smoking status (current, past, and never smokers), and drinking status (current, past, and never drinkers).
Statistical Methods
All analyses were stratified by sex. Descriptive analyses were used to examine sex differences by study covariates and educational level, marital status, and obesity status. P-values were corrected for the correlation between co-twins using multinomial logistic regression for categorical variables and mixed-effects models for continuous variables.
Linear Regression Models
To determine the population (between-individual) effects, we used a mixed-effect linear regression model (Carlin et al., Reference Carlin, Gurrin, Sterne, Morley and Dwyer2005) in all same-sex twins (without regard to twin-pair membership) to analyze the association of educational level and marital status on BMI. Then, multinomial logistic regression analyses were used to analyze the association of educational level and marital status with overweight and obesity. Odds ratios (ORs) for overweight and obesity were compared with normal body mass. Models were estimated using correlated-cluster variance estimates to control for the dependence of observations within twin pairs. Covariates included age (continuous), region (south, north), zygosity (MZ and DZ), cigarette smoking (current, past, and never smokers), and alcohol drinking (current, past, and never drinkers). Within-pair analyses in MZ twin pairs were conducted first using fixed-effect linear regression, with BMI as a dependent variable and educational level, marital status, cigarette smoking, and alcohol drinking as independent variables. Then, conditional logistic regression was used to assess the extent to which educational level and marital status was associated with the risk of being overweight or obesity, controlling for cigarette smoking and alcohol drinking. Only pairs discordant for overweight or obesity were included in conditional logistic regression analyses. Discordant for overweight or obesity was defined as a BMI of 24 kg/m2 or higher in one co-twin while being less than 24 kg/m2 in another co-twin. The effect parameter for educational level and marital status could be estimated by controlling for genetic and environmental factors shared by co-twins using within-pair analyses. Sensitivity analyses in which models only adjusted for age, zygosity, and region were also conducted in order to examine the mediating effect of cigarette smoking and alcohol drinking for educational level, marital status, and obesity.
Marital status is different in younger than older adults and educational level is probably much higher in younger than in older age groups, so we further conducted a stratified analyses to assess the association of educational level and marital status with continuous BMI according to age group (age ≥45 and age <45) in all twins and within MZ twin pairs. The age group-educational level interaction and age group-marital status interaction effect were tested to demonstrate whether the association between educational level/marital status and BMI differs as a function of age group. Analyses were performed using Stata11.2 (Stata Corp, College Station, TX). P-values were two-sided and statistical significance was assumed at p < .05.
Structural Equation Model
A structural equation model was used to examine the extent to which genetic or environmental variance were correlated across educational level, marital status, and BMI in this sample stratified by sex. Marital status was a binary variable, with married participants in one level and unmarried participants in another level (separated, divorced, or widowed participants were not included in analysis). All model-fitting analyses and maximum-likelihood parameter estimates were performed in OpenMx (Version 1.4).
First, we fitted a univariate structural equation model for educational level, marital status, and BMI to separate the observed phenotypic variances into genetic and environmental components: additive (A) genetic components and common (C) or unique (E) environmental components. Because educational level and marital status were categorical variables, heritability was estimated on the basis of a liability model (Verweij et al., Reference Verweij, Mosing, Zietsch and Medland2012), which presumes an underlying, normally distributed susceptibility for the expression of the phenotype of interest with zero mean and unit variance. Categories were defined by thresholds on this underlying curve, such that the area under the curve reflects the proportion of the population in each category (McCaffery et al., Reference McCaffery, Papandonatos, Bond, Lyons and Wing2009). A nested model for which A or C was equated to zero was also fitted and Akaike information criterion (AIC) was used for comparison of goodness of fit of the models. Variance components of BMI were estimated with inclusion of age, region, smoking status, drinking status, educational level, and marital status as covariates.
Next, based on the best fit model we fitted the bivariate Cholesky decomposition models to calculate genetic (r G) and environmental correlations (r E) between educational level, marital status, and BMI and 95% confidence intervals. Similarly, polychoric correlations between pairs of categorical variables were estimated on the basis of a liability model. All variance components of BMI were estimated with inclusion of age, region, smoking status, and drinking status as covariates.
Results
Descriptive Characteristics of the Study Population
A total of 10,448 complete adult twin pairs were included in this study, of whom 70.1% were MZ twin pairs. The sample characteristics are summarized in Table 1. The mean age of this sample was 37.5 years and more than half were males (62.1%). The mean BMI for the total population studied was 22.8 kg/m2, and it was higher in men than in women. The majority of participants were married (74.4%), being more prevalent in males than in females (75.7% vs. 72.3%, p < .001). With respect to educational level, the percentage of participants who attained tertiary education was significantly higher in females than in males (35.7% vs. 19.4%, p < .001).
BMI = body mass index, DZ = dizygotic, MZ = monozygotic, SD = standard deviation.
a p-values were corrected for the correlation between co-twins using mixed-effects models for continuous variables and multinomial logistic regression for categorical variables.
Associations Between Educational Level, Marital Status and Obesity
Results from the sex-specific models treating twins as individuals are summarized in Table 2. After controlling for multiple socio-demographic and lifestyle factors, a significant correlation was observed between BMI, overweight, and obesity status, and educational level across both sexes, with the exception of males with secondary education, in which the likelihood for being obese was similar to those with primary education. However, some noticeable sex differences emerged from our study. The above-mentioned correlation was positive in males while negative in females. More specifically, males with secondary and tertiary education had increased BMI by 0.32 kg/m2 and 0.50 kg/m2 respectively compared to those with primary education (p < .001). The corresponding values of females with secondary and tertiary education compared to primary-educated females were negative at -0.58 kg/m2 and -1.11 kg/m2 respectively (p < .001). The odds ratios for secondary-educated men being overweight or obese was 1.30 (p = .001) and 1.33 (p = .067), while that of secondary educated women was 0.55 and 0.48 (both p < .001). Moreover, the odds ratios for tertiary-educated men being overweight was 1.57 (p < .001) and for obesity was 1.74 (p = .003), while the respective odds ratios for tertiary-educated women were 0.40 (p < .001) for being overweight and 0.36 (p < .001) for obesity. As far as the relationship between marital status and obesity is concerned, married twins had significantly higher BMI than unmarried twins. Besides, married twins had increased odds for being overweight by 98% and 87% among males and females, respectively, compared to unmarried twins (p < .001). The respective values for obesity were even higher, reaching 135% (p < .001) and 116% (p = .002). In particular, men who lived apart also had higher BMI and higher odds for being overweight compared to unmarried men.
BMI = body mass index, CI = confidence interval, OR = odds ratio.
a All regression models were adjusted for age, region, zygosity, smoking status, and drinking status.
Further analyses treating twins as pairs revealed different results, which can be seen in Table 3. There was no significant association between educational level and BMI, overweight or obesity status across both sexes, with the exception of tertiary-educated MZ male twin pairs in which BMI was higher than primary educated ones. With respect to marital status, married twins had a significantly higher BMI in both sexes of MZ twin pairs compared to unmarried twins. The odds ratio for married twins being overweight or obese was only significant in female MZ twin pairs. The models of our primary analyses in which smoking status and drinking status were removed were reanalyzed as sensitivity analyses and the results are represented as Supplementary Table S1 and Table S2. However, there were no significant changes between the primary results and sensitivity results.
BMI = body mass index, CI = confidence interval, OR = odds ratio.
a All regression models were adjusted for smoking status and drinking status.
Further, we tested the statistically significant difference in effect of educational level and marital status on BMI between different age groups (from an interaction term between educational level/marital status and age group), and the results yielded a significant interaction between educational level and age group on BMI in both sexes. Educational level exerted a bigger effect on BMI in older men than in younger men while in women, educational level had less effect on BMI as age increased. We also had the ability to stratify analyses according to age group within MZ twin pairs. For marital status, married twins had a significantly higher BMI compared to unmarried twins, except for older females. Regarding educational level, we found that higher educational level was associated with a higher BMI in both older females and males. Testing for interaction between educational level/marital status and age group revealed similar patterns in all twins (Table 4).
MZ = monozygotic, CI = confidence interval.
a All regression models were adjusted for age, region, zygosity, smoking status and drinking status.
b All regression models were adjusted for smoking status and drinking status.
Genetic and Environmental Contributions to the Socioeconomic Disparities in Body Mass Index
Before examining genetic and environmental factors common across educational level, marital status and BMI, we first estimated the genetic and environmental contributions to each phenotype. The additive genetic/common environment/unique environment (ACE) model offered the best fit for BMI, educational level (in both male and female twins), and marital status (only in male twins); dropping genetic (A) or common environment (C) decreased the fit significantly, with the p-value for differences in model fits all larger than 0.05. On the contrary, genetic effects did not contribute significantly to marital status in female twins, whereas common and unique environmental variance did. The heritability analyses for educational level, marital status and BMI are shown in Table S3.
Table 5 shows the genetic and environmental contributions to phenotypic correlations in this twin sample. The genetic and common environmental correlations between educational level and BMI were significantly negative in females, while positive in males. However, unique environmental correlations were only significant in males. Marital status correlated with BMI with a strong positive common environmental and a somewhat weaker but still highly significant unique environmental correlation in both sexes.
r A = genetic correlation between two phenotypes; r C = common environmental correlation between two phenotypes; r E = unique environmental correlation between two phenotypes.
BMI = body mass index; CI = confidence interval.
a Variance components were estimated with BMI corrected for age, region, smoking status and drinking status.
Discussion
At the individual level, we found clear educational- and marital status-based differences in BMI, overweight, and obesity status among Chinese twins that replicated the previous studies (Dinsa et al., Reference Dinsa, Goryakin, Fumagalli and Suhrcke2012; Kilicarslan et al., Reference Kilicarslan, Isildak, Guven, Oz, Tannover, Duman and Sozen2006). However, our twin fixed-effect analyses yielded generally a weak association between educational level and BMI, overweight or obesity status, although in male MZ twins, the association between tertiary education and BMI tended to suggest a significant effect. Regarding marital status, we found a positive association among MZ twins in both sexes. Genetic modeling analyses showed that genetic and common environmental correlations confounded the relationship between education and BMI in females, while the strong relationship between BMI and marital status in both sexes was due to both common and unique environmental correlations.
According to our results, at the individual level, a significant positive association between educational level and BMI, overweight and obesity status was found in male twins, while in female twins, the association was in the opposite direction, with a lower BMI and a lower risk of overweight and obesity in higher educated females. The sex differences of education on BMI have been noted before. Accumulated evidence suggests an inverse association between education and obesity mostly among women, while in men this association is less consistent (Kowalkowska et al., Reference Kowalkowska, Wadolowska, Weronika, Slowinska and Niedzwiedzka2014; Noh et al., Reference Noh, Jo, Huh, Cheon and Kwon2014; Vernay et al., Reference Vernay, Malon, Oleko, Salanave, Roudier, Szego and Castetbon2009). The difference in findings between men and women might be related to the differential costs of higher body size; for example, the cost of overweight or obesity in terms of reduced labor market opportunities (Sarlio-Lahteenkorva et al., Reference Sarlio-Lahteenkorva, Silventoinen and Lahelma2004) or increased discrimination seems to be higher for women than for men. We also found that educational level had an interaction with age on BMI. For men, educational level exerted a bigger effect on BMI as age increased, while for women, educational level had less effect on BMI as age increased. This may be explained by sex difference roles and consciousness of increased age. For higher educated men, they may be occupied with work and engaged in more social activities (e.g., dinner parties, even in an older age group) that means they have less exercise and a more unhealthy diet. But for women, as their age increases, the importance of appearance decreases (Liang et al., Reference Liang, Shediac-Rizkallah, Celentano and Rohde1999) and they may pay less attention to their body shape, so the negative effect of educational level on BMI is weakened.
When treating twins as pairs, the observed association between education and BMI disappeared in fixed-effect analyses among female MZ twins, which was in agreement with the previous studies (Fujiwara & Kawachi, Reference Fujiwara and Kawachi2009; Silventoinen et al., Reference Silventoinen, Sarlio-Lahteenkorva, Koskenvuo, Lahelma and Kaprio2004). With regard to males, tertiary education remained a significant effect on BMI and subsequent genetic analyses revealed that besides genetic and common environmental factors, unique environmental factors not shared by twin pairs only contributed to the relationship between education and BMI in male twins but not in female twins. This suggested that the educational effect on BMI in female twins we observed in the individual level analyses was due to selection processes related to confounding from genetic factors or common rearing environment. Another factor that seems related to this concern about physical appearance among MZ female twin pairs was peer effects within pairs of twins. Several studies indicate that peer effects might differ between men and women. For instance, Dinand et al. (Webbink et al. Reference Webbink, Martin and Visscher2010) found a statistically significant effect of sibling's schooling on BMI for women but not for men, which suggested that having a higher educated sister reduces the probability of being overweight.
Concerning marital status, married twins had a higher BMI and a higher risk for being overweight or obese in both sexes, compared to unmarried twins. This finding was consistent with other studies conducted in Colombian (Davila et al., Reference Davila, Quintero, Orrego, Ford, Walke, Arenas and Pratt2013) and Greek (Tzotzas et al., Reference Tzotzas, Vlahavas, Papadopoulou, Kapantais, Kaklamanou and Hassapidou2010) adults, and Brazilian adolescents (Silva, Reference Silva2013). Further, in our MZ twins fixed-effect analyses, after cancelling genetic and early family environmental factors, we continued to observe this association, which indicates that the association between marital status and BMI is independent of these factors. However, our findings stand in contrast to a study conducted in middle-aged Danish twins, which reported that twins discordant for marital status did not differ for levels of BMI (Osler et al., Reference Osler, McGue, Lund and Christensen2008). The difference in findings between the Danish study and our study could be due to differences in the study sample, statistical analyses models and adjusted confounding factors. Nevertheless, it is premature to conclude that marital status is causally associated with BMI. The associations reported in our twin fixed-effect analyses might also be due to residual confounding by unmeasured covariates, rather than to the causal effect of marriage on BMI.
The common environment had a strong effect on marital status, while genetic and unique environment had a much smaller effect. We found no genetic effect on marital status among female twins, which means this behavior is mainly decided by environment factors. Results from our bivariate genetic analyses suggested that both common and unique environmental factors explained the association between marital status and BMI. The unique environmental contribution suggested that environmental factors specific to twins, and not common across twins, accounted for the association between marital status and BMI. This result is entirely consistent with our fixed-effect analyses results, which demonstrate a greater BMI in married MZ twins relative to their unmarried co-twins. A direct environmental effect of marriage on BMI that is independent of genetic effects could occur, for example, through reduction in weight perception or increase in appetite and sustaining of a positive energy balance. It is also possible that the unique environmental correlation reflects the effect of a third unmeasured variable on both marriage and BMI, such as energy intake. Taken together, these findings suggest that cumulative experiences across the life-course, including those after marriage, and not just early shared life experiences, shape adult health.
This study is the first that reports on educational level and marital status associated with obesity in the adult Chinese population using a large twin sample from CNTR. Twin studies provide insights into whether the association between educational level, marital status, and obesity in previous studies is because of shared environment, common genetic factors, or other pathways associated with individual twins. Furthermore, our findings also expand the knowledge of the genetic and environmental contribution to these associations.
Meanwhile, it is important to note the limitations of the present study. First, the data on BMI was based on self-reported height and weight, which may be inaccurate. In this study, however, the correlations between self-reported and measured weight and height values were high, at about 0.90. In addition, we had no detailed information on energy intake and physical activity, so the possibility of residual confounding by these unmeasured covariates cannot be excluded. Finally, we were not able to analyze the direction of causation due to cross-sectional design.
Conclusion
In conclusion, education was associated with increased BMI in males, while in females, the association was in the opposite direction in individual-level analyses. However, in fixed-effect analyses cancelling the effect of genetic and early family environment, the associations were less robust between males and females. Married twins tended to have higher BMI than unmarried twins, independent of genetic and shared environmental factors in both sexes. Environmental factors specific to twins might account for this association. The findings of the present study provide evidence that obesity could be faced by tackling specific subgroups such as high educated males and married people. High educational level is an important issue and it should be promoted, along with nutritional education, during early life, mainly in men.
Ethical Approval
All procedures performed in studies involving human participants were in accordance with the ethical standards of the Biomedical Ethics Committee at Peking University, Beijing, China, and with the 1964 Helsinki Declaration and its later amendments or comparable ethical standards.
Informed Consent
Informed consent was obtained from all individual participants included in the study.
Acknowledgments
The authors gratefully acknowledge the cooperation of the CDC twin project staff in nine provinces.
Funding
This study was supported by the Special Fund for Health Scientific Research in Public Welfare (201502006, 201002007) and a Key Project of Chinese Ministry of Education (310006).
Disclosure of Interests
None.
Supplementary material
To view supplementary material for this article, please visit https://doi.org/10.1017/thg.2018.8