Genetically Supported Causality Between Micronutrients and Sleep Behaviors: A Two‐Sample Mendelian Randomization Study

A schematic overview of the research design is depicted in Figure 1. We conducted an MR investigation utilizing data from 18 publicly accessible GWAS to acquire summary statistics. In the two‐sample MR analysis, data concerning sleep behaviors were sourced from three independent GWAS consortia. These data were employed for initial analyses and replication studies, and ultimately integrated into a meta‐analysis to consolidate findings. For the MVMR analysis, we investigated the causal relationships between various micronutrients and sleep behaviors. To increase the statistical robustness of our findings, we combined estimates from various data sources. All studies involved in the GWAS had previously been approved by the appropriate review boards, and no further ethical approval or participant consent was necessary for this analysis.

Participants recorded their own sleep duration by noting the total hours slept every 24 h, including naps, measured in hourly increments. We carried out distinct GWAS for individuals of European descent, categorizing them based on their sleep duration. This included a group with short sleep duration (less than 7 h per night, n = 106,192 cases) and another with long sleep duration (more than 9 h per night, n = 34,184 cases). These were compared to a control group that reported sleeping between 7 and 9 h per night (n = 305,742) (Dashti et al. 2019). We excluded responses that reported extremely low (less than 3 h) or extremely high (more than 18 h) sleep durations. Responses marked as “Do not know” or “Prefer not to answer” were considered missing data. We can obtain the GWAS summary statistics from the Sleep Disorder Knowledge Portal at https://sleep.hugeamp.org/downloads.html↗.

To assess chronotype, subjects responded to the question, “Do you consider yourself to be?” with choices spanning from “Definitely a ‘morning’ person” to “Definitely an ‘evening’ person.” Responses were scored, with “Definitely a ‘morning’ person” and “More a ‘morning’ than ‘evening’ person” classified as cases, assigned two and one points, respectively. Conversely, those identifying as “Definitely an ‘evening’ person” or “More an ‘evening’ than ‘morning’ person” were designated as controls, with scoring of −2 and −1 points, respectively. The study by Jones et al. (2019) encompassed 252,287 cases and 150,908 controls of European ancestry. The GWAS summary statistics for this analysis are also available on the Sleep Disorder Knowledge Portal.

In the assessment of insomnia, participants answered the question: “Do you have trouble falling asleep at night or do you wake up in the middle of the night?” The response options provided were “never/rarely,” “sometimes,” “usually,” or “prefer not to answer.” Participants who chose “usually” were identified as cases of insomnia, while those who answered “never/rarely” were designated as controls. The GWAS, carried out by Watanabe et al. (2022), involved 593,724 cases and 1,771,286 controls of European descent and identified 554 loci associated with insomnia. The GWAS summary statistics are available from https://ctg.cncr.nl/software/summary_statistics/↗.

In our research, we conducted a comprehensive search through PubMed and the IEU OpenGWAS project (https://gwas.mrcieu.ac.uk/↗) to identify the most recent large‐scale GWAS studies on micronutrients, with the final search conducted in April 2024. To avoid overlap between the exposures and outcomes in our study, we excluded certain micronutrients that were obtained from these specific databases during our data collection. We observed a notable absence of genomic studies concerning chloride; fluoride; phosphorus; sulfur; vitamins B1, B2, B3, B5, and B7; and iodine. Furthermore, studies on vitamin K, cobalt, chromium, sodium, and molybdenum were not included due to their inconclusive genomic results (Dashti et al. 2014; Ng et al. 2015). This selection process led us to preliminarily identify 15 micronutrients for further investigation: copper (Evans et al. 2013), calcium (O'Seaghdha et al. 2013), carotene (Ferrucci et al. 2009), folate (Grarup et al. 2013), iron (Bell et al. 2021), magnesium (Meyer et al. 2010), potassium (Meyer et al. 2010), selenium (Evans et al. 2013), vitamin A (Mondul et al. 2011), vitamin B12 (Grarup et al. 2013), vitamin B6 (Hazra et al. 2009), vitamin C (Zheng et al. 2020), vitamin D (Revez et al. 2020), vitamin E (Major et al. 2011), and zinc (Evans et al. 2013).

In our research, we utilized the two‐sample MR approach, employing the Two Sample MR (version 0.5.11) package (Hemani, Tilling, and Smith 2017; Hemani et al. 2018). Our principal technique for MR analysis was the inverse variance weighting (IVW) method. This meta‐analytic approach combines Wald estimates from each SNP to compute overall effect estimates of the exposure on the outcome (Burgess, Butterworth, and Thompson 2013). This method operates under the assumption that all included variants are valid instruments, or that any horizontal pleiotropy is balanced, thus not violating the fundamental assumptions of MR.

We supplemented our primary analysis with several auxiliary methods to further assess causality. The MR‐Egger method (Bowden, Davey Smith, and Burgess 2015) uses weighted linear regression to address small study biases by analyzing the slope of outcome coefficients against exposure coefficients. It offers reliable causal estimates even when all genetic variants may be invalid instruments, albeit with less efficiency compared to IVW and median‐based methods. The weighted median approach integrates data from multiple genetic variants to produce a single causal estimate and tolerates up to 50% of the data originating from potentially invalid instruments. SNPs were classified with mode‐based methods (Hartwig, Davey Smith, and Bowden 2017) into clusters by similarity in causal effects, estimating the causal effect based on the most populous clusters. This approach minimizes bias and reduces type‐I errors, particularly when the SNPs in the largest cluster are valid instruments.

To improve the trustworthiness of our findings, we undertook an extensive series of sensitivity checks. First, we evaluated the heterogeneity of SNP effects, which could bias the IVW estimates, by computing Cochran's Q statistics (Bowden et al. 2019). A p‐value above 0.05 for this test suggested minimal heterogeneity impact. Where heterogeneity was detected, we employed the random effects model of IVW to assess the causal effects more appropriately. Second, to address the risk of horizontal pleiotropy, which could violate the exclusion restriction assumption of Mendel's Third Law instrumental variables (IVs) should not influence the outcome except through the exposure (Didelez and Sheehan 2007; Angrist, Imbens, and Rubin 1996), we analyzed the MR‐Egger regression intercept. An intercept not significantly differing from zero (p > 0.05) indicated an absence of horizontal pleiotropy (Burgess and Thompson 2017). Third, the MR Steiger directional test was utilized to verify the assumption that the exposure influences the outcome, rather than the reverse (Hemani, Tilling, and Smith 2017). This test compares the R² values for the outcome and exposure explained by the IVs. A significantly lower R² for the outcome than the exposure (MR Steiger test p < 0.05) suggested the absence of reverse causality between the two. Lastly, we implemented a leave‐one‐out analysis to ascertain the robustness of the causal effect. This approach involves sequentially removing each IV and recalculating the IVW using the remaining IVs, thus assessing the influence of individual variants on the overall causal estimate. These methods collectively ensure our analysis is both thorough and reliable in detecting true causal relationships.

In this study, we acknowledged the potential for confounding among various vitamins and minerals when using two‐sample or standard MR due to the pleiotropic effects that one micronutrient may exert on others. To address this issue, we employed MVMR analysis. This approach integrates a pleiotropy correction by including all pertinent sleep behaviors in one model, which helps reduce bias (Sanderson 2021). For the MVMR analysis, we utilized all the variants from the two‐sample MR of micronutrients as IVs. This analysis was conducted using the “Mendelian Randomization” R package (version 0.10.0). Within this framework, both the IVW and MR‐Egger methods were employed to determine the causal relationships between one sleep behavior and the other two.

To further assess heterogeneity in the outcomes of SNP, we calculated an adjusted Cochran's Q statistic using summary data (Sanderson et al. 2019), which helps identify variations in SNP effects that could impact the validity of our MR estimates. Additionally, the presence of pleiotropic effects was assessed by evaluating the MR‐Egger intercept term to determine whether the IVs had any effects on the outcome that were not mediated through the exposure. As our primary method, IVW was used under the assumption of no pleiotropic effects. However, when directional pleiotropy was suspected, we employed the multivariable MR‐Egger method, which is specifically designed to accommodate such pleiotropy (Rees, Wood, and Burgess 2017). This comprehensive approach allows us to more accurately discern the direct and indirect effects of sleep behaviors on lifespan within a multivariable framework.

To explore the connections between micronutrients and various sleep behaviors, we utilized a two‐sample MR approach. We identified significant associations with chronotype for folate and vitamins B6 and D (p < 0.05) (Table S1; Figure 2). However, no significant correlations were observed between chronotype and the levels of calcium; carotene; copper; iron; magnesium; phosphorus; potassium; selenium; vitamins A, B12, C, and E; and zinc in the bloodstream (Table S1; Figure 2). Additionally, the MR analysis did not establish causal relationships between circulating micronutrients and the three sleep behaviors of short sleep duration, long sleep duration, and insomnia (Tables S2–S4).

Specifically, for each standard deviation (SD) increase in folate levels, the odds ratio (OR) is 1.09, with a 95% confidence interval (CI) ranging from 1.01 to 1.17 (p = 0.02). The MR‐Egger and weighted median approaches yielded congruent results, reinforcing the relationship. Specifically, the MR‐Egger method reported an OR of 1.22 with a 95% CI ranging from 1.03 to 1.44 and a p‐value of 0.04. The weighted median analysis showed an OR of 1.10 with a 95% CI of 1.10 to 1.19 and a p‐value of 0.03, as detailed in Table S1. Additionally, vitamins B6 and D were negatively correlated with chronotype. For each standard deviation increase, the ORs were 0.91 with a 95% CI of 0.86 to 0.96 (p = 0.001) and 0.94 with a 95% CI of 0.88 to 1.00 (p = 0.03), respectively (Figures 2 and 3).

MR results are presented in scatter plots with different color‐coded trend lines to showcase estimates calculated from the various methods, as seen in Figure 4. Additionally, forest plots depict the influence of each IV of folate, vitamin B6, and vitamin D levels on chronotype (Figure 5). To mitigate potential biases related to pleiotropy and the impact of individual IVs, additional analyses were performed. The Cochran's Q statistic revealed no significant heterogeneity among the IVs, with results for folate showing Q = 19.54, differences (df) = 21, p = 0.08; for vitamin B6, Q = 18.65, df = 15, p = 0.23; and for vitamin D, Q = 8.54, df = 11, p = 0.66. Furthermore, no significant evidence of horizontal pleiotropy was found by the MR‐Egger regression, as demonstrated in Table S2. The robustness of these findings is further supported by the leave‐one‐out analysis, as shown in Figure 6, confirming that no single IV disproportionately influenced the overall causal assessment.

Given the interrelationships among folate, vitamin B6, and vitamin D, the two‐sample MR analysis could not exclude potential confounding because of the other micronutrients. Thus, we conducted an MVMR analysis, estimating the direct effect of each exposure conditional on the others included in the model (Sanderson 2021). In this more comprehensive analysis, folate showed a positive causal effect on chronotype (OR = 1.286, 95% CI = 1.124–1.472, p < 0.001), while vitamin B6 demonstrated a negative causal effect (OR = 0.750, 95% CI = 0.648–0.868, p < 0.001). The impact of vitamin D on chronotype remains unclear (Table S5; Figure 7).

The peer review history for this article is available at https://publons.com/publon/10.1002/brb3.70237↗.