Sex-specific Associations of Sex Hormone Binding Globulin with CKD and Kidney Function: A Univariable and Multivariable Mendelian Randomization Study in the UK Biobank

Study Design

To assess the sex-specific associations of SHBG with CKD and kidney function, we used published genome-wide significant SNPs predicting SHBG in men and women from the latest and largest genome-wide association study (GWAS) of SHBG¹⁵ applied to CKD and kidney function in the UK Biobank. We also replicated the analysis using genetic variants for SHBG from the SHBG gene identified in a previous GWAS.¹⁷ We assessed the sex-specific association of genetically predicted SHBG with systolic BP (SBP) and diastolic BP (DBP), given that BP is a key risk factor for CKD. To assess the role of SHBG independent of testosterone, the main sex hormone in men, we used multivariable MR controlling for testosterone, using genetic instruments for testosterone from the largest published GWAS of testosterone applied to individual level measures of kidney function in the UK Biobank. Estradiol is the main sex hormone in women; however, published genetic instruments for estradiol in women are not available in the largest sex-specific GWAS in the UK Biobank,¹⁵ so the role independent of estradiol in women was not assessed.

Genetic Predictors for SHBG Used in Univariable MR

MR estimates were derived from Wald estimates, namely, genetic association with outcome (here CKD and kidney function) divided by genetic association with the exposure (here SHBG). The genetic variants for SHBG were obtained from the largest sex-specific GWAS conducted in the UK Biobank (178,782 white British men and 230,454 white British women). The GWAS associations were also replicated in three independent studies (Cohorts for Heart and Aging Research in Genomic Epidemiology Consortium, Twins UK, and the European Prospective Investigation into Cancer and Nutrition-Norfolk).¹⁵ There were 357 genome-wide significant (P<5×10⁻⁸), uncorrelated (r²<0.05) SNPs for SHBG in men and 359 uncorrelated SNPs for SHBG in women, with minor allele frequency >0.1%, and an imputation quality score >0.5.¹⁵ The genetic variants and their associations with SHBG are shown in Supplemental Tables 1 and 2. To check for potential pleiotropy, that is, the genetic variants affecting CKD or kidney function via another factor that is not on the causal pathway from SHBG to CKD, we also checked for their association with factors affecting CKD or possibly affecting CKD, but which are not a downstream factor of SHBG, such as potential confounders of SHBG on CKD. As the causes of CKD are unclear, we selected factors known to play a role in major chronic diseases, including Townsend index, smoking, alcohol drinking, and physical activity,^18⇓–20 and checked for genetic associations using the UK Biobank summary statistics at genome-wide significance (P<5×10⁻⁸). Body mass index (BMI) might be a driver²¹ or a downstream factor of SHBG,¹⁵ which means it is a potential confounder (the former) or mediator (the latter), so we also checked for its associations with BMI. We included all SNPs in the main analysis, and repeated the analysis without the SNPs related to potential confounders in a sensitivity analysis.

In the sensitivity analysis, we used another set of published genetic variants from another study, a GWAS meta-analysis of 21,791 participants (12,401 men, 9390 women) from ten studies, and validated in 7046 participants (2537 men, 4509 women) in another six studies.¹⁷ As previously,¹³ we used three SNPs in the SHBG gene. As the GWAS was not conducted in men and women separately, for ease of comparison, we obtained the sex-specific association of each SNP with SHBG in the UK Biobank, using summary statistics provided by the Neale Lab (http://www.nealelab.is/uk-biobank/), adjusted for age, age², and 20 principal components.

Genetic Predictors for Multivariable MR

Genetic predictors for SHBG in men were closely related to total testosterone,¹⁵ so we used multivariable MR controlling for testosterone. Specifically, we included genetic predictors for SHBG (357 SNPs as in univariable MR) and total testosterone. The genetic predictors for total testosterone were from the GWAS in the UK Biobank, specifically, 231 SNPs in men,¹⁵ as shown in Supplemental Table 3. After combining the genetic predictors for SHBG and testosterone, we dropped duplicate SNPs and checked for the correlation of the remaining SNPs in MR-Base and LDlink (https://ldlink.nci.nih.gov/). We dropped correlated SNPs (r²>0.05) and SNPs whose correlations with other SNPs were not available. The remaining SNPs were used for multivariable MR.

Genetic Associations with CKD and Kidney Function

Genetic associations with CKD and kidney function were obtained from individual-level data in the UK Biobank (under application 42468). The UK Biobank is a large, ongoing, prospective cohort study, with median follow up time of 11.1 years.¹⁶ The UK Biobank recruited 502,713 people (aged 40–69 years, mean age 56.5 years, 45.6% men) from 2006 to 2010 from England, Scotland, and Wales, 94% of self-reported European ancestry. As previously,⁶ to control for population stratification, we restricted our analysis to participants of white British ancestry, and for quality control we further excluded participants with inconsistent self-reported and genotyped sex; excess relatedness (more than ten putative third-degree relatives); abnormal sex chromosomes (such as XXY); or poor-quality genotyping (heterozygosity or missing rate >1.5%).

CKD events included fatal and nonfatal CKD, that is, mortality and hospitalization due to chronic renal failure and self-reported chronic renal failure (International Classification of Diseases, Tenth revision [ICD-10] code: N18; ICD-9 code: 5859; and self-report code: 1192), indications of RRT (ICD-10 code Z99.2 [dependence on renal dialysis], Z94.0 [kidney transplant status], and Z49 [encounter for care involving renal dialysis]). Information was obtained from a nurse-led interview at recruitment, ongoing follow-ups via record linkage to inpatient admission and death registration,¹⁶ and eGFR, calculated at baseline on the basis of the Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) formula using serum creatinine,²² <60 ml/min per 1.73 m². We identified 6016 CKD patients in 179,916 white British men, and 5958 CKD patients in 212,079 white British women updated to December 2019.

Secondary outcomes included albuminuria, eGFR, and BP. Albuminuria was identified on the basis of urine albumin-to-creatinine ratio >30 mg/g²³; participants with microalbumin lower than the detection limit were considered to be free from albuminuria. We identified 8845 men and 8275 women with albuminuria. eGFR was calculated on the basis of the CKD-EPI formula using serum creatinine (eGFR_cr)²² and using both creatinine and cystatin C (eGFR_crcys).²⁴

Logistic regression was used to obtain the association of each SNP with CKD and albuminuria, linear regression was used for eGFR. We controlled for age, 20 principal components, assay array (the UK BiLEVE array and UK Biobank Axiom array), smoking, BMI, SBP, and DBP. Smoking, BMI, and BP were controlled for because they are risk factors in common for various chronic diseases, such as CKD and cardiovascular disease (CVD),^25,26 controlling for common risk factors may partly address selection bias from competing risk from other diseases before recruitment.^26,27 Sex-specific genetic associations with SBP and DBP were obtained from the Neale Lab (http://www.nealelab.is/uk-biobank/), adjusted for age, age², and 20 principal components.

Statistical Analysis for MR Estimates Using Univariable MR

After aligning the SNPs on the basis of allele letter related to higher SHBG, we meta-analyzed the Wald estimates^28,29 (i.e., the genetic association with CKD or kidney function divided by the genetic association with SHBG), to obtain the overall association of genetically predicted higher SHBG with CKD and kidney function. Similarly, we assessed the associations of genetically predicted higher SHBG with BP. In the sensitivity analysis, we also aligned the SNPs on the basis of allele letter related to lower SHBG and examined the association of genetically predicted lower SHBG with CKD and kidney function. When there are no outliers, we used inverse variance weighting (IVW) with multiplicative random effects, which is applicable to both individual-level and summary data, and provides equivalent estimates to two-stage least squares.^30,31 Specifically, we obtained genetic associations with SHBG from a published GWAS in the UK Biobank,¹⁵ and obtained genetic associations with CKD and kidney function from individual-level information from the UK Biobank. The strength of these genetic instruments was assessed from the F statistic, calculated using the square of SNP-exposure associations divided by the square of its SEM.³² To examine whether the MR estimates were different in men and women, we calculated the P value for the differences in sex-specific estimates (log ORs for CKD and albuminuria, and beta coefficients for eGFR), where we used a well-established formula to calculate the z statistic (Supplemental Text), and then obtained the two-tailed P value.³³

MR rests on three assumptions, namely, the genetic variants are strongly related to the exposure, are not related to confounders of the exposure-outcome relation, and only influence the outcome via the exposure.³⁴ The IVW estimate is valid when all of the genetic variants meet these assumptions.³¹ As we used hundreds of genetic variants predicting SHBG, and possibly not all of the genetic variants meet these assumptions, in the sensitivity analysis, we used other statistical methods robust to pleiotropy, specifically, MR pleiotropy residual sum and outlier (MR-PRESSO), the contamination mixture method, and a weighted median. MR-PRESSO is able to identify outliers with potential horizontal pleiotropy when using multiple genetic variants as an instrument, and provides a corrected estimate after removing these outliers.³⁵ The contamination mixture method is a newly developed method for dealing with hundreds of genetic variants in MR,³¹ as in this study. It assumes the true causal effect is the value taken by the largest number of genetic variants, so it is robust to outliers,³¹ but provides a more conservative estimates than MR-PRESSO.³⁶ As such, if outliers were detected, we used the estimates from the contamination mixture method in the main analysis. The weighted median estimate is robust to invalid instruments, and able to provide consistent estimation even when up to 50% of the weight is from invalid SNPs.³⁷

For the power calculation, we used the approximation that the sample size required for MR is the sample size needed in the conventional observational study divided by R² (the variance in SHBG explained by the SNPs).³⁸ The required sample size for CKD events and microalbuminuria were calculated on the basis of the log OR, the ratio of patients to nonpatients, and R2,³⁹ the required sample size for eGFR was calculated on the basis of the effect size and R².³⁸

Statistical Analysis for MR Estimates Using Multivariable MR

Multivariable MR extends conventional univariable MR. Multivariable IVW has been developed to take two or more exposures into account, by taking advantage of pleiotropic SNPs predicting two or more exposures, and can be used to estimate the effect of one exposure after controlling for the other exposure(s),⁴⁰ here the role of SHBG adjusted for testosterone. We used a weighted regression-based method, which gives equivalent estimates to two-stage least squares,⁴¹ by compiling all genetic variants predicting SHBG and testosterone, removing the duplicate and correlated (r²>0.05) genetic variants, and obtaining their associations with SHBG, testosterone, and the outcome (CKD or kidney function). The analysis was conducted using the “mr_mvivw” command of the “MendelianRandomization” package. Similar assumptions of univariable MR also apply to multivariable MR, specifically, the genetic variants are related to SHBG and/or testosterone, not related to the confounders in the association of SHBG and testosterone with CKD or kidney function, and not associated with CKD or kidney function other than via SHBG and/or testosterone.⁴⁰ To assess instrument strength, we calculated the conditional F-statistic, namely, the Sanderson-Windmeijer F-statistic.⁴² To assess potential pleiotropy, we estimate modified Cochran’s Q statistic.⁴² Given multivariable IVW estimates might be biased when their assumptions are violated, we also used multivariable MR-Egger, which can detect whether the genetic predictors were acting other than via SHBG or testosterone (directional pleiotropy) indicated by a nonzero intercept and provides a corrected estimate when there is an indication of pleiotropy.⁴³ Given SHBG is the exposure of interest, we orientated the multivariable MR-Egger on SHBG.

All statistical analyses were conducted using R version 3.6.2 (R Foundation for Statistical Computing, Vienna, Austria), the “clumping” function of MR-Base and the R packages “MendelianRandomization” and “MVMR.”

Ethics Approval

This research has been conducted using the UK Biobank resource under application number 42,468. No original data were collected for the MR study. Ethics approval for each of the studies included in the investigation can be found in the original publications (including informed consent from each participant). The UK Biobank has already received ethical approval from the Research Ethics Committee and participants provided written informed consent. The analysis of other publicly available summary statistics does not require additional ethics approval.