Circulating 27-hydroxycholesterol, lipids, and steroid hormones in breast cancer risk: a nested case–control study of the Multiethnic Cohort Study

The Multiethnic Cohort (MEC) is a prospective cohort of 215,251 individuals (male and female) 45–75 years of age at enrollment between 1993 and 1996 [37]. Participants are from five racial and ethnic groups categorized as African American, Japanese American, Latino, Native Hawaiian, and non-Latino White and live in Hawaiʻi or California (primarily Los Angeles County). Participants completed a baseline questionnaire that assessed demographics, lifestyle, diet, and anthropometrics, and for females, menstrual and reproductive history, and hormone therapy use. In 2001–2006, a prospective biorepository was established that collected blood specimens from approximately 70,000 healthy participants. A short questionnaire was administered at biospecimen collection that assessed age, smoking status, weight, and hormone therapy use. In 2003–2008, a follow-up questionnaire was administered that ascertained information on use of lipid-lowering drugs.

Participants diagnosed with invasive breast cancer were identified through linkage to the Hawaiʻi and California tumor registries of the Surveillance, Epidemiology, and End Results Program of the National Cancer Institute. Case and control selection are illustrated in Additional file 1: Fig. 1. This nested case–control study included 1470 females diagnosed with incident invasive breast cancer who were postmenopausal or age > 50 years at cohort entry and provided sufficient pre-diagnostic blood (plasma) sample (cases). Controls were female participants who provided blood samples and were alive and breast cancer free at the age of the matched case’s diagnosis. Controls were matched 1:1 to cases on geographic area (Hawaiʻi or California), race and ethnicity (African American, Japanese American, Latino, Native Hawaiian, and non-Latino White), age at blood draw (± 1 year), birth year (± 1 year), time of blood draw (± 2 h), and hours fasting prior to blood draw (groups: 0 to < 6, 6 to  < 8, 8 to  < 10, 10 + hours). Cases that did not match with these criteria (n = 192, 15%) were matched by sequentially relaxing criteria to comprise age at blood draw and birth year ± 3 years (6.6%), time of blood draw ± 4 h and < / = 1 adjacent fasting group (4.8%), age at blood draw and birth year ± 5 years (3.0%), time of blood draw ± 6 years and < / = 2 fasting groups adjacent (0.4%), and finally, time of blood draw ± 8 years and < / = 4 fasting groups adjacent (0.2%). Thus, the final study population consisted of 1470 matched pairs.

Our main exposure of interest was circulating 27HC. We also assessed circulating lipids (i.e., high-density lipoprotein cholesterol [HDL-C], low-density lipoprotein cholesterol [LDL-C], total cholesterol, and triglycerides), steroid hormones (i.e., total estradiol, estrone, and testosterone), and sex hormone binding globulin (SHBG).

Biomarker assays were conducted at the University of Hawaiʻi Cancer Center Analytical Biochemistry Shared Resource under the supervision of Dr. Adrian Franke. Plasma samples were prepared according to Honda et al. with slight modifications [38] (Additional file 1). 27HC and steroid hormone levels were measured with liquid chromatography-orbitrap mass spectrometry (LC/MS) (Additional file 1) [39]. One matched pair was missing for steroid biomarker assays. Lipid assays were conducted as part of a previous study, so not all cases had lipid assay measurements available (4 of 1470 matched pairs missing). HDL-C, total cholesterol, and triglyceride levels were assayed by an automated chemical analyzer (Cobas Mira Plus, Roche Diagnostics, Switzerland). LDL-C was derived by applying the Friedewald formula, except for participants whose fasting triglyceride was over 400 mg/dl, which resulted in exclusion of an additional 11 matched pairs for LDL-C [40, 41]. Plasma SHBG was assayed by double-antibody enzyme-linked immunosorbent-assay according to manufacturer’s specifications (R&D Systems, Minneapolis, MN) [42].

Laboratory personnel were blinded to case–control status. Matched pairs were assayed in the same batch; quality control pairs were included within each batch, and duplicate pairs were included between batches. All coefficients of variation (CVs) are available in Additional file 1; within-batch CVs were all < 7%, except for estradiol and testosterone which were 16% and 14%, respectively. Analytes below the lower limit of detection (LLOD) were assigned a value of half of the LLOD. For 27HC, no samples were below LLOD. For estradiol, 49.9% of control and 44.7% of case samples were below LLOD. For estrone, 0.4% of control and 0.2% of case samples were below LLOD. For testosterone, 0.4% of control and 0.3% of case samples were below LLOD.

Covariates included socioeconomic, behavioral, and reproductive factors assessed at baseline or blood collection and consisted of factors that were hypothesized confounders of associations between 27HC and breast cancer risk or previously observed to be associated with breast cancer risk (Additional file 1: Fig. 2). Hypothesized confounders were age at blood draw, education, body size, smoking status, alcohol, and diet. Reproductive factors previously observed to be associated with breast cancer risk (i.e., parity, age at menarche, oral contraception, and hormone replacement therapy) were considered since inclusion of these covariates if associated with breast cancer risk in our sample would confer increased precision in our estimates.

Baseline measures were individual-level education (less than high school, some college, college graduate, graduate school, missing), alcohol consumption (yes, no, missing), Alternate Mediterranean Diet total score [43] (quartiles based on distribution of scores in the study population), age at menarche (≤ 12 years, 13–14 years, > 14 years, missing), parity (0,1,2–3, ≥ 4, missing), oral contraceptive use (yes, no), and hormone replacement therapy (never estrogen, past estrogen, current estrogen without progesterone, current estrogen with progesterone, missing).

Covariates collected at the time of blood collection were age at blood draw, body mass index (BMI; underweight and normal weight, < 25.0; overweight, 25.0–29.9; and obese, > 30.0 kg/m², missing), smoking status and pack-years (never smoker, former smoker/ < 20 pack-years, former smoker/ ≥ 20 pack-years, current smoker/ < 20 pack-years, current smoker/ ≥ 20 pack-years, missing), hormone replacement therapy (yes, no, missing), and lipid-lowering drug use (yes, no, missing).

For breast cancer cases, hormone receptor (HR) status was obtained from cancer registries (HR-positive, estrogen receptor- [ER] or progesterone receptor- [PR] positive; HR-negative, ER- and PR-negative, missing).

We calculated the mean, SD, and range of each analyte among control and case populations in the overall study population and across racial and ethnic groups. Distributions of raw values of biomarkers were right skewed; thus, the log-transformed values of biomarkers were used for analysis. We generated frequency distributions of race and ethnicity, HR status, lipid-lowering drug use, and covariates among cases and controls.

We used the quasi-Newton method to determine optimal parameters for multivariable conditional logistic regression to estimate odds ratios (ORs) and 95% confidence intervals (CIs) for associations between log-transformed levels of circulating analytes and breast cancer risk [44]. We examined each circulating analyte in the overall study population and according to race and ethnicity, HR status, and lipid-lowering drug use. 27HC was also analyzed according to levels of testosterone (described below). The frequencies of matched pairs that have the same category of stratifying variables within each model are noted in figures.

Potential covariates were determined with a directed acyclic graph (DAG) involving 27HC, lipid levels, and steroid hormones to breast cancer diagnosis (Additional file 1: Fig. 2). Minimal models were adjusted for age at blood draw. We tested associations between each potential covariate with breast cancer diagnosis; potential covariates with type 3 P-values < 0.1 (Additional file 1: Table 1) were included in fully adjusted models. Full models were adjusted for baseline education and parity as well as age, BMI, and smoking status at blood draw. Spline models with tests for polynomial forms did not indicate substantial nonlinearity, so we present linear model forms with analytes of interest modeled as continuous. ORs represent the increase in odds of breast cancer diagnosis for every unit increase in log-transformed analyte concentration.

To assess joint effects between 27HC and other analytes, an interaction term for 27HC and each lipid, steroid hormone, and SHBG were assessed separately in the full model. Using the Wald test, only the model with the interaction term for 27HC and testosterone levels was significant at p < 0.05 (p for interaction = 0.013). Thus, the association between 27HC and breast cancer risk was assessed across four quartiles of testosterone based on levels among controls (quartile 1, 5 to < 72.5; quartile 2, 72.5 to < 105.6; quartile 3, 105.6 to < 152.5; quartile 4, ≥ 152.46 mg/dL). Only matched pairs with testosterone levels within the same quartile of testosterone were used in this analysis.

To assess whether 27HC associations with breast cancer risk were independent of steroid hormones, full models were additionally adjusted for estrone and testosterone. We also assessed whether associations between 27HC and breast cancer diagnosis differed by BMI status (low BMI, underweight/normal; high BMI, overweight/obese).

To summarize our results on the association between 27HC and breast cancer risk with those of the mostly White, European EPIC-Heidelberg Cohort [36], we used random effects meta-analysis to calculate pooled ORs from study-specific ORs (this study) or relative risks (EPIC-Heidelberg) available for (1) the total study population of this study with postmenopausal females of the EPIC-Heidelberg study, (2) the White female population of this study with postmenopausal females of the EPIC-Heidelberg study, and (3) HR-positive breast cancer. Forest plots were generated to visualize study-specific and pooled estimates.

All p-values were two-sided; p-values < 0.05 were considered statistically significant. All analyses except for meta-analyses were conducted using SAS version 9.4 (SAS Institute, Cary, NC). Meta-analyses were conducted with Stata v17 (StataCorp, College Station, TX).