Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-27T08:51:29.927Z Has data issue: false hasContentIssue false

Early life adversity predicts an accelerated cellular aging phenotype through early timing of puberty

Published online by Cambridge University Press:  16 June 2023

Elissa J. Hamlat*
Affiliation:
Department of Psychiatry and Behavioral Sciences, University of California, San Francisco, CA, USA
Torsten B. Neilands
Affiliation:
Division of Prevention Science | Department of Medicine, University of California, San Francisco, CA, USA
Barbara Laraia
Affiliation:
School of Public Health, University of California, Berkeley, CA, USA
Joshua Zhang
Affiliation:
Department of Human Genetics, University of California, Los Angeles, CA, USA
Ake T. Lu
Affiliation:
Department of Human Genetics, University of California, Los Angeles, CA, USA
Jue Lin
Affiliation:
Department of Biochemistry and Biophysics, University of California, San Francisco, CA, USA
Steve Horvath
Affiliation:
Department of Human Genetics, University of California, Los Angeles, CA, USA Department of Biostatistics, University of California, Los Angeles, CA, USA Altos Labs, San Diego, CA, USA
Elissa S. Epel
Affiliation:
Department of Psychiatry and Behavioral Sciences, University of California, San Francisco, CA, USA
*
Corresponding author: Elissa J. Hamlat; Email: Elissa.Hamlat@ucsf.edu
Rights & Permissions [Opens in a new window]

Abstract

Background

The current study examined if early adversity was associated with accelerated biological aging, and if effects were mediated by the timing of puberty.

Methods

In early mid-life, 187 Black and 198 White (Mage = 39.4, s.d.age = 1.2) women reported on early abuse and age at first menstruation (menarche). Women provided saliva and blood to assess epigenetic aging, telomere length, and C-reactive protein. Using structural equation modeling, we created a latent variable of biological aging using epigenetic aging, telomere length, and C-reactive protein as indicators, and a latent variable of early abuse using indicators of abuse/threat events before age 13, physical abuse, and sexual abuse. We estimated the indirect effects of early abuse and of race on accelerated aging through age at menarche. Race was used as a proxy for adversity in the form of systemic racism.

Results

There was an indirect effect of early adversity on accelerated aging through age at menarche (b = 0.19, 95% CI 0.03–0.44), in that women who experienced more adversity were younger at menarche, which was associated with greater accelerated aging. There was also an indirect effect of race on accelerated aging through age at menarche (b = 0.25, 95% CI 0.04–0.52), in that Black women were younger at menarche, which led to greater accelerated aging.

Conclusions

Early abuse and being Black in the USA may both induce a phenotype of accelerated aging. Early adversity may begin to accelerate aging during childhood, in the form of early pubertal timing.

Type
Original Article
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Childhood adversity has lifelong consequences in the form of poor health in adulthood and premature mortality in that experiencing adverse events before age 18 reliably increases the risk for nine out of 10 leading causes of death in the USA (Hughes et al., Reference Hughes, Bellis, Hardcastle, Sethi, Butchart, Mikton and Dunne2017; Merrick et al., Reference Merrick, Ford, Ports, Guinn, Chen, Klevens and Ottley2019). Health is consistently worse for Black Americans compared to White Americans, including higher rates of the leading causes of death in the USA (Adler & Rehkopf, Reference Adler and Rehkopf2008; Williams, Reference Williams2012). Higher levels of early life adversity may help to explain health disparities between Black and White Americans (Slopen et al., Reference Slopen, Shonkoff, Albert, Yoshikawa, Jacobs, Stoltz and Williams2016). To reduce health disparities, we need to understand the mechanisms that underlie the relationship between early adversity and health outcomes.

Early adversity has been associated with accelerated biological aging (i.e. older than chronological age) as indexed by epigenetic clocks, which are reliable predictors of disease and mortality (Field et al., Reference Field, Robertson, Wang, Havas, Ideker and Adams2018; Horvath & Raj, Reference Horvath and Raj2018). Previous studies have found childhood trauma predicts accelerated epigenetic aging for children and adults (Hamlat et al., Reference Hamlat, Prather, Horvath, Belsky and Epel2021; Sumner, Colich, Uddin, Armstrong, & McLaughlin, Reference Sumner, Colich, Uddin, Armstrong and McLaughlin2019; Wolf et al., Reference Wolf, Maniates, Nugent, Maihofer, Armstrong, Ratanatharathorn and Logue2018; Zannas et al., Reference Zannas, Arloth, Carrillo-Roa, Iurato, Röh, Ressler and Mehta2015). Moreover, early adversity has been associated with other indices of cell aging that predict disease and mortality, including shorter telomere length (TL; Li, He, Wang, Tang, & Chen, Reference Li, He, Wang, Tang and Chen2017) and elevated C-reactive protein (CRP; Baumeister, Akhtar, Ciufolini, Pariante, & Mondelli, Reference Baumeister, Akhtar, Ciufolini, Pariante and Mondelli2016). Childhood adversity predicts shorter TL (Ridout et al., Reference Ridout, Levandowski, Ridout, Gantz, Goonan, Palermo and Tyrka2018); in turn, shorter TL predicts the earlier onset of diseases of aging, such as cardiovascular disease (CVD; D'Mello et al., Reference D'Mello, Ross, Briel, Anand, Gerstein and Paré2015; Haycock et al., Reference Haycock, Heydon, Kaptoge, Butterworth, Thompson and Willeit2014; Willeit et al., Reference Willeit, Raschenberger, Heydon, Tsimikas, Haun, Mayr and Kiechl2014). CRP, an index of systemic inflammation which increases with age and thought to be a mechanism of aging-related disease (Kaptoge et al., Reference Kaptoge, Di Angelantonio, Lowe, Pepys, Thompson, Collins and Danesh2010), has been associated with childhood trauma in meta-analysis (Baumeister et al., Reference Baumeister, Akhtar, Ciufolini, Pariante and Mondelli2016).

Early pubertal timing as accelerated aging

In a risky environment, pubertal maturation may accelerate to increase opportunities to reproduce before the individual dies or becomes compromised, potentially at the expense of investments in adult health and longevity (Belsky, Steinberg, & Draper, Reference Belsky, Steinberg and Draper1991; Ellis, Reference Ellis2004). Early adversity may recalibrate the hypothalamo-pituitary-adrenocortical (HPA) axis, which influences sexual development directly and affects the hypothalamic-pituitary-gonadal axis. Adversity may attenuate HPA-axis function, which results in the earlier onset of adrenal and gonadal hormones and has predicted earlier pubertal development in girls (Saxbe, Negriff, Susman, & Trickett, Reference Saxbe, Negriff, Susman and Trickett2015).

Early pubertal timing has been associated with higher morbidity and earlier mortality (Charalampopoulos, McLoughlin, Elks, & Ong, Reference Charalampopoulos, McLoughlin, Elks and Ong2014) and with accelerated biological aging as indexed by epigenetic clocks (Binder et al., Reference Binder, Corvalan, Mericq, Pereira, Santos, Horvath and Michels2018; Hamlat et al., Reference Hamlat, Prather, Horvath, Belsky and Epel2021; Simpkin et al., Reference Simpkin, Howe, Tilling, Gaunt, Lyttleton, McArdle and Relton2017; Sumner et al., Reference Sumner, Colich, Uddin, Armstrong and McLaughlin2019) and TL (Koss et al., Reference Koss, Schneper, Brooks-Gunn, McLanahan, Mitchell and Notterman2020). In meta-analysis, early adversity was associated with early pubertal timing as well as accelerated cellular aging, as indexed by both epigenetic age and TL (Colich, Rosen, Williams, & McLaughlin, Reference Colich, Rosen, Williams and McLaughlin2020). The possibility that there is an indirect effect of early adversity on health through pubertal timing has rarely been empirically examined. In one study of 73 girls, maternal depression in infancy predicted higher basal cortisol, which predicted accelerated pubertal (adrenarcheal) development, which resulted in health problems at age 18 (Belsky, Ruttle, Boyce, Armstrong, & Essex, Reference Belsky, Ruttle, Boyce, Armstrong and Essex2015). The recalibration of the HPA-axis may also speed up the pace of development (Colich & McLaughlin, Reference Colich and Mclaughlin2022), which would result in earlier pubertal timing and faster aging of physiological systems, more generally, which would be captured in assessments of biological aging.

Multiple biomarkers as an index of biological aging

While a growing number of studies have examined how specific biomarkers may predict health outcomes, few studies have combined biomarkers. Epigenetic aging, TL, and CRP are usually studied independently from one another; however, integrating multiple markers of biological aging may allow for a more complete profile of multisystem-level aging (Liu et al., Reference Liu, Chen, Assimes, Ferrucci, Horvath and Levine2019). Different indices of biological aging are likely to have reciprocal effects on one another regulated by feedback loops (Gassen, Chrousos, Binder, & Zannas, Reference Gassen, Chrousos, Binder and Zannas2017). Given their associations with ELA and interrelationships with one another, epigenetic aging, TL, and elevated CRP may be aggregated and operationalized as a phenotype of biological aging. Each biomarker may represent distinct pathways of aging (Belsky et al., Reference Belsky, Moffitt, Cohen, Corcoran, Levine, Prinz and Caspi2018); their shared variance allows them to be used as indicators of a latent variable.

The current study examines if there is an indirect effect of adversity on such an aggregate composite of accelerated biological aging through pubertal timing. Using structural equation modeling, we created a latent variable of biological aging using epigenetic aging, TL, and CRP as indicators. Structural equation modeling (SEM)s partition variance unique to each indicator into separate residual variance estimates, purifying the structural path coefficients of measurement error, which is partitioned into the indicator-specific residual variances (Kline, Reference Kline2011).

Race differences in aging biomarkers

Race differences in health outcomes are largely due to social determinants and to systemic racism, which is a fundamental cause of racial inequities in health (Churchwell et al., Reference Churchwell, Elkind, Benjamin, Carson, Chang and Lawrence2020; Paradies et al., Reference Paradies, Ben, Denson, Elias, Priest, Pieterse and Gee2015; Phelan & Link, Reference Phelan and Link2015; Williams & Rucker, Reference Williams and Rucker2000; Williams, Lawrence, & Davis, Reference Williams, Lawrence and Davis2019). Systemic racism and related factors that contribute to health disparities between Black and White Americans may engender a phenotype or profile of accelerated aging (Hooten, Pacheco, Smith, & Evans, Reference Hooten, Pacheco, Smith and Evans2022). In one study, by age 30, Black women had a higher allostatic load (i.e. physiological wear on bodily systems due to adaptation to stress; McEwen, Reference McEwen1998) than Black men and White Americans of the same age (Geronimus, Hicken, Keene, & Bound, Reference Geronimus, Hicken, Keene and Bound2006). Although there is variance across studies, evidence supports Black Americans have longer TL than White Americans (Hunt et al., Reference Hunt, Chen, Gardner, Kimura, Srinivasan, Eckfeldt and Aviv2008; Needham et al., Reference Needham, Salerno, Roberts, Boss, Allgood and Mukherjee2019), and that the rate of TL shortening for Blacks may be more rapid than for Whites across time (Rewak et al., Reference Rewak, Buka, Prescott, De Vivo, Loucks, Kawachi and Kubzansky2014). In some studies, by ages 49–55, Black women have shorter TL than White women (Geronimus et al., Reference Geronimus, Hicken, Pearson, Seashols, Brown and Cruz2010). Black adults have larger prospective increases in CRP over time than White adults (Zahodne, Kraal, Zaheed, Farris, & Sol, Reference Zahodne, Kraal, Zaheed, Farris and Sol2019) and Black women have higher CRP levels than Black men and White adults (Khera et al., Reference Khera, McGuire, Murphy, Stanek, Das, Vongpatanasin and de Lemos2005).

There is inconsistent evidence over whether Black Americans have accelerated, decelerated, or equivalent epigenetic aging as compared to White Americans; however, among postmenopausal women, Black women showed accelerated epigenetic aging in comparison to White women (Hamlat et al., Reference Hamlat, Adler, Laraia, Surachman, Lu, Zhang and Epel2022; Horvath et al., Reference Horvath, Gurven, Levine, Trumble, Kaplan, Allayee and Jamieson2016; Liu et al., Reference Liu, Chen, Assimes, Ferrucci, Horvath and Levine2019). In addition to differences in aging biomarkers during adulthood, Black girls experience puberty at significantly younger ages than White girls (Bleil, Booth-LaForce, & Benner, Reference Bleil, Booth-LaForce and Benner2017; Freedman et al., Reference Freedman, Khan, Serdula, Dietz, Srinivasan and Berenson2002), and so demonstrate accelerated aging as indexed by pubertal timing. The current study examined the indirect effect of race (used as a proxy for adversity in the form of systemic racism, which was not directly measured) on accelerated aging through pubertal timing.

The current study

The aims of the current study were to establish there if there was an indirect effect of early adversity on accelerated aging through pubertal timing. The current study makes use of a well-established and well-characterized longitudinal cohort from the National Heart, Lung, and Blood Institute Growth and Health Study (NGHS; Morrison, Reference Morrison1992) that followed young Black and White girls annually for over a decade starting at ages 9–10. As meta-analysis has concluded that specifically adversity characterized as abuse/threat in early life is related to earlier pubertal development (Colich et al., Reference Colich, Rosen, Williams and McLaughlin2020; Sumner et al., Reference Sumner, Colich, Uddin, Armstrong and McLaughlin2019), we operationalized childhood adversity as abuse/threat. We also examined the indirect effect of race on accelerated aging through pubertal timing. To operationalize both early adversity and accelerated aging, we created two latent variables for the respective constructs using SEM. We used three indicators of abuse/threat to construct a latent variable of early life adversity (general abuse/threat before age 13, sexual abuse, and physical abuse). To operationalize accelerated aging, we created a latent variable using the indicators of epigenetic aging, TL, and CRP.

Methods and materials

Participants and procedure

The National Heart, Lung, and Blood Institute Growth and Health Study (NGHS) (1992) assessed Black and White girls annually for 10 years and re-recruited them as adults in early middle age. The initial aims were to track cardiovascular risk factors and other health-related variables annually from childhood through young adulthood in self-identified Black and White girls from Richmond (CA, USA), Cincinnati (OH, USA), and Washington (D.C, USA). In 1987–1988, the NGHS Contra Costa County cohort (887 girls) was recruited at ages 9 and 10 from public and parochial schools in the Richmond Unified School District area. Retention across the 10-year study period was 89%. More details about the initial study sample are available (NGHS, 1992).

In 2016, a follow-up study of the NGHS Contra Costa County cohort was initiated to assess health and well-being in midlife. Over 73% of eligible women (307 Black and 317 White) were enrolled in the follow-up study. Eligibility criteria for the follow-up study included: (1) being an original NGHS participant; (2) not pregnant at the time of recruitment, and had not experienced a pregnancy, miscarriage, or abortion within the last 3 months; and (3) not living abroad, nor incarcerated or otherwise institutionalized. Multiple recruitment strategies were used to re-recruit original NGHS participants from the Richmond site, including mailing and telephone follow-up, social media and electronic outreach, and door-to-door outreach. Eligible participants provided written informed consent and participated in (1) a baseline survey and (2) a home/clinic visit, including blood and saliva collection for biomarker assessment. This study was approved by the local Institutional Review Board.

The sample for the current study consisted of 385 participants (187 Black, 198 White, M age = 39.4, s.d.age = 1.2), who provided blood or saliva samples as part of the follow-up study. The 498 girls who were part of the original NGHS study, but who were not part of the current study, did not significantly differ in race, χ2(1, 883) = 2.39, p = 0.12, childhood income, χ2(1, 837) = 0.03, p = 0.87, or age at menarche, t(833) = 0.37, p = 0.71, from the 385 women of the current study.

Early life adversity

Early adversity was measured via a latent construct combining three measures (general abuse, sexual, and physical abuse) as described below. Creating a latent variable of adversity minimizes measurement error and allowed us to focus on the variance shared between the two measures.

General threat/abuse. The Stress and Adversity Inventory (STRAIN, Slavich & Shields, Reference Slavich and Shields2018) was used to retrospectively measure the number of abuse/threat events before age 13. The STRAIN reliably assesses a person's cumulative exposure to stress over the life course by systematically inquiring about a diverse array of acute life events and chronic difficulties. The STRAIN is widely used for the assessment of both retrospective and prospective life events. Cumulative stress exposure assessed with the STRAIN has been linked to poor metabolic health and mental health in young adulthood (Toussaint, Shields, Dorn, & Slavich, Reference Toussaint, Shields, Dorn and Slavich2016). The general abuse/threat variable included stressors involving emotional abuse, sexual abuse, physical abuse, and prolonged harsh parental discipline. Respondents were also asked at what age the stressor occurred. The abuse/threat variable represented the total events that occurred during the ages of 0–12 years old.

Physical abuse and sexual abuse. Adapted from Felitti et al., (Reference Felitti, Anda, Nordenberg, Williamson, Spitz, Edwards and Marks1998), participants were asked if they had experienced physical abuse or sexual abuse. The physical abuse and sexual abuse variables represented if abuse before age 18 was endorsed.

Pubertal timing

Menarche. During the initial NGHS study, each year from baseline (ages 9/10) for 10 years, participants self-reported age at menarche. When there were multiple reports of age at menarche, the average of all reports was used.

Accelerated aging

Epigenetic age acceleration (GrimAge). DNA methylation analyses with saliva samples were performed at the Semel Institute UCLA Neurosciences Genomics Core (UNGC) using the Illumina Infinium HumanMethylation450 BeadChip (Illumina, Inc.). Genomic DNA was isolated using temperature denaturation and subjected to bisulfite conversion, PCR amplification, and DNA sequencing (EZ DNA Methylation-Gold Kit, Zymo Research, Tustin, California, USA). Methylation profiles were input to Horvath's online calculator https://dnamage.genetics.ucla.edu/, which automatically imputes any missing CpGs. After selection of the advanced analysis option and normalization based on the BMIQ method (Teschendorff et al., Reference Teschendorff, Marabita, Lechner, Bartlett, Tegner, Gomez-Cabrero and Beck2013), the output files contain the estimated epigenetic age of each participant and measures of predictive accuracy and data quality (e.g. for identifying array outliers, ‘corSampleVSgoldstandard’). Before data analysis began, participants (n = 26) were excluded due to quality control issues.

DNAm GrimAgeFootnote Footnote 1 is based on 1030 unique CpGs that robustly predict mortality as well as age-related conditions such as CVD (Li et al., Reference Li, Ploner, Wang, Magnusson, Reynolds, Finkel and Hägg2020; Lu et al., Reference Lu, Quach, Wilson, Reiner, Aviv, Raj and Whitsel2019). We used the recent optimized version of GrimAge which uses new DNAm estimators of plasma proteins: high sensitivity CRP and hemoglobin A1C (Lu et al., Reference Lu, Quach, Wilson, Reiner, Aviv, Raj and Whitsel2019). ‘AgeAccelerationResidual’, the residual resulting from a linear model where DNAm age is regressed on chronological age, was the outcome variable. Positive residual values reflected an individual being older biologically than chronological age and negative residual values reflected the reverse.

Telomere length measurement. Genomic DNA was extracted from 500 μl of saliva collected in the Oragene DNA kit (cat# OG-500, DNA Genotek Inc. Kanata, Ontario, Canada) with the DNA Agencourt DNAdvance kit (cat# A48705, Beckman Coulter Genomics Inc. Brea CA). DNA was stored at −80 °C and TL assays were performed between May and June of 2020. DNA was quantified by measuring OD260 with a NanoDrop 2000c Spectrophotometer (Nanodrop Products, Wilmington, DE, USA) and ran on 0.8% agarose gels to check DNA integrity. Samples that passed the quality control of OD260/OD280 between 1.7 and 2.0, concentration greater than 10 ng/μl and no degradation were used for TL measurement. Five samples had concentration lower than 10 ng/μl and nine samples were degraded.

The TL measurement assay was adapted from the published original method by Cawthon (Cawthon, Reference Cawthon2002; Lin et al., Reference Lin, Epel, Cheon, Kroenke, Sinclair, Bigos and Blackburn2010). After applying Dixon's Q test to remove outliners, the average concentrations of T and S from the triplicate wells were used to calculate the T/S ratios. T/S ratio for each sample was measured twice. When the duplicate T/S value and the initial value varied by more than 7%, the sample was run the third time and the two closest values were reported. 26% samples were run a third time. The coefficient of variation for this study was 2.2 ± 1.6%. The PCR efficiencies for the T and S reactions were 92.9 ± 2.5% and 95.2 ± 2.4% respectively. DNA extraction and TL assays for the entire study were performed using the same lots of reagents. Lab personnel who performed the assays were provided with de-identified samples and were blind to all demographic and clinical data. The intra-class correlation TL values from duplicate DNA extraction from 48 randomly selected samples from the same cohort is 0.95 (CI 0.911–0.972).

C-reactive protein (CRP). High-sensitivity CRP assays were performed by LabCorp (test 120766, CPT 86141). Adult participants had a fasting blood draw in the morning after a 10 h fast at local labs. Blood was collected into a green-top (heparin) tube, and sent to the nearest LabCorp assay lab, which in most cases was local to Richmond, CA. LabCorp has a strictly followed standardized automated protocol, certified by CLIA (Clinical Laboratory Improvement Amendments), and used nationally in each of their labs. The blood was separated into serum from cells within 1 h of drawing. A standard clinically used assay (immunochemiluminometric assay, ICMA on the Integra 800) was used.

Data analysis

To operationalize early adversity, we used three indicators of general abuse/threat before age 13, sexual abuse, and physical abuse to construct a latent variable. We used the three indicators of DNAm GrimAge, TL, and CRP to construct the latent variable of accelerated aging. The early adversity, menarche, and accelerated aging variables were regressed on race (Black = 1, White = 0). Annual income in childhood was regressed on adversity, age at menarche and accelerated aging. Age and current income were regressed on accelerated aging. The (a) direct and indirect (through age at menarche) effects of early adversity on accelerated aging as well as the (b) direct and indirect (through age at menarche) effects of race on accelerated aging were examined (Fig. 1). Global model fit was assessed using the robust χ2 test of exact model fit. Because the χ2 test may be sensitive to trivial amounts of data-model misfit in moderate to large samples (Browne & Cudeck, Reference Browne, Cudeck, Bollen and Long1993), we also assessed model fit using the following approximate fit indices: Bentler's comparative fit index (CFI), the root mean square error of approximation (RMSEA), and the standardized root mean square residuals (SRMR). Satisfactory model fit was determined by Hu and Bentler's (Reference Hu and Bentler1999) recommended two-index strategy of either (a) CFI ⩾0.95 and SRMR ⩽0.08 or (b) RMSEA ⩽0.06 and SRMR ⩽0.08. Inferences for direct and indirect effects were based on the unstandardized regression estimates b and their 95% confidence intervals (CIs), with the latter computed via the non-parametric bias-corrected bootstrap based on 5000 replicate samples (MacKinnon, Lockwood, & Williams, Reference MacKinnon, Lockwood and Williams2004). Descriptive statistics were computed using SPSS version 28.0; latent variable models were fitted using Mplus version 8.7 (Muthén & Muthén, Reference Muthén and Muthén2017).

Figure 1. Direct and indirect effects, through age at menarche, of early adversity and race on accelerated aging.

Results

Descriptive statistics are reported in Table 1 and correlations are reported in Table 2. Between Black and White women, there was no difference in the number of abuse or threat-related events before age 13 or number of sexual abuse experiences before age 18. White women (M = 1.30, s.d. = 0.46) reported significantly more experiences of physical abuse before 18 than Black women (M = 1.18, s.d. = 0.38). As expected, Black women were significantly younger at first menstruation, with a mean age at menarche of 11.96 years (s.d. = 1.22) compared to 12.47 years (s.d. = 1.23) for White women (Table 3).

Table 1. Descriptives of study variables

Note: *p < 0.05; **p < 0.01; ***p < 0.001.

Table 2. Correlations of study variables

Note: Childhood income was categorized as less than $20 000/year or $20 000/year or more. Current income was categorized as less than $60 000/year or $60 000/year or more. *p < 0.05; **p < 0.01; ***p < 0.001.

Table 3. Direct and indirect effects, through age at menarche, of early adversity on accelerated aging (N = 385)

Note: Confidence intervals (CI) were generated via the non-parametric bias-corrected bootstrap based on 5000 replicate samples. Childhood income was categorized as less than $20 000/year or $20 000/year or more. Current income was categorized as less than $60 000/year or $60 000/year or more.

Relative to Black women, White women were significantly more likely to have current annual incomes of at least $60 000 (68.7% v. 38.5%) and to have had household incomes of at least $20 000 annually when aged 9 or 10 (78.8% v. 43.9%).Footnote 2 Black women had significantly higher epigenetic age acceleration (epigenetic age relative to chronological age) than White women. On average, Black women were epigenetically older, 1.24 (5.07), than chronological age and White women were younger, −1.29 (4.83), than chronological age. Black women had significantly higher CRP than White women with a mean of 3.95 (4.17) mg/L compared to 2.69 (3.34) mg/L for White women. Black women had significantly longer TL with a mean T/S ratio of 1.25 (0.27) compared to 1.15 (0.26) for White women.

Model of early abuse and accelerated aging

Model fit was satisfactory: χ2(36) = 63.85, p = 0.001; CFI = .90; RMSEA = 0.05 (95% CI 0.03–0.07), SRMR = 0.04. The observed variables of early adversity (abuse before age 13, physical abuse, and sexual abuse) and accelerated aging (epigenetic age acceleration, CRP, and TL) loaded significantly onto their appropriate latent variables of adversity and accelerated aging, respectively (Fig. 1).

Race was not significantly associated with early adversity (b = −0.14, 95% CI −0.30 to 0.02, β = −0.24). Race was significantly associated with age at menarche (b = −0.62, 95% CI −0.90 to −0.34, β = −0.49), and with accelerated aging (b =1.50, 95% CI 0.51–2.61, β = 0.54), in that Black women had a younger age at menarche and higher accelerated aging. Childhood income was significantly negatively associated with accelerated aging (b = −1.22, 95% CI −2.47 to −0.05, β = −0.44), but not with early adversity (b = −0.06, 95% CI −0.22 to 0.12, β = −0.10), or age at menarche (b = −0.16, 95% CI −0.45 to 0.11, β = −0.13). Current income was significantly negatively associated with accelerated aging (b = −1.35, 95% CI −2.04 to −0.50, β = −0.49).

Early adversity was significantly negatively associated with age at menarche (b = −0.46, 95% CI −0.75 to −0.20, β = −0.21) and age at menarche was significantly negatively associated with accelerated aging (b = −0.40, 95% CI −0.73 to −0.04, β = −0.18), in that higher adversity was related to younger age at menarche and younger age at menarche was related to higher accelerated aging. There was a significant positive indirect effect of early abuse on accelerated aging through age at menarche (b = 0.19, 95% CI 0.03–0.44, β = 0.04), in that woman who experienced more abuse were younger at menarche, which was associated with greater accelerated aging. The direct association between adversity and accelerated aging was not significant (b = −0.31, 95% CI −1.33 to 0.91, β = −0.06). There was also a significant positive indirect effect of race on accelerated aging through age at menarche (b = 0.25, 95% CI 0.04–0.52, β = 0.09), in that Black women were younger at menarche, which was associated with greater accelerated aging.

Discussion

In the current study, adversity in childhood was associated with an earlier age of first menstruation (i.e. menarche), which was in turn associated with accelerated biological aging in mid-life for both Black and White women. As theorized, there was an indirect effect of childhood adversity on accelerated biological aging through age at menarche. Further, Black women had an earlier age at menarche and greater accelerated aging in comparison to White women and there was an indirect effect of race on accelerated aging through age at menarche. Accelerated biological aging may begin in childhood (i.e. early pubertal timing may be a form of accelerated aging) and the accelerated aging process set in motion by abuse during childhood. In line with the biological embedding model (Ehrlich, Ross, Chen, & Miller, Reference Ehrlich, Ross, Chen and Miller2016; Miller, Chen, & Parker, Reference Miller, Chen and Parker2011), adversity may act through epigenetic changes, inflammation, and other biological processes to accelerate biological aging (Finkel & Holbrook, Reference Finkel and Holbrook2000).

Results suggest women who experienced abuse in childhood may mature earlier and present as biologically older in adulthood than same-age peers. Findings align with work showing that both early abuse and earlier age at menarche were associated with faster epigenetic age acceleration (Hamlat et al., Reference Hamlat, Prather, Horvath, Belsky and Epel2021). Black women demonstrated another path of vulnerability by which earlier age at menarche resulted in accelerated biological aging. Along with a younger age at menarche, Black women had greater accelerated aging compared to White women, including higher levels of CRP and faster epigenetic age acceleration. There was no difference in early life adversity, as assessed by a composite of three abuse variables, between Black and White women. Race is a proxy for systemic racism (which was not directly captured in the current study), which is a fundamental cause of racial inequities in health (Phelan & Link, Reference Phelan and Link2015; Williams et al., Reference Williams, Lawrence and Davis2019). Black women may ‘weather’ or experience greater biological aging due to race-related stressors (Geronimus, Reference Geronimus1992), and weathering may begin to influence aging-related biomarkers beginning in childhood. Black girls experience pubertal onset at significantly younger ages than White girls (Bleil et al., Reference Bleil, Booth-LaForce and Benner2017; Freedman et al., Reference Freedman, Khan, Serdula, Dietz, Srinivasan and Berenson2002) and so demonstrate accelerated aging as indexed by pubertal timing, which may contribute to health disparities between Black and White women in later life.

The current study provides support for the psychosocial acceleration hypothesis, which holds that in an early environment characterized by high adversity, pubertal maturation may accelerate to maximize opportunities for reproduction. The focus of resources on the acceleration of puberty may be at the expense of investments for adult health and lead to premature aging decades before the development of serious disease and dysfunction. Taken together, study findings support that early pubertal timing and accelerated biological aging represent similar evolutionary-developmental processes (Belsky, Reference Belsky2019; Belsky & Shalev, Reference Belsky and Shalev2016) and that early puberty may be conceptualized as accelerated aging that begins in childhood.

Accelerated biological aging may serve as a mechanism by which early adversity contributes to health disparities, and girls who experience early adversity, especially Black girls, may benefit from intervention. Puberty is a sensitive period for recalibration of the HPA axis in children who have experienced early life adversity (Gunnar, DePasquale, Reid, & Donzella, Reference Gunnar, DePasquale, Reid and Donzella2019). Intervention during the pubertal transition could protect against accelerated aging and lead to healthier outcomes during adulthood. For example, supportive family environments have been found to buffer against further epigenetic age acceleration for Black youth experiencing high levels of racial discrimination (Brody, Miller, Yu, Beach, & Chen, Reference Brody, Miller, Yu, Beach and Chen2016).

Strengths and limitations

The current study has notable strengths including a sufficiently large sample of Black and White women to examine the indirect effects of early adversity on accelerated biological aging through age at menarche. Secondly, this is the first study to utilize an accelerated aging latent variable using CRP, epigenetic clocks, and TL to investigate the relationship between early adversity and biological aging.Footnote 3 Thirdly, we also used multiple measures of early adversity to construct a latent variable, which included abuse before age 13 as well as childhood physical and sexual abuse. To better isolate effects of early abuse, we also included a measure of early financial adversity (household income in childhood) as a covariate. Finally, examining biological aging as an outcome in midlife allows us to evaluate the influence of early adversity on biological aging decades before the onset of major disease or disability.

Study results should be considered within the context of several limitations. For one, adversity that took place in childhood was assessed retrospectively in adulthood. The accuracy of retrospective recall of childhood experiences should not be assumed (Hardt & Rutter, Reference Hardt and Rutter2004; Reuben et al., Reference Reuben, Moffitt, Caspi, Belsky, Harrington, Schroeder and Danese2016); however, retrospective report of maltreatment is practical with an adult sample (Baldwin, Reuben, Newbury, & Danese, Reference Baldwin, Reuben, Newbury and Danese2019; Newbury et al., Reference Newbury, Arseneault, Moffitt, Caspi, Danese, Baldwin and Fisher2018). Secondly, the current study evaluated the associations between early adversity, age at menarche, and accelerated biological aging in Black and White women and did not include men. Future studies should examine similar associations in both men and women of other racial and ethnic backgrounds. For instance, children in disadvantaged neighborhoods and those with advance pubertal development had faster pace of biological aging as measured by DunedinPoAm,Footnote 4 and Latinx-identifying children had a faster pace of aging than White children (Raffington et al., Reference Raffington, Belsky, Kothari, Malanchini, Tucker-Drob and Harden2021). Thirdly, our research did not have multiple assessments of biological aging. Prospective research should evaluate the effects of early adversity and age of menarche on longitudinal changes of biological aging across the lifespan. Our research did not have multiple assessments of biological aging. Prospective research should evaluate the effects of early adversity and age of menarche on longitudinal changes of biological aging across the lifespan. Finally, in the current study, the direct effect of adversity on aging was not significant. An indirect effect may be statistically significant when the total or direct effect is not significant, and the significance of the total effect should not be used as a requirement for mediation (Fritz, Cox, & MacKinnon, Reference Fritz, Cox and MacKinnon2015; Hayes, Reference Hayes2009; Kenny & Judd, Reference Kenny and Judd2014; O'Rourke & MacKinnon, Reference O'Rourke and MacKinnon2015).

Acknowledgements

This research was supported by the National Institute of Mental Health grant 5T32MH019391, National Institute on Aging grant 1R01AG059677 to E. S. E., National Institute on Aging diversity supplement (R01AG059677; PI: Epel) to E. J. H, and the National Institute of Child Health and Human Development grant 1R01HD073568 to B. L. This work was supported by the National Institute on Aging for the National Institutes of Health under grant number P30AG015272 (University of California San Francisco, Center for Aging in Diverse Communities). The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

Competing interests

Elissa J. Hamlat, Torsten B. Neilands, Barbara Laraia, Joshua Zhang, Ake T. Lu, Jue Lin, Steve Horvath, and Elissa S. Epel reported no biomedical financial interests or potential conflicts of interest.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0033291723001629

Footnotes

The notes appear after the main text.

1 We a priori selected DNA GrimAge over other clocks at the time of study conception for several reasons. DNAm GrimAge has a strong association with age at menopause (Lu et al., Reference Lu, Quach, Wilson, Reiner, Aviv, Raj and Whitsel2019) and thus may be more likely to be associated with reproductive transitions such as age at menarche. When relationships between trauma and age at menarche with four clocks (Horvath DNAm Age, Hannum DNAm Age, DNAm PhenoAge, DNAm GrimAge), GrimAge was the only clock to have significant associations with trauma and age at menarche (Hamlat et al., Reference Hamlat, Prather, Horvath, Belsky and Epel2021).

2 $20 000 was the approximate median household income in Richmond, CA when the initial study began in 1985. $60 000 was the approximate median household income in Richmond, CA when follow-up data collection began in 2016.

3 As a sensitivity analysis (Table S1), the latent accelerated aging variable was replaced by the three biomarkers in the same model. The indirect effects of adversity and of race on CRP and on TL were significant; however, the indirect effects on epigenetic aging did not reach significance. This suggests CRP and telomere length may be driving the association between early adversity and biological aging.

4 In Table S2, we have substituted DunedinPoAm, a newer clock which measures the pace of epigenetic aging, for GrimAge. The primary findings of an indirect effect of childhood adversity on accelerated aging through age at menarche and an indirect effect of race on accelerated aging through age at menarche are supported when DunedinPoAm is substituted; in fact, both indirect effects are larger.

References

Adler, N. E., & Rehkopf, D. H. (2008). US disparities in health: Descriptions, causes, and mechanisms. Annual Review of Public Health, 29, 235252.CrossRefGoogle Scholar
Baldwin, J. R., Reuben, A., Newbury, J. B., & Danese, A. (2019). Agreement between prospective and retrospective measures of childhood maltreatment: A systematic review and meta-analysis. JAMA Psychiatry, 76(6), 584593.CrossRefGoogle ScholarPubMed
Baumeister, D., Akhtar, R., Ciufolini, S., Pariante, C. M., & Mondelli, V. (2016). Childhood trauma and adulthood inflammation: A meta-analysis of peripheral C-reactive protein, interleukin-6 and tumour necrosis factor-α. Molecular Psychiatry, 21(5), 642649.CrossRefGoogle ScholarPubMed
Belsky, D. W., Moffitt, T. E., Cohen, A. A., Corcoran, D. L., Levine, M. E., Prinz, J. A., … Caspi, A. (2018). Eleven telomere, epigenetic clock, and biomarker-composite quantifications of biological aging: Do they measure the same thing? American Journal of Epidemiology, 187(6), 12201230.Google ScholarPubMed
Belsky, J. (2019). Early-life adversity accelerates child and adolescent development. Current Directions in Psychological Science, 28(3), 241246.CrossRefGoogle Scholar
Belsky, J., Ruttle, P. L., Boyce, W. T., Armstrong, J. M., & Essex, M. J. (2015). Early adversity, elevated stress physiology, accelerated sexual maturation, and poor health in females. Developmental Psychology, 51(6), 816.CrossRefGoogle ScholarPubMed
Belsky, J., & Shalev, I. (2016). Contextual adversity, telomere erosion, pubertal development, and health: Two models of accelerated aging, or one? Development and Psychopathology, 28(4), 13671383.CrossRefGoogle ScholarPubMed
Belsky, J., Steinberg, L., & Draper, P. (1991). Childhood experience, interpersonal development, and reproductive strategy: An evolutionary theory of socialization. Child Development, 62(4), 647670.CrossRefGoogle ScholarPubMed
Binder, A. M., Corvalan, C., Mericq, V., Pereira, A., Santos, J. L., Horvath, S., … Michels, K. B. (2018). Faster ticking rate of the epigenetic clock is associated with faster pubertal development in girls. Epigenetics, 13(1), 8594.CrossRefGoogle ScholarPubMed
Bleil, M. E., Booth-LaForce, C., & Benner, A. D. (2017). Race disparities in pubertal timing: Implications for cardiovascular disease risk among African American women. Population Research and Policy Review, 36(5), 717738.CrossRefGoogle ScholarPubMed
Brody, G. H., Miller, G. E., Yu, T., Beach, S. R. H., & Chen, E. (2016). Supportive family environments ameliorate the link between racial discrimination and epigenetic aging: A replication across two longitudinal cohorts. Psychological Science, 27(4), 530541.10.1177/0956797615626703CrossRefGoogle ScholarPubMed
Browne, M. W., & Cudeck, R. (1993). Alternative ways of assessing model fit. In Bollen, K. & Long, K. (Eds.), Testing structural equation models (pp. 136162). Newbury Park: Sage.Google Scholar
Cawthon, R. M. (2002). Telomere measurement by quantitative PCR. Nucleic Acids Research, 30(10), e47e47.CrossRefGoogle ScholarPubMed
Charalampopoulos, D., McLoughlin, A., Elks, C. E., & Ong, K. K. (2014). Age at menarche and risks of all-cause and cardiovascular death: A systematic review and meta-analysis. American Journal of Epidemiology, 180(1), 2940.CrossRefGoogle Scholar
Churchwell, K., Elkind, M. S., Benjamin, R. M., Carson, A. P., Chang, E. K., Lawrence, W., … American Heart Association. (2020). Call to action: structural racism as a fundamental driver of health disparities: a presidential advisory from the American Heart Association. Circulation, 142(24), e454e468.10.1161/CIR.0000000000000936CrossRefGoogle ScholarPubMed
Colich, N. L., & Mclaughlin, K. A. (2022). Accelerated pubertal development as a mechanism linking trauma exposure with depression and anxiety in adolescence. Current Opinion in Psychology, 46, 101338.CrossRefGoogle ScholarPubMed
Colich, N. L., Rosen, M. L., Williams, E. S., & McLaughlin, K. A. (2020). Biological aging in childhood and adolescence following experiences of threat and deprivation: A systematic review and meta-analysis. Psychological Bulletin, 146(9), 721764.CrossRefGoogle ScholarPubMed
D'Mello, M. J., Ross, S. A., Briel, M., Anand, S. S., Gerstein, H., & Paré, G. (2015). Association between shortened leukocyte telomere length and cardiometabolic outcomes: Systematic review and meta-analysis. Circulation: Cardiovascular Genetics, 8(1), 8290.Google ScholarPubMed
Ehrlich, K. B., Ross, K. M., Chen, E., & Miller, G. E. (2016). Testing the biological embedding hypothesis: Is early life adversity associated with a later proinflammatory phenotype?. Development and Psychopathology, 28(4pt2), 12731283.CrossRefGoogle ScholarPubMed
Ellis, B. J. (2004). Timing of pubertal maturation in girls: An integrated life history approach. Psychological Bulletin, 130, 920958.10.1037/0033-2909.130.6.920CrossRefGoogle ScholarPubMed
Felitti, V. J., Anda, R. F., Nordenberg, D., Williamson, D. F., Spitz, A. M., Edwards, V., & Marks, J. S. (1998). Relationship of childhood abuse and household dysfunction to many of the leading causes of death in adults: The adverse childhood experiences (ACE) study. American Journal of Preventive Medicine, 14(4), 245258.CrossRefGoogle ScholarPubMed
Field, A. E., Robertson, N. A., Wang, T., Havas, A., Ideker, T., & Adams, P. D. (2018). DNA methylation clocks in aging: Categories, causes, and consequences. Molecular Cell, 71(6), 882895.CrossRefGoogle ScholarPubMed
Finkel, T., & Holbrook, N. J. (2000). Oxidants, oxidative stress and the biology of ageing. Nature, 408(6809), 239247.CrossRefGoogle ScholarPubMed
Freedman, D. S., Khan, L. K., Serdula, M. K., Dietz, W. H., Srinivasan, S. R., & Berenson, G. S. (2002). Relation of age at menarche to race, time period, and anthropometric dimensions: The Bogalusa Heart Study. Pediatrics, 110(4), e43.10.1542/peds.110.4.e43CrossRefGoogle ScholarPubMed
Fritz, M. S., Cox, M. G., & MacKinnon, D. P. (2015). Increasing statistical power in mediation models without increasing sample size. Evaluation & the Health Professions, 38(3), 343366.CrossRefGoogle ScholarPubMed
Gassen, N. C., Chrousos, G. P., Binder, E. B., & Zannas, A. S. (2017). Life stress, glucocorticoid signaling, and the aging epigenome: Implications for aging-related diseases. Neuroscience & Biobehavioral Reviews, 74, 356365.CrossRefGoogle ScholarPubMed
Geronimus, A. T. (1992). The weathering hypothesis and the health of African-American women and infants: evidence and speculations. Ethnicity and Disease, 2(3), 207221.Google ScholarPubMed
Geronimus, A. T., Hicken, M., Keene, D., & Bound, J. (2006). ‘Weathering’ and age patterns of allostatic load scores among blacks and whites in the United States. American Journal of Public Health, 96(5), 826833.10.2105/AJPH.2004.060749CrossRefGoogle ScholarPubMed
Geronimus, A. T., Hicken, M. T., Pearson, J. A., Seashols, S. J., Brown, K. L., & Cruz, T. D. (2010). Do US black women experience stress-related accelerated biological aging? Human Nature, 21(1), 1938.10.1007/s12110-010-9078-0CrossRefGoogle ScholarPubMed
Gunnar, M. R., DePasquale, C. E., Reid, B. M., & Donzella, B. (2019). Pubertal stress recalibration reverses the effects of early life stress in postinstitutionalized children. Proceedings of the National Academy of Sciences, 116(48), 2398423988.CrossRefGoogle ScholarPubMed
Hamlat, E. J., Adler, N. E., Laraia, B., Surachman, A., Lu, A. T., Zhang, J., … Epel, E. S. (2022). Association of subjective social status with epigenetic aging among black and white women. Psychoneuroendocrinology, 141, 105748.CrossRefGoogle ScholarPubMed
Hamlat, E. J., Prather, A. A., Horvath, S., Belsky, J., & Epel, E. S. (2021). Early life adversity, pubertal timing, and epigenetic age acceleration in adulthood. Developmental Psychobiology, 63(5), 890902.CrossRefGoogle ScholarPubMed
Hardt, J., & Rutter, M. (2004). Validity of adult retrospective reports of adverse childhood experiences: Review of the evidence. Journal of Child Psychology and Psychiatry, and Allied Disciplines, 45(2), 260273.CrossRefGoogle ScholarPubMed
Haycock, P. C., Heydon, E. E., Kaptoge, S., Butterworth, A. S., Thompson, A., & Willeit, P. (2014). Leucocyte telomere length and risk of cardiovascular disease: Systematic review and meta-analysis. British Medical Journal, 349.CrossRefGoogle ScholarPubMed
Hayes, A. F. (2009). Beyond Baron and Kenny: Statistical mediation analysis in the new millennium. Communication Monographs, 76(4), 408420.CrossRefGoogle Scholar
Hooten, N. N., Pacheco, N. L., Smith, J. T., & Evans, M. K. (2022). The accelerated aging phenotype: The role of race and social determinants of health on aging. Ageing Research Reviews, 73, 101536.CrossRefGoogle Scholar
Horvath, S., Gurven, M., Levine, M. E., Trumble, B. C., Kaplan, H., Allayee, H., … Jamieson, B. D. (2016). An epigenetic clock analysis of race/ethnicity, sex, and coronary heart disease. Genome Biology, 17(1), 171.CrossRefGoogle Scholar
Horvath, S., & Raj, K. (2018). DNA methylation-based biomarkers and the epigenetic clock theory of ageing. Nature Reviews Genetics, 19(6), 371384.CrossRefGoogle ScholarPubMed
Hu, L. T., & Bentler, P. M. (1999). Cutoff criteria for fit indexes in covariance structure analysis: Conventional criteria versus new alternatives. Structural Equation Modeling: a Multidisciplinary Journal, 6(1), 155.10.1080/10705519909540118CrossRefGoogle Scholar
Hughes, K., Bellis, M. A., Hardcastle, K. A., Sethi, D., Butchart, A., Mikton, C., … Dunne, M. P. (2017). The effect of multiple adverse childhood experiences on health: A systematic review and meta-analysis. The Lancet Public Health, 2(8), e356e366.CrossRefGoogle Scholar
Hunt, S. C., Chen, W., Gardner, J. P., Kimura, M., Srinivasan, S. R., Eckfeldt, J. H., … Aviv, A. (2008). Leukocyte telomeres are longer in African Americans than in whites: The national heart, lung, and blood institute family heart study and the Bogalusa heart study. Aging Cell, 7(4), 451458.CrossRefGoogle ScholarPubMed
Emerging Risk Factors Collaboration, Kaptoge, S., Di Angelantonio, E., Lowe, G., Pepys, M. B., Thompson, S. G., Collins, R., & Danesh, J. (2010). Emerging risk factors collaboration C-reactive protein concentration and risk of coronary heart disease, stroke, and mortality: An individual participant meta-analysis. The Lancet, 375(9709), 132140.Google ScholarPubMed
Kenny, D. A., & Judd, C. M. (2014). Power anomalies in testing mediation. Psychological Science, 25(2), 334339.CrossRefGoogle ScholarPubMed
Khera, A., McGuire, D. K., Murphy, S. A., Stanek, H. G., Das, S. R., Vongpatanasin, W., … de Lemos, J. A. (2005). Race and gender differences in C-reactive protein levels. Journal of the American College of Cardiology, 46(3), 464469.CrossRefGoogle ScholarPubMed
Kline, R. B. (2011). Principles and practice of structural equation modeling (3rd ed.). New York, NY: The Guilford Press.Google Scholar
Koss, K. J., Schneper, L. M., Brooks-Gunn, J., McLanahan, S., Mitchell, C., & Notterman, D. A. (2020). Early puberty and telomere length in preadolescent girls and mothers. The Journal of Pediatrics, 222, 193199.CrossRefGoogle ScholarPubMed
Li, X., Ploner, A., Wang, Y., Magnusson, P. K., Reynolds, C., Finkel, D., … Hägg, S. (2020). Longitudinal trajectories, correlations and mortality associations of nine biological ages across 20-years follow-up. Elife, 9, e51507.CrossRefGoogle ScholarPubMed
Li, Z., He, Y., Wang, D., Tang, J., & Chen, X. (2017). Association between childhood trauma and accelerated telomere erosion in adulthood: A meta-analytic study. Journal of Psychiatric Research, 93, 6471.10.1016/j.jpsychires.2017.06.002CrossRefGoogle ScholarPubMed
Lin, J., Epel, E., Cheon, J., Kroenke, C., Sinclair, E., Bigos, M., … Blackburn, E. (2010). Analyses and comparisons of telomerase activity and telomere length in human T and B cells: Insights for epidemiology of telomere maintenance. Journal of Immunological Methods, 352(1–2), 7180.CrossRefGoogle Scholar
Liu, Z., Chen, B. H., Assimes, T. L., Ferrucci, L., Horvath, S., & Levine, M. E. (2019). The role of epigenetic aging in education and racial/ethnic mortality disparities among older US Women. Psychoneuroendocrinology, 104, 1824.CrossRefGoogle Scholar
Lu, A. T., Quach, A., Wilson, J. G., Reiner, A. P., Aviv, A., Raj, K., … Whitsel, E. A. (2019). DNA methylation GrimAge strongly predicts lifespan and healthspan. Aging, 11(2), 303.CrossRefGoogle ScholarPubMed
MacKinnon, D. P., Lockwood, C. M., & Williams, J. (2004). Confidence limits for the indirect effect: Distribution of the product and resampling methods. Multivariate Behavioral Research, 39(1), 99128.10.1207/s15327906mbr3901_4CrossRefGoogle ScholarPubMed
McEwen, B. S. (1998). Stress, adaptation, and disease: Allostasis and allostatic load. Annals of the New York Academy of Sciences, 840(1), 3344.10.1111/j.1749-6632.1998.tb09546.xCrossRefGoogle ScholarPubMed
Merrick, M. T., Ford, D. C., Ports, K. A., Guinn, A. S., Chen, J., Klevens, J., … Ottley, P. (2019). Vital signs: Estimated proportion of adult health problems attributable to adverse childhood experiences and implications for prevention – 25 States, 2015–2017. Morbidity and Mortality Weekly Report, 68(44), 9991005.CrossRefGoogle Scholar
Miller, G. E., Chen, E., & Parker, K. J. (2011). Psychological stress in childhood and susceptibility to the chronic diseases of aging: Moving toward a model of behavioral and biological mechanisms. Psychological Bulletin, 137(6), 959997.CrossRefGoogle Scholar
Morrison, J. (1992). Obesity and cardiovascular disease risk factors in black and white girls: The NHLBI Growth and Health Study. American Journal of Public Health, 82(12), 16131620.Google Scholar
Muthén, L. K., & Muthén, B. O. (1998–2017). Mplus user's guide (8th ed.). Los Angeles, CA: Muthén & Muthén.Google Scholar
Needham, B. L., Salerno, S., Roberts, E., Boss, J., Allgood, K. L., & Mukherjee, B. (2019). Do black/white differences in telomere length depend on socioeconomic status? Biodemography and Social Biology, 65(4), 287312.10.1080/19485565.2020.1765734CrossRefGoogle ScholarPubMed
Newbury, J. B., Arseneault, L., Moffitt, T. E., Caspi, A., Danese, A., Baldwin, J. R., & Fisher, H. L. (2018). Measuring childhood maltreatment to predict early-adult psychopathology: Comparison of prospective informant-reports and retrospective self-reports. Journal of Psychiatric Research, 96, 5764.CrossRefGoogle ScholarPubMed
O'Rourke, H. P., & MacKinnon, D. P. (2015). When the test of mediation is more powerful than the test of the total effect. Behavior Research Methods, 47, 424442.CrossRefGoogle Scholar
Paradies, Y., Ben, J., Denson, N., Elias, A., Priest, N., Pieterse, A., … Gee, G. (2015). Racism as a determinant of health: a systematic review and meta-analysis. PloS ONE, 10(9), e0138511.CrossRefGoogle Scholar
Phelan, J. C., & Link, B. G. (2015). Is racism a fundamental cause of inequalities in health? Annual Review of Sociology, 41, 311330.CrossRefGoogle Scholar
Raffington, L., Belsky, D. W., Kothari, M., Malanchini, M., Tucker-Drob, E. M., & Harden, K. P. (2021). Socioeconomic disadvantage and the pace of biological aging in children. Pediatrics, 147(6), e2020024406.CrossRefGoogle ScholarPubMed
Reuben, A., Moffitt, T. E., Caspi, A., Belsky, D. W., Harrington, H., Schroeder, F., … Danese, A. (2016). Lest we forget: Comparing retrospective and prospective assessments of adverse childhood experiences in the prediction of adult health. Journal of Child Psychology and Psychiatry, 57(10), 11031112.CrossRefGoogle ScholarPubMed
Rewak, M., Buka, S., Prescott, J., De Vivo, I., Loucks, E. B., Kawachi, I., … Kubzansky, L. D. (2014). Race-related health disparities and biological aging: Does rate of telomere shortening differ across blacks and whites? Biological Psychology, 99, 9299.CrossRefGoogle ScholarPubMed
Ridout, K. K., Levandowski, M., Ridout, S. J., Gantz, L., Goonan, K., Palermo, D., … Tyrka, A. R. (2018). Early life adversity and telomere length: A meta-analysis. Molecular Psychiatry, 23(4), 858871.CrossRefGoogle ScholarPubMed
Saxbe, D. E., Negriff, S., Susman, E. J., & Trickett, P. K. (2015). Attenuated hypothalamicpituitary-adrenal axis functioning predicts accelerated pubertal development in girls 1 year later. Development and Psychopathology, 27(3), 819828.CrossRefGoogle Scholar
Simpkin, A. J., Howe, L. D., Tilling, K., Gaunt, T. R., Lyttleton, O., McArdle, W. L., … Relton, C. L. (2017). The epigenetic clock and physical development during childhood and adolescence: Longitudinal analysis from a UK birth cohort. International Journal of Epidemiology, 46(2), 549558.Google ScholarPubMed
Slavich, G. M., & Shields, G. S. (2018). Assessing lifetime stress exposure using the Stress and Adversity Inventory for Adults (Adult STRAIN): An overview and initial validation. Psychosomatic Medicine, 80(1), 1727.CrossRefGoogle ScholarPubMed
Slopen, N., Shonkoff, J. P., Albert, M. A., Yoshikawa, H., Jacobs, A., Stoltz, R., & Williams, D. R. (2016). Racial disparities in child adversity in the US: Interactions with family immigration history and income. American Journal of Preventive Medicine, 50(1), 4756.CrossRefGoogle ScholarPubMed
Sumner, J. A., Colich, N. L., Uddin, M., Armstrong, D., & McLaughlin, K. A. (2019). Early experiences of threat, but not deprivation, are associated with accelerated biological aging in children and adolescents. Biological Psychiatry, 85(3), 268278.10.1016/j.biopsych.2018.09.008CrossRefGoogle Scholar
Teschendorff, A. E., Marabita, F., Lechner, M., Bartlett, T., Tegner, J., Gomez-Cabrero, D., & Beck, S. (2013). A beta-mixture quantile normalization method for correcting probe design bias in Illumina Infinium 450 k DNA methylation data. Bioinformatics, 29(2), 189196.10.1093/bioinformatics/bts680CrossRefGoogle ScholarPubMed
The National Heart, Lung, and Blood Institute Growth and Health Study Research Group. (1992). Obesity and cardiovascular disease risk factors in black and white girls: the NHLBI Growth and Health Study. American Journal of Public Health, 82(12), 16131620.CrossRefGoogle Scholar
Toussaint, L., Shields, G. S., Dorn, G., & Slavich, G. M. (2016). Effects of lifetime stress exposure on mental and physical health in young adulthood: How stress degrades and forgiveness protects health. Journal of Health Psychology, 21(6), 10041014.CrossRefGoogle ScholarPubMed
Willeit, P., Raschenberger, J., Heydon, E. E., Tsimikas, S., Haun, M., Mayr, A., … Kiechl, S. (2014). Leucocyte telomere length and risk of type 2 diabetes mellitus: New prospective cohort study and literature-based meta-analysis. PLoS ONE, 9(11), e112483.CrossRefGoogle ScholarPubMed
Williams, D. R. (2012). Miles to go before we sleep: Racial inequities in health. Journal of Health and Social Behavior, 53(3), 279295.10.1177/0022146512455804CrossRefGoogle ScholarPubMed
Williams, D. R., Lawrence, J. A., & Davis, B. A. (2019). Racism and health: Evidence and needed research. Annual Review of Public Health, 40, 105125.CrossRefGoogle ScholarPubMed
Williams, D. R., & Rucker, T. D. (2000). Understanding and addressing racial disparities in health care. Health Care Financing Review, 21(4), 75.Google ScholarPubMed
Wolf, E. J., Maniates, H., Nugent, N., Maihofer, A. X., Armstrong, D., Ratanatharathorn, A., … Logue, M. W. (2018). Traumatic stress and accelerated DNA methylation age: A meta-analysis. Psychoneuroendocrinology, 92, 123134.CrossRefGoogle ScholarPubMed
Zahodne, L. B., Kraal, A. Z., Zaheed, A., Farris, P., & Sol, K. (2019). Longitudinal effects of race, ethnicity, and psychosocial disadvantage on systemic inflammation. SSM-Population Health, 7, 100391.CrossRefGoogle ScholarPubMed
Zannas, A. S., Arloth, J., Carrillo-Roa, T., Iurato, S., Röh, S., Ressler, K. J., … Mehta, D. (2015). Lifetime stress accelerates epigenetic aging in an urban, African American cohort: Relevance of glucocorticoid signaling. Genome Biology, 16, 266.CrossRefGoogle Scholar
Figure 0

Figure 1. Direct and indirect effects, through age at menarche, of early adversity and race on accelerated aging.

Figure 1

Table 1. Descriptives of study variables

Figure 2

Table 2. Correlations of study variables

Figure 3

Table 3. Direct and indirect effects, through age at menarche, of early adversity on accelerated aging (N = 385)

Supplementary material: File

Hamlat et al. supplementary material

Hamlat et al. supplementary material
Download Hamlat et al. supplementary material(File)
File 57 KB