Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-25T03:50:06.412Z Has data issue: false hasContentIssue false

Alzheimer’s Disease Polygenic Scores Predict Changes in Episodic Memory and Executive Function Across 12 Years in Late Middle Age

Published online by Cambridge University Press:  21 February 2022

Daniel E. Gustavson*
Affiliation:
Department of Medicine, Vanderbilt University Medical Center, Nashville, TN, USA Vanderbilt Genetics Institute, Vanderbilt University Medical Center, Nashville, TN, USA Vanderbilt Memory and Alzheimer’s Center, Vanderbilt University Medical Center, Nashville, TN, USA
Chandra A. Reynolds
Affiliation:
Department of Psychology, University of California, Riverside, 900 University Ave., Riverside, CA, USA
Timothy J. Hohman
Affiliation:
Vanderbilt Genetics Institute, Vanderbilt University Medical Center, Nashville, TN, USA Vanderbilt Memory and Alzheimer’s Center, Vanderbilt University Medical Center, Nashville, TN, USA
Angela L. Jefferson
Affiliation:
Vanderbilt Memory and Alzheimer’s Center, Vanderbilt University Medical Center, Nashville, TN, USA
Jeremy A. Elman
Affiliation:
Department of Psychiatry and Center for Behavior Genetics of Aging, University of California, San Diego, La Jolla, CA, USA
Matthew S. Panizzon
Affiliation:
Department of Psychiatry and Center for Behavior Genetics of Aging, University of California, San Diego, La Jolla, CA, USA
Michael C. Neale
Affiliation:
Virginia Institute for Psychiatric and Behavior Genetics, Virginia Commonwealth University, Richmond, VA, USA
Mark W. Logue
Affiliation:
National Center for PTSD, Behavioral Sciences Division, VA Boston Healthcare System, Boston, MA, USA Department of Psychiatry, Boston University School of Medicine, Boston, MA, USA Biomedical Genetics, Boston University School of Medicine, Boston, MA, USA Department of Biostatistics, Boston University School of Public Health, Boston, MA, USA
Michael J. Lyons
Affiliation:
Department of Psychological and Brain Sciences, Boston University, Boston, MA, USA
Carol E. Franz
Affiliation:
Department of Psychiatry and Center for Behavior Genetics of Aging, University of California, San Diego, La Jolla, CA, USA
William S. Kremen
Affiliation:
Department of Psychiatry and Center for Behavior Genetics of Aging, University of California, San Diego, La Jolla, CA, USA
*
*Correspondence and reprint requests to: Daniel Gustavson, Department of Medicine, Vanderbilt University Medical Center, 2525 West End Ave., Suite 700, Nashville, TN, 37203. E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

Alzheimer’s disease (AD) is highly heritable, and AD polygenic risk scores (AD-PRSs) have been derived from genome-wide association studies. However, the nature of genetic influences very early in the disease process is still not well known. Here we tested the hypothesis that an AD-PRSs would be associated with changes in episodic memory and executive function across late midlife in men who were cognitively unimpaired at their baseline midlife assessment..

Method:

We examined 1168 men in the Vietnam Era Twin Study of Aging (VETSA) who were cognitively normal (CN) at their first of up to three assessments across 12 years (mean ages 56, 62, and 68). Latent growth models of episodic memory and executive function were based on 6–7 tests/subtests. AD-PRSs were based on Kunkle et al. (Nature Genetics, 51, 414–430, 2019), p < 5×10−8 threshold.

Results:

AD-PRSs were correlated with linear slopes of change for both cognitive abilities. Men with higher AD-PRSs had steeper declines in both memory (r = −.19, 95% CI [−.35, −.03]) and executive functioning (r = −.27, 95% CI [−.49, −.05]). Associations appeared driven by a combination of APOE and non-APOE genetic influences.

Conclusions:

Memory is most characteristically impaired in AD, but executive functions are one of the first cognitive abilities to decline in midlife in normal aging. This study is among the first to demonstrate that this early decline also relates to AD genetic influences, even in men CN at baseline.

Type
Research Article
Copyright
Copyright © INS. Published by Cambridge University Press, 2022

INTRODUCTION

The Alzheimer’s disease (AD) process begins decades before severe symptoms are observed (Aizenstein et al., Reference Aizenstein, Nebes, Saxton, Price, Mathis, Tsopelas and Klunk2008; Bateman et al., Reference Bateman, Xiong, Benzinger, Fagan, Goate and Fox2012; Bennett et al., Reference Bennett, Schneider, Arvanitakis, Kelly, Aggarwal, Shah and Wilson2006; Kremen et al., Reference Kremen, Jak, Panizzon, Spoon, Franz, Thompson and Lyons2014a). Recent efforts have highlighted the need to identify risk factors early in this process and to identify non-invasive tests that may improve identification of mild cognitive impairment (MCI) or AD, or act as screening tools for other assessments (e.g., biomarker assays) (Kremen et al., Reference Kremen, Jak, Panizzon, Spoon, Franz, Thompson and Lyons2014a; Sperling, Mormino, & Johnson, Reference Sperling, Mormino and Johnson2014; Vos & Duara, Reference Vos and Duara2019; Wang et al., Reference Wang, Coble, McDade, Hassenstab, Fagan and Benzinger2019). Genetic studies are highly relevant, as knowing which individuals are at high genetic risk for AD may allow for targeted interventions before the onset of more severe deficits. However, it is still unclear how AD genetic influences relate to cognitive performance, including cognitive changes across the critical transition period from midlife to older age. The current study sought to shed light on the cognitive correlates of AD genetic risk by examining how polygenic scores for AD predict cognitive performance – including both baseline levels and cognitive changes – across late midlife. As described below, although episodic memory is most characteristic of AD, we also examined executive function as it also associated with early AD-related declines.

In the past decade, genome-wide association studies (GWASs) have unlocked enormous potential for understanding AD biology (Bellenguez, Grenier-Boley, & Lambert, Reference Bellenguez, Grenier-Boley and Lambert2020; Kunkle et al., Reference Kunkle, Grenier-Boley, Sims, Bis, Damotte and Naj2019; Lambert et al., Reference Lambert, Ibrahim-Verbaas, Harold, Naj, Sims, Bellenguez and Amouyel2013), detecting individuals at high risk for AD, and understanding how AD genetic influences may affect cognition and health decades before the onset of AD. Researchers can leverage data from across the genome, including the 40 or more genes/loci the have already been linked to AD risk, to create polygenic risk scores that capture an individual’s relative genetic risk of AD compared to others in the sample (Choi, Mak, & O’Reilly, Reference Choi, Mak and O’Reilly2020; Logue et al., Reference Logue, Panizzon, Elman, Gillespie, Hatton, Gustavson and Kremen2019). Polygenic risk scores for AD (hereafter, AD-PRSs) have already shown promise in understanding early AD-related changes in preclinical samples, for example, by differentiating individuals with amnestic MCI in a sample of middle-aged adults (mean age 56) (Logue et al., Reference Logue, Panizzon, Elman, Gillespie, Hatton, Gustavson and Kremen2019). Beyond understanding how AD-PRSs relate to MCI diagnoses and cognitive impairments in midlife, it will also be important to quantify whether AD genetic risk can also predict cognitive changes across midlife in community-dwelling adults. Such findings would help elucidate whether and how much AD genetic influences contribute to individual differences in aging in the general population, may aid in identifying individuals at elevated risk for cognitive decline or dementia, and may highlight cognitive tests as potential screening tools for more invasive biomarker assays.

When investigating potential associations between AD-PRSs and cognitive change, it is necessary to consider the impact of the APOE gene, which is consistently the region of the genome most strongly associated with AD risk (Kunkle et al., Reference Kunkle, Grenier-Boley, Sims, Bis, Damotte and Naj2019; Lambert et al., Reference Lambert, Ibrahim-Verbaas, Harold, Naj, Sims, Bellenguez and Amouyel2013). Multiple studies have identified associations between APOE ϵ4 alleles and cognitive changes, such as change in general cognitive ability (Moray House test scores) between ages 11 and 80 years in data from the Lothian Birth Cohort (LBC) (Deary et al., Reference Deary, Whiteman, Pattie, Starr, Hayward, Wright and Whalley2002) and general cognitive ability trajectories across mid to late life in the Cognitive Ageing Genetics in England and Scotland (CAGES) cohorts and Swedish replication cohorts (Davies et al., Reference Davies, Harris, Reynolds, Payton, Knight, Liewald and Deary2014). Another study found that APOE genotype was associated with 6-year cognitive change in middle-aged to early old-aged participants for digit symbol substitution in African Americans and delayed word recall and digit symbol substitution in Caucasians (Blair et al., Reference Blair, Folsom, Knopman, Bray, Mosley and Boerwinkle2005). However, word fluency was not associated with APOE genotype in either group in this study (Blair et al., Reference Blair, Folsom, Knopman, Bray, Mosley and Boerwinkle2005), and in other work there were no associations between APOE genotype and cognitive change across short durations in midlife (e.g., 60–64 years) (Bunce et al., Reference Bunce, Bielak, Anstey, Cherbuin, Batterham and Easteal2014). Administration of multiple cognitive tests and utilization of latent variable approaches may help clarify these findings, as they can better capture cognitive ability within each timepoint and therefore improve estimates of change over time (Gustavson et al., Reference Gustavson, Elman, Sanderson-Cimino, Franz, Panizzon, Jak and Kremen2020b).

Episodic memory deficits are the most characteristic deficits in AD, and recent studies have demonstrated how individual differences in memory in cognitively normal (CN) individuals can provide strong prediction of later MCI (Rowe et al., Reference Rowe, Bourgeat, Ellis, Brown, Lim, Mulligan and Villemagne2013), even across midlife (Gustavson et al., Reference Gustavson, Elman, Panizzon, Franz, Zuber, Sanderson-Cimino and Kremen2020a, Reference Gustavson, Elman, Sanderson-Cimino, Franz, Panizzon, Jak and Kremen2020b). Episodic memory is therefore an excellent candidate to examine in relation to AD genetic risk across midlife. Beyond memory, we propose that executive functions are especially important in relation to AD-PRSs in middle age. Executive function deficits are prominent in the early stages of AD (Baudic et al., Reference Baudic, Dalla Barba, Thibaudet, Smagghe, Remy and Traykov2006; Greene, Hodges, & Baddeley, Reference Greene, Hodges and Baddeley1995; Kirova, Bays, & Lagalwar, Reference Kirova, Bays and Lagalwar2015; Lafleche & Albert, Reference Lafleche and Albert1995; Ramanan et al., Reference Ramanan, Bertoux, Flanagan, Irish, Piguet, Hodges and Hornberger2017) and in MCI (Aretouli & Brandt, Reference Aretouli and Brandt2010; Kochhann et al., Reference Kochhann, Pereira, Holz, Chaves and Fonseca2016; Nutter-Upham et al., Reference Nutter-Upham, Saykin, Rabin, Roth, Wishart, Pare and Flashman2008; Zhao, Guo, & Hong, Reference Zhao, Guo and Hong2013). Executive function abilities such as inhibition, task-set shifting, and working memory updating, are of substantial importance because they control other cognitive processes (Friedman & Miyake, Reference Friedman and Miyake2017; Miyake & Friedman, Reference Miyake and Friedman2012), and because their performance and associated brain regions are some of the first to exhibit decline in middle age (Bakkour, Morris, Wolk, & Dickerson, Reference Bakkour, Morris, Wolk and Dickerson2013; Buckner, Reference Buckner2004; Fjell et al., Reference Fjell, Westlye, Amlien, Espeseth, Reinvang, Raz and Walhovd2009). Indeed, classification of MCI based primarily on executive function deficits may predict progression from MCI to dementia even better than traditional memory-based MCI classifications (Junquera et al., Reference Junquera, Garcia-Zamora, Olazaran, Parra and Fernandez-Guinea2020). In summary, executive functions are sensitive to both normal aging and AD, and their changes across midlife may in part be driven by AD genetic risk factors that are influencing cognition when (or possibly even before) AD biomarkers such as amyloid and tau reach thresholds for positivity (Elman et al., Reference Elman, Panizzon, Gustavson, Franz, Sanderson-Cimino and Lyons2020).

In the current study, we evaluated the hypothesis that higher genetic risk for AD will be associated with cognitive changes in episodic memory and executive function from midlife to early old age. We tested this hypothesis in a well-characterized community sample of male twins from the Vietnam Era Twin Study of Aging (VETSA) who participated in extensive cognitive assessments, including seven memory and six executive function tests/subtests, at mean age of 56, 62, and/or 68 years and were CN at their first assessment. Importantly, all individuals were cognitively unimpaired at baseline. Using age-based longitudinal latent growth models, we evaluated how AD-PRSs were associated with (i) baseline episodic memory and executive function abilities and (ii) change in memory and executive function abilities across the 12-year assessment window. AD-PRSs were examined both including and excluding the APOE region.

MATERIAL AND METHODS

Participants

Data analyses were based on 1,168 individuals from VETSA who participated in at least one of three longitudinal VETSA assessments, were diagnosed as CN at their first assessment, and were of European descent (as PRS performance suffers when there is a discrepancy between the GWAS population ancestry and the cohort being scored) (Duncan et al., Reference Duncan, Shen, Gelaye, Meijsen, Ressler, Feldman and Domingue2019; Martin et al., Reference Martin, Gignoux, Walters, Wojcik, Neale, Gravel and Kenny2017). VETSA participants are male twins who served in the United States military at some point between 1965 and 1975 who were randomly recruited from a previous study of Vietnam Era Twin Registry participants (Tsuang, Bar, Harley, & Lyons, Reference Tsuang, Bar, Harley and Lyons2001). VETSA participants are generally representative of American males of their age group with respect to health and lifestyle (Schoenborn & Heyman, Reference Schoenborn and Heyman2009). Nearly 80% of individuals did not serve in combat or in Vietnam (Kremen et al., Reference Kremen, Panizzon, Xian, Barch, Franz, Grant and Lyons2011; Kremen et al., Reference Kremen, Thompson-Brenner, Leung, Grant, Franz, Eisen and Lyons2006) and rates of post-traumatic stress disorder and other psychiatric diagnoses are not elevated compared to other population studies (Gustavson et al., Reference Gustavson, Franz, Panizzon, Lyons and Kremen2019). All participants provided informed consent at each wave, all research was completed in accordance with the Helsinki Declaration, and the study was approved by local Institutional Review Boards at the University of California, San Diego, and Boston University.

Individuals with MCI at their first wave of assessment were excluded because we were primarily interested in whether AD-PRSs would be associated with cognitive change in individuals who were not already showing signs of impairment. VETSA MCI diagnoses use the Jak–Bondi approach requiring impairment on at least two tests within a given domain (>1.5 SD below the age- and education-adjusted normative means) (Bondi et al., Reference Bondi, Edmonds, Jak, Clark, Delano-Wood, McDonald and Salmon2014; Jak et al., Reference Jak, Bondi, Delano-Wood, Wierenga, Corey-Bloom, Salmon and Delis2009; Kremen et al., Reference Kremen, Jak, Panizzon, Spoon, Franz, Thompson and Lyons2014a) and also adjust for performance on a test of general cognitive ability that was taken at mean age 20 years. This adjustment ensures that MCI diagnoses capture a decline in function rather than long-standing low ability.

Figure 1 displays a flowchart of the subjects included in this analysis. Of the 1,291 individuals who completed the VETSA protocol at the first wave, 155 (12.0%) were diagnosed with MCI at wave 1 and 11 were missing MCI diagnosis (e.g., due to lack of covariates). At VETSA 2, an additional 193 attrition replacement subjects were recruited, 38 of which were excluded because they were diagnosed as MCI (i.e., at their first assessment) or were missing MCI diagnoses. 941 individuals returned at VETSA 3, who were combined with 339 subjects who were CN at their first assessment but did not return at VETSA 3, 104 attrition replacement subjects new to VETSA 3 and diagnosed CN, and 4 individuals who were missing MCI diagnoses from their first assessment in VETSA 1 but were diagnosed CN at VETSA 2. Finally, of these 1,388 individuals, our analyses focused on the subset of 1,168 individuals who were of European descent and were not missing genotype data (final N = 1,168) because PRSs must be evaluated in a subset of individuals from the same ancestral background as the reference GWAS (Duncan et al., Reference Duncan, Shen, Gelaye, Meijsen, Ressler, Feldman and Domingue2019; Martin et al., Reference Martin, Gignoux, Walters, Wojcik, Neale, Gravel and Kenny2017).

Fig. 1. Flowchart describing the sample. All subjects included in the final genetic sample were diagnosed cognitively normal at their first assessment and were of European ancestry (necessary for associations with AD-PRS). VETSA 2 was completed M = 5.70 years (SD = .69) after VETSA 1. VETSA 3 was completed M = 5.93 years after VETSA 2. VETSA = Vietnam Era Twin Study of Aging; CN = cognitively normal; MCI = mild cognitive impairment.

Episodic Memory Measures

Episodic memory was measured with the logical memory and visual reproductions subtests of the Wechsler Memory Scale–Third Edition (WMS-III) (Wechsler, Reference Wechsler1997) and the California Verbal Learning Test–Second Edition (CVLT-II) (Delis, Kramer, Kaplan, & Ober, Reference Delis, Kramer, Kaplan and Ober2000). For logical memory and visual reproductions, we examined both immediate recall and delayed recall measures. For the CVLT, we examined short delay free recall, long delay free recall, and the total number of words recalled across the five learning trials (i.e., the sum of all correct responses across learning trials 1 through 5). The hierarchical latent variable model of episodic memory employed in this study was based on earlier confirmatory factor analyses of VETSA 1 and 2 (Gustavson et al., Reference Gustavson, Elman, Sanderson-Cimino, Franz, Panizzon, Jak and Kremen2020b; Kremen et al., Reference Kremen, Panizzon, Franz, Spoon, Vuoksimaa, Jacobson and Lyons2014b; Panizzon et al., Reference Panizzon, Neale, Docherty, Franz, Jacobson, Toomey and Kremen2015) and includes three test-level latent factors (logical memory, visual reproductions, CVLT) and one higher-order episodic memory factory (which we focus on here).

Executive Function Measures

Executive function was measured with six tasks spanning prepotent response inhibition, task-set switching, and working memory span. Inhibition was assessed with the Stroop task (Golden & Freshwater, Reference Golden and Freshwater2002; Stroop, Reference Stroop1935). Shifting was assessed using two tasks from the Delis–Kaplan Executive Function System (D-KEFS) (D-KEFS; Delis, Kaplan, & Kramer, Reference Delis, Kaplan and Kramer2001): the Trail Making Test switching trial and the category-switching subtest for verbal fluency (both measures were adjusted for appropriate baseline conditions). Working memory span was assessed with the letter number sequencing and digit span subtests of the WMS-III (Wechsler, Reference Wechsler1997) and the reading span test (Daneman & Carpenter, Reference Daneman and Carpenter1980).

Our confirmatory model of executive function was also validated in waves 1 and 2 of VETSA (Gustavson et al., Reference Gustavson, Panizzon, Elman, Franz, Reynolds, Jacobson and Kremen2018a; Gustavson et al., Reference Gustavson, Panizzon, Franz, Friedman, Reynolds, Jacobson and Kremen2018b) and includes two latent factors: a common executive function latent factor (based on performance across all six tests) and a working memory-specific factor (based on additional variance in the three working memory span tests not already captured by the latent factor). The present analyses focus on the association between AD-PRSs and the common executive function factor. Latent growth models included the working memory-specific factor to avoid introducing bias in the estimation of common executive function; however only baseline levels of the working memory-specific factor were fit (i.e., intercept-only), as there was essentially no evidence for change variance in this factor in our earlier work (Gustavson et al., Reference Gustavson, Panizzon, Elman, Franz, Reynolds, Jacobson and Kremen2018a) or in preliminary analyses.

Alzheimer’s Disease Polygenic Scores

Genotyping

Genome-wide genotyping was conducted on individual dizygotic twin pairs and unpaired twins, and one randomly selected twin from each monozygotic twin pair (who are genetically identical to their co-twin). Samples were whole-genome amplified, fragmented, precipitated and resuspended prior to hybridization on Illumina HumanOmniExpress−24 v1.0A beadchips (Logue et al., Reference Logue, Panizzon, Elman, Gillespie, Hatton, Gustavson and Kremen2019). Beadchips were imaged using the Illumina iScan System and analyzed with Illumina GenomeStudio v2011.1 software containing Genotyping v1.9.4 module.

Cleaning and imputation

Cleaning and quality control were conducted using PLINK v1.9 (Chang et al., Reference Chang, Chow, Tellier, Vattikuti, Purcell and Lee2015). Single-nucleotide polymorphisms (SNPs) with >5% missing data or with Hardy–Weinberg equilibrium p-values < 10−6 were excluded prior to imputation. Relationships and zygosity were concordant with previously determined relationships derived from microsatellite markers and self-reported ancestry was confirmed using both SNPweights (Chen et al., Reference Chen, Pollack, Hunter, Hirschhorn, Kraft and Price2013) and principal components (PCs) analysis in PLINK in conjunction with 1000 Genomes Phase 3 reference data (1000 Genomes Project Consortium et al., Reference Auton, Brooks, Durbin, Garrison, Kang and Abecasis2015) (see Logue et al. (Reference Logue, Panizzon, Elman, Gillespie, Hatton, Gustavson and Kremen2019) for details). PCs used to adjust for any cryptic population substructure were calculated for the European-descent subjects using 100,000 randomly chosen common SNPs (minor allele frequency > .05) using PLINK. PCs were fit using only 1 twin per pair and then applied to the co-twins (Logue et al., Reference Logue, Panizzon, Elman, Gillespie, Hatton, Gustavson and Kremen2019). Imputation was performed using MiniMac (Fuchsberger, Abecasis, & Hinds, Reference Fuchsberger, Abecasis and Hinds2015; Howie et al., Reference Howie, Fuchsberger, Stephens, Marchini and Abecasis2012) computed at the Michigan Imputation Server. The 1000 genomes phase 3 European data were used as a haplotype reference panel. Imputation was performed using one randomly chosen participant per monozygotic (i.e., identical) twin pair, which was applied to their co-twin. In total, 1,329 European ancestry VETSA participants had genetic data, 1,168 of which are included here for passing the other inclusion criteria.

AD-PRS calculation

AD-PRSs were computed based on the Kunkle et al. (Reference Kunkle, Grenier-Boley, Sims, Bis, Damotte and Naj2019) scores using PLINK (Chang et al., Reference Chang, Chow, Tellier, Vattikuti, Purcell and Lee2015). Scores for each individual reflect a weighted average of the additive imputed SNP dosages with log-odds ratios (ORs) for each SNP estimated in the GWAS used as the weights. We excluded SNPs with minor allele frequency < 1%, SNPs with poor imputation quality (R 2 < .80), and strand ambiguous SNPs from AD-PRS. Remaining SNPs were trimmed for linkage disequilibrium using PLINK’s clumping procedure (r2 threshold of .1 in a 1000 kb window; 1000 Genomes Phase 3 European reference panel). AD-PRS were computed using the p < 5×10−8 threshold, as it has been recently argued that AD-PRS are most accurate when focusing on only the most significant SNPs (Zhang et al., Reference Zhang, Sidorenko, Couvy-Duchesne, Marioni, Wright, Goate and Visscher2020). The optimal threshold varied by sample in that study, but remained close to the typical genome-wide significance threshold of 5×10−8 for all samples, so we elected to use this cutoff. We calculated two versions of the AD-PRS, one with and one without APOE region variants (44,400,000 to 46,500,000 according to GRch37p13) to quantify the effect of the APOE isoform on our findings. AD-PRSs including the APOE region were based on 51 SNPs and AD-PRSs excluding the APOE region were based on 17 SNPs.

Additional AD-PRS calculations

We repeated our primary analyses with two additional methods of computing AD-PRSs. First, we recomputed AD-PRSs based on a p < .1 threshold. This threshold was recommended by Leonenko et al. (Reference Leonenko, Baker, Stevenson-Hoare, Sierksma, Fiers, Williams and Escott-Price2021) when AD-PRS are examined in combination with the APOE genotype. It also allows us to compare whether associations with cognitive decline may be stronger at more liberal thresholds, as others have observed (Kauppi et al., Reference Kauppi, Ronnlund, Nordin Adolfsson, Pudas and Adolfsson2020). These AD-PRSs were based on 50,608 SNPs (including APOE region SNPs) or 50,499 SNPs (excluding APOE region SNPs). Second, we recomputed AD-PRS (both with and without the APOE region) using SbayesR (GCTB v2.03; Lloyd-Jones et al., Reference Lloyd-Jones, Zeng, Sidorenko, Yengo, Moser, Kemper and Visscher2019), with the robust parameterization option. SbayesR is comparable with, or outperforms, other packages (e.g., LDpred2) that compute PRSs without a user-determined p-value threshold.

APOE genotyping

APOE genotyping was conducted earlier at the Puget Sound VA Healthcare System (see Lyons et al., Reference Lyons, Genderson, Grant, Logue, Zink, McKenzie and Kremen2013; Panizzon et al., Reference Panizzon, Hauger, Xian, Vuoksimaa, Spoon, Mendoza and Franz2014). The genotype was independently determined twice, and lab personnel were blind to the zygosity of the participant and genotype of their co-twin. As recommended by Leonenko et al. (Reference Leonenko, Baker, Stevenson-Hoare, Sierksma, Fiers, Williams and Escott-Price2021), analyses involving AD-PRSs without the APOE region included an APOE genotype covariate based on weighted effect sizes from the Kunkle et al. (Reference Kunkle, Grenier-Boley, Sims, Bis, Damotte and Naj2019) GWAS where each ϵ2 allele was scored −.47, each ϵ3 allele was scored .00, and each ϵ4 was scored 1.12.

DATA ANALYSIS

Prior to analyses, all cognitive scores at waves 2 and 3 were adjusted for practice effects, leveraging data from attrition replacement participants who completed the task battery for the first time at wave 2 or wave 3 to estimate the increase in performance expected in returnees who completed the tests two or more times (Elman et al., Reference Elman, Jak, Panizzon, Tu, Chen, Reynolds and Kremen2018).

Statistical analyses were conducted using Mplus version 8.3 (Muthén & Muthén, 1998-Reference Muthén and Muthén2017), which accounts for missing observations using full information maximum likelihood. Model fit was evaluated based on −2 log-likelihood (−2LL), Akaike’s Information Criteria, and Bayesian Information Criteria. Significance of individual parameter estimates were established with standard error-based 95% confidence intervals (CIs) and confirmed with χ2 difference tests by fixing that parameter to zero. Standard errors were adjusted for clustering within families (i.e., using a sandwich estimator), and the χ2 difference tests were appropriately scaled (Satorra & Bentler, Reference Satorra and Bentler2001).

The latent growth curve models of episodic memory and executive function were estimated using “type=complex random” and “algorithm=integration” in Mplus using maximum likelihood estimates and while accounting for the nested structure of twins within families. An example of the final model of episodic memory and AD-PRSs (without parameter estimates) is displayed in Figure 2 (see supplement Figures S1 and S2). Factor loadings on the intercept factors from individual cognitive latent variables were fixed to 1.0 at all waves. Factor loadings on the slope factor were based on the age of each participants at that wave of assessment (scaled in decades). Factor loadings of individual tasks on latent executive function and memory variables were equated across waves and means for individual tasks were also fixed across wave (i.e., assuming scalar invariance). This assumption was evaluated using a set of confirmatory factor models for which we could obtain objective fit statistics, such as the Comparative Fit Index (CFI), Tucker-Lewis Index (TLI), and Root Mean Square Error of Approximation (RMSEA) (e.g., a latent variable model of Common Executive Function at wave 1, wave 2, and wave 3 with correlations between latent factors instead of latent growth intercept/slope factors). Scalar invariance models had good overall model fit (CFI = .977, TLI= .972, RMSEA = .040 for memory; CFI = .975, TLI = .969, RMSEA = .029 for executive function) despite fitting significantly worse than the metric invariance models (χ 2(12) = 222.57, p < .001 for memory; χ 2(12) = 222.57, p < .001 for executive function). Additionally, we equated residual variances on latent memory and executive function factors across waves (to identify the model).

Fig. 2. Path model of the latent growth model of episodic memory with Alzheimer’s disease polygenic risk scores (AD-PRSs). Factor loadings with a “1” indicate loadings were fixed to 1. Loadings with a “*” indicates they were equated across time (e.g., the path from CVLT to Memory Wave 1 was the same as the corresponding path on Memory Wave 2 and Wave 3). Factor loadings on the slope factor represent each individual’s age at that assessment (centered on the mean age at wave 1 and scaled based in decades). At the top of the model, AD-PRS and the intercept and (linear) slope factors are regressed on the first 3 ancestry-based principal components (PCs). Intercept and slope factors were also regressed on APOE ϵ4 status (i.e., a dichotomous variable capturing the presence of an ϵ4 allele) only when AD-PRSs excluded the APOE region. At the bottom of the model, residual correlations between memory tests across waves were included for all tests, but these are displayed for Logical Memory (immediate recall) only for simplicity. Means for each test were also equated across wave and means for intercept and slope factors were estimated but not displayed here. CVLT = California Verbal Learning Task; I = immediate recall; D = delayed recall; L = learning trials.

Based on our earlier confirmatory factor analyses and preliminary analyses, latent growth models needed to include residual correlations among all individual tasks (e.g., wave 1 Stroop with wave 2 Stroop, etc.) to capture the fact that these measures are correlated across time over-and-above the variance captured by the latent variables. Moreover, preliminary analyses in the model of executive function indicated that there was essentially no change variance in the working memory-specific factor (e.g., separate correlated latent factor models revealed correlations near 1.0 between working memory-specific factors across wave), justifying our intercept-only model for working memory-specific variance. This also greatly reduced the number of integration points in the latent growth curve model.

AD-PRSs were included in cognitive latent growth curve models by correlating these scores with both intercept and slope factors (see Figure 2). Two models were run for each cognitive domain: one where AD-PRSs include loci in the APOE region and another where AD-PRSs exclude loci in the APOE region. In all models, we controlled for ancestry by regressing the first 3 ancestry PCs on AD-PRSs and cognitive intercept and slope latent factors. In the model where AD-PRSs excluded APOE loci, we also regressed the APOE genotype score on the cognitive intercept and slope factors.

RESULTS

Descriptive Statistics

Demographic characteristics of the sample are displayed in Table 1. Descriptive statistics for individual cognitive tasks are displayed in the supplement (Table S1).

Table 1. Demographic characteristics of the study

Note: All individuals were of European ancestry.

Latent Growth Models of Executive Function and Episodic Memory

Unstandardized results from latent growth models of episodic memory and executive function (including their association with AD-PRSs) are displayed in the supplement (Figures S1 and S2). Variances of the intercept (i.e., baseline memory performance) and slope (i.e., memory change) factors indicate that change variance in memory across 1 decade (.05) was about 19% as large as the variance in baseline memory ability (.24). Change variance in executive function across 1 decade (.07) was 43% as large as the variance in baseline ability (.17). Intercept and slope variables were not correlated for either ability, suggesting that individuals with relatively poorer cognition at baseline were not more likely to improve or decline in that respective ability compared to those who performed better at baseline, or vice versa. Factor loadings on all latent factors were similar to estimates from our earlier work on this sample at waves 1 and 2 (Gustavson et al., Reference Gustavson, Panizzon, Elman, Franz, Reynolds, Jacobson and Kremen2018a; Gustavson et al., Reference Gustavson, Panizzon, Franz, Friedman, Reynolds, Jacobson and Kremen2018b).

Associations Between Cognition and Alzheimer’s Disease Polygenic Scores

Our primary study hypothesis concerning associations between cognitive change and AD genetic risk were conducted by examining correlations between AD-PRSs and the intercept and slope factors from the cognitive latent growth models. Standardized results are displayed in Table 2, which depict correlations between AD-PRSs and cognitive intercept and slope factors (after adjusting for ancestry-based PCs). All model estimates (and standard errors) are displayed in the supplement (Tables S2 and S3).

Table 2. Associations between Alzheimer’s disease polygenic scores (AD-PRS) and cognitive change across midlife

Note: Associations between AD-PRSs with (A) episodic memory and (B) executive function intercept (baseline) and change (slope) latent factors. AD-PRSs were based on Kunkle et al. (Reference Kunkle, Grenier-Boley, Sims, Bis, Damotte and Naj2019), p < 5×108 threshold. Models were run separately for executive function and memory, and separately for AD-PRS including the APOE region (Model 1) or excluding the APOE region (Model 2). All models adusted for the ancestry by regressing the first 3 ancestry-based principal components on AD-PRS and cognitive intercept/slope latent factors. Model 2 also regressed cognitive intercept and slope factors on APOE genotype (i.e., a score of −.47 per ϵ2 allele, .00 per ϵ3 allele, and 1.12 per ϵ4 allele; rightmost columns). Significant associations are displayed in bold (95% CIs do not overlap 0 and p < .05).

AD-PRSs were associated with change in episodic memory such that high genetic risk for AD was associated with a steeper rate of decline in memory, r = −.19, 95% CI [−.35, −.03]. A similar association was observed for executive function, r = −.27, 95% CI [−.49, −.05]. AD-PRSs were also weakly associated with the intercept factor for executive function, r = .11, 95% CI [.00, .21], such that individuals with better executive function at baseline had slightly higher AD-PRS.

After removing the APOE region variants from AD-PRSs, the associations with memory and executive function slopes were smaller and nonsignificant, yet were within the 95% CIs of the original estimates. The APOE genotype was associated with executive function slopes, β = −.22, 95% CI [.00, .21], suggesting the previous association with AD-PRS was driven by APOE. The association between AD-PRSs and cognitive intercept factors were all nonsignificant after excluding APOE.

Comparison of Alternate AD-PRS Calculations

Analyses were repeated using AD-PRS recomputed from (a) the p < .1 threshold and (b) using SbayesR. Results are displayed in Table 3. Results were similar to our primary results, with two small differences. First, the weak positive correlation between AD-PRS and executive function intercept (in the model including APOE) was nonsignificant with both approaches. This correlation was unexpected to begin with, so we do not discuss it further.

Table 3. Sensitivity analyses using different methods for computing Alzheimer’s Disease polygenic scores (AD-PRS)

Note: Associations between AD-PRSs with episodic memory and executive function intercept (baseline) and change (slope) latent factors using different methods for computing AD-PRS: (A) p < .1 threshold and (B) using SbayesR software (with the robost option), instead of the p < 5×108 threshold from Table 2. Models were run separately for executive function and memory, and separately for AD-PRS including the APOE region (Model 1) or excluding the APOE region (Model 2). All models adusted for the ancestry by regressing the first 3 ancestry-based principal components on AD-PRS and cognitive intercept/slope latent factors. Model 2 also regressed cognitive intercept and slope factors on APOE genotype. Significant associations are displayed in bold (95% CIs do not overlap 0 and p < .05).

Second, using SbayesR only, AD-PRSs excluding APOE were now significantly associated with memory slopes, r = −.14, 95% CI [−.28, .00], providing some evidence that non-APOE loci are related to memory slopes. AD-PRS generated with SbayesR correlated strongly with our original scores based on the p < 5×10−8 threshold (r = .77 including APOE, r = .48 excluding APOE) and moderately with the p < .1 threshold (r = .30 including APOE, r = .46 excluding APOE).

DISCUSSION

This study provides evidence that AD genetic risk predicts changes in episodic memory and executive function across midlife into early old age (between age 56 and 68 years). Although episodic memory is the most characteristic AD cognitive impairment, executive functions may be especially relevant to early AD pathology as they are some of the first cognitive abilities to exhibit age-related changes in midlife. Although there was relatively modest variability in cognitive change across this 12-year interval in late midlife to early old age (especially for memory), individuals at higher genetic risk were more likely to decline in both domains.

When APOE loci were removed, the AD-PRSs were no longer associated with cognitive slope factors in memory or executive function, though there was some evidence for an association with memory using the SbayesR method only. For memory, these findings suggest our results for the full AD-PRS were driven by both APOE and non-APOE loci that generally did not reach significance alone (but were significant when combined into the full AD-PRS). These findings align with an earlier study of Health and Retirement Study participants which included midlife (and older) adults and demonstrated that AD-PRSs were associated with memory decline only when including APOE loci (Marden et al., Reference Marden, Mayeda, Walter, Vivot, Tchetgen Tchetgen, Kawachi and Glymour2016). In contrast, executive function slopes were significantly correlated with APOE genotype (β = −.22), suggesting their association with AD-PRS were generally driven by APOE. Of course, some non-APOE loci may still be relevant to executive function change (e.g., as evidenced by the weak r = −.06 association with AD-PRS excluding APOE), but these effects appear smaller than the contribution of APOE genotype.

Compared to our primary results using the p < 5×10−8 threshold recommended by Zhang et al. (Reference Zhang, Sidorenko, Couvy-Duchesne, Marioni, Wright, Goate and Visscher2020), results using the more liberal threshold of p < .1, and using SbayesR, revealed similar associations. Recent work has suggested that AD-PRS are more strongly predictive of cognitive decline with more liberal thresholds (Kauppi et al., Reference Kauppi, Ronnlund, Nordin Adolfsson, Pudas and Adolfsson2020), but the choice of threshold did not appear to have a strong effect in our sample. However, this earlier study focused on individuals who were subsequently healthy whereas our study included individuals who were CN or MCI at the final timepoint (all individuals were CN at baseline). We did not re-analyze data excluding MCI cases at the final timepoint because we already observed little variance in cognitive change (especially memory change), but it will be interesting to examine how MCI status and p-value thresholds impact associations between AD-PRS and cognition in larger studies (that can more precisely estimate change).

It will be important for future work to examine how AD biomarkers such as amyloid beta are relevant to these findings. On one hand, biomarkers may mediate the associations observed here if genetic risk for AD is associated with pathological biomarker accumulation across middle age, which in turn affects cognitive change. Alternatively (or additionally), there is evidence that cognitive performance changes can also predict later amyloid beta accumulation (Elman et al., Reference Elman, Panizzon, Gustavson, Franz, Sanderson-Cimino and Lyons2020). Although we cannot be certain, it is likely that few participants were biomarker positive at baseline in the current study (age 51–60). AD genetic influences may therefore somewhat independently affect cognition and AD biomarkers (i.e., pleiotropic genetic effects) (Bellou, Stevenson-Hoare, & Escott-Price, Reference Bellou, Stevenson-Hoare and Escott-Price2020), and the time course of observable changes in both cognition and biomarker load may vary in different individuals. Better understanding how AD genetic risk factors relate to cognitive and biomarker phenotypes across midlife will help us understand how these factors influence each other early in the AD trajectory.

Strengths and Limitations

We leveraged data from 3 longitudinal assessments across the critical transition period from middle age to older age to examine how baseline and change variance in episodic memory and executive function relate to AD genetic influences. Latent growth curve models were based on 7 memory tests and 6 executive function tests to more accurately quantify cognitive changes leading into old age. Latent variable approaches are advantageous in this work, especially for executive function, as executive function tasks do not load strongly on their respective latent factors and the common variance across multiple executive function subdomains (inhibition, shifting, updating) appears most relevant to clinical traits (Miyake & Friedman, Reference Miyake and Friedman2012). However, even utilizing this approach, we were not able to estimate both linear and quadratic components of cognitive change in our latent growth models as this requires additional timepoints of data.

Relatedly, it will be important to quantify the extent to which associations between AD genetic risk and memory and executive function are explained by variance shared across both domains versus domain-specific cognitive change. Meta-analytic estimates suggests that an average of 60% of the variance in cognitive change is shared across cognitive abilities (Tucker-Drob, Brandmaier, & Lindenberger, Reference Tucker-Drob, Brandmaier and Lindenberger2019), with even stronger ratios in older adults. Therefore, the associations with AD-PRS described here likely reflect at least some shared variance in change across both domains. Again, however, given the relatively small variance in change observed at the latent variable level here (especially for memory), it will require a large sample to estimate domain-general vs. domain-specific components and their association with AD genetic influences. More broadly, it is necessary to examine PRS only in individuals whose ancestry matches the original GWAS (Martin et al., Reference Martin, Gignoux, Walters, Wojcik, Neale, Gravel and Kenny2017). Therefore, we restricted our attention to the European-descent subset of VETSA, which make up the majority of the cohort. Additionally, our sample only includes men, so it will be important to examine whether these findings generalize to other populations and to women.

This study extends our previous investigation that demonstrated AD-PRSs differentiated individuals with amnestic MCI from CN individuals at the first wave (mean age 56) (Logue et al., Reference Logue, Panizzon, Elman, Gillespie, Hatton, Gustavson and Kremen2019). In the present study, all individuals with MCI at their baseline assessment were excluded from analyses, so it is not surprising that AD-PRSs were not associated with baseline memory ability (i.e., intercept). Executive function intercept was associated with slightly higher AD-PRS scores in some but not all analyses. This association may have been spurious, or perhaps driven by the excluding of impaired individuals at baseline. The present study complements the earlier studies by demonstrating that AD-PRSs also predict changes in cognitive ability in a group of CN individuals from a community-dwelling sample.

CONCLUDING REMARKS

GWAS data allow researchers to examine the impacts of genetic influences on disease decades before onset. We used data from a large longitudinal dataset with comprehensive measures of cognition to demonstrate that AD genetic influences are moderately associated with cognitive changes between middle age to early old age in individuals who were all CN at their first assessment. Considerable correlations between AD-PRSs and executive functions highlight their importance in understanding early AD-related cognitive changes. Executive function abilities control other cognitive processes and they are some of the first to exhibit age-related decline in middle age. These findings are some of the first to link these cognitive changes in executive function to AD genetic risk factors and suggest they should be examined more systematically in predictive studies of early AD pathology.

Supplementary material

For supplementary material accompanying this paper visit https://doi.org/10.1017/S1355617722000108

Acknowledgments

Numerous organizations have provided invaluable assistance in the conduct of the VET Registry, including: Department of Defense; National Personnel Records Center, National Archives and Records Administration; Internal Revenue Service; National Opinion Research Center; National Research Council, National Academy of Sciences; the Institute for Survey Research, Temple University. This material was, in part, the result of work supported with resources of the VA San Diego Center of Excellence for Stress and Mental Health Healthcare System. Most importantly, the authors gratefully acknowledge the continued cooperation and participation of the members of the VET Registry and their families as well as the contributions of many staff members and students.

Financial Support

This research was supported by Grants R03 AG065643, R01 AG050595, and R01 AG022381, K01 AG063805, R01 AG060470, R01 AG059329, and K24 AG046373 from the National Institutes of Health. The content of this manuscript is solely the responsibility of the authors and does not necessarily represent the official views of the National Institute on Aging/National Institute of Health, or the VA. The U.S. Department of Veterans Affairs has provided financial support for the development and maintenance of the Vietnam Era Twin (VET) Registry.

Conflicts of Interest

The authors have nothing to disclose.

References

REFERENCES

1000 Genomes Project Consortium, Auton, A., Brooks, L. D., Durbin, R. M., Garrison, E. P., Kang, H. M., … Abecasis, G. R. (2015). A global reference for human genetic variation. Nature, 526, 6874. doi: 10.1038/nature15393 Google ScholarPubMed
Aizenstein, H. J., Nebes, R. D., Saxton, J. A., Price, J. C., Mathis, C. A., Tsopelas, N. D., … Klunk, W. E. (2008). Frequent amyloid deposition without significant cognitive impairment among the elderly. Archives of Neurology, 65, 15091517. doi: 10.1001/archneur.65.11.1509 CrossRefGoogle ScholarPubMed
Aretouli, E. & Brandt, J. (2010). Everyday functioning in mild cognitive impairment and its relationship with executive cognition. International Journal of Geriatric Psychiatry, 25, 224233. doi: 10.1002/gps.2325 CrossRefGoogle ScholarPubMed
Bakkour, A., Morris, J. C., Wolk, D. A., & Dickerson, B. C. (2013). The effects of aging and Alzheimer’s disease on cerebral cortical anatomy: Specificity and differential relationships with cognition. Neuroimage, 76, 332-–344. doi: 10.1016/j.neuroimage.2013.02.059 CrossRefGoogle ScholarPubMed
Bateman, R. J., Xiong, C., Benzinger, T. L., Fagan, A. M., Goate, A., Fox, N. C., … Dominantly Inherited Alzheimer, N. (2012). Clinical and biomarker changes in dominantly inherited Alzheimer’s disease. New England Journal of Medicine, 367, 795804. doi: 10.1056/NEJMoa1202753 CrossRefGoogle ScholarPubMed
Baudic, S., Dalla Barba, G., Thibaudet, M. C., Smagghe, A., Remy, P., & Traykov, L. (2006). Executive function deficits in early Alzheimer’s disease and their relations with episodic memory. Archives of Clinical Neuropsychology, 21, 1521. doi: 10.1016/j.acn.2005.07.002 CrossRefGoogle ScholarPubMed
Bellenguez, C., Grenier-Boley, B., & Lambert, J. C. (2020). Genetics of Alzheimer’s disease: Where we are, and where we are going. Current Opinion in Neurobiology, 61, 4048. doi: 10.1016/j.conb.2019.11.024 CrossRefGoogle ScholarPubMed
Bellou, E., Stevenson-Hoare, J., & Escott-Price, V. (2020). Polygenic risk and pleiotropy in neurodegenerative diseases. Neurobiology of Disease, 142, 104953. doi: 10.1016/j.nbd.2020.104953 CrossRefGoogle ScholarPubMed
Bennett, D. A., Schneider, J. A., Arvanitakis, Z., Kelly, J. F., Aggarwal, N. T., Shah, R. C., & Wilson, R. S. (2006). Neuropathology of older persons without cognitive impairment from two community-based studies. Neurology, 66, 18371844. doi: 10.1212/01.wnl.0000219668.47116.e6 CrossRefGoogle ScholarPubMed
Blair, C. K., Folsom, A. R., Knopman, D. S., Bray, M. S., Mosley, T. H., Boerwinkle, E., & Atherosclerosis Risk in Communities Study, I. (2005). APOE genotype and cognitive decline in a middle-aged cohort. Neurology, 64, 268276. doi: 10.1212/01.WNL.0000149643.91367.8A CrossRefGoogle Scholar
Bondi, M. W., Edmonds, E. C., Jak, A. J., Clark, L. R., Delano-Wood, L., McDonald, C. R., … Salmon, D. P. (2014). Neuropsychological criteria for mild cognitive impairment improves diagnostic precision, biomarker associations, and progression rates. Journal of Alzheimer’s Disease, 42, 275289. doi: 10.3233/JAD-140276 CrossRefGoogle ScholarPubMed
Buckner, R. L. (2004). Memory and executive function in aging and AD: Multiple factors that cause decline and reserve factors that compensate. Neuron, 44, 195208. doi: 10.1016/j.neuron.2004.09.006 CrossRefGoogle Scholar
Bunce, D., Bielak, A. A., Anstey, K. J., Cherbuin, N., Batterham, P. J., & Easteal, S. (2014). APOE genotype and cognitive change in young, middle-aged, and older adults living in the community. Journals of Gerontology Series A: Biomedical Sciences and Medical Sciences, 69, 379386. doi: 10.1093/gerona/glt103 CrossRefGoogle ScholarPubMed
Chang, C. C., Chow, C. C., Tellier, L. C., Vattikuti, S., Purcell, S. M., & Lee, J. J. (2015). Second-generation PLINK: Rising to the challenge of larger and richer datasets. Gigascience, 4, 7. doi: 10.1186/s13742-015-0047-8 CrossRefGoogle Scholar
Chen, C. Y., Pollack, S., Hunter, D. J., Hirschhorn, J. N., Kraft, P., & Price, A. L. (2013). Improved ancestry inference using weights from external reference panels. Bioinformatics, 29, 13991406. doi: 10.1093/bioinformatics/btt144 CrossRefGoogle ScholarPubMed
Choi, S. W., Mak, T. S., & O’Reilly, P. F. (2020). Tutorial: A guide to performing polygenic risk score analyses. Nature Protocols, 15, 27592772. doi: 10.1038/s41596-020-0353-1 CrossRefGoogle ScholarPubMed
Daneman, M. & Carpenter, P. A. (1980). Individual differences in working memory and reading. Journal of Verbal Learning and Verbal Behavior, 19, 450466. doi: 10.1016/S0022-5371(80)90312-6 CrossRefGoogle Scholar
Davies, G., Harris, S. E., Reynolds, C. A., Payton, A., Knight, H. M., Liewald, D. C., … Deary, I. J. (2014). A genome-wide association study implicates the APOE locus in nonpathological cognitive ageing. Molecular Psychiatry, 19, 7687. doi: 10.1038/mp.2012.159 CrossRefGoogle ScholarPubMed
Deary, I. J., Whiteman, M. C., Pattie, A., Starr, J. M., Hayward, C., Wright, A. F., … Whalley, L. J. (2002). Cognitive change and the APOE epsilon 4 allele. Nature, 418, 932. doi: 10.1038/418932a CrossRefGoogle ScholarPubMed
Delis, D. C., Kaplan, E., & Kramer, J. H. (2001). Delis-Kaplan executive function system (D-KEFS). San Antonio, TX: Psychological Corporation.Google Scholar
Delis, D. C., Kramer, J. H., Kaplan, E., & Ober, B. A. (2000). California verbal learning test (CVLT-2). 2nd ed. San Antonio, TX: Psychological Corporation.Google Scholar
Duncan, L., Shen, H., Gelaye, B., Meijsen, J., Ressler, K., Feldman, M., … Domingue, B. (2019). Analysis of polygenic risk score usage and performance in diverse human populations. Nature Communications, 10, 3328. doi: 10.1038/s41467-019-11112-0 CrossRefGoogle ScholarPubMed
Elman, J. A., Jak, A. J., Panizzon, M. S., Tu, X. M., Chen, T., Reynolds, C. A., … Kremen, W. S. (2018). Underdiagnosis of mild cognitive impairment: A consequence of ignoring practice effects. Alzheimer’s & Dementia: Diagnosis, Assessment & Disease Monitoring, 10, 372381. doi: 10.1016/j.dadm.2018.04.003 Google ScholarPubMed
Elman, J. A., Panizzon, M. S., Gustavson, D. E., Franz, C. E., Sanderson-Cimino, M. E., Lyons, M. J., … Initiative, A. s. D. N. (2020). Amyloid-beta positivity predicts cognitive decline but cognition predicts progression to amyloid-beta positivity. Biological Psychiatry. doi: 10.1016/j.biopsych.2019.12.021 CrossRefGoogle Scholar
Fjell, A. M., Westlye, L. T., Amlien, I., Espeseth, T., Reinvang, I., Raz, N., … Walhovd, K. B. (2009). High consistency of regional cortical thinning in aging across multiple samples. Cerebral Cortex, 19, 20012012. doi: 10.1093/cercor/bhn232 CrossRefGoogle ScholarPubMed
Friedman, N. P. & Miyake, A. (2017). Unity and diversity of executive functions: Individual differences as a window on cognitive structure. Cortex, 86, 186204. doi: 10.1016/j.cortex.2016.04.023 CrossRefGoogle ScholarPubMed
Fuchsberger, C., Abecasis, G. R., & Hinds, D. A. (2015). minimac2: Faster genotype imputation. Bioinformatics, 31, 782784. doi: 10.1093/bioinformatics/btu704 CrossRefGoogle ScholarPubMed
Golden, C. J. & Freshwater, S. M. (2002). The Stroop color and word test: A manual for clinical and experimental uses [adult version]. Stoelting.Google Scholar
Greene, J. D., Hodges, J. R., & Baddeley, A. D. (1995). Autobiographical memory and executive function in early dementia of Alzheimer type. Neuropsychologia, 33, 16471670. doi: 10.1016/0028-3932(95)00046-1 CrossRefGoogle ScholarPubMed
Gustavson, D. E., Elman, J. A., Panizzon, M. S., Franz, C. E., Zuber, J., Sanderson-Cimino, M., … Kremen, W. S. (2020a). Association of baseline semantic fluency and progression to mild cognitive impairment in middle-aged men. Neurology, 95, e973e983. doi: 10.1212/WNL.0000000000010130 CrossRefGoogle ScholarPubMed
Gustavson, D. E., Elman, J. A., Sanderson-Cimino, M., Franz, C. E., Panizzon, M. S., Jak, A. J., … Kremen, W. S. (2020b). Extensive memory testing improves prediction of progression to MCI in late middle age. Alzheimer’s & Dementia: Diagnosis, Assessment & Disease Monitoring, 12, e12004. doi: 10.1002/dad2.12004 Google ScholarPubMed
Gustavson, D. E., Franz, C. E., Panizzon, M. S., Lyons, M. J., & Kremen, W. S. (2019). Internalizing and externalizing psychopathology in middle age: Genetic and environmental architecture and stability of symptoms over 15 to 20 years. Psychological Medicine, 19. doi: 10.1017/S0033291719001533 Google ScholarPubMed
Gustavson, D. E., Panizzon, M. S., Elman, J. A., Franz, C. E., Reynolds, C. A., Jacobson, K. C., … Kremen, W. S. (2018). Stability of genetic and environmental influences on executive functions in midlife. Psychology and Aging, 33, 219231. doi: 10.1037/pag0000230 CrossRefGoogle ScholarPubMed
Gustavson, D. E., Panizzon, M. S., Franz, C. E., Friedman, N. P., Reynolds, C. A., Jacobson, K. C., … Kremen, W. S. (2018). Genetic and environmental architecture of executive functions in midlife. Neuropsychology, 32, 1830. doi: 10.1037/neu0000389 CrossRefGoogle ScholarPubMed
Howie, B., Fuchsberger, C., Stephens, M., Marchini, J., & Abecasis, G. R. (2012). Fast and accurate genotype imputation in genome-wide association studies through pre-phasing. Nature Genetics, 44, 955. doi: 10.1038/ng.2354 CrossRefGoogle ScholarPubMed
Jak, A. J., Bondi, M. W., Delano-Wood, L., Wierenga, C., Corey-Bloom, J., Salmon, D. P., & Delis, D. C. (2009). Quantification of five neuropsychological approaches to defining mild cognitive impairment. The American Journal of Geriatric Psychiatry, 17, 368375. doi: 10.1097/JGP.0b013e31819431d5 CrossRefGoogle ScholarPubMed
Junquera, A., Garcia-Zamora, E., Olazaran, J., Parra, M. A., & Fernandez-Guinea, S. (2020). Role of executive functions in the conversion from mild cognitive impairment to dementia. Journal of Alzheimer’s Disease, 77, 641653. doi: 10.3233/JAD-200586 CrossRefGoogle Scholar
Kauppi, K., Ronnlund, M., Nordin Adolfsson, A., Pudas, S., & Adolfsson, R. (2020). Effects of polygenic risk for Alzheimer’s disease on rate of cognitive decline in normal aging. Translational Psychiatry, 10, 250. doi: 10.1038/s41398-020-00934-y CrossRefGoogle ScholarPubMed
Kirova, A. M., Bays, R. B., & Lagalwar, S. (2015). Working memory and executive function decline across normal aging, mild cognitive impairment, and Alzheimer’s disease. BioMed Research International, 2015, 748212. doi: 10.1155/2015/748212 CrossRefGoogle ScholarPubMed
Kochhann, R., Pereira, A. H., Holz, M. R., Chaves, M. L., & Fonseca, R. P. (2016). Deficits in unconstrained, phonemic and semantic verbal fluency in healthy elders, mild cognitive impairment, and mild Alzheimer’s disease patients. Alzheimer’s & Dementia, 12, P751P752.CrossRefGoogle Scholar
Kremen, W. S., Jak, A. J., Panizzon, M. S., Spoon, K. M., Franz, C. E., Thompson, W. K., … Lyons, M. J. (2014a). Early identification and heritability of mild cognitive impairment. International Journal of Epidemiology, 43, 600610. doi: 10.1093/ije/dyt242 CrossRefGoogle ScholarPubMed
Kremen, W. S., Panizzon, M. S., Franz, C. E., Spoon, K. M., Vuoksimaa, E., Jacobson, K. C., … Lyons, M. J. (2014b). Genetic complexity of episodic memory: A twin approach to studies of aging. Psychology and Aging, 29, 404417. doi: 10.1037/a0035962 CrossRefGoogle ScholarPubMed
Kremen, W. S., Panizzon, M. S., Xian, H., Barch, D. M., Franz, C. E., Grant, M. D., … Lyons, M. J. (2011). Genetic architecture of context processing in late middle age: More than one underlying mechanism. Psychology and Aging, 26, 852863. doi: 10.1037/a0025098 CrossRefGoogle ScholarPubMed
Kremen, W. S., Thompson-Brenner, H., Leung, Y. M., Grant, M. D., Franz, C. E., Eisen, S. A., … Lyons, M. J. (2006). Genes, environment, and time: The Vietnam Era Twin Study of Aging (VETSA). Twin Research and Human Genetics, 9, 10091022. doi: 10.1375/183242706779462750 CrossRefGoogle ScholarPubMed
Kunkle, B. W., Grenier-Boley, B., Sims, R., Bis, J. C., Damotte, V., Naj, A. C., … Environmental Risk for Alzheimer’s Disease, C. (2019). Genetic meta-analysis of diagnosed Alzheimer’s disease identifies new risk loci and implicates Abeta, tau, immunity and lipid processing. Nature Genetics, 51, 414430. doi: 10.1038/s41588-019-0358-2 CrossRefGoogle ScholarPubMed
Lafleche, G., & Albert, M. S. (1995). Executive function deficits in mild Alzheimer’s disease. Neuropsychology, 9, 313320. doi: 10.1037/0894-4105.9.3.313 CrossRefGoogle Scholar
Lambert, J. C., Ibrahim-Verbaas, C. A., Harold, D., Naj, A. C., Sims, R., Bellenguez, C., … Amouyel, P. (2013). Meta-analysis of 74,046 individuals identifies 11 new susceptibility loci for Alzheimer’s disease. Nature Genetics, 45, 14521458. doi: 10.1038/ng.2802 CrossRefGoogle ScholarPubMed
Leonenko, G., Baker, E., Stevenson-Hoare, J., Sierksma, A., Fiers, M., Williams, J., … Escott-Price, V. (2021). Identifying individuals with high risk of Alzheimer’s disease using polygenic risk scores. Nature Communications, 12, 110. doi: 10.1038/s41467-021-24082-z CrossRefGoogle ScholarPubMed
Lloyd-Jones, L. R., Zeng, J., Sidorenko, J., Yengo, L., Moser, G., Kemper, K. E., … Visscher, P. M. (2019). Improved polygenic prediction by Bayesian multiple regression on summary statistics. Nature Communications, 10, 5086. doi: 10.1038/s41467-019-12653-0 CrossRefGoogle ScholarPubMed
Logue, M. W., Panizzon, M. S., Elman, J. A., Gillespie, N. A., Hatton, S. N., Gustavson, D. E., … Kremen, W. S. (2019). Use of an Alzheimer’s disease polygenic risk score to identify mild cognitive impairment in adults in their 50s. Molecular Psychiatry, 24, 421430. doi: 10.1038/s41380-018-0030-8 CrossRefGoogle ScholarPubMed
Lyons, M. J., Genderson, M., Grant, M. D., Logue, M., Zink, T., McKenzie, R., … Kremen, W. S. (2013). Gene-environment interaction of ApoE genotype and combat exposure on PTSD. American Journal of Medical Genetics Part B: Neuropsychiatric Genetics, 162B, 762769. doi: 10.1002/ajmg.b.32154 CrossRefGoogle ScholarPubMed
Marden, J. R., Mayeda, E. R., Walter, S., Vivot, A., Tchetgen Tchetgen, E. J., Kawachi, I., & Glymour, M. M. (2016). Using an Alzheimer Disease polygenic risk score to predict memory decline in black and white Americans over 14 years of follow-up. Alzheimer Disease and Associated Disorders, 30, 195202. doi: 10.1097/WAD.0000000000000137 CrossRefGoogle ScholarPubMed
Martin, A. R., Gignoux, C. R., Walters, R. K., Wojcik, G. L., Neale, B. M., Gravel, S., … Kenny, E. E. (2017). Human demographic history impacts genetic risk prediction across diverse populations. American Journal of Human Genetics, 100, 635649. doi: 10.1016/j.ajhg.2017.03.004 CrossRefGoogle ScholarPubMed
Miyake, A. & Friedman, N. P. (2012). The nature and organization of individual differences in executive functions: Four general conclusions. Current Directions in Psychological Science, 21, 814. doi: 10.1177/0963721411429458 CrossRefGoogle ScholarPubMed
Muthén, L. K. & Muthén, B. O. (1998–2017). Mplus user’s guide: Eighth edition. Los Angeles, CA: Muthén & Muthén.Google Scholar
Nutter-Upham, K. E., Saykin, A. J., Rabin, L. A., Roth, R. M., Wishart, H. A., Pare, N., & Flashman, L. A. (2008). Verbal fluency performance in amnestic MCI and older adults with cognitive complaints. Archives of Clinical Neuropsychology, 23, 229241. doi: 10.1016/j.acn.2008.01.005 CrossRefGoogle ScholarPubMed
Panizzon, M. S., Hauger, R., Xian, H., Vuoksimaa, E., Spoon, K. M., Mendoza, S. P., … Franz, C. E. (2014). Interaction of APOE genotype and testosterone on episodic memory in middle-aged men. Neurobiology of Aging, 35, 1778 e17711778. doi: 10.1016/j.neurobiolaging.2013.12.025 CrossRefGoogle ScholarPubMed
Panizzon, M. S., Neale, M. C., Docherty, A. R., Franz, C. E., Jacobson, K. C., Toomey, R., … Kremen, W. S. (2015). Genetic and environmental architecture of changes in episodic memory from middle to late middle age. Psychology and Aging, 30, 286300. doi: 10.1037/pag0000023 CrossRefGoogle ScholarPubMed
Ramanan, S., Bertoux, M., Flanagan, E., Irish, M., Piguet, O., Hodges, J. R., & Hornberger, M. (2017). Longitudinal executive function and episodic memory profiles in behavioral-variant frontotemporal dementia and Alzheimer’s Disease. Journal of the International Neuropsychological Society, 23, 3443. doi: 10.1017/S1355617716000837 CrossRefGoogle ScholarPubMed
Rowe, C. C., Bourgeat, P., Ellis, K. A., Brown, B., Lim, Y. Y., Mulligan, R., … Villemagne, V. L. (2013). Predicting Alzheimer disease with beta-amyloid imaging: Results from the Australian imaging, biomarkers, and lifestyle study of ageing. Annals of Neurology, 74, 905913. doi: 10.1002/ana.24040 CrossRefGoogle ScholarPubMed
Satorra, A. & Bentler, P. M. (2001). A scaled difference chi-square test statistic for moment structure analysis. Psychometrika, 66, 507514. doi: 10.1007/Bf02296192 CrossRefGoogle Scholar
Schoenborn, C. A. & Heyman, K. M. (2009). Health characteristics of adults aged 55 years and over: United States, 2004–2007. National Health Statistics Report, 16, 131.Google Scholar
Sperling, R. A., Mormino, E., & Johnson, K. (2014). The evolution of preclinical Alzheimer’s disease: Implications for prevention trials. Neuron, 84, 608622. doi: 10.1016/j.neuron.2014.10.038 CrossRefGoogle ScholarPubMed
Stroop, J. R. (1935). Studies of interference in serial verbal reactions. Journal of Experimental Psychology, 18, 643662. doi: 10.1037/0096-3445.121.1.15 CrossRefGoogle Scholar
Tsuang, M. T., Bar, J. L., Harley, R. M., & Lyons, M. J. (2001). The Harvard twin study of substance abuse: What we have learned. Harvard Review of Psychiatry, 9, 267279. doi: 10.1093/hrp/9.6.267 CrossRefGoogle ScholarPubMed
Tucker-Drob, E. M., Brandmaier, A. M., & Lindenberger, U. (2019). Coupled cognitive changes in adulthood: A meta-analysis. Psychological Bulletin, 145, 273301. doi: 10.1037/bul0000179 CrossRefGoogle ScholarPubMed
Vos, S. J. B. & Duara, R. (2019). The prognostic value of ATN Alzheimer biomarker profiles in cognitively normal individuals. Neurology, 94, 643644. doi: 10.1212/WNL.0000000000007223 CrossRefGoogle Scholar
Wang, G., Coble, D., McDade, E. M., Hassenstab, J., Fagan, A. M., Benzinger, T. L. S., … Dominantly Inherited Alzheimer Network (2019). Staging biomarkers in preclinical autosomal dominant Alzheimer’s disease by estimated years to symptom onset. Alzheimer’s & Dementia. doi: 10.1016/j.jalz.2018.12.008 Google ScholarPubMed
Wechsler, D. (1997). Wechsler memory scale (WMS-III). San Antonio, TX: Psychological Corporation.Google Scholar
Zhang, Q., Sidorenko, J., Couvy-Duchesne, B., Marioni, R. E., Wright, M. J., Goate, A. M., … Visscher, P. M. (2020). Risk prediction of late-onset Alzheimer’s disease implies an oligogenic architecture. Nature Communications, 11, 4799. doi: 10.1038/s41467-020-18534-1 CrossRefGoogle ScholarPubMed
Zhao, Q., Guo, Q., & Hong, Z. (2013). Clustering and switching during a semantic verbal fluency test contribute to differential diagnosis of cognitive impairment. Neuroscience Bulletin, 29, 7582. doi: 10.1007/s12264-013-1301-7 CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Flowchart describing the sample. All subjects included in the final genetic sample were diagnosed cognitively normal at their first assessment and were of European ancestry (necessary for associations with AD-PRS). VETSA 2 was completed M = 5.70 years (SD = .69) after VETSA 1. VETSA 3 was completed M = 5.93 years after VETSA 2. VETSA = Vietnam Era Twin Study of Aging; CN = cognitively normal; MCI = mild cognitive impairment.

Figure 1

Fig. 2. Path model of the latent growth model of episodic memory with Alzheimer’s disease polygenic risk scores (AD-PRSs). Factor loadings with a “1” indicate loadings were fixed to 1. Loadings with a “*” indicates they were equated across time (e.g., the path from CVLT to Memory Wave 1 was the same as the corresponding path on Memory Wave 2 and Wave 3). Factor loadings on the slope factor represent each individual’s age at that assessment (centered on the mean age at wave 1 and scaled based in decades). At the top of the model, AD-PRS and the intercept and (linear) slope factors are regressed on the first 3 ancestry-based principal components (PCs). Intercept and slope factors were also regressed on APOE ϵ4 status (i.e., a dichotomous variable capturing the presence of an ϵ4 allele) only when AD-PRSs excluded the APOE region. At the bottom of the model, residual correlations between memory tests across waves were included for all tests, but these are displayed for Logical Memory (immediate recall) only for simplicity. Means for each test were also equated across wave and means for intercept and slope factors were estimated but not displayed here. CVLT = California Verbal Learning Task; I = immediate recall; D = delayed recall; L = learning trials.

Figure 2

Table 1. Demographic characteristics of the study

Figure 3

Table 2. Associations between Alzheimer’s disease polygenic scores (AD-PRS) and cognitive change across midlife

Figure 4

Table 3. Sensitivity analyses using different methods for computing Alzheimer’s Disease polygenic scores (AD-PRS)

Supplementary material: PDF

Gustavson et al. supplementary material

Gustavson et al. supplementary material

Download Gustavson et al. supplementary material(PDF)
PDF 412.5 KB