The protective gene dose effect of the APOE ε2 allele on gray matter volume in cognitively unimpaired individuals

1 BACKGROUND

The apolipoprotein E (APOE) gene is the major genetic risk-modifying factor for sporadic Alzheimer's disease (AD). Carrying one or two copies of the ɛ4 allele confers higher risk for AD (allelic dose odds ratio [OR]: 6), whereas carrying the ɛ2 allele confers lower risk for AD (allelic dose OR: 0.38).1-3 The increased AD risk as a consequence of carrying at least one ɛ4 allele has been primarily related to a higher amyloid-β (Aβ) burden in the brain, in a dose dependent manner (i.e., number of ɛ4 alleles).4 However, neuroimaging studies have shown a relationship between ɛ4 gene dose and lower brain glucose hypometabolism and smaller gray matter (GM) volumes in AD-related brain areas,5, 6 even in cognitively unimpaired individuals. These findings suggest an ɛ4 gene dose reduced capacity to maintain brain health.7

On the other hand, the ε2 allele has received much less attention, presumably due to the low frequency of this polymorphism in the general population (8.4%).8 APOE ɛ2 carriers have lower Aβ burden among non-demented participants.9, 10 However, multiple studies suggest that the ɛ2 allele may reduce the risk of AD through Aβ-independent pathways.11 One of these pathways may be through maintained GM volumes across the lifespan. In healthy adolescents no differences between ɛ2 and ɛ4 carriers or dose dependent effects of these alleles were found in hippocampal volumes.12 However, potential gene dose effects of the ɛ2 allele in adults remain to be described. Previous literature on adults has only reported differences between ɛ2 carriers and non-carriers, or against ε4 carriers, all showing larger GM volumes or cortical thickness in association with the ε2 allele, in AD-sensitive regions such as the entorhinal cortex.13-16 These results suggest that ɛ2 carriers may have higher brain reserve,7 which might allow them to better cope with aging and pathology. In line with this, it has been reported that ɛ2 carriers remain cognitively unimpaired for a longer period even in the rare case of developing AD pathology (i.e., Aβ and tau).17, 18 Studying the brain properties in late-/middle-aged cognitively unimpaired ɛ2 carriers may increase our understanding of the biological mechanisms associated with this protective allele.

Importantly, to better clarify the mechanisms related to the APOE ɛ2 allele, it would be necessary to test its impact both on brain areas that are the target of incipient degeneration, and on those related to cognitive resilience. The thinning of specific areas such as the entorhinal cortex or temporal areas has shown a tight association with the progression of AD.19, 20 On the other hand, the maintenance of metabolism in other areas, such as the anterior cingulate or the temporal pole, has been related to preserved cognitive function.21 These facts suggest that metabolic and volumetric measures in these regions are of particular interest when studying characteristics related to AD.

This study aimed to investigate the association between the APOE ɛ2 genotype and brain morphology in late-/middle-aged cognitively unimpaired individuals, with a focus on ɛ2/ɛ2 individuals and ɛ2 allele dose effects. We performed two sets of analyses: a hypothesis-driven analysis in which we studied the ɛ2 allele effects on areas related to AD (i.e., AD signature and resilience signature); and a hypothesis-free approach in which we expanded these analyses to the whole brain. For both sets of analyses, GM volumes of all ε2 genotypic groups (i.e., ɛ2/ɛ2, ɛ2/ɛ3, and ɛ2/ɛ4) were compared to the reference ε3/ε3 group, as well as to one another. The genotypic dose-dependent effects (i.e., dominant, additive, and recessive) of the ε2 allele were also investigated. Finally, we computed a continuous measure to capture the risk of AD related to the APOE genotype (i.e., APOE genotype-related AD risk). Effects of this measure on GM volumes were explored and compared to those of the ε2 allele. We hypothesized that (1) APOE ε2 carriership would be associated to larger GM volumes in areas known to be affected in AD19 and areas related to successful aging,21 (2) a higher dose of ε2 allele would be related to larger GM volumes, and (3) these effects would contribute to the global APOE genotype-related AD risk effect on GM volumes.

2 METHODS 2.1 Participants

Leveraging a previous multi-cohort study,22 we checked the cohorts for cognitively unimpaired APOE ε2/ε2 individuals and extended our search to new cohorts. The final selection included: the ALFA (Alzheimer's and Families) study from Barcelona, Spain;23 the Amsterdam Dementia Cohort (ADC) from the Netherlands;24, 25 the Gothenburg H70 Birth cohort study (H70) from Sweden;26 the BioFINDER (www.biofinder.se) from Sweden; the Alzheimer's Disease Neuroimaging Initiative (ADNI; http://adni.loni.usc.edu/) from the United States and Canada; and the Open Access Series of Imaging Studies (OASIS; http://www.oasis-brains.org/) from the United States27 (see supporting information for a description of each cohort). The search in AIBL (Australian Imaging, Biomarker & Lifestyle Study of Ageing; https://aibl.csiro.au/) and in Japanese ADNI (https://humandbs.biosciencedbc.jp/en/hum0043-v1) cohorts did not return any APOE ε2/ε2 individual in their magnetic resonance imaging (MRI) arms. The search in AddNeuroMed28 and the CBAS (Czech Brain Aging Study)29 cohorts only identified APOE ε2/ε2 individuals with cognitive impairment, and so were not included in this study.

We first selected all cognitively unimpaired APOE ε2/ε2 individuals who had T1-weighted MRI data available. The criteria for classifying individuals as cognitively unimpaired were similar in all cohorts, including: normal global cognition as reflected by a Clinical Dementia Rating (CDR) score of 0 or a Mini-Mental State Examination (MMSE) score of 25 or higher, and/or normal cognition as decided by a multidisciplinary consensus panel of experts (see supporting information). After selecting the APOE ε2/ε2 individuals as the reference group, we selected one participant of each of the other APOE genotypes to match every APOE ε2/ε2 individual using age, sex, and education as matching variables, within each of the cohorts. Because matching was performed within cohorts, the six APOE genotype groups were also matched for scanner/protocol except for the ADNI, because the ADNI was designed to provide comparable images across scanners and protocols (http://adni.loni.usc.edu/methods/mri-tool/mri-analysis/). In the ADC, some individuals did not get a match with exactly the same MRI protocol. For those individuals, we selected the most similar MRI protocol in terms of manufacturer, field strength, and acquisition parameters.

2.2 Image processing

Participants were scanned using T1-weighted sequences with comparable scanning protocols and image resolution across cohorts (see the supporting information). GM was segmented and warped into Montreal Neurological Institute (MNI) space following a standard procedure using SPM12 (see supporting information). Images were spatially smoothed with an 8-mm full width at half maximum Gaussian kernel. Total intracranial volume (TIV) was computed as the sum of GM, white matter, and cerebrospinal fluid volume partitions using the CAT12 toolbox.

RESEARCH IN CONTEXT

Systematic review: The authors reviewed previous literature related to apolipoprotein E (APOE) effects on Alzheimer's disease (AD)-related phenotypes, with specific attention to those linked to brain morphology. Although studies focusing on the effects of the APOE ε2 allele, and especially of the ε2 homozygosity, are scarce, we have cited those related to our research.

Interpretation: Our study increases our knowledge about APOE, and especially APOE ε2, effects on gray matter volumes and suggest a mechanism through which APOE ε2 homozygotes may maintain their cognitive function throughout life even in the improbable case of developing AD pathology.

Future directions: In this study, we have proved the value of studying gene dose effects of the ε2 allele over the frequently investigated carriership effects. Future studies about the APOE ε2 allele need to further explore these gene dose effects on other important AD-related phenotypes. This may help us to understand the exceptional low risk of these subjects to develop AD dementia.

HIGHLIGHTS Cognitively unimpaired ε2 carriers have larger gray matter (GM) volumes than ε3 homozygotes. Apolipoprotein E (APOE) ε2 carriership is associated with larger GM volumes in the Alzheimer's disease signature.  APOE ε2 homozygotes have larger GM volumes in areas related to cognitive resilience.  Genotypic APOE effect on GM volume is not only due to ε4 but also to ε2 effects.

To calculate regional GM volume we used the cortical and subcortical areas from the Desikan-Killiany30 atlas. We summed the intensity of the modulated GM images in the MNI space in each region across individuals. We also created two composite regions of interest (ROIs) to specifically investigate the brain areas known to be typically affected in AD, as well as areas known to be associated with successful aging or resilience. Following previous studies, the AD signature ROI was created by combining the entorhinal cortex, inferior and middle temporal and fusiform gyrus19; and the resilience signature ROI was created by combining the anterior cingulate and temporal pole regions.21 We also performed asymmetry analysis (see the next section), which included a medial-temporal lobe (MTL) composite ROI that combined hippocampus, amygdala, and parahippocampal ROIs.16

2.3 Statistical analysis

We compared the demographic characteristics across APOE genotypes using analysis of variance (for continuous variables) and χ2 (for categorical variables). All analyses described below for APOE effects on GM volume were performed in two different sets of analyses. First, we specifically tested for APOE effects on areas related to AD (i.e., AD signature and resilience signature). Second, we expanded the approach to a whole-brain analysis.

2.3.1 Comparisons between APOE ε2 genotypic groups

We first compared each ε2 genotypic group (i.e., ε2/ε2, ε2/ε3, and ε2/ε4) to the reference group (i.e., ε3 homozygotes), and also to each other (i.e., ε2/ε2 vs. ε2/ε3, ε2/ε2 vs. ε2/ε4, and ε2/ε3 vs. ε2/ε4). Generalized linear models were used to compare each pair of groups to GM volume as the dependent variable and the APOE genotype as the variable of interest. Age, sex, education, scanner (as a dummy variable), and TIV were included as covariates. The models used were analogous for both sets of analyses (i.e., AD composites and whole brain).

2.3.2 Dose-dependent effects of the APOE ε2 allele on GM volume

The second aim of this study was to investigate particular dose-dependent effects of the ε2 allele on GM volumes. Similar statistical models were used in these analyses but including only ε2 carriers and ε3 homozygotes in this case. APOE ε2/ε4 participants were excluded from this analysis to avoid the influence of the APOE ε4 allele.31 Contrasts were designed to test for dominant (i.e., APOE ε2 carriers vs. APOE ε3/ε3 individuals), additive (i.e., APOE ε2/ε2 vs. APOE ε2/ε3 vs. APOE ε3/ε3), and recessive (i.e., APOE ε2/ε2 vs. APOE ε2/ε3 plus APOE ε3/ε3) effects of the APOE ε2 allele.32

As an additional analysis we also investigated right-left hemispheric asymmetry16, 33 on GM volume in the MTL as a composite and each of the ROIs included in the MTL composite (i.e., hippocampus, amygdala, and parahippocampus). We replicated the previous analysis using the asymmetry metrics as dependent variables and the same covariates excluding TIV, as the asymmetry value is already normalized by the total volume of the region itself.

2.3.3 Comparison of ε2 and global APOE genotype-related AD risk effects on GM volume

The third aim of this study was to investigate the APOE genotypic effect on GM volume and compare it to the previous ε2 dose-dependent effects. We created a new variable that we called “APOE genotype-related AD risk,” which encoded the risk of AD for each of the genotypes as a continuous variable. Our goal was to create a measure related to the APOE genotype that would capture the related risk of developing AD and investigate whether this was associated to GM volumes. This variable was calculated by log-transforming previously published odds ratios for developing AD associated to each APOE genotype, with APOE ε3/ε3 individuals as the reference group (Table S1 in supporting information).3 We repeated the composite-based and the whole-brain analyses using the APOE genotype-related AD risk value as an independent variable (as a continuous variable). In addition, we also performed Spearman's rank correlations between the regional effects of the APOE genotype-related AD risk and the dose-dependent effects of the ε2 allele. These correlations aimed to compare global APOE and ε2 standalone effects on GM volumes.

For all three objectives, statistical significance was set at P < 0.05 using the false discovery rate (FDR) adjustment for multiple testing (hypothesis-free approach), and at uncorrected P < 0.05 for the a priori selected areas related to AD (hypothesis-driven approach). In addition, supporting information shows the results from uncorrected P < 0.05 in the hypothesis-free approach, for completeness of information.

3 RESULTS 3.1 Participants

The sample was composed of 223 cognitively unimpaired individuals, including 38 APOE ε2/ε2 individuals and 38 matched individuals for each of the other APOE genotypes (except for the APOE ε2/ε4 group, which included 33 participants due to unavailability of suitable matches for 5 cases). All individuals were matched for age, sex, and education within the center. As shown in Table 1, there were no statistically significant differences in these variables by the APOE group. Moreover, MMSE scores and TIV did not show significant differences among APOE groups.

TABLE 1. Sample characteristics All (n = 223) ε2/ε2 (n = 38) ε2/ε3 (n = 38) ε3/ε3 (n = 38) ε2/ε4 (n = 33) ε3/ε4 (n = 38) ε4/ε4 (n = 38) P-value Age (years old), mean (SD) [min–max] 64.6 (8.9) [45.8–88.0] 65.0 (9.1) [49.8–88.0] 64.9 (8.8) [47.9–87.0] 65.0 (9.2) [48.8–88.0] 64.2 (9.2) [45.8–88.0] 64.7 (9.2) [50.5–88.0] 64.0 (8.7) [52.1–81.0] 0.994 Women, n (%) 99 (44.4) 17 (44.7) 16 (42.1) 17 (44.7) 14 (42.7) 18 (47.4) 17 (44.7) 0.998 Education (years), mean (SD) 14.2 (3.6) 14.2 (3.8) 14.3 (3.6) 14.5 (3.7) 13.8 (3.2) 14.1 (3.7) 14.1 (3.4) 0.973 MMSE, mean (SD)* 28.9 (1.2) 29.2 (1.0) 29.0 (1.1) 29.1 (1.0) 28.8 (1.2) 28.6 (1.8) 28.8 (1.0) 0.417 TIV (cm3), mean (SD) 1491.4 (146.7) 1481.3 (1287.1) 1474.4 (126.7) 1486.6 (142.9) 1505.8 (158.9) 1490.3 (130.0) 1512.1 (133.7) 0.878

Cohort: ADC/ADNI/ALFA/BioFINDER/H70/OASIS

72/18/42/31/18/42 12/3/7/6/3/7 12/3/7/6/3/7 12/3/7/6/3/7 12/3/7/1/3/7 12/3/7/6/3/7 12/3/7/6/3/7 – *MMSE from one individual is missing. Abbreviations: ADC, Amsterdam Dementia Cohort; ADNI, Alzheimer's Disease Neuroimaging Initiative; ALFA, Alzheimer's and Families; H70, Gothenburg H70 Birth cohort study; MMSE, Mini-Mental State Examination; OASIS, Open Access Series of Imaging Studies; SD, standard deviation; TIV, total intracranial volume. 3.2 Comparisons between APOE ε2 genotypic groups

We first investigated whether there were significant differences between groups on two AD-related GM volume ROI composites: the AD signature and the resilience signature. APOE ε2/ε3 participants had larger GM volume in the AD signature areas compared to ε3 homozygotes (Table 2 and Figure 1). Within the resilience signature, ε2 homozygotes had larger GM volumes than the ε3/ε3 and ε4/ε4 groups.

TABLE 2. APOE effects on GM volumes in AD-related areas AD signature Resilience signature βstd [95%CI] P-value βstd [95%CI] P-value Comparisons between ε2 genotypic groups ε2/ε2 vs. ε3/ε3 1.41 [–0.56, 3.38] 0.161 2.36 [0.39, 4.33] 0.019 ε2/ε3 vs. ε3/ε3 2.71 [0.74, 4.69] 0.007 1.66 [–0.33, 3.63] 0.101 ε2/ε4 vs. ε3/ε3 0.95 [–1.02, 2.92] 0.342 0.62 [–1.36, 2.59] 0.540 ε2/ε2 vs. ε2/ε3 –1.22 [–3.19, 0.74] 0.222 0.75 [–1.22, 3.65] 0.453 ε2/ε2 vs. ε2/ε4 0.41 [–1.56, 2.38] 0.680 1.67 [–0.31, 3.64] 0.098 ε2/ε3 vs. ε2/ε4 1.61 [–0.36, 3.58] 0.109 0.95 [–1.03, 2.93] 0.347 Dose-dependent effects Dominant ε2 2.64 [0.66, 4.62] 0.010 2.07 [0.09, 4.05] 0.041 Additive ε2 1.60 [–0.39, 3.58] 0.114 1.92 [–0.07, 3.87] 0.058 Recessive ε2 0.09 [–1.88, 2.07] 0.926 0.21 [–0.02, 0.47] 0.239 APOE genotype-related AD risk –2.15 [–4.11, –0.17] 0.033 –1.67 [–3.63, 0.30] 0.096 Notes: Results of the analysis of the comparisons between ε2 genotypic groups; dose-dependent (additive, recessive, and dominant) effects of the ε2 allele and APOE genotype-related AD risk effect on GM volume in areas related to AD.19, 21 The first column of each effect shows the βstd (calculated as the estimate divided by SE) and 95%CI, the second the respective P-value. A negative value of the last row shows a negative correlation between GM volume and the APOE genotype-related AD risk, meaning more GM volume for a lower AD risk related to APOE genotype. Significant results (P < 0.05) are shown in bold and those that showed a trend to significance (P < 0.100) are shown in italics Abbreviations: AD, Alzheimer's disease; APOE, apolipoprotein E; CI, confidence interval; GM, gray matter; ROI, region of interest; SE, standard error; βstd, standardized β. image Association between APOE genotype and GM volume in AD-related areas. Adjusted GM volume in areas affected in AD (AD signature;19 left) and in areas known to be associated with successful aging or resilience (resilience signature; right)21 by APOE genotype. GM volumes were adjusted by age, sex, education, scan, and TIV. *P P 

In the whole-brain analysis, ε2/ε2 and ε2/ε3 APOE groups showed larger GM volumes than ε3 homozygotes (Figure 2A). Differences between ε2/ε2 and ε3 homozygotes and between ε2/ε3 and ε3 homozygotes were widespread across the brain. On the other hand, ε2/ε4 participants only showed larger volumes in the inferior parietal and in the inferior temporal gyri, although these differences did not survive the FDR adjustment (Figure S1A in supporting information).

image

Comparisons between APOE ε2 genotypic groups. Comparisons between APOE ε2 genotypic groups and APOE-ε3 homozygotes as the reference group (A); and between each pair of APOE ε2 genotypic groups (B). Colors indicate the effect size of each effect in regions that were statistically significant (P < 0.05 FDR-adjusted). AD, Alzheimer's disease; APOE, apolipoprotein E; FDR, false discovery rate; GM, gray matter; LH, left hemisphere; RH, right hemisphere

When studying differences between ε2 genotypic groups, we found the largest differences between ε2/ε2 and ε2/ε4 groups, including bilateral postcentral gyri, and right parahippocampal and posterior cingulate gyri (Figure 2B). APOE ε2 homozygotes only showed larger volumes than ε2/ε3 participants in the right precentral gyrus, but this difference did not survive the FDR adjustment (Figure S1B). In addition, ε2/ε3 had larger volumes than ε2/ε4 participants in bilateral postcentral gyri.

3.3 Dose-dependent effects of the APOE ε2 allele on GM volume

In the ROI analyses, we found a significant dominant effect of higher GM volume associated with the ε2 allele on both AD-related composites (Table 2). The additive effect also showed a trend to significance in the same direction for the resilience signature, but no other significant effects were observed.

Figure 3 shows the significant areas that had a positive association between GM volume and each of the gene-dose effects of the ε2 allele in whole-brain analyses, after the FDR adjustment for multiple testing. Uncorrected results can be found in the supporting information for completeness of information (Figure S2). The dominant effect was the most widespread including multiple AD-related areas such as the fusiform gyrus, precuneus, or the posterior cingulate. Additive effect was also widespread, although less so than the dominant effect. Finally, the recessive effect was only significant in the paracentral and the pars opercularis of the right hemisphere. Negative associations were not observed for any of the three effects (i.e., the ε2 allele was not associated with a smaller GM volume in any brain region).

image

Dose-dependent effects of the APOE ε2 allele. Dose-dependent effects of the ε2 allele on GM volume (from left to right: dominant, additive, and recessive). APOE ε2/ε4 participants were not included in this analysis. Colors indicate the effect size of each effect in regions that were statistically significant (P < 0.05 FDR-adjusted). AD, Alzheimer's disease; APOE, apolipoprotein E; FDR, false discovery rate; GM, gray matter; LH, left hemisphere; RH, right hemisphere

Additional analyses for asymmetry effects in the subregions of MTL showed that the ε2 recessive, dominant, and additive effects were stronger in the right hemisphere only in the parahippocampal gyrus (Figure S3 in supporting information). More specifically, ε2 homozygotes had greater right–left asymmetry (R > L) than ε3 homozygotes.

3.4 Comparison of ε2 and global APOE genotype-related AD risk effects on GM volume

In the composite-based analysis, the APOE genotype-related AD risk showed a negative association with GM volume in the AD signature (F = 4.61, P = 0.033) and a trend in the resilience signature, in the same direction (F = 2.81, P = 0.096). Both results indicate lower GM volumes for a higher risk of AD, which is related to the APOE genotype in these areas (Table 2). Figure 4A shows the specific regions of this negative correlation for the APOE genotype-related AD risk with GM volume. In particular, the increased risk of AD dementia related to APOE genotype correlated with less GM volume in brain areas overlapping with parts of the AD signature such as the entorhinal and the fusiform, as well as with parts of the resilience signature such as the anterior cingulate. Results uncorrected for multiple comparisons can be found in Figure S4 in supporting information.

image

APOE genotype-related AD risk effect on GM volume and association to APOE ε2 effects. APOE genotype-related AD risk effects on GM volume (A). Colors indicate the effect size of each effect in regions that were statistically significant (P < 0.05 FDR-adjusted). Associations between dose-dependent effects of the ε2 allele (βstd) on GM volume (from left to right: dominant, additive, and recessive) and APOE genotype-related AD risk effect (βstd) on GM volume. Spearman's ρ and P-values are shown in the left bottom corner of each plot. AD, Alzheimer's disease; APOE, apolipoprotein E; FDR, false discovery rate; GM, gray matter; LH, left hemisphere; RH, right hemisphere

We then compared these results to those ones from dose-dependent effect of the ε2 allele, to investigate whether the GM volume effects related to the risk of AD are only due to the ε4 allele or may also be due to the ε2 allele. We found significant negative correlations for the dominant ε2 allele effect (ρ = –0.35, P = 0.004) and the additive ε2 effect (ρ = –0.27, P = 0.028), indicating opposite effects of the ε2 allele (i.e., protective) and the APOE genotype-related AD risk (i.e., deleterious). No significant correlations were observed for the recessive ε2 effect (ρ = –0.13, P = 0.275, Figure 4B).

4 DISCUSSION

In this multi-cohort study, we investigated genotypic and dose-dependent effects of the ε2 allele on GM volumes in late-/middle-aged cognitively unimpaired individuals. As hypothesized, we found that the ε2 allele was associated with larger GM volumes in brain areas relevant for AD. However, the dose-dependent effect of this allele was distinct for different areas. Regions typically affected by AD-related neurodegeneration were similarly protected by the carriership of at least one ε2 allele, regardless of their load. On the other hand, areas related with cognitive maintenance presented larger volumes in relation with the dose (i.e., number) of this allele. In particular, APOE ε2 homozygotes, but not APOE ε2 heterozygotes, showed larger GM volumes than APOE ε3 homozygotes in the resilience signature. This was further supported by the dose-dependent effects analyses, in which we found a trend to significance in the additive model for the ε2 allele, in the resilience but not in the AD signature. Finally, the effect of this protective allele seemed to be spatially related to that of an AD risk measure including all APOE genotypes, suggesting that the ε2 allele plays an opposing effect to that of the ε4 allele on GM volumes.

Our findings extend previous studies showing that having at least one ε2 allele confers larger GM volumes in areas known to be affected in AD.13-15 For instance, the effect of the ε2 carriership on entorhinal volume has previously been observed in cognitively unimpaired individuals,13, 15 as well as in patients with mild cognitive impairment (MCI) and AD dementia.34 A stepwise difference (ɛ2 carriers > ɛ3/ɛ3 individuals > ɛ4 carriers) in cortical thickness in the entorhinal cortex was also found in children and adolescents.35 Further, our results together with a previous study with Aβ-positive subjects suggest that this protective effect of the ɛ2 allele in the MTL, and more specifically in the parahippocampus, may be more pronounced in the right hemisphere.16

In our study we also expand previous findings to regions related with cognitive resilience.21, 36 This result suggests that the well-known low risk of cognitive decline in ε2 carriers may not only be due to a low risk of accumulating Aβ4 and tau37 pathologies (i.e., resistance to AD pathology), but also to preserved brain integrity in areas that are associated with greater resilience to, or capacity to cope with AD pathology.21 A contribution of our study is that we demonstrated that the protective effect on these areas was particularly related to the homozygosity of the ε2 allele. Greater GM volume in areas related to cognitive resilience may also explain why the oldest old ε2 carriers could remain clinically non-demented even when displaying elevated AD pathology.17, 18 With these results in mind, we propose that the increased brain reserve found in ε2 carriers, and especially in ε2 homozygotes, may promote their maintained cognitive functions, even in the rare case of developing AD pathology.

The unique design of our study allowed us to study the ε2 allele effects on GM volume in more detailed ways than previous studies. More specifically, we found that carrying one ε2 allele always seemed to confer an advantage compared to ε3 homozygotes, even when an ε4 allele is also present, although this last result did not survive the adjustment for multiple comparisons. Moreover, our results suggest that having an extra copy of the ε2 allele did not translate into a major gain in areas usually related to neurodegeneration, but it did on resilience areas. Thus, suggesting that carrying one ε2 allele may be sufficient to prevent or decrease AD-related neurodegeneration, maybe in part through lowering AD pathology levels. However, adding an extra copy of the ε2 allele may not be beneficial for GM integrity in these areas, which may be related to the increased risk of APOE ε2 carriers to having cerebrovascular problems.16 On the other hand, being ε2 homozygote increased brain reserve in areas related to cognitive resilience, which may in turn delay their cognitive decline and explain their higher survival rate without AD dementia.3 Altogether, our results highlight that comparing all ε2 genotypic groups is superior to merging all ε2 carriers, when it comes to disentangling the specific effect of the ε2 allele and advance our understanding of its protective effects.3 This accomplishment was an advantage of our large multi-cohort design that has not been possible in previous single-center studies.

Finally, we investigated the effect of a measure capturing the risk of AD due to the APOE genotype (i.e., APOE genotype-related AD risk) on GM volumes and compared it to dose-dependent effects of the ε2 allele. As hypothesized, higher APOE genotype-related AD risk conferred smaller GM volumes both in areas targeted by AD pathology and areas related with brain resilience.19-21 This finding is important and extends previous reports on the APOE ε4 allele5, 38,

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