. 2023 Oct;270(10):4949-4958.

doi: 10.1007/s00415-023-11809-9. Epub 2023 Jun 26.

Genetic risk factors of Alzheimer's Disease disrupt resting-state functional connectivity in cognitively intact young individuals

Ludmila Kucikova^#^{1

2}, Jianmin Zeng^#³, Carlos Muñoz-Neira^{1

4}, Graciela Muniz-Terrera^{5

6}, Weijie Huang^{1

2

7}, Sarah Gregory⁵, Craig Ritchie^{5

8}, John O'Brien⁴, Li Su^{9

10

11}

Affiliations

¹ Department of Neuroscience, Faculty of Medicine, Dentistry and Heath, Sheffield Institute for Translational Neuroscience, University of Sheffield, 385a Glossop Road, Sheffield, S10 2HQ, SY, UK.
² Insigneo Institute for in Silico Medicine, University of Sheffield, Sheffield, UK.
³ Sino-Britain Centre for Cognition and Ageing Research, Faculty of Psychology, Southwest University, Chongqing, China. james_psych@yeah.net.
⁴ Department of Psychiatry, School of Clinical Medicine, University of Cambridge, Cambridge, UK.
⁵ Edinburgh Dementia Prevention, Centre for Clinical Brain Sciences, University of Edinburgh, Edinburgh, UK.
⁶ Ohio University Heritage College of Osteopathic Medicine, Ohio University, Athens, OH, USA.
⁷ School of Systems Science, Beijing Normal University, Beijing, China.
⁸ Scottish Brain Sciences, Edinburgh, UK.
⁹ Department of Neuroscience, Faculty of Medicine, Dentistry and Heath, Sheffield Institute for Translational Neuroscience, University of Sheffield, 385a Glossop Road, Sheffield, S10 2HQ, SY, UK. l.su@sheffield.ac.uk.
¹⁰ Insigneo Institute for in Silico Medicine, University of Sheffield, Sheffield, UK. l.su@sheffield.ac.uk.
¹¹ Department of Psychiatry, School of Clinical Medicine, University of Cambridge, Cambridge, UK. l.su@sheffield.ac.uk.

^# Contributed equally.

PMID: 37358635
PMCID: PMC10511575
DOI: 10.1007/s00415-023-11809-9

Genetic risk factors of Alzheimer's Disease disrupt resting-state functional connectivity in cognitively intact young individuals

Ludmila Kucikova et al. J Neurol. 2023 Oct.

. 2023 Oct;270(10):4949-4958.

doi: 10.1007/s00415-023-11809-9. Epub 2023 Jun 26.

Authors

Affiliations

¹ Department of Neuroscience, Faculty of Medicine, Dentistry and Heath, Sheffield Institute for Translational Neuroscience, University of Sheffield, 385a Glossop Road, Sheffield, S10 2HQ, SY, UK.
² Insigneo Institute for in Silico Medicine, University of Sheffield, Sheffield, UK.
³ Sino-Britain Centre for Cognition and Ageing Research, Faculty of Psychology, Southwest University, Chongqing, China. james_psych@yeah.net.
⁴ Department of Psychiatry, School of Clinical Medicine, University of Cambridge, Cambridge, UK.
⁵ Edinburgh Dementia Prevention, Centre for Clinical Brain Sciences, University of Edinburgh, Edinburgh, UK.
⁶ Ohio University Heritage College of Osteopathic Medicine, Ohio University, Athens, OH, USA.
⁷ School of Systems Science, Beijing Normal University, Beijing, China.
⁸ Scottish Brain Sciences, Edinburgh, UK.
⁹ Department of Neuroscience, Faculty of Medicine, Dentistry and Heath, Sheffield Institute for Translational Neuroscience, University of Sheffield, 385a Glossop Road, Sheffield, S10 2HQ, SY, UK. l.su@sheffield.ac.uk.
¹⁰ Insigneo Institute for in Silico Medicine, University of Sheffield, Sheffield, UK. l.su@sheffield.ac.uk.
¹¹ Department of Psychiatry, School of Clinical Medicine, University of Cambridge, Cambridge, UK. l.su@sheffield.ac.uk.

^# Contributed equally.

PMID: 37358635
PMCID: PMC10511575
DOI: 10.1007/s00415-023-11809-9

Abstract

Background: Past evidence shows that changes in functional brain connectivity in multiple resting-state networks occur in cognitively healthy individuals who have non-modifiable risk factors for Alzheimer's Disease. Here, we aimed to investigate how those changes differ in early adulthood and how they might relate to cognition.

Methods: We investigated the effects of genetic risk factors of AD, namely APOEe4 and MAPTA alleles, on resting-state functional connectivity in a cohort of 129 cognitively intact young adults (aged 17-22 years). We used Independent Component Analysis to identify networks of interest, and Gaussian Random Field Theory to compare connectivity between groups. Seed-based analysis was used to quantify inter-regional connectivity strength from the clusters that exhibited significant between-group differences. To investigate the relationship with cognition, we correlated the connectivity and the performance on the Stroop task.

Results: The analysis revealed a decrease in functional connectivity in the Default Mode Network (DMN) in both APOEe4 carriers and MAPTA carriers in comparison with non-carriers. APOEe4 carriers showed decreased connectivity in the right angular gyrus (size = 246, p-FDR = 0.0079), which was correlated with poorer performance on the Stroop task. MAPTA carriers showed decreased connectivity in the left middle temporal gyrus (size = 546, p-FDR = 0.0001). In addition, we found that only MAPTA carriers had a decreased connectivity between the DMN and multiple other brain regions.

Conclusions: Our findings indicate that APOEe4 and MAPTA alleles modulate brain functional connectivity in the brain regions within the DMN in cognitively intact young adults. APOEe4 carriers also showed a link between connectivity and cognition.

Keywords: Alzheimer’s disease; Cognition; Functional connectivity; Functional neuroimaging; Large-scale networks; Risk factors.

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Conflict of interest statement

LK is a recipient of the University of Sheffield Flagship Scholarship. LS’s participation is funded by Alzheimer's Research UK Senior Research Fellowship (ARUK-SRF2017B-1), NIHR Sheffield Biomedical Research Centre. JZ, CMN, GMT, and WH have no financial conflicts of interests to disclose. JOB has acted as a consultant for TauRx, Novo Nordisk, Biogen, Roche, Lilly and GE Healthcare and received grant or academic support from Avid/ Lilly, Merck and Alliance Medical. CR is the founder of Scottish Brain Sciences, and acted as a consultant for Biogen, Eisai, MSD, Actinogen, Roche, and Eli Lilly, and received payment or honoraria from Roche and Eisai in the past. SG acted as a consultant for Scottish Brain Sciences.

Figures

**Fig. 1**
Identified resting-state networks. A DMN. B Dorsoattentional network. C Sensorimotor network. D Salience network. E Frontoparietal network. F Language network. G Visual network

**Fig. 2**
Violin plots of the functional connectivity differences in the DMN calculated based on the peak connectivity values in each cluster. A *APOEe4* carriers vs non-carriers in Cluster 1. B *MAPTA* carriers vs non-carriers in Cluster 2

**Fig. 3**
The spatial maps of clusters that exhibited significant differences in connectivity between carriers and non-carriers. A Cluster 1 comprising of the right angular gyrus and superior occipital cortex that showed significant differences between *APOEe4* carriers and non-carriers. B Cluster 2 comprising of the left middle temporal gyrus that showed significant differences between *MAPTA* carriers and non-carriers

**Fig. 4**
The spatial map of clusters that exhibited an additional reduction of functional connectivity from Cluster 2

**Fig. 5**
Spearman’s correlations between functional connectivity in respective clusters and Stroop performance (i.e., the accuracy in the colour-incongruent condition) between groups with fitted linear regression lines. *APOEe4* carriers showed a positive relationship between connectivity in Cluster 1 and Stroop performance (R = 0.42, p = 0.037), while no other relationship was observed in *APOEe4* non-carriers (R = − 0.16, p > 0.05), *MAPTA* carriers (R = 0.08, p > 0.05), and *MAPTA* non-carriers (R = 0.2, p > 0.05)

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Genetic risk factors of Alzheimer's Disease disrupt resting-state functional connectivity in cognitively intact young individuals

Affiliations

Genetic risk factors of Alzheimer's Disease disrupt resting-state functional connectivity in cognitively intact young individuals

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Conflict of interest statement

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