Abstract
INTRODUCTION
The genetic pathways that influence longitudinal heterogeneous changes in Alzheimer’s disease (AD) may provide insight into disease mechanisms and potential therapeutic targets.
METHODS
Longitudinal endophenotypes from the Alzheimer’s Disease Neuroimaging Initiative (ADNI) representing amyloid, tau, neurodegeneration (A/T/N), and cognition were selected. Genome-wide association analysis was performed using a linear mixed model (LMM) approach, followed by gene and pathway enrichment with significant and functionally relevant SNPs.
RESULTS
A total of 33 and 19 statistically significant pathways were identified associating with the intercept and longitudinal trajectory, respectively. The longitudinal intercept pathways represent eight groups: immune, metabolic, cell growth and survival, DNA maintenance, neuronal signaling, R
AS/MAPK/ERK signaling pathways, vesicle and lysosomal transport, and transcription modification. Longitudinal trajectory pathways represented six groups: Immune, metabolic, cell signaling, cytoskeleton, and glycosylation.
DISCUSSION
Longitudinal enrichment identified pathways that uniquely associate with trajectories of key AD biomarkers and cognition, providing new insight into AD course-related mechanisms and potential new therapeutic targets.
Highlights
A systematic genome-wide analysis with longitudinal AD biomarker endophenotypes was performed.
Enriched pathways were identified with functionally derived SNP to gene analysis.
Fifty-two pathways were associated with longitudinal trajectory and intercept.
Many of the identified pathways are specific steps in larger pathways implicated in AD.
The identified pathways may provide therapeutic targets and areas for further study.
If you do not see content above, kindly GO TO SOURCE.
Not all publishers encode content in a way that enables republishing at Neuro.vip.
This post is Copyright: Thea J. Rosewood,
Kwangsik Nho,
Shannon L. Risacher,
Shiwei Liu,
Sujuan Gao,
Li Shen,
Tatiana Foroud,
Andrew J. Saykin,
for the Alzheimer’s Disease Neuroimaging Initiative | October 23, 2024