Large-scale Deep Proteomic Analysis in Alzheimer's Disease Brain Regions Across Race and Ethnicity

Overview

Journal Alzheimers Dement

Specialties Neurology
Psychiatry

Date 2024 Nov 13

PMID 39535480

Authors

Fatemeh Seifar

Edward J Fox

Anantharaman Shantaraman

Yue Liu

Eric B Dammer

Erica Modeste

Duc M Duong

Luming Yin

Adam N Trautwig

Qi Guo

Kaiming Xu

Lingyan Ping

Joseph S Reddy

Mariet Allen

Zachary Quicksall

Laura Heath

Jo Scanlan

Erming Wang

Minghui Wang

Abby Vander Linden

William Poehlman

Xianfeng Chen

Saurabh Baheti

Charlotte Ho

Thuy Nguyen

Geovanna Yepez

Adriana O Mitchell

Stephanie R Oatman

Xue Wang

Minerva M Carrasquillo

Alexi Runnels

Thomas Beach

Geidy E Serrano

Dennis W Dickson

Edward B Lee

Todd E Golde

Stefan Prokop

Lisa L Barnes

Bin Zhang

Varham Haroutunian

Marla Gearing

James J Lah

Philip De Jager

David A Bennett

Anna Greenwood

Nilufer Ertekin-Taner

Allan I Levey

Aliza Wingo

Thomas Wingo

Nicholas T Seyfried

Affiliations

Soon will be listed here.

Abstract

Introduction: Alzheimer's disease (AD) is the most prevalent neurodegenerative disease, yet our comprehension predominantly relies on studies within non-Hispanic White (NHW) populations. Here we provide an extensive survey of the proteomic landscape of AD across diverse racial/ethnic groups.

Methods: Two cortical regions, from multiple centers, were harmonized by uniform neuropathological diagnosis. Among 998 unique donors, 273 donors self-identified as African American, 229 as Latino American, and 434 as NHW.

Results: While amyloid precursor protein and the microtubule-associated protein tau demonstrated higher abundance in AD brains, no significant race-related differences were observed. Further proteome-wide and focused analyses (specific amyloid beta [Aβ] species and the tau domains) supported the absence of racial differences in these AD pathologies within the brain proteome.

Discussion: Our findings indicate that the racial differences in AD risk and clinical presentation are not underpinned by dramatically divergent patterns in the brain proteome, suggesting that other determinants account for these clinical disparities.

Highlights: We present a large-scale proteome (∼10,000 proteins) of DLPFC (998) and STG (244) across AD cases. About 50% of samples were from racially and ethnically diverse brain donors. Key AD proteins (amyloid and tau) correlated with CERAD and Braak stages. No significant race-related differences in amyloid and tau protein levels were observed in AD brains. AD-associated protein changes showed a strong correlation between the brain proteomes of African American and White individuals. This dataset advances understanding of ethnoracial-specific AD pathways and potential therapies.

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