Bridging the rodent to human translational gap: Marmosets as model systems for the study of Alzheimer's disease

Stacey J Sukoff Rizzo; Gregg Homanics; David J Schaeffer; Lauren Schaeffer; Jung Eun Park; Julia Oluoch; Tingting Zhang; Annat Haber; Nicholas T Seyfried; Benedict Paten; Anna Greenwood; Takeshi Murai; Sang Ho Choi; Hasi Huhe; Julia Kofler; Peter L Strick; Gregory W Carter; Afonso C Silva

doi:10.1002/trc2.12417

Bridging the rodent to human translational gap: Marmosets as model systems for the study of Alzheimer's disease

Alzheimers Dement (N Y). 2023 Aug 21;9(3):e12417. doi: 10.1002/trc2.12417. eCollection 2023 Jul-Sep.

Authors

Stacey J Sukoff Rizzo¹, Gregg Homanics¹, David J Schaeffer¹, Lauren Schaeffer¹, Jung Eun Park¹, Julia Oluoch¹, Tingting Zhang¹, Annat Haber², Nicholas T Seyfried³, Benedict Paten⁴, Anna Greenwood⁵, Takeshi Murai¹, Sang Ho Choi¹, Hasi Huhe¹, Julia Kofler¹, Peter L Strick¹, Gregory W Carter², Afonso C Silva¹

Affiliations

¹ University of Pittsburgh School of Medicine Pittsburgh Pennsylvania USA.
² The Jackson Laboratory Bar Harbor Maine USA.
³ Department of Biochemistry Emory University School of Medicine Atlanta Georgia USA.
⁴ University of California Santa Cruz Genomics Institute University of California Santa Cruz Santa Cruz California USA.
⁵ Sage Bionetworks Seattle Washington USA.

Abstract

Introduction: Our limited understanding of the mechanisms that trigger the emergence of Alzheimer's disease (AD) has contributed to the lack of interventions that stop, prevent, or fully treat this disease. We believe that the development of a non-human primate model of AD will be an essential step toward overcoming limitations of other model systems and is crucial for investigating primate-specific mechanisms underlying the cellular and molecular root causes of the pathogenesis and progression of AD.

Methods: A new consortium has been established with funding support from the National Institute on Aging aimed at the generation, characterization, and validation of Marmosets As Research Models of AD (MARMO-AD). This consortium will study gene-edited marmoset models carrying genetic risk for AD and wild-type genetically diverse aging marmosets from birth throughout their lifespan, using non-invasive longitudinal assessments. These include characterizing the genetic, molecular, functional, behavioral, cognitive, and pathological features of aging and AD.

Results: The consortium successfully generated viable founders carrying PSEN1 mutations in C410Y and A426P using CRISPR/Cas9 approaches, with germline transmission demonstrated in the C410Y line. Longitudinal characterization of these models, their germline offspring, and normal aging outbred marmosets is ongoing. All data and resources from this consortium will be shared with the greater AD research community.

Discussion: By establishing marmoset models of AD, we will be able to investigate primate-specific cellular and molecular root causes that underlie the pathogenesis and progression of AD, overcome limitations of other model organisms, and support future translational studies to accelerate the pace of bringing therapies to patients.

Keywords: Alzheimer's disease; PSEN1; animal models; biomarkers; cognition; genetic engineering; iPSC; marmoset; multi‐omics.

Abstract

Grants and funding