Directly Converted Astrocytes Retain the Ageing Features of the Donor Fibroblasts and Elucidate the Astrocytic Contribution to Human CNS Health and Disease

Overview

Journal Aging Cell

Specialties Cell Biology
Geriatrics

Date 2020 Dec 14

PMID 33314575

Citations 31

Authors

Noemi Gatto

Cleide Dos Santos Souza

Allan C Shaw

Simon M Bell

Monika A Myszczynska

Samantha Powers

Kathrin Meyer

Lydia M Castelli

Evangelia Karyka

Heather Mortiboys

Mimoun Azzouz

Guillaume M Hautbergue

Nora M Markus

Pamela J Shaw

Laura Ferraiuolo

Affiliations

Soon will be listed here.

Abstract

Astrocytes are highly specialised cells, responsible for CNS homeostasis and neuronal activity. Lack of human in vitro systems able to recapitulate the functional changes affecting astrocytes during ageing represents a major limitation to studying mechanisms and potential therapies aiming to preserve neuronal health. Here, we show that induced astrocytes from fibroblasts donors in their childhood or adulthood display age-related transcriptional differences and functionally diverge in a spectrum of age-associated features, such as altered nuclear compartmentalisation, nucleocytoplasmic shuttling properties, oxidative stress response and DNA damage response. Remarkably, we also show an age-related differential response of induced neural progenitor cells derived astrocytes (iNPC-As) in their ability to support neurons in co-culture upon pro-inflammatory stimuli. These results show that iNPC-As are a renewable, readily available resource of human glia that retain the age-related features of the donor fibroblasts, making them a unique and valuable model to interrogate human astrocyte function over time in human CNS health and disease.

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