What question did this study set out to answer?

The aim is to map transcription factor functions in astrocytes to understand gene regulation and disease mechanisms.

April 25, 2026

Mapping transcription factor functions in astrocytes using in vivo gain-of-function Perturb-seq

Key Points

The aim is to map transcription factor functions in astrocytes to understand gene regulation and disease mechanisms.
Developed iGOF-Perturb-seq platform to map ~1000 transcription factors.
Performed studies in a mouse neuroinflammatory model.
Identified cofunctional modules and disease-associated transcription factor clusters.
Astrocyte-specific overexpression of Ferd3l reduced Alzheimer’s disease symptoms in mice.
iGOF-Perturb-seq identified cofunctional modules and uncharacterized transcription factors.
Predicted disease-associated transcription factor clusters enhance understanding of brain disorders.

Abstract

An in vivo approach combining high-throughput screening with cell type–specific readouts could enable elucidation of genotype-phenotype relationships in complex tissues. We developed an in vivo gain-of-function Perturb-seq platform, termed iGOF–Perturb-seq, to build a functional atlas of ~1000 transcription factors (TFs) in astrocytes, a cell type essential to many brain functions. We then identified cofunctional modules, annotated uncharacterized TFs, and predicted disease-associated TF clusters. Furthermore, iGOF–Perturb-seq performed in a mouse neuroinflammatory model identified Ferd3l as a therapeutic candidate, and astrocyte-specific overexpression of Ferd3l alleviated Alzheimer’s disease symptoms in mice. This study provides resources for understanding gene regulation and disease mechanisms in vivo and for identifying potential therapeutic targets for different brain diseases.

Mapping transcription factor functions in astrocytes using in vivo gain-of-function Perturb-seq

Key Points

Abstract

Cite This Study