Amyloid precursor protein induces reactive astrogliosis

Interrogating mediators of single-cell transcriptional changes in the acute damaged cerebral cortex: Insights into endothelial-astrocyte interactions

Traumatic brain injury (TBI) induces complex cellular and molecular changes, challenging recovery and therapeutic development. Although molecular pathways have been implicated in TBI pathology, the cellular specificity of these mechanisms remains underexplored. Here, we investigate the role of endothelial cell (EC) EphA4, a receptor tyrosine kinase receptor involved in axonal guidance, in modulating cell-specific transcriptomic changes within the damaged cerebral cortex. Utilizing single-cell RNA sequencing (scRNA-seq) in an experimental TBI model, we mapped transcriptional changes across various cell types, with a focus on astrocytes and ECs. Our analysis reveals that EC-specific knockout (KO) of EphA4 triggers significant alterations in astrocyte gene expression and shifts predominate subclusters. We identified six distinct astrocyte clusters (C0-C5) in the damaged cortex including as C0-Mobp/Plp1+; C1-Slc1a3/Clu+; C2-Hbb-bs/Hba-a1/Ndrg2+; C3-GFAP/Lcn2+; C4-Gli3/Mertk+, and C5-Cox8a+. We validate a new Sox9+ cluster expressing Mertk and Gas, which mediates efferocytosis to facilitate apoptotic cell clearance and anti-inflammatory responses. Transcriptomic and CellChat analyses of EC-KO cells highlights upregulation of neuroprotective pathways, including increased amyloid precursor protein (APP) and Gas6. Key pathways predicted to be modulated in astrocytes from EC-KO mice include oxidative phosphorylation and FOXO signaling, mitochondrial dysfunction and ephrin B signaling. Concurrently, metabolic and signaling pathways in endothelial cells-such as ceramide and sphingosine phosphate metabolism and NGF-stimulated transcription-indicate an adaptive response to a metabolically demanding post-injury hypoxic environment. These findings elucidate potential interplay between astrocytic and endothelial responses as well as transcriptional networks underlying cortical tissue damage.

Neuron-Astrocyte Interactions in Aging and Alzheimer's Disease: Dysregulation of Amyloid Precursor Protein

Amyloid precursor protein (APP) is central to Alzheimer's disease (AD) by its role in Aβ build-up and in neuronal and astrocytic malfunction. The major risk factor for late-onset AD is aging, which increases APP processing in both neurons and astrocytes, and consequently increases Aβ production. This focused review covers the subjects of how aging and AD affect APP dynamics within the both cell types and how astrocytes dysfunction can enhance neuroinflammation and neuronal dysfunction and injury. We discuss the interplay between neurons and astrocytes in aging and AD brains, where bi-directional cellular interactions accelerate neurodegeneration.

APP antisense oligonucleotides are effective in rescuing mitochondrial phenotypes in human iPSC-derived trisomy 21 astrocytes

INTRODUCTION

Antisense oligonucleotides (ASOs) have shown promise in reducing amyloid precursor protein (APP) levels in neurons, but their effects in astrocytes, key contributors to neurodegenerative diseases, remain unclear. This study evaluates the efficacy of APP ASOs in astrocytes derived from an individual with Down syndrome (DS), a population at high risk for Alzheimer's disease (AD).

METHODS

Human induced pluripotent stem cells (hiPSCs) from a healthy individual and an individual with DS were differentiated into astrocytes. Astrocytes were treated with APP ASOs for 10 days, and APP levels were quantified. Mitochondrial morphology and superoxide production in DS astrocytes were analyzed using super-resolution and confocal microscopy.

RESULTS

APP ASOs significantly reduced APP levels in astrocytes from both control and DS individuals. In DS astrocytes, treatment restored mitochondrial health, increasing mitochondrial number and size while reducing superoxide production.

DISCUSSION

APP ASOs effectively reduce APP levels and improve mitochondrial health in astrocytes, suggesting their potential as a therapeutic approach for DS and DS-related AD. Further in vivo studies are required to confirm these findings.

HIGHLIGHTS

APP ASOs reduce APP levels in human iPSC-derived astrocytes. APP ASO treatment rescues mitochondrial phenotypes in trisomy 21 astrocytes. This study supports ASOs as a potential therapy for Down syndrome-related Alzheimer's disease.