Transcriptional programs mediating neuronal toxicity and altered glial-neuronal signaling in a Drosophila knock-in tauopathy model.
Hassan BukhariVanitha NithianandamRachel A BattagliaAnthony CicaloSouvarish SarkarAram ComjeanYanhui HuMatthew J LeventhalXianjun DongMel B FeanyPublished in: Genome research (2024)
Missense mutations in the gene encoding the microtubule-associated protein TAU (current and approved symbol is MAPT) cause autosomal dominant forms of frontotemporal dementia. Multiple models of frontotemporal dementia based on transgenic expression of human TAU in experimental model organisms, including Drosophila , have been described. These models replicate key features of the human disease but do not faithfully recreate the genetic context of the human disorder. Here we use CRISPR-Cas-mediated gene editing to model frontotemporal dementia caused by the TAU P301L mutation by creating the orthologous mutation, P251L, in the endogenous Drosophila tau gene. Flies heterozygous or homozygous for Tau P251L display age-dependent neurodegeneration, display metabolic defects, and accumulate DNA damage in affected neurons. To understand the molecular events promoting neuronal dysfunction and death in knock-in flies, we performed single-cell RNA sequencing on approximately 130,000 cells from brains of Tau P251L mutant and control flies. We found that expression of disease-associated mutant tau altered gene expression cell autonomously in all neuronal cell types identified. Gene expression was also altered in glial cells, suggestive of non-cell-autonomous regulation. Cell signaling pathways, including glial-neuronal signaling, were broadly dysregulated as were brain region and cell type-specific protein interaction networks and gene regulatory programs. In summary, we present here a genetic model of tauopathy that faithfully recapitulates the genetic context and phenotypic features of the human disease, and use the results of comprehensive single-cell sequencing analysis to outline pathways of neurotoxicity and highlight the potential role of non-cell-autonomous changes in glia.
Keyphrases
- single cell
- gene expression
- rna seq
- endothelial cells
- cerebrospinal fluid
- dna damage
- genome wide
- cell therapy
- crispr cas
- high throughput
- copy number
- oxidative stress
- dna methylation
- cerebral ischemia
- public health
- signaling pathway
- poor prognosis
- stem cells
- neuropathic pain
- genome editing
- transcription factor
- brain injury
- early onset
- climate change
- dna repair
- resting state
- intellectual disability
- subarachnoid hemorrhage
- drosophila melanogaster
- functional connectivity