Project description:Glial fibrillary acidic protein (GFAP) is a type-3 intermediate filament protein mainly expressed in astrocytes in the central nervous system. Mutations in GFAP cause Alexander Disease (AxD), a rare and fatal neurological disorder. How exactly mutant GFAP eventually leads to white and grey matter deterioration in AxD remains unknown. GFAP is also expressed in radial glial cells, which are neural stem cells in the developing brain. Here, we used AxD patient-derived induced pluripotent stem cells (iPSCs) to explore the impact of mutant GFAP during neurodifferentiation. Our results show that GFAP is already expressed in iPSCs. Moreover, we have found that mutations in GFAP can severely affect neural organoid development through altering lineage commitment in embryoid bodies. Together, these results support a key role for GFAP as an early modulator of neurodevelopment.

Project description:Alexander disease (AxD) is a fatal neurological illness characterized by white-matter degeneration and formation of Rosenthal fibers, which contain glial fibrillary acidic protein (GFAP) as astrocytic inclusion. AxD is mainly caused by a gene mutation encoding GFAP, although the underlying pathomechanism remains unclear.

Project description:Alexander disease (AxD) is a rare, severe neurodegenerative disorder caused by mutations in the glial fibrillary acidic protein (GFAP). While the exact disease mechanism remains unknown, existing studies suggest that the mutant GFAP influences many cellular processes, including cytoskeleton stability, mechanosensing, cell energetics, and proteasome function. While most studies have primarily focused on GFAP-expressing astrocytes, this protein is also expressed by radial glia and neural progenitor cells, prompting questions about the impact of GFAP mutations on central nervous system (CNS) development. In this study, we present an intriguing observation of an impaired differentiation of astrocytes and neurons in co-cultures of astrocytes and neurons, as well as in brain organoids, both generated from patient-derived induced pluripotent stem (iPS) cells with a GFAP (R239C) mutation. Leveraging single-cell RNA sequencing (scRNA-seq), we identified distinct cell populations and transcriptomic changes between the GFAP mutant cells and an isogenic corrected control. These findings are supported with immunocytochemistry and proteomics. In co-cultures, the AxD mutation resulted in an increased abundance of immature cells, while in organoids, we observed an altered cell differentiation and reduced abundance of astrocytes. Additionally, gene expression analysis associated the AxD mutation with increased stress susceptibility, cytoskeletal abnormalities, and altered extracellular matrix and cell-cell communication patterns. Overall, our results suggest the possibility of a faulty differentiation in human iPS cell-derived models of AxD, opening new avenues for AxD research.

Project description:Alexander disease is a rare neurodegenerative disorder caused by mutations in the gene for glial fibrillary acidic protein (GFAP), the major intermediate filament of astrocytes in the central nervous system. GFAP mutation causes a toxic gain-of-function and protein aggregation, ultimately leading to gliosis, astrocyte dysfunction, and neurodegeneration. To better understand the disease process, a rat model has been generated to mimic the common R239H mutation observed in the human disease (R237H in the rat). This study focuses on hippocampus, a brain region with a heavy burden of pathology, to determine the impact of GFAP mutation at presymptomatic (3 weeks of age) and severe stages ( 8 weeks of age) of disease. Transcription profiling shows progressive neuroinflammation and neurodegeneration.

Project description:Chromosomes and genes are non-randomly arranged within the mammalian cell nucleus. Clustering of genes is of great significance in transcriptional regulation. However, the relevance of gene clustering in their expression during differentiation of neural precursor cells (NPCs) into astrocytes remains unclear. We performed a genome-wide enhanced circular chromosomal conformation capture (e4C) to screen genes associated with an astrocyte-specific gene, glial fibrillary acidic protein (Gfap), during astrocyte differentiation. We identified 13 genes that were specifically associated with Gfap and expressed in NPC-derived astrocytes. These results provide evidence for functional significance of gene clustering in transcriptional regulation during NPCs differentiation. comparison of NPCs vs LIF+ vs LIF- cells.

Project description:Chromosomes and genes are non-randomly arranged within the mammalian cell nucleus. Clustering of genes is of great significance in transcriptional regulation. However, the relevance of gene clustering in their expression during differentiation of neural precursor cells (NPCs) into astrocytes remains unclear. We performed a genome-wide enhanced circular chromosomal conformation capture (e4C) to screen genes associated with an astrocyte-specific gene, glial fibrillary acidic protein (Gfap), during astrocyte differentiation. We identified 13 genes that were specifically associated with Gfap and expressed in NPC-derived astrocytes. These results provide evidence for functional significance of gene clustering in transcriptional regulation during NPCs differentiation.

Project description:Olfactory bulb transcript levels for GFAP transgenic mice compared to wildtype at 3wks and 4mos Keywords = GFAP Keywords = Rosenthal fibers Keywords = Alexander disease Keywords: other

Project description:Background: Neuronal and glial differentiation in the murine hypothalamus is not complete at birth, but continues over the first two weeks postnatally. Nutritional status and Leptin deficiency can influence the maturation of neuronal projections and glial patterns, and hypothalamic gliosis occurs in mouse models of obesity. Gnasxl constitutes an alternative transcript of the genomically imprinted Gnas locus and encodes a variant of the signalling protein Gαs, termed XLαs, which is expressed in defined areas of the hypothalamus. Gnasxl-deficient mice show postnatal growth retardation and undernutrition, while surviving adults remain lean and hypermetabolic with increased sympathetic nervous system (SNS) activity. Effects of this knock-out on the hypothalamic neural network have not yet been investigated. Results: RNAseq analysis for gene expression changes in hypothalami of Gnasxl-deficient mice indicated Glial fibrillary acid protein (Gfap) expression to be significantly down-regulated in adult samples. Histological analysis confirmed a reduction in Gfap-positive glial cell numbers specifically in the hypothalamus. This reduction was observed in adult tissue samples, whereas no difference was found in hypothalami of postnatal stages, indicating an adaptation in adult Gnasxl-deficient mice to their earlier growth phenotype and hypermetabolism. Especially noticeable was a loss of many Gfap-positive α-tanycytes and their processes, which form part of the ependymal layer that lines the medial and dorsal regions of the 3rd ventricle, while β-tanycytes along the median eminence (ME) and infundibular recesses appeared unaffected. This was accompanied by local reductions in Vimentin and Nestin expression. Hypothalamic RNA levels of glial solute transporters were, unchanged, indicating a potential compensatory up-regulation in the remaining astrocytes and tanycytes. Conclusion: Gnasxl deficiency does not directly affect glial development in the hypothalamus, since it is expressed in neurons, and Gfap-positive astrocytes and tanycytes appear normal during early postnatal stages. The loss of Gfap-expressing cells in adult hypothalami appears to be a consequence of the postnatal undernutrition, hypoglycaemia and continued hypermetabolism and leanness of Gnasxl-deficient mice, which contrasts with gliosis observed in obese mouse models. Since α-tanycytes also function as adult neural progenitor cells, these findings might indicate further developmental abnormalities in hypothalamic formations of Gnasxl-deficient mice, potentially including neuronal composition and projections. 6 wildtype and 6 Gnasxlm+/p- RNA isolates were used, which were pooled in pairs in equal concentrations prior to rRNA removal using the RiboMinus kit (Life Technologies)

Project description:Gene expression analysis was performed in mouse models with Alexander disease associated GFAP mutations

Project description:In this work we used our zebrafish model of Alexander Desease (AxD), aiming at unraveling the main pathways involved in AxD pathogenesis performing the first multi-omics analysis on a in vivo model of AxD. The obtained results have been functionally validated and they open the way to further investigation about the involvement of metabolic processes in AxD.