GSE21037
GSE GEOL1 retrotransposition in neurons is mediated by MeCP2
Relations
Summary
L1 retrotransposons are active elements in the genome, capable of mobilization in neuronal progenitor cells. Previously, we showed that chromatin remodeling during neuronal differentiation allows for a transient stimulation of L1 transcription. The activity of L1 retrotransposons during brain development can impact gene expression and neuronal function. Here we show that L1 neuronal retrotransposition in rodents is increased in the absence of MeCP2, a protein involved in global methylation and human neurodevelopmental diseases. Using neuronal progenitor cells derived from human induced pluripotent stem cells and human tissues, we revealed that Rett syndrome patients, with MeCP2 mutations, have increased susceptibility for L1 retrotransposition. Our data demonstrate that disease-related genetic mutations can influence the frequency of neuronal L1 retrotransposition, thereby increasing brain-specific genetic mosaicism.
Overall Design
Genetic reprogramming of somatic cells to a pluripotent state (induced pluripotent stem cells, or iPSCs) by over-expression of specific genes has been accomplished for fibroblasts derived from controls and Rett syndrome patients. Different clones from each were compared to respective original fibroblasts and a human embryonic stem cell line. Gene expression profiles measured using human genome Affymetrix Gene Chip arrays were grouped by hierarchical clustering, and correlation coefficients were computed for all pair-wise comparisons.
Analysis (3 steps)
View Data Processing- Gene-level signal estimates were derived from the CEL files by RMA-sketch normalization as a method in the apt-probeset-summarize program (see Yeo et al.
- 2007; PMID 7967047).
- Hierarchical clustering of the full dataset by probeset values was performed by complete linkage using Euclidean distance as a similarity metric in Matlab.