Programmed Genomic Instability Regulates Neural Transdifferentiation of Human Microvascular Pericytes

Transdifferentiation describes transformation in vivo of specialized cells from one lineage into another. While there is extensive literature on forced induction of lineage reprogramming in vitro, endogenous mechanisms that govern transdifferentiation remain largely unknown. The observation that human microvascular pericytes transdifferentiate into interneurons provided an opportunity to explore the endogenous molecular basis for lineage reprogramming. We show that abrupt destabilization of the higher-order chromatin topology that chaperones lineage memory of pericytes is driven by transient global transcriptional arrest. This leads within minutes to localized decompression of the repressed competing higher-order chromatin topology and expression of pro-neural genes. Transition to neural lineage is completed by probabilistic induction of R-loops in key myogenic loci upon re-initiation of RNA polymerase activity, leading to depletion of the myogenic transcriptome and emergence of the neurogenic transcriptome. Findings suggest that the global transcriptional landscape not only shapes the functional cellular identity of pericytes, but also stabilises lineage memory by silencing the competing neural program within a repressed chromatin state.

Keywords: Transdifferrentiation, pericytes, neuron, chromatin topology.

Suggested Citation: Suggested Citation

Rezaei-Lotfi, saba and Vujovic, Filip and Simonian, Mary and Hunter, Neil and M Farahani, Ramin, Programmed Genomic Instability Regulates Neural Transdifferentiation of Human Microvascular Pericytes. Available at SSRN: https://ssrn.com/abstract=3712601 or http://dx.doi.org/10.2139/ssrn.3712601

This version of the paper has not been formally peer reviewed.