Background The neuropeptide calcitonin gene–related peptide (CGRP) plays a key role in migraine. CGRP gene expression involves an enhancer that is active in neurons, yet inactive in glia. In this report, we analyze epigenetic modifications that allow enhancer activation in glia. Methods DNA methylation and histone acetylation states were measured in rat and human-model cell lines and primary cultures of rat trigeminal ganglia glia. The functional consequence of altering the chromatin state was determined by quantitative measurements of both calcitonin (CT) and CGRP mRNAs. Results A hypermethylated CpG island flanking the enhancer was identified in glia and non-expressing cell lines. In addition, the chromatin was hypoacetylated. Treatment with the DNA methylation inhibitor 5-aza-2′-deoxycytidine induced CT mRNA ~30-fold in glial cultures. Treatment with a histone deacetylase inhibitor alone had little effect; however, the combination of inhibitors yielded a synergistic ~80-fold increase in CT and ~threefold increase in CGRP mRNA. Treated glia contained CT precursor (pro-CT) immunoreactivity. Conclusions Epigenetic modulation is sufficient to induce the CGRP gene in glia. Because the CGRP gene is systemically activated by inflammatory conditions, this suggests that glial pro-CT may be an unexplored biomarker during migraine.
Non-neurogenic cell types, such as cortical astroglia and fibroblasts, can be directly converted into neurons by the overexpression of defined transcription factors. Normally, the cellular phenotype of such differentiated cells is remarkably stable and resists direct cell transdifferentiation. Here we show that the Ink4a/Arf (also known as Cdkn2a) locus is a developmental barrier to direct neuronal transdifferentiation induced by transcription factor overexpression. With serial passage in vitro, wild-type postnatal cortical astroglia become progressively resistant to Dlx2-induced neuronal transdifferentiation. In contrast, the neurogenic competence of Ink4a/Arfdeficient astroglia is both greatly increased and does not diminish through serial cell culture passage. Electrophysiological analysis further demonstrates the neuronal identity of cells induced from Ink4a/Arf-null astroglia, and short hairpin RNA-mediated acute knockdown of p16Ink4a and p19Arf p16Ink4a and p19 Arf indicates that these gene products function postnatally as a barrier to cellular transdifferentiation. Finally, we found that mouse fibroblasts deficient for Ink4a/Arf also exhibit greatly enhanced transcription factorinduced neuronal induction. These data indicate that Ink4a/Arf is a potent barrier to direct neuronal transdifferentiation and further suggest that this locus functions normally in the progressive developmental restriction of postnatal astrocytes.
The neuropeptide calcitonin gene-related peptide (CGRP) is a key player in migraine. However, the transcription factors controlling CGRP expression in the migraine-relevant trigeminal ganglion neurons are unknown. Previous in vitro studies demonstrated that upstream stimulatory factor (USF) 1 and USF2 bind to the CGRP neuroendocrine-specific 18-bp enhancer, yet discrepant overexpression results in cell lines, and the ubiquitous nature of the USF cast doubts about its role. To test the functional role of USF, we first demonstrated that small interfering RNAs directed against USF1 and USF2 reduced endogenous CGRP RNA and preferentially targeted the USF binding site at the 18-bp enhancer in the neuronal-like CA77 cell line. In cultured rat trigeminal ganglion neurons, knockdown of either USF1 or USF2 reduced CGRP promoter activity. Conversely, overexpression of USF1 or USF2 increased promoter activity. The activation was even greater upon cotransfection with an upstream activator of mitogen-activated protein kinases and was synergistic in a heterologous cell line. To begin to address the paradox of how ubiquitous USF proteins might direct neuronal-specific activity, we examined USF expression and used a series of adenoviral reporters in the cultured ganglia. Unexpectedly, there was more intense USF immunostaining in neurons than nonneuronal cells. Importantly, the 18-bp USF enhancer driving a minimal promoter was sufficient for neuronal specificity, although it was not the only site that directed neuronal expression. These results demonstrate that USF1 and USF2 are important contributors to neuronal-specific and mitogen-activated protein kinase regulation of the CGRP gene in trigeminal ganglion neurons.
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