Project description:How cell and tissue identity persist despite constant cell turnover is an important biologic question with cell therapy implications. While many mechanisms exist, we investigated the controls for site-specific gene expression in skin given its diverse structures and functions. For example, the transcriptome of in vivo palmoplantar (i.e. volar) epidermis is globally unique including Keratin 9 (KRT9). While volar fibroblasts have the capacity to induce KRT9 in non-volar keratinocytes, we demonstrate here that volar keratinocytes continue to express KRT9 in vitro solo-cultures. Despite this, KRT9 expression is lost with volar keratinocyte passaging, in spite of stable hypo-methylation of its promoter. Coincident with KRT9 loss is a gain of the primitive Keratin 7 and a signature of dsRNA sensing, including the dsRNA receptor DDX58. Exogenous dsRNA inhibits KRT9 expression in early passage volar keratinocytes or in vivo footpads of wild-type mice. Loss of DDX58 in passaged volar keratinocytes rescues KRT9 and inhibits KRT7 expression. Additionally, DDX58 null mice are resistant to the ability of dsRNA to inhibit KRT9 expression. These results demonstrate that the sensing of dsRNA is critical for loss of cell specific gene expression; our results have important implications of how dsRNA sensing is important outside of immune pathways. Keratinocytes were expanded from the sole of the foot and at passage 4 or 8, RNA was harvested to identify unique transcripts

Project description:In vitro gene signature of volar keratinocytes at early vs late passage

Project description:Loss of SAMHD1 causes chronic activaiton of the MDA5/MAVS dsRNA sensing pathway, only when cGAS/STING signaling is intact.

Project description:Loss of SAMHD1 causes chronic activaiton of the MDA5/MAVS dsRNA sensing pathway, only when cGAS/STING signaling is intact.

Project description:Immunotherapy has revolutionized cancer treatment, but many cancers are not impacted by currently available immunotherapeutic strategies. Here, we investigated inflammatory signaling pathways in neuroblastoma, a classically “cold” pediatric cancer. By testing the functional response of a panel of 20 diverse neuroblastoma cell lines to three different inflammatory stimuli, we found that all cell lines have intact interferon signaling and all but one lack functional cytosolic DNA sensing via cGAS-STING. However, dsRNA sensing via TLR3 was heterogeneous, as was signaling through other dsRNA sensors and TLRs more broadly. Seven cell lines showed robust response to dsRNA, six of which are in the mesenchymal epigenetic state, while all unresponsive cell lines are in the adrenergic state. Genetically switching adrenergic cell lines towards the mesenchymal state fully restored responsiveness. In responsive cells, dsRNA sensing results in the secretion of pro-inflammatory cytokines, enrichment of inflammatory transcriptomic signatures, and increased tumor killing by T cells in vitro. Using single cell RNA sequencing data, we show that human neuroblastoma cells with stronger mesenchymal signatures have a higher basal inflammatory state, demonstrating intra tumoral heterogeneity in inflammatory signaling that has significant implications for immunotherapeutic strategies in this aggressive childhood cancer.

Project description:Immunotherapy has revolutionized cancer treatment, but many cancers are not impacted by currently available immunotherapeutic strategies. Here, we investigated inflammatory signaling pathways in neuroblastoma, a classically “cold” pediatric cancer. By testing the functional response of a panel of 20 diverse neuroblastoma cell lines to three different inflammatory stimuli, we found that all cell lines have intact interferon signaling and all but one lack functional cytosolic DNA sensing via cGAS-STING. However, dsRNA sensing via TLR3 was heterogeneous, as was signaling through other dsRNA sensors and TLRs more broadly. Seven cell lines showed robust response to dsRNA, six of which are in the mesenchymal epigenetic state, while all unresponsive cell lines are in the adrenergic state. Genetically switching adrenergic cell lines towards the mesenchymal state fully restored responsiveness. In responsive cells, dsRNA sensing results in the secretion of pro-inflammatory cytokines, enrichment of inflammatory transcriptomic signatures, and increased tumor killing by T cells in vitro. Using single cell RNA sequencing data, we show that human neuroblastoma cells with stronger mesenchymal signatures have a higher basal inflammatory state, demonstrating intra tumoral heterogeneity in inflammatory signaling that has significant implications for immunotherapeutic strategies in this aggressive childhood cancer.

Project description:We were interested in defining the gene signature of volar skin. Punch biopsies of skin were split into epidermis and dermis after dispase treatment. Epidermis was trypsinized and sorted for alpha 6 integrin positive basal layer keratinocytes We collected RNA from basal layer keratinocytes of soles and backs of feet and submitted for Affymetrix Exon arrays. 2 replicates of each site from distinct human donors were included; total of 4 samples analyzed

Project description:Keratin cytoskeletal proteins are crucial for the maintenance of skin integrity. Mutations in genes coding for K5 and K14 cause the human skin disorder epidermolysis bullosa simplex (EBS) leading to substantial alterations in keratin assembly and collapse of keratin filaments into cytoplasmic protein aggregates. The phenotypic consequences of K5 and K14 mutations comprise fragility of basal keratinocytes and skin blistering upon mild mechanical trauma. Treatment of EBS is only supportive and consists primarily of wound care and avoidance of mechanical stress. Besides symptomatic care, no efficient therapeutic treatment is available for EBS. In the present study, we used patient-derived keratinocytes carrying the most frequent K14.R125C mutation as a reproducible EBS model to understand EBS pathomechanisms and to develop a therapy approach aimed to restore a functional keratin network. Numerous post-translational modifications (PTMs) such as phosphorylation have been reported to occur on keratins, which affect the organization of keratin networks. Whether keratin mutations affect the occurrence of PTMs and thereby keratin aggregation in EBS is yet unknown. We find that the K14.R125C mutation alters keratin and keratin-associated protein PTMs in distinct ways and suggest that disease mutations and altered PTMs aggravate keratin aggregation. We reason that chemical compounds affecting the interplay of mutations and PTMs enable the reformation of a keratin cytoskeleton from aggregates are potential candidates for combating EBS.

Project description:Loss of SAMHD1 causes chronic activaiton of the MDA5/MAVS dsRNA sensing pathway, only when cGAS/STING signaling is intact. Peritoneal macrophages from mutant and control mice were isolated by FACS. Total RNA was subjected to next generation mRNA sequencing.

Project description:Loss of SAMHD1 causes chronic activaiton of the MDA5/MAVS dsRNA sensing pathway, only when cGAS/STING signaling is intact. Peritoneal macrophages from mutant and control mice were isolated by FACS. Total RNA was subjected to next generation mRNA sequencing.