Neuron-Keratinocyte Communication in the Epidermis in Painful Diabetic Neuropathy

Abstract

Painful diabetic neuropathy (PDN) is one of the most common and intractable complications of diabetes. PDN is characterized by small-fiber degeneration, which can progress to complete loss of cutaneous innervation and is accompanied by neuropathic pain. Uncovering the mechanisms underlying axonal degeneration in PDN remains a major challenge to finding effective and disease-modifying therapies. Sensory nerve afferents normally extend into the epidermis in close juxtaposition to keratinocytes but degenerate in diabetic skin. Our aim is to identify the changes in gene expression profiles and the interactions between dorsal root ganglion (DRG) neurons and keratinocytes to explore the mechanisms by which keratinocytes communicate with cutaneous afferents and how this communication impacts axonal degeneration underlying neuropathic pain in PDN. We used a mouse model of PDN where mice were fed a regular diet (RD, 11% fat) or a high-fat diet (HFD, 42% fat) for 10 weeks during which these mice develop glucose intolerance, mechanical allodynia, small fiber neuropathy. Using a single-cell RNA (scRNA-seq) sequencing approach we captured DRG and keratinocytes gene expression profiles and generated interactome maps. scRNA-seq identified both neuronal and non-neuronal clusters and several differentially expressed genes between RD and HFD from the DRG. We were able to identify several clusters of immune cells and keratinocytes at different stages of differentiation. scRNA-seq results were validated using RNAscope on DRG and skin frozen sections. Moreover, we generated interactome maps between DRG neurons and the peripheral cells to highlight ligand-receptor interactions and we looked to identify genes that were differentially expressed in these interactions. Taken together our data highlights the importance of studying neurons in conjunction with the cells in the tissues with which they interact to identify ligand-receptor interactions that may lead to the identification of neuron signaling in a chronic pain state such as PDN. Grant support from 1R01AR77691-01. Painful diabetic neuropathy (PDN) is one of the most common and intractable complications of diabetes. PDN is characterized by small-fiber degeneration, which can progress to complete loss of cutaneous innervation and is accompanied by neuropathic pain. Uncovering the mechanisms underlying axonal degeneration in PDN remains a major challenge to finding effective and disease-modifying therapies. Sensory nerve afferents normally extend into the epidermis in close juxtaposition to keratinocytes but degenerate in diabetic skin. Our aim is to identify the changes in gene expression profiles and the interactions between dorsal root ganglion (DRG) neurons and keratinocytes to explore the mechanisms by which keratinocytes communicate with cutaneous afferents and how this communication impacts axonal degeneration underlying neuropathic pain in PDN. We used a mouse model of PDN where mice were fed a regular diet (RD, 11% fat) or a high-fat diet (HFD, 42% fat) for 10 weeks during which these mice develop glucose intolerance, mechanical allodynia, small fiber neuropathy. Using a single-cell RNA (scRNA-seq) sequencing approach we captured DRG and keratinocytes gene expression profiles and generated interactome maps. scRNA-seq identified both neuronal and non-neuronal clusters and several differentially expressed genes between RD and HFD from the DRG. We were able to identify several clusters of immune cells and keratinocytes at different stages of differentiation. scRNA-seq results were validated using RNAscope on DRG and skin frozen sections. Moreover, we generated interactome maps between DRG neurons and the peripheral cells to highlight ligand-receptor interactions and we looked to identify genes that were differentially expressed in these interactions. Taken together our data highlights the importance of studying neurons in conjunction with the cells in the tissues with which they interact to identify ligand-receptor interactions that may lead to the identification of neuron signaling in a chronic pain state such as PDN. Grant support from 1R01AR77691-01.