Estrogen Differentially Regulates Protein Abundance in Exosomes Released From Immortalized Kisspeptin Neurons in Vitro

Abstract

Estrogen (E2) is essential for multiple physiological effects in females, ensuring maximum reproductive fitness and maintaining skeletal homeostasis. E2 has been shown to stimulate cancellous bone formation via activation of estrogen receptor alpha (ERα), an effect widely accepted to be mediated directly at bone. A recent landmark study (Herber et al., Nat Commun 2019) demonstrated bone density increases in female mice harboring ERα-deletions specifically in arcuate Kiss-1 neurons. In this study, bone from transgenic females showed higher osteoblast functioning and increases in the expression of sp7 and runx2, positing a direct neural-bone regulatory axis altered by circulating E2 acting in brain. Our laboratory has used two immortalized Kisspeptin (Kiss1)-expressing and -secreting cell lines, KTaR-1 (representative of female arcuate Kiss-1 neurons) and KTaV-3 cells (representative of female AVPV Kiss-1 neurons) as models to explore the role of Kiss-1 in multiple physiological regulatory contexts. We recently determined that factors in the media of female ARC-derived KTaR-1 cells can affect parameters of osteoblast function in vitro, including increases in sp7 and runx2 expression, and formation of bone matrix (evaluated by Alizarin Red assay). Exposure of canine osteosarcoma cells to conditioned media from KTaR-1 cells led to increases in sp7 expression in an E2-dependent manner, and 24h E2-deprivation of these neurons stimulated secretion of osteogenic factors. In this current study, we have used LCMS-MS proteomic analysis to determine the contents of exosomes isolated from Kisspeptin neurons under varying E2 exposure conditions in vitro. Preliminary results reveal ~150-170 proteins up-regulated by E2 exposure and ~200-220 proteins downregulated by E2 exposure in exosomes of both KTaR-1 and KTaV-3 Kisspeptin neurons. Estrogen-regulated Kiss-1 exosomal proteins include several candidates involved in bone remodeling (pentraxin, osteonectin, osteoclast-stimulating factor-1) and neuronal synaptic plasticity and signaling (annexins, semaphorins, connexins). Current work is exploring the effects of exposure of purified exosomes on morphology and gene expression in immortalized GnRH neurons and osteoblasts. While further study is required, initial results suggest that exosomes may represent additional cellular communication pathways utilized by Kisspeptin neurons to elicit changes in brain and bone.