OR07-5 PARP1 Contributes to the Glucocorticoid Receptor Transcriptional Response And Influences the Skeletal Muscle Phenotype

Abstract Background NAD+-dependent PARP1 (Poly-(ADP-ribosyl)polymerase 1) generates the post-translational modification ADP-Ribosylation (ADPR). Given PARP1-ADPR determines cellular NAD+ availability, which in turn impacts a range of hormonally governed actions, we sought to identify the molecular roles of PARP1 in relation to glucocorticoids in the endocrine sensitive tissue skeletal muscle. Importance: Activity of the glucocorticoid receptor (GR) is dictated by molecular partners whose actions skew the frequency with which GR produces meaningful transcriptional outcomes. As a result, our molecular understanding of this steroid hormone receptor remains incomplete. Hypothesis PARP1 through ADPR actions impacts skeletal muscle phenotype and co-regulates glucocorticoid-mediated transcriptional responses. Experimental Design: Murine muscle myoblasts (C2C12) or primary murine muscle cultures were treated with PARP inhibitors (PJ34(10uM) or BYK204165(1uM)) or transfected with silencing RNA targeting PARP1. Cells were treated with ± dexamethasone (1uM). Major Results Analysis of differentiating muscle revealed PARP1 and ADPR are dynamic at days 0-5 (measured by Western immunoblot. p<0.001; n=6). Chemical inhibition of PARP1 significantly decreased ADPR (Western immunoblot. p<0.001; n=9) but did not prevent myotube formation. To identify if initial ADPR dynamics held consequence for fully differentiated myotubes, cells were treated with a single dose of the PARP1 inhibitor BYK204165 at induction of differentiation. Myotube lysates were collected 5 days later and were subjected to unlabelled SWATH-MS. This measured the abundance of 180 proteins as significantly different in PARP inhibitor-treated cells (n=7). Analyses of these proteins revealed over-representation of pathways governing muscle development (FDR 8.99-08), contraction (FDR 9.47-08, myofiber assembly (FDR 8.06-05), and energy metabolism (FDR 2.93-06). Indicating PARP1-ADPR regulates myogenesis and plays a role in the striated muscle contractile response. ChIP assays for PARP1 binding in cells showed a (30-fold enrichment ±3.2SEM) at GR response elements and detectable ADPR was reduced when exposed to dexamethasone (Western immunoblot n=5). These data support ADPR as responsive to glucocorticoid exposure and PARP1 influences GR recruitment to the genome. RNAseq of siPARP1 (n=4) versus scrambled myoblasts (n=5) identified differential expression of 165 genes. Gene ontology revealed over-representation in siPARP1 cells of those pathways regulating muscle differentiation, including actin-binding, cytoskeletal structure, and NAD+ binding genes. SiRNA of PARP1 had no influence over the ability of glucocorticoids to activate archetype target genes (DUSP1, MURF1, ATROGIN1 & GILZ), but differentially impacted the expression of 434 other genes. Conclusions PARP1 mediated ADPR is critical to the 'early phase' events of muscle cell differentiation. PARP1 influences short-term transcriptional behaviors of the glucocorticoid receptor; in turn, glucocorticoids themselves impact PARP1-genome interaction events. These findings are important for the understanding of general GR mechanisms and have relevance for the widespread functional decline observed during tissue glucocorticoid excess. Presentation: Saturday, June 11, 2022 12:30 p.m. - 12:45 p.m.