While ADP-ribosyltransferase diphtheria toxin-like 1 (ARTD1, formerly PARP1) and its enzymatic activity have been shown to be important for reprogramming and differentiation of cells, such as during adipogenesis, their role and mechanism in regulating osteoclastogenesis and bone homeostasis are largely unknown. Here, in cell culture-based RANKL-induced osteoclastogenesis models, we show that silencing of ARTD1 or inhibition of its enzymatic activity enhances osteoclast differentiation and function. As a consequence of ARTD1 silencing or inhibition, the recruitment of p65/RelA to the IL-1β promoter, which is associated with transcriptionally active histone marks, IL-1β expression and inflammasome-dependent secretion of IL-1β are enhanced. This subsequently promotes sustained induction of the transcription factor Nfatc1/A and osteoclastogenesis in an autocrine manner via the IL-1 receptor. In vivo, Artd1-deficient mice display significantly decreased bone mass as a consequence of increased osteoclast differentiation. Accordingly, the expression of osteoclast markers is enhanced in mutant compared to wild-type mice. Together, these results indicate that ARTD1 controls osteoclast development and bone remodelling via its enzymatic activity by modulating the epigenetic marks surrounding the IL-1β promoter and expression of IL-1β and subsequently also Nfatc1/A.
Although electrophiles are considered as detrimental to cells, accumulating recent evidence indicates that proliferating non-cancerous and particularly cancerous cells utilize these agents for pro-survival and cell cycle promoting signaling. Hence, the redox shift to mild oxidant release must be balanced by multiple defense mechanisms. Our latest findings demonstrate that cell cycle progression, which dictates oxidant level in stress-free conditions, determines PARP1 transcription. Growth modulating factors regulate CDK4/6-RBs-E2Fs axis. In cells arrested in G1 and G0, RB1-E2F1 and RBL2-E2F4 dimers recruit chromatin remodelers such as HDAC1, SWI/SNF and PRC2 to condense chromatin and turn off transcription. Release of retinoblastoma-based repressive complexes from E2F-dependent gene promoters in response to cell transition to S phase enables transcription of PARP1. This enzyme contributes to repair of oxidative DNA damage by supporting several strand break repair pathways and nucleotide or base excision repair pathways, as well as acting as a co-activator of transcription factors such as NRF2 and HIF1a, which control expression of antioxidant enzymes involved in removal of electrophiles and secondary metabolites. Furthermore, PARP1 is indispensible for transcription of the pro-survival kinases MAP2K6, ERK1/2 and AKT1, and for maintaining MAPK activity by suppressing transcription of the MAPK inhibitor, MPK1. In summary, cell cycle controlled PARP1 transcription helps cells to adapt to a pro-oxidant redox shift.
The action of glucocorticoids in high doses is catabolic, but not much is known about the accompanying effects on antioxidative capacity of the entire body. Animals were treated (or not) with dexamethasone (Dex) 2 mg/kg b.w. d-1 during 5 consecutive days followed by recovery, during which an additional group received 3-hydroxy-3-methylbutyrate (40 mg/kg b.w.). Animals were killed after treatment with Dex, and after 5 days of the recovery period. Dexamethasone treatment decreased appetite almost twofold (from 20 g/day to 10 g/day, P < 0.001). Feed restriction, however, seemed to have only minor impact on the effects observed since body weight loss of pair-fed rats after the 5th day of treatment was only 2% and Dex-treated rats decrease in body weight was 22% (P < 0.05). In turn, wet weight of the soleus muscle (expressed per body weight) did not significantly decrease after Dex treatment, suggesting relative resistance of oxidative type muscles to the catabolic action of dexamethasone. Spleen wet weight expressed per body weight dropped by 65% (P<0.001). Additionally, there was a 46% reduction (P<0.001) of blood glutathione (GSH/Hb), and 36% (P < 0.001) of muscle glutathione (GSH/tissue wet weight). This suggests that dexamethasone directly and/or indirectly impaired antioxidant reactions. This was further confirmed by a significant (49%) decline of SOD-1 activity in erythrocytes isolated from the group treated with dexamethasone. Another index of lipid peroxidation (TBARS) was also significantly increased. Activity of blood plasma CK increased by 73% (P<0.001) in Dex-treated rats, indicating moderate injury of muscle tissue. In conclusion, young growing rats were sensitive to the dosage of dexamethasone, but in contrast to lymphoid tissue, could easily compensate the outcomes of impaired antioxidative defence within 5 days of recovery.
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