Endoplasmic Reticulum (ER) stress is the response that occurs after the dysfunction of ER and its structure. Activated UPR triggers a stress response using ER membrane proteins such as PERK, IRE-1, GRP78, ATF5 ve ATF6. Sirtuins are enzymes that carry out post-translational modifications such as deacetylation and ADP-ribosylation. In our previous study, we identified Calreticulin as a SIRT4-interacting protein via mass spectrometry. Calreticulin binds to misfolded proteins, prevents them from leaving ER, which results in the reduction of ER stress. In this study, we aimed to investigate the interaction between SIRT4 and Calreticulin during ER stress in glia cells (IHA-immortalized human astrocytes). To trigger ER stress in glia cells, we first optimized the dose and the duration of the Tunicamycin which is 2.5μg/ml concentration for 16h. SIRT4 gene was silenced with lentiviral particles using 4 MOI (Multiplicity of Infection). In SIRT4-silenced cells, when treated with 2.5μg/ml Tunicamycin for 16h, the increase in the expressions of ATF6, GRP78 and the ratio of spliced/unspliced XBP1 mRNA were reduced. This shows that silencing SIRT4 may decrease ER stress. SIRT4-Calreticulin interaction was shown both in control and ER-stress induced glia cells. Additionally, this interaction did not change with the ER stress. SIRT4 only ADP-ribosylates Calreticulin during ER stress. Normally, SIRT4 ADP-ribosylates and deactivates Calreticulin during ER stress condition. When SIRT4 is silenced, the ADP-ribosylation level of Calreticulin decreases resulting in the activation of Calreticulin and the reduction of ER stress. In summary, SIRT4 inhibitors may be investigated as protective agents or drug candidates in neurodegenerative diseases where ER stress mostly underlies as one of the molecular mechanisms.
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