AIMS: Sirtuins connect energy generation and metabolic stress to the cellular acetylome. Currently, only the mitochondrial sirtuins (SIRT3-5) and SIRT1 have been shown to direct mitochondrial function; however, Aims: NAD-dependent protein deacetylase sirtuin-2 (SIRT2), the primary cytoplasmic sirtuin, is not yet reported to associate with mitochondria. RESULTS: This study revealed a novel physiological function of SIRT2: the regulation of mitochondrial function. First, the acetylation of several metabolic mitochondrial proteins was found to be altered in Sirt2-deficient mice, which was, subsequently, validated by immunoprecipitation experiments in which the acetylated mitochondrial proteins directly interacted with SIRT2. Moreover, immuno-gold electron microscopic images of mouse brains showed that SIRT2 associates with the inner mitochondrial membrane in central nervous system cells. The loss of Sirt2 increased oxidative stress, decreased adenosine triphosphate levels, and altered mitochondrial morphology at the cellular and tissue (i.e., brain) level. Furthermore, the autophagic/mitophagic processes were dysregulated in Sirt2-deficient neurons and mouse embryonic fibroblasts. INNOVATION: For the first time it is shown that SIRT2 directs mitochondrial metabolism. CONCLUSION: Together, these findings support that SIRT2 functions as a mitochondrial sirtuin, as well as a regulator of autophagy/mitophagy to maintain mitochondrial biology, thus facilitating cell survival. Antioxid. Redox Signal. 26, 849-863.
AIMS: Sirtuins connect energy generation and metabolic stress to the cellular acetylome. Currently, only the mitochondrial sirtuins (SIRT3-5) and SIRT1 have been shown to direct mitochondrial function; however, Aims: NAD-dependent protein deacetylase sirtuin-2 (SIRT2), the primary cytoplasmic sirtuin, is not yet reported to associate with mitochondria. RESULTS: This study revealed a novel physiological function of SIRT2: the regulation of mitochondrial function. First, the acetylation of several metabolic mitochondrial proteins was found to be altered in Sirt2-deficientmice, which was, subsequently, validated by immunoprecipitation experiments in which the acetylated mitochondrial proteins directly interacted with SIRT2. Moreover, immuno-gold electron microscopic images of mouse brains showed that SIRT2 associates with the inner mitochondrial membrane in central nervous system cells. The loss of Sirt2 increased oxidative stress, decreased adenosine triphosphate levels, and altered mitochondrial morphology at the cellular and tissue (i.e., brain) level. Furthermore, the autophagic/mitophagic processes were dysregulated in Sirt2-deficient neurons and mouse embryonic fibroblasts. INNOVATION: For the first time it is shown that SIRT2 directs mitochondrial metabolism. CONCLUSION: Together, these findings support that SIRT2 functions as a mitochondrial sirtuin, as well as a regulator of autophagy/mitophagy to maintain mitochondrial biology, thus facilitating cell survival. Antioxid. Redox Signal. 26, 849-863.
Authors: Vinodkumar B Pillai; Sadhana Samant; Nagalingam R Sundaresan; Hariharasundaram Raghuraman; Gene Kim; Michael Y Bonner; Jack L Arbiser; Douglas I Walker; Dean P Jones; David Gius; Mahesh P Gupta Journal: Nat Commun Date: 2015-04-14 Impact factor: 14.919
Authors: Carlos Marques Palmeira; João Soeiro Teodoro; João Alves Amorim; Clemens Steegborn; David A Sinclair; Anabela Pinto Rolo Journal: Free Radic Biol Med Date: 2019-07-24 Impact factor: 7.376
Authors: Robert A Kloner; David A Brown; Marie Csete; Wangde Dai; James M Downey; Roberta A Gottlieb; Sharon L Hale; Jianru Shi Journal: Nat Rev Cardiol Date: 2017-07-27 Impact factor: 32.419
Authors: Yahyah Aman; Johannes Frank; Sofie Hindkjær Lautrup; Adrian Matysek; Zhangming Niu; Guang Yang; Liu Shi; Linda H Bergersen; Jon Storm-Mathisen; Lene J Rasmussen; Vilhelm A Bohr; Hilde Nilsen; Evandro F Fang Journal: Mech Ageing Dev Date: 2019-12-05 Impact factor: 5.432