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Mitochondria are involved in the aging processes that ultimately lead to neurodegeneration and the development of Alzheimer’s disease (AD). A healthy lifestyle, including a diet rich in antioxidants and polyphenols, represents one strategy to protect the brain and to prevent neurodegeneration. We recently reported that a stabilized hexanic rice bran extract (RBE) rich in vitamin E and polyphenols (but unsuitable for human consumption) has beneficial effects on mitochondrial function in vitro and in vivo (doi:10.1016/j.phrs.2013.06.008, 10.3233/JAD-132084). To enable the use of RBE as food additive, a stabilized ethanolic extract has been produced. Here, we compare the vitamin E profiles of both extracts and their effects on mitochondrial function (ATP concentrations, mitochondrial membrane potential, mitochondrial respiration and mitochondrial biogenesis) in PC12 cells. We found that vitamin E contents and the effects of both RBE on mitochondrial function were similar. Furthermore, we aimed to identify components responsible for the mitochondria-protective effects of RBE, but could not achieve a conclusive result. α-Tocotrienol and possibly also γ-tocotrienol, α-tocopherol and δ-tocopherol might be involved, but hitherto unknown components of RBE or a synergistic effect of various components might also play a role in mediating RBE’s beneficial effects on mitochondrial function.
Dissecting the complexities of mammalian heart development and regenerative capacity require thorough understanding of the underlying molecular mechanisms through the expression pattern of proteins and post-translational modifications. To obtain insights intoactivated signaling pathways that control the cellular phenotype during postnatal heart development, we generated a comprehensive map of phosphorylation sites. In total we identified 21,261 phosphorylation sites and 8985 proteins in developing mouse hearts by mass spectrometry. The in-vivo SILAC (stable isotope labeling of amino acids in cell culture) approach allowed robust quantification of phosphorylation sites and proteins, which are regulated during heart development. We found several activated pathways involved in cell cycle regulation and detected numerous kinases and transcription factors to be regulated on protein and phosphopeptide level. Most strikingly, we identified a novel mitochondrial protein, known previously as Perm1, as a highly phosphorylated factor regulated during heart development. We renamed Perm1 as MICOS complex subunit Mic85 since it shows robust physical interaction with MICOS complex subunits, including Mitofilin (Mic60), Chchd3 (Mic19), Chchd6 (Mic25) and the outer membrane protein Samm50. Moreover, Mic85 is localized to the mitochondrial inner membrane facing the intermembrane space and the dynamics of Mic85 protein expression is regulated by the ubiquitin-proteasomal system through phosphorylation of casein kinase 2 on its PEST motif. Silencing of Mic85 in cultured neonatal cardiomyocytes impairs mitochondrial morphology and compromises oxidative capacity. Our findings support a clear role for Mic85 in the maintenance of mitochondrial architecture and in its contribution to enhanced energetics during developing and adult mouse cardiomyocytes. The transgenic Mic85 knockout mouse generated with a GFP knock-in will support future in vivo investigations on the integrity of mitochondria and the function of Mic85 in cardiac development.
In eukaryotic cells, mitochondria host ancient essential bioenergetic and biosynthetic pathways. LYR (leucine/tyrosine/arginine) motif proteins (LYRMs) of the Complex1_LYR-like superfamily interact with protein complexes of bacterial origin. Many LYR proteins function as extra subunits (LYRM3 and LYRM6) or novel assembly factors (LYRM7, LYRM8, ACN9 and FMC1) of the oxidative phosphorylation (OXPHOS) core complexes. Structural insights into complex I accessory subunits LYRM6 and LYRM3 have been provided by analyses of EM and X-ray structures of complex I from bovine and the yeast Yarrowia lipolytica, respectively. Combined structural and biochemical studies revealed that LYRM6 resides at the matrix arm close to the ubiquinone reduction site. For LYRM3, a position at the distal proton-pumping membrane arm facing the matrix space is suggested. Both LYRMs are supposed to anchor an acyl-carrier protein (ACPM) independently to complex I. The function of this duplicated protein interaction of ACPM with respiratory complex I is still unknown. Analysis of protein-protein interaction screens, genetic analyses and predicted multi-domain LYRMs offer further clues on an interaction network and adaptor-like function of LYR proteins in mitochondria.