Ring1B/Rnf2 is a RING finger protein member of the Polycomb group (PcG) of proteins, which form chromatinmodifying complexes essential for embryonic development and stem cell renewal and which are commonly deregulated in cancer. Ring1B/Rnf2 is a ubiquitin E3 ligase that catalyzes the monoubiquitylation of the histone H2A, one of the histone modifications needed for the transcriptional repression activity of the PcG of proteins. Ring1B/Rnf2 was shown to be part of two complexes, the PRC1 PcG complex and the E2F6.com-1 complex, which also contains non-PcG members, thus raising the prospect for additional Ring1B/Rnf2 partners and functions extending beyond the PcG. Here we used a high throughput proteomics approach based on the single step purification, using streptavidin beads, of in vivo biotinylated Ring1B/Rnf2 and associated proteins from a nuclear extract from erythroid cells and their identification by mass spectrometry. About 50 proteins were confidently identified of which 20 had not been identified previously as subunits of Ring1B/Rnf2 complexes. We found that histone demethylases LSD1/Aof2 and Fbxl10/Jhdm1B, casein kinase subunits, and the BcoR corepressor were among the new interactors identified. We also isolated an Fbxl10/Jhdm1B complex by biotinylation tagging to identify shared interacting partners with Ring1B/Rnf2. In this way we identified a novel Ring1B-Fbxl10 complex that also includes Bcl6 corepressor (BcoR), CK2␣, Skp1, and Nspc1/Pcgf1. The putative enzymatic activities and protein interaction and chromatin binding motifs present in this novel Ring1B-Fbxl10 complex potentially provide additional mechanisms for chromatin modification/recruitment to chromatin and more evidence for Ring1B/Rnf2 activities beyond those typically associated with PcG function. Lastly this work demonstrates the utility of biotinylation tagging for the rapid characterization of complex mixtures of multiprotein complexes achieved through the iterative use of this simple yet high throughput proteomics approach.Molecular & Cellular Proteomics 6:820 -834, 2007.In multicellular organisms, cell identity is controlled, at least in part, by epigenetic events, including DNA methylation and post-translational modifications of histones that lead to chromatin structure regulation (1). These modifications are carried out by protein complexes recruited through DNA sequences and/or specific recognition of modified histones. The Polycomb group (PcG) 1 of proteins, first identified genetically as regulators of Hox genes in the fly Drosophila melanogaster (for a review, see Ref. 2), is an example of such a complex. PcG functions cover many aspects of vertebrate development and tissue homeostasis by preventing the inappropriate activation of many transcription factor-coding genes and other genes involved in cell signaling and cell proliferation (3-7). Currently it is believed that PcG proteins play a role in setting the balance between proliferation and differentiation in normal development. Deregulation of PcG proteins disrupts such a ba...
Dietary restriction (DR) lowers mitochondrial reactive oxygen species (ROS) generation and oxidative damage and increases maximum longevity in rodents. Protein restriction (PR) or methionine restriction (MetR), but not lipid or carbohydrate restriction, also cause those kinds of changes. However, previous experiments of MetR were performed only at 80% MetR, and substituting dietary methionine with glutamate in the diet. In order to clarify if MetR can be responsible for the lowered ROS production and oxidative stress induced by standard (40%) DR, Wistar rats were subjected to 40% or 80% MetR without changing other dietary components. It was found that both 40% and 80% MetR decrease mitochondrial ROS generation and percent free radical leak in rat liver mitochondria, similarly to what has been previously observed in 40% PR and 40% DR. The concentration of complexes I and III, apoptosis inducing factor, oxidative damage to mitochondrial DNA, five different markers of protein oxidation, glycoxidation or lipoxidation and fatty acid unsaturation were also lowered. The results show that 40% isocaloric MetR is enough to decrease ROS production and oxidative stress in rat liver. This suggests that the lowered intake of methionine is responsible for the decrease in oxidative stress observed in DR.
Eighty percent dietary methionine restriction (MetR) in rodents (without calorie restriction), like dietary restriction (DR), increases maximum longevity and strongly decreases mitochondrial reactive oxygen species (ROS) production and oxidative stress. Eighty percent MetR also lowers the degree of membrane fatty acid unsaturation in rat liver. Mitochondrial ROS generation and the degree of fatty acid unsaturation are the only two known factors linking oxidative stress with longevity in vertebrates. However, it is unknown whether 40% MetR, the relevant methionine restriction degree to clarify the mechanisms of action of standard (40%) DR can reproduce these effects in mitochondria from vital tissues of strong relevance for aging. Here we study the effect of 40% MetR on ROS production and oxidative stress in rat brain and kidney mitochondria. Male Wistar rats were fed during 7 weeks semipurified diets differing only in their methionine content: control or 40% MetR diets. It was found that 40% MetR decreases mitochondrial ROS production and percent free radical leak (by 62-71%) at complex I during forward (but not during reverse) electron flow in both brain and kidney mitochondria, increases the oxidative phosphorylation capacity of brain mitochondria, lowers oxidative damage to kidney mitochondrial DNA, and decreases specific markers of mitochondrial protein oxidation, lipoxidation, and glycoxidation in both tissues. Forty percent MetR also decreased the amount of respiratory complexes I, III, and IV and apoptosis-inducing factor (AIF) in brain mitochondria and complex IV in kidney mitochondria, without changing the degree of mitochondrial membrane fatty acid unsaturation. Forty percent MetR, differing from 80% MetR, did not inhibit the increase in rat body weight. These changes are very similar to the ones previously found during dietary and protein restriction in rats. We conclude that methionine is the only dietary factor responsible for the decrease in mitochondrial ROS production and oxidative stress, and likely for part of the longevity extension effect, occurring in DR.
Methionine restriction without energy restriction increases, like caloric restriction, maximum longevity in rodents. Previous studies have shown that methionine restriction strongly decreases mitochondrial reactive oxygen species (ROS) production and oxidative damage to mitochondrial DNA, lowers membrane unsaturation, and decreases five different markers of protein oxidation in rat heart and liver mitochondria. It is unknown whether methionine supplementation in the diet can induce opposite changes, which is also interesting because excessive dietary methionine is hepatotoxic and induces cardiovascular alterations. Because the detailed mechanisms of methionine-related hepatotoxicity and cardiovascular toxicity are poorly understood and today many Western human populations consume levels of dietary protein (and thus, methionine) 2-3.3 fold higher than the average adult requirement, in the present experiment we analyze the effect of a methionine supplemented diet on mitochondrial ROS production and oxidative damage in the rat liver and heart mitochondria. In this investigation male Wistar rats were fed either a L-methionine-supplemented (2.5 g/100 g) diet without changing any other dietary components or a control (0.86 g/100 g) diet for 7 weeks. It was found that methionine supplementation increased mitochondrial ROS generation and percent free radical leak in rat liver mitochondria but not in rat heart. In agreement with these data oxidative damage to mitochondrial DNA increased only in rat liver, but no changes were observed in five different markers of protein oxidation in both organs. The content of mitochondrial respiratory chain complexes and AIF (apoptosis inducing factor) did not change after the dietary supplementation while fatty acid unsaturation decreased. Methionine, S-AdenosylMethionine and S-AdenosylHomocysteine concentration increased in both organs in the supplemented group. These results show that methionine supplementation in the diet specifically increases mitochondrial ROS production and mitochondrial DNA oxidative damage in rat liver mitochondria offering a plausible mechanism for its hepatotoxicity.
Previous studies have shown that the decrease in mitochondrial reactive oxygen species (mitROS) generation and oxidative damage to mitochondrial DNA (mtDNA) that occurs during life extending dietary restriction also occurs during protein or methionine restriction, whereas it does not take place during carbohydrate or lipid restriction. In order to study the possible effects of other amino acids, in this investigation all the dietary amino acids, except methionine, were restricted by 40% in male Wistar rats (RESTAAS group). After 6-7 weeks, experimental parameters were measured in the liver. Amino acid restriction did not change the levels of the methionine metabolites S-adenosylmethionine and S-adenosylhomocysteine, mitochondrial oxygen consumption and ROS generation, oxidative damage to mtDNA, amounts of the respiratory complexes I-IV, and the mitochondrial biogenesis factors PGC-1alpha and NRF-2. On the other hand, adenylate energy charge, mitochondrial protein oxidation, lipooxidation and glycooxidation, the degree of mitochondrial fatty acid unsaturation, and the amount of the apoptosis inducing factor (AIF) were decreased in the RESTAAS group. Amino acid restriction also increased SIRT1 protein. These results, together with previous ones, strongly suggest that the decrease in mitROS generation and oxidative damage to mtDNA that occurs during dietary restriction is due to restriction of a single aminoacid: methionine. They also show for the first time that restriction of dietary amino acids different from methionine decreases mitochondrial protein oxidative modification and AIF, and increases SIRT1, in rat liver.
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