Poly ADP-ribosylation of proteins. Processivity of a post-translational modification

The nuclear enzyme poly(ADP-ribose) polymerase (EC 2.4.2.30) participates in DNA excision repair by post-translational selfmodification ("automodification") and the modification of other chromatin proteins ("heteromodification") with ADP-ribose polymers. We have studied the molecular mechanism of these reactions in a reconstituted in vitro system. After activation by DNA, poly(ADP-ribose) polymerase produces polymers with a distinct size pattern. These polymers are attached to a small subfraction of enzyme molecules. As the reaction progresses, more enzyme molecules are recruited for modification with an identical polymer size pattern. Likewise, the auto- and heteromodification reaction in nucleosomal core particles involves the consecutive addition of a highly conserved polymer size pattern to the acceptor proteins. Thus, a highly conserved polymer size pattern may constitute the molecular signal priming chromatin proteins for a role in DNA excision repair in vivo. The priming reaction is processive.     

Monitoring post-translational modification of proteins with allosteric ribozymes

An allosteric hammerhead ribozyme activated specifically by the unphosphorylated form of the protein kinase ERK2 was created through a rational design strategy that relies on molecular recognition of ERK2 to decrease the formation of an alternate, inactive ribozyme conformer. Neither closely related mitogen-activated protein kinases (MAPKs) nor the phosphorylated form of ERK2 induced ribozyme activity. The ribozyme quantitatively detected ERK2 added to mammalian cell lysates and also functioned quantitatively in a multiplexed solution-phase assay. This same strategy was used to construct a second ribozyme selectively activated by the phosphorylated (active) form of ERK2. This approach is generally applicable to the development of ribozymes capable of monitoring post-translational modification of specific proteins.     

Site-selective post-translational modification of proteins using an unnatural amino acid, 3-azidotyrosine

An efficient method for site-selective modification of proteins using an unnatural amino acid, 3-azidotyrosine has been developed. This method utilizes the yeast amber suppressor tRNA(Tyr)/mutated tyrosyl-tRNA synthetase pair as a carrier of 3-azidotyrosine in an Escherichia coli cell-free translation system, and triarylphosphine derivatives for specific modification of the azido group. Using rat calmodulin (CaM) as a model protein, we prepared several unnatural CaM molecules, each carrying an azidotyrosine at predetermined positions 72, 78, 80 or 100, respectively. Post-translational modification of these proteins with a conjugate compound of triarylphosphine and biotin produced site-selectively biotinylated CaM molecules. Reaction efficiency was similar among these proteins irrespective of the position of introduction, and site-specificity of biotinylation was confirmed using mass spectrometry. In addition, CBP-binding activity of the biotinylated CaMs was confirmed to be similar to that of wild-type CaM. This method is intrinsically versatile in that it should be easily applicable to introducing any other desirable compounds (e.g., probes and cross-linkers) into selected sites of proteins as far as appropriate derivative compounds of triarylphosphine could be chemically synthesized. Elucidation of molecular mechanisms of protein functions and protein-to-protein networks will be greatly facilitated by making use of these site-selectively modified proteins.     

Oxidative post-translational modification of tryptophan residues in cardiac mitochondrial proteins

We examined the distribution of N-formylkynurenine, a product of the dioxidation of tryptophan residues in proteins, throughout the human heart mitochondrial proteome. This oxidized amino acid is associated with a distinct subset of proteins, including an over-representation of complex I subunits as well as complex V subunits and enzymes involved in redox metabolism. No relationship was observed between the tryptophan modification and methionine oxidation, a known artifact of sample handling. As the mitochondria were isolated from normal human heart tissue and not subject to any artificially induced oxidative stress, we suggest that the susceptible tryptophan residues in this group of proteins are "hot spots" for oxidation in close proximity to a source of reactive oxygen species in respiring mitochondria.     

Reversible post-translational modification of proteins by nitrated fatty acids in vivo

Nitric oxide ((*)NO)-derived reactive species nitrate unsaturated fatty acids, yielding nitroalkene derivatives, including the clinically abundant nitrated oleic and linoleic acids. The olefinic nitro group renders these derivatives electrophilic at the carbon beta to the nitro group, thus competent for Michael addition reactions with cysteine and histidine. By using chromatographic and mass spectrometric approaches, we characterized this reactivity by using in vitro reaction systems, and we demonstrated that nitroalkene-protein and GSH adducts are present in vivo under basal conditions in healthy human red cells. Nitro-linoleic acid (9-, 10-, 12-, and 13-nitro-9,12-octadecadienoic acids) (m/z 324.2) and nitro-oleic acid (9- and 10-nitro-9-octadecaenoic acids) (m/z 326.2) reacted with GSH (m/z 306.1), yielding adducts with m/z of 631.3 and 633.3, respectively. At physiological concentrations, nitroalkenes inhibited glyceraldehyde-3-phosphate dehydrogenase (GAPDH), which contains a critical catalytic Cys (Cys-149). GAPDH inhibition displayed an IC(50) of approximately 3 microM for both nitroalkenes, an IC(50) equivalent to the potent thiol oxidant peroxynitrite (ONOO(-)) and an IC(50) 30-fold less than H(2)O(2), indicating that nitroalkenes are potent thiol-reactive species. Liquid chromatography-mass spectrometry analysis revealed covalent adducts between fatty acid nitroalkene derivatives and GAPDH, including at the catalytic Cys-149. Liquid chromatography-mass spectrometry-based proteomic analysis of human red cells confirmed that nitroalkenes readily undergo covalent, thiol-reversible post-translational modification of nucleophilic amino acids in GSH and GAPDH in vivo. The adduction of GAPDH and GSH by nitroalkenes significantly increased the hydrophobicity of these molecules, both inducing translocation to membranes and suggesting why these abundant derivatives had not been detected previously via traditional high pressure liquid chromatography analysis. The occurrence of these electrophilic nitroalkylation reactions in vivo indicates that this reversible post-translational protein modification represents a new pathway for redox regulation of enzyme function, cell signaling, and protein trafficking.     

Tissue-specific expression and post-translational modification of histone H3 variants

Analyses of histone H3 from 10 rat tissues using a Middle Down proteomics platform revealed tissue-specific differences in their expression and global PTM abundance. ESI/FTMS with electron capture dissociation showed that, in general, these proteins were hypomodified in heart, liver and testes. H3.3 was hypermodified compared to H3.2 in some, but not all tissues. In addition, a novel rat testes-specific H3 protein was identified with this approach.     

Characterization of isoprenoid involved in the post-translational modification of mammalian cell proteins

Mammalian cell proteins, modified post-translationally by derivatives of [3H]mevalonic acid, were subjected to methylation and sulfonium salt cleavage reactions previously used to release isoprenoids from cysteine residues in yeast peptides. The labeled isoprenoid extracted into chloroform comigrated with farnesol through a series of chromatography steps including Sep-Pak C-18 fractionation, size exclusion on Bio-Beads, and reverse-phase chromatography. Further resolution of the material by normal phase liquid chromatography and thin layer chromatography demonstrated the presence of farnesol, nerolidol, and other unidentified hydrophobic derivatives. Similar products were generated when S-farnesyl cysteine was subjected to the methylation and cleavage procedures. These preliminary findings suggest that farnesylation of cysteine residues accounts for the well documented incorporation of mevalonic acid into mammalian cell proteins.     

Involvement of post-translational modification of neuronal plasticity-related proteins in hyperalgesia revealed by a proteomic analysis

To clarify roles of an endogenous pain modulatory system of the central nervous system (CNS) in hyperalgesia, we tried to identify qualitative and quantitative protein changes by a proteomic analysis using an animal model of hyperalgesia. Specifically, we first induced functional hyperalgesia on male Wistar rats by repeated cold stress (specific alternation of rhythm in temperature, SART). We then compared proteomes of multiple regions of CNS and the dorsal root ganglion between the hyperalgetic rats and non-treated ones by 2-D PAGE in the pI range of 4.0-7.0. We found that SART changed the proteomes prominently in the mesencephalon and cerebellum. We thus analyzed the two brain regions in more detail using gels with narrower pI ranges. As a result, 29 and 23 protein spots were significantly changed in the mesencephalon and the cerebellum, respectively. We successfully identified 12 protein spots by a MALDI-TOF/TOF MS and subsequent protein database searching. They included unc-18 protein homolog 67K, collapsin response mediator protein (CRMP)-2 and CRMP-4, which were reported to be involved in neurotransmitter release or axon elongation. Interestingly, mRNA expression levels of these three proteins were not changed significantly by the induction of hyperalgesia. Instead, we found that the detected changes in the protein spots are caused by the post-translational modification (PTM) of proteolysis or phosphorylation. Taken together, development of the hyperalgesia would be linked to PTM of these three CNS proteins. PTM regulation may be one of the useful ways to treat hyperalgesia.     

Application of chemical selective cleavage methods to analyze post-translational modification in proteins

Three chemical specific cleavage reactions, one for the carboxyl side of aspartyl peptide bonds, one for the carboxyl side of asparaginyl peptide bonds and another for the amino side of seryl/threonyl peptide bonds have been recently established. Additionally, these reactions simultaneously react on several post-translationally modified groups in peptides or proteins. The modified groups cover the external modifications N-formyl, N-acetyl, N-pyroglutamyi residues and C-terminal-alpha amide, as well as the internal modifications such as O-acetyl serine, phosphorylated serine/tyrosine, sulfonylated tyrosine, glycosylated serine/threonine and glycosylated asparagine. These three cleavage reactions relate to key amino acids for modifications, deamidation for asparagine, phosphorylation and acetylation for serine, and glycosylation for asparagine, serine and threonine. The chemical reactions on these modifications change the peptide mapping pattern, and information from these reactions may contribute characterization and location of post-translational modified groups in the protein.     

Factors influencing expression and post-translational modification of recombinant protein C.

Factors affecting the production of recombinant human protein C were investigated. When recombinant cells producing human protein C were cultured with microcarrier in two different scales, we found that (1) as cells grew to confluence, specific productivity of the protein was decreased and that (2) the efficiency of gamma-carboxylation of the generated protein C was lower in a larger culture than in a smaller culture. Higher cell density was shown to influence the specific productivity unfavorably. On the other hand, the amount of oxygen supply as demonstrated by oxygen consumption rate in the Opticell culture system correlated well with the efficiency of gamma-carboxylation, suggesting that oxygen metabolism is somehow implicated in the post-translational modification of recombinant protein C.     

Capillary affinity electrophoresis for the screening of post-translational modification of proteins with carbohydrates

Glycosylation is one of the most important post-translational events for proteins, affecting their functions in health and disease, and plays significant roles in various information traffics for intracellular and intercellular biological events (Hancock, W. S. J. Proteome Res. 2002, 1, 297). We have attempted to obtain the information on the numbers and amounts of carbohydrate chains. Interaction between carbohydrate chains and proteins that recognize them is a target to understand the biological roles of glycosylation. To date, there have been a few strategies for simultaneous analysis of the interactions between complex mixtures of carbohydrates and proteins. Here, we report an approach to categorize carbohydrate chains using a few glycoprotein samples as models for the studies on the analysis of post-translational modification of proteins with carbohydrates. A combination of some specific lectins was used as carbohydrate-binding proteins. The method is based on high-resolution separation of fluorescent-labeled carbohydrates by capillary electrophoresis with laser-induced fluorescent detection in the presence of carbohydrate-binding proteins at different concentrations. The present technique affords (1) simultaneous determination of carbohydrate chains, (2) binding specificity of the constituent carbohydrate chains to specific proteins, and (3) kinetic data such as the association constant of each carbohydrate. We found that the lectins employed in the present study could discriminate subtle difference in linkages and resolved the carbohydrate mixtures. The results will be useful, for example, to understand the biological events expressed with carbohydrate changes on the cell surface.     

Oxidation as a post-translational modification that regulates autophagy

The toxicity associated with accumulation of reactive oxygen species (ROS) has led to the evolution of various defense strategies to overcome oxidative stress, including autophagy. This pathway is involved in the removal and degradation of damaged mitochondria and oxidized proteins. At low levels, however, ROS act as signal transducers in various intracellular pathways. In a recent study we described the role of ROS as signaling molecules in starvation-induced autophagy. We showed that starvation stimulates formation of ROS, specifically H(2)O(2), in the mitochondria. Furthermore, we identified the cysteine protease HsAtg4 as a direct target for oxidation by H(2)O(2), and specified a cysteine residue located near the HsAtg4 catalytic site as critical for this regulation. Here we focus on Atg4, the target of regulation, and discuss possible mechanisms for the regulation of this enzyme in the autophagic process.     

The procyclic acidic repetitive proteins of Trypanosoma brucei. Purification and post-translational modification

The procyclic acidic repetitive protein (PARP) of Trypanosoma brucei was purified by cell fractionation followed by ion-exchange and concanavalin A-Sepharose affinity chromatography. PARP is membrane-bound and comprises about 1% of the total procyclic trypanosome protein or 6 x 10(6) molecules per parasite. The results of NH2-terminal sequencing and amino acid analysis indicate that PARP is processed by removal of an N-terminal signal sequence and the hydrophobic COOH terminus. Metabolic labeling of PARP with [3H] ethanolamine is consistent with attachment of the protein to the membrane via a glycosylphosphatidylinositol anchor. The glycolipid can be removed by base hydrolysis or nitrous acid deamination but is not susceptible to bacterial phosphatidylinositol-specific phospholipase C.     

Subcellular differences in post-translational modification of barley 14-3-3 proteins

Expression and post-translational modification of barley 14-3-3 isoforms, 14-3-3A, 14-3-3B and 14-3-3C, were investigated using isoform-specific antibodies. Although all three isoforms were shown to be present in the cytosolic, the nuclear and the microsomal cell fractions, differences in post-translational modification were identified for the different cell fractions. Germination-related modifications of 14-3-3 proteins were observed in the cytosol and the microsomal fraction, but not in the nucleus. In vitro proteolytic cleavage of 14-3-3 proteins using trypsin suggests that for 14-3-3A this change was caused by proteolytic cleavage of the unconserved C-terminal region.     

Identification of lysine succinylation as a new post-translational modification

Of the 20 ribosomally coded amino acid residues, lysine is the most frequently post-translationally modified, which has important functional and regulatory consequences. Here we report the identification and verification of a previously unreported form of protein post-translational modification (PTM): lysine succinylation. The succinyllysine residue was initially identified by mass spectrometry and protein sequence alignment. The identified succinyllysine peptides derived from in vivo proteins were verified by western blot analysis, in vivo labeling with isotopic succinate, MS/MS and HPLC coelution of their synthetic counterparts. We further show that lysine succinylation is evolutionarily conserved and that this PTM responds to different physiological conditions. Our study also implies that succinyl-CoA might be a cofactor for lysine succinylation. Given the apparent high abundance of lysine succinylation and the significant structural changes induced by this PTM, it is expected that lysine succinylation has important cellular functions.