Ferricytochrome c Directly Oxidizes Aminoacetone to Methylglyoxal, a Catabolite Accumulated in Carbonyl Stress

Age-related diseases are associated with increased production of reactive oxygen and carbonyl species such as methylglyoxal. Aminoacetone, a putative threonine catabolite, is reportedly known to undergo metal-catalyzed oxidation to methylglyoxal, NH4+ ion, and H2O2 coupled with (i) permeabilization of rat liver mitochondria, and (ii) apoptosis of insulin-producing cells. Oxidation of aminoacetone to methylglyoxal is now shown to be accelerated by ferricytochrome c, a reaction initiated by one-electron reduction of ferricytochrome c by aminoacetone without amino acid modifications. the participation of O-2(center dot-) and HO center dot radical intermediates is demonstrated by the inhibitory effect of added superoxide dismutase and Electron Paramagnetic Resonance spin-trapping experiments with 5,5'-dimethyl-1-pyrroline-N-oxide. We hypothesize that two consecutive one-electron transfers from aminoacetone (E-0 values = -0.51 and -1.0 V) to ferricytochrome c (E-0 = 0.26 V) may lead to aminoacetone enoyl radical and, subsequently, imine aminoacetone, whose hydrolysis yields methylglyoxal and NH4+ ion. in the presence of oxygen, aminoacetone enoyl and O-2(center dot-) radicals propagate aminoacetone oxidation to methylglyoxal and H2O2. These data endorse the hypothesis that aminoacetone, putatively accumulated in diabetes, may directly reduce ferricyt c yielding methylglyoxal and free radicals, thereby triggering redox imbalance and adverse mitochondrial responses.Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)INCT Processos Redox em Biomedicina (Brazil)Univ São Paulo, Dept Bioquim, São Paulo, BrazilUniversidade Federal de São Paulo, Dept Bioquim & Biol Mol, São Paulo, BrazilUniversidade Federal de São Paulo, Inst Ciencias Ambientais Quim & Farmaceut, São Paulo, BrazilUniv São Paulo, Dept Fis & Informat, São Paulo, BrazilUniv Fed ABC, Ctr Ciencias Nat & Humanas, São Paulo, BrazilUniversidade Federal de São Paulo, Dept Bioquim & Biol Mol, São Paulo, BrazilUniversidade Federal de São Paulo, Inst Ciencias Ambientais Quim & Farmaceut, São Paulo, BrazilWeb of Scienc

Radical acetylation of aminoacids, peptides, and nucleobases by the biacetyl or methylglyoxal/peroxynitrite systems

Biacetilo (2,3-butanediona) é um contaminante de comida e cigarro, também implicado na hepatoxicidade do álcool e em doenças pulmonares. O metilglioxal (MG), um α-oxoaldeído reativo frequentemente associado ao diabetes e envelhecimento, é produto da fragmentação oxidativa de trioses fosfato, acetona e aminoacetona. Por sua vez, peroxinitrito - um potente oxidante, agente nitrante e nucleófilo formado in vivo pela reação controlada por difusão do ânion radical superóxido com o radical óxido nítrico (k ~1010 M-1s-1) é capaz de se adicionar a CO2 e compostos carbonílicos, gerando produtos potencialmente tóxicos ou sinalizadores celulares. Aminoácidos, peptídeos e nucleobases podem ser acetilados nos grupos amina e na porção desoxiribose. Relativamente ao tratamento com peroxinitrito isolado, níveis superiores de 3-nitrotirosina foram detectados quando tirosina foi tratada com peroxinitrito/biacetilo ou metilglioxal. Ambos os grupos amina de lisina (Lys) ou um deles de derivados de lisina bloqueados e um deles (Ac-Lys-OMe, Z-Lys-OMe) foram acetilados pelo sistema biacetilo ou metilglioxal/peroxinitrito. Em tetrapeptídeos sintéticos contendo lisina como aminoácido amino-terminal (H-KALA-OH, Ac-KALA-OH and H-K(Boc)ALA-OH), a lisina foi acetilada pelo sistemas dicarbonilico/peroxinitrito no grupo α-amina (em maior extensão) e/ou no ε-amina (em menor extensão). No conjunto, estes resultados podem ser interpretados à luz do mecanismo proposto para a reação de compostos α-dicarbonílicos com peroxinitrito, o qual envolve sequencialmente: (i) adição nucleofílica de peroxinitrito à carbonila; (ii) homólise do aduto peroxinitroso formado, liberando •NO2 e um radical oxila do reagente carbonílico; (iii) β-clivagem do radical oxila a um ácido carboxílico (ácido acético no caso de biacetilo e ácido fórmico, a partir de metilglioxal) e radical acetila; (iv) captação do radical acetila pelo oxigênio molecular dissolvido dando acetato, ou por aminoácido ou nucleobase, se presentes, gerando o produto acetilado. Tais resultados são interessantes ao levantar a hipótese de acetilação radicalar como mecanismo de modificação pós-traducional de proteínas, até então considerado um processo realizado apenas por acetilases.Diacetyl (2,3-butanedione) is a food and cigarette contaminant recently implicated in alcohol hepatotoxicity and lung disease. In turn, methylglyoxal (MG) is an α-oxoaldehyde frequently associated with diabetes and aging that is putatively formed by the oxidative fragmentation of trioses phosphate, acetone and aminoacetone. Peroxynitrite - a potent oxidant, nitrating agent and nucleophile formed in vivo by the diffusion-controlled reaction of superoxide radical with nitric oxide (k ~1010 M-1s-1) - is able to form adducts with carbon dioxide and carbonyl compounds. When initially present in the reaction mixtures before addition of ONOO-, amino acids, peptides and nucleobases undergo acetylation at the amino group and purine moieties in the presence of biacetyl or methylglyoxal. Higher levels of 3-nitrotyrosine nitration were measured when peroxynitrite/biacetyl or metilglioxal was added to tyrosine, in comparison with peroxynitrite alone. Both amino groups of L-lysine or one of the amino groups of L-lysine derivatives (Z-Lys-OH and Ac-Lys-OH) were acetylated by biacetyl and methylglyoxal/peroxynitrite system. Using tetrapeptides containing lysine at the terminal amino acid (H-KALA-OH, Ac-KALA-OH and H-K(Boc)ALA-OH), the lysine residue was acetylated at both or either α-amino (major adduct) and ε-amino group (minor adduct). Altogether these data can be interpreted by the mechanism proposed to describe the reaction of α-dicarbonyls with peroxynitrite as follows: (i) nucleophilic addition of peroxynitrite to the carbonyl group of the reagent; (ii) homolysis of the formed peroxynitroso carbonyl adduct to •NO2 and a carbonyloxyl radical; (iii) β-cleavage of the oxyl radical to acetyl radical plus acetic acid (from diacetyl) or formic acid (from methylglyoxal); (iv) competitive scavenging of the acetyl radical by dissolved molecular oxygen and by added amino acid, peptide or nucleobase, ultimately yielding acetate or acetylated biomolecule. If occurring in vivo, these radical reactions may contribute to the post-translational modification of proteins catalyzed by transacetylases

Acetyl Radical Production by the Methylglyoxal-Peroxynitrite System: A Possible Route for L-Lysine Acetylation

Methylglyoxal is an a-oxoaldehyde putatively produced in excess from triose phosphates, aminoacetone, and acetone in some disorders, particularly in diabetes. Here, we investigate the nucleophilic addition of ONOO(-), known as a potent oxidant and nucleophile, to methylglyoxal, yielding an acetyl radical intermediate and ultimately formate and acetate ions. The rate of ONOO(-) decay in the presence of methylglyoxal [k(2,app) = (1.0 +/- 0.1) x 10(3) M(-1) s(-1); k(2) approximate to 1.0 x 10(5) M(-1) s(-1)] at pH 7.2 and 25 degrees C was found to be faster than that reported with monocarbonyl substrates (k(2) < 10(3) M(-1) diacetyl (k(2) = 1.0 x 10(4) M(-1) s(-1)), or CO(2) (k(2) = 3-6 x 10(4) M(-1) s(-1)). The pH profile of the methylglyoxal peroxynitrite reaction describes an ascendant curve with an inflection around pH 7.2, which roughly coincides with the pK(a) values of both ONOOH and H(2)PO(4)(-) ion. Electron paramagnetic resonance spin trapping experiments with 2-methyl-2-nitrosopropane revealed concentration-dependent formation of an adduct that can be attributed to 2-methyl-2-nitrosopropane-CH(3)CO(center dot) (a(N) = 0.83 mT). Spin trapping with 3,5-dibromo-4-nitrosobenzene sulfonate gave a signal that could be assigned to a methyl radical adduct [a(N) = 1.41 mT; a(H) = 1.35 mT; a(H(m)) = 0.08 mT]. The 2-methyl-2-nitrosopropane-CH(3)CO(center dot) adduct could also be observed by replacement of ONOO(-) with H(2)O(2), although at much lower yields. Acetyl radicals could be also trapped by added L-lysine as indicated by the presence of W-acetyl-L-lysine in the spent reaction mixture. This raises the hypothesis that ONOO(-)/H(2)O(2) in the presence of methylglyoxal is endowed with the potential to acetylate proteins in post-translational processes.Fundacao de Amparo a Pesquisa do Estado de Sao Paulo (FAPESP)Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)Conselho Nacional de Desenvolvimento Cientifico e Tecnologico (CNPq)Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)Instituto Nacional de Ciencia e Tecnologia (INCT) RedoxomaInstituto Nacional de Ciencia e Tecnologia (INCT) Redoxom

Low-temperature EPR spectra of ferricyt <i>c</i> treated with AA.

<p>(A) EPR spectra of (300 µM) ferricyt <i>c</i> after a 12-h incubation with (1.0–5.0 mM) AA. (B) Time-response ERP spectra of ferricyt <i>c</i> treated with (1.0 mM) AA for 30 min. Incubation conditions: 50 mM phosphate buffer, pH 7.4, at 37°C. (C) MCD spectra of ferricyt <i>c</i> in the presence of AA. The conditions are ferricyt <i>c</i> (40 µM) MCD spectrum before treatment with AA (thick line) and MCD ferricyt <i>c</i> spectrum after 12 h of (5.0 mM) AA treatment (thin line). (D) CD spectrum of ferricyt <i>c</i> treated with 5.0 mM AA. Incubation conditions: 50 mM phosphate buffer, pH 7.4, at 37°C.</p

Proposed mechanism of AA oxidation catalyzed by iron and copper ions (Adapted from Dutra et al.[14]).

<p>Proposed mechanism of AA oxidation catalyzed by iron and copper ions (Adapted from Dutra et al.<a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0057790#pone.0057790-Dutra1" target="_blank">[14]</a>).</p

EPR spin-trapping studies and computer simulation of the AA system in the presence and absence of ferricyt <i>c</i>, under aerobic conditions.

<p>EPR spectra of DMPO-radical adducts were obtained after a 4-min incubation of (15 mM) AA at 25°C with (150 µM) cyt <i>c</i> in 50 mM phosphate buffer (pH 7.4) with (400 mM) DMPO. (A) Experimental spectrum (trace a) and computer simulations (traces b-d) of the DMPO/AA system, (B) Experimental spectrum (trace a) and computer simulations of the DMPO/AA/cyt <i>c</i> system (traces b-e). Trace <i>c</i> in panels A and B represents the DMPO-<b>^•</b>OH adduct spectrum, and trace d can attributable to the DMPO-AA<b>^•</b> adduct. Trace e in panel B represents an unknown DMPO adduct. Instrumental conditions: microwave power, 20.2 mW; modulation amplitude, 1.0; time constant, 1.63 s; scan rate 0.1 G/s; and receiver gain, 1.12×106.</p

EPR spin-trapping studies of the ferricyt <i>c</i>/AA system under aerobic conditions.

<p>EPR spectra of DMPO-radical adducts were obtained after a 4-min incubation of 15 mM AA at 25°C in 50 mM phosphate buffer (pH 7.4) with (25 mM) DMPO: (A) DMPO experiments, (B) DMPO in the presence of DMSO 30% v/v, (C) DMPO in the presence of ethanol 30% v/v. For all of the figures: (a) control with ferricyt <i>c</i> (150 µM); (b) AA (15mM); (c) AA (15 mM)+desferoxamine (100 µM); (d) ferricyt <i>c</i> (150 µM)+AA (15 mM); (e) system d+CuZnSOD (50 U/mL); (f) system d+catalase (15 µM) for Fig. 2A and 2C only. Instrumental conditions: microwave power, 20.2 mW; modulation amplitude, 1.0; time constant, 1.63 s; scan rate 0.1 G/s; and receiver gain, 1.12×106.</p

Oxygen uptake by AA in the presence of ferricyt <i>c</i>.

<p>Experimental conditions: (50 µM) ferricyt <i>c</i> in the presence or absence of (5.0 mM) AA in 50 mM phosphate buffer, pH 7.4, at 37°C for 30 min. Experiments were performed in the absence or presence of catalase (5.0 µM) or CuZnSOD (50 U/mL). Data are representative of five independent runs. *p<0.05 relative to the system containing only AA and #p<0.05 relative to the AA/ferricyt <i>c</i> system.</p