N-Hydroxyguanidines oxidation by a N3S copper-complex mimicking the reactivity of Dopamine β-Hydroxylase

N-Aryl-N′-hydroxyguanidines are compounds that display interesting pharmacological properties but their chemical reactivity remains poorly investigated. Some of these compounds are substrates for the heme-containing enzymes nitric-oxide synthases (NOS) and act as reducing co-substrates for the copper-containing enzyme Dopamine β-Hydroxylase (DBH) [P. Slama, J.L. Boucher, M. Réglier, Biochem. Biophys. Res. Commun. 316 (2004) 1081-1087]. DBH catalyses the hydroxylation of the important neurotransmitter dopamine into norepinephrine in the presence of both molecular oxygen and a reducing co-substrate. Although many molecules have been used as co-substrates for DBH, their interaction at the active site of DBH and their role in mechanism are not clearly characterized. In the present paper, we have used a water-soluble copper-N₃S complex that mimics the Cu_B site of DBH, and aromatic N-hydroxyguanidines as reducers to address this question. N-Aryl-N′-hydroxyguanidines readily reduced copper(II) to Cu(I) and were oxidized into a nitrosoamidine as previously observed in reactions performed with purified DBH. These data describe for the first time the reactivity of N-aryl-N′-hydroxyguanidines with a water-soluble copper(II) complex and help to understand the interaction of co-substrates with copper at the active site of DBH.     

Iron and cobalt complexes with the ligand (2-aminoethyl)bis(2-pyridylmethyl)amine (uns-penp) and derivatives

A series of iron(II)/(III) and cobalt(II)/(III) complexes with the tetradendate tripodal ligands (2-aminoethyl)bis(2-pyridylmethyl)amine (uns-penp), its methylated derivatives Me₂-uns-penp and Me₄-uns-penp as well as the amide ligand N-acetyl-N,N-bis[(2-pyridyl)methyl]ethylenediamine (acetyl-uns-penp) were synthesized and structurally characterized. They have been investigated in regard to their reactivity towards dioxygen and/or hydrogen peroxide. Complexes of this type seem to have a high potential to be useful in the activation of dioxygen for selective oxidation reactions of organic substrates.     

Evidence for a free radical mechanism of N-demethylation of N,N-dimethylaniline and an analog by hemeprotein--H2O2 systems.

Horseradish peroxidase and metmyoglobin catalyze the H₂O₂-supported N-demethylation of N,N-dimethylaniline and N,N-dimethyl-p-toluidine. The catalytic activities of horseradish peroxidase are more than 100-fold larger than those of metmyoglobin or those previously reported for liver microsomal cytochrome P-450. Distinct free radical species of these N-methyl substrates were detected with both catalysts. These findings establish the general validity of a recently proposed free radical mechanism of oxidative N-demethylation (Griffin, B. W., and Ting, P. L., Biochemistry (1978), 2206–2211), which is quite different from that previously suggested for the analogous cytochrome P-450-dependent reactions.     

Comparison of wild type neuronal nitric oxide synthase and its Tyr588Phe mutant towards various l-arginine analogues

Crystal structures of nitric oxide synthases (NOS) isoforms have shown the presence of a strongly conserved heme active-site residue, Tyr588 (numbering for rat neuronal NOS, nNOS). Preliminary biochemical studies have highlighted its importance in the binding and oxidation to NO of natural substrates L-Arg and N^ω-hydroxy-l-arginine (NOHA) and suggested its involvement in mechanism. We have used UV-visible and EPR spectroscopy to investigate the effects of the Tyr588 to Phe mutation on the heme-distal environment, on the binding of a large series of guanidines and N-hydroxyguanidines that differ from L-Arg and NOHA by the nature of their alkyl- or aryl-side chain, and on the abilities of wild type (WT) and mutant to oxidize these analogues with formation of NO. Our EPR experiments show that the heme environment of the Tyr588Phe mutant differs from that of WT nNOS. However, the addition of L-Arg to this mutant results in EPR spectra similar to that of WT nNOS. Tyr588Phe mutant binds L-Arg and NOHA with much weaker affinities than WT nNOS but both proteins bind non α-amino acid guanidines and N-hydroxyguanidines with close affinities. WT nNOS and mutant do not form NO from the tested guanidines but oxidize several N-hydroxyguanidines with formation of NO in almost identical rates. Our results show that the Tyr588Phe mutation induces structural modifications of the H-bonds network in the heme-distal site that alter the reactivity of the heme. They support recent spectroscopic and mechanistic studies that involve two distinct heme-based active species in the two steps of NOS mechanism.     

Comparison of HNO reactivity with tryptophan and cysteine in small peptides

Recent discoveries of important pharmacological properties have drawn attention to the reactivity of HNO (azanone, nitroxyl) with biologically relevant substrates. Apart from its role in thiol oxidation, HNO has been reported to have nitrosative properties, for example, with tryptophan resulting in N-nitrosotryptophan formation. We have investigated the reactivity of HNO with tryptophan and small peptides containing either tryptophan or both a tryptophan and a cysteine residue. Our results point to the more reactive nature of cysteine towards HNO compared with tryptophan.     

Inhibition of dimethylnitrosamine-induced mutagenesis in Arabidopsis thaliana by diethyldithiocarbamate and carbon monoxide

Diethyldithiocarbamate and carbon monoxide markedly inhibited the frequency of embryonic and chlorophyll mutations induced by the metabolism-requiring mutagen dimethylnitrosamine in the higher plant Arabidopsis thaliana. In contrast, the monoamine oxidase substrates, tryptamine, benzylamine and 2-phenylethylamine, had no such effect. The mutagenicity of a direct-acting mutagen, N-methyl-N-nitrosourea, was not altered by these inhibitors or substrates.     

Energy-dependent endocytosis in erythrocyte ghosts. 3. Hydrophobic character of maleimide inactivation sites of ATPase and of endocytosis

The effects of a variety of reactive compounds on endocytosis in erythrocyte ghosts were observed. Of these reagents, only alkylating reagents were effective at low concentrations. This suggested that an alkylatable site, probably a sulfhydryl group, was important in endocytosis. In a series of N -substituted maleimides, effectiveness of the alkylating agent in inactivating both ATPase and endocytosis correlated very well with a high value of the partition coefficient between octanol and water. This suggested that a hydrophobic region was present at the site of inactivation, so that strongly hydrophobic alkylating agents were bound more firmly by this site. The action of the N -substituted maleimides was clearly due to the reactivity of the carbon-carbon double bond in the heterocyclic ring, since saturation of this bond completely destroyed the effectiveness of the inhibitor. Statistical analysis of the dependence of the effectiveness of N-substituted maleimides upon partition coefficient and Hammett sigma parameters showed that the partition coefficient was by far the most important factor which controlled the effectiveness of these inhibitors. The sigma parameter played a lesser role. The dependence of the effectiveness of the maleimides on these two parameters was the same, within the statistical error, for both the ATPase activity and endocytosis activity. This suggested that inhibition of endocytosis was due to reaction with the same site responsible for inhibition of ATPase.     

Palladium-catalyzed hydrodechlorination of ary chlorides and its mechanism

Successful hydrodechlorinations of aryl chlorides were carried out in the presence of palladium catalyst supported by dppf (1,1′-bis(diphenylphosphino)ferrocene) and sodium formate in DMA (N,N-dimethylacetamide). A series of substituted aryl chlorides as substrates were studied to investigate the influence of electronic effects on the reaction. It was found that the substrates with electron-donating groups are more active than those with electron-withdrawing groups. A proposed mechanism of hydrodechlorination via decarboxylation and reductive elimination was discussed with the supported of in situ IR data. It is suggested that the decarboxylation is the key step of the reaction. This inference of the mechanism is consistent with the results from the in situ IR experiments.     

Methionine-alpha-naphthyl ester, a useful chromogenic substrate for esterproteases of the mouse submandibular gland.

The two aminoacid esters, N-acetyl-l-methionine α-naphthyl ester and N-acetyl-l-alanine α-naphthyl ester have been found to be suitable chromogenic substrates for the demonstration of mouse submandibular esterproteases. Using these substrates, a complex banding pattern of esterproteases was demonstrated by disc electrophoresis of mouse submandibular gland. Of these, protease A, epidermal growth factor binding protein, and the γ-subunits of 7 S nerve growth factor could be identified.     

Substrate-mediated increased reactivity of a critical sulfhydryl group of crystals of cytoplasmic aspartate transaminase

The extramitochondrial isozyme of aspartate aminotransferase (l-aspartate:2-oxoglutarate aminotransferase EC 2.6.1.1) contains a cysteinyl residue (cysteine-390) which, in the presence of substrate, displays enhanced reactivity toward sulfhydryl reagents. To gain insight into the structural similarity of the enzyme in solution compared to its crystalline state and into the type of structural change induced by substrates, the reactivity of Cys-390 in the crystalline enzyme has been studied. The flat yellow plates, crystallized from polyethylene glycol, form spectroscopically detectable enzyme-substrate complexes (C. M. Metzler, D. E. Metzler, D. S. Martin, R. Newman, A. Arnone, and P. Rodgers, 1978, J. Biol. Chem. 253, 5251–5254). The crystals, both in the presence and absence of the substrate pair, glutamate and α-ketoglutarate, were treated with N-ethylmaleimide or N-ethyl[1-¹⁴C]maleimide and the extent of the reaction was monitored by the colorimetric sulfhydryl reaction with 5,5′-dithiobis-2-nitrobenzoic acid, by amino acid analysis, by radioactivity incorporated, and by the measurement of enzyme activity. A cysteine residue was modified only in the presence of substrate; the crystals remained undamaged. Since, any large conformational change in the enzyme would either be prevented by the crystalline lattice or would disrupt its integrity, it is concluded that the enhanced reactivity of cysteine-390 in the presence of substrates must be due to only a small local conformational change in the substrate binding region.     

New ribose-modified fluorescent analogs of adenine and guanine nucleotides available as subtrates for various enzymes

The synthesis of fluorescent derivatives of nucleosides and nucleotides, by reaction with isatoic anhydride in aqueous solution at mild pH and temperature, yielding their 3′-O-anthraniloyl derivatives, is here described. The N-methylanthraniloyl derivatives were also synthesized by reaction with N-methylisatoic anhydride. Upon excitation at 330–350 nm these derivatives exhibited maximum fluorescence emission at 430–445 nm in aqueous solution with quantum yields of 0.12–0.24. Their fluorescence was sensitive to the polarity of the solvent; in N,N-dimethylformamide the quantum yields were 0.83–0.93. The major differences between the two fluorophores were the longer wavelength of the emission maximum of the N-methylanthraniloyl group and its greater quantum yield in water. All anthraniloyl derivatives, as well as the N-methylanthraniloyl ones, had virtually identical fluorescent properties, regardless of their base structures. The ATP derivatives showed considerable substrate activity as a replacement of ATP with adenylate kinase, guanylate kinase, glutamine synthetase, myosin ATPase and sodium-potassium transport ATPase. The ADP derivatives were good substrates for creatine kinase and glutamine syntletase (γ-glutamyl transfer activity). The GMP and adenosine derivatives were substrates for guanylate kinase and adenosine deaminase, respectively. All derivatives had only slightly altered K_m values for these enzymes. While more fluorescent in water, the N-methylanthraniloyl derivatives were found to show relatively low substrate activities against some of these enzymes. The results indicate that these ribose-modified nucleosides and nucleotides can be versatile fluorescent substrate analogs for various enzymes.     

Stereoselectivity and reactivity of α-chymotrypsin modified at methionine-192

Native α-chymotrypsin (N-Chtr) and two modified forms, methionine-192 sulfoxide (O-Chtr) and methionine-192-S-(N-2-carboxyisopropyl)carbamylmethyl (Al-Chtr) α-chy-motrypsin have been compared in hydrolysis of methyl β-phenylpropionate and its d-and l-α-substituted derivatives, in which substituents are Cl, OH, OCOCH₃, NHCHO, and NHCOCH₃. In general, both modifications lower the reactivity of the enzymes in terms of k_cat and K_m(app); the decrease is greater toward l than toward d-enantiomers, and stereoselectivity is decreased. It is proposed that the modifications change the methionine-192 side chain from hydrophobic to hydrophilic, bring it into solution, and enlarge the Met-192-Ser-214 passage in which α-substituents fit. This leads to weaker binding, allows more freedom of motion of substrates and decreases reactivity, while allowing easier access of d-α-substituents. The large modifying substituent of Al-Chtr counters this effect by steric interaction with the large d-α-acetoxy and d-α-acylamido substituents, while the small polar modification in O-Chtr favors hydrolysis of these d-substrates.     

Specificity of a particulate rat renal peptidase and its localization along with other enzymes of mercapturic acid synthesis

Renal processing of S-derivatized glutathiones to mercapturic acids requires the participation of three enzymatic activities: γ-glutamyl hydrolase or transpeptidase, a peptidase which is capable of hydrolyzing S-derivatized cysteinylglycine, and an N-acetyltransferase. A particulate peptidase, which was assayed with S-benzylcysteine-p-nitroanilide, was found to be localized along with γ-glutamyltranspeptidase and N-acetyltransferase in the outer stripe region of the renal medulla. This localization suggests that these three activities may be contained primarily in the proximal straight tubules. Results of differential and isopycnic centrifugation indicate that the particulate peptidase is contained along with γ-glutamyltranspeptidase in the brush border membranes while the N-acetyltransferase is probably associated with the endoplasmic reticulum. The partially purified peptidase (200-fold) exhibits a broad substrate specificity. It has greater activity with reduced than oxidized cysteinylglycine, but S-derivatized substrates are hydrolyzed even faster. Comparison of its activity with various substrates indicates that it prefers peptides with a hydrophobic N-terminal amino acid and that it may require a free amino group. Heat-inactivation studies suggest that all of these activities are attributable to a single enzyme. These results suggest that this peptidase may participate along with γ-glutamyltranspeptidase and an N-acetyltransferase in the conversion of glutathione conjugates to mercapturic acids.     

Intracellular Ca2+-dependent formation of N-acyl-phosphatidylethanolamines by human cytosolic phospholipase A2ε

N-Acyl-phosphatidylethanolamines (NAPEs) are known to be precursors of bioactive N-acylethanolamines (NAEs), including the endocannabinoid arachidonoylethanolamide (anandamide) and anti-inflammatory palmitoylethanolamide. In mammals, NAPEs are produced by N-acyltransferases, which transfer an acyl chain from the sn-1 position of glycerophospholipid to the amino group of phosphatidylethanolamine (PE). Recently, the ɛ isoform of cytosolic phospholipase A₂ (cPLA₂ɛ) was found to be Ca²⁺-dependent N-acyltransferase. However, it was poorly understood which types of phospholipids serve as substrates in living cells. In the present study, we established a human embryonic kidney 293 cell line, in which doxycycline potently induces human cPLA₂ɛ, and used these cells to analyze endogenous substrates and products of cPLA₂ɛ with liquid chromatography-tandem mass spectrometry. When treated with doxycycline and Ca²⁺ ionophore, the cells produced various species of diacyl- and alkenylacyl-types of NAPEs as well as NAEs in large quantities. Moreover, the levels of diacyl- and alkenylacyl-types of PEs and diacyl-phosphatidylcholines (PCs) decreased, while those of lysophosphatidylethanolamines and lysophosphatidylcholines increased. These results suggested that cPLA₂ɛ Ca²⁺-dependently produces NAPEs by utilizing endogenous diacyl- and alkenylacyl-types of PEs as acyl acceptors and diacyl-type PCs and diacyl-type PEs as acyl donors.     

Enzymatic acylation of polar dipeptides: Influence of reaction media and molecular environment of functional groups

The enzymatic acylation of polar dipeptides was investigated. First, the Novozym435^®-catalyzed acylation of Lys-Ser, HCl exhibiting three potential acylable sites was carried out in organic media (2-methyl-2-butanol, oleic acid) and in an ionic liquid ([Bmim]⁺[PF₆]^?). In these reactions, the chemo-selectivity of the acylation was exclusively in favour of the N?-lysine acylation and the efficiency (substrate conversion) was demonstrated to be under control of the peptide solubility. The use of [Bmim]⁺[PF₆]^? permitted to significantly improve the dipeptide solubility, and to enhance both substrates conversion and initial rates of acylation reaction. In the three reaction media used, the O-acylated derivative of the dipeptide was never detected suggesting a weak reactivity of the serine hydroxyl group due to its molecular environment and particularly to the presence of a free carboxylic group known for its electroattractor property.Last, the acylation of a natural dipeptide (carnosine), exhibiting a very low solubility in organic solvents, was also performed. Carnosine was successfully N-acylated in 2-methyl-2-butanol, and a yield of 39% was obtained when improving the substrate solubility: a better dispersibility was obtained by application of a high pressure on the reaction medium just before starting the reaction.     

Kinetic properties of alternatively spliced isoforms of laccase-2 from Tribolium castaneum and Anopheles gambiae

Laccase-2 is a highly conserved multicopper oxidase that functions in insect cuticle pigmentation and tanning. In many species, alternative splicing gives rise to two laccase-2 isoforms. A comparison of laccase-2 sequences from three orders of insects revealed eleven positions at which there are conserved differences between the A and B isoforms. Homology modeling suggested that these eleven residues are not part of the substrate binding pocket. To determine whether the isoforms have different kinetic properties, we compared the activity of laccase-2 isoforms from Tribolium castaneum and Anopheles gambiae. We partially purified the four laccases as recombinant enzymes and analyzed their ability to oxidize a range of laccase substrates. The predicted endogenous substrates tested were dopamine, N-acetyldopamine (NADA), N-β-alanyldopamine (NBAD) and dopa, which were detected in T. castaneum previously and in A. gambiae as part of this study. Two additional diphenols (catechol and hydroquinone) and one non-phenolic substrate (2,2′-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid)) were also tested. We observed no major differences in substrate specificity between the A and B isoforms. Dopamine, NADA and NBAD were oxidized with catalytic efficiencies ranging from 51 to 550 min^?1 mM^?1. These results support the hypothesis that dopamine, NADA and NBAD are endogenous substrates for both isoforms of laccase-2. Catalytic efficiencies associated with dopa oxidation were low, ranging from 8 to 30 min^?1 mM^?1; in comparison, insect tyrosinase oxidized dopa with a catalytic efficiency of 201 min^?1 mM^?1. We found that dopa had the highest redox potential of the four endogenous substrates, and this property of dopa may explain its poor oxidation by laccase-2. We conclude that laccase-2 splice isoforms are likely to oxidize the same substrates in vivo, and additional experiments will be required to discover any isoform-specific functions.     

Liver metabolic reactions: tertiary amine N-dealkylation, tertiary amine N-oxidation, N-oxide reduction, and N-oxide N-dealkylation. II. N,N-dimethylaniline

Rat liver microsomal preparations enzymatically catalyze the N-demethylation and N-oxidation of dimethylaniline as well as the N-demethylation of dimethylaniline-N-oxide. Both compounds were used as substrates and the formation of formaldehyde and N-oxide were determined.Both demethylation and N-oxidation of dimethylaniline are dependent on NADPH. This cofactor also increases the demethylation of dimethylaniline-N-oxide, although it is not an absolute requirement. Nicotinamide increases the rate of formation of formaldehyde and N-oxide from dimethylaniline by a factor of about 4 and decreases the N-oxide demethylation by the same factor. The cofactor optimum consists of NADPH, nicotinamide, and magnesium ions for the demethylation and N-oxidation of dimethylaniline, and of NADPH alone for the demethylation of its N-oxide. The kinetic constants of the three test reactions have been determined under these optimal cofactor requirements.Various agents strongly influence the rates of product formation of the three test reactions studied. SH-blocking agents, the chelating agent EGTA, as well as nicotinamide influence the rates of formaldehyde formation from dimethylaniline and N-oxide demethylation in an opposite way. This demonstrates that, in the tertiary amine demethylation of dimethylaniline, a C-oxidation pathway is operative in addition to an N-oxidation pathway with subsequent N-oxide demethylation. The following influences on the actual metabolic reactions could be deduced from the effects of agents on the test reactions: SKF 525-A inhibits and phenobarbital pretreatment stimulates N-oxide demethylation; EDTA inhibits both the latter reaction and N-oxidation; EGTA and nicotinamide stimulate C-oxidation and inhibit N-oxide demethylation; SH-blocking agents inhibit C-oxidation and stimulate both N-oxidation and N-oxide demethylation.Quantitative and qualitative species differences with respect to cofactor requirement and effect of SKF 525-A have been observed between rat and pig liver microsomes. In addition, profound differences in subcellular localization and metabolic rates between dimethylaniline and other substrates are known. Thus it is unlikely that the three metabolic reactions dealt with in this report are characteristic of tertiarr amine N-dealkylation in general.     

Substrate Specificity of Cytoplasmic N-Glycosyltransferase

N-Linked protein glycosylation is a very common post-translational modification that can be found in all kingdoms of life. The classical, highly conserved pathway entails the assembly of a lipid-linked oligosaccharide and its transfer to an asparagine residue in the sequon NX(S/T) of a secreted protein by the integral membrane protein oligosaccharyltransferase. A few species in the class of γ-proteobacteria encode a cytoplasmic N-glycosylation system mediated by a soluble N-glycosyltransferase (NGT). This enzyme uses nucleotide-activated sugars to modify asparagine residues with single monosaccharides. As these enzymes are not related to oligosaccharyltransferase, NGTs constitute a novel class of N-glycosylation catalyzing enzymes. To characterize the NGT-catalyzed reaction, we developed a sensitive and quantitative in vitro assay based on HPLC separation and quantification of fluorescently labeled substrate peptides. With this assay we were able to directly quantify glycopeptide formation by Actinobacillus pleuropneumoniae NGT and determine its substrate specificities: NGT turns over a number of different sugar donor substrates and allows for activation by both UDP and GDP. Quantitative analysis of peptide substrate turnover demonstrated a strikingly similar specificity as the classical, oligosaccharyltransferase-catalyzed N-glycosylation, with NX(S/T) sequons being the optimal NGT substrates.