Oxidative DNA damage by a metabolite of carcinogenic and reproductive toxic nitrobenzene in the presence of NADH and Cu(II)

The mechanism of DNA damage induced by metabolites of nitrobenzene was investigated in relation to the carcinogenicity and reproductive toxicity of nitrobenzene. Nitrosobenzene, a nitrobenzene metabolite, induced NADH plus Cu(II)-mediated DNA cleavage frequently at thymine and cytosine residues. Catalase and bathocuproine inhibited the DNA damage, suggesting the involvement of H2O2 and Cu(I). Typical free hydroxyl radical scavengers showed no inhibitory effects on DNA damage. Nitrosobenzene caused the formation of 8-oxo-7, 8-dihydro-2'-deoxyguanosine in calf thymus DNA in the presence of NADH and Cu(II). ESR spectroscopic study has confirmed that nitrosobenzene is reduced by NADH to the phenylhydronitroxide radical even in the absence of Cu(II). These results suggest that nitrosobenzene can be reduced non-enzymatically by NADH, and the redox cycle reaction resulted in oxidative DNA damage due to the copper-oxygen complex, derived from the reaction of Cu(I) with H2O2.     

Purification and characterization of nitrobenzene nitroreductase from Pseudomonas pseudoalcaligenes JS45.

Pseudomonas pseudoalcaligenes JS45 grows on nitrobenzene as a sole source of carbon, nitrogen, and energy. The catabolic pathway involves reduction to hydroxylaminobenzene followed by rearrangement to o-amino-phenol and ring fission (S. F. Nishino and J. C. Spain, Appl. Environ. Microbiol. 59:2520, 1993). A nitrobenzene-inducible, oxygen-insensitive nitroreductase was purified from extracts of JS45 by ammonium sulfate precipitation followed by anion-exchange and gel filtration chromatography. A single 33-kDa polypeptide was detected by denaturing gel electrophoresis. The size of the native protein was estimated to be 30 kDa by gel filtration. The enzyme is a flavoprotein with a tightly bound flavin mononucleotide cofactor in a ratio of 2 mol of flavin per mol of protein. The Km for nitrobenzene is 5 microM at an initial NADPH concentration of 0.5 mM. The Km for NADPH at an initial nitrobenzene concentration of 0.1 mM is 183 microM. Nitrosobenzene was not detected as an intermediate of nitrobenzene reduction, but nitrosobenzene is a substrate for the enzyme, and the specific activity for nitrosobenzene is higher than that for nitrobenzene. These results suggest that nitrosobenzene is formed but is immediately reduced to hydroxylaminobenzene. Hydroxylaminobenzene was the only product detected after incubation of the purified enzyme with nitrobenzene and NADPH. Hydroxylaminobenzene does not serve as a substrate for further reduction by this enzyme. The products and intermediates are consistent with two two-electron reductions of the parent compound. Furthermore, the low Km and the inducible control of enzyme synthesis suggest that nitrobenzene is the physiological substrate for this enzyme.     

Characterization of the S-denitrosation activity of protein disulfide isomerase

S-nitrosoglutathione (GSNO) denitrosation activity of recombinant human protein disulfide isomerase (PDI) has been kinetically characterized by monitoring the loss of the S-NO absorbance, using a NO electrode, and with the aid of the fluorogenic NOx probe 2,3-diaminonaphthalene. The initial rates of denitrosation as a function of [GSNO] displayed hyperbolic behavior irrespective of the method used to monitor denitrosation. The Km values estimated for GSNO were 65 +/- 5 microm and 40 +/- 10 microm for the loss in the S-NO bond and NO production (NO electrode or 2,3-diaminonaphthalene), respectively. Hemoglobin assay provided additional evidence that the final product of PDI-dependent GSNO denitrosation was NO*. A catalytic mechanism, involving a nitroxyl disulfide intermediate stabilized by imidazole (His160 a-domain or His589 a'-domain), which after undergoing a one-electron oxidation decomposes to yield NO plus dithiyl radical, has been proposed. Evidence for the formation of thiyl/dithiyl radicals during PDI-catalyzed denitrosation was obtained with 4-((9-acridinecarbonyl)-amino)-2,2,6,6-tetramethylpiperidine-1-oxyl. Evidence has also been obtained showing that in a NO- and O2-rich environment, PDI can form N2O3 in its hydrophobic domains. This "NO-charged PDI" can perform intra- and intermolecular S-nitrosation reactions similar to that proposed for serum albumin. Interestingly, reduced PDI was able to denitrosate S-nitrosated PDI (PDI-SNO) resulting in the release of NO. PDI-SNO, once formed, is stable at room temperature in the absence of reducing agent over the period of 2 h. It has been established that PDI is continuously secreted from cells that are net producers of NO-like endothelial cells. The present demonstration that PDI can be S-nitrosated and that PDI-SNO can be denitrosated by PDI suggests that this enzyme could be intimately involved in the transport of intracellular NO equivalents to the cell surface as well as the previous demonstration of PDI in the transfer of S-nitrosothiol-bound NO to the cytosol.     

Transfer of nitric oxide from the liver to erythrocytes--an ESR study using nitroglycerin-treated mice

Nitric oxide (NO) formation in the liver and blood of the mouse following intraperitoneal treatment with nitroglycerin (glycerol trinitrate, GTN) was determined using electron spin resonance (ESR) spectroscopy. ESR signals of heme-NO complexes were detected at maximum levels within 5 min in the liver, but increased to a maximum level about 15-30 min later in the blood. GTN is not metabolized to release NO in vitro in the blood of the mouse. The hepatic microsomes which showed the heme-NO complexes ESR signals were incubated with mouse erythrocytes, with the result that a hemoglobin-NO signal was obtained from the erythrocytes. The activities of microsomal cytochrome P-450, the hepatic level of glutathione, and the reduction rate of nitroxide radicals in the in vivo liver, measured using L-band ESR spectroscopy, were temporarily decreased following GTN administration. In conclusion, NO in the liver could be scavenged by circulating erythrocytes, which might minimize NO-induced liver damage.     

Degradation of nitrobenzene by a Pseudomonas pseudoalcaligenes.

A Pseudomonas pseudoalcaligenes able to use nitrobenzene as the sole source of carbon, nitrogen, and energy was isolated from soil and groundwater contaminated with nitrobenzene. The range of aromatic substrates able to support growth was limited to nitrobenzene, hydroxylaminobenzene, and 2-aminophenol. Washed suspensions of nitrobenzene-grown cells removed nitrobenzene from culture fluids with the concomitant release of ammonia. Nitrobenzene, nitrosobenzene, hydroxylaminobenzene, and 2-aminophenol stimulated oxygen uptake in resting cells and in extracts of nitrobenzene-grown cells. Under aerobic and anaerobic conditions, crude extracts converted nitrobenzene to 2-aminophenol with oxidation of 2 mol of NADPH. Ring cleavage, which required ferrous iron, produced a transient yellow product with a maximum A380. In the presence of NAD, the product disappeared and NADH was produced. In the absence of NAD, the ring fission product was spontaneously converted to picolinic acid, which was not further metabolized. These results indicate that the catabolic pathway involves the reduction of nitrobenzene to nitrosobenzene and then to hydroxylaminobenzene; each of these steps requires 1 mol of NADPH. An enzyme-mediated Bamberger-like rearrangement converts hydroxylaminobenzene to 2-aminophenol, which then undergoes meta ring cleavage to 2-aminomuconic semialdehyde. The mechanism for release of ammonia and subsequent metabolism are under investigation.     

Co-ordination behaviour of nucleic acid bases against the Fe(I)(NO)-2 group in solution. I. Purines: ESR study.

The binding sites of purine bases in the presence of the Fe(I)(NO)-2 group were investigated on the basis of the nuclear hyperfine structure of the electron spin resonance spectra. Selective isotopic substitution with 15-NO was used to clarify co-ordindination. Coupling constants and different types of complexes were determined by means of computer-simulated ESR spectra. Comparison was made with the binding sites of nucleotides and it was concluded that N-7, in the imidazole ring, is the preferred binding site. A structure with two base molecules bonded to the iron atom was proposed. Finally 8-azaguanine, an antitumoral agent, was studied and the special behaviour of this antimetabolite was demonstrated in the biologically-interesting pH values.     

Transfer of nitric oxide from the liver to erythrocytes — An ESR study using nitroglycerin-treated mice

Nitric oxide (NO) formation in the liver and blood of the mouse following intraperitoneal treatment with nitroglycerin (glycerol trinitrate, GTN) was determined using electron spin resonance (ESR) spectroscopy. ESR signals of heme-NO complexes were detected at maximum levels within 5 min in the liver, but increased to a maximum level about 15–30 min later in the blood. GTN is not metabolized to release NO in vitro in the blood of the mouse. The hepatic microsomes which showed the heme-NO complexes ESR signals were incubated with mouse erythrocytes, with the result that a hemoglobin-NO signal was obtained from the erythrocytes. The activities of microsomal cytochrome P-450, the hepatic level of glutathione, and the reduction rate of nitroxide radicals in the in vivo liver, measured using L-band ESR spectroscopy, were temporarily decreased following GTN administration. In conclusion, NO in the liver could be scavenged by circulating erythrocytes, which might minimize NO-induced liver damage.     

Redox-sensitivity and site-specificity of S- and N- denitrosation in proteins

Background

S-nitrosation – the formation of S-nitrosothiols (RSNOs) at cysteine residues in proteins – is a posttranslational modification involved in signal transduction and nitric oxide (NO) transport. Recent studies would also suggest the formation of N-nitrosamines (RNNOs) in proteins in vivo, although their biological significance remains obscure. In this study, we characterized a redox-based mechanism by which N-nitroso-tryptophan residues in proteins may be denitrosated.

Methodology/Principal Findings

The denitrosation of N-acetyl-nitroso Trp (NANT) by glutathione (GSH) required molecular oxygen and was inhibited by superoxide dismutase (SOD). Transnitrosation to form S-nitrosoglutathione (GSNO) was observed only in the absence of oxygen or presence of SOD. Protein denitrosation by GSH was studied using a set of mutant recombinant human serum albumin (HSA). Trp-214 and Cys-37 were the only two residues nitrosated by NO under aerobic conditions. Nitroso-Trp-214 in HSA was insensitive to denitrosation by GSH or ascorbate while denitrosation at Cys-37 was evident in the presence of GSH but not ascorbate. GSH-dependent denitrosation of Trp-214 was restored in a peptide fragment of helix II containing Trp-214. Finally, incubation of cell lysates with NANT revealed a pattern of protein nitrosation distinct from that observed with GSNO.

Conclusions

We propose that the denitrosation of nitrosated Trp by GSH occurs through homolytic cleavage of nitroso Trp to NO and a Trp aminyl radical, driven by the formation of superoxide derived from the oxidation of GSH to GSSG. Overall, the accessibility of Trp residues to redox-active biomolecules determines the stability of protein-associated nitroso species such that in the case of HSA, N-nitroso-Trp-214 is insensitive to denitrosation by low-molecular-weight antioxidants. Moreover, RNNOs can generate free NO and transfer their NO moiety in an oxygen-dependent fashion, albeit site-specificities appear to differ markedly from that of RSNOs.     

Oxidative Pathway for the Biodegradation of Nitrobenzene by Comamonas sp. Strain JS765

Previous studies have shown that the biodegradation of nitrobenzene by Pseudomonas pseudoalcaligenes JS45 proceeds by the reduction of nitrobenzene through nitrosobenzene and hydroxylaminobenzene, followed by rearrangement to 2-aminophenol, which then undergoes meta ring cleavage. We report here the isolation of a Comamonas sp. that uses an oxidative pathway for the complete mineralization of nitrobenzene. The isolate, designated strain JS765, uses nitrobenzene as a sole source of carbon, nitrogen, and energy. Nitrobenzene-grown cells oxidized nitrobenzene, with the stoichiometric release of nitrite. Extracts of nitrobenzene-grown JS765 showed high levels of catechol 2,3-dioxygenase activity that were not abolished by heating the cell extracts to 60(deg)C for 10 min. The ring cleavage product had an absorbance maximum at 375 nm, consistent with that of 2-hydroxymuconic semialdehyde. Both NAD-dependent dehydrogenase and NAD-independent hydrolase activities towards 2-hydroxymuconic semialdehyde were induced in extracts of nitrobenzene-grown cells. Catechol accumulated in the reaction mixture when cells preincubated with 3-chlorocatechol were incubated with nitrobenzene. Conversion of nitrobenzene to catechol by induced cells in the presence of 3-chlorocatechol and (sup18)O(inf2) demonstrated the simultaneous incorporation of two atoms of oxygen, which indicated that the initial reaction was dioxygenation. The results indicate that the catabolic pathway involves an initial dioxygenase attack on nitrobenzene with the release of nitrite and formation of catechol, which is subsequently degraded by a meta cleavage pathway.     

Studies of the catabolic pathway of degradation of nitrobenzene by Pseudomonas pseudoalcaligenes JS45: removal of the amino group from 2-aminomuconic semialdehyde.

Pseudomonas pseudoalcaligenes JS45 utilizes nitrobenzene as the sole source of nitrogen, carbon, and energy. Previous studies have shown that degradation of nitrobenzene involves the reduction of nitrobenzene to nitrosobenzene and hydroxylaminobenzene, followed by rearrangement to 2-aminophenol, which then undergoes meta ring cleavage to 2-aminomuconic semialdehyde. In the present paper, we report the enzymatic reactions responsible for the release of ammonia after ring cleavage. 2-Aminomuconic semialdehyde was oxidized to 2-aminomuconate in the presence of NAD by enzymes in crude extracts. 2-Aminomuconate was subsequently deaminated stoichiometrically to 4-oxalocrotonic acid. No cofactors are required for the deamination. Two enzymes, 2-aminomuconic semialdehyde dehydrogenase and a novel 2-aminomuconate deaminase, distinguished by partial purification of the crude extracts, catalyzed the two reactions. 4-Oxalocrotonic acid was further degraded to pyruvate and acetaldehyde. The key enzyme, 2-aminomuconate deaminase, catalyzed the hydrolytic deamination that released ammonia, which served as the nitrogen source for growth of the organism.     

Cometabolic biotransformation of nitrobenzene by 3-nitrophenol degrading Pseudomonas putida 2NP8

A strain of Pseudomonas putida (2NP8) capable of growing on both 2-nitrophenol and 3-nitrophenol, but not on nitrobenzene (NB), was isolated from municipal activated sludge. 2-Nitrophenol was degraded by this strain with production of nitrite. Degradation of 3-nitrophenol resulted in the formation of ammonia. Cells grown on 2-nitrophenol did not degrade nitrobenzene. A specific nitrobenzene degradation activity was induced by 3-nitrophenol. Ammonia, nitrosobenzene, and hydroxylaminobenzene have been detected as metabolites of nitrobenzene degradation by cells grown in the presence of 3-nitrophenol. These results indicated a NB cometabolism mediated by 3-nitrophenol nitroreductase.     

Denitrosation of carcinostatic nitrosoureas by purified NADPH cytochrome P-450 reductase and rat liver microsomes to yield nitric oxide under anaerobic conditions

The nitrosoureas, CCNU (1-(2-chloroethyl)-3-(cyclohexyl)-1-nitrosourea) and BCNU (1,3-bis(2-chloroethyl)-1-nitrosourea) are representatives of a class of N-nitroso compounds which undergo denitrosation in the presence of NAD(P)H and deoxygenated hepatic microsomes from rats to yield nitric oxide (NO) and the denitrosated parent compound. Formation of NO during microsomal denitrosation of CCNU and BCNU was determined by three methods. With one procedure, NO was measured and concentration shown to increase over time in the head gas above microsomal incubations with BCNU. Two additional methods utilized NO binding to either ferrous cytochrome P-450 or hemoglobin to form distinct Soret maxima at 444 and 415 nm, respectively. Incubation of either BCNU or CCNU in the presence of NAD(P)H and deoxygenated microsomes resulted in the formation of identical cytochrome P-450 ferrous · NO optical difference spectra. Determination of the P-450 ferrous · NO extinction coefficient by the change in absorbance at 444 minus 500 nm allowed measurement of rates of denitrosation by monitoring the increase in absorbance at 444 nm. The rates of BCNU and CCNU denitrosation were determined to be 4.8 and 2.0 nmol NO/min/mg protein, respectively, for phenobarbital (PB) induced microsomes. For the purpose of comparison, the rate of [¹⁴C]CCNU (1-(2-[¹⁴C]chloroethyl)-3-(cyclohexyl)-1-nitrosourea turnover was examined by the isolation of [¹⁴C]CCU (1-(2-[¹⁴C] chloroethyl)-3-(cyclohexyl)-1-urea) from incubations that contained NADPH and deoxygenated PB-induced microsomes. These analyses showed stoichiometric amounts of NO and [¹⁴C]CCU being formed at a rate of 2.0 nmol/min/mg protein. Denitrosation catalysis by microsomes was enhanced by phenobarbital pretreatment and partially decreased by cytochrome P-450 inhibitors, SKF-525A, α-naphthoflavone (ANF), metyrapone, and CO, suggesting a cytochrome P-450-dependent denitrosation. However, in the presence of NADPH and purified NADPH cytochrome P-450 reductase reconstituted in dilauroylphosphatidylcholine, [¹⁴C]CCNU was shown to undergo denitrosation to [¹⁴C]CCU. Thus, NADPH cytochrome P-450 reductase could support denitrosation in the absence of cytochrome P-450.     

Electron spin resonance studies on the lipoxygenase reaction by spin trapping and spin labelling methods.

The rate of oxygenation and that of trapping linoleic acid free radicals in the lipoxygenase [EC 1.13.11.12] reaction were measured in the presence of linoleic acid, oxygen, and nitrosobenzene at various concentrations, with a Clark oxygen electrode and ESR spectroscopy. The results were interpreted under the assumption that the free radical of linoleic acid, an intermediate of the lipoxygenase reaction, reacts competitively with oxygen or nitrosobenzene. The oxidation of the iron in the active site of lipoxygenase caused by the spin label reagent, 2-(10-carboxydecyl)-2-hexyl-4,4-dimethyl-3-oxazolidinyloxyl, was also observed by ESR- and fluorescence-spectroscopy.     

In vivo on-line detection of no distribution in endotoxin-treated mice by l-band ESR.

The report describes a method for tracing nitric oxide (NO) distribution in endotoxin-treated mice using in vivo low-frequency L-band (1.1 GHz) electron spin resonance spectroscopy (ESR) in combination with extracellular nitric oxide trapping complex consisting of N-methyl-D-glucamine dithiocarbamate and iron (MGD-Fe). An ESR signal characteristic of the MGD-Fe-NO complex was found in the upper abdomen (liver region), lower abdomen and head region of ICR mice. The origin of NO from the L-arginine-NO synthase (NOS) pathway was confirmed using the NOS inhibitor N(G)-monomethyl-L-arginine (NMMA) and isotopic tracing experiments with 15N-labelled L-arginine. Experiments with mice lacking inducible NOS (iNOS) and matched wild type animals were performed using the NO trapping agent diethyldithiocarbamate (DETC). These experiments demonstrated that endotoxin-induced NO generation in the liver tissue of mice occurs via the iNOS isoform of NOS. The described in vivo ESR technique using a "whole body" resonator allows in vivo on-line detection of endogenous NO in mice.     

Biotransformation of N-substituted aromatic compounds in mammalian spermatozoa. Nonoxidative formation of N-hydroxy-N-arylacetamides from nitroso aromatic compounds

The metabolism of N-substituted aromatic compounds, i.e. aniline, acetanilide, N-hydroxyacetanilide, nitrosobenzene, and nitrobenzene in mammalian spermatozoa was investigated. In boar spermatozoa fortified with glucose, no acetylation, deacetylation, and monooxygenation of these compounds were found. Nitrobenzene was reduced slowly, but nitrosobenzene was a good substrate for this reductive activity. In the latter reaction, the products were N-hydroxyacetanilide, azoxybenzene, and an organic phase-nonextractable metabolite(s). Pyruvate was found to be involved in the formation of N-hydroxyacetanilide from nitrosobenzene, and the reaction occurred through a ping-pong mechanism. This enzymatic activity, located in the mid-piece fraction of spermatozoa, was enhanced by thiamine pyrophosphate and Mg2+ and inhibited by thiamine thiazolone pyrophosphate. N-Hydroxyacetanilide formed from [3(-13)C]pyruvate showed complete retention of the isotope at the methyl carbon of the molecule. 2-Nitrosofluorene and 4-nitrosobiphenyl were also transformed into the corresponding N-hydroxy-N-arylacetamides. N-Hydroxyacetanilide was also formed in rat and human spermatozoa. These facts suggest that the formation of N-hydroxy-N-arylacetamides from the nitroso aromatic compounds and pyruvate is mediated by a pyruvate dehydrogenase complex located in the mitochondria of spermatozoa. The formation of both azoxybenzene and the organic phase-nonextractable metabolite(s) was found to be a pyruvate-independent nonenzymatic reaction.     

Antibacterial activity of some α- substituted 2-Methyl-5-nitrofurans

The minimum inhibitory concentration values against Gram-negative and Gram-positive bacteria were determined and compared for a selected group of synthesized alpha-substituted 2-methyl-5-nitrofuran derivatives. In vitro oxidation of thiols to disulfides by 2-(iodomethyl)-5-nitrofuran indicated that oxidation of enzyme-thiol groups to disulfide bonds was a possible mode of action; but was discounted by noninhibition of thiol enzymes by these compounds. Electron-microscopic studies of the morphology of bacteria after treatment with these derivatives showed the formation of unusual elongation, branching and atypical rod shapes in E. coli, while S. aureus manifested multibud formation with some cytoplasmic protrusions. The possible mode of action of these compounds is discussed.     

Protective effect of spin trap agent, N-tert-butyl-alpha-phenylnitrone on hyperoxia-induced oxidative stress and its potential as a nitric oxide donor

We have previously suggested that the spin trap agent, N-tert-butyl-alpha-phenylnitrone (PBN) can function not only as an antioxidant but also as a nitric oxide (NO) donor. To characterize the pharmacological activities of PBN against oxidative damage, we examined the effect of PBN on NO generation under hyperoxic conditions. The formation of NO in mice exposed to 95% oxygen was determined using a NOx analyzer and electron spin resonance (ESR). Levels of NOx, an oxidative product of NO, increased in the blood of mice under these conditions. However, the increase was returned to a normal level by the NOS (nitric oxide synthase) inhibitor, L-NMMA, indicating that the NO was formed via a biosynthetic pathway. In addition, ESR spectra of the liver and brain of control and experimental mice that were measured using Fe(DETC)2 as an NO trap reagent showed strong ESR signals from NO complexes in the livers of mice exposed to 95% oxygen. When examining the effect of PBN in mice, PBN reduced the NOx formation in the blood under the same hyperoxic conditions. In addition, the ESR intensity of the NO complex was weaker in the PBN-treated mice than in the non-treated mice, showing that PBN possess anti-inflammatory properties. However, under a normal atmosphere, NOx and ESR analyses showed that NO levels increased in PBN-treated mice but not in control mice. These findings suggested that PBN functions as an NO donor under specific physiological conditions. PBN appears to protect against hyperoxia-induced NO toxicity by anti-inflammatory action rather than by serving as an NO donor.     

Therapeutic effects of DCDDP, a calcium channel blocker, on chronic pulmonary hypertension in rat.

To explore the effect of dimethyl 4-(2-chlorophenyl)-1,4-dihydro-2,6-dimethyl-3,5-pyridinedicarboxylate (DCDDP) on pulmonary hypertension (PH) induced by monocrotaline (MCT), the parameters of pulmonary hemodynamics, the contents of endothelin-like immunoreactivity, nitric oxide (NO), malondialdehyde, and superoxide dismutase in plasma and pulmonary homogenate were measured. DCDDP was administered in 5, 50, and 500 microg x kg(-1) x day(-1) ip doses, once a day for 28 days. The antiserotonin effect of DCDDP was investigated by using immunohistochemistry, image analysis, and cell culture technique. The results showed that pulmonary arterial pressure was significantly dropped and pulmonary resistance was decreased in DCDDP groups, compared with the MCT group. DCDDP had no influence on endothelin-like immunoreactivity levels in plasma and pulmonary homogenate but reduced the contents of NO, superoxide dismutase, and malondialdehyde in pulmonary homogenate enhanced by MCT. DCDDP also significantly inhibited the increase in numbers of 5-hydroxytryptamine (5-HT) and 5-HT receptor-positive cells in pulmonary tissue of PH rats induced by MCT. The proliferation and contraction of pulmonary arterial smooth muscle cells and the increase in concentration of free Ca(2+) in them evoked by 5-HT were inhibited significantly by DCDDP. The results suggest that DCDDP reduces the production of free radicals and content of 5-HT and 5-HT receptor and the increase in NO in pulmonary tissue, which underlies the mechanisms of DCDDP against MCT-induced PH.     

Direct asymmetric N-specific reaction of nitrosobenzene with aldehydes catalyzed by a chiral primary amine-based organocatalyst

Nitroso compounds have two reactive nitrogen and oxygen atoms. It is interesting and important to perform a nitrogen or oxygen selective reaction with interesting substrates. These atom specific reactions are crucial to specifically synthesis of specific compounds. An enantioselective N-specific reaction of nitrosobenzene with unmodified aldehydes was successfully achieved catalyzed first by a variety of primary amine-based organocatalysts with higher yield and enantioselectivity. The bulkier substituted groups of the organocatalyst and two hydrogen bonds from the organocatalyst and the oxygen atom of nitrosobenzene make the reaction preferentially N-specific and predominantly afford R products.