NQO1酶及其被氧环境诱导表达的研究进展

NAD（P）H：醌氧化还原酶1（NQO1）是真核细胞内普遍存在的一类黄素蛋白酶,它专性催化胞内双电子还原反应,能够解除醌类物质对细胞的毒害,从而起到保护细胞的作用。同时,它又能活化一些醌类抗肿瘤药物。本文综述了NQO1的基因结构、多态性、功能和活性调节,以有它在包内氧化还原环境和肿瘤治疗中的地位等方面的研究进展。     

Changes in the microbial community structure during thermophilic composting of manure as detected by the quinone profile method

Quinone profiles and physico-chemical properties were measured to characterize the microbial community structure during a 14-day thermophilic composting of cattle manure mixed with rice straw as a bulking agent. The change in total quinone content (TQ) and the divergence of quinone (DQ) indicated that the microbial biomass reached a peak followed by a decrease, whereas the microbial community diversity increased continuously during the composting process. The high mole fraction of ubiquinones in the raw materials, and at the beginning of the composting period suggested that fungi and/or Proteobacteria were present. The predominance of MK-7 from days 3 to 7 suggested that Bacillus spp. were the main microbial species. An increase in partially saturated and long-chain menaquinones during the latter composting period indicated that the proliferation of various species of Actinobacteria was occurring. The microbial community structure, as expressed by TQ and DQ, corresponded well to physico-chemical properties such as the C/N ratio, pH, O₂ consumption and compost mass reduction.     

Dopamine Oxidation Alters Mitochondrial Respiration and Induces Permeability Transition in Brain Mitochondria

Both reactive dopamine metabolites and mitochondrial dysfunction have been implicated in the neurodegeneration of Parkinson's disease. Dopamine metabolites, dopamine quinone and reactive oxygen species, can directly alter protein function by oxidative modifications, and several mitochondrial proteins may be targets of this oxidative damage. In this study, we examined, using isolated brain mitochondria, whether dopamine oxidation products alter mitochondrial function. We found that exposure to dopamine quinone caused a large increase in mitochondrial resting state 4 respiration. This effect was prevented by GSH but not superoxide dismutase and catalase. In contrast, exposure to dopamine and monoamine oxidase-generated hydrogen peroxide resulted in a decrease in active state 3 respiration. This inhibition was prevented by both pargyline and catalase. We also examined the effects of dopamine oxidation products on the opening of the mitochondrial permeability transition pore, which has been implicated in neuronal cell death. Dopamine oxidation to dopamine quinone caused a significant increase in swelling of brain and liver mitochondria. This was inhibited by both the pore inhibitor cyclosporin A and GSH, suggesting that swelling was due to pore opening and related to dopamine quinone formation. In contrast, dopamine and endogenous monoamine oxidase had no effect on mitochondrial swelling. These findings suggest that mitochondrial dysfunction induced by products of dopamine oxidation may be involved in neurodegenerative conditions such as Parkinson's disease and methamphetamine-induced neurotoxicity.     

Histochemical Detection of Quinone Reductase Activity In Situ Using LY 83583 Reduction and Oxidation

Abstract: The application of enzymatic staining techniques, using tetrazolium dyes, to aldehyde-treated brain sections has revealed the presence of NADPH-diaphorase activity attributed to nitric oxide synthase. When evaluating the specificity of the putative guanylyl cyclase inhibitor LY 83583, a robust and novel staining pattern was noted in epithelial, endothelial, and astrocytic cells when LY 83583 was included in the NADPH-diaphorase histochemical reaction. This LY 83583-dependent staining could be blocked by the NAD(P)H:quinone oxidoreductase inhibitor dicumarol. Based on its quinone structure, we hypothesized that LY 83583 was a substrate for the enzyme NAD(P)H:quinone oxidoreductase. Transfection of human embryonic kidney 293 cells with the rat liver isoform of NAD(P)H:quinone oxidoreductase resulted in robust NADPH- and LY 83583-dependent staining that was completely blocked by dicumarol and was not observed in untransfected cells. Analysis of transfected cell extracts and brain homogenates indicated that LY 83583 was a substrate for NAD(P)H:quinone oxidoreductase, with a K _m similar to the well-characterized substrate menadione. Sensitivity of the nitroblue tetrazolium reduction to superoxide dismutase indicated that the reduction of LY 83583 by NAD(P)H:quinone oxidoreductase leads to superoxide generation. The localization of NAD(P)H:quinone oxidoreductase activity to astrocytic cells suggests a role for glia in combating oxidative insults to brain and in activating quinone-like drugs such as LY 83583.     

Enhanced NAD(P)H:Quinone Reductase Activity Prevents Glutamate Toxicity Produced by Oxidative Stress

Glutamate toxicity in the N18-RE-105 neuronal cell line results from the inhibition of high-affinity cystine uptake, which leads to a depletion of glutathione and the accumulation of oxidants. Production of superoxides by one-electron oxidation/reduction of quinones is decreased by NAD(P)H:quinone reductase, an enzyme with DT-diaphorase activity. Using glutamate toxicity in N18-RE-105 cells as a model of neuronal oxidative stress, we report that the degree of glutamate toxicity observed is inversely proportional to quinone reductase activity. Induction of quinone reductase activity by treatment with t-butylhydroquinone reduced glutamate toxicity by up to 80%. In contrast, treatment with the quinone reductase inhibitor dicumarol potentiated the toxic effect of glutamate. Measurement of cellular glutathione indicates that increases in its levels are not responsible for the protective effect of t-butylhydroquinone treatment. Because many types of cell death may involve the formation of oxidants, induction of quinone reductase may be a new strategy to combat neurodegenerative disease.     

Fluorescence and energy transfer in phycobiliprotein-containing algae at low temperature

Fluorescence emission spectra of Anacystis nidulans, Porphyridium cruentum and Cyanidium caldarium, three phycobiliprotein-containing algae, were measured at temperatures between 4 and 120 K in the absence and in the presence of quinones as quenchers of chlorophyll fluorescence. In all species three major emission bands were observed in the chlorophyll a region, near 685 nm (F-685), 695 nm (F-695) and between 710 and 730 nm. Additional bands were observed at shorter wavelengths; these were preferentially excited by light absorbed by the phycobiliproteins and are presumably due to phycocyanins and allophycocyanins.

The amplitudes of F-685, F-695 and the long-wave emission showed a distinct increase upon cooling. For F-685 and F-695 the temperature dependence was similar to that earlier observed with spinach chloroplasts, for the long-wave emission it appeared to depend on the location of the emission bands, which was different for different species. All three bands were strongly quenched by quinones. These and other data suggest that the origin of these bands is the same as in higher plants, and that the fluorescence increase upon cooling can be explained by a lowering of the efficiency of energy transfer between chlorophyll molecules. It is concluded that at most a small percentage of the emission at 685 nm can be ascribed to allophycocyanin B, and that the efficiency of energy transfer between allophycocyanin B and chlorophyll a probably exceeds 99% both at 77 and 4 K. Experiments with isolated phycobilisomes suggest that energy transfer from allophycocyanin to allophycocyanin B occurs with an efficiency of about 90% at low temperature.

The effect of quenchers can be understood by the assumption that the quenching is caused by the formation of non-fluorescent traps in the bulk chlorophyll. Of three quinones tested, the strongest quenching was observed with dibromothymoquinone, which quenched F-685, F-695 and the long-wave emission approximately equally. Menadione and 1,4-naphthoquinone, however, preferentially quenched the long-wave bands, indicating a stronger interaction with Photosystem I than with Photosystem II chlorophylls.     

Orientation of the primary quinone of bacterial photosynthetic reaction centers contined in chromatophore and reconstituted membranes

The orientation of the reaction center bacteriochlorophyll dimer, (BChl)₂, and primary quinone, Q_I, has been studied by EPR in chromatophores of Rhodopseudomonas sphaeroides R26 and Chromatium vinosum and in the reconstituted membrane multilayers of the isolated Rps. sphaeroides reaction center protein. The similarity in the angular dependence of the (BChl)₂ triplet and Q_I?Fe²⁺ signals in the chromatophore and reconstituted reaction center membrane multilayers indicates that the reaction center is similarly oriented in both native and model membranes. The principle magnetic axes of the (BChl)₂ triplet are found to lie with the x direction approximately parallel to the plane of the membrane surface, and the z and y directions approx. 10–20° away from the plane of the membrane surface and membrane normal, respectively. The Q_I?Fe²⁺ signals are found to have the g 1.82 component positioned perpendicular to the plane of the membrane surface, with an orthogonal low-field transition (at g 1.68 in Rps. Sphaeroides and at g 1.62 in C. vinosum) lying parallel to the plane of the membrane surface. The orientation of Q_I was determined by the angular dependence of this signal in Fe²⁺-depleted reaction center reconstituted membrane multilayers, and it was found to be situated most likely with the plane of the quinone ring perpendicular to the plane of the membrane surface.     

Immobilized radicals. IV. Biological semiquinone anions and neutral semiquinones

The semiquinone anion and neutral semiquinone radicals of benzoquinone, vitamin K-1, ubiquinone and plastoquinone were generated in both protic and aprotic solvents and frozen to produce immobilized spectra. The linewidths of the neutral semiquinones were always much larger than those of the corresponding anion radicals. Furthermore, the spectra of the neutral radicals often exhibit fine structure. When compared with in vivo spectra of semiquinones, these model systems suggest that the ubisemiquinone anion radical observed in photosynthetic bacteria can exist in either a protic or aprotic environment. There is also the implication that Signal II in chloroplasts may be a plastosemiquinone radical with a spin distribution similar to that of the neutral radical.     

ESR characteristics of Photosystem I in deuterium oxide: Further evidence that electron acceptor A1 is a quinone

The appearance of ESR signals from Photosystem I (PS I) electron acceptors A₁ and A₀ in water or deuterium oxide suspension was followed using a low-temperature photoaccumulation technique. In deuterated samples the A₁ signal was narrowed by a factor of 0.66 compared with the control. This effect was fully reversible upon resuspension of treated samples in H₂O. The narrow ESR signal from deuterated A₁ had similar power saturation characteristics to the normal signal; however, a signal from a second component resolved by deuteration was saturated at higher microwave powers than the control. The power saturation behaviour of A⁻₁ in un-modified reaction centres indicated that it is an anionic semiquinone in a ‘protic’ environment. Deuteration reversibly modified the relative extents of reduction of iron sulphur electron acceptors A and B such that centre B became the more stable electron acceptor. The g-value and line-width of iron sulphur centre X was not modified by deuteration although it appeared to become more efficiently reduced. These results are discussed in the light of current evidence from optical, electron spin polarisation and extraction experiments that suggest that A₁ is a quinone, probably vitamin K-1.     

Electron acceptors of bacterial photosynthetic reaction centers II. H+ binding coupled to secondary electron transfer in the quinone acceptor complex

The photoreduction of ubiquinone in the electron acceptor complex (Q₁Q₁₁) of photosynthetic reaction centers from Rhodopseudomonas sphaeroides, R26, was studied in a series of short, saturating flashes. The specific involvement of H⁺ in the reduction was revealed by the pH dependence of the electron transfer events and by net H⁺ binding during the formation of ubiquinol, which requires two turnovers of the photochemical act. On the first flash Q₁₁ receives an electron via Q₁ to form a stable ubisemiquinone anion (Q?^?₁₁); the second flash generates Q?^?₁. At low pH the two semiquinones rapidly disproportionate with the uptake of 2 H⁺, to produce Q₁₁H₂. This yields out-of-phase binary oscillations for the formation of anionic semiquinone and for H⁺ uptake. Above pH 6 there is a progressive increase in H⁺ binding on the first flash and an equivalent decrease in binding on the second flash until, at about pH 9.5, the extent of H⁺ binding is the same on all flashes. The semiquinone oscillations, however, are undiminished up to pH 9. It is suggested that a non-chromophoric, acid-base group undergoes a pK shift in response to the appearance of the anionic semiquinone and that this group is the site of protonation on the first flash. The acid-base group, which may be in the reaction center protein, appears to be subsequently involved in the protonation events leading to fully reduced ubiquinol. The other proton in the two electron reduction of ubiquinone is always taken up on the second flash and is bound directly to Q?^?₁₁. At pH values above 8.0, it is rate limiting for the disproportionation and the kinetics, which are diffusion controlled, are properly responsive to the prevailing pH. Below pH 8, however, a further step in the reaction mechanism was shown to be rate limiting for both H⁺ binding electron transfer following the second flash.