Regulation of Cytochrome c- and Quinol Oxidases,and Piezotolerance of Their Activities in the Deep-Sea Piezophile Shewanella violacea DSS12 in Response to Growth Conditions

The facultative piezophile Shewanella violacea DSS12 is known to have respiratory components that alter under the influence of hydrostatic pressure during growth, suggesting that its respiratory system is adapted to high pressure. We analyzed the expression of the genes encoding terminal oxidases and some respiratory components of DSS12 under various growth conditions. The expression of some of the genes during growth was regulated by both the O₂ concentration and hydrostatic pressure. Additionally, the activities of cytochrome c oxidase and quinol oxidase of the membrane fraction of DSS12 grown under various conditions were measured under high pressure. The piezotolerance of cytochrome c oxidase activity was dependent on the O₂ concentration during growth, while that of quinol oxidase was influenced by pressure during growth. The activity of quinol oxidase was more piezotolerant than that of cytochrome c oxidase under all growth conditions. Even in the membranes of the non-piezophile Shewanella amazonensis, quinol oxidase was more piezotolerant than cytochrome c oxidase, although both were highly piezosensitive as compared to the activities in DSS12. By phylogenetic analysis, piezophile-specific cytochrome c oxidase, which is also found in the genome of DSS12, was identified in piezophilic Shewanella and related genera. Our observations suggest that DSS12 constitutively expresses piezotolerant respiratory terminal oxidases, and that lower O₂ concentrations and higher hydrostatic pressures induce higher piezotolerance in both types of terminal oxidases. Quinol oxidase might be the dominant terminal oxidase in high-pressure environments, while cytochrome c oxidase might also contribute. These features should contribute to adaptation of DSS12 in deep-sea environments.     

镉和增强紫外线-B辐射复合作用对大豆生长的影响

研究了Cd^2+和增强紫外线-B(UV-B)辐射以及二者复合胁迫(Cd+UV-B)对大豆生长、光合作用、抗氧化酶活性和吲哚乙酸(IAA)氧化酶活性的影响,结果表明,UV-B辐射对大豆生长较CA^2+有更明显的抑制作用,主要是降低了光合作用,生物量减小;抑制节间的分化和伸长,节间减少,株高降低。UV-B辐射对POD、SOD活性有显著诱导作用,而Cd^2+明显颉颃UV-B对POD活性的诱导并抑制IAA氧化酶活性．在复合作用下,植物体内IAA氧化酶和POD活性较UV-B单独作用下显著降低,这两种酶活性降低会引起植物体内IAA含量升高,同时光合作用略有升高,这是株高和生物量较UV-B作用下有所增加的重要原因,复合胁迫还增强了对根伸长生长的抑制作用,根长度较对照显著降低(P<0．05)。IAA氧化酶和POD活性变化以及光合强度变化与大豆株高和生物量变化密切相关,这也是复合胁迫影响大豆生长状况的重要因素。     

Activities of Cu-containing proteins in Cu-depleted pea leaves

The effect of Cu deficiency on Cu-containing enzymes and on their activities was studied with two subsequent generations of Cu-deficient pea plants ( Pisum sativum L., cv. Progress) grown in low Cu²⁺ media. Cu deficiency caused growth inhibition and a decrease in photosynthesis as well as in the activities of 3 Cu-containing enzymes: diamine oxidase (EC 1.4.3.6), ascorbate oxidase (EC 1.10.3.3) and superoxide dismutase (EC 1.15.1.1). Determinations of photosynthetic electron-transport rates as well as the concentrations of several redox components showed that the target of Cu deprivation in the photosynthetic apparatus is the synthesis of Cu-containing plastocyanin which is positively correlated to the Cu content of the leaves. Inhibited formation of plastocyanin resulted in low activities of photosynthetic electron transport in photosystem I. Under Cu-deficient conditions, the activities of diamine oxidase and ascorbate oxidase were inhibited by about 50% in the first and 80% in the second generation of pea plants. Enzyme assays showed an inhibition of the activities of both the plastidic and cytoplasmic Cu/Zn-containing superoxide dismutases. An observed simultaneous increase of Mn-superoxide dismutase may be a compensation mechanism to partially maintain the total superoxide-dismutase activity under Cu-deficient conditions. This result indicates that the formation of superoxide-dismutase isoenzymes is interdependent and coordinated.     

Salt Stress Induced Changes in Growth and Enzyme Activities in Germinating Phaseolus Mungo Seeds

NaCl salt stress induced changes in growth and enzyme activities in blackgram (Phaseolus mungo L.) seeds during germination were studied. A decrease in germination percentage, root length, shoot length, and fresh mass was noticed with an increase in NaCl concentration. With the increase in NaCl concentration and duration of stress proline content increased and catalase (CAT), peroxidase (POX) and polyphenol oxidase (PPO) activities decreased.     

间苯二酚、水杨酸对绿豆下胚轴不定根形成的作用

２０—１００ｍｇＬ（－１）间苯二酚能明显地促进绿豆下胚轴不定根的形成,与２０ｍｇＬ（－１）ＩＢＡ混合处理具加成效应,其作用在于降低生根初期ＩＡＡ氧化酶和多酚氧化酶活性．１０—１００ｍｇＬ（－１）水杨酸抑制下胚轴不定根的形成,随处理浓度的加大,对生根数目、生根范围和根重的抑制作用增加．水杨酸处理后１－３ｄ,能提高ＩＡＡ氧化酶和多酚氧化酶的活性．     

Oxygen activation and defence against oxygen toxicity in a psychrophilic bacteroidaceae

When suddenly exposed to air the growth of the obligate anaerobic bacterium of the bacteroidaceae type, strain B6, continues for a few hours before coming to a complete stop. When air is shut off soon after growth has ceased, the organism is able to reestablish anaerobic conditions due to an ability to reduce O₂, and resumes normal growth after another few hours. The O₂ reducing ability of the organism is due to the presence in the cells of a particlebound NADH oxidase, a soluble NADPH oxidase and a soluble pyruvate oxidase. The two pyridine nucleotide oxidase reduce O₂ to H₂O₂, the pyruvate oxidase reduces O₂ to H₂O. Catalase and peroxidase were not detected in anaerobically grown cells. Kinetic studies with cell-free extracts showed that the pyruvate oxidase had a considerably greater affinity (smaller K _m) for O₂ and capacity (higher V _max) for O₂ reduction than the two other oxidases. It is postulated that the pyruvate oxidase acts as a scavenger for O₂, leading to the non-toxic reduction product H₂O, and thus functions as a defense mechanism against oxygen toxicity when the organism is exposed to aerobic condition.Abbreviations PY peptone-yeast extract - PYG PY-glucose - PN pyridine nucleotide - PNH reduced PN - CCCP carbonylcyanide m-chlorophenylhydrazone - DNP 2.4-dinitrophenol     

RNA interference targeting tNOX attenuates cell migration via a mechanism that involves membrane association of Rac

tNOX, a tumor-associated NADH oxidase, is a growth-related protein present in transformed cells. In this study, we employed RNA interference (RNAi)-mediated down-regulation of tNOX protein expression to explore the role of tNOX in regulating cell growth in human cervical adenocarcinoma (HeLa) cells. In this first reported use of RNAi to decrease tNOX expression, we found that HeLa cell growth was significantly inhibited by shRNA-knockdown of tNOX. Furthermore, cell migration and membrane association of Rac were decreased concomitantly with the reduction in tNOX protein expression. These results indicate that shRNA targeting of tNOX inhibits the growth of cervical cancer cells, and reduces cell migration via a decrease in the membrane association of Rac. We propose that tNOX is a potential upstream mediator of Rho activation that plays a role in regulating cell proliferation, migration, and invasion.     

Biogenesis and turnover of peroxisomes involved in the concurrent oxidation of methanol and methylamine in Hansenula polymorpha

Growth of Hansenula polymorpha in shake flasks and chemostat cultures in the presence of methanol as the sole source of carbon and methylamine as the sole source of nitrogen was associated with the development of peroxisomes in the cells. The organelles were involved in the concurrent oxidation of these two compounds, since they contained both alcohol oxidase and amine oxidase, which are key enzymes in methanol and methylamine metabolism, respectively. In addition catalase was present. Peroxisomes with a completely crystalline substructure were observed in methanol-limited chemostat-grown cells. Amine oxidase probably formed an integral part of these crystalloids, whereas catalase was present in a freely diffusable form. Transfer of cells, grown in a methanol-limited chemostat in the presence of methylamine into glucose/ammonium sulphate media resulted in the loss of both alcohol oxidase and amine oxidase activity from the cells. This process was associated with degradation of the crystalline peroxisomes. However, when cells were transferred into glucose/methylamine media, amine oxidase activity only declined during 2 h after the transfer and thereafter increased again. This subsequent rise in amine oxidase activity was associated with the development of new peroxisomes in the cells in which degradation of the crystalline peroxisomes, originally present, continued. These newly formed organelles probably originated from peroxisomes which had not been affected by degradation. When in the methanollimited chemostat methylamine was replaced by ammonium sulphate, repression of the synthesis of amine oxidase was observed. However, inactivation of this enzyme or degradation of peroxisomes was not detected. The decrease of amine oxidase activity in the culture was accounted for by dilution of enzyme as a result of growth and washout.     

Glycolate oxidase is an alternative source for H2O2 production during plant defense responses and functions independently from NADPH oxidase

The photorespiratory enzyme glycolate oxidase (GOX) was found to be involved in nonhost resistance by regulating plant defense responses through the production of H₂O₂. Silencing of a gene encoding NADPH oxidase (AtRBOHD) in the gox mutants did not further increase susceptibility to a nonhost pathogen, P. syringae pv tabaci, although it caused an increase in bacterial growth in the Atgox1 and Atgox3 mutant backgrounds. In order to confirm this finding, we created double homozygous knockouts AtrbohD x Atgox1 and AtrbohD x Atgox3 to evaluate symptom development and bacterial growth. Here we show that there is no additive effect of disease symptoms or bacterial growth in the AtrbohD x Atgox1 and AtrbohD x Atgox3 double mutants when compared with individual mutants. Slight additive effect observed previously upon silencing of AtRBOHD in Atgox1 and Atgox3 mutants was most likely due to cross-silencing of AtRBOHF. These results further prove that GOX plays a role in nonhost resistance independent of NADPH oxidase.     

Plant hormone homeostasis and the control of avocado fruit size

Control of plant hormone homeostasis is crucial for normal organdevelopment in plants. To elucidate the contribution of plant hormonehomeostasis to fruit growth, tissue distribution and activity of xanthinedehydrogenase (XDH), abscisic aldehyde (AB-ald)- and indole acetaldehyde(IA-ald) oxidase, and cytokinin oxidase (CKOX) were determined in seed, seedcoat and mesocarp of normal 'Hass avocado and its small-fruitphenotype during the linear phase of growth. Activity of these enzymes wasrelated to the tissue content of indole-3-acetic acid (IAA) and abscisic acid(ABA). IA-ald oxidase was present only in seed tissue whereas AB-ald oxidase andXDH activity was found in seed and mesocarp tissue. Seed of the small'Hass fruit had increased XDH and AB-ald oxidase activity and highendogenous ABA, but reduced IA-ald oxidase activity and adenine. There was nodifference in seed, seed coat and mesocarp CKOX activity between normal andsmall fruit. Inhibition of XDH activity in whole fruit by treatment withallopurinol decreased IAA and increased ABA of seed tissue. In mesocarp ofripening fruit allopurinol increased ABA and IAA but had no effect on levels ofiP. Results indicate that activity of IA-ald and AB-ald oxidases in avocadofruit contribute to maintenance of the IAA/ABA ratio in seed and mesocarp tissueand that increased AB-ald oxidase, or reduced IA-ald oxidase, may be part of thesyndrome associated with the appearance of a small-fruit phenotype.     

Inhibition of plasma membrane NADH oxidase activity and growth of HeLa cells by natural and synthetic retinoids

Several retinoids, both natural and synthetic, were evaluated for their ability to modulate NADH oxidase activity of plasma membranes of cultured HeLa cells and the growth of HeLa cells in culture. Both NADH oxidase activity and the growth of cells were inhibited by the naturally-occurring retinoids all trans-retinoic acid (tretinoin) and retinol as well as by the synthetic retinoids, trans-acitretin, 13-cis-acitretin, etretinate and arotonoid ethylester (Ro 13-6298). For all retinoids tested, inhibition of NADH oxidase activity and inhibition of growth were correlated closely. With tretinoin, etretinate and arotonoid ethylester, NADH oxidase activity and cell growth were inhibited in parallel in proportion to the logarithm of retinoid concentration over the range of concentrations 10-8 to 10-5 M. Approximately 70% inhibition of both NADH oxidase activity and growth was reached at 10 µM. With retinol, trans-acitretin and 13-cis-acitretin, inhibition of NADH oxidase activity and growth also were correlated but maximum inhibition of both was about 40% at 10 µM. The possibility is suggested that inhibition of the plasma membrane NADH oxidase activity by retinoids may be related to their mechanism of inhibition of growth of HeLa cells in culture. (Mol Cell Biochem 166: 101-109, 1997)     

Hydrogenosomes in known species of rumen entodiniomorphid protozoa

Abstract Yeasts of the genus Kluyveromyces grew very slowly on methylamine as sole nitrogen source. Methylamine oxidase activity in cell-free extracts was very low. Under conditions known to separate methylamine oxidase from benzylamine oxidase in other yeast genera, only a single enzyme was detected in Kluyveromyces lactis . This enzyme could oxidize benzylamine, n -butylamine and (very poorly) methylamine. The enzyme lost no activity on heating at 45°C and had a high affinity and V _max for benzylamine and 1-aminoalkanes of long-chain length, with a very low affinity and V _max for methylamine. It is concluded that growth of K. lactis on methylamine involves only benzylamine oxidase, and that a methylamine oxidase of the type found in other yeasts does not occur.     

一株口腔链球菌新种—寡发酵链球菌产过氧化氢特性的研究

从健康人口腔中分离的寡发酵链球菌(Streptococcus oligofermentans)能够产生大量的过氧化氢,可能具有抑制致病菌的潜力。为了研究该细菌产过氧化氢的特性,检测了其在不同生长时期和从不同底物产过氧化氢的能力。结果表明,寡发酵链球菌从对数生长早期就开始产过氧化氢,在对数生长后期及稳定期过氧化氢产量达到最高,随后下降。在PYG培养基中,寡发酵链球菌所产的过氧化氢主要来源于大豆蛋白胨和酵母提取物;而代谢终产物乳酸也可作为过氧化氢产生的底物。对3种可能与过氧化氢生成有关的氧化酶的酶活测定表明,寡发酵链球菌具有乳酸氧化酶(LOX)及NADH氧化酶(NOX)的活性,说明其过氧化氢的产生主要依赖于这两种酶的活力。     

培养条件对毛栓菌菌丝体生长和多酚氧化酶分泌的影响

研究了碳源、氮源、培养温度、初始pH值、接种量、通气量等条件对毛栓菌（Trametes trogii)菌丝体生长及多酚氧化酶分泌的影响;结果表明,不同碳源和氮源对菌丝体生长影响较大,对多酚氧化酶分沁也有较大影响,麦草粉和麸皮为碳源,玉米粉、硫酸铵为氮源有利于多酚氧化酶的分泌;初始pH值对酶活影响较小,培养温度、通气量等对酶活影响较大。     

A Possible Role of Slips in Cytochrome C Oxidase in the Antioxygen Defense System of the Cell

Evidence is available showing that the coupling efficiency of the proton pump in cytochrome c oxidase of mitochondria can under certain conditions decrease significantly below the maximum attainable value. The view is developed that slips in the proton pump of cytochrome c oxidase represent an intrinsic switch mechanism which regulates the relative contribution of energy transfer and respiratory protection against oxygen toxicity by the oxidase.     

Influence of chloramphenicol on growth and respiration of soybean (Glycine max L.) suspension cultures

By addition of chloramphenicol (CAP) to the growth medium of green soybean ( Glycine max L.) cells in batch culture, growth is inhibited and the activity of the cytochrome oxidase decreases to 60% of the value found in control cells. The presence of CAP induces an enhancement of the contribution of the alternative pathway to total respiration. This enlarged contribution results both from a higher capacity of the alternative pathway and from a greater part of this capacity being used. Also in mitochondria isolated from cells treated with CAP, a higher capacity of the alternative pathway has been found, while the part of this capacity which is really used is comparable with the values found in control cells.     

The molybdoenzymes xanthine oxidase and aldehyde oxidase contain fast- and slow-DTNB reacting sulphydryl groups

The reactivities with an excess of 5-5-dithiobis (2-nitrobenzoic) acid (DTNB) of sulphydryl residues present in xanthine oxidase and aldehyde oxidase were studied and compared. The results show that two classes of sulphydryl groups with quite different reactivities exist in both enzymes either native or denatured. Some of the available sulphydryl residues thus react instantaneously with the DTNB, whereas the others react very slowly following pseudo-first-order kinetics. The number of sulphydryl residues of each class and the rate constant of slowly reacting groups are, respectively, 1.7 and 0.8 in native xanthine oxidase and 1.6 and 1.7 in native aldehyde oxidase. In denatured enzymes, the number of fast- and slow-reacting sulphydryl residues obtained are, respectively, 13.9 and 7.9 in xanthine oxidase and 5.7 and 5.4 in aldehyde oxidase. Analogously, the rate constant for the slowly reacting groups is similar for the two native enzymes, but in denatured aldehyde oxidase it is double that of denatured xanthine oxidase.