Isolation of a malachite green-degrading Pseudomonas sp. MDB-1 strain and cloning of the tmr2 gene

The release of malachite green, a commonly used triphenylmethane dye, into the environment is causing increasing concern due to its toxicity, mutagenicity, and carcinogenicity. A bacterial strain that could degrade malachite green was isolated from the water of an aquatic hatchery. It was identified as a Pseudomonas sp. based on the morphological, physiological, and biochemical characteristics, as well as the analysis of 16S rRNA gene sequence and designated as MDB-1. This strain was capable of degrading both malachite green and leucomalachite green, as well as other triphenylmethane dyes including Crystal Violet and Basic Fuchsin. The gene tmr2, encoding the triphenylmethane reductase from MDB-1, was cloned, sequenced and effectively expressed in E. coli. These results highlight the potential of this bacterium for the bioremediation of aquatic environments contaminated by malachite green.     

Acute effects of nitrite on ion regulation in two neotropical fish species

To broaden the understanding of physiological responses of tropical fish to environmental stressors, the effects of nitrite on haematological parameters and plasma and red blood cell ion regulation were studied in two neotropical fish species, Astyanax altiparanae and Prochilodus lineatus. Both fish species were exposed to NaNO2 (30 mg l(-1)) over a 96-h period and blood samples were taken for ion and haematological analyses. The results revealed that nitrite leads to a decrease in P. lineatus blood haematocrit and haemoglobin content and an increase in blood methaemoglobin. A. altiparanae did not exhibit any significant difference in these haematological parameters. During the exposure to NO2- both fish species had significantly reduced plasma Na+ concentration and red blood cell (RBC) K+ concentration, but only P. lineatus showed an increase in extracellular K+ concentration. When RBC volume was analyzed in vitro, after 2 min of exposure to NaNO2, a 36% shrinkage was observed in P. lineatus cells, while only a 10% shrinkage was observed in A. altiparanae cells. These results suggest that for P. lineatus, nitrite entrance into the cell leads to methaemoglobin formation and K+ efflux, causing red cell shrinkage and increased plasma K+. However, A. altiparanae proved to be a species more resistant to nitrite, exhibiting fewer responses to this compound.     

Toxicity and metabolism of malachite green and leucomalachite green during short-term feeding to Fischer 344 rats and B6C3F1 mice

Malachite green, an N-methylated diaminotriphenylmethane dye, has been widely used as an antifungal agent in commercial fish hatcheries. Malachite green is reduced to and persists as leucomalachite green in the tissues of fish. Female and male B6C3F1 mice and Fischer 344 rats were fed up to 1200 ppm malachite green or 1160 ppm leucomalachite green for 28 days to determine the toxicity and metabolism of the dyes. Apoptosis in the transitional epithelium of the urinary bladder occurred in all mice fed the highest dose of leucomalachite green. This was not observed with malachite green. Hepatocyte vacuolization was present in rats administered malachite green or leucomalachite green. Rats given leucomalachite green also had apoptotic thyroid follicular epithelial cells. Decreased T4 and increased TSH levels were observed in male rats given leucomalachite green. A comparison of adverse effects suggests that exposure of rats or mice to leucomalachite green causes a greater number of and more severe changes than exposure to malachite green. N-Demethylated and N-oxidized malachite green and leucomalachite green metabolites, including primary arylamines, were detected by high performance liquid chromatography/mass spectrometry in the livers of treated rats. 32P-Postlabeling analyses indicated a single adduct or co-eluting adducts in the liver DNA. These data suggest that malachite green and leucomalachite green are metabolized to primary and secondary arylamines in the tissues of rodents and that these derivatives, following subsequent activation, may be responsible for the adverse effects associated with exposure to malachite green.     

Malachite Green: Applications in Electron Microscopy

Incorporation of malachite green into a glutaraldehyde fixative results in enhanced staining of a number of cellular elements. Ribosomes and myofilaments exhibit increased electron density, but cell membranes generally are not stained. In certain tissues, lipid inclusions are uniformly and heavily stained. Other populations of lipid droplets exhibit differential affinity for malachite green, facilitating their division into subclasses. In addition to its function as a dye, malachite green has previously been reported to stabilize lipid elements soluble in aqueous glutaraldehyde. Such a component was observed in the stroma of uterine endometrium. The variety of cell components which exhibit increased contrast after preparation with malachite green suggests that this technique may find widespread application in fine structure studies.     

Malachite green: applications in electron microscopy.

Incorporation of malachite green into a glutaraldehyde fixative results in enhanced staining of a number of cellular elements. Ribosomes and myofilaments exhibit increased electron density, but cell membranes generally are not stained. In certain tissues, lipid inclusions are uniformly and heavily stained. Other populations of lipid droplets exhibit differential affinity for malachite green, facilitating their division into subclasses. In addition to its function as a dye, malachite green has previously been reported to stabilize lipid elements soluble in aqueous glutaraldehyde. Such a component was observed in the stroma of uterine endometrium. The variety of cell components which exhibit increased contrast after preparation with malachite green suggests that this technique may find widespread application in fine structure studies.     

Evaluation of different malachite green brands in the performance of rappaport's medium

Summary Three malachite green dyes, Merck's concentrated for microscopy and bacteriology (old), Merck's malachite green oxalate (oxal), and Difco's malachite green, were used for preparation of 3 batches of Rappaport's medium. These media were tested for growth of 40 Salmonella serotypes and for inhibition of competing organisms. All Rappaport's media behaved similarly and supported excellent growth of 38 serotypes. When Salmonella cultures were diluted in fecal-saline suspensions and inoculated in all Rappaport media the competing organisms in these suspensions were efficiently inhibited. However, the inhibition of competing organisms was less efficient when Rappaport's media were inoculated with preenrichment cultures of 20 samples of minced meat in buffered peptone water. In this respect, Difco's malachite green was clearly inferior to the other two dyes. It is concluded that Merck's malachite green oxalate is as efficient as the old dye of the same brand which is no longer produced, and can replace it in the preparation of Rappaport's medium.     

Growth of Salmonella enterica in model mixed cultures during a two-step enrichment

Growth of Salmonella enterica was studied in model mixed cultures with Citrobacter freundii or Escherichia coli in buffered peptone water (BPW) and in Rappaport-Vassiliadis medium with soya (RVS) with modified concentrations of MgCl2 and malachite green, and at modified incubation temperatures. Selected S. enterica strains were inoculated in BPW (10(0) cfu/ml) together with selected strains of Citrobacter freundii (up to 10(8) cfu/ml) or selected strains of Escherichia coli (up to 10(8) cfu/ml), incubated overnight and then subcultured (1: 100) in RVS variants. Growth of individual bacterial species was followed by the quantitative real-time polymerase chain reaction (PCR). Optimal culture conditions during the second selective step were: MgCl2.6 H2O concentration of 29 g/l, malachite green concentration of 36 mg/1l, and the incubation temperature of 41.5 degrees C. Citr. freundii was found to be a potent competitor and E. coli was a weaker competitor. At optimal culture conditions, competition was reduced and the density of S. enterica cultures reached the level of 10(4) cfu/ml after not later than 2 h of selective enrichment. The results obtained provide a basis for the development of a short two-step enrichment to be used in rapid real-time PCR-based methods for the detection of S. enterica in food and other matrices.     

Effect of estrogen on the affinity of malachite green for staining cardiac lipid inclusions in mice

The effect of estradiol-17-beta on lipids of the ventricular myocardium of mice has been studied with a cytochemical technique in which malachite green was added to glutaraldehyde. This malachite green-glutaraldehyde fixative enhances the visualization of certain phospholipid-related elements. Estrogen induces an affinity of ventricular cardiac lipid inclusions for the cationic dye malachite green. The staining affinity is evidenced only in the estrous female, not in diestrus. In oophorectomized animals, malachite green staining is seen only following estradiol injection, but this effect is blocked by progesterone. In the male, ventricular lipids do not stain, nor do they develop malachite green affinity with estrogen stimulation. These results imply a blockade of the estradiol-mediated dye affinity by progesterone and testosterone. This reinforces the concept of the heart as a target organ for sex steroids and expands the previously described estrogen effects on myocardium.     

细菌脱色酶TpmD对三苯基甲烷类染料脱色的酶学特性研究

从嗜水气单胞菌DN322中分离纯化出能够对三苯基甲烷类染料结晶紫、碱性品红、灿烂绿及孔雀绿进行有效脱色的脱色酶,命名为TpmD。该酶的亚基分子量为29.4kDa,等电点为5.6。该酶催化上述4种三苯基甲烷类染料脱色反应的适合温度为40~60℃,适合pH范围为5.5~9.0。动力学参数测定结果显示TpmD对结晶紫、碱性品红、灿烂绿及孔雀绿的Km值分别为24.3、40.65、4.2、68.5μmol-1.L-1,Vmax值分别为19.6、74.1、82.8、115.6μmol.L-1.s-1。结晶紫为该酶的最适反应底物。TpmD催化的脱色反应依懒于NADH/NADPH及分子氧的存在,显示该酶属于NADH/NADPH依赖型的氧化酶类。这是国内外首次关于细菌中三苯基甲烷类染料脱色酶酶学性质的描述。     

Stereum hirsutum (Wild) Pers. action in dye degradation

Stereum hirsutum, a white rot fungus, has a good growth in solid state fermentation. This was carried on with wheat bran, soy bran and a mixture of both. Mycelia grown on soy bran showed the highest decolorization activity on Ponceau 2R (xylidine), indigo carmine and malachite green. Optimal relationship between decolorization and detoxification of malachite green was 30 g of fresh weight (mycelia plus substrate) in 500 ml malachite green solution, 42 U/l of laccase was measured in this solution. Decolorization was carried on without the addition either of nutrients or mediators. Conditions for maximal decolorization did not agree with those for maximal ligninolytic enzyme production, but effectiveness of laccase activity on decolorization was evidenced by electrophoretic analysis, that allowed laccase identification and its decolorization activity in gels stained with indigo carmine and malachite green, with ABTS as mediator. Detoxification was assayed using the sensible fungus Phanerochaete chrysosporium.     

Genotoxicity of malachite green and leucomalachite green in female Big Blue B6C3F1 mice

Malachite green, a triphenylmethane dye used in aquaculture as an antifungal agent, is rapidly reduced in vivo to leucomalachite green. Previous studies in which female B6C3F1 mice were fed malachite green produced relatively high levels of liver DNA adducts after 28 days, but no significant induction of liver tumors was detected in a 2-year feeding study. Comparable experiments conducted with leucomalachite green resulted in relatively low levels of liver DNA adducts but a dose-responsive induction of liver tumors. In the present study, we fed transgenic female Big Blue B6C3F1 mice with 450 ppm malachite green and 204 and 408 ppm leucomalachite green (the high doses used in the tumor bioassays) and evaluated genotoxicity after 4 and 16 weeks of treatment. Neither malachite green nor leucomalachite green increased the peripheral blood micronucleus frequency or Hprt lymphocyte mutant frequency at either time point; however, the 16-week treatment with 408 ppm leucomalachite green did increase the liver cII mutant frequency. Similar increases in liver cII mutant frequency were not seen in the mice treated for 16 weeks with malachite green or in female Big Blue rats treated with a comparable dose of leucomalachite green for 16 weeks in a previous study [Mutat. Res. 547 (2004) 5]. These results indicate that leucomalachite green is an in vivo mutagen in transgenic female mouse liver and that the mutagenicities of malachite green and leucomalachite green correlate with their tumorigenicities in mice and rats. The lack of increased micronucleus frequencies and lymphocyte Hprt mutants in female mice treated with leucomalachite green suggests that its genotoxicity is targeted to the tissue at risk for tumor induction.     

Decolorizing activity of malachite green and its mechanisms involved in dye biodegradation by Achromobacter xylosoxidans MG1

An Achromobacter xylosoxidans MG1 strainisolated from the effluent treatment plant of a textile and dyeing factory from Yunnan Province in China was found capable of decolorizing the malachite green dye at a high efficacy. Strain MG1 reduced 86% malachite green at the concentration of 2,000 mg/l within 1 h, representing a greater ability for decolorizing and a higher tolerance of this compound than all previously reported bacteria. Color removal was optimal at pH 6 and 38°C. Further experimental evidences demonstrated that both cytoplasmic and extracellular biodegradation contributed to the decolorization of malachite green. Nested PCR was employed to identify the candidate genes responsible for malachite green decolorization, and we identified a cytoplasmic triphenylmethane reductase gene with 100% amino acid similarity to the corresponding gene in Citrobacter sp. strain. In contrast to our expectation, the addition of metyrapone had little effect on the cytoplasmic biodegradation, suggesting that cytochrome P450 was not involved in the high-performance reduction. The extracellular biodegradation was likely attributable to the secretion of extracellular proteases and some heat-resistant compounds.     

Fiftyfold amplification of the Lowry protein assay

The blue product of the Lowry et al. (1951, J. Biol. Chem. 193, 265-275) reaction interacts with malachite green (MG), inducing a change in the visible light spectrum. At A690 nm the absorbance of malachite green solutions increases 10-fold in the presence of Lowry blue (LB). Under the optimum conditions, 0.01 A700 nm unit of Lowry blue produces a change in A690 nm unit of malachite green of 0.5 and the delta A690 nm is a linear function of Lowry blue concentration. Conditions under which this 50-fold amplification can be exploited to detect less than 100 ng of protein (or 4 micrograms X ml-1) are described. A number of chemicals including sodium dodecyl sulfate can interfere with the assay but a strategy has been devised to overcome these problems. Amplification of the Lowry assay appears to involve a cooperative interaction between malachite green and the Lowry blue product such that about 23 molecules of malachite green undergo a spectral shift per molecule of a model reactant such as tyrosine. Malachite green can be used to amplify the molybdenum blue signal obtained in other assays. Less than 10 pmol of tyrosine can be detected using this procedure. Lowry blue also interacts with auramine O, giving a large increase in A500 nm and a 40-fold amplification of the LB signal. As with malachite green, there is a cooperative interaction between auramine O and LB. About 72 molecules of auramine O undergo a spectral shift per molecule of tyrosine. The product of this reaction is also fluorescent and could be exploited in a protein assay.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protective effect of activators of biological oxidation in nitrite intoxication in rats]

The purpose of the study was to asses the effect of mexidol, cudesan, hypoxen and essenciale on the functions of the immune system, liver and muscular tissue in nitrite intoxication. The investigation was carried out on Wistar rats exposed to sodium nitrite. Administration of mexidol, cudesan or hypoxen to the animals did not affect the indices characterizing the functional activity of immunocytes, hepatocytes and myocytes. Mexidol in combination with cudesan reduced the intensity of the decrease of the functional metabolic activity of leukocytes and the development of the humoral immune response. Mexidol in combination with hypoxen increased the physical working cepacity of the animals. Both the combinations increased the rate of the drug biotransformation in the liver. The use of essenciale in combination with mexidol resulted in normalization of the metabolic functions of the liver. Essenciale in combination with cudesan normalized the majority of the immunity functions. The combination of essenciale with hypoxen recovered the lowered physical working capacity in the animals.     

孔雀石绿脱色菌恶臭假单胞菌菌株M6的分离、鉴定及其生长特性研究

从养殖池污泥中分离了6株对孔雀石绿具有脱色能力的菌株, 经过进一步在孔雀石绿营养肉汤中富集培养及其脱色率的比较, 筛选出对孔雀石绿具有较强脱色能力的优良菌株M6。菌株M6在30°C、150 r/min条件下对孔雀石绿的脱色率为97.14％, 通过革兰氏染色、电镜对其形态进行了观察, 用ATB细菌鉴定仪对其进行了生理生化鉴定; 通过对其16S rDNA序列进行PCR扩增和测序, 与NCBI中收录的与其同源性较高的菌株进行了聚类分析并构建了系统发育树。此外, 对其生长特性也进行了研究。实验结果表明, 菌株M6革兰氏染色阴性, 杆形, 端生一根鞭毛, 大小约为0.45 mm×0.84 mm, 在孔雀石绿营养琼脂平板上形成的菌落特征为圆形、浅蓝色、粘稠、不易挑取; 菌株M6的16S rDNA序列与GenBank基因库中假单胞菌属的细菌菌株的16S rDNA序列有98％~99％的高度同源性, 菌株M6与恶臭假单胞菌OW-16(登录号：DQ112328.1)的亲缘关系最近。结合传统的形态与生理生化特性鉴定以及16S rDNA序列分析鉴定的结果, 判定菌株M6为恶臭假单胞菌(Pseudomonas putida)(登录号：EU348741.1)。此外, 菌株M6在30°C、150 r/min条件下摇床振荡培养的生长曲线为：0 h~4 h为生长延迟期, 4 h~64 h为对数生长期, 64 h~80 h为稳定期, 80 h以后为衰亡期; 其最适生长pH值为7, 最适生长温度为30°C, 在转速为50 r/min~250 r/min条件下, 其浓度随转速的增加而增大。     

The effect of toxic malachite green on the bacterial community in Antarctic soil and the physiology of malachite green-degrading Pseudomonas sp. MGO

The effects of malachite green (MG) on the bacterial community in Antarctic soil were assessed. Culture-independent community analysis using 16S rRNA gene pyrosequencing showed that, in the presence of MG, the relative abundance of Pseudomonas dramatically increased from 2.2 % to 36.6 % (16.6-fold), and Pseudomonas became the predominant genus. The reduction in bacterial biodiversity was demonstrated by diversity indices and rarefaction curves. MG-degrading Pseudomonas sp. MGO was isolated from Antarctic soil. MG tolerance and decolorization activity were confirmed by growth, spectrophotometric, high-performance liquid chromatography, and thin-layer chromatography analyses in high MG concentrations. Our data showed that the decolorization process occurred via biodegradation, while biosorption also occurred after some time during the fed-batch decolorization process. Significant inductions in laccase, nicotinamide adenine dinucleotide–2,6 dichlorophenol indophenol reductase, and MG reductase activities suggested their involvement in the decolorization process. We also showed that the high tolerance of strain MGO to toxic MG might be mediated by upregulation of oxidative stress defense systems such as superoxide dismutase and protease. Collectively, these results demonstrated the response of the Antarctic soil bacterial community to MG and provided insight into the molecular mechanism of MG-tolerant Pseudomonas strains isolated from Antarctic soil.     

Nitrate Reduction to Nitrite,Nitric Oxide and Ammonia by Gut Bacteria under Physiological Conditions

The biological nitrogen cycle involves step-wise reduction of nitrogen oxides to ammonium salts and oxidation of ammonia back to nitrites and nitrates by plants and bacteria. Neither process has been thought to have relevance to mammalian physiology; however in recent years the salivary bacterial reduction of nitrate to nitrite has been recognized as an important metabolic conversion in humans. Several enteric bacteria have also shown the ability of catalytic reduction of nitrate to ammonia via nitrite during dissimilatory respiration; however, the importance of this pathway in bacterial species colonizing the human intestine has been little studied. We measured nitrite, nitric oxide (NO) and ammonia formation in cultures of Escherichia coli, Lactobacillus and Bifidobacterium species grown at different sodium nitrate concentrations and oxygen levels. We found that the presence of 5 mM nitrate provided a growth benefit and induced both nitrite and ammonia generation in E.coli and L.plantarum bacteria grown at oxygen concentrations compatible with the content in the gastrointestinal tract. Nitrite and ammonia accumulated in the growth medium when at least 2.5 mM nitrate was present. Time-course curves suggest that nitrate is first converted to nitrite and subsequently to ammonia. Strains of L.rhamnosus, L.acidophilus and B.longum infantis grown with nitrate produced minor changes in nitrite or ammonia levels in the cultures. However, when supplied with exogenous nitrite, NO gas was readily produced independently of added nitrate. Bacterial production of lactic acid causes medium acidification that in turn generates NO by non-enzymatic nitrite reduction. In contrast, nitrite was converted to NO by E.coli cultures even at neutral pH. We suggest that the bacterial nitrate reduction to ammonia, as well as the related NO formation in the gut, could be an important aspect of the overall mammalian nitrate/nitrite/NO metabolism and is yet another way in which the microbiome links diet and health.     

Reduction of malachite green to leucomalachite green by intestinal bacteria.

Intestinal microfloras from human, rat, mouse, and monkey fecal samples and 14 pure cultures of anaerobic bacteria representative of those found in the human gastrointestinal tract metabolized the triphenylmethane dye malachite green to leucomalachite green. The reduction of malachite green to the leuco derivative suggests that intestinal microflora could play an important role in the metabolic activation of the triphenylmethane dye to a potential carcinogen.     

Health status of rudd (Scardinius erythrophthalmus hesperidicus H.) in Lake Vrana on the Island of Cres, Croatia

The health status of rudd ( Scardinius erythrophthalmus hesperidicus H.) in Lake Vrana, the largest Croatian karstic lake, was evaluated. Studies comprising parasitological, haematological and bacteriological surveys were conducted over a 2-year period. Parasitological examination revealed a light infestation of 27% of the examined fish, mostly Dactylogyrus and Ichthyophthirius species. Haematological studies showed that haematocrit values were lower than the physiological limit. A haematocrit coefficient of correlation in all research periods was higher than 15%, indicating that the majority of fish in the study were susceptible to the development of bacterial and other diseases. Indeed, a diverse array of bacteria were isolated from rudd, mainly Flavobacterium spp. and Aeromonas spp., but also some specific fish pathogens, notably Pasteurella piscicida, Yersinia ruckeri , and Edwardsiella ictaluri , were identified. Under stress conditions, detected bacterial species can give rise to disease outbreaks.     

Effect of sodium nitrite poisoning on the activity of enzymes of anti-oxidant protection and peroxidation processes in mouse erythrocytes]

The intoxication of white mice with sodium nitrite results in the decrease of red cell superoxide dismutase (SOD) and catalase activity. The glutathione peroxidase activity is the same as in the control group. The level of red cell lipid peroxidation in the group of mice that receive sodium nitrite is higher as compared to the control group. After the intoxication the total activity of glucose-6-phosphate dehydrogenase and dehydrogenase of 6-phosphogluconate as well as the activity of glutathione reductase are higher than in the control group. The level of SH-groups and reduced glutathione is higher in the group of mice that receive sodium nitrite in comparison with the control group.