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.     

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.     

Electron microscopy of malachite green--glutaraldehyde fixed bacteria.

Malachite green combined with glutaraldehyde has been used recently as a fixative for preserving and revaling lipid complexes in thin sections of eukaryotic cells examined by electron microscopy. When bacteria were prefixed with the above mixture granular electron dense inclusions were revealed in all cultures tested. These inclusions were replaced by electron transparent areas in cells fixed with glutaraldehyde alone. The structures were frequently located near to or within the nucleoid and adjacent to the cell membrane in Gram-negative bacteria and were associated with the nucleoid and mesosomes in Gram-positive species. Polyhydroxybutyrate granules, generally poorly preserved in thin sections of Aquaspirillum serpens, were well preserved by the malachite green-glutaraldehyde fixative. Malachite green complexes were observed outside of the cells in all preparations. Capsules were neither preserved nor stained.     

Electron Microscopy of Malachite Green— Glutaraldehyde Fixed Bacteria

Malachite green combined with glutaraldehyde has been used recently as a fixative for preserving and revealing lipid complexes in thin sections of eukaryotic cells examined by electron microscopy. When bacteria were prefixed with the above mixture granular electron dense inclusions were revealed in all cultures tested. These inclusions were replaced by electron transparent areas in cells fixed with glutaraldehyde alone. The structures were frequently located near to or within the nucleoid and adjacent to the cell membrane in Gram-negative bacteria and were associated with the nucleoid and mesosomes in Gram-positive species. Polyhydroxybutyrate granules, generally poorly preserved in thin sections of Aquaspirillum serpens, were well preserved by the malachite green-glutaraldehyde fixative. Malachite green complexes were observed outside of the cells in all preparations. Capsules were neither preserved nor stained.     

A simple two-dye basic stain facilitating recognition of mitosis in plastic embedded tissue sections

Semithin sections of buccal and palatal mucosa fixed in 2.5% glutaraldehyde followed by 1% osmium and embedded in Durcupan (an araldite-based resin) were stained with 2% malachite green in 50% ethanol at 80 C and poststained in 0.05% crystal violet in Sorensen's phosphate buffer (pH 6.4) at 45 C. Nuclear envelopes and chromatin stain vivid purple in contrast to the surrounding green cytoplasm and cell borders. Chromosomes of dividing cells stain bluish violet. Nucleoli, depending on their level in the epithelium, stain differing shades of greenish blue. The distinct and differential staining of each of these components facilitates recognition of mitoses in oral epithelium, where the small size and crowding of cells in the proliferative compartment renders more conventional stains for plastic sections inadequate.     

The Use of Buffered Solutions in Staining: Theory and Practice

The importance of pH in staining tissue is emphasized. The effect of pH upon the selectivity and intensity of staining with iron hematoxylin, malachite green, and eosin Y is considered. Many difficulties may be avoided by staining in the higher alcohols and directions are given for the preparation of buffer solutions from pH 1.2-8 in alcohol. The concentration of stains, time of staining, and order of staining are discussed for progressive and regressive staining. At pH 8 in 95% alcohol very few tissues stain with malachite green at a concentration of 1/1000 saturated. At pH 6 most cytoplasmic elements stain with malachite green at a concentration of 1/1000 saturated or with eosin Y at 1/250 saturated. As the pH is lowered more tissue elements stain until the nucleus is completely stained. This behavior is in accord with the theory of chemical combination of dyes with proteins, which states that proteins combine with basic dyes on the basic side of their isoelectric points and with acid dyes on the acid side of their isoelectric points. With hematoxylin stain the pH range is much shorter. A satisfactory hematoxylin stain is composed of 0.1% hematoxylin, 0.1% FeCl₃, and HCl to bring the pH to 1.2-1.6 in 80% alcohol. With this stain, which may be used immediately, the nuclei of most tissues begin to stain at pH 1.2 and much of the cytoplasm will be stained if the pH is raised to 1.4. The shortness of this effective pH range is thought to be due to the dissociation of the hematoxylin-iron-protein complex. The use of different dyes successively at different pH values, such as hematoxylin at 1.3, malachite green at 8, and eosin at 6, permits better differentiation of the tissue elements, and intelligent variations in the staining technic.     

Glutaraldehyde: Role in electron microscopy

In spite of the inherent limitations of chemical fixation, glutaraldehyde is unsurpassed in its ability to preserve cell ultrastructure. This achievement is due to the introduction of irreversible intra-and intermolecular cross-links into cellular proteins by the dialdehyde. Glutaraldehyde is very effective in stabilizing surface as well as intracellular structures for conventional scanning and transmission electron microscopy and high voltage electron microscopy. Even in immunocytochemical and autoradiographical studies, glutaradehyde plays a dominant role. Furthermore, prior to freeze-substitution, freeze-drying and freeze-fracturing, specimens often are stabilized with this dialdehyde. Glutaraldehyde efficiency can be increased by adding appropriate cross-linking and rapidly penetrating reagents as well as contrast enhancing reagents to this dialdehyde. Improved preservation and staining, for example, of ionic sites, soluble inorganic phosphate, lipids, biogenic amines, actin filaments, spermatozoa and phage-infected bacteria can be accomplished by adding polyethyleneimine, lead acetate, malachite green, potassium dichromate, tannic acid, trinitro compounds and uranyl acetate, respectively, to glutaraldehyde. Other refinements include the use of low concentrations of glutaraldehyde, short durations of cross-linking, minimum radiation exposure, and low temperature electron microscopy. The usefulness of glutaraldehyde in high resolution electron microscopy is limited because chemical fixation inevitably causes chemical and structural alterations in the specimen. However, fixation with glutaraldehyde or its mixture with formaldehyde has served immeasurably the progress in the understanding of cell ultrastructure and function. Preservation of specimens with glutaraldehyde for electron microscopy is expected to continue. Therefore, attempts must continue to be made to interpret the dynamics of the living cell from the static electron micrographs.     

Tissue culture fixation with diimidoesters—IV. A comparison between adipimidate and aldehydes of their effects on cell size and morphology

The effects of fixation with dimethyladipimidate (DMA) on cell size and morphology were compared with those from aldehydes (glutaraldehyde, formaldehyde) using African green monkey kidney CV1 cells. Fixation with any of the three fixatives makes the cells resistant to any considerable size alteration. Glutaraldehyde has the strongest stabilizing effect, formaldehyde occupies an intermediate position while DMA forms the least cross-links of all. Morphologically (phase contrast microscopy), DMA-fixed and aldehydes-fixed cells stained with haematoxylin/eosin were similar except that with DMA the nuclei exhibit a granular thread-like structure with apparent granular nucleolei. This was also observed in isolated nuclei. Furthermore, in DMA-fixed unstained cells the cytoplasmic filament bundles are very distinct. This feature is not present to the same extent in aldehydes-fixed cells. Data from stained CV1 monolayers, from determinations of free amino groups and from gel electrophoresis show that DMA fixation does not preclude a subsequent reaction with glutaraldehyde or formaldehyde.     

Comparative ultrastructure of a mucoid strain of Pseudomonas aeruginosa isolated from cystic fibrosis patient and its spontaneous non-mucoid mutant

The ultrastructure of a mucoid strain of Pseudomonas aeruginosa of cystic fibrosis origin and its spontaneous non-mucoid variant was compared by transmission electron microscopy. Negatively-stained preparations of the mucoid strain obtained from plate cultures demonstrated dense, fibrous material projecting from the cell. No such material was observed in thin-sections or in negatively-strained preparations from liquid cultures. Thin-sections of ethanol-precipitated extracellular material from liquid cultures of the mucoid-strain revealed a cottony mesh of thin electron dense fibres. The non-mucoid strain did not produce such material. When prefixed with glutaraldehyde/malachite green mixture, cells of both strains demonstrated electron dense intracellular and extracellular malachite green-stainable structures. The internal complexes were frequently associated with the nucleoid or cell membrane and were replaced by electron transparent areas in cells prefixed with glutaraldehyde alone. Aeruginocins of the R-type were observed in mitomycin C induced cultures of both strains. Bacteriophages with 'claw-shaped' tail-tips were observed in the mucoid strain. Crystalline material was produced by the mucoid strain but only when plated on certain media.     

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.     

Effects of bilayer surface charge density on molecular adsorption and transport across liposome bilayers

Second harmonic generation (SHG) was used to study both the adsorption of malachite green (MG), a positively charged organic dye, onto liposomes of different lipid compositions, and the transport kinetics of MG across the liposome bilayer in real time. We found that the dye adsorption increased linearly with the fraction of negatively charged lipids in the bilayer. Similarly, the transport rate constant for crossing the bilayer increased linearly with the fraction of charged lipid in the bilayer.     

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.     

Particle beam liquid chromatography-mass spectrometry of triphenylmethane dyes: application to confirmation of malachite green in incurred catfish tissue

Eight triphenylmethane dyes (malachite green, leucomalachite green, gentian violet, leucogentian violet, brilliant green, pentamethyl gentian violet, N′,N′-tetramethyl gentian violet and N′,N″-tetramethyl gentian violet) have been characterized by particle beam liquid chromatography-mass spectrometry. The electron ionization spectra obtained of these dyes by this technique exhibit similar fragmentation, with the formation of phenyl and substituted phenyl radicals, and loss of alkyl groups from the amines. It was observed that the six cationic dyes are reduced in the mass spectrometer source to form the corresponding leuco compounds. This technique was evaluated for the confirmation of malachite green and leucomalachite green in incurred catfish (Ictalurus punctatus) muscle tissue.     

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.     

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。     

Inorganic pyrophosphatase as a label in heterogeneous enzyme immunoassay

Inorganic pyrophosphatase from Escherichia coli has been employed as a label in heterogeneous enzyme immunoassays. Enzyme-antibody conjugates were prepared with the use of glutaraldehyde and purified by gel permeation chromatography. Enzyme activity was measured by means of a sensitive one-step color reaction between phosphate, molybdate, and malachite green. The sensitivity in terms of absorbance readings was four to eight times higher than that of peroxidase-based assays. The color change (yellow to greenish blue) inherent in the use of pyrophosphatase as the labeling agent is highly suitable for visual analysis. Other merits of pyrophosphatase include the remarkable stability of the enzyme and its substrate, its compatibility with bacteriostatic agents, and its low Michaelis constant. Examples of the use of phosphatase in the assay of human alpha-fetoprotein and immunoglobulin G are presented.     

A Simple Two-Dye Basic Stain Facilitating Recognition of Mitosis in Plastic Embedded Tissue Sections

Semithin sections of buccal and palatal mucosa fixed in 2.5% glutaraldehvde followed by 1% osmium and embedded in Durcupan (an araldite-baaed resin) were stained with 2% malachite green in 50% ethanol at 80 C and poststained in 0.05% crystal violet in Sorensen's phosphate buffer (pH 6.4) at 45 C Nuclear envelopes and chromatin stain vivid purple in contrast to the surrounding green cytoplasm and cell borders. Chromosomes of dividing cells stain bluish violet. Nucleoli, depending on their level in the epithelium, stain differing shades of greenish blue. The distinct and differential staining of each of these components facilitates recognition of mitoses in oral epithelium, where the small sice and crowding of cells in the proliferative compartment renders more conventional stains for plastic sections inadequate.     

Inorganic pyrophosphatase--a new enzyme label for biochemical analysis

Inorganic pyrophosphatase isolated from Escherichia coli has been proposed as a label in heterogeneous enzyme immunoassays. The enzyme is remarkably stable and insensitive to sodium azide. Enzyme-antibody conjugates were prepared with glutaraldehyde and purified by gel filtration. Enzyme activity was measured by means of a sensitive colour reaction between phosphomolybdate and malachite green. A 5-10-fold increase is sensitivity in terms of absorbance readings was observed compared to peroxidase-based assays. The colour change (yellow/greenish blue) inherent in the use of pyrophosphatase as the labelling agent is highly suitable for visual analysis.     

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.