Evidence that supramolecular Congo red is the sole ligation form of this dye for L chain lambda derived amyloid proteins.

The mechanism of Congo red binding to amyloid protein was studied in order to establish which of two structural dye versions present in water solutions--unimolecular and supramolecular--represent its actual ligation form. Immunoglobulin L chain lambda of amyloidogenic nature, expressed by Congo red binding and easy gel formation, was used as the model amyloid protein. Congo red was coassembled with rhodamine B, designed to be a marker of the Congo red micellar organisation in complexation with protein. The particular suitability of rhodamine B for this role results from significant difference in its binding affinity to Congo red and to protein. It associates readily with Congo red, becoming incorporated into its micellar organisation, but as homogenous dye it shows an almost complete inability to bind to protein. In view of these properties, Congo red was used as a vehicle to draw rhodamine B into complexation with protein, at the same time supplying evidence of its supramolecular ligation form. The results show that both soluble amyloid precursor L chain and the derived gel material attach rhodamine B coassembled with Congo red but not the homogenous rhodamine B. Despite its dynamic, supramolecular character, Congo red participates in complexation with amyloid proteins as an integral ligand unit.     

Is Congo red an amyloid-specific dye?

Congo red (CR) binding, monitored by characteristic yellow-green birefringence under crossed polarization has been used as a diagnostic test for the presence of amyloid in tissue sections for several decades. This assay is also widely used for the characterization of in vitro amyloid fibrils. In order to probe the structural specificity of Congo red binding to amyloid fibrils we have used an induced circular dichroism (CD) assay. Amyloid fibrils from insulin and the variable domain of Ig light chain demonstrate induced CD spectra upon binding to Congo red. Surprisingly, the native conformations of insulin and Ig light chain also induced Congo red circular dichroism, but with different spectral shapes than those from fibrils. In fact, a wide variety of native proteins exhibited induced CR circular dichroism indicating that CR bound to representative proteins from different classes of secondary structure such as alpha (citrate synthase), alpha + beta (lysozyme), beta (concavalin A), and parallel beta-helical proteins (pectate lyase). Partially folded intermediates of apomyoglobin induced different Congo red CD bands than the corresponding native conformation, however, no induced CD bands were observed with unfolded protein. Congo red was also found to induce oligomerization of native proteins, as demonstrated by covalent cross-linking and small angle x-ray scattering. Our data suggest that Congo red is sandwiched between two protein molecules causing protein oligomerization. The fact that Congo red binds to native, partially folded conformations and amyloid fibrils of several proteins shows that it must be used with caution as a diagnostic test for the presence of amyloid fibrils in vitro.     

Understanding the degradation of Congo red and bacterial diversity in an air–cathode microbial fuel cell being evaluated for simultaneous azo dye removal from wastewater and bioelectricity generation

We investigated the mechanism of Congo red degradation and bacterial diversity in a single-chambered microbial fuel cell (MFC) incorporating a microfiltration membrane and air–cathode. The MFC was operated continuously for more than 4 months using a mixture of Congo red and glucose as fuel. We demonstrated that the Congo red azo bonds were reduced at the anode to form aromatic amines. This is consistent with the known mechanism of anaerobic biodegradation of azo dyes. The MFC developed a less dense biofilm at the anode in the presence of Congo red compared to its absence indicating that Congo red degradation negatively affected biofilm formation. Denaturing gradient gel electrophoresis and direct 16S ribosomal DNA gene nucleotide sequencing revealed that the microbial communities differed depending on whether Congo red was present in the MFC. Geobacter-like species known to generate electricity were detected in the presence or absence of Congo red. In contrast, Azospirillum, Methylobacterium, Rhodobacter, Desulfovibrio, Trichococcus, and Bacteroides species were only detected in its presence. These species were most likely responsible for degrading Congo red.     

A novel endoplasmic reticulum membrane protein Rcr1 regulates chitin deposition in the cell wall of Saccharomyces cerevisiae

Congo red binds to the cell wall and inhibits the growth of yeast. In a screening for multicopy suppressor genes of Congo red hypersensitivity of erd1Delta mutant, we found that a previously uncharacterized gene, YBR005w, makes most of the Saccharomyces cerevisiae strains resistant to Congo red. This gene was named RCR1 (resistance to Congo red 1). An rcr1Delta null mutant showed an increased sensitivity to Congo red. RCR1 encodes a novel ER membrane protein with a single transmembrane domain. Molecular dissection suggested that the transmembrane domain and a part of the C-terminal polypeptide are sufficient for the activity. We examined the effect of RCR1 in various null mutants of genes related to the cell wall. The resistance of mutants to Congo red correlates with a reduction of chitin content. Multicopy RCR1 caused a significant decrease in the chitin content while the amount of alkali-soluble glucan did not change. The binding of Calcofluor white to the cell wall significantly decreased in these cells. Our results show that RCR1 regulates the chitin deposition and add firm genetic and biochemical evidences that the primary target of Congo red is chitin in S. cerevisiae.     

Inhibition of cell-cell interactions in Myxococcus xanthus by congo red

The function of molecules associated with the cell surface may be determined by examining the phenotype of cells treated with inhibitors specific to these cell surface molecules. This strategy was used to examine the function of the major Congo red receptor of the myxobacterium Myxococcus xanthus, which has a developmental cycle that involves social interactions among cells. A class of social motility mutations (A+ S-), known as dsp, may inhibit the same subcellular component as Congo red because the phenotype of wild-type cells which had been treated with Congo red resembled in several ways the phenotype of the Dsp mutants. First, Congo red inhibited agglutination of wild-type cells, whereas Dsp cells were incapable of agglutinating, even in the absence of Congo red. Second, Congo red inhibited fruiting body formation by wild-type cells and reduced the yield of myxospores. Untreated Dsp cells were unable to form fruiting bodies and produced few myxospores. Third, Congo red reduced the rate of wild-type gliding motility to a level comparable to that of untreated Dsp cells, but did not inhibit the A motility of Dsp cells. Finally, binding studies showed that Dsp cells lacked the major Congo red receptor. Wild-type cells bound Congo red with an apparent association constant of 2.4 X 10(5) M-1, while Dsp cells bound it with an apparent association constant of 8.5 X 10(3) M-1. Binding of Congo red to wild-type cells was saturated in less than 10 min and was reversible when excess Congo red was removed. These results suggest that the Congo red receptors are controlled by the S motility system and that these receptors are involved in cell cohesion, social motility, and fruiting body formation.     

Kinetics of Congo-red binding by haemin-limited and haemin-excess cells of Porphyromonas gingivalis W50

The binding of Congo red to P. gingivalis W50 grown in a chemostat under haemin-limitation and haemin-excess was quantified. Congo red bound to both haemin-excess and haemin-limited cells with similar capacity and affinity. Binding of Congo red was greater than for ferri- (haemin) or ferroprotoporphyrin IX (haem), and was not influenced by redox potential at low added ligand concentrations. Both haemin-limited and haemin-excess cells showed positive co-operativity towards Congo red binding. Pre-exposure of haemin-limited and haemin-excess cells to sub-saturating concentrations of ferriprotoporphyrin IX did not affect Congo red binding, whereas pre-exposure of haemin-excess cells to ferroprotoporphyrin IX increased binding. Iron protoporphyrin IX binding was enhanced after exposure of both haemin-excess and haemin-limited cells to Congo red, especially under reducing conditions. These results confirm that Congo red binding cannot be used as an indirect measure of haemin binding, nor can Congo red be used to inhibit haemin binding to P. gingivalis.     

Correlation between Congo red binding and contact haemolysin production in Shigella species

Haemolytic strains of Shigella dysenteriae type 1, Shigella flexneri, Shigella boydii and Shigella sonnei cultured on Congo red agar produced pigmented colonies (Pcr+) whereas nonhaemolytic strains produced white colonies and did not bind Congo red (Pcr-). S. flexneri-1 haemolysin negative mutant (lacking plasmid) of haemolysin positive prototroph also did not bind Congo red and produced nonpigmented colonies. Among the twelve strains of Shigella included in this study, the characteristics of Congo red binding, plasmid profile and haemolytic activity appeared to be correlated. Congo red binding occurred comparatively more by haemolysin-producing strains. Congo red binding can be used as a quick and reliable method for virulence traits of pathogens, including haemolysin activity.     

Porphyrin binding by the surface array virulence protein of Aeromonas salmonicida.

Congo red binding by virulent A-layer-containing (A+) and avirulent A-layer-deficient (A-) strains of Aeromonas salmonicida was examined. Congo red binding to A+ cells was enhanced by salt and thus hydrophobically driven, but at low Congo red concentrations binding was salt independent. Congo red was bound by A+ cells by a kinetically distinct mechanism (Kd, 0.25 microM) which was absent in A- isogenic strains. Purified A-layer protein ("A protein") protein A also bound Congo red with similar affinity (Kd, 0.40 microM). Congo red binding was structurally specific; it was not influenced by a wide variety of compounds including amino acids and nucleotides and only weakly inhibited by structurally similar dyes. However, protoporphyrin IX and hemin were strong competitive inhibitors of Congo red binding. Protoporphyrin and hemin were bound only by A+ strains (KdS of 0.41 and 0.63 microM, respectively). Furthermore, binding of these porphyrins was strongly inhibited by Congo red but weakly inhibited by hematoporphyrin. Purified A protein also bound protoporphyrin IX and hemin with affinities similar to those of A+ cells (KdS of 0.94 and 0.41 microM, respectively.     

Quantitative evaluation of congo red binding to amyloid-like proteins with a beta-pleated sheet conformation

The binding of Congo red to several purified amyloid-like peptides having a beta-pleated sheet conformation was quantitatively examined. Congo red binds preferentially to the beta-pleated sheet conformation of both insulin fibrils and poly-L-lysine. Congo red does not bind nearly so well to poly-L-serine or polyglycine, despite the fact that these peptides also have a beta-pleated sheet conformation. Binding to insulin fibrils was saturable with an apparent Bmax of 2 moles of Congo red per mole of insulin fibrils and an apparent KD of 1.75 x 10(-7) M. Binding to beta-poly-L-lysine was similar but had a much higher apparent Bmax of 43. Binding of Congo red to beta-poly-L-lysine was pH dependent and appeared to be determined by the number of protonated lysine residues in the 250 amino acid peptide. We present a new hypothesis in which Congo red binds to amyloid-like proteins via bonds between the two negatively charged sulfonic acid groups of Congo red and two positively charged amino acid residues of two separate protein molecules which are properly oriented by virtue of the beta-pleated sheet conformation of the peptide backbone.     

一色齿毛菌对刚果红的脱色优化及其毒性变化研究

一色齿毛菌Cerrena unicolor是分离自野外的一株能够降解木质素的白腐真菌。为明确一色齿毛菌对染料的脱色能力及脱色前后染料毒性的变化,本研究利用一色齿毛菌对固体条件下4种染料进行脱色能力的检测,筛选出较易脱色的染料后,对该染料的脱色条件进行优化,并以3种豆类发芽率为指标测定该染料脱色前后的毒性变化。结果表明,一色齿毛菌对4种染料均可脱色,其中对刚果红的脱色效果最为明显;一色齿毛菌对刚果红脱色条件的优化结果为：20g/L麦芽糖,1g/L硝酸铵,1mmol/L硫酸镁,接种9块直径1cm菌饼,10mg/L染料浓度,pH 7时脱色效果最好;刚果红染料脱色前后毒性测试结果显示：染料脱色前发酵液毒性>染料脱色后发酵液毒性>清水处理毒性,表明刚果红染料存在一定的毒性,但在被一色齿毛菌脱色后,染料毒性有所降低。本研究为一色齿毛菌在染料废水脱色方面的应用及降低染料废水毒性提供一定的参考依据。     

FT-Raman spectroscopy as diagnostic tool of Congo red binding to amyloids

Chorion is the major component of silkmoth eggshell. More than 95% of its dry mass consists of the A and B families of low molecular weight structural proteins, which have remarkable mechanical and chemical properties protecting the oocyte and developing embryo from environmental hazards. We present data from FT-Raman spectroscopy of silkmoth chorion and amyloid-like fibrils formed from peptide analogues of chorion proteins, both unstained and stained by Congo red. The results show that FT-Raman spectroscopy is not a straightforward diagnostic tool for the specific interactions of Congo red with amyloids: a dilute aqueous solution of the Congo red dye at pH 5.5 and a thin solid film of the dye cast from this solution exhibit the same "diagnostic" Raman shifts relative to the neat Congo red dry powder as do amyloid fibrils formed from peptide analogues of chorion proteins stained by Congo red. An important consequence of this finding is that these shifts of the Raman active modes of Congo red are probably due to the formation of supramolecular dye aggregates in the presence of water. Therefore, this is not an appropriate diagnostic test for Congo red binding to amyloids.     

Congo red binding of elastin in aortic smooth muscle cell cultures

These studies demonstrate that the strong binding capacity of elastin for Congo red can be used to advantage in aortic smooth muscle cell cultures. A fibrous elastin network fluoresces when Congo red is added. Congo red does not alter accumulation of elastin or of total protein, even when the cells are grown in the presence of the dye for long periods of time, indicating that it is not toxic. Porcine pancreatic elastase was used to solubilize elastin in these cultures, to determine the molar ratio of Congo red to elastin, thus making it possible to estimate the amount of elastin solubilized when the cultures are injured. Congo red binding to elastin will be useful in studying elastin accumulation and/or degradation in vitro and in vivo.     

The role of the heat shock protein Hsp12p in the dynamic response of Saccharomyces cerevisiae to the addition of Congo red

In this study, we investigate the electrohydrodynamic and nanomechanical characteristics of two Saccharomyces cerevisiae yeast strains, a wild-type (WT) strain and a strain overexpressing (OE) Hsp12p, in the presence and absence of hydrophobic Congo red compound. By combining these two advanced biophysical methods, we demonstrate that Hsp12p proteins are mostly located within a thin layer ( c . 10 nm thick) positioned at the external side of the cell wall. However, this Hsp12p-enriched layer does not prevent Congo red from entering the cell wall and from interacting with the chitin therein. The entrance of Congo red within the cell wall is reflected in an increase of the turgor pressure for the OE strain and a decrease of that for the WT strain. It is shown that these opposite trends are consistent with significant modulations of the water content within the cell wall from/to the cytoplasm. These are the result of changes in the hydrophobicity/hydrophilicity balance, as governed by the intertwined local concentration variations of Congo red and Hsp12p across the cell wall. In particular, the decrease of the turgor pressure in the case of WT strain upon addition of Congo red is shown to be consistent with an upregulation of Hsp12p in the close vicinity of the plasma membrane.     

Congo red agar, a differential medium for Aeromonas salmonicida, detects the presence of the cell surface protein array involved in virulence.

Strains of the fish pathogen Aeromonas salmonicida which possess the cell surface protein array known as the A-layer (A+) involved in virulence formed deep red colonies on tryptic soy agar containing 30 micrograms of Congo red per ml. These were readily distinguished from colorless or light orange colonies of avirulent mutants lacking A-layer (A-). The utility of Congo red agar for quantifying A+ and A- cells in the routine assessment of culture virulence was demonstrated. Intact A+ cells adsorbed Congo red, whereas A- mutants did not bind Congo red unless first permeabilized with EDTA. The dye-binding component of A+ cells was shown to be the 50,000-Mr A-protein component of the surface array. Purified A-protein avidly bound Congo red at a dye-to-protein molar ratio of about 30 by a nonspecific hydrophobic mechanism enhanced by high salt concentrations. Neither A+ nor A- cells adsorbed to Congo red-Sepharose columns at low salt concentrations. On the other hand, A+ (but not A-) cells were avidly bound at high salt concentrations.     

Use of Congo red as a microscopic fluorescence indicator of hyphal growth

Congo red was found to be feasible as a microscopic fluorescence indicator of hyphal growth at the single-hypha level. When 1 m Congo red was applied to mold of Aspergillus niger, the dye was found to a specific cell-wall component, chitin, without causing any inhibitory effect on hyphal growth. The bound Congo red emitted fluorescence at 614 nm. This binding reaction, however, proceeded more slowly than the growing speed of hypha. Consequently the fluorescence intensity was low at the apex where the surface area of the hypha was expanding rapidly. In contrast, as an apex where the growth was retarded, the fluorescence intensity became remarkably high. Therefore growing hyphae could be distinguished from non-growing hyphae by using Congo red.     

Protein distorsion-derived mechanism of signal discrimination in monocytes revealed using Congo red to stain activated cells

The supramolecular dye Congo red was used to check whether monocyte activation may be mediated by a torsion-dependent mechanism preventing transduction of weak random signals in cell contacts in a way corresponding to the discrimination mechanism found in complement fixation by immune complexes. Tight cell-cell contacts generating torsional effects may be expected to produce alteration of receptor structure, making them accessible for binding of supramolecular dyes. In this study, Congo red was used to observe the binding accessibility of (1) monocytes (human) induced by contact with cancer cells (HCV29T, human), (2) monocytes (mouse) stimulated by interaction with heat-aggregated IgG and (3) monocytes (mouse) activated by rosetting in the presence of an SRBC-anti-SRBC system. Microscopic studies confirmed the activation of monocytes manifested by their clustering and Congo red binding, but only tightly clustered cells appeared to attach the dye on the surface. Usually not the whole cell surface is found to be engaged in dye complexation. Staining occurs predominantly on the interfaces of reacting cells, making probable the suggestion that cell adhesion receptors are involved in dye binding. The cells in the central areas of tight clusters undergo accelerated death. In the presence of Congo red they are easily recognized as intensely fluorescent. The characteristic localization of dead cells in the central area of clusters indicates that death is not random but results from cell activation. The role of Congo red in this process remains to be clarified. The staining characteristics of monocytes after application of Congo red probably discloses the initial step in signal transduction generated by torsional movements in receptor proteins.     

Detection of cellulolytic fungi by using Congo red as an indicator: a comparative study with the dinitrosalicyclic acid reagent method

Cellulolytic fungi can easily be screened within 2 d for the production of cellulolytic enzymes by staining with Congo red, or by measuring the amount of reducing sugar (glucose) produced with the dinitrosalicyclic acid reagent method. Endoglucanase activity is visible in carboxymethyl cellulose agar plates after staining with Congo red, and fixing with HCL or NaOH. This method is essentially based on the interaction of Congo red with intact β-(1-4)-D-glucans in carboxymethyl cellulose. Endoglucanase and exoglucanase activities of cellulases are quantitatively measured with the dinitrosalicyclic acid reagent method. The enzymatic activity detected with Congo red is compared with that obtained by the dinitrosalicyclic acid reagent method.     

The cause of the green polarization color of amyloid stained with Congo red

Summary Experiments done with Congo red crystals and with Congo red deposits polished in a single direction by a glass wheel have shown that the appearance of green polarization color primarily depends on near-perfect parallel alignment of the dye particles. The green polarization color was seen only in the deposits which showed a clear transition from red to colorless when examined for dichroism. Another factor was found to be the thickness of the object, as the green polarization color was not present in too thick or too thin sections of amyloid-containing tissues stained with Congo red.The phenomena can be explained by the assumption that the green polarization color is due to interference between the red ray and the red component of the white ray whenever the retardation by the object approximates half the wavelength of red light.The findings indicate that amyloid differs from other materials which are stained by Congo red in that amyloid deposits bind the dye molecules in a more orderly and parallel fashion. It is suggested that minimal amounts of amyloid which are not visible in Congo red stained sections with ordinary light microscopy and which do not give the green polarization color can best be detected by examination for dichroism in ultraviolet light after having been stained with fluorescent dyes.     

Conversion of Congo red and 2-azoxyfluorene to mutagens following in vitro reduction by whole-cell rat cecal bacteria

Congo red, an azo dye derived from benzidine, and 2-azoxyfluorene, a derivative of 2-aminofluorene, were reduced during overnight incubation with a suspension of rat intestinal bacteria. High performance liquid chromatography and ultraviolet spectral analysis verified the presence of benzidine in extracts of the Congo red incubations and 2-aminofluorene in extracts of the 2-azoxyfluorene incubations. Extracts of the Congo red incubations were mutagenic toward Salmonella typhimurium TA1538 in the presence of a post-mitochondrial activating system, but Congo red was not mutagenic without this reductive pretreatment. Thus, the utility of the Ames test in screening for potential mutagens may be expanded by a reductive pretreatment utilizing cecal bacteria.     

In vivo accumulation of self-assembling dye Congo red in an area marked by specific immune complexes: possible relevance to chemotherapy

Supramolecular micellar structures have been proposed as carriers in aim-oriented drug transportation to a target marked by specific immune complexes. In this study, the self-assembling dye Congo red was used as a model supramolecular carrier and its accumulation in the target was studied in vivo. The target was created in vivo as the local specific inflammation provoked by subcutaneous injection of antigen to the ear of a previously immunized rabbit. The color caused by accumulation of Congo red after its intravenous injection was registered by pictures of the ear with suitably filtered visible light shining through it to distinguish Congo red against the background color of hemoglobin. The results confirmed the expected accumulation and retention of Congo red in the inflammation area marked by deposits of specific immune complexes. The role of albumin and its possible interference with transportation of drugs through the blood by supramolecular carriers was also subjected to preliminary examination. The results revealed that albumin collaborates rather than interferes with drug transportation; this is another factor making the use of supramolecular carriers for aim-oriented chemotherapy highly promising.