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A method of dispersion of single-wall carbon nanotubes (SWNTs) in aqueous media using Congo red (CR) is proposed. Nanotubes covered with CR constitute the high capacity system that provides the possibility of binding and targeted delivery of different drugs, which can intercalate into the supramolecular, ribbon-like CR structure. The study revealed the presence of strong interactions between CR and the surface of SWNTs. The aim of the study was to explain the mechanism of this interaction. The interaction of CR and carbon nanotubes was studied using spectral analysis of the SWNT-CR complex, dynamic light scattering (DLS), differential scanning calorimetry (DSC) and microscopic methods: atomic force microscopy (AFM), transmission (TEM), scanning (SEM) and optical microscopy. The results indicate that the binding of supramolecular CR structures to the surface of the nanotubes is based on the "face to face stacking". CR molecules attached directly to the surface of the nanotubes can bind further, parallel-oriented molecules and form supramolecular and protruding structures. This explains the high CR binding capacity of carbon nanotubes. The presented system - containing SWNTs covered with CR - offers a wide range of biomedical applications.

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Congo red (CR) is a known selective amyloid ligand. The focus of our work is identification (by EM imaging) of dye binding sites and their distribution in amyloids and amyloid-like aggregates formed in vitro. In order to produce the required contrast, CR has been indirectly combined with metal via including Titan yellow (TY) by intercalation which exhibits a relatively strong affinity for silver ions. The resulting combined ligand retains its ability to bind to proteins (which it owes to CR) and can easily be detected in EM studies thanks to TY. We have found, however, that in protein aggregates where unfolding is stabilized by aggregation and therefore is irreversible, TY alone may serve as both, the ligand and the metal carrier. The formation of ordered structures in amyloids was studied using IgG light chains with amyloidogenic properties, converted into amyloids by shaking. The resulting EM images were subjected to interpretation on the basis of the authors' earlier research on the CR/light chain complexation process. Our results indicate that dimeric light chains, which are the subject of our study, produce amyloids or amyloid-like complexes with chain-like properties and strong helicalization tendencies. Cursory analysis suggests that the edge polypeptide loops belonging to unstable light chains form intermolecular bridges which promote creation of loose gel deposits, or are otherwise engaged in the swapping processes leading to higher structural ordering.

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Congo red dye as well as other eagerly self-assembling organic molecules which form rod-like or ribbon-like supramolecular structures in water solutions, appears to represent a new class of protein ligands with possible wide-ranging medical applications. Such molecules associate with proteins as integral clusters and preferentially penetrate into areas of low molecular stability. Abnormal, partly unfolded proteins are the main binding target for such ligands, while well packed molecules are generally inaccessible. Of particular interest is the observation that local susceptibility for binding supramolecular ligands may be promoted in some proteins as a consequence of function-derived structural changes, and that such complexation may alter the activity profile of target proteins. Examples are presented in this paper.

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Among specific amyloid ligands, Congo red and its analogues are often considered potential therapeutic compounds. However, the results of the studies so far have not been univocal because the properties of this dye, derived mostly from its supramolecular nature, are still poorly understood. The supramolecular structure of Congo red, formed by π-π stacking of dye molecules, is susceptible to the influence of the electric field, which may significantly facilitate electron delocalization. Consequently, the electric field may generate altered physico-chemical properties of the dye. Enhanced electron delocalization, induced by the electric field, alters the total charge of Congo red, making the dye more acidic (negatively charged). This is a consequence of withdrawing electrons from polar substituents of aromatic rings-sulfonic and amino groups-thus increasing their tendency to dissociate protons. The electric field-induced charge alteration observed in electrophoresis depends on dye concentration. This concentration-dependent charge alteration effect disappears when the supramolecular structure disintegrates in DMSO. Dipoles formed from supramolecular fibrillar species in the electric field become ordered in the solution, introducing the modified arrangement to liquid crystalline phase. Experimental results and theoretical studies provide evidence confirming predictions that the supramolecular character of Congo red is the main reason for its specific properties and reactivity.

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The ordered amyloid-like organization of protein aggregates was obtained using for their formation the rigid fibrillar nanostructures of Congo red as the scaffolding. The higher rigidity of used dye nanoparticles resulted from the stronger stacking of molecules at low pH (near the pK of the dye amino group) because of the decreased charge repulsion. The polylysine, human globin, and immunoglobulin L chain were arranged in this way to form deposits of amyloid properties. The scaffolding was introduced simply by mixing the dye and proteins at a low pH or the dye was used in the preorganized form by maintaining it in the electric field before and during protein addition. The polarization and electron microscopy studies confirmed the unidirectional organization of the complex. The precipitate of the complex was used for studies directly or after the partial or complete removal of the dye. The results suggest that the process of formation of amyloid-like deposits may bypass the nucleation step. It is possible if the protein aggregation occurs in unidirectionally organized (because of scaffolding) assembly of molecules, arranged prior to self-association. The recognition of the structure of amphoteric Congo red nanoparticles used for the scaffolding was based on the molecular dynamics simulation.

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An allosteric mechanism for the generation of long-distance structural alterations in Fab fragments of antibodies in immune complexes has been postulated and tested in theoretical and experimental analysis. The flexing and/or torsion-derived forces exerted on the elbow region in Fab arms of bivalent antibodies upon binding to antigen were assumed to drive the disruption of hydrogen bonds which stabilize N- and C-terminal chain fragments in V-domains. This allows an extra movement in the elbow followed by a relaxation in the Fab arm and may generate long-distance effects if, in particular, the structural changes are generated asymmetrically involving one chain of the Fab arm only. This mechanism was studied by simulation of molecular dynamics. The local instability in the area involving the site of packing of the N-terminal chain fragment allows penetration and binding of the supramolecular dye Congo red that hence becomes an indicator of the initiated relaxation process and is also the prospective ligand in studies of designing drugs. The susceptibility to dye binding was observed in complexation of bivalent antibodies only, supplying the evidence that constraints associating the interaction with randomly distributed antigenic determinants drive the local structural changes in the V-domain followed by long-distance effects.

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Self-assembling dyes with a structure related to Congo red (e.g. Evans blue) form polymolecular complexes with albumin. The dyes, which are lacking a self-assembling property (Trypan blue, ANS) bind as single molecules. The supramolecular character of dye ligands bound to albumin was demonstrated by indicating the complexation of dye molecules outnumbering the binding sites in albumin and by measuring the hydrodynamic radius of albumin which is growing upon complexation of self-assembling dye in contrast to dyes lacking this property. The self-assembled character of Congo red was also proved using it as a carrier introducing to albumin the intercalated nonbonding foreign compounds. Supramolecular, ordered character of the dye in the complex with albumin was also revealed by finding that self-assembling dyes become chiral upon complexation. Congo red complexation makes albumin less resistant to low pH as concluded from the facilitated N-F transition, observed in studies based on the measurement of hydrodynamic radius. This particular interference with protein stability and the specific changes in digestion resulted from binding of Congo red suggest that the self-assembled dye penetrates the central crevice of albumin.

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INTRODUCTION: The aim of this study was to differentiate heavy and light chain-derived instability of monoclonal myeloma immunoglobulins by complexation of matched supramolecular dyes. These are composed of several micellar pieces of self-assembled dye molecules which may penetrate the protein interior of the binding locus with polypeptide chains. These dyes were used to elicit, by precipitation, the postulated higher aggregation tendency of the heavy chain derived from its higher hydrophobicity. MATERIALS AND METHODS: Agarose gel electrophoresis was used to create conditions for dye complexation and to reveal the precipitation. RESULTS: Congo red derivatives with aromatic ring substitutes, BACR and DBACR, of increased penetrating capability were chosen to provoke the precipitation of abnormal immunoglobulins by displacing association-prone polypeptide chains from the protein interior. CONCLUSIONS: The results of this study confirm the heavy chain-related propensity of some monoclonal immunoglobulins to aggregate and precipitate. The simplicity of the technique may improve clinical diagnosis and facilitate predictions of disease complications.

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The dye Congo red and related self-assembling compounds were found to stabilize immune complexes by binding to antibodies currently engaged in complexation to antigen. In our simulations, it was shown that the site that becomes accessible for binding the supramolecular dye ligand is located in the V domain, and is normally occupied by the N-terminal polypeptide chain fragment. The binding of the ligand disrupts the beta-structure in the domain, increasing the plasticity of the antigen-binding site. The higher fluctuation of CDR-bearing loops enhances antigen binding, and allows even low-affinity antibodies to be engaged in immune complexes. Experimental observations of the enhancement effect were supported by theoretical studies using L lambda chain (4BJL-PDB identification) and the L chain from the complex of IgM-rheumatoid factor bound to the CH3 domain of the Fc fragment (1ADQ-PDB identification) as the initial structures for theoretical studies of dye-induced changes. Commercial IgM-type rheumatoid factor (human) and sheep red blood cells with coupled IgG (human) were used for experimental tests aimed to reveal the dye-enhancement effect in this system. The specificity of antigen-antibody interaction enhanced by dye binding was studied using rabbit anti-sheep red cell antibodies to agglutinate red cells of different species. Red blood cells of hoofed mammals (horse, goat) showed weak enhancement of agglutination in the presence of Congo red. Neither agglutination nor enhancement were observed in the case of human red cells. The dye-enhancement capability in the SRBC-antiSRBC system was lost after pepsin-digestion of antibodies producing (Fab)2 fragments still agglutinating red cells. Monoclonal (myeloma) IgG, L lambda chain and ovoalbumin failed to agglutinate red cells, as expected, and showed no enhancement effect. This indicates that the enhancement effect is specific.

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It was shown experimentally that binding of a micelle composed of Congo red molecules to immunological complexes leads to the enhanced stability of the latter, and simultaneously prevents binding of a complement molecule (C1q). The dye binds in a cavity created by the removal of N-terminal polypeptide chain, as observed experimentally in a model system-immunoglobulin G (IgG) light chain dimer. Molecular Dynamics (MD) simulations of three forms of IgG light chain dimer, with and without the dye, were performed to investigate the role of N-terminal fragment and self-assembled ligand in coupling between V and C domains. Root-mean-square distance (RMSD) time profiles show that removal of N-terminal fragment leads to destabilization of V domain. A micelle composed of four self-assembled dye molecules stabilizes and fixes the domain. Analysis of root-mean-square fluctuation (RMSF) values and dynamic cross-correlation matrices (DCCM) reveals that removal of N-terminal fragment results in complete decoupling between V and C domains. Binding of self-assembled Congo red molecules improves the coupling, albeit slightly. The disruption of a small beta-sheet composed of N- and C-terminal fragments of the domain (NC sheet) is the most likely reason for the decoupling. Self-assembled ligand, bound in the place originally occupied by N-terminal fragment, is not able to take over the function of the beta-sheet. Lack of correlation of motions between residues in V and C domains denotes that light chain-Congo red complexes have hampered ability to transmit conformational changes between domains. This is a likely explanation of the lack of complement binding by immunological complexes, which bind Congo red, and supports the idea that the NC sheet is the key structural fragment taking part in immunological signal transduction.

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Congo red, a dye of high self-assembling tendency, has been found to form complexes with proteins by adhesion of the ribbon-like supramolecular ligand to polypeptide chains of beta-conformation. Complexation is allowed by local or global protein instability, facilitating penetration of the dye to the locus of its binding. At elevated temperatures, L chain lambda of myeloma origin was found to form two distinct complexes with Congo red, easily differentiated in electrophoresis as slow- and fast-migrating fractions, bearing four- and eight-dye-molecule ligands, respectively, in the V domain of each individual chain. The slow-migrating complex is formed after displacement of the N-terminal polypeptide chain fragment (about 20 residues) from its packing locus, thereby exposing the entrance to the binding cavity. In this work the formation and stability of this complex was studied by molecular dynamics (MD) simulations. The effect of three- and five-molecule ligands introduced to the site binding the dye was also analyzed in an attempt to understand the formation of fast-migrating complexes. The wedging of the ligand containing five dye molecules, hence longer than established experimentally as the maximum for the slow-migrating complex, was found to generate significant structural changes. These changes were assumed to represent the crossing of the threshold on the way to forming a fast-migrating complex more capacious for dyes. They led to almost general destabilization of the V domain, making it susceptible to extra dye complexation. Theoretical studies were designed in close reference to experimental findings concerning the number of dye molecules in the ligand inserted to the site binding the dye, the location of the site in the domain, and the conditions of formation of the complexes. The results of the two kinds of studies appeared coherent.

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Monoclonal myeloma proteins often have an abnormal, unstable structure, and tend to aggregate with fatal clinical consequences. A method for early clinical identification of this aggregation tendency is impatiently awaited. This work proposes the use of supramolecular dyes as specific ligands to reveal protein instability. Disclosure of excessive polypeptide chain flexibility in unstable monoclonal proteins, leading to increased susceptibility to penetration by foreign compounds, appeared possible when new supramolecular Congo red-derived dyes with different protein-binding capabilities were used for complexation. Two basic protein instability levels, local and global, were differentiated by comparing the extent of protein loading with dye and the subsequent electrophoretic migration rate of the complexes. A simple electrophoretic test is proposed for assessment of the instability of monoclonal proteins in clinical conditions.

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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.

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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.

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The role of the N-terminal polypeptide fragment of the immunoglobulin l-chain in V domain packing stability, and the flexibility of the whole chain was approached by molecular dynamics simulation. The observations were supported by experimental analysis. The N-terminal polypeptide fragment appeared to be the low-stability packing element in the V domain. At moderately elevated temperature it may be replaced at its packing locus by Congo red and then removed by proteolysis. After removal of Congo red by adsorption to (diethylamino)ethyl (DEAE) cellulose, the stability of complete L chain and of L chain devoid of the N-terminal polypeptide fragment were compared. The results indicated that the N-terminal polypeptide fragment plays an essential role in the stability of the V domain. Its removal makes the domain accessible for ANS and Congo red dye binding without heating. The decreased domain stability was registered in particular as increased root mean square (RMS) fluctuation and higher susceptibility to proteolytic attack. The long-range effect was most clearly manifested at 340 K as independent V and C domain fluctuation in the l-chain devoid of the N-terminal polypeptide fragment. This is likely due to the lack of direct connections between the N- and C-termini of the V domain polypeptide. In a complete V domain the connection involves residues 8-12 and 106-110 in particular. Partial or complete disruption of this connection increases the freedom of V domain rotation, while its increased cohesion strengthens the coupling of the V and C domains, making the whole L chain less flexible.

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BACKGROUND: Frequently observed structural deviations of myeloma-derived immunoglobulins affect polypeptide chain packing and domain stability, enhancing their tendency to aggregate, with all the clinical consequences. Congo red complexation with myeloma immunoglobulins is proposed in this work as a general test to disclose the instability of these proteins. The large ribbon-like supramolecular ligands of Congo red form complexes with proteins by adhesion to beta-conformation polypeptide chains, if allowed to make contact with their backbone interfaces. This can occur in the case of myeloma-derived immunoglobulins with deficient polypeptide chain packing. MATERIAL/METHODS: Specially adapted two-dimensional agarose electrophoresis of serum proteins, which allows the transient contact of Congo red and serum proteins during migration, was used to reveal the presence of protein components amenable to ligand penetration and binding. The combination of electrophoresis and Congo red binding to proteins permits the removal of loosely attached dye and evaluation of the effective complexation properties of the immunoglobulin fraction directly in the serum. RESULTS: Comparative studies of dye complexation with two L chains having different reactivities with Congo red confirmed that dye binding depended on protein instability in the conditions used. Myeloma proteins revealed different binding capabilities in the test used here. CONCLUSIONS: The complexes formed by the supramolecular dye Congo red with myeloma immunoglobulins differ in stability. Those of high stability indicate the abnormal protein structure thought to produce clinical symptoms. This work proposes an easy technique to differentiate the stability of complexes.

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The self-assembling tendency and protein complexation capability of dyes related to Congo red and also some dyes of different structure were compared to explain the mechanism of Congo red binding and the reason for its specific affinity for beta-structure. Complexation with proteins was measured directly and expressed as the number of dye molecules bound to heat-aggregated IgG and to two light chains with different structural stability. Binding of dyes to rabbit antibodies was measured indirectly as the enhancement effect of the dye on immune complex formation. Self-assembling was tested using dynamic light scattering to measure the size of the supramolecular assemblies. In general the results show that the supramolecular form of a dye is the main factor determining its complexation capability. Dyes that in their compact supramolecular organization are ribbon-shaped may adhere to polypeptides of beta-conformation due to the architectural compatibility in this unique structural form. The optimal fit in complexation seems to depend on two contradictory factors involving, on the one hand, the compactness of the non-covalently stabilized supramolecular ligand, and the dynamic character producing its plasticity on the other. As a result, the highest protein binding capability is shown by dyes with a moderate self-assembling tendency, while those arranging into either very rigid or very unstable supramolecular entities are less able to bind.

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