Why do antifreeze proteins require a solenoid?

Proteins whose presence prevents water from freezing in living organisms at temperatures below 0 °C are referred to as antifreeze proteins. This group includes molecules of varying size (from 30 to over 300 aa) and variable secondary/supersecondary conformation. Some of these proteins also contain peculiar structural motifs called solenoids. We have applied the fuzzy oil drop model in the analysis of four categories of antifreeze proteins: 1 - very small proteins, i.e. helical peptides (below 40 aa); 2 - small globular proteins (40-100 aa); 3 - large globular proteins (>100 aa) and 4 - proteins containing solenoids. The FOD model suggests a mechanism by which antifreeze proteins prevent freezing. In accordance with this theory, the presence of the protein itself produces an ordering of water molecules which counteracts the formation of ice crystals. This conclusion is supported by analysis of the ordering of hydrophobic and hydrophilic residues in antifreeze proteins, revealing significant variability - from perfect adherence to the fuzzy oil drop model through structures which lack a clearly defined hydrophobic core, all the way to linear arrangement of alternating local minima and maxima propagating along the principal axis of the solenoid (much like in amyloids). The presented model - alternative with respect to the ice docking model - explains the antifreeze properties of compounds such as saccharides and fatty acids. The fuzzy oil drop model also enables differentiation between amyloids and antifreeze proteins.

Determining protein similarity by comparing hydrophobic core structure.

Formal assessment of structural similarity is - next to protein structure prediction - arguably the most important unsolved problem in proteomics. In this paper we propose a similarity criterion based on commonalities between the proteins' hydrophobic cores. The hydrophobic core emerges as a result of conformational changes through which each residue reaches its intended position in the protein body. A quantitative criterion based on this phenomenon has been proposed in the framework of the CASP challenge. The structure of the hydrophobic core - including the placement and scope of any deviations from the idealized model - may indirectly point to areas of importance from the point of view of the protein's biological function. Our analysis focuses on an arbitrarily selected target from the CASP11 challenge. The proposed measure, while compliant with CASP criteria (70-80% correlation), involves certain adjustments which acknowledge the presence of factors other than simple spatial arrangement of solids.

Intramolecular immunological signal hypothesis revived--structural background of signalling revealed by using Congo Red as a specific tool.

Micellar structures formed by self-assembling Congo red molecules bind to proteins penetrating into function-related unstable packing areas. Here, we have used Congo red--a supramolecular protein ligand--to investigate how the intramolecular structural changes that take place in antibodies following antigen binding lead to complement activation. According to our findings, Congo red binding significantly enhances the formation of antigen-antibody complexes. As a result, even low-affinity transiently binding antibodies can participate in immune complexes in the presence of Congo red, although immune complexes formed by these antibodies fail to trigger the complement cascade. This indicates that binding of antibodies to the antigen may not, by itself, fulfill the necessary conditions to generate the signal which triggers effector activity. These findings, together with the results of molecular dynamics simulation studies, enable us to conclude that, apart from the necessary assembling of antibodies, intramolecular structural changes generated by strains which associate high- affinity bivalent antibody fitting to antigen determinants are also required to cross the complement activation threshold.

Hydrophobic core in domains of immunoglobulin-like fold.

This work analyzes proteins which contain an immunoglobulin fold, focusing on their hydrophobic core structure. The "fuzzy oil drop" model was used to measure the regularity of hydrophobicity distribution in globular domains belonging to proteins which exhibit the above-mentioned fold. Light-chain IgG domains are found to frequently contain regular hydrophobic cores, unlike the corresponding heavy-chain domains. Enzymes and DNA binding proteins present in the data-set are found to exhibit poor accordance with the hydrophobic core model.

Two-intermediate model to characterize the structure of fast-folding proteins.

This paper introduces a new model that enables researchers to conduct protein folding simulations. A two-step in silico process is used in the course of structural analysis of a set of fast-folding proteins. The model assumes an early stage (ES) that depends solely on the backbone conformation, as described by its geometrical properties--specifically, by the V-angle between two sequential peptide bond planes (which determines the radius of curvature, also called R-radius, according to a second-degree polynomial form). The agreement between the structure under consideration and the assumed model is measured in terms of the magnitude of dispersion of both parameters with respect to idealized values. The second step, called late-stage folding (LS), is based on the "fuzzy oil drop" model, which involves an external hydrophobic force field described by a three-dimensional Gauss function. The degree of conformance between the structure under consideration and its idealized model is expressed quantitatively by means of the Kullback-Leibler entropy, which is a measure of disparity between the observed and expected hydrophobicity distributions. A set of proteins, representative of the fast-folding group - specifically, cold shock proteins - is shown to agree with the proposed model.

Geometric parameters defining the structure of proteins--relation to early-stage folding step.

Two geometrical parameters describing the structure of a polypeptide: V-dihedral angle between two sequential peptide bond planes and R-radius of curvature are used for structural classification of polypeptide structure in proteins. The relation between these two parameters was the basis for the definition of the conformational sub-space for early-stage structural forms. The cluster analysis of V and lnR, applied to the selected proteins of well-defined secondary structure (according to DSSP classification) and to proteins without any introductory classified analysis, revealed that several of the discriminated groups of proteins agree with the assumed model of early-stage conformational sub-space. This analysis shows that protein structures may be represented in VR space instead of Phi, Psi angles space, thus lowering the conformational space dimensionality. The VR model allows classification of traditional secondary structure elements as well as different Random Coil motifs, which broadens the range of recognized structural categories (compared to standard secondary structure elements).

Intramolecular signaling in immunoglobulins -- new evidence emerging from the use of supramolecular protein ligands.

The postulated intramolecular signaling in immunoglobulins generated by antigen binding has been controversial for years. The high heterogeneity of immune complexes as signaling systems and the requirement of the immobilized antigen form for efficient triggering of effector activity is likely the reason for the lack of clarity. Here we present new evidence supporting the notion of intramolecular signaling, based on the use of supramolecular dyes that bind to signal-derived specific sites in immunoglobulins.

Lysozyme folded in silico according to the limited conformational sub-space.

The conformational sub-space oriented on early-stage protein folding is applied to lysozyme folding. The part of the Ramachandran map distinguished on the basis of a geometrical model of the polypeptide chain limited to the mutual orientation of the peptide bond planes is shown to deliver the initial structure of the polypeptide for the energy minimization procedure in the ab initio model of protein folding prediction. Two forms of energy minimization and molecular dynamics simulation procedures were applied to the assumed early-stage protein folding of lysozyme. One of them included the disulphide bond system and the other excluded it. The post-energy-minimization and post-dynamics structures were compared using RMS-D and non-bonding contact maps to estimate the degree of approach to the native, target structure of the protein molecule obtained using the limited conformational sub-space for the early stage of folding.

Limited conformational space for early-stage protein folding simulation.

MOTIVATION: The problem of early-stage protein folding is critical for protein structure prediction. The model presented introduces a common definition of protein structures which may be treated as the possible in silico early-stage form of the polypeptide chain. Limitation of the conformational space to the ellipse path on the Ramachandran map was tested as a possible sub-space to represent the early-stage structure for simulation of protein folding. The proposed conformational sub-space was developed on the basis of the backbone conformation, with side-chain interactions excluded. RESULTS: The ellipse-path-limited conformation of BPTI was created using the criterion of shortest distance between Phi, Psi angles in native form of protein and the Phi, Psi angles belonging to the ellipse. No knots were observed in the structure created according to ellipse-path conformational sub-space. The energy minimization procedure applied to ellipse-path derived conformation directed structural changes toward the native form of the protein with SS-bonds system introduced to the procedure. AVAILABILITY: Program 'Ellipse' to create the ellipse-path derived structure available on request: myroterm@cyf-kr.edu.pl

Egg yolk platelet proteins from Xenopus laevis are amyloidogenic.

The association of amphibian (Xenopus laevis) egg yolk platelet proteins, represented predominantly by lipovitellin, was studied as a model of the formation of amyloid deposits. Two kinds of molecular organization formed by this protein material - native and heat-denatured - were found to exhibit amyloid properties although they differ significantly in structural organization. The first consisted in protein molecules arranged in the natural, physiological, net-like platelet organization, with a tendency to orient uni-directionally. The second was obtained by the gradual removal of Congo red from lipovitellin denatured by heating in an excess of dye. This procedure produced the twisted fibrillar organization of molecules typical for amyloids, represented predominantly by end-to-end associated major polypeptide chains of lipovitellin. Both native and denatured structural forms bind Congo red and produce a green birefringence effect, confirming the near parallel alignment of the complexed Congo red molecules. However, a dye(1,4-bis(1-amino-4-sulfonaphtyl-2-azo)phenylene) closely related to Congo red but with a very weak self-assembling tendency appeared inactive when the spectral shift was studied in a cross-polarization system, indicating in this way that dye supramolecularity is an extra factor which may determine binding to amyloid proteins and specific spectral effects.

Heat-induced formation of a specific binding site for self-assembled Congo Red in the V domain of immunoglobulin L chain lambda.

Moderate heating (40-50 degrees C) of immunoglobulins makes them accessible for binding with Congo Red and some related highly associated dyes. The binding is specific and involves supramolecular dye ligands presenting ribbon-like micellar bodies. The L chain lambda dimer, which upon heating disclosed the same binding requirement with respect to supramolecular dye ligands, was used in this work to identify the site of their attachment. Two clearly defined dye-protein (L lambda chain) complexes arise upon heating, here called complex I and complex II. The first is formed at low temperatures (up to 40-45 degrees C) and hence by a still native protein, while the formation of the second one is associated with domain melting above 55 degrees C. They contain 4 and 8 dye molecules bound per L chain monomer, respectively. Complex I also forms efficiently at high dye concentration even at ambient temperature. Complex I and its formation was the object of the present studies. Three structural events that could make the protein accessible to penetration by the large dye ligand were considered to occur in L chains upon heating: local polypeptide chain destabilization, VL-VL domain incoherence, and protein melting. Of these three possibilities, local low-energy structural alteration was found to correlate best with the formation of complex I. It was identified as decreased packing stability of the N-terminal polypeptide chain fragment, which as a result made the V domain accessible for dye penetration. The 19-amino acid N-terminal fragment becomes susceptible to proteolytic cleavage after being replaced by the dye at its packing locus. Its splitting from the dye-protein complex was proved by amino acid sequence analysis. The emptied packing locus, which becomes the site that holds the dye, is bordered by strands of amino acids numbered 74-80 and 105-110, as shown by model analysis. The character of the temperature-induced local polypeptide chain destabilization and its possible role in intramolecular antibody signaling is discussed.

Why Congo red binding is specific for amyloid proteins - model studies and a computer analysis approach.

BACKGROUND: The complexing of Congo red in two different ligand forms - unimolecular and supramolecular (seven molecules in a micelle) - with eight deca-peptides organized in a b-sheet was tested by computational analysis to identify its dye-binding preferences. Polyphenylananine and polylysine peptides were selected to represent the specific side chain interactions expected to ensure particularly the stabilization of the dye-protein complex. Polyalanine was used to verify the participation of non-specific backbone-derived interactions. MATERIAL AND METHODS: The initial complexes for calculation were constructed by intercalating the dye between the peptides in the middle of the beta-sheet. The long axis of the dye molecule (in the case of unimolecular systems) or the long axis of the ribbon-like micelle (in the case of the supramolecular dye form) was oriented parallel to the peptide backbone. This positioning maximally reduced the exposure of the hydrophobic diphenyl (central dye fragment) to water. In general the complexes of supramolecular Congo red ligands appeared more stable than those formed by individual dye molecules. Specific interactions (electrostatic and/or ring stacking) dominated as binding forces in the case of the single molecule, while non-specific surface adsorption seemed decisive in complexing with the supramolecular ligand. RESULTS: Both the unimolecular and supramolecular versions of the dye ligand were found to be likely to form complexes of sufficient stability with peptides. The low stability of the protein and the gap accessible to penetration in the peptide sheet seem sufficient for supramolecular ligand binding, but the presence of positively charged or hydrophobic amino acids may strengthen binding significantly. CONCLUSIONS: The need for specific interaction makes single-molecule Congo red binding rather unusual as a general amyloid protein ligand. The structural feature of Congo red, which enables specific and common interaction with amyloid proteins, probably derives from the ribbon-like self-assembled form of the dye.

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.

Supramolecularity creates nonstandard protein ligands.

Congo red and a group of structurally related dyes long used to stain amyloid proteins are known to associate in water solutions. The self-association of some dyes belonging to this group appears particularly strong. In water solutions their molecules are arranged in ribbon-like micellar forms with liquid crystalline properties. These compounds have recently been found to form complexes with some native proteins in a non-standard way. Gaps formed by the local distribution of beta-sheets in proteins probably represent the receptor sites for these dye ligands. They may result from higher structural instability in unfolding conditions, but also may appear as long range cooperative fluctuations generated by ligand binding. Immunoglobulins G were chosen as model binding proteins to check the mechanism of binding of these dyes. The sites of structural changes generated by antigen binding in antibodies, believed to act as a signal propagated to distant parts of the molecule, were assumed to be suitable sites for the complexation of liquid-crystalline dyes. This assumption was confirmed by proving that antibodies engaged in immune complexation really do bind these dyes; as expected, this binding affects their function by significantly enhancing antigen binding and simultaneously inhibiting C1q attachment. Binding of these supramolecular dyes by some other native proteins including serpins and their natural complexes was also shown. The strict dependence of the ligation properties on strong self-assembling and the particular arrangement of dye molecules indicate that supramolecularity is the feature that creates non-standard protein ligands, with potential uses in medicine and experimental science.

Supramolecular ligands: monomer structure and protein ligation capability.

The aim of this work was to define the chemical structure of compounds self-assembling in water solutions, which appear to interact with proteins as single ligands with their supramolecular nature preserved. For this purpose the ligation to proteins of bis azo dyes, represented by Congo red and its derivatives with designed structural alterations, were tested. The three parameters which characterize the reactivity of supramolecular material were determined in the same conditions for all studied dyes. These were: A) stability of the assembly products; B) binding to heat-denatured protein (human IgG); and C) binding to native protein (rabbit antibodies in the immune complex) measured by the enhancement of hemagglutination. The structural differences between the Congo red derivatives concerned the symmetry of the molecule and the structure of its non-polar component, which occupies the central part of the dye molecule and is thought to be crucial for self-assembly. Other dyes were also studied for the same purpose: Evans blue and Trypan blue, bis-ANS and ANS, as well as a group of compounds with a structural design unlike that of bis azo dyes. Compounds with rigid elongated symmetric molecules with a large non-polar middle fragment are expected to form a ribbon-like supramolecular organization in assembling. They appeared to have ligation properties related to their self-assembling tendency. The compounds with different structures, not corresponding to bis azo dyes, did not reveal ligation capability, at least in respect to native protein. The conditions of binding to denatured proteins seem less restrictive than the conditions of binding to native molecules. The molten hydrophobic protein interior becomes a new binding area allowing for complexation of even non-assembled molecules.

Effect of self association of bis-ANS and bis-azo dyes on protein binding.

A correlation was found between the ability of dyes (ANS, bis-ANS, Congo red, Evans blue) to form self-associated supramolecular structures in water and their tendency to form complexes with proteins. The self-association ability of dyes was measured as the resistance of a molecular sieve to their penetration. Quantitative evaluation of dye-protein interaction involved measuring the effect of dye on antibodies that agglutinate sheep red blood cells. Enhancement of agglutination by dye was assumed to represent its protein complexation ability. The results confirm that, relative to monomers, self-associated ligands also have altered protein binding properties.

The use of congo red as a lyotropic liquid crystal to carry stains in a model immunotargeting system--microscopic studies.

The lyotropic liquid crystal dye-Congo Red was used as a carrier in a model immunotargeting system constructed from sheep red blood cells (SRBC) representing the antigen target and rabbit IgG anti-SRBC as the specific driving immunoglobulin. Rhodamine B and Hemin stains were chosen as example chemicals carried to the target. The carried stains were introduced to the micellar organization of Congo Red by intercalation. Preserving its supramolecular organization, Congo Red binds spontaneously and selectively to antibodies that have altered structure extorted by interaction with the antigen in the immune complex. The functionality of the studied immunotargeting model was verified by fluorescence and electron microscopy. The results indicate that the supramolecular nature of protein ligands offers new ligation capabilities possibly useful for carrying stains or drugs in immune-oriented systems.

Congo red-stabilized intermediates in the lambda light chain transition from native to molten state.

Disruption of tertiary interaction makes a protein accessible to penetration by different small molecular compounds. Their interaction may stabilize the altered protein conformation. Congo red is proposed here as a stabilizer of the molten globule state and also of highly reversible intermediates in the transition from native to molten state. Human immunoglobulin lambda light chain (dimer) was used. Two protein-Congo red complexes were found after heating lambda chain in the presence of Congo red. They differed in the amount of attached dye molecules. The binding of dye was interpreted as a two-step dye penetration process involving the peripheral parts of the protein in the first step (at lower temperatures). It was concluded that the liquid crystal properties of Congo red enable it to form specific complexes with proteins, which have become accessible to penetration by ligands after global or local disruption of tertiary interaction. This dye may thus be used as a stabilizer of unfolding intermediates in the step preceding the molten globule state.

Modelling the optimal simulation path in the peptide chain folding--studies based on geometry of alanine heptapeptide.

The theoretical background of a simple model of polypeptide chain structure using two parameters: R (A)--the radius of curvature for each pentapeptide chain fragment in the protein, and V (deg)--the dihedral angle between two consecutive peptide bond planes, is presented. The mathematical relationship between these two geometrical parameters leads to the optimal searching path for low-energy peptide conformations. This R versus V relation, corresponding to low-energy structures in Ramachandran plot, appeared to fit the square function well. Here, the minimum of this function is taken as the optimal starting point for the minimization of all second-order conformations in the peptide chain. The extension, including all structures that satisfy the square function between V and R, showed the Phi, Psi angles that are optimal in searching for the path to low-energy structures. The path is an ellipse connecting the alpha R-, beta- and alpha L-structures, indicating the possible transitions from one to the next.

Geometrical analysis of structural changes in immunoglobulin domains' transition from native to molten state.

Molecular dynamics simulation (300, 320, 340 K) performed on the Fab (Kol) fragment of immunoglobulin G revealed that the structural changes associated with relaxation of peptides after their release from the stabilized by the tertiary interaction native conformation may be considered characteristic of the transition from native to molten state. The configuration of peptide chains at temperatures close to melting, liberated from the constraints associated with tertiary packing, was found to deviate toward helical rather than extended forms. The direction of the shift is diagonal on the phi-psi map. The torsional angles tend to concentrate in the Cea7 region, and some leak to the alphaR area. The geometrical parameters designed to describe the configuration of the peptide chain in Fab fragment also confirmed that during melting the peptides generally moved toward helical form.