Influence of Chaperones on Amyloid Formation of Ðß Peptide.

BACKGROUND: An extensive study of the folding and stability of proteins and their complexes has revealed a number of problems and questions that need to be answered. One of them is the effect of chaperones on the process of fibrillation of various proteins and peptides. METHODS: We studied the effect of molecular chaperones, such as GroEL and α-crystallin, on the fibrillogenesis of the Aß(1-42) peptide using electron microscopy and surface plasmon resonance. RESULTS: Recombinant GroEL and Aß(1-42) were isolated and purified. It was shown that the assembly of GroEL occurs without the addition of magnesium and potassium ions, as is commonly believed. According to the electron microscopy results, GroEL insignificantly affects the fibrillogenesis of the Aß(1-42) peptide, while α-crystallin prevents the elongation of the Aß(1-42) peptide fibrils. We have demonstrated that GroEL interacts nonspecifically with Aß(1-42), while α-crystallin does not interact with Aß(1-42) at all using surface plasmon resonance. CONCLUSION: The data obtained will help us understand the process of amyloid formation and the effect of various components on it.

Comparative Analysis of Aggregation of Thermus thermophilus Ribosomal Protein bS1 and Its Stable Fragment.

Functionally important multidomain bacterial protein bS1 is the largest ribosomal protein of subunit 30S. It interacts with both mRNA and proteins and is prone to aggregation, although this process has not been studied in detail. Here, we obtained bacterial strains overproducing ribosomal bS1 protein from Thermus thermophilus and its stable fragment bS1(49) and purified these proteins. Using fluorescence spectroscopy, dynamic light scattering, and high-performance liquid chromatography combined with mass spectrometric analysis of products of protein limited proteolysis, we demonstrated that disordered regions at the N- and C-termini of bS1 can play a key role in the aggregation of this protein. The truncated fragment bS1(49) was less prone to aggregation compared to the full-size bS1. The revealed properties of the studied proteins can be used to obtain protein crystals for elucidating the structure of the bS1 stable fragment.

Studies of the Process of Amyloid Formation by Aß Peptide.

Studies of the process of amyloid formation by Aß peptide have been topical due to the critical role of this peptide in the pathogenesis of Alzheimer's disease. Many articles devoted to this process are available in the literature; however, none of them gives a detailed description of the mechanism of the process of generation of amyloids. Moreover, there are no reliable data on the influence of modified forms of Aß peptide on its amyloid formation. To appreciate the role of Aß aggregation in the pathogenesis of Alzheimer's disease and to develop a strategy for its treatment, it is necessary to have a well-defined description of the molecular mechanism underlying the formation of amyloids as well as the contribution of each intermediate to this process. We are convinced that a combined analysis of theoretical and experimental methods is a way for understanding molecular mechanisms of numerous diseases. Based on our experimental data and molecular modeling, we have constructed a general model of the process of amyloid formation by Aß peptide. Using the data described in our previous publications, we propose a model of amyloid formation by this peptide that differs from the generally accepted model. Our model can be applied to other proteins and peptides as well. According to this model, the main building unit for the formation of amyloid fibrils is a ring-like oligomer. Upon interaction with each other, ring-like oligomers form long fibrils of different morphology. This mechanism of generation of amyloid fibrils may be common for other proteins and peptides.

Analysis of Insulin Analogs and the Strategy of Their Further Development.

We analyzed the structural properties of the peptide hormone insulin and described the mechanism of its physiological action, as well as effects of insulin in type 1 and 2 diabetes. Recently published data on the development of novel insulin preparations based on combining molecular design and genetic engineering approaches are presented. New strategies for creation of long-acting insulin analogs, the mechanisms of functioning of these analogs and their structure are discussed. Side effects of insulin preparations are described, including amyloidogenesis and possible mitogenic effect. The pathways for development of novel insulin analogs are outlined with regard to the current requirements for therapeutic preparations due to the wider occurrence of diabetes of both types.

[Amyloid Core Wild-Type Apomyoglobin and Its Mutant Variants Is Formed by Different Regions of the Polypeptide Chain].

As has been recently shown, the toxicity of protein aggregates is determined by their structure. Therefore, special attention has been focused on the search for factors that specify the structural features of formed amyloid fibrils. The effect of amino acid substitutions in apomyoglobin on the structural characteristics of its amyloid aggregates has been analyzed. The morphology and secondary structure of amyloids of the wild-type protein and its mutant variants Val10Ala, Val10Phe, and Trp14Phe have been compared, and the regions involved in intermolecular interactions in fibrils have been determined using limited proteolysis and mass spectrometry. No considerable differences have been found in the morphology (shape, length, or diameter) or the content (percentage) of the cross-ß structure of apomyoglobin amyloids and its mutant variants. Amyloid cores of wild-type apomyoglobin and variants with Val10Phe and Trp14Phe substitutions have been formed by different regions of the polypeptide chain. The case study of apomyoglobin demonstrates that the location of amyloidogenic regions in the polypeptide chain of wild-type protein and its mutant forms can differ. Thus, possible structural changes in amyloids resulting from amino acid substitutions should be taken into account when studying phenotype aggregation.

[Ligand-Induced Reassembly of GroEL/ES Chaperone In Vitro: Visualization by Electron Microscopy].

The products of the reassembly reaction of tetradecameric two-ring quaternary structure of GroEL chaperonin under the pressure of its heptameric co-chaperonin GroES have been visualized by electron microscopy. It has been shown that one-ring heptameric oligomers of GroEL have been formed at the beginning (after ~5 min) of the reaction, while at the final stage of the reaction (after ~70 min), both one-ring heptamers in complex with one GroES and two-rings tetradecamers in complexes with one (asymmetrical complex) or two (symmetrical complex) GroES heptamers are present. The relationship between the data of light scattering, native electrophoresis, and electron microscopy obtained earlier has been discussed.

[Molecular mechanism of amyloid formation by Ab peptide: review of own works]. / Molekuliarnyi mekhanizm amiloidoobrazovaniia Ab peptidom: obzor sobstvennykh rabot.

TA characteristic feature of amyloid structures is polymorphism. The study of amyloid structures and their formation process was carried out for synthetic and recombinant Ab(1-40) and Ab(1-42) peptide preparations. In the study of these peptides, we recognized fibrils of different morphologies. We observed fibrillar formations in the form of single fibrils, ribbons, bundles, bunches, and clusters. Polymorphism of fibrils was observed not only when the environmental conditions changed, but under the same conditions and this was a common characteristics of all amyloid formations. Fibrils of Ab(1-40) peptides tended to form aggregates of fibrils in the form of ribbons, while Ab(1-42) peptide under the same conditions polymerized in the form of rough fibrils of different diameters and tends to branch. We assume that the formation of fibrils of Ab(1-40) and Ab(1-42) peptides occurs according to a simplified scheme: a destabilized monomer ® a ring oligomer ® a mature fibril consisting of ring oligomers. Proceeding from the proposition that the ring oligomer is the main building block of amyloid fibril (similar to the cell in the body), it is easy to explain fibril polymorphism, as well as fragmentation of mature fibrils under various external influences, branching and irregularity of diameter (surface roughness) of fibrils. One aspect of the study of amyloidogenesis is the determination of the regions of the protein chain forming the core of the amyloid fibril. We theoretically predicted amyloidogenic regions for two isoforms of Ab peptides capable of forming an amyloid structure: 16-21 and 32-36 residues. Using the method of tandem mass spectrometry, these regions were determined experimentally. It was shown that the regions of Ab(1-40) peptide from 16 to 22 and from 28 to 40 residues were resistant to the action of proteases, i.e. its formed the core of the amyloid fibril. For Ab(1-42) peptide the whole sequence is not available for the action of proteases, which indicates a different way of associating ring oligomers in the formation of fibrils. Based on electron microscopy and mass spectrometry data we proposed a molecular model of the fibril formed by Ab(1-40) and Ab(1-42) peptides.

α-Crystallins Are Small Heat Shock Proteins: Functional and Structural Properties.

During its life cycle, a cell can be subjected to various external negative effects. Many proteins provide cell protection, including small heat shock proteins (sHsp) that have chaperone-like activity. These proteins have several important functions involving prevention of apoptosis and retention of cytoskeletal integrity; also, sHsp take part in the recovery of enzyme activity. The action mechanism of sHsp is based on the binding of hydrophobic regions exposed to the surface of a molten globule. α-Crystallins presented in chordate cells as two αA- and αB-isoforms are the most studied small heat shock proteins. In this review, we describe the main functions of α-crystallins, features of their secondary and tertiary structures, and examples of their partners in protein-protein interactions.

Peptide Aß(16-25) Forms Nanofilms in the Process of Its Aggregation.

A method for the synthesis and high purification of fragments of Aß(1-42) peptide has been elaborated. We have synthesized the amyloidogenic fragment Aß(16-25) predicted by us and studied the process of its aggregation by electron microscopy and X-ray analysis. Electron microscopy images show that the peptide forms a film, which is not characteristic of amyloid fibrils. At the same time, according to the X-ray diffraction data, its preparations display the presence of two main reflections (4.6-4.8 and 8-12 Å) characteristic of cross-ß structure of amyloid fibrils. Thus, the fragment Aß(16-25) that we predicted is a promising object not only for studying the process of polymerization of the peptides/proteins, but also for using it as a nanomaterial to study a number of biological processes.

Determination of Regions Involved in Amyloid Fibril Formation for Aß(1-40) Peptide.

The studies of amyloid structures and the process of their formation are important problems of biophysics. One of the aspects of such studies is to determine the amyloidogenic regions of a protein chain that form the core of an amyloid fibril. We have theoretically predicted the amyloidogenic regions of the Aß(1-40) peptide capable of forming an amyloid structure. These regions are from 16 to 21 and from 32 to 36 amino acid residues. In this work, we have attempted to identify these sites experimentally by the method of tandem mass spectrometry. As a result, we show that regions of the Aß(1-40) peptide from 16 to 22 and from 28 to 40 amino acid residues are resistant to proteases, i.e. they are included in the core of amyloid fibrils. Our results correlate with the results of the theoretical prediction.

Determination of Size of Folding Nuclei of Fibrils Formed from Recombinant Aß(1-40) Peptide.

We have developed a highly efficient method for purification of the recombinant product Aß(1-40) peptide. The concentration dependence of amyloid formation by recombinant Aß(1-40) peptide was studied using fluorescence spectroscopy and electron microscopy. We found that the process of amyloid formation is preceded by lag time, which indicates that the process is nucleation-dependent. Further exponential growth of amyloid fibrils is followed by branching scenarios. Based on the experimental data on the concentration dependence, the sizes of the folding nuclei of fibrils were calculated. It turned out that the size of the primary nucleus is one "monomer" and the size of the secondary nucleus is zero. This means that the nucleus for new aggregates can be a surface of the fibrils themselves. Using electron microscopy, we have demonstrated that fibrils of these peptides are formed by the association of rounded ring structures.

Supramolecular organization of Hfq-like proteins.

Bacterial Hfq proteins are structural homologs of archaeal and eukaryotic Sm/Lsm proteins, which are characterized by a 5-stranded ß-sheet and an N-terminal α-helix. Previously, it was shown that archaeal Lsm proteins (SmAP) could produce long fibrils spontaneously, in contrast to the Hfq from Escherichia coli that could form similar fibrils only after special treatment. The organization of these fibrils is significantly different, but the reason for the dissimilarity has not been found. In the present work, we studied the process of fibril formation by bacterial protein Hfq from Pseudomonas aeruginosa and archaeal protein SmAP from Methanococcus jannaschii. Both proteins have high homology with E. coli Hfq. We found that Hfq from P. aeruginosa could form fibrils after substitutions in the conserved Sm2 motif only. SmAP from M. jannaschii, like other archaeal Lsm proteins, form fibrils spontaneously. Despite differences in the fibril formation conditions, the architecture of both was similar to that described for E. coli Hfq. Therefore, universal nature of fibril architecture formed by Hfq proteins is suggested.

Structural polymorphism and possible pathways of amyloid fibril formation on the example of insulin protein.

In this review we analyze the main works on amyloid formation of insulin. There are many environmental factors affecting the formation of insulin amyloid fibrils (and other amyloidogenic proteins) such as: protein concentration, pH, ionic strength of solution, medium composition (anions, cations), presence of denaturants (urea, guanidine chloride) or stabilizers (saccharose), temperature regime, agitation. Since polymorphism is potentially crucial for human diseases and may underlie the natural variability of some amyloid diseases, in this review we focus attention on polymorphism that is an important biophysical difference between native protein folding suggesting correspondence between the amino acid sequence and unique folding state, and formation of amyloid fibrils, when the same amino acid sequence can form amyloid fibrils of different morphology. At present, according to the literature data, we can choose three ways of polymerization of insulin molecules depending on the nucleus size. The first suggests that fibrillogenesis can occur through assembly of insulin monomers. The second suggests that precursors of fibrils are dimers, and the third assumes that precursors of fibrils are oligomers. Additional experimental works and new methods of investigation and assessment of results are needed to clarify the general picture of insulin amyloid formation.

Loops and repeats in proteins as footprints of molecular evolution.

This review is devoted to substantiation of new characteristics for classification of living organisms. The novel view of a role of flexible regions in protein functioning and evolution is suggested. It is based on the newly revealed correlation between the number of loops in elongation factors and the complexity of organisms. This correlation allowed us to formulate a hypothesis of evolution of this protein family. In addition, the study of the ribosomal protein S1 family made it possible to consider the number of structural domains as a reliable indicator of a microorganism's affiliation with a particular division and to judge about "direction" of their evolution. The findings allow us to consider the loops and repeats in these proteins as unique imprints of molecular evolution.

[Family of ribosomal proteins S1 contains unique conservative domain].

Different representatives of bacteria have different number of amino acid residues in the ribosomal proteins S1. This number varies from 111 (Spiroplasma kunkelii) to 863 a.a. (Treponema pallidum). Traditionally and for lack of this protein three-dimensional structure, its architecture is represented as repeating S1 domains. Number of these domains depends on the protein's length. Domain's quantity and its boundaries data are contained in the specialized databases, such as SMART, Pfam and PROSITE. However, for the same object these data may be very different. For search of domain's quantity and its boundaries, new approach, based on the analysis of dicted secondary structure (PsiPred), was used. This approach allowed us to reveal structural domains in amino acid sequences of S1 proteins and at that number varied from one to six. Alignment of S1 proteins, containing different domain's number, with the S1 RNAbinding domain of Escherichia coli PNPase elicited a fact that in family of ribosomal proteins SI one domain has maximal homology with S1 domain from PNPase. This conservative domain migrates along polypeptide chain and locates in proteins, containing different domain's number, according to specified pattern. In this domain as well in the S1 domain from PNPase, residues Phe-19, Phe-22, His-34, Asp-64 and Arg-68 are clustered on the surface and formed RNA binding site.

YB-1 is capable of forming extended nanofibrils.

Here we are the first to report that multifunctional Y-box binding protein 1 (YB-1) forms extended fibrils with a diameter of 15-20 nm. The YB-1 fibrils were visualized by atomic force and electron microscopy after 1-h incubation in solution with 2 M LiCl. Their length grew with incubation time and could exceed 10 microm; their shape is helical or zigzag-like. They possess polarity and tend to associate with one another to give structures of a higher order, like ribbons or bundles. The YB-1 fibrillar architecture has a distinct periodicity with a repeat unit of about 52 nm.

[Conformation of the ribosomal protein S1 of Thermus thermophilus in solution under different ionic conditions].

The structure of protein SI of Thermus thermophilus (M = 61 kDa) in solution at low and moderate ionic strengths (0 M and 100 mM NaCl, respectively) has been studied by small-angle X-ray and neutron scattering. It was found that protein S1 has a globular conformation under both ionic conditions. The modelling of different packing of six homologous domains of S1 on the basis of the NMR-resolved structure of one domain showed that the best fit of calculated scattering patterns from such complexes to experimental ones is observed at a compact package of the domains. The calculated value of the radius of gyration of the models is 28-29 angtroms, which is characteristic for globular proteins with a molecular mass of about 60 kDa. It was found that protein S1 has a tendency to form associates, and the type of the associate depends on ionic strength. These associates have, in general, two or three monomers at a moderate ionic strength, while at a low ionic strength the number of monomers exceeds three and they are packed in a compact manner. Strongly elongated associates were observed in neutron experiments at a moderate ionic strength in heavy water. The association of protein molecules was also confirmed by the data of dynamic light scattering. From these data, the translational diffusion coefficient of protein S1 at a moderate ionic strength was calculated to be (D20,w = (2.7 +/- 0.1) x 10(-7)cm2/s). This value is essentially smaller than the expected value (D20,w = (5.8 - 6.0) x 10(-7)cm2/s) for the S1 monomer in the globular conformation, indicating the association of protein molecules under equilibrium conditions.

Proteolysis of ribosomal protein S1 from Escherichia coli and Thermus thermophilus leads to formation of two different fragments.

As a result of limited tryptic proteolysis of S1 ribosomal protein (molecular mass 60 kD) from Thermus thermophilus, 25 N-terminal amino acid residues and 71 C-terminal amino acid residues are split off and a stable high-molecular-weight fragment with molecular mass of 49 kD is formed that retains RNA-binding properties and is capable of interacting with 30S ribosomal subunit. Earlier, application of a similar procedure for the formation of a fragment of S1 protein from Escherichia coli resulted in splitting of 171 N-terminal amino acid residues with the formation of a 41.3 kD fragment that possesses RNA-binding properties only. Thus, in spite of high homology between E. coli and T. thermophilus proteins, the proteolysis leads to the formation of two different fragments, which points, in our opinion, to the fact of significant differences between their structures.

Independent in vitro assembly of all three major morphological parts of the 30S ribosomal subunit of Thermus thermophilus.

Fragments of the 16S rRNA of Thermus thermophilus representing the 3' domain (nucleotides 890-1515) and the 5' domain (nucleotides 1-539) have been prepared by transcription in vitro. Incubation of these fragments with total 30S ribosomal proteins of T. thermophilus resulted in formation of specific RNPs. The particle assembled on the 3' RNA domain contained seven proteins corresponding to Escherichia coli ribosomal proteins S3, S7, S9, S10, S13, S14, and S19. All of them have previously been shown to interact with the 3' domain of the 16S RNA and to be localized in the head of the 30S ribosomal subunit. The particle formed on the 5' RNA domain contained five ribosomal proteins corresponding to E. coli proteins S4, S12, S17, S16, and S20. These proteins are known to be localized in the main part of the body of the 30S subunit. Both types of particle were compact and had sedimentation coefficients of 15.5 S and 13 S, respectively. Together with our recent demonstration of the reconstitution of the RNA particle representing the platform of the T. thermophilus 30S ribosomal subunit [Agalarov, S.C., Zheleznyakova, E.N., Selivanova, O.M., Zheleznaya, L.A., Matvienko, N.I., Vasiliev, V.D. & Spirin, A.S. (1998) Proc. Natl Acad. Sci. USA 95, 999-1003], these experiments establish that all three main structural lobes of the small ribosomal subunit can be reconstituted independently of each other and prepared in the individual state.

In vitro assembly of a ribonucleoprotein particle corresponding to the platform domain of the 30S ribosomal subunit.

A fragment of the 16S RNA of Thermus thermophilus corresponding to the central domain (nucleotides 547-895) has been prepared by transcription in vitro. Incubation of this fragment with the total 30S ribosomal proteins has resulted in the formation of a compact 12S ribonucleoprotein particle. This particle contained five T. thermophilus proteins corresponding to Escherichia coli ribosomal proteins S6, S8, S11, S15, and possibly S18, all of which were previously shown to interact with the central domain of the 16S RNA and to be localized in the platform (side bulge) of the 30S ribosomal subunit. When examined by electron microscopy, isolated particles have an appearance that is similar in size and shape to the corresponding morphological features of the 30S subunit. We conclude that the central domain of the 16S RNA can independently and specifically assemble with a defined subset of ribosomal proteins into a compact ribonucleoprotein particle corresponding to the platform (side bulge) of the 30S subunit.