Alexander A. Timchenko

GroES co‐chaperonin small‐angle X‐ray scattering study shows ring orifice increase in solution

GroES consists of seven identical 10 kDa subunits and is involved in assisting protein folding as the partner of another oligomeric protein, the GroEL chaperonin. Here we studied the GroES structure in solution using small‐angle X‐ray scattering (SAXS). The SAXS pattern, calculated for the GroES crystal structure, was found to be different from the experimental one measured in solution. The synchronic shift in the radial direction and some turning of the protein subunits eliminate the difference and result in the increase of the hole diameter in the GroES ring‐like structure from 8 Å in the crystal to 21 Å in solution.

Analysis of Micro- and Nano-Structures of the Corneal Surface of Drosophila and Its Mutants by Atomic Force Microscopy and Optical Diffraction

Drosophila melanogaster is a model organism instrumental for numerous biological studies. The compound eye of this insect consists of some eight hundred individual ommatidia or facets, ca. 15 µm in cross-section. Each ommatidium contains eighteen cells including four cone cells secreting the lens material (cornea). High-resolution imaging of the cornea of different insects has demonstrated that each lens is covered by the nipple arrays - small outgrowths of ca. 200 nm in diameter. Here we for the first time utilize atomic force microscopy (AFM) to investigate nipple arrays of the Drosophila lens, achieving an unprecedented visualization of the architecture of these nanostructures. We find by Fourier analysis that the nipple arrays of Drosophila are disordered, and that the seemingly ordered appearance is a consequence of dense packing of the nipples. In contrast, Fourier analysis confirms the visibly ordered nature of the eye microstructures - the individual lenses. This is different in the frizzled mutants of Drosophila, where both Fourier analysis and optical imaging detect disorder in lens packing. AFM reveals intercalations of the lens material between individual lenses in frizzled mutants, providing explanation for this disorder. In contrast, nanostructures of the mutant lens show the same organization as in wild-type flies. Thus, frizzled mutants display abnormal organization of the corneal micro-, but not nano-structures. At the same time, nipples of the mutant flies are shorter than those of the wild-type. We also analyze corneal surface of glossy-appearing eyes overexpressing Wingless - the lipoprotein ligand of Frizzled receptors, and find the catastrophic aberration in nipple arrays, providing experimental evidence in favor of the major anti-reflective function of these insect eye nanostructures. The combination of the easily tractable genetic model organism and robust AFM analysis represents a novel methodology to analyze development and architecture of these surface formations.

Different oligomeric properties and stability of highly homologous A1 and proto-oncogenic A2 variants of mammalian translation elongation factor eEF1.

Translation elongation factor 1A (eEF1A) directs aminoacyl-tRNA to the A site of 80S ribosomes. In addition, more than 97% homologous variants of eEF1A, A1 and A2, whose expression in different tissues is mutually exclusive, may fulfill a number of independent moonlighting functions in the cell; for instance, the unusual appearance of A2 in an A1-expressing tissue was recently linked to the induction of carcinogenesis. The structural background explaining the different functional performance of the highly homologous proteins is unclear. Here, the main difference in the structural properties of these proteins was revealed to be the improved ability of A1 to self-associate, as demonstrated by synchrotron small-angle X-ray scattering (SAXS) and analytical ultracentrifugation. Besides, the SAXS measurements at different urea concentrations revealed the low resistance of the A1 protein to urea. Titration of the proteins by hydrophobic dye 8-anilino-1-naphthalenesulfonate showed that the A1 isoform is more hydrophobic than A2. As the different association properties, lipophilicity, and stability of the highly similar eEF1A variants did not influence considerably their translation functions, at least in vitro, we suggest this difference may indicate a structural background for isoform-specific moonlighting roles.

ROUGHNESS OF THE GLOBULAR PROTEIN SURFACE : ANALYSIS OF HIGH RESOLUTION X-RAY DATA

In an earlier publication [Serdyuk, I.N. et al., Biofizika, in press, 1997] we demonstrated that the asymmetry extent of globular proteins does not change with increasing their sizes, and the observed nontrivial dependence of the protein accessible surface area on the molecular mass [Miller, S., J. Mol. Biol. 196:641–656, 1987] (As − M dependence) is a reflection of the protein surface relief peculiarities. To clarify these peculiarities, an analysis of the molecular surface on the basis of high‐resolution x‐ray data has been done for 25 globular proteins not containing prosthetic groups. The procedure was based on studying the dependence of the minimal number (N) of probe bodies (here cubes) covering the entire protein surface, both on their size (N − R dependence) and on the value of dry protein volume (N − V dependence). Two levels of protein surface organization have been detected by molecular surface analysis. On the micro scale (2–7 Å), the surface is characterized by a D = 2.1 fractal dimension which is intrinsic to surfaces with weak deformations and reflects the local atomic group packing. On the macro scale, large‐scale surface defects are revealed that are interpreted as the result of secondary structure elements packing. A simple model of protein surface representation reflecting large‐scale irregularities has been proposed. Proteins 28:194–201, 1997.

Origin of order in bionanostructures

Nanoscale nipple arrays covering the corneal surface of many insects provide antireflection properties and have inspired industrial applications. Based on visual inspection, the dense packing of these nanostructures was initially described to adopt a regular hexagonal order. However, Fourier analysis revealed lack of order over larger distances of the lens cornea, with only patches of hexagonally organized nanostructures. Here we developed a formal mathematical analysis of nippled nanocoatings read by atomic-force microscopy (AFM). This analysis permits automatic assessment of the degree of order in nanostructural packings and its correlation with various characteristics of the nanoscale objects. We applied this analysis to corneae of 17 insect species from 6 orders. We find no correlation between the degree of order and the overall size of the lens. Instead, a strong correlation of the order and the density of the nipple packing exists. Surprisingly, we also see that order correlates with the height of the nanostructures. We discuss these findings in the context of the origin of order in the bio-nanoworld, where order may result largely from the dense packing of the nanostructures, rather than from specialized patterning mechanisms. Our findings uncover mechanisms of order formation, which may also apply to micro- and macro-structures.

The major mRNP protein YB-1: Structural and association properties in solution

YB-1 is a major mRNP protein participating in the regulation of transcription and translation of a wide range of eukaryotic genes in many organisms probably due to its influence on mRNA packing into mRNPs. While the functional properties of YB-1 are extensively studied, little is known about its structural properties. In the present work we focused on studying its secondary structure, rigidity of its tertiary structure, compactness, and oligomerization in vitro by using far UV-CD, DSC, one-dimensional (1)H NMR, SAXS, sedimentation and FPLC. It was shown that only the cold shock domain within the entire YB-1 chain has a well-packed tertiary structure undergoing cooperative heat and cold denaturation transitions. In contrast, the rest of the YB-1 molecule is not rigidly packed and consists of PP II-like helical secondary structure elements and coil-like regions. At the same time, the overall dimension of the protein molecule is unexpectedly small. The polypeptide chains of YB-1 have a high tendency to form oligomers at neutral pH, while the extent and structural organization of the oligomers depend on protein concentration and ionic strength varying from compact monomeric units up to high molecular weight oligomers. These oligomers in solution are unstable and dissociate upon protein concentration decrease.

Dynamics of oligomer formation by denatured carbonic anhydrase II

Aggregation and subsequent development of protein deposition diseases originate from conformational changes in corresponding amyloidogenic proteins. Many proteins unrelated to amyloidoses also fibrillate at the appropriate conditions. These proteins serve as a model for studying the processes of protein misfolding, oligomerization and fibril formation. The accumulated data support the model where protein fibrillogenesis proceeds via the formation of a relatively unfolded amyloidogenic conformation. The urea-induced unfolding of bovine carbonic anhydrase II, BCA II, is characterized by a combination of high-resolution NMR, circular dichroism spectroscopy and small angle X-ray scattering. It is shown that the formation of associates of protein molecules in complex with solvent (water and urea), APS, takes place in the presence of 4-6 M urea. The subsequent increase in urea concentration to 8 M is accompanied by a disruption of APS and leads to a complete unfolding of a protein molecule. Analysis of BCA II self-association in the presence of 4.2 M urea revealed that APS are relatively large mostly beta-structural blocks with the averaged molecular mass of 190-220 kDa. This work also demonstrates some novel NMR-based methodological approaches that provide useful information on protein self-association.

Modes of Escherichia coli Dps Interaction with DNA as Revealed by Atomic Force Microscopy

Multifunctional protein Dps plays an important role in iron assimilation and a crucial role in bacterial genome packaging. Its monomers form dodecameric spherical particles accumulating ~400 molecules of oxidized iron ions within the protein cavity and applying a flexible N-terminal ends of each subunit for interaction with DNA. Deposition of iron is a well-studied process by which cells remove toxic Fe2+ ions from the genetic material and store them in an easily accessible form. However, the mode of interaction with linear DNA remained mysterious and binary complexes with Dps have not been characterized so far. It is widely believed that Dps binds DNA without any sequence or structural preferences but several lines of evidence have demonstrated its ability to differentiate gene expression, which assumes certain specificity. Here we show that Dps has a different affinity for the two DNA fragments taken from the dps gene regulatory region. We found by atomic force microscopy that Dps predominantly occupies thermodynamically unstable ends of linear double-stranded DNA fragments and has high affinity to the central part of the branched DNA molecule self-assembled from three single-stranded oligonucleotides. It was proposed that Dps prefers binding to those regions in DNA that provide more contact pads for the triad of its DNA-binding bundle associated with one vertex of the protein globule. To our knowledge, this is the first study revealed the nucleoid protein with an affinity to branched DNA typical for genomic regions with direct and inverted repeats. As a ubiquitous feature of bacterial and eukaryotic genomes, such structural elements should be of particular care, but the protein system evolutionarily adapted for this function is not yet known, and we suggest Dps as a putative component of this system.

Conformation of Thermus thermophilus ribosomal protein S1 in solution at different ionic strengths

Small-angle x-ray and neutron scattering were used to study the structure of the ribosomal protein S1 (61 kDa) from Thermus thermophilus in solution at low and moderate ionic strength (0 and 100 mM NaCl). The protein was found to be globular in both cases. Modeling of the S1 structure comprising six homologous domains on the basis of the NMR data for one domain showed that the best fit to scattering data was provided by compact domain packing. The calculated gyration radius was 28–29 Å, as typical of globular proteins about 60 kDa. The protein was prone to self-association, forming mainly dimers and trimers at moderate ionic strength and higher compact associates at low ionic strength. Neutron scattering assays in heavy water at 100 mM NaCl revealed markedly elongated associates. The translational diffusion coefficient calculated for S1 at 100 mM NaCl from dynamic light scattering was markedly lower than the one expected for its globular monomer (D20,w = (2.7 ± 0.1)·10−7 versus (5.8–6.0)·10−7 cm2 s−1), confirming protein association under equilibrium conditions.

Different amyloid aggregation of smooth muscles titin in vitro

A comparative study of amyloid properties of the aggregates of smooth muscle titin (SMT) from chicken gizzard was carried out. These aggregates were formed in two solutions: 0.15 M glycine-KOH, pH 7.2–7.4 (SMT(Gly)) and 0.2 M KCl, 10 mM imidazole, pH 7.0 (SMT(KCl)). Electron microscopy data showed that SMT aggregates has an amorphous structure in both cases. The results of atomic-force microscopy demonstrated slight differences in morphology in two types of aggregates. The SMT(Gly) aggregates were represented as branching chains, composed of spherical aggregates approximately 300–500 nm in diameter and up to 35 nm in height. The SMT(KCl) aggregates formed sponge-like structures with strands of 8–10 nm in height. Structural analysis of SMT aggregates by X-ray diffraction revealed the presence of cross-β-sheet structure in the samples under study. In the presence of SMT(Gly) aggregates, thioflavine T fluorescence intensity was higher (~3-fold times) compared with that in the presence of SMT(KCl) aggregates. Congo red-stained SMT(Gly) aggregates had yellow to apple-green birefringence under polarized light, which was not observed for SMT(KCl) aggregates. Dynamic light scattering data showed the similar rate of aggregation for both types of aggregates, though SMT(KCl) aggregates were able to partially disaggregate under increased ionic strength of the solution. The ability of SMT to aggregation followed by disaggregation may be functionally significant in the cell.