Nikolay A. Barinov scite author profile

This study presents purification, activity characterization, and 1 H NMR study of the novel antifungal peptide EcAMP1 from kernels of barnyard grass Echinochloa crus-galli. The peptide adopts a disulfide-stabilized ␣-helical hairpin structure in aqueous solution and thus represents a novel fold among naturally occurring antimicrobial peptides. Micromolar concentrations of EcAMP1 were shown to inhibit growth of several fungal phytopathogens. Confocal microscopy revealed intensive EcAMP1 binding to the surface of fungal conidia followed by internalization and accumulation in the cytoplasm without disturbance of membrane integrity. Close spatial structure similarity between EcAMP1, the trypsin inhibitor VhTI from seeds of Veronica hederifolia, and some scorpion and cone snail toxins suggests natural elaboration of different functions on a common fold.Antimicrobial peptides (AMPs) 4 are a structurally diverse group of generally small, positively charged peptides produced by various living organisms and demonstrating a wide spectrum of antimicrobial activity (1, 2). Natural sources of AMPs range from prokaryotes to higher animals, and their targets include bacteria, fungi, protozoa, and viruses. The mechanism of action of most known AMPs involves their direct or receptor-mediated interaction with microbial membranes (3-5). It has been generally accepted that membrane-disruptive AMPs kill microorganisms by provoking in different ways an increase in plasma membrane permeability. Non-membrane-disruptive peptides have been shown to target cell wall formation or traverse membranes and affect various internal cellular processes, for example, RNA, DNA, and/or protein biosynthesis. Some AMPs can combine disruptive and non-disruptive mechanisms of action (6). Moreover, mechanisms of action of the same peptide may differ depending on the target. Recent studies have also indicated that AMPs are multifunctional molecules; they can interact with host membrane receptors and influence diverse intracellular processes modulating the immune response of the host organism (7,8).Essential variety in detailed mechanisms of action and multifunctionality imply structural diversity among AMPs. The following structural groups are usually recognized: (i) linear peptides that form ␣-helices in contact with membranes; (ii) disulfide-containing with predominance of ␤-structural elements; and (iii) linear non-␣-helix-forming, usually with a high content of certain amino acid residues (1, 2, 9). Most of the approximately 200 AMP spatial structures known at present (see the Antimicrobial Peptide Database v2.26 (10)) fall into one of the first two groups. Further classification is based on unique features in the sequences and/or structures of AMPs. For example, thionins, defensins, nonspecific lipid transfer proteins, and hevein-and knottin-like peptides have been identified in plants (11-13).To characterize the array of AMPs produced by a plant under certain physiological conditions, we have carried out a systematic analysis of these peptides from...

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Visualization of fibrinogen αC regions and their arrangement during fibrin network formation by high‐resolution AFM

Protopopova

Barinov

Zavyalova

et al. 2015

Journal of Thrombosis and Haemostasis

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To cite this article: Protopopova AD, Barinov NA, Zavyalova EG, Kopylov AM, Sergienko VI, Klinov DV. Visualization of fibrinogen aC regions and their arrangement during fibrin network formation by high-resolution AFM. J Thromb Haemost 2015; 13: 570-9.See also Rocco M, Weisel JW. Exposed: the elusive aC regions in fibrinogen, fibrin protofibrils and fibers. This issue, pp 567-9.Summary. Background: Fibrinogen has been intensively studied with transmission electron microscopy and x-ray diffraction. But until now, a complete 3D structure of the molecule has not yet been available because the two highly flexible aC regions could not be resolved in fibrinogen crystals. This study was aimed at determining whether the aC regions can be visualized by high-resolution atomic force microscopy. Methods: Atomic force microscopy with super high resolution was used to image single molecules of fibrinogen and fibrin associates. The key approach was to use a graphite surface modified with the monolayer of amphiphilic carbohydrate-glycine molecules and unique supersharp cantilevers with 1 nm tip diameter. Results: Fibrinogen aC regions were visualized along with the complete domain structure of the protein.In almost all molecules at pH 7.4 the D domain regions had one or two protrusions of average height 0.4 AE 0.1 nm and length 21 AE 6 nm. The complex, formed between thrombin and fibrinogen, was also visualized. Images of growing fibrin fibers with clearly visible aC regions have been obtained. Conclusions: Fibrin aC regions were visible in protofibrils and large fibers; aC regions intertwined near a branchpoint and looked like a zipper. These results support the idea that aC regions are involved in the thickening of fibrin fibers. In addition, new details were revealed about the behavior of individual fibrin molecules during formation of the fibrin network. Under the diluted condition, the positioning of the aC regions could suggest their involvement in long-range interactions between fibrin but not fibrinogen molecules.

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Polymorphism of G4 associates: from stacks to wires via interlocks

Varizhuk

Protopopova

Цветков

et al. 2018

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We examined the assembly of DNA G-quadruplexes (G4s) into higher-order structures using atomic force microscopy, optical and electrophoretic methods, NMR spectroscopy and molecular modeling. Our results suggest that parallel blunt-ended G4s with single-nucleotide or modified loops may form different types of multimers, ranging from stacks of intramolecular structures and/or interlocked dimers and trimers to wires. Decreasing the annealing rate and increasing salt or oligonucleotide concentrations shifted the equilibrium from intramolecular G4s to higher-order structures. Control antiparallel and hybrid G4s demonstrated no polymorphism or aggregation in our experiments. The modification that mimics abasic sites (1′,2′-dideoxyribose residues) in loops enhanced the oligomerization/multimerization of both the 2-tetrad and 3-tetrad G4 motifs. Our results shed light on the rules that govern G4 rearrangements. Gaining control over G4 folding enables the harnessing of the full potential of such structures for guided assembly of supramolecular DNA structures for nanotechnology.

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AFM visualization at a single-molecule level of denaturated states of proteins on graphite

Barinov

Прохоров

Dubrovin

et al. 2016

Colloids and Surfaces B: Biointerfaces

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Protein nanoparticles with ligand-binding and enzymatic activities

Морозова

Pavlova

Bagrov

et al. 2018

IJN

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PurposeTo develop a general method for NP fabrication from various proteins with maintenance of biological activity.MethodsA novel general approach for producing protein nanoparticles (NP) by nanoprecipitation of the protein solutions in 1,1,1,3,3,3-hexafluoroisopropanol is described. Protein NP sizes and shapes were analyzed by dynamic light scattering, scanning electron and atomic force microscopy (SEM and AFM). Chemical composition of the NP was confirmed using ultraviolet (UV) spectroscopy, energy-dispersive X-ray spectroscopy (EDX) and circular dichroism (CD). Biological properties of the NP were analyzed in ELISA, immunofluorescent analysis and lysozyme activity assay.ResultsWater-insoluble NP were constructed from globular (bovine serum albumin (BSA), lysozyme, immunoglobulins), fibrillar (fibrinogen) proteins and linear polylysines by means of nanoprecipitation of protein solutions in fluoroalcohols. AFM and SEM revealed NP sizes of 20–250 nm. The NP chemical structure was confirmed by UV spectroscopy, protease digestion and EDX spectroscopy. CD spectra revealed a stable secondary structure of proteins in NP. The UV spectra, microscopy and SDS-PAA gel electrophoresis (PAGE) proved the NP stability at +4°C for 7 months. Co-precipitation of proteins with fluorophores or nanoprecipitation of pre-labeled BSA resulted in fluorescent NP that retained antigenic structures as shown by their binding with specific antibodies. Moreover, NP from monoclonal antibodies could bind with the hepatitis B virus antigen S. Besides that, lysozyme NP could digest bacterial cellular walls.ConclusionThus, the water-insoluble, stable protein NP were produced by nanoprecipitation without cross-linking and retained ligand-binding and enzymatic activities.

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