Vol 73, No 1 (2018)

The cytoskeleton is formed by a network of protein filaments, including microtubules, actin filaments and intermediate filaments. Filaments permeate the entire cytoplasm; they are involved in maintaining the cell shape, they organize and anchor the organelles, they control the transport of various molecules, cell division and provide signal transduction. To implement these diverse and complex functions, the components of the cytoskeleton must be very dynamic and mobile, be able to rebuilt quickly and interact with each other. This is due to the presence of a large number of actin-binding proteins—nucleators, activators, inactivators of polymerization and depolymerization of actin filaments. This review describes the regulation of actin dynamics by the Arp2/3 complex. In the cell, this complex is in an inactive state. Its activation occurs after it’s interaction with activators. Activators change the conformation and spatial arrangement of the domains of the Arp2/3 complex, providing its interaction with the monomeric and polymeric actin. Activators of the Arp2/3 complex have been known for a long time and include such proteins as WASp and WAVE. All activators possess a specific VCA domain, which is responsible for their binding to the Arp2/3 complex. The structure of the complex with bound activators has been studied using various physical-chemical methods. The inactivators of the complex only recently attracted specific attention of the investigators. At present, at least five different proteins are known to inactivate the Arp2/3 complex by binding to its various subunits. Examples of inactivators are coronin, Gmf and arpin. The structure of the Arp2/3 complex with inactivators was recently published and showed that despite their binding to different subunits of the complex, all inactivators transform the Arp2/3 complex into an “open” state, moving the actin-like Arp subunits apart from each other. Studies of the spatial organization of actin-binding proteins are necessary for understanding the patterns of interaction between them while providing the vital activity of the cell. These data can later be used in the search for new ligands to prevent metastasis of tumor cells.

Exogenous ribonucleases of Bacilli can selectively induce apoptosis of malignant cells. The ability of Bacillus pumilus ribonuclease, binase, to induce processes leading to a dynamic disruption of the integrity of A549 human pulmonary adenocarcinoma cell membranes was analyzed. The influence of different enzyme concentrations on the state of the cytoplasmic membrane of cells and mitochondrial membranes was characterized. Using the methods of flow cytofluorometry and fluorescence microscopy, it has been established that binase leads to disruption in normal functioning of both types of membranes, with mitochondrial membranes affected first. The study made it possible to identify and visualize the effects of binase on the membrane structures of target cells and to confirm that bacterial RNase induces apoptosis of target cells mainly through the “internal” (mitochondrial) pathway.

Nontranscribed spacers (NTS) of 5S rDNA are often polymorphic in closely related species and even in the same genome. The polymorphism of 5S rDNA NTS was shown between genomes St, J, and V of Triticeae species Thinopyrum bessarabicum, Pseudoroegneria spicata, and Dasypyrum villosum, respectively. A molecular genetic marker was designed based on the 5S rDNA NTS polymorphism that allows identification of the St, J, and V genomes. We designed a pair of primers that correspond to the conserved regions of 5S rDNA NTS between the genomes studied. The PCR amplicon length is 158 bp, 171 bp, and 172 bp for V, St, and J genomes, respectively. The fragment of the St genome is characterized by the SmiM I restriction site that enables its differentiation from the J genome fragment that lacks this site. The developed marker showed its efficiency for verification of germplasm accessions and the study of allopolyploids.

Photocurable biocompatible hydrogels were fabricated from methacrylated gelatin and silk proteins (a recombinant analogue of spidroin from Nephila clavipes spider web and fibroin from the cocoons of the silkworm Bombyx mori). These polymers are widely applicable in tissue engineering due to their biocompatibility and biodegradability. Hydrogels were fabricated using two different methods that allowed to obtain either the macroscopic scaffolds or microstructures with a defined shape. Three-dimensional hydrogel samples were prepared via monomers solution photopolymerization for 10 min. As a result, the disk-shaped samples of hydrogels approximately 13 mm in diameter were fabricated. Their porous structure was confirmed by scanning electron microscopy. Microstructures were formed on coverslips using an Eclipse Ti-E microscope equipped with an A1 confocal module (Nikon, Japan) and 405 nm laser. This approach allows to control the topographic features of the obtained substrates, and it is viable for creating the micropattern surfaces to reveal for studying the interaction of cells with a substrate.

The study of the cell wall structure was performed for ten species of Euastrum: E. ansatum (Ehrenb.) Ralfs, E. bidentatum Näg., E. binale (Turp.) Ehrenb. ex Ralfs, E. dubium Näg., E. elegans (Bréb.) Kütz. ex Ralfs, E. germanicum (Schmidle) W. Krieger, E. oblongum (Grev.) Ralfs ex Ralfs, E. pectinatum Bréb. ex Bréb. in Ralfs, E. validum West et G.S.West, E. verrucosum (Ehrenb.) ex Ralfs. The investigation of the cell wall ultrastructure has established for the first time that the pore canal in 6 of 10 species always has a coiled form to some degree. Three species (E. germanicum, E. pectinatum, and E. verrucosum) have both coiled and straight canals, and E. ansatum has only straight ones. A new type of pores (P7), typical only for representatives of the genus Euastrum, was also noted. In addition, a simple and effective method of preparing desmidium algal cells for investigation with transmission electron microscope has been developed.

The purpose of this work was to investigate the sorbents on the basis of polyethylenimine (PEI) intended for collecting biomass of microalgae (MA). For this purpose, a series of porous and insoluble polymeric materials were synthesized by cross-linking of PEI with epichlorohydrine. The analysis of kinetics and efficiency of immobilization assessed for the model culture Chlorella vulgaris, revealed that already within 3 h of incubation, 39–75% of MA cells attached to the surface of tested sorbents. It was shown that on the initial stage of immobilization the sorption activity of polymeric materials depended on the “PEI:crosslinker” ratio. One of the tested sorbents was additionally quartenized by alkylation with dimethyl sulphate resulting in sharp increase of its sorption activity. The estimation of the MA desorption from polymeric surface showed that most Ch. vulgaris cells were practically irreversibly immobilized on all tested sorbents based on the PEI cross-linked with epichlorohydrine.

Diadenosine tetraphosphate (AP4A) belongs to a wide group of naturally derived endogenous purine compounds that have recently been considered as new neurotransmitters in the autonomic nervous system. It has been shown that AP4A induces inhibitory effects and modulates adrenergic control in the heart of adult mammals. Nevertheless, the physiological significance of AP4A in early postnatal development, when sympathetic innervation remains yet immature, has not been investigated. The aim of the present study was to elucidate the effects of AP4A on the heart bioelectrical activity in early postnatal ontogenesis. Action potentials (AP) were recorded using the standard microelectrode technique in multicellular isolated right atrial (RA), left atrial (LA), and ventricle (RV) preparations from male Wistar rats at postnatal days 1, 14, and 21 and from 60-day animals that were considered as adults. The application of AP4A caused significant reduction of AP duration in atrial (RA and LA) preparations from rats of all ages. Also, AP4A caused significant AP shortening in RV preparations from rats of various ages; however, the effect was more pronounced in 21-day-old and adult rats. AP4A failed to alter automaticity of RA preparations from the rats at postnatal days 1, 14, and 21 and weakly decreased spontaneous rhythm in RA preparations from the adult rats. The effect of AP4A was partially abolished by P2-receptor blocker PPADS in LA preparations from both 21-dayold and adult rats, while it failed to suppress AP4A-caused AP shortening in preparations from 1- and 14-dayold animals. Thus, extracellular AP4A causes shortening of AP both in the atrial and ventricular myocardium in the rats of early postnatal ontogenesis and in adults. The effect of AP4A depends on age only for ventricular myocardium where it may be attributed with growing contribution of diadenosine polyphosphates to the control of myocardium inotropy.