G. A. Badun scite author profile

Ethylene oxide and propylene oxide block copolymers (pluronics) are widely known as agents that promote drug penetration across biological barriers. We have studied the interaction of normal and malignant blood cells with pluronics L61 and P85 that have different hydrophobicity. SP2/0 myeloma cells accumulated pluronics while normal cells adsorb most of the polymer on the surface. Interaction of pluronics with cells resulted in drastic changes of membrane microviscosity. Tumor cell membrane microviscosity decreased after pluronics adsorption, in contrast to normal cells, whose membrane microviscosity was enhanced. We suppose that sensitivity of tumor cell membrane microviscosity to the pluronics action correlates with its permeability for molecular substances.z 1999 Federation of European Biochemical Societies.

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Effect of tritium on luminous marine bacteria and enzyme reactions

Selivanova

Mogil'naya

Badun

et al. 2013

Journal of Environmental Radioactivity

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In Situ Spatial Organization of Potato Virus A Coat Protein Subunits as Assessed by Tritium Bombardment

Baratova

Ефимов

Добров

et al. 2001

J Virol

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Potato virus A (PVA) particles were bombarded with thermally activated tritium atoms, and the intramolecular distribution of the label in the amino acids of the coat protein was determined to assess their in situ steric accessibility. This method revealed that the N-terminal 15 amino acids of the PVA coat protein and a region comprising amino acids 27 to 50 are the most accessible at the particle surface to labeling with tritium atoms. A model of the spatial arrangement of the PVA coat protein polypeptide chain within the virus particle was derived from the experimental data obtained by tritium bombardment combined with predictions of secondary-structure elements and the principles of packing ␣-helices and ␤-structures in proteins. The model predicts three regions of tertiary structure: (i) the surface-exposed N-terminal region, comprising an unstructured N terminus of 8 amino acids and two ␤-strands, (ii) a C-terminal region including two ␣-helices, as well as three ␤-strands that form a two-layer structure called an abCd unit, and (iii) a central region comprising a bundle of four ␣-helices in a fold similar to that found in tobacco mosaic virus coat protein. This is the first model of the three-dimensional structure of a potyvirus coat protein.

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Pluronic L61 Accelerates Flip–Flop and Transbilayer Doxorubicin Permeation

Krylova

Melik‐Nubarov

Badun

et al. 2003

Chemistry A European J

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It has recently been found that Pluronics (block copolymers of ethylene oxide, EO, and propylene oxide, PO) favor the permeability and accumulation of anthracycline antibiotics, for example doxorubicin (Dox), in tumor cells. In an effort to understand these results, the interaction of EO(2)/PO(32)/EO(2) (Pluronic L61) with unilamellar egg yolk vesicles (80-100 nm in diameter) was examined. A partition coefficient K(p)=[Pl](membrane)/[Pl](water)=45 was determined. This corresponds to adsorption of about 20 polymer molecules to the surface of each vesicle in a 20 microM polymer solution. Despite this rather weak adsorption, Pluronic has a substantial effect upon the transmembrane permeation rate of Dox and upon the phospholipid flip-flop rate within the bilayers. Thus, the Dox permeation rate increases threefold and the flip-flop rate increases sixfold in 20 microM Pluronic. The two rates increase linearly with the amount of adsorbed polymer. The obvious ability of Pluronics to increase the mobility of membrane components may have important biomedical consequences.

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Tritium planigraphy study of structural alterations in the coat protein of Potato virus X induced by binding of its triple gene block 1 protein to virions

et al. 2009

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Alterations in Potato virus X (PVX) coat protein structure after binding of the protein, encoded by the first gene of PVX triple gene block (triple gene block 1 protein, TGBp1), to the virions were studied using tritium planigraphy. Previously, it has been shown that TGBp1 molecules interact with the PVX particle end, containing the 5′‐terminus of PVX RNA, and that this interaction results in a strong decrease in virion stability and its transformation to a translationally active state. In this work, it has been shown that the interaction of TGBp1 with PVX virions leads to an increase of ∼ 50% in tritium label incorporation into the 176–198 segment of the 236‐residue‐long PVX coat protein subunit, with some decrease in label incorporation into the N‐terminal coat protein region. According to the new ‘sandwich’ variant of our recently proposed model of the three‐dimensional structure of the intravirus PVX coat protein, the 176–198 segment is assigned to the β‐sheet region located at the subunit surface, presumably participating in coat protein interactions with the intravirus RNA and/or in protein–protein interactions, whereas the N‐terminal coat protein region corresponds to the other part of the same β‐sheet. For the remaining segments of the PVX coat protein subunit, no significant difference between tritium incorporation into untreated and TGBp1‐treated PVX was observed. A detailed description of the ‘sandwich’ version of the intravirus PVX coat protein model is presented.

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G. A. Badun

Interaction of tumor and normal blood cells with ethylene oxide and propylene oxide block copolymers

Effect of tritium on luminous marine bacteria and enzyme reactions

In Situ Spatial Organization of Potato Virus A Coat Protein Subunits as Assessed by Tritium Bombardment

Pluronic L61 Accelerates Flip–Flop and Transbilayer Doxorubicin Permeation

Tritium planigraphy study of structural alterations in the coat protein of Potato virus X induced by binding of its triple gene block 1 protein to virions

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