Vladimir Rodionov

Publications:

Vorobjev,I.A., Rodionov, V.I., Maly, I.V., and Borisy, G.G. (1999). Contribution of Plus and Minus End Pathways to Microtubule Turnover. J. Cell Sci., 112(Pt 14):2277-2289.

Borisy, G.G. and Rodionov, V.I.(1999). Lessons from the Melanophore. in press.

Rodionov, V.I., Nadezhdina, E. and Borisy, G.G. (1999). Centrosomal Control of Microtubule Dynamics. PNAS, 96: 115-120.

Chang, S., Rodionov, V.I., Borisy, G.G. and Popov, S. V. (1998). Transport and Turnover of Microtubules in Frog Neurons Depend on the Pattern of Axonal Growth. J. Neurosci., 18(3):821-829

Rodionov, V.I., Hope, A.J., Svitkina, T.M., and Borisy, G.G. (1998). Functional Coordination of Microtubule and Actin Based Motility in Melanophores. Curr. Biol., 8(3): 165-168

Keating TJ, Peloquin JG, Rodionov VI, Momcilovic D, Borisy GG. (1997). Microtubule release from the centrosome. Proc Natl Acad Sci U S A 94(10), 5078-5083

Rodionov, V.I. and Borisy, G.G. (1997). Self Centering Activity of Cytoplasm. Nature 386:170-172.

Rodionov, V.I. and Borisy, G.G. (1997). Microtubule treadmilling in vivo. Science 275: 215-218.

Rodionov, V. I., Lim, S., Gelfand, V. I., and Borisy, G.G. (1994). Microtubule Dynamics in Fish Melanophores. J. Cell Biol. 126: 1455-1464

Rodionov VI, Gyoeva FK, Tanaka E, Bershadsky AD, Vasiliev JM, Gelfand VI. (1993). Microtubule-dependent control of cell shape and pseudopodial activity is inhibited by the antibody to kinesin motor domain. J Cell Biol 123(6), 1811-1820

Rodionov VI, Gelfand VI, Borisy GG. (1993). Kinesin-like molecules involved in spindle formation. J Cell Sci 106( Pt 4), 1179-1188

Rodionov VI, Gyoeva FK, Gelfand VI. (1991). Kinesin is responsible for centrifugal movement of pigment granules in melanophores. Proc Natl Acad Sci U S A 88(11), 4956-4960

Rodionov VI, Gyoeva FK, Kashina AS, Kuznetsov SA, Gelfand VI. (1990). Microtubule-associated proteins and microtubule-based translocators have different binding sites on tubulin molecule. J Biol Chem 265(10), 5702-5707

Bohm KJ, Vater W, Steinmetzer P, Kusnetsov SA, Rodionov VI, Gelfand VI, Unger E. (1990). Effect of MAP 1, MAP 2, and tau-proteins on structural parameters of tubulin assemblies. Acta Histochem Suppl 39, 357-364

Leonova EV, Draberova E, Draber P, Viklitskii V, Rodionov VI. (1988). Microinjections of antibodies against microtubule proteins: the effect on distribution and movement of melanosomes in melanophores. Dokl Akad Nauk SSSR 300(6), 1469-1472

Gyoeva FK, Leonova EV, Rodionov VI, Gelfand VI. (1987). Vimentin intermediate filaments in fish melanophores. J Cell Sci 88( Pt 5), 649-655

Rodionov VI, Vardanyan AG, Kamalov VF, Gelfand VI. (1987). The movement of melanosomes in melanophore fragments obtained by laser microbeam irradiation. Cell Biol Int Rep 11(8), 565-572

Vardanian AG, Gelfand VI, Kamalov VF, Rodionov VI. (1987). Movement of melanosomes in melanocytes fragmented by laser irradiation Dokl Akad Nauk SSSR 293(1), 215-219

Leonova EV, Sorkin AD, Teslenko LV, Rodionov VI, Nadezhdina ES. (1986). A cytoskeletal protein with a molecular weight of 100 kD is a component of the endosomes participating in receptor-mediated endocytosis. Tsitologiia 28(11), 1222-1226

Kuznetsov SA, Rodionov VI, Nadezhdina ES, Murphy DB, Gelfand VI. (1986). Identification of a 34-kD polypeptide as a light chain of microtubule-associated protein-1 (MAP-1) and its association with a MAP-1 peptide that binds to microtubules. J Cell Biol 102(3), 1060-1066

Kuznetsov SA, Nadezhdina ES, Rodionov VI, Murphy DB, Gelfand VI. (1986). Localization of the light chain (LC-1) of the microtubule-associated protein MAP-1 in the tubulin-binding portion of the molecule. Dokl Akad Nauk SSSR 286(1), 224-226

Rodionov VI, Nadezhdina ES, Leonova EV, Vaisberg EA, Kuznetsov SA, Gelfand VI. (1985). Identification of a 100 kD protein associated with microtubules, intermediate filaments and coated vesicles in cultured cells. Exp Cell Res 159(2), 377-387

Kuznetsov SA, Rodionov VI, Gelfand VI, Rosenblat VA. (1984). MAP2 competes with MAP1 for binding to microtubules. Biochem Biophys Res Commun 119(1), 173-178

Shanina NA, Kuznetsov SA, Rodionov VI, Gelfand VI, Rozenblat VA. (1983). Interaction of MAP2 protein of cytoplasmic microtubules with axoneme microtubules. Dokl Akad Nauk SSSR 270(5), 1249-1253

Kuznetsov SA, Rodionov VI, Gelfand VI, Rozenblat VA. (1983). Binding of MAP1 protein to microtubules: the formation of "arms" and competition with MAP2 protein. Dokl Akad Nauk SSSR 270(5), 1243-1246

Kuznetsov SA, Rodionov VI, Gelfand VI, Rosenblat VA. Microtubule-associated protein MAP1 promotes microtubule assembly in vitro. FEBS Lett 135(2), 241-244 (1981).

Kuznetsov SA, Rodionov VI, Gelfand VI, Rosenblat VA . (1981). Purification of high-Mr microtubule proteins MAP1 and MAP2. FEBS Lett 135(2), 237-240

Kuznetsov SA, Rodionov VI, Gelfand VI, Rozenblat VA. (1981). Microtubule-associated MAP1 protein: isolation and evidence of its polymerizing activity. Dokl Akad Nauk SSSR 261(3), 760-762

Kuznetsov SA, Rodionov VI, Bershadsky AD, Gelfand VI, Rosenblat VA. (1980). High molecular weight protein MAP 2 promoting microtubule assembly in vitro is associated with microtubules in cells. Cell Biol Int Rep 4(11), 1017-1024

Kuznetsov SA, Rodionov VI, Gelfand VI, Rosenblat VA. (1978). Purification of a thermostable high molecular weight factor promoting tubulin polymerization. FEBS Lett 95(2), 339-342

Kuznetsov SA, Gelfand VI, Rodionov VI, Rosenblat VA, Gulyaeva JG. (1978). Polymerization of purified tubulin by synthetic polycations. FEBS Lett 95(2), 343-346

Rodionov VI, Gelfand VI, Rozenblat VA. (1978). Microtubule assembly without polymerizing protein factors in the presence of glycerin. Dokl Akad Nauk SSSR 239(1), 231-233

Rodionov VI, Gelfand VI, Rozenblat VA. (1976). 32S Tubulin oligomer. The resistance to factors suppressing the microtubule formation. Biokhimiia 41(11), 2068-2074

Last updated: 7/13/2005 Copyright © Laboratory of Molecular Biology 2005