Your search keyword '"Susan P. Gilbert"' showing total 3 results

1. Kar3Vik1, a member of the Kinesin-14 superfamily, shows a novel kinesin microtubule binding pattern

Author

Susan P. Gilbert, Chun Ju Chen, Katherine C. Rank, Ken Porche, Andreas Hoenger, Julia Cope, and Ivan Rayment

Subjects

Models, Molecular, Saccharomyces cerevisiae Proteins, Kinesins, Saccharomyces cerevisiae, Microtubules, Article, Motor protein, Fungal Proteins, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Binding site, Kinesin 8, Protein Structure, Quaternary, Research Articles, 030304 developmental biology, Microtubule nucleation, Coiled coil, 0303 health sciences, biology, Cryoelectron Microscopy, Cell Biology, Cell biology, Protein Structure, Tertiary, Adenosine Diphosphate, Tubulin, biology.protein, Kinesin, Microtubule-Associated Proteins, 030217 neurology & neurosurgery, Protein Binding

Abstract

The two head domains of the budding yeast Kinesin-14 Kar3Vik1 bind adjacent protofilaments at the start of the motility cycle, followed by release of Vik1 from one protofilament to allow the motor’s powerstroke., Kinesin-14 motors generate microtubule minus-end–directed force used in mitosis and meiosis. These motors are dimeric and operate with a nonprocessive powerstroke mechanism, but the role of the second head in motility has been unclear. In Saccharomyces cerevisiae, the Kinesin-14 Kar3 forms a heterodimer with either Vik1 or Cik1. Vik1 contains a motor homology domain that retains microtubule binding properties but lacks a nucleotide binding site. In this case, both heads are implicated in motility. Here, we show through structural determination of a C-terminal heterodimeric Kar3Vik1, electron microscopy, equilibrium binding, and motility that at the start of the cycle, Kar3Vik1 binds to or occludes two αβ-tubulin subunits on adjacent protofilaments. The cycle begins as Vik1 collides with the microtubule followed by Kar3 microtubule association and ADP release, thereby destabilizing the Vik1–microtubule interaction and positioning the motor for the start of the powerstroke. The results indicate that head–head communication is mediated through the adjoining coiled coil.

Published

2012

2. Bidirectional transport of fluorescently labeled vesicles introduced into extruded axoplasm of squid Loligo pealei

Author

Roger D. Sloboda and Susan P. Gilbert

Subjects

Nerve Tissue Proteins, Axonal Transport, Fluorescence microscope, Animals, Fluorescent Dyes, Neurons, biology, Rhodamines, Vesicle, Cell Membrane, Giant axon, Decapodiformes, Cell Biology, Articles, biology.organism_classification, Photobleaching, Axons, Vesicular transport protein, Microscopy, Electron, Biochemistry, Axoplasm, nervous system, Microscopy, Fluorescence, Biophysics, Axoplasmic transport, Electrophoresis, Polyacrylamide Gel, Oligopeptides

Abstract

A reconstituted model was devised to study the mechanisms of fast axonal transport in the squid Loligo pealei. Axonal vesicles were isolated from axoplasm of the giant axon and labeled with rhodamine-conjugated octadecanol, a membrane-specific fluorescent probe. The labeled vesicles were then injected into a fresh preparation of extruded axoplasm in which endogenous vesicle transport was occurring normally. The movement of the fluorescent, exogenous vesicles was observed by epifluorescence microscopy for as long as 5 min without significant photobleaching, and the transport of endogenous, nonfluorescent vesicles was monitored by video-enhanced differential interference-contrast microscopy. The transport of fluorescent, exogenous vesicles was shown to be bidirectional and ATP-dependent and occurred at a mean rate of 6.98 +/- 4.11 micron/s (mean +/- standard deviation, n = 41). In comparison, the mean rate of transport of nonfluorescent, endogenous vesicles in control axoplasm treated with vesicle buffer alone was 4.76 +/- 1.60 micron/s (n = 64). These rates are slightly higher than the mean rate of endogenous vesicle movement in extruded axoplasm (3.56 +/- 1.05 micron/s, n = 40) not subject to vesicles or vesicle buffer. Not all vesicles and organelles, exogenous or endogenous, were observed to move. In experiments in which proteins of the surface of the fluorescent vesicles were digested with trypsin before injection, no movement of the fluorescent vesicles was observed, although the transport of endogenous vesicles and organelles appeared to proceed normally. The results summarized above indicate that isolated vesicles, incorporated into axoplasm, move with the characteristics of fast axonal transport. Because the vesicles are fluorescent, they can be readily distinguished from nonfluorescent, endogenous vesicles. Moreover, this system permits vesicle characteristics to be experimentally manipulated, and therefore may prove valuable for the elucidation of the mechanisms of fast axonal transport.

Published

1984

3. Identification of a MAP 2-like ATP-binding protein associated with axoplasmic vesicles that translocate on isolated microtubules

Author

Susan P. Gilbert and Roger D. Sloboda

Subjects

Microtubule-associated protein, Vesicle, Movement, Dynein, Optic Lobe, Nonmammalian, Decapodiformes, Kinesins, Affinity Labels, Nerve Tissue Proteins, Cell Biology, Articles, Biology, Microtubules, Adenosine Triphosphate, Axoplasm, Biochemistry, Dynein ATPase, Microtubule, Sea Urchins, Myosin, Biophysics, Axoplasmic transport, Animals, Immunoelectrophoresis, Microtubule-Associated Proteins

Abstract

Axoplasmic vesicles were purified and observed to translocate on isolated microtubules in an ATP-dependent, trypsin-sensitive manner, implying that ATP-binding polypeptides essential for force generation were present on the vesicle surface. To identify these proteins [alpha 32P]8-azidoadenosine 5'-triphosphate ([alpha 32P]8-N3ATP), a photoaffinity analogue of ATP, was used. The results presented here identify and characterize a vesicle-associated polypeptide having a relative molecular mass of 292 kD that bound [alpha 32P]8-N3ATP. The incorporation of label is ultraviolet light-dependent and ATP-sensitive. Moreover, the 292-kD polypeptide could be isolated in association with vesicles or microtubules, depending on the conditions used, and the data indicate that the 292-kD polypeptide is similar to mammalian brain microtubule-associated protein 2 (MAP 2) for the following reasons: The 292-kD polypeptide isolated from either squid axoplasm or optic lobe cross-reacts with antiserum to porcine brain MAP 2. Furthermore, it purifies with taxol-stabilized microtubules and is released with salt. Based on these characteristics, the 292-kD polypeptide is distinct from the known force-generating molecules myosin and flagellar dynein, as well as the 110-130-kD kinesin-like polypeptides that have recently been described (Brady, S. T., 1985, Nature (Lond.), 317:73-75; Vale, R. D., T. S. Reese, and M. P. Sheetz, 1985b, Cell, 42:39-50; Scholey, J. M., M. E. Porter, P. M. Grissom, and J. R. McIntosh, 1985, Nature (Lond.), 318:483-486). Because the 292-kD polypeptide binds ATP and is associated with vesicles that translocate on purified MAP-free microtubules in an ATP-dependent fashion, it is therefore believed to be involved in vesicle-microtubule interactions that promote organelle motility.

Published

1986