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Query: EC:3.6.4.4 (
kinesin
)
5,033
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
This paper addresses the question of whether microtubule-directed transport of vesicular organelles depends on the presence of a pool of cytosolic factors, including soluble motor proteins and accessory factors. Earlier studies with squid axon organelles (Schroer et al., 1988) suggested that the presence of cytosol induces a > 20-fold increase in the number of organelles moving per unit time on microtubules in vitro. These earlier studies, however, did not consider that cytosol might nonspecifically increase the numbers of moving organelles, i.e., by blocking adsorption of organelles to the coverglass. Here we report that treatment of the coverglass with
casein
, in the absence of cytosol, blocks adsorption of organelles to the coverglass and results in vigorous movement of vesicular organelles in the complete absence of soluble proteins. This technical improvement makes it possible, for the first time, to perform quantitative studies of organelle movement in the absence of cytosol. These new studies show that organelle movement activity (numbers of moving organelles/min/micron microtubule) of unextracted organelles is not increased by cytosol. Unextracted organelles move in single directions, approximately two thirds toward the plus-end and one third toward the minus-end of microtubules. Extraction of organelles with 600 mM KI completely inhibits minus-end, but not plus-end directed organelle movement. Upon addition of cytosol, minus-end directed movement of KI organelles is restored, while plus--end directed movement is unaffected. Biochemical studies indicate that KI-extracted organelles attach to microtubules in the presence of AMP-PNP and copurify with tightly bound
kinesin
. The bound
kinesin
is not extracted from organelles by 1 M KI, 1 M NaCl or carbonate (pH 11.3). These results suggest that
kinesin
is irreversibly bound to organelles that move to the plus-end of microtubules and that the presence of soluble
kinesin
and accessory factors is not required for movement of plus-end organelles in squid axons.
...
PMID:Kinesin is bound with high affinity to squid axon organelles that move to the plus-end of microtubules. 140 May 82
We have measured the ATPase activity of squid optic lobe
kinesin
bound to polystyrene beads in the presence of microtubules. We find that there is a substantial increase (> 10-fold) in the microtubule-activated ATPase activity for bead-bound
kinesin
over free
kinesin
. We tentatively attribute such cargo-activated ATPase activity to the presence of a self-inhibited form of
kinesin
in solution, which becomes activated when bound to a bead in the presence of alpha-
casein
. Further experiments are underway to unravel this phenomenon and, in addition, to associate the traveling distance of beads with the observed ATPase rate to determine the average number of ATP consumed per
kinesin
-bead per micron of travel along microtubule.
...
PMID:Cargo-activated ATPase activity of kinesin. 778 91
Conventional
kinesin
is a motor protein that moves stepwise along microtubules carrying membrane-bound organelles toward the periphery of cells. The steps are of amplitude 8.1 nm, the distance between adjacent tubulin binding sites, and are powered by the hydrolysis of ATP. We have asked: how many steps does
kinesin
take for each molecule of ATP that it hydrolyzes? To answer this question, the motility and ATP hydrolysis of recombinant, heterotetrameric and homodimeric conventional Drosophila kinesins adsorbed to 200-nm-diameter
casein
-coated silica beads were assayed under identical, single-molecule conditions. Division of the speed by the maximum microtubule-activated ATPase rate gave a stoichiometry of 1. 08 +/- 0.09 steps for each ATP hydrolyzed at 1 mM ATP. Therefore, under low loads in which the drag force << 1 pN, coupling between the chemical and mechanical cycles of
kinesin
is tight, consistent with conventional power stroke models. Our results rule out models that require two or more ATPs/step, such as some thermal ratchet models, or that propose multiple steps powered by single ATPs.
...
PMID:Kinesin takes one 8-nm step for each ATP that it hydrolyzes. 992 Sep 16
Microtubules and associated motor proteins such as
kinesin
are envisioned for applications such as bioseparation and molecular sorting to powering hybrid synthetic mechanical devices. One of the challenges in realizing such systems is retaining motor functionality on device surfaces. Kinesin motors adsorbed onto glass surfaces lose their functionality or ability to interact with microtubules if not adsorbed with other supporting proteins.
Casein
, a milk protein, is commonly used in microtubule motility assays to preserve
kinesin
functionality. However, the mechanism responsible for this preservation of motor function is unknown. To study
casein
and
kinesin
interaction, a series of microtubule motility assays were performed where whole milk
casein
, or its alphas1 and alphas2, beta or kappa subunits, were introduced or omitted at various steps of the motility assay. In addition, a series of epifluorescence and total internal reflection microscopy (TIRF) experiments were conducted where fluorescently labeled
casein
was introduced at various steps of the motility assay to assess
casein
-
casein
and
casein
-glass binding dynamics. From these experiments it is concluded that
casein
forms a bi-layer which supports the operation of
kinesin
. The first tightly bound layer of
casein
mainly performs the function of anchoring the
kinesin
while the second more loosely bound layer of
casein
positions the head domain of the
kinesin
to more optimally interact with microtubules. Studies on individual
casein
subunits indicate that beta
casein
was most effective in supporting
kinesin
functionality while kappa casein was found to be least effective.
...
PMID:The role of casein in supporting the operation of surface bound kinesin. 1893 63
Conventional
kinesin
is routinely adsorbed to hydrophilic surfaces such as SiO(2). Pretreatment of surfaces with
casein
has become the standard protocol for achieving optimal
kinesin
activity, but the mechanism by which
casein
enhances
kinesin
surface adsorption and function is poorly understood. We used quartz crystal microbalance measurements and microtubule gliding assays to uncover the role that
casein
plays in enhancing the activity of surface-adsorbed
kinesin
. On SiO(2) surfaces,
casein
adsorbs as both a tightly bound monolayer and a reversibly bound second layer that has a dissociation constant of 500 nM and can be desorbed by washing with
casein
-free buffer. Experiments using truncated kinesins demonstrate that in the presence of soluble
casein
,
kinesin
tails bind well to the surface, whereas
kinesin
head binding is blocked. Removing soluble
casein
reverses these binding profiles. Surprisingly, reversibly bound
casein
plays only a moderate role during
kinesin
adsorption, but it significantly enhances
kinesin
activity when surface-adsorbed motors are interacting with microtubules. These results point to a model in which a dynamic
casein
bilayer prevents reversible association of the heads with the surface and enhances association of the
kinesin
tail with the surface. Understanding protein-surface interactions in this model system should provide a framework for engineering surfaces for functional adsorption of other motor proteins and surface-active enzymes.
...
PMID:Surface-bound casein modulates the adsorption and activity of kinesin on SiO2 surfaces. 1938 74
Cells have evolved sophisticated molecular machinery, such as
kinesin
motor proteins and microtubule filaments, to support active intracellular transport of cargo. While kinesins tail domain binds to a variety of cargoes, kinesins head domains utilize the chemical energy stored in ATP molecules to step along the microtubule lattice. The long, stiff microtubules serve as tracks for long-distance intracellular transport. These motors and filaments can also be employed in microfabricated synthetic environments as components of molecular shuttles. In a frequently used design,
kinesin
motors are anchored to the track surface through their tails, and functionalized microtubules serve as cargo carrying elements, which are propelled by these motors. These shuttles can be loaded with cargo by utilizing the strong and selective binding between biotin and streptavidin. The key components (biotinylated tubulin, streptavidin, and biotinylated cargo) are commercially available. Building on the classic inverted motility assay, the construction of molecular shuttles is detailed here. Kinesin motor proteins are adsorbed to a surface precoated with
casein
; microtubules are polymerized from biotinylated tubulin, adhered to the
kinesin
and subsequently coated with rhodamine-labeled streptavidin. The ATP concentration is maintained at subsaturating concentration to achieve a microtubule gliding velocity optimal for loading cargo. Finally, biotinylated fluorescein-labeled nanospheres are added as cargo. Nanospheres attach to microtubules as a result of collisions between gliding microtubules and nanospheres adhering to the surface. The protocol can be readily modified to load a variety of cargoes such as biotinylated DNA, quantum dots or a wide variety of antigens via biotinylated antibodies.
...
PMID:Cargo loading onto kinesin powered molecular shuttles. 2108 3
