Direct observation of single kinesin molecules moving along microtubules

Vale, Ronald D.; Funatsu, Takashi; Pierce, Daniel W.; Romberg, Laura; Harada, Yoshie; Yanagida, Toshio

doi:10.1038/380451a0

Cited by 700 publications

(565 citation statements)

References 22 publications

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“…However, these monomeric kinesins do not exhibit processive movement when assayed as individual motors in a single molecule fluo-rescence motility assay (14) or a bead assay (15). A kinesin motor containing the complete motor and neck domains, on the other hand, forms a dimer and also exhibits processive movement (14,16). Collectively, these studies suggest that the dimeric structure of kinesin is not essential for force-generation per se, although it does appear to be required for processive movement.…”

mentioning

confidence: 73%

“…Bacterial expression of the first 340 amino acids of the Drosophila kinesin heavy chain (which contains the core NH 2 -terminal globular motor domain and the first ϳ10 amino acids of the neck) produces a monomeric protein that generates directed motility when many motors are interacting simultaneously with a single microtubule in gliding motility assays (7,13). However, these monomeric kinesins do not exhibit processive movement when assayed as individual motors in a single molecule fluo-rescence motility assay (14) or a bead assay (15). A kinesin motor containing the complete motor and neck domains, on the other hand, forms a dimer and also exhibits processive movement (14,16).…”

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confidence: 99%

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Demonstration of Coiled-Coil Interactions within the Kinesin Neck Region Using Synthetic Peptides

Tripet

Vale

Hodges

1997

Journal of Biological Chemistry

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Kinesin is a dimeric motor protein that can move for several micrometers along a microtubule without dissociating. The two kinesin motor domains are thought to move processively by operating in a hand-over-hand manner, although the mechanism of such cooperativity is unknown. Recently, a ϳ50-amino acid region adjacent to the globular motor domain (termed the neck) has been shown to be sufficient for conferring dimerization and processive movement. Based upon its amino acid sequence, the neck is proposed to dimerize through a coiled-coil interaction. To determine the accuracy of this prediction and to investigate the possible function of the neck region in motor activity, we have prepared a series of synthetic peptides corresponding to different regions of the human kinesin neck (residues 316 -383) and analyzed each peptide for its respective secondary structure content and stability. Results of our study show that a peptide containing residues 330 -369 displays all of the characteristics of a stable, two-stranded ␣-helical coiled-coil. On the other hand, the NH 2 -terminal segment of the neck (residues ϳ316 -330) has the capacity to adopt a ␤-sheet secondary structure. The COOH-terminal residues of the neck region (residues 370 -383) are not ␣-helical, nor do they contribute significantly to the overall stability of the coiled-coil, suggesting that these residues mark the beginning of a hinge located between the neck and the extended ␣-helical coiled coil stalk domain. Interestingly, the two central heptads of the coiled-coil segment in the neck contain conserved, "non-ideal" residues located within the hydrophobic core, which we show destabilize the coiledcoil interaction. These residues may enable a portion of the coiled-coil to unwind during the mechanochemical cycle, and we present a model in which such a phenomenon plays an important role in kinesin motility.Understanding how motor proteins generate force and movement from the chemical hydrolysis of ATP remains one of the most intriguing problems in biophysics. At present, there are three separate families of motor proteins found within eukaryotic cells: myosins, which move along actin filaments, and kinesins and dyneins, which move along microtubules (1). The motor domains that typify each of these superfamilies exhibit little or no amino acid sequence similarity, and hence it was believed that they had evolved separately and were structurally unrelated. However, the recently determined crystal structure of kinesin revealed an unexpected structural similarity to the core of the myosin motor domain, particularly in the nucleotide binding pocket (2, 3). Hence, myosin and kinesin may share some similarities in how they generate unidirectional movement and force, although the precise mechanistic details remain to be elucidated for both types of motors.Kinesin has proven to be an excellent model system for investigating the mechanism of motility, in part due to the small size of its motor domain (Ͼ2-fold smaller than myosin's). Kinesin purified from tissue sourc...

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confidence: 73%

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confidence: 99%

Demonstration of Coiled-Coil Interactions within the Kinesin Neck Region Using Synthetic Peptides

Tripet

Vale

Hodges

1997

Journal of Biological Chemistry

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“…The kinetic constants for fast axonal transport are expected to be at the high end of this range. Indeed, the average detachment rate from MTs for kinesin-1 is estimated to be 1 s −1 (Schnitzer et al [26], Vale et al [19]) while the average attachment rate for cytoplasmic dynein is estimated to be 1.5 s −1 (Carter and Cross [18], Vale et al [19]). However, the transition rate is expected to be smaller than these estimates because the transition involves detachment from MTs with plus-end-out orientation, switching of kinesin to dynein molecular motors, and then attachment to MTs with minus-end-out orientation.…”

Section: Resultsmentioning

confidence: 99%

“…It is assumed that radiolabeled organelles enter the primary neurite as a pulse; initially the concentration of radiolabeled organelles in the primary neurite is zero, then (at t * 1 = 0) the concentration of kinesin-driven organelles at x * 1 = 0 is suddenly increased to n * in and remains at this level until t * 1 = t * c and then it is suddenly dropped to zero. According to Carter and Cross [18] and Vale et al [19], kinesin-1 (conventional kinesin) walks to the MT plus-ends with an average velocity of 1 μm/s while according to King and Schroer [20] and Toba et al [21], cytoplasmic dynein walks to the MT minus-ends with approximately the same average velocity of 1 μm/s; therefore, for the ease of comparison between transport in axons and dendrites it is assumed that v * kin = v * dyn = v * .…”

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confidence: 99%

Modeling transport of a pulse of radiolabeled organelles in a Drosophila unipolar motor neuron

Кузнецов

2012

J Biol Phys

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Based on published experimental evidence, this paper develops a model for the transport of a pulse of radiolabeled organelles in a unipolar Drosophila motor neuron. In particular, since published data indicate that no microtubules (MTs) travel from the primary neurite into the dendrite, it is investigated how organelles are transported into the dendrite. Analytical solutions describing concentrations of kinesin-and dynein-driven organelles in the primary neurite, axon, and dendrite are obtained. The effects of increasing the width of the pulse and increasing the rate of organelle transition rate from the kinesin-driven to the dynein-driven state are investigated.

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“…The analysis is simplest when there is negligible ADP or P i in solution, as in the force-clamp experiment of Visscher et al (1999), in which case the two backward rate constants, k 32 and k 43 ( f ), may be taken to be zero. We may also simplify matters by neglecting dissociation of the kinesin-tubulin complex, since it has been shown experimentally that kinesin dimers can perform a hundred or more steps before they dissociate from a microtubule (Howard et al 1989;Block et al 1990;Svoboda et al 1993;Vale et al 1996). In that case, given that the ATP hydrolysis in figure 1c is tightly coupled to the kinesin stepping (Visscher et al 1999;Thomas et al 2001), the average velocity v = u 0 R. Since the Law of Mass Action requires that k 12 = K 12 [ATP], where K 12 is the molar rate constant for ATP-binding, we then find that the kinesin stepping velocity v obeys the Michaelis-Menten equation…”

Section: The Michaelis-menten Relation For Kinesinmentioning

confidence: 99%

Kinesin: a molecular motor with a spring in its step

Thomas

Imafuku

Kamiya

et al. 2002

Proc. R. Soc. Lond. B

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A key step in the processive motion of two-headed kinesin along a microtubule is the 'docking' of the neck linker that joins each kinesin head to the motor's dimerized coiled-coil neck. This process is similar to the folding of a protein β-hairpin, which starts in a highly mobile unfolded state that has significant entropic elasticity and finishes in a more rigid folded state. We therefore suggest that neck-linker docking is mechanically equivalent to the thermally activated shortening of a spring that has been stretched by an applied load. This critical tension-dependent step utilizes Brownian motion and it immediately follows the binding of ATP, the hydrolysis of which provides the free energy that drives the kinesin cycle. A simple three-state model incorporating neck-linker docking can account quantitatively for both the kinesin force-velocity relation and the unusual tension-dependence of its Michaelis constant. However, we find that the observed randomness of the kinesin motor requires a more detailed four-state model. Monte Carlo simulations of single-molecule stepping with this model illustrate the possibility of sub-8 nm steps, the size of which is predicted to vary linearly with the applied load.

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Direct observation of single kinesin molecules moving along microtubules

Cited by 700 publications

References 22 publications

Demonstration of Coiled-Coil Interactions within the Kinesin Neck Region Using Synthetic Peptides

Demonstration of Coiled-Coil Interactions within the Kinesin Neck Region Using Synthetic Peptides

Modeling transport of a pulse of radiolabeled organelles in a Drosophila unipolar motor neuron

Kinesin: a molecular motor with a spring in its step

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