Maryanne F. Stock scite author profile

Kinesin undergoes a global folding conformational change from an extended active conformation at high ionic concentrations to a compact inhibited conformation at physiological ionic concentrations. Here we show that much of the observed ATPase activity of folded kinesin is due to contamination with proteolysis fragments that can still fold, but retain an activated ATPase function. In contrast, kinesin that contains an intact IAK-homology region exhibits pronounced inhibition of its ATPase activity (140-fold in 50 mM KCl) and weak net affinity for microtubules in the presence of ATP, resulting from selective inhibition of the release of ADP upon initial interaction with a microtubule. Subsequent processive cycling is only partially inhibited. Fusion proteins containing residues 883-937 of the kinesin alpha-chain bind tightly to microtubules; exposure of this microtubule-binding site in proteolysed species is probably responsible for their activated ATPase activities at low microtubule concentrations.

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Formation of the Compact Confomer of Kinesin Requires a COOH-terminal Heavy Chain Domain and Inhibits Microtubule-stimulated ATPase Activity

Stock

Guerrero²,

Cobb

et al. 1999

Journal of Biological Chemistry

146

145

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Full-length Drosophila kinesin heavy chain from position 1 to 975 was expressed in Escherichia coil (DKH975) and is a dimer. The sedimentation coefficient of DKH975 shifts from 5.4 S at 1 M NaCl to ϳ6.9 S at <0.2 M NaCl. This transition of DKH975 between extended and compact conformations is essentially identical to that for the heavy chain dimer of bovine kinesin (Hackney, D. D., Levitt, J. D., and Suhan, J. (1992) J. Biol. Chem. 267, 8696 -8701). Thus the capacity for undergoing the 7 S/5 S transition is an intrinsic property of the heavy chains and requires neither light chains nor eukaryotic post-translational modification. DKH960 undergoes a similar transition, indicating that the extreme COOH-terminal region is not required. More extensive deletions from the COOH-terminal (DKH945 and DKH937) result in a shift in the midpoint for the transition to lower salt concentrations. DKH927 and shorter constructs remaining extended even in the absence of added salt. Thus the COOH-terminal ϳ50 amino acids are required for the formation of the compact conformation. Separately expressed COOH-terminal tail segments and NH 2 -terminal head/neck segments interact in a salt-dependent manner that is consistent with the compact conformer being produced by the interaction of domains from these regions of the heavy chain dimer. The microtubule-stimulated ATPase rate of DKH975 in the compact conformer is strongly inhibited compared with the rate of extended DKH894 (4 s ؊1 and 35 s ؊1 , respectively, for k cat at saturating microtubules).Kinesin is an ATP-dependent motor protein that is involved in movement of membranous vesicles along MTs 1 (see Refs. 1 and 2). The NH 2 -terminal ϳ340 amino acids of the heavy chain forms a globular motor domain (head) that has MT-stimulated ATPase activity (see Fig. 2B). The motor domain is followed by a long central coiled-coil stalk region and a small nonhelical domain at the COOH-terminal. The central region contains several positions at which the coiled-coil propensity is low and these likely represent hinges in the stalk. The first coiled-coil region that extends from the motor domain is designated the neck region. Constructs that contain the head and the COOHterminal part of the coiled-coil neck form dimers (3). There is a likely hinge at position ϳ400 that marks the boundary between the neck and the stalk. Peptides from the neck (4, 5) and stalk (6) have been demonstrated to interact in a coiled-coil manner by several criteria. The crystal structure of a dimeric head plus neck construct has been recently determined (7) and it directly demonstrates the coiled-coil interactions in the neck region.Native kinesin is a heterotetramer composed of a dimeric heavy chain core with two light chains attached in the COOHterminal region (8, 9). At high salt kinesin exist in an extended conformation with an s 20,w value of ϳ6 S, but adopts a more compact conformation at low salt concentration with an s 20,w value of ϳ9 S. This global conformational transition is readily reversible and can be observed b...

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Characteristic modifications of the breathing pattern of mice to evaluate the effects of airborne chemicals on the respiratory tract

et al. 1993

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A system was developed for exposure of unanesthetized mice to airborne chemicals and for continuous measurement of their breathing pattern prior to, during and following exposure. By measuring inspiratory and expiratory airflows (VI and VE), and integration with time to yield tidal volume (VT), we obtained characteristic modifications to the normal breathing pattern. These permitted recognition that a specific portion of the respiratory tract was affected by the selected airborne chemicals. Following recognition, we also quantitated the degree of effect using one specific measurement in each case. An effect on the upper respiratory tract, induced by the sensory irritant, 2-chlorobenzylchloride, was quantitated by measuring a decrease in respiratory frequency. An effect on the conducting airways, induced by the airway constrictor, carbamylcholine, was quantitated by a decrease in VE at the mid-point of VT. An effect at the alveolar level, induced either by the vagal nerve ending stimulant, propranolol, or by the pulmonary irritant, machining fluid G, was quantitated by an increase in the length of a pause induced at the end of expiration. The system is easy to construct and operate and can be used to rapidly evaluate the effects of airborne chemicals on the respiratory tract.

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Influence of the Kinesin Neck Domain on Dimerization and ATPase Kinetics

Jiang

Stock

et al. 1997

Journal of Biological Chemistry

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Computer assisted recognition and quantitation of the effects of airborne chemicals acting at different areas of the respiratory tract in mice

et al. 1994

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The pattern and timing of a normal breath in unanesthetized mice was analyzed from measurement of inspiratory and expiratory airflows (VI and VE). Airflow was measured via a differential pressure transducer, attached to a pneumotachograph, which itself was attached to a body plethysmograph into which a mouse was placed. The analog voltage from the differential pressure transducer was digitized and stored for analysis on a microcomputer. Criteria were developed to classify each breath as normal (N) or belonging into one of seven abnormal categories. The abnormal categories were arrived at by computer analysis, recognizing specific modifications of the normal pattern into patterns of: sensory irritation of the upper respiratory tract (S), airflow limitation within the conducting airways of the lungs (A) or pulmonary irritation at the alveolar level (P). Combinations of these effects, i.e., S+A, P+A, P+S and P+S+A were also recognized. Computer analysis of each breath also permitted quantitative evaluation of the degree of S, A or P abnormalities. To induce each type of effect we used inhalation exposures to 2-chlorobenzylchloride, carbamylcholine or propranolol. We propose that this approach will permit rapid evaluation of the possible effects of airborne chemicals at three levels of the respiratory tract, with the classification of the type of effect easily obtained in an objective way using well defined criteria, followed by quantitation of the degree of each effect.

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Maryanne F. Stock

Kinesin’s IAK tail domain inhibits initial microtubule-stimulated ADP release

Formation of the Compact Confomer of Kinesin Requires a COOH-terminal Heavy Chain Domain and Inhibits Microtubule-stimulated ATPase Activity

Characteristic modifications of the breathing pattern of mice to evaluate the effects of airborne chemicals on the respiratory tract

Influence of the Kinesin Neck Domain on Dimerization and ATPase Kinetics

Computer assisted recognition and quantitation of the effects of airborne chemicals acting at different areas of the respiratory tract in mice

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