UMLS:C0038454 - FACTA Search

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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.
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PMID:Kinesin takes one 8-nm step for each ATP that it hydrolyzes. 992 Sep 16

We have used polyethylene glycol (PEG) to perturb the actomyosin interaction in active skinned muscle fibers. PEG is known to potentiate protein-protein interactions, including the binding of myosin to actin. The addition of 5% w/v PEG (MW 300 or 4000) to active fibers increased fiber tension and decreased shortening velocity and ATPase activity, all by 25-40%. Variation in [ADP] or [ATP] showed that the addition of PEG had little effect on the dissociation of the cross-bridge at the end of the power stroke. Myosin complexed with ADP and the phosphate analog V(i) or AlF(4) binds weakly to actin and is an analog of a pre-power-stroke state. PEG substantially enhances binding of these states both in active fibers and in solution. Titration of force with increasing [P(i)] showed that PEG increased the free energy available to drive the power stroke by about the same amount as it increased the free energy available from the formation of the actomyosin bond. Thus PEG potentiates the binding of myosin to actin in active fibers, and it provides a method for enhancing populations of some states for structural or mechanical studies, particularly those of the normally weakly bound transient states that precede the power stroke.
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PMID:The effect of polyethylene glycol on the mechanics and ATPase activity of active muscle fibers. 1065 5

Kinesin, a microtubule-based motor, and myosin, an actin-based motor, share a similar core structure, indicating that they arose from a common ancestor. However, kinesin lacks the long lever-arm domain that is believed to drive the myosin power stroke. Here, we present evidence that a much smaller region of ca. 10-40 amino acids serves as a mechanical element for kinesin motor proteins. These 'neck regions' are class conserved and have distinct structures in plus-end and minus-end-directed kinesin motors. Mutagenesis studies also indicate that the neck regions are involved in coupling ATP hydrolysis and energy into directional motion along the microtubule. We suggest that the kinesin necks drive motion by undergoing a conformational change in which they detach and re-dock onto the catalytic core during the ATPase cycle. Thus, kinesin and myosin have evolved unique mechanical elements that amplify small, nucleotide-dependent conformational changes that occur in their similar catalytic cores.
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PMID:Searching for kinesin's mechanical amplifier. 1083 98

In the failing human myocardium, both impaired calcium homoeostasis and alterations in the levels of contractile proteins have been observed, which may be responsible for reduced contractility as well as diastolic dysfunction. In addition, levels of a key protein in calcium cycling, i.e. the sarcoplasmic reticulum Ca(2+)-ATPase, and of the alpha-myosin heavy chain have been shown to be enhanced by treatment with etomoxir, a carnitine palmitoyltransferase inhibitor, in normal and pressure-overloaded rat myocardium. We therefore studied, for the first time, the influence of long-term oral application of etomoxir on cardiac function in patients with chronic heart failure. A dose of 80 mg of etomoxir was given once daily to 10 patients suffering from heart failure (NYHA functional class II-III; mean age 55+/-4 years; one patient with ischaemic heart disease and nine patients with dilated idiopathic cardiomyopathy; all male), in addition to standard therapy. The left ventricular ejection fraction was measured echocardiographically before and after a 3-month period of treatment. Central haemodynamics at rest and exercise (supine position bicycle) were defined by means of a pulmonary artery catheter and thermodilution. All 10 patients improved clinically; no patient had to stop taking the study medication because of side effects; and no patient died during the 3-month period. Maximum cardiac output during exercise increased from 9.72+/-1.25 l/min before to 13.44+/-1.50 l/min after treatment (P<0.01); this increase was mainly due to an increased stroke volume [84+/-7 ml before and 109+/-9 ml after treatment (P<0.01)]. Resting heart rate was slightly reduced (not statistically significant). During exercise, for any given heart rate, stroke volume was significantly enhanced (P<0.05). The left ventricular ejection fraction increased significantly from 21.5+/-2.6% to 27.0+/-2.3% (P<0.01). In acute studies, etomoxir showed neither a positive inotropic effect nor vasodilatory properties. Thus, although the results of this small pilot study are not placebo-controlled, all patients seem to have benefitted from etomoxir treatment. Etomoxir, which has no acute inotropic or vasodilatory properties and is thought to increase gene expression of the sarcoplasmic reticulum Ca(2+)-ATPase and the alpha-myosin heavy chain, improved clinical status, central haemodynamics at rest and during exercise, and left ventricular ejection fraction.
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PMID:First clinical trial with etomoxir in patients with chronic congestive heart failure. 1088 55

Atrial fibrillation (AF) is the most common cardiac arrhythmia, and is often associated with other cardiovascular disorders and diseases. AF can lead to thromboembolism, reduced left ventricular function and stroke, and, importantly, it is independently associated with increased mortality. AF is a progressive disease; numerous lines of evidence suggest that disease progression results from cumulative electrophysiological and structural remodeling of the atria. There is considerable interest in delineating the molecular mechanisms involved in the remodeling that occurs in the atria of patients with AF. Cellular electrophysiological studies have revealed marked reductions in the densities of the L-type voltage-gated Ca2+ current, I(Ca,L), the transient outward K+ current, I(TO), and the ultrarapid delayed rectifier K+ current, I(Kur), in atrial myocytes from patients in chronic AF. Similar (but not identical) changes in currents are evident in myocytes isolated from a canine model of AF and, in this case, the changes in currents are correlated with reduced expression of the underlying channel forming subunits. In both human and canine AF, the reduction in I(Ca,L) appears to be sufficient to explain the observed decreases in action potential duration and effective refractory period that are characteristic features of the remodeled atria. In addition, expression of the sarcoplasmic reticulum Ca2+ ATPase is reduced, suggesting that calcium cycling is affected in AF. These recent studies suggest that calcium overload and perturbations in calcium handling play prominent roles in AF-induced atrial remodeling. Although considerable progress has been made, further studies focused on defining the detailed structural, cellular and molecular changes that accompany the different stages of AF in humans, as well as in animal models of AF, are clearly warranted. It is anticipated that molecular insights gleaned from these studies will facilitate the development of improved therapeutic approaches to treat AF and to prevent the progression of the arrhythmia.
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PMID:Molecular basis of electrical remodeling in atrial fibrillation. 1088 61

Wistar Kyoto (WKY) rats were fed a diet containing 10% rapeseed (canola) oil or soybean oil as the only dietary fat for 13 weeks. From week 5 of feeding, systolic blood pressure of the canola oil group became higher than that of the soybean oil group. The 13-week canola oil intake increased plasma levels of Na(+) and lipids, and decreased the level of K(+) compared to those in the soybean oil group. The canola oil group also showed a high density of neutrophils and a low density of platelets compared to the soybean oil group. Moreover, the activities of catalase and superoxide dismutase in the hepatic cytosol were depressed in the canola oil group. The mechanisms for the higher blood pressure are unclear. However, an increase in body fluid via activation of Na(+) pump or Na(+), K(+)-ATPase and/or a blunt endothelium-dependent vasodilation by increased superoxide might have relevance to the elevated blood pressure. The increased plasma lipids and the changes in the densities of platelets and neutrophils appear not to be critical in WKY rats. However, these would tend to promote peripheral vascular lesions in the strains, such as spontaneously hypertensive rats and stroke-prone spontaneously hypertensive rats, which are prone to present atheroscrelotic vascular injury.
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PMID:Thirteen-week dietary intake of rapeseed oil or soybean oil as the only dietary fat in Wistar Kyoto rats-change in blood pressure. 1093 Jul 2

Twenty stroke-prone spontaneously hypertensive rats were divided into 2 groups of 10 animals each, and fed a defatted diet and orally administered rapeseed (canola) oil or soybean oil at 10 (w/w)% of the consumed diet once a day for 4 weeks. At the 4th week of administration, the systolic blood pressure in the canola oil group was higher (235 +/- 2 mmHg, mean +/- S.E.M., N=10) than that in the soybean oil group (225 +/- 4 mmHg, N=10, P<0.05). In isolated, perfused mesenteric bed from these rats, the increase in perfusion pressure by norepinephrine, ATP, arachidonic acid, endothelin-1, angiotensin II or serotonin showed no between-group differences. There were also no between-group differences in the production of thromboxane A2 and prostaglandin 12 in the outflow by arachidonic acid injection. On the other hand, in the isolated aortic ring from the canola oil group, developed tension in potassium-free solution was enhanced with activation of Na+, K+ -ATPase. These results suggest that canola oil intake as the sole dietary fat increases systolic blood pressure of stroke-prone spontaneously hypertensive rats. The changes in vascular responsiveness to vasoconstrictors and production of prostanoids are unlikely to have relevance to the elevation of blood pressure. However, altered Na+, K+ -ATPase activity may play a role in the promotion of blood pressure elevation.
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PMID:Increase in blood pressure with enhanced Na+, K+ -ATPase activity in stroke-prone spontaneously hypertensive rats after 4-weeks intake of rapeseed oil as the sole dietary fat. 1106 56

Myosin subfragment 1 (S1) is the ATP catalyzing motor protein in muscle. It consists of three domains that catalyze ATP and bind actin (catalytic), conduct energy transduction (converter), and transport the load (lever arm). These domains interface in two places identified as interface I, containing the reactive thiol (SH1) and ATP-sensitive tryptophan (Trp510), and interface II, containing the reactive lysine residue (RLR). Two crystal structures of S1 were extrapolated to working "in solution" or oriented "in tissue" forms, using structure-sensitive optical spectroscopic signals from extrinsic probes located in the interfaces. Observed signals included circular dichroism (CD) and absorption originating from S1 in solution in the presence and absence of actin and fluorescence polarization from cross-bridges in muscle fibers. Theoretical signals were calculated from S1 crystal structure models perturbed with lever arm movement from swiveling at three conserved glycines, 699, 703, and 710 (chicken skeletal myosin numbering). Structures giving the best agreement between the computed and observed signals were selected as the representative forms. Both interfaces undergo dramatic conformational change during ATPase and force development. Changes at interface I suggest the molecular basis for the collisional quenching sensitivity of Trp510 to nucleotide binding. The probe conformation at SH1 suggests how it alters S1 ATPases. At interface II, the spatial relationship of the lever arm and the extrinsic probe at RLR suggests how the probe alters S1 ATPases and that it should inhibit lever arm movement during the power stroke. The latter possibility, if true, establishes a part of the corridor through which the lever arm swings during the power stroke. Global structural changes in actomyosin are discussed in the accompanying paper [Burghardt et al. (2001) Biochemistry 40, 4821-4833].
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PMID:Conformation of myosin interdomain interactions during contraction: deductions from proteins in solution. 1129 51

The aim of this study was to detect a relationship between hemodynamic disorders in patients with hemorrhagic fever with the renal syndrome (HFRS) and erythrocyte aggregability and erythrocyte membrane ATPase activity. A total of 100 patients with HFRS of different severity were examined. Central hemodynamic parameters were studied: circulating blood volume, minute volume, cardiac index, stroke volume, and total peripheral vascular resistance during preoliguria, oliguria, and polyuria periods. Blood parameters were studied: percentage of minimum and maximum aggregation, disaggregation coefficient, activities of transport adenosine triphosphatases (Na, K, and Ca-activated ATPases and Mg-dependent ATPase). The main hemodynamic parameters were increased (p < 0.05) during early preoliguria and decreased during oliguria; during the polyuria period they again corresponded to the hyperkinetic circulation. The minimum erythrocyte aggregation increased by 110 and 130% in medium-severe and severe HFRS, respectively, the maximum erythrocyte aggregation by 20 and 28%, respectively (p < 0.05). Disaggregation coefficient decreased by 55%. The activities of Na, K(+)-ATPases decreased by 13% during preoliguria period, by 17.5% during oliguria, and by 11.7% during polyuria (p < 0.05) in patients with moderate disease. In severe disease these decreases were 14, 19, and 15%, respectively (p < 0.05). Similar changes were observed in the activities of Ca(++)-ATPase and Mg-dependent ATPase. Hence, the detected hemodynamic changes in patients with medium-severe and severe HFRS correlated with disorders in erythrocyte aggregability and decreased activity of transport ATPases, which can be used for evaluation of the severity of clinical condition and early diagnosis.
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PMID:[Central hemodynamic disorders and rheological red blood cell properties in hemorrhagic fever patients with renal syndrome]. 1151 Jan 83

The KIF1 subfamily members are monomeric and contain a number of amino acid inserts in surface loops. A particularly striking insertion of several lysine/arginine residues occurs in L12 and is called the K-loop. Two recent studies have employed both kinetic and single-molecule methods to investigate KIF1 motor properties and have produced very different conclusions about how these motors generate motility. Here we show that a hitherto unstudied member of this group, KIF1D, is not chemically processive and drives fast motility despite demonstrating a slow ATPase. The K-loop of KIF1D was analysed by deletion and insertion mutagenesis coupled with characterization by steady state and transient kinetics. Together, the results indicate that the K-loop not only increases the affinity of the motor for the MT, but crucially also inhibits its subsequent isomerization from weak to strong binding, with coupled ADP release. By stabilizing the weak binding, the K-loop establishes a pool of motors primed to undergo their power stroke.
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PMID:KIF1D is a fast non-processive kinesin that demonstrates novel K-loop-dependent mechanochemistry. 1156 75

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