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Query: UNIPROT:P20020 (
adenosine triphosphatase
)
3,299
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Digoxin
could improve diaphragm contractility and fatigability if inhibition of sodium-potassium
adenosine triphosphatase
enhances calcium influx from extracellular sources, or it could impair contractility and worsen fatigue if it impairs maintenance of the membrane potential. We studied the effects of digoxin on isometric force production, fatigue, and recovery in isolated, directly stimulated, guinea pig and rat diaphragms.
Digoxin
had no effect on maximal twitch or tetanic tensions compared with control diaphragms in either rat (2 ng/ml to 20 micrograms/ml) or guinea pig (2 ng/ml to 2 micrograms/ml) hemidiaphragms.
Digoxin
worsened high frequency fatigue and impaired recovery from fatigue in guinea pigs (200 ng/ml to 2 micrograms/ml) but not in rat (2 micrograms/ml) hemidiaphragms. We conclude that digoxin has no effect on diaphragm contractility. Hypopolarization of the membrane potential is the likely cause for the increased fatigability. The difference in responsiveness between species is likely due to insensitivity of rat sodium-potassium
adenosine triphosphatase
to digoxin.
...
PMID:The effect of digoxin on contractility and fatigue of isolated guinea pig and rat hemidiaphragms. 320 78
The ability of digoxin and a 4-aminocardenolide, ASI-222, to alter atrioventricular nodal refractory period (AVRP) was determined as a function of the maximum subarrhythmic dose (MSAD) in the dog anesthetized with morphine-pentobarbital. ASI-222, a highly polar and potent inhibitor of Na+, K+-
adenosine triphosphatase
produces a cardiotoxicity in dogs prominently involving atrioventricular nodal blockade rather than ventricular premature ectopic beats and tachycardia seen with digoxin. AVRP was assessed with trains of electrically isolated stimuli of decreasing pulse interval delivered to the right atria.
Digoxin
and ASI-222 were infused i.v. at rates which produced cardiac arrhythmias in about 100 min in dogs either: 1) with intact nerves, 2) pretreated with atropine, 3) without reflex receptors (without vagus and carotid sinus nerves, 4) without cardiac sympathetic nerves and adrenals or 5) pretreated with metoprolol. In dogs with intact nerves, ASI-222 produced greater increases in AVRP than digoxin at fractions of the MSAD; however, both glycoside produced a similar elevation at the MSAD (approximately equal to 30% increase). Atropine did not alter the AVRP response to ASI-222 but prevented the lengthening due to digoxin except for that which occurred near the MSAD. Removal of reflex receptor afferents (and vagi) had an effect similar to atropine on the AVRP response to digoxin, but completely prevented any response to ASI-222. Prior sympathectomy or beta adrenergic blockade abolished the AVRP response to ASI-222 but did not alter the responses to digoxin.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Effect of an aminocardenolide and digoxin upon atrioventricular refractory period in the dog. 407 25
The purpose of this study was to see whether the receptor for cardiac glycosides might be localized upon or within the plasma membrane of digitalis-sensitive cells. Ouabain and digoxin were joined covalently to several large protein molecules. These macromolecular conjugates are too large to enter intact cells; consequently, any pharmacologic or biochemical effects which they display should arise from interaction with a cell surface receptor. Conjugates were tested in several cardiac glycoside-sensitive systems: (a), contractility response of isolated cardiac muscle; (b), active (86)Rb(+) uptake by red cells; (c), enzymatic activity of isolated myocardial microsomal (Na(+) + K(+))-activated
adenosine triphosphatase
(
ATPase
); and (d), enzymatic activity of solubilized red cell (Na(+) + K(+))-activated
ATPase
. Results demonstrated that in all of these systems, the macromolecular-glycoside conjugates were 100- to 1000-fold less active than the free glycosides. Careful chromatographic examination of the various conjugates revealed that they contained a small but persistent free cardiac glycoside contaminant. The amount of this species ranged from 0.1 to 1.0% of the total macromolecule-bound glycoside, and its presence fully explains the levels of biologic activity observed with the conjugates. To try to minimize steric factors which could interfere with glycoside-receptor interaction, digoxin and ouabain were also coupled to macromolecule via long, flexible polyamide side-chains. These extended chain conjugates, in which the cardiac glycoside potentially lay some 30 A removed from the surface of the macromolecule, also exhibited negligible digitalis-like effects when tested upon isolated cardiac muscle, red cell (86)Rb(+) uptake, and enzymatic activity of cardiac microsomal (Na(+) + K(+))-
ATPase
. However, the extended chain conjugates were fully active when examined with the solubilized red cell (Na(+) + K(+))-
ATPase
system. To further ensure that the chemical reactions used to couple macromolecule to glycoside did not inactivate the drug, all conjugates were subjected to extensive proteolytic digests exhibited full pharmacologic activity.
Digoxin
was also coupled to the tripeptide alanylglycylglycine, and the resulting conjugate was fully active. Taken together, these results suggest that if the receptor(s) for cardiac glycosides is associated with the plasma membrane, then it may lie deep within it.
...
PMID:Studies on the localization of the cardiac glycoside receptor. 426 Jun 87
The distribution of 3H-digoxin has been measured in a large number of tissues from the central, autonomic, and peripheral nervous system after the induction of ventricular tachycardia by infusing digoxin into anesthetized dogs. In most parts of the nervous system the tissue digoxin concentration was close to that in the cerebrospinal fluid.
Digoxin
accumulation in the choroid plexus probably represented a labeling of
adenosine triphosphatase
. There was a markedly higher concentration of digoxin in the neurohypophysis than in the adenohypophysis, and the very high levels in the neurohypophysis are hard to explain. There may be a relationship between the pituitary and the hypothalamic digoxin levels, although the concentration in the latter was unimpressive. The fornix showed a modest increase in 3H-digoxin concentration and may play a role, as its efferent discharge goes to the hypothalamus. The high concentration of digoxin in the area postrema suggests that this central nervous system structure is responsible, at least in part, for producing digoxin-induced cardiac arrhythmias. It may act as a sensing organ sensitive to blood digoxin concentration. Either it is the only central nervous structure implicated, or it is involved together with the fornix-hypothalamus-hypophysis pathways. Further proof is given for the importance of the autonomic nervous system in cardiac arrhythmias by the high digoxin levels in the superior cervical sympathetic ganglion and adrenal medulla.
...
PMID:3H-digoxin distribution in the nervous system in ventricular tachycardia. 617 30
