Isolation of a Ca2(+)-releasing factor from caffeine-treated skeletal muscle fibres and its effect on Ca2+ release from sarcoplasmic reticulum

Caffeine and other sympathomimetic stimulants: modes of action and effects on sports performance

Stimulants, illegal and legal, continue to be used in competitive sport. The evidence for the ergogenic properties of the most potent stimulants, amphetamines, cocaine and ephedrine, is mostly insubstantial. Low doses of amphetamines may aid performance where effects of fatigue adversely affect higher psychomotor activity. Pseudoephedrine, at high doses, has been suggested to improve high intensity and endurance exercise but phenylpropanolamine has not been proven to be ergogenic. Only caffeine has substantial experimental backing for being ergogenic in exercise. The mode of action of these stimulants centres on their ability to cause persistence of catecholamine neurotransmitters, with the exception of caffeine which is an adenosine receptor antagonist. By these actions, the stimulants are able to influence the activity of neuronal control pathways in the central (and peripheral) nervous system. Rodent models suggest that amphetamines and cocaine interact with different pathways to that affected by caffeine. Caffeine has a variety of pharmacological effects but its affinity for adenosine receptors is comparable with the levels expected to exist in the body after moderate caffeine intake, thus making adenosine receptor blockade the favoured mode of ergogenic action. However, alternative modes of action to account for the ergogenic properties of caffeine have been supported in the literature. Biochemical mechanisms that are consistent with more recent research findings, involving proteins such as DARPP-32 (dopamine and cAMP-regulated phosphoprotein), are helping to rationalize the molecular details of stimulant action in the central nervous system.

Caffeine Use in Sports, Pharmacokinetics in Man, and Cellular Mechanisms of Action

Caffeine is the most widely consumed psychoactive 'drug' in the world and probably one of the most commonly used stimulants in sports. This is not surprising, since it is one of the few ergogenic aids with documented efficiency and minimal side effects. Caffeine is rapidly and completely absorbed by the gastrointestinal tract and is readily distributed throughout all tissues of the body. Peak plasma concentrations after normal consumption are usually around 50 microM, and half-lives for elimination range between 2.5-10 h. The parent compound is extensively metabolized in the liver microsomes to more than 25 derivatives, while considerably less than 5% of the ingested dose is excreted unchanged in the urine. There is, however, considerable inter-individual variability in the handling of caffeine by the body, due to both environmental and genetic factors. Evidence from in vitro studies provides a wealth of different cellular actions that could potentially contribute to the observed effects of caffeine in humans in vivo. These include potentiation of muscle contractility via induction of sarcoplasmic reticulum calcium release, inhibition of phosphodiesterase isoenzymes and concomitant cyclic monophosphate accumulation, inhibition of glycogen phosphorylase enzymes in liver and muscle, non-selective adenosine receptor antagonism, stimulation of the cellular membrane sodium/potassium pump, impairment of phosphoinositide metabolism, as well as other, less thoroughly characterized actions. Not all, however, seem to account for the observed effects in vivo, although a variable degree of contribution cannot be readily discounted on the basis of experimental data. The most physiologically relevant mechanism of action is probably the blockade of adenosine receptors, but evidence suggests that, at least under certain conditions, other biochemical mechanisms may also be operational.

Imaging caffeine-induced Ca2+ transients in individual fast-twitch and slow-twitch rat skeletal muscle fibers

Fast-twitch and slow-twitch rat skeletal muscles produce dissimilar contractures with caffeine. We used digital imaging microscopy to monitor Ca2+ (with fluo 3-acetoxymethyl ester) and sarcomere motion in intact, unrestrained rat muscle fibers to study this difference. Changes in Ca2+ in individual fibers were markedly different from average responses of a population. All fibers showed discrete, nonpropagated, local Ca2+ transients occurring randomly in spots about one sarcomere apart. Caffeine increased local Ca2+ transients and sarcomere motion initially at 4 mM in soleus and 8 mM in extensor digitorum longus (EDL; approximately 23 degrees C). Ca2+ release subsequently adapted or inactivated; this was surmounted by higher doses. Motion also adapted but was not surmounted. Prolonged exposure to caffeine evidently suppressed myofilament interaction in both types of fiber. In EDL fibers, 16 mM caffeine moderately increased local Ca2+ transients. In soleus fibers, 16 mM caffeine greatly increased Ca2+ release and produced propagated waves of Ca2+ (approximately 1.5-2.5 microns/s). Ca2+ waves in slow-twitch fibers reflect the caffeine-sensitive mechanism of Ca2(+)-induced Ca2+ release. Fast-twitch fibers possibly lack this mechanism, which could account for their lower sensitivity to caffeine.

Caffeine-induced calcium oscillations in heavy-sarcoplasmic-reticulum vesicles from rabbit skeletal muscle

Heavy-sarcoplasmic-reticulum vesicles from rabbit skeletal muscle show not only caffeine-induced calcium release in a medium allowing active calcium loading, but also oscillations in calcium concentration under appropriate conditions. The xanthine derivatives 7-isobutyl-1-methylxanthine and theophylline also induce oscillations under the same conditions. Calcium-releasing substances with other chemical structures such as adenosine nucleotides or calmodulin antagonists do not induce this effect. With the help of specific inhibitors such as ruthenium red, neomycin or magnesium it was demonstrated that the oscillation mechanism involves the ryanodine receptor/calcium channel. When ATP was substituted by GTP or ITP no oscillations occurred after caffeine application. The subsequent application of ATP, but not of adenosine 5'-[gamma-thio]triphosphate or adenosine 5'-[beta,gamma-methylene]triphosphate activated the oscillating mechanism, showing ATP to be an essential component of the oscillating system. We investigated the influence of the experimental conditions by altering the caffeine and ATP concentrations, calcium load, pH and ionic strength amongst other parameters. Potassium and anion channels are not involved in calcium oscillations of heavy sarcoplasmic reticulum, nor are the oscillations dependent on membrane potential.

Ca2+ oscillations and sensitization of Ca2+ release in unfertilized mouse eggs injected with a sperm factor

The mechanisms by which a sperm factor caused Ca2+ oscillations in unfertilized mouse eggs was investigated by monitoring the fluorescence of intracellular Fluo-3. Injecting sperm extracts triggered Ca2+ oscillations that varied in number and frequency rather than amplitude. All the sperm factor-induced Ca2+ transients showed a characteristic rapid increase and decline. The oscillations persisted for variable times in eggs bathed in Ca2+ free media and were distinct in character from those caused by inserting pipettes containing inositol 1,4,5-trisphosphate (InsP3). InsP3-induced Ca2+ oscillations were always of high frequency but varied considerably in form and amplitude depending upon InsP3 concentration. The oscillations produced by injecting Ca2+ into unfertilized eggs were similar to those produced with low doses of InsP3 but different from those caused by sperm extract injection. After injection of sperm extracts further injection of InsP3, or Ca2+, produced high frequency large amplitude Ca2+ transients. It is concluded that the sperm factor mediates its effects by sensitizing Ca2+ release mechanisms.

Different triggers for calcium oscillations in mouse eggs involve a ryanodine-sensitive calcium store

Relative intracellular free Ca2+ concentrations ([Ca2+]i) were monitored in mature unfertilized mouse eggs by measuring fluorescence of intracellular fluo3. A number of different agents were found to cause sustained repetitive transient [Ca2+]i oscillations. These were microinjection of a cytosolic sperm factor, sustained injection of Ins-(1,4,5)P1, or extracellular addition of the thiol reagent thimerosal. Stimulating G-protein activity by injection of guanosine 5'-[gamma-thio]triphosphate plus application of carbachol also caused [Ca2+]i oscillations, but less reliably than other stimuli. A role for Ca(2+)-induced Ca2+ release and a ryanodine-sensitive Ca2+ channel in mouse eggs was suggested by the finding that microinjection, or external addition, of ryanodine also caused [Ca2+]i increases. Furthermore, ryanodine, along with thimerosal, increased the sensitivity of eggs to Ca(2+)-induced [Ca2+]i oscillations. When ryanodine was added to eggs oscillating in response to the sperm factor, InsP3 or thimerosal, it caused a decrease in amplitude of oscillations and eventually a block of [Ca2+]i oscillations associated with a sustained elevation of [Ca2+]i. These data suggest that a ryanodine-sensitive Ca(2+)-release mechanism exists in mouse eggs and that a ryanodine-sensitive Ca2+ store plays a role in generating intracellular [Ca2+]i oscillations.

Caffeine- and Ca2(+)-induced mechanical oscillations in isolated skeletal muscle fibres of the frog

Isometric force and subthreshold sarcomeric oscillations were studied in isolated muscle fibres of the frog. In intact muscle fibres, caffeine in a concentration of 2 mM caused a subthreshold oscillatory activation of single sarcomeres, called 'sarcomeric oscillations'. They occurred independently of membrane potential and were blocked by agents which directly interfere with Ca2+ release from the sarcoplasmic reticulum (SR). In skinned muscle fibres, sarcomeric oscillations were also induced by the Ca2+ ion itself (pCa = 6.1). When the free EGTA concentration of the bathing solutions was reduced, fibres responded with long lasting oscillations of force. Both types of oscillations were blocked when the membranes of the SR were solubilized by detergent. The results reveal that caffeine- and Ca2+-induced oscillations in skeletal muscle fibres are triggered by a cyclic release of Ca2+ ions from the SR. It is suggested that they interfere with the process of Ca2+-induced Ca2+ release.