Utilization of bound calcium in the action of caffeine and certain multivalent cations on skeletal muscle

Direct conversion of theophylline to 3-methylxanthine by metabolically engineered E. coli

Background

Methylxanthines are natural and synthetic compounds found in many foods, drinks, pharmaceuticals, and cosmetics. Aside from caffeine, production of many methylxanthines is currently performed by chemical synthesis. This process utilizes many chemicals, multiple reactions, and different reaction conditions, making it complicated, environmentally dissatisfactory, and expensive, especially for monomethylxanthines and paraxanthine. A microbial platform could provide an economical, environmentally friendly approach to produce these chemicals in large quantities. The recently discovered genes in our laboratory from Pseudomonasputida, ndmA, ndmB, and ndmD, provide an excellent starting point for precisely engineering Escherichia coli with various gene combinations to produce specific high-value paraxanthine and 1-, 3-, and 7-methylxanthines from any of the economical feedstocks including caffeine, theobromine or theophylline. Here, we show the first example of direct conversion of theophylline to 3-methylxanthine by a metabolically engineered strain of E. coli.

Results

Here we report the construction of E. coli strains with ndmA and ndmD, capable of producing 3-methylxanthine from exogenously fed theophylline. The strains were engineered with various dosages of the ndmA and ndmD genes, screened, and the best strain was selected for large-scale conversion of theophylline to 3-methylxanthine. Strain pDdA grown in super broth was the most efficient strain; 15 mg/mL cells produced 135 mg/L (0.81 mM) 3-methylxanthine from 1 mM theophylline. An additional 21.6 mg/L (0.13 mM) 1-methylxanthine were also produced, attributed to slight activity of NdmA at the N₃-position of theophylline. The 1- and 3-methylxanthine products were separated by preparative chromatography with less than 5 % loss during purification and were identical to commercially available standards. Purity of the isolated 3-methylxanthine was comparable to a commercially available standard, with no contaminant peaks as observed by liquid chromatography-mass spectrophotometry or nuclear magnetic resonance.

Conclusions

We were able to biologically produce and separate 100 mg of highly pure 3-methylxanthine from theophylline (1,3-dimethylxanthine). The N-demethylation reaction was catalyzed by E. coli engineered with N-demethylase genes, ndmA and ndmD. This microbial conversion represents a first step to develop a new biological platform for the production of methylxanthines from economical feedstocks such as caffeine, theobromine, and theophylline.

Electronic supplementary material

The online version of this article (doi:10.1186/s12934-015-0395-1) contains supplementary material, which is available to authorized users.

The time-dependent and dose-dependent effects of caffeine on the contraction of the ferret heart

1. Trabeculae isolated from ferret heart and from other mammalian hearts have been mounted in a way that enables the tension generated to be measured while the composition of the bathing fluid is rapidly altered.2. Application of caffeine to these trabeculae initiates a rapid transient contracture and depresses the strength of regularly evoked heart beats.3. The strength of the contractures, the rate of tension development and the rate of spontaneous relaxation are all increased by raising the concentration of the applied caffeine.4. The strength of the caffeine contracture is relatively unaffected by changes in the bathing Na(+), K(+) or Ca(2+) concentrations, but is reduced by exposure to the free-base form of local anaesthetics.5. Lowering of the temperature has complex effects on the amplitude of the caffeine contracture due to the differing temperature sensitivities of the contraction and spontaneous relaxation.6. Following a caffeine contracture, a period of perfusion by caffeinefree solution is required before a full-sized contracture can be evoked by the re-application of caffeine. This re-priming of the caffeine contracture has a sigmoidal time course that can be fitted by a two compartment model. The rate constants of the filling of each of the compartments can be obtained analytically, and are found to be increased by raising the extracellular calcium concentration, [Ca](o), by stimulating the preparation or by raising the temperature. Reducing the [Na](o) or raising the [K](o) has little effect on these processes.7. The presence of traces of caffeine in the perfusing fluid between the conditioning and test challenges with the caffeine contracture solution reduces the extent of the re-priming without much affecting its rate.8. The behaviour of several model systems have been compared with that of the heart with the aid of an analogue computer. A four compartment closed system has been found to simulate the results presented in this paper.9. It appears that caffeine has its effects by acting to increase the rate of release of activator calcium from one part of a non-homogeneous intracellular relaxing system present within the mammalian heart, which is likely to be the sarcoplasmic reticulum.

Alterations in calcium homeostasis reduce membrane excitability in amphibian skeletal muscle

The effects of alterations in intracellular calcium homeostasis on surface membrane excitability were investigated in resting Rana temporaria sartorius muscle. This was prompted by initial results from a fatiguing stimulation protocol study that demonstrated a fibre subpopulation in which action potential generation in response to a standard 1.5 V electrical stimulus failed despite mean membrane potentials [E (m), -69+/-2.3 mV (n=14)] compatible with spike firing in a control set of quiescent muscle fibres. Intracellular micro-electrode recordings showed a similar reversible loss of excitability, attributable to an increased threshold, despite only small (7.1+/-1.8 mV) positive changes in E (m) after approximately 60-min exposures to nominally 0 Ca(2+) Ringer solutions in which Ca(2+) was replaced by Mg(2+). This effect was not reproduced by addition of Mg(2+) to the Ringer solution and persisted under conditions of Cl(-) deprivation. The effects of three pharmacological agents, cyclopiazonic acid (CPA), caffeine and 4-chloro-m-cresol (4-CmC), each known to deplete store Ca(2+) and increase cytosolic Ca(2+) through contrasting mechanisms without influencing E (m), were then investigated. All three agents produced a more rapid, but nevertheless still reversible, loss of membrane excitability than in 0 Ca(2+) Ringer solution alone. This reduction in membrane excitability persisted in fibres studied in solutions containing a normal [Ca(2+)] following prior depletion of store Ca(2+) using CPA- and 4-CmC-containing solutions. These novel findings suggest that sarcoplasmic reticulum Ca(2+) content profoundly influences surface membrane excitability, thereby providing a potential mechanism by which spike firing fails in well-polarised fibres during fatigue.

Alkylxanthines as research tools

(1) The methylxanthine caffeine has many pharmacological effects, most of which can be linked to blockade of adenosine receptors, inhibition of phosphodiesterases, and augmentation of calcium-dependent release of calcium from intracellular stores. (2) A variety of xanthines have been developed as potent and/or selective antagonists for adenosine receptors. (3) Several xanthines have been developed that are more potent and more selective inhibitors of cyclic nucleotide phosphodiesterase than caffeine or theophylline. (4) Caffeine remains the xanthine of choice for activation of intracellular calcium-sensitive calcium release channels although millimolar concentrations are required, which can have effects on other aspects of calcium regulation.

AUTORADIOGRAPHIC STUDIES OF INTRACELLULAR CALCIUM IN FROG SKELETAL MUSCLE

Autoradiographs consisting of a 1000 A thick tissue section and a 1400 A thick emulsion film have been prepared from frog toe muscles labeled with Ca⁴⁵. The muscles had been fixed with an oxalate-containing osmium solution at rest at room temperature, at rest at 4°C, during relaxation following K⁺ depolarization or after prolonged depolarization. From 6 to 39 per cent of K⁺ contracture tension was produced during fixation. The grains in the autoradiographs were always concentrated in the center 0.2 to 0.3 µ of the I band and the region of the overlapping of the thick and thin filaments. The greater the tension produced during fixation, the greater was the concentration in the A band and the smaller the concentration in the I band. Autoradiographs of two muscles fixed by freeze-substitution resembled those of muscles which produced little tension during osmium fixation. Muscles which shortened during fixation produced fewer grains. In the narrow (<2.0 µ) sarcomeres of the shortened muscles, grain density decreased with decreasing sarcomere width. A theoretical analysis of the significance of these grain distributions is proposed and discussed.

CONTRACTURE OF SLOW STRIATED MUSCLE DURING CALCIUM DEPRIVATION

When deprived of calcium the slow striated muscle fibers of the frog develop reversible contractures in either hypertonic or isotonic solutions. While calcium deprivation continues because of a flowing calcium-free solution the muscles relax slowly and completely. Restoration of calcium during contracture relaxes the muscle promptly to initial tension. When relaxed during calcium lack the return of calcium does not change tension and the muscle stays relaxed. When contractures are induced by solutions containing small amounts of calcium relaxation does not occur or requires several hours. The rate of tension development depends upon the rate at which calcium moves outward since the contractures develop slower in low concentrations of calcium and are absent or greatly slowed in a stagnant calcium-free solution. Withdrawal of calcium prevents the contractile responses to ACh, KCl, or electrical stimulation through the nerve. Muscles return to their original excitability after calcium is restored. Origin of the contractures is unrelated to nerve activity since they are maximal during transmission failure from calcium lack, occur in denervated muscles, and are not blocked by high concentrations of d-tubocurarine, procaine, or atropine. The experiments also indicate that the contractures do not originate from repetitive activity of muscle membranes. The findings are most simply explained by relating the outward movement of calcium as a link for initiating contraction in slow type striated muscle.

THE ORIGIN OF THE ACETYLCHOLINE RELEASED SPONTANEOUSLY FROM THE GUINEA-PIG ISOLATED ILEUM

When the guinea-pig isolated ileum had been previously treated with the anticholinesterase, NN-diisopropylphosphodiamidic fluoride (mipafox), and attached to an isotonic lever loaded with 0.5 g, it released acetylcholine into Krebs solution gassed with a mixture of 95% oxygen and 5% carbon dioxide. The amount of acetylcholine spontaneously released depended on the duration of the rest period. Cocaine, procaine or cooling the preparation to 25 degrees C greatly reduced this spontaneous output of acetylcholine, thus providing evidence in support of nervous origin of the ester. Reduction of the calcium ion content of the Krebs solution to one-twentieth of its usual value or increase in the magnesium ion content four-fold, changes which inhibit the release of acetylcholine from somatic motor nerve-endings, inhibited the output of acetylcholine from the ileum. When all the calcium of Krebs solution had been replaced by strontium one-third of the control output of acetylcholine was obtained, but the smooth muscle of the guinea-pig ileum would not respond to drugs under these conditions. Strontium could thus partially substitute for calcium in nerves but not in muscle. Hemicholinium-3 (100 mug/ml.) inhibited the spontaneous release of acetylcholine and 400 mug/ml. of choline was required to reverse the inhibition. It is concluded that cocaine, procaine, cooling, reduction of calcium ion and increase of magnesium ion concentrations all reduce the spontaneous output of acetylcholine, which has its origin in the parasympathetic nerve-endings of the intramural nerve plexuses. Further, the hemicholinium experiments seem to justify the conclusion that the release of acetylcholine is reduced because synthesis is reduced.

The role of extracellular calcium in the pathophysiology of myotonic dystrophy

Increased intracellular calcium levels in myotonic dystrophy have been repeatedly reported in many studies. In our recent investigations, the entrance of extracellular calcium ions through voltage sensitive calcium channels (VSCCS) during repetitive action potentials and late after potentials (LAPs) in tetanic responses were found. Since there is an increased amplitude of LAPs and after-discharges in muscle fibers of myotonic dystrophy, we suggest that this pathological increase in the electrical properties of the muscle could also be responsible for this elevated intracellular calcium level.

The importance of calcium ions for in vitro malignant hyperthermia testing

Intracellular Ca++ levels in skeletal muscle are elevated during the in vitro contracture response of muscle from subjects with malignant hyperthermia. The role of Ca++ in the bathing medium and the consequences of substitution of Sr++ for Ca++ in the response to agents associated with malignant hyperthermia were examined. When Ca++ was omitted from the bathing medium the contractures induced in human vastus lateralis by halothane (three per cent) or succinylcholine (50 mM) were reduced by 80 and 100 per cent, respectively, while contractures induced by caffeine (8 mM) were only reduced by 50 per cent. Substitution of Ca++ by another divalent cation, Sr++, completely restored contractures induced by caffeine, but only partially restored contractures induced by halothane or succinylcholine (to 50 and 30 per cent of Ca(++)-containing medium, respectively). Mepacrine (10 microM) was effective in antagonizing contractures by caffeine, whereas verapamil and nifedipine (10 microM) were not. These results support an essential role for extracellular Ca++ not fulfilled by Sr++ in contracture induction by halothane and succinylcholine, but not by caffeine.

Competitive action of divalent cations and D600 in frog slow muscle fibers

Single, slow muscle fibers from Rana temporaria were equilibrated in normal Ringer's. 95 mmol/liter K(+)-solution containing various concentrations of Ca2+, Ni2+, Mn2+ or Mg2+ was applied, and the ensuing contractures were recorded isometrically. While peak tension (Fmax) was little affected, maintained tension (measured 1 min after onset of contracture) strongly depended on the concentration and species of divalent cations. Tension was maintained at its peak value in the presence of all species of divalent cations provided their concentrations were adequately increased. Dose-response curves were hyperbolic; Lineweaver-Burk plots revealed straight lines with different slopes intersecting near 1/Fmax, and indicating the following order of efficiency: Ni2+ greater than Ca2+ greater than Mn2+ much greater than Mg2+. Hill plots for these cations resulted in straight lines with slopes near 1. Qualitatively similar relationships were obtained with contracture solutions containing D600 (3-12 mumol/liter). However, under these conditions higher concentrations of Ca2+ or Ni2+ were required in order to fully maintain tension. After a step concentration change in the medium during contracture, the effects of Ca2+ or D600 were detectable only after a delay of 9 and 18 sec, respectively. It is concluded that divalent cations and D600 compete for the same binding site according to a 1:1 reaction. This site is presumably located inside the transverse tubular system and controls inactivation of the contractile force.

Health and ergogenic effects of caffeine

The indiscriminate use of caffeine by people of all ages may present health hazards. The public at large needs to be more informed of the presence of caffeine in commonly consumed foods and beverages, particularly by infants, children and pregnant women. It is the responsibility of all consumers to investigate the caffeine content of suspected products so that intake may be objectively monitored. Although doubts still exist about the efficacy of caffeine as an ergogenic aid, particularly for exercise of high intensity and short duration, the IOC and the National Collegiate Athletic Association of the US have adopted bans on the use of caffeine to aid sport performance. Currently, both of these organizations prohibit the concentration of caffeine in urine to exceed 15 micrograms-ml-1. That is to say, only very large amounts of caffeine are not permitted at present. Additional research is needed to confirm or deny the contraindications presented by the ingestion of caffeine on a chronic basis.

Potentiation of contraction in bullfrog ventricle strips by manganese and nickel

Sodium-lack contractures by strips of bullfrog ventricle were found to be increased in the presence of manganous ion (1-10 mM). In addition, peak force development was usually attained earlier in the presence of manganous ion and the rate of relaxation was decreased by nickel (0.7-2.0 mM), although the latter cation did not potentiate contractural force. Both manganese and nickel had only depressant effects on potassium-excess contractures, as well as on electrically stimulated twitches. Depressant effects of manganese and nickel on sodium-lack contractures were also found. These were smaller, the lower the extracellular sodium concentration and the higher the extracellular calcium concentration. When these well-known negative inotropic effects of the divalent cations were suppressed in sodium-free, calcium-rich media, their potentiating effects were unmasked, resulting in marked augmentation by these cations of potassium-excess contractures and of twitches, along with slowing of relaxation. Experimental maneuvers that have been reported to bring about entry of manganese into these cardiac cells did not increase the observed positive inotropic effect. It thus seems probable that these ions act on the membrane of the ventricle fiber. Also, in view of earlier evidence that they neither affect myofibrillar function nor induce calcium release from mitochondria, it is provisionally concluded that the mechanism of their potentiating effect on mechanical activation is due to their inhibition of calcium extrusion from the fibers, described in the accompanying paper.

Caffeine inhibition of calcium accumulation by the sarcoplasmic reticulum in mammalian skinned fibers

Oxalate-supported Ca accumulation by the sarcoplasmic reticulum (SR) of chemically skinned mammalian skeletal muscle fibers is activated by MgATP and Ca2+ and partially inhibited by caffeine. Inhibition by caffeine is greatest when Ca2+ exceeds 0.3 to 0.4 microM, when free ATP exceeds 0.8 to 1 mM, and when the inhibitor is present from the beginning of the loading period rather than when it is added after Ca oxalate has already begun to precipitate within the SR. Under the most favorable combination of these conditions, this effect of caffeine is maximal at 2.5 to 5 mM and is half-maximal at approximately 0.5 mM. For a given concentration of caffeine, inhibition decreases to one-half of its maximum value when free ATP is reduced to 0.2 to 0.3 mM. Varying free Mg2+ (0.1 to 2 mM) or MgATP (0.03 to 10 mM) has no effect on inhibition. Average residual uptake rates in the presence of 5 mM caffeine at pCa 6.4 range from 32 to 70% of the control rates in fibers from different animals. The extent of inhibition in whole-muscle homogenates is similar to that observed in skinned fibers, but further purification of SR membranes by differential centrifugation reduces their ability to respond to caffeine. In skinned fibers, caffeine does not alter the Ca2+ concentration dependence of Ca uptake (K0.5, 0.5 to 0.8 microM; Hill n, 1.5 to 2.1). Reductions in rate due to caffeine are accompanied by proportional reductions in maximum capacity of the fibers, and this configuration can be mimicked by treating fibers with the ionophore A23187. Caffeine induces a sustained release of Ca from fibers loaded with Ca oxalate. However, caffeine-induced Ca release is transient when fibers are loaded without oxalate. The effects of caffeine on rate and capacity of Ca uptake as well as the sustained and transient effects on uptake and release observed under different conditions can be accounted for by a single mode of action of caffeine: it increases Ca permeability in a limited population of SR membranes, and these membranes coexist with a population of caffeine-insensitive membranes within the same fiber.

TMB-8 can block twitches without blocking high K+ or caffeine induced contractures in frog's skeletal muscle

TMB-8 [8-(diethylamino)-octyl-3,4,5-trimethoxybenzoate] is known to inhibit calcium ion dependent processes in several tissues by stabilizing some intracellular stores of membrane-bound calcium. TMB-8 was used to study the excitation-contraction (E-C) coupling process in frog's skeletal muscle. TMB-8 (5 X 10(-5) - 10(-4) M) blocked electrically evoked twitches but not high K+ (123 mM)- or caffeine (2.36 mM)-induced contractures in isolated, curarized toe muscles. TMB-8 (10(-4) M) produced a small decrease (16%) in the action potential of frog's sartorius muscle fibres. However, reducing extracellular Na+ to 44.7 mM produced a similar reduction (17%) in action potential amplitude but did not suppress the twitch; i.e. it produced only a small increase (about 10%) in twitch amplitude. It is known that potassium contractures are produced by extracellular Ca++ ions which enter through calcium channels in the t-tubules and that caffeine produces contractures by sensitizing the sarcoplasmic reticulum to Ca++-induced Ca++ release. The present results suggest that TMB-8 blocks twitches by preventing the release of Ca++ ions bound to the intracellular surface of the t-tubular membrane which is often called the store of 'trigger-calcium' ions.

Generation of an unusual depolarizing response in rabbit primary afferent neurones in the absence of divalent cations

The effects of divalent cations on responses to 5-hydroxytryptamine (5-HT), gamma-aminobutyric acid (GABA) and 1,1-dimethyl-4-phenyl piperazinium (DMPP) were investigated using a sucrose-gap method to record population responses. In Ca-free medium responses to 5-HT were enhanced, those to DMPP depressed and those to GABA unchanged. In Mg-free medium responses to 5-HT were unchanged, while those to DMPP and GABA were depressed. Removal of both Ca and Mg from the superfusion medium caused a small reduction of GABA responses and a large reduction of DMPP responses. Responses to 5-HT were not only greatly potentiated but were changed in character; the depolarizing phase became sigmoid and the dose dependence between quantity of 5-HT and response magnitude was lost as if 5-HT were triggering an all-or-nothing phenomenon. Dose--response relationships for GABA were normal in the large majority of preparations. In about 10% of preparations, supramaximal amounts of GABA or DMPP evoked large responses of a similar character to those evoked by 5-HT. The large responses, generated by an unknown mechanism, were termed X responses. Further reduction in tissue divalent cations by EGTA (1 mM) caused X responses to be generated spontaneously. Ca, Mg, Mn or Co (1 mM) could suppress X responses. DMPP responses, reduced in Ca/Mg-free medium, were largely restored by 1 mM-Ca. Depression of GABA responses in Ca/Mg-free medium could be entirely attributed to the absence of Mg, Mn being able to substitute for Mg. X responses were generated only after equilibration for 1 h with Ca/Mg-free medium. Attempts to manipulate [Ca]i with dinitrophenol or caffeine did not produce the conditions under which X responses were generated. Intracellular records of responses to 5-HT, GABA or DMPP showed that cells with A fibres responded to GABA but not to 5-HT or DMPP. Fifty-four out of sixty-seven cells with C fibre axons (80%) were depolarized by 5-HT, thirty-seven out of forty-nine (76%) by DMPP and forty out of fifty-seven (70%) by GABA. Eighteen out of thirty-eight (47%) C cells were depolarized by all three agents. Some C cells were very sensitive to 5-HT, 10(-6) M evoking a substantial response. In most, responses to 10(-5) M-5-HT had a slower rate of rise than responses to 10(-4) or 10(-3) M-GABA or DMPP, yet lower 5-HT concentrations normally elicited X responses in sucrose-gap experiments whereas GABA or DMPP normally did not.(ABSTRACT TRUNCATED AT 400 WORDS)

Potassium contractures and mechanical activation in rat skeletal muscle: effects of multivalent cations, temperature and tetracaine

The effects of cations, temperature and tetracaine on potassium-induced contractures of rat soleus and extensor digitorus longus (e.d.l.) muscles were investigated. In the soleus, the threshold for the potassium contracture was lower (10-20 vs 20-40 mM), the peak amplitude was up to fourteen times larger, and the time course was about one half that in the e.d.l. muscle. The extent of inactivation of a test potassium contracture was directly related to the concentration of potassium in the conditioning solution and the period of exposure. Removal of calcium reduced the amplitude and time course of potassium contractures in both preparations. Addition of cobalt (10 mM) reduced the amplitude but prolonged the time course of contractures. Exposure of muscles to tetracaine (10(-5)-10(-6) M for 30 min) increased, but higher concentrations reduced, the amplitude of potassium contractures. When present for one minute, tetracaine (1 mM) moved the potassium activation curve to higher, and the potassium inactivation curve to lower, potassium concentrations.

The effects and interactions of caffeine, lignocaine and carbachol at the chick neuromuscular junction

The effects and interactions of lignocaine, carbachol and caffeine on the contractile response and endplate potential were investigated in the isolated chick biventer cervicis nerve-muscle preparation using a moving fluid electrode technique. Lignocaine (37 microM-1.8 mM) produced a dose-dependent contracture response that was not related to an endplate depolarization and appeared to inhibit non-competitively the usual depolarization and contractile response to carbachol (5.5 microM-0.8 mM). In contrast, lignocaine enhanced the contractile response to caffeine (0.54-10.8 mM) possibly by lowering the threshold and mainly by increasing the maximal response. The peak effects occurred at the same caffeine concentration regardless of the presence of lignocaine. The possibility that both lignocaine and caffeine may produce contractures in the chick muscle by acting on intracellular calcium concentration is discussed.

A possible explanation for effects of Sr2+ on contraction-relaxation cycle in canine stomach

Effects of Sr2+ on smooth muscle activity and Ca2+ movement by plasma membrane (PM) were examined in preparations isolated from canine stomach to determine how Sr2+ modulates the contraction-relaxation cycle in smooth muscle. Sr2+ caused contraction in Ca2+-free solution. In the presence of Sr2+, KCl caused a response similar to that in normal Ringer's solution, this contraction was inhibited by both nitroprusside and verapamil. Sr2+ inhibited Ca2+ uptake by PM in the presence and absence of ATP. Release of Ca2+ from loaded PM vesicles was accelerated by Sr2+. Results suggest that Sr2+ could replace Ca2+ in Ca2+ binding sites in the cell.

Methylxanthines stimulate calcium transport and inhibit cyclic nucleotide phosphodiesterases in abalone sperm

Experiments were designed to determine the mechanism by which methylxanthines elevate abalone sperm cAMP concentrations and induce the acrosome reaction (AR). Theophylline or, more effectively, 1-methyl-3-isobutylxanthine (MIX) inhibit the cyclic nucleotide phosphodiesterase activities of abalone sperm homogenates. 45Ca2+ uptake by sperm is also stimulated by theophylline, and more effectively by MIX, and this stimulatory effect is blocked by KCN. Verapamil, a compound known to antagonize Ca2+ conductance, has no effect on the Ca2+ or MIX-induced cAMP elevation at concentrations up to 200 microM. However, verapamil reduces the sperm cAMP elevation caused by the addition of Ca2+ plus MIX. This inhibition is not complete, even at 200 microM verapamil. The AR induced by Ca2+ plus MIX is completely inhibited by 200 microM verapamil. The data suggest that these methylxanthines elevate abalone sperm cyclic nucleotide concentrations by inhibiting cyclic nucleotide phosphodiesterase activities. Furthermore, since sperm cAMP metabolism is modulated by Ca2+ flux, methylxanthines also appear to elevate abalone sperm cAMP concentrations by their effects on Ca2+ transport. The Ca2+-induced cAMP elevation occurs through a verapamil-insensitive mechanism, whereas the potentiation by MIX of the Ca2+ effect to elevate cAMP occurs through both verapamil-insensitive and -sensitive mechanisms. The methylxanthine-induced AR is mediated by a primary effect on Ca2+ transport and occurs through a verapamil-sensitive mechanism. Cyclic AMP may play a role in the methylxanthine-induced AR, but does not appear to act as the primary mediator of this exocytotic event.

Regulation of abalone sperm cyclic AMP concentrations and the acrosome reaction by calcium and methylxanthines

When Ca2+ is added to abalone sperm (Haliotis rufescens) in Ca2+-free artificial seawater (CaFASW) to a final concentration of 9.6 mM a 4-fold elevation in sperm cAMP occurs within 15-30 sec. The methylxanthines, theophylline and 1-methyl-3-isobutylxanthine (MIX), also elevate sperm cAMP concentrations. In CaFASW, either compound causes up to a 3-fold increase in cAMP within 15-30 sec. MIX (150 microM), added to sperm in the presence of 9.6 mM Ca2+, elevates sperm cAMP 100-fold within 15-30 sec and also triggers the acrosome reaction (AR) in the same period. Under identical conditions theophylline (1.67 mM) is much less potent at elevating cAMP and inducing the AR. The effects of methylxanthines on cAMP of sperm incubated in the presence of Ca2+ appear to represent a potentiation by these compounds of the action of Ca2+. Neither compound induces the AR in the absence of Ca2+. All of the observed effects on sperm cAMP and the AR are dependent on Ca2+ and methylxanthine concentrations. Added cyclic nucleotides or their derivatives do not induce the AR in either the absence or presence of Ca2+. Experiments with isolated sperm heads and flagella indicate that the dramatic stimulatory response of sperm cAMP to Ca2+ plus MIX is present in the head region (acrosome, nucleus, midpiece) of the cell. The data suggest that the dramatic elevation of cAMP by MIX in the presence of Ca2+ may occur directly by an inhibition of phosphodiesterase activity and indirectly by an increase in cellular Ca2+. A strong temporal correlation between the cAMP elevation and the abalone AR exists, although cAMP elevation by itself does not act as the primary mediator of this exocytotic event.

Effects of divalent and lanthanide ions on motility initiation in rat caudal epididymal spermatozoa

1 Sperm motility initiation of rat caudal epididymal spermatozoa in vitro has been studied.2 Spermatozoa flushed out from the cauda epididymis with a sodium-free medium exhibited a transient motility which decreased progressively. At 40 min, the forward motility was completely suppressed. However, if they were resuspended in a sodium containing medium their motility was completely restored to normal within 15 min.3 This initiation of sperm motility required the presence of extracellular calcium. Maximal stimulation was obtained at a calcium concentration of 10(-3)M. Above this concentration, further increase in calcium produced a fall in motility and at 10(-2)M, motility initiation was completely suppressed.4 The initiation of sperm motility has been shown to depend closely on sodium. Sperm motility initiation alters in a curvilinear fashion with extracellular sodium concentration showing saturation kinetics. High calcium (above 10(-3)M) was found to depress motility initiation induced by sodium, without affecting the apparent affinity constant for sodium.5 The effect of Ca(2+) on sperm motility initiation could be mimicked by Sr(2+) but not by Mg(2+), La(3+) or Eu(3+).6 In the presence of extracellular calcium (1.27 or 2.54 mM), La(3+) and Eu(3+) exerted a dose-dependent inhibition of sperm motility initiation. The IC(50) values for both ions were about 5 x 10(-5)M.7 The possible mechanism of inhibition by lanthanide ions is discussed.

Nickel substitution for calcium and the time course of potassium contractures of single muscle fibres

In the virtual absence of external calcium (10(-9) M), peak tension of potassium contractures is not affected but their time course is markedly reduced. At 22 degrees C, the tension-time integral (area) of K+-contractures is reduced to about half its normal value. A similar reduction in the area of K+-contractures is observed when [Ca2+]0 is reduced to about 100 muM or less. When nickel substitutes for external calcium, K+-contractures present a normal time-course. Since nickel has been shown not to interact with contractile proteins these results indicate that extracellular calcium is apparently not directly participating in contractile activation nor in sustaining the time course of K+-contractures. External calcium deprivation affects also other phenomena related to excitation contraction coupling (ECC), such as the isometric tension-voltage relationship, the time course and extent of contractile repriming after a test contracture, the steady-state inactivation curve, and the capacity to sustain multiple contractures. Some of these effects indicate that external calcium may have a regulatory role on ECC phenomena. Nickel is an effective substitute for calcium in all these phenomena. The numerous contractures that a fibre can develop in the absence of calcium (nickel-substituted) indicate that the sarcoplasmic reticulum has either a large store of contractile activator, or a large recycling capacity.

Comparison of the effects of caffeine and a 2-alkyl-1,2,3-benzotriazinium iodide on frog rectus abdominis

1 The mode of action of 2-n-propyl-4-p-tolylamino-1,2,3-benzotriazinium iodide (TnPBI), which induced contractures of frog rectus abdominis muscle, was investigated. 2 TnPBI caused contractures of frog rectus abdominis when the muscle had been depolarized with potassium chloride. 3 Experiments with TnPBI and caffeine in calcium-free Ringer suggested that both compounds produce contractures by releasing intracellular bound calcium. 4 It is suggested that at least two calcium stores are involved, one of which is sensitive to caffeine while both are sensitive to TnPBI.

Physostigmine-induced contractures in frog skeletal muscle

Physostigmine in 15 mM concentration at pH 8.4 produces reversible contractures of up to 0.3 Po tension output in frog's whole toe muscle or in 7-10 fiber bundles of these muscles, At pH 7.2, the 15 mM physostigmine contracture output is only about 0.10 Po. The 15 mM, pH 8.4 contractures are essentially unaffected by lack of external Ca2+, complete depolarization of the fibers, detubulation by glycerol treatment, and 0 degrees C ambient temperature. These results and other evidence indicate that physostigmine produces contracture by directly releasing activator Ca2+ from the sarcoplasmic reticulum (SR). Pretreatment of muscles with 4 mM procaine reduces physostigmine's capacity to produce contracture, evidently by means of a competitive inhibition at SR sites. The above results indicate similarities between physostagmine and caffeine contractures. But the physostigmine action differs in that it is reversible, and, especially, it lacks the ability, strongly characteristic of caffeine, to sensitize a muscle to produce a rapid cooling contracture. The internal action of physostigmine requires that it be permeant, and, since it is a weak base (pKa = 8.2), this property is provided by its uncharged base. But, once internal, where the pH = 6.8, most of the drug will be protonated and it may act on the SR in this form, in contrast with caffeine which, since its pKa is about 1.0, acts on the SR as uncharged base.

The effect of caffeine and tetracaine on the time course of potassium contractures of single muscle fibres

1. The time course of potassium contractures can be significantly prolonged by low concentrations of caffeine. 2. This effect of caffeine is not due to impairment of the fibre relaxing system. 3. Under conditions were contractile repriming is delayed (low temperature) an extra amount of activator can be released by caffeine, in addition to that released by potassium. 4. The source of this extra amount of activator is intracellular since its release can be shown in a O calcium EGTA medium. 5. Local anaesthetics, tetracaine, and to a lesser extent procaine, affect the release of contractile activator, without impairing the contractile machinery itself. 6. The results of the present paper support the view that the time course of potassium contracture is controlled by a membrane mechanism which is activated upon depolarization and later inactivates with time. 7. The effect of caffeine and local anaesthetics can be explained by assuming that the former prolongs the inactivation time course while the latter shortens it.

Effects of methylxanthines and imidazole on the contractions of guinea-pig ileum induced by transmural stimulation

Methylxanthines (10(-5) to 10(-3)M) were found to increase the amplitude of contractions of guinea-pig ileum induced by transmural stimulation but to inhibit those induced by acetylcholine or histamine. The order of the abilities of methylxanthines to augment the contractile responses was theobromine greater than caffeine greater than theophylline. When the contractions were completely suppressed by reduction of the calcium content in the medium or by addition of cyclic AMP, methylxanthines restored the responses effectively, just as does addition of calcium. Methylxanthines also accelerated the release of acetylcholine from the ileum associated with stimulation. Imidazole (3 X 10(-5) to 10(-3) M) had an essentially similar effect to methylxanthines in potentiating the contractile responses and in augmenting the release of acetylcholine. The present results indicate that the potentiating effects of methylxanthines and imidazole are due to an action on the nerve terminals, not on the postsynaptic membranes or contractile elements. Therefore, it si concluded that theit potentiating actions are due to facilitation of the movement of calcium in the nerve terminals on excitation, resulting in increased release of acetylcholine, and are not due to the effect of cyclic AMP formed as a result of their inhibitory actions on phosphodiesterase.

Some electrical and mechanical effects of strontium on toad ventricular muscle: comparison to calcium

1. The mechanical and electrophysiological effects of Sr were evaluated and compared to those of Ca in isolated, electrically driven toad ventricular muscle strips. The effects of Ca and Sr were compared at concentrations from control (2 mM) to 10 mM either by substitution of Sr for Ca at equimolar concentration, or by maintenance of a constant total Ca plus Sr concentration within which individual Ca and Sr concentrations were varied. 2. Changes in the degree of contractile activation were evaluated in terms of changes in maximal dT/dt of isometric contractions, maximal dL/dt of very lightly loaded isotonic contractions, and the shape of after-loaded force-velocity curves, with specific attention directed to the shape of the curves as they approached Vmax on the velocity axis. Effects on the cell membrane were evaluated in terms of changes in the transmembrane action potential (recorded with glass micro-electrodes) and in the mechanical parameters directly related to its duration in amphibian ventricle, viz. the duration of isometric tension and of isotonic shortening. Isometric tension and action potentials were recorded simultaneously. 3. Ca and Sr, at concentrations above control, had similar but not identical effects on dT/dt and dL/dt. Both ions alone in equimolar concentrations, or together at constant total Ca plus Sr concentration, increased dT/dt and dL/dt and shifted force-velocity curves upward. At constant total Ca plus Sr concentration, force-velocity curves were virtually superimposable as they approached the velocity intercept. 4. The duration of the action potential was markedly prolonged by Sr and shortened by Ca in concentrations above control. Unlike dT/dt and dL/dt, the total duration of isometric tension and isotonic shortening depended upon the specific Ca and Sr concentrations within a constant total concentration, and were progressively prolonged as the Sr concentration was increased. 5. The similar effects of Ca and Sr on dT/dt, dL/dt, and on the force-velocity relationship at light loads depended upon the presence of Ca ions. In Sr alone, dT/dt and dL/dt were faster than in an equimolar concentration of Ca, and time to maximal dT/dt and dL/dt was prolonged. The force-velocity curve in Sr alone was consistently shifted upward beyond the other curves in which Ca was present. These differences between the two ions are attributed in part to the rapid and early repolarization of the action potential in elevated Ca and the resultant abbreviation of the build up in active state and slower dT/dt and dL/dt. 6. The results suggest that Ca and Sr act in a similar although not identical way in activating contraction but are competitive at the cell membrane.