Direct inhibition of chicken gizzard smooth muscle contractile apparatus by caffeine

Antispasmodic Activity of Light-Roasted Coffee Extract and Its Potential Use in Gastrointestinal Motility Disorders

Antispasmodic agents are crucial in managing gastrointestinal motility disorders by modulating muscle contractions and reducing symptoms like cramping and diarrhea. This study investigated the antispasmodic potential of different coffee bean extracts, including light coffee (LC), medium coffee (MC), and dark coffee (DC), on ileum contractions induced by potassium chloride (KCl), and elucidated their mechanisms of action using in vitro isolated tissue techniques. The results demonstrated that all coffee extracts reduced spontaneous contractions of rat ileum tissue in a dose-dependent manner. Among these, LC showed the most significant reduction in ileum contractions, particularly at higher concentrations. The key findings reveal that LC at 5 mg/mL significantly reduced CaCl2-induced contractions in isolated rat ileum tissue, indicating that LC may inhibit calcium influx or interfere with calcium signaling pathways. The presence of nifedipine, propranolol, and N-nitro-L-arginine methyl ester (L-NAME) have been confirmed in their involvement; they block calcium influx and calcium channels and activate β-adrenergic pathways as part of LC's mechanism of action. The presence of their active compounds, particularly chlorogenic acid and caffeine, likely contributes to the observed antispasmodic effects. These findings suggest that LC exerts its antispasmodic effects by targeting key mechanisms involved in muscle spasms and intestinal motility, providing a potential for managing such conditions.

Characterisation of Lipoma-Preferred Partner as a Novel Mechanotransducer in Vascular Smooth Muscle Cells

In arteries and arterioles, a chronic increase in blood pressure raises wall tension. This continuous biomechanical strain causes a change in gene expression in vascular smooth muscle cells (VSMCs) that may lead to pathological changes. Here we have characterised the functional properties of lipoma-preferred partner (LPP), a Lin11-Isl1-Mec3 (LIM)-domain protein, which is most closely related to the mechanotransducer zyxin but selectively expressed by smooth muscle cells, including VSMCs in adult mice. VSMCs isolated from the aorta of LPP knockout (LPP-KO) mice displayed a higher rate of proliferation than their wildtype (WT) counterparts, and when cultured as three-dimensional spheroids, they revealed a higher expression of the proliferation marker Ki 67 and showed greater invasion into a collagen gel. Accordingly, the gelatinase activity was increased in LPP-KO but not WT spheroids. The LPP-KO spheroids adhering to the collagen gel responded with decreased contraction to potassium chloride. The relaxation response to caffeine and norepinephrine was also smaller in the LPP-KO spheroids than in their WT counterparts. The overexpression of zyxin in LPP-KO VSMCs resulted in a reversal to a more quiescent differentiated phenotype. In native VSMCs, i.e., in isolated perfused segments of the mesenteric artery (MA), the contractile responses of LPP-KO segments to potassium chloride, phenylephrine or endothelin-1 did not vary from those in isolated perfused WT segments. In contrast, the myogenic response of LPP-KO MA segments was significantly attenuated while zyxin-deficient MA segments displayed a normal myogenic response. We propose that LPP, which we found to be expressed solely in the medial layer of different arteries from adult mice, may play an important role in controlling the quiescent contractile phenotype of VSMCs.

Using transcriptomics, proteomics and phosphoproteomics as new approach methodology (NAM) to define biological responses for chemical safety assessment

Omic-based technologies are of particular interest and importance for hazard identification and health risk characterization of chemicals. Their application in the new approach methodologies (NAMs) anchored on cellular toxicity pathways is based on the premise that any apical health endpoint change must be underpinned by some alterations at the omic levels. In the present study we examined the cellular responses to two chemicals, caffeine and coumarin, by generating and integrating multi-omic data from multi-dose and multi-time point transcriptomic, proteomic and phosphoproteomic experiments. We showed that the methodology presented here was able to capture the complete chain of events from the first chemical-induced changes at the phosphoproteome level, to changes in gene expression, and lastly to changes in protein abundance, each with vastly different points of departure (PODs). In HepG2 cells we found that the metabolism of lipids and general cellular stress response to be the dominant biological processes in response to caffeine and coumarin exposure, respectively. The phosphoproteomic changes were detected early in time, at very low doses and provided a fast, adaptive cellular response to chemical exposure with 7-37-fold lower points of departure comparing to the transcriptomics. Changes in protein abundance were found much less frequently than transcriptomic changes. While challenges remain, our study provides strong and novel evidence supporting the notion that these three omic technologies can be used in an integrated manner to facilitate a more complete understanding of pathway perturbations and POD determinations for risk assessment of chemical exposures.

Pu-Erh Tea Relaxes the Thoracic Aorta of Rats by Reducing Intracellular Calcium

Previous studies suggested that pu-erh tea aqueous extract could lower blood pressure and ameliorate hypertension symptoms. However, the antihypertension mechanisms of pu-erh tea remain unclear. In this work, the direct effects of pu-erh tea on vessels and cells were investigated by detecting isometric tension and intracellular calcium ([Ca²⁺]_i), respectively. Additionally, to identify the main active components, the aqueous extract of pu-erh was separated by organic solvents to obtain various fractions, and the effects of these fractions on arteries were assessed. The results showed that pu-erh aqueous extract vasodilated rat thoracic aortas preconstricted by phenylephrine or KCl. These vasodilation effects were not significantly affected by the removal of the endothelium or by preincubation with potassium channel blockers (tetraethylammonium, glibenclamide, aminopyridine, or barium chloride). Moreover, pu-erh aqueous extract could reduce the vessel contractibility induced by CaCl₂ and phenylephrine under KCl-depolarizing or Ca²⁺-free buffer conditions, respectively. Furthermore, pu-erh aqueous extract attenuated the KCl-induced increase in [Ca²⁺]_i in cultured rat aortic smooth muscle A7r5 cells. In addition, the chloroform precipitate of pu-erh aqueous extract produced the most potent vasodilation. Theabrownins (the characteristic components of pu-erh tea) accounted for 41.91 ± 1.09 % of the chloroform precipitate and vasodilated arteries in an endothelium-independent manner. In addition, the vasodilation effect of caffeine was verified. In conclusion, theabrownins and caffeine should be the two main active components in pu-erh tea. Pu-erh aqueous extract vasodilated arteries in an endothelium-independent manner, which might partly be attributed to the decrease in extracellular Ca²⁺ influx. Moreover, our study provided data on the potential mechanism of the hypotensive actions of pu-erh tea, which might improve our understanding of the effect of pu-erh tea on the prevention and treatment of hypertension.

Coffee and Endothelial Function: A Coffee Paradox?

Coffee is a popular beverage throughout the world. Coffee contains various chemical compounds (e.g., caffeine, chlorogenic acids, hydroxyhydroquinone, kahweol, cafestol, and complex chemical mixtures). Caffeine is also the most widely consumed pharmacological substance in the world and is included in various beverages (e.g., coffee, tea, soft drinks, and energy drinks), products containing chocolate, and drugs. The effects of coffee and caffeine on cardiovascular diseases remain controversial. It is well known that there are J-curve-type or U-curve-type associations of coffee consumption with cardiovascular events including myocardial infarction and stroke. However, there is little information on the direct and indirect effects of coffee consumption on endothelial function in humans. It is likely that the coffee paradox or caffeine paradox exists the association of coffee intake with cardiovascular diseases, cardiovascular outcomes, and endothelial function. This review focusses on the effects of coffee and caffeine on endothelial function from molecular mechanisms to clinical perspectives.

Phenylephrine, a common cold remedy active ingredient, suppresses uterine contractions through cAMP signalling

Regulation of uterine contractility is an important aspect of women’s health. Phenylephrine, a selective agonist of the α₁-adrenoceptor and a potent smooth muscle constrictor, is widely used in women even during pregnancy to relieve cold-related symptoms, to treat postpartum haemorrhoid, and during routine eye exams. We performed isometric tension recordings to investigate the effect of phenylephrine on mouse uterine contractility. Phenylephrine decreased spontaneous and oxytocin-induced contractions in non-pregnant mouse uterine rings and strips with an IC₅₀ of ~1 μM. Prazosin, an inhibitor of α₁-adrenoceptor, did not prevent phenylephrine-mediated relaxations. Conversely, ICI118551, an antagonist of β2-adrenoceptors, inhibited phenylephrine relaxation. In the presence of ICI118551, high concentrations (>30 μM) of phenylephrine caused mouse uterine contractions, suggesting that β-adrenoceptor-mediated inhibition interferes with the phenylephrine contractile potential. Phenylephrine-dependent relaxation was reduced in the uterus of pregnant mice. We used primary mouse and human uterine smooth muscle cells (M/HUSMC) to establish the underlying mechanisms. Phenylephrine stimulated large increases in intracellular cAMP in M/HUSMCs. These cAMP transients were decreased when HUSMCs were cultured in the presence of oestrogen and progesterone to mimic the pregnancy milieu. Thus, phenylephrine is a strong relaxant in the non-pregnant mouse uterus, but exhibits diminished effect in the pregnant uterus.

Endothelial Nitric Oxide Mediates Caffeine Antagonism of Alcohol-Induced Cerebral Artery Constriction

Despite preventive education, the combined consumption of alcohol and caffeine (particularly from "energy drinks") continues to rise. Physiologic perturbations by separate intake of ethanol and caffeine have been widely documented. However, the biologic actions of the alcohol-caffeine combination and their underlying subcellular mechanisms have been scarcely studied. Using intravital microscopy on a closed-cranial window and isolated, pressurized vessels, we investigated the in vivo and in vitro action of ethanol-caffeine mixtures on cerebral arteries from rats and mice, widely recognized models to address cerebrovascular pathophysiology and pharmacology. Caffeine at concentrations found in human circulation after ingestion of one to two cups of coffee (10 µM) antagonized the endothelium-independent constriction of cerebral arteries evoked by ethanol concentrations found in blood during moderate-heavy alcohol intoxication (40-70 mM). Caffeine antagonism against alcohol was similar whether evaluated in vivo or in vitro, suggesting independence of systemic factors and drug metabolism, but required a functional endothelium. Moreover, caffeine protection against alcohol increased nitric oxide (NO•) levels over those found in the presence of ethanol alone, disappeared upon blocking NO• synthase, and could not be detected in pressurized cerebral arteries from endothelial nitric-oxide synthase knockout (eNOS(-/-)) mice. Finally, incubation of de-endothelialized cerebral arteries with the NO• donor sodium nitroprusside (10 µM) fully restored the protective effect of caffeine. This study demonstrates for the first time that caffeine antagonizes ethanol-induced cerebral artery constriction and identifies endothelial NO• as the critical caffeine effector on smooth muscle targets. Conceivably, situations that perturb endothelial function and/or NO• availability will critically alter caffeine antagonism of alcohol-induced cerebrovascular constriction without significantly disrupting endothelium-independent, alcohol-induced cerebral artery constriction itself.

Caffeine relaxes smooth muscle through actin depolymerization

Caffeine is sometimes used in cell physiological studies to release internally stored Ca(2+). We obtained evidence that caffeine may also act through a different mechanism that has not been previously described and sought to examine this in greater detail. We ruled out a role for phosphodiesterase (PDE) inhibition, since the effect was 1) not reversed by inhibiting PKA or adenylate cyclase; 2) not exacerbated by inhibiting PDE4; and 3) not mimicked by submillimolar caffeine nor theophylline, both of which are sufficient to inhibit PDE. Although caffeine is an agonist of bitter taste receptors, which in turn mediate bronchodilation, its relaxant effect was not mimicked by quinine. After permeabilizing the membrane using β-escin and depleting the internal Ca(2+) store using A23187, we found that 10 mM caffeine reversed tone evoked by direct application of Ca(2+), suggesting it functionally antagonizes the contractile apparatus. Using a variety of molecular techniques, we found that caffeine did not affect phosphorylation of myosin light chain (MLC) by MLC kinase, actin-filament motility catalyzed by MLC kinase, phosphorylation of CPI-17 by either protein kinase C or RhoA kinase, nor the activity of MLC-phosphatase. However, we did obtain evidence that caffeine decreased actin filament binding to phosphorylated myosin heads and increased the ratio of globular to filamentous actin in precontracted tissues. We conclude that, in addition to its other non-RyR targets, caffeine also interferes with actin function (decreased binding by myosin, possibly with depolymerization), an effect that should be borne in mind in studies using caffeine to probe excitation-contraction coupling in smooth muscle.

Caffeine's Vascular Mechanisms of Action

Caffeine is the most widely consumed stimulating substance in the world. It is found in coffee, tea, soft drinks, chocolate, and many medications. Caffeine is a xanthine with various effects and mechanisms of action in vascular tissue. In endothelial cells, it increases intracellular calcium stimulating the production of nitric oxide through the expression of the endothelial nitric oxide synthase enzyme. Nitric oxide is diffused to the vascular smooth muscle cell to produce vasodilation. In vascular smooth muscle cells its effect is predominantly a competitive inhibition of phosphodiesterase, producing an accumulation of cAMP and vasodilation. In addition, it blocks the adenosine receptors present in the vascular tissue to produce vasoconstriction. In this paper the main mechanisms of action of caffeine on the vascular tissue are described, in which it is shown that caffeine has some cardiovascular properties and effects which could be considered beneficial.

High K+-induced contraction requires depolarization-induced Ca2+ release from internal stores in rat gut smooth muscle

AIM

Depolarization-induced contraction of smooth muscle is thought to be mediated by Ca2+ influx through voltage-gated L-type Ca2+channels. We describe a novel contraction mechanism that is independent of Ca2+ entry.

METHODS

Pharmacological experiments were carried out on isolated rat gut longitudinal smooth muscle preparations, measuring isometric contraction strength upon high K+-induced depolarization.

RESULTS

Treatment with verapamil, which presumably leads to a conformational change in the channel, completely abolished K+-induced contraction, while residual contraction still occurred when Ca2+ entry was blocked with Cd2+. These results were further confirmed by measuring intracellular Ca2+ transients using Fura-2. Co-application of Cd2+ and the ryanodine receptor blocker DHBP further reduced contraction, albeit incompletely. Additional blockage of either phospholipase C (U 73122) or inositol 1,4,5-trisphophate (IP3)receptors (2-APB) abolished most contractions, while sole application of these blockers and Cd2+ (without parallel ryanodine receptor manipulation) also resulted in incomplete contraction block.

CONCLUSION

We conclude that there are parallel mechanisms of depolarization-induced smooth muscle contraction via (a) Ca2+ entry and (b) Ca2+ entry-independent, depolarization-induced Ca2+-release through ryanodine receptors and IP3, with the latter being dependent on phospholipase C activation.

F-actin-based Ca signaling-a critical comparison with the current concept of Ca signaling

A short comparative survey on the current idea of Ca signaling and the alternative concept of F-actin-based Ca signaling is given. The two hypotheses differ in one central aspect, the mechanism of Ca storage. The current theory rests on the assumption of Ca-accumulating endoplasmic/sarcoplasmic reticulum-derived vesicles equipped with an ATP-dependent Ca pump and IP3- or ryanodine-sensitive channel-receptors for Ca-release. The alternative hypothesis proceeds from the idea of Ca storage at the high-affinity binding sites of actin filaments. Cellular sites of F-actin-based Ca storage are microvilli and the submembrane cytoskeleton. Several specific features of Ca signaling such as store-channel coupling, quantal Ca release, spiking and oscillations, biphasic and "phasic" uptake kinetics, and Ca-induced Ca release (CICR), which are not adequately described by the current concept, are inherent properties of the F-actin system and its dynamic state of treadmilling.

Cicletanine-induced decreases in cytosolic Ca2+ level and contraction in vascular smooth muscle

The mechanism by which cicletanine (3-(4-chlorophenyl)-1,3-dihydro-7-hydroxy-6-methylfuro-[3,4-c]pyri dine) induces vasodilatation was examined in isolated vascular smooth muscle. Cicletanine inhibited the contraction induced by high K+, norepinephrine (NE) and prostaglandin F2alpha in a concentration-dependent manner in rat aorta. High K+ (15.8-72.7 mM) elicited elevation of cytosolic Ca2+ level ([Ca2+]i) and contraction in a concentration-dependent manner. Cicletanine (300 microM) inhibited the high K+-induced contractions without changing the [Ca2+]i/tension relationship. NE (3-300 nM) elicited greater contractions than high K+ at a given [Ca2+]i, suggesting that NE increased Ca2+ sensitivity of the contractile elements. Cicletanine inhibited the NE-induced contractions without changing the slope of the [Ca2+]i/tension relationship. Cicletanine inhibited the transient increases in both [Ca2+]i and muscle tension elicited by NE but not the transient increase in [Ca2+]i elicited by caffeine in Ca2+-free solution. Cicletanine did not inhibit contraction induced by Ca2+ in the permeabilized rabbit mesenteric artery with alpha-toxin. These results suggest that cicletanine inhibits vascular smooth muscle contraction by multiple mechanisms: 1) inhibition of Ca2+ influx via voltage-dependent Ca2+ channel and 2) inhibition of Ca2+ release mediated by the alpha-adrenoceptors, but not by caffeine.

Possible mechanism of the potent vasoconstrictor responses to ryanodine in dog cerebral arteries

Isolated cerebral (basilar, posterior communicating and middle cerebral) arteries exist in a partially contracted state. To determine the Ca(2+)-buffering function of sarcoplasmic reticulum in the resting state of cerebral arteries, the effects of ryanodine that eliminates the function of sarcoplasmic reticulum, on tension and cellular Ca2+ level were compared in endothelium-denuded strips of the cerebral, coronary and mesenteric arteries of the dog. The addition of ryanodine to strips with basal tone caused a concentration-dependent contraction, which was significantly greater in the cerebral arteries than in the mesenteric or coronary artery. In the presence of 10(-5) M ryanodine, the caffeine (20 mM)-induced contraction was greatly attenuated in these arteries. After washout, the basal tone was greatly elevated in the cerebral arteries. The elevated tone was abolished by 10(-7) M nifedipine. The ryanodine-induced contractions were also abolished by 10(-7) M nifedipine. Nifedipine itself caused a relaxation from the basal tone in the cerebral arteries, suggesting the maintenance of myogenic tone. The basal Ca2+ influx in arteries measured after a 5-min incubation with 45Ca was significantly higher in the basilar artery than in the mesenteric artery. The basal Ca2+ influx was not increased by 10(-5) M ryanodine in either artery. The basal Ca2+ influx was decreased by 10(-7) M nifedipine in the basilar artery, but was unchanged in the mesenteric artery. These results suggest that: (1) the basal Ca2+ influx via L-type voltage-dependent Ca2+ channels was higher in the resting state of the cerebral arteries; (2) the greater part of the higher Ca2+ influx was buffered by Ca2+ uptake into the sarcoplasmic reticulum; and (3) therefore the functional elimination of sarcoplasmic reticulum by ryanodine caused a potent contraction in these arteries. Furthermore, the maintenance of myogenic tone in the cerebral arteries suggests that more Ca2+ enters the smooth muscle cell than the buffering ability of sarcoplasmic reticulum can handle.

Possible mechanism of the potent vasoconstrictor actions of ryanodine on femoral arteries from spontaneously hypertensive rats

1. The Ca2+ buffering function of sarcoplasmic reticulum (SR) in the resting state of arteries from spontaneously hypertensive rats (SHR) was examined. Differences in the effects of ryanodine that removes the function of SR, on tension and cellular Ca2+ level were assessed in endothelium-denuded strips of femoral arteries from 13-week-old SHR and normotensive Wistar-Kyoto rats (WKY). 2. The addition of ryanodine to the resting strips caused a concentration-dependent contraction in SHR. This contraction was extremely small in WKY. In the presence of 10(-5) M ryanodine, caffeine (20 mM) failed to cause a further contraction in SHR, but it caused a small contraction in WKY. After washout of the strips with a Krebs solution, the resting tone was greatly elevated in SHR when compared with WKY. 3. The elevated resting tone in SHR strips was abolished by 10(-7) M nifedipine. The ryanodine-induced contraction was also abolished by 10(-7) M nifedipine. Nifedipine itself caused a relaxation from the resting tone of SHR strips, suggesting the maintenance of myogenic tone. 4. In strips preloaded with fura-PE3, the addition of 10(-5) M ryanodine caused a large and moderate elevation of cytosolic Ca2+ level ([Ca2+]i) in SHR and WKY, respectively. After washout, the resting [Ca2+]i was greatly elevated in SHR. The ryanodine-induced elevation of [Ca2+]i was decreased by 5 x 10(-6) M verapamil in SHR. Verapamil itself caused a decrease in resting [Ca2+]i which was significantly greater in SHR than in WKY, and caused a relaxation only in SHR. 5. The resting Ca2+ influx in arteries measured by a 5 min incubation with 45Ca was significantly increased in SHR when compared with WKY. The resting Ca2+ influx was not increased by 10(-5) M ryanodine in both SHR and WKY. The net cellular Ca2+ uptake in arteries measured by a 30 min incubation with 45Ca was decreased by 10(-5) M ryanodine in both strains. 6. The resting Ca2+ influx was decreased by 10(-7) M nifedipine in the SHR artery, but it was unchanged in the WKY artery. 7. These results suggest that (1) the Ca2+ influx via L-type voltage-dependent Ca2+ channels was increased in the resting state of the SHR femoral artery, (2) the greater part of the increased Ca2+ influx was buffered by Ca2+ uptake into the SR and some Ca2+ reached the myofilaments resulting in the maintenance of the myogenic tone, and (3) therefore the functional removal of SR by ryanodine caused a potent contraction in this artery.

Effects of phenol on vascular smooth muscle in rabbit mesenteric resistance arteries

Although phenol has long been used clinically as a neurolytic agent or as a preservative for injections, little information is available regarding its direct vascular action. We therefore studied the effects of phenol (0.1 μM-2mM) on isolated rabbit small mesenteric arteries, using isometric tension recording methods. All experiments were performed on endothelium-denuded strips. Phenol (≥10 μM) generated transsient contractions in a concentration-dependent manner in both normal Krebs and Ca(2+)-free solutions with EC50 values (concentrations that produced 50% of the maximal response) of 39.8 μM and 99.7 μM, respectively. Depletion of intracellular Ca(2+) stores by A23187 or ryanodine completely elimited the phenol-induced contractions. When caffeine (10 mM) and noradrenaline (NA, 10μM) were consecutively applied in Ca(2+)-free solution with an interval of 7 min (sufficient to prevent caffeine-induced inhibition of Ca(2+) sensitivity), caffeine eliminated the contractions induced by subsequent application of NA. In similar experiments where phenol (1 mM) and NA (10 μM) were consecutively applied in Ca(2+)-free solution, phenol significantly inhibited contractions induced by subsequent application of NA. Phenol (0.1 mM, ∼EC65), applied in the presence of either 128 mM K(+) or NA (10 μM), produced transient vasoconstrictions superimposed on both high K(+)-and NA-induced contractions, but had a lesser effect on maintenance of these contractions. The vascular responses to high K(+), NA, and caffeine after washout of phenol were not significantly different from those before application of phenol (up to 2 mM). The results suggest that phenol stimulates Ca(2+) release from intracellular Ca(2+) stores, which are sensitive to both caffine and NA in this resistance artery. The effect does not appear to reflect a toxic effect on vascular smooth muscle. It seems unlikely that phenol causes adverse hemodynamic changes because of the observed direct vascular action.

Focal [Ca2+]i increases detected by aequorin but not by fura-2 in histamine- and caffeine-stimulated swine carotid artery

1. We hypothesized that the homogeneity of intracellular [Ca2+] ([Ca2+]i) varies and is regulated in arterial smooth muscle. 2. We evaluated this hypothesis by exploiting the different characteristics of several [Ca2+]i indicators: (1) aequorin, which theoretically can measure focal increases in [Ca2+]i, (2) fura-2, which is predominantly a measure of mean cytoplasmic [Ca2+], and (3) myosin light chain phosphorylation and force, which reflect increases in [Ca2+] near the contractile apparatus. 3. From the differences in the observed aequorin and fura-2 signals, we developed an index of the relative degree of [Ca2+]i homogeneity as the ratio of the aequorin signal and fura-2 signal. 4. Stimulation with intermediate concentrations of histamine (1 and 10 microM) or high [K+]o (25 and 40 mM) increased [Ca2+]i and contractile stress. Relative [Ca2+]i homogeneity, estimated from the aequorin/fura-2 ratio, remained similar to levels observed in unstimulated tissues. 5. Higher concentrations of histamine (100 microM) also increased [Ca2+]i and stress, but the aequorin/fura 2 ratio declined , indicating increased [Ca2+]i homogeneity. Similarly, the aequorin/fura-2 ratio decreased when extracellular Ca2+ was removed. 6. Stimulation with histamine in low extracellular [Ca2+] transiently increased [Ca2+]i and the aequorin/fura-2 ratio. Similarly, in tissues treated with low extracellular [Ca2+], restoration of extracellular Ca2+ transiently increased both [Ca2+]i and the aequorin/fura-2 ratio. Although both of these experiments demonstrated a transient decrease in [Ca2+]i homogeneity, only histamine stimulation led to increased myosin light chain phosphorylation and force. These results indicate that the focal increases in [Ca2+]i observed with histamine stimulation and Ca2+ restoration occurred in different cellular regions. 7. Addition of caffeine (20 mM) increased [Ca2+]i and [cAMP], but this was not accompanied by sustained increased myosin light chain phosphorylation or contraction. Phosphorylation of myosin light chain kinase did not appear to underlie the lack of increase in myosin light chain phosphorylation. Rather, caffeine induced a sustained increase in the aequorin/fura-2 ratio, suggesting that caffeine inhibits smooth muscle contraction by localizing increases in [Ca2+]i to a region distant from the contractile apparatus. 8. These data suggest that there can be transient and sustained focal increases in [Ca2+]i. Aequorin detected increased [Ca2+]i in small regions of the cytoplasm during release from and refilling of the intracellular Ca2+ store and with caffeine stimulation. Dual use of aequorin and fura-2 permits determination of relative [Ca2+]i homogeneity in smooth muscle.

The inhibitory effect of Li+ on contractile elements of intestinal smooth muscle

The mechanism of the inhibitory effect of Li+ on contraction was examined in guinea pig ileal longitudinal smooth muscle. Li(+)-substitution (68.4 mM) reversed contractions induced by high K+ (45.4 mM), carbachol (1 microM) and histamine (1 microM) without changing the cytosolic Ca2+ level. Li+ also had no effect on the increase in 45Ca2+ uptake stimulated by high K+. High K+ transiently increased myosin light chain (MLC) phosphorylation, reaching a peak at 6-9 sec. Li(+)-substitution inhibited the high K(+)-induced MLC phosphorylation. In permeabilized ileal strips, contraction induced by 1 microM Ca2+ was inhibited by 10 mM Li+. The inhibitory effect was antagonized by increasing the concentration of Ca2+ or calmodulin. In the permeabilized muscle in which MLC was previously thiophosphorylated with 1 mM ATP gamma S and 3 microM Ca2+, ATP induced contraction in Ca2+ free buffer. Li+ added during this contraction did not show an inhibitory effect. In contrast, when 30 mM Li+ was added during the thiophosphorylation, the contraction induced by the subsequent addition of ATP was inhibited. Li+ (30 mM) changed neither the rate of relaxation induced by removing external Ca2+ in permeabilized muscle nor the rate of dephosphorylation of MLC induced by crude phosphatase extracted from the ileum. Li+ (15 mM), on the other hand, inhibited the rate of phosphorylation of MLC caused by crude MLC kinase extracted from the ileum. Li+ did not inhibit the calmodulin activity as measured with the (Ca2+ +Mg2+)-ATPase activity of the erythrocyte membrane. These results suggest that the inhibitory effect of Li+ on contractions is attributable to the inhibition of MLC kinase in guinea pig ileum.

Compartmentation of ATP synthesis and utilization in smooth muscle: roles of aerobic glycolysis and creatine kinase

The phosphocreatine content of smooth muscle is of similar magnitude to ATP. Thus the function of the creatine kinase system in this tissue cannot simply be regarded as an energy buffer. Thus an understanding of its role in smooth muscle behavior can point to CK function in other systems. From our perspective CK function in smooth muscle is one example of a more general phenomenon, that of the co-localization of ATP synthesis and utilization. In an interesting and analogous fashion distinct glycolytic cascades are also localized in regions of the cell with specialized energy requirements. Similar to CK, glycolytic enzymes are known to be localized on thin filaments, sarcoplasmic reticulum and plasma membrane. In this chapter we will describe the relations between glycolysis and smooth muscle function and compare and contrast to that of the CK system. Our goal is to more fully understand the significance of the compartmentation of distinct pathways for ATP synthesis with specific functions in smooth muscle. This organization of metabolism and function seen most clearly in smooth muscle is likely representative of many other cell types.

Aminophylline preferentially inhibits chloroethylclonidine-insensitive alpha-adrenoceptor-mediated contractions in rat aorta

1. In rat thoracic aortae, contractions induced by methoxamine were inhibited by chloroethylclonidine, whereas oxymetazoline-induced contractions, which were more dependent on Ca(2+)-entry, were insensitive to chloroethylclonidine. 2. Aminophylline inhibited the contractions and 45Ca(2+)-uptake induced by both methoxamine and oxymetazoline. However, oxymetazoline-induced contractions were more sensitive to inhibition by aminophylline and D600. 3. Thus, the partial selectivity of aminophylline for the chloroethylclonidine-resistant, highly dependent on extracellular Ca2+, oxymetazoline-mediated responses may be explained by a preferential inhibition of agonist-induced Ca2+ entry as compared to inhibition of other transduction pathways.

Phosphorylation-contraction coupling in smooth muscle: role of caldesmon

In intact smooth muscle strips from chicken gizzard, carbachol elicited brief, phasic contractions which were associated with a very rapid, transient phosphorylation of the 20 kDa myosin light chains. Phosphorylation was not significantly different from basal levels after 30 s while force still amounted to 50% of the peak value. The rate of tension decline could be increased by addition of atropine, even at apparently basal phosphorylation levels suggesting a phosphorylation independent regulation. The force, at a given level of phosphorylation, could also be modulated by addition of the actin binding, putative regulatory protein, caldesmon. Caldesmon, inhibits phosphorylation dependent force in skinned fiber bundles of chicken gizzard without affecting myosin light chain phosphorylation. This suggests that caldesmon might modulate contraction in smooth muscle. Moreover our results suggest that caldesmon does not function to maintain passive tension.

Caffeine-induced release and reuptake of Ca2+ by Ca2+ stores in myocytes from guinea-pig urinary bladder

1. Voltage-clamped isolated smooth muscle cells from guinea-pig urinary bladder were studied with 3.6 mM extracellular Ca2+ at 36 degrees C. The fluorescence of the Ca(2+)-sensitive dye Indo-1 was used to monitor the cytosolic calcium concentration ([Ca2+]i) and its changes ([Ca2+]i transient). Fast application of caffeine (10 mM) to the cell was used to release the intracellular Ca2+ from a 'caffeine-sensitive Ca2+ store'. 2. At the holding potential -60 mV, a short (1 s) caffeine application increased [Ca2+]i within less than 1 s from the resting 118 +/- 22 nM to 1490 +/- 332 nM. Following the caffeine wash-out, [Ca2+]i fell from this peak to a subresting level of 47 +/- 12 nM, i.e. an 'undershoot' of [Ca2+]i occurred. Subsequent caffeine-induced [Ca2+]i transients had attenuated peaks suggesting that the caffeine-sensitive Ca2+ store had lost a part of the releasable Ca2+. 3. In the continuous presence of caffeine, [Ca2+]i decayed from its peak to control resting [Ca2+]i values. The wash-out of caffeine following prolonged (10-30 s) treatment also resulted in [Ca2+]i undershoot. Subsequent caffeine-induced [Ca2+]i transients were largely abolished as if the caffeine-sensitive Ca2+ store had lost a large part of releasable Ca2+. During the undershoot, hyperpolarization to -100 mV did not affect [Ca2+]i. In most cells studied, recovery of [Ca2+]i from the undershoot to the resting level required depolarizations inducing Ca2+ influx through L-type Ca2+ channels. 4. Block of plasmalemmal Ca(2+)-ATPase (PMCa) with extracellular La3+ (3 mM) did not modify the decay of the [Ca2+]i transients induced by depolarization or by a 1 s caffeine application suggesting that decay rate of both is not limited by PMCa rate. La3+ abolished the undershoot of [Ca2+]i. In the continuous presence of caffeine, La3+ largely prevented the decay of [Ca2+]i. 5. When the depolarizing steps from -60 to 0 mV (160 ms duration) were applied during the period of [Ca2+]i undershoot, the half-time of decay of the corresponding [Ca2+]i transients was up to three times faster than in control. Repetitive depolarizations restored the rate of decay and [Ca2+]i recovered to the resting value. Both processes recovered along a similar time course. 6. Application of the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX; 0.1 mM) or of 8-Br-cAMP (0.1 mM) did not mimic the above caffeine effects suggesting that stimulation of sarcoplasmic reticulum (SR) Ca(2+)-ATPase (SERCa) by cAMP-dependent phosphorylation is not the underlying mechanism.(ABSTRACT TRUNCATED AT 400 WORDS)

Mechanisms of caffeine-induced contraction and relaxation of rat aortic smooth muscle

1. Using front-surface fluorimetry and Fura-2, we determined the effects of caffeine on cytosolic calcium concentration ([Ca2+]i) and on tension of strips of the rat thoracic aorta. We also determined the effects of caffeine on 45Ca2+ influx into the strips. The objective was to elucidate the mechanism of contraction and relaxation in vascular smooth muscle, as induced by caffeine. 2. In normal physiological salt solution (PSS), caffeine induced a transient tension development, while it induced a biphasic change in [Ca2+]i. The initial transient peak in [Ca2+]i which coincided with tension development was followed by a sustained increase. Thus, changes in tension did not follow changes in [Ca2+]i. In Ca(2+)-free PSS, both the caffeine-induced contraction and the increase in [Ca2+]i were transient. It was suggested that in both the presence and absence of extracellular Ca2+, the transient increase in [Ca2+]i was due to the release of Ca2+ from the intracellular store. Although the sustained increase in [Ca2+]i depended on extracellular Ca2+, it was not affected by diltiazem, a Ca2+ antagonist. 3. Caffeine inhibited the increase in [Ca2+]i and tension development during 118 mM-K+ depolarization, in a concentration-dependent manner. The extent of reduction in tension (relaxation) was greater than that expected from the reduction in [Ca2+]i based on the [Ca2+]i-tension relationship observed with K+ depolarization. Pretreatment of the strips with ryanodine did not alter the inhibitory effects of caffeine. 4. Caffeine inhibited the increased [Ca2+]i and developed tension during stimulation by 10(-5) M-noradrenaline, in a concentration-dependent manner. 5. Dibutyryl cAMP (10(-4) M) inhibited both high K(+)-induced and noradrenaline-induced tension development. Inhibition of an increase in [Ca2+]i in relation to the inhibition of tension during noradrenaline stimulation was much greater than that in 118 mM-K+ depolarization. 6. Although caffeine per se had no effect on 45Ca2+ influx in the strips in normal PSS, caffeine did inhibit the increase in 45Ca2+ influx stimulated by 118 mM-K+ or by 10(-5) M-noradrenaline, to a similar extent and with similar IC50 values. 7. The characteristic features of the effects of caffeine on vascular smooth muscle, i.e. the transient nature of contraction and the relaxation of precontracted strips could be explained as follows: caffeine is able to reduce [Ca2+]i after releasing Ca2+ from intracellular stores; however, this may play a minor role. Independent of the [Ca2+]i reduction, the second messenger, cAMP, might directly influence the [Ca2+]i-tension relationship, and if so, would play a major role.

Effects of aminophylline on contractions and 45Ca uptake in isolated rat vascular smooth muscle

1. Aminophylline inhibited the contractions induced in rat isolated aorta by high K and noradrenaline (NA) as well as the transient contraction induced by NA in Ca-free media and suppressed the spontaneous myogenic activity in portal vein segments. 2. Aminophylline had no significant effects on 45Ca influx in resting aorta but inhibited 45Ca influx stimulated by high K or NA. 3. It is concluded that aminophylline inhibited Ca entry through voltage- and receptor-operated channels and NA-induced Ca release from intracellular stores. A part of the vascular inhibitory effects of aminophylline may be mediated by a cAMP-dependent mechanism.

Cyclic AMP-mediated regulation of excitation-contraction coupling in canine gastric smooth muscle

1. Agonists known to increase cyclic AMP levels in gastrointestinal smooth muscles were studied in isolated circular muscles of the canine antrum to investigate the mechanisms of the inhibitory effects of these agents. 2. Muscles were electrically active, generating typical slow wave activity. Cytosolic Ca2+ ([Ca2+]cyt; measured by Indo-1 fluorescence) and tension increased in response to slow waves. 3. Stimulation by isoprenaline (via beta 2-receptors) or forskolin, in the presence or absence of acetylcholine, inhibited the plateau phase and reduced phasic [Ca2+]cyt and contractile responses. 4. Vasoactive intestinal peptide (VIP) and calcitonin gene-related peptide (CGRP), had similar effects to isoprenaline and forskolin. 5. Increases in the plateau phase of slow waves and the associated increases in [Ca2+]cyt and tension caused by direct activation of voltage-dependent Ca2+ channels by Bay K 8644 (0.1 microM) were also reduced by forskolin. 6. Isoprenaline and forskolin induced negative chronotropic effects, but VIP increased frequency. 7. At a given level of [Ca2+]cyt, contractions were greater under control conditions than in the presence of isoprenaline, VIP and CGRP, suggesting that part of the inhibition produced by these agents may be due to decreased Ca2+ sensitivity of the contractile apparatus. 8. Experiments performed on alpha-toxin-permeabilized muscles confirmed that cyclic AMP-dependent effects involve reduced Ca2+ sensitivity of the contractile apparatus. Addition of cyclic AMP (3-300 microM) caused a reduction in Ca(2+)-induced contraction at a constant level of Ca2+ (pCa 5.5). 9. These results suggest that increased cyclic AMP and probably subsequent activation of protein kinase A: (i) decrease [Ca2+]cyt and contraction by an inhibition of Ca2+ influx during slow waves, and (ii) decrease the sensitivity of the contractile apparatus to [Ca2+]cyt. The membrane effects might occur directly by inhibition of Ca2+ channels or indirectly by increasing the open probability of K+ channels which would tend to cause premature repolarization of slow waves.

Mechanisms controlling caffeine-induced relaxation of coronary artery of the pig

1. We studied the effects of caffeine on coronary artery smooth muscle of the pig by measuring changes in isometric tension, cytosolic free Ca(2+) concentration ( [Ca2+]i) and transmembrane potential. 2. In the absence of tone, caffeine induced a concentration-dependent transient contraction of coronary artery strips, followed by sustained relaxation. Simultaneously with the relaxation, caffeine, 25 mM, hyperpolarized the smooth muscle cells by 7.7 +/- 0.9 mV. 3. Caffeine caused a concentration-dependent relaxation of strips precontracted with 10(-5)M acetylcholine (ACH). A supramaximal relaxing concentration of 25 mM caffeine produced an additional transient increase in [Ca2+]i on the Ca2+ plateau of ACh tonic contraction, which was followed by a decrease in [Ca2+]i to a level slightly below the basal concentration. This relaxation was accompanied by a hyperpolarization of 7.3 +/- 0.9 mV. 4. KCI 120 mM (high K+) contracted the strips with a concomitant depolarization of 38.6 +/- 1.6 mV and sustained increase in [Ca2+]i. Caffeine caused a concentration-dependent relaxation of high K+-induced contraction. Caffeine, 25 mM, decreased the Ca2+ plateau to a level that remained above the basal concentration of Ca2+ but did not change the membrane potential. 5. When strips were placed in a Ca(2+)-free medium with EGTA 2mM, and, in addition, ACh was applied successively three times, both intracellular and extracellular mobilizable Ca2+ pools were depleted. In these conditions, phorbol 12,13 dibutyrate (PDBu) 10(-7) M and prostaglandin F 2 alpha (PGF 2 alpha) 10(-5) M contracted the strips. Caffeine (25 mM) inhibited these contractions with no change in [Ca2+]i. 6. Forskolin, 3 x 10 -7M, inhibited ACh induced-contraction but did not affect those induced by PDBu. 7. In conclusion, these results show that caffeine has multiple cellular effects. During caffeine-induced relaxation, [Ca2" Ii, adenosine 3': 5'-cyclic monophosphate (cyclic AMP) content and membrane potential are modified. The findings suggest, however, that these effects are secondary, and that caffeine acts mainly by another unknown mechanism, possibly involving a direct inhibition of the contractile apparatus.

Identification of creatine kinase isoenzymes in the guinea-pig. Presence of mitochondrial creatine kinase in smooth muscle

Isoenzymes of creatine kinase (CK, EC 2.7.3.2) in guinea-pig smooth, cardiac and skeletal muscles as well as in brain were analyzed by cellulose acetate electrophoresis and FPLC gel permeation chromatography. In crude tissue extracts of smooth muscles brain type BB-CK and the hybrid form MB-CK were detected, but in enriched mitochondrial fractions from different guinea-pig smooth muscles, mitochondrial type Mi-CK was unambiguously identified. Smooth muscle Mi-CK displayed the same electrophoretic mobility as Mi-CK from brain, which migrates slower than cardiac Mi-CK. Identical to parallel experiments with Mi-CK from cardiac muscle and brain, smooth muscle Mi-CK could be resolved into dimeric and octameric species, the latter being remarkably stable. In contrast to guinea-pig smooth muscles, Mi-CK was not detected in chicken gizzard tissue extracts nor in enriched mitochondrial fractions thereof. The presence of Mi-CK, predominantly in octameric form, in guinea-pig smooth muscles, but not in chicken gizzard, may represent a clue for the different physiological properties of these muscles and may provide the molecular basis for the dependence of the PCr production on oxidative metabolism observed in the guinea-pig taenia caeci.