Intracellular calibration of the calcium indicator indo-1 in isolated fibers of Xenopus muscle

Increased tetanic calcium in early fatigue of mammalian muscle fibers is accompanied by accelerated force development despite a decreased force

During the initial phase of fatigue induced by repeated contractions in fast-twitch muscle fibers, tetanic force decreases despite increasing tetanic free cytosolic [Ca²⁺ ] ([Ca²⁺ ]_cyt ). Here, we hypothesized that the increase in tetanic [Ca²⁺ ]_cyt nevertheless has positive effects on force in early fatigue. Experiments on enzymatically isolated mouse flexor digitorum brevis (FDB) fibers showed that an increase in tetanic [Ca²⁺ ]_cyt during ten 350 ms contractions required trains of electrical pulses to be elicited at short intervals (≤2 s) and at high frequencies (≥70 Hz). Mechanically dissected mouse FDB fibers showed greater decrease in tetanic force when the stimulation frequency during contractions was gradually reduced to prevent the increase in tetanic [Ca²⁺ ]_cyt . Novel analyses of data from previous studies revealed an increased rate of force development in the tenth fatiguing contraction in mouse FDB fibers, as well as in rat FDB and human intercostal fibers. Mouse FDB fibers deficient in creatine kinase showed no increase in tetanic [Ca²⁺ ]_cyt and slowed force development in the tenth contraction; after injection of creatine kinase to enable phosphocreatine breakdown, these fibers showed an increase in tetanic [Ca²⁺ ]_cyt and accelerated force development. Mouse FDB fibers exposed to ten short contractions (43 ms) produced at short intervals (142 ms) showed increased tetanic [Ca²⁺ ]_cyt accompanied by a marked (~16%) increase in the developed force. In conclusion, the increase in tetanic [Ca²⁺ ]_cyt in early fatigue is accompanied by accelerated force development, which under some circumstances can counteract the decline in physical performance caused by the concomitant decrease in maximum force.

Optimizing Calcium Detection Methods in Animal Systems: A Sandbox for Synthetic Biology

Since the 1970s, the emergence and expansion of novel methods for calcium ion (Ca2+) detection have found diverse applications in vitro and in vivo across a series of model animal systems. Matched with advances in fluorescence imaging techniques, the improvements in the functional range and stability of various calcium indicators have significantly enhanced more accurate study of intracellular Ca2+ dynamics and its effects on cell signaling, growth, differentiation, and regulation. Nonetheless, the current limitations broadly presented by organic calcium dyes, genetically encoded calcium indicators, and calcium-responsive nanoparticles suggest a potential path toward more rapid optimization by taking advantage of a synthetic biology approach. This engineering-oriented discipline applies principles of modularity and standardization to redesign and interrogate endogenous biological systems. This review will elucidate how novel synthetic biology technologies constructed for eukaryotic systems can offer a promising toolkit for interfacing with calcium signaling and overcoming barriers in order to accelerate the process of Ca2+ detection optimization.

Measuring Ca2+ in Living Cells

Measuring free Ca²⁺ concentration ([Ca²⁺]) in the cytosol or organelles is routine in many fields of research. The availability of membrane permeant forms of indicators coupled with the relative ease of transfecting cell lines with biological Ca²⁺ sensors have led to the situation where cellular and subcellular [Ca²⁺] is examined by many non-specialists. In this chapter, we evaluate the most used Ca²⁺ indicators and highlight what their major advantages and disadvantages are. We stress the potential pitfalls of non-ratiometric techniques for measuring Ca²⁺ and the clear advantages of ratiometric methods. Likely improvements and new directions for Ca²⁺ measurement are discussed.

Moderately elevated extracellular [K+] potentiates submaximal force and power in skeletal muscle via increased [Ca2+]i during contractions

The extracellular K+ concentration ([K+]o) increases during physical exercise. We here studied whether moderately elevated [K+]o may increase force and power output during contractions at in vivo-like subtetanic frequencies and whether such potentiation was associated with increased cytosolic free Ca2+ concentration ([Ca2+]i) during contractions. Isolated whole soleus and extensor digitorum longus (EDL) rat muscles were incubated at different levels of [K+]o, and isometric and dynamic contractility were tested at various stimulation frequencies. Furthermore, [Ca2+]i at rest and during contraction was measured along with isometric force in single mouse flexor digitorum brevis (FDB) fibers exposed to elevated [K+]o. Elevating [K+]o from 4 mM up to 8 mM (soleus) and 11 mM (EDL) increased isometric force at subtetanic frequencies, 2–15 Hz in soleus and up to 50 Hz in EDL, while inhibition was seen at tetanic frequency in both muscle types. Elevating [K+]o also increased peak power of dynamic subtetanic contractions, with potentiation being more pronounced in EDL than in soleus muscles. The force-potentiating effect of elevated [K+]o was transient in FDB single fibers, reaching peak after ~4 and 2.5 min in 9 and 11 mM [K+]o, respectively. At the time of peak potentiation, force and [Ca2+]i during 15-Hz contractions were significantly increased, whereas force was slightly decreased and [Ca2+]i unchanged during 50-Hz contractions. Moderate elevation of [K+]o can transiently potentiate force and power during contractions at subtetanic frequencies, which can be explained by a higher [Ca2+]i during contractions.

Mechanical isolation, and measurement of force and myoplasmic free [Ca2+] in fully intact single skeletal muscle fibers

Mechanical dissection of single intact mammalian skeletal muscle fibers permits real-time measurement of intracellular properties and contractile function of living fibers. A major advantage of mechanical over enzymatic fiber dissociation is that single fibers can be isolated with their tendons remaining attached, which allows contractile forces (in the normal expected range of 300-450 kN/m²) to be measured during electrical stimulation. Furthermore, the sarcolemma of single fibers remains fully intact after mechanical dissection, and hence the living fibers can be studied with intact intracellular milieu and normal function and metabolic properties, as well as ionic control. Given that Ca²⁺ is the principal regulator of the contractile force, measurements of myoplasmic free [Ca²⁺] ([Ca²⁺]_i) can be used to further delineate the intrinsic mechanisms underlying changes in skeletal muscle function. [Ca²⁺]_i measurements are most commonly performed in intact single fibers using ratiometric fluorescent indicators such as indo-1 or fura-2. These Ca²⁺ indicators are introduced into the fiber by pressure injection or by using the membrane-permeable indo-1 AM, and [Ca²⁺]_i is measured by calculating a ratio of the fluorescence at specific wavelengths emitted for the Ca²⁺-free and Ca²⁺-bound forms of the dye. We describe here the procedures for mechanical dissection, and for force and [Ca²⁺]_i measurement in intact single fibers from mouse flexor digitorum brevis (FDB) muscle, which is the most commonly used muscle in studies using intact single fibers. This technique can also be used to isolate intact single fibers from various muscles and from various species. As an alternative to Ca²⁺ indicators, single fibers can also be loaded with fluorescent indicators to measure, for instance, reactive oxygen species, pH, and [Mg²⁺], or they can be injected with proteins to change functional properties. The entire protocol, from dissection to the start of an experiment on a single fiber, takes ∼3 h.

An overview of Ca2+ mobilization assays in GPCR drug discovery

INTRODUCTION

Calcium ions (Ca²⁺) serve as a second messenger or universal signal transducer implicated in the regulation of a wide range of physiological processes. A change in the concentration of intracellular Ca²⁺ is an important step in intracellular signal transduction. G protein-coupled receptors (GPCRs), the largest and most versatile group of cell surface receptors, transduce extracellular signals into intracellular responses via their coupling to heterotrimeric G proteins. Since Ca²⁺ plays a crucial role in GPCR-induced signaling, measurement of intracellular Ca²⁺ has attracted more and more attention in GPCR-targeted drug discovery. Areas covered: This review focuses on the most popular functional assays measuring GPCRs-induced intracellular Ca²⁺ signaling. These include photoprotein-based, synthetic fluorescent indicator-based and genetically encoded calcium indicator (GECI)-based Ca²⁺ mobilization assays. A brief discussion of the design strategy of fluorescent probes in GPCR studies is also presented. Expert opinion: GPCR-mediated intracellular signaling is multidimensional. There is an urgent need for the development of multiple-readout screening assays capable of simultaneous detection of biased signaling and screening of both agonists and antagonists in the same assay. It is also necessary to develop GECIs offering low cost and consistent assays suitable for investigating GPCR activation in vivo.

Development and optimization of FLIPR high throughput calcium assays for ion channels and GPCRs

Ca(2+) permeable ion channels and GPCRs linked to Ca(2+) release are important drug targets, with modulation of Ca(2+) signaling increasingly recognized as a valid therapeutic strategy in a range of diseases. The FLIPR is a high throughput imaging plate reader that has contributed substantially to drug discovery efforts and pharmacological characterization of receptors and ion channels coupled to Ca(2+). Now in its fourth generation, the FLIPR(TETRA) is an industry standard for high throughput Ca(2+) assays. With an increasing number of excitation LED banks and emission filter sets available; FLIPR Ca(2+) assays are becoming more versatile. This chapter describes general methods for establishing robust FLIPR Ca(2+) assays, incorporating practical aspects as well as suggestions for assay optimization, to guide the reader in the development and optimization of high throughput FLIPR assays for ion channels and GPCRs.

Rapid Ca2+ flux through the transverse tubular membrane, activated by individual action potentials in mammalian skeletal muscle

Periods of low frequency stimulation are known to increase the net Ca(2+) uptake in skeletal muscle but the mechanism responsible for this Ca(2+) entry is not known. In this study a novel high-resolution fluorescence microscopy approach allowed the detection of an action potential-induced Ca(2+) flux across the tubular (t-) system of rat extensor digitorum longus muscle fibres that appears to be responsible for the net uptake of Ca(2+) in working muscle. Action potentials were triggered in the t-system of mechanically skinned fibres from rat by brief field stimulation and t-system [Ca(2+)] ([Ca(2+)](t-sys)) and cytoplasmic [Ca(2+)] ([Ca(2+)](cyto)) were simultaneously resolved on a confocal microscope. When initial [Ca(2+)](t-sys) was > or = 0.2 mM a Ca(2+) flux from t-system to the cytoplasm was observed following a single action potential. The action potential-induced Ca(2+) flux and associated t-system Ca(2+) permeability decayed exponentially and displayed inactivation characteristics such that further Ca(2+) entry across the t-system could not be observed after 2-3 action potentials at 10 Hz stimulation rate. When [Ca(2+)](t-sys) was closer to 0.1 mM, a transient rise in [Ca(2+)](t-sys) was observed almost concurrently with the increase in [Ca(2+)](cyto) following the action potential. The change in direction of Ca(2+) flux was consistent with changes in the direction of the driving force for Ca(2+). This is the first demonstration of a rapid t-system Ca(2+) flux associated with a single action potential in mammalian skeletal muscle. The properties of this channel are inconsistent with a flux through the L-type Ca(2+) channel suggesting that an as yet unidentified t-system protein is conducting this current. This action potential-activated Ca(2+) flux provides an explanation for the previously described Ca(2+) entry and accumulation observed with prolonged, intermittent muscle activity.

Deficiency in parvalbumin increases fatigue resistance in fast-twitch muscle and upregulates mitochondria

The soluble Ca2+-binding protein parvalbumin (PV) is expressed at high levels in fast-twitch muscles of mice. Deficiency of PV in knockout mice (PV -/-) slows down the speed of twitch relaxation, while maximum force generated during tetanic contraction is unaltered. We observed that PV-deficient fast-twitch muscles were significantly more resistant to fatigue than were the wild type. Thus components involved in Ca2+ homeostasis during the contraction-relaxation cycle were analyzed. No upregulation of another cytosolic Ca2+-binding protein was found. Mitochondria are thought to play a physiological role during muscle relaxation and were thus analyzed. The fractional volume of mitochondria in the fast-twitch muscle extensor digitorum longus (EDL) was almost doubled in PV -/- mice, and this was reflected in an increase of cytochrome c oxidase. A faster removal of intracellular Ca2+ concentration ([Ca2+]i) 200-700 ms after fast-twitch muscle stimulation observed in PV -/- muscles supports the role for mitochondria in late [Ca2+]i removal. The present results also show a significant increase of the density of capillaries in EDL muscles of PV -/- mice. Thus alterations in the dynamics of Ca2+ transients detected in fast-twitch muscles of PV -/- mice might be linked to the increase in mitochondria volume and capillary density, which contribute to the greater fatigue resistance of these muscles.

Role of myoplasmic phosphate in contractile function of skeletal muscle: studies on creatine kinase-deficient mice

1. Increased myoplasmic inorganic phosphate (P(i)) has been suggested to have an important role in skeletal muscle fatigue, especially in the early phase. In the present study we used intact fast-twitch muscle cells from mice completely deficient in creatine kinase (CK(-/-)) to test this suggestion. These CK(-/-) muscle cells provide a good model since they display a higher P(i) concentration in the unfatigued state and fatigue without significant increase of P(i). 2. Tetanic contractions (350 ms duration) were produced in intact single muscle fibres. The free myoplasmic [Ca(2+)] ([Ca(2+)](i)) was measured with the fluorescent indicator indo-1. The force-[Ca(2+)](i) relationship was constructed from tetani at different frequencies. 3. Compared with wild-type fibres, CK(-/-) fibres displayed lower force in 100 Hz tetani and at saturating [Ca(2+)](i) (i.e. 100 Hz stimulation during caffeine exposure), higher tetanic [Ca(2+)](i) during the first 100 ms of tetanic stimulation, reduced myofibrillar Ca(2+) sensitivity when measurements were performed 100-200 ms into tetani, and slowed force relaxation that was due to altered cross-bridge kinetics rather than delayed Ca(2+) removal from the myoplasm. 4. In wild-type fibres, a series of 10 tetani resulted in reduced tetanic force, slowed force relaxation, and increased amplitude of [Ca(2+)](i) tails after tetani. None of these changes were observed in CK(-/-) fibres. 5. Complementary experiments on isolated fast-twitch extensor digitorum longus muscles showed a reduction of tetanic force and relaxation speed in CK(-/-) muscles similar to those observed in single fibres. 6. In conclusion, increased P(i) concentration can explain changes observed in the early phase of skeletal muscle fatigue. Increased P(i) appears to be involved in both fatigue-induced changes of cross-bridge function and SR Ca(2+) handling.

Calibration of the calcium dissociation constant of Rhod(2)in the perfused mouse heart using manganese quenching

Both theoretical and experimental results are presented for in vivo calibration of the dissociation constant K(Ca)(d)of the calcium-sensitive fluorescent dye Rhod(2)in the perfused mouse heart, using manganese quenching of fluorescence transients. An analytical model is derived, based on the biochemical equilibrium of manganese competition with calcium for Rhod(2)binding. Expressing the differential of the changes between systole and diastole in fluorescence transient (delta Delta F(sys-dia)). delta DeltaF(sys-dia)in a beating heart as a function of the perfusate manganese concentration [Mn(2+)](p)allows correlation of the measured differential transient changes delta Delta F(sys-dia)with the calcium dissociation constant K(Ca)(d)of Rhod(2)and the calcium concentration in the heart. Numerical modeling indicates that the K(Ca)(d)predominantly affects the asymptotic slope of the delta Delta F(sys-dia)versus [Mn(2+)](p)curve at certain manganese concentrations, which suggests that the K(Ca)(d)can be inversely calculated by partially fitting the delta Delta F(sys-dia)distribution as a function of the perfusate manganese concentration. The feasibility of this approach is confirmed by quenching of calcium transients by manganese infusion into isolated perfused beating mouse hearts. The resulting calculated dissociation constant K(Ca)(d)of Rhod(2)is 720nM. Using the same approach, we are able to also estimate intracellular calcium concentrations of 700nM at peak systole and 300nM in diastole. This is in good agreement with values obtained by calibration of fluorescence values with a calcium saturation tetanization procedure in the same perfused mouse heart model.

Cellular basis for contractile dysfunction in the diaphragm from a rabbit infarct model of heart failure

Abnormal respiratory muscle function is thought to contribute to breathlessness and exercise intolerance in heart failure but little is known about possible alterations in the function of such muscle. We have measured tetanic force and intracellular Ca(2+) concentration ([Ca(2+)](i)) in isolated, arterially perfused hemidiaphragm preparations from a rabbit coronary artery ligation model of heart failure. Increasing stimulation frequency (10-100 Hz) caused a progressive increase of force and [Ca(2+)](i) in control preparations, whereas force and [Ca(2+)](i) only increased between 10 and 25 Hz stimulation (decreasing at higher frequencies) in preparations from ligated animals. Cyclopiazonic acid produced a dose-dependent shift in the relationship between stimulation frequency and [Ca(2+)](i) in control preparations that was similar to the shift observed in the diaphragm of coronary-ligated animals. These data indicate that the in vitro contractile characteristics of the diaphragm are significantly altered in our model and that altered [Ca(2+)](i) regulation contributes to the reduced diaphragm strength observed in heart failure.

Concentrations of caffeine greater than 20 mM increase the indo-1 fluorescence ratio in a Ca(2+)-independent manner

The methylxanthine, caffeine, quenches the fluorescence of the ratiometric Ca2+ indicator indo-1, but does not affect the ratio (R) of indo-1 fluorescence at 400 and 500 nm in the presence of caffeine concentrations up to 10 mM [1]. We have found that when caffeine is at concentrations of 20 mM or greater in vitro, or in saponinpermeabilized skeletal muscle fibers, a Ca(2+)-independent increase in R occurs, which leads to an overestimation of the free Ca2+ concentration. Depending on experimental conditions, two factors contribute to the alteration in R in vitro. First, when indo-1 fluorescence is low, fluorescence by caffeine, at 400 nm, can be significant. A second, and more dramatic effect, is that quenching of indo-1 fluorescence by 20-50 mM caffeine is dissimilar at 400 and 500 nm. Quenching at 500 nm is not linear, with respect to the concentration of caffeine, and causes a Ca(2+)-independent increase in R, that occurs even when the fluorescence of caffeine is a small portion of total fluorescence. However, unlike R, the Ca2+ calibration constant of indo-1, KD beta, is unchanged in 50 mM caffeine. Therefore, an accurate quantitation of Ca2+ in the presence of even high concentrations of caffeine can be made in vitro by determining the Ca2+ calibration factors of indo-1 (RMIN and RMAX) for each caffeine concentration. These effects of concentrations of caffeine greater than 20 mM are not observed in intact cells loaded with the cell permeant form of indo-1 when caffeine is applied extracellularly. This suggests either that the concentration of caffeine within the cell does not reach that necessary to produce the effect, or that the effects of caffeine on the dye are modified by the environment within the cell.

Calcium transients in single fibers of low-frequency stimulated fast-twitch muscle of rat

Ca(2+) transients were investigated in single fibers isolated from rat extensor digitorum longus muscles exposed to chronic low-frequency stimulation for different time periods up to 10 days. Approximately 2.5-fold increases in resting Ca(2+) concentration ([Ca(2+)]) were observed 2 h after stimulation onset and persisted throughout the stimulation period. The elevated [Ca(2+)] levels were in the range characteristic of slow-twitch fibers from soleus muscle. In addition, we noticed a transitory elevation of the integral [Ca(2+)] per pulse with a maximum ( approximately 5-fold) after 1 day. Steep decreases in rate constant of [Ca(2+)] decay could be explained by an immediate impairment of Ca(2+) uptake and, with longer stimulation periods, by an additional loss of cytosolic Ca(2+) binding capacity resulting from a decay in parvalbumin content. A partial recovery of the rate constant of [Ca(2+)] decay in 10-day stimulated muscle could be explained by an increasing mitochondrial contribution to Ca(2+) sequestration.

Measurement of intracellular calcium

To a certain extent, all cellular, physiological, and pathological phenomena that occur in cells are accompanied by ionic changes. The development of techniques allowing the measurement of such ion activities has contributed substantially to our understanding of normal and abnormal cellular function. Digital video microscopy, confocal laser scanning microscopy, and more recently multiphoton microscopy have allowed the precise spatial analysis of intracellular ion activity at the subcellular level in addition to measurement of its concentration. It is well known that Ca2+ regulates numerous physiological cellular phenomena as a second messenger as well as triggering pathological events such as cell injury and death. A number of methods have been developed to measure intracellular Ca2+. In this review, we summarize the advantages and pitfalls of a variety of Ca2+ indicators used in both optical and nonoptical techniques employed for measuring intracellular Ca2+ concentration.

Prolonged contraction-relaxation cycle of fast-twitch muscles in parvalbumin knockout mice

The calcium-binding protein parvalbumin (PV) occurs at high concentrations in fast-contracting vertebrate muscle fibers. Its putative role in facilitating the rapid relaxation of mammalian fast-twitch muscle fibers by acting as a temporary buffer for Ca2+ is still controversial. We generated knockout mice for PV (PV -/-) and compared the Ca2+ transients and the dynamics of contraction of their muscles with those from heterozygous (PV +/-) and wild-type (WT) mice. In the muscles of PV-deficient mice, the decay of intracellular Ca2+ concentration ([Ca2+]i) after 20-ms stimulation was slower compared with WT mice and led to a prolongation of the time required to attain peak twitch tension and to an extension of the half-relaxation time. The integral [Ca2+]i in muscle fibers of PV -/- mice was higher and consequently the force generated during a single twitch was approximately 40% greater than in PV +/- and WT animals. Acceleration of the contraction-relaxation cycle of fast-twitch muscle fibers by PV may confer an advantage in the performance of rapid, phasic movements.

Cytoplasmic free concentrations of Ca2+ and Mg2+ in skeletal muscle fibers at rest and during contraction

This review summarizes estimates for cytoplasmic-free concentrations of Ca2+ ([Ca2+]i) and Mg2+ ([Mg2+]i) at rest and during contraction of skeletal muscles, from which substantial quantitative information about them has been accumulated. Although the estimates of resting [Ca2+]i in the literature widely differ, which is because of the variety of difficulties related to different methodologies used, recent studies suggest that estimates of resting [Ca2+]i of approximately 0.05-0.1 microM are likely to be correct. Following action potential propagation, the Ca2+ release from the sarcoplasmic reticulum causes a transient rise of [Ca2+]i (Ca2+ transient). The large peak amplitude and brief time course of the Ca2+ transients have been established only recently by studies with low-affinity Ca2+ indicators developed in the past decade. These technical improvements in [Ca2+]i measurements have made it possible to study relationships between [Ca2+]i and force in intact muscle fibers. In the second part of this review, various estimates of [Mg2+]i in the resting muscle are discussed. Relatively recent estimates of the [Mg2+]i level appear to be about 1.0 mM. Using the current knowledge of concentrations and reaction properties of intracellular Ca2+-Mg2+ binding sites, we constructed a model for dynamic Mg2+ movement following Ca2+ transients. The model predicts that with a train of action potentials, the sustained rise of [Ca2+]i produces an elevation of [Mg2+]i of about 200 microM.

Model of sarcomeric Ca2+ movements, including ATP Ca2+ binding and diffusion, during activation of frog skeletal muscle

Cannell and Allen (1984. Biophys. J. 45:913-925) introduced the use of a multi-compartment model to estimate the time course of spread of calcium ions (Ca2+) within a half sarcomere of a frog skeletal muscle fiber activated by an action potential. Under the assumption that the sites of sarcoplasmic reticulum (SR) Ca2+ release are located radially around each myofibril at the Z line, their model calculated the spread of released Ca2+ both along and into the half sarcomere. During diffusion, Ca2+ was assumed to react with metal-binding sites on parvalbumin (a diffusible Ca2+- and Mg2+-binding protein) as well as with fixed sites on troponin. We have developed a similar model, but with several modifications that reflect current knowledge of the myoplasmic environment and SR Ca2+ release. We use a myoplasmic diffusion constant for free Ca2+ that is twofold smaller and an SR Ca2+ release function in response to an action potential that is threefold briefer than used previously. Additionally, our model includes the effects of Ca2+ and Mg2+ binding by adenosine 5'-triphosphate (ATP) and the diffusion of Ca2+-bound ATP (CaATP). Under the assumption that the total myoplasmic concentration of ATP is 8 mM and that the amplitude of SR Ca2+ release is sufficient to drive the peak change in free [Ca2+] (Delta[Ca2+]) to 18 microM (the approximate spatially averaged value that is observed experimentally), our model calculates that (a) the spatially averaged peak increase in [CaATP] is 64 microM; (b) the peak saturation of troponin with Ca2+ is high along the entire thin filament; and (c) the half-width of Delta[Ca2+] is consistent with that observed experimentally. Without ATP, the calculated half-width of spatially averaged Delta[Ca2+] is abnormally brief, and troponin saturation away from the release sites is markedly reduced. We conclude that Ca2+ binding by ATP and diffusion of CaATP make important contributions to the determination of the amplitude and the time course of Delta[Ca2+].

Measurements of intracellular Mg2+ concentration in mouse skeletal muscle fibers with the fluorescent indicator mag-indo-1

Measurements of intracellular free magnesium concentration ([Mg2+]i) were performed on enzymatically isolated skeletal muscle fibers from mice, using the fluorescent ratiometric indicator mag-indo-1. An original procedure was developed to calibrate the dye response within the fibers: fibers were first permeabilized with saponin in the presence of a given extracellular magnesium concentration and were then embedded in silicone grease. The dye was then pressure microinjected into the saponin-permeabilized silicone-embedded fibers, and fluorescence was measured. The results show that for all tested [Mg2+], the value of the measured fluorescence ratio was higher than that found in aqueous solutions. Furthermore, the apparent binding curve that could be fit to the in vivo ratio data was shifted toward higher [Mg2+] by a factor of approximately 2. Using the in vivo calibration parameters, the mean resting [Mg2+]i was found to be 1.53 +/- 0.16 mM (n = 7). In an attempt to gain insight into the myoplasmic magnesium buffering capacity, we measured, together with mag-indo-1 fluorescence, the current elicited by the application of carbamylcholine (CCh) to the endplate of isolated fibers, in the presence of a high extracellular magnesium concentration. The results show that, under these conditions, a change in [Mg2+]i displaying a time course and amplitude qualitatively consistent with the CCh-induced inward current can be measured.

Measuring [Ca2+] with fluorescent indicators: theoretical approach to the ratio method

In this work we present a theoretical analysis of the ratio method, a widely used technique for measuring intracellular calcium concentration, [Ca2+]i, in isolated cells. From the ratio of fluorescence measured at two different excitation or emission wavelengths, [Ca2+]i may be estimated from the equation: [Ca2+]i = Kd.beta.(R-Rmin)/(Rmax-R). From this equation we determined the method sensitivity showing that its maximum is located at [Ca2+] = Kd.beta.(Rmin/Rmax)1/2, i.e. for [Ca2+] < Kd.beta. We also analyzed the error propagation due to inaccuracies in the calibration parameters. The fluorescence phenomenon was described, aiming at providing a basis for the microscopic interpretation of the method and giving physical meaning to the calibration parameters. In this sense beta, is shown to depend not only on the set-up, but also on the spectrum of the indicator for the particular sample studied. A new approach to estimate beta with higher accuracy is also proposed. Experimentally obtained beta values using this approach were not statistically different from those determined as Fmin2/Fmax2. A graphical interpretation of the method is presented to provide users of fluorescence systems with a simple technique to help understand equipment performance and design.

Passive Ca2+ binding in ventricular myocardium of neonatal and adult rats

In this study, passive Ca2+ binding was determined in ventricular homogenates (VH) from neonatal (4-6 days) and adult rats, as well as in digitonin-permeabilized adult ventricular myocytes. Ca2+ binding sites, both endogenous and exogenous (Indo-1 and BAPTA) were titrated. Sarcoplasmic reticulum and mitochondrial Ca2+ uptake were blocked by thapsigargin and Ru360, respectively. Free [Ca2+] ([Ca2+]F) was measured with Indo-1 and bound Ca2+ ([Ca2+]B) was the difference between [Ca2+]F and total Ca2+. Apparent Ca2+ dissociation constants (Kd) for BAPTA and Indo-1 were increased by 10-20 mg VH protein/ml (from 0.35 to 0.92 microM for Indo-1 and from 0.20 to 0.76 microM for BAPTA) and also by ruthenium red in the case of Indo-1. Titration with successive CaCl2 additions (2.5-10 nmoles) yielded delta[Ca2+]B/delta[Ca2+]F for the sum of [Ca2+]B at all three classes of binding sites. From this function, the apparent number of endogenous sites (Ben) and their Kd (Ken) were determined. Similar Ken values were obtained in neonatal and adult VH, as well as in adult myocytes (0.68 +/- 0.14 microM, 0.69 +/- 0.13 microM and 0.53 +/- 0.10 microM, respectively). However, Ben was significantly higher in adult myocytes than in adult VH (1.73 +/- 0.35 versus 0.70 +/- 0.12 nmol/mg protein, P < 0.01), which correspond to approximately 300 and 213 mumol/l cytosol. This indicates that binding sites are more concentrated in myocytes than in other ventricular components and that Ben determined in VH underestimates cellular Ben by 29%. Although Ben values in nmol/mg protein were similar in adult and neonatal VH (0.69 +/- 0.12), protein content was much higher in adult ventricle (125 +/- 7 versus 80 +/- 1 mg protein/g wet weight, P < 0.01). Expressing Ben per unit cell volume (accounting for fractional mitochondrial volume, and 29% dilution in homogenate), the passive Ca2+ binding capacity at high-affinity sites is approximately 300 and 176 mmol/l cytosol in adult and neonatal rat ventricular myocytes, respectively. Additional estimates suggest that passive Ca2+ buffering capacity in rat ventricle increases markedly during the first two weeks of life and that adult levels are attained by the end of the first month.

Effect of hydrogen peroxide and dithiothreitol on contractile function of single skeletal muscle fibres from the mouse

1. We used intact single fibres from a mouse foot muscle to study the role of oxidation-reduction in the modulation of contractile function. 2. The oxidant hydrogen peroxide (H2O2, 100-300 microM) for brief periods did not change myoplasmic Ca2+ concentrations ([Ca2+]i) during submaximal tetani. However, force increased by 27 % during the same contractions. 3. The effects of H2O2 were time dependent. Prolonged exposures resulted in increased resting and tetanic [Ca2+]i, while force was significantly diminished. The force decline was mainly due to reduced myofibrillar Ca2+ sensitivity. There was also evidence of altered sarcoplasmic reticulum (SR) function: passive Ca2+ leak was increased and Ca2+ uptake was decreased. 4. The reductant dithiothreitol (DTT, 0.5-1 mM) did not change tetanic [Ca2+]i, but decreased force by over 40 %. This was completely reversed by subsequent incubations with H2O2. The force decline induced by prolonged exposure to H2O2 was reversed by subsequent exposure to DTT. 5. These results show that the elements of the contractile machinery are differentially responsive to changes in the oxidation-reduction balance of the muscle fibres. Myofibrillar Ca2+ sensitivity appears to be especially susceptible, while the SR functions (Ca2+ leak and uptake) are less so.

Use of Indo-1FF for measurements of rapid micromolar cytoplasmic free Ca2+ increments in a single smooth muscle cell

A low-affinity fluorescent Ca2+ indicator Indo-1FF was used to measure cytoplasmic Ca2+ increments in single smooth muscle cells isolated from the urinary bladder of the guinea-pig. The in vitro Kd of Indo-1FF for Ca2+ measured at the microscope stage was 21 microM. Calibration parameters measured in the cell differed substantially from respective in vitro values suggesting that the properties of the cytoplasmic dye had been altered. Addition of proteins (aldolase or albumin) increased the in vitro F405/F495 ratio close to the range observed intracellularly. Emission spectra of Ca(2+)-free Indo-1FF demonstrated a blue-shift of 29 nm with 10 mg/ml aldolase and 60 nm with 10 mg/ml albumin. The Kd value of Indo-1FF for Ca2+ in vitro was not changed by addition of aldolase (up to 20 mg/ml) and was approximately doubled in the presence of 20 mg/ml albumin. Intracellular calibration either by skinning the cells with beta-escine, 'opening' the cell or by intracellular perfusion of 100 microM free Ca2+ (40 mM DPTA-Ca2+ buffer) suggest that the affinity of intracellular Indo-1FF for Ca2+ is not markedly changed. The Indo-1FF concentration of 20 microM in the patch-pipette was found to be a reasonable compromise between acceptable signal-to-noise ratio and increased cytoplasmic Ca2+ buffering. This is because neither the amplitude nor the time-course of depolarization-induced micromolar Ca2+ increments were significantly changed during cell loading with this concentration of the dye. In contrast to Indo-1 loaded cells where rapid changes of [Ca2+]i were buffered, in Indo-1FF loaded cells ICa evoked rapid (rate of rise 150 microM/s) and large (4-6 microM in 35-60 ms) increments of free Ca2+. This results suggest that [Ca2+]i increments in smooth muscle cells are fast and large.

Intracellular calcium and Na+-Ca2+ exchange current in isolated toad pacemaker cells

1. Single pacemaker cells were isolated from the sinus venosus of cane toad (Bufo marinus) in order to study the mechanisms involved in the spontaneous firing rate of action potentials. Intracellular calcium concentration ([Ca2+]i) was measured with indo-1 to determine whether [Ca2+]i influenced firing rate. A rapid transient rise of [Ca2+]i was recorded together with each spontaneous action potential. [Ca2+]i at the peak of systole was 655 +/- 64 nM and the minimum at the end of diastole was 195 +/- 15 nM. 2. Reduction of extracellular Ca2+ concentration from 2 to 0.5 mM caused a reduction in both systolic and diastolic [Ca2+]i and the spontaneous firing rate also gradually declined. 3. Application of the acetoxymethyl (AM) ester of BAPTA (10 microM), in order to increase intracellular calcium buffering, caused a decline in systolic and diastolic [Ca2+]i. The firing rate declined progressively until the cells stopped firing after 10-15 min. At the time that firing ceased, the diastolic [Ca2+]i had declined by 141 +/- 38 nM. 4. In the presence of ryanodine (2 microM), which interferes with Ca2+ release from the sarcoplasmic reticulum, the systolic and diastolic [Ca2+]i both declined and the firing rate decreased until the cells stopped firing. At quiescence diastolic [Ca2+]i had declined by 93 +/- 20 nM. 5. Exposure of the cells to Na+-free solution caused a rise in [Ca2+]i which exceeded the systolic level after 4.8 +/- 0.3 s. This rise is consistent with Ca2+ entry on a Na+-Ca2+ exchanger. 6. Rapid application of caffeine (10-20 mM) to cells clamped at -60 mV caused a rapid increase in [Ca2+]i which then spontaneously declined. An inward current with a similar time course to that of [Ca2+]i was also generated. Application of Ni2+ (5 mM) or 2,4-dichlorobenzamil (25 microM) reduced the amplitude of the inward current produced by caffeine by 96 +/- 1 % and 74 +/- 10 %, respectively. In a Na+-free solution the caffeine-induced current was reduced by 93 +/- 7 %. 7. Under a variety of circumstances the diastolic [Ca2+]i showed a close association with pacemaker firing rate. The existence of a Na+-Ca2+ exchanger and its estimated contribution to inward current during the pacemaker potential suggest that the Na+-Ca2+ exchange current makes a contribution to pacemaker activity.

Intracellular calcium homeostasis in human primary muscle cells from malignant hyperthermia-susceptible and normal individuals. Effect Of overexpression of recombinant wild-type and Arg163Cys mutated ryanodine receptors

Malignant hyperthermia (MH) is a hypermetabolic disease triggered by volatile anesthetics and succinylcholine in genetically predisposed individuals. Nine point mutations in the skeletal muscle ryanodine receptor (RYR) gene have so far been identified and shown to correlate with the MH-susceptible phenotype, yet direct evidence linking abnormal Ca2+ homeostasis to mutations in the RYR1 cDNA has been obtained for few mutations. In this report, we show for the first time that cultured human skeletal muscle cells derived from MH-susceptible individuals exhibit a half-maximal halothane concentration causing an increase in intracellular Ca2+ concentration which is twofold lower than that of cells derived from MH-negative individuals. We also present evidence demonstrating that overexpression of wild-type RYR1 in cells obtained from MH-susceptible individuals does not restore the MH-negative phenotype, as far as Ca2+ transients elicited by halothane are concerned; on the other hand, overexpression of a mutated RYR1 Arg163Cys Ca2+ channel in muscle cells obtained from MH-negative individuals conveys hypersensitivity to halothane. Finally, our results show that the resting Ca2+ concentration of cultured skeletal muscle cells from MH-negative and MH-susceptible individuals is not significantly different.

Basal intracellular free Mg2+ concentration in smooth muscle cells of guinea pig tenia cecum: intracellular calibration of the fluorescent indicator furaptra

Longitudinal muscle strips dissected from tenia cecum of guinea pig were loaded with the Mg2+ indicator, furaptra, and the relation between the fluorescent ratio signal (R) and cytoplasmic free Mg2+ concentration ([Mg2+]i) was studied in smooth muscle cells at 25 degrees C. After the application of ionophores (4-bromo-A23187, monensin, and nigericin), a small immediate offset of R (deltaRjump) was followed by a slow change in R (deltaRslow), which reached a steady level within 2-5 h. The deltaRjump was independent of Mg2+ concentration in solution ([Mg2+]o), and was thought to be unrelated to the change in [Mg2+]i. The direction of the deltaRslow depended on [Mg2+]o with a reversal at approximately 1 mM [Mg2+]o. The intracellular calibration curve was constructed from the steady levels of deltaRslow, and the dissociation constant was 5.4 mM. With the intracellular calibration curve and correction for the deltaRjump, basal [Mg2+], was estimated to be 0.98 +/- 0.05 mM (mean +/- SE, n = 12). When the same calibration was applied to A7r5 cells and rat ventricular myocytes, estimates of basal [Mg2+]i of these cells were 0.74 +/- 0.02 mM (n = 33) and 1.13 +/- 0.06 mM (n = 9), respectively. These results suggest that the basal [Mg2+] level is approximately 1 mM at least in some types of smooth muscle cells, as generally found in striated muscles.

Apparent Ca2+ dissociation constant of Ca2+ chelators incorporated non-disruptively into intact human red cells

1. A recently developed method of measuring cytoplasmic Ca2+ buffering in intact red cells was applied to re-evaluate the intracellular Ca2+ binding properties of the Ca2+ chelators benz2 and BAPTA. Incorporation of the free chelators was accomplished by incubating the cells with the acetoxymethyl ester forms (benz2 AM or BAPTA AM). The divalent cation ionophore A23187 was used to induce equilibrium distribution of Ca2+ between cells and medium. 45Ca2+ was added stepwise to cell suspensions in the presence and absence of external BAPTA. To induce full Ca2+ equilibration, the plasma membrane Ca2+ pump was inhibited either by depleting the cells of ATP or by adding vanadate to the cell suspension. 2. The properties of the incorporated chelators were assessed from the difference in cytoplasmic Ca2+ buffering between chelator-free and chelator-loaded cells, over a wide range of intracellular ionized calcium concentrations ([Ca2+]i), from nanomolar to millimolar. 3. Under the experimental conditions applied, incorporation of benz2 and BAPTA into the red cells increased their Ca2+ buffering capacity by 300-600 mumol (340 g Hb)-1. The intracellular apparent Ca2+ dissociation constants (KDi) were about 500 nM for benz2 and 800 nM for BAPTA, values much higher than those reported for standard salt solutions (KD) of about 40 and 130 nM, respectively. These results suggest that, contrary to earlier observations, the intracellular red cell environment may cause large shifts in the apparent Ca2+ binding behaviour of incorporated chelators. 4. The possibility that the observed KD shifts are due to reversible binding of the chelators to haemoglobin is considered, and the implications of the present results for early estimates of physiological [Ca2+]i levels is discussed.

Indo-1 fluorescence signals elicited by membrane depolarization in enzymatically isolated mouse skeletal muscle fibers

Indo-1 fluorescence signals were measured from one extremity of enzymatically isolated skeletal muscle fibers of mice. An original and simple method was developed to allow the measurements to be made under voltage-clamp control: the major part of a single fiber was embedded in silicone grease, so that only a short portion of one end of the fiber, from which the fluorescence measurements were taken, was in contact with the external solution. Membrane potential was held and varied by using a patch-clamp amplifier in whole-cell configuration with a single microelectrode, the tip of which was inserted across the silicone grease within the insulated portion of the fiber. In response to 100-ms depolarizing command pulses to voltages more positive than -40 mV (from a holding potential of -80 mV), clear changes in fluorescence were qualitatively observed to feature a time course of rise and decay expected from a change in intracellular calcium concentration ([Ca2+]i) due to voltage-dependent sarcoplasmic reticulum (SR) calcium release. Although the peak [Ca2+]i elicited by a 100-ms depolarization at 0 or +10 mV varied from fiber to fiber, it could clearly reach a value high enough to saturate Indo-1. The overall results show that this method represents an efficient way of measuring depolarization-induced [Ca2+]i changes in enzymatically dissociated skeletal muscle fibers.

Force decline during muscle relaxation promotes calcium release to the cytosol

During relaxation of skeletal muscle, an initial rapid decline of intracellular Ca2+ concentration ([Ca2+]i) (phase 1), is followed by a brief phase in which the decline of [Ca2+]i is markedly slowed or even reversed (phase 2). Phase 2 appears as a prominent "bump" on records of the time course of declining [Ca2+]i during relaxation. The goal of this study was to test the hypothesis that phase 2 represents a release of Ca2+ to the cytosol that occurs with net cross-bridge detachment during relaxation. The experimental approach was to measure [Ca2+]i with indo 1 in stimulated bullfrog semitendinosus muscles and to determine if phase 2 was diminished during relaxation of contractions in which cross-bridge interactions had been reduced by two different methods: 1) stretching muscles to reduce the overlap between actin and myosin filaments or 2) decreasing stimulus duration. The results showed that, when either method was used to reduce cross-bridge interactions during contraction, then the size of phase 2 during relaxation was also decreased. Phase 2 was eliminated during relaxation of contractions in which cross-bridge interactions had been reduced to a lower contraction force approximately 30% of maximum. These findings are consistent with the hypothesis that the phase 2 of [Ca2+]i decline represents a release of Ca2+ to the cytosol that occurs with net cross-bridge detachment during relaxation. This conclusion is consistent with previous studies that suggest that cross-bridge detachment lowers the affinity of troponin for Ca2+.

Slowed relaxation in fatigued skeletal muscle fibers of Xenopus and Mouse. Contribution of [Ca2+]i and cross-bridges

Slowing of relaxation is an important characteristic of skeletal muscle fatigue. The aim of the present study was to quantify the relative contribution of altered Ca2+ handling (calcium component) and factors downstream to Ca2+ (cross-bridge component) to the slowing of relaxation in fatigued fibers of Xenopus and mouse. Two types of Xenopus fibers were used: easily fatigued, type 1 fibers and fatigue resistant, type 2 fibers. In these Xenopus fibers the free myoplasmic [Ca2+] ([Ca2+]i) was measured with indo-1, and the relaxation of Ca2(+)-derived force, constructed from tetanic [Ca2+]i records and in vivo [Ca2+]i-force curves, was analyzed. An alternative method was used in both Xenopus and mouse fibers: fibers were rapidly shortened during the initial phase of relaxation, and the time to the peak of force redevelopment was measured. These two methods gave similar results and showed proportional slowing of the calcium and cross-bridge components of relaxation in both fatigued type 1 and type 2 Xenopus fibers, whereas only the cross-bridge component was slowed in fatigued mouse fibers. Ca2+ removal from the myoplasm during relaxation was markedly less effective in Xenopus fibers as compared to mouse fibers. Fatigued Xenopus fibers displayed a reduced rate of sarcoplasmic reticulum Ca2+ uptake and increased sarcoplasmic reticulum Ca2+ leak. Some fibers were stretched at various times during relaxation. The resistance to these stretches was increased during fatigue, especially in Xenopus fibers, which indicates that longitudinal movements during relaxation had become less pronounced and this might contribute to the increased cross-bridge component of relaxation in fatigue. In conclusion, slowing of relaxation in fatigued Xenopus fibers is caused by impaired Ca2+ handling and altered cross-bridge kinetics, whereas the slowing in mouse fibers is only due to altered cross-bridge kinetics.