Knowledge is power: Issues of measuring training and performance in cycling.

Mobile power meters provide a valid means of measuring cyclists' power output in the field. These field measurements can be performed with very good accuracy and reliability making the power meter a useful tool for monitoring and evaluating training and race demands. This review presents power meter data from a Grand Tour cyclist's training and racing and explores the inherent complications created by its stochastic nature. Simple summary methods cannot reflect a session's variable distribution of power output or indicate its likely metabolic stress. Binning power output data, into training zones for example, provides information on the detail but not the length of efforts within a session. An alternative approach is to track changes in cyclists' modelled training and racing performances. Both critical power and record power profiles have been used for monitoring training-induced changes in this manner. Due to the inadequacy of current methods, the review highlights the need for new methods to be established which quantify the effects of training loads and models their implications for performance.

Response surface methodology study of the combined effects of temperature, pH, and aw on the growth rate of Trichoderma asperellum.

AIMS: To evaluate the influence of environmental parameters (water activity aw, temperature, and pH) on the radial growth rate of Trichoderma asperellum (strains PR10, PR11, PR12, and 659-7), an antagonist of Phytophthora megakarya, the causal agent of cocoa black pod disease. METHODS AND RESULTS: The radial growth of four strains of T. asperellum was monitored for 30 days on modified PDA medium. Six levels of aw (0.995, 0.980, 0.960, 0.930, 0.910, and 0.880) were combined with three values of pH (4.5, 6.5, and 8.5) and three incubation temperatures (20, 25, and 30 degrees C). Whatever the strain, mycelial growth rate was optimal at aw between 0.995 and 0.980, independently of the temperature and pH. Each strain appeared to be very sensitive to aw reduction. In addition, all four strains were able to grow at all temperatures and pH values (4.5-8.5) tested, highest growth rate being observed at 30 degrees C and at pH 4.5-6.5. The use of response surface methodology to model the combined effects of aw, temperature, and pH on the radial growth rate of the T. asperellum strains confirmed the observed results. In our model, growth of the T. asperellum strains showed a greater dependence on aw than on temperature or pH under in vitro conditions. CONCLUSION: aw is a crucial environmental factor. Low aw can prevent growth of T. asperellum strains under some conditions. The observed and predicted radial growth rate of strain PR11 showed its greater capacity to support low aw (0.93) as compared with other tested strains at 20 degrees C. This is in agreement with its better protective level when applied in medium-scale trials on cocoa plantations. SIGNIFICANCE AND IMPACT OF THE STUDY: This study should contribute towards improving the biocontrol efficacy of T. asperellum strains used against P. megakarya. Integrated into a broader study of the impact of environmental factors on the biocontrol agent-pathogen system, this work should help to build a more rational control strategy, possibly involving the use of a compatible adjuvant protecting T. asperellum against desiccation.

In vitro effects of water activity, temperature and solutes on the growth rate of P. italicum Wehmer and P. digitatum Sacc.

AIMS: To evaluate the effect of water activity (a(w) 0.98-0.89, adjusted with glycerol, sorbitol, glucose, or NaCl) and temperature (5-25 degrees C) on the lag phase and radial growth rate (mm day(-1)) of the important citrus spoilage fungi, such as Penicillium italicum and Penicillium digitatum grown in potato dextrose agar (PDA) medium. To select, among models based on the use of different solutes, a model fitting accurately the growth of these species in relation to a(w) and temperature. METHODS AND RESULTS: Extensive data analyses showed for both Penicillium species a highly significant effect of a(w), temperature, solutes and their interactions on radial growth rate (P < 0.0001). Radial growth rate was inhibited and the lag phase (i.e. the time required for growth) lengthened as the a(w) of the medium decreased. NaCl appeared to causes the greatest stress on growth when compared with other nonionic solutes. Penicillium italicum stopped growing at 0.96 a(w) and P. digitatum at 0.93 a(w). Under the dry conditions where growth was observed, P. italicum grew faster than P. digitatum at low temperature and P. digitatum remained more active at ambient temperature. Multiple regression analysis applied to the square roots of the growth rates observed in the presence of each solute showed that both the 'glycerol model' and the 'sorbitol model' yielded a good prediction of P. italicum growth and the 'sorbitol model' gave an accurate fit for P. digitatum growth, offering high-quality prediction within the experimental limits described. CONCLUSIONS: Mathematical models describing and predicting, as a function of a(w) and temperature, the square root of the radial growth rate of the agents responsible for blue and green decays are important tools for understanding the behaviour of these fungi under natural conditions and for predicting citrus fruit spoilage. SIGNIFICANCE AND IMPACT OF THE STUDY: Implementation of these results should contribute towards a more rational control strategy against citrus spoilage fungi.

Effect of incubation temperature and relative humidity on lesion diameter of Botrytis cinerea Pers. and Penicillium expansum Link. on apple fruits.

Previous studies carried out in our laboratory demonstrated that the growth of B. cinerea and P. expansum was highly influenced by water activity and temperature in 'in vitro' conditions. Regardless the temperature, a, minimal for growth was < or = 0.89 and equal to 0.89 for P. expansum and B. cinerea respectively. The effect of incubation temperature (5-25 degrees C) and relative humidity (RH 75-98%) on the lesion diameter of two common fungi B. cinerea and P. expansum was studied and modelled in the controlled laboratory conditions in order to validate previous findings. The obtained results showed that only temperature had a significant effect on fungal growth on wounded apples. The relative humidity of air had no direct influence on growth of fungi. The part of variation explained by both studied factors is 52 and 55% respectively for P. expansum and B. cinerea. 'Lack of Fit' test was no significant for models, suggesting a greater difference between observed and predicted values. The difference between observed and predicted values was 14 and 29% respectively for P. expansum and B. cinerea. Theses results is in contradiction as compared to in vitro conditions and underlined that the humidity inside wounded apple sites is highly sufficient to start the growth of both postharvest pathogens of apples.

Genetic characterization of the yeast Pichia anomala (strain K), an antagonist of postharvest diseases of apple.

AIMS: To obtain information about the genomic organization of Pichia anomala (strain K) and about its genomic diversity at species and intraspecies level. METHODS AND RESULTS: The PFGE karyotype of strain K was composed of four bands ranging in size from 1.1 to 3.2 Mb. The number of chromosomes was estimated at six since bands 2 and 3 seemed to result from the comigration of two chromosomes with similar size. A comparison of strain K and Hansenulawingeii migration profiles led to the estimate of K strain genome size at 11.7 Mb. Comparison with isogenic strains, resulting from the sporulation of strain K, highlighted some major karyotypic differences. Two segregants (KH6 and KH7) showed supernumerary chromosomes and one (KH9) displayed chromosomal length polymorphism. This genomic instability was confirmed by molecular hybridization with four probes, consisting of URA3, LEU2, PAEXG1 and PAEXG2 genes of P. anomala. URA3 and LEU2 probes showed second hybridization signals on supernumerary chromosomes of strain KH7 and on chromosome 6 of strain K for LEU2 only. Karyotypic comparison of seven non-isogenic P. anomala strains revealed chromosomal length polymorphism, a sign of intraspecies variation. CONCLUSIONS: This work has supplied information about genome size and chromosome number of strain K of P. anomala. The strain seems to be aneuploid because of the presence of supernumerary chromosomes and additional hybridization signals for URA3 and LEU2 probes in the chromosomal profile of some segregants. The work also highlighted genomic diversity within the P. anomala species. SIGNIFICANCE AND IMPACT OF THE STUDY: Results obtained here increase information about the aneuploidy of P. anomala (strain K). Information about the genomic diversity of the segregants will be of great interest for further studies on strain K mode of action. The genome size and chromosomal profile of P. anomala presented here are different from the results obtained elsewhere for Hansenula anomala, while Hansenula is included as a synonym of Pichia. This warrants further studies to investigate this taxonomic relationship.

Multiple modes of calcium-induced calcium release in sympathetic neurons I: attenuation of endoplasmic reticulum Ca2+ accumulation at low [Ca2+](i) during weak depolarization.

Many cells express ryanodine receptors (RyRs) whose activation is thought to amplify depolarization-evoked elevations in cytoplasmic Ca2+ concentration [Ca2+](i) through a process of Ca2+ -induced Ca2+ release (CICR). In neurons, it is usually assumed that CICR triggers net Ca2+ release from an ER Ca2+ store. However, since net ER Ca 2+ transport depends on the relative rates of Ca2+ uptake and release via distinct pathways, weak activation of a CICR pathway during periods of ER Ca accumulation would have a totally different effect: attenuation of Ca2+ accumulation. Stronger CICR activation at higher [Ca2+](i) could further attenuate Ca2+ accumulation or trigger net Ca2+ release, depending on the quantitative properties of the underlying Ca2+ transporters. This and the companion study (Hongpaisan, J., N.B. Pivovarova, S.L. Colgrove, R.D. Leapman, and D.D. Friel, and S.B. Andrews. 2001. J. Gen. Physiol. 118:101-112) investigate which of these CICR "modes" operate during depolarization-induced Ca2+ entry in sympathetic neurons. The present study focuses on small [Ca2+](i) elevations (less than approximately 350 nM) evoked by weak depolarization. The following two approaches were used: (1) Ca2+ fluxes were estimated from simultaneous measurements of [Ca2+](i) and I(Ca) in fura-2-loaded cells (perforated patch conditions), and (2) total ER Ca concentrations ([Ca](ER)) were measured using X-ray microanalysis. Flux analysis revealed triggered net Ca2+ release during depolarization in the presence but not the absence of caffeine, and [Ca2+](i) responses were accelerated by SERCA inhibitors, implicating ER Ca2+ accumulation, which was confirmed by direct [Ca](ER) measurements. Ryanodine abolished caffeine-induced CICR and enhanced depolarization-induced ER Ca2+ accumulation, indicating that activation of the CICR pathway normally attenuates ER Ca2+ accumulation, which is a novel mechanism for accelerating evoked [Ca2+](i) responses. Theory shows how such a low gain mode of CICR can operate during weak stimulation and switch to net Ca2+ release at high [Ca2+](i), a transition demonstrated in the companion study. These results emphasize the importance of the relative rates of Ca2+ uptake and release in defining ER contributions to depolarization-induced Ca2+ signals.

Multiple modes of calcium-induced calcium release in sympathetic neurons II: a [Ca2+](i)- and location-dependent transition from endoplasmic reticulum Ca accumulation to net Ca release.

CICR from an intracellular store, here directly characterized as the ER, usually refers to net Ca(2)+ release that amplifies evoked elevations in cytosolic free calcium [Ca2+](i). However, the companion paper (Albrecht, M.A., S.L. Colegrove, J. Hongpaisan, N.B. Pivovarova, S.B. Andrews, and D.D. Friel. 2001. J. Gen. Physiol. 118:83-100) shows that in sympathetic neurons, small [Ca2+](i) elevations evoked by weak depolarization stimulate ER Ca accumulation, but at a rate attenuated by activation of a ryanodine-sensitive CICR pathway. Here, we have measured depolarization-evoked changes in total ER Ca concentration ([Ca](ER)) as a function of [Ca2+](i), and found that progressively larger [Ca2+](i) elevations cause a graded transition from ER Ca accumulation to net release, consistent with the expression of multiple modes of CICR. [Ca](ER) is relatively high at rest (12.8 +/- 0.9 mmol/kg dry weight, mean +/- SEM) and is reduced by thapsigargin or ryanodine (5.5 +/- 0.7 and 4.7 +/- 1.1 mmol/kg, respectively). [Ca](ER) rises during weak depolarization (to 17.0 +/- 1.6 mmol/kg over 120s, [Ca2+](i) less than approximately 350 nM), changes little in response to stronger depolarization (12.1 +/- 1.1 mmol/kg, [Ca2+](i) approximately 700 nM), and declines (to 6.5 +/- 1.0 mmol/kg) with larger [Ca2+](i) elevations (>1 microM) evoked by the same depolarization when mitochondrial Ca2+ uptake is inhibited (FCCP). Thus, net ER Ca2+ transport exhibits a biphasic dependence on [Ca2+](i). With mitochondrial Ca2+ uptake enabled, [Ca](ER) rises after repolarization (to 16.6 +/- 1.8 mmol/kg at 15 min) as [Ca2+](i) falls within the permissive range for ER Ca accumulation over a period lengthened by mitochondrial Ca2+ release. Finally, although spatially averaged [Ca](ER) is unchanged during strong depolarization, net ER Ca2+ release still occurs, but only in the outermost approximately 5-microm cytoplasmic shell where [Ca2+](i) should reach its highest levels. Since mitochondrial Ca accumulation occurs preferentially in peripheral cytoplasm, as demonstrated here by electron energy loss Ca maps, the Ca content of ER and mitochondria exhibit reciprocal dependencies on proximity to sites of Ca2+ entry, possibly reflecting indirect mitochondrial regulation of ER Ca(2)+ transport.

Mitochondria as regulators of stimulus-evoked calcium signals in neurons.

An important challenge in the study of Ca2+ signalling is to understand the dynamics of intracellular Ca2+ levels during and after physiological stimulation. While extensive information is available regarding the structural and biophysical properties of Ca2+ channels, pumps and exchangers that control cellular Ca2+ movements, little is known about the quantitative properties of the transporters that are expressed together in intact cells or about the way they operate as a system to orchestrate stimulus-induced Ca2+ signals. This lack of information is particularly striking given that many qualitative properties of Ca2+ signals (e.g. whether the Ca2+ concentration within a particular organelle rises or falls during stimulation) depend critically on quantitative properties of the underlying Ca2+ transporters (e.g. the rates of Ca2+ uptake and release by the organelle). This monograph describes the in situ characterization of Ca2+ transport pathways in sympathetic neurons, showing how mitochondrial Ca2+ uptake and release systems define the direction and rate of net Ca2+ transport by this organelle, and how the interplay between mitochondrial Ca2+ transport and Ca+2 transport across the plasma membrane contribute to depolarization-evoked Ca2+ signals in intact cells.

Dissection of mitochondrial Ca2+ uptake and release fluxes in situ after depolarization-evoked [Ca2+](i) elevations in sympathetic neurons.

We studied how mitochondrial Ca2+ transport influences [Ca2+](i) dynamics in sympathetic neurons. Cells were treated with thapsigargin to inhibit Ca2+ accumulation by SERCA pumps and depolarized to elevate [Ca2+(i); the recovery that followed repolarization was then examined. The total Ca2+ flux responsible for the [Ca2+](i) recovery was separated into mitochondrial and nonmitochondrial components based on sensitivity to the proton ionophore FCCP, a selective inhibitor of mitochondrial Ca2+ transport in these cells. The nonmitochondrial flux, representing net Ca2+ extrusion across the plasma membrane, has a simple dependence on [Ca2+](i), while the net mitochondrial flux (J(mito)) is biphasic, indicative of Ca+) accumulation during the initial phase of recovery when [Ca2+](i) is high, and net Ca2+ release during later phases of recovery. During each phase, mitochondrial Ca2+ transport has distinct effects on recovery kinetics. J(mito) was separated into components representing mitochondrial Ca2+ uptake and release based on sensitivity to the specific mitochondrial Na(+)/Ca2+ exchange inhibitor, CGP 37157 (CGP). The CGP-resistant (uptake) component of J(mito) increases steeply with [Ca2+](i), as expected for transport by the mitochondrial uniporter. The CGP-sensitive (release) component is inhibited by lowering the intracellular Na(+) concentration and depends on both intra- and extramitochondrial Ca2+ concentration, as expected for the Na(+)/Ca2+ exchanger. Above approximately 400 nM [Ca2+](i), net mitochondrial Ca2+ transport is dominated by uptake and is largely insensitive to CGP. When [Ca2+](i) is approximately 200-300 nM, the net mitochondrial flux is small but represents the sum of much larger uptake and release fluxes that largely cancel. Thus, mitochondrial Ca2+ transport occurs in situ at much lower concentrations than previously thought, and may provide a mechanism for quantitative control of ATP production after brief or low frequency stimuli that raise [Ca(2+)](i) to levels below approximately 500 nM.

Quantitative analysis of mitochondrial Ca2+ uptake and release pathways in sympathetic neurons. Reconstruction of the recovery after depolarization-evoked [Ca2+]i elevations.

Rate equations for mitochondrial Ca2+ uptake and release and plasma membrane Ca2+ transport were determined from the measured fluxes in the preceding study and incorporated into a model of Ca2+ dynamics. It was asked if the measured fluxes are sufficient to account for the [Ca2+]i recovery kinetics after depolarization-evoked [Ca2+]i elevations. Ca2+ transport across the plasma membrane was described by a parallel extrusion/leak system, while the rates of mitochondrial Ca2+ uptake and release were represented using equations like those describing Ca2+ transport by isolated mitochondria. Taken together, these rate descriptions account very well for the time course of recovery after [Ca2+]i elevations evoked by weak and strong depolarization and their differential sensitivity to FCCP, CGP 37157, and [Na+]i. The model also leads to three general conclusions about mitochondrial Ca2+ transport in intact cells: (1) mitochondria are expected to accumulate Ca2+ even in response to stimuli that raise [Ca2+]i only slightly above resting levels; (2) there are two qualitatively different stimulus regimes that parallel the buffering and non-buffering modes of Ca2+ transport by isolated mitochondria that have been described previously; (3) the impact of mitochondrial Ca2+ transport on intracellular calcium dynamics is strongly influenced by nonmitochondrial Ca2+ transport; in particular, the magnitude of the prolonged [Ca2+]i elevation that occurs during the plateau phase of recovery is related to the Ca2+ set-point described in studies of isolated mitochondria, but is a property of mitochondrial Ca2+ transport in a cellular context. Finally, the model resolves the paradoxical finding that stimulus-induced [Ca2+]i elevations as small as approximately 300 nM increase intramitochondrial total Ca2+ concentration, but the steady [Ca2+]i elevations evoked by such stimuli are not influenced by FCCP.

Depolarization-induced mitochondrial Ca accumulation in sympathetic neurons: spatial and temporal characteristics.

Several lines of evidence suggest that neuronal mitochondria accumulate calcium when the cytosolic free Ca(2+) concentration ([Ca(2+)](i)) is elevated to levels approaching approximately 500 nM, but the spatial, temporal, and quantitative characteristics of net mitochondrial Ca uptake during stimulus-evoked [Ca(2+)](i) elevations are not well understood. Here, we report direct measurements of depolarization-induced changes in intramitochondrial total Ca concentration ([Ca](mito)) obtained by x-ray microanalysis of rapidly frozen neurons from frog sympathetic ganglia. Unstimulated control cells exhibited undetectably low [Ca](mito), but high K(+) depolarization (50 mM, 45 sec), which elevates [Ca(2+)](i) to approximately 600 nM, increased [Ca](mito) to 13.0 +/- 1.5 mmol/kg dry weight; this increase was abolished by carbonyl cyanide p-(trifluoromethoxy) phenylhydrazone (FCCP). The elevation of [Ca](mito) was a function of both depolarization strength and duration. After repolarization, [Ca](mito) recovered to prestimulation levels with a time course that paralleled the decline in [Ca(2+)](i). Depolarization-induced increases in [Ca](mito) were spatially heterogeneous. At the level of single mitochondria, [Ca](mito) elevations depended on proximity to the plasma membrane, consistent with predictions of a diffusion model that considers radial [Ca(2+)](i) gradients that exist early during depolarization. Within individual mitochondria, Ca was concentrated in small, discrete sites, possibly reflecting a high-capacity intramitochondrial Ca storage mechanism. These findings demonstrate that in situ Ca accumulation by mitochondria, now directly identified as the structural correlate of the "FCCP-sensitive store, " is robust, reversible, graded with stimulus strength and duration, and dependent on spatial location.

Critical care nurses' perceptions of their educational needs.

A survey of nurses working in critical care units in 89 Queensland hospitals was conducted to investigate their perceptions of critical care nurses' educational needs. Two thirds of the 62 respondents were from rural units and one third were from metropolitan units. Most respondents, irrespective of geographic location, wanted critical care education to be located in hospitals and to be accredited as a graduate diploma course. Rural and metropolitan nurses had similar educational needs and many worked for hospitals that were not offering adequate orientation or inservice critical care education. The findings that nursing staff turnover was a problem in metropolitan units and that the rural workforce was more stable have implications for the development of educational programs.

[Ca2+]i oscillations in sympathetic neurons: an experimental test of a theoretical model.

[Ca2+]i oscillations have been described in a variety of cells. This study focuses on caffeine-induced [Ca2+]i oscillations in sympathetic neurons. Previous work has shown that these oscillations require Ca2+ entry from the extracellular medium and Ca(2+)-induced Ca2+ release from a caffeine- and ryanodine-sensitive store. The aim of the study was to understand the mechanism responsible for the oscillations. As a starting point, [Ca2+]i relaxations were examined after membrane depolarization and exposure to caffeine. For both stimuli, post-stimulus relaxations could be described by the sum of two decaying exponential functions, consistent with a one-pool system in which Ca2+ transport between compartments is regulated by linear Ca2+ pumps and leaks. After modifying the store to include a [Ca2+]i-sensitive leak, the model also exhibits oscillations such as those observed experimentally. The model was tested by comparing measured and predicted net Ca2+ fluxes during the oscillatory cycle. Three independent fluxes were measured, describing the rates of 1) Ca2+ entry across the plasma membrane, 2) Ca2+ release by the internal store, and 3) Ca2+ extrusion across the plasma membrane and uptake by the internal store. Starting with estimates of the model parameters deduced from post-stimulus relaxations and the rapid upstroke, a set of parameter values was found that provides a good description of [Ca2+]i throughout the oscillatory cycle. With the same parameter values, there was also good agreement between the measured and simulated net fluxes. Thus, a one-pool model with a single [Ca2+]i-sensitive Ca2+ permeability is adequate to account for many of the quantitative properties of steady-state [Ca2+]i oscillations in sympathetic neurons. Inactivation of the intracellular Ca2+ permeability, cooperative nonlinear Ca2+ uptake and extrusion mechanisms, and functional links between plasma membrane Ca2+ transport and the internal store are not required.

Calcium oscillations in neurons.

Oscillations in the cytosolic free Ca2+ concentration ([Ca2+]i) have been described in a variety of cells. In some cases, [Ca2+]i oscillations reflect cycles of membrane depolarization and voltage-dependent Ca2+ entry. In others, they are caused by periodic Ca2+ uptake and release by internal stores, with little immediate requirement for external Ca2+. A third type of [Ca2+]i oscillation is typified by caffeine-induced oscillations in sympathetic neurons. Here, the oscillations depend on the interplay between Ca2+ transport across the plasma membrane and transport by a caffeine-sensitive store. These oscillations can occur at a steady membrane potential and are blocked by ryanodine (1 microM), indicating that they do not result from voltage-dependent changes in Ca2+ entry but do require Ca(2+)-induced Ca2+ release. Entry of Ca2+ from the external medium is important during all phases of the oscillatory cycle except the rapid upstroke, which is dominated by Ca2+ release from an internal store. It is proposed that caffeine-induced [Ca2+]i oscillations are cyclic perturbations of [Ca2+]i caused by exchange of Ca2+ between the cytosol and the caffeine-sensitive store: net Ca2+ loss from the store increases [Ca2+]i transiently above its steady-state value ([Ca2+]ss), whereas net accumulation of Ca2+ by the store transiently depresses [Ca2+]i below [Ca2+]ss. The effects of rapid removal of Ca2+ and caffeine on the rate of change of [Ca2+]i (d[Ca2+]i/dt) provide estimates of the rates of net Ca2+ entry and (caffeine-sensitive) Ca2+ release and information on the way these rates vary during the oscillatory cycle.

An FCCP-sensitive Ca2+ store in bullfrog sympathetic neurons and its participation in stimulus-evoked changes in [Ca2+]i.

This study describes a Ca2+ store in fura-2-loaded bullfrog sympathetic neurons that modulates [Ca2+]i responses elicited by either depolarization or Ca2+ release from a caffeine- and ryanodine-sensitive store. This store is insensitive to caffeine and ryanodine, but is sensitive to the protonophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP). The FCCP-sensitive store slows both the rise in [Ca2+]i during stimulation (apparently by accumulating Ca2+ from the cytosol) and the recovery following stimulation (by releasing the accumulated Ca2+ into the cytosol). For a fixed level of depolarization, recovery is slowed to an extent that depends on stimulus duration. [Ca2+]i imaging shows that these effects are prominent in the soma but not in growth cones. Ca2+ uptake by the FCCP-sensitive store appears to be strongly [Ca2+]i dependent, since it becomes influential only when [Ca2+]i approaches approximately 500 nM. Therefore, this store may specifically influence [Ca2+]i during moderate and strong stimulation. The effect of the store on responses to depolarization can be accounted for by a simple three-compartment scheme consisting of the extracellular medium, the cytosol, and a single internal store with a [Ca2+]i-dependent uptake mechanism resembling the mitochondrial Ca2+ uniporter. The store's effect on responses to caffeine-induced Ca2+ release can be accounted for by including a second internal compartment to represent the caffeine-sensitive store. While the identity of the FCCP-sensitive store is unknown, its sensitivity to FCCP is consistent with a mitochondrial pool. It is suggested that by modulating the temporal properties of [Ca2+]i following stimulation, the FCCP-sensitive store may influence the degree of activation of intracellular [Ca2+]i-dependent processes.

Phase-dependent contributions from Ca2+ entry and Ca2+ release to caffeine-induced [Ca2+]i oscillations in bullfrog sympathetic neurons.

Sympathetic neurons display robust [Ca2+]i oscillations in response to caffeine and mild depolarization. Oscillations occur at constant membrane potential, ruling out voltage-dependent changes in plasma membrane conductance. They are terminated by ryanodine, implicating Ca(2+)-induced Ca2+ release. Ca2+ entry is necessary for sustained oscillatory activity, but its importance varies within the oscillatory cycle: the slow interspike rise in [Ca2+]i requires Ca2+ entry, but the rapid upstroke does not, indicating that it reflects internal Ca2+ release. Sudden alterations in [Ca2+]o, [K+]o, or [caffeine]o produce immediate changes in d[Ca2+]i/dt and provide information about the relative rates of surface membrane Ca2+ transport as well as uptake and release by internal stores. Based on our results, [Ca2+]i oscillations can be explained in terms of coordinated changes in Ca2+ fluxes across surface and store membranes.

A caffeine- and ryanodine-sensitive Ca2+ store in bullfrog sympathetic neurones modulates effects of Ca2+ entry on [Ca2+]i.

1. We studied how in changes in cytosolic free Ca2+ concentration ([Ca2+]i) produced by voltage-dependent Ca2+ entry are influenced by a caffeine-sensitive Ca2+ store in bullfrog sympathetic neurones. Ca2+ influx was elicited by K+ depolarization and the store was manipulated with either caffeine or ryanodine. 2. For a time after discharging the store with caffeine and switching to a caffeine-free medium: (a) [Ca2+]i was depressed by up to 40-50 nM below the resting level, (b) caffeine responsiveness was diminished, and (c) brief K+ applications elicited [Ca2+]i responses with slower onset and faster recovery than controls. These effects were more pronounced as the conditioning caffeine concentration was increased over the range 1-30 mM. 3. [Ca2+]i, caffeine and K+ responsiveness recovered in parallel with a half-time of approximately 2 min. Recovery required external Ca2+ and was speeded by increasing the availability of cytosolic Ca2+, suggesting that it reflected replenishment of the store at the expense of cytosolic Ca2+. 4. During recovery, Ca2+ entry stimulated by depolarization had the least effect on [Ca2+]i when the store was filling most rapidly. This suggests that the effect of Ca2+ entry on [Ca2+]i is modified, at least in part, because some of the Ca2+ which enters the cytosol during stimulation is taken up by the store as it refills. 5. Further experiments were carried out to investigate whether the store can also release Ca2+ in response to stimulated Ca2+ entry. In the continued presence of caffeine at a low concentration (1 mM), high K+ elicited a faster and larger [Ca2+]i response compared to controls; at higher concentrations of caffeine (10 and 30 mM) responses were depressed. 6. Ryanodine (1 microM) reduced the rate at which [Ca2+]i increased with Ca2+ entry, but not to the degree observed after discharging the store. At this concentration, ryanodine completely blocked responses to caffeine but had no detectable effect on Ca2+ channel current or the steady [Ca2+]i level achieved during depolarization. 7. We propose that, depending on its Ca2+ content, the caffeine-sensitive store can either attenuate or potentiate responses to depolarization. When depleted and in the process of refilling, the store reduces the impact of Ca2+ entry as some of the Ca2+ entering the cytosol during stimulation is captured by the store.(ABSTRACT TRUNCATED AT 400 WORDS)