Characterization of Membrane Potential Dependency of Mitochondrial Ca2+ Uptake by an Improved Biophysical Model of Mitochondrial Ca2+ Uniporter

Ranjan K Pradhan; Feng Qi; Daniel A Beard; Ranjan K Dash

doi:10.1371/journal.pone.0013278

. 2010 Oct 8;5(10):e13278. doi: 10.1371/journal.pone.0013278

Characterization of Membrane Potential Dependency of Mitochondrial Ca²⁺ Uptake by an Improved Biophysical Model of Mitochondrial Ca²⁺ Uniporter

Ranjan K Pradhan ¹, Feng Qi ¹, Daniel A Beard ¹, Ranjan K Dash ^1,^*

Editor: Jörg Langowski²

PMCID: PMC2951907 PMID: 20949039

Abstract

Mitochondrial Ca²⁺ uniporter is the primary influx pathway for Ca²⁺ into respiring mitochondria, and hence plays a key role in mitochondrial Ca²⁺ homeostasis. Though the mechanism of extra-matrix Ca²⁺ dependency of mitochondrial Ca²⁺ uptake has been well characterized both experimentally and mathematically, the mechanism of membrane potential (ΔΨ) dependency of mitochondrial Ca²⁺ uptake has not been completely characterized. In this paper, we perform a quantitative reevaluation of a previous biophysical model of mitochondrial Ca²⁺ uniporter that characterized the possible mechanism of ΔΨ dependency of mitochondrial Ca²⁺ uptake. Based on a model simulation analysis, we show that model predictions with a variant assumption (Case 2: external and internal Ca²⁺ binding constants for the uniporter are distinct), that provides the best possible description of the ΔΨ dependency, are highly sensitive to variation in matrix [Ca²⁺], indicating limitations in the variant assumption (Case 2) in providing physiologically plausible description of the observed ΔΨ dependency. This sensitivity is attributed to negative estimate of a biophysical parameter that characterizes binding of internal Ca²⁺ to the uniporter. Reparameterization of the model with additional nonnengativity constraints on the biophysical parameters showed that the two variant assumptions (Case 1 and Case 2) are indistinguishable, indicating that the external and internal Ca²⁺ binding constants for the uniporter may be equal (Case 1). The model predictions in this case are insensitive to variation in matrix [Ca²⁺] but do not match the ΔΨ dependent data in the domain ΔΨ≤120 mV. To effectively characterize this ΔΨ dependency, we reformulate the ΔΨ dependencies of the rate constants of Ca²⁺ translocation via the uniporter by exclusively redefining the biophysical parameters associated with the free-energy barrier of Ca²⁺ translocation based on a generalized, non-linear Goldman-Hodgkin-Katz formulation. This alternate uniporter model has all the characteristics of the previous uniporter model and is also able to characterize the possible mechanisms of both the extra-matrix Ca²⁺ and ΔΨ dependencies of mitochondrial Ca²⁺ uptake. In addition, the model is insensitive to variation in matrix [Ca²⁺], predicting relatively stable physiological operation. The model is critical in developing mechanistic, integrated models of mitochondrial bioenergetics and Ca²⁺ handling.

Introduction

Mitochondrial Ca²⁺ uniporter is the primary influx pathway for Ca²⁺ into respiring mitochondria, and hence is a key regulator of mitochondrial Ca²⁺. Mitochondrial Ca²⁺ homeostasis is critical for metabolic regulation, mitochondrial function/dysfunction, and cell physiology/pathophysiology [1]–[9]. Therefore, a mechanistic characterization of mitochondrial Ca²⁺ uptake via the uniporter is essential for developing mechanistic, integrated models of mitochondrial bioenergetics and Ca²⁺ handling that can be helpful in understanding the mechanisms by which Ca²⁺ plays a role in mediating signaling pathways between cytosol and mitochondria and modulating mitochondrial energy metabolism in health and disease [10], [11].

The kinetics of mitochondrial Ca²⁺ uptake depends on the catalytic properties of the uniporter and also on the electrochemical gradient of Ca²⁺ across the inner mitochondrial membrane (IMM), which has been extensively studied both experimentally [12]–[18] and with the help of mathematical models [10], [11], [19]–[21]. Though the mechanism of extra-matrix Ca²⁺ dependency of mitochondrial Ca²⁺ uptake has been well characterized, the mechanism of membrane potential (ΔΨ) dependency of mitochondrial Ca²⁺ uptake has not been completely characterized.

In a recent paper [11], we introduced a mechanistic mathematical model of mitochondrial Ca²⁺ uniporter (presented briefly in Materials S1) that satisfactorily describes the available experimental data on the kinetics of mitochondrial Ca²⁺ uptake, measured in suspensions of respiring mitochondria isolated from rat hearts and rat livers under various experimental conditions [12], [13], [16]. This model is developed based on a multi-state catalytic binding and interconversion mechanism (Michaelis-Menten kinetics) for carrier-mediated facilitated transport [22], [23], and Eyring's free-energy barrier theory for interconversion and electrodiffusion [22], [24]–[26]. The model also accounts for possible allosteric, cooperative binding of Ca²⁺ to the uniporter, as seen experimentally [12], [13]. Therefore, the biophysical formulation, thermodynamic feasibility, and ability to explain a large number of independent experimental data sets are some of the remarkable features of the model [11], compared to the previous models of the uniporter [19]–[21]. The model was able to characterize the possible mechanisms of both the extra-matrix Ca²⁺ and ΔΨ dependencies of the uniporter-mediated mitochondrial Ca²⁺ uptake [12], [13], [16].

In the development of our recent model of the uniporter [11], two different kinetic models (Model 1 or Model 2: fully or partial cooperativity of Ca²⁺ binding to the uniporter) under two different kinetic assumptions (Case 1 or Case 2: external and internal Ca²⁺ binding constants for the uniporter are equal or distinct) were formulated to characterize the extra-matrix Ca²⁺ and ΔΨ dependencies of mitochondrial Ca²⁺ uptake via the uniporter [12], [13], [16] (see Materials S1). Both the models under both the cases were able to satisfactorily describe the extra-matrix Ca²⁺ dependent data [12], [13]. However, the models under two different cases provided two significantly different predictions of the ΔΨ dependent data [16], especially in the domain ΔΨ≤120 mV. While the models under Case 1 were not able to simulate the ΔΨ dependent data in the domain ΔΨ≤120 mV, the models under Case 2 were able to satisfactorily reproduce the ΔΨ dependent data in the entire ΔΨ domain for which data were available. Based on these kinetic analyses, Case 2 was determined to be the most plausible representation of the observed ΔΨ dependency of the uniporter-mediated mitochondrial Ca²⁺ uptake.

The four variant models of the uniporter [11] were parameterized exclusively based on the experimental data [12], [13], [16] in which matrix [Ca²⁺] was unknown from the measurements. For model parameterization, matrix [Ca²⁺] was fixed at 250 nM. Although the two variant models under Case 2 were able to adequately describe all the available experimental data with appropriate model perturbations as provided by the experimental protocols, it was unknown whether physiological variation of matrix [Ca²⁺], as seen in the intact myocyte, have significant impacts on the estimates of model parameters and model predicted trans-matrix Ca²⁺ fluxes via the uniporter. Therefore, it is important to test the robustness of the estimates of model parameters and model predictions subject to such physiological variation.

In the present paper, we attempt to provide a quantitative reevaluation of our previous model of the uniporter [11]. Based on a model simulation analysis, we show that the two variant model predictions under Case 2 are highly sensitive to variation in matrix [Ca²⁺] (ranging from 100 nM to 500 nM), suggesting that the model parameter estimates under Case 2 would vary significantly to variation in matrix [Ca²⁺], and hence can not be robust. This indeed indicates that the Case 2, in which the Ca²⁺ binding constants for the uniporter at the inside and outside of the IMM are distinct, is physiologically implausible, and hence can not be a feasible representation of the observed ΔΨ dependency of the uniporter-mediated mitochondrial Ca²⁺ uptake. Furthermore, the Case 2 is associated with negative estimates of the biophysical parameter α _x (with α _e = 0 fixed) (see Table S1), which is found to be contributing to the high sensitivities of the model predictions to variation in matrix [Ca²⁺]. To reconcile this issue, we reestimate model parameters subject to the constraint: α _e = α _x = α≥0, which implies that the Ca²⁺ binding sites on the uniporter are located at equal distances from the bulk phase on either side of the IMM. This reparameterization shows that the two variant assumptions on the Ca²⁺ binding to the uniporter (Case 1 and Case 2) are indistinguishable from each other, indicating that the external and internal Ca²⁺ binding constants for the uniporter may be equal (Case 1). The model predictions in this case are insensitive to variation in matrix [Ca²⁺], but do not match the ΔΨ dependent data [16] in the domain ΔΨ≤120 mV.

To accurately characterize the ΔΨ dependency of mitochondrial Ca²⁺ uptake via the uniporter in the entire ΔΨ domain for which data are available [16], we reformulate the ΔΨ dependencies of the rate constants k _in and k _out of Ca²⁺ translocation in our previous model of the uniporter [11] by exclusively redefining the biophysical parameters β _e and β _x associated with the free-energy barrier of Ca²⁺ translocation based on a generalized, non-linear GHK (Goldman-Hodgkin-Katz) formalism (see Materials and Methods). This alternative uniporter model has all the characteristics of our previous uniporter model [11], and is also able to satisfactorily characterize the possible mechanisms of both the extra-matrix Ca²⁺ and ΔΨ dependencies of the uniporter-mediated mitochondrial Ca²⁺ uptake [12], [13], [16]. Furthermore, the model is relatively insensitive to variation in matrix [Ca²⁺], making the model physiologically plausible.

Results

This section presents the detailed simulation analyses of our previous model of mitochondrial Ca²⁺ uniporter [11] that describe the sensitivity of the model predicted mitochondrial Ca²⁺ uptake in response to physiologically realistic variation in matrix [Ca²⁺] and is used to test the robustness of the estimates of model parameters and model predictions. This section also presents the reparameterization of our previous model of the uniporter [11] and parameterization of the present alternate model of the uniporter subject to the constraint: α _e = α _x = α≥0 based on the experimental data of Scarpa and coworkers [12], [13] and Gunter and coworkers [16] on the kinetics of Ca²⁺ fluxes via the uniporter. For the purpose of illustrations, only the fully cooperativity binding model (Model 1) under both the kinetic assumptions (Case 1 and Case 2) is chosen, because both the fully and partial cooperativity binding models (Model 1 and Model 2) are indistinguishable from the available experimental data [12], [13], [16] (see Dash et al. [11]).

The simulation analyses of mitochondrial Ca²⁺ uptake based on our previous model (Model 1) of mitochondrial Ca²⁺ uniporter [11] are shown in Figures 1 and 2. The upper and lower panels correspond to the simulation analyses for Case 1 and Case 2, while the left, middle, and right panels correspond to the simulation analyses based on the experimental protocols of Scarpa and Graziotti [12], Vinogradov and Scarpa [13], and Wingrove et al. [16], respectively. The model uses the same parameter values as estimated before (see Table S1).

Simulations and fittings are shown only for Model 1 under two different cases (Case 1: upper panel and Case 2: lower panel). The left panel (A and D) shows the simulations and fittings of the model to the kinetic data of Scarpa and Graziotti [12] in which the initial rates of Ca²⁺ uptake were measured in respiring mitochondria isolated from rat hearts with varying levels of extra-matrix Ca²⁺. The middle panel (B and E) shows the simulations and fittings of the model to the kinetic data of Vinogradov and Scarpa [13] in which the initial rates of Ca²⁺ uptake were measured in respiring mitochondria isolated from rat livers with varying levels of extra-matrix Ca²⁺. For these analyses, ΔΨ was set at 190 mV, corresponding to state 2 respiration. The right panel (C and F) shows the simulations and fittings of the model to the kinetic data of Wingrove et al. [16] in which the initial rates of Ca²⁺ uptake were measured as a function of ΔΨ in respiring mitochondria isolated from rat livers with three different levels of extra-matrix Ca²⁺ ([Ca²⁺]_e = 0.5 µM, 1.0 µM, and 1.5 µM). For sensitivity color maps, matrix [Ca²⁺] was varied from 100 nM to 500 nM. The black lines corresponding to the model fittings to the data are based on 250 nM of matrix [Ca²⁺]. The other black lines define the borders of the color maps. The model uses the same parameter values as estimated before (Table S1).

Simulations are shown only for Model 1 under two different cases (Case 1: upper panel and Case 2: lower panel). The left panel (A and D) shows the model predicted Ca²⁺ uptake in response to varying extra-matrix Ca²⁺ corresponding to the experimental protocol of Scarpa and Graziotti [12] for a range of ΔΨ. The middle panel (B and E) shows the model predicted Ca²⁺ uptake in response to varying extra-matrix Ca²⁺ corresponding to the experimental protocol of Vinogradov and Scarpa [13] for a range of ΔΨ. In these simulations, ΔΨ was varied from 100 mV to 210 mV and matrix [Ca²⁺] was fixed at 0.25 µM. The right panel (C and F) shows the model predicted Ca²⁺ uptake as a function of ΔΨ corresponding to the experimental protocol of Wingrove et al. [16] with extra-matrix [Ca²⁺] ranging from 10 µM to 150 µM and matrix [Ca²⁺] fixed at 0.25 µM. The model uses the same parameter values as estimated earlier (Table S1). The arrows indicate the direction of increasing ΔΨ in plots A, B, D, and E and increasing extra-matrix [Ca²⁺] in plots C and F.

In the experiments of Scarpa and Graziotti [12] and Vinogradov and Scarpa [13], the initial (or pseudo-steady state) rates of Ca²⁺ influx via the uniporter were measured in suspensions of energized mitochondria purified from rat hearts and rat livers following additions of varying levels of extra-matrix Ca²⁺ (with extra-matrix Mg²⁺ fixed at 5 mM and 2 mM, respectively) (Figure 1 (A,D) and 1 (B,E)). In the experiments of Wingrove et al. [16], the initial (or pseudo-steady state) rates of Ca²⁺ influx via the uniporter were measured as a function of ΔΨ in suspensions of energized mitochondria purified from rat livers with three different levels of extra-matrix Ca²⁺ ([Ca²⁺]_e = 0.5 µM, 1.0 µM, and 1.5 µM; [Mg²⁺]_e = 0 mM) (Figure 1 (C,F)); ΔΨ was varied by adding varying levels of malonate to the extra-matrix buffer medium. In these experiments, matrix [Ca²⁺] was fairly unknown. Our previous model of the uniporter [11] was parameterized based on these experimental data with a fixed matrix [Ca²⁺] of 250 nM. Figure 1 illustrates the effects of physiological variation of matrix [Ca²⁺] on the estimates of model parameters and model predicted Ca²⁺ fluxes via the uniporter.

Specifically, Figure 1 shows the model predicted sensitivities of Ca²⁺ fluxes via the uniporter (lines) as functions of extra-matrix [Ca²⁺] (ΔΨ = 190 mV) and ΔΨ ([Ca²⁺]_e = 0.5 µM, 1.0 µM, and 1.5 µM) over a range of matrix [Ca²⁺] along with the experimental data [12], [13], [16] (points). In these simulations, matrix [Ca²⁺] was varied from 100 nM to 500 nM. The simulations corresponding to the model fits to the data are based on matrix [Ca²⁺] of 250 nM. Figure 2 shows the model predicted Ca²⁺ fluxes via the uniporter as a function of extra-matrix [Ca²⁺] for a range of ΔΨ (100 mV to 210 mV) and as a function of ΔΨ for a range of extra-matrix [Ca²⁺] (10 µM to 150 µM), with matrix [Ca²⁺] fixed at 250 nM.

It is apparent from the model simulation analyses in Figure 1 that though the model under Case 2 with matrix [Ca²⁺] fixed at 250 nM is able to fit well to all of the available experimental data [12], [13], [16] with suitable model perturbations as provided by the experimental protocols, the model predictions under this case are extremely sensitive to variation in matrix [Ca²⁺] (Figure 1 (D–F): lower panel). In contrast, the model predictions under Case 1, although do not fit well to the ΔΨ dependent data in the range ΔΨ≤120 mV, are insensitive to variation in matrix [Ca²⁺] (Figure 1 (A–C): upper panel). It is also observed from Figure 2 that the Ca²⁺ uptake profiles under Case 2 have stiff gradients with respect to ΔΨ and reach saturation for a lower level of extra-matrix [Ca²⁺], compared to that under Case 1. Note that the extra-matrix [Ca²⁺] is in µM range, while matrix [Ca²⁺] is in nM range. Therefore, with a positive ΔΨ (ΔΨ = Ψ_e−Ψ_x = outside potential – inside potential; Ψ_e is positive and Ψ_x is negative) (i.e., with a high electrochemical gradient of Ca²⁺ from the extra-matrix to matrix space), it is unlikely that physiological variation of matrix [Ca²⁺] would have any appreciable effects on the experimental measurements and model predictions on Ca²⁺ fluxes via the uniporter as well as on the estimates of the uniporter model parameters. Furthermore, it is unlikely that in the experiments of Scarpa and colleagues [12], [13] and Gunter and colleagues [16], matrix [Ca²⁺] would have been precisely maintained at 250 nM. Therefore, the present model simulation analyses suggest that the model parameter estimates under Case 2 would vary considerably with variation in matrix [Ca²⁺] as well as with different initial guesses for the parameters, compared to that under Case 1. In the other words, the model parameter estimates under Case 2 would be ambiguous and not unique (robust), and are expected to be different for different matrix [Ca²⁺] and different initial guesses for the parameters. Given matrix [Ca²⁺], the initial guesses for the parameters need to be close to the optimal parameter estimates for the optimization algorithm to converge to the optimal parameter estimates. In this case, the sensitivities of the model to variations in matrix [Ca²⁺] would also be different for different model parameter estimates with similar fittings of the model to the experimental data.

As shown in Table S1, Case 2 is associated with negative estimates of the biophysical parameter α _x (with α _e = 0 fixed), which is found to be contributing to the high sensitivities of the model predictions to variation in matrix [Ca²⁺] and stiff gradients of Ca²⁺ uptake profiles to variation in ΔΨ. The Ca²⁺ uptake profiles under Case 2 attaining saturation for a lower level of extra-matrix [Ca²⁺] is attributed to the lower estimates of Inline graphic and parameters that characterize the binding of [Ca²⁺] to the uniporter (see Table S1). To reconcile this issue, we reestimate our previous uniporter model parameters with an additional constraint: α _e = α _x = α≥0, an assumption that implies that Ca²⁺ binding sites on the uniporter are located at equal distances from the bulk phase on either side of the IMM. With this constraint, four unknown parameters were estimated for Case 1, while five unknown parameters were estimated for Case 2, using the two kinetic and thermodynamic constraints of Eq. (S7), as in our previous paper on the uniporter [11] (see Materials S1). Here, we follow a three-step modular approach to reparameterize our previous uniporter model. In the first step, the binding constants Inline graphic and are estimated based on the extra-matrix Ca²⁺ dependent kinetic data of Scarpa and Graziotti [12] and Vinogradov and Scarpa [13] for the rat heart and liver mitochondria, respectively. The rate constants and and the biophysical parameters α, β _e, and β _x are arbitrarily chosen to satisfy the two kinetic and thermodynamic constraints of Eq. (S7) as well as to fit these data sets, as these parameters can not be accurately estimated from these data sets in which ΔΨ is constant. These extra-matrix Ca²⁺ dependent data sets, however, provide accurate estimates of the binding constants Inline graphic and . In the second step, with the values of and fixed, as estimated in the first step from the data of Vinogradov and Scarpa [13] for rat liver mitochondria, the remaining parameters , , α, β _e, and β _x are estimated from the ΔΨ dependent kinetic data of Wingrove et al. [16] for rat liver mitochondria, subject to the two kinetic and thermodynamic constraints of Eq. (A7). These ΔΨ dependent data provide accurate estimates of the biophysical parameters α, β _e, and β _x. In the final step, with the values of Inline graphic , , α, β _e, and β _x fixed, as estimated from the first and second steps, the rate constants and are estimated for the data sets of Scarpa and Graziotti [12] and Vinogradov and Scarpa [13], to allow these parameters to vary over data sets due to different experimental preparations (e.g., mitochondria from the rat heart vs. rat liver, presence of varying amount of Mg²⁺ in the experimental buffer).

Based on this model reparameterization, Case 2 provides multiple estimates of the kinetic parameters Inline graphic and (see Table 1), all giving exactly the same fittings of the model to the data as for Case 1 (not shown, see below). In this case, the sensitivities of the least-square error to these parameters are extremely low, compared to the other parameters. The biophysical parameters were uniquely estimated as α _e = α _x = α≈0, β _e≈0.113, and β _x≈0.887. The new model fittings to the data for both the cases (Case 1 and Case 2) are exactly same as those shown in Figure 1 (A–C; upper panel), and hence are not shown here again; the new kinetic parameter estimates are also of comparable order of magnitudes for both the cases (see Table 1). Therefore, Case 2 is unidentifiable as a distinct case and is indistinguishable from Case 1. These model simulation analyses merely suggest that Case 2 in which the external and internal Ca²⁺ binding constants for the uniporter were assumed to be distinct ( Inline graphic ≠ and ≠) in our previous uniporter model [11] should not be accepted as a possible explanation for the observed ΔΨ dependency of uniporter-mediated mitochondrial Ca²⁺ uptake [16]. Alternatively, the external and internal Ca²⁺ binding constants for the uniporter may be equal ( Inline graphic = and = ).

Table 1. Reestimated parameter values for our previous models of mitochondrial Ca²⁺ uniporter with additional constraint: α _e = α _x = α≥0.

Parameters	Model 1		Model 2		References
	Case 1	Case 2	Case 1	Case 2
	44.50.300.34	44.50.300.34	32.60.380.43	32.60.380.43	[16] [13] [12]
	44.50.300.34	44.5×m²0.30×m²0.34×m²	32.60.380.43	32.6×m²0.38×m²0.43×m²	[16] [13] [12]
	45.9×10⁻⁶45.9×10⁻⁶88.1×10⁻⁶	45.9×10⁻⁶45.9×10⁻⁶88.1×10⁻⁶	38.7×10⁻⁶38.7×10⁻⁶74.3×10⁻⁶	38.7×10⁻⁶38.7×10⁻⁶74.3×10⁻⁶	[16] [13] [12]
	45.9×10⁻⁶45.9×10⁻⁶88.1×10⁻⁶	45.9×10⁻⁶×m45.9×10⁻⁶×m88.1×10⁻⁶×m	38.7×10⁻⁶38.7×10⁻⁶74.3×10⁻⁶	38.7×10⁻⁶×m38.7×10⁻⁶×m74.3×10⁻⁶×m	[16] [13] [12]
α _e = α _x = α	0.0	0.0	0.0	0.0	[12], [13], [16]
β _e	0.113	0.113	0.113	0.113	[12], [13], [16]
β _x	0.887	0.887	0.887	0.887	[12], [13], [16]

Open in a new tab

The rate constants Inline graphic and are redefined here as and and are in the units of nmol/mg/s; the binding constants and are in the units of molar. The kinetic and biophysical parameters satisfy the kinetic and thermodynamic constraints: and as well as the additional constraint: α _e = α _x = α≥0. The Case 1 corresponds to Inline graphic and , while the Case 2 corresponds to and . Note that m is an arbitrary number indicating the existence of multiple estimates of the kinetic parameters and in Case 2 of the uniporter model.

The simulation analyses of mitochondrial Ca²⁺ uptake based on our present alternative model (Model 1) of mitochondrial Ca²⁺ uniporter, in which Inline graphic = = , = = , α _e = α _x = α, and β _e and β _x are functions of ΔΨ and nH (see Eq. 7), are shown in Figures 3 and 4. For model parameterization, a similar modular approach is used as described above. Specifically, the extra-matrix Ca²⁺ dependent kinetic data of Scarpa and coworkers [12], [13] are first used to get an estimate of the binding constant Inline graphic of Ca²⁺ to the uniporter with arbitrary values of , α, and nH. This estimated value is then fixed and the remaining three parameters (, α, and nH) are estimated from the ΔΨ dependent kinetic data of Gunter and coworkers [16]. In the final step, with the estimated values , α, and nH fixed, the rate constant Inline graphic for the data of Scarpa and coworkers [12], [13] is estimated. This approach enables us to obtain a unique and robust set of parameters for our alternate model of the uniporter (see Table 2).

Simulations and fittings are shown only for Model 1 under Case 1 with the biophysical parameters β _e and β _x as functions of ΔΨ. Plot A shows the model simulations and fittings to the kinetic data of Scarpa and Graziotti [12] in which the initial rates of Ca²⁺ uptake were measured in respiring mitochondria isolated from rat hearts with varying levels of extra-matrix Ca²⁺. Plot B shows the model simulations and fittings to the kinetic data of Vinogradov and Scarpa [13] in which the initial rates of Ca²⁺ uptake were measured in respiring mitochondria isolated from rat livers with varying levels of extra-matrix Ca²⁺. For these analyses, ΔΨ was fixed at 190 mV, corresponding to state 2 respiration. Plot C shows the model simulations and fittings to the kinetic data of Wingrove et al. [16] in which the initial rates of Ca²⁺ uptake were measured as a function of ΔΨ in respiring mitochondria isolated from rat livers with three different levels of extra-matrix Ca²⁺ ([Ca²⁺]_e = 0.5 µM, 1.0 µM, and 1.5 µM). For sensitivity color maps, matrix [Ca²⁺] was varied from 100 nM to 500 nM. The black lines corresponding to the model fittings to the data are based on 250 nM of matrix [Ca²⁺]. The model uses the parameter values estimated based on the present uniporter model (Table 2).

Simulations are shown only for Model 1 under Case 1 with the biophysical parameters β _e and β _x as functions of ΔΨ. Plot A shows the model predicted Ca²⁺ uptake in response to varying extra-matrix Ca²⁺ corresponding to the experimental protocol of Scarpa and Graziotti [12] for a range of ΔΨ. Plot B shows the model predicted Ca²⁺ uptake in response to varying extra-matrix Ca²⁺ corresponding to the experimental protocol of Vinogradov and Scarpa [13] for a range of ΔΨ. In these simulations, ΔΨ was varied from 100 mV to 210 mV and matrix [Ca²⁺] was fixed at 0.25 µM. Plot C shows the model predicted Ca²⁺ uptake as a function of ΔΨ corresponding to the experimental protocol of Wingrove et al. [16] with extra-matrix [Ca²⁺] ranging from 10 µM to 150 µM and matrix [Ca²⁺] fixed at 0.25 µM. The model uses the parameter values estimated based on the present uniporter model (Table 2).

Table 2. Estimated parameter values for our present models of mitochondrial Ca²⁺ uniporter, in which , , α _e = α _x = α≥0, and β = β (nH,ΔΨ).

Parameters	Model 1	Model 2	References
	0.0159, 0.0142, 1.99	0.01972, 0.01775, 1.42	[12], [13], [16]
	87.6, 45.6, 45.6	72.8, 37.9, 37.9	[12], [13], [16]
α	0.0	0.0	[12], [13], [16]
nH	2.65	2.65	[12], [13], [16]

Open in a new tab

The rate constants Inline graphic are in the units of nmol/mg/s and the binding constants are in the units of micro-molar (µM). The biophysical parameters β _e and β _x are obtained as functions of nH and ΔΨ from Eq. (7).

Figure 3 depicts the model predicted sensitivities of Ca²⁺ fluxes via the uniporter (lines) as functions of extra-matrix [Ca²⁺] (ΔΨ = 190 mV) and ΔΨ ([Ca²⁺]_e = 0.5 µM, 1.0 µM, and 1.5 µM) with the variation in matrix [Ca²⁺] (100 nM to 500 nM) and their comparisons to the available experimental data [12], [13], [16] (points), obtained with matrix [Ca²⁺] = 250 nM. Figure 4 depicts the model predicted Ca²⁺ fluxes via the uniporter as a function of extra-matrix [Ca²⁺] for a range of ΔΨ (100 mV to 210 mV) and as a function of ΔΨ for a range of extra-matrix [Ca²⁺] (10 µM to 150 µM), obtained with matrix [Ca²⁺] = 250 nM. The left, middle, and right plots correspond to the model simulation analyses based on the experimental protocols of Scarpa and Graziotti [12], Vinogradov and Scarpa [13], and Wingrove et al. [16], respectively.

The model simulation analyses in Figure 3 demonstrate that our present alternative model of the uniporter is able to match all the available experimental data [12], [13], [16] on the kinetics of both the extra-matrix Ca²⁺ and ΔΨ dependencies of mitochondrial Ca²⁺ uptake via the uniporter in the entire ranges of extra-matrix [Ca²⁺] and ΔΨ for which data were available. In addition, this alternate uniporter model is insensitive to variation in matrix [Ca²⁺], making the model physiologically plausible. This characteristic of the model helps provide unique and accurate estimates of the model parameters with different matrix [Ca²⁺]. It is observed from Figure 4 that the Ca²⁺ uptake profiles, obtained from the present alternate uniporter model, do not have stiff gradients with respect to ΔΨ, and reach saturation for a higher level of extra-matrix [Ca²⁺], comparable to that obtained under Case 1 of our previous uniporter model (see Figure 2 (A–C, upper panel), but unlike to that obtained under Case 2 of our previous uniporter model (Figure 2 (D–F), lower panel). The estimates of the Michaelis-Menten kinetic parameters Inline graphic and based on the previous and present models of the uniporter obtained with the constraint: α _e = α _x = α≥0 are of comparable order of magnitudes (compare and from Table 1 vs. Table 2).

The fittings of Model 1 (Case 1) to the extra-matrix Ca²⁺ dependent data of Scarpa and Graziotti [12] from cardiac mitochondria and Vinogradov and Scarpa [13] from liver mitochondria provides the estimates Inline graphic = = 87.6 µM and = = 0.0159 nmol/mg/sec and = = 45.6 µM and = = 0.0142 nmol/mg/sec, respectively (see Table 2). These differences in the estimates of the kinetic parameters may be attributed towards the fact that the data are from two different mitochondrial preparations and two different experimental protocols (e.g., the differences in the amount of Mg²⁺ present in the two experimental buffer mediums, which is known to compete with Ca²⁺ for transport into mitochondria via the uniporter, and hence inhibits mitochondrial Ca²⁺ uptake [12]–[15], [17]). Analysis of these kinetic data with Model 2 (Case 1) showed that the model parameter values are readjusted to provide similar fits of the model to the three independent experimental data sets (see Table 2).

The ΔΨ dependencies of the biophysical parameters β _e and β _x that characterize the ΔΨ dependent factor E(ΔΨ) in the uniporter flux expressions (see Eqs. S8, 5, and 6), and hence the ΔΨ dependency of mitochondrial Ca²⁺ uptake via the uniporter [16], are demonstrated in Figure 5. The solid lines are based on our present alternate model of the uniporter in which β _e and β _x are analytical functions of ΔΨ (Eq. 7), while the dotted lines are based on our previous model of the uniporter [11] in which β _e and β _x are constants and are numerically estimated. The results show that β _e and β _x based on the previous model abruptly change their respective values at ΔΨ = 0, resulting in non-differentiability of the factor E(ΔΨ) at ΔΨ = 0. In contrast, β _e, β _x, and E(ΔΨ) based on the present model are smooth functions of ΔΨ. The ΔΨ dependent factor E(ΔΨ) in the present model has a larger spread, resulting in a better fit of the model to the ΔΨ dependent data [16]. Also the two ΔΨ dependent factors differ in the domain ΔΨ≤120 mV, describing the discrepancy of the fitting of the two models to the ΔΨ dependent data [16] in this domain.

The solid lines are based on our present model of the uniporter in which β_e and β_x are analytical functions of ΔΨ, while the dotted lines are based on our previous model of the uniporter in which β_e and β_x are constants and are numerically estimated.

Discussion

The major contributions of the present paper lies in the improvements of our previous biophysical model of mitochondrial Ca²⁺ uniporter [11], which is the primary influx pathway for Ca²⁺ into energized (respiring) mitochondria, and hence plays an important role in mitochondrial Ca²⁺ homeostasis. Specifically, the present paper provides an alternate (improved) biophysical model of the uniporter that overcomes the limitations of our previous uniporter model by mechanistically recharacterizing the membrane potential (ΔΨ) dependency of mitochondrial Ca²⁺ uptake via the uniporter. This alternate uniporter model is able to accurately characterize the possible mechanisms of both the extra-matrix Ca²⁺ and ΔΨ dependencies of the uniporter-mediated mitochondrial Ca²⁺ uptake [12], [13], [16]. This model along with our recently developed biophysical model of mitochondrial Na⁺/Ca²⁺ exchanger [27] is important in developing mechanistic, integrated models of mitochondrial bioenergetics and Ca²⁺ handling that can be helpful in understanding the mechanisms by which Ca²⁺ plays a role in mediating signaling pathways between cytosol and mitochondria and modulating mitochondrial energy metabolism in health and disease.

Our previous model of the uniporter [11] was developed based on a multi-state catalytic binding and interconversion mechanism (Michaelis-Menten kinetics) for carrier-mediated facilitated transport [22], [23], combined with Eyring's free-energy barrier theory for interconversion and electrodiffusion (Ca²⁺ translocation) [22], [24]–[26]. The model also accounts for possible allosteric cooperative binding of Ca²⁺ to the uniporter, as depicted experimentally [12], [13]. The model was parameterized based on comparisons of model simulated outputs under various kinetic assumptions (Model 1 or Model 2: fully or partial cooperative binding of Ca²⁺ to the uniporter; Case 1 or Case 2: external and internal Ca²⁺ binding constants for the uniporter are equal or distinct) to several independent experimental data sets from the literature on the kinetics of Ca²⁺ fluxes via the uniporter [12], [13], [16], measured in suspensions of respiring mitochondria purified from rat hearts and rat livers under varying experimental conditions. The model was able to adequately describe the extra-matrix Ca²⁺ dependent data of Scarpa and coworkers [12], [13] as well as the ΔΨ dependent data of Gunter and coworkers [16] with the assumption that the dissociation constants associated with the binding of external and internal Ca²⁺ to the uniporter are distinct (Case 2). Therefore, the mechanistic formulation, thermodynamic feasibility, and ability to describe a large number of independent experimental data sets are some of the notable features of the model [11], compared to the previous models of the uniporter [19]–[21]. Since the present alternate uniporter model is developed from the previous uniporter model by exclusively reformulating the ΔΨ dependencies of the rate constants of Ca²⁺ translocation, the present model has all the characteristics of the previous model.

In the experimental studies of Scarpa and colleagues [12], [13] and Gunter and colleagues [16], matrix [Ca²⁺] was not measured. Our two variant models of the uniporter under two different cases [11] were parameterized entirely based on these experimental data [12], [13], [16] with a fixed matrix [Ca²⁺] of 250 nM. Although both the variant models under Case 2 were able to satisfactorily explain all the available experimental data with suitable model perturbations as provided by the experimental protocols, it was not realized whether physiological variation of matrix [Ca²⁺], as observed in the intact myocyte, will have any appreciable effect on the estimates of model parameters and model predicted trans-matrix Ca²⁺ fluxes via the uniporter. The present study provides a quantitative reevaluation of the previous uniporter model [11] to test the robustness of the estimates of model parameters and model predictions subject to physiologically reasonable variation in matrix [Ca²⁺] ranging from 100 nM to 500 nM. Based on this model simulation analysis, it is found that the two variant model predictions under Case 2 are highly sensitive to variation in matrix [Ca²⁺] (Figure 1 (D–F): lower panel), signifying that the model parameter estimates under Case 2 would vary considerably to variation in matrix [Ca²⁺], and hence can not be robust. In addition, Case 2 was associated negative estimates of the biophysical parameter α _x (with α _e = 0 fixed) (Table S1), attributing to the high sensitivities of the model predictions to variation in matrix [Ca²⁺] (Figure 1(D–F): lower panel) and stiff gradients of Ca²⁺ uptake profiles to variation in ΔΨ (Figure 2 (D–F): lower panel). The reparameterization of the model subject to the constraint: α _e = α _x = α≥0 showed that Case 2 is unidentifiable as a distinct case and is indistinguishable from Case 1.

In summary, the reevaluation of our previous model of mitochondrial Ca²⁺ uniporter [11] simply suggest that Case 2 in which the external and internal Ca²⁺ binding constants for the uniporter were assumed distinct ( Inline graphic ≠ and ≠) is unacceptable as a possible explanation for the observed ΔΨ dependency of mitochondrial Ca²⁺ uptake via the uniporter [16]. On the other hand, the external and internal Ca²⁺ binding constants for the uniporter should be equal ( = and = ) (Table 2), and the biophysical parameters β _e and β _x associated with the free-energy barrier of Ca²⁺ translocation via the uniporter should be dependent on ΔΨ (Eq. B7; Figure 5). The alternate uniporter model based on this revised ΔΨ dependent formulation for β _e and β _x is shown to satisfactorily reproduce all the available experimental data [12], [13], [16] on the kinetics of both the extra-matrix Ca²⁺ and ΔΨ dependencies of mitochondrial Ca²⁺ uptake via the uniporter in the entire ranges of extra-matrix [Ca²⁺] and ΔΨ for which data were available (Figure 3). In addition, the model is insensitive to variation in matrix [Ca²⁺], predicting relatively stable physiological operation of the uniporter.

Recently, mitochondria have been recognized as one of the key organelles that actively involves in physiological Ca²⁺ signaling [6], [8], [28]. Its ability to buffer Ca²⁺ in distinct region of the cells and maintain spatial Ca²⁺ concentration low even under strong global Ca²⁺ mobilization upon cell stimulation is critical for the Ca²⁺ sensitive signal transduction within the cell [29]. It is also evident that, mitochondria can potentially modulate the nature of intracellular Ca²⁺ oscillations and waves, generated by the Ca²⁺ release from the endoplasmic reticulum [30], [31]. While numerous efforts have been made to model intracellular Ca²⁺ oscillations, the mitochondrial Ca²⁺ uptake has also been shown to influence significantly the nature of Ca²⁺ oscillations [32]. Furthermore, in many cell types, the respiring mitochondria remain critical for the activity and maintenance of capacitive Ca²⁺ entry [33], [34]. For example, in a recent study it has been shown that, the mitochondrial Ca²⁺ uptake has considerable effect on the STIM1-Orai1-dependent store operated Ca²⁺ entry into endothelial cells [35]. In this context, the present model of mitochondrial Ca²⁺ uniporter will be crucial for developing an integrated model of intracellular and mitochondrial Ca²⁺ handling which can be helpful in understanding many aspects of signal transduction mechanisms.

Materials and Methods

Alternate Model of Mitochondrial Ca²⁺ Uniporter

This section provides the derivation of the present alternate (improved) biophysical model of mitochondrial Ca²⁺ uniporter that accurately characterizes the ΔΨ dependency of mitochondrial Ca²⁺ uptake via the uniporter [16] under Case 1 ( Inline graphic = and = ) and overcomes the limitations of our previous biophysical model of the uniporter [11]. Specifically, to accurately characterize this ΔΨ dependency under Case 1, we reformulate the ΔΨ dependencies of the rate constants k _in and k _out of Ca²⁺ translocation (Eq. S5, Materials S1) in our previous uniporter model [11] by exclusively redefining the biophysical parameters β _e and β _x associated with the free-energy barrier of Ca²⁺ translocation based on a generalized, non-linear Goldman-Hodgkin-Katz (GHK) formulation. The expressions for the binding constants K _e and K _x and the equilibrium constants K _eq remain the same as in Eqs. (S4) and (S6) of Materials S1. Therefore, the present alternative uniporter model has all the characteristics of our previous uniporter model [11]. We also illustrate that this uniporter model is able to characterize the possible mechanisms of both the extra-matrix Ca²⁺ and ΔΨ dependencies of the uniporter-mediated mitochondrial Ca²⁺ uptake [12], [13], [16] under Case 1. Furthermore, this uniporter model is insensitive to variation in matrix [Ca²⁺], making the model physiologically plausible.

Based on a generalized, non-linear GHK formulation, the rate constants k _in and k _out of Ca²⁺ translocation via the uniporter (see Eq. S5) can be expressed in the following form [1], [9]:

(1)

where Inline graphic is an unknown non-linear function to be determined. Substituting Eq. (1) for k _in and k _out and Eq. (S4) for K _e and K _x into Eqs. (S1–S2), the uniporter flux expression is reduced to

(2)

where D = D ₁ for Model 1 (Eq. S9a) and D = D ₂ for Model 2 (Eq. S9b). In order to derive the functional form of Inline graphic , we consider the equilibrium condition for trans-membrane Ca²⁺ transport via the uniporter , which in combination with Eqs. (S3) and (S6) gives:

(3)

Under Case 1 ( Inline graphic = and = ), the kinetic constraint of Eq. (3) is automatically satisfied. However, the thermodynamic constraint of Eq. (3) provides multiple solutions for . The general solution that satisfies the equilibrium condition for passive Ca²⁺ transport via the uniporter in the absence of ΔΦ Inline graphic is given by

(4a)

where

(4b)

is an even function: Inline graphic ; is an arbitrary number to be determined. Thus, the unknown function is fully characterized by only one unknown parameter nH, and hence the two rate constants k _in and k _out in Eq. (1) are fully characterized by only three unknown parameters , and nH, in contrast to four unknown parameters Inline graphic , , β _e and β _x in the previous formulation (see Materials S1). In standard GHK formulation (linear, constant field-type approximation) for interconversion and electrodiffusion of the uniporter-2Ca²⁺ complex, nH = 1, , and [1], [9]. Substituting Eq. (4) into Eq. (2), the uniporter flux expression can be expressed as

graphic file with name pone.0013278.e110.jpg

(5)

where D = D ₁ for Model 1 (Eq. S9a) and D = D ₂ for Model 2 (Eq. S9b). By comparing the present uniporter model (Eq. 5) with the previous uniporter model (Eq. S8), we obtain the following functional relationship between the biophysical parameters α _e, α _x, β _e, β _x, and nH:

(6)

Using Eq. (6) along with the thermodynamic constraint: Inline graphic , the biophysical parameters β _e and β _x can be expressed in terms of ΔΦ as

(7a)

(7b)

Therefore, the biophysical parameters β _e and β _x in the present model of the uniporter become functions of ΔΨ, compared to the previous model of the uniporter [11], in which β _e and β _x were constant with respect to ΔΨ. Furthermore, both the parameters are characterized by only one unknown parameter nH.

Model Parameterization

Both the kinetic models of the uniporter are characterized by seven unknown parameters: Inline graphic . These parameters are estimated based on the experimental data of Scarpa and coworkers [12], [13] and Gunter and coworkers [16] on the kinetics of Ca²⁺ fluxes via the uniporter subject to the constraints: = = , = = , and α _e = α _x = α≥0 (Case 1). Thus, only four unknown parameters Inline graphic are estimated for both the uniporter models. A least-squares estimation technique is used in multiple steps to fit the model simulated outputs to the experimental data.

(8)

where N _exp is the number of experiments and N _data is the number of data points in a particular experiment, Inline graphic are the experimental data on Ca²⁺ uptakes and are the corresponding model simulated outputs which depend on the model parameters , and is the maximum value of . A MATLAB function optimizer FMINCON is used to minimize the mean residual error E() to estimate the model parameters . The accuracy and robustness of the model fitting to the data for a particular uniporter model is assessed based on the value of the mean residual error E( Inline graphic ) and its sensitivities to perturbations in the optimal parameter estimates.

Supporting Information

Materials S1

Supporting materials that briefly describe the previous models of mitochondrial Ca²⁺ uniporter.

(0.14 MB DOC)

Click here for additional data file.^{(139.5KB, doc)}

Table S1

Estimated parameter values in the previous models of mitochondrial Ca²⁺ uniporter.

(0.09 MB DOC)

Click here for additional data file.^{(85KB, doc)}

Footnotes

Competing Interests: The authors have declared that no competing interests exist.

Funding: This work was supported by National Institutes of Health grants R01-HL072011 (DAB) and R01-HL095122 (RKD) and American Heart Association grant SDG-0735093N (RKD). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

References

1.Gunter TE, Pfeiffer DR. Mechanisms by which mitochondria transport calcium. Am J Physiol. 1990;258:C755–786. doi: 10.1152/ajpcell.1990.258.5.C755. [DOI] [PubMed] [Google Scholar]
2.McCormack JG, Halestrap AP, Denton RM. Role of calcium ions in regulation of mammalian intramitochondrial metabolism. Physiol Rev. 1990;70:391–425. doi: 10.1152/physrev.1990.70.2.391. [DOI] [PubMed] [Google Scholar]
3.Gunter TE, Gunter KK, Sheu SS, Gavin CE. Mitochondrial calcium transport: physiological and pathological relevance. Am J Physiol. 1994;267:C313–339. doi: 10.1152/ajpcell.1994.267.2.C313. [DOI] [PubMed] [Google Scholar]
4.Bernardi P. Mitochondrial transport of cations: channels, exchangers, and permeability transition. Physiol Rev. 1999;79:1127–1155. doi: 10.1152/physrev.1999.79.4.1127. [DOI] [PubMed] [Google Scholar]
5.Duchen MR. Mitochondria and Ca2+ in cell physiology and pathophysiology. Cell Calcium. 2000;28:339–348. doi: 10.1054/ceca.2000.0170. [DOI] [PubMed] [Google Scholar]
6.Duchen MR. Mitochondria and calcium: from cell signalling to cell death. J Physiol. 2000;529 Pt 1:57–68. doi: 10.1111/j.1469-7793.2000.00057.x. [DOI] [PMC free article] [PubMed] [Google Scholar]
7.Brookes PS, Yoon Y, Robotham JL, Anders MW, Sheu SS. Calcium, ATP, and ROS: a mitochondrial love-hate triangle. Am J Physiol Cell Physiol. 2004;287:C817–833. doi: 10.1152/ajpcell.00139.2004. [DOI] [PubMed] [Google Scholar]
8.Bers DM. Calcium cycling and signaling in cardiac myocytes. Annu Rev Physiol. 2008;70:23–49. doi: 10.1146/annurev.physiol.70.113006.100455. [DOI] [PubMed] [Google Scholar]
9.Gunter TE, Sheu SS. Characteristics and possible functions of mitochondrial Ca(2+) transport mechanisms. Biochim Biophys Acta. 2009;1787:1291–1308. doi: 10.1016/j.bbabio.2008.12.011. [DOI] [PMC free article] [PubMed] [Google Scholar]
10.Dash RK, Beard DA. Analysis of cardiac mitochondrial Na+-Ca2+ exchanger kinetics with a biophysical model of mitochondrial Ca2+ handling suggests a 3:1 stoichiometry. J Physiol. 2008;586:3267–3285. doi: 10.1113/jphysiol.2008.151977. [DOI] [PMC free article] [PubMed] [Google Scholar]
11.Dash RK, Qi F, Beard DA. A biophysically based mathematical model for the kinetics of mitochondrial calcium uniporter. Biophys J. 2009;96:1318–1332. doi: 10.1016/j.bpj.2008.11.005. [DOI] [PMC free article] [PubMed] [Google Scholar]
12.Scarpa A, Graziotti P. Mechanisms for intracellular calcium regulation in heart. I. Stopped-flow measurements of Ca2+ uptake by cardiac mitochondria. J Gen Physiol. 1973;62:756–772. doi: 10.1085/jgp.62.6.756. [DOI] [PMC free article] [PubMed] [Google Scholar]
13.Vinogradov A, Scarpa A. The initial velocities of calcium uptake by rat liver mitochondria. J Biol Chem. 1973;248:5527–5531. [PubMed] [Google Scholar]
14.Crompton M, Sigel E, Salzmann M, Carafoli E. A kinetic study of the energy-linked influx of Ca2+ into heart mitochondria. Eur J Biochem. 1976;69:429–434. [Google Scholar]
15.Bragadin M, Pozzan T, Azzone GF. Kinetics of Ca2+ carrier in rat liver mitochondria. Biochemistry. 1979;18:5972–5978. doi: 10.1021/bi00593a033. [DOI] [PubMed] [Google Scholar]
16.Wingrove DE, Amatruda JM, Gunter TE. Glucagon effects on the membrane potential and calcium uptake rate of rat liver mitochondria. J Biol Chem. 1984;259:9390–9394. [PubMed] [Google Scholar]
17.McCormack JG, Browne HM, Dawes NJ. Studies on mitochondrial Ca2+-transport and matrix Ca2+ using fura-2-loaded rat heart mitochondria. Biochim Biophys Acta. 1989;973:420–427. doi: 10.1016/s0005-2728(89)80384-6. [DOI] [PubMed] [Google Scholar]
18.Kirichok Y, Krapivinsky G, Clapham DE. The mitochondrial calcium uniporter is a highly selective ion channel. Nature. 2004;427:360–364. doi: 10.1038/nature02246. [DOI] [PubMed] [Google Scholar]
19.Magnus G, Keizer J. Minimal model of beta-cell mitochondrial Ca2+ handling. Am J Physiol. 1997;273:C717–733. doi: 10.1152/ajpcell.1997.273.2.C717. [DOI] [PubMed] [Google Scholar]
20.Cortassa S, Aon MA, O'Rourke B, Jacques R, Tseng HJ, et al. A computational model integrating electrophysiology, contraction, and mitochondrial bioenergetics in the ventricular myocyte. Biophys J. 2006;91:1564–1589. doi: 10.1529/biophysj.105.076174. [DOI] [PMC free article] [PubMed] [Google Scholar]
21.Nguyen MH, Dudycha SJ, Jafri MS. The Effects of Ca2+ on Cardiac Mitochondrial Energy Production is Modulated by Na+ and H+ Dynamics. Am J Physiol Cell Physiol. 2007;292:2004–2020. doi: 10.1152/ajpcell.00271.2006. [DOI] [PubMed] [Google Scholar]
22.Keener JP, Sneyd J. Mathematical Physiology. New York: Springer; 1998. 766 [Google Scholar]
23.Fall CP, Wagner J, Marland E, editors. Computational Cell Biology. New York: Springer; 2002. 468 [Google Scholar]
24.Woodbury JW. Eyring rate theory model of the current-voltage relationship of ion channels in excitable membranes. In: Hirschfelder J, editor. Chemical Dynamics: Papers in Honor of Henry Eyring. New York: John Wiley and Sons, Inc; 1971. [Google Scholar]
25.Lauger P. Ion transport through pores: a rate-theory analysis. Biochim Biophys Acta. 1973;311:423–441. doi: 10.1016/0005-2736(73)90323-4. [DOI] [PubMed] [Google Scholar]
26.Lauger P, Neumcke B. Theoretical analysis of ion conductance in lipid bilayer membranes. Membranes. 1973;2:1–59. [PubMed] [Google Scholar]
27.Pradhan RK, Beard DA, Dash RK. A biophysically-based mathematical model for the kinetics of mitochondrial Na+-Ca2+ antiporter. Biophys J. 2010;98:1–13. doi: 10.1016/j.bpj.2009.10.005. [DOI] [PMC free article] [PubMed] [Google Scholar]
28.Brini M. Ca(2+) signalling in mitochondria: mechanism and role in physiology and pathology. Cell Calcium. 2003;34:399–405. doi: 10.1016/s0143-4160(03)00145-3. [DOI] [PubMed] [Google Scholar]
29.Malli R, Frieden M, Osibow K, Graier WF. Mitochondria efficiently buffer subplasmalemmal Ca2+ elevation during agonist stimulation. J Biol Chem. 2003;278:10807–10815. doi: 10.1074/jbc.M212971200. [DOI] [PubMed] [Google Scholar]
30.Jouaville LS, Ichas F, Holmuhamedov EL, Camacho P, Lechleiter JD. Synchronization of calcium waves by mitochondrial substrates in Xenopus laevis oocytes. Nature. 1995;377:438–441. doi: 10.1038/377438a0. [DOI] [PubMed] [Google Scholar]
31.Rizzuto R, Marchi S, Bonora M, Aguiari P, Bononi A, et al. Ca(2+) transfer from the ER to mitochondria: when, how and why. Biochim Biophys Acta. 2009;1787:1342–1351. doi: 10.1016/j.bbabio.2009.03.015. [DOI] [PMC free article] [PubMed] [Google Scholar]
32.Marhl M, Schuster S, Brumen M. Mitochondria as an important factor in the maintenance of constant amplitudes of cytosolic calcium oscillations. Biophys Chem. 1998;71:125–132. [PubMed] [Google Scholar]
33.Gilabert JA, Parekh AB. Respiring mitochondria determine the pattern of activation and inactivation of the store-operated Ca(2+) current I(CRAC). EMBO J. 2000;19:6401–6407. doi: 10.1093/emboj/19.23.6401. [DOI] [PMC free article] [PubMed] [Google Scholar]
34.Parekh AB. Slow feedback inhibition of calcium release-activated calcium current by calcium entry. J Biol Chem. 1998;273:14925–14932. doi: 10.1074/jbc.273.24.14925. [DOI] [PubMed] [Google Scholar]
35.Naghdi S, Waldeck-Weiermair M, Fertschai I, Poteser M, Graier WF, et al. Mitochondrial Ca2+ uptake and not mitochondrial motility is required for STIM1-Orai1-dependent store-operated Ca2+ entry. J Cell Sci. 2010;123:2553–2564. doi: 10.1242/jcs.070151. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Materials S1

Supporting materials that briefly describe the previous models of mitochondrial Ca²⁺ uniporter.

(0.14 MB DOC)

Click here for additional data file.^{(139.5KB, doc)}

Table S1

Estimated parameter values in the previous models of mitochondrial Ca²⁺ uniporter.

(0.09 MB DOC)

Click here for additional data file.^{(85KB, doc)}

[pone.0013278-Gunter1] 1.Gunter TE, Pfeiffer DR. Mechanisms by which mitochondria transport calcium. Am J Physiol. 1990;258:C755–786. doi: 10.1152/ajpcell.1990.258.5.C755. [DOI] [PubMed] [Google Scholar]

[pone.0013278-McCormack1] 2.McCormack JG, Halestrap AP, Denton RM. Role of calcium ions in regulation of mammalian intramitochondrial metabolism. Physiol Rev. 1990;70:391–425. doi: 10.1152/physrev.1990.70.2.391. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Gunter2] 3.Gunter TE, Gunter KK, Sheu SS, Gavin CE. Mitochondrial calcium transport: physiological and pathological relevance. Am J Physiol. 1994;267:C313–339. doi: 10.1152/ajpcell.1994.267.2.C313. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Bernardi1] 4.Bernardi P. Mitochondrial transport of cations: channels, exchangers, and permeability transition. Physiol Rev. 1999;79:1127–1155. doi: 10.1152/physrev.1999.79.4.1127. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Duchen1] 5.Duchen MR. Mitochondria and Ca2+ in cell physiology and pathophysiology. Cell Calcium. 2000;28:339–348. doi: 10.1054/ceca.2000.0170. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Duchen2] 6.Duchen MR. Mitochondria and calcium: from cell signalling to cell death. J Physiol. 2000;529 Pt 1:57–68. doi: 10.1111/j.1469-7793.2000.00057.x. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Brookes1] 7.Brookes PS, Yoon Y, Robotham JL, Anders MW, Sheu SS. Calcium, ATP, and ROS: a mitochondrial love-hate triangle. Am J Physiol Cell Physiol. 2004;287:C817–833. doi: 10.1152/ajpcell.00139.2004. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Bers1] 8.Bers DM. Calcium cycling and signaling in cardiac myocytes. Annu Rev Physiol. 2008;70:23–49. doi: 10.1146/annurev.physiol.70.113006.100455. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Gunter3] 9.Gunter TE, Sheu SS. Characteristics and possible functions of mitochondrial Ca(2+) transport mechanisms. Biochim Biophys Acta. 2009;1787:1291–1308. doi: 10.1016/j.bbabio.2008.12.011. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Dash1] 10.Dash RK, Beard DA. Analysis of cardiac mitochondrial Na+-Ca2+ exchanger kinetics with a biophysical model of mitochondrial Ca2+ handling suggests a 3:1 stoichiometry. J Physiol. 2008;586:3267–3285. doi: 10.1113/jphysiol.2008.151977. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Dash2] 11.Dash RK, Qi F, Beard DA. A biophysically based mathematical model for the kinetics of mitochondrial calcium uniporter. Biophys J. 2009;96:1318–1332. doi: 10.1016/j.bpj.2008.11.005. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Scarpa1] 12.Scarpa A, Graziotti P. Mechanisms for intracellular calcium regulation in heart. I. Stopped-flow measurements of Ca2+ uptake by cardiac mitochondria. J Gen Physiol. 1973;62:756–772. doi: 10.1085/jgp.62.6.756. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Vinogradov1] 13.Vinogradov A, Scarpa A. The initial velocities of calcium uptake by rat liver mitochondria. J Biol Chem. 1973;248:5527–5531. [PubMed] [Google Scholar]

[pone.0013278-Crompton1] 14.Crompton M, Sigel E, Salzmann M, Carafoli E. A kinetic study of the energy-linked influx of Ca2+ into heart mitochondria. Eur J Biochem. 1976;69:429–434. [Google Scholar]

[pone.0013278-Bragadin1] 15.Bragadin M, Pozzan T, Azzone GF. Kinetics of Ca2+ carrier in rat liver mitochondria. Biochemistry. 1979;18:5972–5978. doi: 10.1021/bi00593a033. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Wingrove1] 16.Wingrove DE, Amatruda JM, Gunter TE. Glucagon effects on the membrane potential and calcium uptake rate of rat liver mitochondria. J Biol Chem. 1984;259:9390–9394. [PubMed] [Google Scholar]

[pone.0013278-McCormack2] 17.McCormack JG, Browne HM, Dawes NJ. Studies on mitochondrial Ca2+-transport and matrix Ca2+ using fura-2-loaded rat heart mitochondria. Biochim Biophys Acta. 1989;973:420–427. doi: 10.1016/s0005-2728(89)80384-6. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Kirichok1] 18.Kirichok Y, Krapivinsky G, Clapham DE. The mitochondrial calcium uniporter is a highly selective ion channel. Nature. 2004;427:360–364. doi: 10.1038/nature02246. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Magnus1] 19.Magnus G, Keizer J. Minimal model of beta-cell mitochondrial Ca2+ handling. Am J Physiol. 1997;273:C717–733. doi: 10.1152/ajpcell.1997.273.2.C717. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Cortassa1] 20.Cortassa S, Aon MA, O'Rourke B, Jacques R, Tseng HJ, et al. A computational model integrating electrophysiology, contraction, and mitochondrial bioenergetics in the ventricular myocyte. Biophys J. 2006;91:1564–1589. doi: 10.1529/biophysj.105.076174. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Nguyen1] 21.Nguyen MH, Dudycha SJ, Jafri MS. The Effects of Ca2+ on Cardiac Mitochondrial Energy Production is Modulated by Na+ and H+ Dynamics. Am J Physiol Cell Physiol. 2007;292:2004–2020. doi: 10.1152/ajpcell.00271.2006. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Keener1] 22.Keener JP, Sneyd J. Mathematical Physiology. New York: Springer; 1998. 766 [Google Scholar]

[pone.0013278-Fall1] 23.Fall CP, Wagner J, Marland E, editors. Computational Cell Biology. New York: Springer; 2002. 468 [Google Scholar]

[pone.0013278-Woodbury1] 24.Woodbury JW. Eyring rate theory model of the current-voltage relationship of ion channels in excitable membranes. In: Hirschfelder J, editor. Chemical Dynamics: Papers in Honor of Henry Eyring. New York: John Wiley and Sons, Inc; 1971. [Google Scholar]

[pone.0013278-Lauger1] 25.Lauger P. Ion transport through pores: a rate-theory analysis. Biochim Biophys Acta. 1973;311:423–441. doi: 10.1016/0005-2736(73)90323-4. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Lauger2] 26.Lauger P, Neumcke B. Theoretical analysis of ion conductance in lipid bilayer membranes. Membranes. 1973;2:1–59. [PubMed] [Google Scholar]

[pone.0013278-Pradhan1] 27.Pradhan RK, Beard DA, Dash RK. A biophysically-based mathematical model for the kinetics of mitochondrial Na+-Ca2+ antiporter. Biophys J. 2010;98:1–13. doi: 10.1016/j.bpj.2009.10.005. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Brini1] 28.Brini M. Ca(2+) signalling in mitochondria: mechanism and role in physiology and pathology. Cell Calcium. 2003;34:399–405. doi: 10.1016/s0143-4160(03)00145-3. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Malli1] 29.Malli R, Frieden M, Osibow K, Graier WF. Mitochondria efficiently buffer subplasmalemmal Ca2+ elevation during agonist stimulation. J Biol Chem. 2003;278:10807–10815. doi: 10.1074/jbc.M212971200. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Jouaville1] 30.Jouaville LS, Ichas F, Holmuhamedov EL, Camacho P, Lechleiter JD. Synchronization of calcium waves by mitochondrial substrates in Xenopus laevis oocytes. Nature. 1995;377:438–441. doi: 10.1038/377438a0. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Rizzuto1] 31.Rizzuto R, Marchi S, Bonora M, Aguiari P, Bononi A, et al. Ca(2+) transfer from the ER to mitochondria: when, how and why. Biochim Biophys Acta. 2009;1787:1342–1351. doi: 10.1016/j.bbabio.2009.03.015. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Marhl1] 32.Marhl M, Schuster S, Brumen M. Mitochondria as an important factor in the maintenance of constant amplitudes of cytosolic calcium oscillations. Biophys Chem. 1998;71:125–132. [PubMed] [Google Scholar]

[pone.0013278-Gilabert1] 33.Gilabert JA, Parekh AB. Respiring mitochondria determine the pattern of activation and inactivation of the store-operated Ca(2+) current I(CRAC). EMBO J. 2000;19:6401–6407. doi: 10.1093/emboj/19.23.6401. [DOI] [PMC free article] [PubMed] [Google Scholar]

[pone.0013278-Parekh1] 34.Parekh AB. Slow feedback inhibition of calcium release-activated calcium current by calcium entry. J Biol Chem. 1998;273:14925–14932. doi: 10.1074/jbc.273.24.14925. [DOI] [PubMed] [Google Scholar]

[pone.0013278-Naghdi1] 35.Naghdi S, Waldeck-Weiermair M, Fertschai I, Poteser M, Graier WF, et al. Mitochondrial Ca2+ uptake and not mitochondrial motility is required for STIM1-Orai1-dependent store-operated Ca2+ entry. J Cell Sci. 2010;123:2553–2564. doi: 10.1242/jcs.070151. [DOI] [PubMed] [Google Scholar]

PERMALINK

Characterization of Membrane Potential Dependency of Mitochondrial Ca²⁺ Uptake by an Improved Biophysical Model of Mitochondrial Ca²⁺ Uniporter

Ranjan K Pradhan

Feng Qi

Daniel A Beard

Ranjan K Dash

Roles

Abstract

Introduction

Results

Figure 1. Predicted sensitivities (color maps) of mitochondrial Ca²⁺ uptakes as functions of extra-matrix [Ca²⁺] and ΔΨ in response to variation in matrix [Ca²⁺] using our previous model of mitochondrial Ca²⁺ uniporter and their comparisons to the available experimental data (points).

Figure 2. Predictions of mitochondrial Ca²⁺ uptake as a function of extra-matrix [Ca²⁺] for a range of ΔΨ and as a function ΔΨ for a range of extra-matrix [Ca²⁺] based on our previous model of mitochondrial Ca²⁺ uniporter.

Table 1. Reestimated parameter values for our previous models of mitochondrial Ca²⁺ uniporter with additional constraint: α _e = α _x = α≥0.

Figure 4. Predictions of mitochondrial Ca²⁺ uptake as a function of extra-matrix [Ca²⁺] for a range of ΔΨ and as a function ΔΨ for a range of extra-matrix [Ca²⁺] based on our present alternate model of mitochondrial Ca²⁺ uniporter.

Table 2. Estimated parameter values for our present models of mitochondrial Ca²⁺ uniporter, in which , , α _e = α _x = α≥0, and β = β (nH,ΔΨ).

Figure 5. Variation of biophysical parameters β_e and β_x as functions of ΔΨ and the corresponding ΔΨ dependent factors in the uniporter flux expressions as functions of β_e and β_x.

Discussion

Materials and Methods

Alternate Model of Mitochondrial Ca²⁺ Uniporter

Model Parameterization

Supporting Information

Footnotes

References

Associated Data

Supplementary Materials

ACTIONS

PERMALINK

RESOURCES

Cite

Add to Collections

PERMALINK

Characterization of Membrane Potential Dependency of Mitochondrial Ca2+ Uptake by an Improved Biophysical Model of Mitochondrial Ca2+ Uniporter

Ranjan K Pradhan

Feng Qi

Daniel A Beard

Ranjan K Dash

Roles

Abstract

Introduction

Results

Figure 1. Predicted sensitivities (color maps) of mitochondrial Ca2+ uptakes as functions of extra-matrix [Ca2+] and ΔΨ in response to variation in matrix [Ca2+] using our previous model of mitochondrial Ca2+ uniporter and their comparisons to the available experimental data (points).

Figure 2. Predictions of mitochondrial Ca2+ uptake as a function of extra-matrix [Ca2+] for a range of ΔΨ and as a function ΔΨ for a range of extra-matrix [Ca2+] based on our previous model of mitochondrial Ca2+ uniporter.

Table 1. Reestimated parameter values for our previous models of mitochondrial Ca2+ uniporter with additional constraint: α e = α x = α≥0.

Figure 3. Predicted sensitivities (color maps) of mitochondrial Ca2+ uptake as functions of extra-matrix [Ca2+] and ΔΨ in response to variation in matrix [Ca2+] using our present alternate model of mitochondrial Ca2+ uniporter and their comparisons to the available experimental data (points).

Figure 4. Predictions of mitochondrial Ca2+ uptake as a function of extra-matrix [Ca2+] for a range of ΔΨ and as a function ΔΨ for a range of extra-matrix [Ca2+] based on our present alternate model of mitochondrial Ca2+ uniporter.

Table 2. Estimated parameter values for our present models of mitochondrial Ca2+ uniporter, in which , , α e = α x = α≥0, and β = β (nH,ΔΨ).

Figure 5. Variation of biophysical parameters βe and βx as functions of ΔΨ and the corresponding ΔΨ dependent factors in the uniporter flux expressions as functions of βe and βx.

Discussion

Materials and Methods

Alternate Model of Mitochondrial Ca2+ Uniporter

Model Parameterization

Supporting Information

Footnotes

References

Associated Data

Supplementary Materials

ACTIONS

PERMALINK

RESOURCES

Similar articles

Cited by other articles

Links to NCBI Databases

Characterization of Membrane Potential Dependency of Mitochondrial Ca²⁺ Uptake by an Improved Biophysical Model of Mitochondrial Ca²⁺ Uniporter

Figure 1. Predicted sensitivities (color maps) of mitochondrial Ca²⁺ uptakes as functions of extra-matrix [Ca²⁺] and ΔΨ in response to variation in matrix [Ca²⁺] using our previous model of mitochondrial Ca²⁺ uniporter and their comparisons to the available experimental data (points).

Figure 2. Predictions of mitochondrial Ca²⁺ uptake as a function of extra-matrix [Ca²⁺] for a range of ΔΨ and as a function ΔΨ for a range of extra-matrix [Ca²⁺] based on our previous model of mitochondrial Ca²⁺ uniporter.

Table 1. Reestimated parameter values for our previous models of mitochondrial Ca²⁺ uniporter with additional constraint: α _e = α _x = α≥0.

Figure 4. Predictions of mitochondrial Ca²⁺ uptake as a function of extra-matrix [Ca²⁺] for a range of ΔΨ and as a function ΔΨ for a range of extra-matrix [Ca²⁺] based on our present alternate model of mitochondrial Ca²⁺ uniporter.

Table 2. Estimated parameter values for our present models of mitochondrial Ca²⁺ uniporter, in which , , α _e = α _x = α≥0, and β = β (nH,ΔΨ).

Figure 5. Variation of biophysical parameters β_e and β_x as functions of ΔΨ and the corresponding ΔΨ dependent factors in the uniporter flux expressions as functions of β_e and β_x.

Alternate Model of Mitochondrial Ca²⁺ Uniporter