CK flux or direct ATP transfer: versatility of energy transfer pathways evidenced by NMR in the perfused heart.

How the myocardium is able to permanently coordinate its intracellular fluxes of ATP synthesis, transfer and utilization is difficult to investigate in the whole organ due to the cellular complexity. The adult myocardium represents a paradigm of an energetically compartmented cell since 50% of total CK activity is bound in the vicinity of other enzymes (myofibrillar sarcolemmal and sarcoplasmic reticulum ATPases as well as mitochondrial adenine nucleotide translocator, ANT). Such vicinity of enzymes is well known in vitro as well as in preparations of skinned fibers to influence the kinetic properties of these enzymes and thus the functioning of the subcellular organelles. Intracellular compartmentation has often been neglected in the NMR analysis of CK kinetics in the whole organ. It is indeed a methodological challenge to reveal subcellular kinetics in a working organ by a global approach such as NMR. To get insight in the energy transfer pathway in the perfused rat heart, we developed a combined analysis of several protocols of magnetization transfer associated with biochemical data and quantitatively evaluated which scheme of energetic exchange best describes the NMR data. This allows to show the kinetic compartmentation of subcellular CKs and to quantify their fluxes. Interestingly, we could show that the energy transfer pathway shifts from the phosphocreatine shuttle in the oxygenated perfused heart to a direct ATP diffusion from mitochondria to cytosol under moderate inhibition of ATP synthesis. Furthermore using NMR measured fluxes and the known kinetic properties of the enzymes, it is possible to model the system, estimate local ADP concentrations and propose hypothesis for the versatility of energy transfer pathway. In the normoxic heart, a 3-fold ADP gradient was found between mitochondrial intermembrane space, cytosol and ADP in the vicinity of ATPases. The shift from PCr to ATP transport observed when ATP synthesis decreases might result from a balance in the activity of two populations of ANT, either coupled or uncoupled to CK. We believe this NMR approach could be a valuable tool to reinvestigate the control of respiration by ADP in the whole heart reconciling the biochemical knowledge of mitochondrial obtained in vitro or in skinned fibers with data on the whole heart as well as to identify the implication of bioenergetics in the pathological heart.

Modeling the energy transfer pathways. creatine kinase activities and heterogeneous distribution of ADP in the perfused heart.

The exchange scheme of high energy phosphate transport in a whole heart relies on a system of CK functioning in different ways. This suggests that the CKs are able to act both like a shuttle and like a buffer for the energy transfer. The challenge is to understand how these two functions are balanced in the CK system. One key of this balance is the knowledge of the local concentrations of the ADP nucleotide. These concentrations cannot be directly measured, but they may be derived by computation. In the present report we introduce the known properties of the enzymes catalyzing the exchange of high energy phosphate into the model of flux pathways derived from NMR experiments to compute both the maximum activity of each enzyme and the local concentrations of all the substrates. We show that the ADP distribution must be heterogeneous for the system to work. Its concentration is 50% higher in the vicinity of ATPase sites and 50% lower in the intermembrane space of the mitochondria than in the cytosol. Another result of this analysis is that the apparent large unbalance of the CKmito pathway is imposed by the adenosine nucleotide transferase fluxes. This analysis proves that it is possible to deduce biochemistry the local concentrations of a substrate by combining data originating from NMR, and enzymology into a common model.

Identification of subcellular energy fluxes by P NMR spectroscopy in the perfused heart: contractility induced modifications of energy transfer pathways.

The identification of subcellular fluxes of exchange of ATP, phosphocreatine (PCr) and Pi between mitochondria, cytosol and ATPases and pathways of energy transfer in a whole organ is a challenge specially in the myocardium where 50% of creatine kinases (CK) are found in close vicinity of ATP producing (mito-CK) and utilizing (MM-bound CK) reactions. To dissect their contribution in cardiac energy transfer we recently developed a new experimental 31P NMR spectroscopy approach. This led to identify three kinetically different subcellular CKs and to evidence experimentally the CK shuttle in a rat heart perfused in isovolumy. Here we show that a decreased energy demand alters energetic pathways : two CKs (cytosolic and MM-bound) functioning at equilibrium and a non mitochondrial ATP<-->Pi exchange was sufficient to describe NMR data. Mito-CK fluxes was not detected anymore. This confirms the dependence of energy pathways upon cardiac activity. Indeed the subcellular localization and activity of CKs may have important bioenergetic consequences for the in vivo control of respiration at high work: free ADP estimated from global CK equilibrium might not always adequately reflect its concentration at the ANT.

Discrimination of cardiac subcellular creatine kinase fluxes by NMR spectroscopy: a new method of analysis.

A challenge in the understanding of creatine kinase (CK) fluxes reflected by NMR magnetization transfer in the perfused rat heart is the choice of a kinetic model of analysis. The complexity of the energetic pathways, due to the presence of adenosine triphosphate (ATP)-inorganic phosphate (Pi) exchange, of metabolite compartmentation and of subcellular localization of CK isozymes cannot be resolve from the sole information obtained from a single NMR protocol. To analyze multicompartment exchanges, we propose a new strategy based on the simultaneous analysis of four inversion transfer protocols. The time course of ATP and Phosphocreatine (PCr) magnetizations computed from the McConnell equations were adjusted to their experimental value for exchange networks of increasing complexity (up to six metabolite pools). Exchange schemes were selected by the quality of their fit and their consistency with data from other sources: the size of mitochondrial pools and the ATP synthesis flux. The consideration of ATP-Pi exchange and of ATP compartmentation were insufficient to describe the data. The most appropriate exchange scheme in our normoxic heart involved the discrimination of three specific CK activities (cytosolic, mitochondrial, and close to ATPases). At the present level of heart contractility, the energy is transferred from mitochondria to myofibrils mainly by PCr.

Evidence for myocardial ATP compartmentation from NMR inversion transfer analysis of creatine kinase fluxes.

The interpretation of creatine kinase (CK) flux measured by (31)P NMR magnetization transfer in vivo is complex because of the presence of competing reactions, metabolite compartmentation, and CK isozyme localization. In the isovolumic perfused rat heart, we considered the influence of both ATP compartmentation and ATP-P(i) exchange on the forward (F(f): PCr --> ATP) and reverse (F(r)) CK fluxes derived from complete analysis of inversion transfer. Although F(f) should equal F(r) because of the steady state, in both protocols when PCr (inv-PCr) or ATP (inv-ATP) was inverted and the contribution of ATP-P(i) was masked by saturation of P(i) (sat-P(i)), F(f)/F(r) significantly differed from 1 (0.80 +/- 0.06 or 1.32 +/- 0.06, respectively, n = 5). These discrepancies could be explained by a compartment of ATP (f(ATP)) not involved in CK. Consistently, neglecting ATP compartmentation in the analysis of CK in vitro results in an underestimation of F(f)/F(r) for inv-PCr and its overestimation for inv-ATP. Both protocols gave access to f(ATP) if the system was adequately analyzed. The fraction of ATP not involved in CK reaction in a heart performing medium work amounts to 20-33% of cellular ATP. Finally, the data suggest that the effect of sat-P(i) might not result only from the masking of ATP-P(i) exchange.

Combination of the novel farnesyltransferase inhibitor RPR130401 and the geranylgeranyltransferase-1 inhibitor GGTI-298 disrupts MAP kinase activation and G(1)-S transition in Ki-Ras-overexpressing transformed adrenocortical cells.

To test the Kirsten-Ras (Ki-Ras) alternative prenylation hypothesis in malignant transformation, we used a novel farnesyltransferase inhibitor competitive to farnesyl-pyrophosphate, RPR130401, and a CaaX peptidomimetic geranylgeranyltransferase-1 inhibitor GGTI-298. In Ki-Ras-overexpressing transformed adrenocortical cells, RPR130401 at 1-10 microM inhibited very efficiently the [(3)H]farnesyl but not [(3)H]geranylgeranyl transfer to Ras. However, proliferation of these cells was only slightly sensitive to RPR130401 (IC(50)=30 microM). GGTI-298 inhibited the growth of these cells with an IC(50) of 11 microM but cell lysis was observed at 15 microM. The combination of 10 microM RPR130401 and 10 microM GGTI-298 inhibited efficiently (80%) cell proliferation. These combined inhibitors but not each inhibitor alone blocked the cell cycle in G(0)/G(1) and disrupted MAP kinase activation. Thus, combination of two inhibitors, at non-cytotoxic concentrations, acting on the farnesyl-pyrophosphate binding site of the farnesyltransferase and the CaaX binding site of the geranylgeranyltransferase-1 respectively is an efficient strategy for disrupting Ki-Ras tumorigenic cell proliferation.

Geranylgeranyl as well as farnesyl moiety is transferred to Ras p21 overproduced in adrenocortical cells transformed by c-Ha-rasEJ oncogene.

The ras-transformed newborn rat adrenocortical (RTAC) cells were obtained by transfection with the mutated c-Ha-rasEJ oncogene. They are proliferative and tumorigenic cells characterized by expression of the c-Ha-rasEJ oncogene and overexpression of a wild-type ras oncogene. The overproduced Ras p21 was identified here as Ki-Ras p21 by western blotting using a specific anti-Ki-Ras monoclonal antibody. Radioactivity derived from [14C]mevalonolactone was strongly incorporated into Ras p21 overproduced in RTAC cells. RTAC cells pretreated with lovastatin and labeled with either [3H]geranylgeranyl-pyrophosphate or [3H]farnesyl-pyrophosphate incorporated also radioactivity into Ras p21. These results showed that overproduced Ras proteins were geranylgeranylated as well as farnesylated in RTAC cells. These findings suggest that the strategy for inhibiting proliferation of Ki-ras-dependent tumorigenic cells should be directed against not only farnesylation but also geranylgeranylation of Ras p21.

Binding constants determined from Ca2+ current responses to rapid applications and washouts of nifedipine in frog cardiac myocytes.

1. A fast perfusion system was used to analyse the kinetics of the response of L-type calcium current (ICa) to rapid applications and washouts of the dihydropyridine antagonist nifedipine in whole-cell patch-clamped frog ventricular myocytes. 2. Both the inhibition of ICa induced by nifedipine and the recovery from inhibition upon washout of the drug behaved as mono-exponential functions of time. 3. During application or washout of 100 nM nifedipine, only the peak amplitude of ICa varied but not its time course of activation or inactivation. 4. The rate constant of the onset of ICa inhibition increased with the concentration of nifedipine. However, the time course of the recovery from inhibition was independent of drug concentration. 5. Both rate constants were strongly sensitive to the holding potential but insensitive to the test potential. 6. Using simple rate equations and a one-binding-site analysis it was possible to determine the rate constants for association (k1) and dissociation (k-1) and the equilibrium dissociation constant (KD) of the reaction between nifedipine and Ca2+ channels. KD values for nifedipine were identical to IC50 values obtained from classical steady-state experiments. 7. With depolarized holding potentials, KD decreased strongly due to a large reduction in k-1 and a modest increase in k1. Assuming that these changes result from the distribution of Ca2+ channels between resting and inactivated states, a low-affinity binding to the resting state (R) and a high-affinity binding to the inactivated state (I) were obtained with the binding constants: k1R = 1.0 x 10(6) M-1 S-1, k-1R = 0.077 S-1, and KDR = 77 nM for the resting state; k1I = 4.47 x 10(6) M-1 S-1, k-1I = 7.7 x 10(-4) S-1, and KDI = 0.17 nM for the inactivated state. 8. Rapid application/washout experiments provide a unique way to determine, in an intact cell and in a relatively short period (2-4 min), the binding rate constants and the KD value of the reaction between a dihydropyridine antagonist and the Ca2+ channels.

Voltage dependence of liver gap-junction channels reconstituted into liposomes and incorporated into planar bilayers.

The voltage dependence of rat liver gap junctions was investigated using non-denaturing solubilization and reconstitution of gap-junction protein into proteoliposomes in controlled conditions of connexon aggregation. The presence of liver connexin 32 in reconstituted proteoliposomes was checked with specific antibodies. The proteoliposomes were inserted into planar lipid bilayers by fusion. The single-channel conductance was voltage independent, and its magnitude was 700-1900 pS in 1 M NaCl, as expected from other reports, assuming that conductance is linear with ion activity. The channels were open at zero voltage and completely closed above 40 mV in either direction. This steep voltage dependence corresponded to an open/closed-state voltage difference of 19 mV and to 3.5 gating charges moving through the field. When several channels were inserted into the bilayer, a large fraction of the membrane conductance became voltage insensitive. These results show that the isolated channel units are highly voltage dependent and are consistent with the assumption that aggregated connexons interact through links which prevent voltage-sensitive conformational changes.

Restoration of gap junction-like structure after detergent solubilization of the proteins from liver gap junctions.

Gap junctions isolated from rat liver were partially solubilized with a mixture of digitonin and octyl glucoside. After supplementation with lecithin and cholesterol, the octyl glucoside was removed from the soluble fraction by dialysis. The membranes of the reconstituted vesicles, observed in freeze-fracture, contained particles ranging from 7 to 12 nm diameter, more or less aggregated depending on the protein-to-lipid ratio. At every protein concentration, the arrangement of particles in contact areas between adjacent membranes closely resembles the organization of intact gap junctions. We conclude that the mixture of digitonin and octyl glucoside is able to solubilize the proteins of the liver gap junctions while preserving their property of restoring a gap junction-like structure.

Distinction between dipolar and inductive effects in modulating the conductance of gramicidin channels.

The ion permeability of transmembrane channels formed by the linear gramicidins is altered by amino acid sequence substitutions. We have previously shown that the polarity of the side chain at position one is important in modulating a channel's conductance and ion selectivity [Russel et al. (1986) Biophys. J. 49, 673-686]. Changes in polarity could alter ion permeability by (through-space) ion-dipole interactions or by (through-bond) inductive electron shifts. We have addressed this question by investigating the permeability characteristics of channels formed by gramicidins where the NH2-terminal amino acid is either phenylalanine or one of a series of substituted phenylalanines: p-hydroxy-, p-methoxy-, o-fluoro-, m-fluoro-, or p-fluorophenylalanine. The electron-donating or -withdrawing nature, as quantified by the Hammett constant, ranges from -0.37 to +0.34 for these side chains. Channels formed by these gramicidins show a more than 2.5-fold variation in their Na+ conductance, but the conductance variations do not rank in the order of the Hammett constants of the side chains. Inductive effects cannot therefore be of primary importance in the modulation of the gramicidin single-channel conductance by these side chains. The results support previous suggestions that electrostatic interactions between side chain dipoles and permeating ions can modify the energy profile for ion movement through the gramicidin channel and thus alter the conductance.

Ultrastructural changes in gap junctions associated with CO2 uncoupling in frog atrial fibres.

The correlation between gap junction morphology and the state of electrical coupling was investigated in the frog auricle, which presents an atypical gap-junction organization. Electrical uncoupling of the tissue was achieved by perfusion with CO2-saturated Ringer medium. The tissue was fixed with glutaraldehyde and freeze-fractured before and during the application of CO2-saturated Ringer medium and after returning to the initial medium. The electrical tissue coupling was assayed by microelectrode recording just before fixation. At least 97% uncoupling was induced by CO2-saturated Ringer medium, as estimated from double sucrose gap experiments on several single atrial trabeculae. Several modifications were induced by CO2-saturated Ringer medium. A decrease in the number of particles per junctional assembly and dispersion of these assemblies in the plane of the membrane, indicate a decrease in the organization of the gap junctions. In parallel, loose clusters of particles became evident on the P-fracture face of the membrane. The size of the particles in these clusters was larger than the size of the background particles, and of the gap junction particles. They never corresponded with complementary pits on the E-fracture face. On return to the initial Ringer perfusion medium the cell coupling was reversed and the gap junction dispersion was also reversed. However, the gap junctions remained small. The relationship between these morphological modifications and the conducting state of the tissue is discussed.

Single-channel studies on linear gramicidins with altered amino acid sequences. A comparison of phenylalanine, tryptophane, and tyrosine substitutions at positions 1 and 11.

The relation between chemical structure and permeability characteristics of transmembrane channels has been investigated with the linear gramicidins (A, B, and C), where the amino acid at position 1 was chemically replaced by phenylalanine, tryptophane or tyrosine. The purity of most of the compounds was estimated to be greater than 99.99%. The modifications resulted in a wide range of conductance changes in NaCl solutions: sixfold from tryptophane gramicidin A to tyrosine gramicidin B. The conductance changes induced by a given amino acid substitution at position 1 are not the same as at position 11. The only important change in the Na+ affinity was observed when the first amino acid was tyrosine. No major conformational changes of the polypeptide backbone structure could be detected on the basis of experiments with mixtures of different analogues and valine gramicidin A (except possibly with tyrosine at position 1), as all the compounds investigated could form hybrid channels with valine gramicidin A. The side chains are not in direct contact with the permeating ions. The results were therefore interpreted in terms of modifications of the energy profile for ion movement through the channel, possibly due to an electrostatic interaction between the dipoles of the side chains and ions in the channel.

Volume- and temperature-dependent permeabilities in isolated rat liver cells.

1. Water, K, Na and Cl contents and fluxes of K and Na were determined in isolated rat hepatocytes incubated at 1 degrees C (90 min) then at 38 degrees C (60 min). At 1 degrees C cells progressively gained Na and Cl, lost K and increased their volume by 17%. 2. Rewarming triggered a net loss of K and gain of Na. They were transitory (about 60 sec) being overcome rapidly by movements in the opposite direction until cells recovered their initial K and Na gradients. 3. Determination of time courses of the K rate constant (kappa' K) and net Na influx (phi Na) in cells incubated in ouabain K-free media indicated that these paradoxical movements were due to a temporary shunting of the Na pump by sudden increases in K and Na permeabilities. 4. Increases in kappa' K and phi' Na were not sensitive to inhibitors of Ca-activated K channels such as quinine (10(-3) M) of apamin (10(-8) M), suggesting they were not dependent on internal ionized Ca. 5. In control media containing 1.8 mM-Ca divalent ionophore A23187, though stimulating the Ca pump (Ca efflux), presumably by increasing internal ionized Ca concentration, did not cause substantial and rapid changes in K permeability. This supports the hypothesis that Ca-sensitive K channels are lacking in rat hepatocytes. 6. A 10% increase in cell volume provoked by a hypo-osmotic shock triggered increases in both kappa' K and phi' Na with time courses very similar to those brought about by rewarming. 7. It is proposed that transient changes in K and Na permeabilities are the consequence of the cell swelling, induced by cooling. These volume-dependent permeabilities are blocked at 1 degrees C and revealed by rewarming.

[Effects of temperature on K, Na and water movements in isolated hepatocytes]. / Effets de la température sur les mouvements de K, de Na, et d'eau dans les hépatocytes isolés.

Isolated hepatocytes incubated at 1 degrees C loss K, gain Na and water. Rewarming results in a transient increase in K and Na permeabilities. These are insensitive to quinine, suggesting that they are not caused by an intracellular Ca accumulation.

[Regulation of isolated rat hepatocyte volume in hypoosmotic media]. / Régulation du volume des hépatocytes isolés de Rat en milieu hypoosmotique.

Isolated hepatocytes behave like osmometers immediately after an incubation in hypo-osmotic media. During long-term incubation periods they recover their normal volume either in the absence or in the presence of ouabain. The volume regulation is parlty due to a decrease in intracellular potassium and amino acid contents.

Fluxes and distribution of calcium in rat liver cells: kinetic analysis and identification of pools.

1. Fluxes and distribution of Ca were studied in the perfused rat liver. Kinetic analysis of (45)Ca exchange revealed three compartments with time constants of 4, 14 and 223 min, pool sizes of 250, 385 and 670 mumole.kg(-1) wet wt. respectively, and one non-exchangeable compartment of 400 mumole.kg(-1).2. (45)Ca uptake by in situ mitochondria followed, as a function of cell loading time, a mono-exponential function with a time constant of 16 min. This suggests that the second compartment may be identified as the intracellular pool of Ca. The calculated cell transmembrane flux of Ca was 28 mumole.kg(-1) min(-1) or 0.17 p-mole.cm(-2).sec(-1).3. The maximum (45)Ca uptake by in situ mitochondria was 2.3 n-mole.mg(-1) of protein which represents, on the basis of 50 mg of mitochondrial protein per g of fresh liver, 115 mumole.kg(-1) or 30% of the cytoplasmic pool. A pool of 10.8 n-mole.mg(-1) protein (or 540 mumole.kg(-1)) of non-exchangeable Ca (at steady state) was probably in the form of Ca phosphate precipitated in the mitochondrial matrix.4. Extracellular Ca pools were studied using competitor of Ca binding (La) or Ca chelators (EGTA). La displaced specifically a homogeneous pool of Ca (tau = 5.1 min) which represented a fraction (55 mumole.kg(-1)) of the rapidly exchangeable Ca (first compartment) without perturbing other external pools. On the other hand, EGTA displaced completely that compartment, and about 85% of the Ca of the third compartment. These results suggest that the first and the major fraction of the third compartments are extracellular. They account for 63% of total exchangeable Ca.5. A model of distribution and exchange of Ca in hepatocytes is proposed.

[Pool kinetics and pathways of 45Ca exchange in rat hepatocytes]. / Cinétique des "pools" et des voles d'échange du 45Ca dans les hépatocytes de rat

The loading and loss kinetics of cellular 45Ca were studied in rat liver cells. The data are described by a three compartment system. Six arrangements of the exchange pathways of these pools are presented. Taking into account the Ca stocking properties of cell organels, two models may be emphasized.