Mg-nucleotides induced dissociation of liposome-bound creatine kinase: reversible changes in its secondary structure and in the fluidity of the bilayer

MgADP binding to mitochondrial creatine kinase (mtCK) adsorbed on liposomes was induced by the photorelease of caged ADP. The nucleotide binding produced two types of structural changes. One was related to the well-established release of mtCK from the liposomes. The other corresponded to reversible structural changes induced by nucleotide binding to mtCK as demonstrated here. Infrared spectroscopy data show that the MgADP-induced desorption of mtCK from vesicles led to a slight increase in alpha-helix structures in mtCK at the expense of a small decrease in beta-sheet structures and a concomitant increase in the fluidity of the membranes. The desorption of mtCK induced by MgADP and MgATP was almost complete, as shown by centrifugation and enzymatic activity measurements. The photorelease of MgADP in a reactive medium containing phosphocreatine and mtCK associated with liposomes led to nucleotide binding and to the formation of MgATP and creatine. Addition of phosphocreatine also desorbed mtCK from liposomes, while addition of creatine did not. Interpretation of these results would suggest that ADP, ATP or phosphocreatine induce the release of mtCK from membranes, increase the phospholipid bilayer fluidity, and may also decrease the number of contact sites between inner and outer mitochondrial membranes, thus affecting the activity of other mitochondrial enzymes. It is tempting to propose that membrane mtCK binding regulation by nucleotide and PCr concentrations may serve as a physiological adaptation for energy supply.     

Mg-nucleotides induced dissociation of liposome-bound creatine kinase: reversible changes in its secondary structure and in the fluidity of the bilayer

MgADP binding to mitochondrial creatine kinase (mtCK) adsorbed on liposomes was induced by the photorelease of caged ADP. The nucleotide binding produced two types of structural changes. One was related to the well-established release of mtCK from the liposomes. The other corresponded to reversible structural changes induced by nucleotide binding to mtCK as demonstrated here. Infrared spectroscopy data show that the MgADP-induced desorption of mtCK from vesicles led to a slight increase in &#102 -helix structures in mtCK at the expense of a small decrease in &#103 -sheet structures and a concomitant increase in the fluidity of the membranes. The desorption of mtCK induced by MgADP and MgATP was almost complete, as shown by centrifugation and enzymatic activity measurements. The photorelease of MgADP in a reactive medium containing phosphocreatine and mtCK associated with liposomes led to nucleotide binding and to the formation of MgATP and creatine. Addition of phosphocreatine also desorbed mtCK from liposomes, while addition of creatine did not. Interpretation of these results would suggest that ADP, ATP or phosphocreatine induce the release of mtCK from membranes, increase the phospholipid bilayer fluidity, and may also decrease the number of contact sites between inner and outer mitochondrial membranes, thus affecting the activity of other mitochondrial enzymes. It is tempting to propose that membrane mtCK binding regulation by nucleotide and PCr concentrations may serve as a physiological adaptation for energy supply.     

Mitochondrial creatine kinase interaction with heterogeneous monolayers: Effect on lipid lateral organization

Our study highlights the tight relationship between protein binding to monolayers and the phase-state of the phospholipids. Interaction of mitochondrial creatine kinase with phospholipidic membranes was analysed using a two-phase monolayer system containing anionic phospholipids under chain mismatch conditions. Monolayers were made up of mixtures of DMPC/DPPG or DPPC/DMPG containing 40% negatively charged phospholipids which is approximately the negative charge content of the mitochondrial inner membrane. Langmuir isotherms of these monolayers showed that they underwent a phase transition from a liquid expanded state to a liquid-condensed phase at about 2 mN/m and 5 mN/m respectively. Interface morphology modifications caused by injection of mtCK under these monolayers at low or high surface pressure were monitored by Brewster angle microscopy. This work provides evidence that the presence at the air/water interface of discrete domains with increased charge density, may lead to difference in partition of soluble proteins such as mtCK, interacting with the lipid monolayer. Conversely these proteins may help to organize charged phospholipid domains in a membrane.     

Mitochondrial Creatine Kinase Binding to Phospholipid Monolayers Induces Cardiolipin Segregation

It is well established that the octameric mitochondrial form of creatine kinase (mtCK) binds to the outer face of the inner mitochondrial membrane mainly via electrostatic interactions with cardiolipin (CL). However, little is known about the consequences of these interactions on membrane and protein levels. Brewster angle microscopy investigations provide, for the first time to our knowledge, images indicating that mtCK binding induced cluster formation on CL monolayers. The thickness of the clusters (10-12 nm) corresponds to the theoretical height of the mtCK-CL complex. Protein insertion into a condensed CL film, together with monolayer stabilization after protein addition, was observed by means of differential capacity measurements. Polarization modulation infrared reflection-absorption spectroscopy showed that the mean orientation of α-helices within the protein shifted upon CL binding from 30° to 45° with respect to the interface plane, demonstrating protein domain movements. A comparison of data obtained with CL and phosphatidylcholine/phosphatidylethanolamine/CL (2:1:1) monolayers indicates that mtCK is able to selectively recruit CL molecules within the mixed monolayer, consolidating and changing the morphology of the interfacial film. Therefore, CL-rich domains induced by mtCK binding could modulate mitochondrial inner membrane morphology into a raft-like organization and influence essential steps of mitochondria-mediated apoptosis.     

Annexin V binding perturbs the cardiolipin fluidity gradient in isolated mitochondria. Can it affect mitochondrial function?

The phosholipid bilayer fluidity of isolated mitochondria and phospholipid vesicles after calcium-dependent binding of annexin V was studied using EPR spectroscopy. The membranes were probed at different depths by alternatively using cardiolipin, phosphatidylcholine, or phosphatidylethanolamine spin labeled at position C-5 or C-12 or C-16 of the beta acyl chain. Computer-aided spectral titration facilitated observing and quantitating the EPR spectrum from phospholipid spin labels affected by annexin binding, and spectral mobility was calibrated by comparison with standard spectra scanned at various temperatures. In most cases it was found that binding of the protein to the membranes makes the inner bilayer more rigid up to acyl position C-12 than afterward, in agreement with the previously observed effect in SUVs [Megli, F. M., Selvaggi, M., Liemann, S., Quagliariello, E., and Huber, R. (1998) Biochemistry 37, 10540-10546]. Moreover, in isolated mitochondrial membranes, cardiolipin apparently is more readily affected than the other main phospholipids, while in vesicles made from mitochondrial phospholipids, the different species are affected in essentially the same way. This behavior is consistent with the existence of distinct cardiolipin pools in mitochondria, and with the already advanced hypothesis that these domains are the binding site for annexin V to the isolated organelles [Megli, F. M., Selvaggi, M., De Lisi, A., and Quagliariello, E. (1995) Biochim. Biophys. Acta 1236, 273-278]. Keeping in mind the funcional importance of cardiolipin in the mitochondrial membrane, the question is raised as to whether the observed influence of annexin V binding to this phospholipid and its consequent local fluidity alteration might affect the mitochondrial functionality, at least in vitro.     

Effect of aging on the composition of mitochondrial membranes from potato slices

The phospholipid content of mitochondrial membranes from slices of potato tuber (Solanum tuberosum) remains stable during aging. The phospholipid compositions of whole mitochondria and inner membranes do not vary during aging whereas the concentrations of phosphatidylinositol and phosphatidyl-glycerol in outer membranes are slightly amplified. The saturation of outer membrane fatty acids is slightly increased during aging. Gel electrophoresis of mitochondrial membrane proteins show slight variations of one polypeptide in outer membranes and of three polypeptides in inner membranes. These results suggest parallel variations of lipids and proteins in membranes during aging, in marked contrast with the large modifications observed in mitochondrial activities.     

Mitochondrial creatine kinase binding to liposomes and vesicle aggregation: effect of cleavage by proteinase K

Mitochondrial creatine kinase and its proteinase K nicked-derivative interaction with liposomes induced slight secondary structure changes evidenced by infrared spectra. In nondenaturing conditions, the N-terminal (K₁) and the C-terminal (K₂) fragments remained associated with each other and bound to liposomes. When the two fragments were separated by denaturation, K₂ was soluble, whereas most of K₁ was adsorbed onto liposomes. The three-dimensional structure of uncleaved mtCK suggests that the C-terminal moiety, which contains positively charged surface residues, interacted with membranes. After denaturation and renaturation of the nicked enzyme, both peptides did not refold properly and did not reassociate with each other. The misfolded K₁ fragment bound to the membrane through a stretch of positive residues, which were buried in the native enzyme. The lack of binding of the ill-folded K₂ peptide could be related to the disruption of the optimal disposition of its positive charges, responsible for the correct interaction of native mtCK with membrane.     

Acyl chain composition determines cardiolipin clustering induced by mitochondrial creatine kinase binding to monolayers

It has been recently shown that mitochondrial creatine kinase (mtCK) organizes mitochondrial model membrane by modulating the state and fluidity of lipids and by promoting the formation of protein-cardiolipin clusters. This report shows, using Brewster angle microscopy, that such clustering is largely dependent on the acyl chain composition of phospholipids. Indeed, mtCK-cardiolipin domains were observed not only with unsaturated cardiolipins, but also with the cardiolipin precursor phosphatidylglycerol. On the other hand, in the case of saturated dimyristoylphosphatidylglycerol and tetramyristoylcardiolipin, mtCK was homogeneously distributed underneath the monolayer. However, an overall decrease in membrane fluidity was indicated by infrared spectroscopy as well as by extrinsic fluorescence spectroscopy using Laurdan as a fluorescent probe, both for tetramyristoylcardiolipin and bovine heart cardiolipin containing liposomes. The binding mechanism implicated the insertion of protein segments into monolayers, as evidenced from alternative current polarography, regardless of the chain unsaturation for the phosphatidylglycerols and cardiolipins tested.     

Interaction of mitochondrial malate dehydrogenase monomer with phospholipid vesicles.

The association between bovine and porcine mitochondrial malate dehydrogenase (EC 1.1.1.37) and phospholipid vesicles was investigated. At concentrations at which malate dehydrogenase exists as a dimer, entrapment within the aqueous compartment but not binding of the 14C-labelled enzyme was observed. The dissociated enzyme was labile to moderate heat and to p-chloromercuribenzoate, but in both cases inactivation was decreased by incubation with suspensions of charged phospholipid vesicles. This suggested an interaction between enzyme subunits and phospholipid, and this was confirmed by direct binding measurements and by studies that followed changes in the fluorescein-labelled enzyme. The circular-dichroism spectra of the enzyme indicated a high alpha-helix content, and suggested that a small conformational change occurred when the enzyme dissociated. Fluorescence data also suggested less-rigid molecules after dissociation. A possible mechanism, based on the flexibility of enzyme monomer and its interaction with phospholipids, by which mitochondrial matrix enzymes are specifically localized in cells, is discussed.     

Corresponding changes in kynurenine hydroxylase activity, membrane fluidity, and sterol composition in Saccharomyces cerevisiae mitochondria.

The effect of sterol composition on the properties of the mitochondrial membrane of Saccharomyces cerevisiae was investigated. The physical state of mitochondrial membranes from wild-type strains and sterol mutants was compared, using a fluorescence polarization technique with 1,6-diphenyl-1,3-5-hexatriene. Changes in the rate of depolarization of the probe molecule as a function of temperature suggest the occurrence of a phase transition in the mitochondrial membranes isolated from the sterol mutants but not in the membranes isolated from the wild types. Arrhenius kinetics of the mitochondrial membrane-bound enzyme L-kynurenine-3-hydroxylase exhibited changes in activation energy at temperatures similar to those observed in the fluorescence polarization study. The ratio of mitochondrial sterol to phospholipid and the phospholipid fatty acid composition of the organisms were characterized.     

Specificity of interaction of hexokinase isozyme II with mitochondrial membranes

Study on the mechanism of hexokinase isozyme II adsorption on mitochondrial membranes in the presence of 10 mM MgCl2 demonstrated that 0.16% of the total proteins of the soluble fraction and the total hexokinase pool are capable of reversible binding to the membrane. The plot for the dependence of the degree of enzyme adsorption on Mg2+ concentration is hyperbolic. Under these conditions, hexokinase competes favourably for the binding sites with lactate dehydrogenase and creatine kinase. Analysis of the adsorption capacity of natural and artificial phospholipid membranes showed that hexokinase isozyme II is adsorbed in much the same way on inner and outer mitochondrial membranes as well as on a mixture of membranes obtained from various sources and on lecithin liposomes. The adsorption properties of hexokinase isozyme II and of its functional analog--isozyme I--point to marked differences in the mechanism of their interaction with the membrane. In contrast with isozyme I, isozyme II of hexokinase undergoes kinetic alterations. Besides, it was found that mild autolysis of isozyme II is accompanied by a loss of the enzyme ability to bind to mitochondrial membranes. The data obtained suggest that the specificity of hexokinase isozyme II adsorption depends on the structural peculiarities of the protein but not on those of the mitochondrial membrane.     

Subzero temperature study of the inner mitochondrial membrane and related phospholipid membrane systems with the fluorescent probe, trans-parinaric acid.

The fluorescence intensity of trans-parinaric acid as a function of the temperature indicates a phase transition in bovine heart mitochondrial inner membranes below 0 degrees C. The comparison of the dye fluorescence intensity in intact inner mitochondrial membranes and in vesicles from extracted phospho lipids of mitochondria revealed a similar intensity increase with decreasing temperature. A synthetic phospholipid system of dioleoyl phosphatidylcholine was investigated because of its low phase transition temperature and showed a very definite intensity change at -25 degrees C. trans-Parinaric acid in membrane systems probes an environment of intermediate polarity; this was found from the excitation and emission spectra and from fluorescence decay.     

Interaction of hexokinase II isoenzyme from rat skeletal muscles with lecithin liposomes

It was found that in the presence of Mg2+ (pH 7.5) rat skeletal muscle hexokinase isozyme II is firmly adsorbed on mitochondrial and artificial phospholipid membranes (lecithin liposomes). In both cases the adsorption isotherm has similar quantitative and qualitative characteristics, which points to the absence of specific binding sites on the membranes. Under these conditions, immobilization of hexokinase on various membranes is concomitant with similar changes in the enzyme stability upon storage as well as with the pH-dependence of the enzyme activity. It was demonstrated that the bound hexokinase form has a greater value of V, an increased affinity for glucose and a decreased sensitivity to the inhibitory action of glucose-6-phosphate as compared to the free form. Besides, this form is in a greater degree subjected to the inhibitory influence of ADP with respect to glucose. In this case, the enzyme affinity for ATP and the Ki value for ADP with respect to ATP is practically the same both for the free and membrane-bound forms. The data obtained suggest that the phospholipid component of mitochondrial membranes participates in the enzyme binding in the presence of Mg2+. It was assumed that the model system used in the present study, i.e., hexokinase-Mg2+-liposomes, may be successfully used for the analysis of an adsorption mechanism of regulation of hexokinase activity in the cell.     

The conformation and thermal stability of soluble cytochrome P-450 and cytochrome P-450 incorporated into liposomal membranes

The α-helix content of the cytochrome P-450 incorporated into the liposomal membranes of either phosphatidylcholine or microsomal phospholipid insignificantly differed from that of the soluble one. The binding of both type I and type II substrates with cytochrome P-450 incorporated into phosphatidylcholine and microsomal phospholipid membranes did not change the conformation of the polypeptide chain. In contrast to this the type II substrates increased the α-helix content of soluble hemoprotein about 3–5%. Dithionite reduction of the cytochrome P-450 haem increased the degree of α spiralization up to 10% for soluble hemoprotein and up to 5% for the membrane-bound enzyme only. The investigation of the thermal stability of the soluble and liposomal forms of cytochrome P-450 showed that the enzyme incorporated into phospholipid vesicles was highly stable. The heating of the enzyme was followed by a slightly pronounced cooperative transition in contrast to the well-pronounced transition for the soluble cytochrome P-450. Hence, the incorporation of the soluble cytochrome P-450 into phospholipid bilayer does not result in significant change of α-helix content, but the increasing of rigidity and thermal stability of the membrane-bound hemoprotein molecule is observed.     

Surface potential and the interaction of weakly acidic uncouplers of oxidative phosphorylation with liposomes and mitochondria

The pH dependence of the binding of weakly acidic uncouplers of oxidative phosphorylation to rat-liver mitochondria and liposomes is mainly determined by the pK_a of the uncoupler molecule.

The absorption and fluorescence excitation spectra of the anionic form of weakly acidic uncouplers of oxidative phosphorylation are red-shifted upon interaction with liposomal or mitochondrial membranes. The affinity for the liposomes, as deduced from the red shift, is independent of the degree of saturation of the fatty acid chains of different lecithins. The intensity of the spectra at one pH value is strongly dependent upon the surface charge of the liposomes. With positively charged liposomes the results obtained can be almost quantitatively explained with the Gouy-Chapman theory, but with negatively charged ones deviations are observed. At a particular pH, the divalent ion Ca²⁺ strongly influences the intensity of the spectra in the presence of negatively charged liposomes, but has no effect with neutral liposomes.

With mitochondrial membranes an effect of Ca²⁺ similar to that with negatively charged liposomes is observed. Depletion of the phospholipids of the mitochondria and subsequent restoration of the mitochondrial membrane with lecithin, strongly diminishes this effect, but restoration with negatively charged phospholipids does not influence it.

From these observations it is concluded that the anionic form of the uncoupler molecule when bound to mitochondria is located within the partly negatively charged phospholipid moiety of the membrane, with its anionic group pointing to the aqueous solution.     

Intracellular distribution of the fluorescent dye nonyl acridine orange responds to the mitochondrial membrane potential: implications for assays of cardiolipin and mitochondrial mass

Cardiolipin, a polyunsaturated acidic phospholipid, is found exclusively in bacterial and mitochondrial membranes where it is intimately associated with the enzyme complexes of the respiratory chain. Cardiolipin structure and concentration are central to the function of these enzyme complexes and damage to the phospholipid may have consequences for mitochondrial function. The fluorescent dye, 10 nonyl acridine orange (NAO), has been shown to bind cardiolipin in vitro and is frequently used as a stain in living cells to assay cardiolipin content. Additionally, NAO staining has been used to measure the mitochondrial content of cells as dye binding to mitochondria is reportedly independent of the membrane potential. We used confocal microscopy to examine the properties of NAO in cortical astrocytes, neonatal cardiomyocytes and in isolated brain mitochondria. We show that NAO, a lipophilic cation, stained mitochondria selectively. However, the accumulation of the dye was clearly dependent upon the mitochondrial membrane potential and depolarisation of mitochondria induced a redistribution of dye. Moreover, depolarisation of mitochondria prior to NAO staining also resulted in a reduced NAO signal. These observations demonstrate that loading and retention of NAO is dependant upon membrane potential, and that the dye cannot be used as an assay of either cardiolipin or mitochondrial mass in living cells.     

Phospholipid complexation and association with apolipoprotein C-II: insights from mass spectrometry

The interactions between phospholipid molecules in suspensions have been studied by using mass spectrometry. Electrospray mass spectra of homogeneous preparations formed from three different phospholipid molecules demonstrate that under certain conditions interactions between 90 and 100 lipid molecules can be preserved. In the presence of apolipoprotein C-II, a phospholipid binding protein, a series of lipid molecules and the protein were observed in complexes. The specificity of binding was demonstrated by proteolysis; the resulting mass spectra reveal lipid-bound peptides that encompass the proposed lipid-binding domain. The mass spectra of heterogeneous suspensions and their complexes with apolipoprotein C-II demonstrate that the protein binds simultaneously to two different phospholipids. Moreover, when apolipoprotein C-II is added to lipid suspensions formed with local concentrations of the same lipid molecule, the protein is capable of remodeling the distribution to form one that is closer to a statistical arrangement. These observations demonstrate a capacity for apolipoprotein C-II to change the topology of the phospholipid surface. More generally, these results highlight the fact that mass spectrometry can be used to probe lipid interactions in both homogeneous and heterogeneous suspensions and demonstrate reorganization of the distribution of lipids upon surface binding of apolipoprotein C-II.     

Interaction of the P-type cardiotoxin with phospholipid membranes.

The cardiotoxin (cytotoxin II, or CTII) isolated from cobra snake (Naja oxiana) venom is a 60-residue basic membrane-active protein featuring three-finger beta sheet fold. To assess possible modes of CTII/membrane interaction 31P- and 1H-NMR spectroscopy was used to study binding of the toxin and its effect onto multilamellar vesicles (MLV) composed of either zwitterionic or anionic phospholipid, dipalmitoylglycerophosphocholine (Pam2Gro-PCho) or dipalmitoylglycerophosphoglycerol (Pam2Gro-PGro), respectively. The analysis of 1H-NMR linewidths of the toxin and 31P-NMR spectral lineshapes of the phospholipid as a function of temperature, lipid-to-protein ratios, and pH values showed that at least three distinct modes of CTII interaction with membranes exist: (a) nonpenetrating mode; in the gel state of the negatively charged MLV the toxin is bound to the surface electrostatically; the binding to Pam2Gro-PCho membranes was not observed; (b) penetrating mode; hydrophobic interactions develop due to penetration of the toxin into Pam2Gro-PGro membranes in the liquid-crystalline state; it is presumed that in this mode CTII is located at the membrane/water interface deepening the side-chains of hydrophobic residues at the tips of the loops 1-3 down to the boundary between the glycerol and acyl regions of the bilayer; (c) the penetrating mode gives way to isotropic phase, stoichiometrically well-defined CTII/phospholipid complexes at CTII/lipid ratio exceeding a threshold value which was found to depend at physiological pH values upon ionization of the imidazole ring of His31. Biological implications of the observed modes of the toxin-membrane interactions are discussed.     

GTP but not GDP analogues promote association of ADP-ribosylation factors, 20-kDa protein activators of cholera toxin, with phospholipids and PC-12 cell membranes.

ADP-ribosylation factors (ARFs) are a family of approximately 20-kDa guanine nucleotide-binding proteins initially identified by their ability to enhance cholera toxin ADP-ribosyltransferase activity in the presence of GTP. ARFs have been purified from both membrane and cytosolic fractions. ARF purified from bovine brain cytosol requires phospholipid plus detergent for high affinity guanine nucleotide binding and for optimal enhancement of cholera toxin ADP-ribosyltransferase activity. The phospholipid requirements, combined with a putative role for ARF in vesicular transport, suggested that the soluble protein might interact reversibly with membranes. A polyclonal antibody against purified bovine ARF (sARF II) was used to detect ARF by immunoblot in membrane and soluble fractions from rat pheochromocytoma (PC-12) cell homogenates. ARF was predominantly cytosolic but increased in membranes during incubation of homogenates with nonhydrolyzable GTP analogues guanosine 5'-O-(3-thiotriphosphate), guanylyl-(beta gamma-imido)-diphosphate, and guanylyl-(beta gamma-methylene)-diphosphate, and to a lesser extent, adenosine 5'-O-(3-thiotriphosphate). GTP, GDP, GMP, and ATP were inactive. Cytosolic ARF similarly associated with added phosphatidylserine, phosphatidylinositol, or cardiolipin in GTP gamma S-dependent fashion. ARF binding to phosphatidylserine was reversible and coincident with stimulation of cholera toxin-catalyzed ADP-ribosylation. These observations may reflect a mechanism by which ARF could cycle between soluble and membrane compartments in vivo.