Studies of the ADP/ATP carrier of mitochondria with fluorescent ADP analogue formycin diphosphate

The ADP/ATP carrier was studied by a fluorescent substrate, formycin diphosphate which is the only fluorescent ADP analogue to bind. Its low quantum yield, short decay time and spectral overlap with tryptophan has as yet prevented its wider use.By incorporating fluorescent acceptors of formycin diphosphate fluorescence, anthracene-maleimide and vinylanthracene, into the membrane, these difficulties were circumvented. Only bound formycin diphosphate transfers energy to the probes so that the secondary emission of these probes is a measure for membrane-bound formycin diphosphate.The fluorescent transfer is inhibited by ADP, bongkrekate and carboxy-atractylate whether added before or after incubation of formycin diphosphate showing that only binding to the adenine nucleotide carrier is measured. It also shows directly that the earlier demonstrated ADP fixation by bongkrekate is indeed a displacement into the matrix.The fluorescence decay time of the bound formycin diphosphate is measured as 1.95 ns compared to 0.95 ns of the free formycin diphosphate, indicating that formycin diphosphate is bound at the carrier in a non-polar environment.The depolarization decay time was found to be larger than 15 ns, indicating that carrier-bound formycin diphosphate is immobile within this time period.     

Interaction of fluorescent adenine nucleotide derivatives with the ADP/ATP carrier in mitochondria. 1. Comparison of various 3'-O-ester adenine nucleotide derivatives

Fluorescent 3'-O-acyl-substituted adenine nucleotide (dimethylamino)naphthoyl and trinitrophenyl groups were studied for binding to the ADP/ATP carrier in mitochondria and submitochondrial particles. The changes in fluorescence intensity and emission maximum are for the most part similar to those observed in nonaqueous solvents. The (dimethylamino)naphthoyl derivatives from a largely quenched aqueous state have a shortwave shift up to 85 nm and increase up to 90-fold (1,5 derivative), whereas the little quenched naphthoyl derivatives show a fluorescence decrease and the weakly fluorescent trinitrophenyl derivative shows only a small increase on binding. All derivatives are good inhibitors (K1 = 1-10 microM) of nucleotide transport. The fluorescence titrations have an apparent K1/2 = 2-7 microM. The fluorescence of the 1,5-DAN nucleotide is fully suppressed by bongkrekate but only partially suppressed by carboxyatractylate. The fluorescence response is much stronger in submitochondrial particles than in mitochondria. Both facts suggest fluorescent binding to the "m" state of the carrier site at the inner face of the membrane. 1,5-DAN-AMP shows a slightly more efficient binding than DAN-ADP or DAN-ATP.     

Interaction of fluorescent 3'-[1,5-(dimethylamino)naphthoyl]adenine nucleotides with the solubilized ADP/ATP carrier

The binding of the 3'-[1,5-(dimethylamino)naphthoyl] (DAN) derivatives of AMP, ADP, and ATP to the solubilized ADP/ATP carrier is studied, evaluating primarily the fluorescence enhancement and 3H-labeled compound binding. DAN nucleotides also fluoresce when adsorbed to Triton X-100 micelles that are used for solubilization of the carrier. The partition of DAN-AMP between water and Triton X-100 micelles is measured, and it is shown to be shifted toward a higher content in Triton micelles with increasing salt concentration. In order to maintain a low level of fluorescence, the Triton content is decreased. The fraction of DAN nucleotide fluorescence due to carrier binding is determined by the suppression with bongkrekate (BKA). In contrast to the membrane-bound carrier, the solubilized preparation shows an increase of total BKA-sensitive fluorescence by 30-60% upon addition of ATP or ADP. In the solubilized atractylate-protein complex, the ADP-stimulated fluorescence amounts even to 80%. The suppression of fluorescence by BKA is independent of the presence of ADP or ATP, while that by carboxyatractylate (CAT) depends on ADP or ATP. The quantitation with [3H]BKA and [3H]CAT of these ligand interactions with DAN-AMP fluorescence shows that DAN-AMP fluorescence reflects the "m"-state carrier population and its redistribution under the influence of ADP or ATP. Thus, besides the "c"/"m" distribution, the kinetics of the c to m transition in the solubilized carrier also can be determined. The m share is increased to 80% when SO4, Pi, or pyrophosphate is present during solubilization. The rate of the ADP- or ATP-stimulated transition to the m state is markedly dependent on pH and on the presence of various anions, whereas the extent is little varied. The affinity decreases 4-fold going from DAN-AMP to DAN-ADP and to DAN-ATP (KD = 0.9, 1.6, and 3.2 microM). Comparison with physical binding of [3H]DAN nucleotides shows that the fluorescence yield of bound DAN-AMP is about 1.4 times higher than that of bound DAN-ATP. DAN substitution causes more than a 100-fold affinity increase for AMP and a 50-fold increase for ADP or ATP, probably because of interaction of the DAN group with a hydrophobic niche. A less specific, low-affinity displacement of DAN nucleotides by GDP, ADP, GTP and ATP (Ki = 1-2 mM) probably reflects primarily the ionic interactions at the binding center.     

Characterization of the ethenoadenosine diphosphate binding site of myosin subfragment 1. Energetics of the equilibrium between two states of nucleotide.S1 and vanadate-induced global conformation changes detected by energy transfer

The fluorescence decay of 1,N6-ethenoadenosine diphosphate (epsilon ADP) bound to myosin subfragment 1 (S1) was studied as a function of temperature. The decay was biexponential, and the two lifetimes were quenched relative to the single lifetime of free epsilon ADP. The temperature dependence of the fractional intensities of the decay components showed two states of the S1.epsilon ADP complex. At pH 7.5 in 30 mM TES, 60 mM KCl, and 3 mM MgCl2, the equilibrium constant for the conversion of the low-temperature state (S1L.epsilon ADP) to the high-temperature state (S1H.epsilon ADP) was 40 at physiological temperatures, and delta H degrees = 13 kcal.mol-1 and delta S degrees = 49 cal.deg-1.mol-1. At 10 degrees C the equilibrium constant of S1 for epsilon ADP was 5, indicating that S1H.epsilon ADP was the dominant state, and that for the vanadate complex epsilon ADP.Vi was 0.7, suggesting that in S1.epsilon ADP.Vi the dominant state of the S1-nucleotide complex was converted from S1H.epsilon ADP to S1L.epsilon ADP. The single rotational correlation time of bound epsilon ADP at 10 degrees C decreased from 107 ns in S1.epsilon ADP to 74 ns in S1+.epsilon ADP.Vi. Conversion of the binary complex to the ternary vanadate complex resulted in a 3-A decrease in the energy transfer distance between bound epsilon ADP and N-[4-(dimethylamino)-3,5-dinitrophenyl]maleimide attached to SH1 and a decrease of the average distance between bound epsilon ADP and bound Co2+ from 12.6 to 8.3 A.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of fluorescent adenine nucleotide derivatives with the ADP/ATP carrier in mitochondria. 2. [5-(Dimethylamino)-1-naphthoyl]adenine nucleotides as probes for the transition between c and m states of the ADP/ATP carrier

The binding to the ADP/ATP carrier in mitochondrial membranes of the 3'-O-(dimethylamino)naphthoyl (DAN) derivatives of AMP, ADP, and ATP was quantitatively analyzed. The sidedness of the fluorescent type binding to the "m" side only was shown comparing the mitochondrial membranes in various stages of integrity and surface orientation. In particles displacement by bongkrekate (BKA) is direct, whereas in the case of carboxyatractylate (CAT) the requirement for ADP and ATP demonstrates the transition from the "m" to the "c" state. Quantitatively the "physical" binding of [3H]DAN-AMP and fluorescence are well correlated, allowing for a little nonfluorescent binding to the c side. For DAN-AMP KD is 1.6 microM, for DAN-ADP KD is 0.8 microM, and in the Hill plot a straight line with n = 1.25 is obtained. The maximum number of binding sites for [3H]DAN-AMP (1.5 mumol/g of protein) is about equal to the sites found for [3H]BKA if the unspecific binding of both ligands is differentiated by blocking carrier sites with CAT. [3H]CAT binding is somewhat lower in accordance with the limited access of CAT to inverted vesicles. ADP is able to decrease fluorescence only by about 35% at high concentrations (10 mM) whereas GDP has virtually no effect. With ADP, DAN-AMP binding decreases by 30% of the total binding sensitive to BKA. Binding to ATPase is low because of the absence of Mg2+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Two-state equilibria of myosin subfragment 1 and its complexes with ADP and actin

We previously reported that the nucleotide complex of myosin subfragment 1, S1.epsilon ADP, exists in two states on the basis of the temperature dependence of the fluorescence decay of bound 1,N6-ethenoadenosine diphosphate (epsilon ADP) [Aguirre, R., Lin. S.-H., Gonsoulin, F., Wang, C.-K., & Cheung, H.C. (1989) Biochemistry 28, 799-809]. We have extended the previous study of the equilibrium between the two states, S1L.ADP in equilibrium S1H.ADP, by using a fluorescently labeled myosin S1 (S1-AF). In S1 alkylated with IAF [5-(iodoacetamido)fluorescein], the decay of the label emission was biexponential both in the presence and absence of ADP and/or actin. In the presence of ADP, the two decay times were 4.30 (alpha 1 = 0.55) and 0.80 ns (alpha 2 = 0.45) at 12.4 degrees C, in a medium containing 60 mM KCl, 30 mM TES (pH 7.5), and 2 mM MgCl2. The steady-state fluorescence intensities of S1-AF, (S1-AF).ADP, acto.(S1-AF), and acto.(S1-AF).ADP were dependent on temperature over the range of 5-30 degrees C. By combining lifetime and steady-state intensity data, we obtained for the two-state transition (S1-AF)L.ADP in equilibrium (S1-AF)H.ADP the following parameters: delta H degrees = 16.1 kcal/mol (67.3 kJ/mol) and delta S degrees = 55.8 cal/(deg.mol) [233.5 J/(deg.mol)], in agreement with previous results obtained with epsilon ADP. The delta H degrees values for the two-state transition of S1-AF, acto.(S1-AF), and acto.(S1-AF).ADP are 13.0, 21.6, and 5.2 kcal/mol, respectively. The corresponding delta S degrees values are 46.9, 79.5, and 17.4 cal/(deg.mol).(ABSTRACT TRUNCATED AT 250 WORDS)     

Influence of ADP on cross-bridge-dependent activation of myofibrillar thin filaments

Contraction of skeletal muscle is regulated by calcium at the level of the thin filament via troponin and tropomyosin. Studies have indicated that strong cross-bridge binding is also involved in activation of the thin filament. To further test this, myofibrils were incubated with a wide range of fluorescent myosin subfragment 1(fS1) at pCa 9 or pCa 4 with or without ADP. Sarcomere fluorescence intensity and the fluorescence intensity ratio (non-overlap region/overlap region) were measured to determine the amount and location of bound fS1 in the myofibril. There was lower sarcomere fluorescence intensity with ADP compared to without ADP for both calcium levels. Similar data were obtained from biochemical measures of bound fS1, validating the fluorescence microscopy measurements. The intensity ratio, which is related to activation of the thin filament, increased with increasing [fS1] with or without ADP. At pCa 9, the fluorescence intensity ratio was constant until 80-160 nM fS1 without ADP conditions, then it went up dramatically and finally attained saturation. The dramatic shift of the ratio demonstrated the cooperative character of strong cross-bridge binding, and this was not observed at high calcium. A similar pattern was observed with ADP in that the ratio was right-shifted with respect to total [fS1]. Saturation was obtained with both the fluorescence intensity and ratio data. Plots of intensity ratio as a function of normalized sarcomere intensity (bound fS1) showed little difference between with and without ADP. This suggests that the amount of strongly bound fS1, not fS1 state (with or without ADP) is related to activation of the thin filament.     

Synthesis and properties of fluorescent derivatives of atractyloside as potential probes of the mitochondrial ADP/ATP carrier protein

The chemical synthesis of fluorescent derivatives of atractyloside (ATR), an inhibitor of the mitochondrial ADP/ATP carrier protein, is described. These derivatives are the following: 6′-O-dansyl ATR, 6′-O-dansyl-aminobutyryl ATR, and 6′-O-naphthoyl ATR. The spectral properties of these analogs were analyzed, and their biological features were compared to those of ATR. The fluorescence emission of the dansyl ATR derivatives was increased in organic solvents and that of naphthoyl ATR was decreased; for both analogs, solubilization in organic solvents resulted in a blue shift of the emission peak. The fluorescent dansyl and naphthoyl ATR derivatives were specifically recognized by the mitochondrial ADP/ATP carrier protein. Because of their spectral properties and their biochemical reactivities, the fluorescent analogs of ATR can be considered as potential probes to investigate the topography of the ADP/ATP carrier in the mitochondrial membrane and to monitor conformational changes of the ADP/ATP carrier protein associated with transport.     

Site-directed labeling of a monoclonal antibody: targeting to a disulfide bond

We have designed and synthesized crabescein, the first member of a class of fluorescent labels that add across disulfide bonds. Crabescein is a fluorescein derivative that reports the rotational correlation time of the immunoglobulin G (IgG) segment to which it is covalently bound. Chemical analysis of the IgG labeled with crabescein indicates that the fluorophore is inserted into the third disulfide bond (cysteine-229 of mouse IgG2a) in the hinge region. The rotational correlation time of this labeled macromolecule was measured as a single exponential with a decay constant of 26.8 ns. This is in contrast to the double exponential with decay constants of 14.3 and 0.2 ns for the same IgG when labeled with fluorescein via a conventional labeling reagent in which the probe is bound to the macromolecule by one-point attachments. Thus, crabescein is the prototype of a class of fluorescent and phosphorescent probes that, by virtue of their two-point attachments to proteins, faithfully report on the dynamics of the segment of macromolecule to which they are covalently bound.     

Isolation of the ADP/ATP translocator from beef heart mitochondria as the bongkrekate-protein complex

1. The isolation of the ADP/ATP translocator from beef heart mitochondria as the bongkrekateprotein complex is described, using hydroxyapatite chromatography and gel filtration in Triton X-100 solution. 2. The inhibitor is bound to the protein prior to solubilization with detergent for protection against denaturation. Only the intact bongkrekate-protein passes easily through the hydroxyapatite column. Bongkrekate shileds the protein in contrast to carboxyatractylate only partially against proteinases present in the crude extract. 3. The isolated bongkrekate protein shows the same molecular weights in dodecylsulfate and Triton X-100, the same amino acid composition and the same isoelectric point as the earlier isolated carboxyatractylate-protein complex. It differs by its higher sensitivity against trypsin and thermolysin. 4. The identity of both proteins is demonstrated by interconversion of the bongkrekate-protein into the carboxyatractylate-protein. The process requires the catalysis by ADP or ATP, the natural substrates of the protein. 5. The formation of the extractable [3H]bongkrekate-protein complex in mitochondria requires the presence of ADP or ATP. 6. These data, the immunological studies presented earlier, and the differences in the reactivity of -SH groups of the isolated bongkrekate and carboxyatractylate complexes (to be published) indicate that both proteins represent different conformational states of the translocator protein (m-state and c-state).     

6'-O-dansyl-gamma-aminobutyryl atractyloside, a fluorescent probe of the ADP/ATP carrier: exploration of conformational changes of the membrane-bound ADP/ATP carrier elicited by substrates and inhibitors

A fluorescent atractyloside analogue, the 6'-O-dansyl-gamma-aminobutyryl atractyloside (DGA), has been used to probe the binding of the inhibitors carboxyatractyloside (CATR) and bongkrekic acid (BA) and nucleotide substrates to the membrane-bound ADP/ATP carrier protein in beef heart mitochondria. Binding and release of DGA were followed by fluorescence responses. Specifically bound DGA was fully released by CATR alone, or by BA in the presence of micromolar amounts of ADP. In the absence of the inhibitors, ADP increased the rate of the specific binding of DGA. The effect of ADP was shared by transportable nucleotides. Non transportable nucleotides were ineffective. These data are consistent with the previously described CATR and BA conformations of the ADP/ATP carrier that are able to bind CATR and BA respectively, the transition between the two conformations being accelerated by micromolar concentrations of transportable nucleotides.     

Conformational dynamics of the mitochondrial ADP/ATP carrier: a simulation study

The mitochondrial ADP/ATP carrier is a six helix bundle membrane transport protein, which couples the exit of ATP from the mitochondrial matrix to the entry of ADP. Extended (4x20 ns) molecular dynamics simulations of the carrier, in the presence and absence of bound inhibitor (carboxyatractyloside), have been used to explore the conformational dynamics of the protein in a lipid bilayer environment, in the presence and absence of the carboxyatractyloside inhibitor. The dynamic flexibility (measured as conformational drift and fluctuations) of the protein is reduced in the presence of bound inhibitor. Proline residues in transmembrane helices H1, H3 and H5 appear to form dynamic hinges. Fluctuations in inter-helix salt bridges are also observed over the time course of the simulations. Inhibitor-protein and lipid-protein interactions have been characterised in some detail. Overall, the simulations support a transport mechanism in which flexibility about the proline hinges enables a transition between a 'closed' and an 'open' pore-like state of the carrier protein.     

Conformational dynamics of the mitochondrial ADP/ATP carrier: a simulation study

The mitochondrial ADP/ATP carrier is a six helix bundle membrane transport protein, which couples the exit of ATP from the mitochondrial matrix to the entry of ADP. Extended (4×20 ns) molecular dynamics simulations of the carrier, in the presence and absence of bound inhibitor (carboxyatractyloside), have been used to explore the conformational dynamics of the protein in a lipid bilayer environment, in the presence and absence of the carboxyatractyloside inhibitor. The dynamic flexibility (measured as conformational drift and fluctuations) of the protein is reduced in the presence of bound inhibitor. Proline residues in transmembrane helices H1, H3 and H5 appear to form dynamic hinges. Fluctuations in inter-helix salt bridges are also observed over the time course of the simulations. Inhibitor-protein and lipid-protein interactions have been characterised in some detail. Overall, the simulations support a transport mechanism in which flexibility about the proline hinges enables a transition between a ‘closed’ and an ‘open’ pore-like state of the carrier protein.     

Nucleotide binding to nucleoside diphosphate kinases: X-ray structure of human NDPK-A in complex with ADP and comparison to protein kinases

NDPK-A, product of the nm23-H1 gene, is one of the two major isoforms of human nucleoside diphosphate kinase. We analyzed the binding of its nucleotide substrates by fluorometric methods. The binding of nucleoside triphosphate (NTP) substrates was detected by following changes of the intrinsic fluorescence of the H118G/F60W variant, a mutant protein engineered for that purpose. Nucleoside diphosphate (NDP) substrate binding was measured by competition with a fluorescent derivative of ADP, following the fluorescence anisotropy of the derivative. We also determined an X-ray structure at 2.0A resolution of the variant NDPK-A in complex with ADP, Ca(2+) and inorganic phosphate, products of ATP hydrolysis. We compared the conformation of the bound nucleotide seen in this complex and the interactions it makes with the protein, with those of the nucleotide substrates, substrate analogues or inhibitors present in other NDP kinase structures. We also compared NDP kinase-bound nucleotides to ATP bound to protein kinases, and showed that the nucleoside monophosphate moieties have nearly identical conformations in spite of the very different protein environments. However, the beta and gamma-phosphate groups are differently positioned and oriented in the two types of kinases, and they bind metal ions with opposite chiralities. Thus, it should be possible to design nucleotide analogues that are good substrates of one type of kinase, and poor substrates or inhibitors of the other kind.     

The 2'-O- and 3'-O-Cy3-EDA-ATP(ADP) complexes with myosin subfragment-1 are spectroscopically distinct

Ribose-modified highly-fluorescent sulfoindocyanine ATP and ADP analogs, 2'(3')-O-Cy3-EDA-AT(D)P, with kinetics similar to AT(D)P, enable myosin and actomyosin ATPase enzymology with single substrate molecules. Stopped-flow studies recording both fluorescence and anisotropy during binding to skeletal muscle myosin subfragment-1 (S1) and subsequent single-turnover decay of steady-state intermediates showed that on complex formation, 2'-O- isomer fluorescence quenched by 5%, anisotropy increased from 0.208 to 0.357, and then decayed with turnover rate k(cat) 0.07 s(-1); however, 3'-O- isomer fluorescence increased 77%, and anisotropy from 0.202 to 0.389, but k(cat) was 0.03 s(-1). Cy3-EDA-ADP.S1 complexes with vanadate (V(i)) were studied kinetically and by time-resolved fluorometry as stable analogs of the steady-state intermediates. Upon formation of the 3'-O-Cy3-EDA-ADP.S1.V(i) complex fluorescence doubled and anisotropy increased to 0.372; for the 2'-O- isomer, anisotropy increased to 0.343 but fluorescence only 6%. Average fluorescent lifetimes of 2'-O- and 3'-O-Cy3-EDA-ADP.S1.V(i) complexes, 0.9 and 1.85 ns, compare with approximately 0.7 ns for free analogs. Dynamic polarization shows rotational correlation times higher than 100 ns for both Cy3-EDA-ADP.S1.V(i) complexes, but the 2'-O-isomer only has also a 0.2-ns component. Thus, when bound, 3'-O-Cy3-EDA-ADP's fluorescence is twofold brighter with motion more restricted and turnover slower than the 2'-O-isomer; these data are relevant for applications of these analogs in single molecule studies.     

Nanosecond spectroscopy of retinol.

Nanosecond fluorescence spectroscopy was used to study the unique binding site of the retinol-binding protein (RBP) from human serum. At pH 7.4, the binding of retinol to RBP caused the following spectroscopic changes in the ligand: (a) an enhancement of the fluorescence decay time (gamma = 8 ns); and (b) an increase in the emission anisotropy (A = 0.29). Retinol in hexane has a fluorescent decay time of 4.2 ns and a low emission anisotropy (A = 0.02). The increase in the fluorescence decay time of bound retinol is not due to dielectric relaxation effects of polar groups, since nanosecond time-resolved emission spectra of either retinol in glycerol or retinol bound to RBP, failed to show any time-dependent shifts in emission maxima during the time period investigated 0 to 30 ns. The degree of rotational mobility of bound retinol was investigated by time emission anisotropy measurements. The observed rotational correlation time (theta = 7.2 ns) is consistent with a rigid compact macromolecule of 21,000 molecular weight.     

Substrate-induced fluorescence changes of the isolated ADP/ATP carrier protein in solution

Fluorescence studies were carried out on a purified preparation of the ADP/ATP carrier protein solubilized in 3-laurylamido-N-N-dimethylpropylaminoxide. The intrinsic fluorescence of the protein was modified upon addition of ADP and ATP and specific inhibitory ligands (carboxyatractyloside and bongkrekic acid). The fluorescence was transitorily enhanced by micromolar concentrations of ADP or ATP. The rise in fluorescence lasted for 10 sec at 25°C. It was suppressed by carboxyatractyloside and on the contrary enhanced by bongkrekic acid. These data were interpreted as reflecting conformational changes probably related to the functioning of the ADP/ATP carrier. Mg⁺⁺ inhibited the ADP- or ATP-induced rise in fluorescence, indicating that the free forms (and not the Mg⁺⁺ complexed forms) of ADP and ATP are the true substrates for the ADP/ATP carrier.     

Kinetics of electrogenic transport by the ADP/ATP carrier.

The electrogenic transport of ATP and ADP by the mitochondrial ADP/ATP carrier (AAC) was investigated by recording transient currents with two different techniques for performing concentration jump experiments: 1) the fast fluid injection method: AAC-containing proteoliposomes were adsorbed to a solid supported membrane (SSM), and the carrier was activated via ATP or ADP concentration jumps. 2) BLM (black lipid membrane) technique: proteoliposomes were adsorbed to a planar lipid bilayer, while the carrier was activated via the photolysis of caged ATP or caged ADP with a UV laser pulse. Two transport modes of the AAC were investigated, ATP(ex)-0(in) and ADP(ex)-0(in). Liposomes not loaded with nucleotides allowed half-cycles of the ADP/ATP exchange to be studied. Under these conditions the AAC transports ADP and ATP electrogenically. Mg(2+) inhibits the nucleotide transport, and the specific inhibitors carboxyatractylate (CAT) and bongkrekate (BKA) prevent the binding of the substrate. The evaluation of the transient currents yielded rate constants of 160 s(-1) for ATP and >/=400 s(-1) for ADP translocation. The function of the carrier is approximately symmetrical, i.e., the kinetic properties are similar in the inside-out and right-side-out orientations. The assumption from previous investigations, that the deprotonated nucleotides are exclusively transported by the AAC, is supported by further experimental evidence. In addition, caged ATP and caged ADP bind to the carrier with similar affinities as the free nucleotides. An inhibitory effect of anions (200-300 mM) was observed, which can be explained as a competitive effect at the binding site. The results are summarized in a transport model.     

The transmembrane arrangement of the ADP/ATP carrier as elucidated by the lysine reagent pyridoxal 5-phosphate

The lysine reagent pyridoxal 5-phosphate was applied to the ADP/ATP carrier (AAC) in order to elucidate topological and functional properties of the numerous lysines within the primary structure. To establish appropriate labeling conditions, the influence of pyridoxal-P on transport and inhibitor binding to the AAC was examined. The ADP/ATP transport is sensitive to low concentrations of pyridoxal-P with a Ki = 0.4 mM. Binding of [3H]carboxyatracylate and [3H]bongkrekate is largely inhibited by pyridoxal-P treatment with Ki approximately 1 mM. [3H]Carboxyatractylate is not and [3H]bongkrekate weakly removed by pyridoxal-P, whereas [3H]atractylate is displaced to a large extent. Under optimized conditions of pyridoxal-P concentration, of pH and of time exposure, the AAC was exposed to [3H]pyridoxal-P in mitochondria, in submitochondrial particles and in the detergent-solubilized carrier. The [3H]pyridoxal-P-labeled AAC was isolated from mitochondria and particles. After citraconylation thermolysinolytic peptides were prepared. The pyridoxyl-lysine-containing peptides were purified and the pyridoxal-P incorporation to specific lysines was determined by sequencing. The pyridoxal-P incorporation into the AAC in various states was evaluated with regard to structural and functional aspects. First, by comparing pyridoxal-P incorporation in mitochondria and sonic particles, the segments of the polypeptide chain exposed to the cytosolic and matrix side of the membrane are detected. Second, the additional lysine incorporation into the isolated as compared to the membrane-bound carrier is attributed to the protein collar facing the phospholipid headgroups. Third, the difference between lysine incorporation into the carboxyatractylate-AAC and bongkrekate-AAC complexes reflect either conformational changes or lysines involved in the translocation channel through the protein. Fourth, the additional lysine labeled in the atractylate-carrier complex as compared to the carboxyatractylate-carrier complex is attributed to a cationic site in the binding center. These results are incorporated into a transmembrane folding model of the carrier.     

Shape and lipid-binding site of the nonspecific lipid-transfer protein (sterol carrier protein 2): a steady-state and time-resolved fluorescence study

The nonspecific lipid-transfer protein (nsL-TP) from bovine liver was studied with time-resolved and steady-state fluorescence techniques. From the decay of the intrinsic tryptophanyl fluorescence, it was estimated that the rotational correlation time of nsL-TP is 15 ns. This parameter increased only slightly upon addition of an excess of negatively charged vesicles, indicating that the basic nsL-TP is not immobilized at the membrane surface under these conditions. Binding studies using fluorescent lipid analogues revealed that nsL-TP is able to extract sn-2-(pyrenehexanoyl) phosphatidylcholine and 1-palmitoyl-2-[3-(diphenylhexatrienyl) propionyl]-sn-3-phosphocholine (DPHp-PC) from a quenched donor vesicle. The fluorescence increase resulting from this binding was poorly quenched by either acrylamide or iodide. This indicates that nsL-TP shields the bound PC molecules from the aqueous environment. Time-resolved analysis of DPH fluorescence originating from DPHp-PC bound to nsL-TP yielded a rotational correlation time of 7.4 ns. This correlation time strongly suggests that the DPH moiety of the bound molecule is immobilized and that the nsL-TP/DPHp-PC complex is not attached to the donor vesicle. In view of the longer rotational correlation time obtained for the intrinsic tryptophanyl fluorescence, we conclude that nsL-TP is highly asymmetric. The data are consistent with a model in which the shape of nsL-TP is ellipsoidal with an axis ratio of 2.8. The implications for the mode of action of nsL-TP are discussed.