Structural mapping of chloroplast coupling factor

Fluorescence resonance energy transfer measurements have been used to investigate the spatial relationships between the nucleotide binding sites and the gamma-subunit of the H+-ATPase from chloroplasts and the orientation of these sites with respect to the membrane surface. Fluorescent maleimides reacted covalently at specific sulfhydryl sites on the gamma-subunit served as energy donors. One sulfhydryl site can be labeled only under energized conditions on the thylakoid membrane surface (light site). The two gamma-sulfhydryls exposed after catalytic activation served as a second donor site (disulfide site). In one set of experiments, the nucleotide analogue 2'(3')-(trinitrophenyl)adenosine triphosphate, selectively bound at each of the three nucleotide binding sites of the solubilized coupling factor, was used as an energy acceptor; in another, octadecylrhodamine with its acyl chain inserted in the vesicle bilayer and the rhodamine fluorophore exposed along the membrane surface was the energy acceptor. The distance between the sulfhydryl and disulfide sites was also obtained by sequentially labeling the sites with coumarin (donor) and fluorescein (acceptor) maleimide derivatives, respectively. The results indicate that all three nucleotide sites are approximately equal to 50 A from the light-labeled gamma-sulfhydryl. Two of the nucleotide sites are very far from the gamma-disulfide (greater than 74 A), while the third site, which binds nucleotides reversibly under all conditions, is 62 A from this sulfhydryl. The light-labeled sulfhydryl and disulfide sites are about 42-47 A apart. Finally, the distance of closest approach between the membrane surface of the reconstituted system and the gamma-disulfide is 31 A.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural map of the dicyclohexylcarbodiimide site of chloroplast coupling factor determined by resonance energy transfer

Fluorescence resonance energy-transfer measurements were made on the membrane-bound chloroplast coupling factor. The distances from the N,N'-dicyclohexylcarbodiimide-binding site on the membrane-bound portion of the enzyme (CF0) to the vesicle surface and to two sulfhydryl sites on the gamma-polypeptide were determined. The dicyclohexylcarbodiimide-binding site was labeled with the fluorescent species N-cyclohexyl-N'-pyrenylcarbodiimide. The vesicle surface was labeled with N-(7-nitro-2,1,3-benzoxadiazol-4-yl)phosphatidylethanolamine. Steady-state energy transfer between the fluorescent-labeled enzyme (energy donor) and varying concentrations of the ethanolamine derivative (energy acceptor) indicated that the distance of closest approach between the energy donor and the outer vesicle surface is 16-24 A. Two specific sites on the gamma-polypeptide were reacted with a coumarinylmaleimide derivative; one is a sulfhydryl that can be labeled only on the thylakoids under energized conditions (the "light" site), while the other is the disulfide site that regulates enzymatic activity. Energy-transfer measurements utilizing steady-state fluorescence and fluorescence lifetime methods indicated that the dicyclohexylcarbodiimide site is approximately 41 A from the light site and approximately 50 A from the gamma-disulfide site. These distances are used to extend the current structural model of the chloroplast coupling factor.     

Structural mapping of nucleotide binding sites on chloroplast coupling factor

Fluorescence resonance energy transfer was used to measure the distances between three nucleotide binding sites on solubilized chloroplast coupling factor from spinach and between each nucleotide site and two tyrosine residues which are important for catalytic activity. The nucleotide energy donor was 1,N6-ethenoadenosine di- or triphosphate, and the nucleotide energy acceptor was 2'(3')-(trinitrophenyl)adenosine diphosphate. The tyrosine residues were specifically labeled with 7-chloro-4-nitro-2,1,3-benzoxadiazole, which served as an energy acceptor. The results obtained indicate the three nucleotide binding sites form a triangle with sides of 44, 48, and 36 A. (The assumption has been made in calculating these distances that the energy donor and acceptor rotate rapidly relative to the fluorescence lifetime.) Two of the nucleotide sites are approximately equidistant from each of the two tyrosines: one of the nucleotide sites is about 37 A and the other about 41 A from each tyrosine. The third nucleotide site is about 41 A from one of the tyrosines and greater than or equal to 41 A from the other tyrosine.     

Investigation of quercetin binding sites on chloroplast coupling factor 1.

The quercetin binding sites on spinach chloroplast coupling factor 1 (CF1) have been investigated using direct and competitive binding, stopped-flow, temperature-jump, and fluorescence resonance energy transfer measurements. It was found that 8-anilino-1-naphthalensulfonic acid (ANS) competes with quercetin binding at two sites on the solubilized enzyme which are distinct from the two tight nucleotide binding sites and the 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl) reactive site. The bimolecular association of quercetin with CF1 is too fast to measure directly and is followed by two slower conformational changes. The distances from the tight nucleotide sites to the quercetin-ANS sites were estimated as 40-48 A by fluorescence resonance energy transfer using 1,N6-ethenoadenosine diphosphate and 1,N6-ethenoadenylyl imidodiphosphate as donors and quercetin as the acceptor. The distance from the quercetin-ANS site to the NBD-C1 reactive site was found to be about 30 A using ANS as a donor and NBD-C1 reacted with a tyrosine group on CF1 as the energy acceptor. A model is proposed for the relative location of these sites on CF1.     

Characterization of three-subunit chloroplast coupling factor

The delta- and epsilon-polypeptides were removed from chloroplast coupling factor 1 (CF1). The resulting enzyme, CF1(-delta, epsilon), is a stable active ATPase containing only alpha-, beta-, and gamma-polypeptides. The dependence of the steady-state kinetics of ATP hydrolysis catalyzed by CF1(-delta, epsilon) on the concentrations of ATP and ADP was found to be essentially the same as by activated CF1. Nucleotide binding studies with CF1(-delta, epsilon) revealed three binding sites: a nondissociable ADP site (site 1), a tight MgATP binding site (site 2), and a site that binds ADP and ATP with a dissociation constant in the micromolar range (site 3). Similar results have been obtained with CF1. For both CF1 and CF1(-delta, epsilon), the binding of MgATP at site 2 is tight only in the presence of Mg2+. Fluorescence resonance energy transfer was used to map distances between the gamma-sulfhydryl ("dark" site) and gamma-disulfide and between the gamma-sulfhydryl and the three nucleotide sites. These distances are within 5% of the corresponding distances on CF1. These results indicate that removal of the delta- and epsilon-polypeptides from CF1 does not cause significant changes in the structure, kinetics, and nucleotide binding sites of the enzyme.     

Binding stoichiometry and structural mapping of the epsilon polypeptide of chloroplast coupling factor 1

Fluorescent probes were attached to the single sulfhydryl residue on the isolated epsilon polypeptide of chloroplast coupling factor 1 (CF1), and the modified polypeptide was reconstituted with the epsilon-deficient enzyme. A binding stoichiometry of one epsilon polypeptide per CF1 was obtained. This stoichiometry corresponded to a maximum inhibition of the Ca2+-dependent ATPase activity of the enzyme induced by epsilon removal. Resonance energy transfer between the modified epsilon polypeptide and fluorescent probes attached to various other sites on the enzyme allowed distance measurements between these sites and the epsilon polypeptide. The epsilon-sulfhydryl is nearly equidistant from both the disulfide (23 A) and the dark-accessible sulfhydryl (26 A) of the gamma subunit. Measurement of the distance between epsilon and the light-accessible gamma-sulfhydryl was not possible due to an apparent exclusion of modified epsilon from epsilon-deficient enzyme after modification of the light-accessible site. The distances measured between epsilon and the nucleotide binding sites on the enzyme were 62, 66, and 49 A for sites 1, 2, and 3, respectively. These measurements place the epsilon subunit in close physical proximity to the sulfhydryl-containing domains of the gamma subunit and approximately 40 A from the membrane surface. Enzyme activity measurements also indicated a close association between the epsilon and gamma subunits: epsilon removal caused a marked increase in accessibility of the gamma-disulfide bond to thiol reagents and exposed a trypsin-sensitive site on the gamma subunit. Either disulfide bond reduction or trypsin cleavage of gamma significantly enhanced the Ca2+-ATPase activity of the epsilon-deficient enzyme. Thus, the epsilon and gamma polypeptides of coupling factor 1 are closely linked, both physically and functionally.     

Membrane-protein structural mapping of chloroplast coupling factor in asolectin vesicles

The spatial relationship of specific sites on chloroplast coupling factor, reconstituted in asolectin vesicles, to the bilayer surface has been studied with fluorescence methods. Fluorescence resonance energy transfer measurements have been used to map the distances of closest approach of the N,N'-dicyclohexylcarbodiimide-binding site and the disulfide on the gamma-polypeptide to the bilayer center. The dicyclohexylcarbodiimide site was labeled with N-cyclohexyl-N'-pyrenylcarbodiimide and the gamma-disulfide site with a coumarinyl derivative. The bilayer center was labeled with 25-[N-(7-nitro-2,1,3-benzoxadiazol-4-yl)-N-methylamino]-27-norc holesterol. The distances obtained, 15 and 43 A, respectively, were combined with previous measurements of the distance of closest approach between these sites and the membrane surface to estimate the perpendicular distances of the sites from the membrane surface. The depth of the dicyclohexylcarbodiimide site was also determined by studying the quenching of fluorescence by 5-, 7-, 12-, and 16-doxylstearic acids. The model developed suggests that the dicyclohexylcarbodiimide site is 6-10 A below the membrane surface and the gamma-disulfide is 16 A above the membrane surface. The distances measured are subject to a considerable uncertainty, but the proposed model provides a useful starting point for further structural studies.     

Localization of site-specific probes on the Ca-ATPase of sarcoplasmic reticulum using fluorescence energy transfer

Highly reactive sulfhydryls, previously labeled with an iodoacetamide spin label on the Ca-ATPase of sarcoplasmic reticulum, were labeled with the fluorescent probe, 5-(2-[iodoacetyl)amino)ethyl)aminonaphthalene-1-sulfonic acid (IAEDANS), without loss of enzymatic activity. We have selectively measured the apparent distance of the more reactive site, relative to other site-specific probes at both the nucleotide and the high affinity calcium binding sites. Fluorescence energy transfer efficiencies from the donor IAEDANS to two acceptors: fluorescein 5'-isothiocyanate or 2',3'-O-(2,4,3-trinitrophenyl)adenosine monophosphate, situated at or near the nucleotide site, were measured using fluorescence lifetimes and yields. Fluorescence on polyacrylamide gels shows that the IAEDANS and fluorescein 5'-isothiocyanate labels are both associated with the B tryptic fragment. The energy transfer measurements are consistent with distances of 56 and 68 A between IAEDANS and these respective binding sites. On the other hand, energy transfer measurements using the lanthanide, praseodymium (Pr3+), as an acceptor indicate that IAEDANS is located 16-18 A from the binding site(s) of this calcium analog. Pr3+ is shown to be a good analog for calcium binding to the high affinity sites on the enzyme since it competitively displaces calcium, as evidenced by the reversal of the specific calcium-dependent intrinsic fluorescent signal and inactivation of ATPase activity, over the same narrow range in Pr3+ concentration where energy transfer is observed. Our observations suggest that the portion of the B fragment spanning the cytoplasmic portion of the ATPase is folded onto the A fragment, bringing the IAEDANS label in close proximity to the high affinity calcium binding domain.     

A fluorescence investigation of the nucleotide binding sites of the Ca ATPase

Competitive binding and fluorescence energy transfer experiments were used to examine the binding of 2'[3']-O-(2,4,6-trinitrophenyl) adenosine-5'-diphosphate (TNP-ADP) to the catalytic site of Ca ATPase. Fluorescein isothiocyanate (FITC), which is known to covalently bind near the catalytic site (13), was shown to exclude all TNP-ADP binding. TNP-ADP, in turn, will protect against FITC labeling of the Ca ATPase in its native state and in both phosphoenzyme forms. The competitive nature of these probes indicates that TNP-ADP binds to the catalytic site exclusively. Fluorescence energy transfer studies using TNP-ADP as an energy acceptor and 1,N6-ethenoadenosine-5'-diphosphate (epsilon-ADP) as an energy donor were used to estimate the distance between nucleotide binding sites in the enzyme complex. A lower limit for the distance measured was 44 A. This is interpreted to be the distance between catalytic sites on adjacent monomers of a dimer unit. The results of this work are consistent with a single nucleotide site per ATPase monomer.     

Selective modification of an alpha subunit of chloroplast coupling factor 1

Lucifer yellow (4-amino-N-[3-(vinylsulfonyl)phenyl]naphthalimide-3,6-disulf onate), a fluorescent probe that can react covalently with sulfhydryl or amino groups, has been used to modify chloroplast coupling factor 1 (CF1). Conditions are described under which Lucifer yellow selectively labels the alpha subunit of CF1 to the extent of about 1 mol of probe per mole of CF1. An especially reactive amino group is apparently labeled, and modification has little effect on the ATPase activity of the enzyme. Lucifer yellow is a useful probe for fluorescence energy transfer measurements. The distances between this probe and fluorescent and absorbing molecules attached to seven specific sites on the beta, gamma, and epsilon subunits were determined. These distances converge to a single location. In addition to providing further information about the structure of CF1, these results suggest that the alpha subunits of CF1 are not structurally equivalent.     

Alteration of the nucleotide-binding site asymmetry of chloroplast coupling factor 1 by catalysis

Fluorescence resonance energy transfer was used to show that ATP hydrolysis induces a change in the properties of two nucleotide-binding sites in isolated chloroplast coupling factor 1 (CF1). The fluorescence donor was Lucifer Yellow vinyl sulfone (4-amino-N-[3-(vinylsulfonyl)phenyl]naphthalimide- 3,6-disulfonate), covalently bound to a unique site on the alpha subunit between nucleotide-binding sites 2 and 3. The fluorescence acceptor was the ATP analog 2'(3')-trinitrophenyladenosine 5'-triphosphate (TNP-ATP), incorporated specifically into nucleotide-binding site 1. Energy transfer from Lucifer Yellow to TNP-ATP in site 1 was greater if catalysis occurred before TNP-ATP was incorporated than if no catalysis occurred, indicating that one of the nucleotide-binding sites near the Lucifer Yellow had changed its properties to those of site 1 as a result of catalysis. The amount of energy transfer increased with the degree of substrate excess during catalysis, as expected if catalysis were required for the new site 1 location. ADP, which binds to CF1, but is not a substrate for hydrolysis, caused little energy transfer. Titration of site 3 with TNP-ATP showed greater energy transfer from Lucifer Yellow when catalysis had not occurred, indicating that sites 1 and 3 switched properties as a result of catalysis. The amount of energy transfer declined exponentially with time between removal of substrate and addition of TNP-ATP to site 1, with a half-time of 1.5-2 h at room temperature. This result suggests that the change that results in switching of nucleotide-binding sites 1 and 3 relaxes in the absence of substrate. Our results show that the asymmetry of the nucleotide-binding sites of CF1 is not a permanent feature of the molecule.     

FRET analysis indicates that the two ATPase active sites of the P-glycoprotein multidrug transporter are closely associated

Members of the ABC superfamily carry out the transport of various molecules and ions across cellular membranes, powered by ATP hydrolysis. Substantial evidence indicates that the two catalytic sites of the nucleotide binding domains function in a highly cooperative, alternating sites mode, which suggests the possibility that they interact with each other physically. In this study, fluorescence energy transfer experiments were used to estimate the distance between two fluors, each covalently linked to a highly conserved Cys residue (Cys428 and Cys1071) within the Walker A motif of the catalytic site. The vanadate.ADP.Mg(2+) complex was trapped in one catalytic site of membrane-bound or highly purified P-glycoprotein, and the other site was labeled with MIANS [2-(4'-maleimidylanilino)naphthalene-6-sulfonic acid]. Following loss of the trapped vanadate complex, the newly vacant site was then labeled with NBD-Cl (7-chloro-4-nitrobenzo-2-oxa-1,3-diazole). The fluorescence properties of the singly labeled P-glycoproteins showed that no energy transfer occurred between MIANS (the donor) and NBD (the acceptor) when they were simply mixed together. On the other hand, the fluorescence emission of the MIANS group in doubly labeled P-glycoprotein was highly quenched as a result of energy transfer to NBD, leading to an estimate of a donor-acceptor separation distance of approximately 16 A for P-glycoprotein labeled in the native plasma membrane and approximately 22 A for P-glycoprotein labeled in detergent solution. The separation of the two fluorophores is compatible with the recently reported crystal structure of the Rad50cd dimer, but not with that of the HisP dimer. These results suggest that the two catalytic sites of the P-glycoprotein nucleotide binding domains are relatively close together, which would facilitate cooperation between them during the catalytic cycle.     

Excitation energy transfer studies on the proximity between SH1 and the adenosinetriphosphatase site in myosin subfragment 1

Excitation energy transfer studies were carried out to determine the distance between the adenosinetriphosphatase (ATPase) site and a unique "fast-reacting" sulfhydryl (referred to as SH1) in myosin subfragment 1. The fluorescent moiety of the probe N-(iodoacetyl)-N'-(5-sulfo-1-naphthyl)ethylene-diamine was used as the donor attached at SH1. The chromophoric nucleotide analogue 2'(3')-0-(2,4,6-trinitrophenyl)adenosine 5'-diphosphate was used as the acceptor noncovalently bound at the ATPase site. The energy transfer efficiency was found to be 56% by measuring the decrease in donor fluorescence lifetime. The critical transfer distance, R0(2/3), was determined to be 40.3 A. Since both donor and acceptor are likely to be rigidly attached, a statistical interpretation of the data was applied (Hillel, Z., & Wu, C.-W. (1976) Biochemistry 15, 2105] to determine distances. The method yielded the following conclusions: most probable distance = 38.7 A; maximum possible distance = 52 A; 10% probability for the distance to be less than 20 A; 3% probability to be less than 15 A. It may be concluded that despite the great influence that the two sites exert on each other, it is not likely that SH1 interacts directly with the ATPase site in myosin subfragment 1. This conclusion is in agreement with the findings of Wiedner et al. [Wiedner, H., Wetzel, R., & Eckstein, F. (1978) J. Biol. Chem. 253, 2763] and Botts et al. [Botts, J., Ue., K., Hozumi, T., & Samet, J. (1979) Biochemistry 18, 5157].     

A series of site-specific fluorescently labeled BPTI derivatives prepared by nonselective acylation and chromatographic separations

Investigation of conformational transitions and, in particular, the folding/unfolding transitions of globular proteins by means of excitation energy transfer measurements depends on the availability of protein derivatives carrying donor and acceptor probes at well-defined pairs of sites. A series of bovine pancreatic trypsin inhibitor (BPTI) derivatives, each labeled at one of the epsilon-amino groups, was prepared. This was achieved by a nonselective acylation reaction using 7-dimethyl-amino-coumarin-4-acetyl-N-hydroxysuccinimide ester (DACA-NHSIE) as a reagent yielding a mixture of products. The mixture was resolved by affinity chromatography and reversed phase high performance liquid chromatography (HPLC). Four derivatives were obtained, each carrying the probe at one of the four amino groups. Identification of site of labeling and determination of the purity of the products was achieved by HPLC-tryptic peptide mapping. The labeled derivatives are active and can undergo a reversible denaturation/renaturation cycle. The spectral characteristics of the probe make it a suitable acceptor in energy-transfer measurements. The advantage of the approach described here, namely nonselective reaction combined with efficient fractionation procedures for the preparation of site specifically labeled derivatives, is that each of the amino groups can be labeled in a simple procedure, thus allowing for a maximal number of labeling sites which cannot be achieved when site-directed reagents (e.g. specific particular protection) are used. The present method yields derivatives which are useful in energy transfer measurements for determination of intramolecular distances between labeled sites. The derivatives should be useful in the analysis of the mechanism of protein folding and the intermediate structures involved.     

Sulfhydryl reagents and energy-linked reactions in monocot thylakoids

Monofunctional maleimides have been used to covalently modify the coupling factor protein of monocot thylakoid membranes. As with dicot thylakoids, incubation of the monocot thylakoids with maleimides in the light but not in the dark results in inhibition of both ATP synthesis and hydrolysis. In the dark, sites on the γ and ε subunits of maize Zea mays coupling factor 1 are modified after incubation of maize mesophyll thylakoids with the fluorescent maleimide N-(anilinonaphthyl-4) maleimide. A light accessible site localized solely to the γ subunit has also been demonstrated. In contrast to the case with dicot thylakoids (spinach [Spinacia oleracea] and pea [Pisum sativum]) treatment of monocot thylakoids (maize, barley [Hordeum vulgare], crabgrass [Digitaria sanguinalis]) with bifunctional maleimides or thiol oxidants in the light does not result in functional uncoupling, i.e the bifunctional reagents act more like energy transfer inhibitors. The lack of functional uncoupling could be due either to a failure of the reagents to cross-link key sulfhydryl residues in the γ subunit or to the continued ability of the γ subunit to gate proton movements through the chloroplast coupling factor complex even though its conformation has been altered by sulfhydryl reagents.     

Proximity between fluorescent probes attached to four essential lysyl residues in phosphoenolpyruvate carboxylase. A resonance energy transfer study

Phosphoenolpyruvate carboxylase, purified from maize leaves, is rapidly inactivated by the fluorescence probe dansyl chloride. The loss of activity can be ascribed to the covalent modification of an R-NH2 group, presumably the epsilon-NH2 group of lysine. Analysis of the data by the statistical method of Tsou [Sci. Sin. 11, 1535-1558 (1962)] provides clear evidence that a pH 8 eight R-NH2 groups can be modified in the tetrameric form of the enzyme, four of which are essential for catalytic activity. Essential groups are modified about five times more rapidly than the non-essential ones. The enzyme was completely protected against inactivation by Mg2+ plus phosphoenolpyruvate and consequently binding of the modifier to the essential groups is completely abolished. Hence the four essential groups seemed to be located at or near the active site(s). One of the four essential groups was modified with dansyl chloride and the other three progressively with eosin isothiocyanate. In the doubly labeled protein non-radiative single-singlet energy transfer between dansyl chloride (donor) and eosin isothiocyanate (acceptor) was observed. The low variance (+/- 5%) in the efficiency of energy transfer obtained at a particular acceptor stoichiometry (0.8-1.1, 1.9-2.1, 2.9-3.1) in triplicate samples provided confidence that the measured transfer efficiency may be interpreted as transfer between specific sites. The distances calculated from the efficiency of resonance energy transfer revealed two acceptor sites, equally separated, 4.8-5.1 nm from the donor site and third site being 6.4 nm apart from the donor. Under conditions where the tetrameric enzyme dissociates into the monomers, no transfer of resonance energy between the protein-bound dansyl chloride and eosin isothiocyanate was observed. Most likely the four essential lysyl residues in the tetrameric enzyme are located in different subunits of the enzyme, hence each of the subunits would contain a substrate-binding site with one lysyl residue crucial for activity.     

Fluorescence resonance energy transfer mapping of the fourth of six nucleotide-binding sites of chloroplast coupling factor 1.

Equilibrium dialysis measurements of adenine nucleotide binding to chloroplast coupling factor 1 suggest that the enzyme has six binding sites for ADP, adenylyl-beta,gamma-imidodiphosphate (AMP-PNP), and 2'(3')-O-2,4,6-trinitrophenyl-ATP (TNP-ATP). High affinity binding at all six sites requires the divalent cation, Mg2+. Three of the nucleotide-binding sites, sites 1, 2, and 3, have been mapped by fluorescence resonance energy transfer distance measurements (see McCarty, R. E., and Hammes, G. G. (1987) Trends Biochem. Sci. 12, 234-237). Using the same technique, we mapped the location of nucleotide-binding site 4, a tight, exchangeable site (Shapiro, A. B., Huber, A. H., and McCarty, R. E. (1991) J. Biol. Chem. 266, 4194-4200). Two arrangements of the energy transfer map of coupling factor 1 were found which are compatible with the available data. The two arrangements make different predictions about which sites interact in cooperative catalysis.     

Fluorescence energy transfer experiments with Escherichia coli carbamoyl-phosphate synthetase

Fluorescence energy transfer experiments were used to measure distances between three fluorescently labeled sulfhydryl sites on Escherichia coli carbamoyl-phosphate synthetase, an unsymmetrical dimer. When five different combinations of fluorescent donor-acceptor pairs are used, the distance between site 1, located on the large subunit, and site 2, located on the small subunit, is in the range of 27-33 A. Similarly, the distance between site 1 and site 3 (large subunit) was approximately 27 A and between site 2 and site 3 was approximately 21 A. A similar approach was employed to determine distances between each sulfhydryl group and the ATP site(s), and in all cases no fluorescence quenching was observed using Cr3+ATP or Co(NH3)4ATP as substrate analogues. A lower limit could be calculated from these data, resulting in a distance of greater than or equal to 21 A from each sulfhydryl site to the ATP site. Additional experiments were performed to evaluate if the substrates ATP, HCO3(-), or glutamine or the allosteric modifiers ornithine, IMP, and UMP altered the distance relationships among the sulfhydryl sites. IMP and UMP produced a slight decrease in fluorescence between sites while glutamine and ATP produced a slight increase in fluorescence.     

Structural mapping of cysteine-63 of the chloroplast ATP synthase beta subunit.

The single sulfhydryl residue (cysteine-63) of the beta subunit of the chloroplast ATP synthase F1 (CF1) was accessible to labeling reagents only after removal of the beta subunit from the enzyme complex. This suggests that cysteine-63 may be located at an interface between the beta and the alpha subunits of CF1, although alternative explanations such as a conformational change in beta brought about by its release from CF1 cannot be ruled out. Cysteine-63 was specifically labeled with [(diethylamino)methylcoumarinyl]-maleimide, and the distance between this site and trinitrophenyl-ADP at the nucleotide binding site on beta was mapped using fluorescence resonance energy transfer. Cysteine-63 is located in a hydrophobic pocket, 42 A away from the nucleotide binding site on beta.     

Structural rearrangements in the active site of smooth-muscle myosin

Structural rearrangements of the myosin upper-50 kD subdomain are thought to play a key role in coordinating actin binding with nucleotide hydrolysis during the myosin ATPase cycle. Such rearrangements could open and close the active site in opposition to the actin-binding cleft, helping explain the opposing affinities of myosin for actin and nucleotide. To directly examine conformational changes across the active site during the ATPase cycle we have genetically engineered a mutant of chicken smooth-muscle myosin, F344W motor domain essential light chain, which contains a single tryptophan (344W) located on a short loop between two alpha helixes that traverse the upper-50 kD subdomain in front of the active site. Fluorescence resonance energy transfer was examined between the 344W donor probe and 2'(3')-O-(N-methylanthraniloyl) (mant)-nucleotide acceptor probes in the active site of this construct. The observed fluorescence resonance energy transfer efficiencies were 6.4% in the presence of mant ADP and 23.8% in the presence of mant ATP, corresponding to distances of 33.4 A and 24.9 A, respectively. Our results are consistent with structural rearrangements in which there is an 8.5-A closure between the 344W residue and the mant moiety during the transition from the strongly (ADP) to weakly (ATP) actin-bound states of the myosin ATPase cycle.