Rotational dynamics of 4-aminobutyrate aminotransferase

The fluorescence dye 1-anilinonaphthalene-8-sulfonate (ANS) was used as a probe of non-polar binding sites in 4-aminobutyrate aminotransferase. ANS binds to a single binding site of the dimeric protein with a K_d of 6 μM. Nanosecond emission anisotropy measurements were performed on the ANS-enzyme in an effort to detect independent rotation of the subunits in the native enzyme. The observed rotational correlation time (φ = 65 ns) corresponds to the rotation of a rather rigid dimeric structure. The microenvironment surrounding the natural probe pyridoxal-5-P covalently bound to the dimeric structure was explored using ³¹P-NMR at 72.86 MHz. In the native enzyme, the pyridoxal-5-P ³¹P-chemical shift is pH-independent, indicating that the phosphate group is well protected from the solvent. The correlation time determined from the ³¹P-spectrum of the aminotransferase exceeds the value calculated for the hydrated spherical model (φ = 40 ns). It is concluded that the phosphate of the pyridoxal-5-P molecule is rigidly bound to the active site of 4-aminobutyrate aminotransferase.     

Brain pyridoxal kinase. Mechanism of substrate addition, binding of ATP, and rotational mobility of the inhibitor pyridoxaloxime

The inhibition kinetic patterns obtained when ATP and pyridoxal analogues are used as inhibitors of the reaction catalyzed by pyridoxal kinase are consistent with a rapid equilibrium random Bi Bi, in which binary complexes, i.e. enzyme . ATP and enzyme . pyridoxal, are formed in kinetically significant amounts. Protein fluorescence quenching was used to determine the dissociation constant (Kd = 25 microM) of ATP . Zn bound to the nucleotide site of the kinase. The binding of ATP to the kinase induces a conformational change which is transmitted to other areas of the macromolecule. Pyridoxaloxime, a competitive inhibitor of pyridoxal, was used as a probe of the pyridoxal-binding site. It binds to the kinase with Ki = 2 microM and displays a fluorescent decay time of 7.8 ns. Time emission anisotropy measurements yield a rotational correlation time for bound pyridoxaloxime of approximately 2 ns, which is considerably shorter than the rotational correlation time of the protein (phi = 38 ns). The fast rotation of pyridoxaloxime remains unaffected by the binding of ATP.     

Fluorescence polarization study of the alpha-ketoglutarate dehydrogenase complex from Escherichia coli

The lipoic acids of the alpha-ketoglutarate dehydrogenase multienzyme complex from Escherichia coli have been modified with two fluorescent probes, N-(1-pyrenyl)-maleimide and 5-[[[(iodoacetyl)amino]ethyl]amino]-naphthylene-1-sulfonic acid. Time-resolved fluorescence polarization of partially labeled complexes (18-77% inhibition of enzyme activity) reveals a complex depolarization process: one component of the anisotropy is characterized by a rotational correlation time much longer than the time scale of the measurements (less than or equal to 400 ns), reflecting the overall rotation of the complex, while a second component of the anisotropy decays with a rotational correlation time of 320 (+/- 50) ns. This decay is essentially independent of viscosity and is consistent with a model in which the depolarization is due to the dissociation from and rotation of lipoic acids between binding sites on the multienzyme complex. The sum of the rate constants characterizing the association and dissociation with the binding sites is approximately 3 x 10(6) s-1. In addition, approximately 5% of the anisotropy of the N-(1-pyrenyl)maleimide-labeled complex decays with a rotational correlation time of 25 ns; this can be attributed to local motion of the probe. At high extents of N-(1-pyrenyl)maleimide labeling (90-95% inhibition of enzyme activity), the anisotropy decay can be described by a constant term plus a rotational correlation time of about 1 microseconds. The increase in the correlation time probably reflects interactions between pyrene moieties. The N-(1-pyrenyl)maleimide-labeled dihydrolipoyl transsuccinylase core of the multienzyme complex has been isolated, and the anisotropy is constant over the observed time range of 300 ns. This suggests that the native structure is necessary for observation of lipoic acid movement within the complex. Fluorescent-labeled limited trypsin digestion fragments of the alpha-ketoglutarate dehydrogenase complex also have been isolated, and anisotropy measurements reveal substantial mobility of the label within the fragments. The time-resolved anisotropy of FAD in the native complex and in the isolated dihydrolipoyl dehydrogenase indicates some rapid local mobility of the FAD (rotational correlation time of 12 ns) that is viscosity independent, as well as a component of the anisotropy that is constant over the 35-ns time scale of the experiments.     

Molecular mobility of a fluorescent probe in binding sites of an albumin molecule

The molecular mobility of the fluorescent probe, N-(carboxymethyl)imide of 4-(dimethylamino)naphthalic acid (K-35), in three types of binding site on a human serum albumin (HSA) molecule has been studied. Study of the time-resolved decay of K-35 polarized fluorescence in HSA has shown that probe molecules bound to different sites have different fluorescence decay times, which poses problems in interpreting the polarization curves. However, it has been found that, in the case of rather slow thermal rotation of the probe, the decay of the vertical and the horizontal components of polarized fluorescence can each be approximated with three exponentials corresponding to three types of binding site. The mobility of the probe in different sites was estimated. The mobility was different but in all cases hindered by tens of times relative to the rotation of K-35 in water. The slowest motion occurred in the sites of the first type localized in the region of the well known drug site I: there the rotational correlation time was at least 72 ns. In the sites of the second type, this time was about 40 ns, and in the sites of the third type, about 10 ns. The faster was the rotation, the higher was the fluorescence quenching rate. Probably, it is this motion that is responsible for different fluorescence decay times in different HSA sites.     

Molecular cloning of rabbit hyaluronic acid synthases and their expression patterns in synovial membrane and articular cartilage

Interaction of camel lens zeta-crystallin with the hydrophobic probe 1-anilinonaphthalene-8-sulfonic acid (ANS) enhanced the ANS fluorescence and quenched the protein fluorescence. Both of these events were concentration-dependent and showed typical saturation curves suggesting specific ANS-zeta-crystallin binding. Quantitative analysis indicated that 1 mole zeta-crystallin bound at most 1 mole ANS. NADPH but not 9,10-phenanthrenequinone (PQ) was able to displace zeta-crystallin-bound ANS. These results suggested the presence of a hydrophobic domain in zeta-crystallin, possibly at the NADPH binding site. alpha-Crystallin as well as NADPH protected zeta-crystallin against thermal inactivation suggesting the importance of this site for enzyme stability. The NADPH:quinone oxidoreductase activity of zeta-crystallin was inhibited by ANS with NADPH as electron donor and PQ as electron acceptor. Lineweaver-Burk plots indicated mixed-type inhibition with respect to NADPH, with a K(i) of 2.3 microM. Secondary plots of inhibition with respect to NADPH indicated a dissociation constant (K'I) of 12 microM for the zeta-crystallin-NADPH-ANS complex. The K(i) being smaller than K'I suggested that competitive inhibition at the NADPH binding site was predominant over non-competitive inhibition. Like ANS-zeta-crystallin binding, inhibition was dependent on ANS concentration but independent of incubation time.     

Opposite effects of Ca(2+) and GTP binding on tissue transglutaminase tertiary structure

Tissue transglutaminase (tTG) belongs to a class of enzymes that catalyze a cross-linking reaction between proteins or peptides. The protein activity is known to be finely tuned by Ca(2+) and GTP binding. In this study we report the effects of these ligands on the enzyme structure, as revealed by circular dichroism, and steady-state and dynamic fluorescence measurements. We have found that calcium and GTP induced opposite conformational changes at the level of the protein tertiary structure. In particular the metal ions were responsible for a small widening of the protein molecule, as indicated by anisotropy decay measurements and by the binding of a hydrophobic probe such as 1-anilino-8-naphthalenesulfonic acid (ANS). Unlike Ca(2+), the nucleotide binding increased the protein dynamics, reducing its rotational correlation lifetime from 32 to 25 ns, preventing also the binding of ANS into the protein matrix. Unfolding of tTG by guanidinium hydrochloride yielded a three-state denaturation mechanism, involving an intermediate species with the characteristics of the so-called "molten globule" state. The effect of GTP binding (but not that of Ca(2+)) had an important consequence on the stability of tissue transglutaminase, increasing the free energy change from the native to the intermediate species by at least approximately 0.7 kcal/mol. Also a greater stability of tTG to high hydrostatic pressure was obtained in presence of GTP. These findings suggest that the molecular mechanism by which tTG activity is inhibited by GTP is essentially due to a protein conformational change which, decreasing the accessibility of the protein matrix to the solvent, renders more difficult the exposure of the active site.     

Fluorescent derivatives of the pyruvate dehydrogenase component of the Escherichia coli pyruvate dehydrogenase complex.

One sulfhydryl group per polypeptide chain of the pyruvate dehydrogenase component of the pyruvate dehydrogenase multienzyme complex from Escherichia coli was selectively labeled with N-[P-(2-benzoxazoyl)phenyl]-maleimide (NBM), 4-dimethylamino-4-magnitude of-maleimidostilbene (NSM), and N-(4-dimethylamino-3,5-dinitrophenyl)maleimide (DDPM) in 0.05 M potassium phosphate (pH 7). Modification of the sulfhydryl group did not alter the enzymatic activity or the binding of 8-anilino-1-naphthalenesulfonate (ANS) or thiochrome diphosphate to the enzyme. The fluorescence of the NBM or NSM coupled to the sulfhydryl group on the enzyme was quenched by binding to the enzyme of the substrate pyruvate the coenzyme thiamine diphosphate, the coenzyme analogue thiochrome diphosphate, the regulatory ligands acetyl-CoA, GTP, and phosphoenolpyruvate, and the acetyl-CoA analogue, ANS. Fluorescence energy transfer measurements were carried out for the enzyme-bound donor-acceptor pairs NBM-ANS, NBM-thiochrome diphosphate ANS-DDPM, and thiochrome diphosphate-DDM. The results indicate that the modified sulfhydryl group is more than 40 A from the active site and approximately 49 A from the acetyl-CoA regulatory site. Thus, a conformational change must accompany the binding of ligands to the regulatory and catalytic sites. Anisotropy depolarization measurements with ANS bound on the isolated pyruvate dehydrogenase in 0.05 M potassium phosphate (pH 7.0) suggest that under these conditions the enzyme is dimeric.     

Molecular motility of a fluorescent probe in binding sites of albumin molecules

The molecular mobility of the fluorescent probe, N-(carboxymethyl)imide of 4-(dimethylamino)naphthalic acid (K-35) in three types of binding sites on a human serum albumin (HSA) molecule has been studied. The time-resolved decay of K-35 polarized fluorescence in HSA has been studied and it has been shown that probe molecules bound to different sites have different fluorescence decay time, which poses problems in the interpretation of polarization decay. However, it has been found that, in the case of rather slow thermal rotation of the probe, the decay of each of vertical and horizontal polarized fluorescence components can be approximated by three exponentials corresponding to three types of binding sites. The mobility of the probe in different sites was estimated. The mobility was different but hindered by tens of times in all sites as compared with the rotation of K-35 in water. The slowest motion occurred in the sites of the first type localized in the region of the well known first drug-binding site: here the rotational correlation was close to 72 ns or more. In the sites of the second type, the time was about 40 ns, and in the sites of the third type, the time was about 10 ns. It was found that the higher the rotation rate, the higher the fluorescence quenching rate. Probably, it is this motion that is responsible for different fluorescence decay times in different HSA sites.     

Investigation of conformational changes in yeast enolase using dynamic fluorescence and steady-state quenching measurements

Conformational changes in yeast enolase were investigated using steady state quenching and dynamic (fluorescence decay and fluorescence anisotropy decay) measurements. The tryptophan fluorescence rotational correlation time increases from 24 to 38 ns on subunit association. The acrylamide quenching constant decreases two-fold when the subunits associate. The conformational metal ion effect suggests a more compact molecule. Under conditions of catalysis, the correlation time decreases 25%, though the sedimentation constant does not change (Holleman, 1973). The enzyme may undergo a hinge-bending motion during catalysis.     

The partially unfolded state of beta-momorcharin characterized with steady-state and time-resolved fluorescence studies

The specific conformation of partially unfolded state of beta-momorcharin was characterized through the steady-state and time-resolved fluorescence spectroscopic studies on a single Trp-190 which located adjacently to the active site. The content of secondary structure was retained, the binding of ANS was remarkably enhanced, and the correlation time of entire protein rotation was prolonged at the partially unfolded state formed by being equilibrated with the mild concentration of guanidine hydrochloride. The time-resolved fluorescence depolarization and excitation energy transfer analysis suggest that Trp-190 approached 2 A closer to Tyr-70 and was hidden from the exposure to the protein surface, while the rotational correlation time and freedom of its segmental motion were shortened and enhanced, respectively. These results suggest that the transient folding/unfolding intermediate state of beta-momorcharin adopt the specific conformation at the vicinity of the active site, although it exhibits very similar properties with those of the generally known molten-globule state.     

Quaternary structure of chloroplast F1-ATPase in solution. Conformational changes in spatial arrangement of subunits upon activation

The hydrodynamic properties of isolated ATPases were studied via their rotational diffusion in buffer solution. Chloroplast F1-ATPase (CF1) and Escherichia coli F1-ATPase (EF1) were covalently labeled with eosinisothiocyanate and then investigated by polarized laser spectroscopy. The rotational correlation time in aqueous buffer of latent (five-subunit) CF1 was 390 ns. Four-subunit (delta-deficient) CF1 showed the same correlation time, however, for three-subunit (delta, epsilon-deficient) CF1 the rotational correlation time was more than eight times larger (3200 ns). The rotational correlation time of activated CF1 was three times larger than the one of latent CF1. These large changes in the rotational correlation times are directly related to changes in the quaternary structure of CF1 upon activation. EF1 was found to behave essentially as activated CF1. Based on the observed rotational correlation times we concluded that the mass distributions of latent CF1 and of delta-deficient CF1 resemble a dimeric arrangement. The structure of delta, epsilon-deficient CF1 more likely resembles a hexagon, the mass centers of the six main subunits lie in one plane. The structure of the activated forms of CF1 can be described best as an intermediate between the dimeric arrangement of latent CF1 and an octahedron. The large changes in the quaternary structure of isolated CF1 are reversed when the activation of the enzyme is reversed.     

Flexibility of the molecular forms of acetylcholinesterase measured with steady-state and time-correlated fluorescence polarization spectroscopy

Steady-state and time-correlated fluorescence polarizations have been examined for selected complexes and covalent conjugates of the 11S and (17 + 13)S forms of Torpedo acetylcholinesterase. The 11S form exists as a tetramer of apparently identical subunits, whereas the (17 + 13)S forms contain two or three sets of tetramers disulfide-linked to an elongated collagen-like tail unit. Pyrenebutyl methylphosphonofluoridate and (dansylsulfonamido)pentyl methylphosphonofluoridate were conjugated at the active center serine whereas propidium was employed as a fluorescent ligand for the spatially removed peripheral anionic site. Steady-state polarization of the pyrenebutyl conjugates indicates rotational correlation times of approximately 400 ns for the 11S species and greater than 1100 ns for the (17 + 13)S species. Hence, the tail unit severely restricts rotational motion of the catalytic subunits. Time-correlated fluorescence polarization analysis of the 11S species indicates multiple rotational correlation times. Anisotropy decay of the propidium complex (tau = 6 ns) occurs in exponential manner with a rotational correlation time of approximately 150 ns, while covalent adducts at the active center exhibit rotational correlation times greater than or equal to 300 ns. Anisotropy decay of the (dansylsulfonamido)pentyl conjugate (tau = 16 ns) appears exponential with a correlation time of approximately 320 ns, whereas decay of the pyrenebutyl conjugate (tau = 100 ns) is described by two correlation times, phi S = 18 ns and phi L = 320 ns, of small (15%) and large (85%) amplitudes, respectively. Two limiting models have been considered to explain the results.(ABSTRACT TRUNCATED AT 250 WORDS)     

Time resolved fluorescence of bacteriophage Pfl DNA binding protein and its complex with DNA

The DNA binding protein of the filamentous bacteriophage Pfl exhibits fluorescence from a single tryptophan residue. The location of the emission maximum at 340 nm ist quite common for proteins, but the single lifetime of 7.8 ns is one of the longest yet reported. Protein fluorescence is quenched more efficiently by Cs⁺ than by I^-; the Trp is located in a partially exposed pocket, in the vicinity of a negative charge.In the native complex of the binding protein with Pfl DNA the fluorescence emission maximum is at 330 nm, indicating a more apolar environment for Trp 14. The native nucleoprotein complex exhibits a similar fluorescence lifetime (6.5 ns) and an approximately equal fluorescence yield, indicating the absence of Trp-DNA stacking. The tryptophan in the complex is virtually inaccessible to ionic quenchers, and thus appears to be buried.Fluorescence depolarisation measurements have been used to examine the rotational mobility of the tryptophan in the protein and in the nucleoprotein complex. In the protein alone a single rotational correlation time () of 19 ns is observed, corresponding to rotation of the entire dimeric molecule; in the native nucleoprotein complex with Pfl DNA, a of 500 ns is observed, corresponding to a rigid unit of at least 50 subunits. In neither case does the tryptophan exhibit any detectable flexibility on the subnanosecond time scale.     

Fluorescence study of lymphocyte plasma membranes]

ANS binding parameters--dissociation constant, number of binding sites, rotation freedom--are measured by fluorescence studies of a complex between ANS and lymph node cell plasma membranes. Divalent ions, Mg++ and Ca++, enhance the complex fluorescence intensity without shifting its maximum wavelength : this enhancement is induced by affinity and quantum yield increases, while the number of binding sites remains constant. The complex fluorescence quenching by ethacrynic acid shows the presence of free SH groups in the ANS binding site. An energy transfer takes place between membrane protein tryptophan residues and bound ANS ; the energy transfer yield is unaffected by Ca++ ions. A correlation of these results is postulated with the biological activity of the membrane.     

Dynamics of tryptophan in the histidine-containing phosphocarrier protein of Streptomyces coelicolor: evidence of multistate equilibrium unfolding

The nanosecond dynamics of the single tryptophan, Trp10, of HPr from Streptomyces coelicolor, HPrsc, has been monitored at different pHs. Time-resolved fluorescence methods and DOSY measurements have been used to map the compactness of the protein. At low pHs, where a molten globule-like species has been described, the correlation times from fluorescence showed an abrupt change as the pH was increased. When the protein was folded (above pH 4), two correlation times were observed, which remained practically constant up to pH 9.5. The long correlation time, around 7.5 ns, corresponds to the global rotational motion of the protein, since this value is in agreement with that determined theoretically from hydrodynamic measurements. The short correlation time, around 1.4 ns, must report on fast movements of the protein segment containing the tryptophan residue. On the other hand, fluorescence lifetimes showed the same abrupt change as the correlation times at low pH, but, in addition, a sigmoidal change with a pKa approximately 4.3 was also observed. On the basis of the modeled structure of HPrsc, this last transition could be due to the proximity of Glu12 to Trp10. The changes monitored by the fluorescence lifetimes agree with those observed previously by steady-state fluorescence, CD, and ANS binding experiments. Taken together, these data suggest a multistate equilibrium during folding of HPrsc starting from low pHs.     

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.     

The effects of ligands on the conformation of phosphoglycerate kinase: fluorescence anisotropy decay and theoretical interpretation

Horse muscle phosphoglycerate kinase (PGK) is a monomer folded into two widely distant domains. In the glycolytic pathway, this enzyme catalyzes the first reaction that produces ATP. It was suggested, by analogy with yeast hexokinase, that a hinge-bending motion may be induced by the binding of specific substrates to the protein. To analyze such a motion, or any structural changes induced by ligand binding, fluorescence anisotropy decay of tryptophan residues in free and liganded PGK was studied. At 293 K, for the free protein and the binary complex with 3-phosphoglycerate, a single correlation time of 26 ns was observed, corresponding to the rotation of the overall protein, whereas upon addition of MgADP, this correlation time decreased to 10 ns. Such a decrease cannot be merely due to a change of the protein's shape and volume. To explain this, it was suggested that the fluorescence anisotropy decay of the PGK-MgADP complex corresponded to the rotation of the only buried tryptophan (Trp 335). The rotational paths of this tryptophan, in the presence and absence of the nucleotide, were established by potential energy minimization calculations. The results indicated that MgADP induces a displacement of helix alpha-13 that decreases the rotational energy barrier of Trp 335 from 16 kcal/mol in the free protein to 8 kcal/mol in the complex.     

Degree of dissociation of apohemoglobin studied by nano-second fluorescence-polarization technique.

A fluorescent dye 1-anilino-8-naphthalene sulfonate was complexed with human apohemoglobin and sperm whale apomyoglobin. Nanosecond fluorescence-polarization kinetics were measured for each of these complexes in KC1 solutions to obtain their fluorescence lifetimes and rotational correlation times. The rotational correlation time of apohemoglobin-dye complex was found to be 21 ns, which was about twice that of apomyoglobin-dye complex, 11 ns. These values were constant over an ionic strength range from 0 to 1.7. Circular dichroism spectra (215-300 nm) and fluorescence lifetimes of the complexes were also found to be independent of the ionic strength, indicating that no gross conformational change occurs with the change in the salt concentration, These results suggest that apohemoglobin remains dimeric over the ionic-strength range examined.     

Nanosecond emission anisotropy of interacting enzymes aspartate aminotransferase glutamate dehydrogenase.

Nanosecond fluorescence studies were performed on mitochondrial aspartate aminotransferase from beef liver to determine whether the dimeric enzyme displays any modes of flexibility in the nanosecond range. The most informative quantities calculated from nanosecond fluorescence measurements S(t) and D(t) decay in a monoexponential manner with decay times τ_S = 13 and τ_D = 10 nanoseconds respectively. The observed rotational correlation time θ = 43 M-seconds yields a volume for the dimeric enzyme of 1.97 × 10⁵ A^o3. The rotational correlation time of aspartate aminotransferase is influenced by the presence of the enzyme glutamate dehydrogenase.     

Binding of naphthalene dyes to the N and A conformers of bovine α-lactalbumin

Contrary to earlier findings, monomeric native α-lactalbumin does bind naphthalene dyes such as ANS and TNS with marked enhancement of their fluorescence. Nanosecond decay measurements indicate there to be two dye binding sites per protein molecule with lifetimes of ca. 2 and 15 ns for ANS and 5 and 11 ns for TNS. The fluorescence titrations curves of α-lactalbumin with ANS and TNS reflect this site multiplicity, i.e., it was not possible to analyze such curves with a single K_diss. The apparent dissociation constants for binding of ANS and TNS to native bovine α-lactalbumin, as determined by an ultracentrifugal technique, ca. 950 and 900 μm, respectively, indicate that such binding is considerably weaker than previously supposed. The A conformer (metal ion-free form) of α-lactalbumin binds ANS and TNS more tightly than the N (native) form of the protein with marked fluorescence enhancement. The A conformer has two dye binding sites with lifetimes for ANS and TNS comparable with those seen with native protein.