Terbium(III) luminescence study of tyrosine emission from Escherichia coli glutamine synthetase.

Radiationless energy transfer from tyrosine to Tb(III) in Escherichia coli glutamine synthetase and its two mutants (W57L and W158S) has been utilized to assess the tyrosine residue(s) responsible for the observed tyrosine emission and to investigate its spatial relationships to the two metal binding sites of GS. The interference from tryptophan fluorescence was removed by chemical modification of the tryptophan residues by N-bromosuccinimide (NBS). The Tyr-Tb(III) distances measured by using F?rster energy-transfer theory were in good agreement among the three enzymes with average distances of 10.7 and 11.2 A from Tyr to the two metal binding sites. The pKa value for the ionization of tyrosine was determined from fluorescence titration experiments to be approximately 10 for both mutant enzymes. The similarities in pKa values and Tyr-Tb(III) distances observed for all three enzymes lead to the conclusion that the same tyrosine residue(s), is (are) most likely responsible for the Tyr emission. According to the crystal structure distances from tyrosine residues to the two metal binding sites of GS, it is believed that Tyr-179 is the main contributor to the observed Tyr emission. The fact that an intense Tyr emission was observed for W57L GS but not for W158S GS indicates that Trp-57 is much more effective than Trp-158 in quenching the Tyr-179 emission probably through a F?rster-type energy transfer. Furthermore, modification of Trp-57 by NBS causes no significant increase in Tyr-179 emission while replacement of Trp-57 by leucine does. This may indicate that oxidized Trp-57 is also an effective quencher for Tyr-179 emission.     

Fluorescent probes for measuring the binding constants and distances between the metal ions bound to Escherichia coli glutamine synthetase.

TNS, 2-p-toluidinylnaphthalene-6-sulfonate, has been used as a fluorescent probe to determine the binding constants of metal ions to the two binding sites of Escherichia coli glutamine synthetase (GS). TNS fluorescence is enhanced dramatically when bound to proteins due to its high quantum yield resulting from its interactions with hydrophobic regions in proteins. The fluorescence energy transfer from a hydrophobic tryptophan residue of GS to TNS has been detected as an excitation band centered at 280 nm. Therefore, TNS is believed to be bound to a hydrophobic site on the GS surface other than the active site and is located near a hydrophobic Trp residue of GS. GS binds lanthanide ions [Ln(III)] more tightly than either Mn(II) or Mg(II), and the binding constants of several lanthanide ions were determined to be in the range (2.1-4.6) x 10(10) and (1.4-3.0) x 10(8) M-1 to the two metal binding sites of GS, respectively. The intermetal distances between the two metal binding sites of GS were also determined by measuring the efficiencies of energy transfer from Tb(III) to other Ln(III) ions. The intermetal distances of Tb(III)-Ho(III) and Tb(III)-Nd(III) were 7.9 and 6.8 A, respectively.     

Time-resolved fluorescence studies of genetically engineered Escherichia coli glutamine synthetase. Effects of ATP on the tryptophan-57 loop.

Single-tryptophan-containing mutants of low adenylation state Escherichia coli glutamine synthetase (wild type has two tryptophans at positions 57 and 158) have been constructed and studied by multifrequency phase/modulation fluorescence spectroscopy. The W57L mutant (retains tryptophan at residue 158) and the W158S mutant (retains tryptophan at residue 57) are both characterized by heterogeneous exponential decay kinetics. Global analysis indicates that for the Mn-bound form of the enzyme at pH 7.4 the fluorescence of both tryptophans is best described by a sum of three discrete expontials with recovered lifetimes of 4.77, 1.72, and 0.10 ns for Trp-57 and 5.04, 2.28, and 0.13 ns for Trp-158. The wild-type enzyme also exhibits decay kinetics described by a triple-exponential model with similar lifetime components. The individual tryptophans are distinguishable by the fractional intensities of the resolvable lifetimes. The wild-type and W158S enzymes are dominated by the 5-ns component which provides nearly 60% and 65%, respectively, of the fractional intensity at five wavelengths spanning the emission spectrum. In contrast, the W57L enzyme demonstrates a larger fraction of the 2-ns lifetime species (60%) and only 35% of the longer lifetime component. The substrate ATP induces a shift to approximately 90% of the 5-ns component for the wild-type and W158S enzymes, whereas the W57L protein is essentially unaffected by this ligand. Steady-state quenching studies with iodide indicate that addition of ATP results in a 3.0-3.5-fold decrease in the apparent Stern-Volmer quenching constants for the wild-type and W158S enzymes. Phase/modulation experiments at several iodide concentrations indicate that the median, 2 ns, lifetime component is selectively quenched compared to the 5-ns lifetime component. These results suggest a model where ATP binding results in a shift in the equilibrium distribution of microconformational states populated by Trp-57. ATP shifts this equilibrium nearly completely to the states exhibiting the long-lifetime component which, based on quenching studies, is less solvent-accessible than the conformational states associated with the other lifetime components.     

Comparison of terbium (III) luminescence enhancement in mutants of EF hand calcium binding proteins.

The luminescent isomorphous Ca2+ analogue, Tb3+, can be bound in the 12-amino acid metal binding sites of proteins of the EF hand family, and its luminescence can be enhanced by energy transfer from a nearby aromatic amino acid. Tb3+ can be used as a sensitive luminescent probe of the structure and function of these proteins. The effect of changing the molecular environment around Tb3+ on its luminescence was studied using native Cod III parvalbumin and site-directed mutants of both oncomodulin and calmodulin. Titrations of these proteins showed stoichiometries of fill corresponding to the number of Ca2+ binding loops present. Tryptophan in binding loop position 7 best enhanced Tb3+ luminescence in the oncomodulin mutant Y57W, as well as VU-9 (F99W) and VU-32 (T26W) calmodulin. Excitation spectra of Y57F, F102W, Y65W oncomodulin, and Cod III parvalbumin revealed that the principal Tb3+ luminescence donor residues were phenylalanine or tyrosine located in position 7 of a loop, despite the presence of other nearby donors, including tryptophan. Spectra also revealed conformational differences between the Ca2+- and Tb(3+)-bound forms. An alternate binding loop, based on Tb3+ binding to model peptides, was inserted into the CD loop of oncomodulin by cassette mutagenesis. The order of fill of Tb3+ in this protein reversed, with the mutated loop binding Tb3+ first. This indicates a much higher affinity for the consensus-based mutant loop. The mutant loop inserted into oncomodulin had 32 times more Tb3+ luminescence than the identical synthetic peptide, despite having the same donor tryptophan and metal binding ligands. In this paper, a ranking of sensitivity of luminescence of bound Tb3+ is made among this subset of calcium binding proteins. This ranking is interpreted in light of the structural differences affecting Tb3+ luminescence enhancement intensity. The mechanism of energy transfer from an aromatic amino acid to Tb3+ is consistent with a short-range process involving the donor triplet state as described by Dexter (Dexter, D. L. (1953) J. Chem. Phys. 21, 836). This cautions against the use of the F?rster equation in approximating distances in these systems.     

The intrinsic tryptophan fluorescence of beta 1-bungarotoxin and the Ca2+-binding domains of the toxin as probed with Tb3+ luminescence.

beta 1-Bungarotoxin has only one tryptophan residue, namely Trp-19 in the phospholipase A2 subunit. The environment of Trp-19 was studied by intrinsic fluorescence and solute quenching. The native protein showed an emission peak at 330 nm. About 90% of the fluorescent tryptophan was accessible to quenching by either acrylamide or KI but not to CsCl. A red-shift in the emission peak occurred between 2.0 M- and 4.0 M-guanidinium chloride, and the helix-coil transition of the polypeptide backbone occurred between 4.0 M- and 6.0 M-guanidinium chloride. These results suggested that Trp-19 was in a less polar medium but near a positive charge. The local conformation around Trp-19 could be disturbed by binding of Tb3+ or Ca2+ or Sr2+ to the toxin molecule. Tb3+ a tervalent lanthanide ion, effectively substituted for Ca2+ in stimulating the phospholipase A2 activity of beta 1-bungarotoxin. Upon the binding of Tb3+ to the toxin, the Tb3+ fluorescence in the 450-650 nm region was enhanced. This resulted from the energy transfer from Trp-19 to Tb3+. The distance between the energy-transfer pair was estimated to be 0.376-0.473 nm at pH 7.6 and 0.486-0.609 nm at pH 6.3. Assuming that there were two Tb3+-binding sites on the toxin molecule, at pH 7.6 the association constants of the high-affinity and the low-affinity sites were determined to be 3.82 x 10(3) M-1 and 2.85 x 10(2) M-1 respectively. At between pH 6.0 and 7.0 Tb3+ bound to the high-affinity site decreased greatly but did not disappear entirely. Both Ca2+ and Sr2+ competed with Tb3+ at the high-affinity sites, but Sr2+ could not substitute for Ca2+ in stimulating the phospholipase A2 activity.     

Binding of terbium and of an elastase inhibitor to bovine pancreatic subunit III, an inactive protease E

Using the Tb3+ luminescence technique, we showed that bovine subunit III, a defective pancreatic serine endopeptidase-like protease, possessed a single metal ion binding site able to bind Tb3+ with a high affinity comparable to that of porcine elastase. The topology of the metal ion binding site in subunit III is predicted from sequence homologies and modeling experiments based on the known crystallographic three-dimensional structures of the equivalent sites in porcine elastase 1 and bovine beta-trypsin. Moreover, the Tb3+ luminescence technique in parallel to a 19F NMR investigation, allowed us to measure the binding of a very potent specific inhibitor of porcine elastase (trifluoroacetyl-L-lysyl-alanyl p-trifluoromethylphenylanilide) to bovine subunit III. These results confirm that, although devoid of any specific activity, subunit III might possess a conformation close to that of an active enzyme and further support the analogy between subunit III and an elastase-like family.     

Time-resolved fluorescence studies of tryptophan mutants of Escherichia coli glutamine synthetase: conformational analysis of intermediates and transition-state complexes.

Single tryptophan-containing mutants of low adenylylation state Escherichia coli glutamine synthetase have been studied by frequency-domain fluorescence spectroscopy in the presence of various substrates and inhibitors. At pH 6.5, the Mn-bound wild-type enzyme (wild type has two tryptophans/subunit) and the mutant enzymes exhibit heterogeneous fluorescence decay kinetics; the individual tryptophans are adequately described by a triple exponential decay scheme. The recovered lifetime values are 5.9 ns, 2.6 ns, and 0.4 ns for Trp-57 and 5.8 ns, 2.3 ns, and 0.4 ns for Trp-158. These values are nearly identical to the previously reported results at pH 7.5 (Atkins, W.M., Stayton, P.S., & Villafranca, J.J., 1991, Biochemistry 30, 3406-3416). In addition, Trp-57 and Trp-158 both exhibit an ATP-induced increase in the relative fraction of the long lifetime component, whereas only Trp-57 is affected by this ligand at pH 7.5. The transition-state analogue L-methionine-(R,S)-sulfoximine (MSOX) causes a dramatic increase in the fractional intensity of the long lifetime component of Trp-158. This ligand has no effect on the W158S mutant protein and causes a small increase in the fractional intensity of the long lifetime component of the W158F mutant protein. Addition of glutamate to the ATP complex, which affords the gamma-glutamylphosphate-ADP complex, results in the presence of new lifetime components at 7, 3.2, and 0.5 ns for Trp-158, but has no effect on Trp-57. Similar results were obtained when ATP was added to the MSOX complex; Trp-57 exhibits heterogeneous fluorescence decay with lifetimes of 7, 3.5, and 0.8 ns. Decay kinetics of Trp-158 are best fit to a nearly homogeneous decay with a lifetime of 5.5 ns in the MSOX-ATP inactivated complex. These results provide a model for the sequence of structural and dynamic changes that take place at the Trp-57 loop and the central loop (Trp-158) during several intermediate stages of catalysis.     

The sites of cleavage on Escherichia coli glutamine synthetase by dithiothreitol, Fe(III) and O2.

Native conformation of an enzyme molecule is required for the specific non-enzymatic cleavage of Escherichia coli glutamine synthetase by a metal-catalyzing oxidation system comprised of dithiothreitol, Fe(III) and O2. The cleavage reaction is greatly inhibited by the addition of Mg(II). Two major cleavage sites are identified between amino acid residues 264 and 268, and roughly between amino acid residues 31 and 34, which are located on the protein segments forming the active site of the enzyme. These results suggest that the cleavage reaction is a largely site-specific process involving active oxygen species generated at the divalent cation binding sites on glutamine synthetase.     

Spectroscopic studies of metal ion binding to a tryptophan-containing parvalbumin

The binding of Ca(II) and members of the trivalent lanthanide ion, Ln(III), series to apoparvalbumin (isotype pI = 4.75) from codfish (Gadus callarius L) results in the development of a distinctive sharp feature in the UV absorption spectrum at about 290 nm. Titration curves obtained by monitoring the spectral change in this region reveal a change in slope after the addition of 1 equiv of metal ion and no further rise after 2 equiv has been added, consistent with sequential binding to the principal EF and CD sites. Laser-induced luminescence excitation spectra of the 7F0----5D0 transition of bound Eu(III) demonstrate the quantitative binding of this ion to the principal sites and disclose the presence of a subsidiary site at pH values greater than 6. Metal ion competition experiments monitored by means of this excitation transition show that the early members of the Ln(III) ion series bind more tightly than those at the end. Tryptophan-sensitized Tb(III) luminescence reveals that this ion binds sequentially to the EF and CD sites, in that order. The intrinsic tryptophan fluorescence of apoparvalbumin is increased in a stepwise fashion as Ca(II) or Ln(III) ions bind sequentially, with the exceptions of Eu(III) and Yb(III). The binding of the latter two ions causes quenching of the protein fluorescence via an energy-transfer process which involves low-lying charge-transfer bands. The distance dependences of the tryptophan to Tb(III) and tryptophan to Eu(III) energy-transfer processes are observed to be identical, consistent with a F?rster-type mechanism in both cases.     

Time-resolved fluorescence and computational studies of adenylylated glutamine synthetase: analysis of intersubunit interactions.

Adenylylation of Tyr-397 of each subunit of Escherichia coli glutamine synthetase (GS) down-regulates enzymatic activity in vivo. The overall structure of the enzyme consists of 12 subunits arranged as two hexamers, face to face. Research reported in this paper addresses the question of whether the covalently attached adenylyl group interacts with neighboring amino acid residues to produce the regulatory phenomenon. Wild-type GS has two Trp residues (positions 57 and 158) and the adenylylation site lies within 7-8 A of the Trp-57 loop in the adjacent subunit of the same hexameric ring; Trp-158 is about 35 A from the site of adenylylation. Fluorescence lifetimes and quantum yields have been determined for two fluorophores with wild-type and mutant GS. One fluorophore is epsilon-AMP adenylylated GS (at Tyr-397), and the other fluorophore is the intrinsic protein residue Trp-57. These experiments were conducted in order to detect possible intersubunit interactions between adenylyl groups and the neighboring Trp-57 to search for a role for the Trp-57 loop in the regulation of GS. The fluorescence due to epsilon-AMP of two adenylylated enzymes, wild-type GS and the W158F mutant, exhibits heterogeneous decay kinetics; the data adequately fit to a double exponential decay model with recovered average lifetime values of 18.2 and 2.1 ns, respectively. The pre-exponential factors range from 0.66 to 0.73 for the long lifetime component, at five emission wavelengths. The W57L-epsilon-AMP enzyme yields longer average lifetime values of 19.5 and 2.4 ns, and the pre-exponential factors range from 0.82 to 0.85 for the long lifetime component. An additional residue in the Trp-57 loop, Lys-58, has been altered and the K58C mutant enzyme has been adenylylated with epsilon-AMP on Tyr-397. Lys-58 is near the ATP binding site and may represent a link by which the adenylyl group controls the activity of GS. The fluorescence of epsilon-AMP-adenylylated K58C mutant GS is best described by a triple exponential decay with average recovered lifetime values of 19.9, 4.6, and 0.58 ns, with the largest fraction being the median lifetime component. Relative quantum yields of epsilon-AMP-Tyr-397 were measured in order to determine if static quenching occurs from adenine-indole stacking in the wild-type GS. The relative quantum yield of the epsilon-AMP-adenylylated W57L mutant is larger than the wild-type protein by the amount predicted from the difference in lifetime values: thus, no static quenching is evident.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparative study of glutamine synthetase bound lanthanide(III) ions using NMR relaxation and lanthanide(III) luminescence techniques

Changes in the intrinsic fluorescence intensity of glutamine synthetase induced by lanthanide(III) ion binding demonstrate the existence of three types of sites for these ions. The sites are populated sequentially during titrations of the enzyme, and the first two have a stoichiometry of 1 per enzyme subunit. The number of water molecules coordinated to Eu(III) bound to the first site was determined by luminescence lifetime techniques to be 4.1 +/- 0.5. The hydration of Gd(III) bound to the same site was studied by magnetic field dependent water proton longitudinal relaxation rate measurements, and by water proton and deuteron relaxation measurements of one sample at single magnetic fields. The magnetic resonance techniques also yield a value of 4 for the hydration number.     

Secondary structure and functional groups of the active center of glutamine synthetase of pea chloroplasts

The circular dichroism spectra of glutamine synthetase (EC 6.3.1.2) from pea chloroplasts were recorded. Based on these spectra the percentage of alpha-helix sites, beta-structures, beta-bends and disordered sites of the polypeptide chain was calculated and was found equal to 23, 57, 1 and 23%, respectively. Data from protein photooxidation in the presence of methylene blue and the type of pH-dependence of pKm suggest that glutamate binding takes place on the imidazole ring of the histidine molecule. The inhibition of native glutamine synthetase by p-chloromercurybenzoate and the presence of free SH-groups in the enzyme molecule (approximately two SH-groups per monomer) suggest that these groups are the functional groups of the enzyme active center.     

A fluorescence investigation of the active site of Pseudomonas aeruginosa exotoxin A.

Single tryptophan mutant proteins of a catalytically active domain III recombinant protein (PE24) from Pseudomonas aeruginosa exotoxin A were prepared by site-directed mutagenesis. The binding of the dinucleotide substrate, NAD+, to the PE24 active site was studied by exploiting intrinsic tryptophan fluorescence for the wild-type, single Trp, and tryptophan-deficient mutant proteins. Various approaches were used to study the substrate binding process, including dynamic quenching, CD spectroscopy, steady-state fluorescence emission analysis, NAD+-glycohydrolase activity, NAD+ binding analysis, protein denaturation experiments, fluorescence lifetime analysis, steady-state anisotropy measurement, stopped flow fluorescence spectroscopy, and quantum yield determination. It was found that the conservative replacement of tryptophan residues with phenylalanine had little or no effect on the folded stability and enzyme activity of the PE24 protein. Dynamic quenching experiments indicated that when bound to the active site of the enzyme, the NAD+ substrate protected Trp-558 from solvent to a large extent but had no effect on the degree of solvent exposure for tryptophans 417 and 466. Also, upon substrate binding, the anisotropy of the Trp-417(W466F/W558F) protein showed the largest increase, followed by Trp-466(W417F/W558F), and there was no effect on Trp-558(W417F/W466F). Furthermore, the intrinsic tryptophan fluorescence exhibited the highest degree of substrate-induced quenching for the wild-type protein, followed in decreasing order by Trp-417(W466F/W558F), Trp-558(W417F/W466F), and Trp-466(W417F/W558F). These data provide evidence for a structural rearrangement in the enzyme domain near Trp-417 invoked by the binding of the NAD+ substrate.     

The roles of tryptophans in primer synthesis by the DNA primase of bacteriophage T7

DNA primases catalyze the synthesis of oligoribonucleotides required for the initiation of lagging strand DNA synthesis. Prokaryotic primases consist of a zinc-binding domain (ZBD) necessary for recognition of a specific template sequence and a catalytic RNA polymerase domain. Interactions of both domains with the DNA template and ribonucleotides are required for primer synthesis. Five tryptophan residues are dispersed in the primase of bacteriophage T7: Trp-42 in the ZBD and Trp-69, -97, -147, and -255 in the RNA polymerase domain. Previous studies showed that replacement of Trp-42 with alanine in the ZBD decreases primer synthesis, whereas substitution of non-aromatic residues for Trp-69 impairs both primer synthesis and delivery. However, the roles of tryptophan at position 97, 147, or 255 remain elusive. To investigate the essential roles of these residues, we replaced each tryptophan with the structurally similar tyrosine and examined the effect of this subtle alteration on primer synthesis. The substitution at position 42, 97, or 147 reduced primer synthesis, whereas substitution at position 69 or 255 did not. The functions of the tryptophans were further examined at each step of primer synthesis. Alteration of residue 42 disturbed the conformation of the ZBD and resulted in partial loss of the zinc ion, impairing binding to the ssDNA template. Replacement of Trp-97 with tyrosine reduced the binding affinity to NTP and the catalysis step. The replacement of Trp-147 with tyrosine also impaired the catalytic step. Therefore, Trp-42 is important in maintaining the conformation of the ZBD for template binding; Trp-97 contributes to NTP binding and the catalysis step; and Trp-147 maintains the catalysis step.     

Catalytic cycle of the biosynthetic reaction catalyzed by adenylylated glutamine synthetase from Escherichia coli

The covalently attached AMP moiety of adenylylated glutamine synthetase from Escherichia coli has been replaced by its fluorescent analog, 2-aza-1,N6-etheno-AMP (aza-epsilon-AMP). The modified glutamine synthetase (aza-epsilon-GS) exhibits divalent cation requirement (Mn2+, rather than Mg2+), pH profile, Vmax, and Km similar to those of naturally adenylylated glutamine synthetase. Whereas naturally adenylylated glutamine synthetase exhibits only negligible fluorescence changes upon the binding of substrates, aza-epsilon-GS exhibits large fluorescence changes. The fluorescence changes have been used by means of a stopped flow technique to reveal the involvement of five fluorometrically distinct intermediates in the catalytic cycle for the biosynthesis of glutamine catalyzed by the adenylylated glutamine synthetase. The mechanism is very similar to that previously established for the unadenylylated enzyme, using intrinsic tryptophan fluorescence. Substrates bind via a rapid equilibrium random mechanism, but the reaction proceeds in a stepwise manner. The formation of an enzyme-bound intermediate (probably gamma-glutamyl phosphate + ADP) from ATP and L-glutamate is the rate-limiting step, with the subsequent reaction of the enzyme-bound intermediate occurring very rapidly. The success in elucidating this complex mechanism is due largely to the vastly different amplitudes of the fluorescence changes at the two excitation maxima (300 nm and 360 nm) of the aza-epsilon-AMP moiety which accompany the formation of the various intermediates.     

Kinetic studies show that Ca2+ and Tb3+ have different binding preferences toward the four Ca2+-binding sites of calmodulin

The stepwise addition of Tb3+ to calmodulin yields a large tyrosine-sensitized Tb3+ luminescence enhancement as the third and fourth ions bind to the protein [Wang, C.-L. A., Aquaron, R. R., Leavis, P. C., & Gergely, J. (1982) Eur. J. Biochem. 124, 7-12]. Since the only tyrosine residues in calmodulin are located within binding sites III and IV, these results suggest that Tb3+ binds first to sites I and II. Recent NMR studies have provided evidence that Ca2+, on the other hand, binds preferentially to sites III and IV. Kinetic studies using a stopped-flow apparatus also show that the preferential binding of Ca2+ and lanthanide ions is different. Upon rapid mixing of 2Ca-calmodulin with two Tb3+ ions, there was a small and rapid tyrosine fluorescence change, but no Tb3+ luminescence was observed, indicating that Tb3+ binds to sites I and II but not sites III and IV. When two Tb3+ ions are mixed with 2Dy-calmodulin, Tb3+ luminescence rises rapidly as Tb3+ binds to the empty sites III and IV, followed by a more gradual decrease (k = 0.4 s-1 as the ions redistribute themselves over the four sites. These results indicate that (i) both Tb3+ and Dy3+ prefer binding to sites I and II of calmodulin and (ii) the binding of Tb3+ to calmodulin is not impeded by the presence of two Ca2+ ions initially bound to the protein. Thus, the Ca2+ and lanthanide ions must exhibit opposite preferences for the four sites of calmodulin: sites III and IV are the high-affinity sites for Ca2+, whereas Tb3+ and Dy3+ prefer sites I and II.     

Investigating the effects of posttranslational adenylylation on the metal binding sites of Escherichia coli glutamine synthetase using lanthanide luminescence spectroscopy.

Lanthanide luminescence was used to examine the effects of posttranslational adenylylation on the metal binding sites of Escherichia coli glutamine synthetase (GS). These studies revealed the presence of two lanthanide ion binding sites of GS of either adenylylation extrema. Individual emission decay lifetimes were obtained in both H2O and D2O solvent systems, allowing for the determination of the number of water molecules coordinated to each bound Eu3+. The results indicate that there are 4.3 +/- 0.5 and 4.6 +/- 0.5 water molecules coordinated to Eu3+ bound to the n1 site of unadenylylated enzyme, GS0, and fully adenylylated enzyme, GS12, respectively, and that there are 2.6 +/- 0.5 water molecules coordinated to Eu3+ at site n2 for both GS0 and GS12. Energy transfer measurements between the lanthanide donor-acceptor pair Eu3+ and Nd3+, obtained an intermetal distance measurement of 12.1 +/- 1.5 A. Distances between a Tb3+ ion at site n2 and tryptophan residues were also performed with the use of single-tryptophan mutant forms of E. coli GS. The dissociation constant for lanthanide ion binding to site n1 was observed to decrease from Kd = 0.35 +/- 0.09 microM for GS0 to Kd = 0.06 +/- 0.02 microM for GS12. The dissociation constant for lanthanide ion binding to site n2 remained unchanged as a function of adenylylation state; Kd = 3.8 +/- 0.9 microM and Kd = 2.6 +/- 0.7 microM for GS0 and GS12, respectively. Competition experiments indicate that Mn2+ affinity at site n1 decreases as a function of increasing adenylylation state, from Kd = 0.05 +/- 0.02 microM for GS0 to Kd = 0.35 +/- 0.09 microM for GS12. Mn2+ affinity at site n2 remains unchanged (Kd = 5.3 +/- 1.3 microM for GS0 and Kd = 4.0 +/- 1.0 microM for GS12). The observed divalent metal ion affinities, which are affected by the adenylylation state, agrees with other steady-state substrate experiments (Abell LM, Villafranca JJ, 1991, Biochemistry 30:1413-1418), supporting the hypothesis that adenylylation regulates GS by altering substrate and metal ion affinities.     

The binding of terbium ions to gelsolin reveals two classes of metal ion binding sites.

Spectroscopically active terbium ions have been used to probe the Ca2+ ion-binding sites on human plasma gelsolin. The luminescence of Tb3+ ions bound to gelsolin is markedly enhanced when excited indirectly at 295 nm due to F?rster type dipole-dipole energy transfer from neighboring tryptophan residues. Titration of this luminescence with increasing concentrations of Tb3+ ions was saturable although the shape of this titration curve was complex indicating the involvement of multiple classes of sites. Luminescence lifetime measurements (obtained by indirect excitation at 295 nm) demonstrate the presence of two classes of sites characterized by a major lifetime of 1.0-1.1 ms and a minor lifetime of 0.7-0.8 ms. However, while the amplitude of the minor lifetime showed a hyperbolic dependence on the Tb3+ ion concentration, the amplitude of the major lifetime showed a strongly sigmoidal dependence. Different classes of Tb3+ ion binding sites can also be distinguished by the different Ca2+ ion concentrations needed to displace Tb3+ ions from these sites on gelsolin. It is proposed that the occupancy of one class of Tb3+ ion binding sites on gelsolin causes a conformational change in gelsolin which then allows a second class of cryptic Tb3+ ion binding sites to be expressed. The implications of these results in terms of the binding of Ca2+ ions to gelsolin and the regulation of the activities of gelsolin by calcium are discussed.     

Need for Aromatic Residue at Position 115 for Proteolytic Activity Found by Site-directed Mutagenesis of Tryptophan 115 in Thermolysin

In thermolysin, tryptophan 115 seems to be at the S2 subsite. Trp-115 was replaced with tyrosine, phenylalanine, leucine, and valine during site-directed mutagenesis in order to evaluate the role of Trp-115 in the proteolytic activity of thermolysin. The mutant enzymes with Tyr-115 or Phe-115 had as much proteolytic activity as the wild-type enzyme, but the other two mutant enzymes had no activity. We found earlier that the substitution of Trp-115 with alanine, glutamic acid, lysine, and glutamine causes the enzyme to lose all activity, so an aromatic amino acid at position 115 seems to be essential for thermolysin.     

Lanthanide spectroscopic studies of the dinuclear and Mg(II)-dependent PvuII restriction endonuclease

Type II restriction enzymes are homodimeric systems that bind four to eight base pair palindromic recognition sequences of DNA and catalyze metal ion-dependent phosphodiester cleavage. While Mg(II) is required for cleavage in these enzymes, in some systems Ca(II) promotes avid substrate binding and sequence discrimination. These properties make them useful model systems for understanding the roles of alkaline earth metal ions in nucleic acid processing. We have previously shown that two Ca(II) ions stimulate DNA binding by PvuII endonuclease and that the trivalent lanthanide ions Tb(III) and Eu(III) support subnanomolar DNA binding in this system. Here we capitalize on this behavior, employing a unique combination of luminescence spectroscopy and DNA binding assays to characterize Ln(III) binding behavior by this enzyme. Upon excitation of tyrosine residues, the emissions of both Tb(III) and Eu(III) are enhanced severalfold. This enhancement is reduced by the addition of a large excess of Ca(II), indicating that these ions bind in the active site. Poor enhancements and affinities in the presence of the active site variant E68A indicate that Glu68 is an important Ln(III) ligand, similar to that observed with Ca(II), Mg(II), and Mn(II). At low micromolar Eu(III) concentrations in the presence of enzyme (10-20 microM), Eu(III) excitation (7)F(0) --> (5)D(0) spectra yield one dominant peak at 579.2 nm. A second, smaller peak at 579.4 nm is apparent at high Eu(III) concentrations (150 microM). Titration data for both Tb(III) and Eu(III) fit well to a two-site model featuring a strong site (K(d) = 1-3 microM) and a much weaker site (K(d) approximately 100-200 microM). Experiments with the E68A variant indicate that the Glu68 side chain is not required for the binding of this second Ln(III) equivalent; however, the dramatic increase in DNA binding affinity around 100 microM Ln(III) for the wild-type enzyme and metal-enhanced substrate affinity for E68A are consistent with functional relevance for this weaker site. This discrimination of sites should make it possible to use lanthanide substitution and lanthanide spectroscopy to probe individual metal ion binding sites, thus adding an important tool to the study of restriction enzyme structure and function.