H(+)-ATPase gamma subunit of Escherichia coli. Role of the conserved carboxyl-terminal region

Cloned uncG genes (wild-type or in vitro mutagenized) for the Escherichia coli gamma subunit were introduced into the uncG mutant Gln-14----end), and the functions of the mutant subunits were studied. The F1's with Ala-283----end and Thr-277----end mutant gamma subunits had 63 and 14% of the wild-type ATPase activity, respectively, and mutants with these subunits showed reduced growth by oxidative phosphorylation, indicating that the 10 residues at the carboxyl terminus (286th residue) are important, but dispensable, for catalysis. On the other hand, F1 with a Gln-269----end gamma subunit was inactive. Replacement of conserved residues (Gln-269, Thr-273, or Glu-275) between Gln-269 and Leu-276 gave enzymes with significantly reduced ATPase activity (2-41% of that of the wild-type) and lower ATP-driven proton conduction. Thus these residues are required for the normal catalytic activity of F1, although they are not absolutely essential. Membranes with amino acid replacements (Thr-277----end, Gln-269----Leu, or Glu-275----Lys) and the frameshift mutation (downstream of Thr-277) had about 15% of the wild-type ATPase activity, but showed different degrees of ATP-dependent H+ translocation and growth yield by oxidative phosphorylation, suggesting that the gamma subunit, especially its carboxyl-terminal region, functions in coupling between catalysis and H+ translocation.     

Role of the carboxyl terminal region of H(+)-ATPase (F0F1) a subunit from Escherichia coli.

The effects of amino acid substitutions in the carboxyl terminal region of the H(+)-ATPase a subunit (271 amino acid residues) of Escherichia coli were studied using a defined expression system for uncB genes coded by recombinant plasmids. The a subunits with the mutations, Tyr-263----end, Trp-231----end, Glu-219----Gln, and Arg-210----Lys (or Gln) were fully defective in ATP-dependent proton translocation, and those with Gln-252----Glu (or Leu), His-245----Glu, Pro-230----Leu, and Glu-219----His were partially defective. On the other hand, the phenotypes of the Glu-269----end, Ser-265----Ala (or end), and Tyr-263----Phe mutants were essentially similar to that of the wild-type. These results suggested that seven amino acid residues between Ser-265 and the carboxyl terminus were not required for the functional proton pathway but that all the other residues except Arg-210, Glu-219, and His-245 were required for maintaining the correct conformation of the proton pathway. The results were consistent with a report that Arg-210 is directly involved in proton translocation.     

Intrinsic membrane sector (Fo) of H+-ATPase (FoF1) from Escherichia coli. Mutations in the alpha subunit give Fo with impaired proton translocation and F1 binding

Mutant alleles for the alpha subunit of H+-translocating ATPase (FoF1) were cloned from Escherichia coli strains isolated in this laboratory. Determination of their DNA sequence revealed four nonsense mutations (KF3 and KF9, Gln-20----end; KF24, Trp-111----end; KF2, Trp-231----end; KF70, Gln-252----end) and one missense mutation (KF45, Pro-143----Ser). The membranes of all the mutants except strain KF9 (KF3) had 50-70% of ATPase activities of the wild-type. Unlike the F1-ATPase of the wild-type, those of the mutants were insensitive to dicyclohexylcarbodiimide and were easier to solubilize from membranes. As membranes of strain KF24 had F1-ATPase activity, these results suggest that at least a part of the F1-binding sites could be formed without a region between residues 111 and the carboxyl terminus of the alpha subunit. However, normal interactions between Fo and F1 require regions between residues 252 and 271 (carboxyl terminus) and in the vicinity of Pro-143. Membranes of strain KF45 were capable of forming a low ATP-driven H+ gradient, whereas other membranes were not. The possibility that the region between residues 252 and 271 is involved in H+ translocation is discussed.     

Mutational replacements of conserved amino acid residues in the beta subunit resulted in defective assembly of H+-translocating ATPase (F0F1) in Escherichia coli

Mutant genes for the beta subunit of H+-translocating ATPase (F0F1) were cloned from Escherichia coli strains isolated in this laboratory. Determination of their nucleotide sequence revealed four missense mutations (strain KF39, Glu-41----Lys; strain KF16 and KF42, Glu-185----Lys; strain KF48, Gly-223----Asp; KF26 and 4 other strains, Ser-292----Phe). Two nonsense mutants (strain KF40, Gln-361----end; strain KF20, Gln-397----end) were also identified. Glu-41, Glu-185, and Ser-292 are conserved in the amino acid sequences of the beta subunits so far studied, and Gly-223, Gln-361, and Gln-397 are conserved in beta subunits from bacteria and mitochondria, but not in those from chloroplasts. The amounts of F1 subunits in the membranes of these strains were studied by immunochemical assay and two-dimensional gel electrophoresis. In the mutants studied, the amounts of alpha and beta subunits in the membranes were 69-21 and 46-2%, respectively, of the amounts in wild-type membranes, the amount depending on the strain. No delta and epsilon subunits were detected in membranes of a missense mutant KF16, although reduced amounts of alpha and beta subunits could be detected, suggesting that the F1 portion may not be connected to F0 through the delta and epsilon subunits. The altered residues in missense mutants or missing domains in nonsense mutants may be important for the subunit-subunit interactions or assembly of the entire complex. Genetic experiments on introduction of suppressor tRNA into strains KF40 and KF20 suggested that F1 could be active even when residue 361 or 397 was replaced by a Ser, Leu, or Tyr residue.     

Escherichia coli H(+)-ATPase: role of the delta subunit in binding Fl to the Fo sector.

The roles of the Escherichia coli H(+)-ATPase (FoFl) delta subunit (177 amino acid residues) was studied by analyzing mutants. The membranes of nonsense (Gln-23----end, Gln-29----end, Gln-74----end) and missense (Gly-150----Asp) mutants had very low ATPase activities, indicating that the delta subunit is essential for the binding of the Fl portion to Fo. The Gln-176----end mutant had essentially the same membrane-bound activity as the wild type, whereas in the Val-174----end mutant most of the ATPase activity was in the cytoplasm. Thus Val-174 (and possibly Leu-175 also) was essential for maintaining the structure of the subunit, whereas the two carboxyl terminal residues Gln-176 and Ser-177 were dispensable. Substitutions were introduced at various residues (Thr-11, Glu-26, Asp-30, Glu-42, Glu-82, Arg-85, Asp-144, Arg-154, Asp-161, Ser-163), including apparently conserved hydrophilic ones. The resulting mutants had essentially the same phenotypes as the wild type, indicating that these residues do not have any significant functional role(s). Analysis of mutations (Gly-150----Asp, Pro, or Ala) indicated that Gly-150 itself was not essential, but that the mutations might affect the structure of the subunit. These results suggest that the overall structure of the delta subunit is necessary, but that individual residues may not have strict functional roles.     

Fo portion of Escherichia coli H+-ATPase. Carboxyl-terminal region of the b subunit is essential for assembly of functional Fo

Six chromosomal uncF mutants of Escherichia coli defective in the b subunit of H+-ATPase (156 amino acid residues) were identified (KF92, Met-1----Val; KF164, Gln-64----end; KF61 and KF144, Gln-104----end; KF138, Gln-106----end; and KF79, Gln-123----end). The membranes of all these mutants had low ATPase activities (less than 5% of that of the wild type), and no functional H+ pathway, although the truncated b subunits were integrated into these membranes. These findings suggest that about 30 carboxyl-terminal amino acid residues of the b subunit are essential for formation of the F1-binding site and H+ pathway. For examination of the role(s) of the carboxyl-terminal region(s) or residue(s) of the b subunit, recombinant plasmids carrying truncated uncF genes of various lengths were constructed by in vitro muta-genesis and introduced into a recA1 derivative of strain KF92 (Met-1----Val). Analyses of the membranes from the resulting strains demonstrated that almost the entire carboxyl-terminal region of the b subunit is necessary for formation of functional Fo, since loss of the carboxyl-terminal residue resulted in significant reduction of both F1 binding and H+ translocation, and loss of two or more residues abolished both activities completely.     

Stability-increasing mutants of glucose dehydrogenase from Bacillus megaterium IWG3

A glucose dehydrogenase gene was isolated from Bacillus megaterium IWG3, and its nucleotide sequence was identified. The amino acid sequence of the enzyme deduced from the nucleotide sequence is very similar to the protein sequence of the enzyme from B. megaterium M1286 reported by Jany et al. (Jany, K.-D., Ulmer, W., Froschle, M., and Pfleiderer, G. (1984) FEBS Lett. 165, 6-10). The isolated gene was mutagenized with hydrazine, formic acid, or sodium nitrite, and 12 clones (H35, H39, F18, F20, F191, F192, N1, N13, N14, N28, N71, and N72) containing mutant genes for thermostable glucose dehydrogenase were obtained. The nucleotide sequences of the 12 genes show that they include 8 kinds of mutants having the following amino acid substitutions: H35 and H39, Glu-96 to Gly; F18 and F191, Glu-96 to Ala; F20, Gln-252 to Leu; F192, Gln-252 to Leu and Ala-258 to Gly; N1, Glu-96 to Lys and Val-183 to Ile; N13 and N14, Glu-96 to Lys, Val-112 to Ala, Glu-133 to Lys, and Tyr-217 to His; N28, Glu-96 to Lys, Asp-108 to Asn, Pro-194 to Gln, and Glu-210 to Lys; and N71 and N72, Tyr-253 to Cys. These mutant enzymes have higher stability at 60 degrees C than the wild-type enzyme. The results of this study indicate that the tetrameric structure of glucose dehydrogenase is stabilized by several kinds of mutation, and at least one of the following amino acid substitutions stabilizes the enzyme: Glu-96 to Gly, Glu-96 to Ala, Gln-252 to Leu, and Tyr-253 to Cys.     

Deconstruction of the catalytic array within the amidotransferase subunit of carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase from Escherichia coli catalyzes the formation of carbamoyl phosphate from bicarbonate, glutamine, and two molecules of ATP. The enzyme consists of a large synthetase subunit, and a small amidotransferase subunit, which belongs to the Triad family of glutamine amidotransferases. Previous studies have established that the reaction mechanism of the small subunit proceeds through the formation of a gamma-glutamyl thioester with Cys-269. The roles in the hydrolysis of glutamine played by the conserved residues, Glu-355, Ser-47, Lys-202, and Gln-273, were determined by mutagenesis. In the X-ray crystal structure of the H353N mutant, Ser-47 and Gln-273 interact with the gamma-glutamyl thioester intermediate [Thoden, J. B., Miran, S. G., Phillips, J. C., Howard, A. J., Raushel, F. M., and Holden, H. M. (1998) Biochemistry 37, 8825-8831]. The mutants E355D and E355A have elevated values of K(m) for glutamine, but the overall carbamoyl phosphate synthesis reaction is unperturbed. E355Q does not significantly affect the bicarbonate-dependent ATPase or glutaminase partial reactions. However, this mutation almost completely uncouples the two partial reactions such that no carbamoyl phosphate is produced. The partial recovery of carbamoyl phosphate synthesis activity in the double mutant E355Q/K202M argues that the loss of activity in E355Q is at least partly due to additional interactions between Gln-355 and Lys-202 in E355Q. The mutants S47A and Q273A have elevated K(m) values for glutamine while the V(max) values are comparable to that of the wild-type enzyme. It is concluded that contrary to the original proposal for the catalytic triad, Glu-355 is not an essential residue for catalysis. The results are consistent with Ser-47 and Gln-273 playing significant roles in the binding of glutamine.     

Pairwise interactions between neuronal alpha7 acetylcholine receptors and alpha-conotoxin ImI.

The present work uses alpha-conotoxin ImI (CTx ImI) to probe the neurotransmitter binding site of neuronal alpha7 acetylcholine receptors. We identify key residues in alpha7 that contribute to CTx ImI affinity, and use mutant cycles analysis to identify pairs of residues that stabilize the receptor-conotoxin complex. We first mutated key residues in the seven known loops of alpha7 that converge at the subunit interface to form the ligand binding site. The mutant subunits were expressed in 293 HEK cells, and CTx ImI binding was measured by competition against the initial rate of 125I-alpha-bungarotoxin binding. The results reveal a predominant contribution by Tyr-195 in alpha7, accompanied by smaller contributions by Thr-77, Tyr-93, Asn-111, Gln-117, and Trp-149. Based upon our previous identification of bioactive residues in CTx ImI, we measured binding of receptor and toxin mutations and analyzed the results using thermodynamic mutant cycles. The results reveal a single dominant interaction between Arg-7 of CTx ImI and Tyr-195 of alpha7 that anchors the toxin to the binding site. We also find multiple weak interactions between Asp-5 of CTx ImI and Trp-149, Tyr-151, and Gly-153 of alpha7, and between Trp-10 of CTx ImI and Thr-77 and Asn-111 of alpha7. The overall results establish the orientation of CTx ImI as it bridges the subunit interface and demonstrate close approach of residues on opposing faces of the alpha7 binding site.     

Differential scanning calorimetric studies of E. coli aspartate transcarbamylase. III. The denaturational thermodynamics of the holoenzyme with single-site mutations in the catalytic chain

Aspartate transcarbamylase (EC 2.1.3.2) from E. coli is a multimeric enzyme consisting of two catalytic subunits and three regulatory subunits whose activity is regulated by subunit interactions. Differential scanning calorimetric (DSC) scans of the wild-type enzyme consist of two peaks, each comprised of at least two components, corresponding to denaturation of the catalytic and regulatory subunits within the intact holoenzyme (Vickers et al., J. Biol. Chem. 253 (1978) 8493; Edge et al., Biochemistry 27 (1988) 8081). We have examined the effects of nine single-site mutations in the catalytic chains. Three of the mutations (Asp-100-Gly, Glu-86-Gln, and Arg-269-Gly) are at sites at the C1: C2 interface between c chains within the catalytic subunit. These mutations disrupt salt linkages present in both the T and R states of the molecule (Honzatko et al., J. Mol. Biol. 160 (1982) 219; Krause et al., J. Mol. Biol. 193 (1987) 527). The remainder (Lys-164-Ile, Tyr-165-Phe, Glu-239-Gln, Glu-239-Ala, Tyr-240-Phe and Asp-271-Ser) are at the C1: C4 interface between catalytic subunits and are involved in interactions which stabilize either the T or R state. DSC scans of all of the mutants except Asp-100-Gly and Arg-269-Gly consisted of two peaks. At intermediate concentrations, Asp-100-Gly and Arg-269-Gly had only a single peak near the Tm of the regulatory subunit transition in the holoenzyme, although their denaturational profiles were more complex at high and low protein concentrations. The catalytic subunits of Glu-86-Gln, Lys-164-Ile and Asp-271-Ser appear to be significantly destabilized relative to wild-type protein while Tyr-165-Phe and Tyr-240-Phe appear to be stabilized. Values of delta delta G degree cr, the difference between the subunit interaction energy of wild-type and mutant proteins, evaluated as suggested by Brandts et al. (Biochemistry 28 (1989) 8588) range from -3.7 kcal mol-1 for Glu-86-Gln to 2.4 kcal mol-1 for Tyr-165-Phe.     

Examination of subunit interactions at the active site of ribulose 1,5-bisphosphate carboxylase/oxygenase fromRhodospirillum rubrum by hybridization of site-directed mutants

The two active sites of homodimeric ribulose bisphosphate carboxylase/oxygenase fromRhodospirillum rubrum are constituted by interacting domains of adjacent subunits, in which residues from each are required for catalytic activity. Active-site residues include Lys-166 of one domain and Glu-48 of the interacting domain from the adjacent subunit. Whereas all substitutions for Lys-166, introduced by site-directed mutagenesis, abolished catalytic activity, only a negatively charged residue (e.g., aspartic acid) resulted in the disruption of the subunit interactions (Lee et al., 1987). This disruption could result from improper folding of the individual polypeptide chains or to more localized effects (e.g., charge-charge repulsion due to proximal negative charges of Asp-166 and Glu-48 of adjacent domains or conformational changes restricted to a single domain). To address these questions, we have examined the ability of the Asp-166 mutant subunit to associate with a mutant subunit in which the negatively charged Glu-48 has been replaced by the neutral glutaminyl residue. Coexpression inEscherichia coli of the genes for both mutant subunits results in formation of a catalytically active hybrid, despite the absence of activity when either gene is expressed individually. Isolation and characterization of the hybrid show that it is composed of one Asp-166 subunit and one Gln-48 subunit, presumably with only one functional active site per dimeric molecule. This association of dissimilar subunits shows that introduction of a negative charge at position 166 does not lead to overall distortion of subunit conformation. In contrast to the wild-type enzyme, the hybrid dissociates spontaneously at low protein concentration but is stablized by elevated ionic strengths or by glycerol.     

Sugar recognition by the lactose permease of Escherichia coli

Biochemical, luminescence and mass spectroscopy approaches indicate that Trp-151 (helix V) plays an important role in hydrophobic stacking with the galactopyranosyl ring of substrate and that Glu-269 (helix VIII) is essential for substrate affinity and specificity. The x-ray structure of the lactose permease (LacY) with bound substrate is consistent with these conclusions and suggests that a possible H-bond between Glu-269 and Trp-151 may play a critical role in the architecture of the binding site. We have now probed this relationship by exploiting the intrinsic luminescence of a single Trp-151 LacY with various replacements for Glu-269. Mutations at position 269 dramatically alter the environment of Trp-151 in a manner that correlates with binding affinity of LacY substrates. Furthermore, chemical modification of Trp-151 with N-bromosuccinimide indicates that Glu-269 forms an H-bond with the indole N. It is concluded that 1) an H-bond between the indole N and Glu-269 optimizes the formation of the substrate binding site in the inward facing conformation of LacY, and 2) the disposition of the residues implicated in sugar binding in different conformers suggests that sugar binding by LacY involves induced fit.     

Kinetic consequences of site-specific mutation of Glu-239----Gln in E. coli aspartate transcarbamylase: comparison with catalytic subunits and Phe-240 mutant enzyme

The kinetic characteristics of E. coli aspartate transcarbamylase, altered by site-specific mutagenesis of Glu-239----Gln, have been determined by equilibrium isotope-exchange kinetics and compared to the wild-type system. In wild-type enzyme, residue Glu-239 helps to stabilize the T-state structure by multiple bonding interactions with Tyr-165 and Lys-164 across the c1-c4 subunit interface; upon conversion to the R-state, these bonds are re-formed within c-chains. Catalysis of both the [14C]Asp in equilibrium C-Asp and [32P]ATP in equilibrium Pi exchanges by mutant enzyme occurs at rates comparable to those for wild-type enzyme. Saturation with different reactant/product pairs produced kinetic patterns consistent with strongly preferred order binding of carbamyl-P prior to Asp and carbamyl-Asp release before Pi. The kinetics for the Gln-239 mutant enzyme resemble those observed for catalytic subunits (c3), namely a R-state enzyme (Hill coefficient nH = 1.0) and Km (Asp) approximately equal to 6 mM. The Glu-239----Gln mutation appears to destablize both the T- and R-states, whereas the Tyr-240----Phe mutation destablizes only the T-state.     

Activity and spectroscopic properties of bacterial D-amino acid transaminase after multiple site-directed mutagenesis of a single tryptophan residue

One of the three tryptophan residues per subunit of thermostable D-amino acid transaminase, Trp-139, is close to the active-site Lys-145 in the sequence of the protein. This tryptophan has been changed to several other types of residues by site-directed mutagenesis. The only mutant protein that was sufficiently active and stable for study had Phe substituted for Trp (W139F). The spectroscopic properties of this mutant enzyme differed from those of the wild-type transaminase. For example, denatured W139F showed the expected decrease in fluorescence emission intensity at 350 nm due to the deletion of one Trp residue, but the fluorescence emission of the wild-type and W139F enzymes in the native state did not differ in intensity. This result suggests that the fluorescence of Trp-139 in the native, wild-type enzyme is not manifested perhaps due to its proximity to the coenzyme, pyridoxal phosphate. Results of energy-transfer studies at several wavelengths could also be interpreted as due to the proximity of Trp-139 and the coenzyme. Circular dichroism studies indicated that the negative Cotton effect at 420 nm due to the coenzyme was still present in W139F. However, the 280-nm optically active band present in the wild-type enzyme was greatly diminished in W139F. The mutant protein with Asp at position 139 (W139D) could not be isolated presumably because it was degraded. The other mutant enzymes, W139P, W139A, and W139H, were isolated with partial activities (15-35%) that were slowly lost upon storage at 4 degrees C. Overall, these results indicate the importance of Trp-139 in the thermostable D-amino acid transaminase.     

E. coli F1-ATPase: site-directed mutagenesis of the beta-subunit

Residues beta Glu-181 and beta Glu-192 of E. coli F1-ATPase (the DCCD-reactive residues) were mutated to Gln. Purified beta Gln-181 F1 showed 7-fold impairment of 'unisite' Pi formation from ATP and a large decrease in affinity for ATP. Thus the beta-181 carboxyl group in normal F1 significantly contributes to catalytic site properties. Also, positive catalytic site cooperativity was attenuated from 5 X 10(4)- to 548-fold in beta Gln-181 F1. In contrast, purified beta Gln-192 F1 showed only 6-fold reduction in 'multisite' ATPase activity. Residues beta Gly-149 and beta Gly-154 were mutated to Ile singly and in combination. These mutations, affecting residues which are strongly conserved in nucleotide-binding proteins, were chosen to hinder conformational motion in a putative 'flexible loop' in beta-subunit. Impairment of purified F1-ATPase ranged from 5 to 61%, with the double mutant F1 less impaired than either single mutant. F1 preparations containing beta Ile-154 showed 2-fold activation after release from membranes, suggesting association with F0 restrained turnover on F1 in these mutants.     

Temperature-sensitive Escherichia coli mutant with an altered initiation codon of the uncG gene for the H+-ATPase gamma subunit.

A mutant of Escherichia coli showing temperature-sensitive growth on succinate was isolated, and its mutation in the initiation codon (ATG to ATA) of the uncG gene (coding for the gamma subunit of H+-ATPase F0F1) was identified. This strain could grow on succinate as the sole carbon source at 25 and 30 degrees C, but not at 37 or 42 degrees C. When this strain was grown at 25 degrees C on succinate or glycerol, its membranes had about 15% of the ATPase activity of wild-type membranes, whereas when it was grown at 42 degrees C, its membranes had about 2% of the wild-type ATPase activity. Membranes of the mutant grown at 25 or 42 degrees C could bind F1 functionally, resulting in about 40% of the specific activity of wild-type membranes. The gamma subunit was identified in an EDTA extract of membranes of the mutant grown at 25 degrees C, but was barely detectable in the same amount of extract from the mutant grown at 42 degrees C. These results indicate that initiation of protein synthesis from the AUA codon is temperature sensitive and that the gamma subunit is essential for assembly of F1 in vivo as shown by in vitro reconstitution experiments (S. D. Dunn and M. Futai, J. Biol. Chem. 255:113-118, 1980).     

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)     

Thermal stabilities of mutant Escherichia coli tryptophan synthase alpha subunits.

Random chemical mutagenesis, in vitro, of the 5' portion of the Escherichia coli trpA gene has yielded 66 mutant alpha subunits containing single amino acid substitutions at 49 different residue sites within the first 121 residues of the protein; this portion of the alpha subunit contains four of the eight alpha helices and three of the eight beta strands in the protein. Sixty-two of the subunits were examined for their heat stabilities by sensitivity to enzymatic inactivation (52 degrees C for 20 min) in crude extracts and by differential scanning calorimetry (DSC) with 29 purified proteins. The enzymatic activities of mutant alpha subunits that contained amino acid substitutions within the alpha and beta secondary structures were more heat labile than the wild-type alpha subunit. Alterations only in three regions, at or immediately C-terminal to the first three beta strands, were stability neutral or stability enhancing with respect to enzymatic inactivation. Enzymatic thermal inactivation appears to be correlated with the relative accessibility of the substituted residues; stability-neutral mutations are found at accessible residual sites, stability-enhancing mutations at buried sites. DSC analyses showed a similar pattern of stabilization/destabilization as indicated by inactivation studies. Tm differences from the wild-type alpha subunit varied +/- 7.6 degrees C. Eighteen mutant proteins containing alterations in helical and sheet structures had Tm's significantly lower (-1.6 to -7.5 degrees C) than the wild-type Tm (59.5 degrees C). In contrast, 6 mutant alpha subunits with alterations in the regions following beta strands 1 and 3 had increased Tm's (+1.4 to +7.6 degrees C). Because of incomplete thermal reversibilities for many of the mutant alpha subunits, most likely due to identifiable aggregated forms in the unfolded state, reliable differences in thermodynamic stability parameters are not possible. The availability of this group of mutant alpha subunits which clearly contain structural alterations should prove useful in defining the roles of certain residues or sequences in the unfolding/folding pathway for this protein when examined by urea/guaninidine denaturation kinetic analysis.     

Two invariant tryptophans on the alpha1 subunit define domains necessary for GABA(A) receptor assembly.

Two invariant tryptophan residues on the N-terminal extracellular region of the rat alpha1 subunit, Trp-69 and Trp-94, are critical for the assembly of the GABA(A) (gamma-aminobutyric acid, type A) receptor into a pentamer. These tryptophans are common not only to all GABA(A) receptor subunits, but also to all ligand-gated ion channel subunits. Converting each Trp residue to Phe and Gly by site-directed mutagenesis allowed us to study the role of these invariant tryptophan residues. Mutant alpha1 subunits, coexpressed with beta2 subunits in baculovirus-infected Sf9 cells, displayed high affinity binding to [(3)H]muscimol, a GABA site ligand, but no binding to [(35)S]t-butyl bicyclophosphorothionate, a ligand for the receptor-associated ion channel. Neither [(3)H]muscimol binding to intact cells nor immunostaining of nonpermeabilized cells gave evidence of surface expression of the receptor. When expressed with beta2 and gamma2 polypeptides, the mutant alpha1 polypeptides did not form [(3)H]flunitrazepam binding sites though wild-type alpha1 polypeptides did. The distribution of the mutant receptors on sucrose gradients suggests that the effects on ligand binding result from the inability of the mutant alpha1 subunits to form pentamers. We conclude that Trp-69 and Trp-94 participate in the formation of the interface between alpha and beta subunits, but not of the GABA binding site.     

Atomic level characterization of the nonproton ligand-sensing domain of ASIC3 channels

Acid-sensing ion channels (ASICs) are known to be primarily activated by extracellular protons. Recently, we characterized a novel nonproton ligand (2-guanidine-4-methylquinazoline, GMQ), which activates the ASIC3 channel subtype at neutral pH. Using an interactive computational-experimental approach, here we extend our investigation to delineate the architecture of the GMQ-sensing domain in the ASIC3 channels. We first established a GMQ binding mode and revealed that residues Glu-423, Glu-79, Leu-77, Arg-376, Gln-271, and Gln-269 play key roles in forming the GMQ-sensing domain. We then verified the GMQ binding mode using ab initio calculation and mutagenesis and demonstrated the critical role of the above GMQ-binding residues in the interplay among GMQ, proton, and Ca(2+) in regulating the function of ASIC3. Additionally, we showed that the same residues involved in coordinating GMQ responses are also critical for activation of the ASIC3(E79C) mutant by thiol-reactive compound DTNB. Thus, a range of complementary techniques provide independent evidence for the structural details of the GMQ-sensing domain at atomic level, laying the foundation for further investigations of endogenous nonproton ligands and gating mechanisms of the ASIC3 channels.