The carbonyl group of glutamic acid-795 is essential for gastric H+,K+-ATPase activity

To study the role of Glu795offresent in the fifth transmembrane domain of the alpha-subunit of gastric H+,K+-ATPase, several mutants were generated and expressed in Sf9 insect cells. The E795Q mutant had rather similar properties as the wild-type enzyme. The apparent affinity for K+ in both the ATPase reaction and the dephosphorylation of the phosphorylated intermediate was even slightly enhanced. This indicates that the carbonyl group of Glu795 is sufficient for enzymatic activity. This carbonyl group, however, has to be at a particular position with respect to the other liganding groups, since the E795D and E795N mutants showed a strongly reduced ATPase activity, a lowered apparent K+ affinity, and a decreased steady-state phosphorylation level. In the absence of a carbonyl residue at position 795, the K+ sensitivity was either strongly decreased (E795A) or completely absent (E795L). The mutant E795L, however, showed a SCH 28080 sensitive ATPase activity in the absence of K+, as well as an enhanced spontaneous dephosphorylation rate, that could not be further enhanced by K+, suggesting that this mutant mimicks the filled K+ binding pocket. The results indicate that the Glu795 residue is involved in K+-stimulated ATPase activity and K+-induced dephosphorylation of the phosphorylated intermediate. Glu795 might also be involved in H+ binding during the phosphorylation step, since the mutants E795N, E795D, and E795A showed a decrease in the phosphorylation rate as well as in the apparent ATP affinity in the phosphorylation reaction. This indicates that Glu795 is not only involved in K+ but might also play a role in H+ binding.     

Phosphorylated and dephosphorylated structures of pig heart, GTP-specific succinyl-CoA synthetase

Succinyl-CoA synthetase (SCS) catalyzes the reversible phosphorylation/dephosphorylation reaction:???rm succinyl ?hbox ?-?CoA+NDP+P_i?leftrightarrow succinate+CoA+NTP??where N denotes adenosine or guanosine. In the course of the reaction, an essential histidine residue is transiently phosphorylated. We have crystallized and solved the structure of the GTP-specific isoform of SCS from pig heart (EC 6.2.1.4) in both the dephosphorylated and phosphorylated forms. The structures were refined to 2.1 A resolution. In the dephosphorylated structure, the enzyme is stabilized via coordination of a phosphate ion by the active-site histidine residue and the two "power" helices, one contributed by each subunit of the alphabeta-dimer. Small changes in the conformations of residues at the amino terminus of the power helix contributed by the alpha-subunit allow the enzyme to accommodate either the covalently bound phosphoryl group or the free phosphate ion. Structural comparisons are made between the active sites in these two forms of the enzyme, both of which can occur along the catalytic path. Comparisons are also made with the structure of Escherichia coli SCS. The domain that has been shown to bind ADP in E. coli SCS is more open in the pig heart, GTP-specific SCS structure.     

Mitochondrial ATP synthase residue betaarginine-408, which interacts with the inhibitory site of regulatory protein IF1, is essential for the function of the enzyme

Mitochondrial ATP synthase (F(1)F(0)-ATPase) is regulated by an intrinsic ATPase inhibitor protein, IF(1). We previously found that six residues of the yeast IF(1) (Phe17, Arg20, Glu21, Arg22, Glu25, and Phe28) form an ATPase inhibitory site [Ichikawa, N. and Ogura, C. (2003) J. Bioenerg. Biomembr. 35, 399-407]. In the crystal structure of the F(1)/IF(1) complex [Cabezón, E. et al. (2003) Nat. Struct. Biol. 10, 744-750], the core residues of the inhibitory site interact with Arg408, Arg412 and Glu454 of the beta-subunit of F(1). In the present study, we examined the roles of the three beta residues by means of site-directed mutagenesis. A total of six yeast mutants were constructed: R408I, R408T, R412I, R412T, E454Q, and E454V. The betaArg412 and betaGlu454 mutants (R412I, R412T, E454Q, and E454V) could grow on a nonfermentable lactate medium, but the betaArg408 mutants (R408I and R408T) could not. The ATPase activity of isolated mitochondria was decreased in R412I, R412T, E454Q, and E454V mutant cells, and undetectable in R408I and R408T cells. The subunits of F(1) (alpha, beta, and gamma) were detected in mitochondria from each mutant on immunoblotting, and the F(1)F(0) complex was isolated from them. These results indicate that betaArg408 is essential not for assembly of the F(1)F(0) complex but for the catalytic activity of the enzyme. In the crystal structure of F(1), betaArg408 binds to alphaGlu399 in the alpha(DP)/beta(DP) pair and seems to be important for formation of the closed alpha(DP)/beta(DP) conformation. IF(1) seems to disrupt this alpha(DP)Glu399/beta(DP)Arg408 interaction by binding to beta(DP)Arg408, and to interfere with the change from the open alpha(DP)/beta(DP) conformation to the closed conformation that is required for catalysis by F(1)F(0)-ATPase.     

The role of Glu74 and Tyr82 in the reaction catalyzed by sheep liver cytosolic serine hydroxymethyltransferase.

The three-dimensional structures of human and rabbit liver cytosolic recombinant serine hydroxymethyltransferases (hcSHMT and rcSHMT) revealed that E75 and Y83 (numbering according to hcSHMT) are probable candidates for proton abstraction and Calpha-Cbeta bond cleavage in the reaction catalyzed by serine hydroxymethyltransferase. Both these residues are completely conserved in all serine hydroxymethyltransferases sequenced to date. In an attempt to decipher the role of these residues in sheep liver cytosolic recombinant serine hydroxymethyltransferase (scSHMT), E74 (corresponding residue is E75 in hcSHMT) was mutated to Q and K, and Y82 (corresponding residue is Y83 in hcSHMT) was mutated to F. The specific activities using serine as the substrate for the E74Q and E74K mutant enzymes were drastically reduced. These mutant enzymes catalyzed the transamination of D-alanine and 5,6,7, 8-tetrahydrofolate independent retroaldol cleavage of Lallo threonine at rates comparable with wild-type enzyme, suggesting that E74 was not involved directly in the proton abstraction step of catalysis, as predicted earlier from crystal structures of hcSHMT and rcSHMT. There was no change in the apparent Tm value of E74Q upon the addition of L-serine, whereas the apparent Tm value of scSHMT was enhanced by 10 degrees C. Differential scanning calorimetric data and proteolytic digestion patterns in the presence of L-serine showed that E74Q was different to scSHMT. These results indicated that E74 might be required for the conformational change involved in reaction specificity. It was predicted from the crystal structures of hcSHMT and rcSHMT that Y82 was involved in hemiacetal formation following Calpha-Cbeta bond cleavage of L-serine and mutation of this residue to F could lead to a rapid release of HCHO. However, the Y82F mutant had only 5% of the activity and failed to form a quinonoid intermediate, suggesting that this residue is not involved in the formation of the hemiacetal intermediate, but might be involved indirectly in the abstraction of the proton and in stabilizing the quinonoid intermediate.     

Identification by mutagenesis of a conserved glutamate (Glu487) residue important for catalytic activity in rat liver carnitine palmitoyltransferase II

Mammalian mitochondrial membranes express two active but distinct carnitine palmitoyltransferases: carnitine palmitoyltransferase I (CPTI), which is malonyl coA-sensitive and detergent-labile; and carnitine palmitoyltransferase II (CPTII), which is malonyl coA-insensitive and detergent-stable. To determine the role of the highly conserved C-terminal acidic residues glutamate 487 (Glu(487)) and glutamate 500 (Glu(500)) on catalytic activity in rat liver CPTII, we separately mutated these residues to alanine, aspartate, or lysine, and the effect of the mutations on CPTII activity was determined in the Escherichia coli-expressed mutants. Substitution of Glu(487) with alanine, aspartate, or lysine resulted in almost complete loss in CPTII activity. Because a conservative substitution mutation of this residue, Glu(487) with aspartate (E487D), resulted in a 97% loss in activity, we predicted that Glu(487) would be at the active-site pocket of CPTII. The substantial loss in CPTII activity observed with the E487K mutant, along with the previously reported loss in activity observed in a child with a CPTII deficiency disease, establishes that Glu(487) is crucial for maintaining the configuration of the liver isoform of the CPTII active site. Substitution of the conserved Glu(500) in CPTII with alanine or aspartate reduced the V(max) for both substrates, suggesting that Glu(500) may be important in stabilization of the enzyme-substrate complex. A conservative substitution of Glu(500) to aspartate resulted in a significant decrease in the V(max) for the substrates. Thus, Glu(500) may play a role in substrate binding and catalysis. Our site-directed mutagenesis studies demonstrate that Glu(487) in the liver isoform of CPTII is essential for catalysis.     

Substitution of glutamic acid 109 by aspartic acid alters the substrate specificity and catalytic activity of the beta-subunit in the tryptophan synthase bienzyme complex from Salmonella typhimurium.

In an effort to understand the catalytic mechanism of the tryptophan synthase beta-subunit from Salmonella typhimurium, possible functional active site residues have been identified (on the basis of the 3-D crystal structure of the bienzyme complex) and targeted for analysis utilizing site-directed mutagenesis. The chromophoric properties of the pyridoxal 5'-phosphate cofactor provide a particularly convenient and sensitive spectral probe to directly investigate changes in catalytic events which occur upon modification of the beta-subunit. Substitution of Asp for Glu 109 in the beta-subunit was found to alter both the catalytic activity and the substrate specificity of the beta-reaction. Steady-state kinetic data reveal that the beta-reaction catalyzed by the beta E109D alpha 2 beta 2 mutant enzyme complex is reduced 27-fold compared to the wild-type enzyme. Rapid-scanning stopped-flow (RSSF) UV-visible spectroscopy shows that the mutation does not seriously affect the pre-steady-state reaction of the beta E109D mutant with L-serine to form the alpha-aminoacrylate intermediate, E(A-A). Binding of the alpha-subunit specific ligand, alpha-glycerol phosphate (GP) to the alpha 2 beta 2 complex exerts the same allosteric effects on the beta-subunit as observed with the wild-type enzyme. However, the pre-steady-state spectral changes for the reaction of indole with E(A-A) show that the formation of the L-tryptophan quinonoid, E(Q3), is drastically altered. Discrimination against E(Q3) formation is also observed for the binding of L-tryptophan to the mutant alpha 2 beta 2 complex in the reverse reaction. In contrast, substitution of Asp for Glu 109 increases the apparent affinity of the beta E109D alpha-aminoacrylate complex for the indole analogue indoline and results in the increased rate of synthesis of the amino acid product dihydroiso-L-tryptophan. Thus, the mutation affects the covalent bond forming addition reactions and the nucleophile specificity of the beta-reaction catalyzed by the bienzyme complex.     

The role of Glu181 in the photoactivation of rhodopsin

The visual pigment rhodopsin is a prototypical seven transmembrane helical G protein-coupled receptor. Photoisomerization of its protonated Schiff base (PSB) retinylidene chromophore initiates a progression of metastable intermediates. We studied the structural dynamics of receptor activation by FTIR spectroscopy of recombinant pigments. Formation of the active state, Meta II, is characterized by neutralization of the PSB and its counterion Glu113. We focused on testing the hypothesis of a PSB counterion switch from Glu113 to Glu181 during the transition of rhodopsin to the still inactive Meta I photointermediate. Our results, especially from studies of the E181Q mutant, support the view that both Glu113 and Glu181 are deprotonated, forming a complex counterion to the PSB in rhodopsin, and that the function of the primary counterion shifts from Glu113 to Glu181 during the transition to Meta I. The Meta I conformation in the E181Q mutant is less constrained compared with that of wild-type Meta I. In particular, the hydrogen bonded network linking transmembrane helices 1, 2, and 7, adopts a conformation that is already Meta II-like, while other parts of the receptor appear to be in a Meta I-like conformation similar to wild-type. We conclude that Glu181 is responsible, in part, for controlling the extraordinary high pK(a) of the chromophore PSB in the dark state, which very likely decreases upon transition to Meta I in a stepwise weakening of the interaction between PSB and its complex counterion during the course of receptor activation. A model for the specific role in coupling chromophore isomerization to protein conformational changes concomitant with receptor activation is presented.     

Cloning, characterization, and expression of the beta subunit of pig heart succinyl-CoA synthetase.

The form of succinyl-CoA synthetase found in mammalian mitochondria is known to be an alpha beta dimer. Both GTP- and ATP-specific isozymes are present in various tissues. We have isolated essentially identical complementary DNA clones encoding the beta subunit of pig heart succinyl-CoA synthetase from both newborn and adult tissues. These cDNAs include a 1.4-kb sequence encoding the cytoplasmic precursor to the beta subunit comprised of 417 amino acid residues including a 22-residue mitochondrial targeting sequence. The cDNA encoding the 395-amino acid, 42,502-Da mature protein was confirmed to be the succinyl-CoA synthetase beta subunit by agreement with the N-terminal protein sequence and by high homology to prokaryotic forms of the beta subunit that were previously cloned (about 45% identical to beta from Escherichia coli). In contrast to a previous report (Nishimura, J.S., Ybarra, J., Mitchell, T., & Horowitz, P.M., 1988, Biochem. J. 250, 429-434), we found no tryptophan residue to be encoded in the sequence for the mature beta subunit, and this finding is corroborated by the fact that highly purified pig heart succinyl-CoA synthetase shows no tryptophan fluorescence or tryptophan content in amino acid compositional analysis. The cDNA clones encoding the mature pig heart beta subunit and its counterpart alpha subunit were coexpressed in a deletion mutant strain of E. coli. Recovery of succinyl-CoA synthetase activity demonstrated that this combination of subunits forms a productive enzymatic complex having GTP specificity.     

K(+)-independent gastric H(+),K(+)-atpase activity. Dissociation of K(+)-independent dephosphorylation and preference for the E1 conformation by combined mutagenesis of transmembrane glutamate residues

Several mutations of residues Glu(795) and Glu(820) present in M5 and M6 of the catalytic subunit of gastric H(+),K(+)-ATPase have resulted in a K(+)-independent, SCH 28080-sensitive ATPase activity, caused by a high spontaneous dephosphorylation rate. The mutants with this property also have a preference for the E(1) conformation. This paper investigates the question of whether these two phenomena are coupled. This possibility was studied by combining mutations in residue Glu(343), present in M4, with those in residues 795 and 820. When in combined mutants Glu and/or Gln residues were present at positions 343, 795, and 820, the residue at position 820 dominated the behavior: a Glu giving K(+)-activated ATPase activity and an E(2) preference and a Gln giving K(+)-independent ATPase activity and an E(1) preference. With an Asp at position 343, the enzyme could be phosphorylated, but the dephosphorylation was blocked, independent of the presence of either a Glu or a Gln at positions 795 and 820. However, in these mutants, the direction of the E(2) <--> E(1) equilibrium was still dominated by the 820 residue: a Glu giving E(2) and a Gln giving E(1). This indicates that the preference for the E(1) conformation of the E820Q mutation is independent of an active dephosphorylation process.     

Reaction mechanism and structural model of ADP-forming Acetyl-CoA synthetase from the hyperthermophilic archaeon Pyrococcus furiosus: evidence for a second active site histidine residue

In Archaea, acetate formation and ATP synthesis from acetyl-CoA is catalyzed by an unusual ADP-forming acetyl-CoA synthetase (ACD) (acetyl-CoA + ADP + P(i) acetate + ATP + HS-CoA) catalyzing the formation of acetate from acetyl-CoA and concomitant ATP synthesis by the mechanism of substrate level phosphorylation. ACD belongs to the protein superfamily of nucleoside diphosphate-forming acyl-CoA synthetases, which also include succinyl-CoA synthetases (SCSs). ACD differs from SCS in domain organization of subunits and in the presence of a second highly conserved histidine residue in the beta-subunit, which is absent in SCS. The influence of these differences on structure and reaction mechanism of ACD was studied with heterotetrameric ACD (alpha(2)beta(2)) from the hyperthermophilic archaeon Pyrococcus furiosus in comparison with heterotetrameric SCS. A structural model of P. furiosus ACD was constructed suggesting a novel spatial arrangement of the subunits different from SCS, however, maintaining a similar catalytic site. Furthermore, kinetic and molecular properties and enzyme phosphorylation as well as the ability to catalyze arsenolysis of acetyl-CoA were studied in wild type ACD and several mutant enzymes. The data indicate that the formation of enzyme-bound acetyl phosphate and enzyme phosphorylation at His-257alpha, respectively, proceed in analogy to SCS. In contrast to SCS, in ACD the phosphoryl group is transferred from the His-257alpha to ADP via transient phosphorylation of a second conserved histidine residue in the beta-subunit, His-71beta. It is proposed that ACD reaction follows a novel four-step mechanism including transient phosphorylation of two active site histidine residues:     

Modification of Glu 58, an amino acid of the active center of ribonuclease T1, to Gln and Asp

Glu 58 is one of the amino acids which participates in its catalytic action of ribonuclease T1. We mutated this residue to Gln 58 or Asp 58 by genetic engineering using chemically synthesized genes. The mutant enzymes were expressed in E. coli as fused proteins and purified to homogeniety on SDS-PAGE after cleavage with cyanogen bromide. Their activities in hydrolyzing pGpC were reduced to 10% in the Asp 58 mutant and about 1% in the Gln 58 mutant compared to that of the wild-type enzyme. These results suggest that Glu 58 is important but not essential for catalysis of ribonuclease T1.     

Alteration of sperm whale myoglobin heme axial ligation by site-directed mutagenesis

Three mutant proteins of sperm whale myoglobin (Mb) that exhibit altered axial ligations were constructed by site-directed mutagenesis of a synthetic gene for sperm whale myoglobin. Substitution of distal pocket residues, histidine E7 and valine E11, with tyrosine and glutamic acid generated His(E7)Tyr Mb and Val(E11)Glu Mb. The normal axial ligand residue, histidine F8, was also replaced with tyrosine, resulting in His(F8)Tyr Mb. These proteins are analogous in their substitutions to the naturally occurring hemoglobin M mutants (HbM). Tyrosine coordination to the ferric heme iron of His(E7)Tyr Mb and His(F8)Tyr Mb is suggested by optical absorption and EPR spectra and is verified by similarities to resonance Raman spectral bands assigned for iron-tyrosine proteins. His(E7)Tyr Mb is high-spin, six-coordinate with the ferric heme iron coordinated to the distal tyrosine and the proximal histidine, resembling Hb M Saskatoon [His(beta E7)Tyr], while the ferrous iron of this Mb mutant is high-spin, five-coordinate with ligation provided by the proximal histidine. His(F8)Tyr Mb is high-spin, five-coordinate in both the oxidized and reduced states, with the ferric heme iron liganded to the proximal tyrosine, resembling Hb M Iwate [His(alpha F8)Tyr] and Hb M Hyde Park [His(beta F8)Tyr]. Val(E11)Glu Mb is high-spin, six-coordinate with the ferric heme iron liganded to the F8 histidine. Glutamate coordination to the ferric iron of this mutant is strongly suggested by the optical and EPR spectral features, which are consistent with those observed for Hb M Milwaukee [Val(beta E11)Glu]. The ferrous iron of Val(E11)Glu Mb exhibits a five-coordinate structure with the F8 histidine-iron bond intact.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interactions of GTP with the ATP-grasp domain of GTP-specific succinyl-CoA synthetase

Two isoforms of succinyl-CoA synthetase exist in mammals, one specific for ATP and the other for GTP. The GTP-specific form of pig succinyl-CoA synthetase has been crystallized in the presence of GTP and the structure determined to 2.1 A resolution. GTP is bound in the ATP-grasp domain, where interactions of the guanine base with a glutamine residue (Gln-20beta) and with backbone atoms provide the specificity. The gamma-phosphate interacts with the side chain of an arginine residue (Arg-54beta) and with backbone amide nitrogen atoms, leading to tight interactions between the gamma-phosphate and the protein. This contrasts with the structures of ATP bound to other members of the family of ATP-grasp proteins where the gamma-phosphate is exposed, free to react with the other substrate. To test if GDP would interact with GTP-specific succinyl-CoA synthetase in the same way that ADP interacts with other members of the family of ATP-grasp proteins, the structure of GDP bound to GTP-specific succinyl-CoA synthetase was also determined. A comparison of the conformations of GTP and GDP shows that the bases adopt the same position but that changes in conformation of the ribose moieties and the alpha- and beta-phosphates allow the gamma-phosphate to interact with the arginine residue and amide nitrogen atoms in GTP, while the beta-phosphate interacts with these residues in GDP. The complex of GTP with succinyl-CoA synthetase shows that the enzyme is able to protect GTP from hydrolysis when the active-site histidine residue is not in position to be phosphorylated.     

Characterization of the Glu and Asp residues in the active site of human beta-hexosaminidase B

Human beta-hexosaminidase A (alpha beta) and B (beta beta) are composed of subunits (alpha and beta) that are 60% identical and have been grouped with other evolutionarily related glycosidases into "Family 20". The three-dimensional structure of only one Family 20 member has been elucidated, a bacterial chitobiase. This enzyme shares primary structure homology with both the human subunits only in its active-site region, and even in this restricted area, the level of identity is only 26%. Thus, the validity of the molecular model for the active site of the human enzyme based on chitobiase must be determined experimentally. In this report, we analyze highly purified mutant forms of human hexosaminidase B that have had conservative substitutions made at Glu and Asp residues predicted by the chitobiase model to be part of its active site. Mutation of beta Glu(355) to Gln reduces k(cat) 5000-fold with only a small effect on K(m), while also shifting the pH optimum. These effects are consistent with assignment of this residue as the acid/base catalytic residue. Similarly, mutation of beta Asp(354) to Asn reduced k(cat) 2000-fold while leaving K(m) essentially unaltered, consistent with assignment of this residue as the residue that interacts with the substrate acetamide group to promote its attack on the anomeric center. These data in conjunction with the mutagenesis studies of Asp(241) and Glu(491) indicate that the molecular model is substantially accurate in its identification of catalytically important residues.     

Structural asymmetry of phosphodiesterase-9, potential protonation of a glutamic acid, and role of the invariant glutamine

PDE9 inhibitors show potential for treatment of diseases such as diabetes. To help with discovery of PDE9 inhibitors, we performed mutagenesis, kinetic, crystallographic, and molecular dynamics analyses on the active site residues of Gln453 and its stabilizing partner Glu406. The crystal structures of the PDE9 Q453E mutant (PDE9Q453E) in complex with inhibitors IBMX and (S)-BAY73-6691 showed asymmetric binding of the inhibitors in two subunits of the PDE9Q453E dimer and also the significant positional change of the M-loop at the active site. The kinetic analysis of the Q453E and E406A mutants suggested that the invariant glutamine is critical for binding of substrates and inhibitors, but is unlikely to play a key role in the differentiation between substrates of cGMP and cAMP. The molecular dynamics simulations suggest that residue Glu406 may be protonated and may thus explain the hydrogen bond distance between two side chain oxygens of Glu453 and Glu406 in the crystal structure of the PDE9Q453E mutant. The information from these studies may be useful for design of PDE9 inhibitors.     

Site-directed mutagenesis of Escherichia coli succinyl-CoA synthetase. Histidine 142 alpha is a facilitative catalytic residue

There are 11 histidine residues in Escherichia coli succinyl-CoA synthetase. His-246 alpha is well established as the phosphorylation site of the enzyme. Replacement of this histidine by asparagine (Mann, C. J., Mitchell, T., and Nishimura, J. S. (1991) Biochemistry 30, 1497-1503) or by aspartic acid (Majumdar, R., Guest, J. R., and Bridger, W. A. (1991) Biochim. Biophys. Acta 1076, 86-90) through site-directed mutagenesis resulted in complete loss of enzyme activity. Chemical modification experiments suggested a second histidine at the active site (Collier, G. E., and Nishimura, J. S. (1979) J. Biol. Chem. 254, 10925-10930). In the present study, we have changed His-142 alpha to an asparagine residue using the technique of site-directed mutagenesis and have purified the mutant enzyme to homogeneity. The resulting mutant enzyme is practically devoid of enzyme activity but can be thiophosphorylated with adenosine 5'-O-(thiotriphosphate) and dethiophosphorylated with ADP at rates that are significantly faster than those with wild type enzyme. The observation that phosphorylated mutant enzyme can be dephosphorylated with succinate and with succinate plus desulfo-CoA at rates comparable with those with wild type enzyme suggests that mutant enzyme can bind succinate and CoA. Dethiophosphorylation of the enzyme in the presence of CoA plus succinate proceeds much faster with wild type than with mutant. While there was no significant change in KCoA or Ksuccinate, the turnover number for dethiophosphorylation of the mutant was 10-fold lower. These data are consistent with location of His-142 alpha at the active site and a facilitative role for this residue in catalysis.     

Pi-turns in proteins and peptides: Classification, conformation, occurrence, hydration and sequence.

The i + 5-->i hydrogen bonded turn conformation (pi-turn) with the fifth residue adopting alpha L conformation is frequently found at the C-terminus of helices in proteins and hence is speculated to be a "helix termination signal." An analysis of the occurrence of i + 5-->i hydrogen bonded turn conformation at any general position in proteins (not specifically at the helix C-terminus), using coordinates of 228 protein crystal structures determined by X-ray crystallography to better than 2.5 A resolution is reported in this paper. Of 486 detected pi-turn conformations, 367 have the (i + 4)th residue in alpha L conformation, generally occurring at the C-terminus of alpha-helices, consistent with previous observations. However, a significant number (111) of pi-turn conformations occur with (i + 4)th residue in alpha R conformation also, generally occurring in alpha-helices as distortions either at the terminii or at the middle, a novel finding. These two sets of pi-turn conformations are referred to by the names pi alpha L and pi alpha R-turns, respectively, depending upon whether the (i + 4)th residue adopts alpha L or alpha R conformations. Four pi-turns, named pi alpha L'-turns, were noticed to be mirror images of pi alpha L-turns, and four more pi-turns, which have the (i + 4)th residue in beta conformation and denoted as pi beta-turns, occur as a part of hairpin bend connecting twisted beta-strands. Consecutive pi-turns occur, but only with pi alpha R-turns. The preference for amino acid residues is different in pi alpha L and pi alpha R-turns. However, both show a preference for Pro after the C-termini. Hydrophilic residues are preferred at positions i + 1, i + 2, and i + 3 of pi alpha L-turns, whereas positions i and i + 5 prefer hydrophobic residues. Residue i + 4 in pi alpha L-turns is mainly Gly and less often Asn. Although pi alpha R-turns generally occur as distortions in helices, their amino acid preference is different from that of helices. Poor helix formers, such as His, Tyr, and Asn, also were found to be preferred for pi alpha R-turns, whereas good helix former Ala is not preferred. pi-Turns in peptides provide a picture of the pi-turn at atomic resolution. Only nine peptide-based pi-turns are reported so far, and all of them belong to pi alpha L-turn type with an achiral residue in position i + 4. The results are of importance for structure prediction, modeling, and de novo design of proteins.     

Construction of a catalytically inactive cholesterol oxidase mutant: investigation of the interplay between active site-residues glutamate 361 and histidine 447

Cholesterol oxidase catalyzes the oxidation of cholesterol to cholest-5-en-3-one and its subsequent isomerization into cholest-4-en-3-one. Two active-site residues, His447 and Glu361, are important for catalyzing the oxidation and isomerization reactions, respectively. Double-mutants were constructed to test the interplay between these residues in catalysis. We observed that the k(cat) of oxidation for the H447Q/E361Q mutant was 3-fold less than that for H447Q and that the k(cat) of oxidation for the H447E/E361Q mutant was 10-fold slower than that for H447E. Because both doubles-mutants do not have a carboxylate at position 361, they do not catalyze isomerization of the reaction intermediate cholest-5-en-3-one to cholest-4-en-3-one. These results suggest that Glu361 can compensate for the loss of histidine at position 447 by acting as a general base catalyst for oxidation of cholesterol. Importantly, the construction of the double-mutant H447E/E361Q yields an enzyme that is 31,000-fold slower than wild type in k(cat) for oxidation. The H447E/E361Q mutant is folded like native enzyme and still associates with model membranes. Thus, this mutant may be used to study the effects of membrane binding in the absence of catalytic activity. It is demonstrated that in assays with caveolae membrane fractions, the wild-type enzyme uncouples platelet-derived growth factor receptor beta (PDGFRbeta) autophosphorylation from tyrosine phosphorylation of neighboring proteins, and the H447E/E361Q mutant does not. Thus maintenance of membrane structure by cholesterol is important for PDGFRbeta-mediated signaling. The cholesterol oxidase mutant probe described will be generally useful for investigating the role of membrane structure in signal transduction pathways in addition to the PDGFRbeta-dependent pathway tested.     

Evidence for a second histidine at the active site of succinyl-CoA synthetase from Escherichia coli.

Ethoxyformic anhydride was used to demonstrate the existence of a second important histidine in succinyl-CoA synthetase from Escherichia coli. Differential labeling of the enzyme by [3H]ethoxyformic anhydride gave a stoichiometry of one important histidine per alpha beta catalytic unit. Data are presented suggesting that this residue and an important thiol group on the beta subunit (Collier, G., and Nishimura, J.S. (1978) J. Biol. Chem. 253, 4938-4943) interact with each other during catalysis. A mechanism of action involving these 2 residues is proposed for one of the partial reactions catalyzed by succinyl-CoA synthetase.