The role of aspartic acid-49 in the active site of phospholipase A2. A site-specific mutagenesis study of porcine pancreatic phospholipase A2 and the rationale of the enzymatic activity of [lysine49]phospholipase A2 from Agkistrodon piscivorus piscivorus' venom

In order to probe the role of Asp-49 in the active site of porcine pancreatic phospholipase A2 two mutant proteins were constructed containing either Glu or Lys at position 49. Their enzymatic activities and their affinities for substrate and for Ca2+ ions were examined in comparison with the native enzyme. Enzymatic characterization indicated that the presence of Asp-49 is essential for effective hydrolysis of phospholipids. Conversion of Asp-49 to either Glu or Lys strongly reduces the binding of Ca2+ ions in particular for the lysine mutant but the affinity for substrate analogues is hardly affected. Extensive purification of [Lys49]phospholipase A2 from the venom of Agkistrodon piscivorus piscivorus yielded a protein which was 4000 times less active than the basic [Asp49]phospholipase A2 from this venom. Inhibition studies with p-bromophenacyl bromide showed that this residual activity was due to a small amount of contaminating enzyme and that the Lys-49 homologue itself is inactive. The results obtained both with the porcine pancreatic phospholipase A2 mutants and with the native venom enzymes show that Asp-49 is essential for the catalytic action of phospholipase A2.     

Ligand requirements for Ca2+ binding to EGF-like domains.

Site-specific mutagenesis studies of the first epidermal growth factor-like (EGF-like) domain of human clotting factor IX suggest that the calcium-binding site present in this domain (dissociation constant Kd = 1.8 mM at pH 7.5 and ionic strength I = 0.15) involved the carboxylate residues Asp47, Asp49 and Asp64. To further characterize the ligands required for calcium binding to EGF-like domains, two new mutations, Asp47----Asn and Asp49----Asn, were introduced into the domain by peptide synthesis. 1H-NMR spectroscopy was used to obtain the dissociation constants for calcium binding to these mutations. Calcium binding to the Asp49----Asn modified domain is only mildly affected (Kd = 6 mM, I = 0.15), whereas binding to the Asp47----Asn modified domain is severely reduced (Kd = 42 mM, I = 0.15). From these data, it is proposed that the anionic oxygen atoms of the side chains of residues 47 and 64 are essential for calcium binding, whereas the side chain ligand for calcium at residue 49 can be a carboxyamide oxygen. As a control, the introduction of the modification Glu78----Asp in a region of the domain not believed to be involved in calcium binding had very little effect on the Kd for calcium (Kd = 2.6 mM, I = 0.15). Finally, the effect of an Asp47----Gly substitution found in the natural haemophilia B mutant, factor IXAlabama, was investigated. This peptide has a markedly reduced affinity for calcium (Kd = 37 mM, I = 0.15), suggesting that the defect in factor IXAlabama is due to impaired calcium binding to its first EGF-like domain.     

Asp383 in the second transmembrane domain of the lutropin receptor is important for high affinity hormone binding and cAMP production.

The lutropin (LH), follitropin, and thyrotropin receptors belong to the superfamily of G-protein coupled receptors and have some unique structural features. These glycoprotein hormone receptors comprise a C-terminal half and an N-terminal half of similar size. The C-terminal half is equivalent to the entire structure of other G-protein coupled receptors and has seven transmembrane domains, three cytoplasmic loops, three exoplasmic loops, and a C terminus. In contrast, the hydrophilic N-terminal half is exoplasmic and unique to the glycoprotein hormone receptors. This large N-terminal half of the LH receptor has recently been shown to be capable of binding the hormone. Therefore, these glycoprotein hormone receptors are structurally and functionally different from other G-protein coupled receptors. In an attempt to define the role of the membrane-associated C-terminal half of the LH receptor, we have prepared several mutant receptors in which an Asp or Glu in the seven transmembrane domains has been converted to Asn or Gln, respectively. These include Asp383----Asn in the second transmembrane domain, Glu410----Gln in the third transmembrane domain, and Asp556----Asn in the sixth transmembrane domain. All these mutant receptors were successfully expressed in Cos 7A cells. The Glu410----Gln and Asp556----Asn mutants maintained normal affinities for hormone binding and cAMP production, but the Asp383----Asn mutant showed significantly lower affinities. Although Asp383 of the LH receptor is conserved in all G-protein coupled receptors cloned to date except the substance P receptor, which has Glu in the place of the Asp residue, this is the first observation of the critical role of the Asp in hormone binding and subsequent stimulation of cAMP production.     

Observation of additional calcium ion in the crystal structure of the triple mutant K56,120,121M of bovine pancreatic phospholipase A2

Phospholipase A(2) catalyses hydrolysis of the ester bond at the C2 position of 3-sn-phosphoglycerides. Here we report the 1.9A resolution crystal structure of the triple mutant K56,120,121M of bovine pancreatic phospholipase A(2). The structure was solved by molecular replacement method using the orthorhombic form of the recombinant phospholipase A(2). The final protein model contains all the 123 amino acid residues, two calcium ions, 125 water molecules and one 2-methyl-2-4-pentanediol molecule. The model has been refined to a crystallographic R-factor of 19.6% (R(free) of 25.9%) for all data between 14.2A and 1.9A. The residues 62-66, which are in a surface loop, are always disordered in the structures of bovine pancreatic phospholipase A(2) and its mutants. It is interesting to note that the residues 62-66 in the present structure is ordered and the conformation varies substantially from those in the previously published structures of this enzyme. An unexpected and interesting observation in the present structure is that, in addition to the functionally important calcium ion in the active site, one more calcium ion is found near the N terminus. Detailed structural analyses suggest that binding of the second calcium ion could be responsible for the conformational change and the ordering of the surface loop. Furthermore, the results suggest a structural reciprocity between the k(cat)(*) allosteric site and surface loop at the i-face, which represents a newly identified structural property of secreted phospholipase A(2).     

Site-directed mutagenesis and X-ray crystallography of two phospholipase A2 mutants: Y52F and Y73F.

Tyr52 and Tyr73 are conserved amino acid residues throughout all vertebrate phospholipases A2. They are part of an extended hydrogen bonding system that links the N-terminal alpha-NH3(+)-group to the catalytic residues His48 and Asp99. These tyrosines were replaced by phenylalanines in a porcine pancreatic phospholipase A2 mutant, in which residues 62-66 had been deleted (delta 62-66PLA2). The mutations did not affect the catalytic properties of the enzyme, nor the folding kinetics. The stability against denaturation by guanidine hydrochloride was decreased, however. To analyse how the enzyme compensates for the loss of the tyrosine hydroxyl group, the X-ray structures of the delta Y52F and delta Y73F mutants were determined. After crystallographic refinement the final crystallographic R-factors were 18.1% for the delta Y52F mutant (data between 7 and 2.3 A resolution) and 19.1% for the delta Y73F mutant (data between 7 and 2.4 A resolution). No conformational changes occurred in the mutants compared with the delta 62-66PLA2, but an empty cavity formed at the site of the hydroxyl group of the former tyrosine. In both mutants the Asp99 side chain loses one of its hydrogen bonds and this might explain the observed destabilization.     

Changes in activity of porcine phospholipase A2 brought about by charge engineering of a major structural element to alter stability.

We have modified the stability of porcine phospholipase A2 by charge engineering. The mutations are situated at the N-terminal of a major helix and are N89D and N89D/E92Q. This engineering has significantly altered the activity of the enzyme to aggregated and monomeric substrates. A N89D/E92K mutant is more stable but considerably less active than wild type. An N89D mutant is more stable and of similar activity to wild type. The substantial change in activity may be due to direct interaction of residue 92 with aggregated substrate or may be via second calcium binding. Second calcium binding may be more probable as activity against monomers is also affected. Additional calcium binding may therefore be an important way of manipulating the activity of phospholipase A2.     

Dispensability of glutamic acid 48 and aspartic acid 134 for Mn2+-dependent activity of Escherichia coli ribonuclease HI

The activities of the eight mutant proteins of Escherichia coli RNase HI, in which the four carboxylic amino acids (Asp(10), Glu(48), Asp(70), and Asp(134)) involved in catalysis are changed to Asn (Gln) or Ala, were examined in the presence of Mn(2+). Of these proteins, the E48A, E48Q, D134A, and D134N proteins exhibited the activity, indicating that Glu(48) and Asp(134) are dispensable for Mn(2+)-dependent activity. The maximal activities of the E48A and D134A proteins were comparable to that of the wild-type protein. However, unlike the wild-type protein, these mutant proteins exhibited the maximal activities in the presence of >100 microM MnCl(2), and their activities were not inhibited at higher Mn(2+) concentrations (up to 10 mM). The wild-type protein contains two Mn(2+) binding sites and is activated upon binding of one Mn(2+) ion at site 1 at low ( approximately 1 microM) Mn(2+) concentrations. This activity is attenuated upon binding of a second Mn(2+) ion at site 2 at high (>10 microM) Mn(2+) concentrations. The cleavage specificities of the mutant proteins, which were examined using oligomeric substrates at high Mn(2+) concentrations, were identical to that of the wild-type protein at low Mn(2+) concentrations but were different from that of the wild-type protein at high Mn(2+) concentrations. These results suggest that one Mn(2+) ion binds to the E48A, E48Q, D134A, and D134N proteins at site 1 or a nearby site with weaker affinities. The binding analyses of the Mn(2+) ion to these proteins in the absence of the substrate support this hypothesis. When Mn(2+) ion is used as a metal cofactor, the Mn(2+) ion itself, instead of Glu(48) and Asp(134), probably holds water molecules required for activity.     

Functional consequences of alterations to Glu309, Glu771, and Asp800 in the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis was used to replace Glu309, Glu771, and Asp800 in the Ca(2+)-ATPase of rabbit fast twitch muscle sarcoplasmic reticulum with their corresponding amides. These residues are predicted to lie in the transmembrane domain and have been suggested as oxygen ligands for Ca2+ binding at high affinity sites (Clarke, D. M., Loo, T. W., Inesi, G., and MacLennan, D. H. (1989) Nature 339, 476-478). The Glu309----Gln and Asp800----Asn mutants were unable to form a phosphoenzyme from ATP at the Ca2+ concentrations examined (up to 12.5 mM), whereas the Glu771----Gln mutant phosphorylated from ATP at 2.5 mM Ca2+. In all three mutants, Ca2+ at concentrations well below 12.5 mM prevented or inhibited phosphorylation with Pi, suggesting that at least one calcium-binding site was functioning in each mutant. In the mutants Glu309----Gln and Glu771----Gln, the ADP-insensitive phosphoenzyme intermediate was unusually stable, as indicated by a very low rate of dephosphorylation observed in kinetic experiments and by an increased apparent affinity for Pi determined in equilibrium phosphorylation experiments. These data indicate a central role of Glu309 and Glu771 in the energy-transducing conformational changes and/or in the activation of phosphoenzyme hydrolysis.     

The amino acid sequence of the phospholipase A2 isoenzyme from porcine pancreas

The primary structure of porcine pancreatic isophospholipase A2 (EC 3.1.1.4) has been investigated. The sequence of procine isophospholipase differs from the sequence of porcine phospholipasy by four substitutions; viz. Ala12 leads to Thr; His17 leads to Asp leads to; Met20 leads to Leu and Glu71 leads to Asn.     

Crystal structure of phospholipase A2 complex with the hydrolysis products of platelet activating factor: equilibrium binding of fatty acid and lysophospholipid-ether at the active site may be mutually exclusive

We have solved the 1.55 A crystal structure of the anion-assisted dimer of porcine pancreatic group IB phospholipase A2 (PLA2), complexed with the products of hydrolysis of the substrate platelet activating factor. The dimer contains five coplanar phosphate anions bound at the contact surface between the two PLA2 subunits. This structure parallels a previously reported anion-assisted dimer that mimics the tetrahedral intermediate of PLA2 bound to a substrate interface [Pan, Y. H., et al. (2001) Biochemistry 40, 609-617]. The dimer structure has a molecule of the product acetate bound in subunit A and the other product 1-octadecyl-sn-glycero-3-phosphocholine (LPC-ether) to subunit B. Therefore, this structure is of the two individual product binary complexes and not of a ternary complex with both products in one active site of PLA2. Protein crystals with bound products were only obtained by cocrystallization starting from the initial substrate. In contrast, an alternate crystal form was obtained when PLA2 was cocrystallized with LPC-ether and succinate, and this crystal form did not contain bound products. The product bound structure has acetate positioned in the catalytic site of subunit A such that one of its oxygen atoms is located 3.5 A from the catalytic calcium. Likewise, a longer than typical Ca-to-Gly(32) carbonyl distance of 3.4 A results in a final Ca coordination that is four-coordinate and has distorted geometry. The other oxygen of acetate makes hydrogen bonds with N(delta)(1)-His(48), O(delta)(1)-Asp(49), and the catalytic assisting water (w7). In contrast, the glycerophosphocholine headgroup of LPC-ether in subunit B makes no contacts with calcium or with the catalytic residues His(48) or Asp(49). The tail of the LPC-ether is located near the active site pocket with the last nine carbons of the sn-1- acyl chain refined in two alternate conformations. The remaining atoms of the LPC-ether product have been modeled into the solvent channel but have their occupancies set to zero in the refined model due to disorder. Together, the crystallographic and equilibrium binding results with the two products show that the simultaneous binding of both the products in a single active site is not favored.     

Identification of the principal catalytically important acidic residue of 3-hydroxy-3-methylglutaryl coenzyme A reductase

Kinetic analysis of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase has implicated a glutamate or aspartate residue in (i) formation of mevaldate thiohemiacetal by proton transfer to the carbonyl oxygen of mevaldate and (ii) enhanced ionization of CoASH by the resulting enzyme carboxylate anion, facilitating attack by CoAS- on the carbonyl carbon of mevaldate (Veloso, D., Cleland, W. W., and Porter, J. W. (1981) Biochemistry 81, 887-894). Although neither the identity of this acidic residue nor its location is known, the catalytic domains of 11 sequenced HMG-CoA reductases contain only 3 conserved acidic residues. For HMG-CoA reductase of Pseudomonas mevalonii, these residues are Glu52, Glu83, and Asp183. To identify the acidic residue that functions in catalysis, we generated mutants having alterations in these residues. The mutant proteins were expressed, purified, and characterized. Mutational alteration of residues Glu52 or Asp183 of P. mevalonii HMG-CoA reductase yielded enzymes with significant, but in some cases reduced, activity (Vmax = 100% Asp183----Ala, 65% Asp183----Asn, and 15% Glu52----Gln of wild-type activity, respectively). Although the activity of mutant enzymes Glu52----Gln and Asp183----Ala was undetectable under standard assay conditions, their Km values for substrates were 4-300-fold higher than those for wild-type enzyme. Km values for wild-type enzyme and for mutant enzymes Glu52----Gln and Asp183----Ala were, respectively: 0.41, 73, and 120 mM [R,S)-mevalonate); 0.080, 4.4, and 2.0 mM (coenzyme A); and 0.26, 4.4, and 1.0 mM (NAD+). By these criteria, neither Glu52 nor Asp183 is the acidic catalytic residue although each may function in substrate recognition. During chromatography on coenzyme A agarose or HMG-CoA agarose, mutant enzymes Asp183----Asn and Glu83----Gln behaved like wild-type enzyme. By contrast, and in support of a role for these residues in substrate recognition, mutant enzymes Glu52----Gln and Asp183----Ala exhibited impaired ability to bind to either support. Despite displaying Km values for substrates and chromatographic behavior on substrate affinity supports comparable to wild-type enzyme, only mutant enzyme Glu83----Gln was essentially inactive under all conditions studied (Vmax = 0.2% that of wild-type enzyme). Glutamate residue 83 of P. mevalonii HMG-CoA reductase, and consequently the glutamate of the consensus Pro-Met-Ala-Thr-Thr-Glu-Gly-Cys-Leu-Val-Ala motif of the catalytic domains of eukaryotic HMG-CoA reductases, is judged to be the acidic residue functional in catalysis.     

Amino acid substitutions of the NH2-terminal Ala1 of porcine pancreatic phospholipase A2: a monolayer study

Previously it has been shown that the binding of porcine pancreatic phospholipase A2 to lipid-water interfaces is governed by the pK of the alpha-NH3+ group of the N-terminal alanine. Chemically modified phospholipases A2 in which the N-terminal Ala has been replaced by D-Ala or in which the polypeptide chain has been elongated with DL-Ala no longer display activity toward micellar substrate. The activity of DL-Ala-1-, [D-Ala1]-, and [Gly1]phospholipases A2 on substrate monolayers, which allow a continuous change in the packing density of the lipid molecule, was investigated. At pH 6 [Gly1]phospholipase A2 behaves like the native enzyme on lecithin monolayers. DL-Ala1- and [D-Ala1]phospholipases A2, although they are active in this system, showed a weaker lipid penetration capacity at this pH. Studies on the pH and Ca2+ ion dependency of the pre-steady-state kinetics and of the activity of these radiolabeled proteins showed that [D-Ala1]phospholipase A2 does not possess a second low-affinity site for Ca2+ ions in contrast to the native phospholipase A2. This second low-affinity Ca2+ binding site, which is also absent in [Gly1]phospholipase A2, is induced in the latter enzyme by the presence of lipid-water interfaces.     

Site-directed mutagenesis of the calcium-binding site of blood coagulation factor XIIIa.

Blood coagulation factor XIIIa is a calcium-dependent enzyme that covalently ligates fibrin molecules during blood coagulation. X-ray crystallography studies identified a major calcium-binding site involving Asp(438), Ala(457), Glu(485), and Glu(490). We mutated two glutamic acid residues (Glu(485) and Glu(490)) and three aspartic acid residues (Asp(472), Asp(476), and Asp(479)) that are in close proximity. Alanine substitution mutants of these residues were constructed, expressed, and purified from Escherichia coli. The K(act) values for calcium ions increased by 3-, 8-, and 21-fold for E485A, E490A, and E485A,E490A, respectively. In addition, susceptibility to proteolysis was increased by 4-, 9-, and 10-fold for E485A, E490A, and E485A,E490A, respectively. Aspartic acids 472, 476, and 479 are not involved directly in calcium binding since the K(act) values were not changed by mutagenesis. However, Asp(476) and Asp(479) are involved in regulating the conformation for exposure of the secondary thrombin cleavage site. This study provides biochemical evidence that Glu(485) and Glu(490) are Ca(2+)-binding ligands that regulate catalysis. The binding of calcium ion to this site protects the molecule from proteolysis. Furthermore, Asp(476) and Asp(479) play a role in modulating calcium-dependent conformational changes that cause factor XIIIa to switch from a protease-sensitive to a protease-resistant molecule.     

Identification of single Mn(2+) binding sites required for activation of the mutant proteins of E.coli RNase HI at Glu48 and/or Asp134 by X-ray crystallography

Escherichia coli RNase HI has two Mn(2+)-binding sites. Site 1 is formed by Asp10, Glu48, and Asp70, and site 2 is formed by Asp10 and Asp134. Site 1 and site 2 have been proposed to be an activation site and an attenuation site, respectively. However, Glu48 and Asp134 are dispensable for Mn(2+)-dependent activity. In order to identify the Mn(2+)-binding sites of the mutant proteins at Glu48 and/or Asp134, the crystal structures of the mutant proteins E48A-RNase HI*, D134A-RNase HI*, and E48A/D134N-RNase HI* in complex with Mn(2+) were determined. In E48A-RNase HI*, Glu48 and Lys87 are replaced by Ala. In D134A-RNase HI*, Asp134 and Lys87 are replaced by Ala. In E48A/D134N-RNase HI*, Glu48 and Lys87 are replaced by Ala and Asp134 is replaced by Asn. All crystals had two or four protein molecules per asymmetric unit and at least two of which had detectable manganese ions. These structures indicated that only one manganese ion binds to the various positions around the center of the active-site pocket. These positions are different from one another, but none of them is similar to site 1. The temperature factors of these manganese ions were considerably larger than those of the surrounding residues. These results suggest that the first manganese ion required for activation of the wild-type protein fluctuates among various positions around the center of the active-site pockets. We propose that this fluctuation is responsible for efficient hydrolysis of the substrates by the protein (metal fluctuation model). The binding position of the first manganese ion is probably forced to shift to site 1 or site 2 upon binding of the second manganese ion.     

The crystal structure of a lysine 49 phospholipase A2 from the venom of the cottonmouth snake at 2.0-A resolution

The crystal structure of a lysine 49 variant phospholipase A2 (K49 PLA2) has been determined at 2.0-A resolution. This particular phospholipase A2, purified from the venom of the eastern cottonmouth (Agkistrodon piscivorus piscivorus), a North American pit viper, differs significantly from others studied crystallographically because of replacement of the aspartate residue at position 49, whose side chain is important in calcium binding, by lysine. The crystallographic analysis of K49 PLA2 was undertaken to assess the structural ramifications of this substitution, particularly as they affect the binding mechanism of both the calcium cofactor and the phospholipid substrate. The protein crystals are tetragonal, space group P4(1)2(1)2, with unit cell dimensions of a = b = 71.7 (1) and c = 57.8 (3) A. Preliminary phases were obtained by molecular replacement techniques with a search model derived from the refined 2.5-A structure of a rattle-snake venom phospholipase A2 (Brunie, S., Bolin, J., Gewirth, D., and Sigler, P. B. (1985) J. Biol. Chem. 260, 9742-9749). The starting model gave an initial crystallographic RF of 0.526 (RF = sigma parallel to Fo /-/ Fc parallel to /sigma/Fo/). The structure was refined against all data to 2.0-A resolution. The final RF is 0.158. The final model includes 150 discrete water molecules. The K49 PLA2 model is composed primarily of alpha-helices joined by loops, some of which are quite extensive. Although dissimilarities are observed in the loop regions, the helical portions are very similar to those in other known phospholipase A2 structures. The proposed catalytic center (His48, Tyr73, and Asp99) is also structurally conserved. The region in K49 PLA2 corresponding to the calcium-binding site in other phospholipases A2 is occupied by the epsilon-amino group of lysine 49.     

Catalytic mechanism of fungal glucoamylase as defined by mutagenesis of Asp176, Glu179 and Glu180 in the enzyme from Aspergillus awamori

Asp176, Glu179 and Glu180 of Aspergillus awamori glucoamylase appeared by differential labeling to be in the active site. To test their functions, they were replaced by mutagenesis with Asn, Gln and Gln respectively, and kinetic parameters and pH dependencies of all enzyme forms were determined. Glu179----Gln glucoamylase was not active on maltose or isomaltose, while the kcat for maltoheptaose hydrolysis decreased almost 2000-fold and the KM was essentially unchanged from wild-type glucoamylase. The The Glu180----Gln mutation drastically increased the KM and moderately decreased the kcat with maltose and maltoheptaose, but affected isomaltose hydrolysis less. Difference in substrate activation energies between Glu180----Gln and wild-type glucoamylases indicate that Glu180 binds D-glucosyl residues in subsite 2. The Asp176----Asn substitution gave moderate increases and decreases in KM and kcat respectively, and therefore similar increases in activation energies for the three substrates. This and the differences in subsite binding energies between Asp176----Asn and wild-type glucoamylases suggest that Asp176 is near subsite 1, where it stabilizes the transition state and interacts with Trp120 at subsite 4. Glu179 and Asp176 are thus proposed as the general catalytic acid and base of pKa 5.9 and 2.7 respectively. The charged Glu180 contributes to the high pKa value of Glu179.     

The role of Asp-49 and other conserved amino acids in phospholipases A2 and their importance for enzymatic activity

The role of aspartic acid-49 (Asp-49) in the active site of porcine pancreatic phospholipase A2 was studied by recombinant DNA techniques: two mutant proteins were constructed containing either glutamic acid (Glu) or lysine (Lys) at position 49. Enzymatic characterization indicated that the presence of Asp-49 is essential for effective hydrolysis of phospholipids. Conversion of Asp-49 to either Glu or Lys strongly reduces the binding of Ca2+ ions, in particular for the lysine mutant, but the affinity for substrate analogues is hardly affected. Extensive purification of naturally occurring Lys-49 phospholipase A2 from the venom of Agkistrodon piscivorus piscivorus yielded a protein that was nearly inactive. Inhibition studies showed that this residual activity was due to a small amount of contaminating enzyme and that the Lys-49 homologue itself has no enzymatic activity. Our results indicate that Asp-49 is essential for the catalytic action of phospholipase A2. The importance of Asp-49 was further evaluated by comparison of the primary sequences of 53 phospholipases A2 and phospholipase homologues showing that substitutions at position 49 are accompanied by structural variations of otherwise conserved residues. The occurrence of several nonconserved substitutions appeared to be a general characteristic of nonactive phospholipase A2 homologues.