Structural and energetic differences between insertions and substitutions in staphylococcal nuclease.

In a previous study, the small protein staphylococcal nuclease was shown to readily accommodate single alanine and glycine insertions, with average losses in stability comparable to substitutions at the same sites (PROT. 7:299-305, 1990). To more fully explore this unexpected adaptability to changes in residue spacing, 2 double amino acid insertions (alanyl-glycine, glycyl-glycine) and 3 additional single amino acid insertions with dissimilar side chains (proline, leucine, and glutamine) were constructed at 10 of the sites previously studied. At 8 of these sites, the type of amino acid side chain on the inserted residue significantly influenced the stability of the mutant protein. However, at 9 of the 10 sites, the double insertions were found to be no more destabilizing than the single alanine or glycine insertions. In contrast, double substitution mutations of staphylococcal nuclease, which replace two adjacent residues with alanine, do not show this striking degree of non-additivity. A comparison of the effects of single glutamine and single glycine insertions with alanyl-glycine insertions indicates that insertion of alanine into the peptide backbone is, on average, less destabilizing than appending the equivalent atoms onto the side chain of a glycine insertion. To explain their very different energetic effects, we propose that, unlike most substitutions, the inserted residue(s) must induce lateral displacements of the polypeptide chain, forcing the folded conformation away from that of wild type. The resulting obligatory shifts in the positioning of residues flanking the insertion generate a large number of degrees of freedom around which the mutant structure can relax.(ABSTRACT TRUNCATED AT 250 WORDS)     

Bioinformatics and molecular modeling in chemical enzymology. Active sites of hydrolases

Comparison and multiple alignments of amino acid sequences of a representative number of related enzymes demonstrate the existence of certain positions of amino acid residues which are permanently reproducible in all members of the whole family. The use of the bioinformatic approach revealed conservative residues in each of the related enzymes and ranked amino acid conservatism for the overall enzymatic catalysis. Glycine and aspartic acid residues were shown to be the most essential for structure and catalytic activity of enzymes. Amino acid residues forming catalytic subsite of the active site of enzymes are always highly conservative. Analysis revealed that aspartic acid carboxyl group is the most frequently employed nucleophilic (in deprotonated form) and electrophilic (in protonated form) agent involved in activation of molecules by the mechanism of general base and acidic catalyses in the catalytic sites of enzymes. Glycine is a unique amino acid possessing the highest possibilities for rotation along C–C and C–N bonds of the polypeptide chain. The conservative fixation of the glycine residue in polypeptide chains of related enzymes provides a possibility for directed assembly of amino acid residues into the catalytic subsite structure. It is possible that the conservative glycines provide known conformational mobility of the protein and the active site. Methods of molecular modeling were used for analysis of structural substitutions of conservative and non-conservative glycines and their effects on geometry of catalytic site of typical hydrolases. The substitution of glycine(s) for alanine significantly altered the catalytic site structures.     

Structure-function relationships in human lecithin:cholesterol acyltransferase. Site-directed mutagenesis at serine residues 181 and 216

The functions of serine residues at positions 181 and 216 of human plasma lecithin:cholesterol acyltransferase have been studied by site-directed mutagenesis. The serine residue at either site was replaced by alanine, glycine, or threonine in LCAT secreted from stably transfected CHO cells. All substitutions at position 181 gave rise to an enzyme product that was normally secreted but had no detectable catalytic activity. On the other hand, all substitutions at position 216 gave active products, whose activity was fully inhibitable by the serine esterase inhibitor diisopropyl fluorophosphate (DFP). A secondary (although not direct) role for serine-216 was indicated by a 14-fold increase in catalytic rate when this residue was substituted by alanine. Sequence comparison with other lipases suggests that serine-216 may be at or near the hinge of a helical flap displaced following substrate binding. These data strengthen the structural-functional relationship between LCAT and other lipases.     

Characterization of a novel Ser-cisSer-Lys catalytic triad in comparison with the classical Ser-His-Asp triad

Amidase signature family enzymes, which are widespread in nature, contain a newly identified Ser-cisSer-Lys catalytic triad in which the peptide bond between Ser131 and the preceding residue Gly130 is in a cis configuration. In order to characterize the property of the novel triad, we have determined the structures of five mutant malonamidase E2 enzymes that contain a Cys-cisSer-Lys, Ser-cisAla-Lys, or Ser-cisSer-Ala triad or a substitution of Gly130 with alanine. Cysteine cannot replace the role of Ser155 due to a hyper-reactivity of the residue, which results in the modification of the cysteine to cysteinyl sulfinic acid, most likely inside the expression host cells. The lysine residue plays a structural as well as a catalytic role, since the substitution of the residue with alanine disrupts the active site structure completely. The two observations are in sharp contrast with the consequences of the corresponding substitutions in the classical Ser-His-Asp triad. Structural data on the mutant containing the Ser-cisAla-Lys triad convincingly suggest that Ser131 plays an analogous catalytic role as the histidine of the Ser-His-Asp triad. The unusual cis configuration of Ser131 appears essential for the precise contacts of this residue with the other triad residues, as indicated by the near invariance of the preceding glycine residue (Gly130), structural data on the G130A mutant, and by a modeling experiment. The data provide a deep understanding of the role of each residue of the new triad at the atomic level and demonstrate that the new triad is a catalytic device distinctively different from the classical triad or its variants.     

Role for the P4 amino acid residue in substrate utilization by the poliovirus 3CD proteinase.

Amino acid insertions or substitutions were introduced into the poliovirus P1 capsid precursor at locations proximal to the two known Q-G cleavage sites to examine the role of the P4 residue in substrate processing by proteinase 3CD. Analysis of the processing profile of P1 precursors containing four-amino-acid insertions into the carboxy terminus of VP3 or a single-amino-acid substitution at the P4 position of the VP3-VP1 cleavage site demonstrates that substitution of the alanine residue in the P4 position of the VP3-VP1 cleavage site significantly affects cleavage at that site by proteinase 3CD. A single-amino-acid substitution at the P4 position of the VP0-VP3 cleavage site, on the other hand, has only a slight effect on 3CD-mediated processing at this cleavage site. Finally, analysis of six amino acid insertion mutations containing Q-G amino acid pairs demonstrates that the in vitro and in vivo selection of a cleavage site from two adjacent Q-G amino acid pairs depends on the presence of an alanine in the P4 position of the cleaved site. Our data provide genetic and biochemical evidence that the alanine residue in the P4 position of the VP3-VP1 cleavage site is a required substrate determinant for the recognition and cleavage of that site by proteinase 3CD and suggest that the P4 alanine residue may be specifically recognized by proteinase 3CD.     

Structural features of glutamine substrates for transglutaminases. Role of extended interactions in the specificity of human plasma factor XIIIa and of the guinea pig liver enzyme

Amino acid residues at several locations in close primary vicinity to a substrate glutamine residue have been recognized as important determinants for the specificities of human plasma factor XIIIa and guinea pig liver transglutaminase (Gorman, J. J., and Folk, J. E. (1981) J. Biol. Chem. 256, 2712-2715). The present studies measure the influence on transglutaminase specificity of some changes in amino acid side chains in a small synthetic glutamine peptide amide, Leu-Gly-Leu-Gly-Gln-Gly-Lys-Val-Leu-GlyNH2, which was designed to contain most of the known elements needed for enzyme recognition. The results are in agreement with previous findings and show that full catalytic activity of each enzyme may be retained upon replacement of the lysine residue by certain other amino acid residues. Evidence is provided that serine in place of glycine at one or more positions causes a significant increase in specificity with factor XIIIa, but not with liver enzyme. The effective substrate property for factor XIIIa seen with the model peptide amide is lost upon reversal of the sequence Val-Leu. This is not the case with the liver enzyme even though replacement of either of these amino acids by alanine causes a pronounced loss in activity with this enzyme. These differences and the effects of various other substitutions in the model peptide amide on the enzymes' specificities points up the relatively stringent structural requirements of factor XIIIa and the rather broad requirements for liver transglutaminase.     

Alanine substitutions of noncysteine residues in the cysteine‐stabilized αβ motif

The protein scaffold is a peptide framework with a high tolerance of residue modifications. The cysteine‐stabilized αβ motif (CSαβ) consists of an α‐helix and an antiparallel triple‐stranded β‐sheet connected by two disulfide bridges. Proteins containing this motif share low sequence identity but high structural similarity and has been suggested as a good scaffold for protein engineering. The Vigna radiate defensin 1 (VrD1), a plant defensin, serves here as a model protein to probe the amino acid tolerance of CSαβ motif. A systematic alanine substitution is performed on the VrD1. The key residues governing the inhibitory function and structure stability are monitored. Thirty‐two of 46 residue positions of VrD1 are altered by site‐directed mutagenesis techniques. The circular dichroism spectrum, intrinsic fluorescence spectrum, and chemical denaturation are used to analyze the conformation and structural stability of proteins. The secondary structures were highly tolerant to the amino acid substitutions; however, the protein stabilities were varied for each mutant. Many mutants, although they maintained their conformations, altered their inhibitory function significantly. In this study, we reported the first alanine scan on the plant defensin containing the CSαβ motif. The information is valuable to the scaffold with the CSαβ motif and protein engineering.     

Identification of residues critical for metallo-β-lactamase function by codon randomization and selection

IMP-1 beta-lactamase is a zinc metallo-enzyme encoded by the transferable bla(IMP-1) gene, which confers resistance to virtually all beta-lactam antibiotics including carbapenems. To understand how IMP-1 recognizes and hydrolyzes beta-lactam antibiotics it is important to determine which amino acid residues are critical for catalysis and which residues control substrate specificity. We randomized 27 individual codons in the bla(IMP-1) gene to create libraries that contain all possible amino acid substitutions at residue positions in and near the active site of IMP-1. Mutants from the random libraries were selected for the ability to confer ampicillin resistance to Escherichia coli. Of the positions randomized, >50% do not tolerate amino acid substitutions, suggesting they are essential for IMP-1 function. The remaining positions tolerate amino acid substitutions and may influence the substrate specificity of the enzyme. Interestingly, kinetic studies for one of the functional mutants, Asn233Ala, indicate that an alanine substitution at this position significantly increases catalytic efficiency as compared with the wild-type enzyme.     

Modification of activity and specificity of haloalkane dehalogenase from Sphingomonas paucimobilis UT26 by engineering of its entrance tunnel

Structural comparison of three different haloalkane dehalogenases suggested that substrate specificity of these bacterial enzymes could be significantly influenced by the size and shape of their entrance tunnels. The surface residue leucine 177 positioned at the tunnel opening of the haloalkane dehalogenase from Sphingomonas paucimobilis UT26 was selected for modification based on structural and phylogenetic analysis; the residue partially blocks the entrance tunnel, and it is the most variable pocket residue in haloalkane dehalogenase-like proteins with nine substitutions in 14 proteins. Mutant genes coding for proteins carrying all possible substitutions in position 177 were constructed by site-directed mutagenesis and heterologously expressed in Escherichia coli. In total, 15 active protein variants were obtained, suggesting a relatively high tolerance of the site for the introduction of mutations. Purified protein variants were kinetically characterized by determination of specific activities with 12 halogenated substrates and steady-state kinetic parameters with two substrates. The effect of mutation on the enzyme activities varied dramatically with the structure of the substrates, suggesting that extrapolation of one substrate to another may be misleading and that a systematic characterization of the protein variants with a number of substrates is essential. Multivariate analysis of activity data revealed that catalytic activity of mutant enzymes generally increased with the introduction of small and nonpolar amino acid in position 177. This result is consistent with the phylogenetic analysis showing that glycine and alanine are the most commonly occurring amino acids in this position among haloalkane dehalogenases. The study demonstrates the advantages of using rational engineering to develop enzymes with modified catalytic properties and substrate specificities. The strategy of using site-directed mutagenesis to modify a specific entrance tunnel residue identified by structural and phylogenetic analyses, rather than combinatorial screening, generated a high percentage of viable mutants.     

Dissection of helix capping in T4 lysozyme by structural and thermodynamic analysis of six amino acid substitutions at Thr 59.

Threonine 59, a helix-capping residue at the amino terminus of the longest helix in T4 phage lysozyme, was substituted with valine, alanine, glycine, serine, asparagine, and aspartic acid. The valine, alanine, and glycine replacements were observed to be somewhat more destabilizing than serine, asparagine, and aspartic acid. The crystal structures of the different variants showed that changes in conformation occurred at the site of substitution, including Asp 61, which is nearby, as well as displacement of a solvent molecule that is hydrogen-bonded to the gamma-oxygen of Thr 59 in wild-type lysozyme. Neither the structures nor the stabilities of the mutant proteins support the hypothesis of Serrano and Fersht (1989) that glycine and alanine are better helix-capping residues than valine because a smaller-sized residue allows better hydration at the end of the helix. In the aspartic acid and asparagine replacements the substituted side chains form hydrogen bonds with the end of the helix, as does threonine and serine at this position. In contrast, however, the Asp and Asn side chains also make unusually close contacts with carbon atoms in Asp 61. This suggests a structural basis for the heretofore puzzling observations that asparagine is more frequently observed as a helix-capping residue than threonine [Richardson, J. S., & Richardson, D. C. (1988) Science 240, 1648-1652] yet Thr----Asn replacements at N-cap positions in barnase were found to be destabilizing [Serrano, L., & Fersht, A. R. (1989) Nature 342, 296-299].(ABSTRACT TRUNCATED AT 250 WORDS)     

Substitution of Met-69 by Ala or Gly in TEM-1 beta-lactamase confer an increased susceptibility to clavulanic acid and other inhibitors

In some inhibitor-resistant TEM-derived beta-lactamases, Met-69 is substituted by Leu, Ile or Val. Residue 69 is located in a region of strong structural constraints, at the beginning of H2 alpha-helix, and in the vicinity of B3 and B4 beta-strands. Analysis of the three-dimensional structure of TEM-1 beta-lactamase suggests that alteration of the substrate-binding site can be produced by changes of the size of residue 69 side chain. Met-69 was substituted by alanine or glycine in TEM-Bs beta-lactamase (a TEM-1-related enzyme) using site-directed mutagenesis. The minimum inhibitory concentrations of the mutants compared with the wild-type revealed an increased susceptibility to beta-lactamase inhibitor-beta-lactam combinations and to first-generation cephalosporins. Comparing the Met69Ala and Met69Gly beta-lactamases with TEM-Bs, K(m) constants of the mutants showed an increased affinity for most beta-lactams but the kcat for most substrates did not change substantially. Mutants also demonstrated lower IC50 for the three inhibitors (clavulanic acid, tazobactam and sulbactam). The two substitutions of the residue 69 by alanine and glycine had a noticeable effect on K(m) values of TEM-Bs beta-lactamase, and on affinity for beta-lactamase inhibitors.     

Crystal structure of cockroach allergen Bla g 2, an unusual zinc binding aspartic protease with a novel mode of self-inhibition

The crystal structure of Bla g 2 was solved in order to investigate the structural basis for the allergenic properties of this unusual protein. This is the first structure of an aspartic protease in which conserved glycine residues, in two canonical DTG triads, are substituted by different amino acid residues. Another unprecedented feature revealed by the structure is the single phenylalanine residue insertion on the tip of the flap, with the side-chain occupying the S1 binding pocket. This and other important amino acid substitutions in the active site region of Bla g 2 modify the interactions in the vicinity of the catalytic aspartate residues, increasing the distance between them to approximately 4A and establishing unique direct contacts between the flap and the catalytic residues. We attribute the absence of substantial catalytic activity in Bla g 2 to these unusual features of the active site. Five disulfide bridges and a Zn-binding site confer stability to the protein, which may contribute to sensitization at lower levels of exposure than other allergens.     

The mutability of enzyme active-site shape determinants

Investigations of enzyme action typically focus on elucidating the catalytic roles of hydrogen bonding interactions between polar active-site residues and substrate molecules. Less clear is the importance of non-hydrogen bonding contacts to enzymatic rate accelerations. To investigate the importance of such interactions in a model system, six residues that participate in van der Waals contacts with substrate glucose within the active site of Escherichia coli glucokinase were individually randomized via site-directed mutagenesis. In vivo selection in a glucokinase-deficient bacterium was employed to identify amino acid substitutions that were complicit with enzyme activity. The results suggest that small residues, such as alanine and glycine, are largely immutable, whereas larger amino acids are more tolerant of diverse substitution patterns. Surprisingly, a glucokinase variant that contains glycine in place of six non-hydrogen bonding contacts retains approximately 1% of the wild-type activity. These findings establish non-hydrogen bonding shape determinants as highly appealing targets for widespread substitution during efforts to redesign the catalytic properties of natural enzymes.     

Vibrational spectroscopy of bacteriorhodopsin mutants: evidence for the interaction of proline-186 with the retinylidene chromophore

Fourier-transform infrared difference spectroscopy has been used to study the role of the three membrane-embedded proline residues, Pro-50, Pro-91, and Pro-186, in the structure and function of bacteriorhodopsin. All three prolines were replaced by alanine and glycine; in addition, Pro-186 was changed to valine. Difference spectra were recorded for the bR----K and bR----M photoreactions of each of these mutants and compared to those of wild-type bacteriorhodopsin. Only substitutions of Pro-186 caused significant perturbations in the frequency of the C = C and C - C stretching modes of the retinylidene chromophore. In addition, these substitutions reduced bands in the amide I and II region associated with secondary structural changes and altered signals assigned to the adjacent Tyr-185. Pro-186----Val caused the largest alterations, producing a second species similar to bR548 and nearly blocking chromophore isomerization at 78 K but not at 250 K. These results are consistent with a model of the retinal binding site in which Pro-186 and Tyr-185 are located in direct proximity to the chromophore and may be involved in linking chromophore isomerization to protein structural changes. Evidence is also found that Pro-50 may be structurally active during the bR----K transition and that substitution of this residue by glycine preserves the normal protein structural changes during the photocycle.     

Structural determinants for activity of glucagon-like peptide-2

Glucagon-like peptide-2 (GLP-2) is a 33 amino acid gastrointestinal hormone that regulates epithelial growth in the intestine. Dipeptidylpeptidase IV cleaves GLP-2 at the position 2 alanine, resulting in the inactivation of peptide activity. To understand the structural basis for GLP-2 action, we studied receptor binding and activation for 56 GLP-2 analogues with either position 2 substitutions or alanine replacements along the length of the peptide. The majority of position 2 substitutions exhibited normal to enhanced GLP-2 receptor (GLP-2R) binding; in contrast, position 2 substitutions were less well tolerated in studies of receptor activation as only Gly, Ile, Pro, alpha-aminobutyric acid, D-Ala, or nor-Val substitutions exhibited enhanced GLP-2R activation. In contrast, alanine replacement at positions 5,6,17, 20, 22, 23, 25, 26, 30, and 31 led to diminished GLP-2R binding. Position 2 substitutions containing Asp, Leu, Lys, Met, Phe, Trp, and Tyr, and Ala substitutions at positions 12 and 21 exhibited normal to enhanced GLP-2R binding but greater than 75% reduction in receptor activation. D-Ala(2), Pro(2) and Gly(2), Ala(16) exhibited significantly lower EC(50)s for receptor activation than the parent peptide (p < 0.01-0.001). Circular dichroism analysis indicated that the enhanced activity of these GLP-2 analogues was independent of the alpha-helical content of the peptide. These results indicate that single amino acid substitutions within GLP-2 can confer structural changes to the ligand-receptor interface, allowing the identification of residues important for GLP-2R binding and receptor activation.     

Long range effects of amino acid substitutions in the catalytic chain of aspartate transcarbamoylase. Localized replacements in the carboxyl-terminal alpha-helix cause marked alterations in allosteric properties and intersubunit interactions.

A single alpha-helical polypeptide segment of 21 amino acids near the carboxyl terminus of the catalytic chain of aspartate transcarbamoylase from Escherichia coli has been shown recently to be important for the in vivo folding of the chains and assembly of the enzyme (Peterson, C. B., and Schachman, H. K. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 458-462). Calorimetric measurements on purified mutant enzymes showed that single amino acid replacements within this secondary structural element affect the overall thermal stability of the oligomeric enzyme and the energetics of the interactions between polypeptide chains within the holoenzyme. Studies presented here demonstrate that marked changes in cooperativity occur due to single amino acid substitutions. Replacement of Gln288 by either Ala or Glu leads to a striking increase in the Hill coefficient of the holoenzymes and a substantial increase in the aspartate concentration corresponding to one-half Vmax. In contrast, the isolated catalytic trimers harboring these same substitutions were similar in activity to the wild-type subunit, with the same affinity for aspartate as indicated by the values of Km. Substituting Ala for the only charged residue in the helix, Arg296, caused a marked reduction in enzyme activity, as well as a greatly reduced stability of the holoenzyme due to a substantial weakening of the interactions between the catalytic and regulatory subunits. A subunit exchange method was used to demonstrate the changes in interchain interactions resulting from the amino acid substitutions and to show the additional weakening upon the binding of the bisubstrate ligand, N-(phosphonacetyl)-L-aspartate, at the active sites. Taken together, the results on this series of mutant enzymes illustrate how the effects of single amino acid replacements in one element of secondary structure are propagated throughout the molecule to positions remote from the site of the substitution.     

Studies of the membrane fusion activities of fusion peptide mutants of influenza virus hemagglutinin.

Influenza virus hemagglutinin (HA) fuses membranes at endosomal pH by a process which involves extrusion of the NH2-terminal region of HA2, the fusion peptide, from its buried location in the native trimer. We have examined the amino acid sequence requirements for a functional fusion peptide by determining the fusion capacities of site-specific mutant HAs expressed by using vaccinia virus recombinants and of synthetic peptide analogs of the mutant fusion peptides. The results indicate that for efficient fusion, alanine can to some extent substitute for the NH2-terminal glycine of the wild-type fusion peptide but that serine, histidine, leucine, isoleucine, or phenylalanine cannot. In addition, mutants containing shorter fusion peptides as a result of single amino acid deletions are inactive, as is a mutant containing an alanine instead of a glycine at HA2 residue 8. Substitution of the glycine at HA2 residue 4 with an alanine increases the pH of fusion, and valine-for-glutamate substitutions at HA2 residues 11 and 15 are without effect. We confirm previous reports on the need for specific HAo cleavage to generate functional HAs, and we show that both inappropriately cleaved HA and mutant HAs, irrespective of their fusion capacities, upon incubation at low pH undergo the structural transition required for fusion.