Induced expression of adipophilin mRNA in human macrophages stimulated with oxidized low-density lipoprotein and in atherosclerotic lesions

The RNase activity of barnase mutants obtained by the permutation of modules or secondary structure units was investigated. Four of the 45 mutants had weak but distinct RNase activity, and they had unique optimum pHs and temperatures like natural enzymes. One of the active mutants had an ordered conformation, but the others did not. An active mutant having disordered conformation formed an ordered conformation in the presence of GMP, which is an inhibitor of this mutant. These results indicate that the amino acid sequences derived from barnase have sufficient plasticity to be rearranged into different proteins with basal enzymatic properties.     

The role of the GX9GX3G motif in the gating of high voltage-activated Ca2+ channels

The putative hinge point revealed by the crystal structure of the MthK potassium channel is a glycine residue that is conserved in many ion channels. In high voltage-activated (HVA) Ca(V) channels, the mid-S6 glycine residue is only present in IS6 and IIS6, corresponding to G422 and G770 in Ca(V)1.2. Two additional glycine residues are found in the distal portion of IS6 (Gly(432) and Gly(436) in Ca(V)1.2) to form a triglycine motif unique to HVA Ca(V) channels. Lethal arrhythmias are associated with mutations of glycine residues in the human L-type Ca(2+) channel. Hence, we undertook a mutational analysis to investigate the role of S6 glycine residues in channel gating. In Ca(V)1.2, alpha-helix-breaking proline mutants (G422P and G432P) as well as the double G422A/G432A channel did not produce functional channels. The macroscopic inactivation kinetics were significantly decreased with Ca(V)1.2 wild type > G770A > G422A congruent with G436A > G432A (from the fastest to the slowest). Mutations at position Gly(432) produced mostly nonfunctional mutants. Macroscopic inactivation kinetics were markedly reduced by mutations of Gly(436) to Ala, Pro, Tyr, Glu, Arg, His, Lys, or Asp residues with stronger effects obtained with charged and polar residues. Mutations within the distal GX(3)G residues blunted Ca(2+)-dependent inactivation kinetics and prevented the increased voltage-dependent inactivation kinetics brought by positively charged residues in the I-II linker. In Ca(V)2.3, mutation of the distal glycine Gly(352) impacted significantly on the inactivation gating. Altogether, these data highlight the role of the GX(3)G motif in the voltage-dependent activation and inactivation gating of HVA Ca(V) channels with the distal glycine residue being mostly involved in the inactivation gating.     

Foldability, enzymatic activity, and interacting ability of barnase mutants obtained by permutation of secondary structure units

Barnase, a well-characterized ribonuclease, has been decomposed into six modules (M1-M6) or secondary structure units (S1-S6). We have studied the foldability and activity of the barnase mutants obtained by permutation of the four internal modules (M2-M5) or secondary structure units (S2-S5) to investigate whether permutation of these building blocks is a useful way to create foldable and/or functional proteins. In this study, we found that one of the secondary structure unit mutants was expressed in Escherichia coli only when His102 was substituted by alanine, which is a catalytic residue of wild-type barnase. This mutant (S2354H102A) had ordered conformations, which unfolded cooperatively during urea-induced unfolding experiments. S2354H102A interacted with other barnase mutants to show a distinct RNase activity, although its own activity was quite weak. This interaction was specific, because S2354H102A interacted with only barnase mutants having His 102 and certain orders of the secondary structure units giving a distinct RNase activity. These results suggest that secondary structure units permuted in barnase mutants maintain their intrinsic "interacting ability" that is used for the folding of wild-type barnase, and the units can form certain conformations that complement those of the appropriate counterparts. Seven of 23 secondary structure unit mutants and only 2 of 23 module mutants had RNase activity. On the basis of the results of analyses of foldability and RNase activity of the mutants performed in this and previous studies, we conclude that secondary structure units are more suitable than modules as building blocks to create novel foldable and/or functional proteins in the case of barnase.     

A mini-protein designed by removing a module from barnase: molecular modeling and NMR measurements of the conformation.

A globular domain can be decomposed into compact modules consisting of contiguous 10-30 amino acid residues. The correlation between modules and exons observed in different proteins suggests that each module was encoded by an ancestral exon and that modules were combined into globular domains by exon fusion. Barnase is a single domain RNase consisting of 110 amino acid residues and was decomposed into six modules. We designed a mini-protein by removing the second module, M2, from barnase in order to gain an insight into the structural and functional roles of the module. In the molecular modeling of the mini-protein, we evaluated thermodynamic stability and aqueous solubility together with mechanical stability of the model. We chemically synthesized a mini-barnase with (15)N-labeling at 10 residues, whose corresponding residues in barnase are all found in the region around the hydrophobic core. Circular dichroism and NMR measurements revealed that mini-barnase takes a non-random specific conformation that has a similar hydrophobic core structure to that of barnase. This result, that a module could be deleted without altering the structure of core region of barnase, supports the view that modules act as the building blocks of protein design.     

Exploring the role of a glycine cluster in cold adaptation of an alkaline phosphatase.

In an effort to explore the role of glycine clusters on the cold adaptation of enzymes, we designed point mutations aiming to alter the distribution of glycine residues close to the active site of the psychrophilic alkaline phosphatase from the Antarctic strain TAB5. The mutagenesis targets were residues Gly261 and Gly262. The replacement of Gly262 by Ala resulted in an inactive enzyme. Substitution of Gly261 by Ala resulted to an enzyme with lower stability and increased energy of activation. The double mutant G261A/Y269A designed on the basis of side-chain packing criteria from a modelled structure of the enzyme resulted in restoration of the energy of activation to the levels of the native enzyme and in an increased stability compared to the mutant G261A. It seems therefore, that the Gly cluster in combination with its structural environment plays a significant role in the cold adaptation of the enzyme.     

Activation of factor V during intrinsic and extrinsic coagulation. Inhibition by heparin, hirudin and D-Phe-Pro-Arg-Ch2Cl.

Ser130, Asp131 and Asn132 ('SDN') are highly conserved residues in class A beta-lactamases forming one wall of the active-site cavity. All three residues of the SDN loop in Streptomyces albus G beta-lactamase were modified by site-directed mutagenesis. The mutant proteins were expressed in Streptomyces lividans, purified from culture supernatants and their kinetic parameters were determined for several substrates. Ser130 was substituted by Asn, Ala and Gly. The first modification yielded an almost totally inactive protein, whereas the smaller-side-chain mutants (A and G) retained some activity, but were less stable than the wild-type enzyme. Ser130 might thus be involved in maintaining the structure of the active-site cavity. Mutations of Asp131 into Glu and Gly proved to be highly detrimental to enzyme stability, reflecting significant structural perturbations. Mutation of Asn132 into Ala resulted in a dramatically decreased enzymic activity (more than 100-fold) especially toward cephalosporin substrates, kcat. being the most affected parameter, which would indicate a role of Asn132 in transition-state stabilization rather than in ground-state binding. Comparison of the N132A and the previously described N132S mutant enzymes underline the importance of an H-bond-forming residue at position 132 for the catalytic process.     

The utility of molecular dynamics simulations for understanding site-directed mutagenesis of glycine residues in biotin carboxylase

Biotin carboxylase from Escherichia coli catalyzes the ATP-dependent carboxylation of biotin and is one component of the multienzyme complex acetyl-CoA carboxylase, which catalyzes the committed step in long-chain fatty acid synthesis. Comparison of the crystal structures of biotin carboxylase in the absence and presence of ATP showed a central B-domain closure when ATP was bound. Peptidic NH groups from two active site glycine residues (Gly165 and Gly166) that form hydrogen bonds to the phosphate oxygens of ATP were postulated to act as a "trigger" for movement of the B-domain. The function of these two glycine residues in the catalytic mechanism was studied by disruption of the hydrogen bonds using site-directed mutagenesis. Both single (G165V) and (G166V) and double mutants (G165V-G166V) were constructed. The mutations did not affect the maximal velocity of a partial reaction, the bicarbonate-dependent ATPase activity. This suggests that the peptidic NH groups of Gly165 and Gly166 are not triggers for domain movement. However, the K(m) values for ATP for each of the mutants was increased over 40-fold when compared with wild-type indicating the peptidic NH groups of Gly165 and Gly166 play a role in binding ATP. Consistent with ATP binding, the maximal velocity for the biotin-dependent ATPase activity (i.e. the complete reaction) was decreased over 100-fold suggesting the mutations have misaligned the reactants for optimal catalysis. Molecular dynamics studies confirm perturbation of the hydrogen bonds from the mutated residues to ATP, whereas the double mutant exhibits antagonistic effects such that hydrogen bonding from residues 165 and 166 to ATP is similar to that in the wild-type. Consistent with the site-directed mutagenesis results the molecular dynamics studies show that ATP is misaligned in the mutants.     

Essential domain motions in barnase revealed by MD simulations

The wealth of data accumulated on the bacterial ribonuclease barnase is complemented by molecular dynamics trajectories starting from four different experimental structures and covering a total of >10 ns. Using principal component analysis, the simulations are interpreted in view of dynamic domains and hinges promoting relative motions of these domains. Two domains with residues 7-22 and 52-108 for the first domain and residues 25-51 for the second domain were consistently observed. Hinge regions consist primarily of Tyr24, Ser50, Ile51, and Gly52. Earlier mutation studies have demonstrated that the residues of the hinge regions play essential roles for the stability and activity of barnase. The domain motions are correlated to inter-domain interactions involving functionally important active site residues, such as Lys27 and Glu73. A model is presented that combines the observation of dynamic domains and their motions with the extensive mutation data from the literature. Enthalpic energy contributions originating from specific inter-domain interactions as well as entropic energy contributions due to the domain motions are discussed in the frame of this model and compared with destabilization energies measured for corresponding mutants.     

Mutational analysis of the RNase-like domain in subunit 2 of fission yeast RNA polymerase II

Local sequence similarity exists between the subunit 2 of eukaryotic RNA polymerases II and the barnase-type bacterial RNases. The RNase-like domain from the Rpb2 ofSchizosaccharomyces pombe was expressed inEscherichia coli as a GST fusion protein and examined for its RNase activity. When the GST fusion protein was incubated in vitro with³²P-labeled RNA, the RNA degradation activity was less than 0.1%, if any, of the level of synthetic barnase. In order to check the in vivo function of this region, we constructed two mutantrpb2 alleles,rpb2 ^E357A andrpb2 ^H3a6L , each carrying a single amino acid substitution at the site correponding to one of the three essential amino acid residues forming the catalytic site in barnase (mutation of barnase at the corresponding sites results in complete loss of RNase activity) and five other mutantrpb2 alleles, each carrying a single mutation at various positions within the RNase-like domain but outside the putative catalytic site for RNase activity. When these mutantrpb2 alleles were expressed in anrpb2-disruptedS. pombe strain, all the mutants grew as well as the wild-type parent and did not show any clear defective phenotypes. These results suggest either that the RNase-like domain in Rpb2 does not function as an RNase in vivo or that the RNase activity of this domain, if present at all, is not essential for cell growth.     

A new member of the bacterial ribonuclease inhibitor family from Saccharopolyspora erythraea

We have identified Sti, the gene of a ribonuclease inhibitor from Saccharopolyspora erythraea, by using a T7 phage display system. A specific phage has been isolated from a genome library by a biopanning procedure, using RNase Sa3, a ribonuclease from Streptomyces aureofaciens, as bait. Sti, a protein of 121 amino acid residues, with molecular mass 13059 Da, is a homolog of barstar and other microbial ribonuclease inhibitors. To overexpress its gene in Escherichia coli, we optimized the secondary structure of its mRNA by introducing a series of silent mutations. Soluble protein was isolated and purified to homogeneity. Inhibition constants of complex of Sti and RNase Sa3 or barnase were determined at pH 7 as 5 x 10(-12) or 7 x 10(-7), respectively.     

Pivotal role of the glycine-rich TM3 helix in gating the MscS mechanosensitive channel

The crystal structure of an open form of the Escherichia coli MscS mechanosensitive channel was recently solved. However, the conformation of the closed state and the gating transition remain uncharacterized. The pore-lining transmembrane helix contains a conserved glycine- and alanine-rich motif that forms a helix-helix interface. We show that introducing 'knobs' on the smooth glycine face by replacing glycine with alanine, and substituting conserved alanines with larger residues, increases the pressure required for gating. Creation of a glycine-glycine interface lowers activation pressure. The importance of residues Gly104, Ala106 and Gly108, which flank the hydrophobic seal, is demonstrated. A new structural model is proposed for the closed-to-open transition that involves rotation and tilt of the pore-lining helices. Introduction of glycine at Ala106 validated this model by acting as a powerful suppressor of defects seen with mutations at Gly104 and Gly108.     

Characterization of two independent amino acid substitutions that disrupt the DNA repair functions of the yeast Apn1

The members of the Endo IV family of DNA repair enzymes, including Saccharomyces cerevisiae Apn1 and Escherichia coli endonuclease IV, possess the capacity to cleave abasic sites and to remove 3'-blocking groups at single-strand breaks via apurinic/apyrimidinic (AP) endonuclease and 3'-diesterase activities, respectively. In addition, Endo IV family members are able to recognize and incise oxidative base damages on the 5'-side of such lesions. We previously identified eight amino acid substitutions that prevent E. coli endonuclease IV from repairing damaged DNA in vivo. Two of these substitutions were glycine replacements of Glu145 and Asp179. Both Glu145 and Asp179 are among nine amino acid residues within the active site pocket of endonuclease IV that coordinate the position of a trinuclear Zn cluster required for efficient phosphodiester bond cleavage. We now report the first structure-function analysis of the eukaryotic counterpart of endonuclease IV, yeast Apn1. We show that glycine substitutions at the corresponding conserved amino acid residues of yeast Apn1, i.e., Glu158 and Asp192, abolish the biological function of this enzyme. However, these Apn1 variants do not exhibit the same characteristics as the corresponding E. coli mutants. Indeed, the Apn1 Glu158Gly mutant, but not the E. coli endonuclease IV Glu145Gly mutant, is able to bind DNA. Moreover, Apn1 Asp192Gly completely lacks enzymatic activity, while the activity of the E. coli counterpart Asp179Gly is reduced by approximately 40-fold. The data suggest that although yeast Apn1 and E. coli endonuclease IV exhibit a high degree of structural and functional similarity, differences exist within the active site pockets of these two enzymes.     

Cumulative stabilizing effects of glycine to alanine substitutions in Bacillus subtilis neutral protease.

Oligonucleotide-directed mutagenesis has been used to replace glycine residues by alanine in neutral protease from Bacillus subtilis. One Gly to Ala substitution (G147A) was located in a helical region of the protein, while the other (G189A) was in a loop. The effects of mutational substitutions on the functional, conformational and stability properties of the enzyme have been investigated using enzymatic assays and spectroscopic measurements. Single substitutions of both Gly147 and Gly189 with Ala residues affect the enzyme kinetic properties using synthetic peptides as substrates. When Gly replacements were concurrently introduced at both positions, the kinetic characteristics of the double mutant were roughly intermediate between those of the two single mutants, and similar to those of the wild-type protease. Both mutants G147A and G189A were found to be more stable towards irreversible thermal inactivation/unfolding than the wild-type species. Moreover, the stabilizing effect of the Gly to Ala substitution was roughly additive in the double mutant G147A/G189A, which shows a 3.2 degrees C increase in Tm with respect to the wild-type protein. These findings indicate that the Gly to Ala substitution can be used as a strategy to stabilize globular proteins. The possible mechanisms of protein stabilization are also discussed.     

Effects of two glycine residues in positions 13 and 17 of pleurocidin on structure and bacterial cell selectivity

Pleurocidin (Ple), a 25-residue alpha-helical antimicrobial peptide, isolated from skin mucosa of the winter flounder, shows potent bacterial cell selectivity. In this study, the effect of two glycine residues in positions 13 and 17 of Ple on structure and bacterial cell selectivity was investigated by Gly-->Ala substitution. Ala-substitution (Gly(13, 17)-->Ala, Gly13-->Ala and Gly17-->Ala) in positions 13 and 17 of Ple did not induce a significant change in antibacterial activity, but increased hemolytic activity. Both Gly(13, 17)-->Ala and Gly17-->Ala substitution did not cause a remarkable change in alpha-helical content in SDS micelles, while Gly(13, 17)-->Ala substitution caused a drastic increase in alpha-helical content. These results suggest that the hinge region from Gly13 to Gly17 of Ple is assumed to provide its conformational flexibility and bacterial cell selectivity.     

Consequences of single-site mutations in the intestinal fatty acid binding protein

The intestinal fatty acid binding protein (IFABP) is a small (15 kDa) protein consisting mostly of 10 antiparallel beta-strands (A-J) and a small helical region that serves as a portal for the ligand. Two beta-sheet structures (strands A-E and F-J) surround a cavity into which the ligand binds. In this work, we investigated how changes in the side chains of specific residues are propagated through the structure. To determine what these changes were and how they relate to changes in stability, (15)N chemical shift perturbations were measured and compared to those of the wild-type protein. Seven mutations, five of which change either valine or leucine to glycine, have been examined. All these mutants were less stable than wild-type IFABP, suggesting some structural changes. For five of the mutants, the data suggest that destabilization of a small region of the protein propagates throughout the structure, resulting in an overall decrease in stability. In two (Leu38Gly and Leu89Gly), the loss of cooperativity in the equilibrium denaturation curves suggests that the destabilization of one region may not be transmitted to other regions in a cooperative manner. It is shown that the effect of mutating hydrophobic residues is much greater than that observed upon mutation of a solvent-exposed polar residue.     

Mechanism of protein folding

The high structural resolution of the main transition states for the formation of native structure for the six small proteins of which Phi-values for a large set of mutants have become available, barstar, barnase, chymotrypsin inhibitor 2, Arc repressor, the src SH3 domain, and a tetrameric p53 domain reveals that for the first 5 of these proteins: (1) Residues that belong to regular secondary structure have a significantly larger average fraction of native structural consolidation than residues in loops; (2) on the other hand, secondary and tertiary structures have built up to the same degree, or at least a high degree, but nonuniformly distributed over the molecule; (3) the most consolidated parts of each protein molecule in the transition state cluster together, and these clusters contain a significantly higher percentage of residues that belong to regular secondary structure than the rest of the molecule. These observations further reconcile the framework model with the nucleation-condensation mechanism for folding: The amazing speed of protein folding can be understood as caused by the catalytic effect of the formation of clusters of residues which have particularly high preferences for the early formation of regular secondary structure in the presence of significant amounts of tertiary structure interactions.     

Site-directed mutagenesis of human nucleoside triphosphate diphosphohydrolase 3: the importance of conserved glycine residues and the identification of additional conserved protein motifs in eNTPDases.

Glycine residues are recognized as important structural determinants in nucleotide-binding domains of many enzymes. The functional significance of seven glycine residues invariant in all 22 eNTPDase sequences was therefore examined. Glycine-to-alanine mutants of eNTPDase3 were analyzed for nucleotidase activities and tertiary and quaternary structure changes. Mutations G98A and G183A had modest effects on ATPase and ADPase activities. The G141A mutation resulted in 4- to 5-fold decreased nucleotidase activity, while the G222A mutation decreased ATPase activity 20-fold, and ADPase activity 6-fold. Unlike the other five glycine mutants, the G263A and G462A mutations caused significant loss of nucleotidase activity which was observed concomitant with lower protein expression levels, large-scale changes in tertiary and quaternary protein structure, and decreased trafficking to the plasma membrane. Thus, these data identify glycine residues that are essential for enzymatic activity and the tertiary and quaternary structure of eNTPDase3. Further, two additional conserved regions in the eNTPDases are identified, apyrase conserved regions ACR1a and ACR4a, which may be involved in phosphate binding/hydrolysis and protein folding, respectively.     

Accommodation of insertion mutations on the surface and in the interior of staphylococcal nuclease.

Alignment of homologous amino acid sequences reveals that insertion mutations are fairly common in evolution. Hitherto, the structural consequences of insertion mutations on the surface and in the interior of proteins of known structures have received little attention. We report here the high-resolution X-ray crystal structures of 2 site-directed insertion mutants of staphylococcal nuclease. The structure of the first insertion mutant, in which 2 glycine residues were inserted on the protein surface in the amino-terminal beta-strand, has been solved to 1.70 A resolution and refined to a crystallographic R value of 0.182. The inserted residues are accommodated in a special 3-residue beta-bulge. A bridging water molecule in the newly created cavity satisfies the hydrogen bonding requirements of the beta-sheet by forming a bifurcated hydrogen bond to 1 beta-strand, and a single hydrogen bond to the other beta-strand. The second insertion mutant contains a single leucine residue inserted at the end of the third beta-strand. The structure was solved to 2.0 A resolution and refined to a final R value of 0.196. The insertion is accommodated in a register shift that changes the conformation of the flexible loop portion of the molecule, relaxing and widening the omega turn. This structural alteration results in changes in position and coordination of a bound calcium ion important for catalysis. These structures illustrate important differences in how amino acid insertions are accommodated: as localized bulges, and as extensive register shifts.     

Engineering photocycle dynamics. Crystal structures and kinetics of three photoactive yellow protein hinge-bending mutants.

Crystallographic and spectroscopic analyses of three hinge-bending mutants of the photoactive yellow protein are described. Previous studies have identified Gly(47) and Gly(51) as possible hinge points in the structure of the protein, allowing backbone segments around the chromophore to undergo large concerted motions. We have designed, crystallized, and solved the structures of three mutants: G47S, G51S, and G47S/G51S. The protein dynamics of these mutants are significantly affected. Transitions in the photocycle, measured with laser induced transient absorption spectroscopy, show rates up to 6-fold different from the wild type protein and show an additive effect in the double mutant. Compared with the native structure, no significant conformational differences were observed in the structures of the mutant proteins. We conclude that the structural and dynamic integrity of the region around these mutations is of crucial importance to the photocycle and suggest that the hinge-bending properties of Gly(51) may also play a role in PAS domain proteins where it is one of the few conserved residues.     

Disulfide-bond formation in the H+-pyrophosphatase of Streptomyces coelicolor and its implications for redox control and enzyme structure

Redox control of disulfide-bond formation in the H+-pyrophosphatase of Streptomyces coelicolor was investigated using cysteine mutants expressed in Escherichia coli. The wild-type enzyme, but not a cysteine-less mutant, was reversibly inactivated by oxidation. To determine the residues involved in oxidative inactivation, different cysteine residues were replaced. Analysis with a cysteine-modifying reagent revealed that the formation of a disulfide bond between cysteines 253 and 621 was responsible for enzyme inactivation. This result suggests that residues in different cytoplasmic loops are close to each other in the tertiary structure. Both cysteine residues are conserved in K+-independent (type II) H+-pyrophosphatases.