Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.31.1 (micrococcal nuclease)
 2,818 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Specific side-by-side interactions between transmembrane alpha-helices may be important in the assembly and function of integral membrane proteins. We describe a system for the genetic and biophysical analysis of these interactions. The transmembrane alpha-helical domain of interest is fused to the C-terminus of staphylococcal nuclease. The resulting chimera can be expressed at high levels in Escherichia coli and is readily purified. In our initial application we study the single transmembrane alpha-helix of human glycophorin A (GpA), thought to mediate the SDS-stable dimerization of this protein. The resulting chimera forms a dimer in SDS, which is disrupted upon addition of a peptide corresponding to the transmembrane domain of GpA. Deletion mutagenesis has been used to delineate the minimum transmembrane domain sufficient for this behavior. Site-specific mutagenesis shows that a methionine residue, previously implicated as a potential interfacial residue, can be replaced with other hydrophobic residues without disrupting dimerization. By contrast, rather conservative substitutions at a valine on a different face of the alpha-helix disrupt dimerization, suggesting a high degree of specificity in the helix-helix interactions. This approach allows the interface between interacting helices to be defined.
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PMID:Glycophorin A dimerization is driven by specific interactions between transmembrane alpha-helices. 156 3

In order to quantitate the contributions of the polar, uncharged amino acids to the stability of the native state of staphylococcal nuclease, each of the 13 alanines, 9 glycines, 9 threonines, 6 prolines, 6 glutamines, 6 asparagines, and 3 serines was substituted, either with both alanine and glycine or with 1 of these 2 amino acids plus valine. For each mutant, the stability to reversible denaturation (delta GH2O) was quantitated by determining the Kapp for this reaction as a function of guanidine hydrochloride concentration. In addition, the parameter mGuHCl (= d(delta G)/d[GuHCl]) was calculated from the data. To identify the local structural features responsible for the relatively large and variable changes in delta GH2O and mGuHCl observed for the same type of substitution at different locations in nuclease, statistical correlations were sought between delta GH2O, mGuHCl, and a number of descriptors of the local structure. As with substitutions of the large hydrophobic amino acids [Shortle, D., Stites, W. E., & Meeker, A. K. (1990) Biochemistry 29, 8033-8041], mutation of polar, uncharged residues to Gly leads to a change in stability that, on average, correlates well with the degree to which the wild-type residue is buried. This correlation is especially significant for threonine, an amino acid with both polar and hydrophobic character, but is not demonstrated for the more typically hydrophobic residue alanine. As reported in the previous study of alanine/glycine substitutions of hydrophobic residues, a significant correlation between changes in stability and changes in the value of mGuHCl is again observed, strengthening the conclusion that the putative structural changes in the denatured state which lead to increases or decreases in mGuHCl are responsible for a significant fraction of the stability loss for an average mutant. The existence of this correlation is consistent with the denatured state of wild-type staphylococcal nuclease having evolved to a relatively high free energy via optimization of a balance between a maximal exposure of hydrophobic surface and a minimal gain in chain entropy. On average, mutations are less stable in proportion to the extent of which they perturb this balance. A new and puzzling correlation is reported between the extent of buriedness of a residue in the wild-type native state versus the difference in mGuHCl between the Ala mutation and the Gly mutation at that position.
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PMID:Contributions of the polar, uncharged amino acids to the stability of staphylococcal nuclease: evidence for mutational effects on the free energy of the denatured state. 161 Aug 20

The crystal structure of the staphylococcal nuclease mutant V66K, in which valine 66 is replaced by lysine, has been solved at 1.97 A resolution. Unlike lysine residues in previously reported protein structures, this residue appears to bury its side-chain in the hydrophobic core without salt bridging, hydrogen bonding or other forms of electrostatic stabilization. Solution studies of the free energy of denaturation, delta GH2O, show marked pH dependence and clearly indicate that the lysine residue must be deprotonated in the folded state. V66K is highly unstable at neutral pH but only modestly less stable than the wild-type protein at high pH. The pH dependence of stability for V66K, in combination with similar measurements for the wild-type protein, allowed determination of the pKa values of the lysine in both the denatured and native forms. The epsilon-amine of this residue has a pKa value in the denatured state of 10.2, but in the native state it must be 6.4 or lower. The epsilon-amine is thus deprotonated in the folded molecule. These values enabled an estimation of the epsilon-amine's relative change in free energy of solvation between solvent and the protein interior at 5.1 kcal/mol or greater. This implies that the value of the dielectric constant of the protein interior must be less than 12.8. Lysine is usually found with the methylene groups of its side-chain partly buried but is nevertheless considered a hydrophilic surface residue. It would appear that the high pKa value of lysine, which gives it a positive charge at physiological pH, is the primary reason for its almost exclusive confinement to the surface proteins. When deprotonated, this amino acid type can be fully incorporated into the hydrophobic core.
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PMID:In a staphylococcal nuclease mutant the side-chain of a lysine replacing valine 66 is fully buried in the hydrophobic core. 192 Apr 20

To quantitate the contributions of the large hydrophobic residues in staphylococcal nuclease to the stability of its native state, single alanine and glycine substitutions were constructed by site-directed mutagenesis for each of the 11 leucine, 9 valine, 7 tyrosine, 5 isoleucine, 4 methionine, and 3 phenylalanine residues. In addition, each isoleucine was also mutated to valine. The resulting collection of 83 mutant nucleases was submitted to guanidine hydrochloride denaturation using intrinsic tryptophan fluorescence to monitor the equilibrium constant between the native and denatured states. From analysis of these data, each mutant protein's stability to reversible denaturation (delta GH2O) and sensitivity to guanidine hydrochloride (mGuHCl or d(delta G)/d[GuHCl]) were obtained. Four unexpected trends were observed. (1) A striking bipartite distribution was found for sites of mutations that altered mGuHCl: mutations that increased this parameter only involved residues that contribute side chains to the major hydrophobic core centered around a five-strand beta-barrel, whereas mutations that caused mGuHCl to decrease clustered around a second, smaller and less well-defined hydrophobic core. (2) The average stability loss for mutants in each of the six residue classes was 2-3 times greater than that estimated on the basis of the free energy of transfer of the hydrophobic side chain from water to n-octanol. (3) The magnitude of the stability loss on substituting Ala or Gly for a particular type of amino acid varied extensively among the different sites of its occurrence in nuclease, indicating that the environment surrounding a specific residue determines how large a stability contribution its side chain will make.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Contributions of the large hydrophobic amino acids to the stability of staphylococcal nuclease. 226 61

We report high-resolution 13C and 15N NMR spectra of crystalline staphylococcal nuclease (Nase) complexed to thymidine 3',5'-diphosphate and Ca2+. High sensitivity and resolution are obtained by applying solid-state NMR techniques--high power proton decoupling and cross-polarization magic angle sample spinning (CPMASS)--to protein samples that have been efficiently synthesized and labeled by an overproducing strain of Escherichia coli. A comparison of CPMASS and solution spectra of Nase labeled with either [methyl-13C]methionine or [15N]valine shows that the chemical shifts in the crystalline and solution states are virtually identical. This result is strong evidence that the protein conformations in the solution and crystalline states are nearly the same. Because of the close correspondence of the crystal and solution chemical shifts, sequential assignments obtained in solution apply to the crystal spectra. It should therefore be possible to study the molecular structure and dynamics of many sequentially assigned atomic sites in Nase crystals. Similar experiments are applicable to the growing number of proteins that can be obtained from efficient expression systems.
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PMID:Comparison of the solution and crystal structures of staphylococcal nuclease with 13C and 15N chemical shifts used as structural fingerprints. 341 1

Hydrogen bonds are a ubiquitous feature of protein structures, yet there is great uncertainty about the energetic contribution of hydrogen bonding to protein stability. This study addresses this question by making a series of single substitution mutations in the model protein staphylococcal nuclease. These mutants have had a residue capable of participating in hydrogen bonding either removed or introduced. The variants we have investigated are as follows: nine valines substituted with threonine and serine; eight threonines converted to valine, serine, and cysteine; and seven tyrosines replaced by phenylalanine and leucine. The stabilities of these 56 mutant proteins were determined by titration with guanidine hydrochloride using fluorescence as a probe of structure. In general, it was found that the stability effects of removing a hydrogen bonding residue and replacing it with a nonbonding residue were relatively small. This was true even in the case of buried residues participating in hydrogen bonds, where the substituted residue leaves an unfulfilled hydrogen bond in the hydrophobic core. In contrast, introducing a hydrogen bonding residue in place of a nonbonding residue was generally more costly energetically. A wide variability in the cost of burying a hydroxyl was observed, but this does not seem to be due to differences in hydrogen bonding. The overall energetic contribution of various wild-type hydrogen bonding interactions was evaluated as being favorable. A range of energies from approximately 1.5 to 4.0 kcal/mol was estimated for the contribution of these interactions to the stability of the native state.
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PMID:Energetic contribution of side chain hydrogen bonding to the stability of staphylococcal nuclease. 757 91

Information about molecular structure and dynamics can potentially be obtained by studying dipole-dipole and chemical-shift anisotropy (CSA) auto-correlation and dipole-CSA cross-correlation effects in high-resolution NMR spectra. Equations for the lineshapes of the HN multiplet in the fragment- 15NH-CH- as a function of NH-CH dihedral angle are derived by including these effects within the framework of the Redfield treatment of relaxation. To test the utility of the theoretical results, 1H[15N] HSQC proton lineshape data for a variant of the enzyme staphylococcal nuclease in which all valine residues are labeled with 15N have been analyzed to obtain the conformational angle (phi) between the N-H and adjacent C-H bonds. The results are generally in good agreement with values of phi obtained from crystal structure data. Considerations in the further development of the analysis of the lineshape of the HN multiplet for experimental determinations of phi are discussed.
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PMID:Cross-correlation effects on NMR lineshapes and peptide conformation. 855 36

To examine the importance of side chain packing to protein stability, each of the 11 leucines in staphylococcal nuclease was substituted with isoleucine and valine. The nine valines were substituted with leucine and isoleucine, while the five isoleucines, previously substituted with valine, were substituted with leucine and methionine. These substitutions conserve the hydrophobic character of these side chains but alter side chain geometry and, in some cases, size. In addition, eight threonine residues, previously substituted with valine, were substituted with isoleucine to test the importance of packing at sites normally not occupied by a hydrophobic residue. The stabilities of these 58 mutant proteins were measured by guanidine hydrochloride denaturation. To the best of our knowledge, this is the largest library of single packing mutants yet characterized. As expected, repacking stability effects are tied to the degree of side chain burial. The average energetic cost of moving a single buried methyl group was 0.9 kcal/mol, albeit with a standard deviation of 0.8 kcal/mol. This average is actually slightly greater than the value of 0.7-0.8 kcal/mol estimated for the hydrophobic transfer energy of a methylene from octanol to water. These results appear to indicate that van der Waals interactions gained from optimal packing are at least as important in stabilizing the native state of proteins as hydrophobic transfer effects.
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PMID:Energetics of side chain packing in staphylococcal nuclease assessed by exchange of valines, isoleucines, and leucines. 1170 91

All 44 possible double mutant permutations of isoleucine, leucine, and valine were constructed in 11 pairings of six sites in the core of staphylococcal nuclease. The stabilities of these mutants were determined by guanidine hydrochloride denaturation. Comparison of the stabilities of all double mutants with those expected from addition of the corresponding single mutants showed that the effects of the two single mutations are energetically independent of each other in 30 of the double mutants. However, a substantial minority, 14, of the double mutants have stability effects that are not additive. In these cases, it appears that direct van der Waals contacts between the two side chains are present. The requirement of direct van der Waals contact for the interdependence of mutational stability effects is somewhat surprising in light of results previously reported by others. In addition, it was found that double mutants that did not alter or lower the overall number of atoms in the core and that showed nonadditive behavior were more stable than expected from addition of the effects of the corresponding single mutants. A net increase in the number of atoms in the core usually, but not always, resulted in a mutant that was less stable than expected. In contrast to previous staphylococcal nuclease double mutants, energetically significant changes to the denatured state do not appear to be occurring in these packing mutants. These conclusions imply that attempts to engineer protein stability based on single mutant data will be generally successful if overall core size is preserved and if residues are not in van der Waals contact.
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PMID:Energetics of side chain packing in staphylococcal nuclease assessed by systematic double mutant cycles. 1170 92

The energy derived from optimized van der Waals interactions in closely packed, folded proteins has been proposed to be of similar energetic magnitude to hydrophobicity in stabilizing the native state. If packing is this energetically important, it should influence the evolution of protein core sequences. To test this hypothesis, the occurrence of various amino acid side chains in the major hydrophobic core of staphylococcal nuclease and 42 homologous proteins was determined. Most such positions in this protein family are usually isoleucine, leucine, or valine. Previously we have constructed and measured the stabilities of 12 single, 44 double, 64 triple, and 32 quadruple mutants, representing all possible permutations of these three side chains at two overlapping sets of four positions in the core of staphylococcal nuclease. The stabilities and interaction energies of those mutants with various combinations of the most common, or consensus, sequence were compared to the stabilities of all other mutants. Mutants which had the consensus side-chain combinations were not necessarily the most stable, but usually were found to have the best interaction energies. In other words, these proteins were far more stable than would be predicted from simply summing the observed energetic effects of the component single mutations, apparently reflecting particularly favorable packing interactions that are possible for the most common side chains. An additional 12 mutants which tested possible alternate explanations of the results were constructed. The stabilities and interaction energies of these mutants also support the conclusion that packing is a crucial determinant guiding the sequence evolution of protein cores.
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PMID:Packing is a key selection factor in the evolution of protein hydrophobic cores. 1173 10


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