The structure and function of omega loop A replacements in cytochrome c.

The structural and functional consequences of replacing omega-loop A (residues 18-32) in yeast iso-1-cytochrome c with the corresponding loop of Rhodospirillum rubrum cytochrome c2 have been examined. The three-dimensional structure of this loop replacement mutant RepA2 cytochrome c, and a second mutant RepA2(Val 20) cytochrome c in which residue 20 was back substituted to valine, were determined using X-ray diffraction techniques. A change in the molecular packing is evident in the RepA2 mutant protein, which has a phenylalanine at position 20, a residue considerably larger than the valine found in wild-type yeast iso-1-cytochrome c. The side chain of Phe 20 is redirected toward the molecular surface, altering the packing of this region of omega-loop A with the hydrophobic core of the protein. In the RepA2(Val 20) structure, omega-loop A contains a valine at position 20, which restores the original wild-type packing arrangement of the hydrophobic core. Also, as a result of omega-loop A replacement, residue 26 is changed from a histidine to asparagine, which results in displacements of the main-chain atoms near residue 44 to which residue 26 is hydrogen bonded. In vivo studies of the growth rate of the mutant strains on nonfermentable media indicate that the RepA2(Val 20) cytochrome c behaves much like the wild-type yeast iso-1 protein, whereas the stability and function of the RepA2 cytochrome c showed a temperature dependence. The midpoint reduction potential measured by cyclic voltammetry of the RepA2 mutant is 271 mV at 25 degrees C. This is 19 mV less than the wild-type and RepA2(Val 20) proteins (290 mV) and may result from disruption of the hydrophobic packing in the heme pocket and increased mobility of omega-loop A in RepA2 cytochrome c. The temperature dependence of the reduction potential is also greatly enhanced in the RepA2 protein.     

Thermal stability studies of a globular protein in aqueous poly(ethylene glycol) by (1)H NMR

The reversible folding destabilization of hen lysozyme has been confirmed by a melting temperature (T(m)) decrease in aqueous poly(ethylene glycol) (PEG). The percent denatured, extracted from the histidine 15 C2H (H15 C2H) native and denatured peak areas from 500-MHz one-dimensional proton nuclear magnetic resonance (1D (1)H NMR) spectra in D(2)O, was analyzed through denaturation temperatures at 0% and 20% (w/w) PEG 1000. The lysozyme (3.5 mM) T(m) decreased by 4.2 degrees C and 7.1 degrees C in 20% (w/w) PEG 1000 at pH 3.8 and 3.0, respectively. The T(m) decreased with increasing lysozyme concentration. Additionally, the temperature-induced resonance migrations of 17 protons from 8 residues indicate that the native lysozyme structure undergoes temperature-induced conformational changes. The changes were essentially identical in both 0% and 20% (w/w) PEG 1000 at both pH 3.0 and 3.8. This small, local restructuring of the hydrophobic box region may be a manifestation of temperature-dependent solution hydrophobicity, whereas active-site cleft fluctuations may be due to the inherent active-site flexibility. The lysozyme structure in PEG at 35 degrees C was determined to be essentially native from the (1)H nuclear Overhauser effect spectroscopy (NOESY) fingerprint regions. Additionally, lysozyme chemical shifts, from 1D spectra, in PEG 200, 300, and 1000 at 35 degrees C and various concentrations were essentially identical, further confirming that the conformation remains native in various PEG solutions. (c) 1996 John Wiley & Sons, Inc.     

The active-site cysteinyls and hydrophobic cavity residues of ResA are important for cytochrome c maturation in Bacillus subtilis

ResA is an extracytoplasmic membrane-bound thiol-disulfide oxidoreductase required for cytochrome c maturation in Bacillus subtilis. Previous biochemical and structural studies have revealed that the active-site cysteinyls cycle between oxidized and reduced states with a low reduction potential and that, upon reduction, a hydrophobic cavity forms close to the active site. Here we report in vivo studies of ResA-deficient B. subtilis complemented with a series of ResA variants. Using a range of methods to analyze the cellular cytochrome c content, we demonstrated (i) that the N-terminal transmembrane segment of ResA serves principally to anchor the protein to the cytoplasmic membrane but also plays a role in mediating the activity of the protein; (ii) that the active-site cysteines are important for cytochrome c maturation activity; (iii) that Pro141, which forms part of the hydrophobic cavity and which adopts a cis conformation, plays an important role in protein stability; (iv) that Glu80, which lies at the base of the hydrophobic cavity, is important for cytochrome c maturation activity; and, finally, (v) that Pro141 and Glu80 ResA mutant variants promote selective maturation of low levels of one c-type cytochrome, subunit II of the cytochrome c oxidase caa(3), indicating that this apocytochrome is distinct from the other three endogenous c-type cytochromes of B. subtilis.     

Thermal denaturation pathway of starch phosphorylase from Corynebacterium callunae: oxyanion binding provides the glue that efficiently stabilizes the dimer structure of the protein

Starch phosphorylase from Corynebacterium callunae is a dimeric protein in which each mol of 90 kDa subunit contains 1 mol pyridoxal 5'-phosphate as an active-site cofactor. To determine the mechanism by which phosphate or sulfate ions bring about a greater than 500-fold stabilization against irreversible inactivation at elevated temperatures (> or = 50 degrees C), enzyme/oxyanion interactions and their role during thermal denaturation of phosphorylase have been studied. By binding to a protein site distinguishable from the catalytic site with dissociation constants of Ksulfate = 4.5 mM and Kphosphate approximately 16 mM, dianionic oxyanions induce formation of a more compact structure of phosphorylase, manifested by (a) an increase by about 5% in the relative composition of the alpha-helical secondary structure, (b) reduced 1H/2H exchange, and (c) protection of a cofactor fluorescence against quenching by iodide. Irreversible loss of enzyme activity is triggered by the release into solution of pyridoxal 5'-phosphate, and results from subsequent intermolecular aggregation driven by hydrophobic interactions between phosphorylase subunits that display a temperature-dependent degree of melting of secondary structure. By specifically increasing the stability of the dimer structure of phosphorylase (probably due to tightened intersubunit contacts), phosphate, and sulfate, this indirectly (1) preserves a functional active site up to approximately 50 degrees C, and (2) stabilizes the covalent protein cofactor linkage up to approximately 70 degrees C. The effect on thermostability shows a sigmoidal and saturatable dependence on the concentration of phosphate, with an apparent binding constant at 50 degrees C of approximately 25 mM. The extra stability conferred by oxyanion-ligand binding to starch phosphorylase is expressed as a dramatic shift of the entire denaturation pathway to a approximately 20 degrees C higher value on the temperature scale.     

Definition of the interaction domain for cytochrome c on cytochrome c oxidase. III. Prediction of the docked complex by a complete, systematic search

The electron transfer complex between bovine cytochrome c oxidase and horse cytochrome c has been predicted with the docking program DOT, which performs a complete, systematic search over all six rotational and translational degrees of freedom. Energies for over 36 billion configurations were calculated, providing a free-energy landscape showing guidance of positively charged cytochrome c to the negative region on the cytochrome c oxidase surface formed by subunit II. In a representative configuration, the solvent-exposed cytochrome c heme edge is within 4 A of the indole ring of subunit II residue Trp(104), indicating a likely electron transfer path. These two groups are surrounded by a small, hydrophobic contact region, which is surrounded by electrostatically complementary hydrophilic interactions. Cytochrome c/cytochrome c oxidase interactions of Lys(13) with Asp(119) and Lys(72) with Gln(103) and Asp(158) are the most critical polar interactions due to their proximity to the hydrophobic region and exclusion from bulk solvent. The predicted complex matches previous mutagenesis, binding, and time-resolved kinetics studies that implicate Trp(104) in electron transfer and show the importance of specific charged residues to protein affinity. Electrostatic forces not only enhance long range protein/protein association; they also predominate in short range alignment, creating the transient interaction needed for rapid turnover.     

The primary structure of Bacillus cereus neutral proteinase and comparison with thermolysin and Bacillus subtilis neutral proteinase

The complete amino-acid sequence of a neutral proteinase, produced by Bacillus cereus, was determined by protein sequencing. The neutral proteinase consists of 317 amino-acid residues. The primary structure is 70% homologous to thermolysin, a thermostable neutral proteinase and 45% homologous to Bacillus subtilis neutral proteinase. The zinc-binding site and the hydrophobic pocket of the active site are highly similar in all three proteinases. B. cereus neutral proteinase which is 20 degrees C less thermostable (60 degrees C) than thermolysin (80 degrees C) shows only minor differences in calcium binding sites and salt bridges compared to thermolysin (known from its X-ray diffraction analysis), whereas B. subtilis neutral proteinase (50 degrees C) differs considerably. Therefore it was assumed that the difference in thermostability between B. cereus neutral proteinase and thermolysin is not caused by different metal binding properties, or differences in the active site, but by changes within the rest of the molecule. Calculation of secondary structure potentials according to Chou & Fasman, hydrophobicity and bulkiness of the different structural elements and preferred cold----hot amino-acid residue exchanges indicated, that the thermostability of thermolysin compared to B. cereus neutral proteinase is caused by small effects contributed by numerous amino-acid exchanges distributed over the whole molecule, resulting in increased hydrophobicity of beta-pleated sheet and higher bulkiness of alpha-helical regions.     

Importance of hydrophobic interaction between a SoxB-type cytochrome c oxidase with its natural substrate cytochrome c-551 and its mutants

Cytochrome c-551, the electron donor of SoxB-type cytochrome c oxidase in thermophilic bacilli, can be over-expressed in Bacillus thermodenitrificans cells by tranformation with pSTEc551. Several mutant cytochromes c-551 were prepared by site-directed mutagenesis to this expression plasmid. Among them, several Lys residues were changed to Ala/Ser, and we found that these mutant cytochromes retained their activity as substrates, although their K(m) values were 0.04-0.12 microM, depending on the site replaced. In contrast, the C19A mutant cytochrome, which was produced in Brevibacillus choshinensis as a secretion protein, lost its activity as a substrate, suggesting that the fatty acyl-glyceryl residue covalently bound to the cysteine residue of the wild-type c-551 plays a very important role in the activity. The importance of the hydrophobic fatty acid residue for the binding of cytochrome c-551 to the oxidase was also shown by the loss of substrate activity in deacylated cytochrome c-551. These results show the importance of the hydrophobic interaction between this cytochrome and SoxB-type oxidase, despite the fact that the importance of an electrostatic interaction between cytochrome c and mitochondrial cytochrome aa(3) oxidase has already been established.     

Improving low-temperature catalysis in the hyperthermostable Pyrococcus furiosus beta-glucosidase CelB by directed evolution

The beta-glucosidase from the hyperthermophilic archaeon Pyrococcus furiosus (CelB) is the most thermostable and thermoactive family 1 glycosylhydrolase described to date. To obtain more insight in the molecular determinants of adaptations to high temperatures and study the possibility of optimizing low-temperature activity of a hyperthermostable enzyme, we generated a library of random CelB mutants in Escherichia coli. This library was screened for increased activity on p-nitrophenyl-beta-D-glucopyranoside at room temperature. Multiple CelB variants were identified with up to 3-fold increased rates of hydrolysis of this aryl glucoside, and 10 of them were characterized in detail. Amino acid substitutions were identified in the active-site region, at subunit interfaces, at the enzyme surface, and buried in the interior of the monomers. Characterization of the mutants revealed that the increase in low-temperature activity was achieved in different ways, including altered substrate specificity and increased flexibility by an apparent overall destabilization of the enzyme. Kinetic characterization of the active-site mutants showed that in all cases the catalytic efficiency at 20 degrees C on p-nitrophenyl-beta-D-glucose, as well as on the disaccharide cellobiose, was increased up to 2-fold. In most cases, this was achieved at the expense of beta-galactosidase activity at 20 degrees C and total catalytic efficiency at 90 degrees C. Substrate specificity was found to be affected by many of the observed amino acid substitutions, of which only some are located in the vicinity of the active site. The largest effect on substrate specificity was observed with the CelB variant N415S that showed a 7.5-fold increase in the ratio of p-nitrophenyl-beta-D-glucopyranoside/p-nitrophenyl-beta-D-galactopyra noside hydrolysis. This asparagine at position 415 is predicted to interact with active-site residues that stabilize the hydroxyl group at the C4 position of the substrate, the conformation of which is equatorial in glucose-containing substrates and axial in galactose-containing substrates.     

Ionization of tyrosine and lysine residues in native and modified horse cytochrome c.

1H-n.m.r. and 13C-n.m.r. spectroscopy of horse cytochrome c and 1H-n.m.r. spectroscopy of the lysine-modified proteins N epsilon-acetimidyl-, N epsilon-amidino-, N epsilon-trifluoroacetyl- and N epsilon-maleyl-cytochrome c have shown that, although the lysine modifications do not greatly perturb the protein structure at pH7 and 27 degrees C, at higher temperature or at alkaline pH some parts of the structure are markedly perturbed. At pH7 and 27 degrees C the region of the protein about Ile-57 is affected in all the modified proteins, though not all to the same degree. N epsilon-Maleylation most seriously affects the protein structure, and the fully maleylated protein is readily unfolded. At 27 degrees C all four of the tyrosine residues of native horse cytochrome c have pKa values above 11, but in N epsilon-acetimidyl-cytochrome c the pKa of one tyrosine residue is 10.2.     

The 108M polymorph of human catechol O-methyltransferase is prone to deformation at physiological temperatures

The human gene for catechol O-methyltransferase (COMT) contains a common polymorphism that results in substitution of methionine (M) for valine (V) at residue 108 of the soluble form of the protein. While the two proteins have similar kinetic properties, 108M COMT loses activity more rapidly than 108V COMT at 37 degrees C. The cosubstrate S-adenosylmethionine (SAM) stabilizes the activity of 108M COMT at 40 degrees C. The 108M allele has been associated with increased risk for breast cancer, obsessive-compulsive disorder, and aggressive and highly antisocial manifestations of schizophrenia. In the current work, we have constructed homology models for both human COMT polymorphs and performed molecular dynamics simulations of these models at 25, 37, and 50 degrees C to explore the structural consequences of the 108V/M polymorphism. The simulations indicated that replacing valine with the larger methionine residue led to greater solvent exposure of residue 108 and heightened packing interactions between M108 and helices alpha2, alpha4 (especially with R78), and alpha5. These altered packing interactions propagated subtle changes between the polymorphic site and the active site 16 A away, leading to a loosening of the active site. At physiological temperature, 108M COMT sampled a larger distribution of conformations than 108V. 108M COMT was more prone to active-site distortion and had greater overall, and SAM binding site, solvent accessibility than 108V COMT at 37 degrees C. Similar structural perturbations were observed in the 108V protein only at 50 degrees C. Addition of SAM tightened up the cosubstrate pocket in both proteins and prevented the altered packing at the polymorphic site in 108M COMT.     

Crystal structure of cholesterol oxidase from Brevibacterium sterolicum refined at 1.8 A resolution

Cholesterol oxidase (3 beta-hydroxysteroid oxidase, EC 1.1.3.6) is an FAD-dependent enzyme that carries out the oxidation and isomerization of steroids with a trans A : B ring junction. The crystal structure of the enzyme from Brevibacterium sterolicum has been determined using the method of isomorphous replacement and refined to 1.8 A resolution. The refined model includes 492 amino acid residues, the FAD prosthetic group and 453 solvent molecules. The crystallographic R-factor is 15.3% for all reflections between 10.0 A and 1.8 A resolution. The structure is made up of two domains: an FAD-binding domain and a steroid-binding domain. The FAD-binding domain consists of three non-continuous segments of sequence, including both the N terminus and the C terminus, and is made up of a six-stranded beta-sheet sandwiched between a four-stranded beta-sheet and three alpha-helices. The overall topology of this domain is very similar to other FAD-binding proteins. The steroid-binding domain consists of two non-continuous segments of sequence and contains a six-stranded antiparallel beta-sheet forming the "roof" of the active-site cavity. This large beta-sheet structure and the connections between the strands are topologically similar to the substrate-binding domain of the FAD-binding protein para-hydroxybenzoate hydroxylase. The active site lies at the interface of the two domains, in a large cavity filled with a well-ordered lattice of 13 solvent molecules. The flavin ring system of FAD lies on the "floor" of the cavity with N-5 of the ring system exposed. The ring system is twisted from a planar conformation by an angle of approximately 17 degrees, allowing hydrogen-bond interactions between the protein and the pyrimidine ring of FAD. The amino acid residues that line the active site are predominantly hydrophobic along the side of the cavity nearest the benzene ring of the flavin ring system, and are more hydrophilic on the opposite side near the pyrimidine ring. The cavity is buried inside the protein molecule, but three hydrophobic loops at the surface of the molecule show relatively high temperature factors, suggesting a flexible region that may form a possible path by which the substrate could enter the cavity. The active-site cavity contains one charged residue, Glu361, for which the side-chain electron density suggests a high degree of mobility for the side-chain. This residue is appropriately positioned to act as the proton acceptor in the proposed mechanism for the isomerization step.     

Activities and kinetic mechanisms of native and soluble NADPH-cytochrome P450 reductase

A highly thermostable xylanase (Xyl I) produced by Thermomonospora sp. was purified to homogeneity and was classified as a family 10 xylanase based on its molecular weight (38,000 Da) and isoelectric point (4.1). K2d analysis showed that the secondary structure of Xyl I was made up of 38% alpha-helix and 10% beta-sheet. The optimal temperature for the activity of Xyl I was 80 degrees C. Xyl I was highly thermostable with half-lives of 86, 30, and 15 min at 80, 90, and 100 degrees C respectively. Xyl I was stable in an expansive pH range of 5 to 10 with more than 75% residual activity. Our present investigation using o-phthalaldehyde (OPTA) as the chemical initiator for fluorescent chemoaffinity labeling and trinitrobenzenesulphonic acid (TNBS) as chemical modifier have revealed the presence of a single lysine residue in the active site of Xyl I. The high pK value for the basic limb of the pH profile reflects the ionization of a lysine residue. The higher K(m) values and similar k(cat) values of the TNBS modified enzyme in comparison to native enzyme and the substrate protection against OPTA and TNBS, suggested the presence of the lysine residue in the substrate-binding site.     

EstA from <Emphasis Type="Italic">Arthrobacter nitroguajacolicus</Emphasis> Rü61a,a Thermo- and Solvent-Tolerant Carboxylesterase Related to Class C β-Lactamases

The estA gene encoding a novel cytoplasmic carboxylesterase from Arthrobacter nitroguajacolicus Rü61a was expressed in Escherichia coli. Sequence analysis and secondary structure predictions suggested that EstA belongs to the family VIII esterases, which are related to class C beta-lactamases. The S-x-x-K motif that in beta-lactamases contains the catalytic nucleophile, and a putative active-site tyrosine residue are conserved in EstA. The native molecular mass of hexahistidine-tagged (His6) EstA, purified by metal chelate affinity chromatography, was estimated to be 95 kDa by gel filtration, whereas the His6EstA peptide has a calculated molecular mass of 42.1 kDa. The enzyme catalyzes the hydrolysis of short-chain phenylacyl esters and triglycerides, and shows weak activity toward 2-hydroxy- and 2-nitroacetanilide. Its catalytic activity was inhibited by the serine-specific effector phenylmethylsulfonyl fluoride, and by Cd2+ and Hg2+ ions. Maximum activity of His6EstA was observed at a pH of 9.5 and a temperature of 50 degrees C to 60 degrees C. The enzyme was fairly thermostable. After 19 days at 50 degrees C and after 24 hours at 60 degrees C, its residual relative esterase activity toward phenylacetate was still 53% and 30%, respectively. Exposure of His6EstA to buffer-solvent mixtures showed that the enzyme was inactivated by several high log P (hydrophobic) solvents, whereas it showed remarkable stability and activity in up to 30% (by volume) of polar (low log P) organic solvents such as dimethylsulfoxide, methanol, acetonitrile, acetone, and propanol.     

Crystal structure of the Mycobacterium tuberculosis beta-ketoacyl-acyl carrier protein synthase III

Mycolic acids (alpha-alkyl-beta-hydroxy long chain fatty acids) cover the surface of mycobacteria, and inhibition of their biosynthesis is an established mechanism of action for several key front-line anti-tuberculosis drugs. In mycobacteria, long chain acyl-CoA products (C(14)-C(26)) generated by a type I fatty-acid synthase can be used directly for the alpha-branch of mycolic acid or can be extended by a type II fatty-acid synthase to make the meromycolic acid (C(50)-C(56)))-derived component. An unusual Mycobacterium tuberculosis beta-ketoacyl-acyl carrier protein (ACP) synthase III (mtFabH) has been identified, purified, and shown to catalyze a Claisen-type condensation between long chain acyl-CoA substrates such as myristoyl-CoA (C(14)) and malonyl-ACP. This enzyme, presumed to play a key role in initiating meromycolic acid biosynthesis, was crystallized, and its structure was determined at 2.1-A resolution. The mtFabH homodimer is closely similar in topology and active-site structure to Escherichia coli FabH (ecFabH), with a CoA/malonyl-ACP-binding channel leading from the enzyme surface to the buried active-site cysteine residue. Unlike ecFabH, mtFabH contains a second hydrophobic channel leading from the active site. In the ecFabH structure, this channel is blocked by a phenylalanine residue, which constrains specificity to acetyl-CoA, whereas in mtFabH, this residue is a threonine, which permits binding of longer acyl chains. This same channel in mtFabH is capped by an alpha-helix formed adjacent to a 4-amino acid sequence insertion, which limits bound acyl chain length to 16 carbons. These observations offer a molecular basis for understanding the unusual substrate specificity of mtFabH and its probable role in regulating the biosynthesis of the two different length acyl chains required for generation of mycolic acids. This mtFabH presents a new target for structure-based design of novel antimycobacterial agents.     

A single proline substitution is critical for the thermostabilization of Clostridium beijerinckii alcohol dehydrogenase

Analysis of the three-dimensional structures of three closely related mesophilic, thermophilic, and hyperthermophilic alcohol dehydrogenases (ADHs) from the respective microorganisms Clostridium beijerinckii (CbADH), Entamoeba histolytica (EhADH1), and Thermoanaerobacter brockii (TbADH) suggested that a unique, strategically located proline residue (Pro100) might be crucial for maintaining the thermal stability of EhADH1. To determine whether proline substitution at this position in TbADH and CbADH would affect thermal stability, we used site-directed mutagenesis to replace the complementary residues in both enzymes with proline. The results showed that replacing Gln100 with proline significantly enhanced the thermal stability of the mesophilic ADH: DeltaT(1/2) (60 min) = + 8 degrees C (temperature of 50% inactivation after incubation for 60 min), DeltaT(1/2) (CD) = +11.5 degrees C (temperature at which 50% of the original CD signal at 218 nm is lost upon heating between 30 degrees and 98 degrees C). A His100 --> Pro substitution in the thermophilic TbADH had no effect on its thermostability. An analysis of the three-dimensional structure of the crystallized thermostable mutant Q100P-CbADH suggested that the proline residue at position 100 stabilized the enzyme by reinforcing hydrophobic interactions and by reducing the flexibility of a loop at this strategic region.     

Molecular dynamics simulations of a protein on hydrophobic and hydrophilic surfaces.

Molecular dynamics simulations have been used to investigate the behavior of the peripheral membrane protein, cytochrome c, covalently tethered to hydrophobic (methyl-terminated) and hydrophilic (thiol-terminated) self-assembled monolayers (SAMs). The simulations predict that the protein will undergo minor structural changes when it is tethered to either surface, and the structures differ qualitatively on the two surfaces: the protein is less spherical on the hydrophilic SAM where the polar surface residues reach out to interact with the SAM surface. The protein is completely excluded from the hydrophobic SAM but partially dissolves in the hydrophilic SAM. Consequently, the surface of the thiol-terminated SAM is considerably less ordered than that of the methyl-terminated SAM, although a comparable, high degree of order is maintained in the bulk of both SAMs: the chains exhibit collective tilts in the nearest-neighbor direction at angles of 20 degrees and 17 degrees with respect to the surface normal in the hydrophobic and the hydrophilic SAMs, respectively. On the hydrophobic SAM the protein is oriented so that the heme plane is more nearly parallel to the surface, whereas on the hydrophilic surface it is more nearly perpendicular. The secondary structure of the protein, dominated by alpha helices, is not significantly affected, but the structure of the loops as well as the helix packing is slightly modified by the surfaces.     

Characterization of four covalently-linked yeast cytochrome c/cytochrome c peroxidase complexes: Evidence for electrostatic interaction between bound cytochrome c molecules

Four covalent complexes between recombinant yeast cytochrome c and cytochrome c peroxidase (rCcP) were synthesized via disulfide bond formation using specifically designed protein mutants (Papa, H. S., and Poulos, T. L. (1995) Biochemistry 34, 6573-6580). One of the complexes, designated V5C/K79C, has cysteine residues replacing valine-5 in rCcP and lysine-79 in cytochrome c with disulfide bond formation between these residues linking the two proteins. The V5C/K79C complex has the covalently bound cytochrome c located on the back-side of cytochrome c peroxidase, approximately 180 degrees from the primary cytochrome c-binding site as defined by the crystallographic structure of the 1:1 noncovalent complex (Pelletier, H., and Kraut J. (1992) Science 258, 1748-1755). Three other complexes have the covalently bound cytochrome c located approximately 90 degrees from the primary binding site and are designated K12C/K79C, N78C/K79C, and K264C/K79C, respectively. Steady-state kinetic studies were used to investigate the catalytic properties of the covalent complexes at both 10 and 100 mM ionic strength at pH 7.5. All four covalent complexes have catalytic activities similar to those of rCcP (within a factor of 2). A comprehensive study of the ionic strength dependence of the steady-state kinetic properties of the V5C/K79C complex provides evidence for significant electrostatic repulsion between the two cytochromes bound in the 2:1 complex at low ionic strength and shows that the electrostatic repulsion decreases as the ionic strength of the buffer increases.     

Swapping core residues in homologous proteins swaps folding mechanism

Rat intestinal fatty acid binding protein (IFABP) displays an intermediate with little if any secondary structure during unfolding, while the structurally homologous rat ileal lipid binding protein (ILBP) displays an intermediate during unfolding with nativelike secondary structure. Double-jump experiments indicate that these intermediates are on the folding path for each protein. To test the hypothesis that differences in the number of buried hydrophobic atoms in a folding initiating site are responsible for the different types of intermediates observed for these proteins, two mutations (F68C-IFABP and C69F-ILBP) were made that swapped a more hydrophobic residue for a more hydrophilic residue in the respective cores of these two proteins. F68C-IFABP followed an unfolding path identical to that of WT-ILBP with an intermediate that showed nativelike secondary structure, whereas C69F-ILBP followed an unfolding path that was identical to that of WT-IFABP with an intermediate that lacked secondary structure. Further, a hydrophilic residue was introduced at an identical hydrophobic structural position in both proteins (F93S-IFABP and F94S-ILBP). Replacement of phenylalanine with serine at this site led to the appearance of an intermediate during refolding that lacked secondary structure for both proteins that was not detected for either parental protein. Altering the chemical characteristics and/or size of residues within an initiating core of hydrophobic interactions is critical to the types of intermediates that are observed during the folding of these proteins.     

Engineering a selectable marker for hyperthermophiles

Limited thermostability of antibiotic resistance markers has restricted genetic research in the field of extremely thermophilic Archaea and bacteria. In this study, we used directed evolution and selection in the thermophilic bacterium Thermus thermophilus HB27 to find thermostable variants of a bleomycin-binding protein from the mesophilic bacterium Streptoalloteichus hindustanus. In a single selection round, we identified eight clones bearing five types of double mutated genes that provided T. thermophilus transformants with bleomycin resistance at 77 degrees C, while the wild-type gene could only do so up to 65 degrees C. Only six different amino acid positions were altered, three of which were glycine residues. All variant proteins were produced in Escherichia coli and analyzed biochemically for thermal stability and functionality at high temperature. A synthetic mutant resistance gene with low GC content was designed that combined four substitutions. The encoded protein showed up to 17 degrees C increased thermostability and unfolded at 85 degrees C in the absence of bleomycin, whereas in its presence the protein unfolded at 100 degrees C. Despite these highly thermophilic properties, this mutant was still able to function normally at mesophilic temperatures in vivo. The mutant protein was co-crystallized with bleomycin, and the structure of the binary complex was determined to a resolution of 1.5 A. Detailed structural analysis revealed possible molecular mechanisms of thermostabilization and enhanced antibiotic binding, which included the introduction of an intersubunit hydrogen bond network, improved hydrophobic packing of surface indentations, reduction of loop flexibility, and alpha-helix stabilization. The potential applicability of the thermostable selection marker is discussed.     

Kinetic stabilization of Bacillus licheniformis alpha-amylase through introduction of hydrophobic residues at the surface

It is generally assumed that in proteins hydrophobic residues are not favorable at solvent-exposed sites, and that amino acid substitutions on the surface have little effect on protein thermostability. Contrary to these assumptions, we have identified hyperthermostable variants of Bacillus licheniformis alpha-amylase (BLA) that result from the incorporation of hydrophobic residues at the surface. Under highly destabilizing conditions, a variant combining five stabilizing mutations unfolds 32 times more slowly and at a temperature 13 degrees C higher than the wild-type. Crystal structure analysis at 1.7 A resolution suggests that stabilization is achieved through (a) extension of the concept of increased hydrophobic packing, usually applied to cavities, to surface indentations, (b) introduction of favorable aromatic-aromatic interactions on the surface, (c) specific stabilization of intrinsic metal binding sites, and (d) stabilization of a beta-sheet by introducing a residue with high beta-sheet forming propensity. All mutated residues are involved in forming complex, cooperative interaction networks that extend from the interior of the protein to its surface and which may therefore constitute "weak points" where BLA unfolding is initiated. This might explain the unexpectedly large effect induced by some of the substitutions on the kinetic stability of BLA. Our study shows that substantial protein stabilization can be achieved by stabilizing surface positions that participate in underlying cooperatively formed substructures. At such positions, even the apparently thermodynamically unfavorable introduction of hydrophobic residues should be explored.