The interaction between residues 62 and 193 play a key role in activity and structural stability of arginine kinase

The purpose of this study is to clarify that the amino acid residues (Asp62 and Arg193) are responsible for the activity and stability of arginine kinase (AK). The amino acid residues Asp62 (D62) and Arg193 (R193) are strictly conserved in monomeric AKs and form an ion pair in the transition state analogue complex. In this research, we replaced D62 with glutamate (E) or glycine (G) and R193 with lysine (K) or glycine (G). The mutants of D62E and R193K retained almost 90% of the wild-type activity, whereas D62G and R193G had a pronounced loss in activity. A detailed comparison was made between the physic-chemical properties and conformational changes of wild-type AK and the mutants by means of ultraviolet (UV) difference and fluorescence spectra. The results indicated that the conformation of all of the mutants had been changed and the stability in a urea solution was also reduced. We speculated that the hydrogen bond and electrostatic interactions formed between residues 62 and 193 play a key role in stabilizing the structure and mediating the synergism in substrate binding of arginine kinase from greasyback shrimp (Metapenaeus ensis).     

Adopting selected hydrogen bonding and ionic interactions from Aspergillus fumigatus phytase structure improves the thermostability of Aspergillus niger PhyA phytase

Although it has been widely used as a feed supplement to reduce manure phosphorus pollution of swine and poultry, Aspergillus niger PhyA phytase is unable to withstand heat inactivation during feed pelleting. Crystal structure comparisons with its close homolog, the thermostable Aspergillus fumigatus phytase (Afp), suggest associations of thermostability with several key residues (E35, S42, R168, and R248) that form a hydrogen bond network in the E35-to-S42 region and ionic interactions between R168 and D161 and between R248 and D244. In this study, loss-of-function mutations (E35A, R168A, and R248A) were introduced singularly or in combination into seven mutants of Afp. All seven mutants displayed decreases in thermostability, with the highest loss (25% [P<0.05]) in the triple mutant (E35A R168A R248A). Subsequently, a set of corresponding substitutions were introduced into nine mutants of PhyA to strengthen the hydrogen bonding and ionic interactions. While four mutants showed improved thermostability, the best response came from the quadruple mutant (A58E P65S Q191R T271R), which retained 20% greater (P<0.05) activity after being heated at 80 degrees C for 10 min and had a 7 degrees C higher melting temperature than that of wild-type PhyA. This study demonstrates the functional importance of the hydrogen bond network and ionic interaction in supporting the high thermostability of Afp and the feasibility of adopting these structural units to improve the thermostability of a homologous PhyA phytase.     

Thermodynamic analysis of the contributions of the copper ion and the disulfide bridge to azurin stability: synergism among multiple depletions

The stabilizing potential of the copper ion and the disulfide bridge in azurin has been explored with the aim of inspecting the ways in which these two factors influence one another. Specifically, whether copper and disulfide contributions to protein stability are additive has been examined. To this aim, the thermal unfolding of a copper-depleted mutant lacking the disulfide bridge between Cys3 and Cys26 (apo C3A/C26A azurin) was studied by differential scanning calorimetry. A comparison of the unfolding parameters of holo and apo C3A/C26A azurin with the apo C3A/C26A protein has shown that the effects of simultaneous copper and disulfide depletion are additive only at two temperatures: T=15 degrees C and T=67 degrees C. Within this range the presence of the copper ion and the disulfide bridge has a positive synergistic effect on azurin stability. These findings might have implications for the rational use of the stabilizing potential of copper and disulfides in copper protein engineering.     

Enhancing the Thermostability of Serratia plymuthica Sucrose Isomerase Using B-Factor-Directed Mutagenesis

The sucrose isomerase of Serratia plymuthica AS9 (AS9 PalI) was expressed in Escherichia coli BL21(DE3) and characterized. The half-life of AS9 PalI was 20 min at 45°C, indicating that it was unstable. In order to improve its thermostability, six amino acid residues with higher B-factors were selected as targets for site-directed mutagenesis, and six mutants (E175N, K576D, K174D, G176D, S575D and N577K) were designed using the RosettaDesign server. The E175N and K576D mutants exhibited improved thermostability in preliminary experiments, so the double mutant E175N/K576D was constructed. These three mutants (E175N, K576D, E175N/K576D) were characterized in detail. The results indicate that the three mutants exhibit a slightly increased optimal temperature (35°C), compared with that of the wild-type enzyme (30°C). The mutants also share an identical pH optimum of 6.0, which is similar to that of the wild-type enzyme. The half-lives of the E175N, K576D and E175N/K576D mutants were 2.30, 1.78 and 7.65 times greater than that of the wild-type enzyme at 45°C, respectively. Kinetic studies showed that the K_m values for the E175N, K576D and E175N/K576D mutants decreased by 6.6%, 2.0% and 11.0%, respectively, and their k_cat/K_m values increased by 38.2%, 4.2% and 19.4%, respectively, compared with those of the wild-type enzyme. After optimizing the conditions for isomaltulose production at 45°C, we found that the E175N, K576D and E175N/K576D mutants displayed slightly improved isomaltulose yields, compared with the wild-type enzyme. Therefore, the mutants produced in this study would be more suitable for industrial biosynthesis of isomaltulose.     

Effect of surface electrostatic interactions on the stability and folding of formate dehydrogenase from Candida methylica

NAD⁺-dependent formate dehydrogenase (FDH-EC 1.2.1.2) is an important enzyme to regenerate valuable NADH required by NAD⁺-dependent oxidoreductases in enzyme catalysis. The limitation in the thermostability of FDH enzyme is a crucial problem for development of biotechnological and industrial processes, despite of its advantages. In this study, to investigate the contribution of surface electrostatic interaction to the thermostability of FDH from Candida methylica (cmFDH) N187E, H13E, Q105R, N300E, N147R N300E/N147R, N187E/Q105R, N187E/N147R,Y160R, Y302R, Y160E and Y302E mutants were designed using a homology model of cmFDH based on Candida boidinii (cb) by considering electrostatic interactions on the protein surface. The effects of site-specific engineering on the stability of this molecule was analyzed according to minimal model of folding and assembly reaction and deduced equilibrium properties of the native system with respect to its thermal and denaturant sensitivities. It was observed that mutations did not change the unfolding pattern of native cmFDH and increased numbers of electrostatic interactions can cause either stabilizing or destabilizing effect on the thermostability of this protein. The thermodynamic and kinetic results suggested that except relatively improved mutants, three out of the nine single mutations increased the melting temperature of cmFDH enzyme.     

Engineering and introduction of <Emphasis Type="Italic">de novo</Emphasis> disulphide bridges in organophosphorus hydrolase enzyme for thermostability improvement

The organophosphorus hydrolase (OPH) has been used to degrade organophosphorus chemicals, as one of the most frequently used decontamination methods. Under chemical and thermal denaturing conditions, the enzyme has been shown to unfold. To utilize this enzyme in various applications, the thermal stability is of importance. The engineering of de novo disulphide bridges has been explored as a means to increase the thermal stability of enzymes in the rational method of protein engineering. In this study, Disulphide by Design software, homology modelling and molecular dynamics simulations were used to select appropriate amino acid pairs for the introduction of disulphide bridge to improve protein thermostability. The thermostability of the wild-type and three selected mutant enzymes were evaluated by half-life, ΔG inactivation (ΔGi) and structural studies (fluorescence and far-UV CD analysis). Data analysis showed that half-life of A204C/T234C and T128C/E153C mutants were increased up to 4 and 24 min, respectively; however, for the G74C/A78C mutant, the half-life was decreased up to 9 min. For the T128C/E124C mutant, both thermal stability and Catalytic efficiency (kcat) were also increased. The half-life and ΔGi results were correlated to the obtained information from structural studies by circular dichroism (CD) spectrometry and extrinsic fluorescence experiments; as rigidity increased in A204C/T2234C and T128C/E153C mutants, half-life and ΔGi also increased. For G74C/A78C mutant, these parameters decreased due to its higher flexibility. The results were submitted a strong evidence for the possibility to improve the thermostability of OPH enzyme by introducing a disulphide bridge after bioinformatics design, even though this design would not be always successful.     

Adopting Selected Hydrogen Bonding and Ionic Interactions from Aspergillus fumigatus Phytase Structure Improves the Thermostability of Aspergillus niger PhyA Phytase

Although it has been widely used as a feed supplement to reduce manure phosphorus pollution of swine and poultry, Aspergillus niger PhyA phytase is unable to withstand heat inactivation during feed pelleting. Crystal structure comparisons with its close homolog, the thermostable Aspergillus fumigatus phytase (Afp), suggest associations of thermostability with several key residues (E35, S42, R168, and R248) that form a hydrogen bond network in the E35-to-S42 region and ionic interactions between R168 and D161 and between R248 and D244. In this study, loss-of-function mutations (E35A, R168A, and R248A) were introduced singularly or in combination into seven mutants of Afp. All seven mutants displayed decreases in thermostability, with the highest loss (25% [P < 0.05]) in the triple mutant (E35A R168A R248A). Subsequently, a set of corresponding substitutions were introduced into nine mutants of PhyA to strengthen the hydrogen bonding and ionic interactions. While four mutants showed improved thermostability, the best response came from the quadruple mutant (A58E P65S Q191R T271R), which retained 20% greater (P < 0.05) activity after being heated at 80°C for 10 min and had a 7°C higher melting temperature than that of wild-type PhyA. This study demonstrates the functional importance of the hydrogen bond network and ionic interaction in supporting the high thermostability of Afp and the feasibility of adopting these structural units to improve the thermostability of a homologous PhyA phytase.     

Correlation of Local Changes in the Temperature-Dependent Conformational Flexibility of Thioredoxins with Their Thermostability

For the development of a method capable of predicting single point mutations substantially affecting protein thermostability, we studied the effect of the E85R and R82E mutations on the thermostability of thioredoxins from Escherichia coli (Trx) andBacillus acidocaldarius (BacTrx), respectively. The basic method of investigation was the molecular dynamics simulation of 3D protein models in an explicit solvent at different temperatures (300 and 373 K). Some thermolabile regions in Trx, BacTrx, and their mutants were revealed by analyzing the temperature effect on the molecular dynamics of the protein molecule. The effect of single point mutations on the temperature changes of the protein conformation flexibility in several thermolabile regions was found. The results of the simulations are in accord with experimental data indicating that the mutation E85R increases Trx thermostability, whereas the mutation R82E decreases BacTrx thermostability. The thermostability of these proteins was revealed to depend on ionic interactions between the thermolabile regions. The single point mutations change the parameters of these interactions and make them more favorable in the E85R-Trx mutant and less favorable in the R82E-BacTrx mutant.     

Investigation of N-terminal domain charged residues on the assembly and stability of HIV-1 CA

The human immunodeficiency virus type 1 (HIV-1) capsid protein (CA) plays a crucial role in both assembly and maturation of the virion as well as viral infectivity. Previous in vivo experiments generated two N-terminal domain charge change mutants (E45A and E128A/R132A) that showed an increase in stability of the viral core. This increase in core stability resulted in decreased infectivity, suggesting the need for a delicate balance of favorable and unfavorable interactions to both allow assembly and facilitate uncoating following infection. Purified CA protein can be triggered to assemble into tubelike structures through the use of a high salt buffer system. The requirement for high salt suggests the need to overcome charge/charge repulsion between subunits. The mutations mentioned above lie within a highly charged region of the N-terminal domain of CA, away from any of the proposed protein/protein interaction sites. We constructed a number of charge mutants in this region (E45A, E45K, E128A, R132A, E128A/R132A, K131A, and K131E) and evaluated their effect on protein stability in addition to their effect on the rate of CA assembly. We find that the mutations alter the rate of assembly of CA without significantly changing the stability of the CA monomer. The changes in rate for the mutants studied are found to be due to varying degrees of electrostatic repulsion between the subunits of each mutant.     

High-resolution X-ray structure of the DNA-binding protein HU from the hyper-thermophilic <Emphasis Type="Italic">Thermotoga maritima</Emphasis> and the determinants of its thermostability

The histone-like DNA-binding proteins (HU) are a convenient model for studying factors affecting thermostability because of their relatively simple, easily comparable structures, their common function, and their presence in organisms of widely differing thermostability. We report the determination of the high-resolution structure (1.53 A) at 273 K and 100 K of the HU protein from the hyper-thermophilic eubacterium Thermotoga maritima(HU Tmar, T(m)=80.5 degrees C). The structural data presented clearly show that the HU Tmar has a fold similar to its thermophilic homologue HU from Bacillus stearothermophilus (HU Bst). Based on primary structure analysis, as well as on the results of mutational analysis of HU Bst ( T(m)=61.6 degrees C) and Bacillus subtilis (HU Bsu, T(m)=39.7 degrees C), we have designed and produced several single and combined mutations to study their effect on the thermostability of the recombinant HU Tmar. Among others, the triplet mutant HU Tmar-G15E/E34D/V42I ( T(m)=35.9 degrees C) has converted the extreme thermophilic protein HU Tmar to mesophilic, like HU Bsu. In an attempt to analyze the various mutants of HU Tmar, we crystallized the point mutation HU Tmar-E34D, in which Glu34 was replaced by Asp, similar to the mesophilic HU Bsu. The mutant has T(m)=72.9 degrees C, as measured by circular dichroism, 7.6 degrees C lower than the wild type. The crystal structure of HU Tmar-E34D was determined at 100 K and refined at 1.72 A resolution. A comparison with the wild-type structures clearly shows that two hydrogen bonds have been disrupted between Glu34 from one subunit and Thr13 from the other subunit, and vice versa. Our analysis points to this as the prime cause of the destabilization compared to the wild type. The three new structures were compared, together with the X-ray structure of a similar protein, HU Bst, with the aim of relating their structural properties and different thermal stability. The presented results show that the HU Tmar protein achieves its stability by employing a dual strategy. On the one hand, we observe local hydrophobic interactions, which stabilize the secondary structure elements, and on the other hand, electrostatic interactions between side chains.     

Cross-linking and lipid efflux properties of apoA-I mutants suggest direct association between apoA-I helices and ABCA1

To explore the functional interactions between apoA-I and ABCA1, we correlated the cross-linking properties of several apoA-I mutants with their ability to promote cholesterol efflux. In a competitive cross-linking assay, amino-terminal deletion and double amino- and carboxy-terminal deletion mutants of apoA-I competed effectively the cross-linking of WT (125)I-apoA-I to ABCA1, while the carboxy-terminal deletion mutant apoA-I[Delta(220-243)] competed poorly. Direct cross-linking of WT apoA-I, amino-terminal, and double deletion mutants of apoA-I to ABCA1 showed similar apparent K(d) values (49-74 nM), whereas the apparent K(d) values of the carboxy-terminal deletion mutants apoA-I[Delta(185-243)] and apoA-I[Delta(220-243)] were increased 3-fold. Analysis of several internal deletions and point mutants of apoA-I showed that apoA-I[Delta(61-78)], apoA-I[Delta(89-99)], apoA-I[Delta(136-143)], apoA-I[Delta(144-165)], apoA-I[D102A/D103A], apoA-I[E125K/E128K/K133E/E139K], apoA-I[L141R], apoA-I[R160V/H162A], and WT apoA-I had similar ABCA1-mediated lipid efflux, and all competed efficiently the cross-linking of WT (125)I-apoA-I to ABCA1. WT apoA-I and ABCA1 could be cross-linked with a 3 A cross-linker. The WT apoA-I, amino, carboxy and double deletion mutants of apoA-I showed differences in the cross-linking to WT ABCA1 and the mutant ABCA1[W590S]. The findings are consistent with a direct association of different combinations of apoA-I helices with a complementary ABCA1 domain. Mutations that alter ABCA1/apoA-I association affect cholesterol efflux and inhibit biogenesis of HDL.     

The role of polar interactions in the molecular recognition of CD40L with its receptor CD40.

CD40 Ligand (CD40L) is transiently expressed on the surface of T-cells and binds to CD40, which is expressed on the surface of B-cells. This binding event leads to the differentiation, proliferation, and isotype switching of the B-cells. The physiological importance of CD40L has been demonstrated by the fact that expression of defective CD40L protein causes an immunodeficiency state characterized by high IgM and low IgG serum levels, indicating faulty T-cell dependent B-cell activation. To understand the structural basis for CD40L/CD40 association, we have used a combination of molecular modeling, mutagenesis, and X-ray crystallography. The structure of the extracellular region of CD40L was determined by protein crystallography, while the CD40 receptor was built using homology modeling based upon a novel alignment of the TNF receptor superfamily, and using the X-ray structure of the TNF receptor as a template. The model shows that the interface of the complex is composed of charged residues, with CD40L presenting basic side chains (K143, R203, R207), and CD40 presenting acidic side chains (D84, E114, E117). These residues were studied experimentally through site-directed mutagenesis, and also theoretically using electrostatic calculations with the program Delphi. The mutagenesis data explored the role of the charged residues in both CD40L and CD40 by switching to Ala (K143A, R203A, R207A of CD40L, and E74A, D84A, E114A, E117A of CD40), charge reversal (K143E, R203E, R207E of CD40L, and D84R, E114R, E117R of CD40), mutation to a polar residue (K143N, R207N, R207Q of CD40L, and D84N, E117N of CD40), and for the basic side chains in CD40L, isosteric substitution to a hydrophobic side chain (R203M, R207M). All the charge-reversal mutants and the majority of the Met and Ala substitutions led to loss of binding, suggesting that charged interactions stabilize the complex. This was supported by the Delphi calculations which confirmed that the CD40/CD40L residue pairs E74-R203, D84-R207, and E117-R207 had a net stabilizing effect on the complex. However, the substitution of hydrophilic side chains at several of the positions was tolerated, which suggests that although charged interactions stabilize the complex, charge per se is not crucial at all positions. Finally, we compared the electrostatic surface of TNF/TNFR with CD40L/CD40 and have identified a set of polar interactions surrounded by a wall of hydrophobic residues that appear to be similar but inverted between the two complexes.     

表面电荷突变与胰蛋白酶底物专一性的改造

分别利用酶切重组和“３＋１”引物ＰＣＲ定点突变的方法构建了三个胰蛋白酶表面电荷双突变体：Ｒ６２Ｄ＋Ｋ９７Ｅ、Ｒ６２Ｄ＋Ｋ１７５Ｅ和Ｋ９７Ｅ＋Ｋ１７５Ｅ．对三者在Ｅ．ｃｏｌｉＸ－９０菌中的表达产物进行了动力学测定,分别得到了三种双突变体在两种ｐＨ条件下,水解ＴＡＭＥ、ＴＬＭＥ两种底物的动力学数据．结果表明,Ｒ６２Ｄ＋Ｋ１７５Ｅ和Ｋ９７Ｅ＋Ｋ１７５Ｅ在ｐＨ６．８５时,对两种底物的催化活性与野生型相比下降了２～３个数量级,当ｐＨ升高至８．８５时,它们的活性基本丧失;双突变体Ｒ６２Ｄ＋Ｋ９７Ｅ虽然催化活性也有所降低,但随着ｐＨ的升高,它对Ｌｙｓ底物的特异性（选择性系数２５倍于Ａｒｇ底物）转变为对Ａｒｇ底物略高的特异性,基本符合分子设计．实验结果还表明,各种双突变体催化活性的降低主要是由于酶和底物的亲和力降低引起的．     

Regulation of Activation and Processing of the Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) by a Complex Electrostatic Interaction between the Regulatory Domain and Cytoplasmic Loop 3

NEG2, a short C-terminal segment (817–838) of the unique regulatory (R) domain of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel, has been reported to regulate CFTR gating in response to cAMP-dependent R domain phosphorylation. The underlying mechanism, however, is unclear. Here, Lys-946 of cytoplasmic loop 3 (CL3) is proposed as counter-ion of Asp-835, Asp-836, or Glu-838 of NEG2 to prevent the channel activation by PKA. Arg-764 or Arg-766 of the Ser-768 phosphorylation site of the R domain is proposed to promote the channel activation possibly by weakening the putative CL3-NEG2 electrostatic attraction. First, not only D835A, D836A, and E838A but also K946A reduced the PKA-dependent CFTR activation. Second, both K946D and D835R/D836R/E838R mutants were activated by ATP and curcumin to a different extent. Third, R764A and R766A mutants enhanced the PKA-dependent activation. However, it is very exciting that D835R/D836R/E838R and K946D/H950D and H950R exhibited normal channel processing and activity whereas D835R/D836R/E838R/K946D/H950D was fractionally misprocessed and silent in response to forskolin. Further, D836R and E838R played a critical role in the asymmetric electrostatic regulation of CFTR processing, and Ser-768 phosphorylation may not be involved. Thus, a complex interfacial interaction among CL3, NEG2, and the Ser-768 phosphorylation site may be responsible for the asymmetric electrostatic regulation of CFTR activation and processing.     

Roles of charged residues in the C-terminal region of PomA, a stator component of the Na+-driven flagellar motor

Bacterial flagellar motors use specific ion gradients to drive their rotation. It has been suggested that the electrostatic interactions between charged residues of the stator and rotor proteins are important for rotation in Escherichia coli. Mutational studies have indicated that the Na(+)-driven motor of Vibrio alginolyticus may incorporate interactions similar to those of the E. coli motor, but the other electrostatic interactions between the rotor and stator proteins may occur in the Na(+)-driven motor. Thus, we investigated the C-terminal charged residues of the stator protein, PomA, in the Na(+)-driven motor. Three of eight charge-reversing mutations, PomA(K203E), PomA(R215E), and PomA(D220K), did not confer motility either with the motor of V. alginolyticus or with the Na(+)-driven chimeric motor of E. coli. Overproduction of the R215E and D220K mutant proteins but not overproduction of the K203E mutant protein impaired the motility of wild-type V. alginolyticus. The R207E mutant conferred motility with the motor of V. alginolyticus but not with the chimeric motor of E. coli. The motility with the E211K and R232E mutants was similar to that with wild-type PomA in V. alginolyticus but was greatly reduced in E. coli. Suppressor analysis suggested that R215 may participate in PomA-PomA interactions or PomA intramolecular interactions to form the stator complex.     

Mutational effects on thermostable superoxide dismutase from Aquifex pyrophilus: understanding the molecular basis of protein thermostability

We designed two mutants of superoxide dismutase (SOD), one is thermostable and the other is thermolabile, which provide valuable insight to identify amino acid residues essential for the thermostability of the SOD from Aquifex pyrophilus (ApSOD). The mutant K12A, in which Lys12 was replaced by Ala, had increased thermostability compared to that of the wild type. The T(1/2) value of K12A was 210 min and that of the wild type was 175 min at 95 degrees C. However, the thermostability of the mutant E41A, which has a T(1/2) value of 25 min at 95 degrees C, was significantly decreased compared to the wild type of ApSOD. To explain the enhanced thermostability of K12A and thermolabile E41A on the structural basis, the crystal structures of the two SOD mutants have been determined. The results have clearly shown the general significance of hydrogen bonds and ion-pair network in the thermostability of proteins.     

Structures and free-energy landscapes of the wild type and mutants of the Abeta(21-30) peptide are determined by an interplay between intrapeptide electrostatic and hydrophobic interactions

The initial events in protein aggregation involve fluctuations that populate monomer conformations, which lead to oligomerization and fibril assembly. The highly populated structures, driven by a balance between hydrophobic and electrostatic interactions in the protease-resistant wild-type Aβ_21-30 peptide and mutants E22Q (Dutch), D23N (Iowa), and K28N, are analyzed using molecular dynamics simulations. Intrapeptide electrostatic interactions were connected to calculated pK_a values that compare well with the experimental estimates. The pK_a values of the titratable residues show that E22 and D23 side chains form salt bridges only infrequently with the K28 side chain. Contacts between E22-K28 are more probable in “dried” salt bridges, whereas D23-K28 contacts are more probable in solvated salt bridges. The strength of the intrapeptide hydrophobic interactions increases as D23N < WT < E22Q < K28A. Free-energy profiles and disconnectivity representation of the energy landscapes show that the monomer structures partition into four distinct basins. The hydrophobic interactions cluster the Aβ_21-30 peptide into two basins, differentiated by the relative position of the DVG(23-25) and GSN(25-27) fragments about the G25 residue. The E22Q mutation increases the population with intact VGSN turn compared to the wild-type (WT) peptide. The increase in the population of the structures in the aggregation-prone Basin I in E22Q, which occurs solely due to the difference in charge states between the Dutch mutant and the WT, gives a structural explanation of the somewhat larger aggregation rate in the mutant. The D23N mutation dramatically reduces the intrapeptide interactions. The K28A mutation increases the intrapeptide hydrophobic interactions that promote population of structures in Basin I and Basin II whose structures are characterized by hydrophobic interaction between V24 and K28 side chains but with well-separated ends of the backbone atoms in the VGSN turn. The intrapeptide electrostatic interactions in the WT and E22Q peptides roughen the free-energy surface compared to the K28A peptide. The D23N mutation has a flat free-energy surface, corresponding to an increased population of random coil-like structures with weak hydrophobic and electrostatic interactions. We propose that mutations or sequences that enhance the probability of occupying Basin I would promote aggregation of Aβ peptides.     

Increasing the thermal stability of cellulase C using rules learned from thermophilic proteins: a pilot study

Some structural features underlying the increased thermostability of enzymes from thermophilic organisms relative to their homologues from mesophiles are known from earlier studies. We used cellulase C from Clostridium thermocellum to test whether thermostability can be increased by mutations designed using rules learned from thermophilic proteins. Cellulase C has a TIM barrel fold with an additional helical subdomain. We designed and produced a number of mutants with the aim to increase its thermostability. Five mutants were designed to create new electrostatic interactions. They all retained catalytic activity but exhibited decreased thermostability relative to the wild-type enzyme. Here, the stabilizing contributions are obviously smaller than the destabilization caused by the introduction of the new side chains. In another mutant, the small helical subdomain was deleted. This mutant lost activity but its melting point was only 3 degrees C lower than that of the wild-type enzyme, which suggests that the subdomain is an independent folding unit and is important for catalytic function. A double mutant was designed to introduce a new disulfide bridge into the enzyme. This mutant is active and has an increased stability (deltaT(m)=3 degrees C, delta(deltaG(u))=1.73 kcal/mol) relative to the wild-type enzyme. Reduction of the disulfide bridge results in destabilization and an altered thermal denaturation behavior. We conclude that rules learned from thermophilic proteins cannot be used in a straightforward way to increase the thermostability of a protein. Creating a crosslink such as a disulfide bond is a relatively sure-fire method but the stabilization may be smaller than calculated due to coupled destabilizing effects.     

Study of the cytochrome c2-reaction center interaction by site-directed mutagenesis.

Photooxidation of Rhodobacter capsulatus cytochrome c2 and four site-directed mutants by detergent solubilized Rhodobacter sphaeroides reaction centers was studied as a function of ionic strength at pH 8.0. Mutants of cytochrome c2 included K12D (lysine 12 substituted by aspartate), K14E (lysine 14 substituted by glutamate), K32E (lysine 32 substituted by glutamate), and K14E/K32E (lysines 14 and 32 substituted by glutamates). With respect to the wild-type, the mutants exhibited decreased second-order rate constants, indicating perturbation of their electrostatic interaction with the reaction center. In the transient complex, the interaction domain charges of the reaction center and wild-type cytochrome c2 were estimated to be -4.8 and +4.8, respectively. In contrast, the interaction domain charges of mutants K12D, K14E, K32E, and K14E/K32E were estimated to be +2.8, +3.7, +3.6 and +1.3, respectively. At infinite ionic strength, the second-order rate constant of the wild-type cytochrome c2 photooxidation (k infinity) was estimated to be 8.7 x 10(6) M-1 s-1. In the case of K32E, k infinity was not changed significantly (8.2 x 10(6) m-1 s-1), suggesting that the electrostatic perturbation of this mutant was largely overcome at high ionic strength. In contrast, the k infinity for K12D, K14E, and K14E/K32E were estimated to be decreased 2-7-fold. Consequently, mutations to R. capsulatus lysines 12 and 14 appear to perturb the distance and/or orientation of the cytochrome c2 relative to the reaction center in the reactive complex, as well as alter electrostatic interactions. Based upon the kinetic results presented here, the cytochrome c2-reaction center transient complex has been modeled.     

Crystal structure of the disulfide bond-deficient azurin mutant C3A/C26A: how important is the S-S bond for folding and stability?

Azurin has a beta-barrel fold comprising eight beta-strands and one alpha helix. A disulfide bond between residues 3 and 26 connects the N-termini of beta strands beta1 and beta3. Three mutant proteins lacking the disulfide bond were constructed, C3A/C26A, C3A/C26I and a putative salt bridge (SB) in the C3A/S25R/C26A/K27R mutant. All three mutants exhibit spectroscopic properties similar to the wild-type protein. Furthermore, the crystal structure of the C3A/C26A mutant was determined at 2.0 A resolution and, in comparison to the wild-type protein, the only differences are found in the immediate proximity of the mutation. The mutants lose the 628 nm charge-transfer band at a temperature 10-22 degrees C lower than the wild-type protein. The folding of the zinc loaded C3A/C26A mutant was studied by guanidine hydrochloride (GdnHCl) induced denaturation monitored both by fluorescence and CD spectroscopy. The midpoint in the folding equilibrium, at 1.3 M GdnHCl, was observed using both CD and fluorescence spectroscopy. The free energy of folding determined from CD is -24.9 kJ.mol-1, a destabilization of approximately 20 kJ.mol-1 compared to the wild-type Zn2+-protein carrying an intact disulfide bond, indicating that the disulfide bond is important for giving azurin its stable structure. The C3A/C26I mutant is more stable and the SB mutant is less stable than C3A/C26A, both in terms of folding energy and thermal denaturation. The folding intermediate of the wild-type Zn2+-azurin is not observed for the disulfide-deficient C3A/C26A mutant. The rate of unfolding for the C3A/C26A mutant is similar to that of the wild-type protein, suggesting that the site of the mutation is not involved in an early unfolding reaction.