Cu/Zn superoxide dismutase mutants associated with amyotrophic lateral sclerosis show enhanced formation of aggregates in vitro.

Mutations in Cu/Zn superoxide dismutase (SOD) are associated with the fatal neurodegenerative disorder amyotrophic lateral sclerosis (ALS). There is considerable evidence that mutant SOD has a gain of toxic function; however, the mechanism of this toxicity is not known. We report here that purified SOD forms aggregates in vitro under destabilizing solution conditions by a process involving a transition from small amorphous species to fibrils. The assembly process and the tinctorial and structural properties of the in vitro aggregates resemble those for aggregates observed in vivo. Furthermore, the familial ALS SOD mutations A4V, G93A, G93R, and E100G decrease protein stability, which correlates with an increase in the propensity of the mutants to form aggregates. These mutations also increase the rate of protein unfolding. Our results suggest three possible mechanisms for the increase in aggregation: (i) an increase in the equilibrium population of unfolded or of partially unfolded states, (ii) an increase in the rate of unfolding, and (iii) a decrease in the rate of folding. Our data support the hypothesis that the gain of toxic function for many different familial ALS-associated mutant SODs is a consequence of protein destabilization, which leads to an increase in the formation of cytotoxic protein aggregates.

Thermodynamics of denaturation of hisactophilin, a beta-trefoil protein.

Hisactophilin is a histidine-rich pH-dependent actin-binding protein from Dictyostelium discoideum. The structure of hisactophilin is typical of the beta-trefoil fold, a common structure adopted by diverse proteins with unrelated primary sequences and functions. The thermodynamics of denaturation of hisactophilin have been measured using fluorescence- and CD-monitored equilibrium urea denaturation curves, pH-denaturation, and thermal denaturation curves, as well as differential scanning calorimetry. Urea denaturation is reversible from pH 5.7 to pH 9.7; however, thermal denaturation is highly reversible only below pH approximately 6.2. Reversible denaturation by urea and heat is well fit using a two-state transition between the native and the denatured states. Urea denaturation curves are best fit using a quadratic dependence of the Gibbs free energy of unfolding upon urea concentration. Hisactophilin has moderate, roughly constant stability from pH 7.7 to pH 9.7; however, below pH 7.7, stability decreases markedly, most likely due to protonation of histidine residues. Enthalpic effects of histidine ionization upon unfolding also appear to be involved in the occurrence of cold unfolding of hisactophilin under relatively mild solution conditions. The stability data for hisactophilin are compared with data on hisactophilin function, and with data for two other beta-trefoil proteins, human interleukin-1beta, and basic fibroblast growth factor.

Purification and characterization of recombinant Thermotoga maritima dihydrofolate reductase.

We have overexpressed the gene for dihydrofolate reductase (DHFR) from Thermotoga maritima in Escherichia coli and characterized the biochemical properties of the recombinant protein. This enzyme is involved in the de novo synthesis of deoxythymidine 5'-phosphate and is critical for cell growth. High levels of T. maritima DHFR in the new expression system conferred resistance to high levels of DHFR inhibitors which inhibit the growth of non-recombinant cells. The enzyme was purified to homogeneity in the following two steps: heat treatment followed by affinity chromatography or cation-exchange chromatography. Most of the biochemical properties of T. maritima DHFR resemble those of other bacterial or eukaryotic DHFRs, however, some are unique to T. maritima DHFR. The pH optima for activity, Km for substrates, and polypeptide chain length of T. maritima DHFR are similar to those of other DHFRs. In addition, the secondary structure of T. maritima DHFR, as measured by circular dichroism, is similar to that of other DHFRs. Interestingly, T. maritima DHFR exhibits some characteristics of eukaryotic DHFRs, such as a basic pI, an excess of positively charged residues in the polypeptide chain and activation of the enzyme by inorganic salts and urea. Unlike most other DHFRs which are monomeric or part of a bifunctional DHFR-thymidylate synthase (TS) enzyme, T. maritima DHFR seems to generally form a dimer in solution and is also much more thermostable than other DHFRs. It may be that dimer formation is a key factor in determining the stability of T. maritima DHFR.

Two-dimensional 1H and 15N NMR titration studies of hisactophilin.

We have used two-dimensional 1H-15N heteronuclear single quantum correlation spectroscopy to measure the pH dependence of backbone amide group chemical shifts in the actin binding protein hisactophilin over the pH range 5.7-11.1. Most of the resonances can be analyzed using a simple equation involving a single apparent ionization constant, pK(app). The majority of resonances in the protein titrate with pK(app) values of 5.6-7.4. The results can be rationalized in terms of titration of many histidine residues in hisactophilin. The titration data provide direct experimental support for the proposed models of the atomic basis of actin and membrane binding by hisactophilin.

NMR solution structure of the antitumor compound PT523 and NADPH in the ternary complex with human dihydrofolate reductase.

The antitumor compound PT523 [N(alpha)-(4-amino-4-deoxypteroyl)-N(delta)-hemiphthaloyl-L- ornithine] was found to have an inhibition constant (K(i)) of 0.35 +/- 0.10 pM against human dihydrofolate reductase (hDHFR), 15-fold lower than that of the classical antifolate drug methotrexate (MTX). The structure of PT523 bound to hDHFR and hDHFR-NADPH was investigated using multinuclear NMR techniques. NMR data indicate that the binary complex has two distinct conformations in solution which are in slow exchange and that the addition of NADPH stabilizes the ternary complex in a single bound state. Comparison of resonance assignments in the PT523 and MTX ternary complexes revealed that substantial protein chemical shift differences are limited to small regions of hDHFR tertiary structure. A restrained molecular dynamics and energy minimization protocol was performed for the hDHFR-PT523-NADPH complex, using 185 NOE restraints (33 intermolecular) to define the ligand-binding region. The positions of the pteridine and pABA rings of PT523 and the nicotinamide and ribose rings of NADPH are well defined in the solution structures (RMSD = 0.59 A) and are consistent with previously determined structures of DHFR complexes. The N(delta)-hemiphthaloyl-L-ornithine group of PT523 is less well defined, and the calculated model structures suggest the hemiphthaloyl ring may adopt more than one conformation in solution. Contacts between the hemiphthaloyl ring and hDHFR, which are not possible in the hDHFR-MTX-NADPH complex, may explain the greater inhibition potency of PT523.

Detection of long-lived bound water molecules in complexes of human dihydrofolate reductase with methotrexate and NADPH.

The locations of long-lived bound water molecules in the binary complex of human dihydrofolate reductase (hDHFR) with methotrexate (MTX) and the ternary complex of hDHFR with MTX and NADPH have been investigated using 15N-resolved, three-dimensional ROESY-HMQC and NOESY-HSQC spectra acquired at 25 degrees C and 8 degrees C. NOEs with NH groups of the protein are detected for five bound water molecules in the binary complex and six bound water molecules in the ternary complex. Inspection of crystal structures of hDHFR reveals that the bound water molecules perform structural and functional roles in the complexes. Two water molecules located outside the active site, WatA and WatB, have similar NOEs in the binary and ternary complexes. These water molecules from multiple hydrogen bonds bridging loops and/or secondary structural elements in crystal structures of hDHFR and so stabilize the tertiary fold of the enzyme. Two water molecules in the active site, WatC and WatD, also have similar NOEs in both complexes. In crystal structures of hDHFR, WatC is involved in MTX binding by forming hydrogen bonds to the ligand and protein, while WatD stabilizes WatC by hydrogen bonding to it and the protein. A third active-site water molecule, WatE, has a markedly stronger NOE in the ternary complex than in the binary complex. Differences in the binding of WatE in the binary and ternary complexes are important for understanding the mechanism of DHFR, since this water molecule is believed to be involved in substrate protonation. Although the increased NOE intensity for WatE could be caused by a change in the position of water molecule, it may also be caused by an increase in its lifetime, since structural fluctuations in the active site are decreased upon cofactor binding. NOEs for one other water molecule, WatF, may be observed in the ternary complex but not the binary complex. WatF forms hydrogen bonds bridging the cofactor and the protein in crystal structures of hDHFR.

Contributions of tryptophan 24 and glutamate 30 to binding long-lived water molecules in the ternary complex of human dihydrofolate reductase with methotrexate and NADPH studied by site-directed mutagenesis and nuclear magnetic resonance spectroscopy.

Previous NMR studies on the ternary complex of human dihydrofolate reductase (hDHFR) with methotrexate (MTX) and NADPH detected six long-lived bound water molecules. Two of the water molecules, WatA and WatB, stabilize the structure of the protein while the other four, WatC, WatD, WatE and WatF, are involved in substrate binding and specificity. WatE may also act as a proton shuttle during catalysis. Here, the contributions of individual residues to the binding of these water molecules are investigated by performing NMR experiments on ternary complexes of mutant enzymes, W24F, E30A and E30Q. W24 and E30 are conserved residues that form hydrogen bonds with WatE in crystal structures of DHFR. Nuclear Overhauser effects (NOEs) are detected between WatE and the protein in all the mutant complexes, hence WatE still has a long lifetime bound to the complex when one of its hydrogen-bonding partners is deleted or altered by mutagenesis. The NOEs for WatE are much weaker, however, in the mutants than in wild-type. The NOEs for the other water molecules in and near the active site, WatA, WatC, WatD and WatF, also tend to be weaker in the mutant complexes. Little or no change is apparent in the NOEs for WatB, which is located outside the active site, farthest from the mutated residues. The decreased NOE intensities for the bound water molecules could be caused by changes in the positions and/or lifetimes of the water molecules. Chemical shift and NOE data indicate that the mutants have structures very similar to that of wild-type hDHFR, with possible conformational changes occurring only near the mutated residues. Based on the lack of structural change in the protein and evidence for increased structural fluctuations in the active sites of the mutant enzymes, it is likely that the NOE changes are caused, at least in part, by decreases in the lifetimes of the bound water molecules.

Structure and dynamics of barnase complexed with 3'-GMP studied by NMR spectroscopy.

The binding of 3'-GMP to the ribonuclease, barnase, has been studied using heteronuclear 2D and 3D NMR spectroscopy. The 1H and 15N NMR spectra of barnase complexed with 3'-GMP have been assigned. 2D and 3D NOESY spectra have been used to identify inter- and intramolecular NOEs, and a solution structure for the barnase-3'-GMP complex has been calculated. The position of the guanine ring of the ligand is reasonably well defined in the structures. The guanine ring forms hydrogen bonds with the NH protons of Ser57 and Arg59. These residues are located in a loop that is conserved among the microbial guanine-specific ribonucleases. The 2'-hydroxyl of 3'-GMP is close to His102 and Glu73, which have been shown to be involved in catalysis. The phosphate group of 3'-GMP is close to a number of positively charged residues that have also been shown to be important for activity. The position of the sugar moiety of 3'-GMP is less well defined in the structures. Structures calculated for the complex could not simultaneously satisfy all the observed intermolecular NOEs for the sugar protons, suggesting that the sugar samples several conformations when bound to barnase. The binding of 3'-GMP to barnase in solution is similar to that observed in the crystal structures of nucleotides bound to related ribonucleases. 3'-GMP binding causes no major conformational change in barnase. In contrast to the small structural changes that occur, there is a significant decrease in the rates of hydrogen/deuterium exchange and aromatic ring rotation in the active site of barnase upon ligand binding.

Effect of active site residues in barnase on activity and stability.

We have mutated residues in the active site of the ribonuclease, barnase, in order to determine their effects on both enzyme activity and protein stability. Mutation of several of the positively charged residues that interact with the negatively charged RNA substrate (Lys27----Ala, Arg59----Ala and His102----Ala) causes large decreases in activity. This is accompanied, however, by an increase in stability. There is presumably electrostatic strain in the active site where positively charged side-chains are clustered. Mutation of several residues that make hydrogen bonds (Ser57----Ala, Asn58----Asp and Tyr103----Phe) causes smaller decreases in activity, but increases or has no effect on stability. Deletion of hydrogen bonding groups elsewhere in proteins has been found previously to decrease stability by 0.5 to 1.5 kcal mol-1. Conversely, we find that two mutations (Asp54----Asn and Gln104----Ala) decrease stability and increase activity. Another mutation (Glu73----Ala) decreases both activity and stability. It is clear that many residues in the active site do not contribute to stability and that for some, but not all, of the residues there is a compromise between activity and stability. This suggests that certain types of local instability may be necessary for substrate binding and catalysis by barnase. This has implications for the understanding of enzyme activity and the design of enzymes.

The folding of an enzyme. V. H/2H exchange-nuclear magnetic resonance studies on the folding pathway of barnase: complementarity to and agreement with protein engineering studies.

Two major methods are currently being used to characterize transient intermediates during protein folding at the level of individual residues. Nuclear magnetic resonance (n.m.r.) measurements on the protection of peptide NH hydrogens against exchange with solvent during refolding can provide information about secondary structure formation. Protein engineering and kinetics can provide direct information about intramolecular interactions of protein side-chains and indirect evidence on secondary structure. These procedures have provided the most complete pictures so far about protein folding intermediates. Both methods have been applied to the characterization of an intermediate in the refolding of barnase. Although the two methods give complementary information, there are some regions of the protein where the methods overlap well. We show that, with one possible exception that is obscure, n.m.r. and protein engineering give identical results for those interactions that can be analysed by both methods. This suggests that these are valid approaches for the study of protein folding intermediates in the case of barnase and that the combination of the methods is a powerful analytical procedure. Information provided by n.m.r. data that is complementary to the protein engineering experiments is: (1) early formation of the C terminus of helix2; (2) early formation of helix3; (3) early formation of several beta-turns (46-49, 101-104 in loop5); and (5) partial formation of loop5. Confirmatory evidence of protein engineering data on the intermediate is: (1) helix1 is complete from residues 10 to 18; (2) the interactions between all beta-strands are present; (3) part of loop2 is not formed; (4) part of loop3 is formed; and (5) some specific tertiary interactions are not made. For some interactions the protein engineering and H/2H exchange methods overlap directly. The information obtained for direct overlap is self consistent.

Characterization of phosphate binding in the active site of barnase by site-directed mutagenesis and NMR.

Phosphate is a competitive inhibitor of transesterification of GpC by the ribonuclease barnase. Barnase is significantly stabilized in the presence of phosphate against urea denaturation. The data are consistent with the existence of a single phosphate binding site in barnase with a dissociation constant, Kd, of 1.3 mM. The 2D 1H NMR spectrum of wild-type barnase with bound phosphate is assigned. Changes in chemical shifts and NOEs for wild type with bound phosphate compared with free wild type indicate that phosphate binds in the active site and that only small conformational changes occur on binding. Site-directed mutagenesis of the active site residues His-102, Lys-27, and Arg-87 to Ala increases the magnitude of Kd for phosphate by more than 20-fold. The 2D 1H NMR spectra of the mutants His-102----Ala, Lys-27----Ala, and Arg-87----Ala are assigned. Comparison with the spectra of wild-type barnase reveals that His-102----Ala and Lys-27----Ala have essentially the same structure as weild type, while some structural changes occur in Arg-87----Ala. It appears that phosphate binding by barnase is effected mainly by positively charge residues including His-102, Lys-27, and Arg-87. This may have applications for the design of phosphate binding sites in other proteins.

Mapping transition states of protein unfolding by protein engineering of ligand-binding sites.

We describe a method for probing the integrity and relative orientation of structural elements that are indirectly linked by ligands in protein complexes during protein folding. The effect of 3'-GMP on the rate constants of unfolding of wild-type barnase and several mutants has been studied. By comparing the rates of unfolding of wild-type and mutant proteins, we show that the interaction between His102 and 3'-GMP is fully retained in the transition state compared with the folded state, while the interaction between Glu60 and the ligand is partly retained and that of Lys27 is broken. Our data suggest that the transition state has a partly formed ligand binding site in which the guanine binding loop containing Glu60 and the loop containing His102 are formed at the sides of the beta-sheet but the docking of the N terminus of the second alpha-helix containing Lys27 on the beta-sheet is disrupted. The active site of barnase in complexes is thus partly retained in the transition state of unfolding. Although the ligand could in principle perturb the unfolding pathway, there is independent evidence that indicates that similar structural changes occur upon unfolding of unligated barnase.