Structure of the SH3-guanylate kinase module from PSD-95 suggests a mechanism for regulated assembly of MAGUK scaffolding proteins.

Membrane-associated guanylate kinases (MAGUKs), such as PSD-95, are modular scaffolds that organize signaling complexes at synapses and other cell junctions. MAGUKs contain PDZ domains, which recruit signaling proteins, as well as a Src homology 3 (SH3) and a guanylate kinase-like (GK) domain, implicated in scaffold oligomerization. The crystal structure of the SH3-GK module from PSD-95 reveals that these domains form an integrated unit: the SH3 fold comprises noncontiguous sequence elements divided by a hinge region and the GK domain. These elements compose two subdomains that can assemble in either an intra- or intermolecular fashion to complete the SH3 fold. We propose a model for MAGUK oligomerization in which complementary SH3 subdomains associate by 3D domain swapping. This model provides a possible mechanism for ligand regulation of oligomerization.

Integration of multiple signals through cooperative regulation of the N-WASP-Arp2/3 complex.

The protein N-WASP [a homolog to the Wiskott-Aldrich syndrome protein (WASP)] regulates actin polymerization by stimulating the actin-nucleating activity of the actin-related protein 2/3 (Arp2/3) complex. N-WASP is tightly regulated by multiple signals: Only costimulation by Cdc42 and phosphatidylinositol (4,5)-bisphosphate (PIP2) yields potent polymerization. We found that regulation requires N-WASP's constitutively active output domain (VCA) and two regulatory domains: a Cdc42-binding domain and a previously undescribed PIP(2)-binding domain. In the absence of stimuli, the regulatory modules together hold the VCA-Arp2/3 complex in an inactive "closed" conformation. In this state, both the Cdc42- and PIP2-binding sites are masked. Binding of either input destabilizes the closed state and enhances binding of the other input. This cooperative activation mechanism shows how combinations of simple binding domains can be used to integrate and amplify coincident signals.

Structure of the enabled/VASP homology 1 domain-peptide complex: a key component in the spatial control of actin assembly.

The Enabled/VASP homology 1 (EVH1; also called WH1) domain is an interaction module found in several proteins implicated in actin-based cell motility. EVH1 domains bind the consensus proline-rich motif FPPPP and are required for targeting the actin assembly machinery to sites of cytoskeletal remodeling. The crystal structure of the mammalian Enabled (Mena) EVH1 domain complexed with a peptide ligand reveals a mechanism of recognition distinct from that used by other proline-binding modules. The EVH1 domain fold is unexpectedly similar to that of the pleckstrin homology domain, a membrane localization module. This finding demonstrates the functional plasticity of the pleckstrin homology fold as a binding scaffold and suggests that membrane association may play an auxiliary role in EVH1 targeting.

Unexpected modes of PDZ domain scaffolding revealed by structure of nNOS-syntrophin complex.

The PDZ protein interaction domain of neuronal nitric oxide synthase (nNOS) can heterodimerize with the PDZ domains of postsynaptic density protein 95 and syntrophin through interactions that are not mediated by recognition of a typical carboxyl-terminal motif. The nNOS-syntrophin PDZ complex structure revealed that the domains interact in an unusual linear head-to-tail arrangement. The nNOS PDZ domain has two opposite interaction surfaces-one face has the canonical peptide binding groove, whereas the other has a beta-hairpin "finger." This nNOS beta finger docks in the syntrophin peptide binding groove, mimicking a peptide ligand, except that a sharp beta turn replaces the normally required carboxyl terminus. This structure explains how PDZ domains can participate in diverse interaction modes to assemble protein networks.

Pressure denaturation of proteins: evaluation of compressibility effects.

One of the key pieces of information from pressure denaturation experiments is the standard volume change for unfolding (Delta V(o)). The pressure dependence of the volume change, the standard compressibility change (Delta K(o)T), is typically assumed to be zero in the analysis of these experiments. We show here that this assumption can be incorrect and that the neglect of compressibility differences can skew the interpretation of experimental results. Analysis of experimental, variable-pressure NMR data for bovine pancreatic ribonuclease A in 2H2O at pH 2.0 and 295 K yielded the following statistically significant, non-zero values: Delta K(o) T = 0.015 +/- 0.002 mL mol-1 bar-1, Delta V(o) = -21 +/- 2 mL mol-1, and Delta G(o) = 2.8 +/- 0.3 kcal mol-1. The experimental protein stability is in good agreement with one (Delta G(o) = 2.5 kcal mol-1) determined independently for the same protein by calorimetry at atmospheric pressure under equivalent conditions [Makhatadze, G. I., Clore, G. M., and Gronenborn, A. M. (1995) Nat. Struct. Biol. 2, 852-855]. The positive value for Delta K(o)T indicates that the denatured form of ribonuclease A is more compressible than the native form; this is explained in terms of an interplay between the intrinsic compressibility of the protein and solvation effects. When the same data were fitted to a model that assumes a zero compressibility change, the Delta G(o) value of 4. 0 +/- 0.1 kcal mol-1 returned by the model no longer agreed with the independent measurement, and the Delta V(o) returned by the model was a very different -59 +/- 1 mL mol-1. By contrast, it was not possible to carry out a similar thermodynamic analysis of fluorescence spectroscopic data for the denaturation of staphylococcal nuclease to yield well-defined values of Delta G(o), Delta V(o), and Delta K(o)T. This limitation was shown by evaluation of synthetic data to be intrinsic to spectroscopic data whose analysis requires fitting of the plateaus at either side of the transition. Because NMR data do not have this requirement, they can be analyzed more rigorously.

Microscopic pKa values of Escherichia coli thioredoxin.

Thiol:disulfide oxidoreductases have a CXXC motif within their active sites. To initiate the reduction of a substrate disulfide bond, the thiolate form of the N-terminal cysteine residue (CXXC) of this motif performs a nucleophilic attack. Escherichia coli thioredoxin [Trx (CGPC)] is the best characterized thiol:disulfide oxidoreductase. Previous determinations of the active-site pKa values of Trx have led to conflicting interpretations. Here, 13C-NMR spectroscopy, site-specific isotopic labeling, and site-directed mutagenesis were used to demonstrate that analysis of the titration behavior of wild-type Trx requires the invocation of microscopic pKa values for two interacting active-site residues: Asp26 (7.5 and 9.2) and Cys32 (CXXC; 7.5 and 9.2). By contrast, in two Trx variants, D26N Trx and D26L Trx, Cys32 exhibits a pKa near 7.5 and has a well-defined, single-pKa titration curve. Similarly, in oxidized wild-type Trx, Asp26 has a pKa near 7.5. In CVWC and CWGC Trx, Cys32 exhibits a single pKa near 6.2. In all five enzymes studied here, there is no evidence for a Cys35 (CXXC) pKa of < 11. This study demonstrates that a comprehensive approach must be used to unravel complex titration behavior of the functional groups in a protein.

The CXXC motif: a rheostat in the active site.

The active-site CXXC motif of thiol:disulfide oxidoreductases is essential for their catalysis of redox reactions. Changing the XX residues can perturb the reduction potential of the active-site disulfide bond of the Escherichia coli enzymes thioredoxin (Trx; CGPC) and DsbA (CPHC). The reduction potential is correlated with the acidity of the N-terminal cysteine residue of the CXXC motif. As the pKa is lowered, the disulfide bond becomes more easy to reduce. A change in pKa can account fully for a change in reduction potential in well-characterized CXXC motifs of DsbA but not of Trx. Formal analysis of the Nernst equation reveals that reduction potential contains both pH-dependent and pH-independent components. Indeed, the difference between the reduction potentials of wild-type Trx and wild-type DsbA cannot be explained solely by differences in thiol pKa values. Structural data for thiol:disulfide oxidoreductases reveal no single factor that determines the pH-independent component of the reduction potential. In addition, the pH-dependent component is complex when the redox state of the CXXC motif affects the titration of residues other than the thiols. These intricacies enable CXXC motifs to vary widely in their capacity to assist electron flow, and thereby engender a family of thiol:disulfide oxidoreductases that play diverse roles in biochemistry.

Coupling between trans/cis proline isomerization and protein stability in staphylococcal nuclease.

The nucleases A produced by two strains of Staphylococcus aureus, which have different stabilities, differ only in the identity of the single amino acid at residue 124. The nuclease from the Foggi strain of S. aureus (by convention nuclease WT), which contains His124, is 1.9 kcal.mol-1 less stable (at pH 5.5 and 20 degrees C) than the nuclease from the V8 strain (by convention nuclease H124L), which contains Leu124. In addition, the population of the trans conformer at the Lys116-Pro117 peptide bond, as observed by NMR spectroscopy, is different for the two variants: about 15% for nuclease WT and 9% for nuclease H124L. In order to improve our understanding of the origin of these differences, we compared the properties of WT and H124L with those of the H124A and H124I variants. We discovered a correlation between effects of different residues at this position on protein stability and on stabilization of the cis configuration of the Lys116-Pro117 peptide bond. In terms of free energy, approximately 17% of the increase in protein stability manifests itself as stabilization of the cis configuration at Lys116-Pro117. This result implies that the differences in stability arise mainly from structural differences between the cis configurational isomers at Pro117 of the different variants at residue 124. We solved the X-ray structure of the cis form of the most stable variant, H124L, and compared it with the published high-resolution X-ray structure of the cis form of the most stable variant, WT (Hynes TR, Fox RO, 1991, Proteins Struct Funct Genet 10:92-105). The two structures are identical within experimental error, except for the side chain at residue 124, which is exposed in the models of both variants. Thus, the increased stability and changes in the trans/cis equilibrium of the Lys116-Pro117 peptide bond observed in H124L relative to WT are due to subtle structural changes that are not observed by current structure determination technique. Residue 124 is located in a helix. However, the stability changes are too large and follow the wrong order of stability to be explained simply by differences in helical propensity. A second site of conformational heterogeneity in native nuclease is found at the His46-Pro47 peptide bond, which is approximately 80% trans in both WT and H124L. Because proline to glycine substitutions at either residue 47 or 117 remove the structural heterogeneity at that position and increase protein stability, we determined the X-ray structures of H124L + P117G and H124L + P47G + P117G and the kinetic parameters of H124L, H124L + P47G, H124L + P117G, and H124L + P47G + P117G. The individual P117G and P47G mutations cause decreases in nuclease activity, with kcat affected more than Km, and their effects are additive. The P117G mutation in nuclease H124L leads to the same local conformational rearrangement described for the P117G mutant of WT (Hynes TR, Hodel A, Fox RO, 1994, Biochemistry 33:5021-5030). In both P117G mutants, the loop formed by residues 112-117 is located closer to the adjacent loop formed by residues 77-85, and residues 115-118 adopt a type I' beta-turn conformation with the Lys116-Gly117 peptide bond in the trans configuration, as compared with the parent protein in which these residues have a typeVIa beta-turn conformation with the Lys116-Pro117 peptide bond in the cis configuration. Addition of the P47G mutation appears not to cause any additional structural changes. However, the electron density for part of the loop containing this peptide bond was not strong enough to be interpreted.

Hydrogen exchange in unligated and ligated staphylococcal nuclease.

The exchange kinetics of over 70% of the 143 backbone amide hydrogens in staphylococcal nuclease H124L (nuclease H124L), both in its unligated state and in its ternary complex with Ca2+ and thymidine 3',5'-bisphosphate, have been quantified by nitrogen-15 resolved proton nuclear magnetic resonance spectroscopy. Protection factors for the slowly exchanging hydrogens in unligated nuclease H124L at 37 degrees C and pH 5.5 were found to vary by over one order of magnitude. This range of protection factors has been interpreted in the framework of global and local structural fluctuations. The three most highly protected hydrogens (K24, L25, M26) map to strand 2 of the central five-stranded beta-barrel. The free energy change for the opening reaction which exposes these hydrogens to the solvent (delta G(degree)op) was calculated from the exchange rates in the native and denatured states, the latter values being estimated from model peptide exchange studies [Molday, R. S., Englander, S. W., & Kallen, R. G. (1972) Biochemistry 11, 150-158]. Close agreement was found between delta G(degree)op and delta G(degree)u, the free energy change of unfolding as measured by urea denaturation experiments. Exchange of these hydrogens thus appears to occur via global unfolding of the protein. One region exhibited somewhat lower protection factors: it mapped to the C-terminal portions of helix 2 and helix 3 and to part of the intervening segment. This region has been identified as a minor hydrophobic domain of nuclease [Shortle, D., Stites, W. E., & Meeker, A. K. (1990) Biochemistry 29, 8033-8041].(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of amino acid substitutions on the pressure denaturation of staphylococcal nuclease as monitored by fluorescence and nuclear magnetic resonance spectroscopy.

In the present study we have used high hydrostatic pressure coupled with either time-resolved and steady-state fluorescence or NMR spectroscopy in order to investigate the effects of amino acid substitutions on the high-pressure denaturation properties of staphylococcal nuclease. This protein has been shown previously to be structurally heterogeneous in its native state. On the NMR time scale, four distinct interconverting conformational forms arise from the population of both cis and trans Xaa-Pro peptide bonds (His46-Pro47 and Lys116-Pro117) [Evans et al. (1989) Biochemistry 28, 362; Loh et al. (1991) in Techniques in Protein Chemistry II, pp 275-282, Academic Press, New York]. Mutations in the protein sequence have been shown to change the distribution among the various forms [Alexandrescu et al. (1989) Biochemistry 28, 204; Alexandrescu et al. (1990) Biochemistry 29, 4516]. Time-resolved fluorescence on a series of mutants with altered equilibria for cis/trans isomerism about the 116-117 peptide bond did not reveal any simple relationship between the position of the cis/trans equilibrium in the folded state and the heterogeneity of the fluorescence decay. However, the specific dynamic properties of each mutant, as revealed by time-resolved fluorescence, do appear to be correlated with their partial molar volume changes of denaturation. A striking finding is that mutation of either (or both) of the prolines that exhibits structural heterogeneity to glycine greatly alters the stability of the protein to pressure. These mutations also result in decreased chain mobility as assessed by time-resolved fluorescence. It appears that packing defects, which allow for peptide bond cis/trans heterogeneity in the wild-type protein, are removed by the Pro-->Gly substitutions.