Structure and characterization of a class 3B proline utilization A: Ligand-induced dimerization and importance of the C-terminal domain for catalysis.

The bifunctional flavoenzyme proline utilization A (PutA) catalyzes the two-step oxidation of proline to glutamate using separate proline dehydrogenase (PRODH) and l-glutamate-γ-semialdehyde dehydrogenase active sites. Because PutAs catalyze sequential reactions, they are good systems for studying how metabolic enzymes communicate via substrate channeling. Although mechanistically similar, PutAs vary widely in domain architecture, oligomeric state, and quaternary structure, and these variations represent different structural solutions to the problem of sequestering a reactive metabolite. Here, we studied PutA from Corynebacterium freiburgense (CfPutA), which belongs to the uncharacterized 3B class of PutAs. A 2.7 Šresolution crystal structure showed the canonical arrangement of PRODH, l-glutamate-γ-semialdehyde dehydrogenase, and C-terminal domains, including an extended interdomain tunnel associated with substrate channeling. The structure unexpectedly revealed a novel open conformation of the PRODH active site, which is interpreted to represent the non-activated conformation, an elusive form of PutA that exhibits suboptimal channeling. Nevertheless, CfPutA exhibited normal substrate-channeling activity, indicating that it isomerizes into the active state under assay conditions. Sedimentation-velocity experiments provided insight into the isomerization process, showing that CfPutA dimerizes in the presence of a proline analog and NAD+ These results are consistent with the morpheein model of enzyme hysteresis, in which substrate binding induces conformational changes that promote assembly of a high-activity oligomer. Finally, we used domain deletion analysis to investigate the function of the C-terminal domain. Although this domain contains neither catalytic residues nor substrate sites, its removal impaired both catalytic activities, suggesting that it may be essential for active-site integrity.

Structural Investigation of a Dimeric Variant of Pyruvate Kinase Muscle Isoform 2.

Pyruvate kinase muscle isoform 2 (PKM2) catalyzes the terminal step in glycolysis, transferring a phosphoryl group from phosphoenolpyruvate to ADP, to produce pyruvate and ATP. PKM2 activity is allosterically regulated by fructose 1,6-bisphosphate (FBP), an upstream glycolytic intermediate. FBP stabilizes the tetrameric form of the enzyme. In its absence, the PKM2 tetramers dissociate, yielding a dimer-monomer mixture having lower enzymatic activity. The S437Y variant of PKM2 is incapable of binding FBP. Consistent with that defect, we find that S437Y exists in a monomer-dimer equilibrium in solution, with a Kd of ∼20 µM. Interestingly, however, the protein crystallizes as a tetramer, providing insight into the structural basis for impaired FBP binding of S437Y.

Importance of the C-Terminus of Aldehyde Dehydrogenase 7A1 for Oligomerization and Catalytic Activity.

Aldehyde dehydrogenase 7A1 (ALDH7A1) catalyzes the terminal step of lysine catabolism, the NAD+-dependent oxidation of α-aminoadipate semialdehyde to α-aminoadipate. Structures of ALDH7A1 reveal the C-terminus is a gate that opens and closes in response to the binding of α-aminoadipate. In the closed state, the C-terminus of one protomer stabilizes the active site of the neighboring protomer in the dimer-of-dimers tetramer. Specifically, Ala505 and Gln506 interact with the conserved aldehyde anchor loop structure in the closed state. The apparent involvement of these residues in catalysis is significant because they are replaced by Pro505 and Lys506 in a genetic deletion (c.1512delG) that causes pyridoxine-dependent epilepsy. Inspired by the c.1512delG defect, we generated variant proteins harboring either A505P, Q506K, or both mutations (A505P/Q506K). Additionally, a C-terminal truncation mutant lacking the last eight residues was prepared. The catalytic behaviors of the variants were examined in steady-state kinetic assays, and their quaternary structures were examined by analytical ultracentrifugation. The mutant enzymes exhibit a profound kinetic defect characterized by markedly elevated Michaelis constants for α-aminoadipate semialdehyde, suggesting that the mutated residues are important for substrate binding. Furthermore, analyses of the in-solution oligomeric states revealed that the mutant enzymes are defective in tetramer formation. Overall, these results suggest that the C-terminus of ALDH7A1 is crucial for the maintenance of both the oligomeric state and the catalytic activity.

EF5 Is the High-Affinity Mg(2+) Site in ALG-2.

The penta-EF-hand (PEF) protein ALG-2 (apoptosis-linked gene 2) has been implicated in several important physiological processes, including endoplasmic reticulum-Golgi vesicular transport and endosomal biogenesis/transport. ALG-2 was recently shown to harbor a metal ion-binding site with a high affinity for Mg(2+) and a low affinity for Ca(2+). We herein present the X-ray structure of Mg(2+)-bound ALG-2des23(wt). Although the C(α) trace is nearly indistinguishable from that of the Ca(2+)-free protein, the orientation of the C-terminal helix differs in the two structures. Consistent with that observation, replacement of the +x ligand in EF5, D169, with alanine eliminates high-affinity Mg(2+) binding. It also eliminates the low-affinity Ca(2+) site and lowers the affinity of the remaining Ca(2+)-binding sites, EF3 and EF1. The coordination environment in EF5 approaches ideal Mg(2+) octahedral geometry. The ligand array, consisting of three carboxylates (+x, +y, +z), a backbone carbonyl (-y), and two water molecules (-x, -z), may offer a recipe for a high-affinity, high-selectivity Mg(2+)-binding site. Sequence data for other PEF proteins indicate that select calpain large subunits, notably CAPN1 and CAPN8, may also possess a high-affinity Mg(2+)-binding site. In Mg(2+)-bound ALG-2, the carbonyl of F188 and the C-terminal carboxylate of V191 interact with the ε-ammonium group of K137 in the opposing subunit, suggesting that Mg(2+) binding could have an impact on dimerization. Interestingly, EF1 and EF3 are also occupied in the crystal, despite having modest affinity for Mg(2+). The results of a calorimetry-based analysis indicate that their Mg(2+) binding constants are 2 orders of magnitude lower than that determined for EF5.

Structural studies of yeast Δ(1)-pyrroline-5-carboxylate dehydrogenase (ALDH4A1): active site flexibility and oligomeric state.

The proline catabolic enzyme Δ(1)-pyrroline-5-carboxylate dehydrogenase (ALDH4A1) catalyzes the NAD(+)-dependent oxidation of γ-glutamate semialdehyde to l-glutamate. In Saccharomyces cerevisiae, ALDH4A1 is encoded by the PUT2 gene and known as Put2p. Here we report the steady-state kinetic parameters of the purified recombinant enzyme, two crystal structures of Put2p, and the determination of the oligomeric state and quaternary structure from small-angle X-ray scattering and sedimentation velocity. Using Δ(1)-pyrroline-5-carboxylate as the substrate, catalytic parameters kcat and Km were determined to be 1.5 s(-1) and 104 µM, respectively, with a catalytic efficiency of 14000 M(-1) s(-1). Although Put2p exhibits the expected aldehyde dehydrogenase superfamily fold, a large portion of the active site is disordered in the crystal structure. Electron density for the 23-residue aldehyde substrate-binding loop is absent, implying substantial conformational flexibility in solution. We furthermore report a new crystal form of human ALDH4A1 (42% identical to Put2p) that also shows disorder in this loop. The crystal structures provide evidence of multiple active site conformations in the substrate-free form of the enzyme, which is consistent with a conformational selection mechanism of substrate binding. We also show that Put2p forms a trimer-of-dimers hexamer in solution. This result is unexpected because human ALDH4A1 is dimeric, whereas some bacterial ALDH4A1s are hexameric. Thus, global sequence identity and domain of life are poor predictors of the oligomeric states of ALDH4A1. Mutation of a single Trp residue that forms knob-in-hole interactions across the dimer-dimer interface abrogates hexamer formation, suggesting that this residue is the center of a protein-protein association hot spot.

Simultaneous addition of two ligands: a potential strategy for estimating divalent ion affinities in EF-hand proteins by isothermal titration calorimetry.

Capable of providing a detailed thermodynamic picture of noncovalent association reactions, isothermal titration calorimetry (ITC) has become a popular method for studying protein-ligand interactions. We routinely employ the technique to study divalent ion-binding by two-site EF-hand proteins from the parvalbumin- and polcalcin lineages. The combination of high Ca(2+) affinity and relatively low Mg(2+) affinity, and the attendant complication of parameter correlation, conspire to make the simultaneous extraction of binding constants and -enthalpies for both ions challenging. Although global analysis of multiple ITC experiments can overcome these hurdles, our current experimental protocol includes upwards of 10 titrations - requiring a substantial investment in labor, machine time, and material. This paper explores the potential for using a smaller suite of experiments that includes simultaneous titrations with Ca(2+) and Mg(2+) at different ratios of the two ions. The results obtained for four proteins, differing substantially in their divalent ion-binding properties, suggest that the approach has merit. The Ca(2+)- and Mg(2+)-binding constants afforded by the streamlined analysis are in reasonable agreement with those obtained from the standard analysis protocol. Likewise, the abbreviated analysis provides comparable values for the Ca(2+)-binding enthalpies. However, the streamlined analysis can yield divergent values for the Mg(2+)-binding enthalpies - particularly those for lower affinity sites. This shortcoming can be remedied, in large measure, by including data from a direct Ca(2+) titration in the presence of a high, fixed Mg(2+) concentration.

Solution structures of polcalcin Phl p 7 in three ligation states: Apo-, hemi-Mg2+-bound, and fully Ca2+-bound.

Polcalcins are small EF-hand proteins believed to assist in regulating pollen-tube growth. Phl p 7, from timothy grass (Phleum pratense), crystallizes as a domain-swapped dimer at low pH. This study describes the solution structures of the recombinant protein in buffered saline at pH 6.0, containing either 5.0 mM EDTA, 5.0 mM Mg(2+), or 100 µM Ca(2+). Phl p 7 is monomeric in all three ligation states. In the apo-form, both EF-hand motifs reside in the closed conformation, with roughly antiparallel N- and C-terminal helical segments. In 5.0 mM Mg(2+), the divalent ion is bound by EF-hand 2, perturbing interhelical angles and imposing more regular helical structure. The structure of Ca(2+)-bound Phl p 7 resembles that previously reported for Bet v 4-likewise exposing apolar surface to the solvent. Occluded in the apo- and Mg(2+)-bound forms, this surface presumably provides the docking site for Phl p 7 targets. Unlike Bet v 4, EF-hand 2 in Phl p 7 includes five potential anionic ligands, due to replacement of the consensus serine residue at -x (residue 55 in Phl p 7) with aspartate. In the Phl p 7 crystal structure, D55 functions as a helix cap for helix D. In solution, however, D55 apparently serves as a ligand to the bound Ca(2+). When Mg(2+) resides in site 2, the D55 carboxylate withdraws to a distance consistent with a role as an outer-sphere ligand. (15)N relaxation data, collected at 600 MHz, indicate that backbone mobility is limited in all three ligation states.

Crystal structure of the bifunctional proline utilization A flavoenzyme from Bradyrhizobium japonicum.

The bifunctional proline catabolic flavoenzyme, proline utilization A (PutA), catalyzes the oxidation of proline to glutamate via the sequential activities of FAD-dependent proline dehydrogenase (PRODH) and NAD(+)-dependent Delta(1)-pyrroline-5-carboxylate dehydrogenase (P5CDH) domains. Although structures for some of the domains of PutA are known, a structure for the full-length protein has not previously been solved. Here we report the 2.1 A resolution crystal structure of PutA from Bradyrhizobium japonicum, along with data from small-angle x-ray scattering, analytical ultracentrifugation, and steady-state and rapid-reaction kinetics. PutA forms a ring-shaped tetramer in solution having a diameter of 150 A. Within each protomer, the PRODH and P5CDH active sites face each other at a distance of 41 A and are connected by a large, irregularly shaped cavity. Kinetics measurements show that glutamate production occurs without a lag phase, suggesting that the intermediate, Delta(1)-pyrroline-5-carboxylate, is preferably transferred to the P5CDH domain rather than released into the bulk medium. The structural and kinetic data imply that the cavity serves both as a microscopic vessel for the hydrolysis of Delta(1)-pyrroline-5-carboxylate to glutamate semialdehyde and a protected conduit for the transport of glutamate semialdehyde to the P5CDH active site.

Solution structures of chicken parvalbumin 3 in the Ca(2+)-free and Ca(2+)-bound states.

Birds express two ß-parvalbumin isoforms, parvalbumin 3 and avian thymic hormone (ATH). Parvalbumin 3 from chicken (CPV3) is identical to rat ß-parvalbumin (ß-PV) at 75 of 108 residues. CPV3 displays intermediate Ca(2+) affinity--higher than that of rat ß-parvalbumin, but lower than that of ATH. As in rat ß-PV, the attenuation of affinity is associated primarily with the CD site (residues 41-70), rather than the EF site (residues 80-108). Structural data for rat α- and ß-parvalbumins suggest that divalent ion affinity is correlated with the similarity of the unliganded and Ca(2+)-bound conformations. We herein present a comparison of the solution structures of Ca(2+)-free and Ca(2+)-bound CPV3. Although the structures are generally similar, the conformations of residues 47 to 50 differ markedly in the two protein forms. These residues are located in the C helix, proximal to the CD binding loop. In response to Ca(2+) removal, F47 experiences much greater solvent accessibility. The side-chain of R48 assumes a position between the C and D helices, adjacent to R69. Significantly, I49 adopts an interior position in the unliganded protein that allows association with the side-chain of L50. Concomitantly, the realignment of F66 and F70 facilitates their interaction with I49 and reduces their contact with residues in the N-terminal AB domain. This reorganization of the hydrophobic core, although less profound, is nevertheless reminiscent of that observed in rat ß-PV. The results lend further support to the idea that Ca(2+) affinity correlates with the structural similarity of the apo- and bound parvalbumin conformations.

Crystal structure of a bacterial phosphoglucomutase, an enzyme involved in the virulence of multiple human pathogens.

The crystal structure of the enzyme phosphoglucomutase from Salmonella typhimurium (StPGM) is reported at 1.7 A resolution. This is the first high-resolution structural characterization of a bacterial protein from this large enzyme family, which has a central role in metabolism and is also important to bacterial virulence and infectivity. A comparison of the active site of StPGM with that of other phosphoglucomutases reveals conserved residues that are likely involved in catalysis and ligand binding for the entire enzyme family. An alternate crystal form of StPGM and normal mode analysis give insights into conformational changes of the C-terminal domain that occur upon ligand binding. A novel observation from the StPGM structure is an apparent dimer in the asymmetric unit of the crystal, mediated largely through contacts in an N-terminal helix. Analytical ultracentrifugation and small-angle X-ray scattering confirm that StPGM forms a dimer in solution. Multiple sequence alignments and phylogenetic studies show that a distinct subset of bacterial PGMs share the signature dimerization helix, while other bacterial and eukaryotic PGMs are likely monomers. These structural, biochemical, and bioinformatic studies of StPGM provide insights into the large α-D-phosphohexomutase enzyme superfamily to which it belongs, and are also relevant to the design of inhibitors specific to the bacterial PGMs.

Crystal structure and immunogenicity of the class C acid phosphatase from Pasteurella multocida.

Pasteurella multocida is a pathogen of veterinary and medical importance. Here, we report the 1.85Å resolution crystal structure of the class C acid phosphatase from this organism (denoted rPmCCAP). The structure shows that rPmCCAP exhibits the same haloacid dehalogenase fold and dimeric assembly as the class C enzyme from Haemophilus influenzae. Formation of the dimer in solution is demonstrated using analytical ultracentrifugation. The active site is devoid of a magnesium ion due to the presence of citrate in the crystallization buffer. Absence of the metal ion minimally perturbs the active site structure, which suggests that the main role of the ion is to balance the negative charge of the substrate rather than stabilize the active site structure. The crystal lattice displays unusual crystal packing involving the C-terminal polyhistidine tag mimicking the substrate. Steady-state kinetic constants are determined for the substrates NMN, 5'-AMP, 3'-AMP, 2'-AMP, and p-nitrophenyl phosphate. The highest catalytic efficiency is observed with NMN. The production of polyclonal anti-rPmCCAP antibodies is demonstrated, and these antibodies are shown to cross-react with the H. influenzae class C phosphatase. The antibodies are used to detect PmCCAP in clinical P. multocida and Mannheimia haemolytica strains cultured from infected animals.

Polcalcin divalent ion-binding behavior and thermal stability: comparison of Bet v 4, Bra n 1, and Bra n 2 to Phl p 7.

Polcalcins are pollen-specific proteins containing two EF-hands. Atypically, the C-terminal EF-hand binding loop in Phl p 7 (from timothy grass) harbors five, rather than four, anionic side chains, due to replacement of the consensus serine at -x by aspartate. This arrangement has been shown to heighten parvalbumin Ca(2+) affinity. To determine whether Phl p 7 likewise exhibits anomalous divalent ion affinity, we have also characterized Bra n 1 and Bra n 2 (both from rapeseed) and Bet v 4 (from birch tree). Relative to Phl p 7, they exhibit N-terminal extensions of one, five, and seven residues, respectively. Interestingly, the divalent ion affinity of Phl p 7 is unexceptional. For example, at -17.84 +/- 0.13 kcal mol(-1), the overall standard free energy for Ca(2+) binding falls within the range observed for the other three proteins (-17.30 +/- 0.10 to -18.15 +/- 0.10 kcal mol(-1)). In further contrast to parvalbumin, replacement of the -x aspartate, via the D55S mutation, actually increases the overall Ca(2+) affinity of Phl p 7, to -18.17 +/- 0.13 kcal mol(-1). Ca(2+)-free Phl p 7 exhibits uncharacteristic thermal stability. Whereas wild-type Phl p 7 and the D55S variant denature at 77.3 and 78.0 degrees C, respectively, the other three polcalcins unfold between 56.1 and 57.9 degrees C. This stability reflects a low denaturational heat capacity increment. Phl p 7 and Phl p 7 D55S exhibit DeltaC(p) values of 0.34 and 0.32 kcal mol(-1) K(-1), respectively. The corresponding values for the other three polcalcins range from 0.66 to 0.95 kcal mol(-1) K(-1).

Oncomodulin is a macrophage-derived signal for axon regeneration in retinal ganglion cells.

The optic nerve, like most mature CNS pathways, does not regenerate after injury. Through unknown mechanisms, however, macrophage activation in the eye stimulates retinal ganglion cells (RGCs) to regenerate long axons beyond the site of optic nerve injury. Here we identify the calcium (Ca(2+))-binding protein oncomodulin as a potent macrophage-derived growth factor for RGCs and other neurons. Oncomodulin binds to rat RGCs with high affinity in a cyclic AMP (cAMP)-dependent manner and stimulates more extensive outgrowth than other known trophic agents. Depletion of oncomodulin from macrophage-conditioned media (MCM) eliminates the axon-promoting activity of MCM. The effects of oncomodulin involve downstream signaling via Ca(2+)/calmodulin kinase and gene transcription. In vivo, oncomodulin released from microspheres promotes regeneration in the mature rat optic nerve. Oncomodulin also stimulates outgrowth from peripheral sensory neurons. Thus, oncomodulin is a new growth factor for neurons of the mature central and peripheral nervous systems.

Evidence for a Ca(2+)-specific conformational change in avian thymic hormone, a high-affinity beta-parvalbumin.

Named for the capacity to stimulate differentiation and maturation of T-cell precursors, avian thymic hormone (ATH) is nonetheless a beta-parvalbumin that is also expressed in the avian retina. With Ca(2+)- and Mg(2+)-binding constants in excess of 10(8) and 10(4) M(-1), respectively, both EF-hand motifs qualify as Ca(2+)/Mg(2+) sites. However, whereas addition of either apo- or Mg(2+)-bound ATH to 1,8-anilinonaphthalenesulfonic acid (ANS) causes a large increase in quantum yield and a pronounced blue shift, addition of the Ca(2+)-bound protein is without effect. These observations suggest that apo- and Mg(2+)-bound ATH adopt conformations distinct from the Ca(2+)-bound protein, exposing apolar surface for interaction with ANS. Differential scanning calorimetry (DSC) data imply that unfolding of apo-ATH is accompanied by diminished exposure of apolar surface, relative to Ca(2+)-free rat beta-PV, perhaps due to greater solvent-accessible apolar surface in the native form. The fluorescence and DSC results, considered together, may indicate that the AB and CD-EF domains of ATH are not tightly associated in the absence of bound Ca(2+). Consistent with this idea, sedimentation velocity data reveal that the apo- and Mg(2+)-bound forms of ATH show greater departures from spherical symmetry than the Ca(2+)-bound state. These findings suggest that a high-affinity binding signature does not require that the parvalbumin apo- and Ca(2+)-bound conformations be indistinguishable, as we have recently proposed. They also suggest that it is possible to engineer a Ca(2+)-dependent conformational change into a high-affinity EF-hand protein, furnishing a mechanism by which the protein could play a reverse Ca(2+) sensor role.

Characterization of a unique class C acid phosphatase from Clostridium perfringens.

Clostridium perfringens is a gram-positive anaerobe and a pathogen of medical importance. The detection of acid phosphatase activity is a powerful diagnostic indicator of the presence of C. perfringens among anaerobic isolates; however, characterization of the enzyme has not previously been reported. Provided here are details of the characterization of a soluble recombinant form of this cell-associated enzyme. The denatured enzyme was approximately 31 kDa and a homodimer in solution. It catalyzed the hydrolysis of several substrates, including para-nitrophenyl phosphate, 4-methylumbelliferyl phosphate, and 3' and 5' nucleoside monophosphates at pH 6. Calculated K(m)s ranged from 0.2 to 0.6 mM with maximum velocity ranging from 0.8 to 1.6 micromol of P(i)/s/mg. Activity was enhanced in the presence of some divalent cations but diminished in the presence of others. Wild-type enzyme was detected in all clinical C. perfringens isolates tested and found to be cell associated. The described enzyme belongs to nonspecific acid phosphatase class C but is devoid of lipid modification commonly attributed to this class.

Solution structure of Ca2+-free rat alpha-parvalbumin.

Mammals express two parvalbumins-an alpha isoform and a beta isoform. In rat, the alpha-parvalbumin (alpha-PV) exhibits superior divalent ion affinity. For example, the standard free energies for Ca2+ binding differ by 5.5 kcal/mol in 0.15 M KCl (pH 7.4). High-resolution structures of the Ca2+-bound proteins provide little insight into this disparity, prompting a structural analysis of the apo-proteins. A recent analysis of rat beta-PV suggested that Ca2+ removal provokes substantial conformational changes-reorientation of the C, D, and E helices; reorganization of the hydrophobic core; reduced interdomain contact; and remodeling of the AB domain. The energetic penalty attendant to reversing these changes, it was suggested, could contribute to the attenuated divalent ion-binding signature of that protein. That hypothesis is supported by data presented herein, describing the solution structure and peptide backbone dynamics of Ca2+-free rat alpha-PV. In marked contrast to rat beta-PV, the apo- and Ca2+-loaded forms of the rat alpha isoform are quite similar. Significant structural differences appear to be confined to the loop regions of the molecule. This finding implies that the alpha-PV isoform enjoys elevated divalent ion affinity because the metal ion-binding events do not require major structural rearrangement and the concomitant sacrifice of binding energy.

Leucine 85 is an important determinant of divalent ion affinity in rat beta-parvalbumin (Oncomodulin).

Despite 69% sequence identity with chicken parvalbumin 3 (CPV3), rat beta-parvalbumin (beta-PV) exhibits a substantially lower Ca(2+) affinity (DeltaDeltaG degrees ' = 2.0 kcal/mol). This difference largely reflects the disparate behavior of the respective CD sites. Replacement of the rat beta-PV codon with the CPV3 codon at positions 49, 50, and 57-60 produces virtual sequence identity with the CPV3 CD site. However, the resulting protein exhibits a modest (0.5 kcal/mol) improvement in Ca(2+) affinity, implying that sequence differences beyond the binding site modulate divalent ion binding behavior. The solution structure of Ca(2+)-free rat beta-PV suggested that Leu-85, phenylalanine in CPV3, might be an important determinant. Therefore, the impact of the L85F mutation on divalent ion affinity was examined in rat beta-PV, in the variant harboring all six of the aforementioned CD site mutations, and in the intermediate CD site variants. We find that the identity of residue 85, located within the E helix, strongly influences divalent ion affinity in the mammalian beta-PV isoform and that its impact is mediated by interactions with residues in the CD site. In the wild-type protein, L85F primarily affects the EF site. By contrast, in the presence of the six CD site mutations, L85F also improves the CD site performance, yielding a protein with Ca(2+) affinity rivaling that of CPV3 and markedly enhanced Mg(2+) affinity as well. The impact of L85F on CD site Ca(2+) affinity is particularly sensitive to the identities of residues 59 and 60. Interestingly, however, significant improvement in CD site Mg(2+) affinity also requires mutation of additional CD site residues.

Divalent ion binding properties of the timothy grass allergen, Phl p 7.

The timothy grass allergen, Phl p 7, was studied by calorimetry, spectroscopy, and analytical ultracentrifugation. As judged by isothermal titration calorimetry (ITC), the protein binds Ca (2+) cooperatively with stepwise macroscopic association constants of 1.73 x 10 (6) and 8.06 x 10 (6) M (-1). By contrast, Mg (2+) binding is sequential with apparent macroscopic association constants of 2.78 x 10 (4) and 170 M (-1). Circular dichroism and ANS fluorescence data suggest that Ca (2+) binding provokes a major conformational change that does not occur upon Mg (2+) binding. Conformational stability was assessed by differential scanning calorimetry (DSC). In phosphate-buffered saline (PBS) containing EDTA, the apoprotein undergoes two-state denaturation with a T m of 78.4 degrees C. In the presence of 0.02 mM Ca (2+), the T m exceeds 120 degrees C. Phl p 7 is known to crystallize as a domain-swapped dimer at low pH. However, analytical ultracentrifugation data indicate that the protein is monomeric in neutral solution at concentrations exceeding 1.0 mM, in both the apo and Ca (2+)-bound states.

Energetics of OCP1-OCP2 complex formation.

OCP1 and OCP2, the most abundant proteins in the cochlea, are putative subunits of an SCF E3 ubiquitin ligase. Previous work has demonstrated that they form a heterodimeric complex. The thermodynamic details of that interaction are herein examined by isothermal titration calorimetry. At 25 degrees C, addition of OCP1 to OCP2 yields an apparent association constant of 4.0 x 10(7) M(-1). Enthalpically-driven (DeltaH=-35.9 kcal/mol) and entropically unfavorable (-TDeltaS=25.5 kcal/mol), the reaction is evidently unaccompanied by protonation/deprotonation events. DeltaH is strongly dependent on temperature, with DeltaC(p)=-1.31 kcal mol(-1) K(-1). Addition of OCP2 to OCP1 produces a slightly less favorable DeltaH, presumably due to the requirement for dissociation of the OCP2 homodimer prior to OCP1 binding. The thermodynamic signature for OCP1/OCP2 complex formation is inconsistent with a rigid-body association and suggests that the reaction is accompanied by a substantial degree of folding.

Ligation events influence ALG-2 dimerization.

ALG-2 dimerization was studied using Förster resonance-energy-transfer. D162C variants of ALG-2des23 were covalently modified with Alexa Fluor 488 and Alexa Fluor 647. When samples of the two labeled protein-preparations are combined, the sensitized emission from AF647 serves as a sensitive probe of dimer formation. At 25 °C, in the absence of divalent ions, the wild-type homodimer, ΔGF122 homodimer, and heterodimer display dissociation constants of 7.1, 26, and 4.5 nM, respectively. At 35 °C, subunit interaction is weaker, indicating that dimer formation is exothermic. Binding of Mg2+ in the C-terminal EF-hand (EF5) dramatically enhances ALG-2 dimer stability. Although occupation of EF5 by Ca2+ likewise has a stabilizing effect, its direct influence on dimer stability would be negligible at cytosolic Ca2+ levels. However, dimer stability is substantially increased by the Ca2+-dependent binding of ALG-2 target-peptides, suggesting that the occupation-status of the target-protein binding site is communicated to the dimer interface. Tween 20 is commonly used to improve ALG-2 solubility, the micelles ostensibly acting as target-protein surrogates. Paradoxically, however, the detergent markedly destabilizes ALG-2 dimers, particularly in the presence of Ca2+.