Folding, stability, and physical properties of the alpha subunit of bacterial luciferase

Bacterial luciferase is a heterodimeric (alphabeta) enzyme composed of homologous subunits. When the Vibrio harveyi luxA gene is expressed in Escherichia coli, the alpha subunit accumulates to high levels. The alpha subunit has a well-defined near-UV circular dichroism spectrum and a higher intrinsic fluorescence than the heterodimer, demonstrating fluorescence quenching in the enzyme which is reduced in the free subunit [Sinclair, J. F., Waddle, J. J., Waddill, W. F., and Baldwin, T. O. (1993) Biochemistry 32, 5036-5044]. Analytical ultracentrifugation of the alpha subunit has revealed a reversible monomer to dimer equilibrium with a dissociation constant of 14.9 +/- 4.0 microM at 18 degrees C in 50 mM phosphate and 100 mM NaCl, pH 7.0. The alpha subunit unfolded and refolded reversibly in urea-containing buffers by a three-state mechanism. The first transition occurred over the range of 0-2 M urea with an associated free-energy change of 2.24 +/- 0.25 kcal/mol at 18 degrees C in 50 mM phosphate buffer, pH 7.0. The second, occurring between 2.5 and 3.5 M urea, comprised a cooperative transition with a free-energy change of 6.50 +/- 0.75 kcal/mol. The intermediate species, populated maximally at ca. 2 M urea, has defined near-UV circular dichroism spectral properties distinct from either the native or the denatured states. The intrinsic fluorescence of the intermediate suggested that, although the quantum yield had decreased, the tryptophanyl residues remained largely buried. The far-UV circular dichroism spectrum of the intermediate indicated that it had lost ca. 40% of its native secondary structure. N-Terminal sequencing of the products of limited proteolysis of the intermediate showed that the C-terminal region of the alpha subunit became protease labile over the urea concentration range at which the intermediate was maximally populated. These observations have led us to propose an unfolding model in which the first transition is the unfolding of a C-terminal subdomain and the second transition represents the unfolding of a more stable N-terminal subdomain. Comparison of the structural properties of the unfolding intermediate using spectroscopic probes and limited proteolysis of the alpha subunit with those of the alphabeta heterodimer suggested that the unfolding pathway of the alpha subunit is the same, whether it is in the form of the free subunit or in the heterodimer.     

Structure of the beta 2 homodimer of bacterial luciferase from Vibrio harveyi: X-ray analysis of a kinetic protein folding trap.

Luciferase, as isolated from Vibrio harveyi, is an alpha beta heterodimer. When allowed to fold in the absence of the alpha subunit, either in vitro or in vivo, the beta subunit of enzyme will form a kinetically stable homodimer that does not unfold even after prolonged incubation in 5 M urea at pH 7.0 and 18 degrees C. This form of the beta subunit, arising via kinetic partitioning on the folding pathway, appears to constitute a kinetically trapped alternative to the heterodimeric enzyme (Sinclair JF, Ziegler MM, Baldwin TO. 1994. Kinetic partitioning during protein folding yields multiple native states. Nature Struct Biol 1: 320-326). Here we describe the X-ray crystal structure of the beta 2 homodimer of luciferase from V. harveyi determined and refined at 1.95 A resolution. Crystals employed in the investigational belonged to the orthorhombic space group P2(1)2(1)2(1) with unit cell dimensions of a = 58.8 A, b = 62.0 A, and c = 218.2 A and contained one dimer per asymmetric unit. Like that observed in the functional luciferase alpha beta heterodimer, the major tertiary structural motif of each beta subunit consists of an (alpha/beta)8 barrel (Fisher AJ, Raushel FM, Baldwin TO, Rayment I. 1995. Three-dimensional structure of bacterial luciferase from Vibrio harveyi at 2.4 A resolution. Biochemistry 34: 6581-6586). The root-mean-square deviation of the alpha-carbon coordinates between the beta subunits of the hetero- and homodimers is 0.7 A. This high resolution X-ray analysis demonstrated that "domain" or "loop" swapping has not occurred upon formation of the beta 2 homodimer and thus the stability of the beta 2 species to denaturation cannot be explained in such simple terms. In fact, the subunit:subunit interfaces observed in both the beta 2 homodimer and alpha beta heterodimer are remarkably similar in hydrogen-bonding patterns and buried surface areas.     

Active site ligand stabilization of quaternary structures of glutamine synthetase from Escherichia coli

Auto-inactivated EScherichia coli glutamine synthetase contains 1 eq each of L-methionine-S-sulfoximine phosphate and ADP and 2 eq of Mn2+ tightly bound to the active site of each subunit of the dodecameric enzyme (Maurizi, M. R., and Ginsburg, A. (1982) J. Biol. Chem. 257, 4271-4278). Complete dissociation and unfolding in 6 M guanidine HCl at pH 7.2 and 37 degrees C requires greater than 4 h for the auto-inactivated enzyme complex (less than 1 min for uncomplexed enzyme). Release of ligands and dissociation and unfolding of the protein occur in parallel but follow non-first order kinetics, suggesting stable intermediates and multiple pathways for the dissociation reactions. Treatment of Partially inactivated glutamine synthetase (2-6 autoinactivated subunits/dodecamer) with EDTA and dithiobisnitrobenzoic acid at pH 8 modifies approximately 2 of the 4 sulfhydryl groups of unliganded subunits and causes dissociation of the enzyme to stable oligomeric intermediates with 4, 6, 8, and 10 subunits, containing equal numbers of uncomplexed subunits and autoinactivated subunits. With greater than 70% inactivated enzyme, no dissociation occurs under these conditions. Electron micrographs of oligomers, presented in the appendix (Haschemeyer, R. H., Wall, J. S., Hainfeld, J., and Maurizi, M. R., (1982) J. Biol. Chem. 257, 7252-7253) suggest that dissociation of partially liganded dodecamers occurs by cleavage of intra-ring subunit contacts across both hexagonal rings and that these intra-ring subunit contacts across both hexagonal rings and that these intra-ring subunit interactions are stabilized by active site ligand binding. Isolated tetramers (Mr = 200,000; s20,w = 9.5 S) retain sufficient native structure to express significant enzymatic activity; tetramers reassociate to dodecamers and show a 5-fold increase in activity upon removal of the thionitrobenzoate groups with 2-mercaptoethanol. Thus, the tight binding of ligands to the subunit active site strengthens both intra- and inter-subunit bonding domains in dodecameric glutamine synthetase.     

Domain Characterization and Interaction of the Yeast Vacuolar ATPase Subunit C with the Peripheral Stator Stalk Subunits E and G

The proton pumping activity of the eukaryotic vacuolar ATPase (V-ATPase) is regulated by a unique mechanism that involves reversible enzyme dissociation. In yeast, under conditions of nutrient depletion, the soluble catalytic V₁ sector disengages from the membrane integral V_o, and at the same time, both functional units are silenced. Notably, during enzyme dissociation, a single V₁ subunit, C, is released into the cytosol. The affinities of the other V₁ and V_o subunits for subunit C are therefore of particular interest. The C subunit crystal structure shows that the subunit is elongated and dumbbell-shaped with two globular domains (C_head and C_foot) separated by a flexible helical neck region (Drory, O., Frolow, F., and Nelson, N. (2004) EMBO Rep. 5, 1148–1152). We have recently shown that subunit C is bound in the V₁-V_o interface where the subunit is in contact with two of the three peripheral stators (subunit EG heterodimers): one via C_head and one via C_foot (Zhang, Z., Zheng, Y., Mazon, H., Milgrom, E., Kitagawa, N., Kish-Trier, E., Heck, A. J., Kane, P. M., and Wilkens, S. (2008) J. Biol. Chem. 283, 35983–35995). In vitro, however, subunit C binds only one EG heterodimer (Féthière, J., Venzke, D., Madden, D. R., and Böttcher, B. (2005) Biochemistry 44, 15906–15914), implying that EG has different affinities for the two domains of the C subunit. To determine which subunit C domain binds EG with high affinity, we have generated C_head and C_foot and characterized their interaction with subunit EG heterodimer. Our findings indicate that the high affinity site for EGC interaction is C_head. In addition, we provide evidence that the EGC_head interaction greatly stabilizes EG heterodimer.     

Two Lysine Residues in the Bacterial Luciferase Mobile Loop Stabilize Reaction Intermediates

Bacterial luciferase catalyzes the reaction of FMNH₂, O₂, and a long chain aliphatic aldehyde, yielding FMN, carboxylic acid, and blue-green light. The most conserved contiguous region of the primary sequence corresponds to a crystallographically disordered loop adjacent to the active center (Fisher, A. J., Raushel, F. M., Baldwin, T. O., and Rayment, I. (1995) Biochemistry 34, 6581–6586; Fisher, A. J., Thompson, T. B., Thoden, J. B., Baldwin, T. O., and Rayment, I. (1996) J. Biol. Chem. 271, 21956–21968). Deletion of the mobile loop does not alter the chemistry of the reaction but decreases the total quantum yield of bioluminescence by 2 orders of magnitude (Sparks, J. M., and Baldwin, T. O. (2001) Biochemistry 40, 15436–15443). In this study, we attempt to localize the loss of activity observed in the loop deletion mutant to individual residues in the mobile loop. Using alanine mutagenesis, the effects of substitution at 15 of the 29 mobile loop residues were examined. Nine of the point mutants had reduced activity in vivo. Two mutations, K283A and K286A, resulted in a loss in quantum yield comparable with that of the loop deletion mutant. The bioluminescence emission spectrum of both mutants was normal, and both yielded the carboxylic acid chemical product at the same efficiency as the wild-type enzyme. Substitution of Lys²⁸³ with alanine resulted in destabilization of intermediate II, whereas mutation of Lys²⁸⁶ had an increase in exposure of reaction intermediates to a dynamic quencher. Based on a model of the enzyme-reduced flavin complex, the two critical lysine residues are adjacent to the quininoidal edge of the isoalloxazine.     

Subunit complementation of thymidylate synthase.

Each of the two active sites of thymidylate synthase contains amino acid residues contributed by the other subunit. For example, Arg-178 of one monomer binds the phosphate group of the substrate dUMP in the active site of the other monomer [Hardy et al. (1987) Science 235, 448-455]. Inactive mutants of such residues should combine with subunits of other inactive mutants to form heterodimeric hybrids with one functional active site. In vivo and in vitro approaches were used to test this hypothesis. In vivo complementation was accomplished by cotransforming plasmid mixtures encoding pools of inactive Arg-178 mutants and pools of inactive Cys-198 mutants into a host strain deficient in thymidylate synthase. Individual inactive mutants of Arg-178 were also cotransformed with the C198A mutant. Subunit complementation was detected by selection or screening for transformants which grew in the absence of thymidine, and hence produced active enzyme. Many mutants at each position representing a wide variety of size and charge supported subunit complementation. In vitro complementation was accomplished by reversible dissociation and unfolding of mixtures of purified individual inactive Arg-178 and Cys-198 mutant proteins. With the R178F + C198A heterodimer, the Km values for dUMP and CH2H4folate were similar to those of the wild-type enzyme. By titrating C198A with R178F under unfolding-refolding conditions, we were able to calculate the kcat value for the active heterodimer. The catalytic efficiency of the single wild-type active site of the C198A + R178F heterodimer approaches that of the wild-type enzyme.     

Genetic analysis of integrin function in man: LAD-1 and other syndromes.

The integrins are cell membrane receptors composed of alpha and beta subunits which orchestrate adhesive events in all tissues of the body (Hynes, R.O., 1992. Integrins: versatility, modulation, and signalling in cell adhesion. Cell 69, 11-25; and Hynes, R.O., 1999. Cell adhesion: old and new questions. Trends Cell Biol. 9, M33-37). At present 18 alpha subunits and 8 beta subunits have been identified which are loosely organised into families. There are three inherited autosomal recessive diseases in man which involve germline mutations in genes coding for integrins. Leukocyte adhesion deficiency-1 (LAD-1) is the result of mutations in the beta2 subunit of the CD11/CD18 integrins, LFA-1, Mac-1, p150,95 and alphadbeta2. The bleeding disorder Glanzmann thrombasthenia is caused by mutations in either the alpha or beta subunit of the platelet integrin, alphaIIbbeta3. Thirdly, it is now recognised than one of the variants of the usually lethal skin blistering disorder, epidermolysis bullosa (JEB-PA), is caused by mutation in either the alpha or beta subunit of the epithelial hemidesmosome integrin, alpha6beta4. Many of the mutations cause defective alphabeta heterodimer formation. The majority of the beta subunit mutations are in the conserved N-terminal region known as the betaI domain. It is suggested that this region participates in alphabeta heterodimer formation.     

Interactions of GroEL/GroES with a heterodimeric intermediate during alpha 2beta 2 assembly of mitochondrial branched-chain alpha-ketoacid dehydrogenase. cis capping of the native-like 86-kDa intermediate by GroES

We showed previously that the interaction of an alphabeta heterodimeric intermediate with GroEL/GroES is essential for efficient alpha(2)beta(2) assembly of human mitochondrial branched-chain alpha-ketoacid dehydrogenase. In the present study, we further characterized the mode of interaction between the chaperonins and the native-like alphabeta heterodimer. The alphabeta heterodimer, as an intact entity, was found to bind to GroEL at a 1:1 stoichiometry with a K(D) of 1.1 x 10(-)(7) m. The 1:1 molar ratio of the GroEL-alphabeta complex was confirmed by the ability of the complex to bind a stoichiometric amount of denatured lysozyme in the trans cavity. Surprisingly, in the presence of Mg-ADP, GroES was able to cap the GroEL-alphabeta complex in cis, despite the size of 86 kDa of the heterodimer (with a His(6) tag and a linker). Incubation of the GroEL-alphabeta complex with Mg-ATP, but not AMP-PNP, resulted in the release of alpha monomers. In the presence of Mg-ATP, the beta subunit was also released but was unable to assemble with the alpha subunit, and rebound to GroEL. The apparent differential subunit release from GroEL is explained, in part, by the significantly higher binding affinity of the beta subunit (K(D) < 4.15 x 10(-9)m) than the alpha (K(D) = 1.6 x 10(-8)m) for GroEL. Incubation of the GroEL-alphabeta complex with Mg-ATP and GroES resulted in dissociation and discharge of both the alpha and beta subunits from GroEL. The beta subunit upon binding to GroEL underwent further folding in the cis cavity sequestered by GroES. This step rendered the beta subunit competent for reassociation with the soluble alpha subunit to produce a new heterodimer. We propose that this mechanism is responsible for the iterative annealing of the kinetically trapped heterodimeric intermediate, leading to an efficient alpha(2)beta(2) assembly of human branched-chain alpha-ketoacid dehydrogenase.     

Functional implications of the unstructured loop in the (beta/alpha)(8) barrel structure of the bacterial luciferase alpha subunit.

Bacterial luciferase catalyzes the conversion of FMNH(2), a long-chain aliphatic aldehyde, and molecular oxygen to FMN, the corresponding carboxylic acid, and H(2)O with the emission of light. The light-emitting species is an enzyme-bound excited state flavin. The enzyme is a heterodimer (alphabeta) of homologous subunits each with an (beta/alpha)(8) barrel structure. A portion of the loop in the alpha subunit that connects beta strand 7 to alpha helix 7 is disordered in the crystal structure. To test the hypothesis that this loop closes over the active site during catalysis and protects the active site from bulk solvent, a mutant was constructed in which the 29 residues that are disordered in the 2.4 A crystal structure were deleted. Deletion of this loop results in a heterodimer with a subunit equilibrium dissociation constant of 1.32 +/- 1.25 microM, whereas the wild-type heterodimer shows no measurable subunit dissociation. This mutant retains its ability to bind substrate flavin and aldehyde with wild-type affinity and can carry out the chemistry of the bioluminescence reaction with nearly wild-type efficiency. However, the bioluminescent quantum yield of the reaction is reduced nearly 2 orders of magnitude from that of the wild-type enzyme.     

Deletion of lactose repressor carboxyl-terminal domain affects tetramer formation.

The carboxyl-terminal sequence of the lac repressor protein contains heptad repeats of leucines at positions 342, 349, and 356 that are required for tetramer assembly, as substitution of these leucine residues yields solely dimeric species (Chakerian, A. E., Tesmer, V. M., Manly, S. P., Brackett, J. K., Lynch, M. J., Hoh, J. T., and Matthews, K. S. (1991) J. Biol. Chem. 266, 1371-1374; Alberti, S., Oehler, S., von Wilcken-Bergmann, B., Kr?mer, H., and Müller-Hill, B. (1991) New Biol. 3, 57-62). To further investigate this region, which may form a leucine zipper motif, a family of lac repressor carboxyl-terminal deletion mutants eliminating the last 4, 5, 11, 18, and 32 amino acids (aa) has been constructed. The -4 aa mutant, in which all of the leucines in the presumed leucine zipper are intact, is tetrameric and displays operator and inducer binding properties similar to wild-type repressor. The -5 aa, -11 aa, -18 aa, and -32 aa deletion mutants, depleted of 1, 2, or all 3 of the leucines in the heptad repeats, are all dimeric, as demonstrated by gel filtration chromatography. Circular dichroism spectra and protease digestion studies indicate similar secondary/tertiary structures for the mutant and wild-type proteins. Differences in reaction with a monoclonal antibody specific for a subunit interface are observed for the dimeric versus tetrameric proteins, indicative of exposure of the target epitope as a consequence of deletion. Inducer binding properties of the deletion mutants are similar to wild-type tetrameric repressor at neutral pH. Only small differences in affinity and cooperativity from wild-type are evident at elevated pH; thus, the cooperative unit within the tetramer appears to be the dimer. "Apparent" operator binding affinity for the dimeric proteins is diminished, although minimal change in operator dissociation rate constants was observed. The diminution in apparent operator affinity may therefore derive from either 1) dissociation of the dimeric mutants to monomer generating a linked equilibrium or 2) alterations in intrinsic operator affinity of the dimers; the former explanation is favored. This detailed characterization of the purified mutant proteins confirms that the carboxyl-terminal region is involved in the dimer-dimer interface and demonstrates that cooperativity for inducer binding is contained within the dimer unit of the tetramer structure.     

Involvement of single residue tryptophan 548 in the quaternary structural stability of pigeon cytosolic malic enzyme

Pigeon cytosolic malic enzyme has a double dimer quaternary structure with three tryptophanyl residues in each monomer distributed in different structural domains. The enzyme showed a three-state unfolding phenomenon upon increasing the urea concentration (Chang, H. C., Chou, W. Y., and Chang, G. G. (2002) J. Biol. Chem. 277, 4663-4671). At urea concentration of 4-4.5 m, where the intermediate form was detected, the enzyme existed as partially unfolded dimers, which were easily polymerized. Mn2+ provided full protection against the polymerization. To further characterize this phenomenon, three mutants of the enzyme (W129, W321, and W548), each with only one tryptophanyl residue left, were constructed. All these mutants were successfully overexpressed in Escherichia coli cells and purified to homogeneity. Changes in the circular dichroism spectra of all mutants revealed a three-state urea-unfolding process in the absence of Mn2+. In the presence of 4 mm Mn2+, W548 and wild type (WT) enzymes shifted to monophasic, while W129 and W321 were still biphasic. Similar results were obtained from the fluorescence spectral changes, except for W321, which showed monophasic denaturation curve with or without Mn2+. Analytical ultracentrifugation analysis indicated that the mutant enzymes were polymerized at 4.5 m urea, and Mn2+ provided protective effect on W548 and WT enzymes only. Other mutants with mutated Trp-548 polymerized at 4.5 m urea in the absence or presence of 4 mm Mn2+. The above results indicate that a single residue, Trp-548, in the subunit interface region, is responsible for the integrity of the quaternary structure of the pigeon cytosolic malic enzyme.     

Nucleotide sequence of the luxB gene of Vibrio harveyi and the complete amino acid sequence of the beta subunit of bacterial luciferase

The nucleotide sequence of the 1.30-kilobase EcoRI/BglII fragment from Vibrio harveyi carrying the majority of the luciferase beta subunit coding region (luxB gene) has been determined. The EcoRI/BglII fragment was derived from a 4.0-kilobase HindIII fragment carrying both luxA and luxB which was detected in a genomic clone bank based on the expression of bioluminescence from colonies of Escherichia coli carrying V. harveyi HindIII fragments in plasmid pBR322 (Baldwin, T. O., Berends, T., Bunch, T. A., Holzman, T. F., Rausch, S. K., Shamansky, L., Treat, M. L., and Ziegler, M. M. (1984) Biochemistry 23, 3663-3667). The entire alpha subunit coding sequence (luxA gene) and the amino-terminal 13 codons of the beta subunit sequence (luxB gene) were contained on a 1.85-kilobase EcoRI fragment, the sequence of which has been reported (Cohn, D. H., Mileham, A. J., Simon, M. I., Nealson, K. H., Rausch, S. K., Bonam, D., and Baldwin, T. O. (1985) J. Biol. Chem. 260, 6139-6146). The beta subunit coding sequence was found to terminate 972 bases past the start of the luxB coding sequence. The beta subunit had a calculated molecular weight of 36,349 and comprised a total of 324 amino acid residues; the alpha beta dimer had a molecular weight (alpha + beta) of 76,457. There were 27 base pairs separating the stop codon of the beta subunit structural gene and a 340-base open reading frame extending to (and beyond) the distal BglII site. Approximately two-thirds of the beta subunit was sequenced by protein chemical techniques. The amino acid sequence predicted from the DNA sequence, with few exceptions, confirmed the chemically determined sequence, and the measured amino acid composition was in excellent agreement with the composition implied from the DNA sequence.     

Split leucine-specific domain of leucyl-tRNA synthetase from the hyperthermophilic bacterium Aquifex aeolicus

Leucyl-tRNA synthetase (LeuRS) from Aquifex aeolicus is the only known heterodimer synthetase. It is named LeuRS alphabeta;, and its alpha and beta subunits contain 634 and 289 residues, respectively. Like Thermus thermophilus LeuRS, LeuRS alphabeta has a large extra domain, the leucine-specific domain, inserted into the catalytic domain. The subunit split site is exactly in the middle of the leucine-specific domain and may have a unique function. Here, a series of mutants of LeuRS alphabeta consisting of either mutated alpha subunits and wild-type beta subunits or wild-type alpha subunits and mutated beta subunits were constructed and purified. ATP-PPi exchange and aminoacylation activities and the ability of the mutants to charge minihelix(Leu) were assayed. Interaction of the mutants with the tRNA was assessed by gel shift. Two peptides of eight and nine amino acid residues in the domain located in the alpha subunit were found to be essential for the enzyme's activity. We also showed that the domain in LeuRS alphabeta plays an important role in minihelix(Leu) recognition. Additionally, the domain was found to have little impact on the assembly of the heterodimer, to play a role in the thermal stability of the whole enzyme, and to interact with the cognate tRNA in the predicted manner.     

Physico-chemical properties of molten dimer ascorbate oxidase

The possible presence of dimeric unfolding intermediates might offer a clue to understanding the relationship between tertiary and quaternary structure formation in dimers. Ascorbate oxidase is a large dimeric enzyme that displays such an intermediate along its unfolding pathway. In this study the combined effect of high pressure and denaturing agents gave new insight on this intermediate and on the mechanism of its formation. The transition from native dimer to the dimeric intermediate is characterized by the release of copper ions forming the tri-nuclear copper center located at the interface between domain 2 and 3 of each subunit. This transition, which is pH-dependent, is accompanied by a decrease in volume, probably associated to electrostriction due to the loosening of intra-subunit electrostatic interactions. The dimeric species is present even at 3 x 10(8) Pa, providing evidence that mechanically or chemically induced unfolding lead to a similar intermediate state. Instead, dissociation occurs with an extremely large and negative volume change (DeltaV approximately -200 mL.mol(-1)) by pressurization in the presence of moderate amounts of denaturant. This volume change can be ascribed to the elimination of voids at the subunit interface. Furthermore, the combination of guanidine and high pressure uncovers the presence of a marginally stable (DeltaG approximately 2 kcal.mol(-1)) monomeric species (which was not observed in previous equilibrium unfolding measurements) that might be populated in the early folding steps of ascorbate oxidase. These findings provide new aspects of the protein folding pathway, further supporting the important role of quaternary interactions in the folding strategy of large dimeric enzymes.     

Localization of subunit C (Vma5p) in the yeast vacuolar ATPase by immuno electron microscopy

Vacuolar ATPases (V1V0 -ATPases) function in proton translocation across lipid membranes of subcellular compartments. We have used antibody labeling and electron microscopy to define the position of subunit C in the vacuolar ATPase from yeast. The data show that subunit C is binding at the interface of the ATPase and proton channel, opposite from another stalk density previously identified as subunit H [Wilkens S., Inoue T., and Forgac M. (2004) Three-dimensional structure of the vacuolar ATPase - Localization of subunit H by difference imaging and chemical cross-linking. J. Biol. Chem. 279, 41942-41949]. A picture of the vacuolar ATPase stalk domain is emerging in which subunits C and H are positioned to play a role in reversible enzyme dissociation and activity silencing.     

Dissociation and unfolding of cold-active alkaline phosphatase from atlantic cod in the presence of guanidinium chloride.

Cold-adaptation of enzymes involves improvements in catalytic efficiency. This paper describes studies on the conformational stability of a cold-active alkaline phosphatase (AP) from Atlantic cod, with the aim of understanding more clearly its structural stability in terms of subunit dissociation and unfolding of monomers. AP is a homodimeric enzyme that is only active in the dimeric state. Tryptophan fluorescence, size-exclusion chromatography and enzyme activity were used to monitor alterations in conformational state induced by guanidinium chloride or urea. In cod AP, a clear distinction could be made between dissociation of dimers into monomers and subsequent unfolding of monomers (fits a three-state model). In contrast, dimer dissociation of calf AP coincided with the monophasic unfolding curve observed by tryptophan fluorescence (fits a two-state model). The DeltaG for dimer dissociation of cod AP was 8.3 kcal.mol-1, and the monomer stabilization free energy was 2.2 kcal.mol-1, giving a total of 12.7 kcal.mol-1, whereas the total free energy of calf intestinal AP was 17.3 kcal.mol-1. Thus, dimer formation provided a major contribution to the overall stability of the cod enzyme. Phosphate, the reaction product, had the effect of promoting dimer dissociation and stabilizing the monomers. Cod AP has reduced affinity for inorganic phosphate, the release of which is the rate-limiting step of the reaction mechanism. More flexible links at the interface between the dimer subunits may ease structural rearrangements that facilitate more rapid release of phosphate, and thus catalytic turnover.     

Demonstration of two independently folding domains in the alpha subunit of bacterial luciferase by preferential ligand binding-induced stabilization

The alpha subunit of bacterial luciferase unfolds and refolds reversibly by a three-state mechanism in urea-containing buffer. It has been proposed that the three-state unfolding of the alpha subunit arises from a stepwise unfolding of a C-terminal folding domain at lower concentrations of urea, followed by unfolding of the N-terminal domain at higher concentrations of urea (Noland, B. W., Dangott, L. J., and Baldwin, T. O. (1999) Biochemistry 38, 16136-16145). The location of an anion binding site in the proposed N-terminal folding domain allowed the folding mechanism to be probed in the context of the intact polypeptide. Anions preferentially stabilized the N-terminal domain in a concentration-dependent manner. The polyvalent anions sulfate and phosphate were found to be more stabilizing than monovalent chloride ion. Cations did not show a similar stabilizing effect, demonstrating that the stabilization was due to the anions alone. The purified N-terminal domain prepared by limited proteolysis and anion exchange chromatography was found to refold cooperatively with a midpoint approximately that of the second unfolding transition of the alpha subunit. Phosphate ion stabilized this fragment to roughly the same extent as it did the alpha subunit. The results presented are consistent with the proposed two-domain folding model and demonstrate that anion binding to the N-terminal folding domain stabilizes the alpha subunit of bacterial luciferase.     

Thermodynamic analysis of unfolding and dissociation in lactose repressor protein.

Lactose repressor protein, regulator of lac enzyme expression in Escherichia coli, maintains its structure and function at extremely low protein concentrations (<10(-)12 M). To examine the unfolding and dissociation of this tetrameric protein, structural transitions in the presence of varying concentrations of urea were monitored by fluorescence and circular dichroism spectroscopy, analytical ultracentrifugation, and functional activities. The spectroscopic data demonstrated a single cooperative transition with no evidence of folded dimeric or monomeric species of this protein. These spectroscopic transitions were reversible provided a long incubation step was employed in the refolding reaction at approximately 3 M urea. The refolded repressor protein possessed the same functional and structural properties as wild-type repressor protein. The absence of concentration dependence expected for tetramer dissociation to unfolded monomer (M4 <--> 4U) in the spectral transitions indicates that the disruption of the monomer-monomer interface and monomer unfolding are a concerted reaction (M4 <--> U4) that may occur prior to the dissociation of the dimer-dimer interface. Thus, we propose that the unfolded monomers remain associated at the C-terminus by the 4-helical coiled-coil structure that forms the dimer-dimer interface and that this intermediate is the end point detected in the spectral transitions. Efforts to confirm the existence of this species by ultracentrifugation were inhibited by the aggregation of this intermediate. Based upon these observations, the wild-type fluorescence and CD data were fit to a model, M4 <--> U4, which resulted in an overall DeltaG degrees for unfolding of 40 kcal/mol. Using a mutant protein, K84L, in which the monomer-monomer interface is stabilized, sedimentation equilibrium results demonstrated that the dimer-dimer interface of lac repressor could persist at higher levels of urea than the monomer-monomer interface. The tetramer-dimer transition monitored using this mutant repressor yields a DeltaG degrees of 20.4 kcal/mol. Using this free energy value for the dissociation process of U4 <--> 4U, an overall free energy change of approximately 60 kcal/mol was calculated for dissociation of all interfaces and unfolding of the tetrameric lac repressor, reflecting the exceptional stability of this protein.