Functional role of the lock and key motif at the subunit interface of glutathione transferase p1-1

The glutathione transferases (GSTs) represent a superfamily of dimeric proteins. Each subunit has an active site, but there is no evidence for the existence of catalytically active monomers. The lock and key motif is responsible for a highly conserved hydrophobic interaction in the subunit interface of pi, mu, and alpha class glutathione transferases. The key residue, which is either Phe or Tyr (Tyr(50) in human GSTP1-1) in one subunit, is wedged into a hydrophobic pocket of the other subunit. To study how an essentially inactive subunit influences the activity of the neighboring subunit, we have generated the heterodimer composed of subunits from the fully active human wild-type GSTP1-1 and the nearly inactive mutant Y50A obtained by mutation of the key residue Tyr(50) to Ala. Although the key residue is located far from the catalytic center, the k(cat) value of mutant Y50A decreased about 1300-fold in comparison with the wild-type enzyme. The decrease of the k(cat) value of the heterodimer by about 27-fold rather than the expected 2-fold in comparison with the wild-type enzyme indicates that the two active sites of the dimeric enzyme work synergistically. Further evidence for cooperativity was found in the nonhyperbolic GSH saturation curves. A network of hydrogen-bonded water molecules, found in crystal structures of GSTP1-1, connects the two active sites and the main chain carbonyl group of Tyr(50), thereby offering a mechanism for communication between the two active sites. It is concluded that a subunit becomes catalytically competent by positioning the key residue of one subunit into the lock pocket of the other subunit, thereby stabilizing the loop following the helix alpha2, which interacts directly with GSH.     

Threonine 183 and adjacent flexible loop residues in the tryptophan synthase alpha subunit have critical roles in modulating the enzymatic activities of the beta subunit in the alpha 2 beta 2 complex.

This study investigates the catalytic and allosteric roles of a flexible loop in the tryptophan synthase alpha 2 beta 2 complex. This loop connects helix 6 and strand 6 in the alpha subunit, an 8-fold alpha/beta barrel polypeptide. We have engineered three mutations in this disordered loop: a deletion of residues 185-187 and the replacement of threonine 183 by serine (T183S) or by alanine (T183A). Position 183 is a site of an inactivating mutation identified by Yanofsky's group (Yanofsky, C., Drapeau, G. R., Guest, J. R., and Carlton, B. C. (1967) Proc. Natl. Acad. Sci. U.S.A. 57, 296-298). The three engineered alpha subunits form stable, stoichiometric alpha 2 beta 2 complexes with the beta subunit which bind alpha and beta subunit ligands. Although changing threonine 183 to serine has little effect on the enzymatic properties, changing threonine 183 to alanine or deleting residues 185-187 results in a 50-fold reduction in the intrinsic activity of the alpha subunit alone and in the alpha site activity of the alpha 2 beta 2 complex. The latter two mutations profoundly alter the way in which the alpha subunit modulates the spectral properties and the activities of the wild-type beta subunit. These mutations also eliminate the effects of alpha subunit ligands on the beta subunit. Although the beta subunit ligand, L-serine, greatly stabilizes the wild-type alpha 2 beta 2 complex to dissociation and to proteolysis, L-serine stabilizes the T183A alpha 2 beta 2 complex weakly or not at all. Our findings suggest that the hydroxyl residue at position 183 and the adjacent residues in the alpha subunit loop play critical roles in the reciprocal communication between the alpha and beta subunits in the alpha 2 beta 2 complex. The results also help to explain how the wild-type alpha subunit or ammonium ion modulates the activities of the beta subunit.     

Genes for the alpha and beta subunits of the phenylalanyl-transfer ribonucleic acid synthetase of Escherichia coli.

The phenylalanyl-transfer ribonucleic acid synthetase of Escherichia coli is a tetramer that contains two different kinds of polypeptide chains. To locate the genes for the two polypeptides, we analyzed temperature-sensitive mutants with defective phenylalanyl-transfer ribonucleic acid synthetases to see which subunit was altered. The method was in vitro complementation; mutant cell extracts were mixed with purified separated alpha or beta subunits of the wild-type enzyme to generate an active hybrid enzyme. With three mutants, enzyme activity appeared when alpha was added, but not when beta was added: these are, therefore, assumed to carry lesions in the gene for the alpha subunit. Two other mutants gave the opposite response and are presumably beta mutants. Enzyme activity is also generated when alpha and beta mutant extracts are mixed, but not when two alpha or two beta mutant extracts are mixed. The inactive mutant enzymes appear to be dissociated, as judged by their sedimentation in sucrose density gradients, but the dissociation may be only partial. The active enzyme generated by complementation occurred in two forms, one that resembled the native wild-type enzyme and one that sedimented more slowly. Both alpha and beta mutants are capable of generating the native form, although alpha mutants require prior urea denaturation of the defective enzyme. With the mutants thus characterized, the genes for the alpha and beta subunits (designated pheS and heT, respectively) were mapped. The gene order, as determined by transduction is aroD-pps-pheT-pheS. The pheS and pheT genes are close together and may be immediately adjacent.     

Mutational analysis of the subunit interface of Vibrio harveyi bacterial luciferase

Bacterial luciferase is a heterodimeric (alphabeta) enzyme which catalyzes a light-producing reaction in Vibrio harveyi. In addition to the alphabeta enzyme, the beta subunit can self-associate to form a stable but inactive homodimer [Sinclair, J. F., Ziegler, M. M., and Baldwin, T. O. (1994) Nat. Struct. Biol. 1, 320-326]. The studies reported here were undertaken to explore the role of the subunit interface in the conformational stability of the enzyme. To this end, we constructed four mutant heterodimers in which residues at the subunit interface were changed in an effort to alter the volume of an apparent solvent accessible channel at the interface or to alter H-bonding groups. Equilibrium unfolding data for the heterodimer have been interpreted in terms of a three-state mechanism [Clark, C. A., Sinclair, J. F., and Baldwin, T. O. (1993) J. Biol. Chem. 268, 10773-10779]. However, we found that unfolding for the wild-type and mutant luciferases is better described by a four-state model. This change in the proposed mechanism of unfolding is based on observation of residual structure in the subunits following dissociation of the heterodimeric intermediate. All of the mutants display modest reductions in activity but, surprisingly, no change in the DeltaG2H2O value for subunit dissociation and no measurable change in the equilibrium dissociation constant relative to that of the wild-type heterodimer. However, the DeltaG1H2O value for the formation of the dimeric intermediate that precedes subunit dissociation is reduced for three of the mutants, indicating that mutations at the interface can alter the stability of a region of the alpha subunit that is distant from the interface. We conclude that the interface region communicates with the distal domains of this subunit, probably through the active center region of the enzyme.     

Mechanism of mutual activation of the tryptophan synthase alpha and beta subunits. Analysis of the reaction specificity and substrate-induced inactivation of active site and tunnel mutants of the beta subunit

The origin of reaction and substrate specificity and the control of activity by protein-protein interaction are investigated using the tryptophan synthase alpha 2 beta 2 complex from Salmonella typhimurium. We have compared some spectroscopic and kinetic properties of the wild type beta subunit and five mutant forms of the beta subunit that have altered catalytic properties. These mutant enzymes, which were engineered by site-directed mutagenesis, have single amino acid replacements in either the active site or in the wall of a tunnel that extends from the active site of the alpha subunit to the active site of the beta subunit in the alpha 2 beta 2 complex. We find that the mutant alpha 2 beta 2 complexes have altered reaction and substrate specificity in beta-elimination and beta-replacement reactions with L-serine and with beta-chloro-L-alanine. Moreover, the mutant enzymes, unlike the wild type alpha 2 beta 2 complex, undergo irreversible substrate-induced inactivation. The mechanism of inactivation appears to be analogous to that first demonstrated by Metzler's group for inhibition of two other pyridoxal phosphate enzymes. Alkaline treatment of the inactivated enzyme yields apoenzyme and a previously described pyridoxal phosphate derivative. We demonstrate for the first time that enzymatic activity can be recovered by addition of pyridoxal phosphate following alkaline treatment. We conclude that the wild type and mutant alpha 2 beta 2 complexes differ in the way they process the amino acrylate intermediate. We suggest that the wild type beta subunit undergoes a conformational change upon association with the alpha subunit that alters the reaction specificity and that the mutant beta subunits do not undergo the same conformational change upon subunit association.     

Crystal structure of thiamin phosphate synthase from Bacillus subtilis at 1.25 A resolution.

The crystal structure of Bacillus subtilis thiamin phosphate synthase complexed with the reaction products thiamin phosphate and pyrophosphate has been determined by multiwavelength anomalous diffraction phasing techniques and refined to 1.25 A resolution. Thiamin phosphate synthase is an alpha/beta protein with a triosephosphate isomerase fold. The active site is in a pocket formed primarily by the loop regions, residues 59-67 (A loop, joining alpha3 and beta2), residues 109-114 (B loop, joining alpha5 and beta4), and residues 151-168 (C loop, joining alpha7 and beta6). The high-resolution structure of thiamin phosphate synthase complexed with its reaction products described here provides a detailed picture of the catalytically important interactions between the enzyme and the substrates. The structure and other mechanistic studies are consistent with a reaction mechanism involving the ionization of 4-amino-2-methyl-5-hydroxymethylpyrimidine pyrophosphate at the active site to give the pyrimidine carbocation. Trapping of the carbocation by the thiazole followed by product dissociation completes the reaction. The ionization step is catalyzed by orienting the C-O bond perpendicular to the plane of the pyrimidine, by hydrogen bonding between the C4' amino group and one of the terminal oxygen atoms of the pyrophosphate, and by extensive hydrogen bonding and electrostatic interactions between the pyrophosphate and the enzyme.     

Amphipathic alpha-helix mediates the heterodimerization of soluble guanylyl cyclase

Soluble guanylyl cyclase (soluble GC) is an enzyme consisting of alpha and beta subunits and catalyzes the conversion of GTP to cGMP. The formation of the heterodimer is essential for the activity of soluble GC. Each subunit of soluble GC has been shown to comprize three functionally different parts: a C-terminal catalytic domain, a central dimerization domain, and an N-terminal regulatory domain. The central dimerization domain of the beta(1) subunit, which contains an N-terminal binding site (NBS) and a C-terminal binding site (CBS), has been postulated to be responsible for the formation of alpha/ beta heterodimer. In this study, we analyzed heterodimerization by the pull-down assay using the affinity between a histidine tag and Ni(2+) Sepharose after co-expression of various N- and C-terminally truncated FLAG-tagged mutants of the alpha(1) subunit and the histidine-tagged wild type of the beta(1) subunit in the vaculovirus/Sf9 system, and demonstrated that the CBS-like sequence of the alpha(1) subunit is critical for the formation of the heterodimer with the beta(1) subunit and the NBS-like sequence of the alpha(1) subunit is essential for the formation of the enzymatically active heterodimer, although this particular sequence was not involved in heterodimerization. The analysis of the secondary structure of the alpha(1) subunit predicted the existence of an amphipathic alpha-helix in residues 431-464. Experiments with site-directed alpha(1) subunit mutant proteins demonstrated that the amphipathicity of the alpha-helix is important for the formation of the heterodimer, and Leu(463) in the alpha-helix region plays a critical role in the formation of a properly arranged active center in the dimer.     

The subunits of the stimulatory regulatory component of adenylate cyclase. Resolution of the activated 45,000-dalton (alpha) subunit

Activation of the stimulatory guanine nucleotide-binding regulatory component (G/F) of adenylate cyclase by guanine nucleotides or by Al3+, Mg2+, and F-stabilizes the protein to thermal denaturation or to inactivation by LiBr, guanidine HCl, or urea. Such activation allows the resolution of the active 45,000-Da alpha subunit from the 35,000-Da beta subunit by a high performance gel filtration procedure. Separation of the active alpha subunit has allowed definitive evaluation of the subunit dissociation model for the activation of G/F. The resolved alpha subunit is sufficient to reconstitute the adenylate cyclase activity of the cyc-S49 cell mutant. The alpha subunit alone is also sufficient to activate a preparation of the catalyst of adenylate cyclase that had been resolved from all other identified components of the enzyme system. The resolved alpha subunit displays hydrodynamic properties characteristic of activated G/F. The alpha subunit contains a high affinity guanine nucleotide-binding site. Activation of G/F by guanine nucleotides or by Al3+ + Mg2+ + F- allows resolution of the activated alpha subunit. Reversal of the activated state of the resolved alpha subunit occurs only slowly. Addition of beta subunit enhances the rate of deactivation. Deactivation of the activated alpha subunit by the beta subunit changes the S20,w for G/F activity from 2.0 to 4.0 (in Lubrol), consistent with a formation of the alpha X beta heterodimer. These data, taken in aggregate, constitute proof for the proposed mechanism of activation of G/F by non-hydrolyzable analogs of GTP and by Al3+, Mg2+, and F-. They are analogous to data obtained for transducin, the GTP-binding regulatory protein from vertebrate rod outer segment discs, and for the putative inhibitory guanine nucleotide-binding regulatory component of adenylate cyclase (the substrate for islet-activating protein). The model provides several powerful tests for study of mechanisms of hormonal regulation of adenylate cyclase in membranes.     

The unexpected structural role of glutamate synthase [4Fe-4S](+1,+2) clusters as demonstrated by site-directed mutagenesis of conserved C residues at the N-terminus of the enzyme beta subunit

Azospirillum brasilense glutamate synthase (GltS) is a complex iron-sulfur flavoprotein whose catalytically active alphabeta protomer (alpha subunit, 162kDa; beta subunit, 52.3 kDa) contains one FAD, one FMN, one [3Fe-4S](0,+1), and two [4Fe-4S](+1,+2) clusters. The structure of the alpha subunit has been determined providing information on the mechanism of ammonia transfer from L-glutamine to 2-oxoglutarate through a 30 A-long intramolecular tunnel. On the contrary, details of the electron transfer pathway from NADPH to the postulated 2-iminoglutarate intermediate through the enzyme flavin co-factors and [Fe-S] clusters are largely indirect. To identify the location and role of each one of the GltS [4Fe-4S] clusters, we individually substituted the four cysteinyl residues forming the first of two conserved C-rich regions at the N-terminus of GltS beta subunit with alanyl residues. The engineered genes encoding the beta subunit variants (and derivatives carrying C-terminal His6-tags) were co-expressed with the wild-type alpha subunit gene. In all cases the C/A substitutions prevented alpha and beta subunits association to yield the GltS alphabeta protomer. This result is consistent with the fact that these residues are responsible for the formation of glutamate synthase [4Fe-4S](+1,+2) clusters within the N-terminal region of the beta subunit, and that these clusters are implicated not only in electron transfer between the GltS flavins, but also in alphabeta heterodimer formation by structuring an N-terminal [Fe-S] beta subunit interface subdomain, as suggested by the three-dimensional structure of dihydropyrimidine dehydrogenase, an enzyme containing an N-terminal beta subunit-like domain.     

Conformational Changes in the tryptophan synthase from a hyperthermophile upon alpha2beta2 complex formation: crystal structure of the complex

The three-dimensional structure of the bifunctional tryptophan synthase alpha(2)beta(2) complex from Pyrococcus furiosus was determined by crystallographic analysis. This crystal structure, with the structures of an alpha subunit monomer and a beta(2) subunit dimer that have already been reported, is the first structural set in which changes in structure that occur upon the association of the individual tryptophan synthase subunits were observed. To elucidate the structural basis of the stimulation of the enzymatic activity of each of the alpha and beta(2) subunits upon alpha(2)beta(2) complex formation, the conformational changes due to complex formation were analyzed in detail compared with the structures of the alpha monomer and beta(2) subunit dimer. The major conformational changes due to complex formation occurred in the region correlated with the catalytic function of the enzyme as follows. (1) Structural changes in the beta subunit were greater than those in the alpha subunit. (2) Large movements of A46 and L165 in the alpha subunit due to complex formation caused a more open conformation favoring the entry of the substrate at the alpha active site. (3) The major changes in the beta subunit were the broadening of a long tunnel through which the alpha subunit product (indole) is transferred to the beta active site and the opening of an entrance at the beta active site. (4) The changes in the conformations of both the alpha and beta subunits due to complex formation contributed to the stabilization of the subunit association, which is critical for the stimulation of the enzymatic activities.     

Three-dimensional structure of the tryptophan synthase alpha 2 beta 2 multienzyme complex from Salmonella typhimurium

The three-dimensional structure of the alpha 2 beta 2 complex of tryptophan synthase from Salmonella typhimurium has been determined by x-ray crystallography at 2.5 A resolution. The four polypeptide chains are arranged nearly linearly in an alpha beta beta alpha order forming a complex 150 A long. The overall polypeptide fold of the smaller alpha subunit, which cleaves indole glycerol phosphate, is that of an 8-fold alpha/beta barrel. The alpha subunit active site has been located by difference Fourier analysis of the binding of indole propanol phosphate, a competitive inhibitor of the alpha subunit and a close structural analog of the natural substrate. The larger pyridoxal phosphate-dependent beta subunit contains two domains of nearly equal size, folded into similar helix/sheet/helix structures. The binding site for the coenzyme pyridoxal phosphate lies deep within the interface between the two beta subunit domains. The active sites of neighboring alpha and beta subunits are separated by a distance of about 25 A. A tunnel with a diameter matching that of the intermediate substrate indole connects these active sites. The tunnel is believed to facilitate the diffusion of indole from its point of production in the alpha subunit active site to the site of tryptophan synthesis in the beta active site and thereby prevent its escape to the solvent during catalysis.     

Mutation of alphaPhe55 of methylamine dehydrogenase alters the reorganization energy and electronic coupling for its electron transfer reaction with amicyanin

Methylamine dehydrogenase (MADH) possesses an alpha(2)beta(2) structure with each smaller beta subunit possessing a tryptophan tryptophylquinone (TTQ) prosthetic group. Phe55 of the alpha subunit is located where the substrate channel from the enzyme surface opens into the active site. Site-directed mutagenesis of alphaPhe55 has revealed roles for this residue in determining substrate specificity and binding monovalent cations at the active site. It is now shown that the alphaF55A mutation also increases the rate of the true electron transfer (ET) reaction from O-quinol MADH to amicyanin. The reorganization energy associated with the ET reaction is decreased from 2.3 to 1.8 eV. The electronic coupling associated with the ET reaction is decreased from 12 to 3 cm(-1). The crystal structure of alphaF55A MADH in complex with its electron acceptors, amicyanin and cytochrome c-551i, has been determined. Little difference in the overall structure is seen, relative to the native complex; however, there are significant changes in the solvent content of the active site and substrate channel. The crystal structure of alphaF55A MADH has also been determined with phenylhydrazine covalently bound to TTQ in the active site. Phenylhydrazine binding significantly perturbs the orientation of the TTQ rings relative to each other. The ET results are discussed in the context of the new and old crystal structures of the native and mutant enzymes.     

Site-directed mutagenesis of bacterial luciferase: Analysis of the ‘essential’ thiol

It has been appreciated for many years that the luciferase from the luminous marine bacterium Vibrio harveyi has a highly reactive cysteinyl residue which is protected from alkylation by binding of flavin. Alkylation of the reactive thiol, which resides in a hydrophobic pocket, leads to inactivation of the enzyme. To determine conclusively whether the reactive thiol is required for the catalytic mechanism, we have constructed a mutant by oligonucleotide directed site-specific mutagenesis in which the reactive cysteinyl residue, which resides at position 106 of the α subunit, has been replaced with a seryl residue. The resulting α106Ser luciferase retains full activity in the bioluminescence reaction, although the mutant enzyme has a ca 100-fold increase in the FMNH₂ dissociation constant. The α106Ser luciferase is still inactivated by N-ethylmaleimide, albeit at about 1/10 the rate of the wild-type (α106Cys) enzyme, demonstrating the existence of a second, less reactive, cysteinyl residue that was obscured in the wild-type enzyme by the highly reactive cysteinyl residue at position α106. An α106Ala variant luciferase was also active, but the α106Val mutant enzyme was about 50-fold less active than the wild type. All three variants (Ser, Ala and Val) appeared to have somewhat reduced affinities for the aldehyde substrate, the valine mutant being the most affected. It is interesting to note that the α106 mutant luciferases are much less subject to aldehyde substrate inhibition than is the wild-type V. harveyi luciferase, suggesting that the molecular mechanism of aldehyde substrate inhibition involves the Cys at α106.     

The crystal structure of three site-directed mutants of Escherichia coli dihydrodipicolinate synthase: further evidence for a catalytic triad

Dihydrodipicolinate synthase (DHDPS, EC 4.2.1.52) catalyses the branchpoint reaction of lysine biosynthesis in plants and microbes: the condensation of (S)-aspartate-beta-semialdehyde and pyruvate. The crystal structure of wild-type DHDPS has been published to 2.5A, revealing a tetrameric molecule comprised of four identical (beta/alpha)(8)-barrels, each containing one active site. Previous workers have hypothesised that the catalytic mechanism of the enzyme involves a catalytic triad of amino acid residues, Tyr133, Thr44 and Tyr107, which provide a proton shuttle to transport protons from the active site to solvent. We have tested this hypothesis using site-directed mutagenesis to produce three mutant enzymes: DHDPS-Y133F, DHDPS-T44V and DHDPS-Y107F. Each of these mutants has substantially reduced activity, consistent with the catalytic triad hypothesis. We have determined each mutant crystal structure to at least 2.35A resolution and compared the structures to the wild-type enzyme. All mutant enzymes crystallised in the same space group as the wild-type form and only minor differences in structure are observed. These results suggest that the catalytic triad is indeed in operation in wild-type DHDPS.     

Organization of the multiple coenzymes and subunits and role of the covalent flavin link in the complex heterotetrameric sarcosine oxidase

Heterotetrameric (alphabetagammadelta) sarcosine oxidase from Corynebacterium sp. P-1 (cTSOX) contains noncovalently bound FAD and NAD(+) and covalently bound FMN, attached to beta(His173). The beta(His173Asn) mutant is expressed as a catalytically inactive, labile heterotetramer. The beta and delta subunits are lost during mutant enzyme purification, which yields a stable alphagamma complex. Addition of stabilizing agents prevents loss of the delta but not the beta subunit. The covalent flavin link is clearly a critical structural element and essential for TSOX activity or preventing FMN loss. The alpha subunit was expressed by itself and purified by affinity chromatography. The alpha and beta subunits each contain an NH(2)-terminal ADP-binding motif that could serve as part of the binding site for NAD(+) or FAD. The alpha subunit and the alphagamma complex were each found to contain 1 mol of NAD(+) but no FAD. Since NAD(+) binds to alpha, FAD probably binds to beta. The latter could not be directly demonstrated since it was not possible to express beta by itself. However, FAD in TSOX from Pseudomonas maltophilia (pTSOX) exhibits properties similar to those observed for the covalently bound FAD in monomeric sarcosine oxidase and N-methyltryptophan oxidase, enzymes that exhibit sequence homology with beta. A highly conserved glycine in the ADP-binding motif of the alpha(Gly139) or beta(Gly30) subunit was mutated in an attempt to generate NAD(+)- or FAD-free cTSOX, respectively. The alpha(Gly139Ala) mutant is expressed only at low temperature (t(optimum) = 15 degrees C), but the purified enzyme exhibited properties indistinguishable from the wild-type enzyme. The much larger barrier to NAD(+) binding in the case of the alpha(Gly139Val) mutant could not be overcome even by growth at 3 degrees C, suggesting that NAD(+) binding is required for TSOX expression. The beta(Gly30Ala) mutant exhibited subunit expression levels similar to those of the wild-type enzyme, but the mutation blocked subunit assembly and covalent attachment of FMN, suggesting that both processes require a conformational change in beta that is induced upon FAD binding. About half of the covalent FMN in recombinant preparations of cTSOX or pTSOX is present as a reversible covalent 4a-adduct with a cysteine residue. Adduct formation is not prevented by mutating any of the three cysteine residues in the beta subunit of cTSOX to Ser or Ala. Since FMN is attached via its 8-methyl group to the beta subunit, the FMN ring must be located at the interface between beta and another subunit that contains the reactive cysteine residue.     

Modeling of the bacterial luciferase-flavin mononucleotide complex combining flexible docking with structure-activity data

Although the crystal structure of Vibrio harveyi luciferase has been elucidated, the binding sites for the flavin mononucleotide and fatty aldehyde substrates are still unknown. The determined location of the phosphate-binding site close to Arg 107 on the alpha subunit of luciferase is supported here by point mutagenesis. This information, together with previous structure-activity data for the length of the linker connecting the phosphate group to the isoalloxazine ring represent important characteristics of the luciferase-bound conformation of the flavin mononucleotide. A model of the luciferase-flavin complex is developed here using flexible docking supplemented by these structural constraints. The location of the phosphate moiety was used as the anchor in a flexible docking procedure performed by conformation search by using the Monte Carlo minimization approach. The resulting databases of energy-ranked feasible conformations of the luciferase complexes with flavin mononucleotide, omega-phosphopentylflavin, omega-phosphobutylflavin, and omega-phosphopropylflavin were filtered according to the structure-activity profile of these analogs. A unique model was sought not only on energetic criteria but also on the geometric requirement that the isoalloxazine ring of the active flavin analogs must assume a common orientation in the luciferase-binding site, an orientation that is also inaccessible to the inactive flavin analog. The resulting model of the bacterial luciferase-flavin mononucleotide complex is consistent with the experimental data available in the literature. Specifically, the isoalloxazine ring of the flavin mononucleotide interacts with the Ala 74-Ala 75 cis-peptide bond as well as with the Cys 106 side chain in the alpha subunit of luciferase. The model of the binary complex reveals a distinct cavity suitable for aldehyde binding adjacent to the isoalloxazine ring and flanked by other key residues (His 44 and Trp 250) implicated in the active site.     

Substitution of ASP193 to ASN at the active site of ribulose-1,5-bisphosphate carboxylase results in conformational changes.

The crystal structure of a mutant of ribulose bisphosphate carboxylase/oxygenase from Rhodospirillium rubrum, where Asp193, one of the ligands of the magnesium ion at the activator site, is replaced by Asn, has been determined to a nominal resolution of 0.26 nm. The mutation of Asp to Asn induces both local and global conformation changes as follows. The side chain of Asn193 moves away from the active site and interacts with main-chain oxygen of residue 165, located in the neighbouring strand beta 1 of the alpha/beta barrel. The side chain of Lys166, which forms a salt bridge with Asp193 in the wild-type enzyme, interacts with Asn54 from the second subunit and creates a new subunit-subunit interaction. Another new subunit-subunit interaction is formed, more than 1.2 nm away from the site of the mutation. In the mutant enzyme, the side chain of Asp263 interacts with the side chain of Thr106 from the second subunit. Asp193 is not part of a subunit-subunit interface area or an allosteric regulatory site. Nevertheless, replacement of this residue by Asn results, unexpectedly, in a difference in the packing of the two subunits, which can be described as a slight rotation of one of the subunits relative to the second. The observed structural changes at the active site of the enzyme provide a molecular explanation for the differing behaviour of the Asp193----Asn mutant with respect to activation.     

Microspectrophotometric studies on single crystals of the tryptophan synthase alpha 2 beta 2 complex demonstrate formation of enzyme-substrate intermediates

Microspectrophotometry of single crystals of the tryptophan synthase alpha 2 beta 2 complex from Salmonella typhimurium is used to compare the catalytic and regulatory properties of the enzyme in the soluble and crystalline states. Polarized absorption spectra demonstrate that chromophoric intermediates are formed between pyridoxal phosphate at the active site of the beta subunit and added substrates, substrate analogs, and reaction intermediate analogs. Although the crystalline and soluble forms of the enzyme produce some of the same enzyme-substrate intermediates, including Schiff base and quinonoid intermediates, in some cases the equilibrium distribution of these intermediates differs in the two states of the enzyme. Ligands which bind to the active site of the alpha subunit alter the distribution of intermediates formed at the active site of the beta subunit in both the crystalline and soluble states. The three-dimensional structures of the tryptophan synthase alpha 2 beta 2 complex and of a derivative with indole-3-propanol phosphate bound at the active site of the alpha subunit have recently been reported (Hyde, C. C., Ahmed, S. A., Padlan, E. A., Miles, E. W., and Davies, D. R. (1988) J. Biol. Chem. 264, 17857-17871). Our present findings help to establish experimental conditions for selecting defined intermediates for future x-ray crystallographic analysis of the alpha 2 beta 2 complex with ligands bound at the active sites of both alpha and beta subunits. These crystallographic studies should explain how catalysis occurs at the active site of the beta subunit and how the binding of a ligand to one active site affects the binding of a ligand to the other active site which is 25 A away.     

The tryptophan synthase alpha 2 beta 2 complex. Cleavage of a flexible loop in the alpha subunit alters allosteric properties

This study explores the catalytic and allosteric roles of a flexible loop in tryptophan synthase. Trypsin is known to cleave the tryptophan synthase alpha 2 beta 2 complex in an alpha subunit loop at Arg-188. Cleavage yields an active "nicked" alpha 2 beta 2 derivative. The new results provide evidence that the alpha subunit loop serves two important roles: substrate binding and communicating the effects of substrate binding to the beta subunit. A role for the loop in substrate binding is supported by our finding that addition of a substrate analogue of the alpha subunit, alpha-glycerol 3-phosphate, decreases the rate of cleavage by trypsin. An allosteric role for the loop is supported by the finding although the native alpha 2 beta 2 complex is strongly inhibited by alpha-glycerol 3-phosphate, the nicked alpha 2 beta 2 complex is desensitized to this inhibition. The time course of proteolysis in the presence and absence of alpha-glycerol 3-phosphate is followed by sodium dodecyl sulfate-gel electrophoresis and by assays of activity in the presence and absence of alpha-glycerol 3-phosphate. We use spectroscopic measurements of the pyridoxal phosphate-L-tryptophan intermediates at the active site of the beta subunit to determine the affinity of the native and nicked enzymes for L-tryptophan and alpha-glycerol 3-phosphate. Although cleavage alters the equilibrium distribution of intermediates and reduces the affinity for alpha-glycerol 3-phosphate, it has little effect on the affinity for amino acids bound to the beta subunit. We conclude that the loop in the alpha subunit is important for ligand binding and for communicating the effects of ligand binding from the alpha subunit to the beta subunit in the alpha 2 beta 2 complex.