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The role of noncovalent interactions in the catalytic mechanism of the Agrobacterium faecalis beta-glucosidase was investigated by steady-state and pre-steady state kinetic analysis of the hydrolysis of a series of monosubstituted aryl glycosides, in which the hydroxyl groups on the glycone were substituted by hydrogen or fluorine. Contributions of each hydroxyl group to binding of these substrates at the ground state are relatively weak (interaction energies of 3.3 kJ/mol or smaller) but are much greater at the two transition states (glycosylation and deglycosylation). The strongest transition state interactions were at the 2 position (at least 18 and 22 kJ/mol for glycosylation and deglycosylation, respectively) with the interactions at the 3 and 6 positions contributing at least another 9 kJ/mol of binding energy at both transition states. The interaction at the 4 position is less crucial to transition state binding but important for stabilization of the glycosyl-enzyme intermediate. Comparison of observed rates with those for spontaneous hydrolysis of the same substrates provides evidence for oxocarbenium ion character at both transition states, that for deglycosylation apparently having the greater positive charge development at the anomeric center.

Glutamate racemase is a cofactor-independent enzyme that employs two active-site cysteine residues as acid/base catalysts during the interconversion of glutamate enantiomers. In a given reaction direction, a thiolate from one of the cysteines abstracts the alpha-proton, and the other cysteine thiol delivers a proton to the opposite face of the resulting carbanionic intermediate. This paper reports that the C73S and C184S mutants are still capable of racemizing glutamate with specificity constants about 10(3)-fold lower than those of the wild-type enzyme. A "one-base requiring" reaction, the elimination of water from N-hydroxyglutamate, has been used to deduce which thiol acts as the base for a given enantiomer. With D-N-hydroxyglutamate the C73S mutant is a much poorer catalyst than wild-type enzyme, whereas the C184S mutant is a somewhat better catalyst. This trend was reversed with L-N-hydroxyglutamate, suggesting that Cys73 is responsible for the deprotonation of D-glutamate and Cys184 is responsible for the deprotonation of L-glutamate. In addition, with C73S the Vmax/KM isotope effect on D-glutamate racemization was greater than that seen with wild-type enzyme, whereas the isotope effect with L-glutamate had decreased. The results were reversed with the C184S mutant. This is interpreted as being due to an asymmetry in the free energy profiles that is induced upon mutation, with the deprotonation step involving a serine becoming the more cleanly rate-determining of the two. These results support the above assignment and the notion that a carbanionic intermediate is formed during catalysis.

A method for the generation of soluble glycosphingolipid derivatives that retain the receptor activity of the parent (BBRC 257:391-394, Carb Res 335:91-100) was used to investigate the consequence of 3'sulfogalactolipid (SGL) specific binding within the N-terminal ATPase-containing domain of Hsc70. Sulfogalactosyl ceramide (SGC) was deacylated, and the resulting sulfogalactosylsphingosine coupled to an alpha-adamantane or a norbornane rigid hydrophobic frame. The resulting conjugate preferentially partitioned into water, as opposed to organic solvent. In the range of 100-300 microM, these conjugates inhibited the specific binding of bovine brain Hsc70 to immobilized SGLs. A similar dose-related inhibition of bovine brain Hsc70 ATPase activity was seen between 100 and 300 microM adamantylSGC (adaSGC). Adamantyl conjugates of glycolipids not bound by Hsp70s had no effect. Kinetic analysis indicated that adaSGC was a noncompetitive inhibitor of Hsc70 ATPase activity, a special case of mixed inhibition since the K(m) values were not statistically different, 0.89 +/- 0.024 microM to 0.93 +/- 0.038 microM, but the V(max) decreased from 0.20 +/- 0.012 pmol min(-1) microg(-1) to 0.15 +/- 0.016 pmol min(-1) microg(-1). A reproducible 5 min lag was observed prior to ATPase inhibition that could be eliminated by preincubation of adaSGC with Hsc70 or by adding the cochaperone Hdj-1. The dependence of ATPase inhibition on the rate of hydrolysis indicates that adaSGC binding occurs at a specific stage of the ATPase cycle. These studies identify a new mechanism for the regulation of Hsp70 ATPase activity.

Although the majority of natural proteins exist as protein-protein complexes, the molecular basis for the formation and regulation of such interactions and the evolution of protein interfaces remain poorly understood. We have investigated these phenomena by characterizing the thermal and chemical denaturation of thermophilic DsrEFH proteins that have a common subunit fold but distinct quaternary structures: homodimeric Tm0979 and homotrimeric Mth1491. Tm0979 forms a moderate affinity dimer, and a monomeric intermediate is readily populated at equilibrium and during folding kinetics. In contrast, the Mth1491 trimer has extremely high stability, so that a monomeric form is not measurably populated at equilibrium, although it may be during folding kinetics. A common mechanism for evolution of quaternary structures may be facile formation of a relatively stable monomeric species, with stabilizing intermolecular interactions centering on alternative environments for a beta-strand at the edge of the monomer, augmented by malleable hydrophobic interactions. The exceptional trimer stability arises from a remarkably slow unfolding rate constant, 6.5 x 10(-13) s(-1), which is a common characteristic of highly stable thermophilic and/or oligomeric proteins. The folding characteristics of Tm0979 and Mth1491 have interesting implications for assembly and regulation of homo- and heterooligomeric proteins in vivo.

Steady-state kinetics of the oxidation of p-coumaric acid (CA) by prostaglandin H synthase and hydrogen peroxide was studied at 25 degrees C in 0.1 M phosphate buffer, pH 8.0, using a stopped-flow apparatus. The following evidence supports a mechanism in which CA serves as a reducing substrate for prostaglandin H synthase through two one-electron oxidation steps: (a) the oxidation product of CA is the same in the prostaglandin H synthase/hydrogen peroxide and the horseradish peroxidase/hydrogen peroxide systems; (b) an identical steady-state enzyme intermediate (compound II) is present in both systems; (c) CA stimulates the cyclooxygenase activity of prostaglandin H synthase; the concentration of CA that produces 50% stimulation, A50, is 350 +/- 30 microM. On the time scale of our experiments, the inactivation of prostaglandin H synthase by hydrogen peroxide was insignificant when CA was present. A molar absorptivity of 17.2 +/- 0.9 mM-1 cm-1 at 300 nm was determined for CA which was used to follow the initial rate of disappearance of CA. The reaction of CA with hydrogen peroxide catalyzed by prostaglandin H synthase showed saturation behavior. An irreversible reaction mechanism for the steady-state kinetics of prostaglandin H synthase is proposed which is consistent with all of our experimental results. Under steady-state conditions, the second-order rate constants for the reactions of prostaglandin H synthase with hydrogen peroxide and prostaglandin H synthase-compound II with CA are (9.2 +/- 0.1) x 10(5) and (2.5 +/- 0.1) x 10(6) M-1 s-1, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

While calcium binding to troponin C (TnC) triggers the contraction of both skeletal and cardiac muscle, there is clear evidence that different mechanisms may be involved. For example, activation of heart myofilaments occurs with binding to a single regulatory site on TnC, whereas activation of fast skeletal myofilaments occurs with binding to two regulatory sites. The physiological difference between activation of cardiac and skeletal myofilaments is not understood at the molecular level due to a lack of structural details for the response of cardiac TnC to calcium. We determined the solution structures of the apo and calcium-saturated regulatory domain of human cardiac TnC by using multinuclear, multidimensional nuclear magnetic resonance spectroscopy. The structure of apo human cardiac TnC is very similar to that of apo turkey skeletal TnC even though there are critical amino acid substitutions in site I. In contrast to the case with the skeletal protein, the calcium-induced conformational transition in the cardiac regulatory domain does not involve an "opening" of the regulatory domain, and the concomitant exposure of a substantial hydrophobic surface area. This result has important implications with regard to potential unique aspects of the interaction of cardiac TnC with cardiac troponin I and of modification of cardiac myofilament regulation by calcium-sensitizer drugs.

The sulfonylurea receptor 1 (SUR1) protein forms the regulatory subunit in ATP sensitive K+ (KATP) channels in the pancreas. SUR proteins are members of the ATP binding cassette (ABC) superfamily of proteins. Binding and hydrolysis of MgATP at the SUR nucleotide binding domains (NBDs) lead to channel opening. Pancreatic KATP channels play an important role in insulin secretion. SUR1 mutations that result in increased levels of channel opening ultimately inhibit insulin secretion and lead to neonatal diabetes. In contrast, SUR1 mutations that disrupt trafficking and/or decrease gating of KATP channels cause congenital hyperinsulinism, where oversecretion of insulin occurs even in the presence of low glucose levels. Here, we present data on the effects of specific congenital hyperinsulinism-causing mutations (G716V, R842G, and K890T) located in different regions of the first nucleotide binding domain (NBD1). Nuclear magnetic resonance (NMR) and fluorescence data indicate that the K890T mutation affects resi...

Phosphoenolpyruvate carboxykinase (PEPCK) is an essential metabolic enzyme operating in the gluconeogenesis and glyceroneogenesis pathways. Recent studies have demonstrated that the enzyme contains a mobile active site lid domain that undergoes a transition between an open, disorded conformation and a closed, ordered conformation as the enzyme progresses through the catalytic cycle. The understanding of how this mobile domain functions in catalysis is incomplete. Previous studies showed that the closure of the lid domain stabilizes the reaction intermediate and protects the reactive intermediate from spurious protonation and thus contributes to the fidelity of the enzyme. To more fully investigate the roles of the lid domain in PEPCK function, we introduced three mutations that replaced the 11-residue lid domain with one, two, and three glycine residues. Kinetic analysis of the mutant enzymes demonstrates that none of the enzyme constructs exhibit any measurable kinetic activity, resulting in a decrease in the catalytic parameters of at least 10(6). Structural characterization of the mutants in complexes representing the catalytic cycle suggests that the inactivity is due to a role for the lid domain in the formation of the fully closed state of the enzyme that is required for catalytic function. In the absence of the lid domain, the enzyme is unable to achieve the fully closed state and is rendered inactive despite possessing all of the residues and substrates required for catalytic function. This work demonstrates how enzyme catalytic function can be abolished through the alteration of conformational equilibria despite all the elements required for chemical conversion of substrates to products remaining intact.

The complete primary and three-dimensional solution structures of subtilosin A (1), a bacteriocin from Bacillus subtilis, were determined by multidimensional NMR studies on peptide produced using isotopically labeled [(13)C,(15)N]medium derived from Anabaena sp. grown on sodium [(13)C]bicarbonate and [(15)N]nitrate. Additional samples of 1 were also generated by separate incorporations of [U-(13)C,(15)N]-L-phenylalanine and [U-(13)C,(15)N]-L-threonine using otherwise unlabeled media. The results demonstrate that in addition to having a cyclized peptide backbone (amide between N and C termini), three cross-links are formed between the sulfurs of Cys13, Cys7, and Cys4 and the alpha-positions of Phe22, Thr28, and Phe31, respectively. The stereochemistry of all residues in 1 except for the three modified ones was confirmed to be L by complete desulfurization with nickel boride, acid hydrolysis to the constituent amino acids, and conversion of these to the corresponding pentafluoropropanamide isopropyl esters for chiral GC MS analysis. The stereochemistry at the modified residues was determined by subjecting each of the eight possible stereoisomers of 1 to eight rounds of ARIA structure calculations, starting with the same NMR peak files and assignments. The stereoisomer with the l stereochemistry at Phe22 (alpha-R) and d stereochemistry at Thr28 (alpha-S) and Phe31 (alpha-S) (LDD isomer) fit the NMR data, giving the lowest energy family of structures with the best rmsd. Thus, biochemical formation of the unusual thio links proceeds with net retention of configuration at Phe22, and inversion at Thr28 and Phe31. Model amino acid derivatives bearing a sulfide moiety at the alpha-carbon were synthesized by reaction of the corresponding alpha-alkoxy compounds with benzyl thiol and SnCl(4). Separation of their pure stereoisomers and desulfurization with nickel boride demonstrated that the reduction of such compounds proceeds with epimerization, in contrast to the previously reported retention of stereochemistry for analogous reaction of steroidal sulfides. However, desulfurization of subtilosin A to cyclic peptide 14, which is inactive as an antimicrobial agent, occurs with inversion of stereochemistry at the alpha-carbons of Phe22 and Thr28 and with 4:1 retention at Phe31. This indicates that the desulfurization reaction proceeds via an N-acyl imine and that the structure of the surrounding peptide controls the geometry of reduction. Posttranslational linkage of a thiol to the alpha-carbon of an amino acid residue is unprecedented in ribosomally synthesized peptides or proteins, and very rare in secondary metabolites. Subtilosin A (1) represents a new class of bacteriocins.

The 4E binding proteins (4E-BP1 and 4E-BP2) inhibit translation by binding to the limiting, proto-oncogenic initiation factor eIF4E. 4E-BPs produced in Escherichia coli had little or no folded structure, measured by NMR and CD. However, these proteins inhibited translation in reticulocyte lysate. Furthermore, they bound to isolated mouse eIF4E, showing a few broader, dispersed new NMR signals but no general increase in chemical shift dispersion. A peptide with the sequence of 4E-BP1 residues 49-68 was sufficient to bind eIF4E and to inhibit translation in reticulocyte lysate. These results suggest that a short central region of the 4E-BPs is responsible for eIF4E binding and translation inhibition while the remainder is unfolded and flexible.