Conformational dynamics and solvent viscosity effects in carboxypeptidase‐A‐catalyzed benzoylglycylphenyllactate hydrolysis

Goguadze, Nina G.; Hammerstad-Pedersen, Jan M.; Khoshtariya, Dimitrij E.; Ulstrup, Jens

doi:10.1111/j.1432-1033.1991.tb16200.x

Cited by 44 publications

(39 citation statements)

References 78 publications

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“…Here, we note that under standard conditions (no urea or TMAO added), the results for k cat and K m regarding both substrates are within the range of published results, 3,4,12,[17][18][19]45 with a much larger spread for the latter parameter which, seemingly, is caused by the following : (i) determination of K m through the Lineweaver-Burk procedure, in general, is connected to the extrapolation of experimental points over larger numerical windows and, (ii) in this particular case, the large uncertainty in choosing the ''valid'' intervals of substrate concentration when the method of ''initial slopes'' is applied, cf. Figures S3 and S4 ; note large positive value for the latter one) for the hydrolyses of Bz-Gly-OPhe, an even more notable deviation from the published results (ranging within 40 to 54 kJ mol 21 for DH a(eff) , and occurring around 240 J K 21 mol…”

Section: Figuresupporting

confidence: 77%

“…Kinetic traces were recorded at a fixed wavelength of 260 nm, where the spectral changes due to both the hydrolytic processes are optimal. 19,45 The working concentration for the substrates (1 mM) was such that the absorbance in the stopped-flow optical cell did not exceed 1. The necessary calibrating (static) spectra of substrates and the hydrolysis products were recorded on a Cary 3 (Varian) UV-Vis instrument.…”

Section: Apparatus and Kinetic Measurementsmentioning

confidence: 99%

“…[3][4][5][6][12][13][14][15][16][20][21][22][23][24][25][26][27] The ''promoted water'' pathway entails direct participation of Zn 21 -activated water in a rate-determining step as a nucleophile with the carboxylate group of Glu270 acting as a general base (Scheme 1), whereas the ''anhydride intermediate'' pathway implies direct nucleophilic attack by Glu270 (Scheme 2), with water to be involved in the following stage (for the detailed discussion, see Results and Discussion). Notwithstanding that the mechanistic difference for peptide and ester substrates has been discussed numerous times, [3][4][5][6]12,13,18,19,26,27 definitely this problem requires further clarification, implying both the adequate classification and theory-based description, on the grounds of matching current concepts (vide infra). Much inconvenience on the way of experiment-aided mechanistic analysis comes from the fact that small specific probing substrates, both peptide and ester, for which combined kinetic studies usually give decisive mechanistic information (see, e.g., Refs.…”

mentioning

confidence: 98%

“…3,6,8,[23][24][25][26][27][28] This situation is rather distinct from some other classes of model enzymes such as, e.g., serine hydrolases for which the major mechanistic pattern has been firmly established. 29,30 Among other complexities, extremely diverse kinetic manifestations showing up through the pH profiles, [3][4][5][6]12 inhibition/activation patterns (due to substrates or other effectors), [3][4][5][6]12,13,22 cryospectroscopic (intermediate trapping) experiments, 6,14,16 and viscosity impact observations, [17][18][19] should be mentioned. Interestingly, rather diverse performance has been observed not only between two families of more natural yet synthetic (''probing'') peptide and the counterpart ester (depsi-peptide) substrates but also within the substrates of either of these types that may differ in the chain length and/or residue specificity.…”

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confidence: 99%

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Diverse role of conformational dynamics in carboxypeptidase A‐driven peptide and ester hydrolyses: Disclosing the “Perfect Induced Fit” and “Protein Local Unfolding” pathways by altering protein stability

et al. 2011

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Catalytic mechanisms of carboxypeptidase A (CPA) are well known for their diversity and the relative inaccessibility for a decisive comprehension. Recent encouraging attempts through modern computational techniques promoted new challenges for the complementary experimental endeavors. In this work, we have applied the stopped-flow technique and the method of reaction progress curve fitting to extract kinetic parameters for the CPA-catalyzed hydrolyses of smaller (typical) peptide and ester substrates, known for their strong activating/inhibiting impact, thus to which the traditional method of "initial rates" is not applicable. Our approach that innately implies the overall constancy of the affecter (substrate plus "active" product) concentration, made it possible to rigorously determine the physically meaningful "effective" values for the catalytic and Michaelis constants under diverse experimental conditions including variable temperature and urea or trimethylamine N-oxide concentrations. Analysis of the obtained results allowed for: (i) the further substantiation of diverse mechanistic patterns for archetypal specific peptide and ester substrates, (ii) testing and disclosure of intrinsic links between the stabilizing/destabilizing and activating/inhibiting effects for the important model enzyme, CPA, and (iii) tentative explanation of a distinct activating/inhibiting impact of these substrates through the strong specific interaction of their benzyl (Bz) moiety with the substrate binding S(3) subsite of CPA. We have demonstrated that stabilization of CPA either through the interaction with an extra Bz moiety (belonging to another substrate or to the product) leads to the increase of its catalytic power with respect to the specific peptide substrate and to its decrease with respect to the counterpart ester substrate. We conjecture that the catalytic mechanisms operating in these two cases include: (a) the "promoted water" mechanism for the peptide substrate that, seemingly, provides the almost "perfect induced fit" (low-barrier conformational adaptation), and (b) presumably, the "anhydride intermediate" mechanism for the ester substrate that, anyway, requires substantial conformational rearrangement (in fact, "partial or local unfolding") of the protein environment in the course of the rate-determining step.

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Section: Figuresupporting

confidence: 77%

Section: Apparatus and Kinetic Measurementsmentioning

confidence: 99%

mentioning

confidence: 98%

mentioning

confidence: 99%

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Diverse role of conformational dynamics in carboxypeptidase A‐driven peptide and ester hydrolyses: Disclosing the “Perfect Induced Fit” and “Protein Local Unfolding” pathways by altering protein stability

et al. 2011

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“…Assuming that ΔH Ã a ¼ 7.2 kJ mol −1 (because still V AB ≪ λ o ∕4; see above), one obtains H aðηÞ ¼ 15.4 − 7.2 ¼ 8.2 ðkJ mol −1 Þ, a value that can be attributed to the accompanying relaxation process (es) of the slowly fluctuating protein/water/SAM environment (see also refs. 24,28,54). Interestingly, the value of ΔH aðEXPÞ for n ¼ 10 (the transition point between two regimes; Fig.…”

Section: Resultsmentioning

confidence: 99%

Fundamental signatures of short- and long-range electron transfer for the blue copper protein azurin at Au/SAM junctions

Khoshtariya

Dolidze

Shushanyan

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

126

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The blue copper protein from Pseudomonas aeruginosa, azurin, immobilized at gold electrodes through hydrophobic interaction with alkanethiol self-assembled monolayers (SAMs) of the general type [−S − ðCH 2 Þ n − CH 3 ] (n ¼ 4, 10, and 15) was employed to gain detailed insight into the physical mechanisms of short-and long-range biomolecular electron transfer (ET). Fast scan cyclic voltammetry and a Marcus equation analysis were used to determine unimolecular standard rate constants and reorganization free energies for variable n, temperature (2-55°C), and pressure (5-150 MPa) conditions. A novel global fitting procedure was found to account for the reduced ET rate constant over almost five orders of magnitude (covering different n, temperature, and pressure) and revealed that electron exchange is a direct ET process and not conformationally gated. All the ET data, addressing SAMs with thickness variable over ca. 12 Å, could be described by using a single reorganization energy (0.3 eV), however, the values for the enthalpies and volumes of activation were found to vary with n. These data and their comparison with theory show how to discriminate between the fundamental signatures of short-and long-range biomolecular ET that are theoretically anticipated for the adiabatic and nonadiabatic ET mechanisms, respectively. electron transfer mechanism | pressure | protein friction | reorganization | temperature T he intrinsic electron transfer (ET) mechanisms of even small and otherwise well-characterized proteins such as cytochrome c or azurin (Az) are difficult to identify conclusively because of the proteins' complexity, i.e., inhomogeneous structural and dynamic properties (1-14). The use of bioelectrochemical tunneling junctions, such as self-assembled monolayer (SAM) films of variable composition and thickness on metal electrodes, with redox proteins immobilized at the solution interface (or freely diffusing to the SAM terminal groups) have been shown to provide an assembly with well-defined and variable control parameters. As such, these assemblies are well suited for fundamental studies (15-32) and offer promise for versatile nanotechnology applications (32,33). On the basis of earlier fundamental efforts, this work studies ET between a Au electrode that is coated with a SAM alkanethiol film of variable thickness and a "model" biomolecular target, the blue copper protein, Az, from Pseudomonas aeruginosa that is immobilized through hydrophobic interactions onto the SAM. As a decisive development of the preceding work (19,20,25,26), we offer unique kinetic data obtained through temperature-and pressure-variation and the mechanistic analysis through a unique global fitting procedure accounting for ET at different SAM thickness, temperature, and pressure conditions that provided the variation of the reduced ET rate constant over almost five orders of magnitude. Importantly, our previous work demonstrated that Au-deposited SAMs can withstand pressure-related stress within 5 to 150 MPa (27, 28, 34).The rate constant, k ...

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Solvent‐Fluctuation Control of Solution Reactions and its Manifestation in Protein Functions

Sumi¹

1999

Advances in Chemical Physics

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Conformational dynamics and solvent viscosity effects in carboxypeptidase‐A‐catalyzed benzoylglycylphenyllactate hydrolysis

Cited by 44 publications

References 78 publications

Diverse role of conformational dynamics in carboxypeptidase A‐driven peptide and ester hydrolyses: Disclosing the “Perfect Induced Fit” and “Protein Local Unfolding” pathways by altering protein stability

Diverse role of conformational dynamics in carboxypeptidase A‐driven peptide and ester hydrolyses: Disclosing the “Perfect Induced Fit” and “Protein Local Unfolding” pathways by altering protein stability

Fundamental signatures of short- and long-range electron transfer for the blue copper protein azurin at Au/SAM junctions

Solvent‐Fluctuation Control of Solution Reactions and its Manifestation in Protein Functions

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