Thermodynamic Studies on the Protonation Equilibria of Some Hydroxamic Acids in NaNO<sub>3</sub> Solutions in Water and in Mixtures of Water and Dioxane

Fazary, Ahmed E.

doi:10.1021/je0496185

Cited by 32 publications

(25 citation statements)

References 35 publications

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“…Also unknown are p K a values for these ligands which are needed to characterize the complex stability at variable pH. As one can see from Table p K a of SHA‐OMe is very close to p K a1 of SHA in agreement with assignment of first deprotonation of SHA to phenolic OH and p K a1 of SHA‐NMe is significantly lower than that of SHA as is typical for N‐substituted hydroxamic acids . Both methylated derivatives form anionic deprotonated complexes with PBA with β 1,1,‐1 values slightly smaller in case of SHA‐OMe and even larger in case of SHA‐NMe than that for SHA.…”

Section: Resultssupporting

confidence: 52%

“…As one can see from Table 1 pK a of SHA-OMe is very close to pK a1 of SHA in agreement with assignment of first deprotonation of SHA to phenolic OH [15] and pK a1 of SHA-NMe is significantly lower than that of SHA as is typical for Nsubstituted hydroxamic acids. [17] Both methylated derivatives form anionic deprotonated complexes with PBA with β 1,1,-1 values slightly smaller in case of SHA-OMe and even larger in case of SHA-NMe than that for SHA. The K obs values for both derivatives in pH range 7-9 are smaller than K obs for SHA only by a factor of 2 ( Figure 1).…”

Section: Resultsmentioning

confidence: 97%

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Thermodynamic and structural study of complexation of phenylboronic acid with salicylhydroxamic acid and related ligands

Martínez‐Aguirre

Flores-Álamo

Yatsimirsky

2018

Applied Organom Chemis

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Stability constants of boronate complexes with a highly efficient bioconjugation ligand salicylhydroxamic acid, its derivatives and some structurally related compounds were determined by potentiometric and spectroscopic titrations at variable pH allowing one to obtain detailed stability – pH profiles and to identify the optimum pH for complexation with each ligand. The N,O‐binding of salicylhydroxamic acid via condensation of boronic acid with phenolic OH and hydroxamic NH groups was established by crystal structure determination of isolated complexes with phenylboronic and 4‐nitrophenylboronic acids. Although this type of binding is impossible for N‐methylated salicylhydroxamic acid it still forms stable boronate complexes supposedly involving unusual 7‐membered –O‐B‐O‐ cycle supported by 1H NMR studies. Hydroxamic acids lacking ortho‐OH group and salicyloyl hydrazide form less stable boronate complexes, which nevertheless possess stabilities similar to those of catechole complexes and may be useful for conjugation applications. In contrast to other ligands, which form tetrahedral anionic complexes, salicylamidoxime forms tetrahedral, but neutral boronate complex with high stability in weakly acid solutions. The highest affinity in neutral and acid solutions surpassing that of salicylhydroxamic acid is observed with 2,6‐dihydroxybenzhydroxamic acid (Kobs = 5.2 × 104 at pH 7.4). Fairly stable mono‐ and bisboronate complexes are formed with 2,5‐dihydroxy‐1,4‐benzdihydroxamic acid, which also possesses intense fluorescence and may serve as a boronic acid sensor with detection limit 4 μM. Results presented in this study provide quantitative basis for rational applications of hydroxamic acid derivatives in bioconjugation and sensing.

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Section: Resultssupporting

confidence: 52%

Section: Resultsmentioning

confidence: 97%

Thermodynamic and structural study of complexation of phenylboronic acid with salicylhydroxamic acid and related ligands

Martínez‐Aguirre

Flores-Álamo

Yatsimirsky

2018

Applied Organom Chemis

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“…The pK a values were calculated adopting the Irving and Rossotti technique as described in our previous work [24][25][26]. Computations related to the estimation of dissociation constants were performed by regression analysis of titration curves using the least-squares computer ESAB [16,17] and PKPOT programmes [18].…”

Section: Calculationsmentioning

confidence: 99%

Protonation equilibria studies of the standard α-amino acids in NaNO3 solutions in water and in mixtures of water and dioxane

Fazary¹,

Mohamed²,

Lebedeva³

2006

The Journal of Chemical Thermodynamics

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“…The significantly lower affinity for 8-HQ than free Zn 2+ likely reflects the lower charge density on the BPA-bound zinc ion thus a weaker bond with 8-HQ, which gave rise to an overall weaker affinity of [Zn(BPA)] 2+ than free Zn 2+ for 8-HQ. 16 With a pKa value of 9.28, 44 AHA is expected to undergo deprotonation upon binding to Zn 2+ , contributing to the difference between the logKa and logβ values. As mentioned earlier, the slightly more basic pH than the 6.80 used for the 8-HQ study was necessary in order to increase AHA affinity for [Zn(BPA)] 2+ for accurate determination of the binding parameters.…”

Section: [Zn(bpa)] 2+ Interactions With 8-hq and Ahamentioning

confidence: 99%

Calorimetric studies of the interactions of metalloenzyme active site mimetics with zinc-binding inhibitors

et al. 2016

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The binding of drugs to metalloenzymes is an intricate process that involves several interactions, including binding of the drug to the enzyme active site metal, as well as multiple interactions between the drug and the enzyme residues. In order to determine the free energy contribution of Zn(2+) binding by known metalloenzyme inhibitors without the other interactions, valid active site zinc structural mimetics must be formed and binding studies need to be performed in biologically relevant conditions. The potential of each of five ligands to form a structural mimetic with Zn(2+) was investigated in buffer using Isothermal Titration Calorimetry (ITC). All five ligands formed strong 1 : 1 (ligand : Zn(2+)) binary complexes. The complexes were used in further ITC experiments to study their interaction with 8-hydroxyquinoline (8-HQ) and/or acetohydroxamic acid (AHA), two bidentate anionic zinc-chelating enzyme inhibitors. It was found that tetradentate ligands were not suitable for creating zinc structural mimetics for inhibitor binding in solution due to insufficient coordination sites remaining on Zn(2+). A stable binary complex, [Zn(BPA)](2+), which was formed by a tridentate ligand, bis(2-pyridylmethyl)amine (BPA), was found to bind one AHA in buffer or a methanol : buffer mixture (60 : 40 by volume) at pH 7.25 or one 8-HQ in the methanol : buffer mixture at pH 6.80, making it an effective structural mimetic for the active site of zinc metalloenzymes. These results are consistent with the observation that metalloenzyme active site zinc ions have three residues coordinated to them, leaving one or two sites open for inhibitors to bind. Our findings indicate that Zn(BPA)X2 can be used as an active site structural mimetic for zinc metalloenzymes for estimating the free energy contribution of zinc binding to the overall inhibitor active site interactions. Such use will help aid in the rational design of inhibitors to a variety of zinc metalloenzymes.

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Thermodynamic Studies on the Protonation Equilibria of Some Hydroxamic Acids in NaNO₃ Solutions in Water and in Mixtures of Water and Dioxane

Cited by 32 publications

References 35 publications

Thermodynamic and structural study of complexation of phenylboronic acid with salicylhydroxamic acid and related ligands

Thermodynamic and structural study of complexation of phenylboronic acid with salicylhydroxamic acid and related ligands

Protonation equilibria studies of the standard α-amino acids in NaNO3 solutions in water and in mixtures of water and dioxane

Calorimetric studies of the interactions of metalloenzyme active site mimetics with zinc-binding inhibitors

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Thermodynamic Studies on the Protonation Equilibria of Some Hydroxamic Acids in NaNO3 Solutions in Water and in Mixtures of Water and Dioxane

Cited by 32 publications

References 35 publications

Thermodynamic and structural study of complexation of phenylboronic acid with salicylhydroxamic acid and related ligands

Thermodynamic and structural study of complexation of phenylboronic acid with salicylhydroxamic acid and related ligands

Protonation equilibria studies of the standard α-amino acids in NaNO3 solutions in water and in mixtures of water and dioxane

Calorimetric studies of the interactions of metalloenzyme active site mimetics with zinc-binding inhibitors

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Thermodynamic Studies on the Protonation Equilibria of Some Hydroxamic Acids in NaNO₃ Solutions in Water and in Mixtures of Water and Dioxane