Calorimetric, spectroscopic and computational investigation of morin binding effect on bovine serum albumin stability

Precupaş, Aurica; Sandu, Romică; Neculae, Alexandru Vincentiu Florian; Neacsu, Andreea; Popa, Vlad Tudor

doi:10.1016/j.molliq.2021.115953

Cited by 10 publications

(4 citation statements)

References 61 publications

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“…Previous calorimetric studies [24] concerning BSA thermal stability in phosphate buffer evidenced only the endothermal denaturation process. That was confirmed by our previous contributions [25][26][27]. In other words, the phosphate buffer covers the exothermal calorimetric signature of the aggregation process; although, the later takes place in the temperature range investigated.…”

Section: Evaluation Of Protein Thermal Stability By Differential Scan...supporting

confidence: 84%

“…The stabilization effect on the secondary structure of the protein, observed for both 1:1 and 10:1 SA:BSA molar ratios, could be correlated with µDSC data, where T d increases in the presence of the ligand. Similar results were obtained for the interaction of morin [25], caffeic acid [26], and caffeoylquinic acids [36] with BSA.…”

Section: Circular Dichroism (Cd) Spectrasupporting

confidence: 84%

“…A significant impact was observed for a 10:1 SA:BSA molar ratio, pointing to the stabilization effect of the excess free ligand. A similar influence was obtained for morin, a polyphenol that belongs to the flavanol class of flavonoids, in interaction with BSA [25]. The stabilization of protein structure could be generated by the electrostatic attraction between the negatively charged SA and the positively charged amino acid residues from the protein binding site, as observed by our group for the caffeic acid interaction with BSA [26].…”

Section: Evaluation Of Protein Thermal Stability By Differential Scan...supporting

confidence: 79%

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Impact of Sinapic Acid on Bovine Serum Albumin Thermal Stability

Precupas,

Popa

2024

IJMS

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The thermal stability of bovine serum albumin (BSA) in Tris buffer, as well as the effect of sinapic acid (SA) on protein conformation were investigated via calorimetric (differential scanning microcalorimetry—μDSC), spectroscopic (dynamic light scattering—DLS; circular dichroism—CD), and molecular docking approaches. μDSC data revealed both the denaturation (endotherm) and aggregation (exotherm) of the protein, demonstrating the dual effect of SA on protein thermal stability. With an increase in ligand concentration, (i) protein denaturation shifts to a higher temperature (indicating native form stabilization), while (ii) the aggregation process shifts to a lower temperature (indicating enhanced reactivity of the denatured form). The stabilization effect of SA on the native structure of the protein was supported by CD results. High temperature (338 K) incubation induced protein unfolding and aggregation, and increasing the concentration of SA altered the size distribution of the protein population, as DLS measurements demonstrated. Complementary information offered by molecular docking allowed for the assessment of the ligand binding within the Sudlow’s site I of the protein. The deeper insight into the SA–BSA interaction offered by the present study may serve in the clarification of ligand pharmacokinetics and pharmacodynamics, thus opening paths for future research and therapeutic applications.

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Section: Evaluation Of Protein Thermal Stability By Differential Scan...supporting

confidence: 84%

Section: Circular Dichroism (Cd) Spectrasupporting

confidence: 84%

Section: Evaluation Of Protein Thermal Stability By Differential Scan...supporting

confidence: 79%

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Impact of Sinapic Acid on Bovine Serum Albumin Thermal Stability

Precupas,

Popa

2024

IJMS

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“…The binding process between small molecules and proteins in solution may involve different interactions strictly related to their structural properties. Van der Waals forces, electrostatic and hydrophobic interactions are usually the main driving forces that occur in the recognition process [31][32][33][34]. Due to the specific structures of both hydrazones and serum albumins examined in this work, the binding events may be mainly attributed to (i) hydrophobic interactions between the aromatic moiety of the hydrazones and the hydrophobic cavity of the protein, (ii) electrostatic interactions between the phosphate group of the hydrazones and the polar amino groups of BSA/HSA, (iii) hydrogen bonding between the hydroxyl and phosphate groups of the hydrazones and the amino and hydroxyl groups of BSA/HSA and (iv) desolvation and/or structural re-arrangement of both the hydrazone and the protein upon complexation [35][36][37].…”

Section: Resultsmentioning

confidence: 99%

Isothermal titration calorimetry investigation of the interactions between vitamin B6-derived hydrazones and bovine and human serum albumin

Migliore

Завалишин

Гамов

et al. 2022

J Therm Anal Calorim

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The binding of low molecular weight compounds with the transport proteins of blood is an essential step of their delivery into living cells and thus the accurate investigation of the interactions occurring in solution at physiological conditions is crucial for the development of efficient biologically active molecules. In this work, we report on the complex species, stability constants and thermodynamic parameters for the binding reactions of hydrazones derived from pyridoxal-5ʹ-phosphate (PLP) with bovine and human serum albumin (BSA and HSA) in neutral aqueous solution. The study has been carried out using isothermal titration calorimetry which allowed to directly obtain both binding constant and enthalpy change values for the systems investigated. The thermodynamic characterization in solution revealed that the PLP-hydrazone derivatives are able to effectively interact with both bovine and human serum albumin and enabled the determination of the driving forces for the molecular recognition process. The formation of the 1:1 complex was found to be always enthalpy favored and driven due to the insertion of the hydrazone moieties into the hydrophobic pockets of BSA or HSA.

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