AI Article Synopsis
- The study explores how SiO-nanoparticles affect the structure and function of the enzyme elastase at varying temperatures in a specific pH environment.
- Notably, SiO-nanoparticles were found to decrease elastase fluorescence intensity, indicating a static binding mechanism, and suggested that interactions like van der Waals forces and hydrogen bonds are critical to the stability of this enzyme-nanoparticle complex.
- Additionally, the research revealed that SiO-nanoparticles altered the secondary structure of elastase, impacting both its activity and thermal stability, indicating a potential for tailoring enzyme activity through nanoparticle modification.
Article Abstract
The increasing use of nanoparticles in various industries has triggered the need to study their interconnection with biological macromolecules. The goal of this study was to survey the SiO-nanoparticles efficacy on the thermal denaturation, conformation and activity of elastase at three temperatures of 303, 313 and 323K in the Tris buffer at pH of 8.5. In this work, distinct techniques such as UV-vis Spectrophotometry, Spectrofluorometry, and circular dichroism were employed. The fluorescence studies showed that SiO nanoparticles extremely reduced the intensity of elastase with the static mechanism. Thermodynamic parameter analysis also indicated that the process of binding of SiO-nanoparticles to elastase was spontaneous, thereby suggesting that van der Waals forces or hydrogen bonding interactions played a key role in determining the complex stability. Far-UV circular dichroism studies further revealed that SiO nanoparticles could cause 9.79% reduction in the content of the α-helix and 3.24% increase in the content of the β-sheet. Furthermore, kinetic parameters (V and K/K) indicated that SiO nanoparticles had an activation effect on the elastase activity. Melting temperature studies at the selected concentration of SiO nanoparticles also showed that by adding SiO nanoparticles, elastase thermal stability was slightly increased. Overall, these nanoparticles modified the structure of the elastase, ultimately changing the activity and stability of this enzyme.
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| http://dx.doi.org/10.1016/j.ijbiomac.2019.05.007 | DOI Listing |
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