Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Mohammadi, Amirreza, Jafarian, Vahab, Khalifeh, Khosrow, Shirdel, Akram, Khatami, Fatemeh
Format: Artículo científico
Sprache:en
Veröffentlicht: Photochemical & photobiological sciences : Official journal of the European Photochemistry Association and the European Society for Photobiology 2025
Online-Zugang:https://pubmed.ncbi.nlm.nih.gov/41186848/
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1868266130311741442
author Mohammadi, Amirreza
Jafarian, Vahab
Khalifeh, Khosrow
Shirdel, Akram
Khatami, Fatemeh
author_facet Mohammadi, Amirreza
Jafarian, Vahab
Khalifeh, Khosrow
Shirdel, Akram
Khatami, Fatemeh
Mohammadi, Amirreza
Jafarian, Vahab
Khalifeh, Khosrow
Shirdel, Akram
Khatami, Fatemeh
collection PubMed - marine biology
contents The Charge-driven Engineering of Mnemiopsin 2: Impact of Serine 35 Mutation on Activity and Stability. Mohammadi, Amirreza Jafarian, Vahab Khalifeh, Khosrow Shirdel, Akram Khatami, Fatemeh Bioluminescence in marine organisms, driven by photoproteins like mnemiopsin 2 from Mnemiopsis leidyi, relies on calcium-regulated light emission. This study investigates the functional and structural effects of site-directed mutagenesis at serine 35 in mnemiopsin 2, replacing it with lysine or glutamic acid to explore charge and polarity impacts on the structure and function of the photoprotein. Homology modeling and molecular docking were used and confirm that the S35K mutation enhances coelenterazine binding. In contrast, the S35E mutant displays weaker interactions with coelenterazine. The S35K mutation significantly increased the initial bioluminescent intensity to 208% of the wild-type. Strikingly, both mutations dramatically slowed the photoprotein’s decay rate, prolonging luminescence from 1.4 s in the wild-type to 5.2 s, indicating highly stabilized intermediate states compared with the WT. Additionally, S35E shifted the optimal pH of bioluminescent activity from 9 to 8.75. Thermal denaturation analyses showed higher values of the enthalpy change for the thermal unfolding reaction of the mutant, demonstrating more cooperativity in the stabilizing interactions at moderate temperatures. The observed cooperativity was confirmed by the fluorescence spectroscopy, revealing a more compact tertiary structure in the S35K mutant. These findings emphasize the critical role of charge-mediated structural dynamics and binding properties in modulating photoprotein properties, such as advanced imaging and biotechnological applications.
format Artículo científico
id pubmed_41186848
institution PubMed
language en
publishDate 2025
publisher Photochemical & photobiological sciences : Official journal of the European Photochemistry Association and the European Society for Photobiology
record_format pubmed
spellingShingle The Charge-driven Engineering of Mnemiopsin 2: Impact of Serine 35 Mutation on Activity and Stability.
Mohammadi, Amirreza
Jafarian, Vahab
Khalifeh, Khosrow
Shirdel, Akram
Khatami, Fatemeh
The Charge-driven Engineering of Mnemiopsin 2: Impact of Serine 35 Mutation on Activity and Stability. Mohammadi, Amirreza Jafarian, Vahab Khalifeh, Khosrow Shirdel, Akram Khatami, Fatemeh Bioluminescence in marine organisms, driven by photoproteins like mnemiopsin 2 from Mnemiopsis leidyi, relies on calcium-regulated light emission. This study investigates the functional and structural effects of site-directed mutagenesis at serine 35 in mnemiopsin 2, replacing it with lysine or glutamic acid to explore charge and polarity impacts on the structure and function of the photoprotein. Homology modeling and molecular docking were used and confirm that the S35K mutation enhances coelenterazine binding. In contrast, the S35E mutant displays weaker interactions with coelenterazine. The S35K mutation significantly increased the initial bioluminescent intensity to 208% of the wild-type. Strikingly, both mutations dramatically slowed the photoprotein’s decay rate, prolonging luminescence from 1.4 s in the wild-type to 5.2 s, indicating highly stabilized intermediate states compared with the WT. Additionally, S35E shifted the optimal pH of bioluminescent activity from 9 to 8.75. Thermal denaturation analyses showed higher values of the enthalpy change for the thermal unfolding reaction of the mutant, demonstrating more cooperativity in the stabilizing interactions at moderate temperatures. The observed cooperativity was confirmed by the fluorescence spectroscopy, revealing a more compact tertiary structure in the S35K mutant. These findings emphasize the critical role of charge-mediated structural dynamics and binding properties in modulating photoprotein properties, such as advanced imaging and biotechnological applications.
title The Charge-driven Engineering of Mnemiopsin 2: Impact of Serine 35 Mutation on Activity and Stability.
url https://pubmed.ncbi.nlm.nih.gov/41186848/