Zahra Fanaei Kahrani scite author profile

Zahra Fanaei Kahrani

2Publications

23Citation Statements Received

71Citation Statements Given

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Affiliations

University of Isfahan

Publications

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Super RLuc8: A novel engineered Renilla luciferase with a red-shifted spectrum and stable light emission

Rahnama

Saffar

Kahrani

et al. 2017

Enzyme and Microbial Technology

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Renilla luciferase is a bioluminescent enzyme which is broadly used as a reporter protein in molecular biosensors. In this study, a novel luciferase with desired light emission wavelength and thermostability is reported. The results indicated that the new luciferase, namely super RLuc8, had a red-shifted spectrum and showed stable light emission. Super RLuc8 showed a 10-fold (p-value=0.0084) increase in the thermostability at 37°C after 20min incubation, in comparison to the native enzyme. The optimum temperature of the mutant increased from 30 to 37°C. Molecular dynamics simulation analysis indicated that the increased thermostability was most probably caused by a better structural compactness and more local rigidity in the regions out of the emitter site.

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Molecular basis of thermostability enhancement of Renilla luciferase at higher temperatures by insertion of a disulfide bridge into the structure

Kahrani

Emamzadeh

Nazari

et al. 2017

Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics

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Renilla luciferase (RLuc), also known as Renilla-luciferin 2-monooxygenase, is a light producing enzyme used in many biotechnological applications such as bioreporters. However, its kinetics stability -especially at higher temperatures- is a limiting factor for developing thermostable bioreporters. The aim of this study was to improve the stability of super Renilla luciferase 8 (SRLuc 8) which is a red-emitter variety of RLuc at higher temperatures, by introduction of a disulfide bridge into its structure. In this study, the choice of the proper disulfide bond formation was based on computational methods and enzyme functionality (active site position) which is called geometric-functional method. N45 and A71 at the N-terminal of the enzyme were selected for directed evolution. The engineered luciferase was called C-SRLuc 8 and its activity and stability were assayed. The results indicated that the kinetic stability of C-SRLuc 8 increased significantly at 60°C to 70°C as compared to SRLuc 8; the residual activity of C-SRLuc 8 was approximately 20% after incubation at 65°C for 5min. Moreover, the enzyme activity decreased compared with SRLuc 8. The molecular basis of the structural changes was considered using molecular dynamics simulations and the results indicated that the N45C/A71C crosslink was involved in a hotspot foldon which seemed to be the rate-limiting step of conformational collapse at higher temperatures. The present study may provide an opportunity for the development of the next-generation of thermostable RLuc-based biosensors.

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