Metalloprotein design using genetic code expansion

Cheng Hu; Sunney I. Chan; Elizabeth B. Sawyer; Yang Yu; Jiangyun Wang

doi:10.1039/c4cs00018h

Metalloprotein design using genetic code expansion

Cheng Hu, Sunney I. Chan, Elizabeth B. Sawyer, Yang Yu, Jiangyun Wang^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

71 Citations (Scopus)

Abstract

More than one third of all proteins are metalloproteins. They catalyze important reactions such as photosynthesis, nitrogen fixation and CO₂ reduction. Metalloproteins such as the olfactory receptors also serve as highly elaborate sensors. Here we review recent developments in functional metalloprotein design using the genetic code expansion approach. We show that, through the site-specific incorporation of metal-chelating unnatural amino acids (UAAs), proton and electron transfer mediators, and UAAs bearing bioorthogonal reaction groups, small soluble proteins can recapitulate and expand the important functions of complex metalloproteins. Further developments along this route may result in cell factories and live-cell sensors with unprecedented efficiency and selectivity.

Original language	English
Pages (from-to)	6498-6510
Number of pages	13
Journal	Chemical Society Reviews
Volume	43
Issue number	18
DOIs	https://doi.org/10.1039/c4cs00018h
Publication status	Published - 21 Sept 2014
Externally published	Yes

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title = "Metalloprotein design using genetic code expansion",

abstract = "More than one third of all proteins are metalloproteins. They catalyze important reactions such as photosynthesis, nitrogen fixation and CO2 reduction. Metalloproteins such as the olfactory receptors also serve as highly elaborate sensors. Here we review recent developments in functional metalloprotein design using the genetic code expansion approach. We show that, through the site-specific incorporation of metal-chelating unnatural amino acids (UAAs), proton and electron transfer mediators, and UAAs bearing bioorthogonal reaction groups, small soluble proteins can recapitulate and expand the important functions of complex metalloproteins. Further developments along this route may result in cell factories and live-cell sensors with unprecedented efficiency and selectivity.",

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AU - Hu, Cheng

AU - Chan, Sunney I.

AU - Sawyer, Elizabeth B.

AU - Yu, Yang

AU - Wang, Jiangyun

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Y1 - 2014/9/21

N2 - More than one third of all proteins are metalloproteins. They catalyze important reactions such as photosynthesis, nitrogen fixation and CO2 reduction. Metalloproteins such as the olfactory receptors also serve as highly elaborate sensors. Here we review recent developments in functional metalloprotein design using the genetic code expansion approach. We show that, through the site-specific incorporation of metal-chelating unnatural amino acids (UAAs), proton and electron transfer mediators, and UAAs bearing bioorthogonal reaction groups, small soluble proteins can recapitulate and expand the important functions of complex metalloproteins. Further developments along this route may result in cell factories and live-cell sensors with unprecedented efficiency and selectivity.

AB - More than one third of all proteins are metalloproteins. They catalyze important reactions such as photosynthesis, nitrogen fixation and CO2 reduction. Metalloproteins such as the olfactory receptors also serve as highly elaborate sensors. Here we review recent developments in functional metalloprotein design using the genetic code expansion approach. We show that, through the site-specific incorporation of metal-chelating unnatural amino acids (UAAs), proton and electron transfer mediators, and UAAs bearing bioorthogonal reaction groups, small soluble proteins can recapitulate and expand the important functions of complex metalloproteins. Further developments along this route may result in cell factories and live-cell sensors with unprecedented efficiency and selectivity.

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JO - Chemical Society Reviews

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Metalloprotein design using genetic code expansion

Abstract

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