Barton Y. Linderman scite author profile

Barton Y. Linderman

2Publications

54Citation Statements Received

113Citation Statements Given

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109

Affiliations

Franklin & Marshall College

Publications

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Probing Local Environments with the Infrared Probe: l-4-Nitrophenylalanine

et al. 2011

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The genetic incorporation of unnatural amino acids (UAAs) with high efficiency and fidelity is a powerful tool for the study of protein structure and dynamics with site-specificity in a relatively nonintrusive manner. Here, we illustrate the ability of L-4-nitrophenylalanine to serve as a sensitive IR probe of local protein environments in the 247 residue superfolder green fluorescent protein (sfGFP). Specifically, the nitro symmetric stretching frequency of L-4-nitrophenylalanine was shown to be sensitive to both solvents that mimic different protein environments and (15)N isotopic labeling of the three-atom nitro group of this UAA. (14)NO(2) and (15)NO(2) variants of this UAA were incorporated utilizing an engineered orthogonal aminoacyl-tRNA synthetase/tRNA pair into a solvent exposed and a partially buried position in sfGFP with high efficiency and fidelity. The combination of isotopic labeling and difference FTIR spectroscopy permitted the nitro symmetric stretching frequency of L-4-nitrophenylalanine to be experimentally measured at either site in sfGFP. The (14)NO(2) symmetric stretching frequency red-shifted 7.7 cm(-1) between the solvent exposed and partially buried position, thus illustrating the ability of this UAA to serve as an effective IR probe of local protein environments.

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Probing Local Protein Environments with the Infrared Probe: L-4-Nitrophenylalanine

Smith¹,

Linderman²,

Luskin³

et al. 2011

Biophysical Journal

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CALI and the labelling specificity that fluorescent proteins provide is very useful to avoid uncontrolled photodamage. Indeed, fluorescent proteins have been successfully used in CALI, although of the inactivation mechanisms by ROS are dependent on the fluorescent protein used and are not fully understood [2,3]. Here, we present a quantitative study of the ability of TagRFP to produce ROS, in particular singlet oxygen. TagRFP is able to photosensitize singlet oxygen with an estimated quantum yield of 0.004 [4]. This is the first estimation of a quantum yield of singlet oxygen production value for a GFP-like protein. We also find that TagRFP has a short triplet lifetime, which reflects relatively high oxygen accessibility to the chromophore compared to EGFP. Our results provide photophysical insight that allows the understanding of the mechanism behind CALI. Moreover, it has implications in improving photobleaching in fluorescent proteins.[1] K.

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