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Proteins that Efficiently Generate Singlet Oxygen Background
University of California System: University of California, San Diego Technology Transfer Office
posted on 03/04/2010
Singlet oxygen generation is a well-known technique in proteomic studies that involve localization of proteins by electron microscopy, inactivation of proteins for functional studies, and measurement of the distances between interacting proteins.
One of the most widely used reagent systems is the biarsenical ReAsh-Tetracysteine system from Life Technologies. While partially genetically encoded, it requires the cells to be stimulated to overexpress a needed cofactor and generate singlet oxygen with a quantum yield of less than 0.05. Attempts to develop other systems have not resulted in higher quantum yields and, in some cases while resulting in fluorescence, have not been shown to produce singlet oxygen.Advantages
- Significantly higher quantum yields than current system.
- No exogenous co-factors needed.
- Provides a new level of detection and utility for proteomic studies utilizing:
- Electron microscopy and fluorescent imaging.
- Chromophore assisted light inactivation for functional proteomics.
- Greater monitoring of protein-protein distances than FRET based sensors that is independent of chromophore orientation.
Detailed Description
UC San Diego researchers have developed a fully genetically encoded singlet oxygen system called mini-SOG. The system uses truncated proteins that can be fused to a protein of interest and expressed in either bacterial or mammalian cells. Although requiring flavin mononucleotide (FMN) as a co-factor, it is endogenously available to cells, and because it is a derivative of riboflavin, no exogenous addition is necessary. The FMN holoprotein will fluoresce upon light excitation and generates singlet oxygen with quantum yields in excess of 0.4.
File Number: 20715
Other Information:
Intellectual Property Info
A provisional patent application has been filed.
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