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. 1990 Feb;172(2):595–602. doi: 10.1128/jb.172.2.595-602.1990

A simple and sensitive in vivo luciferase assay for tRNA-mediated nonsense suppression.

D W Schultz 1, M Yarus 1
PMCID: PMC208482  PMID: 2105299

Abstract

We present a rapid assay for tRNA suppression in living Escherichia coli. An amber, ochre, or opal nonsense mutation in a cloned luxB gene from the bacterium Vibrio harveyi was suppressed. Because luciferase (Lux) activity depends completely on the appearance of the full-length luxB gene product, the amount of light produced was proportional to tRNA-mediated nonsense suppression in the cell. This luminometric assay was notably quicker, easier, and more sensitive than a traditional colorimetric assay employing beta-galactosidase. Assays required only one addition to a growing culture and were complete within 1 min. Light output was directly proportional to the amount of bacterial luciferase in a sample over a range of greater than or equal to 40,000-fold. Fewer than 100 cells were required for detection of Lux with ordinary instrumentation; assays were 80-fold more sensitive than simultaneous beta-galactosidase measurements. Assayed cells survived and could be recovered as colony formers. The beta-galactosidase colorimetric assay and the luciferase assay were similarly reproducible. Light from colonies expressing Lux was visible to the dark-adapted eye and useful for screening. A rapid assay that does not depend on the formation of permanent transformants can be based on electroporation followed by luminometry.

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Selected References

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