Sigma cycle during in vitro transcription: demonstration by nanosecond fluorescence depolarization spectroscopy.

Abstract

Studies of RNA chain initiation have suggested that the sigma subunit of Escherichia coli RNA polymerase (RNA nucleotidyltransferase; nucleosidetriphosphate: RNA nucleotidyltransferase; EC 2.7.7.6) is released from the enzyme-template complex during transcription and may be reused by another core polymerase. Nanosecond fluorescence depolarization spectroscopy was used to follow the sigma cycle. Isolated sigma subunit labeled with the fluorescent probe dansyl (DNS) chloride bound stoichiometrically to core polymerase and stimulated transcription of phage T7 DNA to the same extent as did unlabeled sigma. DNS-sigma showed an exponential fluorescence anisotropy decay corresponding to a rotational correlation time of about 100 nsec. This value was unaffected by addition of T7 DNA, but increased about 6-fold when core polymerase was added, and increased further when T7 DNA was added. Such increases are expected for the formation of molecular complexes. Using the anisotropy decays for free DNS-sigma and DNS-sigma-core enzyme bound to T7 DNA, we calculated theoretical decay curves for various mixtures of free and bound sigma. Comparison of the observed anisotropy decay with the calculated curves indicated that about 55% of DNA-sigma was released from the enzyme-T7 DNA complex in the presence of four nucleoside triphosphates under low salt conditions. Sigma release did not occur if rifampicin was added prior to addition of four nucleoside triphosphates or if only three nucleoside triphosphates were present. After sigma was released, addition of core polymerase with rifampicin reduced the free sigma to less than 15%, indicating that the released sigma was accessible to the added core enzyme. Thus these studies have provided physical evidence for the sigma cycle during in vitro transcription.