ABSTRACT
Transcription termination is one of the least understood processes of gene expression. As the prototype model for transcription studies, the single-subunit T7 RNA polymerase (RNAP) was known to response to two types of termination signals, while the mechanism underlying such termination especially the specific elements of the polymerase involved in is still unclear, due to the lack of a termination complex structure. Here we applied phage-assisted continuous evolution to obtain variants of T7 RNAP that can bypass the typical class I T7 terminator with stem-loop structure. Through in vivo selection and in vitro characterization, we discovered a single mutation S43Y that significantly decreased the termination efficiency of T7 RNAP at all transcription terminators tested. Coincidently, the S43Y mutation almost eliminates the RNA-dependent RNA polymerase (RdRp) of T7 RNAP without affecting the major DNA-dependent RNA polymerase (DdRp) activity of the enzyme, indicating the relationship between transcription termination and RdRp activity, and suggesting a model in which the stem-loop terminator induces the RdRp activity which competes with the ongoing DdRp activity to cause transcription termination. The T7 RNAP S43Y mutant as an enzymatic reagent for in vitro transcription reduces the undesired termination in run-off RNA synthesis and produces RNA with higher terminal homogeneity.