The in vitro initiation properties of the PR promoter of bacteriophage lambda and of a PR mutant, x3, were compared. Using the abortive initiation reaction, we measured the lags in the approach to a final steady-state rate when dinucleotide synthesis was initiated with RNA polymerase. These lags corresponded to the average times required for the formation of transcriptionally active open complexes. By measuring the lags at different RNA polymerase concentrations, we could separate open complex formation into two steps, based on a simple model in which the initial bimolecular association of free promoter and polymerase in a closed complex is followed by an isomerization to the open complex. The contribution of each step to the overall rate of open complex formation was quantitated for both promoters. We found that the x3 mutation, which is located in the -35 region of PR, resulted in a decrease in the association constant for the initial binding to the closed complex to 5% of its wild-type value and a decrease in the rate of the isomerization to 20%. The lifetimes and abortive initiation characteristics of the mutant and wild-type promoters were similar. We concluded that the main effect of the x3 mutation was to increase the average time of open complex formation and that the functional properties of the open complexes did not differ significantly between the two promoters.