The poly(A) signal, without the assistance of any downstream element, directs RNA polymerase II to pause in vivo and then to release stochastically from the template.

Genes encoding polyadenylated mRNAs depend on their poly(A) signals for termination of transcription. Typically, transcription downstream of the poly(A) signal gradually declines to zero, but often there is a transient increase in polymerase density immediately preceding the decline. Special elements called pause sites are traditionally invoked to account for this increase. Using run-on transcription from the nuclei of transfected cells, we show that both the pause and the gradual decline that follow a poly(A) site are generated entirely by the poly(A) signal itself in a series of model constructs. We found no other elements to be involved and argue that the elements called pause sites do not function through pausing. Both the poly(A)-dependent pause and the subsequent decline occurred earlier for a stronger poly(A) signal than for a weaker one. Because the gradual decline resembles the abortive elongation that occurs downstream of many promoters, one model has proposed that the poly(A) signal flips the polymerase from the elongation mode to the abortive mode like a binary switch. We compared abortive elongators with poly(A) terminators and found a 4-fold difference in processivity. We conclude that poly(A) terminating polymerases do not merely revert to their prior state of low processivity but rather convert to a new termination-prone condition.