Accelerated poly(A) loss and mRNA stabilization are independent effects of protein synthesis inhibition on alpha-tubulin mRNA in Chlamydomonas.

In Chlamydomonas, the usual rapid degradation of tubulin mRNAs induced by flagellar amputation is prevented by inhibition of protein synthesis with cycloheximide. Evidence is presented that the ability of cycloheximide to stabilize alpha-tubulin mRNA depends on the time of addition. Addition of cycloheximide to cells before induction strongly stabilizes the induced mRNAs, while addition after their synthesis stabilizes them only transiently. Moreover, cycloheximide inhibition does not stabilize the same alpha-tubulin mRNA species in uninduced cells. These results suggest that cycloheximide is not acting to stabilize the induced alpha-tubulin mRNAs simply by preventing ribosome translocation. The stabilized state of tubulin mRNA was found to correlate with its occurrence on smaller polysomes but larger EDTA-released mRNP particles than the unstable state. A second effect of cycloheximide on the metabolism of induced tubulin mRNAs is to accelerate complete poly(A) removal. This effect of cycloheximide inhibition, unlike stabilization, occurs whenever cycloheximide is added to cells, and appears unrelated to stabilization. The effect is shown to be mRNA-specific; poly(A)-shortening on the rbcS2 mRNA is not altered in the presence of cycloheximide, nor do completely deadenylated molecules accumulate. Experiments in which cells were released from cycloheximide inhibition suggest that deadenylated alpha-tubulin mRNAs may be less stable than their polyadenylated counterparts during active translation.