In both prokaryotes and eukaryotes, nonsense mutations in a gene can enhance the decay rate or reduce the abundance of the mRNA transcribed from that gene, and we call this process nonsense-mediated mRNA decay. We have been investigating the cis-acting sequences involved in this decay pathway. Previous experiments have demonstrated that, in addition to a nonsense codon, specific sequences 3 of a nonsense mutation, which have been defined as downstream elements, are required for mRNA destabilization. The results presented here identify a sequence motif (TGYYGATGYYYYY, where Y stands for either T or C) that can predict regions in genes that, when positioned 3 of a nonsense codon, promote rapid decay of its mRNA. Sequences harboring two copies of the motif from five regions in the PGK1, ADE3, and HIS4 genes were able to function as downstream elements. In addition, four copies of this motif can function as an independent downstream element. The sequences flanking the motif played a more significant role in modulating its activity when fewer copies of the sequence motif were present. Our results indicate the sequences 5 of the motif can modulate its activity by maintaining a certain distance between the sequence motif and the termination codon. We also suggest that the sequences 3 of the motif modulate the activity of the downstream element by forming RNA secondary structures. Consistent with this view, a stem-loop structure positioned 3 of the sequence motif can enhance the activity of the downstream element. This sequence motif is one of the few elements that have been identified that can predict regions in genes that can be involved in mRNA turnover. The role of these sequences in mRNA decay is discussed.The rates at which mRNAs decay play an important role in regulating gene expression. mRNA half-lives can vary from each other by as much as 100-fold (28,55,59,62,64), and this variation determines, in part, the cytoplasmic abundance of these RNAs. In addition, the decay rate of an mRNA can be modulated, and its half-life can vary depending on the cell type or the environmental situation of the cell (e.g., hormones, stress, cell cycle, etc. [3,55,62]). The goal of our work is to understand the cellular mechanisms that determine the stability of mRNAs.We are studying mRNA decay in the yeast Saccharomyces cerevisiae. Our results, as well as work from other laboratories, strongly indicate that the processes of mRNA turnover and translation are intimately linked and that understanding of this relationship is critical in elucidating the mechanism of mRNA decay (2, 5, 9, 11, 15, 21, 23, 29-31, 41, 53, 55-59, 76). The role of translation in determination of mRNA decay rates is direct, and, for certain instability elements identified in protein coding regions and 3Ј untranslated regions (3Ј-UTRs), translation of the protein coding region must occur in order for them to function (2,11,15,21,23,29,41,53,60,66,76).One clear example of the relationship between translation and mRNA decay is the observation that nonsense mutati...