Molecular genetic and biochemical evidence for the involvement of the heptapeptide cleavage sequence in determining the reaction profile at two tobacco etch virus cleavage sites in cell-free assays.

Potyviruses express their genetic information from a genome length RNA as a single polyprotein, which is post-translationally processed by at least two different viral-encoded proteolytic activities. Since regulation of the expression of individual genes is not likely to occur at the transcriptional level, we sought to determine if post-translational regulation of gene expression was possible via differential proteolytic processing. Modulating the rate of cleavage at different gene product junctions could be a potential mechanism to regulate the kinetics of formation of specific gene products. We have examined the proteolytic processing of two tobacco etch virus (TEV) cleavage sites using a cell-free system in which synthetic polyprotein precursors were processed by the TEV 49-kDa proteinase. The amino acid sequences at these two sites contained both conserved and variable positions. The cleavage reaction at the TEV 50/71-kDa junction was characterized as "slow" (T1/2 = approximately 27 min) while the cleavage reaction at the 58/30-kDa junction was judged "fast" (T1/2 = approximately 5 min). Similar cleavage reactions were observed whether the cleavage site was in its natural polyprotein context or placed in a foreign position. The slow and fast cleavage sites could be interconverted by changing the nonconserved amino acid positions. The data suggest that the heptapeptide sequence proximal to a TEV cleavage site determines not only cleavage at a particular junction but influences the cleavage reaction profile in cell-free studies.