Encephalomyocarditis virus 3C protease: efficient cell-free expression from clones which link viral 5' noncoding sequences to the P3 region.

Abstract

All picornaviral peptides are derived by progressive posttranslational cleavage of a giant precursor polyprotein. Translation of encephalomyocarditis virus (EMC) RNA in rabbit reticulocyte extracts produces active viral peptides, including protease 3C, which is responsible for many cleavage reactions within the processing cascade. DNA plasmids containing 5' noncoding sequences of EMC linked to other portions of the viral genome were constructed and transcribed into RNA. Like virion RNA, the clone-derived transcripts directed efficient protein translation in vitro. The 5'-linked constructions may represent examples of a general method for cell-free expression of any cloned gene segment. One construction produced a self-cleaving P3 region precursor, which contained active 3C protease. A genetically engineered insertion within the 3C sequences eliminated endogenous self-cleavage activity without altering the ability of the P3 peptide to serve as substrate in bimolecular reactions with added 3C. Another plasmid encoding the L-VP0 portion of the capsid region was used to demonstrate that scission between the leader peptide (L) and capsid protein VP0 can be catalyzed by 3C. The enzyme responsible for this step was previously unidentified. A rapid purification scheme for isolation of 3C from EMC-infected HeLa cells is also presented.