N-Terminal arginylation of proteins in explants of injured sciatic nerves and embryonic brains of rats

Posttranslational modification of proteins by arginine and lysine has been demonstrated in crude extracts of vertebrate nerves and brain but not in intact cells. In the present experiments we have exploited the fact that Arg is added posttranslationally only at the N-terminus of target proteins, to demonstrate these reactions in intact cells of sciatic nerves and embryonic brains of rats. Sciatic nerves were crushed in anaesthesized rats and 2 hrs later segments of nerve, including the site of the crush, were removed and incubated in media containing ³H]Arg. Incorporation of ³H]Arg into total proteins was analyzed by acid precipitation and the presence of label at the N-terminus was determined by a modification of the Edman degradation procedure. Approximately 25% of protein bound ³H]Arg was released from the N-terminus by the Edman reaction indicating that it was added posttranslationally rather than through protein synthesis. N-terminal labeling was not detectable in nerves not crushed prior to explant and incubation. Slices of embryonic day 20 visual cortex, when incubated under similar conditions as injured sciatic nerves, also showed approximately 25% of the protein incorporated ³H]Arg at the N-terminus, while arginylation was not detectable in adult rat brain slices. Since Lys is not added posttranslationally to the N-terminus, we have attempted to observe lysylation of proteins in intact cells by using cycloheximide (Cx) to block protein synthesis without interfering with protein modification. The posttranslational incorporation of Arg/Lys into proteins was found to be insensitive to up to 2.0 mM Cx in tissue extracts (in vitro). However, in intact cells, doses as low as 10 uM Cx completely inhibited the incorporation of ³H]Arg/Lys into proteins. One uM Cx allowed for some incorporation of ³H]Arg/Lys into protein and approximately 40% of the Cx insensitive Arg was incorporated into the N-terminal. These results show that in vivo but not in vitro, Cx can block protein modification, suggesting that either in intact cells protein modification requires protein synthesis, or that Cx has effects other than as an inhibitor of protein synthesis on cells in culture, effects that it does not have on the partially purified components of the reaction.