Transfer RNA (tRNA) has been demonstrated to be present in axons of both invertebrates and the higher vertebrates, but nothing is known of its role in the metabolism of the axon. The present experiments were performed to determine whether tRNA functions in axons as a participant in post-translational protein modification of endogenous proteins. RNA was extracted from the axoplasm of squid giant axons and incubated with a variety of 3H-amino acids, aminoacyl-tRNA synthetases (obtained from squid optic lobe), and an appropriate reaction mixture. All of the amino acids tested were bound to an RNA fraction, but this reaction did not occur when samples were incubated in the presence of ribonuclease or in the absence of axoplasmic RNA. When radioactive RNA was chromatographed by polyacrylamide gel electrophoresis, the radioactivity comigrated with known tRNA markers, suggesting the presence of 3H-aminoacylated tRNA. Aminoacylation of RNA could also be demonstrated by incubating fresh axoplasm with labeled amino acids and a reaction mixture, minus exogenous aminoacyl-tRNA synthetases. These findings indicate the presence in axoplasm of a variety of species of aminoacyl-tRNAs as well as their corresponding synthetase enzymes. In the latter experiment no radioactivity was found associated with the protein fraction. This was also the finding when 3H-aminoacylated tRNA was either injected directly into the axon or incubated with extruded axoplasm. Thus, under the conditions described above, there is no evidence of transfer of amino acids from tRNA to proteins. In other experiments, axoplasm was pooled to a volume of 50 to 100 microliters, homogenized gently, and centrifuged at 150,000 X g for 1 hr. Some of the high speed supernatant was incubated with labeled amino acids and an appropriate reaction mixture, and the remainder was passed through an S-200 Sephacryl column before incubation with the same reaction mixture. There was no incorporation of amino acids into protein in the high speed supernatant fraction. However, in the S-200 purified fraction 3H-labeled Arg, Lys, Tyr, Leu, and Asp were all incorporated into proteins in amounts of 44, 30, 7, 5 and 3.5 times heat-inactivated controls. The reaction is not inhibited by Ca2+ or Ca2+-activated proteases, but appears to be dependent on the presence of tRNA. The addition of amino acids to protein is not protein synthesis since the reactions occurred in a partially purified fraction of the 150,000 X g supernatant, a fraction devoid of ribosomes and free amino acids.(ABSTRACT TRUNCATED AT 400 WORDS)
Experiments were performed to determine whether posttranslational addition of amino acids to axonal proteins occurs in axons of the rat sciatic nerve. Two ligatures were placed 1 cm apart on sciatic nerves. Six days later, segments proximal to each ligature were removed, homogenized, centrifuged at 150,000 X g, and analyzed for the ability to incorporate 3H-amino acids into proteins. No incorporation of amino acids into proteins was found in the high-speed supernatant, but when the supernatant was passed through a Sephacryl S-200 chromatography column (removing molecules less than 20 kD), [3H]arginine, lysine, leucine and aspartic acid were incorporated into proteins in both proximal and distal nerve segments. Small but consistently greater amounts of radioactivity were incorporated into proteins in proximal segments compared with distal segments, indicating that the components necessary for the reaction are transported axonally. This reaction represents the posttranslational incorporation of a variety of amino acids into proteins of rat sciatic nerve axons. Other experiments showed that the incorporation of amino acids into proteins is by covalent bonding, that the amino acid donor is likely to be tRNA, and that the reaction is inhibited in vivo by a substance whose molecular mass is less than 20 kD. This inhibition is not affected by incubation with physiological concentrations of unlabeled amino acids, by boiling, or by treatment with Proteinase K. When the axonally transported component of the reaction was determined in regenerating nerves, the amount of incorporation of amino acids into protein was 15-150 times that in intact nerves.(ABSTRACT TRUNCATED AT 250 WORDS)
Previous experiments have demonstrated that 4S RNA, (tRNA), is transported axonally during the reconnection and maturation of regenerating optic nerves of goldfish. The present experiments were performed to determine if tRNA is transported axonally during elongation of these regenerating nerves and whether, as has been demonstrated in other systems, it participates in posttranslational protein modification (PTPM). [3H]Uridine was injected into both eyes of fish with intact optic nerves and 0, 2, 4, or 8 days after bilateral optic nerve cut. Fish were killed 2 days after injection, and [3H]RNA was isolated from retinae and nerves by phenol extraction and ethanol precipitation. [3H]RNA was fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Although the percentage of [3H]4S RNA remained constant in all retinal and control nerve samples, regenerating nerves showed a twofold increase by 6 days after injury, suggesting that [3H]4S RNA is transported axonally in regenerating nerves as early as 6 days after injury. In other experiments, the 150,000-g supernatant of optic nerves was analyzed for incorporation of 3H-amino acids into proteins. No incorporation of 3H-amino acid was found in the soluble supernatant, but when the supernatant was passed through a Sephacryl S-200 column (removing molecules less than 20,000 daltons), [3H]Arg, [3H]Lys, and [3H]Leu were incorporated into proteins. This posttranslational addition of amino acids was greater (1.4-5 times for Lys and 2-13 times for Leu) in regenerating optic nerves than nonregenerating nerves, and the growing tips of regenerating nerves incorporated 5-15 times more [3H]Lys and [3H]Leu into proteins than did the shafts.(ABSTRACT TRUNCATED AT 250 WORDS)
A 150,000-g supernatant from axoplasm of the giant axon of the stellate nerve of the squid and from rat sciatic and goldfish optic nerves was found to be able to incorporate covalently [3H]putrescine and [3H]spermidine into an exogenous protein (N,N'-dimethylcasein). Incorporation of radioactivity was inhibited by CuSO4, a specific inhibitor of transglutaminases, the enzymes mediating these reactions in other tissues. Analysis of pH and temperature range and enzyme kinetics displayed characteristics predicted for transglutaminase-mediated reactions. Transglutaminase activity increased during regeneration of both vertebrate nerves, but greater activity was found in segments of nerve containing no intact axons than in either intact segments or in segments containing regenerating axons. Polyacrylamide gel electrophoresis of endogenous modified proteins (in the absence of N,N'-dimethylcasein) showed labeling of 18-, 46- and 200-kilodalton proteins by both [3H]putrescine and [3H]spermidine. Analysis of the protein-bound radioactivity from intact and regenerating rat sciatic nerves demonstrated it to be predominantly in the form of the parent radioactive polyamine. These experiments demonstrate the covalent modification of proteins by polyamines at low levels in squid axoplasm and at relatively higher levels in rat sciatic and goldfish optic nerves. In the latter two cases, the activity of these modification reactions may be due in part to the modification of axonal proteins, but the majority of the activity occurs in nonneuronal cells of the nerve.
This study reports that 4S RNA present in regenerating optic axons of goldfish is likely to be transfer RNA. Evidence is also presented which indicates that this transfer RNA is similar to transfer RNA found in tectal cells and that its aminocylation is likely to occur both in retinal ganglion cells prior to axonal transport as well as in the axon itself. Fish with regenerating optic nerves received intraocular injections of [3H]uridine followed 4 days later by intracranial injections of [14C]uridine. Radioactive tectal 4S RNA was isolated 6 days after [3H]uridine injections and chromatographed by BD cellulose chromatography. Optical density as well as radioactivity profiles for both [14C]4S RNA (from tectal cells) and [3H]4S RNA (90% of which originated from regenerating optic axons) were found to be similar to E. coli transfer RNA optical density profiles, indicating that the intra-axonal 4S RNA is likely to be transfer RNA. Moreover, comparisons of 3H/14C suggest that intra-axonal and cellular 4S RNAs are composed of similar species of transfer RNA. Results of other experiments indicate that aminoacylation of axonally transported tRNA occurs both in the retina and in optic axons subsequent to axonal transport.
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