N-acetylphenylalanyl-tRNA hydrolase from yeast. Purification and properties.

This paper describes the purification and properties of an enzyme present in yeast which splits N-acetylphenylalanyl-tRNA to N-acetylphenylalanine and tRNA. The enzyme has been 35000 as estimated by filtration on Sephadex G-150, is maximally active in the presence of a divalent cation (Mg2+ , Mn2+ or Ca2+) and has a pH optimum at around neutrality. The enzyme is highly specific in hydrolyzing N-acetylphenylalanyl-tRNA (Km = 0.4 micron). Phenylalanyl-tRNA is hydrolyzed with a similar apparent affinity but with an efficiency of 40% of that found for N-acetylphenylalanyl-tRNA. Other free or N-substituted aminoacyl-tRNAs are not substrates of this hydrolase. Neither of the two reaction products are effective inhibitors of this enzyme. Based on its substrate specificity, the trivial name of N-acetylphenylalanyl-tRNA hydrolase is proposed for this enzyme.     

Characterization of ribonucleoprotein particles released from isolated nuclei of regenerating rat liver in two different in vitro systems.

The ribonucleoprotein particles released from isolated nuclei of regenerating rat liver in two in vitro systems were studied and the following results were obtained. 1. When the isolated nuclei of regenerating rat liver labeled in vivo with [14C] orotic acid were incubated in medium containing ATP and an energy-regenerating system (medium I) release of labeled 40-S particles was observed. Analysis of these 40-S particles showed that they contained heterogeneous RNA but no 18 S or 28 S ribosomal RNAs and their buoyant density in CsCl was 1.42-1.45 g/cm3, suggesting that they were nuclear informosome-like particles released during incubation. 2. When the same nuclei were incubated in the same medium fortified with dialyzed cytosol, spermidine and yeast RNA (medium II), release of labeled 60-S and 40-S particles was observed. Using CsCl buoyant density gradient centrifugation, two components were found in the labeled ribonucleoprotein particles released from nuclei in this medium. The labeled 60-S particles were found to contain 28-S RNA as the main component and their buoyant density in CsCl was 1.61 g/cm3, suggesting that they were labeled large ribosomal subunits. The labeled 40-S particles contained both 18 S RNA and heterogeneous RNA and they formed two discrete bands in CsCl, at 1.40 and 1.56 g/cm3, suggesting that they contained small ribosomal subunits and nuclear informosome-like particles. 3. These results clearly indicate that addition of dialyzed cytosol, spermidine and low molecular yeast RNA to medium I causes the release of ribosomal subunits or their precursors from isolated nuclei in the in vitro system.     

Secondary methylation of yeast ribosomal precursor RNA.

The timing of methylation of the ribosomal sequences of ribosomal precursor RNA (pre-rRNA) from the yeast Saccharomyces carlsbergensis was investigated by fingerprint analysis of the methylated oligonucleotides derived from the various precursors. From the total of 37 ribose and 6 base-methyl groups found in 26-S rRNA, the two copies of the base-methylated nucleoside m3U as well as the doubly methylated sequence Um-Gm psi are not yet present in 37-S RNA, the predominant common precursor of 26-S and 17-S rRNA. Introduction of these methyl groups into the ribosomal sequences appears to take place at the level of 29-S pre-rRNA, the immediate precursor to 26-S rRNA. From the total of 18 ribose-methylated and 6 base-methylated nucleosides found in 17-S rRNA, the latter group (one copy of m7G, the m62A-m62A- sequence and the hypermodified methylated nucleoside "mX") is completely missing in 37-S pre-rRNA. The methyl group of m7G is introduced into 18-S pre-rRNA, the direct precursor of 17-S rRNA, in the nucleus. The -m62A-m62A- sequence is methylated after transport of the 18-S pre-rRNA to the cytoplasm prior to the final maturation into 17-S rRNA.     

Human bleomycin hydrolase binds ribosomal proteins.

Bleomycin hydrolase (BH) is a cysteine proteinase that inactivates the anticancer drug bleomycin. Yeast BH forms a homohexameric structure that resembles a 20S proteasome and binds to single-stranded RNA and DNA. We now demonstrate that human BH (hBH) interacts and colocalizes with ribosomal proteins. Using a yeast two-hybrid system, we found hBH bound to human homologues of rat ribosomal proteins L11 and L29. The N-terminus of hBH (amino acids 14-175), which contains a catalytic Cys93, was critical for the binding to L11 in the two-hybrid environment. hBH precipitated 35S-labeled L11 and L29 in vitro, and hBH colocalized with L11 and L29 as determined by immunofluorescence. In addition to cytosolic bleomycin hydrolase, we found abundant bleomycin hydrolase activity associated with the ribosomal subcellular fraction by differential centrifugation. hBH was also detected by Western immunoblotting in a high-speed particulate fraction, where the majority of L11 and L29 were found. In vitro experiments showed recombinant hBH binds to Chinese hamster ovary cell microsomes. Thus, our data strongly suggest that hBH exists as both a free cytosolic and ribosome-associated protein.     

Independent temporal expression of two N-substituted aminoacyl-tRNA hydrolases during the development of Artemia salina.

Encysted embryos of the crustacean Artemia salina contain an enzymatic activity which hydrolyzes N-acetylphenylalanyl-tRNA to N-acetylphenylalanine and tRNA. The enzyme apparently does not hydrolyze other free or N-substituted aminoacyl-tRNAs. The levels of this enzyme do not significantly change during embryonic and early larval development. In contrast, an unspecific hydrolase active on several N-substituted aminoacyl-tRNAs is practically absent in the encysted embryos and during embryogenesis and appears abruptly during larval development. The independent temporal expression of these two hydrolases during Artemia salina differentiation makes this organism siuitable for the study of the physiological role of these enzymes.     

Quantitative analysis of the protein composition of yeast ribosomes

The molecular weights of the individual yeast ribosomal proteins were determined. The ribosomal proteins from the 40-S subunit have molecular weights ranging from 11 800 to 31 000 (average molecular weight = 21 300). The molecular weights of the 60-S subunit proteins range from 10 000 to 48 400 (average molecular weight = 21 800). Stoichiometric measurements, performed by densitometric scanning on ribosomal proteins extracted from high-salt dissociated subunits revealed that isolated ribosomal subunits contain, besides some protein species occurring in submolar amounts, a number of protein species which are present in multiple copies: S13, S27, L22, L31, L33, L34 and L39. The mass fractions of the ribosomal proteins which were found to be present on isolated ribosomes in non-unimolar amounts, were re-examined by using an isotope dilution technique. Applying this method to proteins extracted from mildely isolated 80-S ribosomes, we found that some protein species such as S32, S34 and L43 still are present in submolar amounts. On the other hand, however, we conclude that some other ribosomal proteins, in particular the strongly acidic proteins L44 and L45 get partially lost during ribosome dissociation. Proteins L44/L45 appears to be present on 80-S ribosomes in three copies.     

The formation of a defective small subunit of the mitochondrial ribosomes in petite mutants of Saccharomyces cerevisiae

The involvement of mitochondrial protein synthesis in the assembly of the mitochondrial ribosomes was investigated by studying the extent to which the assembly process can proceed in petite mutants of Saccharomyces cerevisiae which lack mitochondrial protein synthetic activity due to the deletion of some tRNA genes and/or one of the rRNA genes on the mtDNA. Petite strains which retain the 15-S rRNA gene can synthesize this rRNA species, but do not contain any detectable amounts of the small mitochondrial ribosomal subunit. Instead, a ribonucleoparticle with a sedimentation coefficient of 30 S (instead of 37 S) was observed. This ribonucleoparticle contained all the small ribosomal subunit proteins with the exception of the var1 and three to five other proteins, which indicates that the 30-S ribonucleoparticle is related to the small mitochondrial ribosomal subunit (37 S). Reconstitution experiments using the 30-S particle and the large mitochondrial ribosomal subunit from a wild-type yeast strain indicate that the 30-S particle is not active in translating the artificial message poly(U). The large mitochondrial ribosomal subunit was present in petite strains retaining the 21-S rRNA gene. The petite 54-S subunit is biologically active in the translation of poly(U) when reconstituted with the small subunit (37 S) from a wild-type strain. The above results indicate that mitochondrial protein synthetic activity is essential for the assembly of the mature small ribosomal subunit, but not for the large subunit. Since the var1 protein is the only mitochondrial translation product known to date to be associated with the mitochondrial ribosomes, the results suggest that this protein is essential for the assembly of the mature small subunit.     

Implication of arginyl residues in aminoacyl-tRNA binding to ribosomes

Modification of the 50-S subunits of Escherichia coli ribosomes with the arginine reagent phenylglyoxal produces inactivation of peptidyl transferase and inhibition of the binding of C(U)-A-C-C-A-LeuAc, phenylalanyl-tRNA and N-acetylphenylalanyl-tRNA to the ribosome. Hybridization experiments, using 1.25 M LiCl core particles and the corresponding split proteins from untreated and phenylglyoxal-treated 50-S subunits, indicate that inactivation and inhibition of binding are the effects of modification of a protein fraction, the functionality of the RNA moiety being unaffected by the reagent. The split proteins from phenylglyoxal-modified 50-S subunits are incorporated to 1.25 M LiCl core particles as well as those obtained from unmodified subunits, thus excluding the failure to bind as the cause of inactivation. In agreement with the general role played by the arginyl residues as positive binding sites for anionic ligands, the present results indicate that the arginyl residues of a protein fraction from 50-S subunits might be important in the binding of aminoacyl-tRNA and peptidyl-tRNA to ribosomes.     

Photochemical cross-linking of yeast tRNA(Phe) containing 8-azidoadenosine at positions 73 and 76 to the Escherichia coli ribosome

The 3'-terminal -A-C-C-A sequence of yeast tRNA(Phe) has been modified by replacing either adenosine-73 or adenosine-76 with the photoreactive analogue 8-azidoadenosine (8N3A). The incorporation of 8N3A into tRNA(Phe) was accomplished by ligation of 8-azidoadenosine 3',5'-bisphosphate to the 3' end of tRNA molecules which were shortened by either one or four nucleotides. Replacement of the 3'-terminal A76 with 8N3A completely blocked aminoacylation of the tRNA. In contrast, the replacement of A73 with 8N3A has virtually no effect on the aminoacylation of tRNA(Phe). Neither substitution hindered binding of the modified tRNAs to Escherichia coli ribosomes in the presence of poly(U). Photoreactive tRNA derivatives bound noncovalently to the ribosomal P site were cross-linked to the 50S subunit upon irradiation at 300 nm. Nonaminoacylated tRNA(Phe) containing 8N3A at either position 73 or position 76 cross-linked exclusively to protein L27. When N-acetylphenylalanyl-tRNA(Phe) containing 8N3A at position 73 was bound to the P site and irradiated, 23S rRNA was the main ribosomal component labeled, while smaller amounts of the tRNA were cross-linked to proteins L27 and L2. Differences in the labeling pattern of nonaminoacylated and aminoacylated tRNA(Phe) containing 8N3A in position 73 suggest that the aminoacyl moiety may play an important role in the proper positioning of the 3' end of tRNA in the ribosomal P site. More generally, the results demonstrate the utility of 8N3A-substituted tRNA probes for the specific labeling of ribosomal components at the peptidyltransferase center.     

The course of the assembly of ribosomal subunits in yeast

The course of the assembly of the various ribosomal proteins of yeast into ribosomal particles has been studied by following the incorporation of radioactive individual protein species in cytoplasmic ribosomal particles after pulse-labelling of yeast protoplasts with tritiated amino acids. The pool of ribosomal proteins is small relative to the rate of ribosomal protein synthesis, and, therefore, does not affect essentially the appearance of labelled ribosomal proteins on the ribosomal particles. From the labelling kinetics of individual protein species it can be concluded that a number of ribosomal proteins of the 60 S subunit (L6, L7, L8, L9, L11, L15, L16, L23, L24, L30, L32, L36, L40, L41, L42, L44 and L45) associate with the ribonucleoprotein particles at a relatively late stage of the ribosomal maturation process. The same was found to be true for a number of proteins of the 40 S ribosomal subunit (S10, S27, S31, S32, S33 and S34). Several members (L7, L9, L24 and L30) of the late associating group of 60-S subunit proteins were found to be absent from a nuclear 66 S precursor ribosomal fraction. These results indicate that incorporation of these proteins into the ribosomal particles takes place in the cytoplasm at a late stage of the ribosomal maturation process.     

The organization of ribosomal RNA genes in the mitochondrial DNA of Tetrahymena pyriformis strain ST.

1. We have constructed a physical map of the mtDNA of Tetrahymena pyriformis strain ST using the restriction endonucleases EcoRI, PstI, SacI, HindIII and HhaI. 2. Hybridization of mitochondrial 21 S and 14 S ribosomal RNA to restriction fragments of strain ST mtDNA shows that this DNA contains two 21-S and only one 14-S ribosomal RNA genes. By S1 nuclease treatment of briefly renatured single-stranded DNA the terminal duplication-inversion previously detected in this DNA (Arnberg et al. (1975) Biochim. Biophys. Acta 383, 359--369) has been isolated and shown to contain both 21-S ribosomal RNA genes. 14 S ribosomal RNA hybridizes to a region in the central part of the DNA, about 8000 nucleotides or 20% of the total DNA length apart from the nearest 21 S ribosomal RNA gene. 3. We have confirmed this position of the three ribosomal RNA genes by electron microscopical analysis of DNA . RNA hybrid molecules and R-loop molecules. 4. Hybridization of 21 S ribosomal RNA with duplex mtDNA digested either with phage lambda-induced exonuclease or exonuclease III of Escherichia coli, shows that the 21-S ribosomal RNA genes are located on the 5'-ends of each DNA strand. Electron microscopy of denaturated mtDNA hybridized with a mixture of 14-S and 21-S ribosomal RNAs show that the 14 S ribosomal RNA gene has the same polarity as the nearest 21 S ribosomal RNA gene. 5. Tetrahymena mtDNA is (after Saccharomyces mtDNA) the second mtDNA in which the two ribosomal RNA cistrons are far apart and the first mtDNA in which one of the ribosomal RNA cistrons is duplicated.     

Specific hydrolysis of methionyl-tRNA Met f catalyzed by a purified peptide.

A peptide initiation factor purified from rat liver and promoting the binding of initiator tRNA and model initiators to 40S and 80S ribosome at an acid pH liberates methionine and N-acetylmethionine from Trna Met f at neutral reaction. Phenylalanyl-tRNA, N-acetylphenylalanyl-tRNA and methionyl-tRNA Met m are not hydrolyzed under the same conditions. Hydrolysis of methionyl-tRNA Met f is stimulated by the presence of the 40S ribosomal subunit and preceeds at 37 degrees C until all the substrate has been split. No hydrolysis of initiator tRNA or N-acetylmethionyl-tRNA Met f occurs at 0 degrees C. Hydrolysis is slightly stimulated by GTP and MG2+ but not by KCl. The binding and hydrolyzing activity associated with a single protein factor may have an important function in regulating the rate of peptide initiation.     

Interaction between membrane functions and protein synthesis in reticulocytes: specific cleavage of 28-S ribosomal RNA by a membrane constituent

A factor isolated from rabbit reticulocyte white ghosts by Triton X-100 treatment blocks protein synthesis at the elongation-termination stage. Factor-treated ribosomes were found to have an identical buoyant density to that of control ribosomes. When incubated with either reticulocyte ribosomes or ribosomal RNA, the factor products specific cuts in the 28-S ribosomal RNA compenent without damaging the 18-S RNA. Incubations of pancreatic or T1 RNase, with ribosomal RNA, at similar protein-synthesis inhibitory concentrations effected a complete breakdown to oligo and mononucleotides. When challenged with isolated 28-S or 18-S reticulocyte ribosomal RNA, the highly purified factor only attacked the 28-S RNA species. There was no accumulation of nucleotides or oligonucleotides and we concluded that the membrane factor causes inhibition of protein synthesis by having a specific endonucleolytic cleavage activity.     

Defective assembly of the mitochondrial ribosomes in yeast cells grown in the presence of mitochondrial protein synthesis inhibitors

The involvement of mitochondrial protein synthesis in the assembly of the mitochondrial ribosomes was investigated by studying the extent to which the assembly process can proceed in the presence of mitochondrial protein synthesis inhibitors erythromycin and chloramphenicol. Yeast cells grown in the presence of erythromycin (2 mg/ml) do not appear to contain any detectable amounts of the mitochondrial small (37 S) ribosomal subunit. Instead, a ribonucleoparticle with a sedimentation coefficient of 30 S was observed; this particle could be shown to be related to the mitochondrial small ribosomal subunit by two-dimensional gel electrophoretic analysis of its protein components. Since the var1 protein is the only mitochondrial translation product known to be associated with the mitochondrial ribosome, our results suggest that this protein is essential for the assembly of the mature small subunit, and that the var1 protein enters the pathway for the assembly of the small subunit at a late step. In at least one strain of yeast the accumulation of the 30-S particle appears to be very sensitive to catabolite repression. When yeast cells are grown in the presence of chloramphenicol instead of erythromycin, assembly of the small subunit appears to be only partially inhibited, and the presence of the 30-S particle could not be clearly demonstrated. This observation is consistent with the fact that in yeast, chloramphenicol inhibits mitochondrial protein synthesis by about 95% only and that the synthesis of the var1 protein appears to be the least sensitive to this inhibition.     

Kinetic studies on ribosomal proteins assembly in preribosomal particles and ribosomal subunits of mammalian cells.

Proteins were isolated from 80-S preribosomal particles and ribosomal subunits of murine L5178Y cells after short and longer periods of incubation with tritiated amino acids. The labeling patterns of ribosomal proteins were compared by two-dimensional polyacrylamide gel electrophoresis. The analysis of isotopic ratios in individual protein spots showed marked differences in the relative kinetics of protein appearance within nucleolar peribosomes and cytoplasmic subunits. Among the about 60 distinct proteins characterized in 80-S preribosomes, 9 ribosomal proteins appeared to incorporate radioactive amino acids more rapidly. These proteins become labeled gradually in the cytoplasmic ribosomal subunits. It was found that one non-ribosomal protein associated with 80-S preribosomes takes up label far more quickly than other preribosomal polypeptides. It is suggested that this set of proteins could associate early with newly transcribed pre-rRNA, more rapidly than others after their synthesis on polyribosomes, and could therefore play a role in the regulation of ribosome synthesis. In isolated 60-S and 40-S ribosomal subunits, we detected five proteins from the large subunit and four proteins from the small subunit which incorporate tritiated amino acids more quickly than the remainder. These proteins were shown to be absent or very faintly labeled in 80-S preribosomal particles, and would associate with ribosomal particles at later stages of the maturation process.     

Effect of polaymines on yeast cell-free protein synthesizing system. I. Influence of spermine and spermidine on aminoacyl-tRNA transfer reaction.

Spermine and spermidine added to a Saccharomyces cerevisiae cell-free protein synthesizing system increased phenylalanine polymerization reaction several-fold at suboptimal concentration of Mg2+ and approximately two-fold at optimal amounts of Mg2+. The addition of polyamines greatly stimulated the enzymatic and nonenzymatic binding of phenylalanyl-tRNA and N-acetylphenylalanyl-tRNA to ribosomes. The binding of the acetylated derivative was higher than phenylalanyl-tRNA, however, as it was shown the former was bound exclusively to the A site of the ribosome. Contrary to the binding process, the puromycin reaction was not stimulated by spermine added at a concentration which enhanced the polyphenylalanine synthesis. These results indicate that polyamines have not only a sparing effect on the Mg2+ requirement for yeast protein synthesis in vitro and suggest that one of the possible sites of polyamines action might be the binding of aminoacyl-tRNA to ribosomes.     

Binding of ribosome recycling factor to ribosomes,comparison with tRNA

The prokaryotic post-termination ribosomal complex is disassembled by ribosome recycling factor (RRF) and elongation factor G. Because of the structural similarity of RRF and tRNA, we compared the biochemical characteristics of RRF binding to ribosomes with that of tRNA. Unesterified tRNA inhibited the disassembly of the post-termination complex in a competitive manner with RRF, suggesting that RRF binds to the A-site. Approximately one molecule of ribosome-bound RRF was detected after isolation of the RRF-ribosome complex. RRF and unesterified tRNA similarly inhibited the binding of N-acetylphenylalanyl-tRNA to the P-site of non-programmed but not programmed ribosomes. Under the conditions in which unesterified tRNA binds to both the P- and E-sites of non-programmed ribosomes, RRF inhibited 50% of the tRNA binding, suggesting that RRF does not bind to the E-site. The results are consistent with the notion that a single RRF binds to the A- and P-sites in a somewhat analogous manner to the A/P-site bound peptidyl tRNA. The binding of RRF and tRNA to ribosomes was influenced by Mg(2+) and NH(4)(+) ions in a similar manner.     

Isolation of cloned DNA sequences containing ribosomal protein genes from Saccharomyces cerevisiae.

Yeast mRNA enriched for ribosomal protein mRNA was obtained by isolating poly(A)+ small mRNA from small polysomes. A comparison of cell-free translation of this small mRNA and total mRNA, and electrophoresis of the products on two-dimensional gels which resolve most yeast ribosomal proteins, demonstrated that a 5-10 fold enrichment for ribosomal protein mRNA was obtained. One hundred different recombinant DNA molecules possibly containing ribosomal protein genes were selected by differential colony hybridization of this enriched mRNA and unfractionated mRNA to a bank of yeast pMB9 hybrid plasmids. After screening twenty-five of these candidates, five different clones were found which contain yeast ribosomal protein gene sequences. The yeast mRNAs complementary to these five plasmids code for 35S-methionine-labeled polypeptides which co-migrate on two-dimensional gels with yeast ribosomal proteins. Consistent with previous studies on ribosomal protein mRNAs, the amounts of mRNA complementary to three of these cloned genes are controlled by the RNA2 locus. Although two of the five clones contain more than one yeast gene, none contain more than one identifiable ribosomal protein gene. Thus there is no evidence for "tight" linkage of yeast ribosomal protein genes. Two of the cloned ribosomal protein genes are single-copy genes, whereas two other cloned sequences contain two different copies of the same ribosomal protein gene. The fifth plasmid contains sequences which are repeated in the yeast genome, but it is not known whether any or all of the ribosomal protein gene on this clone contains repetitive DNA.     

In vivo suppression of coding associated with bacteriophage-induced S-adenosylmethionine hydrolase

The methylation of ribosomal and transfer ribonucleic acid (RNA) synthesized after the induction of a hydrolase for S-adenosylmethionine by phage T3 infection is reducible to 50% of the methylation of RNA in uninfected cells. Hypomethylated ribosomal RNA is found in 70S particles that dissociate in 100 mum Mg(++) to yield only 30S and 50S subunits. By this criterion, the omitted methyl groups apparently are not required for ribosomal maturation or stability. The rate of production of alkaline phosphatase in a phosphatase amber mutant was examined after phage infection in the presence and in the absence of streptomycin to determine the effect on the translation process consequent to S-adenosyl-l-methionine (SAM) hydrolase induction. Significant increases in the rates of phosphatase production were found when ultraviolet-inactivated T3 or streptomycin was added. The effects were cumulative when the cells were treated with both bacteriophage and the drug. Ultraviolet-inactivated T7, a phage closely related to T3 but which does not produce the SAM hydrolase, did not enhance the rate of alkaline phosphatase production. We suggest that the production of SAM hydrolase affects the stability of the translation process by the observed hypomethylation or by mechanisms concerning polyamine metabolism.     

The site of hydrolysis by rabbit reticulocyte peptidyl-tRNA hydrolase is the 3'-AMP terminus of susceptible tRNA substrates.

The preceding paper (Gross, M., Starn, T.K., Rundquist, C., Crow, P., White, J., Olin, A., and Wagner, T. (1992) J. Biol. Chem. 267, 2073-2079) reported the purification and partial characterization of rabbit reticulocyte peptidyl-tRNA hydrolase. In this article we demonstrate that, unlike bacterial and yeast peptidyl-tRNA hydrolase which act by deacylation, the reticulocyte enzyme hydrolyzes N-acylaminoacyl-tRNA to N-acylaminoacyl-AMP. Reticulocyte lysate has a separate enzyme, that we have isolated and termed aminoacyl-AMP deacylase, which hydrolyzes N-acylaminoacyl-AMP and aminoacyl-AMP, recycling the amino acid and nucleotide components. The action of this enzyme is relatively specific for the N-acylaminoacyl-AMP generated by peptidyl-tRNA hydrolase, since it is much less active with N-acylaminoacyl-adenosine and inactive with N-acylaminoacyl-ACCAC, N-acylaminoacyl-tRNA, or aminoacyl-tRNA. The tRNA product of peptidyl-tRNA hydrolase action is tRNA missing only its 3'-AMP terminus (tRNA(c-c)), since reaminoacylation requires tRNA nucleotidyltransferase but not CTP. The 3' exonucleolytic action of reticulocyte peptidyl-tRNA hydrolase is specific to susceptible tRNA substrates, since it does not hydrolyze CACCA, CACCA-N-acylamino acid, polyuridylic acid, or the 3' polyadenylate tail of globin mRNA, and, since its ability to hydrolyze Escherichia coli f[3H]Met-tRNA(fMet) is not reduced by excess 5 S or 28 S ribosomal RNA and is reduced only slightly by excess tRNA(c-c). Reticulocyte peptidyl-tRNA hydrolase also hydrolyzes th 3'-AMP terminus of deacylated tRNA. This property may explain why the 3'-terminal AMP of tRNA undergoes turnover in reticulocytes and reticulocyte lysate, since we find that such turnover in gel-filtered reticulocyte lysate is increased under conditions where aminoacylation is reduced.