The kinetics and specificity of cleavage by RNase P is mainly dependent on the structure of the amino acid acceptor stem.

Cleavage by RNase P of the tRNA(His precursor yields a mature tRNA with an 8 base pair amino acid acceptor stem instead of the usual 7 base pair stem. Here we show, both in vivo and in vitro, that this is mainly dependent on the primary structure and length of the acceptor stem in the precursor. Furthermore, the tRNA(His) precursor used in this study was processed with a change in both kinetic constants, Km and kcat, in comparison to the kinetics of cleavage of the precursor to tRNA(Tyr)Su3. Cleavage of a chimeric tRNA precursor showed that these altered kinetics were due to a difference in the primary structure and in the length of the acceptor stems of these two tRNA precursors. We also studied the cleavage reaction as a function of base substitutions at positions -1 and/or +73 in the precursor to tRNA(His). Our results suggest that the nucleotide at position +73 in tRNA(His) plays a significant role in the kinetics of cleavage of its precursor, possibly in product release. In addition, it appears that the C5 protein of RNase P is involved in the interaction between the enzyme and its substrate in a substrate-dependent manner, as previously suggested.     

tRNA 3' processing in plants: nuclear and mitochondrial activities differ

The nuclear tRNA 3' processing activity from wheat has been characterized and partially purified. Several characteristics of the wheat nuclear 3' processing enzyme now allow this activity to be distinguished from its mitochondrial counterpart. The nuclear enzyme is an endonuclease, which we termed nuclear RNase Z. The enzyme cleaves at the discriminator base and seems to consist only of protein subunits, since essential RNA subunits could not be detected. RNase Z leaves 5' terminal phosphoryl and 3' terminal hydroxyl groups at the processing products. It is a stable enzyme being active over broad temperature and pH ranges, with the highest activity at 35 degrees C and pH 8.4. The apparent molecular mass according to gel filtration chromatography is 122 kDa. The nuclear RNase Z does process 5' extended pretRNAs but with a much lower efficiency than 5' matured pretRNAs. Nuclear intron-containing precursor tRNAs as well as mitochondrial precursor tRNAs are efficiently cleaved by the nuclear RNase Z. Mitochondrial pretRNA(His) is processed by the nuclear RNase Z, generating a mature tRNA(His) containing an 8 base pair acceptor stem. The edited mitochondrial pretRNA(Phe) is cleaved easily, while the unedited version having a mismatch in the acceptor stem is not cleaved. Thus, an intact acceptor stem seems to be required for processing. Experiments with precursors containing mutated tRNAs showed that a completely intact anticodon arm is not necessary for processing by RNase Z. Comparison of the plant nuclear tRNA 3' processing enzyme with the plant mitochondrial one suggests that both activities are different enzymes.     

Metal ion and substrate structure dependence of the processing of tRNA precursors by RNase P and M1 RNA

A synthetic tRNA precursor analog containing the structural elements of Escherichia coli tRNA(Phe) was characterized as a substrate for E. coli ribonuclease P and for M1 RNA, the catalytic RNA subunit. Processing of the synthetic precursor exhibited a Mg2+ dependence quite similar to that of natural tRNA precursors such as E. coli tRNA(Tyr) precursor. It was found that Sr2+, Ca2+, and Ba2+ ions promoted processing of the dimeric precursor at Mg2+ concentrations otherwise insufficient to support processing; very similar behavior was noted for E. coli tRNA(Tyr). As noted previously for natural tRNA precursors, the absence of the 3'-terminal CA sequence in the synthetic precursor diminished the facility of processing of this substrate by RNase P and M1 RNA. A study of the Mg2+ dependence of processing of the synthetic tRNA dimeric substrate radiolabeled between C75 and A76 provided unequivocal evidence for an alteration in the actual site of processing by E. coli RNase P as a function of Mg2+ concentration. This property was subsequently demonstrated to obtain (Carter, B. J., Vold, B.S., and Hecht, S. M. (1990) J. Biol. Chem. 265, 7100-7103) for a mutant Bacillus subtilis tRNAHis precursor containing a potential A-C base pair at the end of the acceptor stem.     

Processing of histidine transfer RNA precursors. Abnormal cleavage site for RNase P

The 5'-terminal guanylate residue (G-1) of mature Escherichia coli tRNA(His) is generated as a result of an unusual cleavage by RNase P (Orellana, O., Cooley, L., and S?ll, D. (1986) Mol. Cell. Biol. 6, 525-529). We have examined the importance of the unique acceptor stem structure of E. coli tRNA(His) in determining the specificity of RNase P cleavage. Mutant tRNA(His) precursors bearing substitutions of the normal base G-1 or the opposing, potentially paired base, C73, can be cleaved at the +1 position, in contrast to wild-type precursors which are cut exclusively at the -1 position. These data indicate that the nature of the base at position -1 is of greater importance in determining the site of RNase P cleavage than potential base pairing between nucleotides -1 and 73. In addition, processing of the mutant precursors by M1-RNA or P RNA under conditions of ribozyme catalysis yields a higher proportion of +1-cleaved products in comparison to the reaction catalyzed by the RNase P holoenzyme. This lower sensitivity of the holoenzyme to alterations in acceptor stem structure suggests that the protein moiety of RNase P may play a role in determining the specificity of the reaction and implies that recognition of the substrate involves additional regions of the tRNA. We have also shown that the RNase P holoenzyme and tRNA(His) precursor of Saccharomyces cerevisiae, unlike their prokaryotic counterparts, do not possess these abilities to carry out this unusual reaction.     

The effects of matrices of paired substitutions in mid-acceptor stem on Drosophila tRNA(His) structure and end-processing

End-maturation reactions, in which the 5' end leader and 3' end trailer of precursor tRNA are removed by RNase P and 3'-tRNase, respectively, are early, essential steps in eukaryotic precursor tRNA processing. End-processing enzymes may be expected to contact the acceptor stem of tRNA due to its proximity to both cleavage sites. We constructed matrices of pair-wise substitutions in mid-acceptor stem at nt 3/70 and 4/69 of Drosophila tRNA(His) and analyzed their ability to be processed by Drosophila RNase P and 3'-tRNase. In accord with our earlier study of D/T loop processing matrices, we find that tRNA end processing enzymes respond to sequence changes differently. More processing defects were observed with 3'-tRNase than with RNase P, and substitutions at 4/69 reduced processing more than those at 3/70. We evaluated tRNA folding using structure probing nucleases and investigated the contribution of K(M) and V(Max) to the processing efficiency of selected variants. In one substitution (C3A), mis-folding correlates with processing defects. In another (C69A), a disruption of structure appears to be transmitted laterally to both ends of the acceptor stem. Poor processing of C69A by RNase P is due entirely to a reduction in V(Max), but for 3'-tRNase, it is due to an increase in K(M).     

Processing of a multimeric tRNA precursor from Bacillus subtilis by the RNA component of RNase P

Processing of multimeric precursor tRNAs from Bacillus subtilis by the catalytic RNA component of RNase P was studied in vitro. Previous studies on processing by either Escherichia coli or B. subtilis RNase P-RNA utilized monomeric or dimeric substrates. In the experiments described here, a multimeric precursor tRNA containing six complete tRNA sequences and the partial sequence of a seventh were used. One species did not encode the 3'-terminal CCA sequence and the partial tRNA lacked 3' nucleotides and could form only a 3-base pair instead of a 7-base paired aminoacyl stem. Two species had the potential for forming extended base-paired aminoacyl stems. Processing was studied under varied ionic conditions. Chemical sequencing of the products showed that the RNase P-RNA cleavage produced the proper mature 5' termini for all of the six complete tRNA species, but no 5'-cleavage of the partial species was observed. At suboptimal ionic concentrations, the two species capable of forming extended base-paired aminoacyl stems were not observed. Thus, encoding of the 3'-CCA in a tRNA species is not critical for processing, but the formation of an aminoacyl stem with more than 3 base pairs is necessary. Particularly noteworthy was the observation that all species of the multimeric precursor could be processed at significantly lower ionic conditions than monomeric precursors used previously by ourselves and others. However, a single precursor species produced from the multimeric precursor could also be processed at the same lower ionic conditions as the multimeric precursor. This demonstrates that precursor tRNA species can differ widely in their ionic requirements for processing and that, to a large extent, the optimal conditions of MgCl2 or NH4Cl are a function of the substrate which is used.     

The processing of wild type and mutant forms of rat nuclear pre-tRNA(Lys) by the homologous RNase P.

The 5' processing of rat pre-tRNA(Lys) and a series of mutant derivatives by rat cytosolic RNase P was examined. In standard, non-kinetic assays, mutant precursors synthesized in vitro with 5' leader sequences of 10, 17, 24, 25, and 46 nucleotides were processed to approximately equal levels and yielded precisely cleaved 5' processed intermediates with the normal 7-base pair aminoacyl stems. The construct containing the tRNA(Lys) with the 46-nucleotide leader was modified by PCR to give a series of pre-tRNA(Lys) mutants designed to measure the effect on processing by (1) substituting the nucleotide at the +1 position, (2) pairing and unpairing the +1 and +72 bases, (3) elongating the aminoacyl stem, and (4) disrupting the helix of the aminoacyl stem. Comparative kinetic analyses revealed that changing the wild type +1G to A, C, or U was well tolerated by the RNase P provided that compensatory changes at +72 created a base pair or a G.U noncanonical pair. Mutants with elongated aminoacyl stems that were produced either by inserting an additional base pair at +3:a + 69:a or by pairing the -1A with a +73U, were processed to yield 7-base pair aminoacyl stems, but with different efficiencies. The efficiency seen with the double insertion mutant was higher than even the wild type precursor, but the -1A-U + 73 mutant was a relatively poor substrate. Disrupting the aminoacyl stem helix by introducing a +7G G + 66 mispairing or by inserting a single G at the +3:a position dramatically reduced the processing efficiency, although the position of cleavage occurred precisely at the wild type cleavage site. However, the single insertion of a C at the +69:a position resulted in an efficiently cleaved precursor, but permitted a minor, secondary cleavage within the leader between the -6 and -5 nucleotides in addition to the dominant wild type scission.     

Structural requirements for processing of synthetic tRNAHis precursors by the catalytic RNA component of RNase P

Experiments were conducted to investigate structural features of the aminoacyl stem region of precursor histidine tRNA critical for the proper cleavage by the catalytic RNA component of RNase P that is responsible for 5' maturation. Histidine tRNA was chosen for study because tRNAHis has an 8 base pair instead of the typical 7-base pair aminoacyl stem. The importance of the 3' proximal CCA sequence in the 5'-processing reaction was also investigated. Our results show that the tRNAHis precursor patterned after the natural Bacillus subtilis gene is cleaved by catalytic RNAs from B. subtilis or Escherichia coli, leaving an extra G residue at the 5'-end of the aminoacyl stem. Replacing the 3' proximal CCA sequence in the substrate still allowed the catalytic RNA to cleave at the proper position, but it increased the Km of the reaction. Changing the sequence of the 3' leader region to increase the length of the aminoacyl stem did not alter the cleavage site but reduced the reaction rate. However, replacing the G residue at the expected 5' mature end by an A changed the processing site, resulting in the creation of a 7-base pair aminoacyl stem. The Km of this reaction was not substantially altered. These experiments indicate that the extra 5' G residue in B. subtilis tRNAHis is left on by RNase P processing because of the precursor's structure at the aminoacyl stem and that the cleavage site can be altered by a single base change. We have also shown that the catalytic RNA alone from either B. subtilis or E. coli is capable of cleaving a precursor tRNA in which the 3' proximal CCA sequence is replaced by other nucleotides.     

Sequence changes in both flanking sequences of a pre-tRNA influence the cleavage specificity of RNase P.

The cleavage specificities of the RNase P holoenzymes from Escherichia coli and the yeast Schizosaccharomyces pombe and of the catalytic M1 RNA from E. coli were analyzed in 5'-processing experiments using a yeast serine pre-tRNA with mutations in both flanking sequences. The template DNAs were obtained by enzymatic reactions in vitro and transcribed with phage SP6 or T7 RNA polymerase. The various mutations did not alter the cleavage specificity of the yeast RNase P holoenzyme; cleavage always occurred predominantly at position G + 1, generating the typical seven base-pair acceptor stem. In contrast, the specificity of the prokaryotic RNase P activities, i.e. the catalytic M1 RNA and the RNase P holoenzyme from E. coli, was influenced by some of the mutated pre-tRNA substrates, which resulted in an unusual cleavage pattern, generating extended acceptor stems. The bases G - 1 and C + 73, forming the eighth base pair in these extended acceptor stems, were an important motif in promoting the unusual cleavage pattern. It was found only in some natural pre-tRNAs, including tRNA(SeCys) from E. coli, and tRNAs(His) from bacteria and chloroplasts. Also, the corresponding mature tRNAs in vivo contain an eight base pair acceptor stem. The presence of the CCA sequence at the 3' end of the tRNA moiety is known to enhance the cleavage efficiency with the catalytic M1 RNA. Surprisingly, the presence or absence of this sequence in two of our substrate mutants drastically altered the cleavage specificity of M1 RNA and of the E. coli holoenzyme, respectively. Possible reasons for the different cleavage specificities of the enzymes, the influence of sequence alterations and the importance of stacking forces in the acceptor stems are discussed.     

Structural and sequence elements important for recognition of Escherichia coli formylmethionine tRNA by methionyl-tRNA transformylase are clustered in the acceptor stem

We show that the structure and/or sequence of the first three base pairs at the end of the amino acid acceptor stem of Escherichia coli initiator tRNA and the discriminator base 73 are important for its formylation by E. coli methionyl-tRNA transformylase. This conclusion is based on mutagenesis of the E. coli initiator tRNA gene followed by measurement of kinetic parameters for formylation of the mutant tRNAs in vitro and function in protein synthesis in vivo. The first base pair found at the end of the amino acid acceptor stem in all other tRNAs is replaced by a C.A. "mismatch" in E. coli initiator tRNA. Mutation of this C.A. to U:A, a weak base pair, or U.G., a mismatch, has little effect on formylation, whereas mutation to C:G, a strong base pair, has a dramatic effect lowering Vmax/Kappm by 495-fold. Mutation of the second basepair G2:C71 to U2:A71 lowers Vmax/Kappm by 236-fold. Replacement of the third base-pair C3:G70 by U3:A70, A3:U70, or G3:C70 lowers Vmax/Kappm by about 67-, 27-, and 30-fold, respectively. Changes in the rest of the acceptor stem, dihydrouridine stem, anticodon stem, anticodon sequence, and T psi C stem have little or no effect on formylation.     

Minimum requirements for substrates of mammalian tRNA 3' processing endoribonuclease.

Mammalian tRNA 3' processing endoribonuclease (3' tRNase) removes a 3' trailer after the discriminator nucleotide from precursor tRNA (pre-tRNA). To elucidate the minimum requirements for 3' tRNase substrates, we tested small pre-tRNA(Arg) substrates lacking the D and anticodon stem-loop domain for cleavage by purified pig 3' tRNase. A small pre-tRNA (R-ATW) composed of an acceptor stem, an extra loop, a T stem-loop domain, a discriminator nucleotide, and a 3' trailer was cleaved more efficiently than the full-length wild type. The catalytic efficiencies of three R-ATW derivatives, which were constructed to destroy the original T stem base pairs, were also higher than that of the full-length wild type. Pig 3' tRNase efficiently processed a "minihelix" (R-ATM5) that consists of a T stem-loop domain, an acceptor stem, a discriminator nucleotide, and a 3' trailer, while the enzyme never cleaved a "microhelix" that is composed of a T loop, an acceptor stem, a discriminator nucleotide, and a 3' trailer. Five R-ATM5 derivatives that have one to seven base substitutions in the T loop were all cleaved slightly more efficiently than the full-length wild type and slightly less efficiently than R-ATM5. A helix ("minihelixDelta1") one base pair smaller than minihelices was a good substrate, while small helices containing a continuous 10-base pair stem were poor substrates. The cleavage of these three small substrates occurred after the discriminator and one to three nucleotides downstream of the discriminator. From these results, we conclude that minimum substrates for efficient cleavage by mammalian 3' tRNase are minihelices or minihelicesDelta1, in which there seem to be no essential bases.     

Distinct modes of mature and precursor tRNA binding to Escherichia coli RNase P RNA revealed by NAIM analyses

We have analyzed by nucleotide analog interference mapping (NAIM) pools of precursor or mature tRNA molecules, carrying a low level of Rp-RMPalphaS (R = A, G, I) or Rp-c7-deaza-RMPalphaS (R = A, G) modifications, to identify functional groups that contribute to the specific interaction with and processing efficiency by Escherichia coli RNase P RNA. The majority of interferences were found in the acceptor stem, T arm, and D arm, including the strongest effects observed at positions G19, G53, A58, and G71. In some cases (interferences at G5, G18, and G71), the affected functional groups are candidates for direct contacts with RNase P RNA. Several modifications disrupt intramolecular tertiary contacts known to stabilize the authentic tRNA fold. Such indirect interference effects were informative as well, because they allowed us to compare the structural constraints required for ptRNA processing versus product binding. Our ptRNA processing and mature tRNA binding NAIM analyses revealed overlapping but nonidentical patterns of interference effects, suggesting that substrate binding and cleavage involves binding modes or conformational states distinct from the binding mode of mature tRNA, the product of the reaction.     

Functional compensation of a recognition-defective transfer RNA by a distal base pair substitution.

A single G3:U70 base pair in the acceptor helix is the major determinant of alanine acceptance in alanine transfer RNAs. Transfer of this base pair into other transfer RNAs confers alanine acceptance. A G3:C70 substitution eliminates alanine acceptance in vivo and in vitro. In this work, a population of mutagenized G3:C70 alanine tRNA amber suppressors was subjected to a selection for mutations that compensate for the inactivating G3:C70 substitution. No compensatory mutations located in the acceptor helix were obtained. Instead, a U27:U43 substitution that replaced the wild-type C27:G43 in the anticodon stem created a U27:U43/G3:C70 mutant alanine tRNA that inserts alanine at amber codons in vivo. The U27:U43 substitution is at a location where previous footprinting work established an RNA-protein contact. Thus, this mutation may act by functionally coupling a distal part of the tRNA structure to the active site.     

Transfer RNA precursors are accumulated in Escherichia coli in the absence of RNase E

A temperature-sensitive Escherichia coli mutant, which contains a heat-labile RNase E, fails to produce 5-S rRNA at a non-permissive temperature. It accumulates a number of RNA molecules in the 4-12-S range. One of these molecules, a 9-S RNA, is a precursor to 5-S rRNA [Ghora, B. K. and Apirion, D. (1978) Cell, 15, 1055-1056]. These molecules were purified and processed in a cell-free system. Some of these RNA molecules, after processing, give rise to products the size of transfer RNA, but not to 5-S-rRNA. Further characterization of the processed products of one such precursor molecule shows that it contains tRNA1Leu and tRNA1His. RNase E is necessary but not sufficient for the processing of this molecule to mature tRNAs in vitro. The accumulation of such tRNA precursors in an RNase E mutant cell and the obligatory participation of RNase E in its processing indicate that RNase E functions in the maturation of transfer RNAs as well as of 5-S rRNA.     

Reaction in vitro of some mutants of RNase P with wild-type and temperature-sensitive substrates

The reaction of wild-type and two mutant derivatives of RNase P have been examined with wild-type and mutant substrates. We show that a mutant derivative of tRNA(Tyr)Su3, tRNA(Tyr)Su3A15, in which the G15.C48(57) base-pair essential for folding of the tRNA moiety is altered, is a temperature-sensitive suppressor in vivo. The precursor to tRNA(Tyr)Su3A15 is cleaved in a temperature-sensitive manner in vitro by RNase P and with a higher Km compared to the precursor to tRNA(Tyr)Su3. The precursor to tRNA(Tyr)Su3A2, another temperature-sensitive suppressor in vivo in which the G2.C71(80) base-pair in the acceptor stem is changed to A2.C71(80), behaves like the precursor to tRNA(Tyr)Su3 in vitro; that is, it is not cleaved in a temperature-sensitive manner. Therefore, there are at least two ways in which a suppressor tRNA can acquire a temperature-sensitive phenotype in vivo. One of the mutant derivatives of RNase P we have tested, rnpA49, which affects the protein cofactor of the enzyme, has a decreased kcat compared to wild-type, which can explain its phenotype in vivo.     

Suppression of amber codons in vivo as evidence that mutants derived from Escherichia coli initiator tRNA can act at the step of elongation in protein synthesis

The absence of a Watson-Crick base pair at the end of the amino acid acceptor stem is one of the features which distinguishes prokaryotic initiator tRNAs as a class from all other tRNAs. We show that this structural feature prevents Escherichia coli initiator tRNA from acting as an elongator in protein synthesis in vivo. We generated a mutant of E. coli initiator tRNA in which the anticodon sequence is changed from CAU to CUA (the T35A36 mutant). This mutant tRNA has the potential to read the amber termination codon UAG. We then coupled this mutation to others which change the C1.A72 mismatch at the end of the acceptor stem to either a U1:A72 base pair (T1 mutant) or a C1:G72 base pair (G72 mutant). Transformation of E. coli CA274 (HfrC Su- lacZ125am trpEam) with multicopy plasmids carrying the mutant initiator tRNA genes show that mutant tRNAs carrying changes in both the anticodon sequence and the acceptor stem suppress amber codons in vivo, whereas mutant tRNA with changes in the anticodon sequence alone does not. Mutant tRNAs with the above anticodon sequence change are aminoacylated with glutamine in vitro. Measurement of kinetic parameters for aminoacylation by E. coli glutaminyl-tRNA synthetase show that both the nature of the base pair at the end of the acceptor stem and the presence or absence of a base pair at this position can affect aminoacylation kinetics. We discuss the implications of this result on recognition of tRNAs by E. coli glutaminyl-tRNA synthetase.