Formylatable methionine transfer RNA from Mycoplasma: purification and comparison of partial nucleotide sequences with those of other prokaryotic initiator tRNAs.

The major species of the formylatable methionine tRNA from Mycoplasma mycoides var capri has been purified. The 5'- and 3'-terminal sequences of the purified tRNA are pC-G- and C-A-A-C-C-AOH, respectively. Thus, this tRNA also contains the unique structural feature found in two other prokaryotic initiator tRNAs in that the first nucleotide at the 5'-end cannot form a Watson-Crick type of base-pair to the fifth nucleotide from the 3'-end. The Mycoplasma tRNA does not contain ribothymidine; however, a specific uridine residue in the sequence G-U-psi-C-G- can be enzymatically methylated by E. coli extracts to yield G-T-psi-C-G. Since ribothymidine is absent in crude tRNA from this strain of Mycoplasma, the absence of T is probably due to the lack of a U yields T modifying enzyme.     

Structure and function of initiator methionine tRNA from the mitochondria of Neurospora crassa.

Initiator methionine tRNA from the mitochondria of Neurospora crassa has been purified and sequenced. This mitochondrial tRNA can be aminoacylated and formylated by E. coli enzymes, and is capable of initiating protein synthesis in E. coli extracts. The nucleotide composition of the mitochondrial initiator tRNA (the first mitochondrial tRNA subjected to sequence analysis) is very rich in A + U, like that reported for total mitochondrial tRNA. In two of the unique features which differentiate procaryotic from eucaryotic cytoplasmic initiator tRNAs, the mitochondrial tRNA appears to resemble the eucaryotic initiator tRNAs. Thus unlike procaryotic initiator tRNAs in which the 5′ terminal nucleotide cannot form a Watson-Crick base pair to the fifth nucleotide from the 3′ end, the mitochondrial tRNA can form such a base pair; and like the eucaryotic cytoplasmic initiator tRNAs, the mitochondrial initiator tRNA lacks the sequence -TΨCG(or A) in loop IV. The corresponding sequence in the mitochondrial tRNA, however, is -UGCA- and not -AU(or Ψ)CG-as found in all eucaryotic cytoplasmic initiator tRNAs. In spite of some similarity of the mitochondrial initiator tRNA to both eucaryotic and procaryotic initiator tRNAs, the mitochondrial initiator tRNA is basically different from both these tRNAs. Between these two classes of initiator tRNAs, however, it is more homologous in sequence to procaryotic (56–60%) than to eucaryotic cytoplasmic initiator tRNAs (45–51%).     

Involvement of the size and sequence of the anticodon loop in tRNA recognition by mammalian and E. coli methionyl-tRNA synthetases.

The rates of the cross-aminoacylation reactions of tRNAs(Met) catalyzed by methionyl-tRNA synthetases from various organisms suggest the occurrence of two types of tRNA(Met)/methionyl-tRNA synthetase systems. In this study, the tRNA determinants recognized by mammalian or E. coli methionyl-tRNA synthetases, which are representative members of the two types, have been examined. Like its prokaryotic counterpart, the mammalian enzyme utilizes the anticodon of tRNA as main recognition element. However, the mammalian cytoplasmic elongator tRNA(Met) species is not recognized by the bacterial synthetase, and both the initiator and elongator E. coli tRNA(Met) behave as poor substrates of the mammalian cytoplasmic synthetase. Synthetic genes encoding variants of tRNAs(Met), including the elongator one from mammals, were expressed in E. coli. tRNAs(Met) recognized by a synthetase of a given type can be converted into a substrate of an enzyme of the other type by introducing one-base substitutions in the anticodon loop or stem. In particular, a reduction of the size of the anticodon loop of cytoplasmic mammalian elongator tRNA(Met) from 9 to 7 bases, through the creation of an additional Watson-Crick pair at the bottom of the anticodon stem, makes it a substrate of the prokaryotic enzyme and decreases its ability to be methionylated by the mammalian enzyme. Moreover, enlarging the size of the anticodon loop of E. coli tRNA(Metm) from 7 to 9 bases, by disrupting the base pair at the bottom of the anticodon stem, renders the resulting tRNA a good substrate of the mammalian enzyme, while strongly altering its reaction with the prokaryotic synthetase. Finally, E. coli tRNA(Metf) can be rendered a better substrate of the mammalian enzyme by changing its U33 into a C. This modification makes the sequence of the anticodon loop of tRNA(Metf) identical to that of cytoplasmic initiator tRNA(Met).     

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.     

Yeast mitochondrial methionine initiator tRNA: characterization and nucleotide sequence.

Two methionine tRNAs from yeast mitochondria have been purified. The mitochondrial initiator tRNA has been identified by formylation using a mitochondrial enzyme extract. E. coli transformylase however, does not formylate the yeast mitochondrial initiator tRNA. The sequence was determined using both 32P-in vivo labeled and 32P-end labeled mt tRNAf(Met). This tRNA, unlike N. crassa mitochondrial tRNAf(Met), has two structural features typical of procaryotic initiator tRNAs: (i) it lacks a Watson-Crick base-pair at the end of the acceptor stem and (ii) has a T-psi-C-A sequence in loop IV. However, both yeast and N. crassa mitochondrial initiator tRNAs have a U11:A24 base-pair in the D-stem unlike procaryotic initiator tRNAs which have A11:U24. Interestingly, both mitochondrial initiator tRNAs, as well as bean chloroplast tRNAf(Met), have only two G:C pairs next to the anticodon loop, unlike any other initiator tRNA whatever its origin. In terms of overall sequence homology, yeast mitochondrial tRNA(Met)f differs from both procaryotic or eucaryotic initiator tRNAs, showing the highest homology with N. crassa mitochondrial initiator tRNA.     

The phenylalanine tRNA from Mycoplasma sp. (Kid): a tRNA lacking hypermodified nucleosides functional in protein synthesis

Phenylalanine tRNA from Mycoplasma sp. (Kid) was purified and characterized. The tRNA can be aminoacylated by phenylalanyl-tRNA synthetase from both Mycoplasma and E. coli. In a tRNA-dependent cell-free E. coli amino acid incorporating system programmed with poly U pure Mycoplasma tRNA(Phe) was fully active in promoting phenylalanine incorporation, even in direct competition with homologous E. coli tRNA(Phe). Since the Mycoplasma tRNA lacks isopentenyladenosine, or any related hypermodified nucleoside, it appears that the presence of such nucleosides in tRNA is not an absolute requirement for protein synthesis.     

Initiator-Elongator Discrimination in Vertebrate tRNAs for Protein Synthesis

Initiator tRNAs are used exclusively for initiation of protein synthesis and not for the elongation step. We show, in vivo and in vitro, that the primary sequence feature that prevents the human initiator tRNA from acting in the elongation step is the nature of base pairs 50:64 and 51:63 in the TΨC stem of the initiator tRNA. Various considerations suggest that this is due to sequence-dependent perturbation of the sugar phosphate backbone in the TΨC stem of initiator tRNA, which most likely blocks binding of the elongation factor to the tRNA. Because the sequences of all vertebrate initiator tRNAs are identical, our findings with the human initiator tRNA are likely to be valid for all vertebrate systems. We have developed reporter systems that can be used to monitor, in mammalian cells, the activity in elongation of mutant human initiator tRNAs carrying anticodon sequence mutations from CAU to CCU (the C35 mutant) or to CUA (the U35A36 mutant). Combination of the anticodon sequence mutation with mutations in base pairs 50:64 and 51:63 yielded tRNAs that act as elongators in mammalian cells. Further mutation of the A1:U72 base pair, which is conserved in virtually all eukaryotic initiator tRNAs, to G1:C72 in the C35 mutant background yielded tRNAs that were even more active in elongation. In addition, in a rabbit reticulocyte in vitro protein-synthesizing system, a tRNA carrying the TΨC stem and the A1:U72-to-G1:C72 mutations was almost as active in elongation as the elongator methionine tRNA. The combination of mutant initiator tRNA with the CCU anticodon and the reporter system developed here provides the first example of missense suppression in mammalian cells.     

Nucleotide sequence of Neurospora crassa cytoplasmic initiator tRNA.

Initiator methionine tRNA from the cytoplasm of Neurospora crassa has been purified and sequenced. The sequence is: pAGCUGCAUm1GGCGCAGCGGAAGCGCM22GCY*GGGCUCAUt6AACCCGGAGm7GU (or D) - CACUCGAUCGm1AAACGAG*UUGCAGCUACCAOH. Similar to initiator tRNAs from the cytoplasm of other eukaryotes, this tRNA also contains the sequence -AUCG- instead of the usual -TphiCG (or A)- found in loop IV of other tRNAs. The sequence of the N. crassa cytoplasmic initiator tRNA is quite different from that of the corresponding mitochondrial initiator tRNA. Comparison of the sequence of N. crassa cytoplasmic initiator tRNA to those of yeast, wheat germ and vertebrate cytoplasmic initiator tRNA indicates that the sequences of the two fungal tRNAs are no more similar to each other than they are to those of other initiator tRNAs.     

Nucleotide sequence of Streptomyces griseus initiator tRNA.

The primary structure of initiator tRNA from Streptomyces griseus was determined by post-labeling procedures. The nucleotide sequence is pC-G-C-G-G-G-G-U-G-G-A-G-C-A-G-C-U-C-G-G-D-A-G-C-U-C-G-C-U-G-G-G-C-U-C-A-U-A-A-C-C- C-A-G-A-G-G-U-C-G-C-A-G-G-U-psi-C-A-m1A-A-U-C-C-U-G-U-C-C-C-C-G-C-U-A-C-C-A0H. The unique feature of the sequence of this tRNA is that residue 54 is occupied by unmodified U, while ribothymidine is located in that position in most initiator tRNAs from eubacteria.     

Nucleotide sequence of initiator tRNA from Mycobacterium smegmatis.

The nucleotide sequence of initiator tRNA from Mycobacterium smegmatis was determined to be pCGCGGGGUGGAGCAGCUCGGDAGCUCGCUGGGCUCAUAACCCAGAGm7GUCG CAGGU psi CGm1AAUCCUGUCCCCGCUACCAOH . The nucleotide sequence of Mycobacterium initiator tRNA was found to be the same as that of Streptomyces initiator tRNA, except that G46 and A57 were replaced by m7G46 and G57 , respectively. The striking feature of Mycobacterium initiator tRNA is the absence of ribothymidine at residue 54, and the presence of 1-methyladenosine at residue 58 which makes the sequence of this tRNA similar to that of eukaryotic initiator tRNA.     

Assembly of the mitochondrial membrane system. Sequences of yeast mitochondrial tRNA genes

Two cytoplasmic "petite" (rho-) clones of Saccharomyces cerevisiae have been selected for the retention of the aspartic acid tRNA gene. The two clones, designated DS200/A102 and DS200/A5, have tandemly repeated segments of mitochondrial DNA (mtDNA) with unit lengths of 1,000 and 6,400 base pairs, respectively. The DS200/A102 genome has a single tRNA gene with a 3'-CUG-5' anticodon capable of recognizing the 5'-GAC-3' and 5'-GAU-3' codons for aspartic acid. The mtDNA segment of DS200/A102 has been determined to represent the wild type sequence from 5.3 to 6.8 map units. The genome of DS200/A5 is more complex encompassing the region of wild type mtDNA from 3.5 to 12.7 units. A continuous sequence has been obtained from 3.5 to 8.6 units. In addition to the aspartic acid tRNA, this region codes for the tRNAUGCAla,tRNAUCUArg, tRNAACGArg, tRNAGCUSer,tRNAUCCGly and tRNAUUULys. The DNA sequence of the DS200/A5 genome has allowed us to deduce the secondary structures of the seven tRNAs and to assign precise map positions for their genes. All the tRNAs except tRNA GUCAsp exhibit most of the invariant features of prokaryotic and eukaryotic tRNAs. The aspartic acid tRNA has unusual D and T psi C loops. The structure of this tRNA is similar to the mitochondrial initiator tRNA of Neurospora crassa (Heckman, J.E., Hecker, L.I., Shwartzbach, S.D., Barnett, W.E., Baumstark, B., and RajBhandary, U.L. Cell 13, 83-95).     

Biochemical research on oogenesis. Nucleotide sequence of initiator tRNA from oocytes and from somatic cells of Xenopus laevis.

The nucleotide sequence of initiator tRNA, tRNAfMet, from vitellogenic oocytes of Xenopus laevis was determined. The sequence was deduced from analysis of all T1 and pancreatic oligonucleotides and comparison with the sequence of initiator tRNA from other animal species. At least 80% of all initiator tRNA molecules from oocytes have the same nucleotide sequence. This means that most and probably all initiator tRNA genes which are active in oocytes are identical to one another. No structural difference was observed between liver and oocyte initiator tRNAs. Initiator tRNA from X. laevis has the same nucleotide sequence as initiator tRNA from several species of mammals. The genes coding for this RNA have therefore remained unchanged in the mammalian and amphibian lines for at least 300000000 years.     

The fate of the initiator tRNAs is sensitive to the critical balance between interacting proteins

Formylation of the initiator tRNA is essential for normal growth of Escherichia coli. The initiator tRNA containing the U35A36 mutation (CUA anticodon) initiates from UAG codon. However, an additional mutation at position 72 (72A --> G) renders the tRNA (G72/U35A36) inactive in initiation because it is defective in formylation. In this study, we isolated U1G72/U35A36 tRNA containing a wobble base pair at 1-72 positions as an intragenic suppressor of the G72 mutation. The U1G72/U35A36 tRNA is formylated and participates in initiation. More importantly, we show that the mismatch at 1-72 positions of the initiator tRNA, which was thus far thought to be the hallmark of the resistance of this tRNA against peptidyl-tRNA hydrolase (PTH), is not sufficient. The amino acid attached to the initiator tRNA is also important in conferring protection against PTH. Further, we show that the relative levels of PTH and IF2 influence the path adopted by the initiator tRNAs in protein synthesis. These findings provide an important clue to understand the dual function of the single tRNA(Met) in initiation and elongation, in the mitochondria of various organisms.     

Nucleotide sequence of Scenedesmus obliquus cytoplasmic initiator tRNA.

The cytoplasmic initiator tRNA from the green alga Scenedesmus obliquus has been purified and its sequence shown to be p A G C U G A G-U m G m G C G C A G D G G A A G C G psi m G A psi G G G C U C A U t A A--C C C A U A G m G D m C A C A G G A U C G m A A A C C U Gm U C U C A--G C U A C C A-O H. The sequence has been deduced and confirmed using several different P-post labelling techniques. The sequence is similar to those of other eukaryotic cytoplasmic initiator tRNAs and it has the sequence G A U C in place of the usual G T psi C. Although it resembles lower eukaryotic species in having a U preceding the anticodon and a modified G in the T psi C stem, in overall homology it is closer to the higher eukaryotic than to the fungal initiator tRNAs.     

Antideterminants present in minihelix(Sec) hinder its recognition by prokaryotic elongation factor Tu.

During protein biosynthesis, all aminoacylated elongator tRNAs except selenocysteine-inserting tRNA Sec form ternary complexes with activated elongation factor. tRNA Sec is bound by its own translation factor, an elongation factor analogue, e.g. the SELB factor in prokaryotes. An apparent reason for this discrimination could be related to the unusual length of tRNA Sec amino acid-acceptor branch formed by 13 bp. However, it has been recently shown that an aspartylated minihelix of 13 bp derived from yeast tRNA Asp is an efficient substrate for Thermus thermophilus EF-Tu-GTP, suggesting that features other than the length of tRNA Sec prevent its recognition by EF-Tu-GTP. A stepwise mutational analysis of a minihelix derived from tRNA Sec in which sequence elements of tRNA Asp were introduced showed that the sequence of the amino acid- acceptor branch of Escherichia coli tRNA Sec contains a specific structural element that hinders its binding to T.thermophilus EF-Tu-GTP. This antideterminant is located in the 8th, 9th and 10th bp in the acceptor branch of tRNA Sec, corresponding to the last base pair in the amino acid acceptor stem and the two first pairs in the T-stem. The function of this C7.G66/G49.U65/C50.G64 box was tested by its transplantation into a minihelix derived from tRNA Asp, abolishing its recognition by EF-Tu-GTP. The specific role of this nucleotide combination is further supported by its absence in all known prokaryotic elongator tRNAs.     

Nucleotide sequence of starfish initiator tRNA.

The nucleotide sequence of starfish ovary initiator tRNA was determined to be pA-G-C-A-G-A-G-U-m1G-m2G-C-G-C-A-G-U-G-G-A-A-G-C-G-U-G-C-U-G-G-G-C-C-C-A-U-t6A-A-C-C-C-A-G-A-G-m7G-D-m5C-C-G-A-G-G-A-psi-C-G-m1A-A-A-C-C-U-C-G-C-U-C-U-G-C-U-A-C-C-AOH. The sequence was determined by a combination of the two different post-labeling techniques. Two-dimensional cellulose thin-layer chromatography was adopted for analysis of 5'-terminal nucleotides of tRNA fragments produced by formamide treatment. The nucleotide sequence of starfish initiator tRNA is very similar to that of mammalian cytoplasmic initiator tRNAs, but has seven different nucleotide residues and two modifications: residue 55 is psi instead of U, and residue 26 is unmodified G instead of m2G.     

Nucleotide sequence of cytoplasmic initiator tRNA from Tetrahymena thermophila.

The total primary structure of cytoplasmic initiator tRNA from Tetrahymena thermophila mating type IV, was determined by post labeling techniques. The sequence is pa-G-C-A-G-G-G-U-m1G-G-C-G-A-A-A-D-Gm-G-A-A-U-C-G-C-G-U-Psi-G-G-G-C-U-C-A-U-t6A -A-C-Psi-C-A-A-A-A-m7G-U-m5C-A-G-A-G-G-A-Psi-C-G-m1A-A-A-C-C-U-C-U-C-U-C-U-G-C- U-A-C-C-AOH. The nucleotide residue in the position next to the 5'-end of the anticodon of this tRNA (residue No. 33) is uridine instead of cytidine, which has been found in cytoplasmic initiator tRNAs from multicellular eukaryotic organisms. The sequence of three consecutive G-C base pairs in the anticodon stem common to all other cytoplasmic initiator tRNAs is disrupted in this tRNA; namely, the cytidine at residue 40 in this region is replaced by pseudouridine in Tetrahymena initiator tRNA.     

Expression and function of a human initiator tRNA gene in the yeast Saccharomyces cerevisiae.

We showed previously that the human initiator tRNA gene, in the context of its own 5'- and 3'-flanking sequences, was not expressed in Saccharomyces cerevisiae. Here we show that switching its 5'-flanking sequence with that of a yeast arginine tRNA gene allows its functional expression in yeast cells. The human initiator tRNA coding sequence was either cloned downstream of the yeast arginine tRNA gene, with various lengths of intergenic spacer separating them, or linked directly to the 5'-flanking sequence of the yeast arginine tRNA coding sequence. The human initiator tRNA made in yeast cells can be aminoacylated with methionine, and it was clearly separated from the yeast initiator and elongator methionine tRNAs by RPC-5 column chromatography. It was also functional in yeast cells. Expression of the human initiator tRNA in transformants of a slow-growing mutant yeast strain, in which three of the four endogenous initiator tRNA genes had been inactivated by gene disruption, resulted in enhancement of the growth rate. The degree of growth rate enhancement correlated with the steady-state levels of human tRNA in the transformants. Besides providing a possible assay for in vivo function of mutant human initiator tRNAs, this work represents the only example of the functional expression of a vertebrate RNA polymerase III-transcribed gene in yeast cells.     

Nucleotide sequence of wheat germ cytoplasmic initiator methionine transfer ribonucleic acid

The primary sequence of wheat germ initiator tRNA has been determined using in vitro labelling techniques. The sequence is: pAUCAGAGUm1Gm2GCGCAG CGGAAGCGUm2GG psi GGGCCCAUt6AACCCACAGm7GDm5Cm5CCAGGA psi CGm1AAACCUG*GCUCUGAUACCAOH. As in other eukaryotic initiator tRNAs, the sequence -T psi CG(A)- present in loop IV of virtually all tRNA active in protein synthesis is absent and is replaced by -A psi CG-. The base pair G2:C71 present in all other initiator tRNAs recognized by E. coli Met-tRNA transformylase is absent and is replaced by U2:A71. Since wheat germ initiator tRNA is not formylated by E. coli Met-tRNA transformylase this implies a possible role of the G2:C71 base pair present in other initiator tRNAs in formylation of initiator tRNA species.