Characterization of tRNA precursor splicing in mammalian extracts

Transcription of a Xenopus laevis tRNATyr gene and splicing of the transcript have been studied in HeLa cell extracts. This tRNATyr gene has a 13-base intervening sequence and is expressed as mature tRNA when transfected into mammalian cells. The tRNATyr gene is transcribed under conditions of low concentrations of magnesium and ATP, but is processed by splicing only when both of these cofactors are added at higher concentrations. The endonucleolytic activity of the tRNA-splicing system in the HeLa extract produces exons with 3'-phosphate and 5'-hydroxyl groups. The 3'-phosphate is retained during the ligation reaction and forms the phosphodiester bond in the mature tRNA. Retention of the 3'-phosphate during tRNA splicing differs from the more extensively studied process in yeast extracts where a phosphate group from an ATP cofactor is used to form the phosphodiester bond joining the exons. Thus, eucaryotic organisms can splice tRNA precursors by at least two distinguishable mechanisms.

Measurement of suppressor transfer RNA activity

Transfer RNA (tRNA) suppression of nonsense mutations in prokaryotic systems has been widely used to study the structure and function of different prokaryotic genes. Through genetic engineering techniques, it is now possible to introduce suppressor (Su+) tRNA molecules into mammalian cells. A quantitative assay of the suppressor tRNA activity in these mammalian cells is described; it is based on the amount of tRNA-mediated readthrough of a terminating codon in the influenza virus NS1 gene after the cells are infected with virus. Suppressor activity in L cells continuously expressing Su+ (tRNAtyr) was 3.5 percent and that in CV-1 cells infected with an SV40- Su+ (tRNAtyr) recombinant was 22.5 percent.

Functional suppression in mammalian cells of nonsense mutations in the herpes simplex virus thymidine kinase gene by suppressor tRNA genes

A nonsense mutation (UAG) in the thymidine kinase gene of herpes simplex virus type 1 can be suppressed in vivo to produce active thymidine kinase by prior infection with a defective simian virus 40 stock which acts as a vector to introduce a functional suppressor tRNA gene into mammalian cells in culture. The suppression is specific for UAG, but not UGA or missense, mutants and restores thymidine kinase activity to 20 to 40% of the wild-type level. These results suggest that many cell lines susceptible to simian virus 40 infection may be transiently converted to a suppressor-positive phenotype for use in the genetic study of mammalian viruses.

High-frequency spontaneous mutation in the bacterio-opsin gene in Halobacterium halobium is mediated by transposable elements

We have recently characterized a transposable element, ISH1, which inactivates the bacterio-opsin (BO) gene in two purple membrane-deficient (Pum-) mutants of Halobacterium halobium. Examination of nine additional Pum- mutants now shows that in all of these the BO gene has been inactivated by insertion of one of two types of transposable elements. Four Pum- strains contain ISH1 within the BO gene, probably at the same site that we have previously characterized. A second element, ISH2, which is present in four more strains, inserts at multiple sites within the BO coding sequence. Significantly, another Pum- strain contains the ISH2 element 102 nucleotides upstream from the initiator codon for BO. ISH2, which is 520 nucleotides long, is the smallest insertion sequence known. Its sequence has been determined: it is A + T-rich (53%), contains a 19-base-pair inverted repeat at its termini, and, interestingly, duplicates either 10 or 20 base pairs at the target site during insertion. ISH2 is present in multiple copy numbers in the genome and contains several relatively short open reading frames.

Chemical reactivity of E. coli 5S RNA in situ in the 50S ribosomal subunit

E. coli 50S ribosomal subunits were reacted with monoperphthalic acid under conditions in which non-base paired adenines are modified to their 1-N-oxides. 5S RNA was isolated from such chemically reacted subunits and the two modified adenines were identified as A73 and A99. The modified 5S RNA, when used in reconstitution of 50S subunits, yielded particles with reduced biological activity (50%). The results are discussed with respect to a recently proposed three-dimensional structure for 5S RNA, the interaction of the RNA with proteins E-L5, E-L18 and E-L25 and previously proposed interactions of 5S RNA with tRNA, 16S and 23S ribosomal RNAs.

A transposable element from Halobacterium halobium which inactivates the bacteriorhodopsin gene

We describe the characterization of a transposable element from an archaebacterium. The bacteriorhodopsin genes from the wild-type and two mutant Halobacterium halobium strains have been cloned as BamHI fragments in pBR322. The cloned DNA fragments from the two mutants both contain a 1.1-kilobase-pair insertion sequence (ISH1) near the NH2 terminus of the bacteriorhodopsin coding sequence. ISH1 is present in the two mutants in an identical palindromic site but in opposite orientations. The complete sequence of ISH1 has been determined; it is 1,118 nucleotides long, it has 8-base-pair interrupted inverted repeats at the ends, and it duplicates an 8-base-pair (A-G-T-T-A-T-T-G) target sequence upon insertion. As for most eukaryotic and some prokaryotic transposable elements, the sequence of the ISH1 begins with T-G and ends in C-A. ISH1 contains an open reading frame 810 nucleotides long and codes for an RNA approximately 900 nucleotides long. The copy number of ISH1 ranges from one to five or more in different H. halobium strains. In at least one of the strains, one copy of ISH1 is present also on a plasmid DNA.

Intron within the large rRNA gene of N. crassa mitochondria: a long open reading frame and a consensus sequence possibly important in splicing

We describe the sequence of the 2295 nucleotide long intron and 245 nucleotides of the flanking exon sequences within the large (24S) rRNA gene of Neurospora crassa mitochondria. The intron contains a long open reading frame, which could correspond to ribosomal protein S5. Comparison with the corresponding intron of the large rRNA gene of yeast mitochondria reveals a single highly homologous 57 nucleotide long sequence, including the sequence (formula; see text), which is present in virtually all the sequenced introns of yeast, Aspergillus nidulans and Zea mays mitochondrial genes, and which may be important for their processing. Sequences closely related to this consensus sequence are also present within all four of the introns of nuclear rRNA genes which have been sequenced. The intron is located within a highly conserved region of the large rRNA sequence and at exactly the same site as in the corresponding introns in yeast mitochondria and also in Physarum polycephalum nuclei.

Establishment of mammalian cell lines containing multiple nonsense mutations and functional suppressor tRNA genes

We describe the generation of mammalian cell lines carrying amber suppressor genes. Nonsense mutants in the herpes simplex virus thymidine kinase (HSV tk) gene, the Escherichia coli xanthine-guanine phosphoribosyl transferase (Eco-gpt) gene and the aminoglycoside 3' phosphotransferase gene of the Tn5 transposon (NPT-II) were isolated and characterized. Each gene was engineered with the appropriate control signals to allow expression in both E. coli and mammalian cells. Expression in E. coli made possible the use of well developed bacterial and phage genetic manipulations to isolate and characterize the nonsense mutants. Once characterized, the nonsense mutants were transferred into mammalian cells by microinjection and used, in turn, to select for amber suppressor genes. Xenopus laevis amber suppressor genes, prepared by site-specific mutagenesis of a normal X. laevis tRNA gene, were microinjected into the above cell lines and selected for the expression of one or more of the amber mutant gene products. The resulting cell lines, containing functional amber suppressor genes, are stable and exhibit normal growth rates.

The nucleotide sequence of blue-green algae phenylalanine-tRNA and the evolutionary origin of chloroplasts

Phenylalanine tRNA from the blue-green alga, Agmenellum quadruplicatum, has been purified to homogeneity. The nucleotide sequence of this tRNA was determined to be: (see tests) Comparisons of the sequence and the modified nucleosides of this tRNA with those of other tRNAPhes thus far sequenced, indicate that this blue green algal tRNAPhe is typically prokaryotic and closely resembles the chloroplast tRNAPhes of higher plants and Euglena. The significance of this observation to the evolutionary origin of chloroplasts is discussed.

An amber suppressor tRNA gene derived by site-specific mutagenesis: cloning and function in mammalian cells

We describe the synthesis, cloning, expression, and in vivo function of a suppressor tRNA gene in mammalian cells. By using "primer-directed mutagenesis" on a Xenopus laevis tyrosine tRNA gene cloned into the recombinant single-strand phage M13mp5, we have generated an amber suppressor tRNA gene that has a nucleotide change--GTA leads to CTA--in the anticodon sequence. The suppressor (Su) tRNA gene was introduced into monkey kidney cells (CV-1) by using simian virus 40 (SV40) DNA as vector (SV40-tRNATyrSu+). CV-1 cells infected with virus containing the mutant, but not the wild-type, tRNA gene produce a functional amber suppressor tRNA as indicated by suppression of amber mutations in co-infecting adenovirus serotype 2-SV40 hybrids. Further evidence that suppression of these amber mutations is tRNA mediated was derived by isolation of total tRNA from CV-1 cells infected with the SV40-tRNATyr (Su+) recombinant and its use in demonstration of read through of an amber codon during in vitro translation of tobacco mosaic virus RNA in reticulocyte extracts. Interestingly, the amplification of an amber suppressor gene in CV-1 cells does not interfere with SV40 production, suggesting that suppression of amber codons may not be very deleterious to mammalian cell metabolism.

Expression of a X. laevis tRNATyr gene in mammalian cells

Expression of a X. laevis tRNATyr gene has been studied in mammalian cells. This tRNATyr gene has a 13 base intervening sequence adjacent to its anticodon. A fragment containing the tRNATyr gene was cloned into the late region of SV40. Cells infected with a recombinant virus stock vastly overproduce a tRNATyr that is properly spliced, processed and modified. It was also found that the X. laevis tRNATyr is identical or nearly identical to an endogenous tRNATyr of monkey kidney cells. The possibility of using the X. laevis tRNATyr gene to create an amber suppressor for mammalian cells is discussed.

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.

Cytochrome oxidase subunit III gene in Neurospora crassa mitochondria. Location and sequence

We have located and sequenced the gene for cytochrome oxidase subunit III (CoIII) in Neurospora crassa mitochondria. The CoIII gene is located downstream from the small rRNA gene within a cluster of tRNA genes and is coded by the same strand as the tRNA and the rRNA genes. Like the tRNA and the rRNA genes, the CoIII gene is also flanked by the GC-rich palindromic DNA sequences which are highly conserved in N. crassa mitochondria. The CoIII coding sequence predicts a protein 269 amino acids long including 8 tryptophan residues. All 8 tryptophan residues are coded for by UGA. This supports our previous conclusion based on the anticodon sequence of N. crassa mitochondrial tryptophan tRNA and provides evidence for the notion that use of UGA as a codon for tryptophan rather than chain termination may be a feature common to most mitochondrial protein synthesis systems. The close correspondence between the amino acid composition of N. crassa CoIII and that of the protein predicted by the CoIII gene sequence suggests that unlike in mammalian mitochondria, AUA is a codon for isoleucine and not for methionine in N. crassa mitochondria. The N. crassa CoIII sequence shows strong homologies to the corresponding yeast and human proteins (53 and 47%, respectively). The overall hydrophobic character of the protein is consistent with suggestions that most of CoIII is embedded in the mitochondrial inner membrane.

Structure and organization of tRNA, rRNA, and protein genes in neurospora crassa mitochondria

Our studies on Neurospora crassa mitochondria have included sequence analysis of tRNAs, mapping and cloning of the tRNA, rRNA, and protein genes and the DNA sequence analysis of these genes. Results from tRNA sequence analyses explain how the mitochondrial protein synthesizing system can function with a much smaller number of tRNAs than other systems. Mapping studies have shown that the two rRNA genes and almost all of the tRNA genes are clustered onto a third of the mitochondrial genome. The two rRNA genes and all of the tRNA genes are coded for by the same DNA strand. DNA sequence analysis has provided several interesting results. Twenty-four tRNA genes have been identified. Highly conserved GC rich palindromic sequences flank tRNA genes. The intervening sequence within the large rRNA gene has a long open reading frame capable of coding for a protein 426 amino acids long. The gene for cytochrome oxidase subunit 3 has been localized within the tRNA-rRNA gene cluster and has been sequenced. This gene is also flanked by the highly conserved GC rich palindromic DNA sequences.

Highly conserved GC-rich palindromic DNA sequences flank tRNA genes in Neurospora crassa mitochondria

In sequencing a 2200 bp region of the Neurospora crassa mitochondrial DNA encoding the 3' end of the large rRNA gene and a cluster of six tRNA genes, we have found that the tRNA genes are flanked by highly conserved GC-rich palindromic DNA sequences. An 18 bp long core sequence, 5'-CC CTGCAG TA CTGCAG GG-3', containing two closely spaced Pst I sites, is common to all these palindromic sequences. Each of the eight Pst I sites mapped in the 2200 bp region consists of two closely spaced Pst I sites; thus this 2200 bp long segment actually contains 16 Pst I sites. Between 5-10% of the N. crassa DNA may consist of these GC-rich palindromic sequences that include the 18 base long core sequence. The same core sequence is present within both the 5' and 3' side of the intervening sequence of the large rRNA gene, close to, but not at, the intron-exon boundaries. We discuss probable roles for these sequences in N. crassa mitochondrial function, including their role as signals either in the synthesis or processing (or both) of RNA in the mitochondria.

Site-specific mutagenesis on cloned DNAs: generation of a mutant of Escherichia coli tyrosine suppressor tRNA in which the sequence G-T-T-C corresponding to the universal G-T-pseudouracil-C sequence of tRNAs is changed to G-A-T-C

We have cloned the Escherichia coli tyrosine-inserting amber suppressor tRNA gene into the recombinant single-strand phage M12mp3. By using the M13mp3SuIII+ recombinant phage DNA as template and an oligonucleotide bearing a mismatch as primer, we have synthesized in vitro an M13mp3SuIII heteroduplex DNA that has a single mismatch at a predetermined site in the tRNA gene. Transformation of E. coli with the heteroduplex DNA yielded M13 recombinant phages carrying a mutant suppressor tRNA gene in which the sequence G-T-T-C, corresponding to the universal G-T-pseudouracil-C sequence in E. coli tRNAs, is changed to G-A-T-C. The mutant DNA has been characterized by restriction mapping and by sequence analysis. In contrast to results with the wild-type suppressor tRNA gene, cells transformed with recombinant plasmids carrying the mutant tRNA gene are phenotypically Su-. Thus, the single nucleotide change introduced has inactivated the function of the tRNA gene. By using E. coli minicells for studying the expression in vivo of cloned tRNA genes, we have found that cells transformed with recombinant plasmids carrying the mutant tRNA gene contain very little, if any, mature mutant suppressor tRNA. In contrast, the predominant low molecular weight RNA in cells transformed with recombinant plasmids carrying the wild-type suppressor tRNA gene is the mature tyrosine suppressor tRNA. Thus, while our results imply an important role for the G-T-pseudouracil-C sequence common to all E. coli tRNAs, whether this sequence is essential for tRNA biosynthesis, tRNA stability in vivo, or tRNA function remains to be determined. The procedures used to generate the mutant should be of general application toward site-specific mutagenesis on cloned DNAs, including regions that possess high degrees of secondary structure. In addition, the frequency of mutants among the progeny is high enough to enable one to identify and isolate site-specific mutants on any cloned DNA without requiring phenotypic selection.

The nucleotide sequence of Euglena cytoplasmic phenylalanine transfer RNA. Evidence for possible classifications of Euglena among the animal rather than the plant kingdom

The nucleotide sequence of cytoplasmic phenylalanine tRNA from Euglena gracilis has been elucidated using procedures described previously for the corresponding chloroplastic tRNA [Cell, 9, 717 (1976)]. The sequence is: pG-C-C-G-A-C-U-U-A-m(2)G-C-U-Cm-A-G-D-D-G-G-G-A-G-A-G-C-m(2)2G-psi-psi-A-G-A-Cm -U-Gm-A-A-Y-A-psi-C-U-A-A-A-G-m(7)G-U-C-*C-C-U-G-G-T-psi-C-G-m(1)A-U-C-C-C-G-G- G-A-G-psi-C-G-G-C-A-C-C-A. Like other tRNA Phes thus far sequenced, this tRNA has a chain length of 76 nucleotides. The sequence of E. gracilis cytoplasmic tRNA Phe is quite different (27 nucleotides out of 76 different) from that of the corresponding chloroplastic tRNA but is surprisingly similar (72 out of 76 nucleotides identical) to that of tRNA Phe from mammalian cytoplasm. This extent of sequence homology even exceeds that found between E. gracilis and wheat germ cytoplasmic tRNA Phe. These findings raise interesting questions on the evolution of tRNAs and the taxonomy of Euglena.

Bacteriorhodopsin: partial sequence of mRNA provides amino acid sequence in the precursor region

mRNA for bacteriorhodopsin from Halobacterium halobium has been partially purified. By using this mRNA as template in the presence of reverse transcriptase RNA-dependent DNA nucleotidyltransferase and a 5'-[32P] synthetic oligodeoxyribonucleotide corresponding to amino acids 9-12 of bacteriorhodopsin as primer, we have isolated the major 5'-[32P]cDNA product, approximately 80 nucleotides long, and determined its sequence. Based on the cDNA sequence, the 5'-proximal sequence of bacteriorhodopsin mRNA is G-C-A-U-G-U-U-G-G-A-G-U-U-A-U-U-G-C-C-A-A-C-A-G-C-A-G-U-G-G-A-G-G-G-G-G-U-A-U-C -G-C-A-G-G-C-C-C-A-G-A-U-C-A-C-C-G-G-A-C-G-U-C-C-G. This includes the expected sequence for amino acids 1-8 and shows that bacteriorhodopsin is synthesized as a precursor that is at least 13 amino acids longer (Met-Leu-Glu-Leu-Leu-Pro-Thr-Ala-Val-Glu-Gly-Val-Ser) at the NH2 terminus. Agarose/urea gel electrophoresis of the partially purified mRNA showed several bands; of these, a major one hybridized with 5'-[32P]cDNA. These results suggest that the bacteriorhodopsin mRNA in the partially purified preparation is homogeneous in size and that it constitutes a substantial portion of the RNA preparation subjected to electrophoresis.

Dispersed 5S RNA genes in N. crassa: structure, expression and evolution

The 5S RNA genes (5S genes) in N. crassa are not tandemly arranged or tightly clustered as in other eucaryotes that have been examined. 55 RNA or cloned 5S DNA hybridizes to at least 30 different restriction fragments of Neurospora DNA. Of 34 5S DNA clones examined, each contains a single 5S gene. Saturation hybridization analyses indicate that there are about 100 copies of 5S genes in the genome of this organism. We have partially or completely sequenced the 5S region of 15 clones. Both identical and highly divergent 5S coding regions were found. Nine are of one type (alpha). The other six include four different types (beta, beta', gamma and delta) which differ from each other and from the alpha genes to various degrees. Eleven of 15 genes have distinct flanking regions. Analysis of Neurospora 5S RNA showed that it consists of one principal species which matches the alpha-type gene sequence. Additional 5S species corresponding to the less abundant 5S gene types were also detected. The pattern of nucleotide substitutions between the predicted Neurospora 5S RNAs and between these and S. cerevisiae 5S RNA suggests that a particular 5S RNA secondary structure occurs in vivo and is conserved.

Novel features in the genetic code and codon reading patterns in Neurospora crassa mitochondria based on sequences of six mitochondrial tRNAs

We report the sequences of Neurospora crassa mitochondrial alanine, leucine(1), leucine(2), threonine, tryptophan, and valine tRNAs. On the basis of the anticodon sequences of these tRNAs and of a glutamine tRNA, whose sequence analysis is nearly complete, we infer the following: (i) The N. crassa mitochondrial tRNA species for alanine, leucine(2), threonine, and valine, amino acids that belong to four-codon families (GCN, CUN, ACN, and GUN, respectively; N = U, C, A, or G) all contain an unmodified U in the first position of the anticodon. In contrast, tRNA species for glutamine, leucine(1), and tryptophan, amino acids that use codons ending in purines (CA(G) (A), UU(G) (A), and UG(G) (A), respectively) contain a modified U derivative in the same position. These findings and the fact that we have not detected any other isoacceptor tRNAs for these amino acids suggest that N. crassa mitochondrial tRNAs containing U in the first position of the anticodon are capable of reading all four codons of a four-codon family whereas those containing a modified U are restricted to reading codons ending in A or G. Such an expanded codon-reading ability of certain mitochondrial tRNAs will explain how the mitochondrial protein-synthesizing system operates with a much lower number of tRNA species than do systems present in prokaryotes or in eukaryotic cytoplasm. (ii) The anticodon sequence of the N. crassa mitochondrial tryptophan tRNA is U(*)CA and not CCA or CmCA as is the case with tryptophan tRNAs from prokaryotes or from eukaryotic cytoplasm. Because a tRNA with U(*)CA in the anti-codon would be expected to read the codon UGA, as well as the normal tryptophan codon UGG, this suggests that in N. crassa mitochondria, as in yeast and in human mitochondria, UGA is a codon for tryptophan and not a signal for chain termination. (iii) The anticodon sequences of the two leucine tRNAs indicate that N. crassa mitochondria use both families of leucine codons (UU(A) (G) and CUN; N = U, C, A, or G) for leucine, in contrast to yeast mitochondria [Li, M. & Tzagoloff, A. (1979) Cell 18, 47-53] in which the CUA leucine codon and possibly the entire CUN family of leucine codons may be translated as threonine.

The nucleotide sequence of phenylalanine tRNA from the cytoplasm of Neurospora crassa

The phenylalanine tRNA from the cytoplasm of Neurospora crassa has been purified and sequenced. The sequence is: pGCGGGUUUAm2GCUCA (N) GDDGGGAGAGCm22GpsiCAGACmUGmAAYApsim5CUGAAGm7GDm5CGUGUGTpsiCGm1AUCCACACAAACCGCACCAOH. Both in the nature of modified nucleotides which are present in this tRNA and in the overall sequence, this tRNA resembles more closely phenylalanine tRNAs of eukaryotic cytoplasm than those of prokaryotes. The sequence of this tRNA differs from those of the corresponding tRNAs of wheat germ and yeast by only 6 and 7 nucleotides respectively out of 76 nucleotides.U

Secondary structure of mouse and rabbit alpha- and beta-globin mRNAs: differential accessibility of alpha and beta initiator AUG codons towards nucleases

The nucleotide sequence from the 5' terminus inward of one third of mouse alpha- and beta maj-globin messenger RNAs has been established. In addition, using 5' 32P end-labeled mRNAs as substrates and S1 and T1 nucleases as probes for single-stranded regions, the secondary structures of mouse and rabbit alpha- and beta-globin mRNAs have been analyzed. Our results indicate that the AUG initiator codon in both mouse and rabbit beta-globin mRNA is quite susceptible to cleavage with S1 and T1 nucleases, suggesting that it resides in a single-stranded exposed region. In contrast, the initiator AUG in the alpha-globin mRNA of both species is inaccessible to cleavage, indicating that it is either buried by tertiary structure or is base-paired. Since the rate of initiation of protein synthesis with beta-globin mRNA in rabbit reticulocyte is 30--40% faster than for alpha-globin mRNA, these results imply a possible correlation between the differential rates of initiation with these two mRNAs and the accessibility of the respective AUG initiator codons.