Changes in tertiary structure accompanying a single base change in transfer RNA. Proton magnetic resonance and aminoacylation studies of Escherichia coli tRNAMet f1 and tRNAMet f3 and their spin-labeled (s4U8) derivatives.

The properties of Escherichia coli tRNAMet f1 and tRNAMet f3 that differ by only one base change, m7G to A at position 47, have been compared structurally by proton magnetic resonance and functionally by the aminoacylation reaction. The NMR spectra of the two tRNA species in the region between 0 and 4 ppm below 4,4-dimethyl-4-silapentane-1-sulfonic acid (DSS) (methyl and methylene region) were the same except for the absence of the lowest field peak at 3.8 ppm in tRNAMet f3, thus unequivocally identifying this resonance at the methyl group of m7G47 of tRNAMet f1. The same resonance disappears in tRNAMet f1 spin-labeled at s4U8 and reappears in the diamagnetic reduced spin-labeled tRNAMet f1 from which the average distance between the spin-label and the methyl protons of m7G is estimated to be less than 15 A. The proximity of m7G47 but not T55 to s4U8 in the structure of E. coli tRNAMet f1 in solution is consistant with the crystallographic model for yeast tRNAPhe. A spectral comparison of the hydrogen-bond regions (11-14 ppm below DSS) of tRNAMet f1 and tRNAMet f3 reveals major shifts of four resonances previously assigned to tertiary hydrogen bonds. Of the four, the one at lowest field (14.8 ppm) had been assigned by chemical modification to the tertiary (s4U8-A14) hydrogen bond and the one at 13.3 ppm had been tentatively assigned to the tertiary hydrogen bond G23-m7G47 of the 13-23-47 triple. A more positive assignment of the G23-m7G47 at 13.3 ppm could be made from the additional evidence that this resonance, which was first observed in the difference spectrum between spin-labeled tRNAMet f1 and its reduced form, is the only one missing in the analogous difference spectrum of tRNAMet f3. At low ionic strength and in the absence of magnesium ions, the differences in the hydrogen-bonded region of the NMR spectra of tRNAMet f1 and tRNAMet f3 are much greater than in the presence of magnesium ions. The optimal magnesium concentration required for maximal initial velocities is also higher for tRNAMet f3 than for tRNAMet f1. The perturbation caused by the spin-label in destabilizing hydrogen bonds in the region between 13 and 14 ppm is greater for tRNAMet f3 than tRNAMet f1 but the distance relations for the hydrogen bonds in the region between 12 and 13 ppm (the major paramagnetic perturbations) are conserved in the two species. The disruption of one hydrogen bond relative to native tRNAMet f1 either by spin-labeling (s4U8-A14) or by substitution of m7G by A in tRNAMet f3 has little effect on the aminoacyl acceptor activity or the velocity of the aminoacylation reaction at optimal magnesium concentration, but the absence of both tertiary hydrogen bonds in the augmented D-helix region in the spin-labeled tRNAMet f3 results in approximately 60% reduction both in acceptance activity and in initial velocity of the aminoacylation reaction.     

Chemical and physical properties of mammalian mitochondrial aminoacyl-transfer RNAs. II. Analysis of 7-methylguanosine in mitochondrial and cytosolic aminoacyl-transfer RNAs.

The 7-methylguanosine (m7G) content of two individual mitochondrial tRNAs, labelled in the aminoacyl moiety was assayed by the specific cleavage of the tRNA at this nucleotide followed by electrophoretic analysis to identify the 3'-terminal fragment of the tRNA. Neither Syriam hamster mitochondrial tRNALeu nor tRNAMet were found to contain m7G. In contrast, cytosolic tRNAMetS were cleaved indicating the presence of m7G, apparently 27--28 and 29 nucleotides from their 3' terminus. Cystolic tRNALeu was not cleaved. These results are discussed in relationship to the reported low content of methylated nucleosides in mitochondrial 4 S RNA.     

Distribution of family-specific sequence homologies in six families of isoaccepting tRNAs

The nucleotide occupancy of 288 sequences of tRNA has been analyzed for every position on the standard tRnA sequence, except for the anticodon and the variable regions of the D and V loops. Modified nucleotides were assimilated to the canonical nucleotide from which they derive. A X2 test applied at the P = 0.01 level of significance showed family-specific patterns in each of the 6 isoacceptor families (tRNAMet, tRNAPhe, tRNALeu, tRNASer, tRNAVal and tRNAGly) where enough sequences are known to apply the test. The number of positions showing such a pattern ranged from 6 in the tRNASer and tRNAVal families to 15 in the tRNAMet, which is mostly formed of initiator tRNAs. Seven positions (12, 22, 31, 39, 44, 59 and 73) showed homologies in at least four families. The localization of most homologous nucleotides on the tRNA molecule makes it plausible that they interact with the recognition of the aminoacyl tRNA synthetase or, in a few cases, with the anticodon-codon recognition. A few positions (44, 59, 63) show homologies which are difficult to explain by a common functional constraint according to current ideas on the structure and function of tRNAs.     

Isolation and characterization of rabbit anti-m7G-5''-P antibodies of high apparent affinity.

Antibodies highly specific for intact pm7G (7methylguanosine-5'-mono-phosphate) were induced by immunization of rabbits with a pm7G-BSA conjugate. Since the nucleotide is six-fold more stable than m7G (7-methylguanosine) to alkali-catalyzed fission of the imidazole ring, it is a more desirable antigen for obtaining antibodies capable of binding caps on eukaryotic mRNA. UV spectra demonstrated that the nucleotide in the conjugate was predominantly the intact form. Competition radioimmunoassay showed 1) high apparent affinities for pm7G, on the order of 10(-8)M, 2) low competition by the ring-opened form of the homologous hapten (*pm7G), and by m7G, 3) little or no competition by AMP, GMP, CMP, UMP or m6A, and 4) high apparent affinities for m7GpppAm, m7GpppN6MAm, m7GpppGm, m7GpppA.     

Nucleotide sequence of a lysine tRNA from Bacillus subtilis.

A lysine tRNA (tRNA1Lys) was purified from Bacillus subtilis W168 by a consecutive use of several column chromatographic systems. The nucleotide sequence was determined to be pG-A-G-C-C-A-U-U-A-G-C-U-C-A-G-U-D-G-G-D-A-G-A-G-C-A-U-C-U-G-A-C-U-U(U*)-U-U-K-A-psi-C-A-G-A-G-G-m7G(G)-U-C-G-A-A-G-G-T-psi-C-G-A-G-U-C-C-U-U-C-A-U-G-G-C-U-C-A-C-C-AOH, where K and U* are unidentified nucleosides. The nucleosides of U34 and m7G46 were partially substituted with U* and G, respectively. The binding ability of lysyl-tRNA1Lys to Escherichia coli ribosomes was stimulated with ApApA as well as ApApG.     

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.     

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.     

Effect of sequence context on O(6)-methylguanine repair and replication in vivo.

Understanding the origins of mutational hotspots is complicated by the intertwining of several variables. The selective formation, repair, and replication of a DNA lesion, such as O(6)-methylguanine (m(6)G), can, in principle, be influenced by the surrounding nucleotide environment. A nearest-neighbor analysis was used to address the contribution of sequence context on m(6)G repair by the Escherichia coli methyltransferases Ada or Ogt, and on DNA polymerase infidelity in vivo. Sixteen M13 viral genomes with m(6)G flanked by all permutations of G, A, T, and C were constructed and individually transformed into repair-deficient and repair-proficient isogenic cell strains. The 16 genomes were introduced in duplicate into 5 different cellular backgrounds for a total of 160 independent experiments, for which mutations were scored using a recently developed assay. The Ada methyltransferase demonstrated strong 5' and 3' sequence-specific repair of m(6)G in vivo. The Ada 5' preference decreased in the general order: GXN > CXN > TXN > AXN (X = m(6)G, N = any base), while the Ada 3' preference decreased in the order: NX(T/C) > NX(G/A), with mutation frequencies (MFs) ranging from 35% to 90%. The Ogt methyltransferase provided MFs ranging from 10% to 25%. As was demonstrated by Ada, the Ogt methyltransferase repaired m(6)G poorly in an AXN context. When both methyltransferases were removed, the MF was nearly 100% for all sequence contexts, consistent with the view that the replicative DNA polymerase places T opposite m(6)G during replication irrespective of the local sequence environment.     

5'-Terminal and internal methylated nucleotide sequences in HeLa cell mRNA.

The 5'-terminal oligonucleotides m7G(5')ppp(5')NmpNp and m7G(5')ppp(5')NmpNmpNp were isolated by DEAE-cellulose column chromatography after enzymatic digestion of 32P- or methyl-3H-labeled poly(A)" HeLa cell mRNA. The recovery of such oligonucleotides indicated that a high percentage of mRNA has blocked termini. The dimethylated nucleoside, N6, O2'-dimethyladenosine (m6Am), as well as the four common 2'-O-methylribonucleosides (Gm, Am, Um, Cm) were present in the second position linked through the triphosphate bridge to 7-methylguanosine (m7G) whereas little m6Am was in the third position. The only internal methylated nucleoside, N6-methyladenosine (m6A), was found exclusively as m6ApC and Apm6ApC after digestion with RNase A, T1, and alkaline phosphatase. Digestion with RNase A and alkaline phat pyrimidines are present in much smaller amounts or absent from this position. These results imply a considerable sequence specificity since there are thousands of different mRNA species in HeLa cells. Our studies are consistent with the following model of HeLa cell mRNA in which Nm may be m6Am, Gm, Cm, Um, or Am and one or more m6A residues are present at an unspecified internal location: m7G(5')ppp(5')Nm-(Nm)---(G or A)-m6A-C---(A)100-200A.     

Growth-active peptides are produced from alpha-lactalbumin and lysozyme

We determined the growth-active domains of milk-growth factor (MGF), human alpha-lactalbumin (HMLA) and human lysozyme (HMLZ), and their sequences. Fetal calf serum (FCS) showed inhibitors against proteases. The growth-stimulation of IMR90 cells in CG medium (free-serum) without FCS was induced in a dose-dependent manner up to 400 ng/ml of HMLA, HMLZ or chicken lysozyme (ChLZ), and also in a time-dependent manner until 48 h but was induced gradually until 1000 ng/ml of bovine alpha-lactalbumin (BVLA). The HMLAL6-peptide (HMLAL6), a cleaved product from HMLA by Endpeptidase Lys C, was growth-stimulative. The sequence of HMLAL6 was matched to 35 amino-acid residues (from No. 59 to No. 93 of HMLA), owing to the sequences of HMLAL6R3, HMLAL6R5 and HMLAL6R7 after the reduction of HMLAL6. The sequences of the reduced peptides from MGFL7-peptide (MGFL7: a cleaved product from MGF by Endpeptidase lysine C matched to those of the peptides from HMLAL6, and were similarly identified as the partial sequence of HMLA (59-93, H(2)N-L.W.C.?.K./S.S.Q.V.P.Q.S.R.N.I.?.D.I.S.?.D.K./F.L. D.D.D.I.T.D.D.I.M.?.A.-COOH). The sequence of HMLZ is similar to that of HMLA. HMLZT7-peptide (HMLZT7), a cleaved product of HMLZ by trypsin, was confirmed to have growth-stimulating activity and it's sequence was partially identified as Y. W.?.N.D.G.K.T.P.G.A.V.N.A.?.H.L. -, owing to the results of HMLZT7R1 (reduction of HMLZT7) and HMLZA7R2 (reduction of HMLZA7-peptide (HMLZA7) cleaved product of HMLZ by Endpeptidase Arg C) and is accordingly the sequence from No. 63 to No. 97 of HMLZ. Therefore, the peptides produced from LA and LZ by proteolysis may play a role of growth-stimulation.     

A new gypsy-type retrotransposon, RIRE7: preferential insertion into the tandem repeat sequence TrsD in pericentromeric heterochromatin regions of rice chromosomes

A portion of an insertion sequence present in a member of the RIRE3 family of retrotransposons in Oryza sativa L. cv. IR36 was found to have an LTR sequence followed by a PBS sequence complementary to the 3'-end region of tRNAMet, indicative of another rice retrotransposon (named RIRE7). Cloning and sequencing of PCR-amplified fragments that made up all parts of the RIRE7 sequence showed that RIRE7 is a gypsy-type retrotransposon with partial homology in the pol region to the rice gypsy-type retrotransposons RIRE2 and RIRE3 identified in rice previously. Interestingly, various portions of the RIRE7 sequence were homologous to several DNA segments present in the centromere regions of cereal chromosomes. Further cloning and nucleotide sequencing of fragments flanking RIRE7 copies showed that RIRE7 was inserted into a site within a tandem repeat sequence that has a unit length of 155 bp. The tandem repeat sequence, named TrsD, was homologous to tandem repeat sequences RCS2 and CentC, previously identified in the centromeric regions of rice and maize chromosomes. Fluorescence in situ hybridization (FISH) analysis of the metaphase chromosomes of O. sativa cv. Nipponbare showed that both RIRE7 and TrsD sequences were present in the centromere regions of the chromosomes. The presence of RIRE7 and the TrsD sequences in the centromere regions of several chromosomes was confirmed by the identification of several YAC clones whose chromosomal locations are known. Further FISH analysis of rice pachytene chromosomes showed that the TrsD sequences were located in a pericentromeric heterochromatin region. These findings strongly suggest that RIRE7 and TrsD are components of the pericentromeric heterochromatin of rice chromosomes.     

Sequence specificity of internal methylation in B77 avian sarcoma virus RNA subunits.

Following ribonuclease digestion of methyl-3H-labeled B77 avian sarcoma virus RNA subunits, methylated oligonucleotides were isolated by diethylaminoethylcellulose chromotogrpahy. Partial nucleotide sequences were deduced from the known enzymatic specificities of the ribonucleases. In addition to methylated nucleosides in the 5'-terminal cap structure, m7G(5')GmpCp, N6-methyladenosine(m6A) was found to be present in only two internal sequences of the RNA molecule, Gpm6ApC and Apm6ApC. The average numbers of methylated nucleosides per RNA subunit are about 12-13 in Gpm6ApC, 1-2 in Apm6ApC, and 2 in m7GpppGmpCp. The sequences containing m6A in B77 sarcoma virus RNA are identical to m6A-containing sequences previously reported for the bulk mRNA from HeLa cells (Wei, C.M., Gershowitz, A., and Moss, B. (1976), Biochemistry 15, 397-401). Analysis of the oligonucleotides produced by RNase A digestion indicated that the sequence of bases on the 5' side of these trinucleotides is not specific. The oligonucleotide profile, however, was highly reproducible in different virus preparations. This suggests that the methylations occur at specific positions on the RNA molecule. Some of the methylated oligonucleotides produced by RNase A digestion appear to be present in less than molar amounts. Several hypotheses are proposed to explain this result.     

Nucleotide sequences of tobacco chloroplast genes for elongator tRNAMet and tRNAVal (UAC): the tRNAVal (UAC) gene contains a long intron.

The nucleotide sequences of tobacco chloroplast genes for elongator tRNAMet and tRNAVal (UAC) have been determined. The tRNAVal gene contains a 571 base pairs intron located in the anticodon loop. The tRNAVal gene is transcribed as a 750 bases precursor RNA molecule. Both tRNAs deduced from the DNA sequences show 97% sequence homologies with those of spinach chloroplasts.