Mammalian tRNA genes: nucleotide sequence of rat genes for tRNAAsp, tRNAGly and tRNAGlu

Modification of the 5' terminus of Sindbis virus genomic RNA allows nsP4 RNA polymerases with nonaromatic amino acids at the N terminus to function in RNA replication

We have previously shown that Sindbis virus RNA polymerase requires an N-terminal aromatic amino acid or histidine for wild-type or pseudo-wild-type function; mutant viruses with a nonaromatic amino acid at the N terminus of the polymerase, but which are otherwise wild type, are unable to produce progeny viruses and will not form a plaque at any temperature tested. We now show that such mutant polymerases can function to produce progeny virus sufficient to form plaques at both 30 and 40 degrees C upon addition of AU, AUA, or AUU to the 5' terminus of the genomic RNA or upon substitution of A for U as the third nucleotide of the genome. These results are consistent with the hypothesis that (i) 3'-UA-5' is required at the 3' terminus of the minus-strand RNA for initiation of plus-strand genomic RNA synthesis; (ii) in the wild-type virus this sequence is present in a secondary structure that can be opened by the wild-type polymerase but not by the mutant polymerase; (iii) the addition of AU, AUA, or AUU to the 5' end of the genomic RNA provides unpaired 3'-UA-5' at the 3' end of the minus strand that can be utilized by the mutant polymerase, and similarly, the effect of the U3A mutation is to destabilize the secondary structure, freeing 3'-terminal UA; and (iv) the N terminus of nsP4 may directly interact with the 3' terminus of the minus-strand RNA for the initiation of the plus-strand genomic RNA synthesis. This hypothesis is discussed in light of our present results as well as of previous studies of alphavirus RNAs, including defective interfering RNAs.

d(GA x TC)(n) microsatellite DNA sequences enhance homologous DNA recombination in SV40 minichromosomes

The genomic distribution of the abundant eukaryotic d(GA x TC)(n) DNA microsatellite suggests that it could contribute to DNA recombination. Here, it is shown that this type of microsatellite DNA sequence enhances DNA recombination in SV40 minichromosomes, the rate of homologous DNA recombination increasing by as much as two orders of magnitude in the presence of a d(GA x TC)(22) sequence. This effect depends on the region of the SV40 genome at which the d(GA x TC)(22) sequence is cloned. It is high when the sequence is located proximal to the SV40 control region but no effect is observed when located 3.5 kb away from the SV40 ori. These results indicate that the recombination potential of d(GA x TC)(n) sequences is likely linked to DNA replication and/or transcription. The potential contribution of the structural properties of d(GA x TC)(n) sequences to this effect is discussed.

Structure and phylogenetic analysis of an endogenous retrovirus inserted into the human growth factor gene pleiotrophin

A human endogenous retrovirus-like element (HERV), flanked by long terminal repeats of 502 and 495 nucleotides is inserted into the human pleiotrophin (PTN) gene upstream of the open reading frame. Based on its Glu-tRNA primer binding site specificity and the location within the PTN gene, we named this element HERV-E.PTN. HERV-E.PTN appears to be a recombined viral element based on its high homology (70 to 86%) in distinct areas to members of two distantly related HERV type C families, HERV-E and retrovirus-like element I (RTVL-I). Furthermore, its pseudogene region is organized from 5' to 3' into gag-, pol-, env-, pol-, env-similar sequences. Interestingly, full-length and partial HERV-E.PTN-homologous sequences were found in the human X chromosome, the human hereditary haemochromatosis region, and the BRCA1 pseudogene. Finally, Southern analyses indicate that the HERV-E.PTN element is present in the PTN gene of humans, chimpanzees, and gorillas but not of rhesus monkeys, suggesting that genomic insertion occurred after the separation of monkeys and apes about 25 million years ago.

The effect of zinc on the secondary structure of d(GA.TC)n DNA sequences of different length: a model for the formation *H-DNA

Alternating d(GA.TC)n DNA sequences are known to undergo transition to *H-DNA in the presence of zinc. Here, the effect of zinc on the secondary DNA structure of d(GA.TC)n sequences of different length (n = 5, 8, 10 and 19) was determined. Short d(GA.TC)n sequences form *H-DNA with a higher difficulty than longer ones. At bacterial negative superhelical density (- sigma = 0.05), zinc still induces transition to the *H-DNA conformation at a d(GA.TC)10 sequence but shorter sequences do not form *H-DNA. Transition to *H-DNA at a d(GA.TC)8 sequence is observed under conditions which destabilize the DNA double helix such as high negative supercoiling or low ionic strength. Our results indicate that a first step in the transition to *H-DNA is the formation of a denaturation bubble at the centre of the repeated DNA sequence, suggesting that the primary role of zinc is to induce a local denaturation of the DNA double helix. Subsequently, zinc might also participate in the stabilization of the altered DNA conformation through its direct interaction with the bases. Based on these results a model for the formation of *H-DNA is proposed.

Two nucleotides next to the anticodon of cytoplasmic rat tRNA(Asp) are likely generated by RNA editing

The nucleotide sequences of major cytoplasmic tRNA(Asp) from rat liver and rat ascites hepatoma comprise a U32 and C33 next to the anticodon as was confirmed by different procedures. Additionally we identified a tRNA(Asp) with C32 and U33 in a minor proportion. We have shown earlier that the tRNA(Asp) gene is part of a cluster of tRNA genes which is amplified at least ten times in the rat nuclear genome. Six independent isolated clones display identical sequences in the coding region of the tRNA(Asp) gene which differ from tRNA(Asp) in having C32 and T33. Using a combination of single-strand conformation polymorphism (SSCP) analyses and direct sequencing of polymerase chain reaction (PCR) products we have now demonstrated that no variant allele of the tRNA(Asp) gene with T32 and C33 exists in the rat genome. Together with the RNA sequencing data these findings strongly indicate that major rat tRNA(Asp) is generated by post-transcriptional pyrimidine transitions at positions 32 and 33 and that the minor tRNA(Asp) is its unedited precursor.

SV40 recombinants carrying a d(CT.GA)22 sequence show increased genomic instability

Repetitive d(CT.GA)n sequences are commonly found in eukaryotic genomic DNA. They are frequently located in sites involved in genetic recombination or in promoter regions. To test for their possible biological function, a d(CT.GA)22 synthetic sequence was introduced into the genome of SV40, since it constitutes an appropriate model system for eukaryotic chromatin. When SV40 infects permissive cells, it proliferates in the form of a minichromosome. The simple repetitive sequence indicated above was inserted at the unique HpaII site of SV40 (at nt 346), and the genomic stability of SV40 recombinants carrying the d(CT.GA)22 sequence (SV/CT22 viruses) was analyzed. Upon serial passage through permissive CV1 cells, SV/CT22 recombinants show an increased production of defective viruses. Generation of SV/CT22 variants is likely to take place via recombination between and within viral molecules. The enhancement of the rate of recombination induced by the repetitive sequence is likely to be related to its known propensity to form triple-stranded structures. Many different variants coexist in the same viral population indicating that the mechanism by which they are produced is not unique. One variant (SV/X), showing a replicative advantage, was characterized in detail. Variant SV/X accounts for a large proportion of the total viral population. Its genomic organization corresponds to a tandem duplication of an early SV40 DNA fragment spanning from approx. nt 3200-nt 160. Variant SV/X contains a duplicated SV40 ori.

Retroviral and pseudogene insertion sites reveal the lineage of human salivary and pancreatic amylase genes from a single gene during primate evolution

We have analyzed the junction regions of inserted elements within the human amylase gene complex. This complex contains five genes which are expressed at high levels either in the pancreas or in the parotid gland. The proximal 5'-flanking regions of these genes contain two inserted elements. A gamma-actin pseudogene is located at a position 200 base pairs upstream of the first coding exon. All of the amylase genes contain this insert. The subsequent insertion of an endogenous retrovirus interrupted the gamma-actin pseudogene within its 3'-untranslated region. Nucleotide sequence analysis of the inserted elements associated with each of the five human amylase genes has revealed a series of molecular events during the recent history of this gene family. The data indicate that the entire gene family was generated during primate evolution from one ancestral gene copy and that the retroviral insertion activated a cryptic promoter.

Retroviral and pseudogene insertion sites reveal the lineage of human salivary and pancreatic amylase genes from a single gene during primate evolution

We have analyzed the junction regions of inserted elements within the human amylase gene complex. This complex contains five genes which are expressed at high levels either in the pancreas or in the parotid gland. The proximal 5'-flanking regions of these genes contain two inserted elements. A gamma-actin pseudogene is located at a position 200 base pairs upstream of the first coding exon. All of the amylase genes contain this insert. The subsequent insertion of an endogenous retrovirus interrupted the gamma-actin pseudogene within its 3'-untranslated region. Nucleotide sequence analysis of the inserted elements associated with each of the five human amylase genes has revealed a series of molecular events during the recent history of this gene family. The data indicate that the entire gene family was generated during primate evolution from one ancestral gene copy and that the retroviral insertion activated a cryptic promoter.

Diverse soybean actin transcripts contain a large intron in the 5' untranslated leader: structural similarity to vertebrate muscle actin genes

Plant actins are encoded by complex and highly divergent multigene families. Despite the general lack of intron conservation in animal, fungal and protist actin genes, evidence is presented which indicates that higher plant actin genes have an untranslated leader exon with structural similarity to that found in vertebrate actin genes. All functional higher plant actin genes sequenced to date contain a potential intron acceptor site in the 5' untranslated region 10 to 13 nucleotides upstream of the initiator ATG. A leader specific cDNA probe hybridized to sequences over 1.0 kbp upstream from the coding region confirming the presence of an upstream exon. Primer extension of mRNA with gene-specific oligonucleotides was used to analyze the 5' untranslated exon and leader intron from four divergent soybean actin genes, SAc3, 4, 6 and 7. The 5' ends of all four mRNAs are heterogeneous. The consensus promoter elements of the SAc7 actin promoter were identified. Gene specific primer extension sequencing of actin mRNAs indicated that splicing of the 5' leader intron occurred at the predicted acceptor site in SAc6 and SAc7. The SAc6 and SAc7 5' untranslated exons are small (88-111 nt) and the leader introns are relatively large (844-1496 nt). The presence of an intron within the 5' RNA leader and an intron which splits a glycine codon at position 152 in all plant actin genes and all vertebrate muscle actin genes suggests that these structures may have been conserved due to a functional role in actin expression. The 5' regions of these two soybean actin genes contain many unusual features including (CT) repeats and long stretches of pyrimidine-rich DNA. The possible roles of the upstream exon/intron and the C + T-rich regions are discussed.

Flanking sequences are required for efficient transcription and stable complex formation for the human tRNAiMet3-coding gene

An analysis of 5' and 3' deletions of the human tRNAiMet3 gene has revealed upstream regions required for efficient transcription and stable complex formation in vitro. The 5' boundary of this essential region lies between nucleotides -39 to -18 (start point = + 1), and it has been shown that 3'-flanking sequences near the first termination site are also important for stable complex formation. The transcriptional efficiency of two non-allelic loci (TMET3 and TMET2) has been compared and TMET2 is more active. An analysis of chimeric (hybrid) genes indicates that much of the difference seen is due to 5'-flanking sequences and that there may be complex interactions between 5' and 3' sequences.

Effects of 5' flanking sequences and changes in the 5' internal control region on the transcription of rice tRNA % MathType!MTEF!2!1!+-% feaafiart1ev1aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn% hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr% 4rNCHbGeaGqiVu0Je9sqqrpepC0xbbL8F4rqqrFfpeea0xe9Lq-Jc9% vqaqpepm0xbba9pwe9Q8fs0-yqaqpepae9pg0FirpepeKkFr0xfr-x% fr-xb9adbaqaaeGaciGaaiaabeqaamaabaabaaqcKbay-haafaqabe% GabaaabaGaae4raiaabYgacaqG5baabaGaae4raiaaboeacaqGdbaa% aaaa!3CC7!\[\begin{array}{*{20}c} {{\text{Gly}}} \\ {{\text{GCC}}} \\ \end{array} \]

A stretch of 71 nucleotides in a 1.2 kilobase pair Pst I fragment of rice DNA was identified as tRNA% MathType!MTEF!2!1!+-% feaafiart1ev1aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn% hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqtubsr% 4rNCHbGeaGqiVu0Je9sqqrpepC0xbbL8F4rqqrFfpeea0xe9Lq-Jc9% vqaqpepm0xbba9pwe9Q8fs0-yqaqpepae9pg0FirpepeKkFr0xfr-x% fr-xb9adbaqaaeGaciGaaiaabeqaamaabaabaaqcaauaauaabeqace% aaaeaacaqGhbGaaeiBaiaabccacaqG5baabaGaae4raiaaboeacaqG% dbaaaaaa!3BE7!\[\begin{array}{*{20}c} {{\text{Gl y}}} \\ {{\text{GCC}}} \\ \end{array} \] gene by hybridization and nucleotide sequence analyses. The hybridization of genomic DNA with the tRNA gene showed that there are about 10 glycine tRNA genes per diploid rice genome. The 3' and 5' internal control regions, where RNA polymerase III and transcription factors bind, were found to be present in the coding sequence. The gene was transcribed into a 4S product in an yeast cell-free extract. The substitution of 5' internal control region with analogous sequences from either M13mp19 or M13mp18 DNA did not affect the transcription of the gene in vitro. The changes in three highly conserved nucleotides in the consensus 5' internal control region (RGYNNARYGG; R = purine, Y = pyrimidine, N = any nucleotide) did not affect transcription showing that these nucleotides are not essential for promotion of transcription. There were two 16 base pair repeats, 'TGTTTGTTTCAGCTTA' at -130 and -375 positions upstream from the start of the gene. Deletion of 5' flanking sequences including the 16 base pair repeat at -375 showed increased transcription indicating that these sequences negatively modulate the expression of the gene.

Increased levels of glycine tRNA associated with collagen synthesis

Analysis of codon usage for chick Type I collagen indicates that 89% of glycine codons are GGU/C. Since collagens are one-third glycine, chick Type I collagen synthesis should require large amounts of tRNAGly with the anticodon GCC. Earlier chromatographic studies of chick tRNA had indicated that connective tissues showed altered tRNAGly isoacceptor profiles [P. J. Christner and J. Rosenbloom (1976) Arch. Biochem. Biophys. 172, 399-409; H. J. Drabkin and L. N. Lukens (1978) J. Biol. Chem. 253, 6233-6241]. We have therefore used both two-dimensional gel electrophoresis and hybridization analysis to investigate whether collagen synthesis in chick connective tissues is associated with expression of a novel tRNAGly. Liver and calvaria tRNAs produced qualitatively similar patterns when separated on 2-D gels. Northern blots of 2-D-separated tRNAs from liver and calvaria, when hybridized to genes for vertebrate tRNAGly isoacceptors with GCC or UCC anticodons, showed hybridization to the same tRNAs in both tissues. Quantitation of tRNA species by dot blot hybridization indicated an increase in levels of the tRNAGly isoacceptor with anticodon GCC. Tissues synthesizing Type I collagen had a two- to threefold increase in this tRNA while tissues synthesizing Type II collagen showed a more modest increase. We conclude that elevated tRNAGly levels associated with collagen synthesis are due to increased amounts of the same isoacceptor which is the major tRNAGly in other tissues.

Sequence analysis of the glutamate tRNA family: evidence for pseudogenes

Human tRNA(CUCGlu) has been isolated by direct hybridization of the tRNA to 28S ribosomal RNA. We now report the isolation of mouse tRNA(CUCGlu) using the same procedure. Partial sequence analysis of the mouse tRNA shows that it is identical to the human tRNA and to a cloned rat tDNA(CUCGlu) sequence. This mouse tRNA(CUCGlu), however, differs by one nucleotide from a previously cloned mouse tDNA(CUCGlu) sequence, suggesting that the tDNA may be a pseudogene. Further evolutionary comparison of these and other glutamate tRNAs and tDNAs has provided evidence to suggest that two other tDNA(Glu) sequences arose by mutation of functional tRNAGlu genes such that their anticodon sequences were converted from one glutamate isoacceptor to the other. These tDNA sequences may also represent pseudogenes.

The sequences of two nuclear genes and a pseudogene for tRNA(Pro) from the higher plant Phaseolus vulgaris

A genomic bank of nuclear DNA (nDNA) from the higher plant Phaseolus vulgaris, constructed using the lambda EMBL-4 vector, has been screened for the presence of tRNA genes. One of the many positive recombinants was found to hybridise several times stronger than the other positives, and has been shown to contain several tRNA genes. We report the structure of two nuclear tRNA genes for tRNA(Pro), namely tRNA(Pro)(UGG) and tRNA(Pro)(AGG), and that of a 'pseudogene' for tRNA(Pro). This 'pseudogene', despite showing 95% homology with the other tRNA(Pro) species presented here, has several features which are likely to affect its transcription or its functioning as a tRNA.

Nucleotide sequence of a full-length human endogenous retroviral segment

The nucleotide sequence of a full-length (8.8-kilobase) endogenous C-type human retroviral DNA (clone 4-1) is presented and compared with that of Moloney murine leukemia virus (MoMuLV) DNA. Colinearity of deduced amino acids of clone 4-1 with MoMuLV in the gag and pol regions was clearly evident, and overall amino acid homology in these regions was about 40%. Identification of the putative N terminus of gag and p30, the gag-pol junction, and the C terminus of pol could be established on the basis of sequence homology with MoMuLV. Unique characteristics of the endogenous human retroviral DNA included a tRNA Glu primer binding site separated from the 5' long terminal repeat by a pentanucleotide and a putative env sequence which does not appear to overlap the C terminus of pol and has virtually no homology with the env gene of known infectious retroviruses. Clone 4-1 represents a defective prototype of a human C-type retrovirus which integrated into the germ line some time in the distant past.

Studies of defective interfering RNAs of Sindbis virus with and without tRNAAsp sequences at their 5' termini

Three of six independently derived defective interfering (DI) particles of Sindbis virus generated by high-multiplicity passaging in cultured cells have tRNAAsp sequences at the 5' terminus of their RNAs (Monroe and Schlesinger, J. Virol. 49:865-872, 1984). In the present work, we found that the 5'-terminal sequences of the three tRNAAsp-negative DI RNAs were all derived from viral genomic RNA. One DI RNA sample had the same 5'-terminal sequence as the standard genome. The DI RNAs from another DI particle preparation were heterogeneous at the 5' terminus, with the sequence being either that of the standard 5' end or rearrangements of regions near the 5' end. The sequence of the 5' terminus of the third DI RNA sample consisted of the 5' terminus of the subgenomic 26S mRNA with a deletion from nucleotides 24 to 67 of the 26S RNA sequence. These data showed that the 5'-terminal nucleotides can undergo extensive variations and that the RNA is still replicated by virus-specific enzymes. DI RNAs of Sindbis virus evolve from larger to smaller species. In the two cases in which we followed the evolution of DI RNAs, the appearance of tRNAAsp-positive molecules occurred at the same time as did the emergence of the smaller species of DI RNAs. In pairwise competition experiments, one of the tRNAAsp-positive DI RNAs proved to be the most effective DI RNA, but under identical conditions, a second tRNAAsp-positive DI RNA was unable to compete with the tRNAAsp-negative DIs. Therefore, the tRNAAsp sequence at the 5' terminus of a Sindbis DI RNA is not the primary factor in determining which DI RNA becomes the predominant species in a population of DI RNA molecules.

The statistical distribution of nucleic acid similarities

All pairs of a large set of known vertebrate DNA sequences were searched by computer for most similar segments. Analysis of this data shows that the computed similarity scores are distributed proportionally to the logarithm of the product of the lengths of the sequences involved. This distribution is closely related to recent results of Erdos and others on the longest run of heads in coin tossing. A simple rule is derived for determination of statistical significance of the similarity scores and to assist in relating statistical and biological significance.

Structure and transcription of eukaryotic tRNA genes

The availability of cloned tRNA genes and a variety of eukaryotic in vitro transcription systems allowed rapid progress during the past few years in the characterization of signals in the DNA-controlling gene transcription and in the processing of the precurser RNAs formed. This will be the subject matter discussed in this review.

Human U1 RNA genes contain an unusually sensitive nuclease S1 cleavage site within the conserved 3' flanking region

We find that the cloned DNAs of human U1 small nuclear RNA genes contain two nuclease S1-sensitive sites, one about 1.8 kilobases downstream of the U1 RNA coding region and the other around 0.3 kilobase upstream. The downstream site is unusually sensitive to the nuclease, being cleaved in both linear and negatively supercoiled DNAs. The extent of cleavage at this site is enhanced at lower pH and reduced concentrations of NaCl; the effects of salt are more apparent on linear than supercoiled DNAs. The nuclease S1 sensitivity of this downstream site is dependent on the presence of the sequence (dC-dT)n X (dA-dG)n, where n = 15-25. (One gene with n = 5 is resistant to nuclease S1 cleavage in this region.) In contrast, the nuclease S1 site upstream of the coding region is cleaved only when the DNA is supercoiled. This site also has a homopyrimidine X homopurine bias in the DNA strands, but the sequence is less regular. In the course of these studies, we detected several discrepancies between our restriction maps of some U1 RNA genes and those published by others. Our maps demonstrate that all seven cloned human U1 RNA genes are very similar in sequence for as much as 2.3 kilobases downstream of the U1 RNA coding region.

Distinctive termini characterize two families of human endogenous retroviral sequences

Human DNA contains many copies of endogenous retroviral sequences. Characterization of molecular clones of these structures reveals the existence of two related families. One family consists of full-length (8.8 kilobases) proviral structures, with typical long terminal repeates (LTR's). The other family consists of structures, which contain only 4.1 kilobases of gag-pol sequences, bounded by a tandem array of imperfect repeats 72 to 76 base pairs in length. Typical LTR sequences that exist as solitary elements in the genome were cloned and characterized.

The nucleotide sequence of mannosyl-Q-containing tRNAAsp from Xenopus laevis oocytes

The nucleotide sequence of tRNAAsp from X. laevis oocytes was determined as being: (sequence in text) The tRNA is 75 nucleotides long. This sequence is very similar (75% to 97% identity) to all other eukaryotic tRNAAsp sequenced so far, except for the bovine liver tRNAAsp (32% identity). The relation between the presence of a mannosyl group on queuosine (Q) at position 34 and the nucleotide sequence of the anticodon loop is discussed.

Genes and pseudogenes in a reiterated rat tRNA gene cluster

A 13.4 kb rat genomic DNA fragment containing two related tRNA gene clusters was isolated from a rat lambda recombinant and analyzed for gene arrangement and nucleotide sequence. One cluster was found to contain a tRNALeuCUG gene while the second contained a tRNALeuCUA pseudogene with multiple base substitutions. The tRNALeu gene was found to possess an intact coding region and a functional transcription termination signal at the 3' end as demonstrated by in vitro transcription and processing of precursors to mature size tRNA. The first tRNA gene cluster was found to contain in addition to tRNALeu, three other transcribable genes coding for tRNAAspGAC(U), tRNAGlyGGA(G) and tRNAGluGAG; the second cluster contained in addition to tRNALeu pseudogene, the tRNAAsp tRNAGly and tRNAGlu genes. Examination of flanking sequences of the corresponding tRNA genes in the two clusters shows no homology at the 5' ends and partial conservation of sequences at the 3'-end region. Genomic rat DNA blot hybridizations show that the tRNALeu gene is distributed together with the tRNAAsp, tRNAGly and tRNAGlu on a 10 fold repeat of 3.2 kb EcoRI fragment.

Nucleotide sequences of two regions of the human genome containing tRNAAsn genes

The primary structures of two human tRNAAsn genes and 600-700 nucleotides of their flanking regions have been determined from two separate isolates of a fetal DNA library in phage lambda vector. The tRNA gene from one clone differs from the major mammalian tRNAAsn by a single base substitution at position 47, with an A replacing a G, while the tRNAAsn gene from the second clone has base substitutions at positions 17 and 65, with a G replacing a C and a T replacing a C, respectively. The sequences of the noncoding 5'- and 3'-flanking regions of both clones are over 90% homologous. As with other mammalian tRNA genes, these two human tRNAAsn genes contain CTTTTPu, which might act as a transcription termination signal, 11 bp 3' to the structural gene. In vitro transcription experiments in a HeLa cell extract demonstrate that both cloned tRNAAsn genes can be transcribed and processed to mature-sized tRNAs.

Common and distinct regions of defective-interfering RNAs of Sindbis virus

Defective-interfering (DI) particles are helper-dependent deletion mutants which interfere specifically with the replication of the homologous standard virus. Serial passaging of alphaviruses in cultured cells leads to the accumulation of DI particles whose genomic RNAs are heterogeneous in size and sequence composition. In an effort to examine the sequence organization of an individual DI RNA species generated from Sindbis virus, we isolated and sequenced a representative cDNA clone derived from a Sindbis DI RNA population. Our data showed that: (i) the 3' end of the DI RNA template was identical to the 50 nucleotides at the 3' end of the standard RNA; (ii) the majority (75%) of the DI RNA template was derived from the 1,200 5'-terminal nucleotides of the standard RNA and included repeats of these sequences; and (iii) the 5' end of the DI RNA template was not derived from the standard RNA, but is nearly identical to a cellular tRNAAsp (S. S. Monroe and S. Schlesinger, Proc. Natl. Acad. Sci. U.S.A. 80:3279-3283, 1983). We have also utilized restriction fragments from cloned DNAs to probe by blot hybridization for the presence of conserved sequences in several independently derived DI RNA populations. These studies indicated that: (i) a 51-nucleotide conserved sequence located close to the 5' end of several alphavirus RNAs was most likely retained in the DI RNAs; (ii) the junction region containing the 5' end of the subgenomic 26S mRNA was deleted from the DI RNAs; and (iii) the presence of tRNAAsp sequences was a common occurrence in Sindbis virus DI RNAs derived by passaging in chicken embryo fibroblasts.

Screening recombinant phage M13 plaques with RNA probes; a one-step procedure which identifies clones containing either of the complementary DNA strands

We describe a method for detecting specific DNA sequences cloned in M13 phage vectors, based on the procedure of Woo (in Wu, R., Methods in Enzymology, Vol. 68, Academic Press, New York, 1979, pp. 389-395). M13 plaques are adsorbed to a nitrocellulose filter that has been pre-saturated with bacteria. The filter is incubated on an agar plate to amplify the phage; the DNA is alkali-denatured and then hybridized with a radioactive RNA probe. Unlike standard procedures, this method detects and distinguishes M13 plaques containing phage particles which harbor either the coding or non-coding (RNA-like) DNA strand, when single-stranded RNA is used as probe. We have optimized this procedure with M13 clones containing mouse histidine tRNA gene sequences and have used it to determine the sequence of both strands of a mouse glycine tRNA gene.

Molecular cloning, sequence analysis and in vitro expression of a rat tRNA gene cluster

A rat genomic DNA fragment containing a tRNA gene cluster was isolated from a lambda phage library. Hybridization and nucleotide sequence analysis revealed the presence of a 83 bp tRNALeuCUG gene and a 72 bp tRNAAspGUG gene. Both genes possessed intact coding regions and putative transcription termination signals at their respective 3' ends. In vitro transcription analysis of the two subcloned genes in a HeLa cell S-100 system demonstrated the specific synthesis of a number of RNAs by RNA polymerase III. Studies carried out in the presence of alpha-amanitin showed that the larger RNAs are precursors for the final processed transcripts of the tRNALeu and tRNAAsp genes, respectively. Further nucleotide sequence analysis of the cluster revealed the presence of tRNAGly and a tRNAGlu pseudogenes with missing areas within their coding regions which are essential for transcription by RNA polymerase III. Within the region of DNA between the tRNALeu and tRNAAsp genes is a sequence which is 65% homologous to a region of the rat B1 element. The significance of this latter structure within the gene cluster is unknown.

Structure and evolution of a mouse tRNA gene cluster encoding tRNAAsp, tRNAGly and tRNAGlu and an unlinked, solitary gene encoding tRNAAsp

We have sequenced mouse tRNA genes from two recombinant lambda phage. An 1800 bp sequence from one phage contains 3 tRNA genes, potentially encoding tRNAAsp, tRNAGly, and tRNAGlu, separated by spacer sequences of 587 bp and 436 bp, respectively. The mouse tRNA gene cluster is homologous to a rat sequence (Sekiya et al., 1981, Nucleic Acids Res. 9, 2239-2250). The mouse and rat tRNAAsp and tRNAGly coding regions are identical. The tRNAGlu coding regions differ at two positions. The flanking sequences contain 3 non-homologous areas: a c. 100 bp insertion in the first mouse spacer, short tandemly repeated sequences in the second spacers and unrelated sequences at the 3' ends of the clusters. In contrast, most of the flanking regions are homologous, consisting of strings of consecutive, identical residues (5-17 bp) separated by single base differences and short insertions/deletions. The latter are often associated with short repeats. The homology of the flanking regions is c. 75%, similar to other murine genes. The second lambda clone contains a solitary mouse tRNAAsp gene. The coding region is identical to that of the clustered tRNAAsp gene. The 5' flanking regions of the two genes contain homologous areas (10-25 bp) separated by unrelated sequences. Overall, the flanking regions of the two mouse tRNAAsp genes are less homologous than those of the mouse and rat clusters.

Isolation and characterization of genomic mouse DNA clones containing sequences homologous to tRNAs and 5S rRNA

We have cloned and characterized three fragments of Balb/c mouse DNA which hybridize to mouse cell tRNAs. Fractionation of the tRNAs which hybridize to these clones reveals that two of the clones, lambda Mt-4A and lambda Mt-6A hybridize to only one or two tRNAs, while one clone, lambda Mt-4B, hybridizes to at least seven tRNAs. Two of the tRNAs were identified as tRNAProCCG and tRNAGlyGGA, and others have been identified as tRNAs which are selectively encapsidated into virions of murine leukemia virus and avian reticuloendotheliosis virus. The DNA sequences of putative genes for tRNAProCCG and tRNAGlyGGA, plus flanking regions, were determined. A clone of Balb/c mouse DNA which selectively hybridized to 5S rRNA was also isolated and partially characterized.

RNAs from two independently isolated defective interfering particles of Sindbis virus contain a cellular tRNA sequence at their 5' ends

Defective interfering (DI) particles are deletion mutants that interfere specifically with the replication of homologous standard virus. We have determined the 5'-terminal nucleotide sequences of two DI RNA populations by the following methods: (i) cloning of the cDNA from one of the DI RNA populations and sequencing a representative clone, and (ii) using both DI RNA populations as templates for preparing primer-directed cDNA transcripts and sequencing these transcripts. The 5' terminal sequences of the two DI RNA populations were not derived from standard Sindbis viral RNA but were almost identical to those of a cellular tRNAAsp.

Isolation and characterization of three cloned fragments of human DNA coding for tRNAs and small nuclear RNA U1

Employing a human fetal liver library in lambda Charon 4A phage vector, we have isolated and characterized three clones of human DNA containing genes for tRNAs. One clone contains at least three tRNA genes (tRNALys, tRNAGln and tRNALeu) within 2 kb of each other. The other two clones contain two different single genes for tRNAAsn. One of these latter two DNAs also contains a gene for U1 small nuclear RNA.

Genes for two small cytoplasmic Ro RNAs are adjacent and appear to be single-copy in the human genome

Anti-Ro autoantibodies precipitate several small cytoplasmic ribonucleoproteins from mammalian cells. The RNA components of these particles, designated hY1-hY5 in human cells and mY1 and mY2 in mouse cells, are about 100 nucleotides long. We have analyzed a genomic clone that appears to contain true RNA-coding regions for two of the human Ro RNAs, hY1 and hY3. These RNAs exhibit many sequence and secondary structure homologies, both with each other and with the recently sequenced hY5 RNA. The hY2 RNA is a slightly truncated form of hY1; several shorter versions of hY3 are also detected in cell extracts and immunoprecipitates. The human hY1 and hY3 genes cross-hybridize with the mouse Ro RNAs, mY1 and mY2, respectively; we show that the mouse Ro RNAs are exclusively contained in Ro particles. The genes for hY1 and hY3 are transcribed in vitro by RNA polymerase III. In contrast with all other mammalian class III genes described, they appear to be present as single copies in the human genome.

Isolation and nucleotide sequence of a plant tRNA gene: petunia asparagine tRNA

A 14.3 kb petunia genomic DNA fragment was isolated and found to contain a single tRNA gene coding for asparagine tRNA. The nucleotide sequence of the asparagine tRNA gene and its flanking regions has been determined. This gene does not contain intervening sequences nor the 3'-end CCA sequence of the mature tRNA and presents a similar overall sequence homology (70%) to both E. coli and mammalian asparagine tRNA. As in other eukaryotic tRNA genes the 5'-flanking region does not seem to contain any special sequence that could function as a regulatory element and the 3'-end is followed by a short cluster of T that may function as the transcription termination site.

Nucleotide sequence of a segment of human DNA containing the three tRNA genes

A 1.65 kb segment of DNA from a human-lambda recombinant, selected for human tRNA genes, was subcloned in the plasmid pAT 153 for sequence determination. Three human tRNA genes were found; one, a tRNAlys gene which appears to specify a tRNA identical in sequence to the previously described tRNA3lys from rat liver (AAA,G); another a tRNAgln gene, the product of which would be expected to recognize only the codon CAG; and a third which would direct synthesis of a tRNAleu specific for CUA and G. Intervening sequences are not found in any of these genes. The three tRNA genes are separated by about 0.5 kb segments of DNA containing no apparent informational sequences. Examination of flanking sequences shows some similarities at the 5'-ends of the three genes, but less similarity to 5' flanking sequences of tRNA genes in other eucaryotes. All three tRNA genes direct synthesis of appropriate sized products in a HeLa cell lysate in vitro transcription system.

A rat tRNA gene cluster containing the genes for tRNAPro and tRNALys. Analysis of nucleotide sequences of the genes and the surrounding regions

A lambda clone carrying a rat DNA fragment of 11.9 kb was isolated from a rat gene library with total rat tRNA as a probe. Nucleotide sequence analysis revealed that the DNA fragment contained six tRNA genes, three for tRNAPro and three for tRNALys. Of the six genes all but one tRNAPro gene have the same polarity. Each tRNA gene is separated by a DNA region of 0.1 to 3.6 kb. The 5'-flanking regions of the six rat genes in the cluster do not have any significant sequence homology, but in the 3'-flanking region, each gene has a short T cluster, which is supposed to be a transcription termination signal.

The nucleotide sequence of a glutamate tRNA from rat liver

A glutamate tRNA from rat liver was purified. By means of post-labeling techniques, its nucleotide sequence was shown to be: pU-C-C-C-A-C-A-U-m1G-G-U-C-psi-A-G-C- G-G-D-D-A-G-G-A-U-U-C-C-U-G-G-psi-U-mcm5s2U-U-C-A-C-C-C-A-G-G-C-G- G-C-m5C-m5C-G-G-G-Tm-psi-C-G-A-C-U-C-C-C-G-G-U-G-U-G-G-G-A-A-C-C-AOH. The sequence is remarkably similar to that of tRNA4Glu from Drosophila melanogaster. Only 10 out of 75 nucleotides in the two tRNAs are different.

Characterization of a rat tRNA gene cluster containing the genes for tRNAAsp, tRNAGly and tRNAGlu, and pseudogenes

The putative genes for tRNAGAUAsp(C), tRNAGGAGly(G) and tRNAGAGGlu are in a cluster on the rat chromosome and are present exclusively in a 3.3 kb region cleaved with a restriction endonuclease EcoRI. The cluster reiterates about 10 times on the haploid DNA. Four lambda clones each containing an independent repeating unit were isolated from a rat gene library. The studies on the cloned DNA revealed that the length of the repeating unit including the 3.3 kb EcoRI fragment was at least 13.5 kb. Nucleotide sequence analysis of the 3.3 kb DNA in the isolated clones showed sequence variations among the repeating units and incomplete genes for tRNAGly and tRNAGlu within the clusters.

The nucleotide sequence of a glutamine tRNA from rat liver

A glutamate tRNA from rat liver was purified. By means of post-labeling techniques, its nucleotide sequence was shown to be: pU-C-C-C-A-C-A-U-m1G-G-U-C-psi-A-G-C- G-G-D-D-A-G-G-A-U-U-C-C-U-G-G-psi-U-mcm5S2U-U-C-A-C-C-C-A-G-G-C-G- G-C-m5C-m5C-G-G-G-Tm-psi-C-G-A-C-U-C-C-C-G-G-U-G-U-G-G-G-A-A-C-C-AOH. The sequence is remarkably similar to that of tRNAGlu from Drosophila melanogaster. Only 10 out of 75 nucleotides in the two tRNAs are different.

Precursor molecules of both human 5S ribosomal RNA and transfer RNAs are bound by a cellular protein reactive with anti-La lupus antibodies

The small ribonucleoproteins recognized by anti-La autoantibodies contain a heterogeneous mixture of small RNAs from uninfected mammalian cells. The identity of many of these has now been established by the discovery of precursor forms of 5S rRNA and of certain tRNAs among La RNAs from HeLa cells. The small fraction of 5S rRNA molecules that exist as La ribonucleoproteins in vivo possess 1 or 2 additional U residues at their 3' ends. Such 5S molecules bound to the La protein have also been identified with in vitro nuclear transcription systems. Pulse-chase experiments performed both in vivo and in vitro support the idea that most newly synthesized 5S rRNA molecules are transiently associated with the La protein. Cell extracts contain a processing activity that converts longer in vitro-synthesized 5S RNA transcripts into molecules of mature size. The presence of in vivo tRNA precursors in the heterogeneous mixture of La RNAs is demonstrated by the identification of precursor forms of five different specific tRNAs (Meti, Asp, Gly, Glu, Asn). After in vitro transcription of a tRNA gene (tRNAiMet), only products the size of precursor molecules are precipitable by anti-La antibodies. The realization that virtually every known RNA polymerase III product associates at least initially with the La antigen suggests that this protein plays an essential role in the synthesis or maturation of all class III transcripts.

Clustered genes require extragenic territorial DNA sequences

This paper is concerned with the basic question as to whether there exists a complex interaction between DNA sequences which have little specific function and functional genes regarding the spatial arrangement of the gene. Since gene clusters are a characteristic and basic feature of gene structure in higher eukaryotes, the size of extragenic DNA sequences surrounding the individual genes of various clustered gene families were compared. The size of the intergenic region, which is composed of the extragenic DNA sequences flanking the 3'-end of one gene and those flanking the 5'-end of the other gene, of the paired genes increases as the genes becomes larger. However, such a gene size-dependent increase is not seen if the total gene size of the paired genes is less than 0.3 kb or greater than 4 kb. The results suggests that a higher eukaryote gene requires extragenic territorial DNA sequences surrounding it, which presumably are necessary to maintain the gene's active functions.

Isolation and characterization of cloned rat DNA fragment carrying tRNA genes

A rat genomic library was screened for tRNA genes with an unfractionated rat liver tRNA probe. About 70 clones containing tRNA genes were detected per rat genome. The organization of tRNA genes in five clones was analyzed by restriction endonuclease digestion, RNA-DNA hybridization and in vitro transcription with nuclear extracts from Xenopus oocytes. Evidence is presented suggesting that tRNA genes are distributed in the rat genome in small clusters spanning 1 to 2 kb and interspersed with large regions (minimum 8 to 20 kb) of non tRNA-coding DNA. The tRNA gene clusters were found to contain the sequences for a variety of tRNA species. Genes for a single isoacceptor, were found in more than one clone. The detailed study of one clone shows the repetition of a cluster of four tRNA sequences at a distance of about 8 kb. The arrangement of tRNA genes in rat appears to follow the irregular pattern of tRNA gene organization previously reported in Drosophila and Xenopus.