Functional characterization of the dimer linkage structure RNA of Moloney murine sarcoma virus.

Several determinants that appear to promote the dimerization of murine retroviral genomic RNA have been identified. The interaction between these determinants has not been extensively examined. Previously, we proposed that dimerization of the Moloney murine sarcoma virus genomic RNAs relies upon the concentration-dependent interactions of a conserved palindrome that is initiated by separate G-rich stretches (H. Ly, D. P. Nierlich, J. C. Olsen, and A. H. Kaplan, J. Virol. 73:7255-7261, 1999). The cooperative action of these two elements was examined using a combination of genetic and antisense approaches. Dimerization of RNA molecules carrying both the palindrome and G-rich sequences was completely inhibited by an oligonucleotide complementary to the palindrome; molecules lacking the palindrome could not dimerize in the presence of oligomers that hybridize to two G-rich sequences. The results of spontaneous dimerization experiments also demonstrated that RNA molecules lacking either of the two stretches of guanines dimerized much more slowly than the full-length molecule which includes the dimer linkage structure (DLS). However, the addition of an oligonucleotide complementary to the remaining stretch of guanines restored the kinetics of dimerization to wild-type levels. The ability of this oligomer to rescue the kinetics of dimerization was dependent on the presence of the palindrome, suggesting that interactions within the G-rich regions produce changes in the palindrome that allow dimerization to proceed with maximum efficiency. Further, unsuccessful attempts to produce heterodimers between constructs lacking various combinations of these elements indicate that the G-rich regions and the palindrome do not interact directly. Finally, we demonstrate that both of these elements are important in maintaining efficient viral replication. Modified antisense oligonucleotides targeting the DLS were found to reduce the level of viral vector titer production. The reduction in viral titer is due to a decrease in the efficiency of viral genomic RNA encapsidation. Overall, our data support a dynamic model of retroviral RNA dimerization in which discrete dimerization elements act in a concerted fashion.

Heart-specific splice-variant of a human mitochondrial ribosomal protein (mRNA processing; tissue specific splicing).

It has been proposed that splice-variants of proteins involved in mitochondrial RNA processing and translation may be involved in the tissue specificity of mitochondrial DNA disease mutations (Fischel-Ghodsian, 1998. Mol. Genet. Metab. 65, 97-104). To identify and characterize the structural components of mitochondrial RNA processing and translation, the Mammalian Mitochondrial Ribosomal Consortium has been formed. The 338 amino acid (aa) residues long MRP-L5 was identified (O'Brien et al., 1999. J. Biol. Chem. 274, 36043-36051), and its transcript was screened for tissue specific splice-variants. Screening of the EST databases revealed a single putative splice-variant, due to the insertion of an exon consisting of 89 nucleotides prior to the last exon. Screening of multiple cDNA libraries revealed this inserted exon to be present only in heart tissue, in addition to the predominant MRP-L5 transcript. Sequencing of this region confirmed the EST sequence, and showed in the splice-variant a termination triplet at the beginning of the last exon. Thus the inserted exon replaces the coding sequence of the regular last exon, and creates a new 353 aa long protein (MRP-L5V1). Sequence analysis and 3D modeling reveal similarity between MRP-L5 and threonyl-t-RNA synthetases, and a likely RNA binding site within MRP-L5, with the C-terminus in proximity to the RNA binding site. Sequence analysis of MRP-L5V1 also suggests a likely transmembrane domain at the C-terminus. Thus it is possible that the MRP-L5V1 C-terminus could interfere with RNA binding and may have gained a transmembrane domain. Further studies will be required to elucidate the functional significance of MRP-L5V1.

Moloney murine sarcoma virus genomic RNAs dimerize via a two-step process: a concentration-dependent kissing-loop interaction is driven by initial contact between consecutive guanines.

Retroviruses contain two plus-strand genomic RNAs, which are stably but noncovalently joined in their 5' regions by a dimer linkage structure (DLS). Two models have been put forward to explain the mechanisms by which the RNAs dimerize; each model emphasizes the role of specific molecular determinants. The kissing-loop model implicates interactions between palindromic sequences in the DLS region. The second model proposes that purine-rich stretches in the region form purine quartet structures. Here, we present an examination of the in vitro dimerization of Moloney murine sarcoma virus (MuSV) RNA in the context of these two models. Dimers were found to form spontaneously in a temperature-, time-, concentration-, and salt-dependent manner. In contrast to earlier reports, we found that deletion of neither the palindrome nor the consensus purine motifs (PuGGAPuA) affected the level of dimer formation at low concentrations of RNA. Rather, different purine-rich sequences, i.e., consecutive stretches of guanines, were found to enhance both in vitro RNA dimerization and in vivo viral replication. Biochemical evidence further suggests that these guanine-rich (G-rich) stretches form guanine quartet structures. We also found that the palindromic sequences could support dimerization at significantly higher RNA concentrations. In addition, the G-rich stretches were as important as the palindromic sequence for maintaining efficient viral replication. Overall, our data support a model that entails contributions from both of the previously proposed mechanisms of retroviral RNA dimerization.

Transcription and decay of the lac messenger: role of an intergenic terminator.

Prior work has indicated that the polycistronic lacZYA mRNA of Escherichia coli is cleaved during decay at approximately intergenic sites (L. W. Lim and D. Kennell, J. Mol. Biol. 135: 369-390, 1979). In this work, we characterized the products by using probes specific for the different cistrons. This analysis indicated that six lac mRNA species are present in the following order of decreasing abundance: lacZ, -A, -ZYA, -ZY, -YA, and -Y. Very little lacYA and lacY mRNAs were present, whereas in cells induced to steady state, there was 10 times more lacZ than lacZYA mRNA. The lacZ mRNA appeared as a discrete species extending to a site in the lacZ-Y intergenic space (ca. residue 3150). This site is just distal to a potential rho-independent termination sequence. We examined the function of this sequence to determine whether it contributes to the distribution of the mRNAs. Although the termination sequence was shown to function in vitro, when it was recloned into an expression vector, no termination was seen in vivo. Moreover, direct examination of the kinetics of lac messenger synthesis revealed that after initiation, most transcription continued to the end of the operon. We conclude that during normal growth, the operon is transcribed in its entirety and that the individual lac mRNAs are formed by cleavage. These results confirm earlier work implying that the lac operon is transcribed in its entirety but are in conflict with several recent reports suggesting that internal termination occurs. Our findings indicate that the natural polarity of the operon (lacZ is expressed sixfold more strongly than lacA) is based on posttranslational effects and not on polarity of transcription.

Use of the lac repressor in constructing sequential deletions and a new sequencing vector.

Large sequencing projects require an efficient strategy to generate a series of overlapping clones. This can be accomplished by protecting one end of a linear DNA molecule while sequential deletions are introduced into the other end by exonuclease digestion. We demonstrate that the lac repressor can protect the ends of linear nucleotide sequences from digestion by exonuclease if these ends contain the lac operator sequence. To exploit this, we have inserted the lac operator sequence between the primer-binding site and multiple cloning site of an M13 sequencing vector. Linearizing the replicative form and binding lac repressor protein protects the end next to the vector sequences. Sequential deletions are then introduced into the insert by digesting with exonuclease III or BAL 31. Because the rate and time of digestion are readily controlled, the region brought next to the sequencing primer site, after religation, can be selected in a timed series of reactions. This minimizes the screening needed to isolate an overlapping series of clones and facilitates sequencing of long regions.

Mapping the lacZ ribosome binding site by RNA footprinting.

The ribosome binding site of the Escherichia coli lacZ mRNA has been characterized by using an RNA footprinting technique. Purified E. coli 70S ribosomes and fMet-tRNA were incubated with mRNA, and the complex was treated with RNA-reactive reagents or RNases as probes. The protected sites on the mRNA were then mapped by extending a radioactive primer with reverse transcriptase. Dimethyl sulfate, diethyl pyrocarbonate, and 1,10-phenanthroline-copper ion oxidative complex were used as reagent probes; they detected interaction sites within the ribosome binding site. A region of approximately 35 nucleotides was protected by the ribosome, specifically across the Shine-Dalgarno region, around the fMet initiation codon, and at a region 7-12 nucleotides distal to the fMet codon. In addition, an enhanced reaction occurred between the fMet codon and the distal site. These results imply an internally selective interaction between the ribosome and the mRNA sequence. The enhanced reactivity of a site distal to the initiation site--flanked by the AUG codon and a site previously identified as conserved in a study of initiation sequences--may indicate a region where the mRNA is specifically exposed.

Scission of RNA by the chemical nuclease of 1,10-phenanthroline-copper ion: preference for single-stranded loops.

The scission of RNA by the chemical nuclease activity of 1,10-phenanthroline-copper (OP-Cu) has been studied using a lac mRNA fragment and tRNAphe as substrates. Since the chemical mechanism of scission involves oxidative attack on the ribose, scission is observed at all nucleotides including dihydrouridine and Y-bases. Specificity for single-stranded loop regions is apparent from the similarity of the reactivity of OP-Cu to the single-strand specific reagents dimethyl sulfate and diethyl pyrocarbonate using the fragment of lac mRNA as a substrate. Similar preference is observed in the reaction with tRNA although scission in the helical acceptor stem is also observed.

Distribution of 5'-triphosphate termini on the mRNA of Escherichia coli.

We have determined the distribution of 5'-nucleoside triphosphates on the RNA in Escherichia coli. These groups represent the initial nucleoside triphosphate incorporated when RNA polymerase initiates transcription. It was estimated that at least 15% of polysome-associated messengers had triphosphates. This was interpreted to mean that removal of the triphosphate or messenger leader is not necessary for the functioning of most mRNAs but that a substantial amount of messenger processing occurs in the polysome pool. We found that the ratio of GTP- to ATP-initiated messengers was about 2 to 1. Since prior work has indicated that G- and A-initiated RNAs decay at the same rate and since a compilation of messenger start sites shows an A preference, this value implies that there is a significant physiological selection of G-initiated transcripts. We also characterized the 5'-terminal groups on RNAs in other fractions. A small amount was found associated with 30S ribosomes, presumably in initiation complexes; such complexes have not previously been detected in situ. In addition, it was concluded that the 5' terminus of rRNA precursors is processed more rapidly than is implied by the current literature.

Expression of a tRNA gene in the context of the lacZ mRNA.

Fusions of the gene for tyrosine suppressor tRNA, tyrT(Sup3), and the lacZ gene of Escherichia coli were constructed such that the tRNA gene could be expressed from either its own promoter or that of the lac operon. These chimeras, carried on phage M13 vectors, were tested for the expression of the tRNA in E. coli. The tRNA gene was expressed on the order of 10-fold more weakly from the lac promoter than from its own promoter. To examine whether pausing or premature termination of transcription played a role in determining the relative strength, the fusions were tested in a variety of genetic backgrounds and under different physiological conditions that uncouple transcription and translation. The expression of the tRNA was not enhanced in backgrounds in which polarity was weakened or under the other conditions tested, although a dependence on nusB function was observed when the tRNA was transcribed from the lac promoter. These results indicate that pausing or premature termination of transcription did not play a role in the weak expression of the gene fusions. The results further suggest that the transcription of the tyrT gene does not normally require relief from polarity as imposed by any of the known transcriptional termination systems, in contrast to the antitermination system thought to be involved in the expression of the rRNAs.

Plotting genetic maps on a microcomputer.

Maps of genetic linkage and restriction enzyme cleavage sites can be quickly prepared on an IBM PC microcomputer with the commercially available program Lotus 1-2-3. Data can be entered on the keyboard or imported from other programs. The maps can be displayed on the screen or with a printer or plotter. These procedures should be useful in the research laboratory, in preparing figures for publication and in teaching.

DNA sequence of the lactose operon: the lacA gene and the transcriptional termination region.

The lac operon of Escherichia coli spans approximately 5300 base pairs and includes the lacZ, lacY, and lacA genes in addition to the operator, promoter, and transcription termination regions. We report here the sequence of the lacA gene and the region distal to it, confirming the sequence of thiogalactoside transacetylase and completing the sequence of the lac operon. The lacA gene is characterized by use of rare codons, suggesting an origin from a plasmid, transposon, or virus gene. UUG is the translation initiation codon. A preliminary examination of 3' end of the lac messenger in the region distal to the lacA gene indicates several endpoints. A predominant one is located at the 3' end of a G + C-rich hairpin structure, which may be involved in termination of transcription or in post-transcriptional processing. An open reading frame of 702 base pairs is present on the complementary strand downstream from lacA.

Fragmentary 5S rRNA gene in the human mitochondrial genome.

The human mitochondrial genome contains a 23-nucleotide sequence that is homologous to a part of the 5S rRNA's of bacteria. This homology, the structure of the likely transcript, and the location of the sequence relative to the mitochondrial rRNA genes suggest that the sequence represents a fragmentary 5S rRNA gene.

Sequence and organization of the human mitochondrial genome.

The complete sequence of the 16,569-base pair human mitochondrial genome is presented. The genes for the 12S and 16S rRNAs, 22 tRNAs, cytochrome c oxidase subunits I, II and III, ATPase subunit 6, cytochrome b and eight other predicted protein coding genes have been located. The sequence shows extreme economy in that the genes have none or only a few noncoding bases between them, and in many cases the termination codons are not coded in the DNA but are created post-transcriptionally by polyadenylation of the mRNAs.

Distinctive sequence of human mitochondrial ribosomal RNA genes.

The nucleotide sequence spanning the ribosomal RNA (rRNA) genes of cloned human mitochondrial DNA reveals an extremely compact genome organization wherein the putative tRNA genes are probably 'butt-jointed' around the two rRNA genes. The sequences of the rRNA genes are significantly homologous in some regions to eukaryotic and prokaryotic sequences, but distinctive; the tRNA genes also have unusual nucleotide sequences. It seems that human mitochondria did not originate from recognizable relatives of present day organisms.

Different pattern of codon recognition by mammalian mitochondrial tRNAs.

Analysis of an almost complete mammalian mitochondrial DNA sequence has identified 23 possible tRNA genes and we speculate here that these are sufficient to translate all the codons of the mitochondrial genetic code. This number is much smaller than the minimum of 31 required by the wobble hypothesis. For each of the eight genetic code boxes with four codons for one amino acid we find a single specific tRNA gene with T in the first (wobble) position of the anticodon. We suggest that these tRNAs with U in the wobble position can recognize all four codons in these genetic code boxes either by a "two out of three" base interaction or by U.N wobble.

Isolation of the transfer RNA genes of bacteriophage T4 and transfer RNA synthesis in vitro.

Non-glucosylated T4 DNA was restricted with the endonuclease EcoRI and the mixture of DNA fragments separated by gel electrophoresis and transcribed with purified Escherichia coli RNA polymerase. Three purified fragments were shown to act as templates for tRNA synthesis. A smaller fragment, shown to be hybridizable to 32P-labeled T4 tRNA was not transcribable. It was concluded that the promoter for T4 tRNA synthesis had been separated from the structural genes in the smaller fragment by EcoRI and that the distal portion of the tRNA gene cluster lacks internal promoters which display in vitro activity. Preparations of non-glucosylated T4 DNA were never fully restricted with EcoRI and when the larger purified fragments carrying the tRNA were restricted with excess enzyme only a slight cleavage to yield the smaller fragments was obtained. The property of the DNA-limiting complete restriction is not know.

Yeast mutant, rna 1, affects the entry into polysomes of ribosomal RNA as well as messenger RNA.

The entry of newly labeled ribosomal subunits and mRNA into polysomes was examined in the yeast mutant rna1. The entry of both types of RNA into polysomes is inhibited rapidly at the restrictive temperature. Analysis of the labeling of the ATP pool and the kinetics of synthesis and processing of mRNA at the restrictive temperature leads to the conclusion that the primary defect in the mutant affects transport of both ribosomes and messenger across the nuclear membrane.