Further characterization of mRNA''s of mouse hepatitis virus: presence of common 5''-end nucleotides

The mouse hepatitis virus strain A59 codes for seven RNA species in the infected cells. These virus-specific RNAs were found to be polysome associated and therefore likely to represent mRNA's. All of them have common 3'-end sequences (Lai et al., J. Virol. 39:823-834, 1981). Their structure was further studied with respect to their 5'-end sequences. It was found that all of these mRNA's contained cap structures at their 5' ends. Furthermore, the cap-containing oligonucleotides which represent the sequences immediately adjacent to the 5' ends were found to be the same for most, if not all, of the seven virus-specific mRNA's. These sequences are also identical to the 5'-end sequences of the virion RNA genome. The 5'-end sequences were tentatively determined to be 5'-cap-N-UAAG. The presence of the common nucleotides in all of the virus-specific RNAs in mouse hepatitis virus strain A59 suggests several possible mechanisms of synthesis for these RNAs. The significance of these findings is discussed.     

Functional nucleotides of U5 LTR determining substrate specificity of prototype foamy virus integrase

In order to study functional nucleotides in prototype foamy virus (PFV) DNA on specific recognition by PFV integrase (IN), we designed chimeric U5 long terminal repeat (LTR) DNA substrates by exchanging comparative sequences between human immunodeficiency virus type-1 (HIV-1) and PFV U5 LTRs, and investigated the 3'-end processing reactivity using HIV-1 and PFV INs, respectively. HIV-1 IN recognized the nucleotides present in the fifth and sixth positions at the 3'-end of the substrates more specifically than any other nucleotides in the viral DNA. However, PFV IN recognized the eighth and ninth nucleotides as distinctively as the fifth and sixth nucleotides in the reactions. In addition, none of the nucleotides present in the twelfth, sixteenth, seventeenth, eighteenth, nineteenth, and twentieth positions were not differentially recognized by HIV-1 and PFV INs, respectively. Therefore, our results suggest that the functional nucleotides that are specifically recognized by its own IN in the PFV U5 LTR are different from those in the HIV-1 U5 LTR in aspects of the positions and nucleotide sequences. Furthermore, it is proposed that the functional nucleotides related to the specific recognition by retroviral INs are present inside ten nucleotides from the 3'-end of the U5 LTR.     

Sequence of 1019 nucleotides encompassing one of the inverted repeats from the yeast 2 micrometer plasmid.

A sequence of 1019 nucleotides encompassing one of the 600 base inverted repeats and non-repeated flanking regions has been determined in the type A yeast 2 micrometers plasmid cloned in pMB9. Methods are described for applying the Maxam-Gilbert sequencing procedure to DNA fragments labelled at the 3'-end using a T4-polymerase exchange/repair reaction and for sequencing 5'-end labelled fragments using dideoxy-nucleotides as chain terminators in the presence of E. coli DNA polymerase (nach Klenow). A notable feature of the sequence is its unusual content of symmetry elements. In one region of 140 nucleotides, 137 are involved in a complex arrangement of direct and inverted repeats linked by palindromic sequences.     

The nucleotide sequence at the 3''-end of Neurospora crassa 25S-rRNA and the location of a 5.8S-rRNA binding site

The sequence of 110 nucleotides adjacent to the 3'-end of Neurospora crassa 25S-rRNA has been derived by chemical sequencing methods. Sequences present between 40 and 85 nucleotides of the 3'-end were found to complement sequences at the 3'- and 5'-ends of 5.8S-rRNA. Interaction was shown to occur between 5.8S-rRNA and a specific 3'-terminal fragment of 85 nucleotides derived from 25S-rRNA. We have also demonstrated that the nucleotide sequence at the 3'-end of N. crassa 5.8S-rRNA (-UCAUUOH) is different from the published sequence (-UUUUOH) which was derived from rDNA.     

Addition of oligonucleotides to the 5''-terminus of DNA by T4 RNA ligase.

Bacteriophage T4-induced RNA ligase catalyzes the controlled template-independent addition of RNA to the 5'-phosphoryl end of large DNA molecules. Restriction enzyme-generated fragments of Co1E1 DNA with completely basepaired or cohesive ends and linear single-stranded ?X174 viral DNA were all good substrates. DNA molecules from 10 to 6000 nucleotides long were quantitatively joined in an hour to a number of different RNA homopolymers. The most efficient of these was A(pA)5; I(pI)5 and C(pC)5 were also utilized while U(pU)5 was not. The optimum ribohomopolymer length was six nucleotides. Joining of ribohomopolymers between 10 and 20 nucleotides long occurred at approximately 1/2 the maximal rate and a trimer was the shortest substrate. Thus RNA ligase provides a method for generating extensions of predetermined length and base composition at the 5'-end of large DNA molecules that complements the available procedures for extending the 3'-hydroxyl terminus of DNA.     

The distribution and properties of RNA primed initiation sites of DNA synthesis at the replication origin of Escherichia coli chromosome.

RNA-linked DNA molecules were obtained from E. coli dnaCts cells synchronously initiating a new round of chromosome replication. The deoxynucleotides at the transition from primer RNA to DNA were 32P-labeled, and their positions were located on the nucleotide sequence of 1.4 kb genomic region (position -906 to +493) including the oriC and its leftside flanking region. In the r-strand (the counterclockwise strand), many strong transition sites were mapped in the left half portion of the oriC and a few weak sites in the left outside region. In the 1-strand (the clockwise strand), no transition sites were found inside the oriC but many weak sites were found in the left outside region. The results support the initiation mechanism in which the first leading strand synthesis starts with the r-strand counterclockwise from the oriC that is followed by the 1-strand synthesis on the displaced template strand on the left of oriC. Primer RNA molecules attached to the strong r-strand transition sites were only a few residues in length. Properties of the transition sites were discussed.     

Analysis of 5'-ends of short DNA fragments excreted by phytohemagglutinin stimulated lymphocytes

Human peripheral blood lymphocytes were stimulated with phytohemagglutinin and the excreted DNA was isolated from the medium after four days of incubation of cells. The excreted DNA was labeled at the 5'-end with [gamma-32P]ATP and polynucleotide kinase. Analysis of the end-labeled material revealed a size distribution with a chain length of 6 - 60 nucleotides. These short DNA fragments did not contain ribo-nucleotides at their 5'-termini. P1 nuclease digestion did not release specific deoxyribonucleoside monophosphates from the 5'-end of the excreted DNA fragments. These results point to the non-specific degradation of DNA excreted by stimulated lymphocytes.     

The nucleotide sequence of cysteine transfer ribonucleic acid from baker''s yeast. Identification of the products from partial degradation of the molecule and derivation of the complete sequence.

1. A series of large oligonucleotide fragments derived from tRNA Cys, were separated chromatographically and the sequence of each was deduced by examination of the products of digestion with pancreatic and T1 ribonucleases. 2. The location of the specific cleavage points in the nucleotide chain was similar to that produced by brief treatment with pancreatic ribonuclease. 3. The fragments could be arranged into two alternative sequences. The correct sequence was deduced by the sequential removal and identification of the first nine nucleotides from the 3'-end of the terminal half of the molecules.     

Cleavage of substrates with mismatched nucleotides by Flap endonuclease-1. Implications for mammalian Okazaki fragment processing.

Flap endonuclease-1 (FEN1) is proposed to participate in removal of the initiator RNA of mammalian Okazaki fragments by two pathways. In one pathway, RNase HI removes most of the RNA, leaving a single ribonucleotide adjacent to the DNA. FEN1 removes this ribonucleotide exonucleolytically. In the other pathway, FEN1 removes the entire primer endonucleolytically after displacement of the 5'-end region of the Okazaki fragment. Cleavage would occur beyond the RNA, a short distance into the DNA. The initiator RNA and an adjacent short region of DNA are synthesized by DNA polymerase alpha/primase. Because the fidelity of DNA polymerase alpha is lower than that of the DNA polymerases that complete DNA extension, mismatches occur relatively frequently near the 5'-ends of Okazaki fragments. We have examined the ability of FEN1 to repair such errors. Results show that mismatched bases up to 15 nucleotides from the 5'-end of an annealed DNA strand change the pattern of FEN1 cleavage. Instead of removing terminal nucleotides sequentially, FEN1 appears to cleave a portion of the mismatched strand endonucleolytically. We propose that a mismatch destabilizes the helical structure over a nearby area. This allows FEN1 to cleave more efficiently, facilitating removal of the mismatch. If mismatches were not introduced during synthesis of the Okazaki fragment, helical disruption would not occur, nor would unnecessary degradation of the 5'-end of the fragment.     

Template requirements and binding of hepatitis C virus NS5B polymerase during in vitro RNA synthesis from the 3'-end of virus minus-strand RNA

In our attempt to obtain further information on the replication mechanism of the hepatitis C virus (HCV), we have studied the role of sequences at the 3'-end of HCV minus-strand RNA in the initiation of synthesis of the viral genome by viral RNA-dependent RNA polymerase (RdRp). In this report, we investigated the template and binding properties of mutated and deleted RNA fragments of the 3'-end of the minus-strand HCV RNA in the presence of viral polymerase. These mutants were designed following the newly established secondary structure of this viral RNA fragment. We showed that deletion of the 3'-SL-A1 stem loop significantly reduced the level of RNA synthesis whereas modifications performed in the SL-B1 stem loop increased RNA synthesis. Study of the region encompassing the 341 nucleotides of the 3'-end of the minus-strand RNA shows that these two hairpins play a very limited role in binding to the viral polymerase. On the contrary, deletions of sequences in the 5'-end of this fragment greatly impaired both RNA synthesis and RNA binding. Our results strongly suggest that several domains of the 341 nucleotide region of the minus-strand 3'-end interact with HCV RdRp during in vitro RNA synthesis, in particular the region located between nucleotides 219 and 239.     

NMR studies of DNA duplexes singly cross-linked by different synthetic linkers.

Molecular modelling studies resulted in the design of a variety of non-nucleotidic covalent linkers to bridge the 3'-end of the (+)-strand and the 5'-end of the (-)-strand in DNA duplexes. Three of these linkers were synthesized and used to prepare singly cross-linked duplexes d(GTGGAATTC)-linker-d(GAATTCCAC). Linker I is an assembly of a propylene-, a phosphate- and a second propylene-group and is thought to mimic the backbone of two nucleotides. Linkers II and III consist of five and six ethyleneglycol units, respectively. The melting temperatures of the cross-linked duplexes are 65 degrees C for I and 73 degrees C for II and III, as compared with 36 degrees C for the corresponding non-linked nonadeoxynucleotide duplex. The three cross-linked duplexes were structurally characterized by nuclear magnetic resonance spectroscopy. The 1H and 31P resonance assignments in the DNA stem were obtained using standard methods. For the resonance assignment of the linker protons, two-dimensional 1H-31P heteronuclear COSY and two-quantum-experiments were used. Distance geometry calculations with NOE-derived distance constraints were performed and the resulting structures were energy-minimized. In duplex I, the nucleotides flanking the propylene-phosphate-propylene-linker do not form a Watson-Crick base pair, whereas in duplexes II and III the entire DNA stem is in a B-type double helix conformation.     

Characterization of the Escherichia coli 23S Ribosomal RNA region associated with ribosomal protein L1. Evidence for homologies with the 5''-end region of the L11 operon.

The results previously obtained upon studying the L1-23S RNA complex by the fingerprint technique have been reexamined in the light of new data on 23S RNA primary structure. The 23S RNA region that remains associated with the L1 ribosomal protein after RNase digestion of the synthetic complex lies between nucleotides 2067 and 2235 from the 5'-end of the molecule. This region contains a m7G near to the 5'-end and possesses a high degree of mutability in E. coli. Three different sequences were observed in E. coli MRE 600. All three sequences differ in two positions relative to the corresponding sequence in rrnB cistron from E. coli K12. Striking homology is observed between the 23S RNA region associated with protein L1 and the 5'-part of L11 operon. This observation supports the model of feedback regulation of r-proteins synthesis proposed by Yates et al. (PNAS, 77, 1837) and strongly suggests that the region of 23S RNA located between positions 2155 and 2202 is essential for the binding of protein L1.     

The human thyroglobulin gene contains two 15-17 kb introns near its 3''-end.

We have cloned overlapping segments of the human thyroglobulin gene from a genomic cosmid library. Restriction mapping and electron microscopy show that a region of 38 kb at or near the 3'-end of this gene encodes only 850 nucleotides or 10% of the messenger RNA (mRNA) sequence. The region contains five exons of 130-210 nucleotides, split by introns of 1 to 15-17 kb. This represents the lowest ratio of coding to non-coding DNA (2.2%) found thus far in any eukaryotic gene. Blot hybridization under non-stringent conditions shows the presence of only one copy of this gene in the human genome and the absence of other closely related sequences.     

Binding sites of rat liver 5S RNA to ribosomal protein L5

The ribonucleoprotein complex consisting of 5S RNA and the protein L5 was prepared from the large subunit of rat liver ribosomes. The RNA in the complex was digested in situ with RNase A or RNase T1. The RNase-resistant RNA fragments bound to the protein were recovered and purified by 2D-PAGE, and their nucleotide sequences were determined in order to elucidate the binding sites of the RNA to the protein. The results showed that the fragments had arisen from the 5'-end region (residues 1-21), from the second hairpin loop (residues 77-102) and from the 3'-end region (residues 106-120). Harsher digestion trimmed these fragments to shorter fragments. It was concluded that the minimal interactive sequences of 5S RNA to the protein L5 were residues 13-21, residues 85-102, and residues 106-114. A part of the first hairpin loop, residues 41-52, was also suspected to interact with the protein. These protein-binding sites of rat liver 5S RNA were compared with those of Escherichia coli, Halobacterium cutirubrum and yeast, and their probable conservation from eubacteria to eukaryotes is discussed.     

Two distinct recognition signals define the site of endonucleolytic cleavage at the 5''-end of yeast 18S rRNA.

Three of the four eukaryotic ribosomal RNA molecules (18S, 5.8S and 25-28S rRNA) are transcribed as a single precursor, which is subsequently processed into the mature species by a complex series of cleavage and modification reactions. Early cleavage at site A1 generates the mature 5'-end of 18S rRNA. Mutational analyses have identified a number of upstream regions in the 5' external transcribed spacer (5' ETS), including a U3 binding site, which are required in cis for processing at A1. Nothing is known, however, about the requirement for cis-acting elements which define the position of the 5'-end of the 18S rRNA or of any other eukaryotic rRNA. We have introduced mutations around A1 and analyzed them in vivo in a genetic background where the mutant pre-rRNA is the only species synthesized. The results indicate that the mature 5'-end of 18S rRNA in yeast is identified by two partially independent recognition systems, both defining the same cleavage site. One mechanism identifies the site of cleavage at A1 in a sequence-specific manner involving recognition of phylogenetically conserved nucleotides immediately upstream of A1 in the 5' ETS. The second mechanism specifies the 5'-end of 18S rRNA by spacing the A1 cleavage at a fixed distance of 3 nt from the 5' stem-loop/pseudoknot structure located within the mature sequence. The 5' product of the A1 processing reaction can also be identified, showing that, in contrast to yeast 5.8S rRNA, the 5'-end of 18S rRNA is generated by endonucleolytic cleavage.     

Primary structure of the potato virus X genome: the region preceding the capsid protein cistron

DNA copies of the potato virus X (PVX) RNA corresponding to 2300 nucleotides at the 3'-end have been cloned. The cloned cDNA copies containing the nucleotides 445-1280 from the 3'-end have been sequenced. The 5'-terminal region of the PVX coat protein gene corresponds to residues 445-786 from the 3'-end. The amino acid sequences of two more open reading frames (ORF) have been deduced from the nucleotide sequence. The potential translation products of these ORF's would correspond to the nonstructural viral proteins. We have located the ORF1 within the region of residues 799-1009 preceding the coat protein cistron. The tentative protein is composed of 70 amino acids and has an aminoterminal segment which is markedly hydrophobic. ORF2 in the PVX sequence ends with UAG at nucleotides 942-944 and extends to the 5'-terminus for additional 340 nucleotides. The distant sequence homology exists between a carboxyterminal portion of PVX ORF2 and that of the nonstructural "30 K-proteins" of the plant tobamoviruses.     

Elimination of introns from the interleukin 1 beta genome by DNA amplification and expression of interleukin 1 beta in Escherichia coli]

The use of the polymerase chain reaction was proposed for intron excision from genomic genes with known nucleotide sequences. Three exons (5, 6 and 7) of genomic interleukin 1 beta gene were amplified by means of thermostable DNA polymerase TthI from Thermus thermophilus on the base of cloned in M13 phage human genomic interleukin 1 beta gene. Synthetic oligonucleotides complementary to sequences flanking exons were used as primers. The fragments obtained by exon DNA amplification were joined in the correct order due to reciprocal complementation of end sequences, that was foreseen during synthesis of oligonucleotide primers followed by amplification of the enlarged fragments. As a result the structural interleukin-1 beta gene consisting of three exons was assembled. DNA sequences carrying the ATG initiation codon and XbaI recognition site at the 5'-end, and PstI recognition site at the 3'-end (essential for insertion into the expression vector) were formed by the additional end sequences of primers. The nucleotide sequence analysis of the obtained structural gene revealed its complete identity with natural interleukin 1 beta human gene. We created the expression vector pPR114 with phage lambda promoter PR thermo-inducible in case of the cIts857 repressor presence in cells. It was used for expression of the present gene. The interleukin 1 beta synthesized in E. coli had biological activity.