Euglena gracilis chloroplast DNA: the untranslated leader of tufA-ORF206 gene contains an intron.

Structural features of a dicistronic 1.95 kb mRNA coding for the chloroplast specific elongation factor Tu and ORF206 are described. The unspliced pre-mRNA is composed of 2562 nucleotides and undergoes four splicing events which remove a total of 606 nucleotides. The first intron splits the untranslated leader, two introns dissect the tufA coding region and the forth intron is within ORF206, which codes for a putative protein that is to 34% homologous with the putative protein of chloroplast ORF184 of tobacco. Introns neither belong to group I nor II, and 5' and 3' intron boundaries do not follow consensus sequences. Potential ribosome binding sites are located 58 and 32 positions upstream of the tufA and ORF206 start codon, respectively.     

cis-Elements involved in expression of unspliced RNA in Moloney murine leukemia virus.

Murine leukemia virus (MLV) produces the unspliced RNA and the singly spliced RNA at a proper ratio at a time. To identify cis-elements involved in the production of the unspliced RNA, we examined the level of unspliced RNA in a series of mutants derived from a prototype Moloney MLV mutant gag-encoding G3.6. Our present data indicated that nt 1560-1906 region in the CA-encoding region in gag was the negative cis-element and nt 5119-5355 region, which was immediately upstream of the splice acceptor site, was the positive cis-element for expression of the unspliced RNA. It was found that the former element made expression of the unspliced RNA dependent upon the latter. These two elements were functional as discrete elements and their activities were relatively position-independent.     

The osa gene of pSa encodes a 21.1-kilodalton protein that suppresses Agrobacterium tumefaciens oncogenicity.

The incompatibility group W plasmid pSa suppresses Agrobacterium tumefaciens oncogenicity (J. Loper and C. Kado, J. Bacteriol. 139:591-596, 1979). The oncogenic suppressive activity was localized to a 3.1-kb region of pSa by Tn5 mutagenesis and deletion analysis. Within this fragment, a 1.1-kb subclone bearing oncogenic suppressive activity was subjected to further characterization. Nucleotide sequencing of the 1.1-kb fragment revealed a 570-bp open reading frame (ORF1) that has a coding capacity for a protein of 21.1 kDa. Sequencing of flanking regions revealed a second ORF (ORF2) located 3 bp upstream of ORF1, with a coding capacity for a protein of 22.8 kDa. Gene fusions of these ORFs to a T7 phi 10 expression system in Escherichia coli resulted in the synthesis of polypeptides of the predicted sizes. An E. coli promoter consensus sequence was not found in the expected positions in the region preceding ORF1. However, several sequences with similarity to the consensus -10 sequence of the A. tumefaciens vir gene promoters were found upstream of ORF1. Potential translational start signals are upstream of ORF1 and ORF2. These sequences showed no significant similarity at the nucleotide or amino acid levels with those in available data bases. However, the C-terminal portion of the ORF1 protein is rich in hydrophobic residues. Perhaps oncogenicity suppression is effected by an association of this protein with the Agrobacterium membrane such that T-DNA transfer is blocked.     

Translation of the first upstream ORF in the hepatitis B virus pregenomic RNA modulates translation at the core and polymerase initiation codons

The human hepatitis B virus (HBV) has a compact genome encoding four major overlapping coding regions: the core, polymerase, surface and X. The polymerase initiation codon is preceded by the partially overlapping core and four or more upstream initiation codons. There is evidence that several mechanisms are used to enable the synthesis of the polymerase protein, including leaky scanning and ribosome reinitiation. We have examined the first AUG in the pregenomic RNA, it precedes that of the core. It initiates an uncharacterized short upstream open reading frame (uORF), highly conserved in all HBV subtypes, we designated the C0 ORF. This arrangement suggested that expression of the core and polymerase may be affected by this uORF. Initiation at the C0 ORF was confirmed in reporter constructs in transfected cells. The C0 ORF had an inhibitory role in downstream expression from the core initiation site in HepG2 cells and in vitro, but also stimulated reinitiation at the polymerase start when in an optimal context. Our results indicate that the C0 ORF is a determinant in balancing the synthesis of the core and polymerase proteins.     

The Choice of Translation Initiation Site of the Rep Proteins from Goose Parvovirus P9-Generated mRNA Is Governed by Splicing and the Nature of the Excised Intron

The goose parvovirus (GPV) Rep 1 and Rep 2 proteins are encoded by P9-generated mRNAs that are either unspliced or spliced within the rep gene region, respectively. These mRNAs are present in an approximately equal ratio. The translation of Rep 1 was initiated from the first AUG in unspliced P9-generated mRNA; however, this AUG was bypassed in spliced P9-generated RNA and Rep 2 translation initiated predominately at the next initiating AUG downstream. We show that the choice of the site of initiation of translation of GPV Rep-encoding mRNAs is governed both by the splicing process itself and by the nature of the excised intron.Goose parvovirus (GPV) has identical hairpin termini, is most similar in both nucleotide sequence and protein homology to adeno-associated virus 2 (AAV2), and has been classified as a member of the Dependovirus genus (10-12); however, unlike the AAVs, GPV can replicate efficiently without the aid of a helper virus (12). The RNA expression profile of GPV is a surprising hybrid of features of the Parvovirus and Dependovirus genera of the Parvovirinae (7). Similar to the Dependovirus AAV5, RNAs transcribed from the GPV upstream P9 promoter, which encode the viral Rep protein(s), are polyadenylated at high efficiency at a polyadenylation [(pA)p] site located within the small intron in the center of the genome (7). No promoter analogous to the Dependovirus P19 promoter has been detected; however, similar to minute virus of mice (MVM) and other members of the Parvovirus genus, approximately half of the pre-mRNAs generated from the P9 promoter are additionally spliced within the putative GPV Rep coding region between a donor site located at nucleotide (nt) 814 and an acceptor site at nt 1198 (7). The GPV RNA profile has been shown to be the same in both human 293T and goose CGBQ cells (7). Thus, the mechanism that GPV uses for the expression of its nonstructural gene is more like that used by members of the autonomous Parvovirus group.In this report, we describe the coding strategy for the nonstructural proteins of GPV. We demonstrate that the large Rep 1 protein is encoded uninterruptedly in open reading frame 1 (ORF 1) from the unspliced P9-generated mRNA using an initiating AUG codon at nt 537. The smaller Rep 2 protein is encoded by the spliced P9-generated mRNA; it initiates in ORF 2 at an AUG at nt 650 and continues in ORF 1 after the splice. Strikingly, the first upstream AUG at nt 537 is not utilized in spliced P9-generated mRNA. We show that the choice of initiation site is governed by the splicing process itself and by the nature of the excised intron.     

Sequential Partially Overlapping Gene Arrangement in the Tricistronic S1 Genome Segments of Avian Reovirus and Nelson Bay Reovirus: Implications for Translation Initiation

Previous studies of the avian reovirus strain S1133 (ARV-S1133) S1 genome segment revealed that the open reading frame (ORF) encoding the final sigmaC viral cell attachment protein initiates over 600 nucleotides distal from the 5' end of the S1 mRNA and is preceded by two predicted small nonoverlapping ORFs. To more clearly define the translational properties of this unusual polycistronic RNA, we pursued a comparative analysis of the S1 genome segment of the related Nelson Bay reovirus (NBV). Sequence analysis indicated that the 3'-proximal ORF present on the NBV S1 genome segment also encodes a final sigmaC homolog, as evidenced by the presence of an extended N-terminal heptad repeat characteristic of the coiled-coil region common to the cell attachment proteins of reoviruses. Most importantly, the NBV S1 genome segment contains two conserved ORFs upstream of the final sigmaC coding region that are extended relative to the predicted ORFs of ARV-S1133 and are arranged in a sequential, partially overlapping fashion. Sequence analysis of the S1 genome segments of two additional strains of ARV indicated a similar overlapping tricistronic gene arrangement as predicted for the NBV S1 genome segment. Expression analysis of the ARV S1 genome segment indicated that all three ORFs are functional in vitro and in virus-infected cells. In addition to the previously described p10 and final sigmaC gene products, the S1 genome segment encodes from the central ORF a 17-kDa basic protein (p17) of no known function. Optimizing the translation start site of the ARV p10 ORF lead to an approximately 15-fold increase in p10 expression with little or no effect on translation of the downstream final sigmaC ORF. These results suggest that translation initiation complexes can bypass over 600 nucleotides and two functional overlapping upstream ORFs in order to access the distal final sigmaC start site.     

First committed step of lipid A biosynthesis in Escherichia coli: sequence of the lpxA gene.

The min 4 region of the Escherichia coli genome contains genes (lpxA and lpxB) that encode proteins involved in lipid A biosynthesis. We have determined the sequence of 1,350 base pairs of DNA upstream of the lpxB gene. This fragment of DNA contains the complete coding sequence for the 28.0-kilodalton lpxA gene product and an upstream open reading frame capable of encoding a 17-kilodalton protein (ORF17). In addition there appears to be an additional open reading frame (ORF?) immediately upstream of ORF17. The initiation codon for lpxA is a GUG codon, and the start codon for ORF17 is apparently a UUG codon. The start and stop codons overlap between ORF? and ORF17, ORF17 and lpxA, and lpxA and lpxB. This overlap is suggestive of translational coupling and argues that the genes are cotranscribed. Crowell et al. (D.N. Crowell, W.S. Reznikoff, and C.R.H. Raetz, J. Bacteriol. 169:5727-5734, 1987) and Tomasiewicz and McHenry (H.G. Tomasiewicz and C.S. McHenry, J. Bacteriol. 169:5735-5744, 1987) have demonstrated that there are three similarly overlapping coding regions downstream of lpxB including dnaE, suggesting the existence of a complex operon of at least seven genes: 5'-ORF?-ORF17-lpxA-lpxB-ORF23-dnaE-ORF37-3 '.     

Possible role of splice acceptor site in expression of unspliced gag-containing message of Moloney murine leukemia virus.

Moloney murine leukemia virus (MLV) having the gag coding region alone, G3.6, produced a low level of mRNA (1/10 of the wild-type level). Ligation of 441 nucleotides (nt) containing a splice acceptor (SA) site to the downstream portion of the remaining gag region restored the level of the unspliced message, simultaneously activating a cryptic splice donor (SD) site in the middle of the p30 coding region (between nt 1596 and 1597). Ligation of the 441 nt in the same site in the inverted orientation also increased the level of the unspliced message, activating the same SD site (between nt 1596 and 1597) and a new SA site just in front of the inserted 441 nt (between nt 4770 and 4771). Deletion or inversion of the 441-nt SA sequence from the wild-type MLV or from int in-frame deletion or int frameshift mutant MLVs of nearly full size resulted in the loss of spliced mRNA and concomitantly in a severe reduction of the unspliced mRNA, particularly at 37 degrees C. Deletion of the 5' SD site did not result in the reduction of the unspliced-mRNA level. When the gag region in G3.6 was replaced with a Neo(r) coding region, the level of expression was high. The data taken together suggest that the presence of an SA signal is necessary for high-level expression of unspliced mRNA encoding Gag or Gag-Pol.     

Characterization of IS1221 from Mycoplasma hyorhinis: expression of its putative transposase in Escherichia coli incorporates a ribosomal frameshift mechanism

Seven complete and two partial copies of IS1221 variants from Mycoplasma hyorhinis and Mycoplasma hyopneumoniae characterized to date have established a consensus IS1221 as a 1513 bp element with unique structural characteristics resembling the IS3 family of bacterial insertion sequences. Each IS1221 copy contains highly conserved 28 bp imperfect terminal inverted repeats and three distinctive internal inverted repeats (LIR, RIR and IIR). IIR is located within the coding region of the element and it is proposed that it plays a critical role in the regulation of putative transposase expression. Consensus IS1221 and one particular copy, G1135.2, contain a single long open reading frame (ORF). Two potential initiation codons are present at nucleotide 46 (AUG46) and nucleotide 397 (AUG397) and both are preceded by strong ribosome-binding sites. Both initiation codons can be used efficiently in an Escherichia coli T7 expression system. The LIR has a negative regulatory effect on translation initiation from AUG46. A -1 translational frameshift event is shown to be involved in expression of the IS1221 ORF and results in the production of 20kDa and 6kDa truncated proteins from the respective upstream initiation codons of the IS1221 ORF. Base substitution and deletion mutations in sequences resembling characterized motifs in documented examples of translational frameshifting resulted in a significant increase in the full-length products and a corresponding decrease in the truncated products from the IS1221 ORF. In contrast to the usual -1 frameshift regulatory event in the IS3 family, which produces a transframe fusion product as the active transposase, IS1221 may have evolved a high-frequency -1 frameshift mechanism that produces a truncated product from the upstream coding domain and thereby results in the regulated low-level production of the full-length presumptive transposase.