Nucleotide sequences of the genes for the alpha,beta and epsilon subunits of wheat chloroplast ATP synthase

Summary The nucleotide sequences of the chloroplast genes for the alpha, beta and epsilon subunits of wheat chloroplast ATP synthase have been determined. Open reading frames of 1512 bp, 1494 bp and 411 bp are deduced to code for polypeptides of molecular weights 55201, 53796 and 15200, identified as the alpha, beta and epsilon subunits respectively by homology with the subunits from other sources and by amino acid sequencing of the epsilon subunit. The genes for the beta and epsilon subunits overlap by 4 bp. The gene for methionine tRNA is located 118 bp downstream from the epsilon subunit gene. Comparisons of the deduced amino acid sequences of the alpha and beta subunits with those from other species suggest regions of the proteins involved in adenine nucleotide binding.     

The barley chloroplast DNA atpBE, trnM2, and trnV1 loci.

The nucleotide sequence of a barley chloroplast DNA 3.7 kb SmaI-HindIII fragment is presented. This fragment contains atpBE, the genes for the beta and epsilon subunits of ATPase; trnM2, the gene for tRNA2met; and trnV1, the gene for tRNA1va1. The atpE-trnM2 interval is 126 bp and trnM2 is transcribed towards atpBE. The trnM2-trnV1 interval is 203 bp and trnV1 is transcribed away from trnM2. The trnV1 locus has a 597 bp intervening sequence. the organization and sequences of these genes are compared to the analogous genes from maize and tobacco chloroplast DNA. Using the latter comparisons the nature of sequence divergence between chloroplast DNAs is discussed.     

The nucleotide sequence of rabbit embryonic globin gene beta 3

The nucleotide sequence of a rabbit embryonic globin gene, beta 3, has been determined from 161 base pairs (bp) on the 5' side of the mRNA cap site to 209 base pairs beyond the 3' poly A addition site. The 5' and 3' ends of mRNA from both embryonic globin genes beta 3 and beta 4 have been determined by an S1 protection assay. Sequences that are highly conserved in the 5' flanking region of eukaryotic structural genes, AATAAAA and CCAAT, are located -25 to -31 nucleotides and -81 to -85 nucleotides, respectively, before the cap site. The CCAAT sequence is duplicated at -108 to -112 nucleotides, as it is in the human fetal gamma-globin genes. Small (124 bp) and large (817 bp) intervening sequences are located between codons 30 and 31 and between 104 and 105, respectively. The sequence AATAAA precedes the predominant poly(A) addition site by 19 nucleotides. Although rabbit globin gene beta 3 is transcribed and translated almost exclusively in embryonic erythrocytes, it shares striking homology with the human gamma-globin genes which are expressed in erythrocytes from fetal liver. The evolutionary conservation of rabbit beta 3 and human gamma correlates well with their similar chromosomal positions in the two genes families.     

Junctions of the large single copy region and the inverted repeats in Spinacia oleracea and Nicotiana debneyi chloroplast DNA: sequence of the genes for tRNAHis and the ribosomal proteins S19 and L2.

This work describes the organization, at the nucleotide sequence level, of genes flanking the junctions of the large single copy regions and the inverted repeats of Spinacia oleracea (spinach) and Nicotiana debneyi chloroplast DNAs. In both genomes, trnH1, the gene for tRNA-His(GUG) is located at the extremity of the large single copy region 3' to psbA, the gene for the 35 kd Photosystem 2 protein. Both psbA and trnH1 are transcribed towards the inverted repeat. In spinach, the first 48 codons of rps19, the gene for the chloroplast ribosomal protein S19, lie in the inverted repeat and the last 44 codons lie in the large single copy region at the end opposite to that carrying trnH1. The gene for a protein homologous to the E. coli ribosomal protein L2, rp12, is in the inverted repeat immediately 5' to rps19 and, like rps19, is transcribed towards the large single copy region. In N. debneyi, but not in spinach, rp12 is interrupted by a 666 bp insertion. The gene for tRNA-lle(CAT), trnl1, is located in the inverted repeats of spinach and N. debneyi, 5' to rp12 and is transcribed in the same direction as rp12.     

Translation through an uncDC mRNA secondary structure governs the level of uncC expression in Escherichia coli.

Escherichia coli expresses the beta and epsilon subunits of F1F0-ATP synthase at relative levels consistent with the 3:1 (beta/epsilon) stoichiometry in the holoenzyme. The mechanism of translational control of expression of the uncC gene (epsilon subunit) relative to the immediately 5' uncD gene (beta subunit) was examined. Previous expression studies and a computer analysis suggested the presence of an RNA secondary structure including the 3' end of uncD, the uncDC intergenic region, and the uncC Shine-Dalgarno sequence (S. D. Dunn and H. G. Dallmann, J. Bacteriol. 172:2782-2784, 1990). Analysis of in vitro-transcribed RNA by cleavage with RNases T1, V1, and CL3 and by chemical modification with dimethyl sulfate and diethyl pyrocarbonate confirmed a predicted structure. Introduction of premature uncD stop codons inserted 5' of the secondary structure strongly reduced epsilon expression, whereas stop codons inserted at positions within the secondary structure showed smaller effects, indicating that translational control of epsilon synthesis involves partial coupling to beta synthesis. Possible mechanisms by which the RNA secondary structure and the unfolding of this structure by translation of uncD may govern the level of uncC expression are discussed.     

Translation of chloroplast-encoded mRNA: potential initiation and termination signals.

A survey of 196 protein-coding chloroplast DNA sequences demonstrated the preference for AUG and UAA codons for initiation and termination of translation, respectively. As in prokaryotes at every nucleotide position from -25 to +25 (AUG is +1 to +3) and for 25 nucleotides 5' and 3' to the termination codon an A or U is predominant, except for C at +5 and G at +22. A Shine-Dalgarno (SD) sequence (GGAGG or tri- or tetranucleotide variant) was found within 100 bp 5' to the AUG codon in 92% of the genes. In 40% of these cases, the location of the SD sequence was similar to that of the consensus for prokaryotes (-12 to -7 5' to AUG), presumed to be optimal for translation initiation. A SD sequence could not be located in 6% of the chloroplast sequences. We propose that mRNA secondary structures may be required for the relocation of a distal SD sequences to within the optimal region (-12 to -7) for initiation of translation. We further suggest that termination at UGA codons in chloroplast genes may occur by a mechanism, involving 16S rRNA secondary structure, which has been proposed for UGA termination in E. coli.     

Nucleotide sequence of a 1.1 kb fragment of the pea chloroplast genome containing three tRNA genes, one of which is located within an open reading frame of 91 codons.

The nucleotide sequence of a 1082 bp fragment from the pea (Pisum sativum) chloroplast genome is presented. This fragment contains genes for tRNAGlu, tRNATyr and tRNAAsp as well as an open reading frame (ORF) of 91 codons on one strand and two ORFs of 52 and 59 codons on the complementary strand. The tRNAAsp gene is located entirely within the ORF of 91 codons. The first 366 bp of the fragment correspond to 376 bp at one end of a recently published (1) sequence from the broad bean (Vicia faba) chloroplast genome. These regions contain the tRNAGlu and tRNATyr genes, which are identical and separated by 60 bp in both species. These two genes are probably cotranscribed. The intergenic regions in the corresponding segments from the two species are, except for a 10 bp deletion in the pea sequence, 94% homologous.     

Stability of structures of the epsilon subunit and terminator of thermophilic ATPase

F1-type ATPase is the central enzyme for ATP synthesis in most organisms. Because of the extreme reconstitutability of thermophilic ATPase (TF1) and diversity of the minor subunits of F1 type ATPase, an operon coding for TF1 was isolated from DNA of thermophilic bacterium PS3, and its terminal region containing the epsilon subunit (TF1 epsilon) and terminator was sequenced. The primary structure of the epsilon subunit (Mr = 14 333) was deduced from the nucleotide sequence (396 base-pairs) and amino-acid sequence of its amino terminus. The conclusions drawn from the results are as follows. Homologies: TF1 epsilon shows only 6% homology with the epsilon subunits of eight species reported, but 50% homology with Escherichia coli epsilon and 41% with chloroplast. The residues having a tendency to form reverse turns (Gly, Pro and Tyr) and His are relatively well conserved. Unlike some F1 epsilon types TF1 epsilon has no ATPase inhibitor activity and is not homologous with ATPase inhibitor. TF1 epsilon is essential to connect F1 to F0, like the b subunit, and is weakly homologous with the b subunit of F0F1. The cause of 3 beta: 1 epsilon subunit stoichiometry: The ribosome binding sequence of TF1 epsilon is TAGGN7, which is incomplete compared with that of TF1 beta. The codon usage for TF1 epsilon is similar to that for TF1 epsilon. The cause of stability of TF1 epsilon and its gene: There are 18 ionic groups at the putative reverse turns and the N- and C-termini of TF1 epsilon, but only 10 ionic groups in the corresponding sites of E. coli epsilon subunit. These ionic groups enhance the external polarity of TF1 epsilon and may intensify subunit-subunit interaction. There is a terminator at the 3' end of the TF1 epsilon gene, which is stabilized by a long (13 base-pairs) stem.     

The nucleotide sequence of a nematode vitellogenin gene.

The nematode, Caenorhabditis elegans, contains a family of six genes that code for vitellogenins. Here we report the complete nucleotide sequence of one of these genes, vit-5. The gene specifies a mRNA of 4869 nucleotides, including untranslated regions of 9 bases at the 5' end and 51 bases at the 3' end. Vit-5 contains four short introns totalling 218 bp. The predicted vitellogenin, yp170A, has a molecular weight of 186,430. At its N terminus it is clearly related to the vitellogenins of vertebrates. However, the vit-5-encoded protein does not contain a serine-rich sequence related to the vertebrate vitellin, phosvitin. In fact, the amino acid composition of the nematode protein is very similar to that of the vertebrate protein without phosvitin. Vit-5 has a highly asymmetric codon choice dictionary. The favored codons are different from those favored in other organisms, but are characteristic of highly expressed C. elegans genes. The strong selection against rare codons is not as great near the 5' end of the gene; rare codons are 15 times more frequent within the first 54 bp than in the next 4.8 kb.     

Chloroplast genes encoding subunits of the H+-ATPase complex of Chlamydomonas reinhardtii are rearranged compared to higher plants: sequence of the atpE gene and location of the atpF and atpI genes

Summary The chloroplast gene for the epsilon subunit (atpE) of the CF₁/CF₀ ATPase in the green alga Chlamydomonas reinhardtii has been localized and sequenced. In contrast to higher plants, the atpE gene does not lie at the 3 end of the beta subunit (atpB) gene in the chloroplast genome of C. reinhardtii, but is located at a position 92 kb away in the other single copy region. The uninterrupted open reading frame for the atpE gene is 423 bp, and the epsilon subunit exhibits 43% derived amino acid homology to that from spinach. Codon usage for the atpE gene follows the restricted pattern seen in other C. reinhardtii chloroplast genes.The genes for the CF₀ subunits I (atpF) and IV (atpI) of the ATPase complex have also been mapped on the chloroplast genome of C. reinhardtii. The six chloroplast ATPase genes in C. reinhardtii are dispersed individually between the two single copy regions of the chloroplast genome, an organization strikingly different from the highly conserved arrangement in two operon-like units seen in chloroplast genomes of higher plants.Abbreviations bp base pairs - CF₁ chloroplast coupling factor 1 - CF₀ chloroplast coupling factor 0 - F₁ coupling factor 1 - F₀ coupling factor 0 - kb kilobase pairs     

Complete nucleotide sequence of the chloroplast genome from a leptosporangiate fern, Adiantum capillus-veneris L.

We determined the complete nucleotide sequence of the chloroplast genome of the leptosporangiate fern, Adiantum capillus-veneris L. (Pteridaceae). The circular genome is 150,568 bp, with a large single-copy region (LSC) of 82,282 bp, a small-single copy region (SSC) of 21,392 bp and inverted repeats (IR) of 23,447 bp each. We compared the sequence to other published chloroplast genomes to infer the location of putative genes. When the IR is considered only once, we assigned 118 genes, of which 85 encode proteins, 29 encode tRNAs and 4 encode rRNAs. Four protein-coding genes, all four rRNA genes and six tRNA genes occur in the IR. Most (57) putative protein-coding genes appear to start with an ATG codon, but we also detected five other possible start codons, some of which suggest tRNA editing. We also found 26 apparent stop codons in 18 putative genes, also suggestive of RNA editing. We found all but one of the tRNA genes necessary to encode the complete repertoire required for translation. The missing trnK gene appears to have been disrupted by a large inversion, relative to other published chloroplast genomes. We detected several structural rearrangements that may provide useful information for phylogenetic studies.     

The nucleotide sequences of tRNASer (GCU) and tRNAGln (UUG) genes from tobacco chloroplasts.

The nucleotide sequence of tobacco chloroplast genes for tRNASer (GCU) and tRNAGln (UUG) have been determined. These tRNA genes are encoded on the same DNA strand and separated by 1144 bp. Two open reading frames of 52 codons and 98 codons have been found in this spacer region. The tRNASer (GCU) and tRNAGln (UUG) deduced from the DNA sequences show 67% and 76% sequence homologies with E. coli tRNASer (GCU) and tRNAGln (UUG), respectively.     

Competency for nonsense-mediated reduction in collagen X mRNA is specified by the 3' UTR and corresponds to the position of mutations in Schmid metaphyseal chondrodysplasia

Nonsense-mediated decay (NMD) is a eukaryotic cellular RNA surveillance and quality-control mechanism that degrades mRNA containing premature stop codons (nonsense mutations) that otherwise may exert a deleterious effect by the production of dysfunctional truncated proteins. Collagen X (COL10A1) nonsense mutations in Schmid-type metaphyseal chondrodysplasia are localized in a region toward the 3' end of the last exon (exon 3) and result in mRNA decay, in contrast to most other genes in which terminal-exon nonsense mutations are resistant to NMD. We introduce nonsense mutations into the mouse Col10a1 gene and express these in a hypertrophic-chondrocyte cell line to explore the mechanism of last-exon mRNA decay of Col10a1 and demonstrate that mRNA decay is spatially restricted to mutations occurring in a 3' region of the exon 3 coding sequence; this region corresponds to where human mutations have been described. This localization of mRNA-decay competency suggested that a downstream region, such as the 3' UTR, may play a role in specifying decay of mutant Col10a1 mRNA containing nonsense mutations. We found that deleting any of the three conserved sequence regions within the 3' UTR (region I, 23 bp; region II, 170 bp; and region III, 76 bp) prevented mutant mRNA decay, but a smaller 13 bp deletion within region III was permissive for decay. These data suggest that the 3' UTR participates in collagen X last-exon mRNA decay and that overall 3' UTR configuration, rather than specific linear-sequence motifs, may be important in specifying decay of Col10a1 mRNA containing nonsense mutations.     

Translation is required for regulation of histone mRNA degradation

When DNA synthesis is inhibited, the mRNAs coding for the replication-dependent histone proteins are selectively destabilized. The histone genes have been altered and reintroduced into tk- mouse L cells by cotransfection with the herpesvirus thymidine kinase gene. Two features of the mRNA are necessary for regulation of degradation: first, the hairpin loop must be present at the 3' end of the histone mRNA; and second, the histone mRNA must be capable of being translated to within 300 nucleotides of the 3' end of the RNA. Polyadenylated histone mRNAs are stable, as are histone mRNAs that contain in-frame termination codons early in the coding region or 500 nucleotide 3' untranslated regions with a normal hairpin loop at the 3' end.