Nucleotide sequence of the split tRNA UAA Leu gene from Vicia faba chloroplasts: evidence for structural homologies of the chloroplast tRNALeu intron with the intron from the autosplicable Tetrahymena ribosomal RNA precursor

Transfer RNAs and tRNA genes of Vicia faba chloroplasts

Isolated chloroplasts from broad bean and common bean were found to contain a minimum of 31 and 32 tRNA species, respectively. These individual chloroplast tRNAs were (32)P-labeled in vitro and hybridized to DNA fragments obtained upon digestion of broad bean and common bean chloroplast DNAs with various restriction endonucleases. At least 30 tRNA genes were localized on the physical maps of the two chloroplast genomes. Comparison of the broad bean tRNA gene map to that of common bean revealed DNA sequence rearrangements, such as inversions, insertions/ deletions and duplications, within these two members of the Legu minosae family.

Evolution of the chloroplast trnL-trnF region in the gymnosperm lineages Taxaceae and Cephalotaxaceae

The trnL-trnF region is located in the large single-copy region of the chloroplast genome. It consists of the trnL gene, a group I intron, and the trnL-F intergenic spacer. We analyzed the evolution of the region in three gymnosperm families, Taxaceae, Cephalotaxaceae, and Podocarpaceae, with especially dense sampling in Taxaceae and Cephalotaxaceae, for which we sequenced 43 accessions, representing all species. The trnL intron has a conserved secondary structure and contains elements that are homologous across land plants, and the spacer is highly variable in length and composition. The spatial distribution of nucleotide diversity along the trnL-F region suggests that different portions of this region have different evolutionary patterns. Tandem repeats that form stem-loop structures were detected in both the trnL intron and the trnL-F spacer, and the spacer sequences contain promoter elements for the trnF gene. The presence of promoters and stem-loop structures in the trnL-F spacer and high sequence variation in this region suggest that trnL and trnF are independently transcribed. Stem-loop regions P6, P8, and P9 of the trnL intron and the trnL-F spacer (except the promoter elements) might undergo neutral evolution with respect to their escape from functional constraints.

The chloroplast trnT-trnF region in the seed plant lineage Gnetales

The trnT-trnF region is located in the large single-copy region of the chloroplast genome. It consists of the trnL intron, a group I intron, and the trnT-trnL and trnL-trnF intergenic spacers. We analyzed the evolution of the region in the three genera of the gymnosperm lineage Gnetales (Gnetum, Welwitschia, and Ephedra), with especially dense sampling in Gnetum for which we sequenced 41 accessions, representing most of the 25-35 species. The trnL intron has a conserved secondary structure and contains elements that are homologous across land plants, while the spacers are so variable in length and composition that homology cannot be found even among the three genera. Palindromic sequences that form hairpin structures were detected in the trnL-trnF spacer, but neither spacer contained promoter elements for the tRNA genes. The absence of promoters, presence of hairpin structures in the trnL-trnF spacer, and high sequence variation in both spacers together suggest that trnT and trnF are independently transcribed. Our model for the expression and processing of the genes tRNA(Thr)(UGU), tRNA(Leu)(UAA), and tRNA(Phe) (GAA) therefore attributes the seemingly neutral evolution of the two spacers to their escape from functional constraints.

Chloroplast and nuclear evidence for multiple origins of polyploids and diploids of Hedera (Araliaceae) in the Mediterranean basin

Chloroplast (trnT-L) and nuclear rDNA (ITS) sequence analyses of the Araliaceae provide strong molecular evidence for the monophyly of the genus Hedera. Phylogenetic reconstructions suggest multiple origins and an active polyploidization process not only in the formation of tetraploids (2n = 96), hexaploids (2n = 144), and octoploids (2n = 192), but also of diploids (2n = 48). A high basic chromosome number of x = 24, extensive polyphyly in widespread diploids, and terminal placement of Hedera in phylogenies of the Araliaceae reveal that extant diploid taxa may be, in fact, assemblages of ancestral polyploids from plants of n = 12. Four major lineages containing four types of chloroplast (chlorotypes I, II, III, and IV), which are defined by different trnT-L nucleotide substitutions and two large insertions (50- and 30-bp), provide evidence for evolutionary processes and historical biogeography in Hedera. We propose a scenario where an initial colonization in the Mediterranean basin by Asian ancestors (carrying the ancestral Araliaceae chlorotype I) is followed by differentiation into the four chlorotypes of the Mediterranean region, and then recolonization of Asia and northern Europe only by chlorotype III. The Macaronesian taxa (Hedera azorica, Hedera maderensis ssp. maderensis, and Hedera canariensis) appear to have originated from a single-colonization event to each archipelago with no further contact either with continental or insular species.

Patterns of nucleotide substitution in angiosperm cpDNA trnL (UAA)-trnF (GAA) regions

Patterns of substitution in chloroplast encoded trnL_F regions were compared between species of Actaea (Ranunculales), Digitalis (Scrophulariales), Drosera (Caryophyllales), Panicoideae (Poales), the small chromosome species clade of Pelargonium (Geraniales), each representing a different order of flowering plants, and Huperzia (Lycopodiales). In total, the study included 265 taxa, each with > 900-bp sequences, totaling 0.24 Mb. Both pairwise and phylogeny-based comparisons were used to assess nucleotide substitution patterns. In all six groups, we found that transition/transversion ratios, as estimated by maximum likelihood on most-parsimonious trees, ranged between 0.8 and 1.0 for ingroups. These values occurred both at low sequence divergences, where substitutional saturation, i.e., multiple substitutions having occurred at the same (homologous) nucleotide position, was not expected, and at higher levels of divergence. This suggests that the angiosperm trnL-F regions evolve in a pattern different from that generally observed for nuclear and animal mtDNA (transitional/transversion ratio > or = 2). Transition/transversion ratios in the intron and the spacer region differed in all alignments compared, yet base compositions between the regions were highly similar in all six groups. A>-<T and G<->C transversions were significantly less frequent than the other four substitution types. This correlates with results from studies on fidelity mechanisms in DNA replication that predict A<->T and G<->C transversions to be least likely to occur. It therefore strengthens confidence in the link between mutation bias at the polymerase level and the actual fixation of substitutions as recorded on evolutionary trees, and concomitantly, in the neutrality of nucleotide substitutions as phylogenetic markers.

Evolution and mechanism of translation in chloroplasts

The entire sequence (120-190 kb) of chloroplast genomes has been determined from a dozen plant species. The genome contains from 87 to 183 known genes, of which half encode components involved in translation. These include a complete set of rRNAs and about 30 tRNAs, which are likely to be sufficient to support translation in chloroplasts. RNA editing (mostly C to U base changes) occurs in some chloroplast transcripts, creating start and stop codons and changing codons to retain conserved amino acids. Many components that constitute the chloroplast translational machinery are similar to those of Escherichia coli, whereas only one third of the chloroplast mRNAs contain Shine-Dalgarno-like sequences at the correct positions. Analyses conducted in vivo and in vitro have revealed the existence of multiple mechanisms for translational initiation in chloroplasts.

Complete nucleotide sequence of the chloroplast genome from the green alga Chlorella vulgaris: the existence of genes possibly involved in chloroplast division

The complete nucleotide sequence of the chloroplast genome (150,613 bp) from the unicellular green alga Chlorella vulgaris C-27 has been determined. The genome contains no large inverted repeat and has one copy of rRNA gene cluster consisting of 16S, 23S, and 5S rRNA genes. It contains 31 tRNA genes, of which the tRNALeu(GAG) gene has not been found in land plant chloroplast DNAs analyzed so far. Sixty-nine protein genes and eight ORFs conserved with those found in land plant chloroplasts have also been found. The most striking is the existence of two adjacent genes homologous to bacterial genes involved in cell division, minD and minE, which are arranged in the same order in Escherichia coli. This finding suggests that the mechanism of chloroplast division is similar to bacterial division. Other than minD and minE homologues, genes encoding ribosomal proteins L5, L12, L19, and S9 (rpl5, rpl12, rpl19, and rps9); a chlorophyll biosynthesis Mg chelating subunit (chlI); and elongation factor EF-Tu (tufA), which have not been reported from land plant chloroplast DNAs, are present in this genome. However, many of the new chloroplast genes recently found in red and brown algae have not been found in C. vulgaris. Furthermore, this algal species possesses two long ORFs related to ycf1 and ycf2 that are exclusively found in land plants. These observations suggest that C. vulgaris is closer to land plants than to red and brown algae.

The chloroplast chlL gene of the green alga Chlorella vulgaris C-27 contains a self-splicing group I intron

The chlL gene product is involved in the light-independent synthesis of chlorophyll in photosynthetic bacteria, green algae and non-flowering plants. The chloroplast genome of Chlorella vulgaris strain C-27 contains the first example of a split chlL gene, which is interrupted by 951 bp group I intron in the coding region. In vitro synthesized pre-mRNA containing the entire intron and parts of the flanking exon sequence is able to efficiently self-splice in vitro in the presence of a divalent and a monovalent cation and GTP, to yield the ligated exons and other splicing intermediates characteristic of self-splicing group I introns. The 5' and 3' splice sites were confirmed by cDNA sequencing and the products of the splicing reaction were characterized by primer extension analysis. The absence of a significant ORF in the long P9 region (522 nt), separating the catalytic core from the 3' splice site, makes this intron different from the other known examples of group I introns. Guanosine-mediated attack at the 3' splice site and the presence of G-exchange reaction sites internal to the intron are some other properties demonstrated for the first time by an intron of a protein-coding plastid gene.

The chloroplast genome

The chloroplast genome consists of homogeneous circular DNA molecules. To date, the entire nucleotide sequences (120-190 kbp) of chloroplast genomes have been determined from eight plant species. The chloroplast genomes of land plants and green algae contain about 110 different genes, which can be classified into two main groups: genes involved in gene expression and those related to photosynthesis. The red alga Porphyra chloroplast genome has 70 additional genes, one-third of which are related to biosynthesis of amino acids and other low molecular mass compounds. Chloroplast genes contain at least three structurally distinct promoters and transcribe two or more classes of RNA polymerase. Two chloroplast genes, rps12 of land plants and psaA of Chlamydomonas, are divided into two to three pieces and scattered over the genome. Each portion is transcribed separately, and two to three separate transcripts are joined together to yield a functional mRNA by trans-splicing. RNA editing (C to U base changes) occurs in some of the chloroplast transcripts. Most edited codons are functionally significant, creating start and stop codons and changing codons to retain conserved amino acids.

Mutational analysis of conserved nucleotides in a self-splicing group I intron

We have constructed all single base substitutions in almost all of the highly conserved residues of the Tetrahymena self-splicing intron. Mutation of highly conserved residues almost invariably leads to loss of enzymatic activity. In many cases, activity could be regained by making additional mutations that restored predicted base-pairings; these second site suppressors in general confirm the secondary structure derived from phylogenetic data. At several positions, our suppression data can be most readily explained by assuming non-Watson-Crick base-pairings. In addition to the requirements imposed by the secondary structure, the sequence of the intron is constrained by "negative interactions", the exclusion of particular nucleotide sequences that would form undesirable secondary structures. A comparison of genetic and phylogenetic data suggests sites that may be involved in tertiary structural interactions.

Group I introns as mobile genetic elements: facts and mechanistic speculations--a review

Group I introns form a structural and functional group of introns with widespread but irregular distribution among very diverse organisms and genetic systems. Evidence is now accumulating that several group I introns are mobile genetic elements with properties similar to those originally described for the omega system of Saccharomyces cerevisiae: mobile group I introns encode sequence-specific double-strand (ds) endoDNases, which recognize and cleave intronless genes to insert a copy of the intron by a ds-break repair mechanism. This mechanism results in: the efficient propagation of group I introns into their cognate sites; their maintenance at the site against spontaneous loss; and, perhaps, their transposition to different sites. The spontaneous loss of group I introns occurs with low frequency by an RNA-mediated mechanism. This mechanism eliminates introns defective for mobility and/or for RNA splicing. Mechanisms of intron acquisition and intron loss must create an equilibrium, which explains the irregular distribution of group I introns in various genetic systems. Furthermore, the observed distribution also predicts that horizontal transfer of intron sequences must occur between unrelated species, using vectors yet to be discovered.

Gene structure, organization, and expression in archaebacteria

Major advances have recently been made in understanding the molecular biology of the archaebacteria. In this review, we compare the structure of protein and stable RNA-encoding genes cloned and sequenced from each of the major classes of archaebacteria: the methanogens, extreme halophiles, and acid thermophiles. Protein-encoding genes, including some encoding proteins directly involved in methanogenesis and photoautotrophy, are analyzed on the basis of gene organization and structure, transcriptional control signals, codon usage, and evolutionary conservation. Stable RNA-encoding genes are compared for gene organization and structure, transcriptional signals, and processing events involved in RNA maturation, including intron removal. Comparisons of archaebacterial structures and regulatory systems are made with their eubacterial and eukaryotic homologs.

Conserved sequences and structures of group I introns: building an active site for RNA catalysis--a review

Group I introns fold to form an active site to mediate their own RNA splicing. Sequence elements conserved among the available set of 66 group I introns are compiled. Comparative sequence analysis leads to the prediction of some conserved structural features that have not been widely appreciated. The possible significance of conserved nucleotides within base-paired duplexes is discussed; they might be involved in base triplets or alternate pairing interactions.

Organization and nucleotide sequence of the broad bean chloroplast genes trnL-UAG, ndhF and two unidentified open reading frames

We have determined the nucleotide sequence of a 6.9 kbp BamHI-XbaI fragment of broad bean chloroplasts. Part of this fragment (subfragment BglII-ClaI) is known to contain three tRNA genes (trnL-CAA, trnL-UAA and trnF). We have now further identified a gene coding for the third tRNA(Leu) isoacceptor (trnL-UAG) which is located close to trnF. The BamHI-XbaI fragment also contains the gene for subunit 5 of NADH dehydrogenase (ndhF) and two unidentified open reading frames (ORFx and ORF48). ORFx shares a high sequence homology with the long reading frames of tobacco (ORF1708), spinach (ORF2131), and liverwort (ORF2136), while ORF48 shares sequence homology with ORF69 of liverwort and ORF55 of tobacco.

A class-I intron in a cyanelle tRNA gene from Cyanophora paradoxa: phylogenetic relationship between cyanelles and plant chloroplasts

Cyanelles are photosynthetic organelles which are considered as intermediates between cyanobacteria and chloroplasts, and which have been found in unicellular eukaryotes such as Cyanophora paradoxa. The nucleotide sequence of a 667-bp region of the cyanelle genome from Cyanophora paradoxa containing genes coding for tRNA(UUCGlu) and tRNA(UAALeu) has been determined. The gene coding for tRNA(UAALeu) is split by a 232-bp intron which has a secondary structure typical for class-I structured introns and which is closely related to the intron located in the corresponding gene from liverwort and higher plant chloroplasts. It appears therefore that these tRNA(UAALeu) genes are all derived from one common ancestral gene which already contained a class-I intron.

Structure and organization of Marchantia polymorpha chloroplast genome. II. Gene organization of the large single copy region from rps'12 to atpB

The nucleotide sequence (56,410 base-pairs) of the large single-copy region of chloroplast DNA from the liverwort Marchantia polymorpha has been determined. The sequence starts from one end (JLA) of the large single-copy region and encompasses genes for 21 tRNAs, six ATPase subunits (atpA, atpB, atpE, atpF, atpH and atpI), two photosystem I polypeptides (psaA and psaB), four photosystem II polypeptides (psbA, psbC, psbD and psbG), five ribosomal proteins (rps2, rps4, rps7, rps'12 and rps14), and three RNA polymerase subunits (rpoB, rpoC1 and rpoC2). In addition, we detected 18 open reading frames ranging from 29 to 2136 amino acid residues long, four of which share significant amino acid sequence homology to those of an Escherichia coli malK protein (designated mbpX), human mitochondrial ND2 (ndh2) and ND3 (ndh3) of a respiratory chain NADH dehydrogenase, or a bacterial antenna protein of a light-harvesting complex (lhcA). Sequence analysis suggests that four tRNA genes and six protein genes might be split by introns; they are trnG(UCC), trnK(UUU), trnL(UAA), trnV(UAC), atpF, ndh2, rpoC1, rps'12, ORF135 and ORF167. In the large single-copy region described here, the gene organization deduced is highly conserved with respect to that of higher plants, but an inversion of some 30,000 base-pairs flanked by trnL(CAA) and trnD(GUC) was seen between the liverwort and tobacco chloroplast genomes.

Structure and organization of Marchantia polymorpha chloroplast genome. I. Cloning and gene identification

We have determined the complete nucleotide sequence of chloroplast DNA from a liverwort, Marchantia polymorpha, using a clone bank of chloroplast DNA fragments. The circular genome consists of 121,024 base-pairs and includes two large inverted repeats (IRA and IRB, each 10,058 base-pairs), a large single-copy region (LSC, 81,095 base-pairs), and a small single-copy region (SSC, 19,813 base-pairs). The nucleotide sequence was analysed with a computer to deduce the entire gene organization, assuming the universal genetic code and the presence of introns in the coding sequences. We detected 136 possible genes. 103 gene products of which are related to known stable RNA or protein molecules. Stable RNA genes for four species of ribosomal RNA and 32 species of tRNA were located, although one of the tRNA genes may be defective. Twenty genes encoding polypeptides involved in photosynthesis and electron transport were identified by comparison with known chloroplast genes. Twenty-five open reading frames (ORFs) show structural similarities to Escherichia coli RNA polymerase subunits, 19 ribosomal proteins and two related proteins. Seven ORFs are comparable with human mitochondrial NADH dehydrogenase genes. A computer-aided homology search predicted possible chloroplast homologues of bacterial proteins; two ORFs for bacterial 4Fe-4S-type ferredoxin, two for distinct subunits of a protein-dependent transport system, one ORF for a component of nitrogenase, and one for an antenna protein of a light-harvesting complex. The other 33 ORFs, consisting of 29 to 2136 codons, remain to be identified, but some of them seem to be conserved in evolution. Detailed information on gene identification is presented in the accompanying papers. We postulated that there were 22 introns in 20 genes (8 tRNA genes and 12 ORFs), which may be classified into the groups I and II found in fungal mitochondrial genes. The structural gene for ribosomal protein S12 is trans-split on the opposite DNA strand. The universal genetic code was confirmed by the substitution pattern of simultaneous codons, and by possible codon recognition of the chloroplast-encoded tRNA molecules, assuming no importation of tRNA molecules from the cytoplasm. The nucleotide residue A or T is preferred at the third position of the codons (G+C, 11.9%) and in intergenic spacers (G+C, 19.5%), resulting in an overall G+C content that is low (28.8%) throughout the liverwort chloroplast genome. Possible gene expression signals such as promoters and terminators for transcription, predicted locations of gene products, and DNA replicative origins are discussed.

Pea chloroplast tRNA(Lys) (UUU) gene: transcription and analysis of an intron-containing gene

The pea chloroplast trnK gene which encodes tRNA(Lys) (UUU) was sequenced. TrnK is located 210 bp upstream from the promoter of psbA and immediately downstream from the 3'-end of rbcL. The gene is transcribed from the same DNA strand as psbA and rbcL. A 2447 bp intron with class II features is located in the trnK anticodon loop. The intron contains a 506 amino acid open reading frame which could encode an RNA maturase. The primary transcript of trnK is 2.9 kb long; its 5'-end was identified as a site of transcription initiation by in vitro transcription experiments. The 5'-terminus is adjacent to DNA sequences previously identified as transcription promoter elements. The most abundant trnK transcript is 2.5 kb long with termini corresponding to the 5' and 3' ends of the trnK exons. Intron specific RNAs were not detected. This suggests that RNA processing which produces tRNA(Lys) leads to rapid degradation of intron sequences.

Introns in chloroplast protein-coding genes of land plants

Several protein-coding genes from land plant chloroplasts have been shown to contain introns. The majority of these introns resemble the fungal mitochondrial group II introns due to considerable nucleotide sequence homology at their 5' and 3' ends and they can readily be folded to form six hairpins characteristic of the predicted secondary structure of the mitochondrial group II introns. Recently it has been demonstrated that some mitochondrial group II introns are capable of self-splicing in vitro in the absence of protein co-factors. However evidence presented in this overview suggests that this is probably not the case for chloroplast introns and that trans-acting factors are almost certainly involved in their processing reactions.

Physical map and gene localization on sunflower (Helianthus annuus) chloroplast DNA: evidence for an inversion of a 23.5-kbp segment in the large single copy region

As a first step in the study of chloroplast genome variability in the genus Helianthus, a physical restriction map of sunflower (Helianthus annuus) chloroplast DNA (cpDNA) has been constructed using restriction endonucleases BamH I, Hind III, Pst I, Pvu II and Sac. I. Sunflower circular DNA contains an inverted repeat structure with the two copies (23 kbp each) separated by a large (86 kbp) and a small (20 kbp) single copy region. Its total length is therefore about 152 kbp. Sunflower cpDNA is essentially colinear with that of tobacco with the exception of an inversion of a 23.5-kbp segment in the large single copy region. Gene localization on the sunflower cpDNA and comparison of the gene map with that from tobacco chloroplasts have revealed that the endpoints of the inversion are located between the trnT and trnE genes on the one hand, and between the trnG and trnS genes on the other hand.Analysis of BamH I restriction fragment patterns of H. annuus, H. occidentalis ssp. plantagineus, H. grossesseratus, H. decapetalus, H. giganteus, H. maximiliani and H. tuberosus cpDNAs suggests that structural variations are present in the genus Helianthus.

The maize plastid psbB-psbF-petB-petD gene cluster: spliced and unspliced petB and petD RNAs encode alternative products

The chloroplast psbB, psbF, petB, and petD genes are cotranscribed and give rise to many overlapping RNAs. The mechanism and significance of this mode of expression are of interest, particularly because the accumulation of the psb and pet gene products respond differently to both light and, in C4 species such as maize, developmental signals. We present an analysis of the maize psbB, psbF, petB, and petD genes and intergenic regions. The genes are organized similarly in maize (a C4 species) and in several C3 species. Functional class II-like introns interrupt the 5' ends of petB and petD. Both spliced and unspliced RNAs accumulate; these encode alternative forms of the petB and petD proteins, differing at their N-termini. Promoter-like elements between psbF and petB, and biased codon usage suggest that the differential regulation of the psb and pet genes might be achieved at both the transcriptional and translational levels.

The chloroplast tRNALys(UUU) gene from mustard (Sinapis alba) contains a class II intron potentially coding for a maturase-related polypeptide

The trnK gene endocing the tRNALys(UUU) has been located on mustard (Sinapis alba) chloroplast DNA, 263 bp upstream of the psbA gene on the same strand. The nucleotide sequence of the trnK gene and its flanking regions as well as the putative transcription start and termination sites are shown. The 5' end of the transcript lies 121 bp upstream of the 5' tRNA coding region and is preceded by procaryotic-type "-10" and "-35" sequence elements, while the 3' end maps 2.77 kb downstream to a DNA region with possible stemloop secondary structure. The anticodon loop of the tRNALys is interrupted by a 2,574 bp intron containing a long open reading frame, which codes for 524 amino acids. Based on conserved stem and loop structures, this intron has characteristic features of a class II intron. A region near the carboxyl terminus of the derived polypeptide appears structurally related to maturases.

DNA sequences of tobacco chloroplast genes for tRNA(Ser) (GGA), tRNA (Thr) (UGU), tRNA (Leu) (UAA), tRNA (Phe) (GAA): the tRNA (Leu) gene contains a 503 bp intron

The location and nucleotide sequence of tobacco chloroplast genes for tRNA(Ser) (GGA), tRNA(Thr) (UGU), tRNA(Leu) (UAA) and tRNA(Phe) (GAA) (trnS-GGA, trnT-UGU, trnL-UAA and trnF-GAA, respectively) have been determined. These genes are located in the 10 kbp BamHI fragment which lies in the middle of the large single-copy region of the chloroplast DNA. The gene order is trnS-trnT-trnL-trnF. The trnS, trnL and trnF are encoded on the same strand while the trnT on the opposite strand. The trnL contains a 503 bp intron like maize and broad bean trnL-UAAs.

The mosaic cox1 gene in the mitochondrial genome of Schizosaccharomyces pombe: minimal structural requirements and evolution of group I introns

The gene encoding subunit 1 of cytochrome oxidase (cox1) in the fission yeast Schizosaccharomyces pombe is polymorphic. In strain 50 it contains two group I introns with open reading frames (ORFs) in phase with the upstream exons (Lang, 1984). In strain EF1 two additional very short group I introns which do not possess ORFs were detected by DNA sequencing. These two introns (AI2a and AI3) share distinct characteristics concerning their nucleotide sequence and secondary structure and are located at identical positions as the introns AI4 and AI5 beta, respectively, in the cox1 gene of Saccharomyces cerevisiae. The sequence homology of the cob and cox1 genes around the splice points of introns AI2a, AI4, and BI4 (cob intron 4) might reflect horizontal gene transfer between the distantly related species S. pombe and S. cerevisiae.

Nucleotide sequence of the split tRNAleu(UAA) gene from Sorghum bicolor chloroplasts

The nucleotide (nt) sequence of the split tRNAleu(UAA) gene and 328 nt of its flanking regions from sorghum chloroplasts (cp) has been determined. This gene is located in the BamHI-6 fragment in a map position very similar to that of maize. The exon of sorghum tRNAleu gene has an identical nt sequence to its counterpart in maize. Although the 450 nt of intron in sorghum is 8 nt shorter than that of maize, the nt sequence between them shows 97% homology. Like maize and broad bean, the intron from sorghum cp tRNAleu gene could be folded into a secondary structure which is similar to the postulated structure of the intron from the auto-spliceable rRNA precursor of Tetrahymena. Both introns from sorghum and maize contain open reading frames (ORFs) which are conserved at the N terminus. The putative AUG initiation codon for both ORFs is located in the stem region of a 12-bp secondary structure of highly A + T-rich sequences.

Nucleotide sequences of transfer RNA genes in the Pisum sativum chloroplast DNA

Eight transfer RNA (tRNA) genes which were previously mapped to five regions of the Pisum sativum (pea) chloroplast DNA (ctDNA) have been sequenced. They have been identified as tRNA(Val)(GAC), tRNA(Asn)(GUU), tRNA(Arg)(ACG), tRNA(Leu)(CAA), tRNA(Tyr)(GUA), tRNA(Glu)(UUC), tRNA(His)(GUG), and tRNA(Arg)(UCU) by their anticodons and by their similarity to other previously identified tRNA genes from the chloroplast DNAs of higher plants or from E. gracilis. In addition,two other tRNA genes, tRNA(Gly) (UCC) and tRNA(Ile)(GAU), have been partially sequenced. The tRNA genes are compared to other known chloroplast tRNA genes from higher plants and are found to be 90-100% homologous. In addition there are similarities in the overall arrangement of the individual genes between different plants. The 5' flanking regions and the internal sequences of tRNA genes have been studied for conserved regions and consensus sequences. Two unusual features have been found: there is an apparent intron in the D-loop of the tRNA(Gly)(UCC), and the tRNA(Glu)(UUC) contains GATTC in its T-loop.

Analysis of class I introns in a mitochondrial plasmid associated with senescence of Podospora anserina reveals extraordinary resemblance to the Tetrahymena ribosomal intron

Recently, the nucleotide sequences for three "mitochondrial plasmids" associated with senescence of Podospora anserina were determined (Cummings et al. 1985). One of these sequences, corresponding to the plasmid termed epsilon senDNA, contains three class I introns, all within a protein coding sequence equivalent to the mammalian "URF1" gene. Here, we present primary and secondary structure analyses for two of these introns as well as a partial analysis for the third, which extends beyond the DNA sequence determined. With regard to both primary and secondary structure, the closest known relative of intron 1 is the self-splicing intron in the large ribosomal RNA gene of Tetrahymena. One secondary structure domain at the periphery of intron 1 and Tetrahymena models is also present in intron 2. The latter intron is the longest known class I member and contains remnants of two protein-coding sequences, one of which is split by the other. Evolutionary processes that might be responsible for the unusual structure of introns 1 and 2 are discussed.

RNA splicing in Neurospora mitochondria. Defective splicing of mitochondrial mRNA precursors in the nuclear mutant cyt18-1

cyt18-1 (299-9) is a nuclear mutant of Neurospora crassa that has been shown to have a temperature-sensitive defect in splicing the mitochondrial large rRNA intron. In the present work, we investigate the effect of the cyt18-1 mutation on splicing of mitochondrial mRNA introns. Two genes were studied in detail; the cytochrome b (cob) gene, which contains two introns, and a "long form" of the cytochrome oxidase subunit I (coI) gene, which contains four introns. We found that splicing of both cob introns and splicing of at least two of the coI introns are strongly inhibited in the mutant, whereas splicing of coI intron 1, which is excised as a 2.6 X 10(3) base circle, is relatively unaffected. The rRNA intron and both cob introns are group I introns, whereas the circular coI intron may belong to another structural class. Control experiments showed that the degree of inhibition of splicing is greater in the mutant than can be accounted for by severe inhibition of mitochondrial protein synthesis. Finally, experiments in which mutant cells were shifted from 25 degrees C to 37 degrees C showed that splicing of the large rRNA precursor and splicing of the coI mRNA precursor are inhibited with similar kinetics. Considered together, our results suggest that the cyt18 gene encodes a trans-acting component that is required for the splicing of group I mitochondrial DNA introns or some subclass thereof. Since Neurospora cob intron 1 has been shown to be self-splicing in vitro, defective splicing of this intron in cyt18-1 indicates that an essentially RNA-catalyzed splicing reaction must be facilitated by a trans-acting factor, presumably a protein, in vivo.

The intergenic region between the Vicia faba chloroplast tRNA(CAALeu) and tRNA(UAALeu) genes contains a partial copy of the split tRNA(UAALeu) gene

A cluster of three tRNA genes located on fragment Bam6a from Vicia faba chloroplast DNA has been sequenced: it contains the genes for tRNA(CAALeu), tRNA(UAALeu) and tRNA(Phe). The two tRNA(Leu) genes are separated by 443 bp and are transcribed divergently from different DNA strands. The intergenic region contains a series of short repeats and a partial copy of the split tRNA(UAALeu) gene which includes 100 bp of the 5' flanking region, 35 bp of the 5'exon and the first 42 bp of the intron. It is possible that some of these duplications occurred upon the rearrangement of the two tRNA(Leu) genes in broad bean (and in pea) or upon the deletion of one copy of the inverted repeat, since in all other higher plant chloroplast genomes studied so far these two tRNA(Leu) genes are located far apart on the genome, one being in the inverted repeat region, the other one in the large single copy region. The tRNA(Phe) and tRNA(UAALeu) are encoded by the same DNA strand, and separated by 110 bp.

Location and nucleotide sequence of the genes for tobacco chloroplast tRNAArg (ACG) and tRNALeu(UAG)

The location and nucleotide sequence of the genes and flanking regions for tRNAArg(ACG) and tRNALeu(UAG) on tobacco chloroplast DNA have been determined. The gene arrangement is 5S rRNA-260 bp-tRNAArg-581 bp-tRNAAsn-5.2 kbp-tRNALeu. The tRNAArg and tRNALeu genes are expressed in the chloroplasts. The opposite strand of the tRNAArg gene contains a tRNAArg-like sequence. The tRNAArg, tRNAAsn and tRNALeu coding regions are contained in open reading frames.