Overlapping divergent genes in the maize chloroplast chromosome and in vitro transcription of the gene for tRNA

Plant Defenses Against Pests Driven by a Bidirectional Promoter

The plant defense responses to pests results in the synchronized change of a complex network of interconnected genes and signaling pathways. An essential part of this process is mediated by the binding of transcription factors to the specific responsive cis-elements within in the promoters of phytophagous-responsive genes. In this work, it is reported the identification and characterization of a bidirectional promoter that simultaneously co-regulate two divergent genes, At5g10300 and At5g10290, upon arthropod feeding. Computational analysis identified the presence of cis-elements within the intergenic region between two loci, mainly from the DOF but also from the AP2/ERF, Golden 2-like and bHLH families. The function of the bidirectional promoter was analyzed using two enhanced variants of the GFP and CherryFP reporter genes, in both orientations, in transient tobacco and stably transformed Arabidopsis plants. Promoter activity was tested in response to feeding of Tetranychus urticae and Pieris brassicae, as well as wounding, flagellin and chitin treatments. Using RT-qPCR assays and confocal microscopy, it was shown that all treatments resulted in the induction of both reporter genes. Furthermore, our findings revealed the asymmetric character of the promoter with stronger activity in the forward than in the reverse orientation. This study provides an example of a bidirectional promoter with a strong potential to be used in plant biotechnology in pest control that requires stacking of the defense genes.

Structural and Functional Analysis of a Bidirectional Promoter from Gossypium hirsutum in Arabidopsis

Stacked traits have become an important trend in the current development of genomically modified crops. The bidirectional promoter can not only prevent the co-suppression of multigene expression, but also increase the efficiency of the cultivation of transgenic plants with multigenes. In Gossypium hirsutum, Ghrack1 and Ghuhrf1 are head-to-head gene pairs located on chromosome D09. We cloned the 1429-bp intergenic region between the Ghrack1 and Ghuhrf1 genes from Gossypium hirsutum. The cloned DNA fragment GhZU had the characteristics of a bidirectional promoter, with 38.7% G+C content, three CpG islands and no TATA-box. Using gfp and gus as reporter genes, a series of expression vectors were constructed into young leaves of tobacco. The histochemical GUS (Beta-glucuronidase) assay and GFP (green fluorescence protein) detection results indicated that GhZU could drive the expression of the reporter genes gus and gfp simultaneously in both orientations. Furthermore, we transformed the expression vectors into Arabidopsis and found that GUS was concentrated at vigorous growth sites, such as the leaf tip, the base of the leaves and pod, and the stigma. GFP was also mainly expressed in the epidermis of young leaves. In summary, we determined that the intergenic region GhZU was an orientation-dependent bidirectional promoter, and this is the first report on the bidirectional promoter from Gossypium hirsutum. Our findings in this study are likely to enhance understanding on the regulatory mechanisms of plant bidirectional promoters.

Differential transcription in vivo and in vitro of two adjacent maize chloroplast genes: The large subunit of ribulosebisphosphate carboxylase and the 2.2-kilobase gene

The transcription of cloned maize plastid DNA sequences in vitro by maize plastid DNA-dependent RNA polymerase has been studied to expose the roles of the enzyme, polypeptide cofactors, and DNA sequences in the regulation of gene expression. The 4.35-kilobase pair BamHI fragment 9 carries the maize plastid gene for the large subunit of ribulosebisphosphate carboxylase and part of the gene for a 2.2-kilobase RNA. These two genes are separated by approximately 330 base pairs and are transcribed divergently. Transcripts of the gene for the large subunit of ribulosebisphosphate carboxylase are abundant in bundle sheath cells of maize leaves and we show here that transcripts of the 2.2-kilobase RNA gene are present in both mesophyll cells and the adjacent bundle sheath cells. In vitro, in the presence of the S factor, maize chloroplast DNA-dependent RNA polymerase produces a transcript of the gene for the large subunit of ribulose-bisphosphate carboxylase with a 5' terminus like that of the corresponding mRNA isolated from plastids, transcribes chloroplast DNA sequences of Bam fragment 9 in a chimeric plasmid in preference to the vehicle RSF 1030 and, in a ratio of 3:1, preferentially transcribes the gene for the large subunit of ribulosebisphosphate carboxylase over the 2.2-kilobase RNA gene from supercoiled chimeric plasmid DNA.

A gene coding for tRNA is located near 5' terminus of 16S rRNA gene in Zea mays chloroplast genome

A region of 635 base pairs preceding a gene for 16S rRNA in the Zea mays chloroplast genome has been mapped and its sequence has been determined. Screening for structural elements common to tRNAs reveals a gene coding for tRNA(Val) (GU(U) (C)) positioned 303 base pairs proximal to the 5' end of the 16S rRNA gene. Both the tRNA(Val) and the 16S rRNA are coded in the same DNA strand. The tRNA nucleotide sequence predicted from the DNA sequence meets all structural characteristics common to tRNA primary and secondary structures. In a quantitative comparison with primary structures of the 14 known tRNA(Val) species the chloroplast isoaceptor shows much higher homology with that from prokaryotic than that from eukaryotic species. Regions that Escherichia coli RNA polymerase protects from nuclease attack are observed 25 and 100 base pairs upstream of the tRNA(Val) gene and 105 base pairs upstream of the 16S rRNA gene. Within these regions are short sequences that are very similar to those in the -35 region of E. coli rrn and that may therefore represent all or parts of transcription initiation signals of the respective genes.

Genome-wide identification of C2H2 zinc-finger gene family in rice and their phylogeny and expression analysis

Transcription factors regulate gene expression in response to various external and internal cues by activating or suppressing downstream genes in a pathway. In this study, we provide a complete overview of the genes encoding C(2)H(2) zinc-finger transcription factors in rice, describing the gene structure, gene expression, genome localization, and phylogenetic relationship of each member. The genome of Oryza sativa codes for 189 C(2)H(2) zinc-finger transcription factors, which possess two main types of zinc-fingers (named C and Q). The Q-type zinc fingers contain a conserved motif, QALGGH, and are plant specific, whereas C type zinc fingers are found in other organisms as well. A genome-wide microarray based gene expression analysis involving 14 stages of vegetative and reproductive development along with 3 stress conditions has revealed that C(2)H(2) gene family in indica rice could be involved during all the stages of reproductive development from panicle initiation till seed maturation. A total of 39 genes are up-regulated more than 2-fold, in comparison to vegetative stages, during reproductive development of rice, out of which 18 are specific to panicle development and 12 genes are seed-specific. Twenty-six genes have been found to be up-regulated during three abiotic stresses and of these, 14 genes express specifically during the stress conditions analyzed while 12 are also up-regulated during reproductive development, suggesting that some components of the stress response pathways are also involved in reproduction.

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.

The CaTin1 (Capsicum annuum TMV-induced clone 1) and CaTin1-2 genes are linked head-to-head and share a bidirectional promoter

CaTin1 was expressed relatively early in the TMV-inoculated leaves of hot pepper which is resistant to TMV-P(0) infection. Interestingly, there was another homologous gene (CaTin1-2) located in front of CaTin1 in a head-to-head fashion and they shared a single promoter. The expression profile of the CaTin1-2 was very similar to CaTin1 in all the treatments except the slower induction time compared to CaTin1 upon TMV-P(0) inoculation. The promoter analysis of CaTin1 and CaTin1-2 revealed bidirectionality both in cis-elements and activity. The CaTin1-2 promoter had two TATA-boxes, four GCC-boxes, the root responsive element, and a W1-box. The ethylene-inducible promoter activity depended on GCC-boxes and TMV-inducible activity of the CaTin1-2 promoter reached its highest activity when this promoter had a W1-box.

Cloning, analysis and inactivation of the ndhK gene encoding a subunit of NADH quinone oxidoreductase from Anabaena PCC 7120

The function of the type-1 pyridine nucleotide dehydrogenase (NDH-1) in the cyanobacterium Anabaena PCC 7120 was investigated. Immunological analysis with antibodies raised against NdhK from Synechocystis PCC 6803, a subunit of NDH-1, showed that NdhK in Anabaena PCC 7120 is only present on the plasma membrane, which confirms the results of previous studies [Howitt, C.A., Smith, G.D. & Day, D. A. (1993) Biochim. Biophys. Acta 114], 313-320]. Southern analysis with probes from the operon encoding ndhC-K-J from Synechocystis PCC 6803 showed that this operon is also conserved in Anabaena PCC 7120. Part of the operon was amplified using PCR with degenerate primers designed against two sequences encoding regions of NdhC and NdhJ that are conserved between cyanobacteria and chloroplasts. The nucleotide sequence of ndhK encodes a protein of 245 amino acids with a predicted molecular mass of 27.5 kDa. The coding regions of ndhC and ndhK overlap by 7 bp, as found in the chloroplasts of liverwort, maize, and rice. This is markedly different from the case in Synechocystis PCC 6803 where a 71-bp non-coding, intergenic spacer region lies between ndhC and ndhK. The ndhK clone was interrupted by the insertion of a kanamycin-resistance gene and used to transform Anabaena PCC 7120.20 unsegregated transformants were produced, all of which died during attempts to segregate them. This indicates that under the selection conditions used, ndhK is an essential gene in Anabaena PCC 7120.

Active transcription from a promoter positioned within the coding region of a divergently oriented gene: the tobacco chloroplast rpl32 gene

A new transcription unit has been identified and characterized in the small single-copy region of tobacco chloroplast DNA. A primary transcript (1550 nucleotides) spanning the entire transcription unit contains no significant open reading frames (ORFs), other than ORF55, recently identified as the gene encoding the ribosomal protein CL32 (rpl32). The leader sequence extends 1101 nucleotides from the rpl32 initiation codon. Primer extension and in vitro capping experiments in combination with ribonuclease protection assays, revealed a promoter situated more than 322 bp inside the coding region of ndhF, which is divergently oriented with respect to rpl32. A canonical Pribnow-box is found just upstream of the transcription start site, but a typical -35 motif was not detected. This is the first internal divergent promoter to be characterized in the chloroplast genome.

Characterization of the ndhC-psbG-ORF157/159 operon of maize plastid DNA and of the cyanobacterium Synechocystis sp. PCC6803

The ndhC and ORF159 genes of the maize plastid DNA (ptDNA) were sequenced and maize ORF159 was used to screen a library of genomic DNA of the blue-green alga Synechocystis sp. PCC 6803. The cyanobacterial gene homologous to ORF159 (ORF157) was isolated and sequenced. In sequencing the region upstream of ORF157, reading frames with homology to the ndhC and psbG genes of maize ptDNA were identified. The ndhC and psbG genes overlap in the ptDNAs of maize, tobacco and Marchantia polymorpha, but are separated by a noncoding spacer in Synechocystis. Northern blot analysis showed that the ndhC, psbG and ORF157/159 genes are cotranscribed in maize and Synechocystis. The three genes occur in the same order in ptDNA of maize, tobacco, and M. polymorpha as in Synechocystis 6803. The amino acid sequences of the NDH-C, PSII-G and the ORF157/159 proteins deduced from the maize genes are 65%, 52% and 53% homologous to those of Synechocystis. However, the cyanobacterial and higher plant NDH-C protein sequences are only 23% homologous to the mitochondrial NDH-3 protein. Protein products of in vitro transcription/translation of the Synechocystis transcription unit had apparent molecular masses of 6 kDa (NDH-C), 25 kDa (PSII-G) and 22 kDa (ORF157) on lithium dodecyl sulfate (LDS) polyacrylamide gel electrophoresis. If these are components of an NADH dehydrogenase, cyanobacteria appear to resemble mitochondria more than they do Escherichia coli and Rhodopseudomonas capsulata with regard to this enzyme complex.

Primary structure and sequence organization of the 16S-23S spacer in the ribosomal operon of soybean (Glycine max L.) chloroplast DNA

The nucleotide sequence of a spacer region between 16S and 23S rRNA genes from soybean chloroplasts has been determined. The spacer region is over 3000 bp long and contains two tRNA genes, coding for rRNA(Ile) and tRNA(Ala) which contain intervening sequences of 953 and 811 base pairs respectively. There is a strong homology between the two introns suggesting that they have a common origin. These spacer tRNAs are synthesized as part of a kb precursor molecule containing 16S and 23S rRNA sequences.

The role of insertions/deletions in the evolution of the intergenic region between psbA and trnH in the chloroplast genome

TrnH and the intergenic region between trnH and psbA of the chloroplast genomes of alfalfa (Medicago sativa), Fabaceae, and petunia (Petunia hybrida), Solanaceae, were sequenced and compared to published sequences of that region from other members of those families. A striking feature of these comparisons is the occurrence of insertions/deletions between short, nearly perfect AT-rich direct repeats. The directionality of these mutations in the petunia, tobacco and Nicotiana debneyi lineages within the Solanaceae cannot be discerned. However, we present several alternative hypotheses that are consistent with Goodspeed's 1954 evolutionary treatment of the genus Nicotiana and family Solanaceae. Within the Fabaceae, the major size differences in the intergenic region between alfalfa, pea and soybean are due to insertions/deletions between direct repeats. The alfalfa intergenic region has an inverted repeat stem-loop structure of 210 bases directly 5' to trnH. This structure is an insert relative to the liver-wort. Marchantia polymorpha. Portions of the insert are found also in pea and soybean as well as in published sequences from other dicots representing diverse orders: petunia, tobacco, N. debneyi (Scrophulariales), spinach (Caryophyllales), and Brassica napus (Capparales). Some of the regions of the insert that are missing in these plants appear to have resulted from deletions of sequences between different imperfect direct repeats within, or 5' to and within the insert. Other deletions are not flanked by repeated sequences. A short insert flanked by imperfect direct repeats in B. napus occurs just within the longer alfalfa insert suggesting that both alfalfa and B. napus have remnants of an even longer insert relative to M. polymorpha. From these analyses we hypothesize the insertion of a stem-loop structure into an M. polymorpha-like ancestral land plant, followed by deletions of sequences, often between different imperfect direct repeats within and upstream of the insert, leading to the psbA-trnH intergenic sequences represented by the present-day plants examined.

The sequences of two nuclear genes and a pseudogene for tRNA(Pro) from the higher plant Phaseolus vulgaris

A genomic bank of nuclear DNA (nDNA) from the higher plant Phaseolus vulgaris, constructed using the lambda EMBL-4 vector, has been screened for the presence of tRNA genes. One of the many positive recombinants was found to hybridise several times stronger than the other positives, and has been shown to contain several tRNA genes. We report the structure of two nuclear tRNA genes for tRNA(Pro), namely tRNA(Pro)(UGG) and tRNA(Pro)(AGG), and that of a 'pseudogene' for tRNA(Pro). This 'pseudogene', despite showing 95% homology with the other tRNA(Pro) species presented here, has several features which are likely to affect its transcription or its functioning as a tRNA.

Accurate transcription and processing of 19 Euglena chloroplast tRNAs in a Euglena soluble extract

The transcription and accurate processing of 19 different Euglena gracilis chloroplast tRNAs in a homologous chloroplast soluble extract is described. The chloroplast DNA dependent-RNA polymerase present in the extract selectively transcribes the tRNA genes (Greenberg et al., 1984, J. Biol. Chem., 259: 14880-14887). Two dimensional polyacrylamide gel electrophoresis and RNA fingerprint analysis were used to show that the tRNAs are correctly processed at the 5'- and 3'-ends. The Euglena chloroplast soluble extract contains a 5'-processing or 'RNase P-like' activity and RNases responsible for processing tRNA termini. However, it was not determined if the 3'-CCA was added. Therefore, the soluble extract contains activities that are quite similar to an extract of spinach chloroplasts (Greenberg et al. (1984), Plant Mol. Biol., 3: 97-109). After transcription of total chloroplast DNA in the Euglena soluble extract, thirty-three tRNA sized products were resolved by two dimensional polyacrylamide gel electrophoresis. Nineteen tRNAs could be identified in this mixture.

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.

Localization and nucleotide sequences of the tRNA GCC (Gly) , tRNA GUC (Asp) and tRNA GCA (Cys) genes from wheat chloroplast

The location on the wheat chloroplast DNA map and the nucleotide sequences of the genes coding for tRNA GCC (Gly) (trnG-GCC), tRNA GUC (Asp) (trnD-GUC) and tRNA GCA (Cys) (trnC-GCA) have been determined. These three genes are located in the large single copy region of the chloroplast genome, about half-way between one of the inverted repeats and the gene for the α subunit of ATP synthase. They are located on two Bam H1 fragments, called B6 and B18 by Bowmanet al. (1), which are separated by about 450 bp and which were cloned in our laboratory to allow sequencing. ThetrnD-GUC andtrnC-GCA sequences show 98.6 and 89% homology, respectively, with the corresponding spinach chloroplast tRNA genes sequences (2), which are the only other higher plant chloroplasttrnD-GUC andtrnC-GCA sequenced so far, while no othertrnG-GCC sequence has been published. ThetrnG-GCC sequence shows only 58% homology with the corresponding gene sequence inEuglena chloroplasts (3).

Chloroplast transfer RNAs and tRNA genes of wheat

Fractionation (by two-dimensional polyacrylamide gel electrophoresis) of total tRNA from wheat chloroplasts yields about 33 RNA spots. Of these, 30 have been identified by aminoacylation as containing tRNAs specific for 17 amino acids.Hybridization of labeled individual tRNAs to cloned chloroplast DNA fragments has revealed the location of at least nine pairs of tRNA genes in the segments of the inverted repeat, at least twelve tRNA genes in the large single copy region and one tRNA gene in the small single copy region.A comparison of this wheat chloroplast tRNA gene map to that of maize and of other higher plants suggests that gene rearrangements have occurred during evolution, even within cereal chloroplast DNA. These rearrangements have taken place within the inverted repeat, within the large single copy region and between the inverted repeat and the large single copy region.

Sequence of histidyl tRNA, present as a chloroplast insert in mtDNA ofZea mays

Unfractionated tRNA, isolated from maize mitochondria, has been specifically labeled at the -CCA end and used to recover a tRNA gene-bearing fragment from a clone bank of maize mitochondrial DNA. This gene has been mapped, sequenced and found to carry the anticodon for histidine. The sequence of the gene and that of bases in its near vicinity are identical to maize chloroplast tRNA(His), although sequences more distant on the fragment are not homologous with cpDNA. The junction of the cpDNA insert has been sequenced.

Organization and sequence of five tRNA genes and of an unidentified reading frame in the wheat chloroplast genome: evidence for gene rearrangements during the evolution of chloroplast genomes

The genes for the initiator tRNA(Met)CAU, tRNA(Gly)UCC, tRNA(Thr)GGU, tRNA(Glu)UUC and tRNA(Tyr)GUA and an open reading frame of 62 codons have been identified by sequencing a 2,358 bp BamHI and a 1,378 bp BamHI-Sst2 DNA fragments from wheat chloroplasts. A comparison of the organization of these five tRNA genes and of the open reading frame on the wheat, tobacco and spinach chloroplast genomes suggests that at least three genomic inversions must have occurred during the evolution of the wheat chloroplast genome from a spinach-like ancestor genome. Furthermore, it seems that in wheat the 91 bp intergenic region between the genes for the initiator tRNA(Met) and the gene for tRNA(Gly)UCC is one end-point of the 20 kbp genomic inversion proposed by Palmer and Thompson in the case of maize (Palmer and Thompson 1982). A 119 bp duplication is located at this junction: the first copy comprises the 91 bp of the intergenic region and the first 28 bp of the tRNA(Met) gene, the second copy is found downstream of the tRNA(Met) gene.

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.

An in vitro system for accurate transcription initiation of chloroplast protein genes

We have developed an homologous in vitro system from spinach chloroplasts that correctly initiates transcription of the plastid genes for the large subunit of ribulose-1,5-bisphosphate carboxylase (rbcL) and the beta subunit of the plastid ATPase (atpB). The transcriptionally active extracts from spinach chloroplasts require circular DNA templates for specific initiation. The RNA polymerase activity is insensitive to rifampicin. The extent of transcription in vitro is a function of the extract:template ratio. The efficiency of the rbcL transcription in vitro is more than one transcript per one hundred templates per hour.

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.

The nucleotide sequences of the genes coding for tRNAArgUCU, tRNAArgACG and tRNAAsnGUU on Spirodela oligorhiza chloroplast DNA

The nucleotide sequences of the genes coding for tRNAArgUCU, tRNAArgACG and tRNAAsnGUU on chloroplast DNA of Spirodela oligorhiza have been determined. All three genes are expressed. 5' Proximal to these genes sequences are found homologous to prokaryotic promoter sequences, which might be involved as transcriptional start motifs.

Accurate processing and pseudouridylation of chloroplast transfer RNA in a chloroplast transcription system

The trancription of a cloned trnV1-trnN1-trnR1 cluster from Euglena gracilis chloroplast (ct) DNA and the processing of a tRNA(Val)-tRNA(Asn)-tRNA(Arg) polycistronic precursor were studied in a spinach ct transcription extract. A soluble ct RNA polymerase selectively transcribes the trnV1-trnN1-trnR1-trnL1 locus in the EcoG fragment from the Euglena ct genome. Restriction enzyme modified templates and RNA fingerprint analysis were used to confirm that the tRNA genes were correctly transcribed. The tRNA(Val)-tRNA(Asn)-tRNA(Arg) polycistronic precursor transcribed by RNA polymerase III in a HeLa cell extract was used as a substrate to demonstrate that a ct tRNA precursor molecule is correctly processed by the ct tRNA processing enzymes. The oligonucleotide pattern of tRNAs processed in vitro from the tRNA(Val)-tRNA(Asn)-RNA(Arg) polycistronic precursor is indistinguishable from tRNA(Val), tRNA(Asn) and tRNA(Arg) transcribed by the ct RNA polymerase and processed in the ct transcription extract. The 3'-CCAOH is added to the tRNAs by a 3' nucleotidyltransferase after correct processing of the 3' terminus. Correct pseudouridylation was demonstrated for uridine residues in a tRNA(Met) m molecule transcribed from a spinach ct trnM1 locus. Thus, the enzymatic activities involved in tRNA biosynthesis in vitro include DNA-dependent (tDNA) RNA polymerase, a 5'-processing activity (RNase P-like), a 3'-exonuclease, an endoribonuclease involved in 3'-tRNA maturation, a tRNA nucleotidyltransferase, and pseudouridylate synthetase.

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.

Nucleotide sequence of soybean chloroplast DNA regions which contain the psb A and trn H genes and cover the ends of the large single copy region and one end of the inverted repeats

The soybean chloroplast psb A gene (photosystem II thylakoid membrane protein of Mr 32 000, lysine-free) and the trn H gene (tRNAHisGUG), which both map in the large single copy region adjacent to one of the inverted repeat structures (IR1), have been sequenced including flanking regions. The psb A gene shows in its structural part 92% sequence homology with the corresponding genes of spinach and N. debneyi and contains also an open reading frame for 353 aminoacids. The aminoacid sequence of a potential primary translation product (calculated Mr, 38 904, no lysine) diverges from that of spinach and N. debneyi in only two positions in the C-terminal part. The trn H gene has the same polarity as the psb A gene and the coding region is located at the very end of the large single copy region. The deduced sequence of the soybean chloroplast tRNAHisGUG is identical with that of Zea mays chloroplasts. Both ends of the large single copy region were sequenced including a small segment of the adjacent IR1 and IR2.

Maize chloroplast DNA encodes a protein sequence homologous to the bacterial ribosome assembly protein S4

A cloned restriction fragment of maize chloroplast DNA (Bam H1 fragment 5) is shown to contain an open reading frame which encodes a basic protein of 201 amino acid residues with 40-50% sequence homology to E. coli ribosomal protein S4. Based on the experimentally determined sequence homology between the highly conserved bacterial ribosomal protein L12 and its chloroplast homologue (Bartsch M., Kimura, M. and Subramanian, A.R. (1982) Proc. Natl. Acad. Sci. USA 79, 6871), we conclude that this reading frame represents the maize chloroplast S4 gene. The nucleotide sequence of a 1100 base pair DNA segment containing the putative gene is presented.

A detailed restriction endonuclease site map of theZea mays plastid genome

Fragments produced by partial digestion of plastid DNA fromZea mays withEco RI were cloned in Charon 4A. A circular, fine structure physical map of the plastid DNA was then constructed from restriction endonucleaseSal I,Pst I,Eco RI, andBam HI recognition site maps of cloned overlapping segments of the plastid genome. These fragments were assigned molecular weights by reference to size markers from both pBR322 and lambda phage DNA. Because of the detail and extent of the derived map, it has been possible to construct a coordinate system which has a unique zero point and within which all the restriction fragments and previously described structural features can be mapped. A computer program was constructed which will display in a circular fashion any of the above features using an X-Y plotter.

Transfer RNA genes ofZea mays chloroplast DNA

A minimum of 37 genes corresponding to tRNAs for 17 different amino acids have been localized on the restriction endonuclease cleavage site map of theZea mays chloroplast DNA molecule. Of these, 14 genes corresponding to tRNAs for 11 amino acids are located in the larger of the two single-copy regions which separate the two inverted copies of the repeat region. One tRNA gene is in the smaller single-copy region. Each copy of the large repeated sequence contains, in addition to the ribosomal RNA genes, 11 tRNA genes corresponding to tRNAs for 8 amino acids. The genes for tRNA2 (Ile) and tRNA(Ala) map in the ribosomal spacer sequence separating the 16S and 23S ribosomal RNA genes. The three isoaccepting species for the tRNAs(Leu) and the three for tRNAs(Ser), as well as the two isoaccepting species for tRNA(Asn), tRNA(Gly), tRNAs(Ile), tRNAs(Met), tRNAs(Thr), are shown to be encoded at different loci.Two independent methods have been used for the localization of tRNA genes on the physical map of the maize chloroplast DNA molecule: (a) cloned chloroplast DNA fragments were hybridized with radioactively-labelled total 4S RNAs, the hybridized RNAs were then eluted, and identified by two-dimensional polyacrylamide gel electrophoresis, and (b) individual tRNAs were(32)P-labelledin vitro and hybridized to DNA fragments generated by digestion of maize chloroplast DNA with various restriction endonucleases.

Nucleotide sequences of tobacco chloroplast genes for elongator tRNAMet and tRNAVal (UAC): the tRNAVal (UAC) gene contains a long intron

The nucleotide sequences of tobacco chloroplast genes for elongator tRNAMet and tRNAVal (UAC) have been determined. The tRNAVal gene contains a 571 base pairs intron located in the anticodon loop. The tRNAVal gene is transcribed as a 750 bases precursor RNA molecule. Both tRNAs deduced from the DNA sequences show 97% sequence homologies with those of spinach chloroplasts.

Post-transcriptional nucleotide addition is responsible for the formation of the 5' terminus of histidine tRNA

All sequenced histidine tRNAs have one additional nucleotide at the 5' end when compared to other tRNA species. Sequence analysis of histidine tRNA genes from Drosophila melanogaster and Schizosaccharomyces pombe showed that the terminal guanylate residue of the mature tRNAs is not encoded by the genes. Analysis of the products from in vitro transcription of these genes in extracts from Drosophila Kc cells demonstrated that the 5'-terminal nucleotide present in the mature tRNA is added post-transcriptionally. The addition reaction requires ATP. A portion of the mature tRNAs are then modified at the 5'-terminal pG. Analysis of the RNA species formed during the in vitro maturation of the Drosophila histidine tRNA primary transcript uncovered the following maturation scheme: (i) the primary transcript is processed by RNase P at the 5' end to form an intermediate precursor; (ii) the 3'-flanking sequence is endonucleolytically removed, and a guanylate moiety is added to the 5' end to form mature-sized histidine tRNA; and (iii) a fraction of the 5'-terminal guanylate residues then undergoes modification. In contrast to the capping of eukaryotic mRNA, the guanylate addition to histidine tRNA results in the formation of a (3'-5')-phosphodiester bond. There are no precedents for the post-transcriptional addition of nucleotides (in phosphodiester linkage) to the 5' end of RNA precursors.

Nucleotide sequence of the 16S - 23S spacer region in an rRNA gene cluster from tobacco chloroplast DNA

The nucleotide sequence of a spacer region between 16S and 23S rRNA genes from tobacco chloroplasts has been determined. The spacer region is 2080 bp long and encodes tRNAIle and tRNAAla genes which contain intervening sequences of 707 bp and 710 bp, respectively. Strong homology between the two intervening sequences is observed. These spacer tRNAs are synthesized as part of an 8.2 kb precursor molecule containing 16S and 23S rRNA sequences.

The nucleotide sequences of two tRNAAsn genes from tobacco chloroplasts

Recombinant plasmids which contain EcoRI fragments of tobacco chloroplast DNA carrying tRNA genes were constructed. Plasmids pTC211 and pTC293 contain the base sequences for tRNAAsn in their 1.4 and 1.1 Md EcoRI fragments, respectively. These two tRNA sequences are identical and are; 5'-TCCTCAGTAGCTCAGTGGTAGAGCGGTCGGCTGTTAACCGATTGGTCGTAGGTTCGAATCCTACTTGGGGAG-3'. Each tRNAAsn gene is located at about 0.9 kb apart from the distal end of each 5S rRNA gene and is coded for by the DNA strand opposite from that of the rRNA genes.