Genes for tRNAIle and tRNAAla in the spacer between the 16S and 23S rRNA genes of a blue-green alga: strong homology to chloroplast tRNA genes and tRNA genes of the E. coli rrnD gene cluster

Characterization of the 16S-23S internal transcribed spacer among 34 higher plants: suitability for interspecific plastid transformation

Biomanufacturing by chloroplast transgene expression has the potential to produce significant amounts of biopharmaceuticals, endow plants with novel commercial or humanitarian capabilities, enhance phytoremediation methods and harden plants against adverse environments. Plastid bioengineering exploits the phenomenon of homologous recombination to specifically integrate heterologous sequences into the plastid genome. Previous research suggests the plastid genome 16S-23S internal transcribed spacer provides an advantageous integration site for transgene expression. To characterize the suitability of the 16S-23S region for interspecific recombination, we developed primers against conserved plastid sequences and amplified approximately 2.6 kb from 25 plant species. We analyzed the amplicons with nine species from Genbank for homeology, phylogenetic relationships, potential to form chimeric rDNA elements disruptive to translational/replication systems, and the potential number of recombination events for various minimal essential processing segments (MEPS) lengths. Multiple sequence alignment of the 34 species revealed considerable conservation, with identities exceeding 95% among the angiosperms. Substitutions were statistically clustered, generally in noncoding sites, although proposed functional elements such as the OriA region and 3' terminus of the 16S rRNA exhibited unexpected variation. The nonrandom distribution of substitutions undermines the established, statistical method of estimating the number of recombination initiation sites. This finding is further substantiated by comparing statistical estimates of the number of MEPS sites to a direct count at three different MEPS lengths. We frame this in silico analysis in terms of the potential of the 16S-23S region as a target for interspecific transformation, and describe a 'primer-to-plastid' system to rapidly generate species-specific flanking regions for transformation vectors.

Cloning and sequencing of 16S rDNA and 16S-23S rDNA internal spacer region (ISR) from urease-positive thermophilic Campylobacter (UPTC)

AIMS

To clone and sequence the 16S rDNA and 16S-23S rDNA internal spacer region (ISR) from urease-positive thermophilic Campylobacter (UPTC).

METHODS AND RESULTS

The primer sets for 16S rDNA and 16S-23S rDNA ISR amplified almost the full length of 16S rDNA and 16S-23S rDNA ISR. About 1500 bp for 16S rDNA and about 720 bp for 16S-23S rDNA ISR of the rrn operon of four strains of UPTC were identified after molecular cloning and sequencing.

CONCLUSIONS

The four strains and CCUG18267 of UPTC showed approximately 99% sequence homology of 16S rDNA to each other, 96-97% to Camp. coli, 97-98% to Camp. jejuni and 97-98% to Camp. lari.

SIGNIFICANCE AND IMPACT OF THE STUDY

For the first time, the nucleotide sequence of 16S-23S rDNA ISR of UPTC has been analysed. The sequence of ISR was almost identical among the four strains of UPTC. It is interesting that the UPTC intercistronic tRNAs demonstrated an order of tRNA of 5'-16S-tRNAAla-tRNAIle-23S-3' in the organisms.

Genotyping of axenic and non-axenic isolates of the genus Prochlorococcus and the OMF-'Synechococcus' clade by size, sequence analysis or RFLP of the Internal Transcribed Spacer of the ribosomal operon

PCR amplicons of the Internal Transcribed Spacer (ITS) of the rrn operon of three axenic OMF (oceanic, marine and freshwater) strains of 'Synechococcus' (WH7803, PCC 7001 and PCC 6307, respectively) differ greatly in length from that of the axenic Prochlorococcus marinus subsp. pastoris PCC 9511(T), although these four cyanobacteria cluster relatively closely in phylogenetic trees inferred from 16S rRNA gene sequences. The ITSs of three strains (PCC 9511(T), PCC 6307 and PCC 7001) were sequenced and compared with those available for strains Prochlorococcus MED4 (CCMP 1378) and MIT9313 from genome sequencing projects. In spite of large differences in length, sequence and mean DNA base composition, conserved domains important for transcriptional antitermination and folding of the rRNA transcripts were identified in all ITSs. A new group-specific primer permitted ITS amplification even with non-axenic isolates of Prochlorococcus and one OMF-'Synechococcus' strain. Prochlorococcus isolates of the high-light-adapted clade (HL) differed from representatives of the low-light-adapted clade (LL) by the length of their ITS. Restriction fragment length polymorphism (RFLP) of the ITS amplicons revealed three subclusters among the HL strains. Size, sequence data and RFLP of the ITS amplicons will therefore be valuable markers for the identification of different Prochlorococcus genotypes and for their discrimination from other cyanobacterial relatives with which they often co-exist in oceanic ecosystems.

Is the 16S-23S rRNA internal transcribed spacer region a good tool for use in molecular systematics and population genetics? A case study in cyanobacteria

We amplified, TA-cloned, and sequenced the 16S-23S internal transcribed spacer (ITS) regions from single isolates of several cyanobacterial species, Calothrix parietina, Scytonema hyalinum, Coelodesmium wrangelii, Tolypothrix distorta, and a putative new genus (isolates SRS6 and SRS70), to investigate the potential of this DNA sequence for phylogenetic and population genetic studies. All isolates carried ITS regions containing the sequences coding for two tRNA molecules (tRNA and tRNA). We retrieved additional sequences without tRNA features from both C. parietina and S. hyalinum. Furthermore, in S. hyalinum, we found two of these non-tRNA-encoding regions to be identical in length but different in sequence. This is the first report of ITS regions from a single cyanobacterial isolate not only different in configuration, but also, within one configuration, different in sequence. The potential of the ITS region as a tool for studying molecular systematics and population genetics is significant, but the presence of multiple nonidentical rRNA operons poses problems. Multiple nonidentical rRNA operons may impact both studies that depend on comparisons of phylogenetically homologous sequences and those that employ restriction enzyme digests of PCR products. We review current knowledge of the numbers and kinds of 16S-23S ITS regions present across bacterial groups and plastids, and we discuss broad patterns congruent with higher-level systematics of prokaryotes.

Comparison of conserved structural and regulatory domains within divergent 16S rRNA-23S rRNA spacer sequences of cyanobacteria

PCR amplification of the internal transcribed spacer (ITS) between the 16S rRNA and 23S rRNA genes of the cyanobacterium NOSTOC: PCC 7120 gave three products. Two represented true ITS regions of different sizes, while the third was a heteroduplex. The longer spacer (ITS-L) contained 512 nucleotides and carried tRNA(Ile) and tRNA(Ala) genes, separated by a large stem-loop structure (V2) composed of short tandemly repeated repetitive sequences. Both tRNA genes, and the 5' half of the intervening stem, were absent from the shorter spacer (ITS-S), of length 283 nucleotides, which was otherwise almost completely identical to ITS-L. The two spacer regions of NOSTOC: PCC 7120 were aligned to published ITS sequences of cyanobacteria, the cyanelle of Cyanophora paradoxa and Escherichia coli. Although the ITS regions of cyanobacteria vary in length from 283 to 545 nucleotides and contain either both tRNA(Ile) and tRNA(Ala) genes, only the tRNA(Ile) gene, or neither, there is no correlation between ITS size and coding capacity for tRNAs. Putative secondary structures were determined for the deduced transcripts of the rrn operons of several cyanobacteria and were compared to that of E. coli. Highly conserved motifs important for folding and for maturation of the rRNA transcripts were identified, and regions homologous to bacterial antiterminators (box B-box A) were located. The conserved and variable regions of the cyanobacterial ITS are potential targets of PCR primers and oligonucleotide probes for detection and identification of cyanobacteria at different taxonomic levels.

Complete sequences and organization of the rrnA operon from campylobacter jejuni TGH9011 (ATCC43431)

The rrnA ribosomal RNA (rRNA) operon of Campylobacter jejuni (Cj) TGH9011 (ATCC43431) was cloned and sequenced to completion. rRNAs were then characterized by primer extension and S1 nuclease mapping analysis. The secondary structure models of Cj 16S and 23S rRNAs were constructed, and the models were compared to the corresponding models from other eubacterial rRNA. The analysis presented a typical 5'-promoter-16S-tRNAs-23S-5S-terminator-3' prokaryotic rRNA operon structure. However, an unusual organization of the intercistronic tRNAs was observed where the two tRNAs, tRNA(Ala) and tRNA(Ile), were present in the order 5'-16S-tRNA(Ala)-tRNA(Ile)-23S-3', which is opposite of the typical 5'-16S-tRNA(Ile)-tRNA(Ala)-23S-3' structure observed in other bacteria.

Chloroplast ribosomes and protein synthesis

Consistent with their postulated origin from endosymbiotic cyanobacteria, chloroplasts of plants and algae have ribosomes whose component RNAs and proteins are strikingly similar to those of eubacteria. Comparison of the secondary structures of 16S rRNAs of chloroplasts and bacteria has been particularly useful in identifying highly conserved regions likely to have essential functions. Comparative analysis of ribosomal protein sequences may likewise prove valuable in determining their roles in protein synthesis. This review is concerned primarily with the RNAs and proteins that constitute the chloroplast ribosome, the genes that encode these components, and their expression. It begins with an overview of chloroplast genome structure in land plants and algae and then presents a brief comparison of chloroplast and prokaryotic protein-synthesizing systems and a more detailed analysis of chloroplast rRNAs and ribosomal proteins. A description of the synthesis and assembly of chloroplast ribosomes follows. The review concludes with discussion of whether chloroplast protein synthesis is essential for cell survival.

Loss of transfer RNA genes from the plastid 16S-23S ribosomal RNA gene spacer in a parasitic plant

The plastid 16S-23S intergenic spacer region in Conopholis americana, a totally heterotrophic angiosperm in the family Orobanchaceae, has undergone large deletions, including the entire tRNA(Ile) gene and all but small remnants of the tRNA(Ala) gene. The length of the region is less than 20% of that of other land plants which have been investigated, making it the smallest 16S-23S intergenic spacer reported thus far for any land plant. The remaining sequences in the spacer are 90.1% identical to tobacco, indicating that, while the region is well conserved at the sequence level, it is evolving rapidly by deletion. Experiments using the polymerase chain reaction and hybridization to DNA gel blots have failed to reveal either of the two missing tRNA genes elsewhere in the Conopholis cell.

Expression of the Synechocystis sp. strain PCC 6803 tRNA(Glu) gene provides tRNA for protein and chlorophyll biosynthesis

In the cyanobacterium Synechocystis sp. strain PCC 6803 (Synechocystis 6803) delta-aminolevulinic acid (ALA), the sole precursor for the synthesis of the porphyrin rings of heme and chlorophyll, is formed from glutamate activated by acylation to tRNA(Glu) (G. P. O'Neill, D. M. Peterson, A. Schön, M. W. Chen, and D. Söll, J. Bacteriol. 170:3810-3816, 1988; S. Rieble and S. I. Beale, J. Biol. Chem. 263:8864-8871, 1988). We report here that Synechocystis 6803 possesses a single tRNA(Glu) gene which was transcribed as monomeric precursor tRNA and matured into the two tRNA(Glu) species. They differed in the extent of modification of the first anticodon base, 5-methylaminomethyl-2-thiouridine (O'Neill et al., 1988). The two tRNA species had equivalent capacities to stimulate the tRNA-dependent formation of ALA in Synechocystis 6803 and to provide glutamate for protein biosynthesis in an Escherichia coli-derived translation system. These results are in support of a dual role of tRNA(Glu). The levels of tRNA(Glu) were examined by Northern (RNA) blot analysis of cellular RNA and by aminoacylation assays in cultures of Synechocystis 6803 in which the amount of chlorophyll synthesized was modulated over a 10-fold range by various illumination regimens or by the addition of inhibitors of chlorophyll and ALA biosynthesis. In these cultures, the level of tRNA(Glu) was always a constant fraction of the total tRNA population, suggesting that tRNA(Glu) and chlorophyll levels are regulated independently. In addition, the tRNA(Glu) was always fully aminoacylated in vivo.

Sequence analysis of the plastid rDNA spacer region of the chlorophyll c-containing alga Cryptomonas phi

A 0.8 kb AvaI/SmaI fragment of the plastid genome of the chlorophyll c-containing alga Cryptomonas phi encompassing the rRNA spacer region and flanking genes has been cloned and sequenced. The spacer region between the 16S and 23S rRNA genes is 275 base pairs long, one of the shortest yet reported, and it contains uninterrupted genes for tRNA(Ile) and tRNA(Ala) separated by only two base pairs. The coding regions for tRNAs and rRNAs have been compared with those from cyanobacteria, land plants and other algae and the possible evolutionary relationships discussed.

Chloroplast ribosomal DNA organization in the chromophytic alga Olisthodiscus luteus

There are almost no data describing chloroplast genome organization in chromophytic (chlorophyll a/c) plants. In this study chloroplast ribosomal operon placement and gene organization has been determined for the golden-brown alga Olisthodiscus luteus. Ribosomal RNA genes are located on the chloroplast DNA inverted repeat structure. Nucleotide sequence analysis, demonstrated that in contrast to the larger spacer regions in land plants, the 16S-23S rDNA spacer of O. luteus is only 265 bp in length. This spacer contains tRNA(Ile) and tRNA(Ala) genes which lack introns and are separated by only 3 bp. The sequences of the tRNA genes and 16S and 23S rDNA termini flanking the spacer were examined to determine homology between O. luteus, chlorophytic plant chloroplast DNA, and prokaryotes.

The central part of the cyanelle rDNA unit of Cyanophora paradoxa: Sequence comparison with chloroplasts and cyanobacteria

The 287-bp spacer and the flanking 3'-end of the 16S- and 5'-end of the 23S-rRNA genes of the cyanelles from Cyanophora paradoxa have been sequenced and compared with the corresponding regions of cyanobacteria and chloroplasts. The spacer contains the uninterrupted genes for tRNA(ile) and tRNA(ala). All coding regions show high homology to their prokaryotic counterparts. At the 3'-end of the 16S-rDNA a CCTCCTTT sequence has been identified which is complementary to putative ribosome binding sites observed immediately upstream of the coding region of cyanelle protein genes.

Sequence studies on the soybean chloroplast 16S-23S rDNA spacer region : Comparison with other angiosperm sequences and proposal of a generalized RNA secondary structure model for the intergenic regions

The sequence of the ribosomal spacer region of soybean chloroplast DNA including the 3' end of the 16S rRNA gene, the tRNA(Ala) and tRNA(Ile) genes (but not their introns), the three intergenic regions and the 5' end of the 23S rRNA gene, has been determined. This sequence has been compared to corresponding regions of other angiosperm chloroplast DNAs. Secondary structure models are proposed for the entirety of the intergenic regions a, b and c and for the flanking rRNA regions. A model for a common secondary structure of the ribosomal spacer intergenic regions from chloroplasts of higher plants is proposed, which is supported by comparative evidence.

Identification and sequence analysis of a silent gene (ushA0) in Salmonella typhimurium

The evolution of new or improved enzyme specificities in prokaryotes has been proposed to involve gene duplication, followed by silencing of one of the duplicates at the transcriptional or translational level. Such "silent gene intermediates" are distinct from "cryptic" genes, which are proposed to have a different role in evolution. We describe the identification in Salmonella typhimurium of a silent gene (ushA0) using the active (homologous) ushA gene (encoding UDP-sugar hydrolase) from Escherichia coli as a probe. The ushA0 gene has been cloned and, in the multicopy state, very weak expression can be detected; the gene product was shown to be immunologically and functionally related to the enzyme from E. coli. The sequence of the ushA0 gene was found to be highly homologous to the previously determined sequence of the ushA gene, and the respective promoter and ribosomal-binding sites are also very similar. However, a presumed strong rho-independent terminator in the ushA gene is absent from ushA0; although a weak stem-and-loop structure is present in the 3' region of ushA0, its structure is atypical of rho-independent terminators. The sequence analysis also revealed an insertion-sequence like sequence at the 3' end of ushA0 with a convergent open reading frame terminating 116 base-pairs from the ushA0 stop codon. A deletion of the 5' region of the open reading frame results in increased expression of ushA0, indicating that convergent transcription plays some role in the silencing of ushA0. S. typhimurium contains a UDP-sugar hydrolase, biochemically and genetically distinct from that in E. coli, encoded by the ushB gene. Our results indicate that ushB is not strongly sequence-related to ushA0, and its gene product is not immunologically related to the ushA gene product. ushB is hence a functional duplicate of ushA and provides a rationale for the silencing of ushA0. This situation, and the DNA sequence comparison of ushA and ushA0, strongly suggests that rather than being a cryptic gene, ushA0 has been silenced recently during the evolution of S. typhimurium.

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.

Genes for the alpha and beta subunits of phycocyanin

Phycocyanin (PC) is a light-harvesting protein common to blue-green and red algae. We have isolated the genes for the two apoprotein subunits, alpha and beta, of PC from the blue-green alga Agmenellum quadruplicatum PR-6. We synthesized eight sense-strand tetradecameric oligonucleotide probes that could encode a particular pentapeptide in PC alpha from A. quadruplicatum. Only one probe hybridized with total RNA from this organism. This oligonucleotide showed homology to a unique restriction fragment when used to probe Southern blots of A. quadruplicatum DNA. The probe-homologous 3.1-kilobase pair HindIII fragment was cloned. The nucleotide sequence of a 1.7-kilobase pair segment of this clone was determined. Two open reading frames are contained in this region, which correspond in deduced amino acid sequence to PC alpha and PC beta subunits. Both coding sequences are in the same orientation, separated by 105 base pairs, with the PC beta gene 5' to the PC alpha gene. Each gene has a Shine-Dalgarno-type sequence near the initiation codon. Codon frequencies in the two genes may be correlated with the abundance of their products. The deduced amino acid sequences of the gene products show considerable homology with the alpha and beta PC subunits from other species.

Apparent operon for a 5S ribosomal RNA gene and for tRNA genes in the archaebacterium Methanococcus vannielii

The nucleotide sequence of the chromosomal segment from Methanococcus vannielii previously shown to encode a gene for 5S ribosomal RNA (rRNA) unlinked to any other rRNA genes (Jarsch et al. 1983) was determined. It was found that the 5S rRNA gene is flanked by seven genes for tRNA (tRNAPro, tRNAThr, tRNATyr, tRNALys and tRNAAsp). Two of the tRNA genes (tRNAAsp and tRNALys) are repeated in the cluster. Only the tRNAPro cistron encodes the 3'-CCA tRNA sequence. The 5S rRNA/tRNA gene cluster probably represents one transcriptional unit. The 5'- and 3'-flanking sequences of the tRNA/5S rRNA gene cluster bear some similarity with initiation and termination signals in eubacteria. There is indication that the different 5S rRNA genes from Methanococcus exhibit sequence polymorphism.

Complete nucleotide sequence of the 23S rRNA gene of the Cyanobacterium, Anacystis nidulans

The nucleotide sequence of the Anacystis nidulans 23S rRNA gene, including the 5'- and 3'-flanking regions has been determined. The gene is 2876 nucleotides long and shows higher primary sequence homology to the 23S rRNAs of plastids (84.5%) than to that of E. coli (79%). The predicted rRNA transcript also shares many secondary structural features with those of plastids, reinforcing the endosymbiont hypothesis for the origin of these organelles.

DNA sequence of the 16S rRNA/23S rRNA intercistronic spacer of two rDNA operons of the archaebacterium Methanococcus vannielii

The DNA sequence of the spacer (plus flanking) regions separating the 16S rRNA and 23S rRNA genes of two presumptive rDNA operons of the archaebacterium Methanococcus vannielii was determined. The spacers are 156 and 242 base pairs in size and they share a sequence homology of 49 base pairs following the 3' terminus of the 16S rRNA gene and of about 60 base pairs preceding the 5' end of the 23S rRNA gene. The 242 base pair spacer, in addition contains a sequence which can be transcribed into tRNAAla, whereas no tRNA-like secondary structure can be delineated from the 156 base pair spacer region. Almost complete sequence homology was detected between the end of the 16S rRNA gene and the 3' termini of either Escherichia coli or Halobacterium halobium 16S rRNA, whereas the putative 5' terminal 23S rRNA sequence shared partial homology with E. coli 23S rRNA and eukaryotic 5.8S rRNA.