The nucleotide sequence of the chloroplast 5S ribosomal RNA from spinach

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.

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.

Structure and transcription of the 5S rRNA gene from spinach chloroplasts

The nucleotide sequence of the spinach chloroplast 5S rRNA gene and its flanking regions has been determined. A prokaryotic type promoter is to be found upstream of the 5S rRNA gene. Northern blot experiments with selected gene probes show that the 5S gene is co-transcribed with the other ribosomal genes of the operon. This result is confirmed by 5' S1 mapping of in vivo RNAs synthesised in chloroplasts or in an E. coli strain harboring a multicopy plasmid containing the 5S rRNA gene and its flanking regions. In vitro transcription experiments show that initiation of transcription does not occur at the level of the putative 5S rRNA gene promoter. Therefore, we conclude that the 5S rRNA is synthesized only be co-transcription of its gene with the other ribosomal genes of the operon. 3' S1 nuclease mapping in the spacer region between the 4.5S and the 5S rRNA genes reveals a set of protected fragments located in an A.T rich region downstream of a very stable hairpin and immediately upstream of the putative 5S promoter. This result is interpreted by the presence of preterminated transcripts or processing sites in this region.

Structural requirements for the interaction of 5S rRNA with the eukaryotic transcription factor IIIA

In order to study the binding of the eukaryotic transcription factor IIIA to heterologous 5S rRNAs with a low degree of overall sequence conservation (less than 20%) we have utilized a transcription competition assay involving eubacterial, archaebacterial and eukaryotic 5S rRNAs. All the molecules inhibit Xenopus 5S rRNA transcription specifically, which suggests that only a small amount of specific conserved RNA sequences, if indeed any, are essential for the interaction of the transcription factor with the 5S rRNA molecule, whereas universal 5S rRNA secondary structure elements seem to be required. A fragment of Xenopus laevis oocyte 5S rRNA (nucleotides 41-120), which partially maintains the original 5S rRNA structure, also competes for TF III A. In vitro transcription of a naturally occurring mutant of the Xenopus laevis oocyte 5S rRNA gene, the pseudogene, which carries several point mutations within the TF III A binding domain is equally inhibited by exogenous Xenopus 5S rRNA.

A transfer RNAArg gene of Pelargonium chloroplasts, but not a 5S RNA gene, is efficiently transcribed after injection into Xenopus oocyte nuclei

We present the primary structure of a chloroplast tRNAArgACG gene of the plant, Pelargonium zonale, and its faithful expression in Xenopus oocyte nuclei. This tRNAArg gene is located 250 bp downstream of a 5S RNA gene within a cloned 5kb long ribosomal DNA segment (Fig. 1). The Pelargonium tRNAArg gene shares 97% and 86% sequence homology with tRNAArgACG genes of Spirodela oligorhiza and Euglena gracilis chloroplasts, respectively, and also extensive homology (70%) with the corresponding gene of E. coli. It lacks an intervening sequence and, like eukaryotic tRNA genes, does not code for the 3' terminal CCA nucleotides. Moreover, the chloroplast tRNAArg gene carries all the sequence elements essential for transcription by vertebrate RNA polymerase III since it is efficiently expressed in Xenopus oocyte nuclei, even in the presence of 1 microgram/ml alpha-amanitin. In Xenopus oocyte nuclei, no transcripts of the chloroplast 5S RNA gene were detected.

Nucleotide sequences of chloroplast 5S ribosomal RNA from cell suspension cultures of the liverworts Marchantia polymorpha and Jungermannia subulata

The nucleotide sequences of chloroplast 5S rRNAs from cell suspension cultures of the liverworts Marchantia polymorpha and Jungermannia subulata were determined. Their nucleotide sequences, 119 nucleotides long, were highly homologous to each other (96% identity) and had high homology with those from chloroplast 5S rRNAs of two higher plants, tobacco (92% identity) and spinach (92-91% identity), but less homology (87-85% identity) with that from a lower plant, the fern Dryopteris acuminata.

Dynamics of ribosomal RNA structure

The structural dynamics of ribosomal 5S RNAs have been investigated by probing single strandedness through enzymatic cleavage and chemical modification. This comparative study includes 5S rRNAs from E. coli, B. stearothermophilus, T. thermophilus, H. cutirubrum, spinach chloroplast, spinach cytomplasm, and Artemia salina. The structural studies support a unique tertiary interaction in eubacterial 5S rRNAs, involving nucleotides around positions 43 and 75. In addition long range structural effects are demonstrated in E. coli 5S rRNA due to the conversion of C to U at position 92.

The nucleotide sequence of the 4.5S and 5S rRNA genes and flanking regions from Spirodela oligorhiza chloroplasts

The base sequence of Spirodela oligorhiza chloroplast DNA coding for 4.5S and 5S ribosomal RNA, the flanking regions and the spacer between these two genes has been determined. We have compared these sequences with the corresponding ones in other higher plants. Besides a high degree of homology, some interesting differences are found.

Comparative structural analysis of cytoplasmic and chloroplastic 5S rRNA from spinach

5S rRNAs from Spinacea oleracea cytoplasmic and chloroplastic ribosomes have been subjected to digestion with the single strand specific nuclease S1 and to chemical modification of cytidines by sodium bisulphite in order to probe the RNA structure. According to these data, cytoplasmic 5S rRNA can be folded as proposed in the general eukaryotic 5S rRNA structure (1) and 5S rRNA from chloroplastides is shown to be more related to the general eubacterial structure (2).

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

A 6.3 kbp Eco RI-Bam HI fragment which carries most of one of the two rRNA gene clusters of the blue-green alga Anacystis nidulans was cloned into plasmid pBR322. Sequence analysis of the spacer region between the 16S and 23S rRNA genes reveals the presence of genes for tRNAIle and tRNAAla. The 16S rRNA gene is separated from the tRNAIle gene by a 162 bp spacer which shows significant homology to the comparable region in Zea mays plastids. The spacer between the two tRNA genes is 33 bp long and can be folded into a 9 bp stem and loop structure. The 5' portion of the tRNAIle gene is 60% homologous to a "pseudogene"-like sequence which maps beyond the 5S rRNA gene.

Generalized structures of the 5S ribosomal RNAs

The sequences of 5S ribosomal RNAs from a wide-range of organisms have been compared. All sequences fit a generalized 5S RNA secondary structural model. Twenty-three nucleotide positions are found universally, i.e., in 5S RNAs of eukaryotes, prokaryotes, archaebacteria, chloroplasts and mitochondria. One major distinguishing feature between the prokaryotic and eukaryotic 5S RNAs is the number of nucleotide positions between certain universal positions, e.g., prokaryotic 5S RNAs have three positions between the universal positions PuU40 and G44 (using the E. coli numbering system) and eukaryotic 5S RNAs have two. The archaebacterial 5S RNAs appear to resemble the eukaryotic 5S RNAs to varying degrees depending on the species of archaebacteria although all the RNAs conform with the prokaryotic "rule" of chain length between PuU40 and G44. The green plant chloroplast and wheat mitochondrial 5S RNAs appear prokaryotic-like when comparing the number of positions between universal nucleotides. Nucleotide positions common to eukaryotic 5S RNAs have been mapped; in addition, nucleotide sequences, helix lengths and looped-out residues specific to phyla are proposed. Several of the common nucleotides found in the 5S RNAs of metazoan somatic tissue differ in the 5S RNAs of oocytes. These changes may indicate an important functional role of the 5S RNA during oocyte maturation.

Size heterogeneity in Spinacia oleracea (spinach) chloroplast 5S ribosomal RNA

Images

The nucleotide sequence of chloroplast 5S ribosomal RNA from a fern, Dryopteris acuminata

Dryopteris acuminata chloroplasts were found to contain three species of 5S rRNAs with different electrophoretic mobility. The large 5S rRNA species is composed of 122 nucleotides and its sequence is: pUAUUCUGGUGUCCCAGGCGUAGAGGAACCACAC-CGAUCCAUCUCGAACUUGGUGGUGAAACUCUGCCGCGGUAACCA AUACUCGGGGGGGGCCCU-GCGGAAAAAUAGCUCGAUGCCAGGAUAOH. This 5S rRNA shows high sequence homology with those from chloroplasts of flowering plants and from a blue-green alga, Anacystis nidulans.

The 5S ribosomal RNAs of Paracoccus denitrificans and Prochloron

The nucleotide sequences of the 5S rRNAs of Paracoccus denitrificans and Prochloron sp. are (formula: see text), respectively. Specific phylogenetic relationships of P. denitrificans with purple non-sulphur bacteria, and of Prochloron with cyanobacteria are demonstrated, and unique features of potential secondary structure are described.

Conservation of secondary structure in 5 S ribosomal RNA: a uniform model for eukaryotic, eubacterial, archaebacterial and organelle sequences is energetically favourable

The most commonly accepted secondary structure models for 5S RNA differ for molecules of eubacterial origin, where the four-helix model of Fox and Woese is generally cited, and those of eukaryotic origin, where a fifth helix is assumed to exist. We have carefully aligned all available sequences from eukaryotes, eubacteria, chloroplasts, archaebacteria and plant mitochondria. We could thus derive a unified secondary structure model applicable to all 5S RNA sequences known to-date. It contains the five helices already present in the eukaryotic model, extended by additional segments that were not previously assumed to be universally present. One of the helices can be written in two equilibrium forms, which could reflect the existence of a flexible, dynamic structure. For the derivation of the model and the estimation of the free energies we followed a set of rules optimized to predict the tRNA cloverleaf. The stability of the unified model is higher than that of nearly all previously proposed sequence-specific and general models.

The 5S ribosomal RNA of Euglena gracilis cytoplasmic ribosomes is closely homologous to the 5S RNA of the trypanosomatid protozoa

The complete nucleotide sequence of the major species of cytoplasmic 5S ribosomal RNA of Euglena gracilis has been determined. The sequence is: 5' GGCGUACGGCCAUACUACCGGGAAUACACCUGAACCCGUUCGAUUUCAGAAGUUAAGCCUGGUCAGGCCCAGUUAGUAC UGAGGUGGGCGACCACUUGGGAACACUGGGUGCUGUACGCUUOH3'. This sequence can be fitted to the secondary structural models recently proposed for eukaryotic 5S ribosomal RNAs (1,2). Several properties of the Euglena 5S RNA reveal a close phylogenetic relationship between this organism and the protozoa. Large stretches of nucleotide sequences in predominantly single-stranded regions of the RNA are homologous to that of the trypanosomatid protozoan Crithidia fasticulata. There is less homology when compared to the RNAs of the green alga Chlorella or to the RNAs of the higher plants. The sequence AGAAC near position 40 that is common to plant 5S RNAs is CGAUU in both Euglena and Crithidia. The Euglena 5S RNA has secondary structural features at positions 79-99 similar to that of the protozoa and different from that of the plants. The conclusions drawn from comparative studies of cytochrome c structures which indicate a close phylogenetic relatedness between Euglena and the trypanosomatid protozoa are supported by the comparative data with 5S ribosomal RNAs.