The enigma of the gene coding for ribosomal protein S12 in the chloroplasts of Nicotiana.

A 2.9 kbp region from within the inverted repeat of Nicotiana chloroplast DNA hybridized with a chloroplast DNA fragment from Euglena containing the complete rps12 gene coding for ribosomal protein S12. Nucleotide sequencing within this region revealed the existance of two rps12 coding stretches interrupted by 540 bp having class II intron structure. Joining and decoding the exon regions produced a sequence of 85 amino acids colinear and 81% homologous to the S12 protein of Euglena chloroplasts and E. coli, starting from amino acid residue 38 to the stop codon. Immediately upstream of codon 38, conserved intron sequences were located. However, the 5' 37 codon of Nicotiana chloroplast rps12 could not be identified by electron microscopy of RNA-DNA hybrids within a DNA region extending 4000 bp upstream of codon 38, nor by computer search of a completely sequenced region extending for more than 9000 bp upstream of this codon. In E. coli, alteration in rps12 codons 42 or 87 causes streptomycin resistance. However, the nucleotide sequence of the identified rps12 exons in two Nicotiana chloroplast mutants resistant to streptomycin were found to be identical to that of wild type.     

Gene clusters for ribosomal proteins in the mitochondrial genome of a liverwort, Marchantia polymorpha.

We detected 16 genes for ribosomal proteins in the complete sequence of the mitochondrial DNA from a liverwort, Marchantia polymorpha. The genes formed two major clusters, rps12-rps7 and rps10-rpl2-rps19-rps3-rpl16-rpl5- rps14-rps8- rpl6-rps13-rps11-rps1, very similar in organization to Escherichia coli ribosomal protein operons (str and S10-spc-alpha operons, respectively). In contrast, rps2 and rps4 genes were located separately in the liverwort mitochondrial genome (the latter was part of the alpha operon in E. coli). Furthermore, several ribosomal proteins encoded by the liverwort mitochondrial genome differed substantially in size from their counterparts in E. coli and liverwort chloroplast.     

Genes for the ribosomal proteins S12 and S7 and elongation factors EF-G and EF-Tu of the cyanobacterium, Anacystis nidulans: structural homology between 16S rRNA and S7 mRNA

Summary A 6.5 kb region from the genome of the cyanobacterium, Anacystis nidulans 6301 was cloned using the tobacco chloroplast gene for ribosomal protein S12 as a probe. Sequence analysis revealed the presence of genes for ribosomal proteins S12 and S6 and elongation factors EF-G and EF-Tu in this DNA region. The arrangement is rps12 (124 codons)-167 bp spacer-rps7 (156 codons)-77 bp spacer-fus (694 codons)-26 bp spacer-tufA (409 codons), which is similar to that of the Escherichia coli str operon. The deduced amino acid sequences of the A. nidulans S12 and EF-Tu show high homology (72%–82%) with the E. coli and chloroplast counterparts while those of the A. nidulans S7 and EF-G give low homology (51%–59%). Striking structural homology was found between the potential S7 binding region of 16S rRNA and the beginning of S7 mRNA, suggesting that feedback regulation of rps7 expression operates in A. nidulans.     

Isocitrate dehydrogenases from Haloferax volcanii and Sulfolobus solfataricus: enzyme purification, characterisation and N-terminal sequence

Abstract A Pyrococcus woesei Eco RI DNA fragment (3400 bp) harbouring the gene fus for elongation factor 2 (EF-2) was cloned and almost completely sequenced. Unlike Methanococcus vannielii (which displays the 'str operon'-like fus and tuf gene context, 5'- rps 12- rps 7- fus-tuf -3⊃ and similar to Sulfolobus acidocaldarius and Desulfurococcus mobilis , the Pyrococcus fus gene (732 codons) is unlinked to the rps and tuf genes, and is immediately followed (57 bp intergenic spacing) by an ORF of 106 codons. Both ORFs are preceded by potential archaeal promoters located 52 bp (for fus ) and 37 bp (for ORF106) upstream of the putative start codons. The Pyrococcus EF-2(G) equivalent factor is somewhat closer to the eukaryal than to the bacterial homolog, and also shares with the former the C-terminal sequence required for ADP ribosylation of EF-2 by Diphtheria toxin.     

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.     

Euglena gracilis chloroplast ribosomal protein operon: a new chloroplast gene for ribosomal protein L5 and description of a novel organelle intron category designated group III

We describe the structure (3840 bp) of a novel Euglena gracilis chloroplast ribosomal protein operon that encodes the five genes rpl16-rpl14-rpl5-rps8-rpl36. The gene organization resembles the spc and the 3'-end of the S10 ribosomal protein operons of E. coli. The rpl5 is a new chloroplast gene not previously reported for any chloroplast genome to date and also not described as a nuclear-encoded, chloroplast protein gene. The operon contains at least 7 introns. We present evidence from primer extension analysis of chloroplast RNA for the correct in vivo splicing of five of the introns. Two of the introns within the rps8 gene flank an 8 bp exon, the smallest exon yet characterized in a chloroplast gene. Three introns resemble the classical group II introns of organelle genomes. The remaining 4 introns appear to be unique to the Euglena chloroplast DNA. They are uniform in size (95-109 nt), share common features with each other and are distinct from both group I and group II introns. We designate this new intron category as 'group III'.     

Photosystem II of rye. Cloning and determination of the nucleotide sequence of chloroplast DNA fragments, comprising the psbA gene coding for D1 proteins

EcoRI and BamHI fragments of rye chloroplast DNA comprising psbA gene were cloned and a 2729 bp region was sequenced. Cloning of EcoRI fragment into pTZ19R plasmid led to a single nucleotide deletion in the coding region of psbA gene. A scheme of full-length psbA gene cloning is proposed, allowing one to escape the damage effect of the psbA gene expression product on the host cell. The differences between monocot and dicot in nucleotide sequences of DNA downstream of psbA genes are discussed. Gene rps19 is located 131 bp downstream from psbA gene on the complementary strand. The amino acid sequences of D1 and S19 proteins of different species are compared.     

A putative gene of tobacco chloroplast coding for ribosomal protein similar to E. coli ribosomal protein S19.

A partial sequence of a cloned 3.2 Md BamHI fragment from tobacco chloroplast DNA revealed the occurrence of a putative gene for ribosomal protein. The putative gene is located on the left margin of the large single-copy region in the chloroplast DNA. The coding region contains 276 bp (92 codons). The amino acid sequence deduced from the DNA sequence shows 55% homology with that of E. coli S19 (91 amino acid residues).     

The chloroplast genome from a lycophyte (microphyllophyte), <Emphasis Type="Italic">Selaginella uncinata</Emphasis>, has a unique inversion,transpositions and many gene losses

We determined the complete nucleotide sequence of the chloroplast genome of Selaginella uncinata, a lycophyte belonging to the basal lineage of the vascular plants. The circular double-stranded DNA is 144,170 bp, with an inverted repeat of 25,578 bp separated by a large single copy region (LSC) of 77,706 bp and a small single copy region (SSC) of 40,886 bp. We assigned 81 protein-coding genes including four pseudogenes, four rRNA genes and only 12 tRNA genes. Four genes, rps15, rps16, rpl32 and ycf10, found in most chloroplast genomes in land plants were not present in S. uncinata. While gene order and arrangement of the chloroplast genome of another lycophyte, Hupertzia lucidula, are almost the same as those of bryophytes, those of S. uncinata differ considerably from the typical structure of bryophytes with respect to the presence of a unique 20 kb inversion within the LSC, transposition of two segments from the LSC to the SSC and many gene losses. Thus, the organization of the S. uncinata chloroplast genome provides a new insight into the evolution of lycophytes, which were separated from euphyllophytes approximately 400 million years ago. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Chloroplast ribosomal protein S7 of Chlamydomonas binds to chloroplast mRNA leader sequences and may be involved in translation initiation

Certain mutations isolated in the 5' untranslated region (5'UTR) of the chloroplast rps7 gene in Chlamydomonas reduce expression of reporter genes. Second site suppressors in this 5'UTR sequence restore reporter expression. 5'UTR sequences with the original mutations fail to bind a 20-kD protein, one of five proteins that bind to leaders of several chloroplast genes. However, 5'UTRs from suppressed mutants restore binding to this protein but do not bind a 47-kD protein present on the wild type and the original mutant 5'UTRs. The 20-kD protein was shown to be the S7 protein of the chloroplast ribosomal small subunit encoded by rps7, whereas the 47-kD protein was shown to be RB47, a poly(A) binding protein. Our data are consistent with the hypothesis that the S7 protein plays either a general or a specific regulatory role in translation initiation in the chloroplast.     

Antibiotic Resistance Mutations in the Chloroplast 16s and 23s Rrna Genes of Chlamydomonas Reinhardtii: Correlation of Genetic and Physical Maps of the Chloroplast Genome

Mutants resistant to streptomycin, spectinomycin, neamine/kanamycin and erythromycin define eight genetic loci in a linear linkage group corresponding to about 21 kb of the circular chloroplast genome of Chlamydomonas reinhardtii. With one exception, all of these mutants represent single base-pair changes in conserved regions of the genes encoding the 16S and 23S chloroplast ribosomal RNAs. Streptomycin resistance can result from changes at the bases equivalent to Escherichia coli 13, 523, and 912-915 in the 16S gene, or from mutations in the rps12 gene encoding chloroplast ribosomal protein S12. In the 912-915 region of the 16S gene, three mutations were identified that resulted in different levels of streptomycin resistance in vitro. Although the three regions of the 16S rRNA mutable to streptomycin resistance are widely separated in the primary sequence, studies by other laboratories of RNA secondary structure and protein cross-linking suggest that all three regions are involved in a common ribosomal neighborhood that interacts with ribosomal proteins S4, S5 and S12. Three different changes within a conserved region of the 16S gene, equivalent to E. coli bases 1191-1193, confer varying levels of spectinomycin resistance, while resistance to neamine and kanamycin results from mutations in the 16S gene at bases equivalent to E. coli 1408 and 1409. Five mutations in two genetically distinct erythromycin resistance loci map in the 23S rDNA of C. reinhardtii, at positions equivalent to E. coli 2057-2058 and 2611, corresponding to the rib3 and rib2 loci of yeast mitochondria respectively. Although all five mutants are highly resistant to erythromycin, they differ in levels of cross-resistance to lincomycin and clindamycin. The order and spacing of all these mutations in the physical map are entirely consistent with our genetic map of the same loci and thereby validate the zygote clone method of analysis used to generate this map. These results are discussed in comparison with other published maps of chloroplast genes based on analysis by different methods using many of the same mutants.