Structure and organization of Marchantia polymorpha chloroplast genome. III. Gene organization of the large single copy region from rbcL to trnI(CAU)

The nucleotide sequence (25,320 base-pairs) of a part of the large single-copy region of chloroplast DNA from the liverwort Marchantia polymorpha was determined. This region encodes putative genes for four tRNAs, isoleucine tRNA(CAU), arginine tRNA(CCG), proline tRNA(UGG) and tryptophan tRNA(CCA); eight photosynthetic polypeptides, the large subunit of ribulose bisphosphate carboxylase/oxygenase (rbcL), 51,000 Mr photosystem II chlorophyll alpha apoprotein (psbB), apocytochrome b-559 polypeptides (psbE and psbF), 10,000 Mr phosphoprotein (psbH), cytochrome f preprotein (petA), cytochrome b6 polypeptide (petB), and cytochrome b6/f complex subunit 4 polypeptide (petD); 13 ribosomal proteins (L2, L14, L16, L20, L22, L23, L33, S3, S8, S11, S12, S18 and S19); initiation factor 1 (infA); ribosome-associating polypeptide (secX); and alpha subunit of RNA polymerase (rpoA). Functionally related genes were located in several clusters in this region of the genome. There were two ribosomal protein gene clusters: rpl23-rpl2-rps19-rpl22-rps3-rpl16-+ ++rpl14-rps8-infA-secX-rps11-rpoA, with a gene arrangement similar to that of the Escherichia coli S10-spc-alpha operons, and the rps12'-rpl20-rps18-rpl33 cluster. There were gene clusters encoding photosynthesis components such as the psbB-psbH-petB-petD and the psbE-psbF clusters. Thirteen open reading frames, ranging in length from 31 to 434 amino acid residues, remain to be identified.     

Comparative and functional analysis of the rRNA-operons and their tRNA gene complement in different lactic acid bacteria

The complete genome sequences of the lactic acid bacteria (LAB), Lactobacillus plantarum, Lactococcus lactis, and Lactobacillus johnsonii were used to compare location, sequence, organisation, and regulation of the ribosomal RNA (rrn) operons. All rrn operons of the examined LAB diverge from the origin of replication, which is compatible with their efficient expression. All operons show a common organisation of 5'-16S-23S-5S-3' structure, but differ in the number, location and specificity of the tRNA genes. In the 16S-23S intergenic spacer region, two of the five rrn operons of Lb. plantarum and three of the six of Lb. johnsonii contain tRNA-ala and tRNA-ile genes, while L. lactis has a tRNA-ala gene in all six operons. The number of tRNA genes following the 5S rRNA gene ranges up to 14, 16, and 21 for L. lactis, Lb. johnsonii and Lb. plantarum, respectively. The tRNA gene complements are similar to each other and to those of other bacteria. Micro-heterogeneity was found within the rRNA structural genes and spacer regions of each strain. In the rrn operon promoter regions of Lb. plantarum and L. lactis marked differences were found, while the promoter regions of Lb. johnsonii showed a similar tandem promoter structure in all operons. The rrn promoters of L. lactis show either a single or a tandem promoter structure. All promoters of Lb. plantarum contain two or three -10 and -35 regions, of which either zero to two were followed by an UP-element. The Lb. plantarum rrnA, rrnB, and rrnC promoter regions display similarity to the rrn promoter structure of Esherichia coli. Differences in regulation between the five Lb. plantarum promoters were studied using a low copy promoter-probe plasmid. Taking copy number and growth rate into account, a differential expression over time was shown. Although all five Lb. plantarum rrn promoters are significantly different, this study shows that their activity was very similar under the circumstances tested. An active promoter was also identified within the Lb. plantarum rrnC operon preceding a cluster of 17 tRNA genes.     

Cloning and analysis of the spc ribosomal protein operon of Bacillus subtilis: comparison with the spc operon of Escherichia coli.

A segment of Bacillus subtilis chromosomal DNA homologous to the Escherichia coli spc ribosomal protein operon was isolated using cloned E. coli rplE (L5) DNA as a hybridization probe. DNA sequence analysis of the B. subtilis cloned DNA indicated a high degree of conservation of spc operon ribosomal protein genes between B. subtilis and E. coli. This fragment contains DNA homologous to the promoter-proximal region of the spc operon, including coding sequences for ribosomal proteins L14, L24, L5, S14, and part of S8; the organization of B. subtilis genes in this region is identical to that found in E. coli. A region homologous to the E. coli L16, L29 and S17 genes, the last genes of the S10 operon, was located upstream from the gene for L14, the first gene in the spc operon. Although the ribosomal protein coding sequences showed 40-60% amino acid identity with E. coli sequences, we failed to find sequences which would form a structure resembling the E. coli target site for the S8 translational repressor, located near the beginning of the L5 coding region in E. coli, in this region or elsewhere in the B. subtilis spc DNA.     

Spectinomycin operon ofMicrococcus luteus: Evolutionary implications of organization and novel codon usage

Summary The complete DNA sequence of theMicrococcus luteus spectinomycin (spc) operon and its adjacent regions has been determined. The sequence has revealed the presence of genes that are homologous to those of theEscherichia coli ribosomal and related proteins, L14, L24, L5, S8, L6, L18, S5, L30, L15, and secretion protein Y (secY), and the gene for adenylate kinase (adk). The gene arrangement in the spc operon is essentially the same as that ofE. coli except for the absence in theM. luteus spc operon of the genes for S14 and X protein that exist in theE. coli spc operon.SecY andadk seem to be composed of another operon (adk operon) with at least an open reading frame. The deduced amino acid sequences for these ribosomal proteins are well conserved among the two species (40–65% identity). Reflecting the high genomic guanine and cytosine (GC) content ofM. luteus (74%), the codon usage of the genes is extremely biased toward use of G and C, about 94% of the codon third positions being G or C. Seven codons, AUA, AAA, AGA, UUA, GUA, CUA, and CAA, all of which have A at the codon third positions, are completely absent in theM. luteus genes examined. Out of 11 genes in theM. luteus spc and adk operons, 5 (10) use GUG (UGA) and 6 (1) use AUG (UAA) as an initiation (termination) codon.     

Characterisation of the ribosomal binding site for eukaryotic elongation factor 2 by chemical cross-linking

Ribosomal complexes containing elongation factor 2 (EF-2) were formed by incubation of 80 S ribosomes in the presence of EF-2 and the non-hydrolysable GTP analogue GuoPP[CH2]P. The factor was covalently coupled to the ribosomal proteins located at the factor binding site, by treatment with bifunctional reagents. After isolation of the covalent EF-2.ribosomal protein complexes, the proteins were labelled with 125I and the introduced covalent links cleaved. The ribosomal proteins were identified by electrophoresis in two independent two-dimensional gel systems, followed by autoradiography. After cross-linking with bis(hydroxysuccinimidyl) tartrate (4 A between the reactive groups), protein S3/S3a, S7 and S11 were found as the major ribosomal proteins covalently linked to EF-2. The longer reagent, dimethyl 3,8-diaza-4,7-dioxo-5,6-dihydroxydecanbisimidate (11 A between the reactive groups), covalently coupled proteins S7, S11, L5, L13, L21, L23, L26, L27a and L32 to EF-2. After cross-linking with dimethyl suberimidate (9 A between the reactive groups) proteins S3/3a, S7, S11, L5, L8, L13, L21, L23, L26, L27a, L31 and L32 were identified as belonging to the EF-2-binding site. The results indicate that the ribosomal domain interacting with EF-2 is located on both the small and the large ribosomal subunit close to the subunit interface.     

Translational regulation by ribosomal protein S8 in Escherichia coli: structural homology between rRNA binding site and feedback target on mRNA.

It has been previously shown that ribosomal protein synthesis in Escherichia coli is regulated at the level of translation by certain key ribosomal proteins. In the spc operon, S8 regulates the expression of L5 and some of the subsequent genes, while the first two genes (L14 and L24) are regulated independently. We therefore determined the DNA sequence at the junction of the L24 and L5 genes, which corresponds to the putative feedback target for S8. We show that there is a striking homology between the structure of the mRNA for this region and the known binding site for S8 on 16S rRNA. These results support the theory that the regulation of ribosomal protein synthesis is based on competition between rRNA and mRNA for regulatory ribosomal proteins.     

Analysis of the spc ribosomal protein operon of Thermus aquaticus

The gene region of Thermus aquaticus corresponding to the distal portion of the S10 operon and to the 5'-portion of the Escherichia coli spc operon was cloned, using the E. coli gene for the ribosomal protein L5 as hybridization probe. The gene arrangement was found to be identical to E. coli, i.e. S17, L14, L24, L5, S14, S8 and L6. Stop and start regions of contiguous cistrons overlap, except for the S14-S8 intergenic region, whose size (67 bases) even exceeds the corresponding spacer regions in E. coli and Bacillus subtilis. A G + C content of 94% in third positions of codons was found in the ribosomal protein genes of T. aquaticus analyzed here. The stop codon of gene S17 (the last gene of the S10 operon in E. coli) and the start codon of gene L14 (the first gene of the spc operon in E. coli) overlap in T. aquaticus, thus leaving no space to accommodate an intergenic promoter preceding spc-operon-encoded genes in T. aquaticus. A possible promoter, localized within the S17 coding region, yielded only weak resistance (20 micrograms/ml) to chloramphenicol in E. coli and therefore could be largely excluded as the main promoter for spc-operon-encoded genes. We failed to detect a structure resembling the protein S8 translational repressor site, located at the beginning of the L5 gene in E. coli, in the corresponding region or any other region in the cloned T. aquaticus spc DNA.