The S7 ribosomal protein gene is truncated and overlaps a cytochrome c biogenesis gene in pea mitochondria

The pea mitochondrial genome contains a truncated rps7 gene lacking ca. 40 codons at its 5 terminus. This single-copy sequence is immediately downstream of and slightly overlapping an actively transcribed and edited reading frame of 744 bp (designated ccb248) homologous to the bacterial helC gene which encodes a subunit of the ABC-type heme transporter involved in cytochrome c biogenesis. This region of mitochondrial DNA appears recombinogenic, and the carboxy-termini of helC-type proteins are predicted to vary in sequence and length among plants. Sequences corresponding to the 5 coding region of rps7 were not detected elsewhere in the pea mitochondrial genome using wheat rps7 probes, and only a very short internal rps7 segment was observed in soybean mitochondrial DNA. The presence of rps7-homologous sequences in the nuclear genomes of pea and soybean is consistent with the recent transfer of a functional mitochondrial rps7 gene to the nucleus in certain plant lineages.     

Structure of a cyanobacterial gene encoding the 50S ribosomal protein L9

The rplI gene encoding the ribosomal protein L9 was found 4 kbp downstream from the desA gene, but on the opposite strand, in the genome of the cyanobacterium Synechocystis PCC6803. The deduced amino acid sequence is homologous to the sequences of the L9 proteins from Escherichia coli and chloroplasts of Arabidopsis and pea. The gene is present as a single copy in the chromosome and is transcribed as a mRNA of 0.64 kb. An open reading frame of unknown function (ORF291) was found in the upstream region of the rplI gene.     

Studies of the gene expression in a somatic hybrid of dihaploid Solanum tuberosum and diploid S. brevidens using two-dimensional protein electrophoresis

Two-dimensional protein electrophoretic patterns of leaf, stem and microtuber were compared between a somatic hybrid (Solanum tuberosum + S. brevidens) and parental plants. Polypeptide spots observed in leaf of the somatic hybrid (BT-1) were similar to those of S. brevidens. In the stem of BT-1, the spots characteristic for each parental plants were also observed. Three specific spots (W, X, Y) found in BT-1 were identical to those of S. tuberosum, however their appearance in S. brevidens depended on the culture conditions (observed at 16h daylength regime, but not in the dark with high sucrose concentration). Potato tuber storage protein patatin was observed in small amounts in the microtubers of BT-1. The data indicated that gene expression unique to each parental plants also existed in the somatic hybrid.Abbreviations BAP 6-benzylaminopurine - 2,4-D (2,4-dichlorophenoxy) acetic acid - IAA indole-3-acetic acid - MES 2-(N-morpholino) ethanesulfonic acid - NAA 1-naphthaleneacetic acid - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecylsulfate     

Organisation of the S10, spc and alpha ribosomal protein gene clusters in prokaryotic genomes

Although it is well known that there is no long range colinearity in gene order in bacterial genomes, it is thought that there are several regions that are under strong structural constraints during evolution, in which gene order is extremely conserved. One such region is the str locus, containing the S10-spc-alpha operons. These operons contain genes coding for ribosomal proteins and for a number of housekeeping genes. We compared the organisation of these gene clusters in 111 sequenced prokaryotic genomes (99 bacterial and 12 archaeal genomes). We also compared the organisation to the phylogeny based on 16S ribosomal RNA gene sequences and the sequences of the ribosomal proteins L22, L16 and S14. Our data indicate that there is much variation in gene order and content in these gene clusters, both in bacterial as well as in archaeal genomes. Our data indicate that differential gene loss has occurred on multiple occasions during evolution. We also noted several discrepancies between phylogenetic trees based on 16S rRNA gene sequences and sequences of ribosomal proteins L16, L22 and S14, suggesting that horizontal gene transfer did play a significant role in the evolution of the S10-spc-alpha gene clusters.     

Conservation of ribosomal RNA gene arrangement in the mitochondrial DNA of angiosperms

In six different angiosperms, mitochondrial genes for 18S and 5S rRNAs were found to be closely linked but distant from mitochondrial 26S rRNA genes.This is paper no. 5 in the series Organization and Expression of the Mitochondrial Genome of Plants     

The potato mitochondrial initiator methionine tRNA gene and its flanking regions: an illustration of the diversity of mitochondrial genome rearrangements among plant species

The initiator methionine transfer RNA (tRNAf ^Met) gene was identified on a 347 bpEco RI-Hind III DNA fragment of the potato mitochondrial (mt) genome. The sequence of this gene shows 1 to 7 nucleotide differences with the other plant mt tRNAsf ^Met or tRNAf ^Met genes studied so far. Whereas the tRNAf ^Met gene is present as a single copy in the potato mt genome, a tRNA pseudogene corresponding to 60% of a complete tRNA (from the 5 end to the variable region) and located at 105 nucleotides upstream of the tRNAf ^Met gene on the opposite strand was shown to be repeated at least three times. Furthermore, the physical environment of the tRNAf ^Met gene in the mt genome is very different among plants, which suggests that the tRNAf ^Met gene region has often been implicated in recombination events of plant mt genomes leading to important rearrangements in gene order.     

5S ribosomal gene variation in the soybean and its progenitor

Summary The soybean, Glycine max and its wild progenitor, Glycine soja, have been surveyed for repeat length variation for the nuclearly encoded 5S ribosomal RNA genes. There is little variation among the 33 accessions assayed, with a common repeat length of 345 bases being typical of both taxa. A 334 base size variant was encountered in individuals from two populations of G. soja from China. The low level of variability is in marked contrast to the variation observed within and between the species of the perennial subgenus Glycine.     

A novel plant nuclear gene encoding chloroplast ribosomal protein S9 has a transit peptide related to that of rice chloroplast ribosomal protein L12

We have cloned a novel nuclear gene for a ribosomal protein of rice and Arabidopsis that is like the bacterial ribosomal protein S9. To determine the subcellular localization of the gene product, we fused the N-terminal region and green fluorescent protein and expressed it transiently in rice seedlings. Localized fluorescence was detectable only in chloroplasts, indicating that this nuclear gene encodes chloroplast ribosomal protein S9. The N-terminal region of rice ribosomal protein S9 was found to have a high sequence similarity to the transit peptide region of the rice chloroplast ribosomal protein L12, suggesting that these transit peptides have a common lineage.     

Characterization and functional analysis of a pollen-specific gene st901 in Solanum tuberosum

A pollen-specific gene, sb401, which was isolated from a cDNA library of in vitro geminated pollen of the diploid potato species Solanum berthaultii, belongs to the class of genes expressed late during pollen development. Using sb401 as a probe, a pollen-specific gene st901 was isolated from the genomic library of a potato species Solanum tuberosum cv. Desiree. Sequencing and RT-PCR analysis showed that the st901 genomic gene is 2,889 bp long, contains three exons and two introns, and encodes a putative polypeptide of 217 residues. The predicted protein sequence contains four imperfect repeated motifs of V–V–E–K–K–N/E–E; the core sequence of the repeats (K–K–N/E–E) resembles a microtubule-binding domain of the microtubule-associated protein MAP1B from mouse. The examination of a promoter–reporter construct in transgenic potato plants revealed that the st901 is expressed exclusively in mature pollen grains, which is consistent with the results of Northern blot and RT-PCR. For analysis of the function of st901, transgenic plants harboring antisense copies of st901 cDNA driven by a native st901 promoter were generated. Suppression of st901 gene in potato resulted in aberrant pollen at maturation and pollen viability of transgenic plants ranged from 4.4 to 14.8%, while that of control plants were more than 90%. These results strongly suggest that st901 has an essential role in pollen development.The st901 gene sequence has been deposited in GenBank under accession number AY526087. Accession number for SB401 is X95984.1     

Exploitation of the ribosomal protein L10 R98S mutation to enhance recombinant protein production in mammalian cells

Mammalian cells are commonly used to produce recombinant protein therapeutics, but suffer from a high cost per mg of protein produced. There is therefore great interest in improving protein yields to reduce production cost. We present an entirely novel approach to reach this goal through direct engineering of the cellular translation machinery by introducing the R98S point mutation in the catalytically essential ribosomal protein L10 (RPL10‐R98S). Our data support that RPL10‐R98S enhances translation levels and fidelity and reduces proteasomal activity in lymphoid Ba/F3 and Jurkat cell models. In HEK293T cells cultured in chemically defined medium, knock‐in of RPL10‐R98S was associated with a 1.7‐ to 2.5‐fold increased production of four transiently expressed recombinant proteins and 1.7‐fold for one out of two stably expressed proteins. In CHO‐S cells, eGFP reached a 2‐fold increased expression under stable but not transient conditions, but there was no production benefit for monoclonal antibodies. The RPL10‐R98S associated production gain thus depends on culture conditions, cell type, and the nature of the expressed protein. Our study demonstrates the potential for using a ribosomal protein mutation for pharmaceutical protein production gains, and further research on how various factors influence RPL10‐R98S phenotypes can maximize its exploitability for the mammalian protein production industry.     

Evolutionary conservation of nuclear and nucleolar targeting sequences in yeast ribosomal protein S6A

Over 1 billion years ago, the animal kingdom diverged from the fungi. Nevertheless, a high sequence homology of 62% exists between human ribosomal protein S6 and S6A of Saccharomyces cerevisiae. To investigate whether this similarity in primary structure is mirrored in corresponding functional protein domains, the nuclear and nucleolar targeting signals were delineated in yeast S6A and compared to the known human S6 signals. The complete sequence of S6A and cDNA fragments was fused to the 5'-end of the LacZ gene, the constructs were transiently expressed in COS cells, and the subcellular localization of the fusion proteins was detected by indirect immunofluorescence. One bipartite and two monopartite nuclear localization signals as well as two nucleolar binding domains were identified in yeast S6A, which are located at homologous regions in human S6 protein. Remarkably, the number, nature, and position of these targeting signals have been conserved, albeit their amino acid sequences have presumably undergone a process of co-evolution with their corresponding rRNAs.