RNA editing in the cox3 mRNA of Magnolia is more extensive than in other dicot or monocot plants.

The Magnoliaceae are discussed as one of the key species at the root of the flowering plants. To obtain molecular information for one of these phylogenetically interesting plant species, we determined genomic and cDNA sequences of the mitochondrial cox3 gene in Magnolia grandiflora. Twenty-two RNA editing events are identified to alter cytidines in the mRNA to uridines, all but one of which change the encoded amino acid identity. RNA editing in the cox3 coding region is thus more frequent in Magnolia than in other dicot or monocot plants investigated and almost as predominant as in some gymnosperms. The cox3 RNA editing frequency in Magnolia thus occupies an intermediate position between angiosperms and gymnosperms consistent with the phylogenetic position of the Magnoliales.

Physiological, biochemical and molecular aspects of mitochondrial complex I in plants

Respiratory complex I of plant mitochondria has to date been investigated with respect to physiological function, biochemical properties and molecular structure. In the respiratory chain complex I is the major entry gate for low potential electrons from matrix NADH, reducing ubiquinone and utilizing the released energy to pump protons across the inner membrane. Plant complex I is active against a background of several other NAD(P)H dehydrogenases, which do not contribute in proton pumping, but permit and establish several different routes of shuttling electrons from NAD(P)H to ubiquinone. Identification of the corresponding molecular structures, that is the proteins and genes of the different NADH dehydrogenases, will allow more detailed studies of this interactive regulatory network in plant mitochondria. Present knowledge of the structure of complex I and the respective mitochondrial and nuclear genes encoding various subunits of this complex in plants is summarized here. Copyright 1998 Elsevier Science B.V.

Unusually high recombination rate detected in the sex locus region of the honey bee (Apis mellifera).

Sex determination in Hymenoptera is controlled by haplo-diploidy in which unfertilized eggs develop into fertile haploid males. A single sex determination locus with several complementary alleles was proposed for Hymenoptera [so-called complementary sex determination (CSD)]. Heterozygotes at the sex determination locus are normal, fertile females, whereas diploid zygotes that are homozygous develop into sterile males. This results in a strong heterozygote advantage, and the sex locus exhibits extreme polymorphism maintained by overdominant selection. We characterized the sex-determining region by genetic linkage and physical mapping analyses. Detailed linkage and physical mapping studies showed that the recombination rate is <44 kb/cM in the sex-determining region. Comparing genetic map distance along the linkage group III in three crosses revealed a large marker gap in the sex-determining region, suggesting that the recombination rate is high. We suggest that a "hotspot" for recombination has resulted here because of selection for combining favorable genotypes, and perhaps as a result of selection against deleterious mutations. The mapping data, based on long-range restriction mapping, suggest that the Q DNA-marker is within 20,000 bp of the sex locus, which should accelerate molecular analyses.

Gene MRP-L4, encoding mitochondrial ribosomal protein YmL4, is indispensable for proper non-respiratory cell functions in yeast.

In order to characterize individual protein components of the mitochondrial (mt) ribosome for regulatory, functional and evolutionary studies, the yeast nuclear gene MRP-L4 (accession No. Z30582), coding for the mt ribosomal protein (MRP) YmL4, has been cloned using oligodeoxyribonucleotides (oligos) deduced from a partial amino acid (aa) sequence [Graack et al., FEBS Lett. 242 (1988) 4-8] as screening probes. MRP-L4 is located on chromosome XII and codes for a slightly basic protein of 319 aa. The first 14 aa have not been found in the mature protein, and putatively form a signal peptide that is cleaved off during or after mt import. YmL4 has an N terminus very rich in Pro residues, and at its C terminus contains four hydrophobic domains. YmL4 shows no significant sequence similarity to any other sequence from the databases. Gene disruption shows the MRP-L4 product to be indispensable for mt function in cells growing on non-fermentable carbon sources. In contrast to nearly all other MRPs investigated so far, gene disruption of MRP-L4 also affects growth of yeast cells on fermentable carbon sources, suggesting additional cytosolic and/or mt functions of YmL4 besides its involvement in mt protein biosynthesis.

Mitochondrial ribosomes of yeast: isolation of individual proteins and N-terminal sequencing.

Proteins of the small and large subunits of mitochondrial ribosomes from the yeast Saccharomyces cerevisiae were isolated and characterized by two-dimensional gel electrophoresis. Ribosomal proteins of the large subunit were separated by reverse-phase HPLC and up to 37 amino acid residues of the N-terminal sequences of L3, L4, L9 and L31 were determined. No significant homology to ribosomal protein sequences so far determined from other organisms was found.

The mitochondrial genome on its way to the nucleus: different stages of gene transfer in higher plants.

The vast majority of mitochondrial proteins are in all eukaryotes encoded in the nuclear genomes by genes which have been transferred from the original endosymbiont. DNA as well as RNA was and is exchanged between organelles. A functionally successful information transfer, however, requires complex structural and regulatory alterations of the concerned gene. The recently identified variations of the information content in mitochondrial genomes of different plant species represent different stages of the transfer process. These evolutionary intermediates allow a definition of requirements and chances of successful gene transfers.

Extended N-terminal sequencing of proteins of the large ribosomal subunit from yeast mitochondria.

We have determined the N-termini of 26 proteins of the large ribosomal subunit from yeast mitochondria by direct amino acid micro-sequencing. The N-terminal sequences of proteins YmL33 and YmL38 showed a significant similarity to eubacterial ribosomal (r-) proteins L30 and L14, respectively. In addition, several proteins could be assigned to their corresponding yeast nuclear genes. Based on a comparison of the protein sequences deduced from the corresponding DNA regions with the N-termini of the mature proteins, the putative leader peptides responsible for mitochondrial matrix-targeting were compiled. In most leader sequences a relative abundance of aromatic amino acids, preferentially phenylalanine, was found.

The nuclear coded mitoribosomal proteins YmL27 and YmL31 are both essential for mitochondrial function in yeast.

Using synthetic oligonucleotides deduced from the N-terminal amino acid sequence of purified mitoribosomal protein (mt r-protein) YmL27, the corresponding nuclear gene MRP-L27 of the yeast Saccharomyces cerevisiae has been cloned and sequenced. The MRP-L27 gene codes for 146 amino acids and is located on chromosome X. The mature YmL27 protein consists of 130 amino acids - after cleaving the putative mitochondrial signal peptide - with a net charge of +17 and a calculated relative molecular mass of 14,798 Da. The YmL27 protein as well as the yeast mitoribosomal protein YmL31, which had been characterized and its gene (MRP-L31) cloned previously, is essential for mitochondrial function as shown by the inability of gene disrupted mutants for the MRP-L27 or MRP-L31 genes to grow on non-fermentable carbon sources.

Alternative microbial testing: a novel DNA-based detection system for specified microorganisms in pharmaceutical preparations.

Fluorescence-coupled PCR technology was employed to quantify DNA segments specific for Staphylococcus aureus, Pseudomonas aeruginosa, and Enterobacteriaceae. The PCR procedure is put forward as an alternative method for detecting microbial contaminations in pharmaceutical preparations and is compared to the tests for specified microorganisms described in European Pharmacopoeia (EP) 2, 2.6.13 and the USP, chapter 61. Data presented here describe the validation of this analytical method when used for proof of absence of specified microorganisms. The detection systems were specific for the microorganisms analyzed, and led to linear results over a wide range (more than 6-7 log intervals). The correlation coefficients lay above 0.99. The precision of replicate determinations within a single test was observed to be high, the relative standard deviation being between 0.39% and 1.53%. The precision between different tests was also high, with a relative standard deviation between 0.76% and 1.91%. The sensitivity without pre-enrichment amounted to 1-10 CFU. Since determination of the specified bacteria was performed following pre-enrichment, the limit of detection amounted to 1 CFU. Equivalent results were obtained in a study on nine batches of a milky hydrophilic cream (SH-No. M 440 A) with the conventional test for microbial contamination and the PCR procedure. The data presented here strongly indicate that the use of fluorescence-coupled PCR techniques can prove the absence of specified bacteria faster and more efficiently than conventional methods.

The mitochondrial gene encoding ribosomal protein S12 has been translocated to the nuclear genome in Oenothera.

The Oenothera mitochondrial genome contains only a gene fragment for ribosomal protein S12 (rps12), while other plants encode a functional gene in the mitochondrion. The complete Oenothera rps12 gene is located in the nucleus. The transit sequence necessary to target this protein to the mitochondrion is encoded by a 5'-extension of the open reading frame. Comparison of the amino acid sequence encoded by the nuclear gene with the polypeptides encoded by edited mitochondrial cDNA and genomic sequences of other plants suggests that gene transfer between mitochondrion and nucleus started from edited mitochondrial RNA molecules. Mechanisms and requirements of gene transfer and activation are discussed.

The plant mitochondrial 22 kDa (PSST) subunit of respiratory chain complex I is encoded by a nuclear gene with enhanced transcript levels in flowers.

Genes for subunits of respiratory chain complex I are found in mitochondrial, plastid and/or nuclear genomes with varying distributions in the diverse eukaryotic species. The intrinsic PSST subunit of complex I is a mitochondrially encoded protein in Paramecium but is specified by a nuclear gene in animals. In plants to date only the homologous plastid encoded NDH-K gene product has been described. The analogous plant mitochondrial protein is now identified as the 22 kDa complex I subunit and found to be encoded in the nuclear genome of Arabidopsis and potato. The cDNA sequences of clones isolated from both plants are 79% identical in the conserved coding region, while the 5' parts of the reading frames specifying the N-terminal presequences for mitochondrial import differ significantly. The expression of the genes examined in different organs of both plants by Northern blot analysis shows elevated steady-state mRNA levels in flowers. Hence, expression of the gene appears to be organ-specifically regulated by its transcription rate and/or mRNA stability. A 1.6 kb long genomic DNA sequence of Arabidopsis upstream of the transcribed gene region encoding the PSST subunit in Arabidopsis contains several putative promoter sequence motifs. The results are discussed with regard to the appearance of a nuclearly integrated, former mitochondrial gene.

Cloning and characterization of nuclear genes for two mitochondrial ribosomal proteins in Saccharomyces cerevisiae.

The genes for two large subunit proteins, YmL8 and YmL20, of the mitochondrial ribosome of Saccharomyces cerevisiae were cloned by hybridization with synthetic oligonucleotide mixtures corresponding to their N-terminal amino acid sequences. They were termed MRP-L8 and MRP-L20, respectively, and their nucleotide sequences were determined using a DNA sequencer. The MRP-L8 gene was found to encode a 26.8-kDa protein whose deduced amino acid sequence has a high degree of similarity to ribosomal protein L17 of Escherichia coli. The gene MRP-L20 was found to encode a 22.3-kDa protein with a presequence consisting of 18 amino acid residues. By Southern blot hybridization to the yeast chromosomes separated by field-inversion gel electrophoresis, the MRP-L8 and MRP-L20 genes were located on chromosomes X and XI, respectively. Gene disruption experiments indicate that their products, YmL8 and YmL20 proteins, are essential for the mitochondrial function and the absence of these proteins causes instability of the mitochondrial DNA.

Molecular cloning of the nuclear gene for mitochondrial ribosomal protein YmL31 from Saccharomyces cerevisiae.

The nuclear gene for mitochondrial ribosomal protein YmL31 (MRP-L31) of Saccharomyces cerevisiae was cloned using synthetic oligonucleotide mixtures which correspond to the N-terminal amino acid sequence of the mature YmL31. The gene MRP-L31 codes for a basic protein with a calculated molecular mass of 15.5 kDa and resides on chromosome XI. A comparison of the amino acid sequence deduced from the nucleotide sequence of the MRP-L31 gene and the N-terminal sequence of the isolated protein revealed the existence of a leader peptide sequence of 12 amino acid residues. No significant similarity to known ribosomal protein sequences of other organisms was found.

Promoters of nuclear-encoded respiratory chain complex I genes from Arabidopsis thaliana contain a region essential for anther/pollen-specific expression.

Regulatory promoter regions responsible for the enhanced expression in anthers and pollen are defined in detail for three nuclear encoded mitochondrial Complex I (nCl) genes from Arabidopsis thaliana. Specific regulatory elements were found conserved in the 5' upstream regions between three different genes encoding the 22 kDa (PSST), 55 kDa NADH binding (55 kDa) and 28 kDa (TYKY) subunits, respectively. Northern blot analysis and transgenic Arabidopsis plants carrying progressive deletions of the promoters fused to the beta-glucuronidase (GUS) reporter gene by histochemical and fluorimetric methods showed that all three promoters drive enhanced expression of GUS specifically in anther tissues and in pollen grains. In at least two of these promoters the -200/-100 regions actively convey the pollen/anther-specific expression in gain of function experiments using CaMV 35S as a minimal promoter. These nCl promoters thus contain a specific regulatory region responding to the physiological demands on mitochondrial function during pollen maturation. Pollen-specific motifs located in these regions appear to consist of as little as seven nucleotides in the respective promoter context.

An extended ubiquitin of Dictyostelium is located in the small ribosomal subunit.

According to its cDNA sequence, the product of the DUB1 gene of Dictyostelium discoideum, called ubex52, consists of a ubiquitin monomer with a basic COOH-terminal tail of 52 amino acids that includes a putative zinc finger motif. Antipeptide antibodies raised against the COOH-terminal end of the tail indicated that the ubex52 protein is present in all developmental stages of D. discoideum and that similar proteins with apparent molecular masses of 15 to 17 kDa are found in yeast, wheat germ, Drosophila, and mammals. Subcellular fractionation showed that the D. discoideum and Saccharomyces cerevisiae proteins recognized by the antibodies are associated with the ribosomal fraction. After separation and purification of the 40 and 60 S ribosomal subunits of D. discoideum, the ubex52 protein was exclusively recovered in the small subunit.

YmL9, a nucleus-encoded mitochondrial ribosomal protein of yeast, is homologous to L3 ribosomal proteins from all natural kingdoms and photosynthetic organelles.

The nuclear gene for mitochondrial ribosomal protein YmL9 (MRP-L9) of yeast has been cloned and sequenced. The deduced amino acid sequence characterizes YmL9 as a basic (net charge + 30) protein of 27.5 kDa with a putative signal peptide for mitochondrial import of 19 amino acid residues. The intact MRP-L9 gene is essential for mitochondrial function and is located on chromosome XV or VII. YmL9 shows significant sequence similarities to Escherichia coli ribosomal protein L3 and related proteins from various organisms of all three natural kingdoms as well as photosynthetic organelles (cyanelles). The observed structural conservation is located mostly in the C-terminal half and is independent of the intracellular location of the corresponding genes [Graack, H.-R., Grohmann, L. & Kitakawa, M. (1990) Biol. Chem. Hoppe Seyler 371, 787-788]. YmL9 shows the highest degree of sequence similarity to its eubacterial and cyanelle homologues and is less related to the archaebacterial or eukaryotic cytoplasmic ribosomal proteins. Due to their high sequence similarity to the YmL9 protein two mammalian cytoplasmic ribosomal proteins [MRL3 human and rat; Ou, J.-H., Yen, T. S. B., Wang, Y.-F., Kam, W. K. & Rutter, W. J. (1987) Nucleic Acids Res. 15, 8919-8934] are postulated to be true nucleus-encoded mitochondrial ribosomal proteins.

The 28.5-kDa iron-sulfur protein of mitochondrial complex I is encoded in the nucleus in plants.

The intrinsic 28.5-kDa iron-sulfur protein of complex I in the mitochondrial respiratory chain is encoded in the nucleus in animals and fungi, but specified by a mitochondrial gene in trypanosomes. In plants, the homologous protein is now found to be encoded by a single-copy nuclear gene in Arabidopsis thaliana and by two nuclear genes in potato. The cysteine motifs involved in binding two iron-sulfur clusters are conserved in the plant protein sequences. The locations of the seven introns, with sizes between 60 and 1700 nucleotides, are identical in the A. thaliana and the two potato genes, while their primary sequences diverge considerably. The A + T contents of the intron sequences range between 61% and 73%, as is characteristic for dicot plants, but are in some instances not higher than in the adjacent exons. Here, differences in T content may instead serve to discriminate exons and introns. In potato, both genes are expressed, with the highest levels found in flowers. Sequence similarities between the homologous nuclear and mitochondrial genes indicate that the nuclear forms in animals and plants originate from the endosymbiont genome.

Ellis-van Creveld syndrome. An inbred kindred with five cases.

Five additional cases of a kindred with inbred Ellis-van Creveld syndrome are reported. Ectodermal dysplasia polydactyly, chondroectodermal dysplasia and possibly congenital heart diseases were present in all our cases. Cephalometric radiographs from one patient showed an enlargement of the mentum-groove-labial distance. The diagnosis of two individuals was performed by clinical and radiological examinations. An autosomal recessive mode of inheritance is strongly suggested by their pedigree.