Physical and genetic organization of Petite and Grande yeast mitochondrial DNA. II. DNA-DNA hybridization studies and buoyant density determinations

Buoyant density of mitochondrial DNA from 14 cytoplasmic petite mutants issued from the same grande yeast Saccharomyces cerevisiae was determined. Mutants that have retained the mitochondrial gene conferring resistance to erythromycin displayed higher buoyant density, while mutants that have retained the mitochondrial gene conferring resistance to chloramphenicol displayed lower buoyant density. It is inferred that the segment which carries the E^R gene has a higher G + C content than the segment which carries the C^R gene. DNA-DNA filter hybridizations were carried out systematically in different reciprocal pair-wise combinations between mtDNAs purified from various mutants and from the grande. All petites were found to be deleted in 42 to 93% of the grande sequence, depending on the mutant studied. Sequence homology between petite mtDNAs was greatest in mutants retaining common genetic markers and was least when different genetic markers were retained. Practically no hybridization was found between some C^RE^O and C^OE^R mutants. Correlations established between the extent of DNA-DNA hybridization, kinetic and genetic complexity show that a selective enrichment of gene specific sequences occurs in mtDNA of petites.     

Mapping of the mitochondrial 16S ribosomal RNA gene and its expression in the cytoplasmic petite mutants ofSaccharomyces cerevisiae

The 16S ribosomal RNA gene of yeast mitochondria was titrated in various cytoplasmic petite mutants by DNA-RNA hybridization. The gene was located close to the prolyl transfer RNA gene. The properties of the rho^? strains suggest that the gene order would be: - P_I - 16S - prolyl tRNA - valyl tRNA - (tRNAs) - R_I - R_III -; the 23S ribosomal gene is far from the 16S one. Several petite mutants were found which have retained, in addition to many transfer RNA genes, both of the 23S and 16S ribosomal RNA genes. The two genes seem to be transcribed in these mutants.     

Characterization of a novel small RNA encoded by Dictyostelium discoideum mitochondrial DNA

In this study, we analyzed a mitochondrial small (ms) RNA in Dictyostelium discoideum, which is 129 nucleotides long and has a GC content of only 22.5%. In the mitochondrial DNA, a single-copy gene (msr) for the ms RNA was located downstream of the gene for large-subunit rRNA. The location of msr was similar to that of the 5S rRNA gene in prokaryotes and chloroplasts, but clearly different from that in mitochondria of plants, liverwort and the chlorophycean alga Prototheca wikerhamii, in which small-subunit rRNA and 5S rRNA genes are closely linked. The primary sequence of ms RNA showed low homology with mitochondrial 5S rRNA from plants, liverwort and the chlorophycean alga, but the proposed secondary structure of ms RNA was similar to that of cytoplasmic 5S rRNA. In addition, ms RNA showed a highly conserved GAAC sequence in the same loop as in common 5S rRNA. However, ms RNA was detected mainly in the mitochondrial 25?000?×?g supernatant fraction which was devoid of ribosomes. It is possible that ms RNA is an evolutionary derivative of mitochondrial 5S rRNA.     

A PIF-dependent recombinogenic signal in the mitochondrial DNA of yeast

From their recombination properties, tandem rho^- mutants of the mitochondrial genome of Saccharomyces cerevisiae were divided into two categories. In crosses between PIF-independent rho^- and rho⁺ strains, the recombination frequency is low and similar in PIF/pif and pif/pif diploids. In crosses between PIF-dependent rho^- and rho⁺ strains, the recombination frequency is stimulated 10-50 times in PIF/pif diploids and is drastically decreased in pif/pif diploids. These results suggest that a recombinogenic signal is present in the mitochondrial (mt) DNA of PIF-dependent rho^- clones. This signal is not recognized in pif mutants. Sequence analysis of a series of small (<300 bp) overlapping tandem rho^- genomes located in the ery region of the 21S rRNA gene led us to identify an essential element of this signal within a 41-bp A+T sequence exhibiting over 26 bp a perfect dyad symmetry. However the recombinogenic signal is not sequence-specific since the sequence described above does not characterize PIF-dependent rho^- clones located in the oli1 region. Our results rather suggest that the recombinogenic signal is related to the topology of rho^- DNA. Denaturated sites in the double helix or cruciform structures elicited by local negative supercoiling might be preferred sites of the initiation of recombination.     

Paramecium mitochondrial genes. II. Large subunit rRNA gene sequence and microevolution

Mature Paramecium mitochondrial large subunit rRNA consists of two stable segments: a 20 S segment described previously and a unique 283-base segment similar to 5.8 S rRNAs typically found in eucaryotic cytoplasmic RNA. pBR325 clones of both gene regions from both Paramecium primaurelia and Paramecium tetraurelia were sequenced and aligned. The gene segments lie adjacent to each other very near the replicative terminal end of the linear Paramecium mitochondrial genome and are transcribed from a common 23 S precursor. The precise gene ends were determined using nuclease S1 protection; the large subunit rRNA gene complex (consisting of "5.8 S-like" rRNA, a 19-26-base excised region, and 20 S rRNA) spans about 2654 base pairs. The gene complex is preceded by a 15-base poly(T) tract and terminates randomly within a 20-base A + T-rich segment immediately preceding the tRNATyr gene. The sequences from the two species were 4% divergent, the changes consisting of 59% transitions, 38% transversions, and 3% insertions or deletions. The sequences were aligned with Escherichia coli 23 S rRNA, and a secondary structure model is presented for the entire molecule based on structures proposed for E. coli 23 S rRNA.     

Fine mapping of the ribosomal RNA genes of HeLa cell mitochondrial DNA

A fine mapping study of the ribosomal RNA region of HeLa cell mitochondrial DNA has been carried out by using as an approach the protection by hybridized 12 S and 16 S rRNA of the complementary sequences in DNA against digestion with the single strand-specific Aspergillus nuclease S₁ or Escherichia coli exonuclease VII. No inserts have been detected in the main body of the 12 S and 16 S rRNA cistrons, in contrast to the situation described in the large mitochondrial ribosomal RNA gene of some strains of yeast and of Neurospora crassa. Furthermore, it has been possible to assign more precisely than previously the positions of the 5′ and 3′-ends of the 12 S rRNA and 16 S rRNA genes in the HpaII restriction map of HeLa cell mitochondrial DNA.     

<Emphasis Type="Italic">Shewanella upenei</Emphasis> sp. nov., a lipolytic bacterium isolated from bensasi goatfish <Emphasis Type="Italic">Upeneus bensasi</Emphasis>

A Gram-staining-negative, motile, non-spore-forming and rod-shaped bacterial strain, 20-23R^T, was isolated from intestine of bensasi goatfish, Upeneus bensasi, and its taxonomic position was investigated by using a polyphasic study. Phylogenetic analyses based on 16S rRNA gene sequences revealed that strain 20-23R^T belonged to the genus Shewanella. Strain 20-23R^T exhibited 16S rRNA gene sequence similarity values of 99.5, 99.2, and 97.5% to Shewanella algae ATCC 51192^T, Shewanella haliotis DW01^T, and Shewanella chilikensis JC5^T, respectively. Strain 20-23R^T exhibited 93.1–96.0% 16S rRNA gene sequence similarity to the other Shewanella species. It also exhibited 98.3–98.4% gyrB sequence similarity to the type strains of S. algae and S. haliotis. Strain 20-23R^T contained simultaneously both menaquinones and ubiquinones; the predominant menaquinone was MK-7 and the predominant ubiquinones were Q-8 and Q-7. The fatty acid profiles of strain 20–23R^T, S. algae KCTC 22552^T and S. haliotis KCTC 12896^T were similar; major components were iso-C_15:0, C_16:0, C_16:1 ω7c and/or iso-C_15:0 2-OH and C_17:1 ω8c. The DNA G+C content of strain 20-23R^T was 53.9 mol%. Differential phenotypic properties and genetic distinctiveness of strain 20–23R^T, together with the phylogenetic distinctiveness, revealed that this strain is distinguishable from recognized Shewanella species. On the basis of the data presented, strain 20-23R^T represents a novel species of the genus Shewanella, for which the name Shewanella upenei sp. nov. is proposed. The type strain is 20–23R^T (=KCTC 22806^T =CCUG 58400^T).     

Plastid DNA in the mitochondrial genome of Oenothera: Intra- and interorganellar rearrangements involving part of the plastid ribosomal cistron

Summary Part of the plastid rRNA cistron is present in the mitochondrial genome of Oenothera. This sequence of 2081 nucleotides contains the 3 half of the plastid 23 S rRNA, the adjacent intergenic region and the 4.5 S rRNA. Secondary intramitochondrial sequence rearrangements involve this region of plastid origin and the gene encoding the putative mitochondrial small ribosomal protein S13. Sequence comparison suggests that the interorganellar transfer event occurred a long time ago. The mitochondrial sequence contains regions more homologous to the plastid DNA from tobacco than from Oenothera itself in the regions analysed, suggesting faster sequence evolution in plastids than in mitochondria of Oenothera.     

Translation of mitochondrial RNA from yeast cytoplasmic petite mutants in anE. coli cell-free system

Mitochondrial RNA from two cytoplasmic ?^? mutants ofS. cerevisiae, which have kept the mitochondrial DNA segment including the ATPase-oligomycin resistance-conferring gene, stimulates protein synthesis in anE. coli cell-free system. SDS-acrylamide gel electrophoresis of the protein product revealed one major peak and two minor ones with apparent molecular weights of around 11,000, 13,500 and 17,000 respectively. The effect is specific since no stimulation is observed with RNA from a ?^? mutant devoid of detectable mitochondrial DNA. These results are interpreted to mean that the mitochondrial DNA of these mutants codes for anin vitro translatable mRNA.     

Evaluation of a novel 16S rRNA/tRNA mitochondrial marker for the identification and phylogenetic analysis of shrimp species belonging to the superfamily Penaeoidea

In this study, we infer the phylogenetic relationships within commercial shrimp using sequence data from a novel mitochondrial marker consisting of an approximately 530-bp region of the 16S ribosomal RNA (rRNA)/transfer RNA (tRNA)^Val genes compared with two other mitochondrial genes: 16S rRNA and cytochrome c oxidase I (COI). All three mitochondrial markers were considerably AT rich, exhibiting values up to 78.2% for the species Penaeus monodon in the 16S rRNA/tRNA^Val genes, notably higher than the average among other Malacostracan mitochondrial genomes. Unlike the 16S rRNA and COI genes, the 16S rRNA/tRNA^Val marker evidenced that Parapenaeus is more closely related to Metapenaeus than to Solenocera, a result that seems to be more in agreement with the taxonomic status of these genera. To our knowledge, our study using the 16S rRNA/tRNA^Val gene as a marker for phylogenetic analysis offers the first genetic evidence to confirm that Pleoticus muelleri and Solenocera agassizi constitute a separate group and that they are more related to each other than to genera belonging to the family Penaeidae. The 16S rRNA/tRNA^Val region was also found to contain more variable sites (56%) than the other two regions studied (33.4% for the 16S rRNA region and 42.7% for the COI region). The presence of more variable sites in the 16S rRNA/tRNA^Val marker allowed the interspecific differentiation of all 19 species examined. This is especially useful at the commercial level for the identification of a large number of shrimp species, particularly when the lack of morphological characteristics prevents their differentiation.     

Properties of a discrete high molecular weight poly(A) containing mitochondrial RNA

Pulse-labeled mitochondrial RNA from hamster cells contains a number of discrete high molecular weight poly[A(+)] and poly[A(?)] RNAs. Characterization of the largest and most plentiful of the poly[A(+)] RNAs, the “20S_E RNA,” showed it to be a labile, unmethylated component with a molecular weight ～- 730,000. Hybridization of the 20S_E RNA to mtDNA was 60–70% inhibited in the presence of excess 17S rRNA, suggesting a significant degree of primary sequence homology between these RNA species. In vitro treatment with RNAse III converted the 20S_E RNA to a poly[A(?)] “17S” product, while similar treatment of mitochondrial 17S rRNA or a poly[A(+)] 12S_E RNA had no effect on these RNAs. These data support the proposition that the 20S_E RNA is a precursor to the 17S rRNA.     

Biogenesis of mitochondria: XXV. Studies on the mitochondrial genomes of petite mutants of yeast using ethidium bromide as a probe

This paper describes investigations into the effects of ethidium bromide on the mitochondrial genomes of a number of different petite mutants derived from one respiratory competent strain of Saccharomyces cerevisiae. It is shown that the mutagenic effects of ethidium bromide on petite mutants occur by a similar mechanism to that previously reported for the action of this dye on grande cells. The consequences of ethidium bromide action in both cases are inhibition of the replication of mitochondrial DNA, fragmentation of pre-existing mitochondrial DNA, and the induction, often in high frequency, of cells devoid of mitochondrial genetic information (ρ ° cells).The susceptibility of the mitochondrial genomes to these effects of ethidium bromide varies in the different clones studied. The inhibition of mitochondrial DNA replication requires higher concentrations of ethidium bromide in petite cells than in the parent grande strain. Furthermore, the susceptibility of mitochondrial DNA replication to inhibition by ethidium bromide varies in different petite clones.It is found that during ethidium bromide treatment of the suppressive petite clones, the over-all suppressiveness of the cultures is reduced in parallel with the reduction in the over-all cellular levels of mitochondrial DNA. Furthermore, ethidium bromide treatment of petite clones carrying mitochondrial erythromycin resistance genes (ρ^?ER^r) leads to the elimination of these genes from the cultures. The rates of elimination of these genes are different in two ρ^?ER^r clones, and in both the gene elimination rate is slower than in the parent ρ⁺ ER^r strain. It is proposed that the rate of elimination of erythromycin resistance genes by ethidium bromide is related to the absolute number of copies of these genes in different cell types. In general, the more copies of the gene in the starting cells, the slower is the rate of elimination by ethidium bromide. These concepts lead us to suggest that petite mutants provide a system for the biological purification of particular regions of yeast mitochondrial DNA and of particular relevance is the possible purification of erythromycin resistance genes.     

Diversity and Functional Analysis of Bacterial Communities Associated with Natural Hydrocarbon Seeps in Acidic Soils at Rainbow Springs, Yellowstone National Park

In this paper we describe the bacterial communities associated with natural hydrocarbon seeps in nonthermal soils at Rainbow Springs, Yellowstone National Park. Soil chemical analysis revealed high sulfate concentrations and low pH values (pH 2.8 to 3.8), which are characteristic of acid-sulfate geothermal activity. The hydrocarbon composition of the seep soils consisted almost entirely of saturated, acyclic alkanes (e.g., n-alkanes with chain lengths of C₁₅ to C₃₀, as well as branched alkanes, predominately pristane and phytane). Bacterial populations present in the seep soils were phylogenetically characterized by 16S rRNA gene clone library analysis. The majority of the sequences recovered (>75%) were related to sequences of heterotrophic acidophilic bacteria, including Acidisphaera spp. and Acidiphilium spp. of the α-Proteobacteria. Clones related to the iron- and sulfur-oxidizing chemolithotroph Acidithiobacillus spp. were also recovered from one of the seep soils. Hydrocarbon-amended soil-sand mixtures were established to examine [¹⁴C]hexadecane mineralization and corresponding changes in the bacterial populations using denaturing gradient gel electrophoresis (DGGE) of 16S rRNA gene fragments. Approximately 50% of the [¹⁴C]hexadecane added was recovered as ¹⁴CO₂ during an 80-day incubation, and this was accompanied by detection of heterotrophic acidophile-related sequences as dominant DGGE bands. An alkane-degrading isolate was cultivated, whose 16S rRNA gene sequence was identical to the sequence of a dominant DGGE band in the soil-sand mixture, as well as the clone sequence recovered most frequently from the original soil. This and the presence of an alkB gene homolog in this isolate confirmed the alkane degradation capability of one population indigenous to acidic hydrocarbon seep soils.     

Parendozoicomonas haliclonae gen. nov. sp. nov. isolated from a marine sponge of the genus Haliclona and description of the family Endozoicomonadaceae fam. nov. comprising the genera Endozoicomonas,Parendozoicomonas, and Kistimonas

Two Gram-stain-negative, facultative anaerobic, motile, rod-shaped strains, S-B4-1U^T and JOB-63a, forming small whitish transparent colonies on marine agar, were isolated from a sponge of the genus Haliclona. The strains shared 99.7% 16S rRNA gene sequence identity and a DNA-DNA hybridization value of 100%, but were differentiated by genomic fingerprinting using rep-PCRs. 16S rRNA gene sequence phylogeny placed the strains as a sister branch to the monophyletic genus Endozoicomonas (Oceanospirillales; Gammaproteobacteria) with 92.3–94.3% 16S rRNA gene sequence similarity to Endozoicomonas spp., 91.9 and 92.1% to Candidatus Endonucleobacter bathymodiolin, and 91.9 to 92.1% to the type strains of Kistimonas spp. Core genome based phylogeny of strain S-B4-1U^T confirmed the phylogenetic placement. Major fatty acids were summed feature 3 (C_16:1 ω7c/C_16:1 ω6c) and 8 (C_18:1 ω7c/C_18:1 ω6c) followed by C_10:0 3-OH, C_16:0, and C_18:0. The G + C content was 50.1–51.4 mol%. The peptidoglycan diamino acid of strain S-B4-1U^T was meso-diaminopimelic acid, the predominant polyamine spermidine, the major respiratory quinone ubiquinone Q-9; phosphatidylethanolamine, phosphatidylglycerol and phosphatidylserine were major polar lipids. Based on the clear phylogenetic distinction, the genus Parendozoicomonas gen. nov. is proposed, with Parendozoicomonas haliclonae sp. nov. as type species and strain S-B4-1U^T (= CCM 8713^T = DSM 103671^T = LMG 29769^T) as type strain and JOB-63a as a second strain of the species. Based on the 16S rRNA gene sequence phylogeny of the Oceanospirillales within the Gammaproteobacteria, the Endozoicomonaceae fam. nov. is proposed including the genera Endozoicomonas, Parendozoicomonas, and Kistimonas as well as the Candidatus genus Endonucleobacter.     

Sequence analysis of the maize mitochondrial 26 S rRNA gene and flanking regions

A single copy of the large ribosomal 26 S rRNA gene is found in the maize mitochondrial genome. The sequence of this gene and the flanking regions has been determined using the M13 dideoxy sequencing method. The maize mt 26 S rDNA shares a high degree of homology with the Escherichia coli 23 S rDNA, and the approximate 5′ and 3′ ends of the maize 26 S rDNA have been located by comparison with the E. coli sequence. The maize mt 26 S rDNA has also been compared with the sequences of the maize chloroplast 23 S rDNA, the human mitochondrial 16 S rDNA, part of the yeast mitochondrial 21 S rDNA, and the yeast cytoplasmic 25 S rDNA. In all cases, there are numerous regions of 70% or higher homology.     

Photosynthetic refixing of CO2 is responsible for the apparent disparity between mitochondrial respiration in the light and in the dark

The net photosynthetic rate (P _N), the sample room CO₂ concentration (CO₂S) and the intercellular CO₂ concentration (C _i) in response to PAR, of C₃ (wheat and bean) and C₄ (maize and three-colored amaranth) plants were measured. Results showed that photorespiration (R _p) of wheat and bean could not occur at 2 % O₂. At 2 % O₂ and 0 μmol mol^?1 CO₂, P _N can be used to estimate the rate of mitochondrial respiration in the light (R _d). The R _d decreased with increasing PAR, and ranged between 3.20 and 2.09 μmol CO₂ m^?2 s^?1 in wheat. The trend was similar for bean (between 2.95 and 1.70 μmol CO₂ m^?2 s^?1), maize (between 2.27 and 0.62 μmol CO₂ m^?2 s^?1) and three-colored amaranth (between 1.37 and 0.49 μmol CO₂ m^?2 s^?1). The widely observed phenomenon of R _d being lower than R _n can be attributed to refixation, rather than light inhibition. For all plants tested, CO₂ recovery rates increased with increasing light intensity from 32 to 55 % (wheat), 29 to 59 % (bean), 54 to 87 % (maize) and 72 to 90 % (three-colored amaranth) at 50 and 2,000 μmol m^?2 s^?1, respectively.     

Physical mapping of genes on yeast mitochondrial DNA: Localization of antibiotic resistance loci, and rRNA and tRNA genes

Summary We have physically mapped the loci conferring resistance to antibiotics that inhibit mitochondrial protein synthesis (erythromycin, chloramphenicol and paromomycin) or respiration (oligomycin I and II), as well as the 21s and 14s rRNA and tRNA genes on the restriction map of the mitochondrial genome of the yeast Saccharomyces cerevisiae. The mitochondrial genes were localized by hybridization of labeled RNA probes to restriction fragments of grande (strain MH41-7B) mitochondrial DNA (mtDNA)¹ generated by endonucleases EcoRI, HpaI, BamHI, HindIII, SalI, PstI and HhaI. We have derived the HhaI restriction fragment map of MH41-7B mit DNA, to be added to our previously reported maps for the six other endonucleases.The antibiotic resistance loci (ant ^R) were mapped by hybridization of ³H-cRNA transcribed from single marker petite mtDNA's of low kinetic complexity to grande restriction fragments. We have chosen the single Sal I site as the origin of the circular physical map and have positioned the antibiotic loci as follows: C (99.5-1.Ou)-P(27-36.Ou)-O_II (58.3-62u)-O_I (80-84u)-E (94.4-98.4u). The 21s rRNA is localized at 94.4-99.2u, and the 14s rRNA is positioned between 36.2-39.8u. The two rRNA species are separated by 36% of the genome. Total mitochondrial tRNA labeled with ¹²⁵I hybridized primarily to two regions of the genome, at 99.5-11.5u and 34-44u. A third region of hybridization was occasionally detected at 70-76u, which probably corresponds to seryl and glutamyl tRNA genes, previously located to this region by petite deletion mapping.Supported by USPHS Training Grant T32-GM-07197.Supported by USPHS Training Grant 5-T01-GM-0090-19.The Franklin McLean Memorial Research Institute is operated by the University of Chicago for the U. S. Energy Research and Development Administration under Contract EY-76-C-02-0069.     

Complete sequence of bovine mitochondrial DNA conserved features of the mammalian mitochondrial genome

We present here the complete 16,338 nucleotide DNA sequence of the bovine mitochondrial genome. This sequence is homologous to that of the human mitochondrial genome (Anderson et al., 1981) and the genes are organized in virtually identical fashion. The bovine mitochondrial protein genes are 63 to 79% homologous to their human counterparts, and most of the nucleotide differences occur in the third positions of codons. The minimum rate of base substitution that accounts for the nucleotide differences in the codon third positions is very high: at least 6 × 10^?9 changes per position per year. The bovine and human mitochondrial transfer RNA genes exhibit more interspecies variation than do their cytoplasmic counterparts, with the “TΨC” loop being the most variable part of the molecule. The bovine 12 S and 16 S ribosomal RNA genes, when compared with those from human mitochondrial DNA, show conserved features that are consistent with proposed secondary structure models for the ribosomal RNAs. Unlike the pattern of moderate-to-high homology between the bovine and human mitochondrial DNAs found over most of the genome, the DNA sequence in the bovine D-loop region is only slightly homologous to the corresponding region in the human mitochondrial genome. This region is also quite variable in length, and accounts for the bulk of the size difference between the human and bovine mitochondrial DNAs.