Partial duplication of the large ribosomal RNA sequence in an inverted repeat in circular mitochondrial DNA from Kloeckera africana: Implications for mechanisms of the petite mutation

The 27,100 base-pair circular mitochondrial DNA from the yeast Kloeckera africana has been found to contain an inverted duplication spanning 8600 base-pairs. Sequences hybridizing to transfer RNAs and the large ribosomal RNA are present in the duplication; however, one end of this segment terminates in the large mitochondrial ribosomal RNA sequence so that at least 1000 base-pairs of the gene are not repeated. The large and small mitochondrial ribosomal RNAs have been shown to have lengths of 2700 and 1450 bases, respectively, and genes for these sequences are separated by a minimum of 1300 base-pairs and a maximum of 1750 base-pairs. Consequences of the large inverted duplication to mechanisms of the petite mutation are discussed in terms of previous hypotheses centred on intramolecular recombination in yeast mitochondrial DNA at sequences of homology or partial homology. Despite the long inverted duplication in K. africana mitochondrial DNA, this yeast has one of the lowest frequencies of spontaneous petite mutants amongst petite positive yeasts. One implication of these findings is that in this yeast intra-molecular mitochondrial DNA sequence homology may not be an important factor in the excision process leading to petite formation.     

Anaerobic degradation of papermill sludge in a two-phase digester containing rumen microorganisms and colonized polyurethane foam

Summary The use of reticulated polyurethane foam as a support material for the immobilization of methanogenic associations and its application to the anaerobic treatment of fine particulate solid wastes was investigated. The colonization of polyurethane support particles in a continuous upflow reactor fed on a mixture of acetate, propionate and butyrate, was both rapid and dense. The combination of rumen microorganisms and colonized support particles in a two-phase digester resulted in an efficient anaerobic decomposition of papermill sludge.     

A vital function for mitochondrial DNA in the petite-negative yeastKluyveromyces lactis

Petite-negative yeasts do not form viable respiratory-deficient mutants on treatment with DNA-targeting drugs that readily eliminate the mitochondial DNA (mtDNA) from petite-positive yeasts. However, in the petite-negative yeastKluyveromyces lactis, specific mutations in the nuclear genesMGI2 andMGI5 encoding theα- andγ-subunits of the mitochondrial F₁-ATPase, allow mtDNA to be lost. In this study we show that wild-typeK. lactis does not survive in the absence of its mitochondrial genome and that the function ofmgi mutations is to suppress lethality caused by loss of mtDNA. Firstly, we find that loss of a multicopy plasmid bearing amgi allele readily occurs from a wild-type strain with functional mtDNA but is not tolerated in the absence of mtDNA. Secondly, we cloned theK. lactis homologue of theSaccharomyces cerevisiae mitochondrial genome maintenance geneMGM101, and disrupted one of the two copies in a diploid. Following sporulation, we find that segregants containing the disrupted gene form minicolonies containing 6-8000 inviable cells. By contrast, disruption ofMGM101 is not lethal in a haploidmgi strain with a specific mutation in a subunit of the mitochondrial F₁-ATPase. These observations suggest that mtDNA inK. lactis encodes a vital function which may reside in one of the three mitochondrially encoded subunits of F₀.     

Sequence rearrangements at theori 7 region ofSaccharomyces cerevisiae mitochondrial DNA

Summary Threeori elements (ori 2,ori 5, andori 7) have been sequenced inSaccharomyces cerevisiae strain Dip 2 and compared to the equivalentori elements of a second strain (B). Bothori 2 andori 5 exhibit 98% base matching between strains Dip 2 and B. In contrast, the thirdori element (ori 7) exhibits extensive sequence rearrangements whereby a segment located downstream in the consensus strain occurs within theori structure in Dip 2. This represents a novel polymorphic form of the yeast mitochondrial genome.     

Sequence rearrangements between mitochondrial DNAs of Torulopsis glabrata and Kloeckera africana identified by hybridization with six polypeptide encoding regions from Saccharomyces cerevisiae mitochondrial DNA

Sequences hybridizing to six mitochondrial DNA encoded polypeptide genes of Saccharomyces cerevisiae have been mapped in the 18·9 and 27·1 kbp² circular mitochondrial DNAs from Torulopsis glabrata and Kloeckera africana. With the possible exception of cytochrome oxidase subunit 1 and ATPase subunit 6 genes, no two hybridizable sequences share the same order in the two mtDNAs nor is there any topographical similarity to S. cerevisiae mtDNA apart from the grouping mentioned above. Because sequence rearrangements are prevalent in yeast mitochondrial DNAs we infer that order is not critical for mitochondrial gene expression and that prokaryotic-like operons do not exist. In contrast to S. cerevisiae, the cytochrome b region in T. glabrata and K. africana is confined to 1·46 or 1·58 kbp, respectively, which suggests that intervening sequences in this gene are either small or absent. On the other hand, hybridizable sequences to a 5·2 kbp portion of the S. cerevisiae cytochrome oxidase subunit 1 gene, retaining exons 3 to 7 or 8, span 3 to 4 kbp in the two mtDNAs. In addition an 0·8 to 0·9 kbp intervening sequence is present in each case, which does not hybridize to either exon or intron regions of the S. cerevisiae probe. These results imply that the cytochrome oxidase subunit 1 gene in both mtDNAs has a mosaic organization of coding and noncoding sequences.     

Alpha and beta subunits of F1-ATPase are required for survival of petite mutants in Saccharomyces cerevisiae

Although Saccharomyces cerevisiae can form petite mutants with deletions in mitochondrial DNA (mtDNA) (ρ⁻) and can survive complete loss of the organellar genome (ρ^o), the genetic factor(s) that permit(s) survival of ρ⁻ and ρ^o mutants remain(s) unknown. In this report we show that a function associated with the F₁-ATPase, which is distinct from its role in energy transduction, is required for the petite-positive phenotype of S. cerevisiae. Inactivation of either the α or β subunit, but not the γ, δ, or ɛ subunit of F₁, renders cells petite-negative. The F₁ complex, or a subcomplex composed of the α and β subunits only, is essential for survival of ρ^o cells and those impaired in electron transport. The activity of F₁ that suppresses ρ^o lethality is independent of the membrane F_o complex, but is associated with an intrinsic ATPase activity. A further demonstration of the ability of F₁ subunits to suppress ρ^o lethality has been achieved by simultaneous expression of S. cerevisiae F₁α and γ subunit genes in Kluyveromyces lactis– which allows this petite-negative yeast to survive the loss of its mtDNA. Consequently, ATP1 and ATP2, in addition to the previously identified AAC2, YME1 and PEL1/PGS1 genes, are required for establishment of ρ⁻ or ρ^o mutations in S. cerevisiae. Received: 20 March 1999 / Accepted: 18 July 1999     

Mutant residues suppressing rho(0)-lethality in Kluyveromyces lactis occur at contact sites between subunits of F(1)-ATPase

Characterisation of 35 Kluyveromyces lactis strains lacking mitochondrial DNA has shown that mutations suppressing rho(0)-lethality are limited to the ATP1, 2 and 3 genes coding for the alpha-, beta- and gamma- subunits of mitochondrial F(1)-ATPase. All atp mutations reduce growth on glucose and three alleles, atp1-2, 1-3 and atp3-1, produce a respiratory deficient phenotype that indicates a drop in efficiency of the F(1)F(0)-ATP synthase complex. ATPase activity is needed for suppression as a double mutant containing an atp allele, together with a mutation abolishing catalytic activity, does not suppress rho(0)-lethality. Positioning of the seven amino acids subject to mutation on the bovine F(1)-ATPase structure shows that two residues are found in a membrane proximal region while five amino acids occur at a region suggested to be a molecular bearing. The intriguing juxtaposition of mutable amino acids to other residues subject to change suggests that mutations affect subunit interactions and alter the properties of F(1) in a manner yet to be determined. An explanation for suppressor activity of atp mutations is discussed in the context of a possible role for F(1)-ATPase in the maintenance of mitochondrial inner membrane potential.     

The F1-ATP synthase complex in bloodstream stage trypanosomes has an unusual and essential function

Survival of bloodstream form Trypanosoma brucei, the agent of African sleeping sickness, normally requires mitochondrial gene expression, despite the absence of oxidative phosphorylation in this stage of the parasite's life cycle. Here we report that silencing expression of the alpha subunit of the mitochondrial F(1)-ATP synthase complex is lethal for bloodstream stage T. brucei as well as for T. evansi, a closely related species that lacks mitochondrial protein coding genes (i.e. is dyskinetoplastic). Our results suggest that the lethal effect is due to collapse of the mitochondrial membrane potential, which is required for mitochondrial function and biogenesis. We also identified a mutation in the gamma subunit of F(1) that is likely to be involved in circumventing the requirement for mitochondrial gene expression in another dyskinetoplastic form. Our data reveal that the mitochondrial ATP synthase complex functions in the bloodstream stage opposite to that in the insect stage and in most other eukaryotes, namely using ATP hydrolysis to generate the mitochondrial membrane potential.     

Airway cellularity, lipid laden macrophages and microbiology of gastric juice and airways in children with reflux oesophagitis

Background and methods

Human metapneumovirus (hMPV) is a recently discovered respiratory virus associated with bronchiolitis, pneumonia, croup and exacerbations of asthma. Since respiratory viruses are frequently detected in patients with acute exacerbations of COPD (AE-COPD) it was our aim to investigate the frequency of hMPV detection in a prospective cohort of hospitalized patients with AE-COPD compared to patients with stable COPD and to smokers without by means of quantitative real-time RT-PCR.

Results

We analysed nasal lavage and induced sputum of 130 patients with AE-COPD, 65 patients with stable COPD and 34 smokers without COPD. HMPV was detected in 3/130 (2.3%) AE-COPD patients with a mean of 6.5 × 10⁵ viral copies/ml in nasal lavage and 1.88 × 10⁵ viral copies/ml in induced sputum. It was not found in patients with stable COPD or smokers without COPD.

Conclusion

HMPV is only found in a very small number of patients with AE-COPD. However it should be considered as a further possible viral trigger of AE-COPD because asymptomatic carriage is unlikely.