Does any yeast mitochondrial carrier have a native uncoupling protein function?

In this study, we explore the hypothesis that some member of the mitochondrial carrier family has specific uncoupling activity that is responsible for the basal proton conductance of mitochondria. Twenty-seven of the 35 yeast mitochondrial carrier genes were independently disrupted in Saccharomyces cerevisiae. Six knockout strains did not grow on nonfermentable carbon sources such as lactate. Mitochondria were isolated from the remaining 21 strains, and their proton conductances were measured. None of the 21 carriers contributed significantly to the basal proton leak of yeast mitochondria. A possible exception was the succinate/fumarate carrier encoded by the Xc2 gene, but deletion of this gene also affected yeast growth and respiratory chain activity, suggesting a more general alteration in mitochondrial function. If a specific protein is responsible for the basal proton conductance of yeast mitochondria, its identity remains unknown.     

Rearrangement,amplification, and assortment of mitochondrial DNA molecules in cultured cells of Brassica campestris

Summary We compared Brassica campestris mitochondrial and chloroplast DNAs from whole plants and from a 2-year-old cell culture. No differences were observed in the chloroplast DNAs (cpDNAs), whereas the culture mitochondrial DNA (mtDNA) was extensively altered. Hybridization analysis revealed that the alterations are due entirely to rearrangement. At least two inversions and one large duplication are found in the culture mtDNA. The duplication element is shown to have the usual properties of a plant mtDNA high frequency recombination repeat. The culture mtDNA exists as a complex heterogeneous population of rearranged and unrearranged molecules. Some of the culture-associated rearranged molecules are present in low levels in native plant tissue and appear to have sorted out and amplified in the culture. Other mtDNA rearrangements may have occurred de novo. In addition to alterations of the main mitochondrial genome, an 11.3 kb linear mtDNA plasmid present in whole plants is absent from the culture. Contrary to findings in cultured cells of other plants, small circular mtDNA molecules were not detected in the B. campestris cell culture.     

An ADP/ATP-specific mitochondrial carrier protein in the microsporidian Antonospora locustae

The mitochondrion is one of the defining characteristics of eukaryotic cells, and to date, no eukaryotic lineage has been shown to have lost mitochondria entirely. In certain anaerobic or microaerophilic lineages, however, the mitochondrion has become severely reduced that it lacks a genome and no longer synthesizes ATP. One example of such a reduced organelle, called the mitosome, is found in microsporidian parasites. Only a handful of potential mitosomal proteins were found to be encoded in the complete genome of the microsporidian Encephalitozoon cuniculi, and significantly no proteins of the mitochondrial carrier family were identified. These carriers facilitate the transport of solutes across the inner mitochondrial membrane, are a means of communication between the mitochondrion and cytosol, and are abundant in organisms with aerobic mitochondria. Here, we report the characterization of a mitochondrial carrier protein in the microsporidian Antonospora locustae and demonstrate that the protein is heterologously targeted to mitochondria in Saccharomyces cerevisiae. The protein is phylogenetically allied to the NAD⁺ transporter of S. cerevisiae, but we show that it has high specificity for ATP and ADP when expressed in Escherichia coli. An ADP/ATP carrier may provide ATP for essential ATP-dependent mitosomal processes such as Hsp70-dependent protein import and export of iron-sulfur clusters to the cytosol.     

Yeast mitochondrial ADP/ATP carriers are monomeric in detergents as demonstrated by differential affinity purification

Most mitochondrial carriers carry out equimolar exchange of substrates and they are believed widely to exist as homo-dimers. Here we show by differential tagging that the yeast mitochondrial ADP/ATP carrier AAC2 is a monomer in mild detergents. Carriers with and without six-histidine or hemagglutinin tags were co-expressed in defined molar ratios in yeast mitochondrial membranes. Their specific transport activity was unaffected by tagging or by co-expression. The co-expressed carriers were extracted from the membranes with mild detergents and purified rapidly by affinity chromatography. All of the untagged carriers were in the flow-through of the affinity column, whereas all of the tagged carriers bound to the column and were eluted subsequently, showing that stable dimers, consisting of associated tagged and untagged carriers, were not present. The specific inhibitors carboxyatractyloside and bongkrekic acid and the substrates ADP, ATP and ADP plus ATP were added during the experiments to determine whether lack of association might have been caused by carriers being prevented from cycling through the various states in the transport cycle where dimers might form. All of the protein was accounted for, but stable dimers were not detected in any of these conditions, showing that yeast ADP/ATP carriers are monomeric in detergents in agreement with their hydrodynamic properties and with their structure. Since strong interactions between monomers were not observed in any part of the transport cycle, it is highly unlikely that the carriers function cooperatively. Therefore, transport mechanisms need to be considered in which the carrier is operational as a monomer.     

Complete mitochondrial genome of Tubulipora flabellaris (Bryozoa: Stenolaemata): the first representative from the class Stenolaemata with unique gene order

Mitochondrial genomes play a significant role in the reconstruction of phylogenetic relationships within metazoans. There are still many controversies concerning the phylogenetic position of the phylum Bryozoa. In this research, we have finished the complete mitochondrial genome of one bryozoan (Tubulipora flabellaris), which is the first representative from the class Stenolaemata. The complete mitochondrial genome of T. flabellaris is 13,763 bp in length and contains 36 genes, which lacks the atp8 gene in contrast to the typical metazoan mitochondrial genomes. Gene arrangement comparisons indicate that the mitochondrial genome of T. flabellaris has unique gene order when compared with other metazoans. The four known bryozoans complete mitochondrial genomes also have very different gene arrangements, indicates that bryozoan mitochondrial genomes have experienced drastic rearrangements. To investigate the phylogenetic relationship of Bryozoa, phylogenetic analyses based on amino acid sequences of 11 protein coding genes (excluding atp6 and atp8) from 26 metazoan complete mitochondrial genomes were made utilizing Maximum Likelihood (ML) and Bayesian methods, respectively. The results indicate the monopoly of Lophotrochozoa and a close relationship between Chaetognatha and Bryozoa. However, more evidences are needed to clarify the relationship between two groups. Lophophorate appeared to be polyphyletic according to our analyses. Meanwhile, neither analysis supports close relationship between Branchiopod and Phoronida. Four bryozoans form a clade and the relationship among them is T. flabellaris + (F. hispida + (B. neritina + W. subtorquata)), which is in coincidence with traditional classification system.     

RAPD-derived, PCR-based mitochondrial markers for Larix species and their usefulness in phylogeny

Random amplified polymorphic DNA (RAPDs) from plants contains numerous fragments of mitochondrial origin. In the present study, the association between RAPD bands and previously recognized mitochondrial polymorphism in a Larix population was used to identify fragments of mitochondrial origin and to develop PCR-based mitochondrial DNA markers useful to study phylogeny in larches, Larix sp. (Pinaceae).     

Evolution of fragmented mitochondrial ribosomal RNA genes inChlamydomonas

The fragmented mitochondrial ribosomal RNAs (rRNAs) of the green algaeChlamydomonas eugametos andChlamydomonas reinhardtii are discontinuously encoded in subgenic modules that are scrambled in order and interspersed with protein coding and tRNA genes. The mitochondrial rRNA genes of these two algae differ, however, in both the distribution and organization of rRNA coding information within their respective genomes. The objectives of this study were (1) to examine the phylogenetic relationships between the mitochondrial rRNA gene sequences ofC. eugametos andC. reinhardtii and those of the conventional mitochondrial rRNA genes of the green alga,Prototheca wickerhamii, and land plants and (2) to attempt to deduce the evolutionary pathways that gave rise to the unusual mitochondrial rRNA gene structures in the genusChlamydomonas. Although phylogenetic analysis revealed an affiliation between the mitochondrial rRNA gene sequences of the twoChlamydomonas taxa to the exclusion of all other mitochondrial rRNA gene sequences tested, no specific affiliation was noted between theChlamydomonas sequences andP. wickerhamii or land plants. Calculations of the minimal number of transpositions required to convert hypothetical ancestral rRNA gene organizations to the arrangements observed forC. eugametos andC. reinhardtii mitochondrial rRNA genes, as well as a limited survey of the size of mitochondrial rRNAs in other members of the genus, lead us to propose that the last common ancestor ofChlamydomonas algae contained fragmented mitochondrial rRNA genes that were nearly co-linear with conventional rRNA genes.     

Molecular analyses of mitochondrial pseudogenes within the nuclear genome of arvicoline rodents

Nuclear sequences of mitochondrial origin (numts) are common among animals and plants. The mechanism(s) by which numts transfer from the mitochondrion to the nucleus is uncertain, but their insertions may be mediated in part by chromosomal repair mechanisms. If so, then lineages where chromosomal rearrangements are common should be good models for the study of numt evolution. Arvicoline rodents are known for their karyotypic plasticity and numt pseudogenes have been discovered in this group. Here, we characterize a 4 kb numt pseudogene in the arvicoline vole Microtus rossiaemeridionalis. This sequence is among the largest numts described for a mammal lacking a completely sequenced genome. It encompasses three protein-coding and six tRNA pseudogenes that span ∼25% of the entire mammalian mitochondrial genome. It is bordered by a dinucleotide microsatellite repeat and contains four transposable elements within its sequence and flanking regions. To determine the phylogenetic distribution of this numt among the arvicolines, we characterized one of the mitochondrial pseudogenes (cytochrome b) in 21 additional arvicoline species. Average rates of nucleotide substitution in this arvicoline pseudogene are estimated as 2.3 × 10⁻⁸ substitutions/per site/per year. Furthermore, we performed comparative analyses among all species to estimate the age of this mitochondrial transfer at nearly 4 MYA, predating the origin of most arvicolines. All sequences generated in this study have been deposited within the GenBank database.     

Localization of tRNA genes on the Petunia hybrida 3704 mitochondrial genome

22 tRNA genes corresponding to 17 tRNA species were localized on the master circle of Petunia hybrida mitochondrial (mt) DNA. Genes for trnN, trnM, trnS-GGA, trnW and trnH are of the chloroplast-like type and presumably originate from promiscuous chloroplast (cp) DNA sequences inserted into the petunia mitochondrial genome. A comparison of the mt tRNAs or tRNA genes population present in two monocotyledonous plants (wheat and maize) and two dicotyledonous plants (petunia and potato) show slight differences in the genetic origin of individual tRNAs. The organization of the petunia mt tRNA genes as well as the number of tRNA gene copies, compared to other plant species, is discussed.     

Analysis of chloroplast and mitochondrial DNA in asymmetric somatic hybrids betweenSolanum tuberosum and irradiatedS. brevidens

Organellar DNA of asymmetric somatic hybrids betweenSolanum tuberosum and irradiatedS. brevidens were analysed by DNA hybridization methods using the spinach chloroplast probepSBD, wheat mitochondrial genenad5 and petunia mitochondrial geneorf25. Eight of the 12 asymmetric hybrid plants hadS. tuberosum chloroplast DNA and the remaining fourS. brevidens chloroplast DNA. A novel mitochondrial hybridization pattern was present in eight out of the 17 hybrids tested. In six hybrids, novel combinations of chloroplasts and mitochondria were found, indicating that both organelle types sorted out independently.     

Several nuclear genes control both male sterility and mitochondrial protein synthesis in Nicotiana sylvestris protoclones

Summary Male sterile plants appeared in the progeny of three fertile plants obtained after one cycle of protoplast culture from a fertile botanical line and two androgenetic lines ofNicotiana sylvestris. These plants showed the same foliar and floral abnormalities as the cytoplasmic male sterile (cms) mitochondrial variants obtained after two cycles of culture. We show that male sterility in these plants is controlled by three independent nuclear genes,ms1, ms2 andms3, while no changes can be seen in the mitochondrial genome. However, differences were found between thein organello mitochondrial protein synthesis patterns of male sterile and parent plants. Two reproducible changes were observed: the presence of a new 20 kDa polypeptide and the absence of a 40 kDa one. Such variations were described previously in mitochondrial protein synthesis patterns of the cms lines. Fertile hybrids of male sterile plants showed normal synthesis patterns. The male sterile plants are thus mutated in nuclear genes involved in changes observed in mitochondrial protein synthesis patterns.     

Fluorescence microscopic study of the formation of giant mitochondrial nuclei in the young ovules ofPelargonium zonale

Summary The size of mitochondrial genomes in higher plants are known to range from 200 to 2400 kilobase pairs. However, we failed to identify cytochemically any mitochondria that contain an identifiable master mitochondrial genome. In the present experiments, we have found the giant mitochondrial nuclei which have the capacity for including the master mitochondrial genome in the young ovaries ofPelargonium zonale by use of a 4-6-diamidino-2-phenylindole (DAPI) epifluorescence microscopy, a Technovit embedding, and a video-intensified photon counting system.     

Variability of mitochondrial population in Chlamydomonas reinhardii

Several details have been published cocerning the mitochondrial number and shapes at various stages of the synchronized vegetative and generative cell cycle in Chlamydomonas reinhardii. The present study, based on ultrathin serial sections and threedimensional reconstructions, completes these data. Quantitative analysis of serial micrographs makes it possible to give specific details of mitochondrial volumes in cells at early intermediate stages of the vegetative life cycle. Our investigations clearly show that mitochondria have a relatively wide range of sizes, within certain limits, and vary like the mitochondrial shapes; in fact, they vary in various cells at various stages as well as in several cells at the same stage and even in one and the same cell. Thus, we present a plastic insight into the dynamically changing micromorphology of the mitochondrial population in Chlamydomonas reinhardii.     

Assessing mitochondrial outer membrane permeabilization during apoptosis

Mitochondria play a pivotal role in the regulation of apoptosis. An imbalance in apoptosis can lead to disease. Unscheduled apoptosis has been linked to neurodegeneration while inhibition of apoptosis can cause cancer. An early and key event during apoptosis is the release of factors from mitochondria. In apoptosis the mitochondrial outer membrane becomes permeable, leading to release of apoptogenic factors into the cytosol. One such factor, cytochrome c, is an electron carrier of the respiratory chain normally trapped within the mitochondrial intermembrane space. Many apoptotic studies investigate mitochondrial outer membrane permeabilization (MOMP) by monitoring the release of cytochrome c. Here, we describe three reliable techniques that detect cytochrome c release from mitochondria, through subcellular fractionation or immunocytochemistry and fluorescence microscopy, or isolated mitochondria and recombinant Bax and t-Bid proteins in vitro. These techniques will help to identify mechanisms and characterize factors regulating MOMP.     

Cell-free synthesis, reconstitution, and characterization of a mitochondrial dicarboxylate-tricarboxylate carrier of Plasmodium falciparum

The malaria parasite, Plasmodium falciparum, was recently shown to operate a branched pathway of tricarboxylic acid (TCA) metabolism. To identify and characterize membrane transporters required for such TCA metabolism in the parasite, we isolated a cDNA for a dicarboxylate–tricarboxylate carrier homolog (PfDTC), synthesized the encoded protein with the use of a cell-free translation system, and determined the substrate specificity of its transport activity with a proteoliposome reconstitution system. PfDTC was found to mediate efficient oxoglutarate–malate, oxoglutarate–oxaloacetate, or oxoglutarate–oxoglutarate exchange across the liposome membrane. Our results suggest that PfDTC may mediate the oxoglutarate–malate exchange across the inner mitochondrial membrane required for the branched pathway of TCA metabolism in the malaria parasite.     

Linear kalilo DNA is a Neurospora mitochondrial plasmid that integrates into the mitochondrial DNA

Summary The linear autonomous form of kalilo DNA (previously called AR-kalDNA) is shown to be resident within mitochondria rather than nuclei, as had been suggested by previous experiments. This form has been renamed mtAR-kalDNA, to signify its mitochondrial location. Experiments are described that illustrate the inheritance and somatic transmission patterns of the mitochondrial kalilo plasmid and the mitochondrial inserted form of kalilo DNA (mtlS-kalDNA). Progeny of a cross with a pre-senescent subculture as the female parent inherited mtAR-ka1DNA only; mtIS-kalDNA was not transmitted sexually. During somatic propagation of the ascospore cultures, novel kalilo DNA inserts appeared and most of them persisted until death. We propose that these inserts originated from de novo integration of mtAR-kalDNA into the mitochondrial DNA. In two of the ascopore-derived series analyzed, the first inserts detected were seen only transiently and inserts appearing subsequent to the transient inserts were retained until death. We propose that these enduring inserts originated either from rearrangements of the transient inserts or from novel integration events, either from mtAR-kalDNA or from transposition of the transient inserts.     

Somaclonal variation of the mitochondrial ATPase subunit 6 gene region in regenerated triticale shoots and full-grown plants

Comparative hybridization analyses of total DNA from fertile and cytoplasmic male-sterile (CMS) triticale plants which had been regenerated from embryogenic callus cultures revealed the organization and variation of the mitochondrial atp6 gene region. In order to compare different developmental phases, we analysed mitochondrial DNA (mtDNA) from both the shoots and full-grown regenerants. Somaclonal variants were identified on the basis of differences in the mtDNA from fertile and CMS triticale. Several shoots as well as all of the full-grown plants analysed showed somaclonal variation. This phenomenon could be traced back to having primarily orginated from the influence of the nuclear background, which give rise to a stoichiometric increase in a rye-specific orf25 gene copy, and a tissue culture-induced combination of fertile and CMS-specific mtDNA organization of the atp6 gene area. The latter event is probably caused by the homologous recombination of repetitive sequences that may be accompanied by selective amplifications.