Influence of mitochondria on gene expression in a citrus cybrid

The production of cybrids, combining nucleus of a species with alien cytoplasmic organelles, is a valuable method used for improvement of various crops. Several citrus cybrids have been created by somatic hybridization. These genotypes are interesting models to analyze the impact of cytoplasmic genome change on nuclear genome expression. Herein, we report genome-wide gene expression analysis in leaves of a citrus cybrid between C. reticulata cv ‘Willowleaf mandarin’ and C. limon cv ‘Eureka lemon’ compared with its lemon parent, using a Citrus 20K cDNA microarray. Molecular analysis showed that this cybrid possesses nuclear and chloroplast genomes of Eureka lemon plus mitochondria from Willowleaf mandarin and, therefore, can be considered as a lemon bearing foreign mitochondria. Mandarin mitochondria influenced the expression of a large set of lemon nuclear genes causing an over-expression of 480 of them and repression of 39 genes. Quantitative real-time RT–PCR further confirmed the credibility of microarray data. Genes over-expressed in cybrid leaves are predominantly attributed to the functional category “cellular protein metabolism” whereas in the down-regulated none functional category was enriched. Overall, mitochondria replacement affected different nuclear genes including particularly genes predicted to be involved in mitochondrial retrograde signaling. Mitochondria regulate all cell structures even chloroplast status. These results suggest that nuclear gene expression is modulated with respect to new information received from the foreign organelle, with the final objective to suit specific needs to ensure better cell physiological balance.     

A new method to reconstruct recombination events at a genomic scale

Recombination is one of the main forces shaping genome diversity, but the information it generates is often overlooked. A recombination event creates a junction between two parental sequences that may be transmitted to the subsequent generations. Just like mutations, these junctions carry evidence of the shared past of the sequences. We present the IRiS algorithm, which detects past recombination events from extant sequences and specifies the place of each recombination and which are the recombinants sequences. We have validated and calibrated IRiS for the human genome using coalescent simulations replicating standard human demographic history and a variable recombination rate model, and we have fine-tuned IRiS parameters to simultaneously optimize for false discovery rate, sensitivity, and accuracy in placing the recombination events in the sequence. Newer recombinations overwrite traces of past ones and our results indicate more recent recombinations are detected by IRiS with greater sensitivity. IRiS analysis of the MS32 region, previously studied using sperm typing, showed good concordance with estimated recombination rates. We also applied IRiS to haplotypes for 18 X-chromosome regions in HapMap Phase 3 populations. Recombination events detected for each individual were recoded as binary allelic states and combined into recotypes. Principal component analysis and multidimensional scaling based on recotypes reproduced the relationships between the eleven HapMap Phase III populations that can be expected from known human population history, thus further validating IRiS. We believe that our new method will contribute to the study of the distribution of recombination events across the genomes and, for the first time, it will allow the use of recombination as genetic marker to study human genetic variation.     

ASY1 coordinates early events in the plant meiotic recombination pathway

Meiosis is a fundamental and evolutionarily conserved process that is central to the life cycles of all sexually reproducing eukaryotes. An understanding of this process is critical to furthering research on reproduction, fertility, genetics and breeding. Plants have been used extensively in cytogenetic studies of meiosis during the last century. Until recently, our knowledge of the molecular and functional aspects of meiosis has emerged from the study of non-plant model organisms, especially budding yeast. However, the emergence of Arabidopsis thaliana as the model organism for plant molecular biology and genetics has enabled significant progress in the characterisation of key genes and proteins controlling plant meiosis. The development of molecular and cytological techniques in Arabidopsis, besides allowing investigation of the more conserved aspects of meiosis, are also providing insights into features of this complex process which may vary between organisms. This review highlights an example of this recent progress by focussing on ASY1, a meiosis-specific Arabidopsis protein which shares some similarity with the N-terminus region of the yeast axial core-associated protein, HOP1, a component of a multiprotein complex which acts as a meiosis-specific barrier to sister-chromatid repair in budding yeast. In the absence of ASY1, synapsis is interrupted and chiasma formation is dramatically reduced. ASY1 protein is initially detected during early meiotic G2 as numerous foci distributed over the chromatin. As G2 progresses the signal appears to be increasingly continuous and is closely associated with the axial elements. State-of-the-art cytogenetic techniques have revealed that initiation of recombination is synchronised with the formation of the chromosome axis. Furthermore, in the context of the developing chromosome axes, ASY1 plays a crucial role in co-ordinating the activity of a key member of the homologous recombination machinery, AtDMC1.     

Origin of the CMS gene locus in rapeseed cybrid mitochondria: active and inactive recombination produces the complex CMS gene region in the mitochondrial genomes of Brassicaceae

CMS (cytoplasmic male sterile) rapeseed is produced by asymmetrical somatic cell fusion between the Brassica napus cv. Westar and the Raphanus sativus Kosena CMS line (Kosena radish). The CMS rapeseed contains a CMS gene, orf125, which is derived from Kosena radish. Our sequence analyses revealed that the orf125 region in CMS rapeseed originated from recombination between the orf125/orfB region and the nad1C/ccmFN1 region by way of a 63 bp repeat. A precise sequence comparison among the related sequences in CMS rapeseed, Kosena radish and normal rapeseed showed that the orf125 region in CMS rapeseed consisted of the Kosena orf125/orfB region and the rapeseed nad1C/ccmFN1 region, even though Kosena radish had both the orf125/orfB region and the nad1C/ccmFN1 region in its mitochondrial genome. We also identified three tandem repeat sequences in the regions surrounding orf125, including a 63 bp repeat, which were involved in several recombination events. Interestingly, differences in the recombination activity for each repeat sequence were observed, even though these sequences were located adjacent to each other in the mitochondrial genome. We report results indicating that recombination events within the mitochondrial genomes are regulated at the level of specific repeat sequences depending on the cellular environment.     

DNA recombination activity in soybean mitochondria

Mitochondrial genomes in higher plants are much larger and more complex as compared to animal mitochondrial genomes. There is growing evidence that plant mitochondrial genomes exist predominantly as a collection of linear and highly branched DNA molecules and replicate by a recombination-dependent mechanism. However, biochemical evidence of mitochondrial DNA (mtDNA) recombination activity in plants has previously been lacking. We provide the first report of strand-invasion activity in plant mitochondria. Similar to bacterial RecA, this activity from soybean is dependent on the presence of ATP and Mg(2+). Western blot analysis using an antibody against the Arabidopsis mitochondrial RecA protein shows cross-reaction with a soybean protein of about 44 kDa, indicating conservation of this protein in at least these two plant species. mtDNA structure was analyzed by electron microscopy of total soybean mtDNA and molecules recovered after field-inversion gel electrophoresis (FIGE). While most molecules were found to be linear, some molecules contained highly branched DNA structures and a small but reproducible proportion consisted of circular molecules (many with tails) similar to recombination intermediates. The presence of recombination intermediates in plant mitochondria preparations is further supported by analysis of mtDNA molecules by 2-D agarose gel electrophoresis, which indicated the presence of complex recombination structures along with a considerable amount of single-stranded DNA. These data collectively provide convincing evidence for the occurrence of homologous DNA recombination in plant mitochondria.     

Efficient repair of genomic double-strand breaks by homologous recombination between directly repeated sequences in the plant genome

Previous studies demonstrated that in somatic plant cells, homologous recombination (HR) is several orders of magnitude less efficient than nonhomologous end joining and that HR is little used for genomic double-strand break (DSB) repair. Here, we provide evidence that if genomic DSBs are induced in close proximity to homologous repeats, they can be repaired in up to one-third of cases by HR in transgenic tobacco. Our findings are relevant for the evolution of plant genomes because they indicate that sequences containing direct repeats such as retroelements might be less stable in plants that harbor active mobile elements than anticipated previously. Furthermore, our experimental setup enabled us to demonstrate that transgenic sequences flanked by sites of a rare cutting restriction enzyme can be excised efficiently from the genome of a higher eukaryote by HR as well as by nonhomologous end joining. This makes DSB-induced recombination an attractive alternative to the currently applied sequence-specific recombination systems used for genome manipulations, such as marker gene excision.     

Recent advances in plant recombination

Recombination is an essential cellular process and a source of genetic diversity. Recent studies have demonstrated the effects of various factors (e.g. DNA sequence similarity and activation of transposons) on rates of recombination and the distribution of recombination breakpoints in plants. These studies have also provided detailed characterizations of interchromatid and interhomolog recombination events. New approaches offer the promise of achieving the long-awaited goal of gene targeting in plants.     

Contrasting recombination patterns and demographic histories of the plant pathogen Ralstonia solanacearum inferred from MLSA

We used multilocus sequence analysis (MLSA) on a worldwide collection of the plant pathogenic Ralstonia solanacearum (Betaproteobacteria) to retrace its complex evolutionary history. Using genetic imprints left during R. solanacearum evolution, we were able to delineate distinct evolutionary complex displaying contrasting dynamics. Among the phylotypes already described (I, IIA, IIB, III, IV), eight groups of strains with distinct evolutionary patterns, named clades, were identified. From our recombination analysis, we identified 21 recombination events that occurred within and across these lineages. Although appearing the most divergent and ancestral phylotype, phylotype IV was inferred as a gene donor for the majority of the recombination events that we detected. Whereas this phylotype apparently fuelled the species diversity, ongoing diversification was mainly detected within phylotype I, IIA and III. These three groups presented a recent expanding population structure, a high level of homologous recombination and evidences of long-distance migrations. Factors such as adaptation to a specific host or intense trading of infected crops may have promoted this diversification. Whether R. solanacearum lineages will eventually evolve in distinct species remains an open question. The intensification of cropping and increase of geographical dispersion may favour situations of phylotype sympatry and promote higher exchange of key factors for host adaptation from their common genetic pool.     

Pervasive genomic recombination of HIV-1 in vivo

Recombinants of preexisting human immunodeficiency virus type 1 (HIV-1) strains are now circulating globally. To increase our understanding of the importance of these recombinants, we assessed recombination within an individual infected from a single source by studying the linkage patterns of the auxiliary genes of HIV-1 subtype B. Maximum-likelihood phylogenetic techniques revealed evidence for recombination from topological incongruence among adjacent genes. Coalescent methods were then used to estimate the in vivo recombination rate. The estimated mean rate of 1.38 x 10(-4) recombination events/adjacent sites/generation is approximately 5.5-fold greater than the reported point mutation rate of 2.5 x 10(-5)/site/generation. Recombination was found to be frequent enough to mask evidence for purifying selection by Tajima's D test. Thus, recombination is a major evolutionary force affecting genetic variation within an HIV-1-infected individual, of the same order of magnitude as point mutational change.     

A broad survey of recombination in animal mitochondria

Recombination in mitochondrial DNA (mtDNA) remains a controversial topic. Here we present a survey of 279 animal mtDNA data sets, of which 12 were from asexual species. Using four separate tests, we show that there is widespread evidence of recombination; for one test as many as 14.2% of the data sets reject a model of clonal inheritance and in several data sets, including primates, the recombinants can be identified visually. We show that none of the tests give significant results for obligate clonal species (apomictic pathogens) and that the sexual species show significantly greater evidence of recombination than asexual species. For some data sets, such as Macaca nemestrina, additional data sets suggest that the recombinants are not artifacts. For others, it cannot be determined whether the recombinants are real or produced by laboratory error. Either way, the results have important implications for how mtDNA is sequenced and used.     

Anion transporters in plant mitochondria

The swelling of potato (Solanum tuberosum L.) mitochondria in isosmotic ammonium salts of phosphate, chloride, malate, succinate, and citrate was investigated by measuring light scattering. Potato mitochondria swell spontaneously in ammonium phosphate, and this swelling can be inhibited in N-ethylmaleimide. They swell in ammonium malate or succinate only after the addition of inorganic phosphate and in ammonium citrate only after the addition of both phosphate and a dicarboxylic acid. Pentylmalonate inhibits swelling in ammonium citrate solutions by competing for dicarboxylate entry. The results indicate that potato mitochondria possess a phosphate-hydroxyl carrier, a dicarboxylate carrier, and a tricarboxylate carrier.     

Oxaloacetate translocator in plant mitochondria

(1) Mitochondria were prepared from leaves of spinach, green and etiolated seedlings and roots of pea, potato tuber and rat liver and heart. In the case of leaf mitochondria, an improved isolation procedure resulted in high respiratory rates (460–510 nmol/mg protein per min) and good respiratory control ratio (6.8–9.8) with glycine as substrate. (2) In these mitochondria oxaloacetate transport was studied either by following the inhibitory effect of oxaloacetate on the respiration of NADH-linked substrates or by determining the consumption of [4-¹⁴C]oxaloacetate. (3) Studies of the competition by other carboxylates and effect of inhibitors on the oxaloacetate transport demonstrate that mitochondria from spinach leaves, green pea seedlings, etiolated pea seedlings and pea roots contain a specific translocator for oxaloacetate with a very high affinity to its substrate (K_m = 3–7 μM) and an even higher sensitivity to its competitive inhibitor phthalonate (K_i = 3–5 μM). The V_max values ranged from 150 to 180 nmol/mg protein per min for mitochondria from etiolated pea seedlings and pea roots and from 550 to 570 nmol/mg protein per min for mitochondria from spinach leaves and green pea seedlings. In mitochondria from potato tuber, the K_m was about one order of magnitude higher (V_max = 450 nmol/mg protein per min). In mitochondria from rat liver and rat heart, a specific translocator for oxaloacetate was not found. (4) The oxaloacetate translocator enables the functioning of a malate-oxaloacetate shuttle for the transfer of reducing equivalents across the inner mitochondrial membrane. (5) This malate-oxaloacetate shuttle appears to play a role in the photorespiratory cycle in catalyzing the transfer of reducing equivalents generated in the mitochondria during glycine oxydation to the peroxysomal compartment for the reduction of β-hydroxypyruvate. (6) Interaction between the mitochondrial and the chloroplastic malate oxaloacetate shuttles would make it possible for surplus-reducing equivalents, generated by photosynthetic electron transport, to be oxidized by mitochondrial electron transport.     

RNA editing in plant mitochondria

RNA editing in plant mitochondria alters nearly all mRNAs by C to U and U to C transitions. In some species more than 400 edited sites have been identified with significant effects on the encoded proteins. RNA editing occurs in higher and lower plants and presumably has evolved before the differentiation of land plants. Current research focuses on the elucidation of the biochemistry and the specificity determinants of RNA editing in plant mitochrondria.     

'Illegitimate' recombination events in polyoma-transformed rat cells

In the LPT line of polyoma (Py)-transformed rat cells, amplification of the integrated viral DNA and of cell nucleotide sequences flanking the viral integration site, can be induced either spontaneously or by treatment with carcinogens. We show here that the amplified DNA includes interspersed viral and cellular sequences generated by 'illegitimate' recombination events. Genomic libraries have been prepared in phage lambda vectors from LPT cells treated with the inducing agent mitomycin C and from untreated LPT cells. Four phages, including viral-cell DNA recombinants, have been isolated from these libraries. Sequencing through the recombination sites revealed the following characteristics: (i) The crossover points map at four different positions in the viral DNA and at four different positions in the flanking cell DNA. (ii) There are very short homologous sequences of 1, 2, or 4 bp, at the recombination sites. (iii) Aside from the exchanges between the viral and the cellular DNA, no further rearrangements occurred around the new viral-cellular DNA junctions. (iv) Next to the recombination sites, there are blocks of homopurine-homopyrimidine sequences, which may assume a structure that differs from the Watson-Crick double helix. (v) Clustered homologous sequence blocks of up to 10 bp are present less than 200 bp away from the recombination sites. These homologies are not in register. Based on these results, we propose a model that may account for these recombination events and, more generally, for recombination events that occur during gene amplification in mammalian cells.     

Protein phosphorylation in plant mitochondria

Reversible phosphorylation of proteins is one of the most common regulatory mechanisms in eukaryotic cells and it can affect virtually any property of a protein. We predict that plant mitochondria possess 50–200 protein kinases (PKs), at least as many target proteins and 10–30 protein phosphatases although all will not be expressed at the same time in the same cell type or tissue. Presently available high-throughput methods for the identification of phosphoproteins and their phosphorylation sites are first reviewed and a number of useful databases listed. We then discuss the known phosphoproteins, PKs and phosphatases in plant mitochondria and compare with yeast and mammalian mitochondria. Three case stories—respiratory chain complex I, pyruvate dehydrogenase and formate dehydrogenase—are briefly considered before a final treatment of mitochondrial protein phosphorylation in intracellular signal transduction and programmed cell death.