Synthesis and turnover of Euglena gracilis mitochondrial DNA

DNA maintenance in plastids and mitochondria of plants

The DNA molecules in plastids and mitochondria of plants have been studied for over 40 years. Here, we review the data on the circular or linear form, replication, repair, and persistence of the organellar DNA (orgDNA) in plants. The bacterial origin of orgDNA appears to have profoundly influenced ideas about the properties of chromosomal DNA molecules in these organelles to the point of dismissing data inconsistent with ideas from the 1970s. When found at all, circular genome-sized molecules comprise a few percent of orgDNA. In cells active in orgDNA replication, most orgDNA is found as linear and branched-linear forms larger than the size of the genome, likely a consequence of a virus-like DNA replication mechanism. In contrast to the stable chromosomal DNA molecules in bacteria and the plant nucleus, the molecular integrity of orgDNA declines during leaf development at a rate that varies among plant species. This decline is attributed to degradation of damaged-but-not-repaired molecules, with a proposed repair cost-saving benefit most evident in grasses. All orgDNA maintenance activities are proposed to occur on the nucleoid tethered to organellar membranes by developmentally-regulated proteins.

Implications of mutation of organelle genomes for organelle function and evolution

Organelle genomes undergo more variation, including that resulting from damage, than eukaryotic nuclear genomes, or bacterial genomes, under the same conditions. Recent advances in characterizing the changes to genomes of chloroplasts and mitochondria of Zea mays should, when applied more widely, help our understanding of how damage to organelle genomes relates to how organelle function is maintained through the life of individuals and in succeeding generations. Understanding of the degree of variation in the changes to organelle DNA and its repair among photosynthetic organisms might help to explain the variations in the rate of nucleotide substitution among organelle genomes. Further studies of organelle DNA variation, including that due to damage and its repair might also help us to understand why the extent of DNA turnover in the organelles is so much greater than that in their bacterial (cyanobacteria for chloroplasts, proteobacteria for mitochondria) relatives with similar rates of production of DNA-damaging reactive oxygen species. Finally, from the available data, even the longest-lived organelle-encoded proteins, and the RNAs needed for their synthesis, are unlikely to maintain organelle function for much more than a week after the complete loss of organelle DNA.

Changes in DNA damage, molecular integrity, and copy number for plastid DNA and mitochondrial DNA during maize development

The amount and structural integrity of organellar DNAs change during plant development, although the mechanisms of change are poorly understood. Using PCR-based methods, we quantified DNA damage, molecular integrity, and genome copy number for plastid and mitochondrial DNAs of maize seedlings. A DNA repair assay was also used to assess DNA impediments. During development, DNA damage increased and molecules with impediments that prevented amplification by Taq DNA polymerase increased, with light causing the greatest change. DNA copy number values depended on the assay method, with standard real-time quantitative PCR (qPCR) values exceeding those determined by long-PCR by 100- to 1000-fold. As the organelles develop, their DNAs may be damaged in oxidative environments created by photo-oxidative reactions and photosynthetic/respiratory electron transfer. Some molecules may be repaired, while molecules with unrepaired damage may be degraded to non-functional fragments measured by standard qPCR but not by long-PCR.

DNA abandonment and the mechanisms of uniparental inheritance of mitochondria and chloroplasts

For most eukaryotic organisms, the nuclear genomes of both parents are transmitted to the progeny following biparental inheritance. For mitochondria and chloroplasts, however, uniparental inheritance (UPI) is frequently observed. The maternal mode of inheritance for mitochondria in animals can be nearly absolute, suggesting an adaptive advantage for UPI. In other organisms, however, the mode of inheritance for mitochondria and chloroplasts can vary greatly even among strains of a species. Here, I review the data on the transmission of organellar DNA (orgDNA) from parent to progeny and the structure, copy number, and stability of orgDNA molecules. I propose that UPI is an incidental by-product of DNA abandonment, a process that lowers the metabolic cost of orgDNA repair.

Net synthesis of chloroplast DNA throughout the synchronized vegetative cell-cycle of Chlamydomonas

The accumulation of chloroplast and nuclear DNAs during the 12 h light and 12 h dark synchronized vegetative cell-cycle of Chlamydomonas reinhardtii was monitored by the direct optical quantification of these DNAs in the analytical ultracentrifuge. Net synthesis of nuclear DNA was sharply discontinuous and this synthesis occurred during the first 6 h of the dark period. In contrast, the net synthesis of chloroplast DNA appeared continuous throughout the cell-cycle. The rate of this accumulation, however, was greatest in the dark period.

Dispersive labelling of Chlamydomonas chloroplast DNA in (15)N- (14)N density transfer experiments

(15)N-(14)N density transfer experiments with synchronized vegetative cultures of Chlamydomonas reinhardtii revealed a dispersive labelling of chloroplast DNA (cpDNA) while the labelling of nuclear DNA was consistent with semiconservative replication. The dispersive labelling of cpDNA was progressive and extensive as after less than two net doublings of this DNA in (14)N-medium no significant amount of fully heavy, (15)N-strands could be detected in denatured cpDNA preparations; the average size of DNA in these preparations corresponded to 6% of the intact chloroplast genome or about 12 kbp. The density shifts of native cpDNA samples were found to be consistent with the net amounts of cpDNA synthesized. This observation indicates that essentially all (15)N atoms incorporated prior to the transfer were conserved and that metabolic turnover of cpDNA was probably absent. Our results are best explained by the exchange of homologous single-stranded segments between cpDNA molecules to form heteroduplex regions and by each DNA molecule undergoing several rounds of heteroduplex formation.

Mitochondrial DNA, chloroplast DNA and the origins of development in eukaryotic organisms

Background

Several proposals have been made to explain the rise of multicellular life forms. An internal environment can be created and controlled, germ cells can be protected in novel structures, and increased organismal size allows a "division of labor" among cell types. These proposals describe advantages of multicellular versus unicellular organisms at levels of organization at or above the individual cell. I focus on a subsequent phase of evolution, when multicellular organisms initiated the process of development that later became the more complex embryonic development found in animals and plants. The advantage here is realized at the level of the mitochondrion and chloroplast.

Hypothesis

The extreme instability of DNA in mitochondria and chloroplasts has not been widely appreciated even though it was first reported four decades ago. Here, I show that the evolutionary success of multicellular animals and plants can be traced to the protection of organellar DNA. Three stages are envisioned. Sequestration allowed mitochondria and chloroplasts to be placed in "quiet" germ line cells so that their DNA is not exposed to the oxidative stress produced by these organelles in "active" somatic cells. This advantage then provided Opportunity, a period of time during which novel processes arose for signaling within and between cells and (in animals) for cell-cell recognition molecules to evolve. Development then led to the enormous diversity of animals and plants.

Implications

The potency of a somatic stem cell is its potential to generate cell types other than itself, and this is a systems property. One of the biochemical properties required for stemness to emerge from a population of cells might be the metabolic quiescence that protects organellar DNA from oxidative stress.

Reviewers

This article was reviewed by John Logsdon, Arcady Mushegian, and Patrick Forterre.

The curious history of yeast mitochondrial DNA

Forty years ago, soon after yeast mitochondrial DNA (mtDNA) was recognized, some animal versions of mtDNA were shown to comprise circular molecules. Supporting an idea that mitochondria had evolved from bacteria, this finding generated a dogmatic belief that yeast mtDNA was also circular, and the endless linear molecules actually observed in yeast were regarded as broken circles. This concept persisted for 30 years and has distorted our understanding of the true nature of the molecule.

The structure of mitochondrial DNA from the liverwort, Marchantia polymorpha

The structure of mitochondrial DNA (mtDNA) from cultured cells of the liverwort, Marchantia polymorpha, was analyzed by pulsed-field gel electrophoresis (PFGE) and moving pictures of the fluorescently labeled molecules. Previous electron microscopic analysis with this liverwort revealed a unique property among land plants: mtDNA circles of only one size, that of the 186 kb genome, with no subgenomic circles. Most of the mtDNA was immobile in PFGE and contained complex structures, larger than the genome size with a bright fluorescent node and multiple attached fibers. The mobile mtDNA was mostly linear molecules in monomeric to pentameric lengths of the unit genome that increased following mung bean nuclease digestion, with a corresponding decrease in the immobile fraction. From 0 to 5% of the mtDNA was found as circular molecules the size of the genome and its oligomers; no subgenome-sized circles were present. Radiolabeling revealed that mtDNA synthesis began soon after transfer of cells to fresh medium and most newly replicated mtDNA was immobile; the circular form of the genome was not rapidly labeled.

[Periodic, metabolic and structural phenomena in a protist, Euglena gracilis]

Sychronous divisions of Euglena gracilis strain Z can be obtained by various methods. When the cells are cultivated in a medium containing lactate as the sole carbon source, synchronous divisions are observed, independent of the conditions of illumination. Nevertheless, there exists a relationship between the phase of cell division and ther periods of light and darkness applied to the culture. During the cell cycle, the synthesis of macromolecules is discontinuous--this is true of nuclear and mitochondrial DNA, ribosomal and nonribosomal RNA, and certain proteins (cytochrome c 558). Cyclic variations in the structure of mitochondria and chloroplasts are observed. In the course of the cell cycle, sequential metabolic processes accompany structural modifications of the organelles. Also, at the beginning of the cycle, at the start of phase G1, the cytoplasmic ribosomes are synthesized, and then, in green euglenids, nonribosomal RNAs are formed. These syntheses of RNA precede enlargement of the chondriome and plastids. In mid-G1 phase, a new synthesis of RNA begins, which precedes synthesis of nuclear and mitochondrial DNA. At the end of G1 phase, division of organelles starts, beginning with the chondriome and plastids, arranged in a network.

Replication of bromodeoxyuridylate-substituted mitochondrial DNA in yeast

The DNA of several strains of Saccharomyces cerevisiae was labeled by growing the culture in medium supplemented with thymidylate and bromodeoxyuridylate. It was thus possible to follow the course of mitochondrial DNA replication in density shift experiments by determining the buoyant density distribution of unreplicated and replicated DNAs in analytical CsCl gradients. DNA replication was followed for three generations after transfer of cultures from light medium to heavy medium and heavy medium to light medium. Under both conditions, the density shifts observed for mitochondrial DNA were those expected for semiconservative, nondispersive replication. This was further confirmed by analysis of the buoyant density of alkali-denatured hybrid mitochondrial DNA. With this method, no significant recombination between replicated and unreplicated DNA was detected after three generations of growth.

Replicative deoxyribonucleic acid synthesis in isolated mitochondria from Saccharomyces cerevisiae

The characteristics of a system for the in vitro synthesis of mitochondrial deoxyribonucleic acid (mtDNA) in mitochondria isolated from Saccharomyces cerevisiae are described. In this system the exclusive product of the reaction is mtDNA. Under optimal conditions the initial rate of synthesis is close to the calculated in vivo rate; the rate is approximately linear for 20 min but then decreases gradually with time. DNA synthesis proceeds for at least 60 min and the de novo synthesis of an amount of mtDNA equivalent to 15% of the mtDNA initially present is achieved. The rate and extent of synthesis observed with mitochondria isolated from grande and petite (rho(-)) strains were similar. The mode of DNA synthesis is semiconservative; after density labeling with 5-bromodeoxyuridine triphosphate, in vitro, the majority of labeled DNA fragments of duplex molecular weight, 6 x 10(6), are of a density close to that calculated for hybrid yeast mtDNA. The density label is incorporated into one strand of the duplex molecules. These properties indicate that the synthesis resembles replicative rather than repair synthesis. This system therefore provides a convenient method for the study of mtDNA synthesis in S. cerevisiae. The observation that mtDNA synthesis is semiconservative in vitro suggests that the dispersive mode of synthesis observed in S. cerevisiae in vivo labeling studies is the result of some other process, possibly a high recombination rate.

Light-stimulated synthesis of chloroplast DNA

Light-stimulated chloroplast DNA synthesis was studied during chloroplast development in the absence of cell division and nuclear DNA synthesis. Incorporation of 32Pi was stimulated 10-15 fold, however, the ratio of chloroplast DNA to nuclear DNA remained constant. Isotope dilution experiments suggested that stimulated labeling of chloroplast DNA represented more efficient utilization of exogenously supplied Pi rather than stimulated turnover of chloroplast DNA. The low level of DNA synthesis and chloroplast development were resistant to nalidixic acid which inhibits semiconservative replication of chloroplast DNA.