Analysis of the tobacco chloroplast DNA replication origin (oriB) downstream of the 23 S rRNA gene

Characterization of the DNA accessibility of chloroplast genomes in grasses

Although the chloroplast genome (cpDNA) of higher plants is known to exist as a large protein-DNA complex called 'plastid nucleoid', researches on its DNA state and regulatory elements are limited. In this study, we performed the assay for transposase-accessible chromatin sequencing (ATAC-seq) on five common tissues across five grasses, and found that the accessibility of different regions in cpDNA varied widely, with the transcribed regions being highly accessible and accessibility patterns around gene start and end sites varying depending on the level of gene expression. Further analysis identified a total of 3970 putative protein binding footprints on cpDNAs of five grasses. These footprints were enriched in intergenic regions and co-localized with known functional elements. Footprints and their flanking accessibility varied dynamically among tissues. Cross-species analysis showed that footprints in coding regions tended to overlap non-degenerate sites and contain a high proportion of highly conserved sites, indicating that they are subject to evolutionary constraints. Taken together, our results suggest that the accessibility of cpDNA has biological implications and provide new insights into the transcriptional regulation of chloroplasts.

Analysis of Mitochondrial DNA Replication by Two-Dimensional Agarose Gel Electrophoresis

Two-dimensional neutral/neutral agarose gel electrophoresis (2D-AGE) has been employed for nearly two decades in the analysis of replication and maintenance processes of animal mitochondrial DNA, but the method's potential has not been fully exploited. Here, we describe the various steps involved in this technique, from DNA isolation, to two-dimensional neutral/neutral agarose gel electrophoresis (2D-AGE), Southern hybridization and interpretation. We also provide examples of the applicability of 2D-AGE to investigate the different features of mtDNA maintenance and regulation.

Repairing TALEN-mediated double-strand break by microhomology-mediated recombination in tobacco plastids generates abundant subgenomic DNA

Transcription activator-like effector nuclease (TALEN) technology has been widely used to edit nuclear genomes in plants but rarely for editing organellar genomes. In addition, ciprofloxacin, commonly used to cause the double-strand break of organellar DNA for studying the repair mechanism in plants, confers no organellar selectivity and site-specificity. To demonstrate the feasibility of TALEN-mediated chloroplast DNA editing and to use it for studying the repair mechanism in plastids, we developed a TALEN-mediated editing technology fused with chloroplast transit peptide (cpTALEN) to site-specifically edit the rpoB gene via Agrobacteria-mediated transformation of tobacco leaf. Transgenic plants showed various degrees of chlorotic phenotype. Repairing damaged plastid DNA resulted in point mutation, large deletion and small inversion surrounding the rpoB gene by homologous recombination and/or microhomology-mediated recombination. In an albino line, microhomology-mediated recombination via a pair of 12-bp direct repeats between rpoC2 and ycf2 genes generated the chimeric ycf2-rpoC2 subgenome, with the level about 3- to 5-fold higher for subgenomic DNA than ycf2. Additionally, the expression of chimeric ycf2-rpoC2 transcripts versus ycf2 mRNA agreed well with the level of corresponding DNA. The ycf2-rpoC2 subgenomic DNA might independently and preferentially replicate in plastids.

Plastid Genomes of Flowering Plants: Essential Principles

The plastid genome (plastome ) has proved a valuable source of data for evaluating evolutionary relationships among angiosperms. Through basic and applied approaches, plastid transformation technology offers the potential to understand and improve plant productivity, providing food, fiber, energy, and medicines to meet the needs of a burgeoning global population. The growing genomic resources available to both phylogenetic and biotechnological investigations is allowing novel insights and expanding the scope of plastome research to encompass new species. In this chapter, we present an overview of some of the seminal and contemporary research that has contributed to our current understanding of plastome evolution and attempt to highlight the relationship between evolutionary mechanisms and the tools of plastid genetic engineering.

The plastid genomes of flowering plants

The plastid genome (plastome) has proved a valuable source of data for evaluating evolutionary relationships among angiosperms. Through basic and applied approaches, plastid transformation technology offers the potential to understand and improve plant productivity, providing food, fiber, energy and medicines to meet the needs of a burgeoning global population. The growing genomic resources available to both phylogenetic and biotechnological investigations are allowing novel insights and expanding the scope of plastome research to encompass new species. In this chapter we present an overview of some of the seminal and contemporary research that has contributed to our current understanding of plastome evolution and attempt to highlight the relationship between evolutionary mechanisms and tools of plastid genetic engineering.

The replication of plastid minicircles involves rolling circle intermediates

Plastid genomes of peridinin-containing dinoflagellates are unique in that its genes are found on multiple circular DNA molecules known as ‘minicircles’ of ∼2–3 kb in size, carrying from one to three genes. The non-coding regions (NCRs) of these minicircles share a conserved core region (250–500 bp) that are AT-rich and have several inverted or direct repeats. Southern blot analysis using an NCR probe, after resolving a dinoflagellate whole DNA extract in pulsed-field gel electrophoresis (PFGE), revealed additional positive bands (APBs) of 6–8 kb in size. APBs preferentially diminished from cells treated with the DNA-replication inhibitor aphidicolin, when compared with 2–3 kb minicircles, implicating they are not large minicircles. The APBs are also exonuclease III-sensitive, implicating the presence of linear DNA. These properties and the migration pattern of the APBs in a 2D-gel electrophoresis were in agreement with a rolling circle type of replication, rather than the bubble-forming type. Atomic force microscopy of 6–8 kb DNA separated by PFGE revealed DNA intermediates with rolling circle shapes. Accumulating data thus supports the involvement of rolling circle intermediates in the replication of the minicircles.

Methylation of chloroplast DNA does not affect viability and maternal inheritance in tobacco and may provide a strategy towards transgene containment

We report the integration of a type II restriction-methylase, mFokI, into the tobacco chloroplast genome and we demonstrate that the introduced enzyme effectively directs the methylation of its target sequence in vivo and does not affect maternal inheritance. We further report the transformation of tobacco with an E. coli dcm methylase targeted to plastids and we demonstrate efficient cytosine methylation of the plastid genome. Both adenosine methylation of FokI sites and cytosine methylation of dcm sites appeared phenotypically neutral. The ability to tolerate such plastid genome methylation is a pre-requisite for a proposed plant transgene containment system. In such a system, a chloroplast located, maternally inherited restriction methylase would provide protection from a nuclear-encoded, plastid targeted restriction endonuclease. As plastids are not paternally inherited in most crop species, pollen from such plants would carry the endonuclease transgene but not the corresponding methylase; the consequence of this should be containment of all nuclear transgenes, as pollination will only be viable in crosses to the appropriate transplastomic maternal background.

Targeted inactivation of the tobacco plastome origins of replication A and B

According to the Kolodner and Tewari model [Kolodner, R.D. and Tewari, K.K. (1975) Nature, 256, 708.], plastid DNA replication involves displacement-loop and rolling-circle modes of replication, which are initiated on a pair of origins of replication (ori). In accordance with the model, such a pair of oris -oriA and oriB- was described in Nicotiana tabacum [Kunnimalaiyaan, M. and Nielsen B.L. (1997b) Nucl. Acids Res. 25, 3681.]. However, as reported previously, both copies of oriA can be deleted without abolishing replication. Deletion of both oriBs was not found [Mühlbauer, S.K. et al. (2002) Plant J. 32, 175.]. Here we describe new ori inactivation lines, in which one oriB is deleted and the other copy is strongly mutated. In addition, lines oriA and oriB were deleted from the same inverted repeat. In contrast to the expectations of the model, neither oriA nor oriB is essential. Some of the deletions led to reduced growth of plants and reduced plastid DNA copy number in later stages of leaf development. The gross structure of plastid DNA was unchanged; however, the location of the ends of branched plastid DNA complexes was different in the inactivation mutants. Taken together, the results indicate that there are additional mechanisms of plastid DNA replication and/or additional origins of replication. These mechanisms seem to be different from those found in eubacteria, which, according to the endosymbiont theory, are the progenitors of plastids.

Linear molecules of tobacco ptDNA end at known replication origins and additional loci

Higher plant plastid DNA (ptDNA) is generally described as a double-stranded circular molecule of the size of the monomer of the plastid genome. Also, the substrates and products of ptDNA replication are generally assumed to be circular molecules. Linear or partly linear ptDNA molecules were detected in our present study using pulsed-field gel electrophoresis and Southern blotting of ptDNA restricted with 'single cutter' restriction enzymes. These linear DNA molecules show discrete end points which were mapped using appropriate probes. One possible explanation of discrete ends would be that they represent origins of replication. Indeed, some of the mapped ends correlate well with the known origins of replication of tobacco plastids, i.e. both of the oriA sequences and--less pronouncedly--with the oriB elements. Other ends correspond to replication origins that were described for Oenothera hookeri, Zea mays, Glycine max and Chlamydomonas reinhardtii, respectively, while some of the mapped ends were not described previously and might therefore represent additional origins of replication.

Stable transformation of the cotton plastid genome and maternal inheritance of transgenes

Chloroplast genetic engineering overcomes concerns of gene containment, low levels of transgene expression, gene silencing, positional and pleiotropic effects or presence of vector sequences in transformed genomes. Several therapeutic proteins and agronomic traits have been highly expressed via the tobacco chloroplast genome but extending this concept to important crops has been a major challenge; lack of 100 homologous species-specific chloroplast transformation vectors containing suitable selectable markers, ability to regulate transgene expression in developing plastids and inadequate tissue culture systems via somatic embryogenesis are major challenges. We employed a 'Double Gene/Single Selection (DGSS)' plastid transformation vector that harbors two selectable marker genes (aph A-6 and npt II) to detoxify the same antibiotic by two enzymes, irrespective of the type of tissues or plastids; by combining this with an efficient regeneration system via somatic embryogenesis, cotton plastid transformation was achieved for the first time. The DGSS transformation vector is at least 8-fold (1 event/2.4 bombarded plates) more efficient than 'Single Gene/Single Selection (SGSS)' vector (aph A-6; 1 event per 20 bombarded plates). Chloroplast transgenic lines were fertile, flowered and set seeds similar to untransformed plants. Transgenes stably integrated into the cotton chloroplast genome were maternally inherited and were not transmitted via pollen when out-crossed with untransformed female plants. Cotton is one of the most important genetically modified crops (120 billion US dollars US annual economy). Successful transformation of the chloroplast genome should address concerns about transgene escape, insects developing resistance, inadequate insect control and promote public acceptance of genetically modified cotton.

Most chloroplast DNA of maize seedlings in linear molecules with defined ends and branched forms

We used pulsed-field gel electrophoresis, restriction fragment mapping, and fluorescence microscopy of individual DNA molecules to analyze the structure of chloroplast DNA (cpDNA) from shoots of ten to 14 day old maize seedlings. We find that most of the cpDNA is in linear and complex branched forms, with only 3-4% as circles. We find the ends of linear genomic monomers and head-to-tail (h-t) concatemers within inverted repeat sequences (IRs) near probable origins of replication, not at random sites as expected from broken circles. Our results predict two major and three minor populations of linear molecules, each with different ends and putative origins of replication. Our mapping data predict equimolar populations of h-t linear concatemeric molecules differing only in the relative orientation (inversion) of the single copy regions. We show how recombination during replication can produce h-t linear concatemers containing an inversion of single copy sequences that has for 20 years been attributed to recombinational flipping between IRs in a circular chromosome. We propose that replication is initiated predominantly on linear, not circular, DNA, producing multi-genomic branched chromosomes and that most replication involves strand invasion of internal regions by the ends of linear molecules, rather than the generally accepted D-loop-to-theta mechanism. We speculate that if the minor amount of cpDNA in circular form is useful to the plant, its contribution to chloroplast function does not depend on the circularity of these cpDNA molecules.

Functional analysis of plastid DNA replication origins in tobacco by targeted inactivation

Sequences described as chloroplast DNA replication origins were analysed in vivo by creating deletion and insertion mutants via plastid transformation in tobacco. Deletion of the described oriA sequence, which is located within the intron of the trnI gene, resulted in heteroplastomic transformants, when the selection marker was inserted within the intron. Removal of the complete intron sequence together with the oriA sequence, however, yielded homoplastomic transformants of normal phenotype, in which wild-type signals were no longer detectable through Southern analysis, thus bringing the role of the described oriA sequence for plastome replication into question. Similarly, deletion of sequence elements upstream of trnI, which have a possible ori function in Oenothera, did not show any effect in tobacco. The two copies of oriB, which are located at the very end of the plastome Inverted Repeats, were targeted with two different transformation vectors in a cotransformation approach. While in initial transformants integration of the selection marker could be detected at both sites, the transgene was found exclusively at one site or the other after additional rounds of regeneration. Whereas the copy of oriB in Inverted Repeat B could be completely deleted, targeting of the copy in Inverted Repeat A resulted in heteroplastomic lines, as the essential ycf1 gene was also affected. Due to the strong selection against cotransformants we conclude that at least one copy of the oriB sequence is essential for plastome replication, whereas replication appears possible without oriA elements.

The plastid chromosome of Atropa belladonna and its comparison with that of Nicotiana tabacum: the role of RNA editing in generating divergence in the process of plant speciation

The nuclear and plastid genomes of the plant cell form a coevolving unit which in interspecific combinations can lead to genetic incompatibility of compartments even between closely related taxa. This phenomenon has been observed for instance in Atropa-Nicotiana cybrids. We have sequenced the plastid chromosome of Atropa belladonna (deadly nightshade), a circular DNA molecule of 156,688 bp, and compared it with the corresponding published sequence of its relative Nicotiana tabacum (tobacco) to understand how divergence at the level of this genome can contribute to nuclear-plastid incompatibilities and to speciation. It appears that (1) regulatory elements, i.e., promoters as well as translational and replicational signal elements, are well conserved between the two species; (2) genes--including introns--are even more highly conserved, with differences residing predominantly in regions of low functional importance; and (3) RNA editotypes differ between the two species, which makes this process an intriguing candidate for causing rapid reproductive isolation of populations.

The plastid DNA of the malaria parasite Plasmodium falciparum is replicated by two mechanisms

In common with other apicomplexan parasites, Plasmodium falciparum, a causative organism of human malaria, harbours a residual plastid derived from an ancient secondary endosymbiotic acquisition of an alga. The function of the 35 kb plastid genome is unknown, but its evolutionary origin and genetic content make it a likely target for chemotherapy. Pulsed field gel electrophoresis and ionizing radiation have shown that essentially all the plastid DNA comprises covalently closed circular monomers, together with a tiny minority of linear 35 kb molecules. Using two-dimensional gels and electron microscopy, two replication mechanisms have been revealed. One, sensitive to the topoisomerase inhibitor ciprofloxacin, appears to initiate at twin D-loops located in a large inverted repeat carrying duplicated rRNA and tRNA genes, whereas the second, less drug sensitive, probably involves rolling circles that initiate outside the inverted repeat.

Evolution of dinoflagellate unigenic minicircles and the partially concerted divergence of their putative replicon origins

Dinoflagellate chloroplast genes are unique in that each gene is on a separate minicircular chromosome. To understand the origin and evolution of this exceptional genomic organization we completely sequenced chloroplast psbA and 23S rRNA gene minicircles from four dinoflagellates: three closely related Heterocapsa species (H. pygmaea, H. rotundata, and H. niei) and the very distantly related Amphidinium carterae. We also completely sequenced a Protoceratium reticulatum minicircle with a 23S rRNA gene of novel structure. Comparison of these minicircles with those previously sequenced from H. triquetra and A. operculatum shows that in addition to the single gene all have noncoding regions of approximately a kilobase, which are likely to include a replication origin, promoter, and perhaps segregation sequences. The noncoding regions always have a high potential for folding into hairpins and loops. In all six dinoflagellate strains for which multiple minicircles are fully sequenced, parts of the noncoding regions, designated cores, are almost identical between the psbA and 23S rRNA minicircles, but the remainder is very different. There are two, three, or four cores per circle, sometimes highly related in sequence, but no sequence identity is detectable between cores of different species, even within one genus. This contrast between very high core conservation within a species, but none among species, indicates that cores are diverging relatively rapidly in a concerted manner. This is the first well-established case of concerted evolution of noncoding regions on numerous separate chromosomes. It differs from concerted evolution among tandemly repeated spacers between rRNA genes, and that of inverted repeats in plant chloroplast genomes, in involving only the noncoding DNA cores. We present two models for the origin of chloroplast gene minicircles in dinoflagellates from a typical ancestral multigenic chloroplast genome. Both involve substantial genomic reduction and gene transfer to the nucleus. One assumes differential gene deletion within a multicopy population of the resulting oligogenic circles. The other postulates active transposition of putative replicon origins and formation of minicircles by homologous recombination between them.

Fine mapping of replication origins (ori A and ori B) in Nicotiana tabacum chloroplast DNA

Using a partially purified replication complex from tobacco chloroplasts, replication origins have been localized to minimal sequences of 82 (pKN8, positions 137 683-137 764) and 243 bp (pKN3, positions 130 513-130 755) for ori A and ori B respectively. Analysis of in vitro replication products by two-dimensional agarose gel electrophoresis showed simple Y patterns for single ori sequence-containing clones, indicative of rolling circle replication. Double Y patterns were observed when a chloroplast DNA template containing both ori s (pKN9) was tested. Dpn I analysis and control assays with Escherichia coli DNA polymerase provide a clear method to distinguish between true replication and DNA repair synthesis. These controls also support the reliability of this in vitro chloroplast DNA replication system. EM analysis of in vitro replicated products showed rolling circle replication intermediates for single ori clones (ori A or ori B), whereas D loops were observed for a clone (pKN9) containing both ori s. The minimal ori regions contain sequences which are capable of forming stem-loop structures with relatively high free energy and other sequences which interact with specific protein(s) from the chloroplast replication fraction. Apparently the minimal ori sequences reported here contain all the necessary elements for support of chloroplast DNA replication in vitro.