Botanisches Institut der Ludwig-Maximilians-Universität München, Germany
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Abstract |
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Introduction |
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The coding potential of plastids, the plastome, is deposited in a multitude of identical circular DNA molecules of 75250 kbp, depending on the plant species. Sequences of plastid chromosomes are available for a variety of vascular plants and algae (for a list of completed plastid chromosomes, see http://www.ncbi.nlm.nih.gov/PMGifs/Genomes/plastids_tax.html). Their analysis has so far focused on the question of coding potential and the origin of plastids and land plants (Martin et al. 1998
; Gray 1999
; Stoebe and Kowallik 1999
; Lemieux, Otis, and Turmel 2000
). Available sequence data have revealed the conservative nature of contemporary plastid chromosomes with regard to both structure and gene content. The similarity is particularly striking when defined phylogenetic groups are considered, for example, the streptophytes and their sister group, the chlorophytes (http://www.ncbi.nlm.nih.gov/PMGifs/Genomes/plastids_tax.html). With rare exceptions, these plastid chromosomes exhibit a quadripartite structure and contain a similar set of genes, specifying predominantly constituents of the photosynthetic and genetic machineries. Genes and operons are densely packed, with conserved reading frames sometimes even overlapping; intergenic regions are relatively short and often target sites for nuclear-coded factors regulating plastid gene expression and implicit development. For instance, nuclear-coded sigma-factors mediate transcription initiation by the plastid-coded core RNA polymerase (Allison 2000
), and nuclear-coded proteins bind to 5' or 3' untranslated regions (UTRs) of plastid messages that influence their turnover rates (Monde, Schuster, and Stern 2000
). Furthermore, plastid messages, most of them polycistronic, have to be dissected, trimmed, polyadenylated, spliced, and edited, all of which depends on specific interactions with nuclear factors that have to be imported from the cytoplasm (Barkan and Goldschmidt-Clermont 2000)
.
Sequence comparisons of complete plastid chromosomes have been carried out using exclusively more distantly related lineages, except the Graminean species rice, maize, and wheat (Maier et al. 1995
; Ogihara et al. 2002
), for which hot-spots of divergence have been analyzed with respect to mechanistic rather than evolutionary issues. Aspects of microevolution and their impact on plant speciation have been addressed only by comparisons of a few plastid sequence stretches (e.g., Young and dePamphilis 2000)
. From these data, it is clear that differences reside predominantly in the rapidly evolving intergenic regions when closely related plants are analyzed (e.g., Gielly and Taberlet 1994
). Intergenic regions harbor many sequence elements functioning in gene expression like promoters or translational enhancers, which are indispensable for development and maintenance of the organelle. In general, these elements are far more conserved than the surrounding sequence (e.g., Manen, Savolainen, and Simon 1994
). The question remains whether it is the divergence of intergenic functional elements and hence the regulation of gene expression that causes incompatibility of genetic compartments, or whether the coding regions themselves are the source of this phenomenon.
Here, we present the complete sequence of the plastid chromosome of A. belladonna and compare it with the corresponding sequence of tobacco (Shinozaki et al. 1986
), with emphasis on differences relevant to interspecific incompatibilities of plastid and nuclear genomes.
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Materials and Methods |
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RNA was reverse transcribed with a random primer mixture using SuperscriptTM (GIBCOBRL; Maier et al. 1995
). DNA and cDNA were amplified according to a standard protocol with 30 cycles of 94°C (for 20 s), 55°C (for 20 s), and 72°C (for 45 s) with a 2-min extension at 94°C for the first cycle and a 4-min extension at 72°C for the final cycle in the presence of 2.5 mM magnesium chloride.
A recombinant DNA library containing XhoI, BamHI, SalI, PstI, and ApaI plastid DNA fragments of A. belladonna Ab5 in pBluescript II SK- (Stratagene, La Jolla, CA) provided templates for sequencing. PCR-derived amplification products were used to close gaps between restriction fragments. Nucleotide sequences were determined by the dideoxy chain termination method (Sanger, Nicklen, and Coulsen 1977
) using a set of approximately 400 representative primers for both DNA strands with an ABI 377 sequencer (Applied Biosystems, USA). Oligonucleotides used for the PCR and for sequencing were purchased from MWG Biotech (Ebersberg, Germany). Sequences were evaluated and assembled using Sequencher 3.0 (Gene Codes Corporation, USA). The sequences were aligned using the BioEdit sequence alignment editor (North Carolina State University).
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Results and Discussion |
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Coding Regions are Highly Conserved Between Atropa and Tobacco
As an important interface in nuclear-plastid interactions, plastome-encoded polypeptides and RNAs, as well as distinct sequence motifs in the plastid chromosome itself have to interact with nuclear-encoded polypeptides (and possibly RNAs), for instance during gene expression or assembly of multiprotein complexes. Considering that coevolution of polypeptides with their interaction partners is a well-described phenomenon (Goh et al. 2000)
, divergence of plastid polypeptides may hamper interspecific interactions of compartments. Differences in homologous polypeptide sequences encoded by the Atropa and tobacco plastid chromosomes occur as amino acid substitutions and, rarely, also as insertions and deletions.
Altogether 10 indels are present in six polypeptide genes, of which six can be attributed to replication slippage (fig. 2
and data not shown). The eight codons not present in Atropa accD, which encodes the ß-subunit of the prokaryotic-type acetyl-CoAcarboxylase, reside in a region of relatively low sequence conservation among land plant species (fig. 2A
). Deletions relative to tobacco occur in most other species examined. Similarly, a single codon missing in Atropa ccsA, specifying a protein involved in c-type cytochrome synthesis, is located in a short stretch coding for rather poorly conserved amino acid sequences (fig. 2B
). In Atropa rpoC2, coding for a subunit of a plastid RNA polymerase, three successive codons are absent relative to tobacco and all other higher plant sequences examined. Deletions further downstream affecting the same region of RpoC2 are also known from other plant species (fig. 2C
). For Atropa rps16, specifying a ribosomal polypeptide, a 9-bp deletion including the tobacco stop codon leads to a short carboxy-terminal extension of the encoded polypeptide identical to the one found in spinach (Spinacia oleracea). It has been shown that the Rps16 C-terminus does not interact with rRNA or with other ribosomal proteins, which questions its importance in ribosomal function (Allard et al. 2000
) (fig. 2D
). Additional indels have been found in the ycf1 and ycf2 reading frames. These two genes are known to be essential for plant survival (Drescher et al. 2000)
, though their functions have not been determined yet. Unlike ycf2, ycf1 is speckled with indels and rarely occurring conserved elements. None of the four deletions noted in Atropa ycf1 affects these conserved elements, and all of the codons deleted in tobacco ycf1 are also absent in other dicot species (data not shown). For ycf2, the two insertions found in tobacco, one of them three codons in size, the other eight, form direct repeats with adjacent sequence elements and are also situated outside highly conserved domains (data not shown).
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Most amino acid substitutions caused by differences in the plastome sequences of Atropa and tobacco occur at nonconserved positions in polypeptides or are conservative, that is, probably without effect on protein function. But 11 of the altogether 360 substitutions (3%) concern highly conserved residues, a phenomenon affecting the products of nine genes (table 2
). To assess the potential functional importance of these residues, we analyzed conservation of the sequence neighborhood by counting variable residues in a window of 20 amino acids surrounding the residue in question. The position of the window was chosen to minimize the number of variable positions, as the residue of interest can be at the edge as well as in the center of a conserved domain. The proportion of all variable positions in this window yields a value suitable for comparison of the impact on domain conservation of different substitutions (table 2
). Among the five substitutions located in the domains most rigidly conserved, four are reverted by C-to-U editing of the respective codon in the tobacco transcript (at atpA site 1, the psbE site and rps14 site 1, according to Tsudzuki, Wakasugi, and Sugiura [2001]
, and at one site in ndhD, here referred to as ndhD site 3, not described so far [unpublished data]). The fifth, found in PsaB, a core subunit of photosystem I, is located at a surface region of the protein that is suggested not to interact with neighboring components (Jordan et al. 2001)
, as revealed by analysis of structural data of the homologous polypeptide in Synechococcus (PDB Id: 1JB0) using SWISS PDB viewer V3.7b2 (www.expasy.ch/spdbv/mainpage.html). Similarly, for two substitutions at less-conserved positions in AtpB, the ß-subunit of ATP synthase, residues are found exposed to solvent (PDB IFX0; Groth and Pohl 2001)
. In contrast, the L264 in Atropa AtpA, a component of the same multiprotein complex, is situated at the core of the protein and in silico exchange to proline, the unedited state in tobacco, revealed undesirable interactions with A267 and F318 (data not shown). In summary, most of the codon substitutions at highly conserved positions are rescued by RNA editing, so that differences on the chromosomal level are adjusted on the transcript level. The reverse, that diverse amino acid positions result from differences in editing, has not been observed.
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All -10 and -35 boxes of PEP promoters as well as all YAT-motives in NEP promoters are identical between Atropa and tobacco. In addition, elements regulating promoter activity, like those upstream of the psbD blue-light promoter or the rpoB promoter (Allison and Maliga 1995
; Inada et al. 1997
), are identical. Base substitutions between Atropa and tobacco promoters have only been found in four instances (trnG-UCC, atpI, rps16, and clpP), but always outside the core elements. In E. coli, it has been shown that sequences outside the -10 and -35 boxes may be randomized without compromising promoter function (Busby and Ebright 1994
), and for NEP promoters, mutational analysis have shown that mutations outside the YAT motif decrease, but do not abolish transcriptional activity (Kapoor and Sugiura 1999
; Liere and Maliga 1999
). Collectively, promoter structures are almost invariant between the two plastid chromosomes. Concerning nuclear trans factors necessary for transcription of plastid genes, it has been shown that they can differ between higher order taxa, leading to a differential usage of one of several distinct promoters situated upstream of a single transcription unit (Sriraman, Silhavy, and Maliga, 1998
). According to these data, the apparatus of both species should be capable of properly initiating transcription in a given promoter region in organelle exchange situation, although initiation sites may differ.
Shine-Dalgarno Sequences and Other Translation-Mediating Elements
Sequence requirements for plastid translation are relatively poorly characterized (Zerges 2000)
. The plastid chromosome codes for only a limited number of ribosomal proteins and depends on nuclear factors for both mechanistic and regulatory aspects of translation. Only few of these regulatory nuclear factors are known from higher plants (Sugiura, Hirose, and Sugita 1998
; Fisk, Walker, and Barkan 1999
). Although the plastid translational machinery is of prokaryotic origin, quite a few plastid genes do not have any obvious Shine-Dalgarno (SD)-like sequence, and if they do, it is often shifted to a more upstream position, untypical for eubacterial translation systems (Sugiura, Hirose, and Sugita 1998
). In some instances, novel sequence elements not found in prokaryotes seem to replace or extend the function of SD sequences (e.g., Hirose and Sugiura 1996
). Comparison of all known sequence elements for tobacco plastid translation with the homologous sequences in Atropa revealed either complete (all SD-like sequences) or nearly complete (other translational enhancers) identity (data not shown). It therefore appears unlikely that they have played a significant role in generating genetic diversity of these two species.
Origins of Replication
Origins of plastome replication are known to be divergent between species examined so far (Kunnimalaiyaan and Nielsen 1997
). It has been proposed that differences in origins of replication between different species affect the specificity and efficiency of replication (Hornung et al. 1996
). In tobacco, two replication origins have been mapped using electron microscopy of replication intermediates and an in vitro replication approach (Kunnimalaiyaan and Nielsen 1997
; Kunnimalaiyaan, Shi, and Nielsen 1997
). One of them, designated OriA, is situated within the trnI-GAU intron. It consists minimally of 82 bp with a stem-loop structure and a direct repeat. Only one base is changed in Atropa relative to tobacco. The second element, termed OriB, was mapped to the ycf1 gene. It also comprises a large stem-loop structure and several direct repeats. In this case, 4 out of 243 bp differ between Atropa and tobacco. A third sequence element conferring autonomous replication to plasmids in yeast has been described in tobacco situated within the ndhF reading frame (Ohtani et al. 1984
). This element comprises approximately 350 bp, of which only five differ between Atropa and tobacco. Differences in replication efficiency have been invoked in Oenothera to play a role in the segregation rates of different plastid types combined in one cell (Hornung et al. 1996
). It is known that most, if not all, components of the replication machinery are coded in the nucleus. In the genus Oenothera, species differ substantially in the number of direct repeats and overall length of the region containing the replication origin (Sears, Stoike, and Chiu 1996
). Interestingly, tobacco and Atropa exhibit no substantial divergence in their predicted Ori structures. It therefore seems unlikely that differences in replication arising from alterations in the three origins identified so far in tobacco are responsible for the observed compartmental incompatibility in cybrids between Atropa and tobacco.
Introns and Editing Sites
Before translation, plastid messages can be subject to RNA splicing and RNA editing, two posttranscriptional processing events that vitally interfere with the message's coding content (Barkan and Goldschmidt-Clermont 2000
; Bock 2000
). Intron structures are highly conserved between Atropa and tobacco. The crucial determinants for intron splicing, that is, the splice donor and acceptor sites, are identical, with five exceptions. The clpP second intronthird exon boundary exhibits a 5-bp deletion in Atropa (fig. 3
). Furthermore, single base pair substitutions occur between Atropa and tobacco in the intron3'exon boundary region of trnL(UAA), trnV(UAC), rps16 and the second intron of ycf3 (fig. 3
). These differences impartially affect introns of different classes, suggesting that there is no biased evolution of a subgroup of introns in the two species. It remains a matter of speculation whether these differences might affect splicing of the respective genes in interspecific combinations of organelles, but it is for certain noteworthy that all four mentioned differences in group II introns affect domain VI. Domain VI is the most rigidly conserved part of the whole intron structure (Michel, Umesono, and Ozeki 1998
) and is central to the splice chemistry. Interactions of nuclear factors with domain VI may therefore contribute to compartmental incompatibilities.
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To determine whether Atropa is capable of processing the 28 shared sites, corresponding cDNA fragments were amplified by polymerase chain reaction (PCR) and sequenced directly. It turned out that Atropa harbors activities to edit all 28 sites, although with two quantitative differences to tobacco: both rpoB (site 2) and rps14 (site 1) are edited to a lesser extent in Atropa tissue in comparison with tobacco (fig. 4 ). In both cases, editing efficiency, which is 100% in tobacco, is greatly reduced in Atropa, with the signal from the unedited message, the C-peak, even predominating. Other editing sites are fully edited in Atropa, including, for instance, rpoB site 3 from the same message (fig. 4 ), indicating that contaminating DNA is not the cause of the observed C-signal. In addition, sites known to be only partially edited, like ndhD site 1 and rpoA, are processed to a similar extent in both species (fig. 4 and data not shown).
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What evolutionary or functional significance might be attributed to these findings? First, our data emphasize that RNA editing is a rapidly evolving trait, with editing sites changing quickly between taxa (Freyer, Kiefer-Meyer, and Kössel 1997
; Corneille, Lutz, and Maliga 2000
; Tsudzuki, Wakasugi, and Sugiura 2001
). Second, the reduced editing efficiency found for rps14 (site 1) and rpoB (site 2) might be interpreted as the first step on the way to losing an editing site because a marginally edited site ultimately poses the danger of incorporating the "wrong" amino acid into the respective protein. This should launch a counterselective pressure favoring C-to-T transitions already on DNA, thereby obliterating the need to edit the site at all and hence relieving the problem caused by partial editing. In this scenario, a decreased editing efficiency would be a dysfunctional chance event entailing the loss of a site, but it is of course also conceivable that both messages, the edited as well as the unedited, serve some purpose, maybe because both amino acids are beneficial in different ways for protein function (Hirose et al. 1999
; Karcher and Bock 2002
).
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Conclusions |
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It had previously been noted that intergenic sequence is a source for interspecific variance (Wolfe, Li, and Sharp 1987
; Gielly and Taberlet 1994
). It was therefore tempting to speculate that the regulatory elements responsible for plastid gene expression, which reside predominantly in intergenic regions, are rapidly evolving and play a key role in interspecific divergence. However, in the intrafamilial comparison of the two plastid chromosomes presented here, promoters, translational enhancers, and replication origins are well conserved, as are the coding regions. In contrast, RNA editotypes differ between the two species both qualitatively and quantitatively. RNA editing thus fulfils all requirements for a major trait in speciation because it is evolving rapidly and may have a substantial effect on plant fitness via protein function (Bock, Kössel, and Maliga 1994
; Zito et al. 1997
; Sasaki et al. 2001
). Differences in editotypes in this light have the quality of a yes or no decision with regard to protein function, quite in contrast to the accumulative effect of other differences described here. Because the nuclear-encoded editing machinery is known to be species- and site-specific (Chaudhuri, Carrer, and Maliga 1995
; Bock and Koop 1997
; Schmitz-Linneweber et al. 2001b
), it is imperative for a plant to express the correct set of editing factors. It has to be expected that whenever an editotype from one species is joined with an inadequate set of nuclear factors of a second one, as in interspecific hybrids and cybrids, editing failures and thus fatal defects will ensue. However, this does not explain the marked differences in Atropa-tobacco and tobacco-Atropa cybrid phenotypes. As our data show, the nuclei of both cybrids, the tobacco as well as the Atropa, face the challenge of editing sites not present in their genuine plastome. But only recently we could show that the allotetraploid nucleus of tobacco harbors more editing factors than needed for the endogenous sites and is therefore capable of heterologous editing. Interestingly, this has been shown for a spinach site, which is homologous to the Atropa-specific ndhA site described here and which is edited efficiently in the tobacco nuclear background (Schmitz-Linneweber et al. 2001b
). Hence, it is expected that the tobacco nucleus is also capable of editing at least this Atropa-specific site.
Conclusively, we propose that plastid chromosomal divergence affects speciation in two aspects. First, a broad variety of differences in polypeptides or intron structure generates gradual deviation between populations. Second, RNA editing as a trait with decisive impact on plant fitness might influence speciation in a more saltatorial manner. Work on interspecific hybrids and cybrids should help us to understand which of these components of divergence is most influential in producing new species.
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Acknowledgements |
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Footnotes |
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Keywords: sequence analysis
plastid chromosome
Atropa belladonna
nucleus-plastid incompatibility
speciation
Address for correspondence and reprints: Botanisches Institut der Ludwig-Maximilians-Universität München, Menzinger Str. 67, 80638 München, Germany. E-mail: raimaier{at}botanik.biologie.uni-muenchen.de
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