RECG Maintains Plastid and Mitochondrial Genome Stability by Suppressing Extensive Recombination between Short Dispersed Repeats
Recombinational DNA repair plays an important role in the maintenance of genomic stability by repairing DNA double-strand breaks and stalled replication forks. However, recombination between nonallelic similar sequences such as dispersed repeated sequences results in genomic instability. Plant plastid and mitochondrial genomes are compact (generally approximately 100–500 kb in size), but they contain essential genes. A substantial number of repeats are dispersed in these genomes, particularly in the mitochondrial genome. In this study, we showed that a knockout mutation of the newly identified plant-specific homolog of bacterial RecG DNA helicase RECG caused some defects in plastids and significant defects in the mitochondria. The organelle genomes in these mutants were destabilized by induced aberrant recombination between short (<100 bp) dispersed repeats. Recombination was induced at repeats as short as 8 bp. This suggests that RECG maintains plastid and mitochondrial genome stability by suppressing aberrant recombination between short dispersed repeats. Because such a phenomenon, to our knowledge, has not been observed in bacterial recG mutants, our results suggest an organelle-specific genome maintenance system distinct from that of bacteria.
Published in the journal:
RECG Maintains Plastid and Mitochondrial Genome Stability by Suppressing Extensive Recombination between Short Dispersed Repeats. PLoS Genet 11(3): e32767. doi:10.1371/journal.pgen.1005080
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1005080
Summary
Recombinational DNA repair plays an important role in the maintenance of genomic stability by repairing DNA double-strand breaks and stalled replication forks. However, recombination between nonallelic similar sequences such as dispersed repeated sequences results in genomic instability. Plant plastid and mitochondrial genomes are compact (generally approximately 100–500 kb in size), but they contain essential genes. A substantial number of repeats are dispersed in these genomes, particularly in the mitochondrial genome. In this study, we showed that a knockout mutation of the newly identified plant-specific homolog of bacterial RecG DNA helicase RECG caused some defects in plastids and significant defects in the mitochondria. The organelle genomes in these mutants were destabilized by induced aberrant recombination between short (<100 bp) dispersed repeats. Recombination was induced at repeats as short as 8 bp. This suggests that RECG maintains plastid and mitochondrial genome stability by suppressing aberrant recombination between short dispersed repeats. Because such a phenomenon, to our knowledge, has not been observed in bacterial recG mutants, our results suggest an organelle-specific genome maintenance system distinct from that of bacteria.
Introduction
Plants have two organelles, plastid and mitochondrion, that possess their own genomic DNA. The organelle genomes have become compact due to the endosymbiotic transfer of ancestral bacterial genes into the nucleus throughout evolution [1]. However, their genomes still encode components essential for photosynthesis, respiration and gene expression in organelles [2]. Since electron transport in photosynthesis and respiration produce reactive oxygen species (ROS), a harmful factor that damages DNA, plant organelle DNA is exposed to more severe conditions than nuclear DNA. Ultraviolet (UV) radiation from sunlight can also damage organelle DNA. However, the mechanism of how plant organelle DNA stability is maintained remains largely unknown.
Nuclear genes involved in mtDNA stability have been identified through the analyses of mutants displaying variegated leaves or by mutating genes that were predicted to be involved in organelle DNA metabolism [3]. The bryophyte P. patens has two functional bacterial-type RecA homologs, RECA1 and RECA2, which localize to mitochondria and plastids, respectively [4,5]. A RECA1 KO strain exhibits defects in growth and mitochondrial morphology, and results in lower rate of the recovery of damaged mtDNA [4,6]. Moreover, the RECA1 KO mutant displays gross rearrangements due to aberrant recombination between short repeats ranging from 62 to 84 bp scattered throughout mtDNA, which suggests that RECA1 maintains mtDNA stability by suppressing gross rearrangements [6].
In the angiosperm Arabidopsis thaliana, a mutation in the MutS homolog 1 (MSH1) causes mtDNA instability due to aberrant recombination between short dispersed repeats ranging in size from 108 to 556 bp [7–10]. Similarly, mutations in plant-specific single strand DNA-binding proteins, WHY2 from the whirly family of proteins [11] and organellar single-stranded DNA binding protein 1 (OSB1; [12]), lead to aberrant recombination between repeats. In the OSB1 mutant, repeats ranging in size from 249 to 556 bp are involved in the recombination [12], while in the WHY2 mutant, the recombination occurs between short repeats (<30 bp) and is gyrase inhibitor-dependent [11]. Mutations in RECA3, a RecA homolog, also cause mtDNA instability due to aberrant recombination between a few pairs of repeats (∼200 bp) [13].
A few genes are reported to be involved in the maintenance of plastid DNA (ptDNA) stability. Double mutations in WHY1 and WHY3, whirly family genes in A. thaliana, induce recombination between 10–18 bp ptDNA repeats. Thus, WHY1 and WHY3 protect ptDNA against illegitimate recombination [14]. A recent report showed that a mutation in A. thaliana MSH1 also induced rearrangements of plastid loci containing short repeats [15].
Bacterial RecG protein is a double-stranded DNA helicase that unwinds a variety of branched DNAs modeled after Holliday junctions and replication forks [16,17]. Analyses of a recG mutant suggest that RecG plays a role in homologous recombination and replication fork repair in vivo, similar to the proposed role of RecA [18]. In vitro studies also suggest the role of RecG in the repair of stalled replication forks [17,19,20] Recent reports suggest that RecG has an important function in the control of chromosomal replication and segregation in E. coli [21–23]. In this report, we analyzed a nuclear-encoded homolog of bacterial DNA helicase RecG, named RECG, which localized to both plastid and mitochondrial nucleoids in P. patens. We found that both organelle genomes of the RECG KO mutant were destabilized due to recombination between repeated sequences within a broad range in size (8–79 bp) and that the induced mtDNA recombination in RECG and RECA1 KO mutants partly differed. Here, we propose a vital role for RECG in the maintenance of plastid and mitochondrial genome stability.
Results
P. patens RECG protein localizes to both plastid and mitochondrial nucleoids
We identified a homolog of E. coli RecG in the P. patens nuclear genomic sequence [24] and named it RECG. Homologs of RecG are found in other plants, but not in fungi or animals, like bacterial-type RecA homologs [25]. Based on its cDNA sequence which we determined by rapid amplification of cDNA ends (RACE), the RECG protein is predicted to be 1152 amino acids in length and shares a high degree of sequence similarity with E. coli RecG, except for its extended N-terminal region (S1A Fig.). The extended N-terminal region, which is assumed to be a signal peptide that targets the protein to organelles, is potentially sufficient for localization to both plastid and mitochondrion (S1B Fig.) as judged by TargetP [26]. A similar N-terminal extension also exists in an annotated version of the RecG homolog in A. thaliana with a potential for localizing to both plastid and mitochondria (S1B Fig.). Fluorescent microscopy of protoplast cells expressing green fluorescent protein (GFP) gene fused to downstream of the 5’UTR and the N-terminus of RECG cDNA showed that the RECG-GFP localized to both plastids and mitochondria (Fig. 1A). Similar analysis with GFP gene fused to full-length RECG coding sequence demonstrated GFP fluorescence foci in both plastids and extra-plastid cytoplasmic space (Fig. 1B). 4′,6-diamidino-2-phenylindole (DAPI) staining of the cell showed that the GFP foci sometimes corresponded to some plastid and mitochondrial nucleoids (Fig. 1C and D), suggesting that RECG protein associates with these nucleoids.
RECG partially complements the defects of E. coli recG cells
To characterize the function of RECG, we examined whether RECG could complement the defects of an E. coli recG-deficient strain. E. coli recG-deficient strains harboring P. patens RECG lacking the signal peptide, intact E. coli recG, or no recG were subjected to UV irradiation after the induction of these genes. As reported by Ishioka et al. [27], the recG-deficient strain exhibited greater sensitivity to UV than the strain harboring the recG gene (Fig. 2), which implies that E. coli RecG participates in the recovery from UV damage. Expression of P. patens RECG conferred more than 10-fold greater resistance to UV in the recG-deficient cells, although not to the same degree as E. coli recG (Fig. 2). Therefore, RECG can partially complement the defects of E. coli recG-deficient cells.
Knock-out of the RECG gene causes growth and developmental defects
Efficient targeting of nuclear genes [28] and a sequenced nuclear genome [24] enable easy knock-out of nuclear genes in P. patens. Thus, we knocked out the RECG gene to analyze the in vivo role of RECG (S2 Fig.). To investigate the effect of RECG KO on the growth and development of P. patens, we compared the RECG KO lines (named recG-1 and recG-2) with wild type (WT). After inoculation on agar medium, we observed that P. patens initially formed colonies composed of filamentous protonemal cells, and gametophores subsequently developed in the colonies. The RECG KO colonies appeared small and had less developed gametophores, which indicates defects in growth and development, although the extent of the defects were milder than those of the RECA1 KO strain (Fig. 3A). The RECG KO colonies consisted of protonemal cells with heterogeneity in growth; relatively normal (recG-N) and atrophic (recG-A) protonemal cells. The recG-A protonemal cells were shorter and darker than the recG-N protonemal cells, while the recG-A cells are still shorter and darker than the WT (S3A Fig.). The atrophic protonemal cells of the RECG KO colonies were shorter than those of WT and were dense with plastids, likely due to a reduction in cell volume. Notably, the morphological abnormalities of the RECG KO and RECA1 KO colonies were similar (Fig. 3B). These morphological effects imply that RECG plays an important role in the growth and development of P. patens, and suggest that RECG and RECA1 share similar roles.
Abnormal mitochondria and plastids in RECG KO cells
To analyze the effect of the RECG KO on the ultrastructure of subcellular components, especially on those of mitochondria and plastids, we observed RECG KO cells by transmission electron microscopy (TEM). Since the RECG KO plant appeared to be composed of recG-N and recG-A protonemal cells, these two cell types were analyzed separately. TEM analyses revealed that the RECG KO had various effects on the ultrastructure of mitochondria, plastids, and other cell components. Both recG-N and recG-A mitochondria had a lower number of cristae and cristae enlargement (Fig. 4D-F), and recG-A cell mitochondria showed weaker matrix staining, indicating a lower electron density of the mitochondrial matrix (Fig. 4F). Some RECG KO mitochondria were abnormally extended (Fig. 4B, C and G), and their sizes were sometimes comparable to those of plastids (S3B Fig.). The extended mitochondria were more frequently observed in recG-N cells than in recG-A cells. It is notable that these mitochondrial abnormalities, including a lower number of cristae, cristae disorganization, weaker matrix staining, and stretching, are also observed in RECA1 KO mitochondria [6]. We further analyzed the stretching by performing TEM on serial thin sections to elucidate the three-dimensional structure of the extended mitochondria, and found that one of these mitochondria penetrated 16 serial thin sections (S3C Fig.) and that the edge of each mitochondrion was swollen (S3D Fig.). This result suggested that the extended mitochondria were actually disc-shaped with thick edges.
The RECG KO affected plastids. Although plastids in recG-N cells looked mostly normal (Fig. 4I), abnormally extended plastids were occasionally detected. Some of these plastids appeared to have a disturbance in cell division septum formation (S3E Fig.). Plastids in recG-A cell had abnormal shapes, and their membranes, including thylakoid, outer and inner membranes, appeared frail (Fig. 4J). Moreover, most plastids in recG-A cells abundantly accumulated starch and had an underdeveloped thylakoid membrane (Fig. 4C and J). The RECG KO also affected cell structure and cell components, especially in recG-A cells. Some recG-A protonemal cells accumulated oil (S3F Fig.), which is in contrast to wild type protonemal cells, which have few or no oil bodies [29]. These observations indicate that RECG KO had various effects on cell ultrastructure that were likely caused by functional defects in mitochondria and plastids.
Mitochondrial DNA rearrangements in RECG KO plants
In RECA1 KO mitochondria, aberrant recombination occurs frequently between repeats ranging in size from 62 to 84 bp and results in gross DNA rearrangements, which appear to be responsible for the phenotypic defects observed in RECA1 KO plants [6]. Therefore, the similar phenotype of RECG and RECA1 KO plants, as described above, predicts that RECG KO mtDNA also undergoes gross DNA rearrangements. To test this hypothesis, we carried out structural analyses of RECG KO mtDNA and compared the results with those of RECA1 KO mtDNA.
A product resulting from recombination between 69 bp direct repeats existing in nad2 and atp9 loci of mtDNA, which appears as a 1.8 kb EcoRI fragment on DNA gel blots [6], was confirmed in a blot hybridized with nad2 probe in RECA1 KO lines (Fig. 5A). The blot showed that the 1.8 kb EcoRI fragment of the nad2-atp9 recombination product was hardly detectable in the RECG KO lines, while a weak 1.9 kb band was detected in both RECG KO lines (Fig. 5A). Since the RECG KO-specific 1.9 kb DNA fragment strongly hybridized to both an atp9 probe, which does not hybridize to the nad2-atp9 recombination product, and a ccmF probe (Fig. 5A), this fragment is likely to be the result of recombination between the atp9 locus and ccmF locus. Forty-seven base pair repeats at both loci are suspected to be involved in recombination (Fig. 5B and S4D Fig.), and the size of the recombination product is consistent with the size of the observed 1.9 kb ccmF-atp9 product. Because the ccmF-atp9 recombination product includes the 69 bp nad2-atp9 repeats (Fig. 5B), it hybridized weakly to the nad2 probe (Fig. 5A). The ccmF-atp9 product also appeared in the RECG KO lines with the sizes of the DNA products resulting from recombination between the 47 bp repeats when the mtDNAs were digested with HindIII or NdeI (S4A–C Fig.). PCR amplification of the ccmF-atp9 product from RECG KO plants and direct sequencing analysis of the amplified fragments showed that almost all of the recombination junctions were within the 47 bp repeats, yet the sequence similarity extended to the region flanking the repeat (S4D Fig.). These results indicate that the ccmF-atp9 recombination product, but not the nad2-atp9 recombination product, accumulates in the RECG KO lines.
Next, we analyzed whether other hotspots identified in RECA1 KO mtDNA rearrangements [6] also induced recombination in the RECG KO plants. DNA gel blot analysis showed that recombination occurred between the 79 bp nad7-nad9 direct repeats in the RECG KO lines as well as the RECA1 KO lines (Fig. 5C). In the RECG KO lines, we also identified signals corresponding to 11 kb of deleted circular mtDNA (Fig. 5D), which is produced by recombination between the nad7-nad9 repeats, as reported in RECA1 KO plants [6]. In addition, we carried out quantitative PCR (qPCR) analyses to assess the copy number of DNA resulting from recombination between 62 bp inverted repeats (mtIR), another hot spot located in the intergenic region of mtDNA [6]. The results showed that the recombination at this locus was induced in the RECG KO lines and that the recombination level of one line was comparable to that of the RECA1 KO line (Fig. 5E). These results suggest that frequent mtDNA rearrangements, which associated with deletion in some cases, occur at multiple hot spots in RECG KO plants, and that some hot spots differ from those of the RECA1 KO plants.
Since the recombination described above can cause deletion of mtDNA, it is possible that the copy number of RECG and RECA1 KO mtDNA loci altered. To test this, we measured the copy number of three mitochondrial loci, rps4, nad6 and rpl2, by qPCR. The results showed that the copy number of each mtDNA locus varied in the RECA1 KO lines whereas increased in the RECG KO lines (S4E Fig.).
Repeat-mediated genomic instability in RECG and RECA1 KO mitochondria
To analyze the effect of RECG or RECA1 KO on global structure of mtDNA, we performed a comprehensive analysis of DNA molecules resulting from recombination between repeats dispersed in the mtDNA. We first analyzed mtDNA repeat-mediated rearrangements in both KO mutants by DNA gel blot, and identified two DNA fragments that were most likely to be derived from recombination between nad4-nad1 direct repeats, named R4 (90 bp) or R6 (56 bp) [6], as judged by their sizes (Fig. 6A). Note that the DNA fragments were detected only in RECA1 KO lines, but not in RECG KO line as well as WT. We next carried out quantification of DNA resulting from recombination between other direct repeats (46–57 bp, R5, R11, R12, R13, R18, and R19) by qPCR. The results showed that recombined DNA from every tested repeats were apparently accumulated in both RECG and RECA1 KO lines; the level of accumulation was very high in the RECA1 KO lines regarding R5 and R13, and high in RECA1 KO lines regarding R11 and R18 (Fig. 6C). Collectively, these results suggest that the repeat-mediated recombination were induced in both RECG and RECA1 KO mitochondria at multiple loci, but the degree and the site of the recombination were somewhat different between them.
To understand further the effect of RECG and RECA1 KO on mtDNA stability, we examined whether shorter repeats were involved in the mtDNA instability. REPuter, a program that detects repeated sequences in DNA sequence [30], identified approximately 900 pairs of repeats (15–35 bp) in P. patens mtDNA [4]. Among the repeats, we analyzed selected repeats (S1 Table) by PCR with respect to the accumulation of recombination products, and the levels of DNA amplification at each repeat are shown in Fig. 6D. A greater level of amplification was observed in both KO lines than in the WT strain. Sequencing of the amplified DNA confirmed that they were the products of recombination between the 21, 18, 15 or 13 bp inverted or direct repeats (S1 Table and S8 Fig.). Moreover, the analysis further showed that an additional region of DNA, which was the product resulting from recombination between 8 bp repeats that are distantly positioned around the 21 bp repeats, was amplified in the RECG KO lines (Fig. 6D, panel 1). Therefore, DNA accumulates as a result of recombination between repeats ranging from 8 to 21 bp in the RECG KO, and from 13 to 21 bp in the RECA1 KO mitochondria.
Decrease in the levels of specific mitochondrial gene transcripts in RECG KO plants
The data presented here showed efficient rearrangements of RECG KO mtDNA at nad7, nad9, atp9, and ccmF loci caused by recombination between short repeats. Quantitative analysis using DNA gel blots revealed that the copy number of normal mtDNA bands (e.g., 1.5 kb of nad7 band and 1.7 kb nad9 band in S5A and B Fig.) in the RECG KO plants decreased to approximately 30%–45% and 35%–50% of WT at nad7 and nad9 loci, respectively. The copy number of normal mtDNA bands at atp9 and ccmF loci did not significantly change (S5C and D Fig.). To investigate the effect of the mtDNA rearrangements on mitochondrial transcripts, we analyzed the transcripts of these loci in the RECG KO plants. Quantitative RT-PCR (qRT-PCR) analysis demonstrated a significant reduction in the levels of transcripts from nad7 and nad9 for some of the primer pairs in the RECG KO mutants (Fig. 7A and B). We found a significant reduction (<10% of WT levels) in the levels of the transcript fragments when the primers were arranged to amplify a segment including a junction of exon 2 and 3 for nad7 or exon 1 and 2 for nad9 (Fig. 7A and B). Because the introns contain repeats involved in the mtDNA rearrangements (Fig. 7A and B), these results suggest that a substantial number of the nad7 and nad9 transcripts exist as chimeric transcripts of nad7 and nad9 and not as individual intact forms. RT-PCR analysis demonstrated the efficient amplification of nad7-nad9 chimeric transcripts from RECG KO mutants (Fig. 7C). We confirmed that the chimeric transcripts were precisely spliced between nad7 exon2 and nad9 exon2 (S5E Fig.). In contrast, similar qRT-PCR analysis demonstrated no significant differences in the levels of transcripts from ccmF and atp9 loci between the WT and RECG KO mutants (S5F Fig.). These results suggest that the efficient rearrangements of some mtDNA loci were associated with a decrease in the normal levels of mtDNA and a significant decrease in the number of the corresponding intact transcripts.
Repeat-mediated genomic instability in RECG KO plastids
The fact that RECG protein not only localizes to mitochondria, but also to plastids, raises the possibility that RECG plays a role in both plastids and mitochondria. We then analyzed the structure of RECG KO ptDNA, and focused on recombination between repeated sequences. We searched for repeats using REPuter and identified 16 pairs of repeats longer than 40 bp in the P. patens ptDNA sequence [31], most of which were located immediately downstream of genes as palindromic sequences (S2 Table), probably functioning in the stabilization of transcripts [32]. Among the repeats, we analyzed the level of recombination between inverted repeats-1 (ptIR-1, 63 bp long, shown as R6 in S2 Table), which are located in rpl16 and trnG, or direct repeats-1 (ptDR-1, 48 bp long, shown as R12 in S2 Table), which are located in psaA and psaB (S6A Fig.). DNA gel blot analysis using a plastid rpl16 probe showed accumulation of 4.3 kb DNA fragments in the RECG KO mutants (Fig. 8A). The size of these DNA fragments corresponds to that of a predicted product resulting from recombination between ptIR-1 (Fig. 8B). We next analyzed the IR-1 recombination product using qPCR (S6 Fig.). The analyses revealed that the product formed by recombination between ptIR-1 showed ∼160-fold increase in the RECG KO mutants (Fig. 8C). Similar qPCR analysis of a product formed by recombination between ptDR-1 showed a 6–16-fold increase in the RECG KO mutants compared with WT (Fig. 8C). These results showed increased accumulation of ptIR-1 and ptDR-1 recombination products in the RECG KO lines. To assess the effect of RECG KO on copy number of ptDNA, qPCR analysis of ptDNA loci was performed. The copy number of three plastidic loci rbcL, atpA and ndhH showed increases in the RECG KO lines compared with WT (S6B Fig.). As the RECG KO mutants showed increase of ptDNA in every tested locus, it is possible that plastid number was increased in the RECG KO mutants. However, no significant difference was observed in the number of plastids per cell between WT and RECG KO mutants (S6C Fig.).
In the analyses described above, we applied PCR amplification for detection of DNA recombined between repeated sequences in the RECG or RECA1 KO lines. However, since such a recombined DNA can be created during PCR reaction, named PCR jumping, as reported by Alverson et al. [33], we quantified the amount of the artificially recombined DNA in our qPCR assay to evaluate the effect of PCR jumping. We first prepared two DNA fragments that contain copy1 or copy2 of ptIR-1, and then the two fragments were mixed so as to contain the amount of each IR-1 copy equivalent to that of the WT total genomic DNA (S6D Fig.). Next we quantified copy number of DNA recombined between the copy1 and copy2 of ptIR-1 using WT genomic DNA or the mixed DNA as templates. The amount of DNA recombined between IR-1 from the mixed DNA by PCR jumping was ∼1.5% of that from WT genomic DNA (S6D Fig.), indicating that recombination between IR-1 copies occurred during the qPCR reaction, but the efficiency was very low. Accordingly, these results suggest that the amplified recombined DNA that we observed was mostly derived from in vivo recombination of organelle DNA, and that the contribution of in vitro recombination, if it occurred, was very small.
We extended the analyses to shorter repeats (15–35 bp), which are abundant (approximately 2000 pairs) in ptDNA. We carried out PCR analyses to estimate the amount of DNA that recombined between short repeats. Reliable DNA amplification occurred only in the RECG KO lines (Fig. 8D), and sequencing of the amplified DNAs demonstrated that they were the result of recombination between the 34, 28, 19 or 17 bp repeats (S3 Table and S8 Fig.). Moreover, some types of additional DNA, which were determined to be products of recombination between 13 bp or 15 bp repeats (S3 Table), were amplified only in the RECG KO lines (Fig. 8D). Collectively, these results suggest that genomic instability was induced in the RECG KO plastids by aberrant recombination among repeated sequences, ranging in size from 13 to 63 bp.
Increased accumulation of recombined mtDNA in recG-A cells
To investigate the relationship between the heterogeneity of atrophic phenotype of RECG KO plants appearing as recG-A and recG-N cells (S3A Fig.) and the stability of plastid and mitochondrial genomes, we compared the status of organelle DNA in recG-A and recG-N cells. We separately extracted total genomic DNA from protonemal cells mainly composed of recG-A cells or recG-N cells and measured the amount of mtDNA and ptDNA resulting from recombination between short repeats, using qPCR as described above (Fig. 6C and 8C). qPCR analyses of mtDNA showed that the number of the DNA molecules resulting from recombination between most of the tested repeats was higher in recG-A cells than that in recG-N cells. The levels of these recombination products in recG-N cells were still higher than those in WT cells (Fig. 9A). The levels of recombination product from ccmF-atp9 repeats (originally identified as repeats involved in the mtDNA instability, Fig. 5A) and R12 significantly increased in recG-A cells (Fig. 9A). However, the qPCR analysis of ptDNA showed no significant difference between the amounts of ptIR-1 or ptDR-1 recombination products in recG-A and recG-N cells (Fig. 9B).
Discussion
In this report, we showed that knocking out a plant-specific RecG homolog RECG induced genomic instability due to repeat-mediated recombination in both mitochondrial genome and plastid genome of P. patens. The induction of organelle genome recombination by RECG KO implies that organelle genomes can potentially undergo repeat-mediated recombination under normal culture conditions. Indeed, plant mitochondrial genomes are occasionally rearranged by recombination between short (<1 kb, in most cases <200 bp) repeats [34], and double-strand breaks in the plastid genome are repaired efficiently by utilizing recombination between short (<100 bp) repeats [35,36], both of which could contribute to potential genome rearrangements in plant organelles. Repeat-mediated recombination similar to those described in this paper were not observed in the bacterial recG mutants as far as we know. We propose that an important role of RECG is to maintain organelle genome stability by suppressing recombination among dispersed repeats.
Analysis of RECG-GFP subcellular localization revealed that the product(s) from the RECG gene localized to both plastids and mitochondria (Fig. 1). Examples of product(s) from a single gene being targeted to both plastid and mitochondrion, named dual targeting, have been reported and classified into two types [37]: an ambiguous signal peptide that can be recognized by both plastid and mitochondrion, or multiple N-terminal signal peptides for different organelles that are produced by alternative translation initiation and/or alternative splicing. Either type may account for the dual targeting of RECG, since RECG has two in-frame AUG codons in its 5’part that could localize their products to both organelles (S1B Fig.). Since A. thaliana RecG homolog also has the potential to localize to both organelles, as determined by our in silico analysis, dual targeting of RecG homolog may be conserved in both P. patens and A. thaliana.
Full-length RECG-GFP formed foci in plastids and mitochondria, and the foci sometimes corresponded to organelle nucleoids. This suggests that RECG is not a constitutive nucleoid protein but associates with organelle nucleoids with a bias. The nucleoid-associating RECG-GFP may be the functional RECG interacting with organelle DNA to maintain genomic stability.
Intriguingly, the RECG KO plants exhibited similar defects in growth, cell morphology, and mitochondrial morphology/activity to those of RECA1 KO plants (Figs. 3 and 4). Mitochondrial defects including disorganized cristae, a lower electron density of the matrix, and an enlarged disc-shape, were also characteristic phenotypes of RECA1 KO plants. The lower electron density of the matrix suggests lower mitochondrial activity, and was frequently observed in recG-A cells, suggesting that mitochondrial dysfunction was the cause of the atrophic phenotype. On the other hand, disorganized cristae and the enlarged disc-shaped mitochondria were commonly observed in recG-A and recG-N cells. As some of the disc-shaped mitochondria exhibited a normal matrix electron density (Fig. 4 and S3 Fig.), mitochondrial dysfunction was probably not responsible for the disc-shape. Disc-shaped mitochondria have been reported to occur in tobacco cells in response to low oxygen pressure without loss of membrane potential [38]. Thus, the disc-shaped mitochondria we observed may reflect the dynamics of mitochondrial morphology rather than mitochondrial dysfunction. The mitochondria of RECG and RECA1 KO plants might change their shape to regulate their activity.
Our results revealed extensive mtDNA rearrangements due to recombination between short repeats in RECG KO plants (Figs. 5 and 6). Rearranged mtDNA produced by recombination between relatively long repeats (47–79 bp, most of which exist in introns as direct repeats) accumulated to a high level as detected by DNA gel blot. We found that in such mtDNA rearrangements, for some loci, there was a decrease in normal mtDNA and a significant decrease in intact transcript levels. The decrease in the production of intact transcripts (<10% of WT) was more extensive than the decrease in the levels of normal mtDNA (30%–50% of WT). On the other hand, a substantial amount of chimeric transcript derived from the rearranged mtDNA accumulated in the RECG KO mutants. Although the chimeric transcripts were properly spliced, the translation product from the chimeric transcripts had to be largely truncated due to the accidental appearance of stop codon; therefore, it should be defective or dominantly negative to the normal translation products. We also found that aberrant recombination between shorter repeats (<35 bp), which is abundantly scattered in the mitochondrial genome, was induced in both the RECG KO and RECA1 KO mtDNA. This type of recombination occurred at a low frequency, but could produce defective mtDNA with deletion of various loci. Collectively, the RECG KO mitochondria are thought to be in a pathological state that includes many kinds of defective mtDNA. These could cause mitochondrial defects via heteroplasmic effect if the normal mtDNA falls below a certain threshold level that is required for normal mitochondria function, as has been conceptually suggested in maize [39]. We found that some kinds of recombined defective mtDNA were highly accumulated in the recG-A cells than in recG-N cells (Fig. 9), proposing a relationship between the accumulation of the mutated mtDNA and atrophic phenotypes. The cytoplasmic segregation of heteroplasmic RECG KO cells with defective mtDNA may have resulted in the biased sorting of the defective mtDNA; when the population of the defective mtDNA exceeds the threshold for the normal mitochondrial function, the cell might exhibit atrophic phenotypes such as those displayed by recG-A cells.
A knock-out of the RECG gene caused genomic instability due to aberrant recombination among 13–63 bp dispersed repeats in the plastids (Fig. 8) as well as in the mitochondria. Since relatively long repeats ptIR-1 (63 bp) and ptDR-1 (48 bp) exist in the structural genes rpl16 and trnG, and psaA and psaB, respectively, recombination between the repeats causes truncation or chimerization in these genes (S6A Fig.). In addition, recombination between abundant dispersed short repeats (< 35 bp) causes deletions or inversions in various ptDNA loci. Thus, RECG KO plants heteroplasmically contain a substantial proportion of defective ptDNA. On the other hand, most of the plastidic longer repeats (> 40 bp), in which RECG KO is assumed to induce recombination more frequently than in shorter repeats, are characteristically located downstream of genes as palindromes (S2 Table), and thus recombinations between them do not disrupt genes directly nor produce defective ptDNA. This property of the plastidic long repeats might alleviate the effect of RECG KO on plastid function. The RECG KO cells, in particular recG-A cells, nevertheless exhibited defects in plastid structure (Fig. 4). Since the amount of the recombined ptDNA was not significantly different between the recG-A cells and recG-N cells, other ptDNA defect might account for the plastid defects as well as the atrophic phenotypes. Alternatively, the accumulation of starch and oil in the recG-A plastids might reflect reduced respiration activity due to mitochondrial dysfunction.
A. thaliana whirly mutant organelle DNA and A. thaliana MSH1 mutant ptDNA exhibit instability due to recombination between repeats shorter than ∼20 bp [11,14,15], and repeats with similar length are involved in the RECG KO organelle DNA instability. This suggests a possibility that RECG, whirly proteins and MSH1 suppress rearrangements in a similar way, however, whirly homologs do not seem to exist in the P. patens genome [24]. On the other hand, the length of the repeats (8–79 bp) involved in recombination of the mtDNA observed in RECG KO mutants differ from those of the A. thaliana MSH1, OSB1 and RECA3 mutants, in which repeats longer than 100 bp are involved [10,12,13]. As P. patens mtDNA has no repeats longer than 100 bp [6], it is impossible to analyze the effect of RECG KO mutants on recombination between repeats longer than 100 bp. Analysis of RECG and these genes in A. thaliana will be needed to elucidate the relationship between RECG and these genes.
Some repeated sequences were involved specifically in either RECG KO or RECA1 KO mutant mtDNA rearrangements, while others were involved in both (Fig. 5 and 6). This suggests that RECG and RECA1 suppress recombination in overlapping but also partially distinct ways in mitochondria. We previously proposed a model in which RECA1 prevents aberrant recombination during the process of repairing stalled or collapsed replication forks [6], based on the suggested role of E. coli RecA [40,41]. Similar to RecA, RecG is thought to function in the processing of stalled replication forks by reversing it in E. coli [17], which raises the possibility that P. patens RECG may also be involved in the repair of replication forks stalled by lesions on the template DNA. The lesions might be created by ROS or UV since they can cause replication fork stalling [42,43]. RECG may reverse stalled replication forks perhaps to prevent subsequent fork collapse and DNA double-strand breaks that can induce genomic instability such as aberrant recombination. Furthermore, RECG might also suppress aberrant recombination by stabilizing recombination intermediate between highly homologous sequences, as demonstrated in E. coli [44]. Differences between the mtDNA rearrangement caused by RECG KO and RECA1 KO might reflect differences in their roles in the repair of impaired replication forks, as studies in E. coli suggest that RecA and RecG function in replication fork repair in distinct situations [18,45]. On the other hand, similarities in organelle DNA defects of RECG, RECA1, MSH1, whirly, and OSB1 mutants might suggest that all of these genes are involved in the integrity of replication forks.
In conclusion, our results suggest that RECG suppresses the recombination between the scattered repeats in organelle genomes and that the pathway partly overlaps that of RECA1 in the mitochondria. A future genetic analysis of double KO mutants of these genes and comprehensive analysis of the mtDNA mutations induced in the single and double KO mutants may elucidate the exact relationship between RECA1 and RECG in the maintenance of mitochondrial genome stability. Our results for the RECG KO mutants indicate that the mechanisms of the suppression of aberrant recombination are probably common to plastids and mitochondria. Another RECA has been found in plastids of P. patens [5] and other plant species [25]. The investigation of the functional relationships between RECA and RECG may shed new light on the molecular mechanisms of plastid genome stability.
Materials and Methods
Plant materials, growth conditions, and preparation of nucleic acids
Physcomitrella patens Bruch & Schimp subsp. patens was used in this study. Protonemata of P. patens were cultured on BCDATG or BCDAT agar medium [46] at 25°C in white light. Growth rate comparisons were performed as described in Odahara et al. [6]. Genomic DNA was extracted by the CTAB method [47] from protonemata cultivated for four days after homogenization and inoculation on agar medium. Total RNA was extracted from protonemata using the RNeasy Plant Mini Kit (Qiagen).
Sequence determination of RECG cDNA
RACE was performed according to Hiwatashi et al. [48] using total RNA. RECG sequence data can be found in the GenBank/EMBL database under accession number AB646798.
Fluorescent microscopy
RECG cDNA corresponding to the full-length 5’UTR and the 284-amino acids of the N-terminal region was amplified by PCR using primers TCCGGATCCTTGCTACACCCTTCTTTCTGCTCCG and CGACCATGGTGCCATCCACAGTGGATTTGTACAGC and fused in frame to the GFP gene of p7133-sGFP [49], and the fused gene was expressed under control of E7133 promoter [50]. Similarly, full-length RECG coding sequence amplified by primers ACTACATCTAGAGGATCCCCGCGATGGCAATTAGAGGTTGTAG and AAGCTTTCCCATGGCCACCCAGTTTTGTTTATCTAGAGCCTCCAG was fused in frame to N-termini of GFP gene and expressed under control of the E7133 promoter. The resulting plasmid was introduced into P. patens protoplasts, and the protoplasts stained with 125 nM Mito Tracker Orange (Molecular Probes) or 1 μg/ml DAPI were observed with an epifluorescence microscope (AX80, Olympus; Axio Imager 2, Zeiss).
Complementation assay in E. coli cells
The RECG cDNA, except for a part corresponding to the N-terminal putative signal peptide (374 amino acids), was amplified by PCR using primers CCTCCATGGGAGCTGCTAACTACAAAGATTGTG and CCTCCCGGGCAACATTATCCTAAAGAACCCGGTG, and E. coli recG was amplified by primers CCCGAATTCACCATGAAAGGTCGGCTGTTAG and CCCCTGCAGTTACGCATTCGAGTAACGTTCCG. Both were placed under the inducible arabinose promoter of pBAD24 [51], and each of the resulting plasmids or pBAD24 was introduced into the E. coli recG deficient strain HRS2000 [27]. After cultivating the strains to an optical density at 600 nm of 0.5 in L broth medium [52] containing 0.5% arabinose, the cells were appropriately diluted and spread on L broth agar media. Then, they were subjected to UV (254 nm) irradiation and cultivated at 37°C. Colony-forming units (cfu) were counted and the surviving fraction was calculated by dividing the cfu in UV irradiated cells by that in nonirradiated cells.
Generating the RECG gene knockout
To prepare the RECG KO construct, fragments of the RECG gene were amplified using primers CAGAATGAGAGCTCTGAGTATGGTGTTC and GAGCCGCGGGAGAGGCTAAGCCTGAAACATTGGAG to obtain a 1.6-kb fragment from the 5’ region, and CAGATCGATGCGACAGTAACGCAAGAAGAAGCAC and GAAGGGCCCTGGGGATTAAGTCTTCTAGTTTGCCTG to obtain the 1.6-kb fragment from the 3’ region. Each of them was then introduced into either side of the nptII cassette of pTN3 [46]. The resulting plasmid, named pMSD202, was linearized before the transformation. Moss transformation was performed according to Nishiyama et al. [46]. The transformants were selected on medium containing G418. To confirm knockout of RECG gene, PCR was performed with primers TCCGGATCCTTGCTACACCCTTCTTTCTGCTCCG and GTTGCTCATCCACAACAGCC.
Transmission electron microscopy
Protonemata cultivated on BCDAT agar medium were fixed with 4% paraformaldehyde and 2% glutaraldehyde in sodium cacodylate buffer, pH 7.4, for overnight at 4°C. Then, cells were fixed with 1% osmium tetroxide in cacodylate buffer, pH 7.4, for 5 h at room temperature. After dehydration in a graded methanol series, the samples were embedded in Epon812 resin. Thin sections were stained with uranyl acetate and lead citrate and observed with JEM-1400 electron microscope (JEOL).
DNA gel blot analysis
Total genomic DNA was separated on a 0.7% agarose gel and blotted onto a nylon membrane. To detect nuclear-encoded and mitochondrial-encoded genes, 4 and 0.5 μg of total genomic DNA were used, respectively. Probes were prepared by PCR using the PCR DIG Probe Synthesis Kit (Roche) and the following primers: GCCTAGGAGGGCGCGTTTGGGAAGACG and CCCAGACACATAACTATAGTGCTAGCCG for nad2; AACACTTGGGTACATGCCAGCCA and GGACACACGGCTACTATGCGATT for atp9; GTGAATGAGTATAAGCTTCGCTGCTCAA and CTATGTATAGCCACTTTGGTAGTGCTTG for ccmF; CGGGTTAGGGGTACGACAGATAGCG and TAATACGACTCACTATAGGGCGAGTAGTTCTATCTATCTACCTCTCC for nad7; GCGCATGCACATTTCCAAGC and GTAGTTATGCTTCAGATGCTTTGC for nad7 in S5A Fig.; CTTGAGAAGCGCAACCTGTG and GCTGTGCCTTTGAAGCTTCG for nad9; ATCCCTGATCCCAGAATACGACTG and GGCTAAGAGCATGAAGACAGATCC for nad4; GTCTGCTGGCAGAAATTCATC and TTGCGCCTTGACCTGGATTC for rpl2; AACGAGTCGTACACTAAGC and ATTCGCGGTCGTTCGTATG for rpl16; and GGACGAATTTTCCATCTCCAAGG and GGAGGAGTTGCTGTAGATTTACC for ndhH. Hybridization of the probes was performed at 37°C, and the membranes were washed in 2x SSC with 0.1% SDS at 25°C and 0.5x SSC with 0.1% SDS at 65°C. Detection of the DIG-labeled probes was performed with Anti-DIG-Alkaline Phosphatase (Roche) and AttoPhos (Promega). All the DNA gel blots were re-hybridized to mitochondrial rpl2 or plastid ndhH probe to estimate organelle DNA copy number (S7 Fig.).
PCR analysis of organelle DNA
PCR analyses of DNA generated by recombination between repeated sequences were performed using total genomic DNA and the primers listed in S4 Table. Quantitative PCR was performed with the Applied Biosystems 7500 Fast Real-Time PCR System and POWER SYBR Green Master Mix (Applied Biosystems International). qPCR was performed with technical replicates of three independent reactions. Standard PCR analysis was performed in the exponential amplification phase, and the quantity of amplification products was compared using ethidium bromide staining.
RT-PCR analysis of mitochondrial transcripts
Total RNA extracted from protonemal cells was treated with TURBO DNase (Ambion) to remove residual genomic DNA and then reverse-transcribed using random hexamer. Quantitative RT-PCR was performed using primers listed in S5 Table with the Applied Biosystems 7500 Fast Real-Time PCR System and POWER SYBR Green Master Mix (Applied Biosystems International). Serine threonine protein phosphatase 2a, ST-P 2a, was used as a reference gene [53]. qRT-PCR was performed with technical replicates of three independent reactions. Standard RT-PCR analysis was performed in the exponential amplification phase.
Assay for evaluation of PCR jumping in qPCR
DNA fragments harboring copy 1 or 2 of ptIR-1 was amplified by standard PCR using primers GGTCCATAAAGGAGCCGTATG and GGGTAGTGGGAATCGAACC for the copy 1 of ptIR-1; CATCCTTCCTCTATGTTGTTTACGA and TCACAAGAAGCCGGATGAAA for the copy 2 of ptIR-1. Relative copy number of the products was analyzed by qPCR using the same primer pairs, and the two fragments were mixed to contain the same copy number of copy 1 or 2 of ptIR-1 as the WT genomic DNA. Then copy number of the DNA recombined between copy 1 and 2 of ptIR-1 were analyzed by qPCR using primers GAATCGAACCCACATCATTAGCT and TATTCACAAGAAGCCGGATGAA and the WT genomic DNA or the mixed DNA fragments as templates.
Supporting Information
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Štítky
Genetika Reprodukčná medicínaČlánok vyšiel v časopise
PLOS Genetics
2015 Číslo 3
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