Figures
Abstract
Background
Bacteria of the family Rickettsiaceae are principally associated with arthropods. Recently, endosymbionts of the Rickettsiaceae have been found in non-phagotrophic cells of the volvocalean green algae Carteria cerasiformis, Pleodorina japonica, and Volvox carteri. Such endosymbionts were present in only C. cerasiformis strain NIES-425 and V. carteri strain UTEX 2180, of various strains of Carteria and V. carteri examined, suggesting that rickettsial endosymbionts may have been transmitted to only a few algal strains very recently. However, in preliminary work, we detected a sequence similar to that of a rickettsial gene in the nuclear genome of V. carteri strain EVE.
Methodology/Principal Findings
Here we explored the origin of the rickettsial gene-like sequences in the endosymbiont-lacking V. carteri strain EVE, by performing comparative analyses on 13 strains of V. carteri. By reference to our ongoing genomic sequence of rickettsial endosymbionts in C. cerasiformis strain NIES-425 cells, we confirmed that an approximately 9-kbp DNA sequence encompassing a region similar to that of four rickettsial genes was present in the nuclear genome of V. carteri strain EVE. Phylogenetic analyses, and comparisons of the synteny of rickettsial gene-like sequences from various strains of V. carteri, indicated that the rickettsial gene-like sequences in the nuclear genome of V. carteri strain EVE were closely related to rickettsial gene sequences of P. japonica, rather than those of V. carteri strain UTEX 2180.
Conclusion/Significance
At least two different rickettsial organisms may have invaded the V. carteri lineage, one of which may be the direct ancestor of the endosymbiont of V. carteri strain UTEX 2180, whereas the other may be closely related to the endosymbiont of P. japonica. Endosymbiotic gene transfer from the latter rickettsial organism may have occurred in an ancestor of V. carteri. Thus, the rickettsiae may be widely associated with V. carteri, and likely have often been lost during host evolution.
Citation: Kawafune K, Hongoh Y, Hamaji T, Sakamoto T, Kurata T, Hirooka S, et al. (2015) Two Different Rickettsial Bacteria Invading Volvox carteri. PLoS ONE 10(2): e0116192. https://doi.org/10.1371/journal.pone.0116192
Academic Editor: Robert E. Steele, UC Irvine, UNITED STATES
Received: July 17, 2014; Accepted: December 2, 2014; Published: February 11, 2015
Copyright: © 2015 Kawafune et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: Newly yielded sequences are available from DDBJ/EMBL/Genbank LC004701-LC004725. All the other relevant data are within the paper and its Supporting Information files.
Funding: This work was supported by Grants-in-Aid for JSPS Fellows (No. 24-9265 to KK), Scientific Research for Plant Graduate Students from Nara Institute of Science and Technology (to TS and TK), Scientific Research on Innovative Areas (No. 26117708 to HN) and Scientific Research (A) (No. 24247042 to HN) from the Ministry of Education, Culture, Sports, Science and Technology (MEXT)/Japan Society for the Promotion of Science (JSPS) KAKENHI (http://www.mext.go.jp/english/). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Background
The order Rickettsiales (Alphaproteobacteria), generally termed the rickettsiae, contains Gram-negative obligate intracellular bacteria [1], which are well-studied pathogens of mammals; are manipulators of host sexual reproduction [2]; and are candidate organisms for mitochondrial ancestors [3]. The family Rickettsiaceae of the Rickettsiales includes many agents causing tick-borne disease, and contains two genera, Rickettsia and Orientia, both of which are hosted principally by arthropod cells [1]. Bacteria of the Rickettsiaceae are also found as endosymbionts of non-arthropod organisms including leeches [4],[5], hydras [6], and ciliates [7–9]; the endosymbionts hosted by non-arthropods form a monophyletic group (termed the “hydra group”) within the family Rickettsiaceae, based on phylogenetic analyses of 16S ribosomal RNA (rRNA) genes [10]. Recently, endosymbiotic bacteria of the hydra group have been found in non-phagotrophic cells of the green algae Carteria cerasiformis, Pleodorina japonica, and Volvox carteri (Volvocales, Chlorophyceae)[11],[12] and marine green macroalgae (Bryopsis spp). (Ulvophyceae)[13]. Schrallhammer et al. [8] suggested a provisional species name “Candidatus Megaira polyxenophila” for endosymbionts of the hydra group harbored by cells of ciliates and volvocalean algae.
Infection or transmission of endosymbionts belonging to the Rickettsiaceae is transmitted from arthropods to vertebrates (reviewed in e.g.: [14]) and to land plants [15], although several studies have suggested that other routes of horizontal transmission may be in play [5],[9],[10]. Thus, the mode of transmission of rickettsial endosymbionts to non-phagotrophic cells of Volvocales is an interesting question. Of 10 strains of four closely related species of Carteria, the rickettsial endosymbiont was detected in only C. cerasiformis strain NIES-425 [11]. A similar situation was evident when V. carteri was studied; the endosymbiont was detected in only V. carteri f. weismannia strain UTEX 2180, among nine strains belonging to three forms (f. weismannia, f. nagariensis, and f. kawasakiensis) of this species [12]. These data suggest that the rickettsial endosymbiont may have been transmitted to the algal strains only very recently, after divergence of such strains.
V. carteri serves as a model organism for studies on multicellularity and the evolution of sexual reproduction [16],[17]. The nuclear genomic sequence of V. carteri f. nagariensis strain EVE has been determined recently [18]. Although no rickettsial endosymbiont was evident in this strain (based on performance of genomic PCR using the hydra group-specific primers, and 4′,6-diamidino-2-phenylindole [DAPI]-staining of algal cells [12]), we detected in preliminary work a sequence similar to that of rickettsial 16S rRNA genes in the nuclear genome of V. carteri f. nagariensis strain EVE. The presence of rickettsial gene-like sequences in the nuclear genome of this strain may indicate the occurrence of horizontal gene transfer (HGT) from a rickettsial bacterium to the ancestor of V. carteri f. nagariensis strain EVE.
The present study was undertaken to elucidate the origin of rickettsial gene-like sequences within the nuclear genome of V. carteri f. nagariensis strain EVR, compared with other 12 strains of V. carteri. Phylogenetic analyses of rickettsial gene and gene-like sequences from the endosymbionts, and the nuclear genomes of volvocalean algae, indicated that the rickettsial sequence of V. carteri f. nagariensis strain EVE was closely related to that of P. japonica, rather than that of V. carteri f. weismannia strain UTEX 2180.
Results
Sequences and synteny of rickettsial gene/gene-like sequences in nuclear genomes, and endosymbionts harbored by cells of the Volvocales
We performed a BLASTN search using long contiguous (contig) sequences (>5 kbp), from our ongoing genome data collection of the Carteria cerasiformis strain NIES-425 rickettsial endosymbiont, against the Volvox carteri f. nagariensis strain EVE nuclear genome. We found that the three rickettsial gene-like sequences with the highest E-values (S1 Table) were localized in a synteny region within scaffold 6 of the V. carteri f. nagariensis strain EVE nuclear genome (Fig. 1A). The three genes were a 16S rRNA gene, a gene encoding UDP-N-acetylenolpyruvylglucosamine reductase (murB), and a gene encoding D-alanine-D-alanine-ligase B (ddlB). In addition to these three rickettsial gene-like sequences, the synteny contained a short sequence similar to that of the cell division septal protein FtsQ gene (ftsQ; this was found upon additional BLASTN searching) and three V. carteri-specific sequences (see below) within a region approximately 9 kbp in length (Fig. 1A). In order to make sure that the synteny region is not contaminated and correctly assembled, this 9 kbp-region was confirmed via direct sequencing of genomic PCR products from total DNA of V. carteri f. nagariensis strain EVE (see Fig. 1A and Materials and Methods). No nucleotide difference was found between the ca. 9 kbp-region sequenced and the corresponding region of scaffold 6 of strain EVE genome.
Schematic representations of arrangements/synteny of several rickettsial genes and gene-like sequences present in DNA of the nuclear genome of V. carteri (A) and in the genomes of rickettsial possible endosymbionts harbored by three volvocalean species (B-D). Coding DNA sequences (CDSs) and CDS-like regions are shown as boxes. Rickettsial CDSs/CDS-like regions are shown in pale yellow, the V. carteri transposon Jordan-like region in green and others in black. Placement of boxes above/below the line indicates gene direction (from left-to-right or right-to-left, respectively). Black double-headed arrows on the baseline indicate the regions sequenced in the present study. Colored triangles under boxes indicate the locations of primers used for semi-quantitative genomic PCR (16S rRNA gene 5′-region: magenta, 16S rRNA gene 3′-region: light blue, murB: orange, ddlB: green; Fig. 2E). For accession numbers of sequences used in this figure, see S3 Table. (A) Part of scaffold 6 of the V. carteri f. nagariensis strain EVE nuclear genome. (B) Part of the Carteria cerasiformis NIES-425 draft endosymbiont genome, including 16S rRNA (first line) and murB-ftsQ (second line). White triangles indicate primers used to amplify the sequencing templates (ccmF-R02 and phbB-F01; see Materials and Methods). (C) Part of the genome of a possible endosymbiont of V. carteri f. weismannia strain UTEX 2180, including murB and ddlB (right). The 16S rRNA gene of the endosymbiont [12] is also shown (left). (D) Part of the genome of a possible endosymbiont of Pleodorina japonica strain NIES-577, including murB and ddlB (right). The 16S rRNA gene [11] is also shown (left).
Schematic representations of arrangements/synteny (A-D) in, and semi-quantitative genomic PCR data (E) from, several rickettsial gene-like sequences possibly located in the nuclear genomes of V. carteri strains. Coding DNA sequence (CDS)-like regions are shown as boxes. Rickettsial CDS-like regions are shown in pale yellow, the V. carteri transposon Jordan-like region in green and others in black. Placement of boxes above/below the line indicates the gene direction (from left-to-right or right-to-left, respectively). Black double-headed arrows on the baseline indicate the regions sequenced in the present study. Colored triangles under boxes indicate the primers used for semi-quantitative genomic PCR (16S rRNA gene 5′-region: magenta, 16S rRNA gene 3′-region: light blue, murB: orange, ddlB: green; Fig. 2E). For accession numbers of sequences used in this figure, see S3 Table. (A) Sequences including rickettsial CDS-like regions of V. carteri f. nagariensis strains UTEX 1886, NIES-397 and NIES-398. (B) Sequences including rickettsial gene homologs of V. carteri f. weismannia strains UTEX 1875 and UTEX 1876. Plus (+) indicates a frameshift deletion. (C) Sequence including rickettsial murB-like sequence of V. carteri f. weismannia strain UTEX 2170. (D) Sequences including rickettsial 16S rRNA gene-like sequences of V. carteri f. kawasakiensis NIES-732 and NIES-733. (E) Semi-quantitative genomic PCR of rickettsial genes and gene-like sequences. Each rickettsial gene-like sequence was amplified via genomic PCR using rickettsia-specific primer sets (see Materials and Methods). The positions of primer sets with reference to target positions are shown in both Fig. 1 and this Fig. 2. As a control, the actin gene was amplified. Chlamydomonas reinhardtii strain CC-503 was used as negative control.
The rickettsial 16S rRNA gene-like sequence within the synteny region of the V. carteri f. nagariensis strain EVE genome was 412 bp in length and corresponded to the 5′-region of the C. cerasiformis strain NIES-425 endosymbiont 16S rRNA gene (including the 5′ end). The 3′-region of the 16S rRNA gene-like sequence was truncated, and lay adjacent to a sequence similar to that of the rickettsial murB gene. This murB-like sequence was 768 bp in length, contained the 3′-end of the coding region, and exhibited no frameshift or premature stop codon, although the sequence seemed to lack a 5′-coding-region of 117 bp (including the start codon) when compared with murB of the C. cerasiformis strain NIES-425 endosymbiont. The sequence similar to that of rickettsial ddlB was interrupted by a 1,021-bp insertion (“V. carteri multicopy A” in Fig. 1A), but had both a start and a stop codon, and exhibited no frameshift or premature stop codon (the insertion was excluded from analysis). The insertion (V. carteri multicopy A) had no sequence similar to that of rickettsial genes, but had 103 DNA sequences similar to those distributed in the V. carteri f. nagariensis strain EVE nuclear genome (E-value = 0; nucleotide identity, 84–100%; a BLASTN search yielded these data). Thus, it appeared specific to V. carteri. The ftsQ-like sequence was short (75 bp), but exhibited high-level similarity (nucleotide identity: 88%) to the 5′-region (including the start codon) of ftsQ of the endosymbiont of C. cerasiformis strain NIES-425. A sequence resembling the 5′-region of the V. carteri-specific transposon Jordan [19] was also found (E value = 0; nucleotide identity 96%); the sequence was located near the ftsQ-like sequence, but lacked the 5′-inverted terminal repeat found in Jordan [19]. A DNA sequence of 516 bp located in the 5′-upstream region of the rickettsial 16S rRNA-like sequence (“V. carteri multicopy B” in Fig. 1A) may also be V. carteri-specific because it had 32 similar DNA sequences (E values = 0.0, nucleotide identity 95–98%) within the V. carteri f. nagariensis strain EVE nuclear genome (found using a BLASTN search). This region exhibited no similarity to the rickettsial genes or DNA inserted in the ddlB-like sequence. At both ends of the ca. 9 kbp-DNA region including rickettsial gene-like sequences, two regions (asmbl_81.volvox20_pasa2 and asmbl_82.volvox20_pasa2) that match with EST sequences are identified on Phytozome version 9.1 (http://www.phytozome.net) [20]. These regions were not similar to any sequences in our preliminary genome assembly database of the rickettsial endosymbiont of C. cerasiformis strain NIES-425, and their functions are unknown.
In the rickettsial endosymbiont genome of C. cerasiformis strain NIES-425, murB, ddlB, and ftsQ formed a synteny, but the 16S rRNA gene was separated from the three genes, being composed of two separate DNA sequences (Fig. 1B). One sequence was 1,422 bp long and encoded a 16S rRNA gene positioned between genes encoding nucleoside triphosphate pyrophosphohydrolase (mutT) and a M23 superfamily membrane-bound metallopeptidase (nlpD2). The other sequence was 6,230 bp long and encoded murB, ddlB, ftsQ, UDP-N-acetylmuramate-alanine ligase (murC), and three other proteins (Fig. 1B, black double-headed arrows on the baseline). In the endosymbiont genome of C. cerasiformis strain NIES-425, a coding DNA sequence (CDS) for a hypothetical protein was inserted between murB and ddlB.
Partial genomic DNA sequences including the murC, murB, ddlB, and ftsQ genes were obtained using total DNAs of rickettsial endosymbiont-containing cells of V. carteri f. weismannia strain UTEX 2180 (Fig. 1C) and P. japonica strain NIES-577 (Fig. 1D). These sequences were similar to that of the endosymbiont of C. cerasiformis strain NIES-425 in terms of gene arrangement. However, the P. japonica strain NIES-577 sequence differed from the other two sequences in that an additional CDS was lacking between murB and ddlB, and a CDS encoding a DDE transposase was located between DNA encoding 1-acyl-sn-glycerol-3-phosphate acyltransferase (plsC) and acetoacetyl-CoA reductase (phbB) (Fig. 1D).
Rickettsial gene-like sequences in various V. carteri strains
Performance of genomic PCR using 16S rRNA primers specific to the hydra group, and DAPI-staining of algal cells from 13 strains of three forms of V. carteri, showed that V. carteri f. weismannia strain UTEX 2180 harbored a rickettsial endosymbiont, whereas the 12 other strains (including V. carteri f. nagariensis strain EVE) did not [12] (S1, S2 Figs.). Sequences similar to those of rickettsial genes were detected in nine endosymbiont-lacking strains of V. carteri via genomic PCR using specific primers (S2 Table) targeting endosymbiont genes and rickettsial gene-like sequences in the nuclear genome of V. carteri f. nagariensis strain EVE (Fig. 1). We sequenced the PCR products from all nine strains (Fig. 2E and S3 Fig.). The sequences were classified into four types: (A)-(D). Type A: V. carteri f. nagariensis strains UTEX 1886, NIES-397, and NIES-398 had sequences of 6,284–6,290 bp that were completely or almost identical (99–100% nucleotide identity) to part of scaffold 6 of the published V. carteri f. nagariensis strain EVE nuclear genome (Fig. 1A), encompassing sequences similar to those of rickettsial 16S rRNA, murB, ddlB, ftsQ, V. carteri-specific transposon Jordan, and two V. carteri-specific sequences (V. carteri multicopies A and B) (Fig. 2A); Type B: V. carteri f. weismannia strains UTEX 1875 and 1876 contained DNA sequences including five regions that were very similar to a sequence of C. cerasiformis strain NIES-425 (containing the murC, murB, ddlB, ftsQ, and plsC genes; 88–92% nucleotide identity; Fig. 2B). In these five regions, the sequences similar to murB, ddlB, and ftsQ exhibited intact open reading frames (ORFs), whereas the murC-like sequences had frameshift mutations in the 3′ regions. The gene arrangement of this DNA sequence was similar to that of P. japonica strain NIES-577, in that a CDS encoding a hypothetical protein, lying between the murB and ddlB genes/gene-like sequences, was lacking. Type C: A 678 bp sequence (only), similar to that of truncated rickettsial murB, was detected in V. carteri f. weismannia strain UTEX 2170 (Fig. 2C). This murB-like sequence lacked both the 5′ and 3′ ends, although no frameshift or premature stop codon was evident. Type D: In V. carteri f. kawasakiensis strains NIES-732 and NIES-733, no sequence exhibiting similarity to those encoding rickettsial murB, ddlB, or ftsQ was detected, but we found a rickettsial 16S rRNA gene-like sequence (Fig. 2D). This sequence was 882 bp long and corresponded to the 3′-region of the 16S rRNA gene from the endosymbiont of C. cerasiformis strain NIES-425 (Fig. 1B). However, sequence corresponding to the partial 16S rRNA gene-like sequence (the 5'-region) found in the nuclear genome of V. carteri f. nagariensis strains was lacking.
Semi-quantitative PCR of rickettsial gene/gene-like sequences from Volvox carteri strains
To determine whether the rickettsial gene/gene-like sequences were present in the nuclear genome or in endosymbionts of the cytoplasm, we performed semi-quantitative PCR on total DNA of 13 strains of V. carteri (Fig. 2E). Of these V. carteri strains, the rickettsia-harboring V. carteri f. weismannia strain UTEX 2180 exhibited apparently higher amplification than did the other 12 strains lacking rickettsial endosymbionts, when primer sets targeting rickettsial gene and gene-like sequences were employed (Fig. 2E). This indicated that the numbers of rickettsial gene or gene-like sequence molecules targeted by PCR in the rickettsia-harboring strain (V. carteri f. weismannia strain UTEX 2180) was greater than those of other cells lacking endosymbionts. Thus, high-level detection of V. carteri f. weismannia strain UTEX 2180 sequences may reflect the presence of many endosymbionts within host algal cells, and lower-level detection the presence of low copy-number sequences within the nuclear genome.
Phylogenetic analysis of rickettsial gene-like sequences from V. carteri
In a phylogenetic tree constructed using rickettsial 16S rRNA gene and gene-like sequences, the family Rickettsiaceae was divided into two robust monophyletic groups, as shown previously [12]: the first group corresponded to “Rickettsia” [4],[5] that included certain endosymbionts of leeches, and the second the hydra group (Fig. 3). The second group was subdivided into two subclades A and B, as previously described [12] [supported by 76–93% bootstrap values upon maximum-likelihood (ML) and maximum parsimony (MP) analysis, and a 1.00 posterior probability (PP) by Bayesian inference (BI)]. Subclade A contained bacterial sequences derived from coral, endosymbionts hosted by Hydra oligactis, marine green macroalgae (Bryopsis spp.), and the freshwater ciliate Ichthyophthirius multifiliis. Subclade B included 16S rRNA gene-like sequences from six endosymbiont-lacking strains of V. carteri f. kawasakiensis and f. nagariensis, and those of 16S rRNA genes from endosymbionts of C. cerasiformis strain NIES-425, P. japonica strain NIES-577, and V. carteri f. weismannia strain UTEX2180 [11],[12]. These endosymbionts, and those hosted by ciliates (in subclade B), have been assigned to “Candidatus Megaira polyxenophila” [9]. Within subclade B, endosymbionts from C. cerasiformis strain NIES-425, and four ciliates, formed a robust monophyletic group (88–89% bootstrap values and a PP of 0.99). A weak bootstrap value (52%) upon ML analysis suggested that the endosymbiont of P. japonica strain NIES-577, and the 16S rRNA gene-like sequences from four strains of V. carteri f. nagariensis, were positioned into a small monophyletic group that did not include the endosymbiont of V. carteri f. weismannia strain UTEX 2180 or the gene-like sequence of V. carteri f. kawasakiensis.
The tree was inferred using the maximum-likelihood (ML) method based on 43 sequences and 1,403 nucleotides of the 16S rRNA genes from bacteria, endosymbionts (En) of eukaryotic hosts, and other environmental samples, of the family Rickettsiaceae, including rickettsial 16S rRNA gene-like sequences obtained from endosymbiont-lacking strains of V. carteri (bold). Bootstrap values (≥50%) for the ML and maximum parsimony analyses, and posterior probabilities (≥0.90) for Bayesian interference, are indicated at the respective nodes. The scale bar corresponds to 0.02 nucleotide substitutions per position. The hydra group and ‘Candidatus Megaira polyxenophila’ refer to the organisms studied by Weinert et al. [10] and Schrallhammer et al. [9], respectively.
Phylogenetic analyses of murB and ddlB genes and gene-like sequences yielded essentially the same results (S4, S5 Figs.). Rickettsial gene-like sequences from endosymbiont-lacking strains of V. carteri f. nagariensis and f. weismannia formed a robust monophyletic group, combined with sequences from three endosymbiont-containing strains (C. cerasiformis strain NIES-425, P. japonica strain NIES-577, and V. carteri f. weismannia strain UTEX 2180); the bootstrap values were 99–100% by both ML and MP analysis. In this monophyletic group, V. carteri f. weismannia strain UTEX 2180 and Carteria cerasiformis strain NIES-425 were (respectively) primarily and secondarily basal to all others members. Combined amino acid data from these two gene/gene-like sequences (Fig. 4) showed that rickettsia-lacking strains of V. carteri f. nagariensis and f. weismannia, and the endosymbiont-containing P. japonica strain NIES-577, formed a robust small clade (with 97–99% bootstrap values upon ML and MP analyses), which did not include V. carteri f. weismannia strain UTEX 2180 or C. cerasiformis strain NIES-425.
The tree was inferred using the maximum-likelihood (ML) method based on 637 amino acid sites in translated and combined murB and ddlB gene/gene-like sequences from 30 operational taxonomic units of bacteria in the Rickettsiaceae, including possible endosymbionts (En) of algal hosts, and possible nuclear-encoded sequences from endosymbiont-lacking strains of V. carteri (bold). Bootstrap values (≥50%) for ML and maximum parsimony analyses are indicated at the respective nodes. The scale bar corresponds to 0.1 amino acid substitutions per position.
Phylogenetic relationships among various strains of three forms of Volvox carteri based on ITS-2 sequences of nuclear rDNA
Coleman [21] derived phylogenetic relationships among three forms of V. carteri based on internal transcribed spacer (ITS) sequences of nuclear ribosomal DNA (rDNA) (ITS-1, the 5.8S rRNA gene, and ITS-2), using only five strains. Thus, we constructed a phylogenetic tree based on nuclear rDNA ITS-2 sequences from 13 strains of three forms of V. carteri (S3 Table). As reported by Coleman [21], strains of f. nagariensis and f. kawasakiensis formed a robust monophyletic group (91% bootstrap values) to which strains of f. weismannia were sister (Fig. 5). Within f. weismannia, two sister clades were well-resolved (with 81–92% bootstrap values); one contained the rickettsia-lacking strains UTEX 1875, UTEX 1876, and UTEX 2170, in which (at least) rickettsial murB gene homologs were detected in the present study; and the other the rickettsia-lacking strains UTEX 1874 and UTEX 2904, and the rickettsia-containing strain UTEX 2180.
The tree was inferred using the maximum-likelihood (ML) method based on alignment of 471 nucleotide sites in the internal transcribed spacer 2 sequences of 10 operational taxonomic units of V. carteri strains and V. obversus strain UTEX 1865 (the outgroup). Bootstrap values (50% or more) for the ML and maximum parsimony analyses are indicated at the respective nodes. The scale bar shows 0.05 nucleotide substitutions per position. The presence (+) or absence (-) of rickettsial endosymbionts based on the data of Kawafune et al. [12], and those of the present study (S1, S2 Figs.), are shown in the central column. Possible nuclear-encoded, rickettsial gene homologs detected in the present study (Fig. 2E and S3 Fig.) are shown in the column on the right. The gene names shown in bold were used in phylogenetic analyses (Figs. 3, 4 and S4, S5 Figs.). The letters A-D following gene names correspond to the forms of genetic composition shown in Fig. 2. No rickettsial gene-like sequences were detected (in the present study) in strains UTEX 2903, UTEX 1874 or UTEX 2904.
Discussion
The present phylogenetic analyses (Figs. 3, 4 and S4, S5 Figs.) indicated that the rickettsial sequences derived from nine strains of V. carteri apparently belong to the hydra group. However, our PCR experiment of these nine strains using the hydra group-specific primers [12] (S2 Fig.) demonstrated the absence of the whole 16S rRNA gene that is essential for the living endosymbiotic bacteria. In addition, the DAPI-staining of the algal cells in these nine strains [12] (S2 Fig.) clearly shows the absence of bacterial cells within the host algal cells. Thus, the rickettsial gene-like sequences detected in the nine strains of V. carteri cannot be actual genes of endosymbionts. It should also be noted that, even if the 16S rRNA gene-specific primers and light microscopic examination by the DAPI-staining could have missed rickettsial endosymbiotic variants that do not belong to the hydra group, the sequences positioned within the possible hydra group (Figs. 3, 4 and S4, S5 Figs.) should not originate from such missing endosymbionts. In addition, our semi-quantitative PCR results of the 12 endosymbiont-lacking strains of V. carteri (Fig. 2E) indicated that the degree of amplification of their sequences is consistent with that of the low copy DNA such as that in the nuclear genome. Thus, the rickettsial gene-like sequences from the endosymbiont-lacking V. carteri strains are considered to be coded in the nuclear genome of the host cells. It could also be speculated that the rickettsial gene-like sequences in rickettsial endosymbiont-lacking strains of V. carteri might have been transferred to other endosymbionts still remaining in the host. However, this scenario seems very unlikely because we experimentally confirmed the 6–9 kbp-DNA sequences encompassing both rickettsial and V. carteri-specific sequences (Figs. 1A, 2A).
The rickettsial 16S rRNA and/or murB gene homologs were found in various V. carteri strains lacking rickettsial endosymbionts in the cytoplasm (Figs. 1, 2A-2D). Upon phylogenetic analysis, the nuclear-encoded 16S rRNA gene homologs of V. carteri f. nagariensis (strains EVE, UTEX 1886, NIES-397, and NIES-398) and f. kawasakiensis (strains NIES-732 and NIES-733) belonged to subclade B within the hydra group, as did the sequences of rickettsial endosymbionts of V. carteri f. weismannia strain UTEX 2180, P. japonica strain NIES-577, and C. cerasiformis strain NIES-425 (Fig. 3). Although rickettsial 16S rRNA gene-like sequences were not evident in three endosymbiont-lacking strains of V. carteri f. weismannia (UTEX 1875, UTEX 1876, and UTEX 2170), their murB and ddlB (except for UTEX 2170) homologs formed a monophyletic group in which endosymbiotic genes of V. carteri f. weismannia strain UTEX 2180 and C. cerasiformis strain NIES-425 were basally positioned (Fig. 4 and S4, S5 Figs.). Therefore, rickettsial gene homologs in the nuclear genome of V. carteri may have originated from rickettsial bacteria of subclade B via horizontal gene transfer. As the Rickettsiales are obligate intracellular bacteria, and as their hosts (green algal cells) are not phagotrophic, the donor rickettsial organisms may have been harbored by ancestral cells of rickettsial endosymbiont-lacking strains of V. carteri. Thus, endosymbiotic gene transfer (EGT) may have been used to transfer rickettsial gene-like sequences to the host nuclear genome. However, the donor rickettsial endosymbionts of V. carteri strains have apparently been subsequently lost.
All of murC, murB, ddlB, and ftsQ are component of the dcw (division and cell wall) cluster [22]. Some genes of dcw cluster have previously been shown to transfer from endosymbiotic bacteria to host eukaryote genomes; e.g., that of an adzuki bean beetle (a gene encoding cell division protein FtsZ [ftsZ]) [23]; that of a rotifer (ddl) [24]; and that of Trichoplax adhaerens (UDP-N-acetylglucosamine enoylpyruvyl transferase = murA) [25]. In the T. adhaerens model, it was suggested that the transferred murA gene was expressed, and limited the growth of endosymbionts of the family Midichloriaceae (Rickettsiales) [25]. In this study, however, although expression of rickettsial gene-like sequences in the nuclear genome of V. carteri f. nagariensis strains was not examined, most nuclear-encoded rickettsial gene-like sequences were incomplete when compared with the CDS of rickettsial genes of C. cerasiformis strain NIES-425 and V. carteri f. weismannia strain UTEX 2180 endosymbionts. Thus, such nuclear-encoded sequences may be non-functional in cells of V. carteri f. nagariensis strains. In addition, rickettsial 16S rRNA gene-like sequences in the nuclear genomes of V. carteri f. nagariensis strains lack sequences corresponding to the 3′ ends, and should be non-functional. Similarly, the genome of Trichonympha agilis, an eukaryotic symbiont in the termite gut, contains 16S rRNA pseudogenes that were likely transferred from bacterial endosymbionts, but have large deletions. It remains unknown whether such pseudogenes have a certain function as non-cording DNA or not [26].
Although the statistical support was weak (52% upon ML analysis), our phylogenetic analysis of 16S rRNA gene/gene-like sequences suggested that gene-like sequences in rickettsial endosymbiont-lacking strains of V. carteri f. nagariensis (EVE, UTEX 1886, NIES-397, and NIES-398) were closely related to that of the endosymbiont P. japonica strain NIES-577, rather than those of the endosymbionts of V. carteri f. weismannia strain UTEX 2180 or C. cerasiformis strain NIES-425 (Fig. 3). The close relationship between rickettsial genes/gene-like sequences of V. carteri f. nagariensis and the endosymbiont of P. japonica strain NIES-577 was robustly supported by phylogenetic analyses (Fig. 4 and S4, S5 Figs.) of murB and ddlB genes/gene-like sequences. In addition, the synteny of murB and ddlB in P. japonica strain NIES-577 was similar to that of V. carteri f. nagariensis gene-like sequences, lacking a CDS for a hypothetical protein encoded between murB and ddlB in endosymbionts of V. carteri f. weismannia strain UTEX 2180 and C. cerasiformis strain NIES-425 (Figs. 1, 2A). Thus, rickettsial gene-like sequences in the nuclear genome of V. carteri f. nagariensis may have been transmitted from an endosymbiont closely related to that of P. japonica strain NIES-577. It appears that such sequences were not derived directly from an endosymbiont closely related to that of V. carteri f. weismannia strain UTEX 2180. A similar EGT event featuring an endosymbiont closely related to that of the P. japonica strain NIES-577 may explain the origin of rickettsial gene-like sequences in three endosymbiont-lacking strains of V. carteri f. weismannia (Fig. 2B, C). MurB and ddlB gene/gene-like sequences from V. carteri f. weismannia strains, V. carteri f. nagariensis strains, and P. japonica strain NIES-577 formed a small clade distinct from those of V. carteri f. weismannia strain UTEX 2180 (Fig. 4 and S4, S5 Figs.). However, the phylogenetic positions of rickettsial 16S rRNA gene-like sequences from V. carteri f. kawasakiensis strains NIES-732 and NIES-733 remain ambiguous because the sequences are short and no other rickettsial gene-like sequences were detected in these strains (Fig. 3).
MurB and ddlB gene/gene-like sequences from endosymbiont-lacking strains of V. carteri f. nagariensis and f. weismannia were closely related to those of the endosymbiont (or rickettsial gene-like sequences) of P. japonica NIES-577 (Fig. 4 and S4, S5 Figs.). However, these two forms of V. carteri were robustly separated upon phylogenetic analysis (Fig. 5). Thus, rickettsial gene-like sequences may have been independently transmitted to ancestors of the two forms of V. carteri, from endosymbiont(s) containing a sequence closely related to that of P. japonica strain NIES-577. Alternatively, such transmission may have occurred only once, in a common ancestor of the three forms of V. carteri. A similar EGT event occurring during historical endosymbiosis has been reported in an aphid genome; genes and pseudogenes were transferred from not only the primary endosymbiont Buchnera aphidicola (Gammaproteobacteria), but also from organisms related to Wolbachia spp. (Anaplasmataceae, Rickettsiales) and Orientia tsutsugamushi, neither of which exist in aphid cells [27],[28]. However, the EGT event that occurred in V. carteri remains unique, in that two different but closely related endosymbionts may have invaded closely related hosts. Thus, host specificity may be not high among endosymbionts within subclade B (Fig. 3) of the Rickettsiaceae.
Of the lineages of V. carteri f. weismannia, only UTEX 2180 contains the rickettsial endosymbiont. Nuclear rDNA ITS-2 sequences from UTEX 2180, UTEX 1874, and UTEX 2904 of V. carteri f. weismannia were almost identical (only two nucleotide deletions were noted). Thus, transmission of the rickettsial endosymbiont to UTEX 2180 may have been very recent, occurring after divergence of the three strains. Alternatively, transmission might have taken place prior to divergence of the three strains, with subsequent loss of endosymbionts in UTEX 1874 and UTEX 2904. Support for the latter scenario is afforded by the frequent loss of rickettsial endosymbionts in V. carteri. In our present study, we found that rickettsial gene-like EGT sequences were widely distributed in endosymbiont-lacking strains of V. carteri. Thus, loss of rickettsial endosymbionts may have been very common during evolution of V. carteri.
V. carteri f. weismannia strain UTEX 2180 and other hosts of rickettsial endosymbionts in the Volvocales may have acquired rickettsial EGT from present and past endosymbionts and may contain rickettsial gene-like EGT sequences in their nuclear genomes. Both rickettsial genes and gene-like EGT sequences are potentially amplified by PCR performed on total DNA of such strains. In the present study, rickettsial 16S rRNA sequences amplified from V. carteri f. weismannia strain UTEX 2180 and P. japonica strain NIES-577 (Fig. 1C-1D) came from the rickettsial endosymbionts, as previously confirmed by fluorescence in situ hybridization [11],[12]. The other rickettsial gene homologs (e.g., murB, ddlB) of V. carteri f. weismannia strain UTEX 2180 (Fig. 1C) are also thought to come from endosymbionts, as revealed by semi-quantitative PCR (Fig. 2E). However, we could not detect possible nuclear-encoded rickettsial gene-like sequences by direct sequencing of this strain, possibly because we studied only a limited number of genes employing selective primer sets. We speculate that the presence of high numbers of rickettsial endosymbiont cells may inhibit amplification of low copy-number EGT sequences in the nuclear genomes of host cells. It is impossible to distinguish between sequences derived from existing rickettsial endosymbionts and nuclear genomic sequences when the sizes of amplified fragments are near-identical.
Of V. carteri strains lacking rickettsial endosymbionts, no amplification of rickettsial gene-like sequences was observed in V. carteri f. nagariensis strain UTEX 2903 and f. weismannia strains UTEX 1874 and UTEX 2904 (S3 Fig.). Nevertheless, it remains possible that the genomes of these strains harbor other EGT sequences derived from past rickettsial endosymbionts. Whole-genome analyses of these V. carteri strains may reveal other EGT sequences.
Conclusions
We showed that possible EGT-derived Rickettsiaceae gene-like sequences were present in various V. carteri strains that currently lack rickettsial endosymbionts. Comparison of synteny regions (Figs. 1, 2) and phylogenetic analyses of such gene-like sequences (Figs. 3, 4) revealed that at least two different rickettsial organisms invaded the V. carteri lineage; of which one was a direct ancestor of the endosymbiont of V. carteri f. weismannia strain UTEX 2180 and the other was closely related to the endosymbiont or rickettsial gene-like sequences of P. japonica. The latter rickettsial bacterium may have invaded ancestral cells of V. carteri f. nagariensis and f. weismannia strains, contributing to establishment of EGT nuclear genes, but has subsequently disappeared. As rickettsial endosymbionts harbored by green algal cells of the Volvocales are closely related to those of ciliates (Fig. 3), transmission of the rickettsial endosymbionts of subclade B may be based on ingestion of algal cells by ciliates, as suggested previously [8], implying that invasion and rickettsial gene transfer occurred several times in other species of Volvocales. In addition, endosymbionts may have been frequently lost, because rickettsial gene-like sequences are present in various endosymbiont-lacking strains of V. carteri, and because endosymbiont distribution is sporadic in the phylogenetic trees of V. carteri (Fig. 5) and Carteria [11]. A more detailed survey using further genomic information will reveal the details of the relationships between rickettsiae and cells of the Volvocales.
Materials and Methods
Culture, DNA extraction, and sequencing of the internal transcribed spacer (ITS) region
The strains of V. carteri, V. obversus, C. cerasiformis and P. japonica used in the present study (S3 Table) were supplied by the Culture Collection of Algae at the University of Texas at Austin (UTEX, USA; http://www.utex.org/) and the Microbial Culture Collection at the National Institute for Environmental Studies (NIES, Japan) [29]. Volvox cultures were sterilized and grown as described previously [12]. C. cerasiformis and P. japonica cultures were grown as described in Kawafune et al. [11]. Chlamydomonas reinhardtii strain CC-503 (cw92 mt+) was supplied from Chlamydomonas Resource Center (http://chlamycollection.org) and was grown as described previously [12] except that TAP medium [30] was used. Total DNA was extracted as described by Kawafune et al. [11]. The presence or absence of rickettsial endosymbionts in nine V. carteri strains was established previously [12]. The V. carteri strains UTEX 1874, UTEX 1886, UTEX 2903, and UTEX 2904 were subjected to DAPI staining and genomic PCR to determine the presence or absence of rickettsial endosymbionts, as described previously [12]. The ITS regions of nuclear rDNA sequences of V. carteri strains and V. obversus UTEX 1865 (S3 Table) were identified as described in Setohigashi et al. [31], except for those of V. carteri f. weismannia strain UTEX 1875 and UTEX 1876, which are publicably available [32].
BLAST-based screening of the V. carteri genome for transferred rickettsial genes
A BLASTN search [33] was performed on the V. carteri f. nagariensis EVE genome data (version 2, 8x, not masked) [18] on Phytozome version 9.1 (http://www.phytozome.net) [20] using 81 contigs (>5 kb) derived from our preliminary genome assembly database of the rickettsial endosymbiont hosted by C. cerasiformis strain NIES-425 (acquired as part of the Plant Global Education Project of the Nara Institute of Science and Technology) as queries. High-scoring segment pairs (HSPs) with E-values ≤1.0e-50 were annotated (S1 Table) using BLASTN and BLASTX searches [33] against nucleotide data and non-redundant protein sequences lodged in the National Center for Biotechnology Information database (NCBI, http://www.ncbi.nlm.nih.gov). Sequences associated with the three HSPs (similar to the rickettsial 16S rRNA gene, murB, and ddlB) that afforded the highest scores and E-values, were concentrated around base no. 940,000 of scaffold 6 on the V. carteri EVE genome. Additional BLASTN searching (using bases 935,001–945,000 of scaffold 6 as the query) against the 81 contigs of the C. cerasiformis NIES-425 rickettsial endosymbiont genome found one further short HSP (similar to rickettsial ftsQ, S1 Table); this HSP was also annotated as described above.
Sequencing of rickettsial gene/gene-like sequences
To determine genomic sequences (including those of murB, ddlB, and ftsQ of rickettsial endosymbionts), PCR primers ccmF-R02 and phbB-F01 (S2 Table) were designed based on preliminary genomic information on the C. cerasiformis NIES-425 endosymbiont. Using these primers, ca. 10-kbp segments lying between the gene encoding cytochrome C type biogenesis protein CCMF (ccmF) and phbB were amplified from total DNAs of C. cerasiformis strain NIES-425, P. japonica strain NIES-577, and V. carteri f. weismannia strain UTEX 2180, via PCR (35 cycles of 98°C 10s, 60°C 15s and 68°C 5 min) with ca. 400 pg/μL DNA in 20 μL PCR solution, using Tks Gflex DNA Polymerase (Takara Bio Inc., Otsu, Japan).
In order to make sure the sequence of scaffold 6 of V. carteri f. nagariensis EVE genome, the sequence between bases 934,933–943,805 of scaffold 6 was amplified from total DNA of that strain via PCR using a TaKaRa LA Taq with GC I buffer (Takara Bio Inc.) and specific primers (eveFZ, eveRJ, eveFX, eveRD, eveFV, eveRT, asmb81_F4, asmb82_R2; S2 Table) with ca. 150 pg/μL DNA in 20 μL PCR solution, for 35 cycles of 94°C 20s, 53–55°C 30s and 72°C 2–5 min, followed by 72°C for 7 minutes. Each PCR product was purified using an illustra GFX PCR DNA and Gel Band Purification Kit (GE Healthcare UK Ltd., Buckinghamshire, UK) and directly sequenced on an ABI PRISM 3130xl Genetic Analyzer (ABI Life Technologies, Carlsbad, CA) using a BigDye Terminator Cycle Sequencing Ready Reaction Kit version 3.1 (Life Technologies) and internal sequencing primers (S2 Table).
For sequencing the rickettsial gene-like sequence of other V. carteri strains, genomic PCR was performed using various combinations of the rickettsial gene and gene-like sequence-specific primers (S2 Table). These primers were appropriately designed by reference to such sequences, as were primers amplifying previously determined 16S rRNA gene sequences of rickettsial endosymbionts (accession numbers: AB688628, AB688629, and AB861537) [11],[12]. PCR was performed with ca. 6–400 pg/μL DNA in 20 μL PCR solution, with 35 cycles of 94°C 20s, 53–57°C 30s and 72°C 2–5 min, followed by 72°C for 7 minutes. PCR products were directly sequenced as described above. In order to determine sequences around the murB-like sequence, vectorette PCR was also performed as described in Ko et al. [34] on the total DNA of V. carteri f. weismannia strain UTEX 2170, using TaKaRa LA Taq with GC I Buffer and the restriction enzymes EcoRI (TOYOBO Co., Ltd., Osaka, Japan) and ApoI (New England Biolabs, Ipswich, MA). PCR products were directly sequenced as described above.
Detection of rickettsial gene and gene-like sequence by genomic PCR and semi-quantitative PCR
For confirming the detection of the rickettsial gene and gene-like sequence, genomic PCR was re-performed on total DNAs of V. carteri strains using the rickettsia-specific primer sets (16S rRNA 5′-region: eveFC and eveRD; 16S rRNA 3′-region: enFN and enRG; murB: murB-FP and murB-RK2; ddlB: ddlB-FQ and ddlB-RH2; 18S rRNA gene as positive control: 18S-FA and 18S-RD; see S2 Table), with 35 cycles of 94°C 20s, 55°C 30s and 72°C 40 sec, followed by 72°C for 7 minutes. An initial DNA concentration of PCR solution was ca. 2–3 pg/μL in 20 μL PCR solution. Total DNA of Chlamydomonas reinhardtii cc-503 was used as negative control; in the Chlamydomonas reinhardtii genome data (version 5.5, not masked) on Phytozome, no sequences similar to the rickettsial 16S rRNA gene, murB, ddlB and ftsQ were detected by a BLASTN search (E-values≤1.0e-50) using sequences of the rickettsial endosymbiont of C. cerasiformis strain NIES-425 as queries.
Semi-quantitative genomic PCR was also performed on total DNAs of V. carteri strains and Chlamydomonas reinhardtii CC-503 (as negative control), using TaKaRa LA Taq with GC Buffer I, and the same specific primer sets as the genomic PCR described above, with 27 cycles of 94°C 20s, 55°C 30s and 72°C 40 sec, followed by 72°C for 7 minutes and with a modification that the actin gene was amplified as a control (primers ONact1 and ONact2 for V. carteri and ONact1_CR and CR_IDA5_R3 for Chlamydomonas reinhardtii were used; see S2 Table) instead of 18S rRNA gene. An initial DNA concentration of PCR solution was ca. 2–3 pg/μL in 20 μL PCR solution.
Phylogenetic analysis
The 16S rRNA gene-like sequences of V. carteri were aligned using ARB software [35] with a data matrix that has been described previously [12], modified by addition of the following operational taxonomic units (OTUs): an endosymbiont of Euplotes octocarinatus (accession number: FR823004); an endosymbiont of Spirostomum sp. (FR822998); an endosymbiont of Paramecium caudatum (FR822997); and an endosymbiont of Diophrys oligothrix DS12/4 (FR823001). Alignment was corrected manually (S1 File; also available from TreeBASE [http://treebase.org/treebase-web/home.html; study ID: 16773]) by reference to secondary structure.
The murB and ddlB gene-like sequences of V. carteri were manually aligned with the murB and ddlB nucleotide sequences of bacteria belonging to the family Rickettsiaceae, including those of the preliminary genomic sequence of the C. cerasiformis strain NIES-425 endosymbiont and sequences obtained from total DNAs of P. japonica strain NIES-577 and V. carteri f. weismannia strain UTEX 2180 (S4 Table). These nucleotide sequences were next converted to translated amino acid sequences (S1 File; also available from TreeBASE [study ID: 16773]).
Phylogenetic analyses of 16S rRNA gene/gene-like sequences, translated murB, translated ddl, and combined [translated murB and ddlB] genes/gene-like sequences, were performed using both ML and MP methods, employing PhyML 3.0 [36] and PAUP 4.0b10 [37], respectively, with 1,000 bootstrap replications. In addition, 16S rRNA genes/gene-like sequences were subjected to BI testing using MrBayes 3.2 [38]. For both ML analyses and BI, the GTR+gamma+I model was selected by jModelTest 2 [39],[40] to analyze the data matrix of 16S rRNA genes/gene-like sequences; and the CpREV+gamma, JTT+gamma+I+F, and JTT+gamma+I+F models were selected by ProtTest3 [39],[41] to analyze the the data matrixes of translated murB, ddlB, and combined genes/gene-like sequences, respectively.
The nuclear rDNA ITS-2 sequences of V. carteri strains and V. obversus strain UTEX 1865 were aligned based on secondary structures, predicted using the RNA Folding Form on the mFold Web Server (http://mfold.rna.albany.edu/?q=mfold) [42]; revised based on the data of previous studies [43],[44]; and drawn using VARNA 3.9 [45] (S2 File). Phylogenetic analyses of aligned sequences (S1 File; also available from TreeBASE [study ID: 16773]) were performed as described by Nozaki et al. [46].
Supporting Information
S1 Fig. Somatic cells of five Volvox carteri strains stained with DAPI.
Vertical panels show the same cells shown at the same magnification, composed of epifluorescence images (A-E) and Nomarski differential interference images (F-J). The arrow, ‘n’ and ‘p’ indicate the chloroplast nucleoid, host cell nuclei and pyrenoid respectively. Scale bar = 10 μm. Any bacteria-like rod-shaped bodies were not observed in the cells of f. weismannia strain UTEX 1874 (A, F), f. nagariensis strain UTEX 1886 (B, G), f. nagariensis strain UTEX 2903 (C, H) and f. weismannia strain UTEX 2904 (D, I). On the other hand, the bacterial endosymbionts (arrowheads) were observed in the cell of f. weismannia strain UTEX 2180 (E, J) as rod-shaped fluorescent bodies as observed previously [12].
https://doi.org/10.1371/journal.pone.0116192.s001
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S2 Fig. Detection of 16S rRNA gene of the Rickettsiaceae in Volvox carteri strains by genomic PCR.
PCR amplification using the forward primer eveFC and reverse primer enRB (specific 16S rRNA primers specific to the bacteria belonging to the hydra group, see S2 Table) corresponds the presence or absence of rickettsial endosymbionts. EVE (lacking rickettsial endosymbiont) and UTEX 2180 (having rickettsial endosymbiont) are shown as negative and positive controls respectively. As a PCR control, the eukaryotic 18S rRNA gene was amplified as described previously [12].
https://doi.org/10.1371/journal.pone.0116192.s002
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S3 Fig. Detection of rickettsial gene-like sequences in 13 strains of Volvox carteri.
Rickettsial gene-like sequences were amplified via genomic PCR using rickettsia-specific primer sets (see Materials and Methods). For PCR amplification, 12 endosymbiont-lacking strains of V. carteri, endosymbiont-containing V. carteri f. weismannia strain UTEX 2180 (positive control) and Chlamydomonas reihnardtii strain CC-503 (negative control) were used. As a control, the eukaryotic 18S rRNA gene was amplified.
https://doi.org/10.1371/journal.pone.0116192.s003
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S4 Fig. Phylogenetic positions of rickettsial murB gene-like sequences from endosymbiont-lacking strains of Volvox carteri.
The tree was inferred based on translated rickettsial murB genes and gene-like sequences (227 amino acid sites) from endosymbiont-lacking strains of V. carteri (boldface), with 26 translated murB sequences from bacteria and possible endosymbionts (En) of algal hosts in the family Rickettsiaceae, using the maximum-likelihood (ML) method. Bootstrap values (≥50%) for the ML and maximum parsimony analyses are indicated at the respective nodes. The scale bar corresponds to 0.1 amino acid substitutions per position.
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S5 Fig. Phylogenetic positions of rickettsial ddlB gene-like sequences from endosymbiont-lacking strains of Volvox carteri.
The tree was inferred based on translated rickettsial ddlB genes and gene-like sequences (361 amino acid sites) from endosymbiont-lacking strains of V. carter (boldface) with 28 translated ddlB sequences from bacteria and possible endosymbionts (En) of algal hosts in the family Rickettsiaceae, using the maximum-likelihood (ML) method. Bootstrap values (≥50%) for the ML and maximum parsimony analyses are indicated at the respective nodes. The scale bar corresponds to 0.1 amino acid substitutions per position.
https://doi.org/10.1371/journal.pone.0116192.s005
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S1 File. Alignments of three rickettsial genes/gene-like sequences (16S rRNA, murB and ddlB) and nuclear ribosomal DNA internal transcribed spacer 2 region used in phylogenetic analyses.
The sequences of murB and ddlB are translated. Combined alignment of translated murB and ddlB is also shown. These alignments are also available from TreeBASE (http://treebase.org/treebase-web/home.html; study ID: 16773).
https://doi.org/10.1371/journal.pone.0116192.s006
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S2 File. Whole secondary structure of nuclear ribosomal DNA internal transcribed spacer 2 region of the strains of Volvox obversus and V. carteri.
The structure was predicted and drawn as described in Materials and Methods. The U-U mismatch in helix 2 (arrowheads) and the UGGU motif on the 5′ side near the apex of helix 3 (boldface) are the universally conserved features [43]. Among the ITS-2 sequences of V. carteri f. nagariensis strains, one nucleotide of UTEX 1886 and NIES-398, and three of UTEX 2903 are different from those of strains EVE and NIES-397 (shown around the structures). ITS-2 sequences of V. carteri f. weismannia strains UTEX 1874 and UTEX 2904 differ from that of V. carteri f. weismannia strain UTEX 2180 in missing of one pair of “AU” from AU repeats in helix 4 (asterisk).
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S1 Table. The high scoring hits of Volvox carteri f. nagariensis strain EVE genome sequence by BLASTN searches using Carteria cerasiformis rickettsial endosymbiont draft genome.
BLASTN searches were performed on Phytozome v9.1, using 81 contigs (>5 kb) from preliminary genome assembly database of C. cerasiformis NIES-425 rickettsial endosymbiont. Hits with the E-value ≤1.0e-50 of BLASTN searches and the information of ftsQ-like sequence found in following BLASTN search in scaffold 6 of EVE genome are shown.
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S2 Table. The list of primers used in genomic PCR, semi-quantitative genomic PCR and sequencing of this study.
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S3 Table. List of Volvox carteri and other algal strains used in this study.
DDBJ/EMBL/GenBank accession numbers of nuclear ribosomal DNA internal transcribed spacer regions and rickettsial gene-like sequences determined in this study are also shown.
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S4 Table. DDBJ/EMBL/GenBank accession numbers of the rickettsial murB and ddlB genes/gene-like sequences used in this study.
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Author Contributions
Conceived and designed the experiments: KK YH TH TK SH SM HN. Performed the experiments: KK YH TS TK SH SM HN. Analyzed the data: KK TS TK HN. Wrote the paper: KK HN.
References
- 1.
Dumler JS, Walker DH (2005) Order II. Rickettsiales Gieszczykiewicz 1939, 25AL emend. Dumler, Barbet, Bekker, Dasch, Palmer, Ray, Rikihisa and Rurangirwa 2001, 2156. In: Garrity GM, Boone DR, Castenholz RW, editors. Bergey’s manual of systematic bacteriology. Volume 2. 2nd edition. East Lansing (MI): Springer. https://doi.org/10.1097/01.NURSE.0000459798.79840.95 pmid:25585219
- 2. Engelstädter J, Hurst GDD (2009) The ecology and evolution of microbes that manipulate host reproduction. Annu Rev Ecol Evol Syst 40: 127–149.
- 3. Ferla MP, Thrash JC, Giovannoni SJ, Patrick WM (2013) New rRNA gene-based phylogenies of the Alphaproteobacteria provide perspective on major groups, mitochondrial ancestry and phylogenetic instability. PLoS ONE 8: e83383. pmid:24349502
- 4. Kikuchi Y, Sameshima S, Kitade O, Kojima J, Fukatsu T (2002) Novel clade of Rickettsia spp. from leeches. Appl Environm Microbiol 68: 999–1004. pmid:11823253
- 5. Kikuchi Y, Fukatsu T (2005) Rickettsia infection in natural leech populations. Microb Ecol 49: 265–271. pmid:15965725
- 6. Fraune S, Bosch TCG (2007) Long-term maintenance of species-specific bacterial microbiota in the basal metazoan Hydra. Proc Natl Acad Sci USA 104: 13146–13151. pmid:17664430
- 7. Ferrantini F, Fokin SI, Modeo L, Andreoli I, Dini F, et al. (2009) “Candidatus Cryptoprodotis polytropus,” a novel Rickettsia-like organism in the Ciliated protist Pseudomicrothorax dubius (Chiliophora, Nassophorea). J Eukaryot Microbiol 56: 119–129. pmid:19457052
- 8. Schrallhammer M, Ferrantini F, Vannini C, Galati S, Schweikert M, et al. (2013) ‘Candidatus Megaira polyxenophila’gen. nov., sp. nov.: considerations on evolutionary history, host range and shift of early divergent rickettsiae. PLoS ONE 8: e72581. pmid:23977321
- 9. Vannini C, Boscaro V, Ferrantini F, Benken KA, Mironov TI, et al. (2014) Flagellar movement in two bacteria of the family Rickettsiaceae: a re-evaluation of motility in an evolutionary perspective. PLoS ONE 9: e87718. pmid:24505307
- 10. Weinert LA, Werren JH, Aebi A, Stone GN, Jiggins FM (2009) Evolution and diversity of Rickettsia bacteria. BMC Biol 7: 6–20. pmid:19187530
- 11. Kawafune K, Hongoh Y, Hamaji T, Nozaki H (2012) Molecular identification of rickettsial endosymbionts in the non-phagotrophic volvocalean green algae. PLoS ONE 7: e31749. pmid:22363720
- 12. Kawafune K, Hongoh Y, Nozaki H (2014) A rickettsial endosymbiont inhabiting the cytoplasm of Volvox carteri (Volvocales, Chlorophyceae). Phycologia 53: 95–99.
- 13. Hollants J, Leliaert F, Verbruggen H, Willems A, De Clerck O (2013) Permanent residents or temporary lodgers: characterizing intracellular bacterial communities in the siphonous green alga Bryopsis. Proc R Soc Lond B Biol Sci 280: 20122659.
- 14.
Yu XJ, Walker DH (2012) Rickettsia and Rickettsial diseases. In: Morse SA, editor. Bioterrorism. InTech. pp. 179–192
- 15. Caspi-Fluger A, Inbar M, Mozes-Daube N, Katzir N, Portnoy V, et al. (2011) Horizontal transmission of the insect symbiont Rickettsia is plant-mediated. Proc R Soc Lond B Biol Sci 279: 1791–1796.
- 16. Herron MD, Hackett JD, Aylward FO, Michod RE (2009) Triassic origin and early radiation of multicellular volvocine algae. Proc Natl Acad Sci USA 106: 3254–3258. pmid:19223580
- 17. Ferris P, Olson BJSC, De Hoff PL, Douglass S, Casero D, et al. (2010) Evolution of an expanded sex-determining locus in Volvox. Science 328: 351–354. pmid:20395508
- 18. Prochnik SE, Umen J, Nedelcu AM, Hallmann A, Miller SM, et al. (2010) Genomic analysis of organismal complexity in the multicellular green alga Volvox carteri. Science 329: 223–226. pmid:20616280
- 19. Miller SM, Schmitt R, Kirk DL (1993) Jordan, an active Volvox transposable element similar to higher plant transposons. Plant Cell 5: 1125–1138. pmid:8400878
- 20. Goodstein DM, Shu S, Howson R, Neupane R, Hayes RD, et al. (2012) Phytozome: a comparative platform for green plant genomics. Ncl Acids Res 40: D1178–D1186. pmid:22110026
- 21. Coleman AW (1999) Phylogenetic analysis of “Volvocacae” for comparative genetic studies. Proc Natl Acad Sci USA 96: 13892–13897. pmid:10570169
- 22. Mingorance J, Tamames J, Vicente M (2004) Genomic channeling in bacterial cell division. J Mol Recognit 17: 481–487. pmid:15362108
- 23. Kondo N, Nikoh N, Ijichi N, Shimada M, Fukatsu T (2002) Genome fragment of Wolbachia endosymbiont transferred to X chromosome of host insect. Proc Natl Acad Sci USA 99: 14280–14285. pmid:12386340
- 24. Gladyshev EA, Meselson M, Arkhipova IR (2008) Massive horizontal gene transfer in bdelloid rotifers. Science 320: 1210–1213. pmid:18511688
- 25. Driscoll T, Gillespie JJ, Nordberg EK, Azad AF, Sobral BW (2013) Bacterial DNA sifted from the Trichoplax adhaerens (Animalia: Placozoa) genome project reveals a putative rickettsial endosymbiont. Genome biol evol 5: 621–645. pmid:23475938
- 26. Sato T, Kuwahara H, Fujita K, Noda S, Kihara K, Yamada A, et al. (2014) Intranuclear verrucomicrobial symbionts and evidence of lateral gene transfer to the host protist in the termite gut. ISME J 8: 1008–1019. pmid:24335826
- 27. Nikoh N, Nakabachi A (2009) Aphids acquired symbiotic genes via lateral gene transfer. BMC Biol 7: 12. pmid:19284544
- 28. Nikoh N, McCutcheon JP, Kudo T, Miyagishima SY, Moran NA, Nakabachi A (2010) Bacterial genes in the aphid genome: absence of functional gene transfer from Buchnera to its host. PLoS Genet 6: e1000827. pmid:20195500
- 29. Kasai F, Kawachi M, Erata M, Mori F, Yumoto K, et al. (2009) NIES-Collection. List of Strains. 8th Edition. Jpn J Phycol (Sôrui) 57: suppl.1–350, pls1–7. pmid:23136238
- 30.
Harris EH (1989) The Chlamydomonas Source Book. Academic Press, San Diego, CA. pmid:25144100
- 31. Setohigashi Y, Hamaji T, Hayama M, Matsuzaki R, Nozaki H (2011) Uniparental inheritance of chloroplast DNA is strict in the isogamous Volvocalean Gonium. PLoS ONE 6: e19545. pmid:21559302
- 32. Hiraide R, Kawai-Toyooka H, Hamaji T, Matsuzaki R, Kawafune K, et al. (2013) The evolution of male-female sexual dimorphism predates the gender-based divergence of the mating locus gene MAT3/RB. Mol Biol Evol 30: 1038–1040. pmid:23364323
- 33. Altschul SF, Madden TL, Schaffer AA, Zhang J, Zhang Z, et al. (1997) Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res 25: 3389–3402. pmid:9254694
- 34. Ko WY, David RM, Akashi H (2003) Molecular phylogeny of the Drosophila melanogaster species subgroup. J Mol Evol 57: 562–573. pmid:14738315
- 35. Ludwig W, Strunk O, Westram R, Richter L, Meier H, et al. (2004) ARB: a software enviroment for sequence data. Ncleic Acids Res 32: 1363–1371. pmid:14985472
- 36. Guindon S, Dufayard JF, Lefort V, Anisimova M, Hordijk W, et al. (2010) New algorithms and methods to estimate maximum-likelihood phylogenies: assessing the performance of PhyML 3.0. Syst Biol 59: 307–321. pmid:20525638
- 37.
Swofford DL (2003) PAUP*. Phylogenetic analysis using parsimony (*and other methods). Version 4.0b10. Sunderland, MA: Sinauer Associates. pmid:25057689
- 38. Ronquist F, Teslenko M, van der Mark P, Ayres DL, Darling A, et al. (2012) MrBayes 3.2: efficient Bayesian phylogenetic inference and model choice across a large model space. Syst Biol 61: 539–542. pmid:22357727
- 39. Darriba D, Taboada GL, Doallo R, Posada D (2012) jModelTest 2: more models, new heuristics and parallel computing. Nat Methods 9: 772–772. pmid:22847109
- 40. Guindon S, Gascuel O (2003) A simple, fast, and accurate algorithm to estimate large phylogenies by maximum likelihood. Syst Biol 52: 696–704. pmid:14530136
- 41. Darriba D, Taboada GL, Doallo R, Posada D (2011) ProtTest 3: fast selection of best-fit models of protein evolution. Bioinformatics 27: 1164–1165. pmid:21335321
- 42. Zuker M (2003) Mfold web server for nucleic acid folding and hybridization prediction. Nucleic Acids Res 31: 3406–3415. pmid:12824337
- 43. Coleman AW, Mai JC (1997) Ribosomal DNA and ITS-2 sequence comparisons as a tool for predicting genetic relatedness. J Mol Evol 45: 168–177. pmid:9236277
- 44. Caisová L, Marin B, Melkonian M (2013) A consensus secondary structure of ITS2 in the Chlorophyta identified by phylogenetic reconstruction. Protist 164: 482–496. pmid:23770573
- 45. Darty K, Denise A, Ponty Y (2009) VARNA: Interactive drawing and editing of the RNA secondary structure. Bioinformatics 25: 1974–1975. pmid:19398448
- 46. Nozaki H, Yamada TK, Takahashi F, Matsuzaki R, Nakada T (2014) New “missing link” genus of the colonial volvocine green algae gives insights into the evolution of oogamy. BMC Evol Biol 14: 37. pmid:24589311