F1000ResearchF1000Research2046-1402F1000 Research LimitedLondon, UK10.12688/f1000research.21551.1Research ArticleArticlesWidespread use of the “ascidian” mitochondrial genetic code in tunicates
[version 1; peer review: 2 approved]
PichonJulienConceptualizationFormal AnalysisFunding AcquisitionInvestigationVisualizationWriting – Original Draft PreparationWriting – Review & Editinghttps://orcid.org/0000-0002-8065-002412LuscombeNicholas M.Funding AcquisitionProject AdministrationSupervisionWriting – Original Draft PreparationWriting – Review & Editinghttps://orcid.org/0000-0001-5293-4778134PlessyCharlesConceptualizationData CurationFormal AnalysisInvestigationMethodologyProject AdministrationSupervisionVisualizationWriting – Original Draft PreparationWriting – Review & Editinghttps://orcid.org/0000-0001-7410-6295a1
Genomics and Regulatory Systems Unit, Okinawa Institute of Science and Technology Graduate University, Onna-son, Okinawa, 904-0495, Japan
Université de Paris, Paris, France
The Francis Crick Institute, London, NW1 1AT, UK
Genetics Institute, University College London, London, WC1E 6BT, UKcharles.plessy@oist.jp
Background: Ascidians, a tunicate class, use a mitochondrial genetic code that is distinct from vertebrates and other invertebrates. Though it has been used to translate the coding sequences from other tunicate species on a case-by-case basis, it is has not been investigated whether this can be done systematically. This is an important because a) some tunicate mitochondrial sequences are currently translated with the invertebrate code by repositories such as NCBI GenBank, and b) uncertainties about the genetic code to use can complicate or introduce errors in phylogenetic studies based on translated mitochondrial protein sequences.
Methods: We collected publicly available nucleotide sequences for non-ascidian tunicates including appendicularians such as
Oikopleura dioica, translated them using the ascidian mitochondrial code, and built multiple sequence alignments covering all tunicate classes.
Results: All tunicates studied here appear to translate AGR codons to glycine instead of serine (invertebrates) or as a stop codon (vertebrates), as initially described in ascidians. Among Oikopleuridae, we suggest further possible changes in the use of the ATA (Ile
→ Met) and TGA (Trp
→ Arg) codons.
Conclusions: We recommend using the ascidian mitochondrial code in automatic translation pipelines of mitochondrial sequences for all tunicates. Further investigation is required for additional species-specific differences.
TunicateOikopleuraGenetic codeMitochondriaCytochrome oxidase subunit IOkinawa Institute of Science and Technology Graduate UniversityMinistère de l'Enseignement Supérieur, de la Recherche Scientifique et de la Formation des CadresJP’s internship at OIST was supported by the French Ministry for Education and Research and by laboratory funding from OISTThe funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.Introduction
Tunicates are marine animals that have acquired the capacity to produce cellulose by horizontal gene transfer approximately 500 million years ago (
Matthysse
et al., 2004;
Nakashima
et al., 2004). Together with vertebrates and cephalochordates, they belong to the chordate phylum, in which they share morphological features such as a muscular tail during larval stages. Phylogenetic studies place the tunicates as the closest living relatives of vertebrates (
Delsuc
et al., 2006). Tunicates can be subdivided in three classes: Thaliacea (free-swimming colonial species, for instance salps or dolioids), Appendicularia (free-swimming solitary species with an adult morphologically similar to the larval stage of other tunicates), and Ascidiacea (attached to solid substrates in their adult stage, for instance sea squirts). The relationship between these classes and therefore their mono- or paraphyly has been revised multiple times. For instance the 18S rRNA analysis of
Stach & Turbeville (2002) nested Appendicularia within Ascidiacea, but more recently
Delsuc
et al. (2018) placed them as sister groups using a multigene approach. The paraphyly of Ascidiacea is now widely accepted, as the above studies and others demonstrated that they contain the Thaliacea.
Mitochondrial genomes undergo major changes at the geological time scale due to their small size and clonal reproduction, including changes to their genetic code (
Osawa
et al., 1992). The first evidence that ascidians use a specific mitochondrial genetic code stemmed from observations that the cytochrome c oxidase subunit 1 (
Cox1) sequence from
Halocynthia roretzi (
Yokobori
et al., 1993) and the
Cox3 sequence of
Pyura stolonifera (
Durrheim
et al., 1993) are interrupted by stop codons if translated using the vertebrate mitochondrial code. Reassignment of AGR codons to glycine was later confirmed by the discovery of a glycine (Gly) tRNA in the
H. roretzi genome (
Yokobori
et al., 1999) and by the sequencing of its anticodon (U*CU) (
Kondow
et al., 1999). Apart from the AGR codons, the ascidian code is similar to the vertebrate and the invertebrate ones, with ATA assigned to methionine (Met) and TGA to tryptophan (Trp) (
Yokobori
et al., 1993).
This genetic code is known as the “ascidian” genetic code; however, it is also used by non-ascidian tunicates, such as the thaliacean
Doliolum nationalis (
Yokobori
et al., 2005). The possibility that this genetic code emerged earlier than tunicates was raised by the study of partial genome sequences of
Branchiostoma lanceolatum (
Delarbre
et al., 1997) leading to the proposition that AGR might encode Gly in cephalochordates. While this seemed to be supported by the discovery of a putative TCT (Gly) tRNA in the full mitochondrial genome of
B. lanceolatum (
Spruyt
et al., 1998), this hypothesis was later ruled out by an analysis of the related amphioxus
Branchiostoma floridae (
Boore
et al., 1999), and has not been reconsidered since. Finally, studies on the appendicularian branch showed compatibility between the mitochondrial sequence of
Oikopleura dioica and the ascidian code (
Denoeud
et al., 2010). Nevertheless, support for compatibility was not demonstrated explicitly for the ATA and TGA codons and the mitochondrial sequence of
O. dioica were not released in International Nucleotide Sequence Database Collaborations (INSDC) databanks.
Cox1 is the most conserved mitochondrial protein. Although no mitochondrial genome has been fully sequenced yet for appendicularians, partial
Cox1 sequences are present in the INSDC databanks for Oikopleuridae.
Sakaguchi
et al. (2017) reported that all
Oikopleura mitochondrial sequences (
AY116609–
AY116611 and
KF977307) may be contaminations from bacteria or cnidarians, and provided partial sequences for
Oikopleura longicauda in the same study. Partial mitochondrial sequences were published for
Bathochordaeus and
Mesochordaeus species by
Sherlock
et al. (2017). In addition,
Naville
et al. (2019) recently published draft genome for several appendicularian species. Therefore, to assess whether the ascidian mitochondrial code is used across the whole tunicate subphylum, we took advantage of these public data and prepared a curated alignment of Cox1 sequences comprising representatives of the major tunicate branches, to study the consensus sequences at conserved residues.
Methods
We identified
Cox1 and Cytochrome b (
Cob) gene sequences for
Oikopleura longicauda,
Mesochordaeus erythrocephalus and
Bathochordaeus stygius by screening published genome assemblies (
Naville
et al., 2019) with the partial Cox1 sequence of
O. longicaudaLC222754.1 (
Sakaguchi
et al., 2017) using
tblastn and the ascidian mitochondrial code (
-db_gencode=13) (
Gertz
et al., 2006). Mitochondrial genome sequences were then translated using the
cons and
getorf commands from EMBOSS (
Rice
et al., 2000), using the ascidian mitochondrial code.
We identified the circular contig
SCLD01101138.1 (length: 10,324 nt) as a potential mitochondrial genome, and translated
Cox1 from position 4530 to 6230. We also translated
Cob from 3697 to 4668.
We translated
Cox1 in contig
SCLF01725989.1 (length 7,034 nt) on reverse strand from position 1792 to 272. Using the same method with
O. longicauda’s Cob sequence as a bait, we also recovered a
Cob sequence from contig
SCLF01109548.1 (length 5,010 nt), reverse strand, 1604 to 2590.
We used the consensus of the published
B. stygius Cox1 sequences
KX599267.1 to
KX599281.1 from GenBank (
Sherlock
et al., 2017), to screen the genome and scaffold
SCLE01415711.1 (length 10,388 nt) gave a perfect hit. We translated
Cox1 from position 8054 to 6522 on the reverse strand, and a partial
Cob sequence from scaffold
SCLE01415711.1 (2319 to 2963, reverse strand). We also found a second fragment aligning well with C-terminal sequences between positions 2373 and 1978, but we did not include it due to the difficulty of resolving the overlap between both fragments. When screening with the
M. erythrocephalus Cox1 sequence recovered above, we found that another scaffold
SCLE01416475.1 gave a perfect hit, hinting at a possible contamination.
<italic toggle="yes">Oikopleura dioica</italic>
To assemble a
Cox1 sequence in
O. dioica, we downloaded expressed sequence tags (file
10_ESTall.txt) from Oikobase (
Danks
et al., 2012) and extracted hits matching the
O. longicauda sequence using
tblastn (see above). We then aligned and visualised the hits using
Clustal Omega (
Sievers
et al., 2011) and
SeaView (
Gouy
et al., 2009), filtering out those too short or introducing gap columns. Inspection of the alignment let us notice three possible haplotypes. We generated a consensus for each of them, translated them (see above) and trimmed the proteins sequences in order to match the length of the other reference sequences in the alignment. All variants found between the haplotypes were synonymous codons. We used the same methodology to generate a consensus for
Cob and translate it.
Translated
Cox1 and
Cob sequences were aligned using Clustal Omega (
Sievers
et al., 2011) and SeaView (
Gouy
et al., 2009). The alignments were post-processed using the
showalign -show=n command of EMBOSS (
Rice
et al., 2000) to show the differences to the inferred consensus. Graphical processing of the alignments were performed with Jalview (
Waterhouse
et al., 2009). The codon sequences encoding Cox1 and Cob of the tunicate species were then added aligned to the corresponding amino-acid (three lines per species, see
Extended data (
Plessy & Pichon, 2019)) and then the text files were transposed, so that each line would correspond to a single position in the alignment, and interrogated with custom Unix commands to compute the tables presented in this manuscript.
ResultsAGR encodes for Gly across all tunicates
We selected species according to sequence availability and to ensure coverage of the tunicate subphylum in a way that stays broad under the various hypotheses of monophyly or paraphyly for its major groups. For ascidians, we have included the phlebobranchian
Ciona intestinalis, the aplousobranchian
Clavelina oblonga and the pyurid stolidobranchian
Halocynthia roretzi. For thaliaceans, we selected
Doliolum nationalis and
Salpa thompsoni. For appendicularians we selected
Oikopleura dioica,
Oikopleura longicauda,
Bathochordaeus stygius and
Mesochordaeus erythrocephalus. We ensured that all tunicate sequences were translated with the ascidian mitochondrial genetic code. Lastly, we included outgroup sequences from
Caenorhabditis elegans and
Branchiostoma lanceolatum (invertebrate mitochondrial code) and from
Mus musculus (vertebrate mitochondrial code) to better highlight conserved amino acid positions. In
Figure 1, we illustrate the relation between these species based on the phylogeny of
Naville
et al. (2019) for appendicularians and of
Delsuc
et al. (2018) for the other tunicates. We prepared
Cox1 sequences from the selected species using mitochondrial genomes (for ascidians, thaliaceans, and outgroups), from draft genomes in which we found a putative mitochondrial contig after screening with a partial or a related
Cox1 sequence (for
O. longicauda,
B. stygius, and
M. erythrocephalus) and from EST sequences (for
O. dioica). We aligned the translated Cox1 and Cob sequences (
Figure 2 and
Figure 3) and inspected the positions where all species use the same amino acid. Conserved glycines supported the use of AGR codons across the whole tunicate clade. We confirmed this observation with
Cob sequences obtained with the same method.
Left: Cladogram illustrating the relations between the species selected in study.
Different branch colors indicate different mitochondrial genetic codes. Codon assignments with an equal sign indicate how the nucleotide sequences were translated. Codon assignments with a question mark indicate a possible finding, but were not used for translation. Ascidians, in which the AGR to Gly codon reassignment was initially discovered, are highlighted among the tunicates. Right: codon sequence of
Cox1 genes on positions where proposed changes of genetic code would make all species use the same amino acid.
Sequence alignment of Cox1 proteins.
White stars indicate conserved cysteines when at least one tunicate uses an AGR codon. Black stars indicate positions suggesting a different genetic code.
Sequence alignment of Cob proteins.
White stars indicate conserved cysteines when at least one tunicate uses an AGR codon. Black stars indicate positions suggesting a different genetic code.
Possible lineage specific use of ATA Ile and TGA Arg codons
We then searched for positions where a single tunicate species differed from the other sequences with the same replacement amino acid more than once. We found multiple cases of methionine being replaced by isoleucine and arginine replaced by tryptophan in
O. longicauda and
B. stygius (
Figure 2). Given their phylogenetic proximity, we grouped the two species in the analysis below and we calculated the number of mismatches to the other sequences. We redefined a position as “conserved” if there is at most one mismatch from one sequence to the others.
M. erythrocephalus does not seem to use ATA codons and
O. longicauda and
B. stygius use ATA codons at positions where all other species had an isoleucine (Ile) (
Table 1 and
Table 2). In the ancestral invertebrate mitochondrial code and the sister vertebrate code, ATA encodes Met. Although Met and Ile both have hydrophobic side chains that often can substitute for each other, this also suggests a change of the genetic code. Evidence for this is that 1) non-appendicularian species do not display ATA codons at positions where all other species encode Ile; 2) the change would be parsimonious as
O. longicauda,
B. stygius and
M. erythrocephalus are more closely related to each other than to
O. dioica (
Naville
et al., 2019); and 3) these three species never have ATA codons at positions where Met is conserved in every species (in contrast to
O. dioica). Furthermore, reversion of the ATA codon to Ile have occurred in other branches of the tree of Life, for instance in echinoderms (
Jacobs
et al., 1988). Finally, inspection of a partial
Cox1 sequence of the related
Bathochordaeus charon (KT881544.1) provided one extra instance of an ATA codon at a conserved Ile position.
ATN codons in
<italic toggle="yes">Cox1</italic> in Oikopleuridae.
O. dio.
O. lon.
B. sty.
M. ery.
ATA number
22
12
16
0
ATC number
3
8
0
2
ATG number
14
34
25
33
ATT number
29
18
21
38
ATA on cons. Met
5
0
0
0
ATA on cons. Ile
0
4
2
0
ATN codons in
<italic toggle="yes">Cob</italic> in Oikopleuridae.
O. dio.
O. lon.
B. sty.
M. ery.
ATA number
6
9
9
0
ATC number
5
2
1
2
ATG number
9
9
8
16
ATT number
21
11
11
22
ATA on cons. Met
0
0
0
0
ATA on cons. Ile
0
1
1
0
The TGA codon is known to encode tryptophan (Trp) in vertebrate, invertebrate and ascidian mitochondria (
Fox, 1979). We found that
B. stygius uses TGA at positions where all other species would encode Arg (
Table 3 and
Table 4). This is surprising as these two amino acids are unlikely to functionally substitute for each other.
O. longicauda does not use TGA codons, and
M. erythrocephalus does not use TGA at conserved Arg, although it is found at a position where all other species encode for Arg except
C. elegans which encodes lysine, the other positively charged amino-acid. This again suggests a possible change of genetic code, although the numbers are currently too small to draw a solid conclusion.
TGR codons in
<italic toggle="yes">Cox1</italic> in Oikopleuridae.
O. dio.
O. lon.
B. sty.
M. ery.
TGA number
2
0
3
1
TGG number
13
16
19
16
TGA on cons. Trp
1
0
0
0
TGA on cons. Arg
0
0
2
0
TGR codons in
<italic toggle="yes">Cob</italic> in Oikopleuridae.
O. dio.
O. lon.
B. sty.
M. ery.
TGA number
3
0
2
1
TGG number
4
7
4
5
TGA on cons. Trp
1
0
0
0
TGA on cons. Arg
0
0
1
0
Discussion
We extracted
Cox1 and
Cob sequences of four different appendicularians from public databases. As a nucleotide sequence,
Cox1 might be useful for mining databases of molecular barcodes sequenced from the environment, or for studies of population diversity within a species. As a protein sequence, Cox1 might be useful for refining the phylogeny of appendicularians. However, a translation code needs to be chosen.
Our alignments of tunicate Cox1 and Cob protein sequences support the view that all tunicates translate AGR codons as Gly (although this conclusion might be limited by the lack of coverage for the Kowalevskiidae and Fritillariidae families). While our analysis suggests that the last common ancestor of the tunicates used the “ascidian” code, it is not possible to conclude that all contemporary tunicates still do, as we found discrepancies on other conserved residues that could be explained by a genetic code change of ATA and TGA codons within a sub-clade of the appendicularians containing
M. erythrocephalus,
O. longicauda and
B. stygius.
The “ascidian” genetic code is table number 13 in the NCBI protein database, where it is used to translate sequences from ascidians and non-ascidian tunicates, for instance
D. nationalis. However for appendicularians, the NCBI currently applies the invertebrate table (number 5). This has the consequences of turning Gly to Ser at functionally important positions. Therefore, the ascidian is probably a more appropriate default. At present, it is unclear whether some appendicularians have additional changes; however, the accurate translation of AGR codons to Gly would nonetheless reduce the amount of error in translated protein sequences.
To confirm a change of genetic code, it is necessary to detect corresponding changes in the respective tRNAs. This beyond reach for the present study because the mitochondrial genomic sequences that we used are extracted from draft genome sequences that may be incomplete, or even contain contaminations (see
B. stygius in the Methods section). As a result, we also cannot entirely rule out the possibility that we have examined pseudogenes, although the high conservation found in the alignments suggest this in unlikely. For all these reasons, it is necessary to sequence full-length mitochondrial genomes from appendicularians.
Conclusions
Our alignments of translated mitochondrial sequences suggest that the last common ancestor of living tunicates may have already used the “ascidian” genetic code. Thus, we recommend the use of that code instead of the “invertebrate” one for all tunicates in automatic translation pipelines, with the caveat that additional changes might be found in appendicularians. This observation is a reminder that in biology, exception is the rule, and that each time a mitochondrial sequence is extracted from a species for the first time, it is important to carefully examine its genetic code.
Data availabilityUnderlying data
All data underlying the results are available as part of the article and no additional source data are required.
Extended data
Zenodo: Aligned Cox1 and Cob sequences from Oikopleura dioica and other tunicates.
https://doi.org/10.5281/zenodo.3490310 (
Plessy & Pichon, 2019).
This project contains alignment files and descriptions of how the files were generated.
Extended data are available under the terms of the
Creative Commons Zero “No rights reserved” data waiver (CC0 1.0 Public domain dedication).
Acknowledgements
We thank the OIST’s Scientific Computing & Data Analysis Section for their support, and Ferdinand Marlétaz for critical comments on our manuscript.
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838187810.1007/bf0240730110.5256/f1000research.23747.r59671Reviewer response for version 1LiYuanning1Refereehttps://orcid.org/0000-0002-2206-5804
Department of Ecology and Evolutionary Biology, Yale University, New Haven, CT, USA
Competing interests: No competing interests were disclosed.
Pichon
et al. conducted a study by comparing two mt genes across tunicates and recovered conserved tunicate-specific mt codon usage and potential Oikopleuridae-codon. The writing of the manuscript is clear and easy to follow. The methods are also valid and the findings should be interesting and important to the field. However, there are a few things I suggest to incorporate in the current draft.
In the introduction, the authors mainly discussed the tunicate genetic codon, but we already know there are more codon changes in deuterostomes (e.g. Hemichordates contain two mt genetic codons). So it would be better to incorporate this part of the introduction to make sure readers understand there are many mt codon changes within deuterostomes.
The authors also briefly discussed the possible change of tRNA structures responsible for codon change. Is it possible to extract tRNA sequences from available tunicate transcriptomic data and compare them to the existing ones? I am also fine with this if that is beyond the scope of this manuscript.
Is the work clearly and accurately presented and does it cite the current literature?
Yes
If applicable, is the statistical analysis and its interpretation appropriate?
Yes
Are all the source data underlying the results available to ensure full reproducibility?
Yes
Is the study design appropriate and is the work technically sound?
Yes
Are the conclusions drawn adequately supported by the results?
Yes
Are sufficient details of methods and analysis provided to allow replication by others?
Yes
Reviewer Expertise:
Evolutionary genomics and phylogenetics in marine invertebrates.
I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard.
PlessyCharlesOkinawa Institute of Science and Technology Graduate University, Japan
Competing interests: No competing interests were disclosed.
2732020
We thank the reviewer for their 2 suggestions.
1) “
To make sure readers understand there are many mt codon changes within deuterostomes”, we are adding the following text and references to our introduction:
In animals, alternative genetic codes have first been found in large clades, for instance echinoderms (Himeno
et al., 1987) and hemichordates (Castresana
et al., 1998), but more recent works underline the presence of changes deeper in the phylogenetic tree, for instance within nematodes (Jacob
et al., 2009) and within hemichordates (Li
et al., 2019).
2) On whether it is “
possible to extract tRNA sequences from available tunicate transcriptomic data”: as absence of evidence is not evidence for absence, our standpoint is that a rigorous analysis using a reference mitochondrial genome will be preferable. We hope that our methods section, that points at genomic scaffolds that are potential drafts of mitochondrial genomes, will be useful to the researchers interested in pursuing this direction.
10.5256/f1000research.23747.r57710Reviewer response for version 1LemairePatrick1Refereehttps://orcid.org/0000-0003-4925-2009
Montpellier Cell Biology Research Center (CRBM), CNRS, University of Montpellier, Montpellier, France
Competing interests: No competing interests were disclosed.
In this short article Pichon and colleagues use publicly available molecular datasets, mostly partial mitochondrial genomes, to re-explore the mitochondrial genetic code across tunicates, based on the analysis of the Cox1 and Cob genes.
Their data suggest that the AGR codon was already translated into Glycine in the last common ancestor of tunicates and that additional changes may have occured in some Oikopleuridae at least. The work is important because it shows that all tunicates, including appendicularians should be associated in Genbank to the "ascidian" genetic code (Table 13).
A limitation of the work, which the authors acknowledge, is that they could not identify the corresponding tRNAs in appendicularians. They therefore call for the sequencing of full-length mitochondrial genomes for appendicularians.
Is the work clearly and accurately presented and does it cite the current literature?
Yes
If applicable, is the statistical analysis and its interpretation appropriate?
Not applicable
Are all the source data underlying the results available to ensure full reproducibility?
Yes
Is the study design appropriate and is the work technically sound?
Yes
Are the conclusions drawn adequately supported by the results?
Yes
Are sufficient details of methods and analysis provided to allow replication by others?
Yes
Reviewer Expertise:
Tunicate embryology and genomics
I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard.