Comparative genomics of 10 new<i>Caenorhabditis</i>species

Stevens, Lewis; Félix, Marie‐Anne; Beltran, Toni; Braendle, Christian; Caurcel, Carlos; Fausett, Sarah; Fitch, David; Frézal, Lise; Gosse, Charlie; Kaur, Taniya; Kiontke, Karin; Newton, Matthew D.; Noble, Luke M.; Richaud, Aurélien; Rockman, Matthew V.; Sudhaus, Walter; Blaxter, Mark

doi:10.1002/evl3.110

Cited by 132 publications

(166 citation statements)

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“…Chlamydomonas species, but addressing this is a question of taxonomy rather than sequencing 705 effort. This is somewhat analogous to the past situation for Caenorhabditis, where only very 706 recent advances in ecological knowledge have led to a rapid increase in the number of sampled 707 species and sequenced genomes (Stevens et al 2019). We hope that this study will encourage 708…”

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confidence: 59%

Comparative genomics ofChlamydomonas

Craig

Hasan

Ness

et al. 2020

Preprint

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1 2 Despite its fundamental role as a model organism in plant sciences, the green alga 3Chlamydomonas reinhardtii entirely lacks genomic resources for any closely related species, 4 obstructing its development as a study system in several fields. We present highly contiguous 5 and well-annotated genome assemblies for the two closest known relatives of the species, 6Chlamydomonas incerta and Chlamydomonas schloesseri, and a third more distantly related 7 species, Edaphochlamys debaryana. We find the three Chlamydomonas genomes to be highly 8 syntenous with similar gene contents, although the 129.2 Mb C. incerta and 130.2 Mb C. 9 schloesseri assemblies are more repeat-rich than the 111.1 Mb C. reinhardtii genome. We 10 identify the major centromeric repeat in C. reinhardtii as an L1 LINE transposable element 11 homologous to Zepp (the centromeric repeat in Coccomyxa subellipsoidea) and infer that 12 centromere locations and structure are likely conserved in C. incerta and C. schloesseri. We 13 report extensive rearrangements, but limited gene turnover, between the minus mating-type loci 14 of the Chlamydomonas species, potentially representing the early stages of mating-type 15 haplotype reformation. We produce an 8-species whole-genome alignment of unicellular and 16 multicellular volvocine algae and identify evolutionarily conserved elements in the C. reinhardtii 17 genome. We find that short introns (<~100 bp) are extensively overlapped by conserved 18 elements, and likely represent an important functional class of regulatory sequence in C. 19 reinhardtii. In summary, these novel resources enable comparative genomics analyses to be 20 performed for C. reinhardtii, significantly developing the analytical toolkit for this important 21 model system. 22 23 24 25 26 27 28 29 30 31 The unicellular green alga Chlamydomonas reinhardtii is a long-standing model organism across 62 several fields, including cell biology, plant physiology and molecular biology, and algal 63 biotechnology (Salomé and Merchant 2019). Because of its significance, the ~110 Mb haploid 64 genome of C. reinhardtii was among the earliest eukaryotic genomes to be sequenced (Grossman 65 et al. 2003; Merchant et al. 2007), and both the genome assembly and annotation are actively 66 being developed and improved (Blaby et al. 2014). Despite its quality and extensive application, 67 the C. reinhardtii genome currently meets the 'phylogenetically isolated' definition. The closest 68 confirmed relatives of C. reinhardtii that have genome assemblies belong to the clade of 69 multicellular algae that includes Volvox carteri, the Tetrabaenaceae-Goniaceae-Volvocaceae, or 70 TGV clade. Collectively, C. reinhardtii and the TGV clade are part of the highly diverse order 71 Volvocales, and the more taxonomically limited clades Reinhardtinia and core-Reinhardtinia 72 (Nakada et al. 2008; Nakada et al. 2016). Although these species are regularly considered close 73 relatives, multicellularity likely originated in the TGV clade over 200 million years ago (Herron 74 e...

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confidence: 59%

Comparative genomics ofChlamydomonas

Craig

Hasan

Ness

et al. 2020

Preprint

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“…As a biomedical model organism, the free-living soil nematode Caenorhabditis elegans is the first model nematode, and the first eukaryotic animal ever had its whole genome sequenced (The Caenorhabditis elegans Sequencing Consortium 1998). Other free-living nematodes had their genome sequenced subsequently in the last two decades (Stein et al 2003;Dieterich et al 2008;Kanzaki et al 2018;Ren et al 2018;Yin et al 2018;Stevens et al 2019;Weinstein et al 2019). Aside from C. elegans, Pristionchus pacificus is the only satellite model nematode with advanced functional genomic resources, bioinformatics and genetic tools (Rödelsperger et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Establishment of a marine nematode model for animal functional genomics, environmental adaptation and developmental evolution

Xie

Zhang

Xue

et al. 2020

Preprint

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Nematodes play key roles in marine ecosystem. Although oceans cover 71% of the Earth's surface, none of marine model nematode has been reported. Here, we constructed the first inbred line of free-living marine nematode Litoditis marina, sequenced and assembled its genome. Furthermore, we successfully applied CRISPR/Cas9 genome editing in L. marina.Comparative genomics revealed that immunity and oxygen regulation genes are expanded, which is probably central to its sediment adaptation. While L. marina exhibits massive gene contractions in NHRs, chemoreceptors, xenobiotics detoxification and core histones, which could explain the more defined marine environment. Our experiments showed that dozens of H4 genes in Caenorhabditis elegans might contribute to its adaptation to the complex terrestrial environments, while two H4 genes in L. marina are involved in salinity stress adaptation. Additionally, ninety-two conserved genes appear to be positively selected in L. marina, which may underpin its osmotic, neuronal and epigenetic changes in the sea. With short generation time, highly inbred lines, and genomic resources, our report brings L. marina a promising marine animal model, and a unique satellite marine model to the wellknown biomedical model nematode C. elegans. This study will underpin ongoing work on animal functional genomics, environmental adaptation and developmental evolution. 4 marine nematodes have had their genomes sequenced and analysed (International Helminth Genomes Consortium 2019; Smythe et al. 2019; Weinstein et al. 2019). Oceans cover 71% of the Earth's surface, and represents almost 99% of available habitat, which are a key element for the existence and evolution of life (Robert 1999; Peng et al. 2020). In marine sediments, free-living nematodes abound both in numbers and in local species diversity, comprising about 80% of the abundance of meiofauna (Heip et al. 1985; Danovaro et al. 2010; Nascimento et al. 2012), they play a key role in the benthic food web and ecosystem. However, the study of marine nematodes is largely limited to taxonomy and ecology (De Meester et al. 2016; Derycke et al. 2016). Molecular mechanisms underlying their evolution, development regulation and adaptation mechanisms are rarely reported, and none of marine model nematode has been reported. The bacterivorous marine nematode Litoditis marina (Bastian, 1865) Sudhaus, 2011, formerly known as Rhabditis marina or Pellioditis marina, is found widely distributed in the littoral zone of coasts and estuaries of European, American, African and Asian countries, and play an important role in these marine ecosystems (Tietjen et al. 1970; Kito 1981; Houthoofd et al. 2003; Derycke et al. 2016). In addition, the embryonic cell lineage of L. marina has been reported by Houthoofd et al. (2003). In comparison with C. elegans, the overall L. marina lineage homology is 95.5%, whereas the fate homology is only 76.4%, and most of the differences in fate homology concern nervous, epidermal, and pharyngeal tissues, suggesting that L. marina wil...

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“…A set of non-duplicated rhabditid UGGTs which depicts more phylogenetic affinity with UGGT-a, in terms of branch length and topology, interposes both Caenorhabditis subclades. The topologies of both subtrees, based on UGGT1/UGGT-a or UGGT2/UGGT-b, are congruent with the phylogeny of vertebrates (Fong et al 2012) and Caenorhabditis species (Kiontke et al 2011;Stevens et al 2019).…”

Section: Independent Duplications Of Uggt Genes In Caenorhabditis Andmentioning

confidence: 54%

Origin and Evolution of Two Independently Duplicated Genes Encoding UDP- Glucose: Glycoprotein Glucosyltransferases inCaenorhabditisand Vertebrates

Caraballo

Buzzi

Modenutti

et al. 2020

G3 Genes|Genomes|Genetics

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UDP-glucose: glycoprotein glucosyltransferase (UGGT) is a protein that operates as the gatekeeper for the endoplasmic reticulum (ER) quality control mechanism of glycoprotein folding. It is known that vertebrates and Caenorhabditis genomes harbor two uggt gene copies that exhibit differences in their properties.Bayesian phylogenetic inference based on 195 UGGT and UGGT-like protein sequences of an ample spectrum of eukaryotic species showed that uggt genes went through independent duplications in Caenorhabditis and vertebrates. In both lineages, the catalytic domain of the duplicated genes was subjected to a strong purifying selective pressure, while the recognition domain was subjected to episodic positive diversifying selection. Selective relaxation in the recognition domain was more pronounced in Caenorhabditis uggt-b than in vertebrates uggt-2. Structural bioinformatics analysis revealed that Caenorhabditis UGGT-b protein lacks essential sequences proposed to be involved in the recognition of unfolded proteins. When we assayed glucosyltrasferase activity of a chimeric protein composed by Caenorhabditis uggt-b recognition domain fused to S. pombe catalytic domain expressed in yeast, no activity was detected.The present results support the conservation of the UGGT activity in the catalytic domain and a putative divergent function of the recognition domain for the UGGT2 protein in vertebrates, which would have gone through a specialization process. In Caenorhabditis, uggt-b evolved under different constraints compared to uggt-a which, by means of a putative neofunctionalization process, resulted in a non-redundant paralog. The non-canonical function of uggt-b in the worm lineage highlights the need to take precautions before generalizing gene functions in model organisms. KEYWORDS

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Comparative genomics of 10 newCaenorhabditisspecies

Cited by 132 publications

References 83 publications

Comparative genomics ofChlamydomonas

Comparative genomics ofChlamydomonas

Establishment of a marine nematode model for animal functional genomics, environmental adaptation and developmental evolution

Origin and Evolution of Two Independently Duplicated Genes Encoding UDP- Glucose: Glycoprotein Glucosyltransferases inCaenorhabditisand Vertebrates

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