• Meyer, A. et al. Giant lungfish genome elucidates the conquest of land by vertebrates. Nature 590, 284–289 (2021).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Wang, K. et al. African lungfish genome sheds light on the vertebrate water-to-land transition. Cell 184, 1362–1376.e1318 (2021).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Irisarri, I. et al. Phylotranscriptomic consolidation of the jawed vertebrate timetree. Nat. Ecol. Evol. 1, 1370–1378 (2017).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Krefft, J. L. G. Description of a gigantic amphibian allied to the genus Lepidosiren from the Wide-Bay district, Queensland. Proc. Zool. Soc. Lond. 1870, 221–224 (1870).


    Google Scholar
     

  • Meyer, A. & Dolven, S. I. Molecules, fossils, and the origin of tetrapods. J. Mol. Evol. 35, 102–113 (1992).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Kemp, A. The biology of the Australian lungfish, Neoceratodus forsteri (Krefft 1870). J. Morphol. 190, 181–198 (1986).

    Article 

    Google Scholar
     

  • Nowoshilow, S. et al. The axolotl genome and the evolution of key tissue formation regulators. Nature 554, 50–55 (2018).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Shao, C. et al. The enormous repetitive Antarctic krill genome reveals environmental adaptations and population insights. Cell 186, 1279–1294.e1219 (2023).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Oliveira, C. et al. Chromosome formulae of neotropical freshwater fishes. Rev. Brasil. Genet. 11, 577–624 (1988).


    Google Scholar
     

  • Suzuki, A. & Yamanaka, K. Chromosomes of an African Lungfish, Protopterus annectens. Proc. Jpn Acad. B Phys. Biol. Sci. 64, 119–121 (1988).

    Article 
    ADS 

    Google Scholar
     

  • Nurk, S. et al. The complete sequence of a human genome. Science 376, 44–53 (2022).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Irisarri, I. & Meyer, A. The identification of the closest living relative(s) of tetrapods: phylogenomic lessons for resolving short ancient internodes. Syst. Biol. 65, 1057–1075 (2016).

    Article 
    PubMed 

    Google Scholar
     

  • Brownstein, C. D., Harrington, R. C. & Near, T. J. The biogeography of extant lungfishes traces the breakup of Gondwana. J. Biogeogr. 50, 1191–1198 (2023).

    Article 

    Google Scholar
     

  • Simakov, O. et al. Deeply conserved synteny resolves early events in vertebrate evolution. Nat. Ecol. Evol. 4, 820–830 (2020).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Simakov, O. et al. Deeply conserved synteny and the evolution of metazoan chromosomes. Sci. Adv. 8, eabi5884 (2022).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Muffato, M. et al. Reconstruction of hundreds of reference ancestral genomes across the eukaryotic kingdom. Nat. Ecol. Evol. 7, 355–366 (2023).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Bourque, G. et al. Ten things you should know about transposable elements. Genome Biol. 19, 199 (2018).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Meyer, A. & Schartl, M. Gene and genome duplications in vertebrates: the one-to-four (-to-eight in fish) rule and the evolution of novel gene functions. Curr. Opin. Cell Biol. 11, 699–704 (1999).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Thomson, K. S. An attempt to reconstruct evolutionary changes in the cellular DNA content of lungfish. J. Exp. Zool. 180, 363–371 (1972).

    Article 

    Google Scholar
     

  • Gregory, T. R. The bigger the C-value, the larger the cell: genome size and red blood cell size in vertebrates. Blood Cells Mol. Dis. 27, 830–843 (2001).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Nystedt, B. et al. The Norway spruce genome sequence and conifer genome evolution. Nature 497, 579–584 (2013).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Falcon, F., Tanaka, E. M. & Rodriguez-Terrones, D. Transposon waves at the water-to-land transition. Curr. Opin. Genet. Dev. 81, 102059 (2023).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Brennecke, J. et al. Discrete small RNA-generating loci as master regulators of transposon activity in Drosophila. Cell 128, 1089–1103 (2007).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Yi, M. et al. Rapid evolution of piRNA pathway in the teleost fish: implication for an adaptation to transposon diversity. Genome Biol. Evol. 6, 1393–1407 (2014).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Wang, J. et al. Transposable element and host silencing activity in gigantic genomes. Front. Cell Dev. Biol. 11, 1124374 (2023).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Song, J. et al. Variation in piRNA and transposable element content in strains of Drosophila melanogaster. Genome Biol. Evol. 6, 2786–2798 (2014).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Aravin, A. A. et al. A piRNA pathway primed by individual transposons is linked to de novo DNA methylation in mice. Mol. Cell 31, 785–799 (2008).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Wang, W. et al. The initial uridine of primary piRNAs does not create the tenth adenine that is the hallmark of secondary piRNAs. Mol. Cell 56, 708–716 (2014).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Pasquesi, G. I. M. et al. Vertebrate lineages exhibit diverse patterns of transposable element regulation and expression across tissues. Genome Biol. Evol. 12, 506–521 (2020).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Kofler, R. piRNA clusters need a minimum size to control transposable element invasions. Genome Biol. Evol. 12, 736–749 (2020).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Liu, X. et al. Transposable element expansion and low-level piRNA silencing in grasshoppers may cause genome gigantism. BMC Biol. 20, 243 (2022).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Yang, P., Wang, Y. & Macfarlan, T. S. The role of KRAB-ZFPs in transposable element repression and mammalian evolution. Trends Genet. 33, 871–881 (2017).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Imbeault, M., Helleboid, P.-Y. & Trono, D. KRAB zinc-finger proteins contribute to the evolution of gene regulatory networks. Nature 543, 550–554 (2017).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Kaessmann, H., Vinckenbosch, N. & Long, M. RNA-based gene duplication: mechanistic and evolutionary insights. Nat. Rev. Genet. 10, 19–31 (2009).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Carelli, F. N. et al. The life history of retrocopies illuminates the evolution of new mammalian genes. Genome Res. 26, 301–314 (2016).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Chen, M. et al. Evolutionary patterns of RNA-based duplication in non-mammalian chordates. PLoS ONE 6, e21466 (2011).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Okabe, M. & Graham, A. The origin of the parathyroid gland. Proc. Natl Acad. Sci. USA 101, 17716–17719 (2004).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Li, C. et al. Genome sequences reveal global dispersal routes and suggest convergent genetic adaptations in seahorse evolution. Nat. Commun. 12, 1094 (2021).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Kerr, T. The scales of modern lungfish. Proc. Zool. Soc. Lond. 125, 335–345 (1955).

    Article 

    Google Scholar
     

  • Lander, E. S. et al. Initial sequencing and analysis of the human genome. Nature 409, 860–921 (2001).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Di-Poï, N., Montoya-Burgos, J. I. & Duboule, D. Atypical relaxation of structural constraints in Hox gene clusters of the green anole lizard. Genome Res. 19, 602–610 (2009).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Feiner, N. Accumulation of transposable elements in Hox gene clusters during adaptive radiation of Anolis lizards. Proc. Biol. Sci. 283, 20161555 (2016).

    PubMed 
    PubMed Central 

    Google Scholar
     

  • Woltering, J. M., Noordermeer, D., Leleu, M. & Duboule, D. Conservation and divergence of regulatory strategies at Hox loci and the origin of tetrapod digits. PLoS Biol. 12, e1001773 (2014).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Berlivet, S. et al. Clustering of tissue-specific sub-TADs accompanies the regulation of HoxA genes in developing limbs. PLoS Genet. 9, e1004018 (2013).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Kemp, A., Cavin, L. & Guinot, G. Evolutionary history of lungfishes with a new phylogeny of post-Devonian genera. Palaeogeogr. Palaeoclimatol. Palaeoecol. 471, 209–219 (2017).

    Article 

    Google Scholar
     

  • Díaz-González, F. et al. Biallelic cGMP-dependent type II protein kinase gene (PRKG2) variants cause a novel acromesomelic dysplasia. J. Med. Genet. 59, 28–38 (2022).

    Article 
    PubMed 

    Google Scholar
     

  • Lewandowski, J. P. et al. Spatiotemporal regulation of GLI target genes in the mammalian limb bud. Dev. Biol. 406, 92–103 (2015).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Breslow, D. K. et al. A CRISPR-based screen for Hedgehog signaling provides insights into ciliary function and ciliopathies. Nat. Genet. 50, 460–471 (2018).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Yang, L. et al. Enlarged fins of Tibetan catfish provide new evidence of adaptation to high plateau. Sci. China Life Sci. 66, 1554–1568 (2023).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Letelier, J. et al. The Shh/Gli3 gene regulatory network precedes the origin of paired fins and reveals the deep homology between distal fins and digits. Proc. Natl Acad. Sci. USA 118, e2100575118 (2021).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Woltering, J. M. et al. Sarcopterygian fin ontogeny elucidates the origin of hands with digits. Sci. Adv. 6, eabc3510 (2020).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Kvon, E. Z. et al. Comprehensive in vivo interrogation reveals phenotypic impact of human enhancer variants. Cell 180, 1262–1271.e1215 (2020).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Roscito, J. G. et al. Convergent and lineage-specific genomic differences in limb regulatory elements in limbless reptile lineages. Cell Rep. 38, 110280 (2022).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Ovchinnikov, V. et al. Caecilian genomes reveal the molecular basis of adaptation and convergent evolution of limblessness in snakes and caecilians. Mol. Biol. Evol. 40, msad102 (2023).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Lopez-Rios, J. The many lives of SHH in limb development and evolution. Semin. Cell Dev. Biol. 49, 116–124 (2016).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Farrell, E. R. & Münsterberg, A. E. csal1 is controlled by a combination of FGF and Wnt signals in developing limb buds. Dev. Biol. 225, 447–458 (2000).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Carneiro, J. et al. Evidence of cryptic speciation in South American lungfish. J. Zool. Syst. Evol. Res. 59, 760–771 (2021).

  • Storer, J., Hubley, R., Rosen, J., Wheeler, T. J. & Smit, A. F. The Dfam community resource of transposable element families, sequence models, and genome annotations. Mob. DNA 12, 2 (2021); https://pubmed.ncbi.nlm.nih.gov/33436076/.

  • Flynn, J. M. et al. RepeatModeler2 for automated genomic discovery of transposable element families. Proc. Natl Acad. Sci USA 117, 9451–9457 (2020); https://pubmed.ncbi.nlm.nih.gov/32300014/.

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Benson, G. Tandem repeats finder: a program to analyze DNA sequences. Nucleic Acids Res. 27, 573–580 (1999); https://pubmed.ncbi.nlm.nih.gov/9862982/.

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Bao, Z., & Edyy, S. R. Automated de novo identification of repeat sequence families in sequenced genomes. Genome Res. 12, 1269–1276 (2002).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Price, A. L., Jones, N. C. & Pevzner, P. A. De novo identification of repeat families in large genomes. Bioinformatics 21, i351–i358 (2005).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Camacho, C. et al. BLAST+: architecture and applications. BMC Bioinform. 10, 421 (2009).

  • Chalopin, D., Naville, M., Plard, F., Galiana, D. & Volff, J.-N. Comparative analysis of transposable elements highlights mobilome diversity and evolution in vertebrates. Genome Biol. Evol. 7, 567–580 (2015).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Conte, M. A. et al. Chromosome-scale assemblies reveal the structural evolution of African cichlid genomes. Gigascience 8, giz030 (2019).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Brawand, D. et al. The genomic substrate for adaptive radiation in African cichlid fish. Nature 513, 375–381 (2014).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Kong, Y. et al. Transposable element expression in tumors is associated with immune infiltration and increased antigenicity. Nat. Commun. 10, 5228 (2019).

    Article 
    ADS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Yang, W. R., Ardeljan, D., Pacyna, C. N., Payer, L. M. & Burns, K. H. SQuIRE reveals locus-specific regulation of interspersed repeat expression. Nucleic Acids Res. 47, e27 (2019).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Peona, V. et al. The avian W chromosome is a refugium for endogenous retroviruses with likely effects on female-biased mutational load and genetic incompatibilities. Philos. Trans. R. Soc. Lond. B Biol. Sci. 376, 20200186 (2021).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Finn, R. D. et al. Pfam: the protein families database. Nucleic Acids Res. 42, D222–D230 (2014).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Ellinghaus, D., Kurtz, S. & Willhoeft, U. LTRharvest, an efficient and flexible software for de novo detection of LTR retrotransposons. BMC Bioinform. 9, 18 (2008).

    Article 

    Google Scholar
     

  • Steinbiss, S., Willhoeft, U., Gremme, G. & Kurtz, S. Fine-grained annotation and classification of de novo predicted LTR retrotransposons. Nucleic Acids Res. 37, 7002–7013 (2009).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Llorens, C. et al. The Gypsy Database (GyDB) of mobile genetic elements: release 2.0. Nucleic Acids Res. 39, D70–D74 (2011).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Groza, C., Chen, X., Wheeler, T. J., Bourque, G. & Goubert, C. GraffiTE: a unified framework to analyzetransposable element insertion polymorphisms using genome-graphs. Preprint at bioRxiv https://doi.org/10.1101/2023.09.11.557209 (2023).

  • She, R., Chu, J. S., Wang, K., Pei, J. & Chen, N. GenBlastA: enabling BLAST to identify homologous gene sequences. Genome Res. 19, 143–149 (2009).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Pearson, W. R. Finding protein and nucleotide similarities with FASTA. Curr. Protoc. Bioinform. 53, 3.9.1–3.9.25 (2016).

    Article 

    Google Scholar
     

  • Birney, E., Clamp, M. & Durbin, R. GeneWise and Genomewise. Genome Res. 14, 988–995 (2004).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Sellitto, A. et al. Molecular and functional characterization of the somatic PIWIL1/piRNA pathway in colorectal cancer cells. Cells 8, 1390 (2019).

  • Schmieder, R. & Edwards, R. Quality control and preprocessing of metagenomic datasets. Bioinformatics 27, 863–864 (2011).

  • Rosenkranz, D. & Zischler, H. proTRAC-a software for probabilistic piRNA cluster detection, visualization and analysis. BMC Bioinform. 13, 5 (2012).

    Article 

    Google Scholar
     

  • Camacho, C. et al. BLAST+: architecture and applications. BMC Bioinform. 10, 421 (2009).

    Article 

    Google Scholar
     

  • Emms, D. M. & Kelly, S. OrthoFinder: phylogenetic orthology inference for comparative genomics. Genome Biol. 20, 238 (2019).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Lartillot, N., Rodrigue, N., Stubbs, D. & Richer, J. PhyloBayes MPI: phylogenetic reconstruction with infinite mixtures of profiles in a parallel environment. Syst. Biol. 62, 611–615 (2013).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Delsuc, F., Brinkmann, H., Chourrout, D. & Philippe, H. Tunicates and not cephalochordates are the closest living relatives of vertebrates. Nature 439, 965–968 (2006).

    Article 
    ADS 
    CAS 
    PubMed 

    Google Scholar
     

  • Revell, L. J. phytools: an R package for phylogenetic comparative biology (and other things). Methods Ecol. Evol. 3, 217–223 (2012).

    Article 

    Google Scholar
     

  • Thomson, K. S. & Muraszko, K. Estimation of cell size and DNA content in fossil fishes and amphibians. J. Exp. Zool. 205, 315–320 (1978).

    Article 
    CAS 

    Google Scholar
     

  • Huang, Z. et al. Three amphioxus reference genomes reveal gene and chromosome evolution of chordates. Proc. Natl Acad. Sci. USA 120, e2201504120 (2023).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Kautt, A. F. et al. Contrasting signatures of genomic divergence during sympatric speciation. Nature 588, 106–111 (2020).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Suyama, M., Torrents, D. & Bork, P. PAL2NAL: robust conversion of protein sequence alignments into the corresponding codon alignments. Nucleic Acids Res. 34, W609–W612 (2006).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Edgar, R. C. MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Res. 32, 1792–1797 (2004).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Castresana, J. Selection of conserved blocks from multiple alignments for their use in phylogenetic analysis. Mol. Biol. Evol. 17, 540–552 (2000).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Huerta-Cepas, J., Serra, F. & Bork, P. ETE 3: reconstruction, analysis, and visualization of phylogenomic data. Mol. Biol. Evol. 33, 1635–1638 (2016).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Emms, D. M. & Kelly, S. OrthoFinder: phylogenetic orthology inference for comparative genomics. Genome Biol. 20, 238 (2019).

  • Deng, W., Nickle, D. C., Learn, G. H., Maust, B. & Mullins, J. I. ViroBLAST: a stand-alone BLAST web server for flexible queries of multiple databases and user’s datasets. Bioinformatics 23, 2334–2336 (2007).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Montavon, T. et al. A regulatory archipelago controls Hox genes transcription in digits. Cell 147, 1132–1145 (2011).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Dixon, J. R. et al. Topological domains in mammalian genomes identified by analysis of chromatin interactions. Nature 485, 376–380 (2012).

    Article 
    ADS 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Wang, Y. et al. The 3D Genome Browser: a web-based browser for visualizing 3D genome organization and long-range chromatin interactions. Genome Biol. 19, 151 (2018).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Ramírez, F. et al. High-resolution TADs reveal DNA sequences underlying genome organization in flies. Nat. Commun. 9, 189 (2018).

    Article 
    ADS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Taylor, W. & Van Dyke, G. Revised procedures for staining and clearing small fishes and other vertebrates for bone and cartilage study. Cybium 9, 107–119 (1985).


    Google Scholar
     

  • Kvon, E. Z. et al. Progressive loss of function in a limb enhancer during snake evolution. Cell 167, 633–642.e611 (2016).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Osterwalder, M. et al. in Craniofacial Development Vol. 2403 (ed. Dworkin, S.) 147−186 (Humana, 2022).

  • Du, K. Lungfish genome annotation. figshare https://doi.org/10.6084/m9.figshare.24147732.v1 (2024).



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