This work is licensed under the Creative Commons Attribution 4.0 International License.
Darwin C. 1859. On the Origin of Species. 1st edition (London: John Murray), p.127.DarwinC18591st editionLondonJohn Murray127Search in Google Scholar
Preiner M, Asche S, Becker S, Betts HC, Boniface A, Camprubi E, Chandru K, Erastova V, Garg SG, Khawaja N, Kostyrka G, Machné R, Moggioli G, Muchowska KB, Neukirchen S, Peter B, Pichlhöfer E, Radványi Á, Rossetto D, Salditt A, Schmelling NM, Sousa FL, Tria FDK, Vörös D, Xavier JC. 2020. The Future of Origin of Life Research: Bridging Decades-Old Divisions. Life,10, 20.PreinerMAscheSBeckerSBettsHCBonifaceACamprubiEChandruKErastovaVGargSGKhawajaNKostyrkaGMachnéRMoggioliGMuchowskaKBNeukirchenSPeterBPichlhöferERadványiÁRossettoDSaldittASchmellingNMSousaFLTriaFDKVörösDXavierJC2020The Future of Origin of Life Research: Bridging Decades-Old Divisions1020Search in Google Scholar
Eigen M. 2002. Error catastrophe and antiviral strategy. Proc Natl Acad Sci, 99(21): 13374–13376.EigenM2002Error catastrophe and antiviral strategy99211337413376Search in Google Scholar
Summers J, Litwin S. 2005. Examining the Theory of Error Catastrophe. Journal of Virology, 80:20–26; DOI: 10.1128/JVI.80.1.20-26.2006.SummersJLitwinS2005Examining the Theory of Error Catastrophe80202610.1128/JVI.80.1.20-26.2006Open DOISearch in Google Scholar
Goel NS, Yčas M. 1975. The error catastrophe hypothesis with reference to aging and the evolution of the protein synthesizing machinery. Journal of Theoretical Biology, 55:245–282.GoelNSYčasM1975The error catastrophe hypothesis with reference to aging and the evolution of the protein synthesizing machinery55245282Search in Google Scholar
Simons AM. 2002. The continuity of microevolution and macroevolution. Journal of Evolutionary Biology, 15: 688–701. doi:10.1046/j.1420-9101.2002.00437.xSimonsAM2002The continuity of microevolution and macroevolution1568870110.1046/j.1420-9101.2002.00437.xOpen DOISearch in Google Scholar
Tupper AS, Higgs PG. 2017. Error thresholds for RNA replication in the presence of both point mutations and premature termination errors. Journal of Theoretical Biology, 428, 34–42.TupperASHiggsPG2017Error thresholds for RNA replication in the presence of both point mutations and premature termination errors4283442Search in Google Scholar
Sosson M, Richert C, Beilstein J. 2018. Org Chem. Enzyme-free genetic copying of DNA and RNA sequences. Org Chem, 14: 603–617.SossonMRichertCBeilsteinJ2018Org Chem. Enzyme-free genetic copying of DNA and RNA sequences14603617Search in Google Scholar
Edelmann P, Gallant J. 1977. On the translational error theory of aging. Proc Natl Acad Sci, 74 (8), 3396–3398.EdelmannPGallantJ1977On the translational error theory of aging74833963398Search in Google Scholar
Joyce GF, Szostak JW. 2018. Protocells and RNA Self-Replication. Cold Spring Harb Perspect Biol. 2018 Sep 4;10(9).JoyceGFSzostakJW2018Protocells and RNA Self-Replication2018Sep4109Search in Google Scholar
Sutherland J. 2017. Opinion: Studies on the origin of life — the end of the beginning. Nat Rev Chem 1, 0012. https://doi.org/10.1038/s41570-016-0012SutherlandJ2017Opinion: Studies on the origin of life — the end of the beginning10012. https://doi.org/10.1038/s41570-016-0012Search in Google Scholar
Adamski P, Eleveld M, Sood A, et al. 2020. From self-replication to replicator systems en route to de novo life. Nat Rev Chem 4, 386–403. https://doi.org/10.1038/s41570-020-0196-xAdamskiPEleveldMSoodA2020From self-replication to replicator systems en route to de novo life4386403https://doi.org/10.1038/s41570-020-0196-xSearch in Google Scholar
Wolf YI, Koonin EV. 2007. On the origin of the translation system and the genetic code in the RNA world by means of natural selection, exaptation, and subfunctionalization. Biology Direct, 2007, 2:14.WolfYIKooninEV2007On the origin of the translation system and the genetic code in the RNA world by means of natural selection, exaptation, and subfunctionalization2007214Search in Google Scholar
Wolpert L. 1994. The evolutionary origin of development: cycles, patterning, privilege and continuity. Development, 1994: 79–84.WolpertL1994The evolutionary origin of development: cycles, patterning, privilege and continuity19947984Search in Google Scholar
Eldredge N, Gould SJ. 1972. “Punctuated equilibria: an alternative to phyletic gradualism” in Schopf TJM (ed) Models in Paleobiology. Freeman Cooper and Co. San Francisco. pp 82–115.EldredgeNGouldSJ1972“Punctuated equilibria: an alternative to phyletic gradualism”inSchopfTJM(ed)Freeman Cooper and Co.San Francisco82115Search in Google Scholar
Koonin EV. 2007. The Biological Big Bang model for the major transitions in evolution. Biology Direct, 2:21. https://doi.org/10.1186/1745-6150-2-21KooninEV2007The Biological Big Bang model for the major transitions in evolution221https://doi.org/10.1186/1745-6150-2-21Search in Google Scholar
Fontana W, Schuster P. 1998. Continuity in Evolution: On the Nature of Transitions. Science, 280:1451–1455. doi: 10.1126/science.280.5368.1451FontanaWSchusterP1998Continuity in Evolution: On the Nature of Transitions2801451145510.1126/science.280.5368.1451Open DOISearch in Google Scholar
Raggi L, Bada JL, Lazcano A. 2016. On the lack of evolutionary continuity between prebiotic peptides and extant enzymes. Phys. Chem. Chem. Phys.,18, 20028–20032.RaggiLBadaJLLazcanoA2016On the lack of evolutionary continuity between prebiotic peptides and extant enzymes182002820032Search in Google Scholar
Margulis L. 1996. Archaeal-eubacterial mergers in the origin of Eukarya: phylogenetic classification of life. Proceedings of the National Academy of Sciences of the United States of America, 93(3): 1071–1076. doi:10.1073/pnas.93.3.1071MargulisL1996Archaeal-eubacterial mergers in the origin of Eukarya: phylogenetic classification of life9331071107610.1073/pnas.93.3.1071Open DOISearch in Google Scholar
Martin WF, Garg S, Zimorski V. 2015. Endosymbiotic theories for eukaryote origin. Philos Trans R Soc Lond B Biol Sci., 370(1678). doi: 10.1098/rstb.2014.0330MartinWFGargSZimorskiV2015Endosymbiotic theories for eukaryote origin370167810.1098/rstb.2014.0330Open DOISearch in Google Scholar
Dehal P, Boore JL. 2005. Two rounds of whole genome duplication in the ancestral vertebrate. PLoS Biol., 3:E314.DehalPBooreJL2005Two rounds of whole genome duplication in the ancestral vertebrate3E314Search in Google Scholar
Coate JE, Doyle JJ. 2011. Divergent evolutionary fates of major photosynthetic gene networks following gene and whole genome duplications. Plant Signal Behav., 6:594–597.CoateJEDoyleJJ2011Divergent evolutionary fates of major photosynthetic gene networks following gene and whole genome duplications6594597Search in Google Scholar
Morris SC. 1989. Burgess Shale Faunas and the Cambrian Explosion. Science, 246:339–346.MorrisSC1989Burgess Shale Faunas and the Cambrian Explosion246339346Search in Google Scholar
Lee MSY, Soubrier J, Edgecombe GD. 2013. Rates of Phenotypic and Genomic Evolution during the Cambrian Explosion. Current Biology, 23:1889–1895.LeeMSYSoubrierJEdgecombeGD2013Rates of Phenotypic and Genomic Evolution during the Cambrian Explosion2318891895Search in Google Scholar
Conway Morris S. 2006. Darwin's dilemma: the realities of the Cambrian ‘explosion’. Phil. Trans. R. Soc. B 361, 1069–1083.Conway MorrisS2006Darwin's dilemma: the realities of the Cambrian ‘explosion’36110691083Search in Google Scholar
Minelli A, Chagas A, Edgecomb GD. 2009. Saltational evolution of trunk segment number in centipedes. Evolution & Development, 11:3, 318–322. doi: 10.1111/j.1525-142X.2009.00334.xMinelliAChagasAEdgecombGD2009Saltational evolution of trunk segment number in centipedes11331832210.1111/j.1525-142X.2009.00334.xOpen DOISearch in Google Scholar
Theissen G. 2009. Saltational evolution: hopeful monsters are here to stay. Theory Biosci., 128:43–51. doi: 10.1007/s12064-009-0058-zTheissenG2009Saltational evolution: hopeful monsters are here to stay128435110.1007/s12064-009-0058-zOpen DOISearch in Google Scholar
Laland KN, Uller T, Feldman MW, Sterelny K, Müller GB, Moczek A, Jablonka E, Odling-Smee J. 2015. The extended evolutionary synthesis: its structure, assumptions and predictions. Proc. R. Soc. B, 282: 20151019. http://dx.doi.org/10.1098/rspb.2015.1019LalandKNUllerTFeldmanMWSterelnyKMüllerGBMoczekAJablonkaEOdling-SmeeJ2015The extended evolutionary synthesis: its structure, assumptions and predictions28220151019. http://dx.doi.org/10.1098/rspb.2015.1019Search in Google Scholar
Gabora L. 2006. Self-other organization: Why early life did not evolve through natural selection. Journal of Theoretical Biology, 241:443–450.GaboraL2006Self-other organization: Why early life did not evolve through natural selection241443450Search in Google Scholar
Tour J. 2017. An Open Letter to My Colleagues. Inference: Inter. Rev. Science, 3, 2. https://inference-review.com/article/an-open-letter-to-my-colleagues.TourJ2017An Open Letter to My Colleagues32https://inference-review.com/article/an-open-letter-to-my-colleagues.Search in Google Scholar
Koonin EV. 2007. The cosmological model of eternal inflation and the transition from chance to biological evolution in the history of life. Biol Direct 2, 15. https://doi.org/10.1186/1745-6150-2-15KooninEV2007The cosmological model of eternal inflation and the transition from chance to biological evolution in the history of life215https://doi.org/10.1186/1745-6150-2-15Search in Google Scholar
Garte, S. 2020. The Continuity Principle and the Evolution of Replication Fidelity. Acta Biotheor. https://doi.org/10.1007/s10441-020-09399-4GarteS2020The Continuity Principle and the Evolution of Replication Fidelityhttps://doi.org/10.1007/s10441-020-09399-4Search in Google Scholar
Keightley PD, Lynch M. 2003. Toward a Realistic Model of Mutations Affecting Fitness. Evolution, 57(3), pp. 683–685.KeightleyPDLynchM2003Toward a Realistic Model of Mutations Affecting Fitness573683685Search in Google Scholar
Szathmáry E (2006) The origin of replicators and reproducers. Philos Trans R Soc B Biol Sci, 361(1474):1761–1776.SzathmáryE2006The origin of replicators and reproducers361147417611776Search in Google Scholar
Alberts B, et al. 2008. Molecular Biology of the Cell. Fifth Edition, Garland Science, New York NY, pp 268, 378.AlbertsB2008Fifth EditionGarland ScienceNew York NY268378Search in Google Scholar
Xu J, Green NJ, Gibard C, Krishnamurthy R, Sutherland JD. 2019. Prebiotic phosphorylation of 2-thiouridine provides either nucleotides or DNA building blocks via photoreduction. Nature Chemistry, 11: 457–462.XuJGreenNJGibardCKrishnamurthyRSutherlandJD2019Prebiotic phosphorylation of 2-thiouridine provides either nucleotides or DNA building blocks via photoreduction11457462Search in Google Scholar
Higgs, P.G. 2017. Chemical Evolution and the Evolutionary Definition of Life. J Mol Evol 84, 225–235.HiggsP.G2017Chemical Evolution and the Evolutionary Definition of Life84225235Search in Google Scholar
Szostak JW. 2012. The eightfold path to non-enzymatic RNA replication. Journal of Systems Chemistry, 3:2. http://www.jsystchem.com/content/3/1/2.SzostakJW2012The eightfold path to non-enzymatic RNA replication32http://www.jsystchem.com/content/3/1/2.Search in Google Scholar
Lane N. 2017. Serial endosymbiosis or singular event at the origin of eukaryotes? Journal of Theoretical Biology, 434, 58–67.LaneN2017Serial endosymbiosis or singular event at the origin of eukaryotes?4345867Search in Google Scholar
Davies P. 2020. Does new physics lurk inside living matter? Physics Today 73, 8, 34.DaviesP2020Does new physics lurk inside living matter?73834Search in Google Scholar
Noble R, Noble D. 2017. Was the Watchmaker Blind? Or Was She One-Eyed? Biology (Basel), Dec 20;6(4):47. doi: 10.3390/biology6040047.NobleRNobleD2017Was the Watchmaker Blind? Or Was She One-Eyed?Dec20644710.3390/biology6040047Open DOISearch in Google Scholar
Garte S. 2017. Teleology and the Origin of Evolution. Perspectives on Science and Christian Faith, 69:42–50.GarteS2017Teleology and the Origin of Evolution694250Search in Google Scholar