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  1. Eukaryotes first: how could that be? [REVIEW]Carlos Mariscal & W. Ford Doolittle - 2015 - Philosophical Transactions of the Royal Society B: Biological Sciences 370:1-10.
    In the half century since the formulation of the prokaryote : eukaryote dichotomy, many authors have proposed that the former evolved from something resembling the latter, in defiance of common (and possibly common sense) views. In such ‘eukaryotes first’ (EF) scenarios, the last universal common ancestor is imagined to have possessed significantly many of the complex characteristics of contemporary eukaryotes, as relics of an earlier ‘progenotic’ period or RNAworld. Bacteria and Archaea thus must have lost these complex features secondarily, through (...)
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  • An interpretive review of the origin of life research.David Penny - 2005 - Biology and Philosophy 20 (4):633-671.
    Life appears to be a natural property of matter, but the problem of its origin only arose after early scientists refuted continuous spontaneous generation. There is no chance of life arising ‘all at once’, we need the standard scientific incremental explanation with large numbers of small steps, an approach used in both physical and evolutionary sciences. The necessity for considering both theoretical and experimental approaches is emphasized. After describing basic principles that are available (including the Darwin-Eigen cycle), the search for (...)
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  • Getting from an RNA world to modern cells just got a little easier.Anthony M. Poole - 2006 - Bioessays 28 (2):105-108.
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  • More than the sum of their parts: On the evolution of proteins from peptides.Johannes Söding & Andrei N. Lupas - 2003 - Bioessays 25 (9):837-846.
    Despite their seemingly endless diversity, proteins adopt a limited number of structural forms. It has been estimated that 80% of proteins will be found to adopt one of only about 400 folds, most of which are already known. These folds are largely formed by a limited ‘vocabulary’ of recurring supersecondary structure elements, often by repetition of the same element and, increasingly, elements similar in both structure and sequence are discovered. This suggests that modern proteins evolved by fusion and recombination from (...)
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  • The RNA dreamtime.Charles G. Kurland - 2010 - Bioessays 32 (10):866-871.
    Modern cells present no signs of a putative prebiotic RNA world. However, RNA coding is not a sine qua non for the accumulation of catalytic polypeptides. Thus, cellular proteins spontaneously fold into active structures that are resistant to proteolysis. The law of mass action suggests that binding domains are stabilized by specific interactions with their substrates. Random polypeptide synthesis in a prebiotic world has the potential to initially produce only a very small fraction of polypeptides that can fold spontaneously into (...)
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  • Photosynthetic Systems Suggest an Evolutionary Pathway to Diderms.Scott O. Rogers - 2020 - Acta Biotheoretica 69 (3):343-358.
    Bacteria are divided primarily into monoderms and diderms. Photosynthetic species are spread among the taxonomic groups, some having type I reaction centers, others with type II reaction centers, and some containing both. In most bacterial phylograms, photosystem types and diderm taxa are polyphyletic. A more parsimonious arrangement, which is supported by photosystem evolution, as well as additional sets of molecular characters, suggests that endosymbiotic events resulted in the formation of the diderms. In the model presented, monoderms readily form a monophyletic (...)
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  • Prebiotic world, macroevolution, and Darwin’s theory: a new insight.Luis Boto, Ignacio Doadrio & Rui Diogo - 2009 - Biology and Philosophy 24 (1):119-128.
    Darwin’s main contribution to modern biology was to make clear that all history of life on earth is dominated by a simple principle, which is usually summarised as 'descent with modification'. However, interpretations about how this modification is produced have been controversial. In light of the data provided by recent studies on molecular biology, developmental biology, genomics, and other biological disciplines we discuss, in this paper, how Darwin's theory may apply to two main 'types' of evolution: that occurring in the (...)
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