Affiliation:
1. Bharat Institute of Technology, Meerut, UP.
Abstract
In the “ecosystems-first” approach to the origins of life, networks of noncovalent assemblies of molecules (composomes), rather than individual protocells, evolved under the constraints of molecular complementarity. Composomes evolved into the hyperstructures of modern bacteria. We extend the ecosystems-first approach to explain the origin of eukaryotic cells through the integration of mixed populations of bacteria. We suggest that mutualism and symbiosis resulted in cellular mergers entailing the loss of redundant hyperstructures, the uncoupling of transcription and translation, and the emergence of introns and multiple chromosomes. Molecular complementarity also facilitated integration of bacterial hyperstructures to perform cytoskeletal and movement functions.
Reference37 articles.
1. Hunding, A.; Kepes, F.; Lancet, D.; Minsky, A.; Norris, V.; Raine, D.; Sriram, K.; RootBernstein, R. Compositional complementarity and prebiotic ecology in the origin of life. Bioessays 2006, 28, 399-412. Int. J. Mol. Sci. 2009, 10 2627.
2. Norris, V.; Hunding, A.; Kepes, F.; Lancet, D.; Minsky, A.; Raine, D.; Root-Bernstein, R.; Sriram, K. Question 7: the first units of life were not simple cells. Orig. Life Evol. Biosph. 2007, 37, 429-432.
3. Root-Bernstein, R.S. An "ecosystems-first" theory of the origin of life based on molecular complementarity. In Astrobiology: Emergence, Search, and Detection of Life; Basiuk, V.A., Ed.; American Scientific Publishers: Valencia, CA, USA, 2009; pp. 1-30.
4. Root-Bernstein, R.S.; Dillon, P.F. Molecular complementarity I: The complementarity theory of the origin and evolution of life. J. Theor. Biol. 1997, 188, 447-479.
5. Segre, D.; Lancet, D. A statistical chemistry approach to the origin of life. Chemtracts– Biochem. Mol. Biol. 1999, 12, 382-397.
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