Subject(s)
Origin of Life , Environment , Evolution, Molecular , Humans , Probability , RNA/physiology , Selection, GeneticSubject(s)
Bacteria/ultrastructure , Bacterial Physiological Phenomena , Biological Evolution , Eukaryotic Cells/physiology , Eukaryotic Cells/ultrastructure , Animals , Cell Nucleus/physiology , Cell Size , Cell Wall , Humans , Microbodies/physiology , Mitochondria/physiology , Oxygen/metabolism , Phagocytosis , Plants/ultrastructure , Plastids/physiologySubject(s)
Glucagon , Belgium , Glucagon/metabolism , History, 20th Century , Humans , Insulin/pharmacology , Liver/drug effects , Liver/metabolism , Nobel PrizeABSTRACT
A model [Wächtershäuser, G. (1988) Microbiol. Rev. 52, 452-484], according to which life started in the form of a monomolecular layer of interacting anionic metabolites electrostatically bound to a positively charged surface, is examined critically. The model raises a number of thermodynamic and kinetic difficulties.
Subject(s)
Models, Biological , Models, Chemical , Origin of Life , Animals , Anions , Biological Evolution , Iron/chemistry , Kinetics , Minerals , Nucleic Acid Precursors/chemistry , Nucleic Acids/chemistry , Polymers/chemistry , Sulfides/chemistry , Surface Properties , ThermodynamicsSubject(s)
Insulin/history , Animals , Glucose/metabolism , History, 20th Century , Insulin/pharmacology , Liver/drug effects , Liver/metabolismSubject(s)
Catalase/history , Oxidoreductases/history , Animals , Belgium , History, 20th Century , Liver/enzymology , RatsSubject(s)
Catalase/history , Liver/enzymology , Oxidoreductases/history , Animals , History, 20th Century , RatsABSTRACT
A model is proposed to account for selective chemical evolution, progressing from a relatively simple initial set of abiotic synthetic phenomena up to the elaborately sophisticated processes that are almost certainly required to produce the complex molecules, such as replicatable RNA-like oligonucleotides, needed for a Darwinian form of selection to start operating. The model makes the following assumptions: (i) that a small number of micromolecular substances were present at high concentration; (ii) that a random assembly mechanism combined these molecules into a variety of multimeric compounds comprising a wide repertoire of rudimentary catalytic activities; and (iii) that a lytic system capable of breaking down the assembled products existed. The model assumes further that catalysts supplied with substrates were significantly protected against breakdown. It is shown that, by granting these assumptions, an increasingly complex network of metabolic pathways would progressively be established. At the same time, the catalysts concerned would accumulate selectively to become choice substrates for elongation and other modifications that could enhance their efficiency, as well as their survival. Chemical evolution would thus proceed by a dual process of metabolic extension and catalytic innovation. Such a process should be largely deterministic and predictable from initial conditions.
Subject(s)
Biochemistry , Selection, Genetic , Biochemical Phenomena , Catalysis , Kinetics , Models, TheoreticalABSTRACT
Glycosomes, the microbodies of Trypanosoma brucei, contain a number of enzymes involved in glucose and glycerol metabolism. The biogenesis of three of these enzymes has been studied. Aldolase, D-glyceraldehyde-3-phosphate dehydrogenase and NAD-linked glycerol-3-phosphate dehydrogenase are all synthesized in the cytosol on free rather than on membrane-bound polysomes. In vitro, as well as in vivo, these polypeptides are synthesized at their mature size, and no evidence was found for any processing upon entry into the glycosomes. Continuous and pulse-chase labelling experiments with procyclic trypomastigotes revealed that the enzymes have a half-life in the cytosol of approximately 3 min or less, and then turn over rapidly in the glycosomes, with half-lives as short as 30 min.
