TY - JOUR
T1 - Toy trains, loaded dice and the origin of life
T2 - Dimerization on mineral surfaces under periodic drive with gaussian inputs
AU - Ball, Rowena
AU - Brindley, John
N1 - Publisher Copyright:
© 2017 The Authors.
PY - 2017/11/8
Y1 - 2017/11/8
N2 - In a major extension of previous work, we model the putative hydrothermal rock pore setting for the origin of life on Earth as a series of coupled continuous flow units (the toy train). Perfusing through this train are reactants that set up thermochemical and pH oscillations, and an activated nucleotide that produces monomer and dimer monophosphates. The dynamical equations that model this system are thermally self-consistent. In an innovative step that breaks some new ground, we build stochasticity of the inputs into the model. The computational results infer various constraints and conditions on, and insights into, chemical evolution and the origin of life and its physical setting: long, interconnected porous structures with longitudinal nonuniformity would have been favourable, and the ubiquitous pH dependences of biology may have been established in the prebiotic era. We demonstrate the important role of Gaussian fluctuations of the inputs in driving polymerization, evolution and diversification. In particular, we find that the probability distribution of the resulting output fluctuations is left-skewed and right-weighted (the loaded dice), which could favour chemical evolution towards a living RNA world.We tentatively name this distribution ‘Goldilocks’. These results also vindicate the general approach of constructing and running a simple model to learn important new information about a complex system.
AB - In a major extension of previous work, we model the putative hydrothermal rock pore setting for the origin of life on Earth as a series of coupled continuous flow units (the toy train). Perfusing through this train are reactants that set up thermochemical and pH oscillations, and an activated nucleotide that produces monomer and dimer monophosphates. The dynamical equations that model this system are thermally self-consistent. In an innovative step that breaks some new ground, we build stochasticity of the inputs into the model. The computational results infer various constraints and conditions on, and insights into, chemical evolution and the origin of life and its physical setting: long, interconnected porous structures with longitudinal nonuniformity would have been favourable, and the ubiquitous pH dependences of biology may have been established in the prebiotic era. We demonstrate the important role of Gaussian fluctuations of the inputs in driving polymerization, evolution and diversification. In particular, we find that the probability distribution of the resulting output fluctuations is left-skewed and right-weighted (the loaded dice), which could favour chemical evolution towards a living RNA world.We tentatively name this distribution ‘Goldilocks’. These results also vindicate the general approach of constructing and running a simple model to learn important new information about a complex system.
KW - Chemical evolution
KW - Left-skewed right-weighted probability distribution
KW - Origin of life
KW - Stochastic dynamical model
KW - Thermochemical and pH oscillator
UR - http://www.scopus.com/inward/record.url?scp=85033594910&partnerID=8YFLogxK
U2 - 10.1098/rsos.170141
DO - 10.1098/rsos.170141
M3 - Article
SN - 2054-5703
VL - 4
JO - Royal Society Open Science
JF - Royal Society Open Science
IS - 11
M1 - 170141
ER -