Autocatalytic Sets and the Origin of Life

Hordijk, Wim; Hein, Jotun; Steel, Mike

doi:10.3390/e12071733

Cited by 162 publications

(170 citation statements)

References 56 publications

(51 reference statements)

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“…Autocatalysis is a basic property of life [9,14,15,63,64]. Furthermore, the catalytic functionalities and self-reproduction processes of life are supported in intrinsically chiral systems: this means that there is experimental evidence that life is based on enantioselective autocatalysis [65].…”

Section: Abiotic Track Towards Biological Homochiralitymentioning

confidence: 99%

“…Autocatalysis is a necessary condition for life [2,14] and emerges during the evolutionary stage of the onset of replicator molecules and template mechanisms of self-reproduction. The emergence of primordial replicators is simulated in systems leading to steady state dynamics, such as those of the living cell, as was already quoted by Oparin [15] and later, subsequently formulated on a physical chemistry basis (see for example [16][17][18]).…”

Section: Introductionmentioning

confidence: 99%

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Spontaneous mirror symmetry breaking and origin of biological homochirality

Ribó

Hochberg

Crusats

et al. 2017

J. R. Soc. Interface.

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Recent reports on both theoretical simulations and on the physical chemistry basis of spontaneous mirror symmetry breaking (SMSB), that is, asymmetric synthesis in the absence of any chiral polarizations other than those arising from the chiral recognition between enantiomers, strongly suggest that the same nonlinear dynamics acting during the crucial stages of abiotic chemical evolution leading to the formation and selection of instructed polymers and replicators, would have led to the homochirality of instructed polymers. We review, in the first instance, which reaction networks lead to the nonlinear kinetics necessary for SMSB, and the thermodynamic features of the systems where this potentiality may be realized. This could aid not only in the understanding of SMSB, but also the design of reliable scenarios in abiotic evolution where biological homochirality could have taken place. Furthermore, when the emergence of biological chirality is assumed to occur during the stages of chemical evolution leading to the selection of polymeric species, one may hypothesize on a tandem track of the decrease of symmetry order towards biological homochirality, and the transition from the simple chemistry of astrophysical scenarios to the complexity of systems chemistry yielding Darwinian evolution.

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Section: Abiotic Track Towards Biological Homochiralitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Spontaneous mirror symmetry breaking and origin of biological homochirality

Ribó

Hochberg

Crusats

et al. 2017

J. R. Soc. Interface.

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“…While initially that process of imperfect replication might involve the preferential formation of the more rapid replicating oligomeric sequences, as demonstrated in the classic RNA replication experiments of Mills et al [16], the emergence of replicating networks (also termed autocatalytic sets) [2,6,47,48] with their enhanced replicating capability in comparison with individual molecular replicators, would open up new kinetic options within replicator space. And those particular sequences that would be capable of catalyzing the formation of other chemical classes, e.g., peptides, that exhibit catalytic activity with respect to the replication reaction itself, would further add to the process of complexification and evolution toward more stable dynamic kinetic systems.…”

Section: Toward a General (Extended) Theory Of Evolutionmentioning

confidence: 99%

Toward a general theory of evolution: Extending Darwinian theory to inanimate matter

Pross

2011

J Syst Chem

121

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Though Darwinian theory dramatically revolutionized biological understanding, its strictly biological focus has resulted in a widening conceptual gulf between the biological and physical sciences. In this paper we strive to extend and reformulate Darwinian theory in physicochemical terms so it can accommodate both animate and inanimate systems, thereby helping to bridge this scientific divide. The extended formulation is based on the recently proposed concept of dynamic kinetic stability and data from the newly emerging area of systems chemistry. The analysis leads us to conclude that abiogenesis and evolution, rather than manifesting two discrete stages in the emergence of complex life, actually constitute one single physicochemical process. Based on that proposed unification, the extended theory offers some additional insights into life's unique characteristics, as well as added means for addressing the three central questions of biology: what is life, how did it emerge, and how would one make it?

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“…Hordijk and Steel [34] and Hordijk et al [35] define their chemical reaction system by a tuple Q = {X, R, C}, (their symbols) in which X is a set of molecular types, R a set of reactions and C a set of catalytic relations specifying which molecular types catalyse each member of R. The system is also provided with a set of resource molecules F ⊆ X, freely available in the environment, to serve as raw materials for anabolism (noting that whilst we are defining an organisational closure, we may (and indeed must) permit the system to be materially and thermodynamically open). The autocatalytic set is that subset of reactions R ⊆ R, strictly involving the subset X ⊆ X, which is:…”

Section: The Kantian Whole As a Materials Systemmentioning

confidence: 97%

Can a Robot Have Free Will?

Farnsworth

2017

Entropy

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Using insights from cybernetics and an information-based understanding of biological systems, a precise, scientifically inspired, definition of free-will is offered and the essential requirements for an agent to possess it in principle are set out. These are: (a) there must be a self to self-determine; (b) there must be a non-zero probability of more than one option being enacted; (c) there must be an internal means of choosing among options (which is not merely random, since randomness is not a choice). For (a) to be fulfilled, the agent of self-determination must be organisationally closed (a "Kantian whole"). For (c) to be fulfilled: (d) options must be generated from an internal model of the self which can calculate future states contingent on possible responses; (e) choosing among these options requires their evaluation using an internally generated goal defined on an objective function representing the overall "master function" of the agent and (f) for "deep free-will", at least two nested levels of choice and goal (d-e) must be enacted by the agent. The agent must also be able to enact its choice in physical reality. The only systems known to meet all these criteria are living organisms, not just humans, but a wide range of organisms. The main impediment to free-will in present-day artificial robots, is their lack of being a Kantian whole. Consciousness does not seem to be a requirement and the minimum complexity for a free-will system may be quite low and include relatively simple life-forms that are at least able to learn.

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Autocatalytic Sets and the Origin of Life

Cited by 162 publications

References 56 publications

Spontaneous mirror symmetry breaking and origin of biological homochirality

Spontaneous mirror symmetry breaking and origin of biological homochirality

Toward a general theory of evolution: Extending Darwinian theory to inanimate matter

Can a Robot Have Free Will?

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