Optimal size for emergence of self-replicating polymer system

Matsubara, Yoshiya J.; Kaneko, Kunihiko

doi:10.1103/physreve.93.032503

Cited by 11 publications

(13 citation statements)

References 29 publications

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“…Specifically, several recent theoretical studies have reported that, in certain chemical reaction systems, the chemical compositions and underlying dynamics can be drastically altered under a small-number condition [3][4][5][6][7][8][9][10][11][12][13][14][15][16]23,24 compared to those expected in the rate equation assuming with a large volume and a large number of molecules. These phenomena are induced by molecular discreteness and its associated stochasticity, designated as "small-number effects" or "discreteness-induced transitions," which are exemplified by the emergence of multi-modality, [3][4][5][6][7][10][11][12] reversal of reaction current, 16 and slow relaxation.…”

Section: Introductionmentioning

confidence: 99%

Motif analysis for small-number effects in chemical reaction dynamics

Saito

Sughiyama

Kaneko

2016

The Journal of Chemical Physics

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The number of molecules involved in a cell or subcellular structure is sometimes rather small. In this situation, ordinary macroscopic-level fluctuations can be overwhelmed by non-negligible large fluctuations, which results in drastic changes in chemical-reaction dynamics and statistics compared to those observed under a macroscopic system (i.e., with a large number of molecules). In order to understand how salient changes emerge from fluctuations in molecular number, we here quantitatively define small-number effect by focusing on a 'mesoscopic' level, in which the concentration distribution is distinguishable both from micro-and macroscopic ones, and propose a criterion for determining whether or not such an effect can emerge in a given chemical reaction network. Using the proposed criterion, we systematically derive a list of motifs of chemical reaction networks that can show small-number effects, which includes motifs showing emergence of the power law and the bimodal distribution observable in a mesoscopic regime with respect to molecule number. The list of motifs provided herein is helpful in the search for candidates of biochemical reactions with a small-number effect for possible biological functions, as well as for designing a reaction system whose behavior can change drastically depending on molecule number, rather than concentration.

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Section: Introductionmentioning

confidence: 99%

Motif analysis for small-number effects in chemical reaction dynamics

Saito

Sughiyama

Kaneko

2016

The Journal of Chemical Physics

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“…Theory and computation are thus two very important aspects of origins of life research, and two of the main pioneers in theoretical evolution studies are Kunihiko Kaneko and Takashi Ikegami of the University of Tokyo [3,132,133]. Recent theoretical work by the Kaneko Laboratory has featured optimizing parameters for self-replicating polymer systems [134], designing replicatory protocells [135], and identifying the effect on selection pressure magnitude on evolutionary systems [136], just to name a few. In fact, many of their initial studies on origins and evolution of life are relevant to artificial life systems, both in silico and in real systems, resulting in a large amount of their research specifically on the topic of what characteristics define life and studying the emergence of these complex life-defining phenomena, such as signaling [137] or motility [138].…”

Section: Primitive Biopolymer Evolutionmentioning

confidence: 99%

Recent Advances in Origins of Life Research by Biophysicists in Japan

Jia

Kuruma

2019

Challenges

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Biophysics research tends to focus on utilizing multidisciplinary technologies and interdisciplinary collaborations to study biological phenomena through the lens of chemistry and physics. Although most current biophysics work is focused on studying extant biology, the fact remains that modern biological systems at some point were descended from a universal common ancestor. At the core of modern biology is the important question of how the earliest life on (or off) Earth emerged. Recent technological and methodological advances developed by biophysicists in Japan have allowed researchers to gain a new suite of knowledge related to the origins of life (OoL). Using these reports as inspiration, here, we highlight some of the significant OoL advances contributed by members of the biophysical research field in Japan with respect to the synthesis and assembly of biological (or pre-biological) components on early Earth, the co-assembly of primitive compartments with biopolymer systems, and the evolution of early genetic systems. We hope to provide inspiration to other biophysicists to not only use the always-advancing suite of available multidisciplinary technologies to continue their own line of work, but to also consider how their work or techniques can contribute to the ever-growing field of OoL research.

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“…In the prebiotic world, complex monomer sequences therefore have been synthesized by reactions with templates as catalysts, which are also synthesized via such template reaction. Thus, the polymerization processes are autocatalytic in nature, as has been extensively investigated [9][10][11][12][13][14][15] 24], including theoretical models that explicitly consider template-like selfreplicating polymerization [8,[16][17][18][19][20][21][22][23] and some synthesis experiments [6, 25, 26].If there exist multiple catalytic polymers with sufficient lengths, then the autocatalytic process for their synthesis can select one of such polymers. Here we study the dependence of the selected sequence on the flow rate of monomers.…”

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Kinetic Selection of Template Polymer with Complex Sequences

Matsubara

Kaneko

2018

Phys. Rev. Lett.

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The emergence and maintenance of polymers with complex sequences pose a major question in the study of the origin of life. To answer this, we study a model polymerization reaction, where polymers are synthesized by stepwise ligation from two types of monomers, catalyzed by a long polymer as a template. Direct stochastic simulation and dynamical systems analysis reveal that the most dominant polymer sequence in a population successively changes, depending on the flow rate of monomers to the system, with more complex sequences selected at a lower flow rate. We discuss the relevance of this kinetic sequence selection through nonequilibrium flow to the origin of complex polymers.

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Optimal size for emergence of self-replicating polymer system

Cited by 11 publications

References 29 publications

Motif analysis for small-number effects in chemical reaction dynamics

Motif analysis for small-number effects in chemical reaction dynamics

Recent Advances in Origins of Life Research by Biophysicists in Japan

Kinetic Selection of Template Polymer with Complex Sequences

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