Exact solution of the quasispecies model in a sharply peaked fitness landscape

Galluccio, Stefano

doi:10.1103/physreve.56.4526

Cited by 64 publications

(73 citation statements)

References 21 publications

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“…A variant of Eigen's model was solved exactly for any N in [43]. The model is defined in discrete time but the mutations are restricted to mutants within Hamming distance equal to one, as for the continuous time mutation rates (6).…”

Section: Exact Solution Of a Sharp Peak Modelmentioning

confidence: 99%

Adaptation in Simple and Complex Fitness Landscapes

Jain

Krug

2007

Structural Approaches to Sequence Evolution

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Section: Exact Solution Of a Sharp Peak Modelmentioning

confidence: 99%

Adaptation in Simple and Complex Fitness Landscapes

Jain

Krug

2007

Structural Approaches to Sequence Evolution

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“…It was first observed by Leuthäusser [14] that the discrete time dynamics (3) can be interpreted as a transfer matrix of a two-dimensional Ising model, where the genotype sequences become one-dimensional spin configurations that are coupled in the time direction through the mutation matrix (1) [15]. A similar relation can be established between (3) and the transfer matrix of a polymer directed along the time axis [16,17]. In addition, Baake and coworkers have recently exploited the equivalence between quantum spin chains and a class of kinetic evolution equations closely related to the quasispecies model, in which mutation and selection occur in parallel [12,18].…”

mentioning

confidence: 88%

“…For the simplest case of a single peak fitness landscape, where the master sequence replicates at rate W 0 and all other sequences replicate at rate W 1 < W 0 , the selective advantage is A = W 0 /W 1 , while for randomly distributed replication rates it is a functional of the rate distribution [19,20]. In terms of the physical analogies described above, the error threshold phenomenon is equivalent to the thermal phase transition in the Ising model [14,15,18,20,21] and to the thermal unbinding of a directed polymer bound to an attractive columnar defect along the time direction [16,17]. Much less appears to be known about the evolutionary dynamics of the model, that is, the approach to the final quasispecies distribution from an initial localized or delocalized state.…”

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confidence: 99%

Tempo and mode in quasispecies evolution

Krug

2002

Biological Evolution and Statistical Physics

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Evolutionary dynamics in an uncorrelated rugged fitness landscape is studied in the framework of Eigen's molecular quasispecies model. We consider the case of strong selection, which is analogous to the zero temperature limit in the equivalent problem of directed polymers in random media. In this limit the population is always localized at a single temporary master sequence σ * (t), and we study the statistical properties of the evolutionary trajectory which σ * (t) traces out in sequence space. Numerical results for binary sequences of length N = 10 and exponential and uniform fitness distributions are presented. Evolution proceeds by intermittent jumps between local fitness maxima, where high lying maxima are visited more frequently by the trajectories. The probability distribution for the total time T required to reach the global maximum shows a T −2 -tail, which is argued to be universal and to derive from near-degenerate fitness maxima. The total number of jumps along any given trajectory is always small, much smaller than predicted by the statistics of records for random longranged evolutionary jumps. * Permanent address.

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“…Therefore, the first thing to try is the sharply-peaked landscape on the hypercube. This model was solved exactly by Galluccio et al [33,34].…”

Section: Introductionmentioning

confidence: 99%

Selective advantage of topological disorder in biological evolution

Kolář

Slanina

2003

The European Physical Journal B - Condensed Matter

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Abstract. We examine a model of biological evolution of Eigen's quasispecies in a so-called holey fitness landscape, where the fitness of a site is either 0 (lethal site) or a uniform positive constant (viable site). The evolution dynamics is therefore determined by the topology of the genome space which is modelled by the random Bethe lattice. We use the effective medium and single-defect approximations to find the criteria under which the localized quasispecies cloud is created. We find that shorter genomes, which are more robust to random mutations than average, represent a selective advantage which we call "topological". A way of assessing empirically the relative importance of reproductive success and topological advantage is suggested.

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Exact solution of the quasispecies model in a sharply peaked fitness landscape

Cited by 64 publications

References 21 publications

Adaptation in Simple and Complex Fitness Landscapes

Adaptation in Simple and Complex Fitness Landscapes

Tempo and mode in quasispecies evolution

Selective advantage of topological disorder in biological evolution

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