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Computer Simulation of the Evolution of Microbial Population : Overcoming Local Minima When Reaching a Peak on the Fitness Landscape. / Lashin, S. A.; Mustafin, Z. S.; Klimenko, A. I. и др.

в: Russian Journal of Genetics, Том 56, № 2, 01.02.2020, стр. 242-252.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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APA

Vancouver

Lashin SA, Mustafin ZS, Klimenko AI, Afonnikov DA, Matushkin YG. Computer Simulation of the Evolution of Microbial Population: Overcoming Local Minima When Reaching a Peak on the Fitness Landscape. Russian Journal of Genetics. 2020 февр. 1;56(2):242-252. doi: 10.1134/S1022795420020076

Author

Lashin, S. A. ; Mustafin, Z. S. ; Klimenko, A. I. и др. / Computer Simulation of the Evolution of Microbial Population : Overcoming Local Minima When Reaching a Peak on the Fitness Landscape. в: Russian Journal of Genetics. 2020 ; Том 56, № 2. стр. 242-252.

BibTeX

@article{0469fa189e67477d99e490fc64b20d0d,
title = "Computer Simulation of the Evolution of Microbial Population: Overcoming Local Minima When Reaching a Peak on the Fitness Landscape",
abstract = "The study focuses on the mechanisms of crossing the valleys of fitness by a population of haploid microorganisms, whose fitness depends on allelic values at two different loci and is determined by a complex landscape, the shape of which corresponds to the pattern “a mountain in the field surrounded by a trench”; these mechanisms are analyzed using computer modeling. We have studied the influence of various biological factors on the evolutionary perspective of microbial colonies, the reproduction rate of which is controlled by a protein consisting of two subunits encoded at different loci. Molecular genetic (mutation rate, affinity of subunits), population (fitness function landscape and population density), and ecological (concentration of available substrate in the habitat, flow intensity) factors have been considered. Our results demonstrate that the difference in fitness for various allelic combinations, while determining the shape of the fitness landscape, sets the optimal mutation rates to overcome its valleys and opens a window of opportunity for the evolution of the population toward the state of the highest average fitness. Moreover, depending on the fitness landscape type, either gradual or saltational evolutionary regimes are optimal for reaching the peak.",
keywords = "ecological modeling, evolution, fitness landscape, fitness valley, microbial community, mutation rate",
author = "Lashin, {S. A.} and Mustafin, {Z. S.} and Klimenko, {A. I.} and Afonnikov, {D. A.} and Matushkin, {Yu G.}",
year = "2020",
month = feb,
day = "1",
doi = "10.1134/S1022795420020076",
language = "English",
volume = "56",
pages = "242--252",
journal = "Russian Journal of Genetics",
issn = "1022-7954",
publisher = "PLEIADES PUBLISHING INC",
number = "2",

}

RIS

TY - JOUR

T1 - Computer Simulation of the Evolution of Microbial Population

T2 - Overcoming Local Minima When Reaching a Peak on the Fitness Landscape

AU - Lashin, S. A.

AU - Mustafin, Z. S.

AU - Klimenko, A. I.

AU - Afonnikov, D. A.

AU - Matushkin, Yu G.

PY - 2020/2/1

Y1 - 2020/2/1

N2 - The study focuses on the mechanisms of crossing the valleys of fitness by a population of haploid microorganisms, whose fitness depends on allelic values at two different loci and is determined by a complex landscape, the shape of which corresponds to the pattern “a mountain in the field surrounded by a trench”; these mechanisms are analyzed using computer modeling. We have studied the influence of various biological factors on the evolutionary perspective of microbial colonies, the reproduction rate of which is controlled by a protein consisting of two subunits encoded at different loci. Molecular genetic (mutation rate, affinity of subunits), population (fitness function landscape and population density), and ecological (concentration of available substrate in the habitat, flow intensity) factors have been considered. Our results demonstrate that the difference in fitness for various allelic combinations, while determining the shape of the fitness landscape, sets the optimal mutation rates to overcome its valleys and opens a window of opportunity for the evolution of the population toward the state of the highest average fitness. Moreover, depending on the fitness landscape type, either gradual or saltational evolutionary regimes are optimal for reaching the peak.

AB - The study focuses on the mechanisms of crossing the valleys of fitness by a population of haploid microorganisms, whose fitness depends on allelic values at two different loci and is determined by a complex landscape, the shape of which corresponds to the pattern “a mountain in the field surrounded by a trench”; these mechanisms are analyzed using computer modeling. We have studied the influence of various biological factors on the evolutionary perspective of microbial colonies, the reproduction rate of which is controlled by a protein consisting of two subunits encoded at different loci. Molecular genetic (mutation rate, affinity of subunits), population (fitness function landscape and population density), and ecological (concentration of available substrate in the habitat, flow intensity) factors have been considered. Our results demonstrate that the difference in fitness for various allelic combinations, while determining the shape of the fitness landscape, sets the optimal mutation rates to overcome its valleys and opens a window of opportunity for the evolution of the population toward the state of the highest average fitness. Moreover, depending on the fitness landscape type, either gradual or saltational evolutionary regimes are optimal for reaching the peak.

KW - ecological modeling

KW - evolution

KW - fitness landscape

KW - fitness valley

KW - microbial community

KW - mutation rate

UR - http://www.scopus.com/inward/record.url?scp=85082169851&partnerID=8YFLogxK

U2 - 10.1134/S1022795420020076

DO - 10.1134/S1022795420020076

M3 - Article

AN - SCOPUS:85082169851

VL - 56

SP - 242

EP - 252

JO - Russian Journal of Genetics

JF - Russian Journal of Genetics

SN - 1022-7954

IS - 2

ER -

ID: 23878468