Simulating the Influence of Conjugative Plasmids Kinetic Values on the Multilevel Dynamics of Antimicrobial Resistance in a Membrane Computing Model

Abstract: 20Plasmids harboring antibiotic resistance genes differ in their kinetic values as plasmid 21 conjugation rate, segregation rate by incompatibility with related plasmids, rate of 22 stochastic loss during replication, cost reducing the host-cell fitness, and frequency of 23 compensatory mutations to reduce plasmid cost, depending on the cell mutation 24 frequency. How variation in these values influence the success of a plasmid and their 25 resistance genes in complex ecosystems, as the microbiota? Genes ar… Show more

“…Another recent modular platform that aims to serve as a kind of standard model is the Antibiotic Resistance Evolution Simulator (ARES), which can simulate nested compartments from the ecosystem level to the bacterial host [95] . It has been applied to examine how the rate of antibiotic resistance among bacterial species is influenced by a variety of variables that determine the complex parameter space that defines the interaction of biological elements in a given environment [96] and how the plasmid kinetic values that are determined by conjugation rate and segregation rate due to stochastic loss and incompatibility with other plasmids influences the population ecology of antibiotic resistance in a hospital setting [97] .…”

The ecology of plasmid-coded antibiotic resistance: a basic framework for experimental research and modeling

“…Another recent modular platform that aims to serve as a kind of standard model is the Antibiotic Resistance Evolution Simulator (ARES), which can simulate nested compartments from the ecosystem level to the bacterial host [95] . It has been applied to examine how the rate of antibiotic resistance among bacterial species is influenced by a variety of variables that determine the complex parameter space that defines the interaction of biological elements in a given environment [96] and how the plasmid kinetic values that are determined by conjugation rate and segregation rate due to stochastic loss and incompatibility with other plasmids influences the population ecology of antibiotic resistance in a hospital setting [97] .…”

The ecology of plasmid-coded antibiotic resistance: a basic framework for experimental research and modeling

“…In the computational model presented in this article, an epidemic process caused by a particular entity (the virus) occurs among computational entities simulating a community with a particular populational structure, contacts, and behaviours resembling those that occur in the real world. This "virtual community approach" has been recently applied to simulate the infective spread of extrachromosomal genetic elements (plasmids) among bacteria and to predict various interventions to limit the spread of antibiotic resistance genes, bacterial species and their clones in the hospital and community settings (Campos et al 2015;Baquero et al, 2018b;Baquero et al 2019;Campos et al 2020;Gil-Gil et al 2021) The suitability of this approach for studying the effects of potential interventions aimed at limiting the spread of or perpetuation of COVID-19 epidemics is clear. For this purpose, severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is considered a particular object that interacts with other objects (hosts, represented by membranes) in particular scenarios, according to a set of rules and having sensitivity to the frequencies of interacting objects.…”

Simulating the impact of non-pharmaceutical interventions limiting transmission in COVID-19 epidemics using a membrane computing model