Abstract
Beneficial and deleterious mutations change an organism’s fitness but the distribution of these mutational effects on fitness are unknown. Several experimental, theoretical, and computational studies have explored this question but are limited because of experimental restrictions, or disconnect with physiology. Here we attempt to characterize the distribution of fitness effects (DFE) due to mutations in a cellular regulatory motif. We use a simple mathematical model to describe the dynamics of gene expression in the lactose utilization network, and use a cost-benefit framework to link the model output to fitness. We simulate mutations by changing model parameters and computing altered fitness to obtain the DFE. We find beneficial mutations distributed exponentially, but distribution of deleterious mutations seems far more complex. In addition, we find neither the starting fitness, nor the exact location on the fitness landscape, affecting these distributions qualitatively. Lastly, we quantify epistasis in our model and find that the distribution of epistatic effects remains qualitatively conserved across different locations on the fitness landscape. Overall, we present a first attempt at exploring the specific statistical features of the fitness landscape associated with a system, by using the specific mathematical model associated with it.
Highlights
Mutations occur spontaneously during the course of reproduction of an organism
These limitations motivated us to ask if it would be possible to obtain a specific fitness landscape and distribution of fitness effects (DFE) of a biological system, derived from the mathematical model defined to functionally characterize the system. Such mathematical models of biological systems when tuned with experimentally derived parameter sets, have been extremely successful in describing the behaviour and dynamical properties of a number of systems[18,19]. If these models truly capture the system’s mechanistic dynamics, it is expected that it should be able to predict the change in the system dynamics upon change in the system parameters by way of mutations, and give us a handle to estimate the altered fitness of the organism
Lactose utilization in E. coli is enabled by the lac operon, which contains genes which encode for the sugar transporter LacY, the metabolic enzyme LacZ, and a protein LacA, which contributes towards lactose utilization via a yet to be characterized mechanism[31,32,33]
Summary
Mutations occur spontaneously during the course of reproduction of an organism. Mutations that impart a beneficial characteristic to the organism are selected and the frequency of the mutant allele increases in the population. The above approaches, either assume an abstract mutational model, or use existing dynamic population level data to estimate fitness effect sizes of mutations (Amino Acid variants or SNPs) in the populations These help provide a general picture, but cannot capture the specific dynamics of a real biological system. These limitations motivated us to ask if it would be possible to obtain a specific fitness landscape and DFE of a biological system, derived from the mathematical model defined to functionally characterize the system Such mathematical models of biological systems when tuned with experimentally derived parameter sets, have been extremely successful in describing the behaviour and dynamical properties of a number of systems[18,19]. If these models truly capture the system’s mechanistic dynamics, it is expected that it should be able to predict the change in the system dynamics upon change in the system parameters by way of mutations, and give us a handle to estimate the altered fitness of the organism
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