Abstract
BackgroundOptimal selection of multiple regulatory genes, known as targets, for deletion to enhance or suppress the activities of downstream genes or metabolites is an important problem in genetic engineering. Such problems become more feasible to address in silico due to the availability of more realistic dynamical system models of gene regulatory and metabolic networks. The goal of the computational problem is to search for a subset of genes to knock out so that the activity of a downstream gene or a metabolite is optimized.Methodology/Principal FindingsBased on discrete dynamical system modeling of gene regulatory networks, an integer programming problem is formulated for the optimal in silico target gene deletion problem. In the first result, the integer programming problem is proved to be NP-hard and equivalent to a nonlinear programming problem. In the second result, a heuristic algorithm, called GKONP, is designed to approximate the optimal solution, involving an approach to prune insignificant terms in the objective function, and the parallel differential evolution algorithm. In the third result, the effectiveness of the GKONP algorithm is demonstrated by applying it to a discrete dynamical system model of the yeast pheromone pathways. The empirical accuracy and time efficiency are assessed in comparison to an optimal, but exhaustive search strategy.SignificanceAlthough the in silico target gene deletion problem has enormous potential applications in genetic engineering, one must overcome the computational challenge due to its NP-hardness. The presented solution, which has been demonstrated to approximate the optimal solution in a practical amount of time, is among the few that address the computational challenge. In the experiment on the yeast pheromone pathways, the identified best subset of genes for deletion showed advantage over genes that were selected empirically. Once validated in vivo, the optimal target genes are expected to achieve higher genetic engineering effectiveness than a trial-and-error procedure.
Highlights
Selecting in silico, in a dynamic model of gene regulatory and metabolic networks, the right target genes for deletion so as to modify phenotypes can substantially expedite and lower the cost of genetic engineering
Our work extends to dynamic models, searching the target genes in silico from any subset of genes in a gene regulatory network (GRN) for deletion to maximize the concentration of a downstream gene
Optimal Deletion in the Yeast Pheromone Pathways We demonstrate our GKONP algorithm using a realistic
Summary
In a dynamic model of gene regulatory and metabolic networks, the right target genes for deletion so as to modify phenotypes can substantially expedite and lower the cost of genetic engineering. The few extant in silico genetic engineering strategies are seriously hampered by the scarcity of realistic dynamic models of gene regulatory and metabolic networks. Optimal selection of multiple regulatory genes, known as targets, for deletion to enhance or suppress the activities of downstream genes or metabolites is an important problem in genetic engineering. Such problems become more feasible to address in silico due to the availability of more realistic dynamical system models of gene regulatory and metabolic networks. The goal of the computational problem is to search for a subset of genes to knock out so that the activity of a downstream gene or a metabolite is optimized
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