François Coutte1,2, Joachim Niehren3,4, Debarun Dhali5,6, Mathias John6,3, Cristian Versari6,3, Philippe Jacques5,6. 1. ProBioGEM team, Research Institute for Food and Biotechnology - Charles Viollette (EA7394), University of Lille, Villeneuve d'Ascq, France. francois.coutte@polytech-lille.fr. 2. University of Lille, Villeneuve d'Ascq, France. francois.coutte@polytech-lille.fr. 3. BioComputing team, CRIStAL Lab (CNRS UMR9189), University of Lille, Villeneuve d'Ascq, France. 4. Inria Lille, Villeneuve d'Ascq, France. 5. ProBioGEM team, Research Institute for Food and Biotechnology - Charles Viollette (EA7394), University of Lille, Villeneuve d'Ascq, France. 6. University of Lille, Villeneuve d'Ascq, France.
Abstract
A Bacillus subtilis mutant strain overexpressing surfactin biosynthetic genes was previously constructed. In order to further increase the production of this biosurfactant, our hypothesis is that the surfactin precursors, especially leucine, must be overproduced. We present a three step approach for leucine overproduction directed by methods from computational biology. Firstly, we develop a new algorithm for gene knockout prediction based on abstract interpretation, which applies to a recent modeling language for reaction networks with partial kinetic information. Secondly, we model the leucine metabolic pathway as a reaction network in this language, and apply the knockout prediction algorithm with the target of leucine overproduction. Out of the 21 reactions corresponding to potential gene knockouts, the prediction algorithm selects 12 reactions. Six knockouts were introduced in B. subtilis 168 derivatives strains to verify their effects on surfactin production. For all generated mutants, the specific surfactin production is increased from 1.6- to 20.9-fold during the exponential growth phase, depending on the medium composition. These results show the effectiveness of the knockout prediction approach based on formal models for metabolic reaction networks with partial kinetic information, and confirms our hypothesis that precursors supply is one of the main parameters to optimize surfactin overproduction.
A Bacillus subtilis mutant strain overexpressing surfactin biosynthetic genes was previously constructed. In order to further increase the production of this biosurfactant, our hypothesis is that the surfactin precursors, especially leucine, must be overproduced. We present a three step approach for leucine overproduction directed by methods from computational biology. Firstly, we develop a new algorithm for gene knockout prediction based on abstract interpretation, which applies to a recent modeling language for reaction networks with partial kinetic information. Secondly, we model the leucine metabolic pathway as a reaction network in this language, and apply the knockout prediction algorithm with the target of leucine overproduction. Out of the 21 reactions corresponding to potential gene knockouts, the prediction algorithm selects 12 reactions. Six knockouts were introduced in B. subtilis 168 derivatives strains to verify their effects on surfactin production. For all generated mutants, the specific surfactin production is increased from 1.6- to 20.9-fold during the exponential growth phase, depending on the medium composition. These results show the effectiveness of the knockout prediction approach based on formal models for metabolic reaction networks with partial kinetic information, and confirms our hypothesis that precursors supply is one of the main parameters to optimize surfactin overproduction.
Authors: A Théatre; A C R Hoste; A Rigolet; I Benneceur; M Bechet; M Ongena; M Deleu; P Jacques Journal: Adv Biochem Eng Biotechnol Date: 2022 Impact factor: 2.635