Biological systems are inherently complex, composed of many interacting molecules. Even with knowledge of the properties of each individual component, these interactions create a challenge for predicting how changing one enzyme will affect the performance of the whole pathway and the growth of the organism. While synthetic biology has the potential to address certain critical national challenges, progress is hampered by a lack of mathematical models that can be used to guide the optimization of complex biological systems. This project works to optimize the mechanisms that incorporate carbon gas into cell material in order to develop an efficient organism for generating products such as fuels or pigments. The results of the experiments will then yield a computational model capable of predicting the effects of novel combinations of genes. This project will directly lead to specific improvements in an important biotechnological platform, while simultaneously demonstrating a generic approach to using computational biology to efficiently apply the power of genome editing to a variety of synthetic biology challenges. The project also will develop and disseminate computational tools via websites, publications, workshops, and classes that will make it easier for students and researchers to simulate and analyze metabolic networks to learn about fundamental quantitative concepts that underlie their function, and provide interdisciplinary training for undergraduates, graduate students, and postdoctoral fellows.

Epistasis represents a critical challenge to optimizing biological systems. When mutational effects upon growth or product generation depend on the genetic background, assessing performance across the entire parameter space of any system of realistic size quickly becomes impossible. There is an immediate need for two linked developments: empirical techniques that can rapidly generate and assess rational, combinatorial variants, and kinetic modeling techniques to incorporate these data and to make predictions. This project will use this novel approach to optimize the function of the high-efficiency ribulose monophosphate (RuMP) pathway that the team has successfully introduced into the model methanol-consuming organism, Methylobacterium extorquens. In this project, gene editing of a plasmid-encoded suite of enzymes will be performed along with deep sequencing to rapidly assess the fitnesses of a quarter-million genotypes with combinatorial variation in nine dimensions of expression. The resulting epistasis data, combined with direct measurement of intracellular metabolite concentrations for select variant combinations, will be used to infer the numerous parameter values in the kinetic model, which then will be utilized to predict which regions of parameter space would be more or less flexible. These parameter spaces will be targeted and compared in a second round of editing, experimentation and evaluation.

This project is funded by the Systems and Synthetic Biology Program in the Division of Molecular and Cellular Biosciences.

Agency
National Science Foundation (NSF)
Institute
Division of Molecular and Cellular Biosciences (MCB)
Type
Standard Grant (Standard)
Application #
1714949
Program Officer
David Rockcliffe
Project Start
Project End
Budget Start
2017-07-15
Budget End
2021-06-30
Support Year
Fiscal Year
2017
Total Cost
$692,761
Indirect Cost
Name
Regents of the University of Idaho
Department
Type
DUNS #
City
Moscow
State
ID
Country
United States
Zip Code
83844