This project will develop a
commercially scalable emerging model organism, called Clostridium
autoethanogenum, that converts a single carbon (C1) feedstock (carbon
dioxide, carbon monoxide, etc. from waste gas emissions) into 3-hydroxyproprionic
acid. 3-hydroxypropionic acid is an ideal biorenewable precursor to
industrially important polymers such as acrylates. To do this, we will apply
several systems and synthetic biology technologies, coupling together
algorithmic design approaches, highly multiplexed genome-scale engineering
techniques, and omics measurements, to exert complete control over the
metabolism of Clostridium autoethanogenum. First, we will employ an
integrated computational-experimental approach to engineer optimized
biosynthesis pathways for 3-hydroxypropionic acid in Clostridium
autoethanogenum. Second, to redirect metabolic flows towards 3-
hydroxypropionic acid production, we will develop and demonstrate a very highly
multiplexed version of CRISPR that utilizes highly non-repetitive genetic parts
to up-regulate or down-regulate up to 20 targeted genes simultaneously. Third,
we will perform technoeconomic assessments of C1 bioconversion to
3-hydroxypropionic acid and couple those assessments to algorithm-designed
genetic modifications, determining genotype-phenotype-cost relationships across
several metrics. This project will result in a commercially scalable emerging
model organism capable of producing 3-hydroxypropionic acid at economically
competitive, high productivities from low-cost C1 feedstock. This project is a
collaboration with LanzaTech Inc.
