Bob Van Hove

A sigma factor toolbox for orthogonal gene expression in Escherichia coli

Abstract Synthetic genetic sensors and circuits enable programmable control over timing and conditions of gene expression and, as a result, are increasingly incorporated into the control of complex and multi-gene pathways. Size and complexity of genetic circuits are growing, but stay limited by a shortage of regulatory parts that can be used without interference. Therefore, orthogonal expression and regulation systems are needed to minimize undesired crosstalk and allow for dynamic control of separate modules. This work presents a set of orthogonal expression systems for use in Escherichia coli based on heterologous sigma factors from Bacillus subtilis that recognize specific promoter sequences. Up to four of the analyzed sigma factors can be combined to function orthogonally between each other and toward the host. Additionally, the toolbox is expanded by creating promoter libraries for three sigma factors without loss of their orthogonal nature. As this set covers a wide range of transcription initiation frequencies, it enables tuning of multiple outputs of the circuit in response to different sensory signals in an orthogonal manner. This sigma factor toolbox constitutes an interesting expansion of the synthetic biology toolbox and may contribute to the assembly of more complex synthetic genetic systems in the future.

Recursive DNA Assembly Using Protected Oligonucleotide Duplex Assisted Cloning (PODAC)

A problem rarely tackled by current DNA assembly methods is the issue of cloning additional parts into an already assembled construct. Costly PCR workflows are often hindered by repeated sequences, and restriction based strategies impose design constraints for each enzyme used. Here we present Protected Oligonucleotide Duplex Assisted Cloning (PODAC), a novel technique that makes use of an oligonucleotide duplex for iterative Golden Gate cloning using only one restriction enzyme. Methylated bases confer protection from digestion during the assembly reaction and are removed during replication in vivo, unveiling a new cloning site in the process. We used this method to efficiently and accurately assemble a biosynthetic pathway and demonstrated its robustness toward sequence repeats by constructing artificial CRISPR arrays. As PODAC is readily amenable to standardization, it would make a useful addition to the synthetic biology toolkit.

Improving formaldehyde consumption drives methanol assimilation in engineered E. coli

Due to volatile sugar prices, the food vs fuel debate, and recent increases in the supply of natural gas, methanol has emerged as a promising feedstock for the bio-based economy. However, attempts to engineer Escherichia coli to metabolize methanol have achieved limited success. Here, we provide a rigorous systematic analysis of several potential pathway bottlenecks. We show that regeneration of ribulose 5-phosphate in E. coli is insufficient to sustain methanol assimilation, and overcome this by activating the sedoheptulose bisphosphatase variant of the ribulose monophosphate pathway. By leveraging the kinetic isotope effect associated with deuterated methanol as a chemical probe, we further demonstrate that under these conditions overall pathway flux is kinetically limited by methanol dehydrogenase. Finally, we identify NADH as a potent kinetic inhibitor of this enzyme. These results provide direction for future engineering strategies to improve methanol utilization, and underscore the value of chemical biology methodologies in metabolic engineering.Engineering E. coli for metabolization of methanol to produce fuels and chemicals has not been fully achieved. Here, the authors combine metabolic engineering and chemical inhibition to improve methanol assimilation and distinguish the role of kinetics and thermodynamics under various culture conditions.

Novel DNA and RNA Elements

Impressive advances in the field of synthetic biology go hand in hand with the discovery, design, and use of novel DNA and RNA elements. Efficient synthesis of large oligonucleotides and double-stranded DNA parts, chip-based synthesis of DNA libraries, and a detailed understanding of fundamental biological mechanisms and increased capacities in bioinformatics enable new findings and applications.

Programming Biology: Expanding the Toolset for the Engineering of Transcription

Transcription is a complex and dynamic process representing the first step in gene expression that can be readily controlled through current tools in molecular biology. Elucidating and subsequently controlling transcriptional processes in various prokaryotic and eukaryotic organisms have been a key element in translational research, yielding a variety of new opportunities for scientists and engineers. This chapter aims to give an overview of how the fields of molecular and synthetic biology have contributed both historically and presently to the state of the art in transcriptional engineering. The described tools and techniques, as well as the emerging genetic circuit engineering discipline, open the door to new advances in the fields of medical and industrial biotechnology.