Prokaryotic cell-free coupled transcription–translation (TX-TL) systems are emerging as a powerful tool to examine natural product biosynthetic pathways in a test tube. The key advantages of this approach are the reduced experimental time scales and controlled reaction conditions. To realize this potential, it is essential to develop specialized cell-free systems in organisms enriched for biosynthetic gene clusters. This requires strong protein production and well-characterized synthetic biology tools. The Streptomyces genus is a major source of natural products. To study enzymes and pathways from Streptomyces , we originally developed a homologous Streptomyces cell-free system to provide a native protein folding environment, a high G+C (%) tRNA pool, and an active background metabolism. However, our initial yields were low (36 μg/mL) and showed a high level of batch-to-batch variation. Here, we present an updated high-yield and robust Streptomyces TX-TL protocol, reaching up to yields of 266 μg/mL of expressed recombinant protein. To complement this, we rapidly characterize a range of DNA parts with different reporters, express high G+C (%) biosynthetic genes, and demonstrate an initial proof of concept for combined transcription, translation, and biosynthesis of Streptomyces metabolic pathways in a single “one-pot” reaction.
Cell-free gene expression (CFE) systems are an attractive tool for engineering within synthetic biology and for industrial production of high-value recombinant proteins. CFE reactions require a cell extract, energy system, amino acids, and DNA, to catalyse mRNA transcription and protein synthesis. To provide an amino acid source, CFE systems typically use a commercial standard, which is often proprietary. Herein we show that a range of common microbiology rich media (i.e., tryptone, peptone, yeast extract and casamino acids) unexpectedly provide an effective and low-cost amino acid source. We show that this approach is generalisable, by comparing batch variability and protein production in the following range of CFE systems: Escherichia coli (Rosetta™ 2 (DE3), BL21(DE3)), Streptomyces venezuelae and Pichia pastoris. In all CFE systems, we show equivalent or increased protein synthesis capacity upon replacement of the commercial amino acid source. In conclusion, we suggest rich microbiology media provides a new amino acid source for CFE systems with potential broad use in synthetic biology and industrial biotechnology applications.
Streptomyces spp. are a major source of clinical antibiotics and industrial chemicals. Streptomyces venezuelae ATCC 10712 is a fast-growing strain and a natural producer of chloramphenicol, jadomycin and pikromycin, which makes it an attractive candidate as a next-generation synthetic biology chassis. Therefore, genetic tools that accelerate the development of S. venezuelae ATCC 10712, as well as other Streptomyces spp. models, are highly desirable for natural product engineering and discovery. To this end, a dedicated S. venezuelae ATCC 10712 cell-free system is provided in this protocol to enable high-yield heterologous expression of high G+C (%) genes. This protocol is suitable for small scale (10-100 μL) batch reactions in either 96-well or 384-well plate format, while reactions are potentially scalable. The cell-free system is robust and can achieve high yields (~5-10 μM) for a range of recombinant proteins in a minimal setup. This work also incorporates a broad plasmid toolset for real-time measurement of mRNA and protein synthesis, as well as in-gel fluorescence staining of tagged proteins. This protocol can also be integrated with high-throughput synthetic biology workflows or bespoke studies on biosynthetic pathways or single enzymes derived from high G+C (%) genes present in Actinomycetes genomes.
Antimicrobial resistance (AMR) is a pandemic spread across multiple priority infectious disease threats. While the cell envelope plays a key role in AMR, this also makes it challenging to study how antibiotics function inside the cell. Herein, we present aKlebsiella pneumoniaecell-free gene expression (CFE) platform for the rapid profiling of intracellular antibiotic sensitivity and resistance. This cell-free approach provides the unique macromolecular and metabolite components from this microbe, which include multiple antibiotic targets from transcription, translation, and metabolic processes. First, we compare theK. pneumoniaeCFE system to whole cell antimicrobial assays. We find that several antibiotic classes show higher sensitivity in the CFE system, suggesting limitations in antibiotic transport in the whole cell assay. Next, we evolvedK. pneumoniaestrains with resistance to specific antibiotics and use whole genome sequencing analysis for genotyping. As an exemplary case, we show that a single RNA polymerase beta subunit variant H526L (also frequently found in multidrug resistantMycobacterium tuberculosis) confers a 58-fold increase in CFE resistance to rifampicin. Overall, we describe a safe (i.e., non-living, non-pathogenic) platform suitable for studying an infectious disease model in a Containment Level 1 laboratory. Our CFE strategy is generalisable to laboratory and clinicalK. pneumoniaestrains and provides a new experimental tool to profile intracellular AMR variants. In conclusion, our CFE tool provides a significant advance towards understanding AMR and complements wider infectious disease studies.
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