Cell-Free Synthesis: Expediting Biomanufacturing of Chemical and Biological Molecules.

The increasing demand for sustainable alternatives underscores the critical need for a shift away from traditional hydrocarbon-dependent processes. In this landscape, biomanufacturing emerges as a compelling solution, offering a pathway to produce essential chemical materials with significantly reduced environmental impacts. By utilizing engineered microorganisms and biomass as raw materials, biomanufacturing seeks to achieve a carbon-neutral footprint, effectively counteracting the carbon dioxide emissions associated with fossil fuel use. The efficiency and specificity of biocatalysts further contribute to lowering energy consumption and enhancing the sustainability of the production process. Within this context, cell-free synthesis emerges as a promising approach to accelerate the shift towards biomanufacturing. Operating with cellular machinery in a controlled environment, cell-free synthesis offers multiple advantages: it enables the rapid evaluation of biosynthetic pathways and optimization of the conditions for the synthesis of specific chemicals. It also holds potential as an on-demand platform for the production of personalized and specialized products. This review explores recent progress in cell-free synthesis, highlighting its potential to expedite the transformation of chemical processes into more sustainable biomanufacturing practices. We discuss how cell-free techniques not only accelerate the development of new bioproducts but also broaden the horizons for sustainable chemical production. Additionally, we address the challenges of scaling these technologies for commercial use and ensuring their affordability, which are critical for cell-free systems to meet the future demands of industries and fully realize their potential.

A cell-free biosensor for multiplexed and sensitive detection of biological warfare agents.

The rapid and precise detection of pathogenic agents is critical for public health and societal stability. The detection of biological warfare agents (BWAs) is especially vital within military and counter-terrorism contexts, essential in defending against biological threats. Traditional methods, such as polymerase chain reaction (PCR), are limited by their need for specific settings, impacting their adaptability and versatility. This study introduces a cell-free biosensor for BWA detection by converting the 16S rRNA of targeted pathogens into detectable functional protein molecules. The modular nature of this approach allows for the flexible configuration of pathogen detection, enabling the simultaneous identification of multiple pathogenic 16S rRNAs through customized reporter proteins for each targeted sequence. Furthermore, we demonstrate how this method integrates with techniques utilizing retroreflective Janus particles (RJPs) for facile and highly sensitive pathogen detection. The cell-free biosensor, employing RJPs to measure the reflection of non-chromatic white light, can detect 16S rRNA from BWAs at femtomolar levels, corresponding to tens of colony-forming units per milliliter of pathogenic bacteria. These findings represent a significant advancement in pathogen detection, offering a more efficient and accessible alternative to conventional methodologies.

Sensitive Methods to Detect Single-Stranded Nucleic Acids of Food Pathogens Based on Cell-Free Protein Synthesis and Retroreflection Signal Detection.

Cell-free protein synthesis (CFPS) has recently gained considerable attention as a new platform for developing methods to detect various molecules, ranging from small chemicals to biological macromolecules. Retroreflection has been used as an alternative signal to develop analytical methods because it can be detected by using a simple instrument comprising a white light source and a camera. Here, we report a novel reporter protein that couples the capability of CFPS and the simplicity of retroreflection signal detection. The design of the reporter was based on two pairs of protein-peptide interactions, SpyCatcher003-SpyTag003 and MDM2-PMI(N8A). MDM2-MDM2-SpyCatcher003 was decided as the reporter protein, and the two peptides, SpyTag003 and PMI(N8A), were immobilized on the surfaces of retroreflective Janus particles and microfluidic chips, respectively. The developed retroreflection signal detection system was combined with a previously reported CFPS reaction that can transduce the presence of a single-stranded nucleic acid into protein synthesis. The resulting methods were applied to detect 16S rRNAs of several foodborne pathogens. Concentration-dependent relationships were observed over a range of 10° fM to 102 pM, with the limits of detection being single-digit femtomolar concentrations. Considering the designability of the CFPS system for other targets, the retroreflection signal detection method will enable the development of novel methods to detect various molecules.