A droplet microfluidics based platform for mining metagenomic libraries for natural compounds
Downloadmicromachines-08-00230.pdf (10.29Mb)
Terms of use
Metadata
Show full item recordAbstract
Historically, microbes from the environment have been a reliable source for novel bio-active compounds. Cloning and expression of metagenomic DNA in heterologous strains of bacteria has broadened the range of potential compounds accessible. However, such metagenomic libraries have been under-exploited for applications in mammalian cells because of a lack of integrated methods. We present an innovative platform to systematically mine natural resources for pro-apoptotic compounds that relies on the combination of bacterial delivery and droplet microfluidics. Using the violacein operon from C. violaceum as a model, we demonstrate that E. coli modified to be invasive can serve as an efficient delivery vehicle of natural compounds. This approach permits the seamless screening of metagenomic libraries with mammalian cell assays and alleviates the need for laborious extraction of natural compounds. In addition, we leverage the unique properties of droplet microfluidics to amplify bacterial clones and perform clonal screening at high-throughput in place of one-compound-per-well assays in multi-well format. We also use droplet microfluidics to establish a cell aggregate strategy that overcomes the issue of background apoptosis. Altogether, this work forms the foundation of a versatile platform to efficiently mine the metagenome for compounds with therapeutic potential. ©2017 Keywords: metagenomic screening; droplet microfluidics; high-throughput screening; natural compound
Date issued
2017-07-25Department
Massachusetts Institute of Technology. Department of ChemistryJournal
Micromachines
Publisher
Multidisciplinary Digital Publishing Institute
Citation
Theodorou, Elias, Randall Scanga, Mariusz Twardowski, Michael P. Snyder, and Eric Brouzes, "A droplet microfluidics based platform for mining metagenomic libraries for natural compounds." Micromachines 8, 8 (2017): no. 230 doi 10.3390/mi8080230 ©2017 Author(s)
Version: Final published version
ISSN
2072-666X