A programmable encapsulation system improves delivery of therapeutic bacteria in mice

Tetsuhiro Harimoto(Columbia University), Jaeseung Hahn(Columbia University), Yuyu Chen(Columbia University), Jongwon Im(Columbia University), Joanna Zhang(Columbia University), Nicholas Hou(Columbia University), Fangda Li(Columbia University), Courtney Coker(Columbia University), Kelsey Gray(Columbia University), Nicole Harr(Columbia University), Sreyan Chowdhury(Columbia University), Kelly Pu(Columbia University), Clare A. Nimura(Columbia University), Nicholas Arpaia(Columbia University Irving Medical Center), Kam W. Leong(Columbia University Irving Medical Center), Tal Danino(Columbia University Irving Medical Center)
Nature Biotechnology
March 17, 2022
10.1038/s41587-022-01244-y
Cited by 240Open Access
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Abstract

Living bacteria therapies have been proposed as an alternative approach to treating a broad array of cancers. In this study, we developed a genetically encoded microbial encapsulation system with tunable and dynamic expression of surface capsular polysaccharides that enhances systemic delivery. Based on a small RNA screen of capsular biosynthesis pathways, we constructed inducible synthetic gene circuits that regulate bacterial encapsulation in Escherichia coli Nissle 1917. These bacteria are capable of temporarily evading immune attack, whereas subsequent loss of encapsulation results in effective clearance in vivo. This dynamic delivery strategy enabled a ten-fold increase in maximum tolerated dose of bacteria and improved anti-tumor efficacy in murine models of cancer. Furthermore, in situ encapsulation increased the fraction of microbial translocation among mouse tumors, leading to efficacy in distal tumors. The programmable encapsulation system promises to enhance the therapeutic utility of living engineered bacteria for cancer.

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