Investigation of engineered bacterial adhesins for opportunity to interface cells with abiotic materials

Jessica L. Terrell; Hong Dong; Ellen L. Holthoff; Meagan C. Small; Deborah A. Sarkes; Margaret M. Hurley; Dimitra N. Stratis-Cullum

doi:10.1117/12.2225722

13 May 2016 Investigation of engineered bacterial adhesins for opportunity to interface cells with abiotic materials

Jessica L. Terrell, Hong Dong, Ellen L. Holthoff, Meagan C. Small, Deborah A. Sarkes, Margaret M. Hurley, Dimitra N. Stratis-Cullum

Author Affiliations +

Proceedings Volume 9863, Smart Biomedical and Physiological Sensor Technology XIII; 986308 (2016) https://doi.org/10.1117/12.2225722
Event: SPIE Commercial + Scientific Sensing and Imaging, 2016, Baltimore, MD, United States

Abstract

The convenience of cellular genetic engineering has afforded the power to build ‘smart’ synthetic biological tools with novel applications. Here, we have explored opportunities to hybridize engineered cells with inorganic materials toward the development of 'living' device-compatible systems. Cellular structural biology is engineerable based on the ability to rewrite genetic code to generate recombinant, foreign, or even unnatural proteins. With this capability on the biological end, it should be possible to achieve superior abio-compatibility with the inorganic materials that compose current microfabricated technology.

This work investigated the hair-like appendages of Escherichia coli known as Type 1 fimbriae that enable natural adhesion to glycosylated substrates. Sequence alterations within the fimbrial gene cluster were found to be well-tolerated, evidenced by tagging the fimbriae with peptide-based probes. As a further development, fimbriae tips could be reconfigured to, in turn, alter cell binding. In particular, the fimbriae were fused with a genetically optimized peptide-for-inorganics to enable metal binding.

This work established methodologies to systematically survey cell adhesion properties across a suite of fimbriae-modified cell types as well as to direct patterned cell adhesion. Cell types were further customized for added complexity including turning on secondary gene expression and binding to gold surfaces. The former demonstrates potential for programmable gene switches and the latter for interfacing biology with inorganic materials. In general, the incorporation of 'programmed' cells into devices can be used to provide the feature of dynamic and automated cell response. The outcomes of this study are foundational toward the critical feature of deliberate positioning of cells as configurable biocomponentry. Overall, cellular integration into bioMEMs will yield advanced sensing and actuation.

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Jessica L. Terrell, Hong Dong, Ellen L. Holthoff, Meagan C. Small, Deborah A. Sarkes, Margaret M. Hurley, and Dimitra N. Stratis-Cullum "Investigation of engineered bacterial adhesins for opportunity to interface cells with abiotic materials ", Proc. SPIE 9863, Smart Biomedical and Physiological Sensor Technology XIII, 986308 (13 May 2016); https://doi.org/10.1117/12.2225722

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