Affiliation:
1. Department of Food Science College of Agricultural and Life Sciences Cornell University Stocking Hall Ithaca NY 14853 USA
2. Department of Clinical Sciences College of Veterinary Medicine Cornell University 602 Tower Rd. Ithaca NY 14853 USA
3. DEVCOM Soldier Center Soldier Sustainment Directorate Combat Feeding Division Food Protection & Innovative Packaging Team Natick MA 01760 USA
Abstract
AbstractAdaptive laboratory evolution (ALE) can be used to make bacteria less susceptible to oxidative stress. An alternative to large batch scale ALE cultures is to use microfluidic platforms, which are often more economical and more efficient. Microfluidic ALE platforms have shown promise, but many have suffered from subpar cell passaging mechanisms and poor spatial definition. A new approach is presented using a microfluidic Evolution on a Chip (EVoc) design which progressively drives microbial cells from areas of lower H2O2 concentration to areas of higher concentration. Prolonged exposure, up to 72 h, revealed the survival of adaptive strains of Lacticaseibacillus rhamnosus GG, a beneficial probiotic often included in food products. After performing ALE on this microfluidic platform, the bacteria persisted under high H2O2 concentrations in repeated trials. After two progressive exposures, the ability of L. rhamnosus to grow in the presence of H2O2 increased from 1 mm H2O2 after a lag time of 31 h to 1 mm after 21 h, 2 mm after 28 h, and 3 mm after 42 h. The adaptive strains have different morphology, and gene expression compared to wild type, and genome sequencing revealed a potentially meaningful single nucleotide mutation in the protein omega‐amidase.
Funder
National Institute of Food and Agriculture
U.S. Army Natick Soldier Research, Development and Engineering Center
National Science Foundation
Subject
Biomaterials,Biotechnology,General Materials Science,General Chemistry