Nichola Wong scite author profile

The human gut microbiota is complex, dense, and hugely influential to health. Imbalances in the microbiota have been associated with numerous disease states, in many cases due to the overgrowth of Enterobacteriaceae, such as Escherichia coli. We describe an oligonucleotide antimicrobial that selectively reduces levels of Enterobacteriaceae in vitro, in a model of the human colonic microbiota, and in vivo in a murine study, whilst leaving the core microbiota intact. The antimicrobials are Transcription Factor Decoys (TFDs) that bind to and competitively inhibit an identified transcription factor necessary for growth in the intestine. This is highly conserved amongst Enterobacteriaceae and controls anaerobic respiration and response to nitrosative stress caused by the innate immune response of the host. A nanoparticulate formulation delivers the TFDs to the cytoplasm of E. coli, as visualized by confocal microscopy, and rapidly kills the bacteria under microaerobic conditions. When applied to anin vitro model of the human intestinal microbiota the TFD produced a decrease up to log10 6 c.f.u. ml−1 in coliforms within the Enterobacteriaceae family while other families remain intact. When delivered orally to the intestines of mice similar results were seen: Enterobacteriaceae were decreased or cleared from the wild-type intestinal microbiota while the remaining bacteria were unaffected. This demonstrates that TFDs can be used to make precise changes to the microbiota and has utility in testing associations between dysbiosis and disease and developing microbiota targeted therapeutics.

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Oligonucleotide transcription factor decoys as tools to control bacterial transcription

Louis

McArthur

Wong

2019

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Transcription Factor Decoys (TFDs) are short synthetic oligonucleotides that contain the binding site for specific bacterial transcription factors. When translocated into bacterial cytoplasm they can rapidly kill cells when targeted against essential bacterial pathways. Translocation is currently achieved by combination of the TFD with a proprietary lipidic delivery agent, CM2, to form nanoparticles. These interact with highly conserved anionic phospholipids, such as Cardiolipin, to effect delivery to both Gram-positive and Gram-negative bacteria. Simplifying translocation would be an advance that would allow serial screening of large libraries of TFDs to delineate genetic regulatory networks in numerous types of bacteria, including emerging strains. To achieve this we have combined key chemical moieties of the CM2 delivery molecule to the oligonucleotide conjugate by Click chemistry and show that these discrete conjugates are capable of translocation. Confocal laser scanning microscopy was used to monitor the uptake of the TFD-conjugates to E. coli and in parallel their effect on the targeted genetic pathways was confirmed with reporter strains and plating under selective conditions. Hence, it was confirmed that these conjugates can be used as tools to efficiently and specifically modify gene expression by inhibition of selected transcription factors.

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Nichola Wong

Color, Flavor, and Iron Bioavailability in Iron-Fortified Chocolate Milk

Enterobacteriaceae-selective modification of the intestinal microbiota using oligonucleotide antimicrobials

Oligonucleotide transcription factor decoys as tools to control bacterial transcription

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