Detection of β-D-glucuronidase activity in environmental samples using 4-fluorophenyl β-D-glucuronide and 19F NMR

Aleksandra Teriosina; Igor L.  Barsukov; Alan Cartmell; Andrew K. Powell; Andrew V.  Stachulski; Edwin A. Yates

doi:10.1039/D4AY01723D

Detection of β-D-glucuronidase activity in environmental samples using 4-fluorophenyl β-D-glucuronide and 19F NMR

Aleksandra Teriosina, Igor L. Barsukov, Alan Cartmell, Andrew K. Powell, Andrew V. Stachulski, Edwin A. Yates

Biology

Research output: Contribution to journal › Article › peer-review

Abstract

Common methods for establishing the presence of enteric bacteria polluting water supplies, or in other samples, rely on detecting the hydrolysis of model glucuronide substrates by glucuronidases to release a phenolic product quantifiable by absorbance or fluorescence. Substrates include the β-D-glucuronides of p-nitrophenol, and umbelliferyl or quercetin derivatives. One limitation is that it may be difficult or impossible to quantify the released phenolic moiety in samples that are strongly coloured or, that contain fluorescent compounds. Exploiting the sensitivity available from the 19F nucleus to changes in chemical environment which can be detected by 19F NMR spectroscopy, and the almost complete absence of 19F from naturally-occurring samples containing organic matter, which provides background-free signals, we propose a model substrate; 4-fluorophenyl β-D-glucuronide (4FP-glucuronide). The 19F NMR chemical shift position of 4FP-glucuronide changes from -121.0 ppm upon hydrolysis to release 4-fluorophenol, at -124.9 ppm (at pH 6.8), enabling detection of β-glucuronidase activity. We illustrate the use of this substrate with environmental samples from forest soil, standing water, and mud from cattle pasture. Each of these would challenge conventional methods, owing to their opacity or the presence of coloured organic material. The technique enables detection of glucuronidases, a widely-used proxy for enteric bacteria, extending the scope of testing beyond water to include environmental and other challenging samples.

Original language	English
Number of pages	6
Journal	Analytical methods
Early online date	10 Feb 2025
DOIs	https://doi.org/10.1039/D4AY01723D https://doi.org/10.1039/d4ay01723d
Publication status	E-pub ahead of print - 10 Feb 2025

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10.1039/D4AY01723DLicence: CC BY
10.1039/d4ay01723d

Detection of b-D-glucuronidase activity in environmental samples using 4-fluorophenyl b-Dglucuronide and 19F NMR
© The Royal Society of Chemistry 2025
Final published version, 470 KBLicence: CC BY

Cite this

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title = "Detection of β-D-glucuronidase activity in environmental samples using 4-fluorophenyl β-D-glucuronide and 19F NMR",

abstract = "Common methods for establishing the presence of enteric bacteria polluting water supplies, or in other samples, rely on detecting the hydrolysis of model glucuronide substrates by glucuronidases to release a phenolic product quantifiable by absorbance or fluorescence. Substrates include the β-D-glucuronides of p-nitrophenol, and umbelliferyl or quercetin derivatives. One limitation is that it may be difficult or impossible to quantify the released phenolic moiety in samples that are strongly coloured or, that contain fluorescent compounds. Exploiting the sensitivity available from the 19F nucleus to changes in chemical environment which can be detected by 19F NMR spectroscopy, and the almost complete absence of 19F from naturally-occurring samples containing organic matter, which provides background-free signals, we propose a model substrate; 4-fluorophenyl β-D-glucuronide (4FP-glucuronide). The 19F NMR chemical shift position of 4FP-glucuronide changes from -121.0 ppm upon hydrolysis to release 4-fluorophenol, at -124.9 ppm (at pH 6.8), enabling detection of β-glucuronidase activity. We illustrate the use of this substrate with environmental samples from forest soil, standing water, and mud from cattle pasture. Each of these would challenge conventional methods, owing to their opacity or the presence of coloured organic material. The technique enables detection of glucuronidases, a widely-used proxy for enteric bacteria, extending the scope of testing beyond water to include environmental and other challenging samples.",

author = "Aleksandra Teriosina and Barsukov, {Igor L.} and Alan Cartmell and Powell, {Andrew K.} and Stachulski, {Andrew V.} and Yates, {Edwin A.}",

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AU - Teriosina, Aleksandra

AU - Barsukov, Igor L.

AU - Cartmell, Alan

AU - Powell, Andrew K.

AU - Stachulski, Andrew V.

AU - Yates, Edwin A.

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AB - Common methods for establishing the presence of enteric bacteria polluting water supplies, or in other samples, rely on detecting the hydrolysis of model glucuronide substrates by glucuronidases to release a phenolic product quantifiable by absorbance or fluorescence. Substrates include the β-D-glucuronides of p-nitrophenol, and umbelliferyl or quercetin derivatives. One limitation is that it may be difficult or impossible to quantify the released phenolic moiety in samples that are strongly coloured or, that contain fluorescent compounds. Exploiting the sensitivity available from the 19F nucleus to changes in chemical environment which can be detected by 19F NMR spectroscopy, and the almost complete absence of 19F from naturally-occurring samples containing organic matter, which provides background-free signals, we propose a model substrate; 4-fluorophenyl β-D-glucuronide (4FP-glucuronide). The 19F NMR chemical shift position of 4FP-glucuronide changes from -121.0 ppm upon hydrolysis to release 4-fluorophenol, at -124.9 ppm (at pH 6.8), enabling detection of β-glucuronidase activity. We illustrate the use of this substrate with environmental samples from forest soil, standing water, and mud from cattle pasture. Each of these would challenge conventional methods, owing to their opacity or the presence of coloured organic material. The technique enables detection of glucuronidases, a widely-used proxy for enteric bacteria, extending the scope of testing beyond water to include environmental and other challenging samples.

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