Rate-Limiting Mass Transfer in Micropollutant Degradation Revealed by Isotope Fractionation in Chemostat

Ehrl, Benno N.; Kundu, Kalipada; Gharasoo, Mehdi; Marozava, Sviatlana; Elsner, Martin

doi:10.1021/acs.est.8b05175

Cited by 41 publications

(90 citation statements)

References 62 publications

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“…Indeed, the calculated atrazine lipid diffusion coefficient D lip = 1.3 × 10 –17 m 2 /s was, as expected, smaller, but in the same range as D lip recently observed for atrazine in a single lipid bilayer of the Gram-positive A. aurescens TC1. 31 This demonstrates that our modeling approach yields realistic values for k tr allowing us to use k tr to predict a decreasing observed fractionation factor ε* with decreasing atrazine concentrations according to Thullner et al 30 Consistent with our experimental results, at a concentration of 4 mg/L the enzymatic fractionation factor of ε = −5.3 ‰ is already reduced to ε* = −3.5 ‰, and it is predicted to be further reduced to below −3 ‰ already at an atrazine concentration of 1 mg/L.…”

Section: Results and Discussionmentioning

confidence: 99%

“…29,30 Based on these studies, we recently discovered that cell wall permeation was not relevant for atrazine biodegradation by Arthrobacter aurescens TC1 at high concentrations but became suddenly rate-limiting at low concentrations (low microgram per liter range). 31 This finding is challenged by earlier observations by Meyer et al that even at high concentrations, isotope fractionation in atrazine degradation varied significantly between bacterial strains catalyzing the same reaction. 32 Usually, the isotope fractionation factor is assumed to be characteristic for a specific transformation pathway if the underlying enzyme reaction is identical.…”

Section: Introductionmentioning

confidence: 92%

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Isotope Fractionation Pinpoints Membrane Permeability as a Barrier to Atrazine Biodegradation in Gram-negative Polaromonas sp. Nea-C

Ehrl

Gharasoo

Elsner

2018

Environ. Sci. Technol.

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Biodegradation of persistent pesticides like atrazine often stalls at low concentrations in the environment. While mass transfer does not limit atrazine degradation by the Gram-positive Arthrobacter aurescens TC1 at high concentrations (>1 mg/L), evidence of bioavailability limitations is emerging at trace concentrations (<0.1 mg/L). To assess the bioavailability constraints on biodegradation, the roles of cell wall physiology and transporters remain imperfectly understood. Here, compound-specific isotope analysis (CSIA) demonstrates that cell wall physiology (i.e., the difference between Gram-negative and Gram-positive bacteria) imposes mass transfer limitations in atrazine biodegradation even at high concentrations. Atrazine biodegradation by Gram-negative Polaromonas sp. Nea-C caused significantly less isotope fractionation (ε(C) = -3.5 ‰) than expected for hydrolysis by the enzyme TrzN (ε(C) = -5.0 ‰) and observed in Gram-positive Arthrobacter aurescens TC1 (ε(C) = -5.4 ‰). Isotope fractionation was recovered in cell-free extracts (ε(C) = -5.3 ‰) where no cell envelope restricted pollutant uptake. When active transport was inhibited with cyanide, atrazine degradation rates remained constant demonstrating that atrazine mass transfer across the cell envelope does not depend on active transport but is a consequence of passive cell wall permeation. Taken together, our results identify the cell envelope of the Gram-negative bacterium Polaromonas sp. Nea-C as a relevant barrier for atrazine biodegradation.

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Section: Results and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 92%

Isotope Fractionation Pinpoints Membrane Permeability as a Barrier to Atrazine Biodegradation in Gram-negative Polaromonas sp. Nea-C

Ehrl

Gharasoo

Elsner

2018

Environ. Sci. Technol.

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“…[20][21][22][23] Recent work highlights the particular role of pollutant mass transfer into microbial cells as a rate-limiting step for biodegradation, especially at low pollutant concentrations. 24,25 The mass transfer of polar and charged species (e.g., zwitterionic glyphosate 26 ) into bacterial cells is currently assumed to occur by active transport. 27,28 Little is known whether charged molecules can directly permeate the cell membrane as non-polar pollutants do, 29,30 and if so, to what extent the bacterial membrane as diffusion barrier constitutes an even stronger bioavailability limitation for these charged molecules than for non-charged pollutants.…”

Section: Abstract Art Introductionmentioning

confidence: 99%

“…[51][52][53] As a consequence, the enzymatic isotope fractionation that is observable in solution becomes masked in the presence of mass transfer limitations -i.e., when active transport (or passive membrane permeation) into and out of the cell is the rate-determining step in biodegradation. 25,33 For this study, we used a combined approach to gain insight into the role of passive permeation for biodegradation of the zwitterionic pollutant glyphosate, which carries either one (pH < 6) or two (pH > 6) net negative charges at circumneutral pH. First, an NMR study was conducted to experimentally determine pH-dependent passive membrane permeation of glyphosate in phosphatidylcholine liposomes as model system.…”

Section: Abstract Art Introductionmentioning

confidence: 99%

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High Permeation Rates in Liposome Systems Explain Rapid Glyphosate Biodegradation Associated with Strong Isotope Fractionation

Ehrl

Mogusu

Kim

et al. 2018

Environ. Sci. Technol.

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Bacterial uptake of charged organic pollutants such as the widely used herbicide glyphosate is typically attributed to active transporters, whereas passive membrane permeation as an uptake pathway is usually neglected. For 1-palmitoyl-2-oleoyl- sn-glycero-3-phosphocholine (POPC) liposomes, the pH-dependent apparent membrane permeation coefficients ( P) of glyphosate, determined by nuclear magnetic resonance (NMR) spectroscopy, varied from P (pH 7.0) = 3.7 (±0.3) × 10 m·s to P (pH 4.1) = 4.2 (±0.1) × 10 m·s. The magnitude of this surprisingly rapid membrane permeation depended on glyphosate speciation and was, at circumneutral pH, in the range of polar, noncharged molecules. These findings point to passive membrane permeation as a potential uptake pathway during glyphosate biodegradation. To test this hypothesis, a Gram-negative glyphosate degrader, Ochrobactrum sp. FrEM, was isolated from glyphosate-treated soil and glyphosate permeation rates inferred from the liposome model system were compared to bacterial degradation rates. Estimated maximum permeation rates were, indeed, 2 orders of magnitude higher than degradation rates of glyphosate. In addition, biodegradation of millimolar glyphosate concentrations gave rise to pronounced carbon isotope fractionation with an apparent kinetic isotope effect, AKIE, of 1.014 ± 0.003. This value lies in the range typical of non-masked enzymatic isotope fractionation demonstrating that glyphosate biodegradation was not subject to mass transfer limitations and glyphosate exchange across the cell membrane was rapid relative to enzymatic turnover.

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Compound-Specific Isotope Analyses to Investigate Pesticide Transformation in Soil and Water

Gilevska,

Imfeld

2024

Tracing the Sources and Fate of Contaminants in Agroecosystems

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This chapter provides an overview of approaches employed in tracking pesticide degradation within agricultural catchments, focusing on the existing challenges and burgeonic prospects afforded by pesticide compound-specific isotope analyses (CSIA). The discussion centers on the development of CSIA for low concentrations of pesticides in environmental matrices. Additionally, the chapter explores the viability of implementing pesticide CSIA in field applications for tasks such as for source apportionment, discerning transformation reactions, and quantifying the extent of degradation on a catchment scale.

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Rate-Limiting Mass Transfer in Micropollutant Degradation Revealed by Isotope Fractionation in Chemostat

Cited by 41 publications

References 62 publications

Isotope Fractionation Pinpoints Membrane Permeability as a Barrier to Atrazine Biodegradation in Gram-negative Polaromonas sp. Nea-C

Isotope Fractionation Pinpoints Membrane Permeability as a Barrier to Atrazine Biodegradation in Gram-negative Polaromonas sp. Nea-C

High Permeation Rates in Liposome Systems Explain Rapid Glyphosate Biodegradation Associated with Strong Isotope Fractionation

Compound-Specific Isotope Analyses to Investigate Pesticide Transformation in Soil and Water

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