Sources of Uncertainty in Biotransformation Mechanistic Interpretations and Remediation Studies using CSIA

Ojeda, Ann; Phillips, Elizabeth; Mancini, Silvia; Lollar, Barbara Sherwood

doi:10.1021/acs.analchem.9b01756

Cited by 42 publications

(33 citation statements)

References 45 publications

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“…It can be determined either by simply using the two enrichment factors and the right-hand side of equation 1 on one hand, or from regression analysis in a dual-isotope plots with isotope data of one element versus data of another element in the same compound ( Figure 1). Lambda values were obtained in many studies (Ojeda et al, 2019, Palau et al, 2017, Rosell et al, 2007, Rodriguez-Fernandez et al, 2018, Rodriguez-Fernandez et al, 2018, Dogan-Subasi et al, 2017, Cretnik et al, 2013, Audi-Miro et al, 2013, Palau et al, 2014, Lian et al, 2019, Badin et al, 2016, Mogusu et al, 2015, Ponsin et al, 2019, McKelvie et al, 2009, Pati et al, 2012 from the regression analyses in dual-isotope plots (i.e., ratios of one isotope as a function of another isotope as delta values; Figure 1A).…”

Section: Introductionmentioning

confidence: 98%

“…The slope of the dual-isotope plot (Lambda, ) reflects changes of the isotope ratios of each element, which can be specific to a reaction mechanism, and thus inform about transformation processes in the laboratory or in the field. (Vogt et al, 2016, Elsner, 2010 Several studies (Masbou et al, 2018, Huntscha et al, 2014, Lian et al, 2019, Bouchard et al, 2018, Vogt et al, 2016, Elsner, 2010, Ojeda et al, 2019 refer to  using the simple definition in eq. 1, which is written here as an example for hydrogen vs carbon d values (eq.…”

Section: Introductionmentioning

confidence: 99%

“…Apart from those two different conventions for plotting isotope data, different methods of linear regression were proposed to obtain . These include the ordinary linear regression (OLR), the reduced major axis regression (RMA), and the York linear regression, which have been compared recently (Ojeda et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Quantification of Lambda (Λ) in multi-elemental compound-specific isotope analysis

Höhener

Imfeld

2021

Chemosphere

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Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Quantification of Lambda (Λ) in multi-elemental compound-specific isotope analysis

Höhener

Imfeld

2021

Chemosphere

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“…(iii) Calculating Λs and its uncertainty by dual-isotope plots that use regression with York method (Ojeda et al 2019). Plotting dual-isotope, OLR only minimizes the sum of squares of one type of isotope signature set as y-variable, without considering the measurement error of another one.…”

Section: Introductionmentioning

confidence: 99%

“…While measurement errors are inherent to both variables and neither of them could be ignored. Λyork is obtained by regressing measured data through the York method that incorporates uncertainty in both isotope measurements (Ojeda et al 2019), then Λyork as a more appropriate estimation of Lambda than ΛOLR was proposed.…”

Section: Introductionmentioning

confidence: 99%

A modified method to calculate dual-isotope slopes for the natural attenuation of organic pollutants in the environment

Feng

2021

Environ Sci Pollut Res

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Two-dimensional compound specific isotope analysis has become a powerful tool to distinguish reaction mechanism. Lambda (Λ), an essential and important parameter for processing two-dimensional isotope fractionation data, is specific to a reaction mechanism. In the present article, we modified the existing algorithms for Lambdas based on the review of the current methods. Specifically, through regressing] by York method, a novel method was developed to calculate Λs. The improved method eliminates both the influence of non-reacting position and the initial isotope signatures. Furthermore, this method retains the advantages of two-dimension isotope plot, which eliminates contributions from commitment to catalysis, no need to determine fraction of remaining substrate and can be constructed even from filed data. At the same time, one sample t test is applied to generate 95% confidence interval of data set of Λris for various reaction mechanisms. The range of 5.6724.8, 8.549.80, 0.518.35, 25.236.8, 7.0921.9 are responsible for oxidation of C-H bonds (ZC=1, ZH=3), oxidation of C-H bonds (ZC=1,ZH=4), aerobic biodegradation of benzene (ZC=6,ZH=6), methanogenic or sulfatereducing biodegradation of benzene (ZC=6,ZH=6), and nitrate-reducing biodegradation of benzene (ZC=6,ZH=6). The accumulation and correction of these values will make the data measured in the field easier to interpret.

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Vitamin B₁₂ as a source of variability in isotope effects for chloroform biotransformation by Dehalobacter

Phillips,

Picott,

Kümmel

et al. 2024

MicrobiologyOpen

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Carbon and chlorine isotope effects for biotransformation of chloroform by different microbes show significant variability. Reductive dehalogenases (RDase) enzymes contain different cobamides, affecting substrate preferences, growth yields, and dechlorination rates and extent. We investigate the role of cobamide type on carbon and chlorine isotopic signals observed during reductive dechlorination of chloroform by the RDase CfrA. Microcosm experiments with two subcultures of a Dehalobacter‐containing culture expressing CfrA—one with exogenous cobamide (Vitamin B12, B12+) and one without (to drive native cobamide production)—resulted in a markedly smaller carbon isotope enrichment factor (εC, bulk) for B12− (−22.1 ± 1.9‰) compared to B12+ (−26.8 ± 3.2‰). Both cultures exhibited significant chlorine isotope fractionation, and although a lower εCl, bulk was observed for B12− (−6.17 ± 0.72‰) compared to B12+ (−6.86 ± 0.77‰) cultures, these values are not statistically different. Importantly, dual‐isotope plots produced identical slopes of ΛCl/C (ΛCl/C, B12+ = 3.41 ± 0.15, ΛCl/C, B12− = 3.39 ± 0.15), suggesting the same reaction mechanism is involved in both experiments, independent of the lower cobamide bases. A nonisotopically fractionating masking effect may explain the smaller fractionations observed for the B12− containing culture.

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Sources of Uncertainty in Biotransformation Mechanistic Interpretations and Remediation Studies using CSIA

Cited by 42 publications

References 45 publications

Quantification of Lambda (Λ) in multi-elemental compound-specific isotope analysis

Quantification of Lambda (Λ) in multi-elemental compound-specific isotope analysis

A modified method to calculate dual-isotope slopes for the natural attenuation of organic pollutants in the environment

Vitamin B₁₂ as a source of variability in isotope effects for chloroform biotransformation by Dehalobacter

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Sources of Uncertainty in Biotransformation Mechanistic Interpretations and Remediation Studies using CSIA

Cited by 42 publications

References 45 publications

Quantification of Lambda (Λ) in multi-elemental compound-specific isotope analysis

Quantification of Lambda (Λ) in multi-elemental compound-specific isotope analysis

A modified method to calculate dual-isotope slopes for the natural attenuation of organic pollutants in the environment

Vitamin B12 as a source of variability in isotope effects for chloroform biotransformation by Dehalobacter

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Vitamin B₁₂ as a source of variability in isotope effects for chloroform biotransformation by Dehalobacter