维生素 B12 是 Dehalobacter 进行氯仿生物转化时同位素效应变化的来源。

IF 3.9 3区生物学 Q2 MICROBIOLOGY MicrobiologyOpen Pub Date : 2024-08-27 DOI:10.1002/mbo3.1433

Elizabeth Phillips, Katherine Picott, Steffen Kümmel, Olivia Bulka, Elizabeth Edwards, Po-Hsiang Wang, Matthias Gehre, Ivonne Nijenhuis, Barbara S. Lollar

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引用次数: 0

摘要

不同微生物对氯的生物转化所产生的碳和氯同位素效应存在很大差异。还原脱卤酶（RDase）酶含有不同的酰胺，会影响底物偏好、生长产量以及脱氯速率和程度。我们研究了在还原脱卤酶 CfrA 对氯仿进行还原脱氯过程中观察到的碳和氯同位素信号中，钴酰胺类型所起的作用。我们对含有表达 CfrA 的 Dehalobacter 培养物的两个亚培养物进行了微观世界实验--一个含有外源钴酰胺（维生素 B12，B12+），另一个不含外源钴酰胺（驱动原生钴酰胺的产生）--实验结果表明，与 B12+（-26.8 ± 3.2‰）相比，B12-（-22.1 ± 1.9‰）的碳同位素富集因子（εC，bulk）明显较小。两种培养物都表现出明显的氯同位素分馏，虽然与 B12+ 培养物（-6.86 ± 0.77‰）相比，B12- 培养物（-6.17 ± 0.72‰）的εCl、体积较小，但这些值在统计学上没有差异。重要的是，双同位素图产生了相同的ΛCl/C 斜率（ΛCl/C，B12+ = 3.41 ± 0.15，ΛCl/C，B12- = 3.39 ± 0.15），表明两个实验涉及相同的反应机制，与低钴胺碱无关。非同位素分馏掩蔽效应可能解释了在含有 B12- 的培养物中观察到的较小分馏。

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

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 (ε_{C, 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 ε_{Cl, 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 Λ_Cl/C (Λ_{Cl/C, B12+} = 3.41 ± 0.15, Λ_{Cl/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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来源期刊

MicrobiologyOpen MICROBIOLOGY-

CiteScore

8.00

自引率

0.00%

发文量

审稿时长

20 weeks

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