Department of Geosciences, Princeton University, Guyot Hall, Princeton, New Jersey 08544, United States.
Environ Sci Technol. 2012 Jun 5;46(11):5727-35. doi: 10.1021/es204593q. Epub 2012 May 23.
In order to (i) establish the biological systematics necessary to interpret nitrogen (N) and oxygen (O) isotope ratios of nitrate ((15)N/(14)N and (18)O/(16)O) in the environment and (ii) investigate the potential for isotopes to elucidate the mechanism of a key N cycle enzyme, we measured the nitrate N and O isotope effects ((15)ε and (18)ε) for nitrate reduction by two assimilatory eukaryotic nitrate reductase (eukNR) enzymes. The (15)ε for purified extracts of NADPH eukNR from the fungus Aspergillus niger and the (15)ε for NADH eukNR from cell homogenates of the marine diatom Thalassiosira weissflogii were indistinguishable, yielding a mean (15)ε for the enzyme of 26.6 ± 0.2‰. Both forms of eukNR imparted near equivalent fractionation on N and O isotopes. The increase in (18)O/(16)O versus the increase in (15)N/(14)N (relative to their natural abundances) was 0.96 ± 0.01 for NADPH eukNR and 1.09 ± 0.03 for NADH eukNR. These results are the first reliable measurements of the coupled N and O isotope effects for any form of eukNR. They support the prevailing view that intracellular reduction by eukNR is the dominant step in isotope fractionation during nitrate assimilation and that it drives the (18)ε:(15)ε ≈ 1 observed in phytoplankton cultures, suggesting that this O-to-N isotope signature will apply broadly in the environment. Our measured (15)ε and (18)ε may represent the intrinsic isotope effects for eukNR-mediated N-O bond rupture, a potential constraint on the nature of the enzyme's transition state.
为了(i) 建立解释环境中硝酸盐((15)N/(14)N 和 (18)O/(16)O)氮(N)和氧(O)同位素比值所需的生物系统学,以及 (ii) 研究同位素阐明关键 N 循环酶机制的潜力,我们测量了两种同化真核硝酸盐还原酶(eukNR)酶的硝酸盐 N 和 O 同位素效应((15)ε 和 (18)ε)。来自黑曲霉的 NADPH eukNR 纯化提取物的 (15)ε 和海洋硅藻塔玛斯西亚威氏的细胞匀浆中 NADH eukNR 的 (15)ε 无法区分,得出该酶的平均 (15)ε 为 26.6 ± 0.2‰。两种形式的 eukNR 对 N 和 O 同位素赋予了近乎相等的分馏作用。与天然丰度相比,NADPH eukNR 的 (18)O/(16)O 与 (15)N/(14)N 的增加量之比为 0.96 ± 0.01,NADH eukNR 的增加量为 1.09 ± 0.03。这些结果是首次对任何形式的 eukNR 的耦合 N 和 O 同位素效应进行的可靠测量。它们支持这样一种观点,即真核 NR 细胞内还原是硝酸盐同化过程中同位素分馏的主导步骤,并且它驱动了在浮游植物培养物中观察到的 (18)ε:(15)ε≈1,表明这种 O 到 N 的同位素特征将广泛适用于环境。我们测量的 (15)ε 和 (18)ε 可能代表了 eukNR 介导的 N-O 键断裂的固有同位素效应,这可能是酶过渡态性质的潜在限制。
