Dual nitrogen and oxygen isotope fractionation during anaerobic ammonium oxidation by anammox bacteria

Abstract

Natural abundance of stable nitrogen (N) and oxygen (O) isotopes are invaluable biogeochemical tracers for assessing the N transformations in the environment. To fully exploit these tracers, the N and O isotope effects (¹⁵ε and ¹⁸ε) associated with the respective nitrogen transformation processes must be known. However, the N and O isotope effects of anaerobic ammonium oxidation (anammox), one of the major fixed N sinks and NO₃⁻ producers, are not well known. Here, we report the dual N and O isotope effects associated with anammox by three different anammox bacteria including “Ca. Scalindua japonica”, a putative marine species, which were measured in continuous enrichment culture experiments. All three anammox species yielded similar N isotope effects of NH₄⁺ oxidation to N₂ (¹⁵ε_NH4→N2) ranging from 30.9‰ to 32.7‰ and inverse kinetic isotope effects of NO₂⁻ oxidation to NO₃⁻ (¹⁵ε_NO2→NO3 = −45.3‰ to −30.1‰). In contrast, ¹⁵ε_NO2→N2 (NO₂⁻ reduction to N₂) were significantly different among three species, which is probably because individual anammox bacteria species might possess different types of nitrite reductase. We also report the combined O isotope effects for NO₂⁻ oxidation (¹⁸E_NO2→NO3) by anammox bacteria. These obtained dual N and O isotopic effects could provide significant insights into the contribution of anammox bacteria to the fixed N loss and NO₂⁻ reoxidation (N recycling) in various natural environments.

Introduction

Both nitrogen (N) and oxygen (O) isotopes of fixed nitrogen compounds (i.e., ammonia, nitrite, and nitrate) are fractionated during their microbial production and consumption processes comprising the global marine N cycle. Thus, measurements of nitrogen (¹⁵N/¹⁴N) and oxygen (¹⁸O/¹⁶O) isotope ratios of fixed nitrogen compounds have long been used as invaluable biogeochemical stable isotopic tracers to estimate the global marine N budget [1, 2]. The dual N and O isotope analyses provide complementary signatures of co-occurring N transformation processes that could not be revealed by N isotope measurement alone [3]. By convention, these stable isotope ratios are expressed in delta notation (δ¹⁵N and δ¹⁸O) in per mille (‰) versus atmospheric N₂ (air) and Vienna Standard Mean Ocean Water (VSMOW): δ¹⁵N = ([¹⁵N/¹⁴N]_sample/[¹⁵N/¹⁴N]_air − 1) × 1000 and δ¹⁸O = ([¹⁸O/¹⁶O]_sample/[¹⁸O/¹⁶O]_VSMOW − 1) × 1000, respectively. To quantitatively assess the impacts of these processes on dissolved nitrogen species, the degree of isotope fractionation is quantified by the kinetic isotope effect, ε (‰) = [(k_L/k_H) – 1] × 1000, where k_L/k_H is the ratio of the reaction rate constants between the light (k_L) and heavy (k_H) isotopically substituted substrates. The kinetic N and O isotope effects (¹⁵ε and ¹⁸ε, respectively) for key microbial processes provide the basis for interpretation of natural abundance N isotopic distributions in the ocean, freshwater, terrestrial, and groundwater ecosystems.

The kinetic N and O isotope effects associated with microbial ammonium oxidation [4,5,6,7,8], nitrite oxidation [9, 10], dissimilatory nitrite reduction to nitric oxide [11], dissimilatory nitrate reduction (denitrification) [12, 13], and assimilatory nitrate reduction [14, 15] have been determined for laboratory cultures of corresponding bacteria (Fig. 1). These isotope effects vary depending on the microbial species [12], enzymes [11], growth conditions, and/or rates of reaction [6]. Furthermore, the coupled N and O isotope measurements of NO_x (nitrate and/or nitrite) have been performed in the North Pacific margin (e.g. [16,17,18]), Hadal oceans [19], and the Peru oxygen-deficient zone (ODZ) [20,21,22] to assess the regional N cycles. However, there is still much uncertainty with regard to the N cycling processes, especially in ODZs because the isotope effects are not well known for all of the relevant processes.

Fig. 1

Marine microbial nitrogen cycle with the reported N and O isotope effects (¹⁵ε and ¹⁸ε, respectively) of key transformation processes. The O isotope effects of anammox have not been determined yet

Anaerobic ammonium oxidation (anammox) and denitrification are the two major sinks of fixed nitrogen (N) in the ocean. It has been estimated that these microbial processes together remove 230–450 Tg N yr⁻¹ from the global ocean [23, 24], which is thought to occur mainly in oxygen-deficient water columns and sediments. Furthermore, anammox bacteria also contribute to re-oxidation of nitrite to nitrate (i.e., recycling N), because they fix CO₂ into biomass with reducing equivalents generated from oxidation of nitrite to nitrate [25]. Nitrate production by anammox bacteria significantly influences the nitrite and nitrate N and O isotope effects in freshwater and marine systems, which, however, has been overlooked so far [26]. Despite the importance of anammox bacteria in the global N cycle [27,28,29,30,31], the N isotope effect (¹⁵ε) associated with anammox metabolism has been determined for only one freshwater anammox strain, “Ca. Kuenenia stuttgartiensis” [32]. The kinetic O isotope effect (¹⁸ε) of anammox metabolism has not yet been determined. Consequently, their impacts on the distributions of N and O isotopes in the natural environmets could not be addressed.

Five candidatus genera, ‘Ca. Brocadia’ [33], ‘Ca. Kuenenia’ [34], ‘Ca. Scalindua’ [35], ‘Ca. Anammoxoglobus’ [36] and ‘Ca. Jettenia’ [37], and about 20 candidatus species have been tentatively identified to date. The genus ‘Ca. Scalindua’ is halotolerant and the most abundant anammox bacteria found in marine environments [38]. We therefore hypothesized that the nitrite and nitrate N and O isotope effects induced by different genera of anammox bacteria might be different, since they are phylogenetically diverse and might possess different enzymes (e.g., nitrite reductase) and consequently different metabolic pathways [39]. Especially, the determination of isotope effects of marine anammox species, ‘Ca. Scalindua’, is essential to better understand the natural abundance of stable isotope ratios (δ¹⁸O and δ¹⁵N) in the ocean.

Here, we analyzed the N and O isotope effects (¹⁵ε and ¹⁸ε) of nitrite and nitrate associated with anammox metabolism by three anammox species: ‘Ca. S. japonica’, ‘Ca. J. caeni’, and ‘Ca. B. sinica’ in continuous enrichment cultures. We found that species-dependent N and O isotope effects (¹⁵ε and ¹⁸ε), which could provide significant insights into the relative contribution of anammox bacteria to the fixed N loss and nitrite re-oxidation (recycling N) in various natural environments.

Materials and methods

Continuous culture experiments

Free-living planktonic cultures of three anammox bacteria species were enriched and cultivated in 3 L membrane bioreactors (MBRs) equipped with a hollow fiber membrane module (pore size 0.1 μm, polyethylene) as previously described [38, 40, 41] (Fig. S1). The pH was not controlled but was always between 7.9–8.0 for “Ca. S. japonica”, 8.6–8.9 for “Ca. J. caeni”, and 7.3–7.4 for “Ca. B. sinica”, respectively. The temperature was controlled at 25 °C for “Ca. S. japonica”, 30 °C for “Ca. J. caeni”, and 37 °C for “Ca. B. sinica”, respectively. The details of reactor operation and culture preparation are given in Fig. S1. Once the MBRs have reached a steady state (the concentrations of nitrogen compounds (NH₄⁺, NO₂⁻, and NO₃⁻) in the effluents stabilized after about 2-month operation), three or four sub-samples of MBR influent and effluent (permeate) were taken. After sampling, pH was measured and immediately filtered using 0.2-μm cellulose acetate filter (Advantec) for concentration and isotopic measurements of NH₄⁺, NO₂⁻, and NO₃⁻.

Sample preparation for isotopic analysis

After filtration, immediately samples were adjusted to pH 2 by adding 2 M H₂SO₄ solution and then stored at −20 °C until analysis for N isotope of NH₄⁺ to prevent NH₄⁺ from volatilizing. To analyze N and O isotope of NO₂⁻, after filtration, immediately sample solution was adjusted to pH 12 by adding 2 M NaOH solution and stored at −20 °C until analysis to prevent O isotope exchange between NO₂⁻ and H₂O during sample storage. To analyze N and O isotope of NO₃⁻, after filtration, if the concentration ratio of NO₂⁻/NO₃⁻ was over 5%, NO₂⁻ in the sample solution was immediately removed by adding sulfamic acid (H₃NSO₃), because NO₂⁻ interferes with NO₃⁻ isotope analysis. The concentration of NO₂⁻ was measured with naphthylethylenediamine method [42] to confirm NO₂⁻ was completely removed. We confirmed that NO₂⁻ was completely removed in all samples. Then, sample solution was adjusted to pH 8.5–9 by adding 2 M NaOH solution and stored at −20 °C until analysis.

Chemical analyses

The concentration of NH₄⁺ was measured by the indophenol blue method [42] with a multi-label plate reader (ARVO MX 1420-01J; PerkinElmer; Waltham, MA, USA). The NO₂⁻ concentration was measured by the naphthylethylenediamine method [42]. The concentration of NO₃⁻ was measured using ion chromatographs (IC-2010, TOSOH; Tokyo, Japan) equipped with a TSKgel IC-Anion HS column (TOSOH; Tokyo, Japan).

Isotope ratio analyses

NH₄⁺ nitrogen isotope analyses were performed by using the ammonium diffusion method [43, 44] and subsequently measured by a EA-IRMS (Flash EA1112, ConFlo IV interface, Delta plus Advantage; ThremoFinnigan). International and internal NH₄⁺ isotopic standards, USGS25 (δ¹⁵N = −30.4‰), USGS26 (δ¹⁵N = 53.7‰), and IAEA-N-2 (δ¹⁵N = 20.3‰) were used for the calibration. Replicate analyses yielded respective precision of 0.3‰ for δ¹⁵N_NH4+.

NO₂⁻ nitrogen and oxygen isotope ratios were measured by chemical conversion of NO₂⁻ to nitrous oxide (N₂O) with the azide method [45]. All samples and standards were exactly adjusted to same pH (pH = 12) and salinity (0.5 M NaCl) as mentioned above. The N₂O was then analyzed in duplicate using a GC–IRMS (SerCon) with in-house calibrated NO₂⁻ isotopic standards that were calibrated against N-23, N-7373, and N-10219 [46]; NO2-1 (δ¹⁵N = −66.9‰, δ¹⁸O = 27.0‰), NO2-2 (δ¹⁵N = −64.8‰, δ¹⁸O = 1.1‰), NO2-3 (δ¹⁵N = −67.3‰, δ¹⁸O = 20.3‰), NO2-4 (δ¹⁵N = −68.4‰, δ¹⁸O = 14.9‰), NO2-5 (δ¹⁵N = 0.2‰, δ¹⁸O = 20.2‰). Replicate analyses yielded respective precisions of 0.3‰ for δ¹⁵N_NO2− and 0.5‰ for δ¹⁸O_NO2-, respectively.

NO₃⁻ nitrogen and oxygen isotope ratios were measured by microbial conversion of NO₃⁻ to N₂O with the denitrifier method [47, 48]. N₂O was analyzed in triplicate using a GC–IRMS (SerCon) with international NO₃⁻ isotopic standards; IAEAN3 (δ¹⁵N = 4.7‰, δ¹⁸O = 25.6‰), USGS32 (δ¹⁵N = 180‰, δ¹⁸O = 25.7‰), USGS34 (δ¹⁵N = −1.8‰, δ¹⁸O = −27.9‰), and USGS35 (δ¹⁸O = 57.5‰). Replicate analyses yielded respective precisions of 0.2‰ for δ¹⁵N_NO3− and 1.0‰ for δ¹⁸O_NO3−, respectively.

Calculations of isotope effects

Anammox bacteria oxidize NH₄⁺ directly to N₂ gas with NO₂⁻ as the terminal electron acceptor in the absence of oxygen, and NO₂⁻ is concomitantly oxidized to NO₃⁻ as shown in the following stoichiometric equation [49]:

$$\begin{array}{l}1{\mathrm{NH}}_4^ + + 1.146{\mathrm{NO}}_2^ - + 0.071{\mathrm{HCO}}_3^ - + 0.057{\mathrm{H}}^ + \\ \to 0.986{\mathrm{N}}_2 + 0.161{\mathrm{NO}}_3^ - + 0.071{\mathrm{CH}}_{1.74}{\mathrm{O}}_{0.31}{\mathrm{N}}_{0.20} + 2.002{\mathrm{H}}_2{\mathrm{O}}\end{array}$$

The continuous MBR system is considered as an open system with balanced input and two or three output fluxes (product(s) and residual substrate) [50]. The N isotope effects were analyzed for the following redox reaction: (1) NH₄⁺ oxidation to N₂, (2) NO₂⁻ reduction to N₂, and (3) NO₂⁻ oxidation to NO₃⁻.

N isotope effect of NH₄ ⁺ oxidation to N₂

Ammonium (NH₄⁺) was continuously fed into the MBR where NH₄⁺ oxidation to N₂ (NH₄⁺ →  N₂) occurs with fractionation (¹⁵ε₁), and unused NH₄⁺ exits without further fractionation (i.e., ¹⁵ε₂ = 0) (Fig. 2a). The isotope compositions of product N₂ (δ_product) and residual NH₄⁺ (δ_RS) at steady state can be given simply by subtracting ε fractionations from the isotope composition of intermediate pool (δ_p) [50].

$$\delta_{{\mathrm{product}}} = \delta _{\mathrm{p}} - {\, }^{15}\varepsilon _{1}$$

(1)

$${\mathrm{\delta }}_{{\mathrm{RS}}} = {\mathrm{\delta }}_{\mathrm{p}} - {\, }^{15}{\mathrm{\varepsilon }}_2 = {\mathrm{\delta }}_{\mathrm{p}}\;\;\left( {{\mathrm{when}}\, {\, }^{15}{\mathrm{\varepsilon }}_2 = 0} \right)$$

(2)

Fig. 2

Diagram of a steady-state box model. a a substrate (NH₄⁺) entering to a MBR and a product (N₂) is formed and unused substrate (NH₄⁺) exits without further fractionation. b A substrate (NO₂⁻) entering to a MBR and two products (N₂ and NO₃⁻) are formed and unused substrate (NO₂⁻) exits without further fractionation

The steady-state isotope mass balance can be described as follows:

$$\begin{array}{*{20}{c}} {\delta _{{\mathrm{IN}}} = f\delta _{{\mathrm{product}}} + \left( {1-f} \right)\delta _{{\mathrm{RS}}}} \\ {\delta _{{\mathrm{IN}}} = f\left( {\delta _{\mathrm{p}} - {\, }^{15}\varepsilon _{1}} \right) + \left( {1-f} \right)\left( {\delta _{\mathrm{p}} - {\, }^{15}\varepsilon _{2}} \right)} \\ {\delta _{\mathrm{p}} = \delta _{{\mathrm{IN}}} + f^{15}\varepsilon _{1}} \end{array}$$

(3)

where f is the fraction of NH₄⁺ consumed at steady state.

Therefore, from Eqs. (2) and (3), the kinetic isotope effects associated with NH₄⁺ oxidation to N₂ (¹⁵ε₁) can be determined as follows, when δ_IN, δ_RS, and f are measured experimentally:

$$\begin{array}{*{20}{c}} {{}^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{1}} = \left( {{\mathrm{\delta }}_{{\mathrm{RS}}} - {\mathrm{\delta }}_{{\mathrm{IN}}}} \right){\mathrm{/f}}} \\ {f = \left( {{\mathrm{C}}_{{\mathrm{in - NH4 + }}} - {\mathrm{C}}_{{\mathrm{out - NH4 + }}}} \right){\mathrm{/C}}_{{\mathrm{in - NH4 + }}}} \end{array}$$

(4)

where C_in-NH4+ and C_out-NH4+ are the NH₄⁺ concentrations of MBR influent and effluent, respectively.

N isotope effects of NO₂ ⁻ reduction and oxidation

Nitrite (NO₂⁻) is also continuously fed together with NH₄⁺ into the MBR where NO₂⁻ reduction to N₂ and NO₂⁻ oxidation to NO₃⁻ concomitantly occur with fractionations (defined as ¹⁵ε₃ and ¹⁵ε₅, respectively), and unused residual NO₂⁻ exits the MBR without further fractionation (i.e., ¹⁵ε₄ = 0) (Fig. 2b). The isotope compositions of product N₂ (δ_product1), product NO₃⁻ (δ_product2), and residual NO₂⁻ (δ_RS) at steady state can be given simply by subtracting ε fractionations from the isotope composition of intermediate pool (δ_p):

$${\mathrm{\delta }}_{{\mathrm{product1}}} = {\mathrm{\delta }}_{\mathrm{p}}-{}^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{3}}$$

(5)

$$\delta_{\mathrm{RS}} = \delta_{\mathrm{p}}-{ }^{15}\varepsilon_{4} = \delta_{\mathrm{p}}\left({\, }^{15}\varepsilon_{4} = 0\right)$$

(6)

$$\delta _{{\mathrm{product2}}} = \delta _{\mathrm{p}}- {}^{15}\varepsilon _{5}$$

(7)

Now it is assumed that input flux is 1 and output flux is divided into α, β, and γ (Fig. 2b)

$${\mathrm{1}} = {\mathrm{\alpha }} + {\mathrm{\beta }} + {\mathrm{\gamma }}$$

(8)

where α is the fraction of NO₂⁻ converted to N₂. It is represented by NH₄⁺ consumption, because NH₄⁺ and NO₂⁻ react at 1:1 ratio to form N₂ (excluding NO₂⁻ oxidation to NO₃⁻ from the overall anammox reaction).

$${\mathrm{\alpha }} = \left( {{\mathrm{C}}_{{\mathrm{in - NH4}} + } - {\mathrm{C}}_{{\mathrm{out - NH4}} + }} \right)/{\mathrm{C}}_{{\mathrm{in - NO2 - }}}$$

(9)

β is the fraction of residual NO₂⁻ (unused) at steady state, which is experimentally determined.

$${\mathrm{\beta }} = {\mathrm{C}}_{{\mathrm{out - NO2 - }}}/{\mathrm{C}}_{{\mathrm{in - NO2 - }}}$$

(10)

γ is the fraction of NO₂⁻ oxidized to NO₃⁻. Although γ could be determined from the NO₃⁻ concentration in MBR effluent at steady state, the influence of heterotrophic denitrification and dissimilatory nitrate reduction to ammonium (DNRA) by anammox bacteria cannot be excluded. Therefore, γ was determined as follows:

$${\mathrm{\gamma }} = {\mathrm{1}} - {\mathrm{\alpha }} - {\mathrm{\beta }}$$

(11)

Applying Eqs. (5), (6), and (7) yields the following steady-state isotope mass balance:

$$\delta _{{\mathrm{IN}}} = \alpha \, \delta _{{\mathrm{product}}1} + \beta \, \delta _{{\mathrm{RS}}} + \gamma \, \delta _{{\mathrm{product}}2}$$

(12)

$${\mathrm{\delta }}_{{\mathrm{IN}}} = {\mathrm{\alpha }}\left( {{\mathrm{\delta }}_{\mathrm{p}}-{}^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{3}}} \right) + {\mathrm{\beta }}\,{\mathrm{\delta }}_{\mathrm{p}} + {\mathrm{\gamma }}\left( {{\mathrm{\delta }}_{\mathrm{p}}-{}^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{5}}} \right)\\ \\ = \left( {{\mathrm{\alpha }} + {\mathrm{\beta }} + {\mathrm{\gamma }}} \right){\mathrm{\delta }}_{\mathrm{p}}-{\mathrm{\alpha }}^{15}{\mathrm{\varepsilon }}_3-{\mathrm{\gamma }}^{15}{\mathrm{\varepsilon }}_{5}$$

(13)

$$\hskip 15pt = {\mathrm{\delta }}_{\mathrm{p}}-{\mathrm{\alpha }}^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{3}}-{\mathrm{\gamma }}^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{5}} = {\mathrm{\delta }}_{{\mathrm{RS}}}-{\mathrm{\alpha }}^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{3}}-{\mathrm{\gamma }}^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{5}}$$

(14)

Therefore, ¹⁵ε₃ and ¹⁵ε₅ can be calculated as follows, when δ_IN, δ_RS, and δ_product2 are measured experimentally:

$$^{15}{\mathrm{\varepsilon }}_3 = \left( {{\mathrm{\delta }}_{{\mathrm{RS}}} - {\mathrm{\delta }}_{{\mathrm{IN}}} - {\mathrm{\gamma }}^{15}{\mathrm{\varepsilon }}_5} \right){\mathrm{/\alpha }}$$

(15)

$$^{{\mathrm{15}}}{\mathrm{\varepsilon }}_{\mathrm{5}} = {\mathrm{\delta }}_{{\mathrm{RS}}} - {\mathrm{\delta }}_{{\mathrm{product2}}}$$

(16)

δ_product2 in the Eqs. (7) and (16) is not simply δ_out-NO3- because the influent media contained 0.84–1.21 mmol-N/L of NO₃⁻, which was originated from the university ground water (Table S1). Thus, the background isotope ratio of NO₃⁻ should be considered.

Isotope mass balance

$${\mathrm{\delta }}_{{\mathrm{out - NO3 - }}} \times {\mathrm{C}}_{{\mathrm{out - NO3 - }}} = \,\,{\mathrm{\delta }}_{{\mathrm{in - NO3 - }}} \times {\mathrm{C}}_{{\mathrm{in - NO3 - }}} \\ + {\mathrm{\delta }}_{{\mathrm{produced - NO3 - }}} \times {\mathrm{C}}_{{\mathrm{produced - NO3 - }}}$$

(17)

Mass balance

$${\mathrm{C}}_{{\mathrm{out - NO3 - }}} = {\mathrm{C}}_{{\mathrm{in - NO3 - }}} + {\mathrm{C}}_{{\mathrm{produced - NO3 - }}}$$

(18)

Applying Eqs. (17) and (18) yields the following equation for δ_{produced-NO3-}:

$$ {\mathrm{\delta }}_{{\mathrm{produced - NO3 - }}} = {\mathrm{\delta }}_{{\mathrm{product2}}} =\\ \ \ \left( {{\mathrm{\delta }}_{{\mathrm{out - NO3 - }}} \times {\mathrm{C}}_{{\mathrm{out - NO3 - }}} - {\mathrm{\delta }}_{{\mathrm{in - NO3 - }}} \times {\mathrm{C}}_{{\mathrm{in - NO3 - }}}} \right)\\ \ /{\mathrm{C}}_{{\mathrm{produced - NO3 - }}}$$

(19)

O isotope effect of nitrite oxidation

For calculation of oxygen isotope effect for nitrite oxidation (NO₂⁻ → NO₃⁻), the produced NO₃⁻ contains three oxygen atoms: two oxygen atoms come from NO₂⁻ and one oxygen atom comes from H₂O. The incorporation of an oxygen atom from water should be considered (¹⁸ε₆ in Fig. 2b). Thus, for oxygen isotopes, Eq. (7) is rewritten as

$${\mathrm{\delta }}_{{\mathrm{product2}}} = {\mathrm{2}}/{\mathrm{3}}\left( {{\mathrm{\delta }}_{{\mathrm{RS}}} - ^{{\mathrm{18}}}{\mathrm{\varepsilon }}_{\mathrm{5}}} \right) + {\mathrm{1/3}}\left( {{\mathrm{\delta }}_{{\mathrm{H2O}}} - ^{{\mathrm{18}}}{\mathrm{\varepsilon }}_{\mathrm{6}}} \right)$$

(20)

$${\mathrm{\delta }}_{{\mathrm{product2}}} = {\mathrm{2}}/{\mathrm{3\delta }}_{{\mathrm{RS}}} + {\mathrm{1/3\delta }}_{{\mathrm{H2O}}} - \left( {{\mathrm{2/3}}^{{\mathrm{18}}}{\mathrm{\varepsilon }}_{\mathrm{5}} + {\mathrm{1/3}}^{{\mathrm{18}}}{\mathrm{\varepsilon }}_{\mathrm{6}}} \right)$$

(21)

¹⁸ε₆ is the isotope effect for water incorporation. Since there are two unknown values (¹⁸ε₅ and ¹⁸ε₆) in the Eq. (21), ¹⁸ε₅ and ¹⁸ε₆ cannot be calculated independently. Thus, the term (2/3 ¹⁸ε₅ + 1/3 ¹⁸ε₆) in Eq. (21) is denoted as a combined oxygen isotope effect ¹⁸E_{NO2−→NO3−}.

$$ ^{{\mathrm{18}}}{\mathrm{E}}_{{\mathrm{NO2}} \to {\mathrm{NO3 - }}} =\\ \ \left( {{\mathrm{2/3}}^{{\mathrm{18}}}{\mathrm{\varepsilon }}_{\mathrm{5}} + {\mathrm{1/3}}^{{\mathrm{18}}}{\mathrm{\varepsilon }}_{\mathrm{6}}} \right) = {\mathrm{2/3\delta }}_{{\mathrm{RS}}} + {\mathrm{1/3\delta }}_{{\mathrm{H2O}}} - {\mathrm{\delta }}_{{\mathrm{product2}}}$$

(22)

This combined oxygen isotope effect can be calculated from the obtained data set in this study.

Results

Reactor performance

After the MBRs have reached a steady state, three or four sub-samples of MBR influent and effluent (permeate) were taken and analyzed for the concentrations and N and O isotope ratios of NH₄⁺, NO₂⁻, and NO₃⁻, respectively. The steady-state concentrations of NH₄⁺, NO₂⁻, and NO₃⁻ in the MBR effluents were very stable during the entire experiments (Tables S1 and 1). NO₂⁻ was almost completely consumed, whereas 1.3–3.1 mM NH₄⁺ remained in all the MBR effluents and a small amount of NO₃⁻ was produced. The average stoichiometric ratios of consumed NO₂⁻ and consumed NH₄⁺ (∆NO₂⁻/∆NH₄⁺, ranging from 1.11 ± 0.5 to 1.28 ± 0.5) and produced NO₃⁻ and consumed NH₄⁺ (∆NO₃⁻/∆NH₄⁺, ranging from 0.10 ± 0.01 to 0.2 ± 0.03) (Table 1) agreed with the previously observed stoichiometry of anammox process (i.e. 1.15 and 0.16 for ∆NO₂⁻/∆NH₄⁺ and ∆NO₃⁻/∆NH₄⁺, respectively) [49], suggesting that the anammox process being responsible for transformation of nitrogen compounds occurring in all three MBRs.

Table 1 Summary of MBR performance and N and O isotope analyses

Although influent NH₄⁺ and NO₂⁻ concentrations were different (~10 mM for “Ca. S. japonica”, 10 mM for “Ca. J. caeni” and 16 mM for “Ca. B. sinica”), anammox activity in each MBR culture was consistent as demonstrated by similar volumetric NH₄⁺ consumption, NO₂⁻ consumption, and NO₃⁻ production rates (Table 1). Furthermore, there were no significant difference in specific NH₄⁺ consumption rates (ranging from 1.14 ± 0.06 to 1.27 ± 0.06 mg-N mg-protein⁻¹ h⁻¹), NO₂⁻ consumption rates (ranging from 1.41 ± 0.05 to 1.48 ± 0.04 mg-N mg-protein⁻¹ h⁻¹), and NO₃⁻ production rates (ranging from 0.11 ± 0.01 to 0.24 ± 0.03 mg-N mg-protein⁻¹ h⁻¹) among three MBR cultures.

The ratio of anammox bacteria to the cell culture (degree of enrichment cultures) was determined by fluorescent in situ hybridization (FISH); 94.4 ± 6.5% for “Ca. S. japonica”, 86.1 ± 4.9% for “Ca. J. caeni”, and 96.9 ± 2.6% for “Ca. B. sinica”, respectively.

Nitrogen isotope effects (¹⁵ε)

The culture media with an equimolar amount of NH₄⁺ (δ¹⁵N_IN = −7.0 ± 0.3‰ to −2.4 ± 0.2‰) and NO₂⁻ (δ¹⁵N_IN = −3.7 ± 0.1‰ to −2.6 ± 0.7‰ and δ¹⁸O_IN = 6.0 ± 0.5‰ to 8.1 ± 0.7‰) were continuously fed to the individual MBR cultures (Table 1). N isotope effects of NH₄⁺ oxidation to N₂ (¹⁵ε_NH4→N2), NO₂⁻ reduction to N₂ (¹⁵ε_NO2→N2), and NO₂⁻ oxidation to NO₃⁻ (¹⁵ε_NO2→NO3) were calculated for all three species using the equations described in “Materials and methods” (Fig. 3 and Table S1). In the case of NH₄⁺ oxidation to N₂, the values of ¹⁵ε_NH4→N2 were consistent among three species (30.9 ± 0.2‰ – 32.7 ± 0.7‰). In contrast, there were significant differences in the ¹⁵ε_NO2→N2 values (NO₂⁻ reduction to N₂). “Ca. J. caeni” showed the largest value (29.5 ± 3.9‰), whereas “Ca. B. sinica” yielded the smallest value (5.9 ± 4.5‰). The value of “Ca. S. japonica” was ¹⁵ε_NO2→N2 = 19.9 ± 1.7‰, which was close to the previously reported value of “Ca. K. stuttgartiensis” (16.0 ± 4.5‰) [32]. In the case of NO₂⁻ oxidation to NO₃⁻, all three species showed strong inverse kinetic isotope effects (¹⁵ε_NO2→NO3 < 0); −30.1 ± 3.0‰ for “Ca. S. japonica”, −45.3 ± 4.2‰ for “Ca. J. caeni”, and −31.5 ± 4.0‰ for “Ca. B. sinica”, respectively (Fig. 3 and Table S1), which consists with the previously reported value of “Ca. K. stuttgartiensis” (−31.1 ± 3.9‰) [32].

Fig. 3

Summary of N and O isotope effects induced by different anammox species

Oxygen isotope effect (¹⁸ε)

δ¹⁸O_H2O of ground water which was used for medium preparation was determined to be −11.12‰ ± 0.2‰ (n = 3) and remained stable during an entire experimental period. Both δ¹⁸O_NO2− and δ¹⁸O_NO3− in MBR influents were consistent among three anammox cultures, respectively (Table 1). Under steady-state conditions, similar values of δ¹⁸O_NO2− were determined in all three MBR effluents; 6.4 ± 0.2‰ for “Ca. S. japonica”, 5.2 ± 0.3‰ for “Ca. J. caeni”, and 4.9 ± 1.4‰ for “Ca. B. sinica”, respectively (Table 1). In contrast, the “Ca. S. japonica” MBR yielded a higher δ¹⁸O_{NO3- produced} value (12.7 ± 0.8‰) as compared with those of “Ca. J. caeni” (1.7 ± 0.8‰) and “Ca. B. sinica” (1.0 ± 0.4‰). Based on these δ¹⁸O data, the combined O isotope effect during NO₂⁻ oxidation to NO₃⁻ was calculated for all three species using the Eq. (22) (¹⁸E_NO2→NO3 = (2/3 ¹⁸ε₅ + 1/3 ¹⁸ε₆) = 2/3δ_RS + 1/3δ_H2O−δ_product2) (Table S1 and Fig. 3). All three species showed inverse kinetic isotope effects; −12.1 ± 0.8‰ for “Ca. S. japonica”, −1.9 ± 0.8‰ for “Ca. J. caeni”, and −1.5 ± 1.2‰ for “Ca. B. sinica”, respectively.

Discussion

Continuous culture method

In this study, the N and O isotope effects induced by anammox bacteria were measured using continuous MBR anammox-enrichment cultures. There are some advantages of use of the continuous culture system over batch system. A steady-state fractionation model is basically simpler than a batch model such as the Rayleigh model, in which the isotope effect (ε) values can be directly determined from the isotopic compositions of reactants in the influent and products in the effluent at steady state (Fig. 2). Nearly identical results of the N and O isotope effects were obtained from the different sampling campaigns for “Ca. B. sinica” (Table S2), which indicates the high reproducibility of continuous steady-state culturing systems for isotope effect analyses (Table S3). The precision of ¹⁵ε and ¹⁸ε as measured in the steady-state continuous systems compares favorably with that of batch culture experiments [7].

In addition, growth conditions (i.e., pH, concentrations of reactants and products, and so on) vary over time, which may also significantly affect the isotope fractionations. However, oxygen isotope exchange between NO₂⁻ and H₂O cannot be evaluated in the continuous culture experiment alone, and thus batch culture experiments must be conducted in parallel.

Species-level differences

Among five tentatively proposed candidatus genera of anammox bacteria, one putative marine strain (‘Ca. Scalindua japonica’) and two freshwater strains (‘Ca. Brocadia sinica’ and ‘Ca. Jettenia caeni’) were examined for N and O isotope effects of anammox metabolism in this study. The results revealed species-dependent isotope effects of NO₂⁻ reduction to N₂. During anammox metabolism (NO₂⁻ + NH₄⁺ → N₂), the following three enzymatic reactions occur; (i) NO₂⁻ reduction to nitric oxide (NO) or hydroxylamine (NH₂OH) [51], (ii) hydrazine (N₂H₄) formation from NO or NH₂OH and NH₄⁺, and (iii) N₂H₄ oxidation to N₂ [25]. Hydrazine synthesis is considered to be the rate-limiting step in this reaction sequence due to three-electron reduction reaction [25].

For the conversion of NH₄⁺ to N₂, the N isotope effects (¹⁵ε_NH4→N2) of all three species are consistent (30.9–32.7‰), which also do not significantly differ from the range of ¹⁵ε_NH4→N2 reported previously for “Ca. K. stuttgartiensis” (23.5–29.1‰) [32]. This is probably because this reaction is mediated through the same enzymes, such as hydrazine synthase (hzs) and hydrazine dehydrogenase (hdh) in all anammox bacteria species (Fig. 4).

Fig. 4

Proposed species-level difference in N isotope effects of nitrite (¹⁵ε_NO2→N2) induced by different anammox bacteria species

On the other hand, for the conversion of NO₂⁻ to N₂, significant variations of the N isotope effects (¹⁵ε_NO2→N2) were found among the three species: ¹⁵ε_NO2→N2 = 19.9 ± 1.7‰ for “Ca. S. japonica”, ¹⁵ε_NO2→N2 = 29.5 ± 3.9‰ for “Ca. J. caeni”, and ¹⁵ε_NO2→N2 = 5.9 ± 4.5‰ for “Ca. B. sinica”, respectively (Fig. 3 and Table S1.). The previously reported ¹⁵ε_NO2→N2 values of “Ca. K. stuttgartiensis” ranged between 11.9‰ and 18.9‰ (average = 16.0 ± 4.5‰) [32].

Different degree of N isotopic fractionation could be imparted by different nitrite reductase (Fig. 4). It has been reported that “Ca. S. japonica” and “Ca. K. stuttgartiensis” possess a cytochrome cd₁(iron, Fe)-type NO-forming nitrite reductase (Fe-NIR) [52, 53], whereas “Ca. J. caeni” has a copper (Cu)-containing NO-forming nitrite reductase (Cu-NIR) [40]. “Ca. B. sinica”, however, does not possess canonical nitrite reductase genes (neither Fe-NIR nor Cu-NIR) and reduces NO₂⁻ to NH₂OH, instead of NO [51]. Interestingly, both “Ca. S. japonica” and “Ca. K. stuttgartiensis” yielded similar ¹⁵ε_NO2→N2 values (¹⁵ε_NO2→N2 = 19.9 ± 1.7‰ and 16.0 ± 4.5‰), while “Ca. J. caeni” yielded higher values (¹⁵ε_NO2→N2 = 29.5 ± 3.9‰). Furthermore, “Ca. B. sinica” yielded distinctively lower ¹⁵ε_NO2→N2 values (5.9 ± 4.5‰) (Fig. 4). The different N and O isotope effects between Fe-NIR and Cu-NIR were also demonstrated for nitrite reduction by denitrifying bacteria [11]. This difference was explained by the difference in NO₂⁻ and enzyme-binding mechanism: the Cu-NIR binds to both O atoms of NO₂⁻ whereas the Fe-NIR binds to the N atom, resulting in a smaller N isotope effect for Fe-NIR [11].

However, the recent literatures have reported that Fe-NirS was not hardly expressed at the transcriptional level in both “Ca. K. stuttgartiensis” [54] and Scalindua-related single amplified genomes from ODZs [55, 56]. In addition, Cu-NirK expression was not identified in “Ca. J. caeni” [40]. It has been postulated recently that the reduction of NO₂⁻ to NO could be catalyzed by a HAO-like octahaem oxidoreductase in the case of “Ca. K. stuttgartiensis” [54]. The highly similar protein was also identified in the ODZ SAGs [56]. “Ca. B. sinica” that has neither NirS nor NirK also possesses the identical HAO-like octahaem oxidoreductase [51]. However, nitrite reductase that actually works in individual anammox species is not identified yet. To confirm this enzyme-level differences in ¹⁵ε_NO2→N2, true nitrite reductase must be identified.

Three anammox bacterial species were cultured at different pH and temperature in this study; pH 7.9–8.0 and 25 °C for “Ca. S. japonica”, pH 8.6–8.9 and 30 °C for “Ca. J. caeni”, and pH 7.3–7.4 and 37 °C for “Ca. B. sinica”, respectively. However, this probably does not cause variations in ¹⁵ε_NO2→N2. To our best knowledge, there were no studies that show a dependence of the organism-level N isotope effect on either pH or temperature so far, although temperature and pH influence the O isotope effect of NO₂⁻ due to isotopic exchange with H₂O [8, 57]. Taken together, a difference in nitrite reductase would most likely cause the differences in NO₂⁻ reduction isotope effects (¹⁵ε_NO2→N2) in this study.

For the oxidation of NO₂⁻ to NO₃⁻, all three anammox species exhibited pronounced inverse N isotope effects (−45.3 ± 4.2‰ to −30.1 ± 3.0‰), which agreed with the previously reported value for “Ca. K. stuttgartiensis” (−31.1‰ ± 3.9‰) [32], but exceeded the values for nitrite-oxidizing bacteria (NOB) (−9.1‰ to −20.6‰) [10]. Anammox bacteria can reverse this enzymatic reaction, namely they can reduce NO₃⁻ back to NO₂⁻ [58, 59]. It is thus hypothesized that this reversible reaction would promote isotope exchange between NO₂⁻ and NO₃⁻ and lead to more pronounced isotope effects as observed in sulfur metabolism [60]. Intriguingly, it has been also speculated that environmental stresses cause a significant N isotope exchange between NO₂⁻ and NO₃⁻ (−60.5 ± 1.0‰) in a “Ca. K. stuttgartiensis” batch culture [32]. However, since this phenomenon was not ubiquitously observed, it still remained unclear whether this was caused by cell lysis during cultivation and/or sample preparation. In the present study, all samples for isotope effect measurements were collected from steady-state continuous anammox-enrichment cultures grown under physiological anoxic conditions. Thus, environmental stresses could be minimized, and active biomass dominated in all cultures (>98% were active cells as determined Live/Dead staining, data not shown). Since isotope exchange between NO₂⁻ and NO₃⁻ is indeed an interesting and important phenomenon for interpretation of the N and O isotope effects, it must be addressed in the future.

It should be also noted that N and O isotope effects are influenced even by subcellular localization and amino acid sequences of enzymes (Fig. S2). For example, membrane-bound cytoplasmic and periplasmic Nxr of Nitrobacter and Nitrospira yielded significantly different ¹⁵ε_{NO2−→NO3−} and ¹⁸ε_{NO2−→NO3−} [10]. However, since the actual subcellular localization and amino acid sequences of enzymes in anammox bacteria are not fully understood currently, their influences need to be further investigated.

O isotope effects of NO₂ ⁻ and NO₃ ⁻

We could report only the combined O isotope effects for NO₂⁻ oxidation to NO₃⁻ (¹⁸E_{NO2−→NO3−} = 2/3 ¹⁸ε_{NO2−→NO3−} + 1/3 ¹⁸ε_H2O, Eq. (22)) by anammox bacteria in this study. Since both NO₂⁻ reduction to N₂ and oxidation to NO₃⁻ are simultaneously occurring in anammox process (Fig. S3B), the δ¹⁸O values of NO₂⁻ represents a superimposed signal of the two processes. In addition, the δ¹⁸O_NO2 value is affected by abiotic O isotope exchange between NO₂⁻ and H₂O (¹⁸ε_eq in Fig. S3). A water-derived O atom is also incorporated into NO₃⁻ during NO₂⁻ oxidation to NO₃⁻ [61]. Therefore, the δ¹⁸O_NO3 value of the MBR effluent is directly related to the culture medium (water) δ¹⁸O_H2O through both O isotope equilibration of NO₂⁻ (¹⁸ε_eq) and incorporation of a water-derived O atom (¹⁸ε_H2O) [26]. Thus, O isotope effect for NO₂⁻ oxidation to NO₃⁻ (¹⁸ε_{NO2−→NO3−}) and O isotope effect for water incorporation (¹⁸ε_H2O) cannot be determined separately in the continuous culture experiment alone in this study. These parameters could be species dependent and thus should be separately determined for individual anammox bacteria species for better understanding of N and O isotope systematics and nitrogen cycling in natural environments.

The combined O isotope effects for NO₂⁻ oxidation (¹⁸E_{NO2−→NO3−}) showed inverse kinetic isotope effects; ¹⁸E_{NO2 → NO3}: −12.1 ± 0.8‰ for “Ca. S. japonica”, −1.9 ± 0.8‰ for “Ca. J. caeni” and −1.5 ± 1.2‰ for “Ca. B. sinica”, respectively (Fig. 3 and Table S1). According to the Eq. (22) for the combined O isotope effect (¹⁸E_{NO2−→NO3−} = 2/3 ¹⁸ε_{NO2−→NO3−} + 1/3 ¹⁸ε_H2O), ¹⁸ε_{NO2−→NO3−} by anammox bacteria can be estimated when O isotope effect for water incorporation (¹⁸ε_H2O) was assumed to be 14‰ as assumed for NOB previously [18, 26]: −25.2‰ for “Ca. S. japonica”, −9.9‰ for “Ca. J. caeni”, and −9.3‰ for “Ca. B. sinica”, respectively. Aerobic nitrite oxidizing bacteria (NOB) also yielded inverse kinetic isotope effects of NO₂⁻ oxidation (¹⁸ε_NO2→NO3) ranging from −1.3 ± 0.4‰ to −8.2 ± 2.5‰ [9]. It should be noted again that we report a combined O isotope effect (Eq. (22)) whereas Buchwald and Casciotti [9] report the kinetic isotope effect on NO₂⁻ alone (equivalent to ¹⁸ε₅ in Eq. (20)).

The rate of abiotic O isotope exchange between NO₂⁻ and H₂O is rapid relative to the biological NO₂⁻ turnover rate and dependent on temperature and pH [8, 57]. The rate is faster at lower pH and higher temperature. Three anammox bacterial species were cultured at different pH and temperatures in this study, which might cause variations in δ¹⁸O_NO2 and δ¹⁸O_NO3 values of MBR effluent and consequently the combined O isotope effects for NO₂⁻ oxidation (¹⁸E_NO2→NO3) (Table S1).

Application to ecological studies

Although natural abundance N and O isotope ratios of nitrate (δ¹⁵N_NO3 and δ¹⁸O_NO3) have been used as an invaluable tool to identify the source and to determine the biogeochemical transformation processes [62], the isotope balances of oceanic NO₃⁻ are still poorly constrained at present. This is partly because NO₃⁻ can be produced during anammox (Fig. 1), which has been overlooked and led to divergent interpretation of δ¹⁵N_NO3 in freshwater and marine systems. Therefore, the contribution of anammox bacteria to NO₂⁻ reoxidation to NO₃⁻ (recycling N) in the environments is currently one of the most prominent research topics.

A numerical NO₃⁻ isotope dynamics model was developed to evaluate the relative contribution of anammox to NO₃⁻ production in the marine and freshwater systems [26]. In this model, since O isotope effect of NO₂⁻ oxidation to NO³⁻ (¹⁸ε_{NO2−→NO3−}) by anammox bacteria was not available, the ¹⁸ε_{NO2−→NO3−} values of NOB (−7.0‰ to −3.0‰) were used instead. According to this model, the inverse N and O isotope effects significantly influence the δ¹⁵N and δ¹⁸O of produced NO₃⁻ and consequently the corresponding Δδ¹⁸O:Δδ¹⁵N trajectories. More negative (i.e., lower) ¹⁵ε_{NO2−→NO3−} value pushes up δ¹⁵N_NO3− value, thereby lowering the Δδ¹⁸O:Δδ¹⁵N trajectories. In contrast, more negative ¹⁸ε_{NO2−→NO3−} value pushes up δ¹⁸N_NO3− value, thereby lifting up the Δδ¹⁸O:Δδ¹⁵N trajectories. It should be noted that the lower ¹⁸E_{NO2−→NO3−} value (i.e., more negative) was yielded for a marine species “Ca. S. japonica” than other two freshwater species (Fig. 3), suggesting that the higher Δδ¹⁸O:Δδ¹⁵N trajectories could be expected in marine systems than in freshwater systems. This can partly explain the widely observed Δδ¹⁸O:Δδ¹⁵N trajectories in freshwater systems (<1) and in marine systems (≥1).

Nitrite is an important branch compound between N loss by denitrification and anammox, and N retention by NO₂⁻ reoxidation to NO₃⁻. Natural abundance N and O isotopes of nitrite (δ¹⁵N_NO2 and δ¹⁸O_NO2) also provided an additional diagnostic to estimate the relative contribution of anammox to the NO₃⁻ pool [26]. Nitrite δ¹⁵N and δ¹⁸O measurements have been used to evaluate what oxidative and reductive NO₂⁻ transformation processes are occurring and to what extent in ODZs [3].

Anammox bacteria in ODZs do not affiliate with the genus Scalindua, but with distinct clusters that are clearly separated from the sediment species [56]. Thus, dual N and O isotope effects of NO₂⁻ reoxidation should be further explored for other marine water and sediment anammox species for better model simulations for the oceanic N budget.