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Applied and Environmental Microbiology, September 2002, p. 4679-4683, Vol. 68, No. 9
0099-2240/02/$04.00+0     DOI: 10.1128/AEM.68.9.4679-4683.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

Comparison of Models Describing Light Dependence of N₂ Fixation in Heterocystous Cyanobacteria

Marc Staal,^1* Sacco te Lintel Hekkert,² Peter Herman,³ and Lucas J. Stal¹

Department of Marine Microbiology,¹ Department of Spatial Ecology, NIOO-KNAW, 4400 AC Yerseke,³ Life Science Trace Gas Facility, Department of Molecular and Laser Physics, University of Nijmegen, Toernooiveld, 6525 ED Nijmegen, The Netherlands²

Received 29 January 2002/ Accepted 26 June 2002

Top Abstract Introduction References

 
The abilities of four models to describe nitrogenase light-response curves were compared, using the heterocystous cyanobacterium Nodularia spumigena and a cyanobacterial bloom from the Baltic Sea as examples. All tested models gave a good fit of the data, and the rectangular hyperbola model is recommended for fitting nitrogenase-light response curves. This model describes an enzymatic process, while the others are empirical. It was possible to convert the process parameters between the four models and compare N₂ fixation with photosynthesis. The physiological meanings of the process parameters are discussed and compared to those of photosynthesis.

Top Abstract Introduction References

 
Cyanobacteria are oxygenic photoautotrophic microorganisms, and many species are capable of diazotrophic growth, i.e., possess the ability to fix N₂ (3). This property allows such organisms to form dense water blooms in N-depleted aquatic environments. Freshwater and brackish environments often develop blooms of heterocystous cyanobacteria (8). The heterocyst is a differentiated cell that is the site of N₂ fixation in these organisms. It is devoid of the oxygenic photosystem II, and the anoxic interior of the heterocyst provides an environment in which the oxygen-sensitive nitrogenase is protected (14).

Because N₂ fixation in heterocystous cyanobacteria is partly dependent on light, light-response curves have been recorded in a manner similar to those done for photosynthesis (10). N₂ fixation in cyanobacteria is often measured either at ambient light or at a fixed light intensity in the laboratory considered to be saturating, i.e., resulting in maximum nitrogenase activity. In the former case, it is assumed that the measured nitrogenase activity represents the actual activity of the organisms in their natural environment. However, it would be more informative to measure potential N₂ fixation rates at different irradiances that are not influenced by ambient light fluctuations. The mathematical formulation of the nitrogenase-versus-irradiance curve can then be used for the calculation of the actual rate of N₂ fixation at any incident irradiance. Hence, it would be possible to calculate daily and water column-integrated rates of N₂ fixation (12). Measurement and fitting of a light-response curve of nitrogenase activity not only provide the actual rate of N₂ fixation at a given irradiance (11) but also give a variety of physiological parameters, e.g., light affinity coefficient, light saturation coefficient, maximum nitrogenase activity, and nitrogenase activity in the dark. These parameters can give information about the physiological status of the organism as well as its adaptation to different light regimens, in this case with respect to N₂ fixation.

In photosynthesis research, the models of Webb et al. (15) and of Jassby and Platt (7) have been most commonly used. Both models describe the photosynthesis-versus-irradiance curves rather well, but since they yield different values for the photosynthesis parameters, the results cannot readily be compared. These models have also been applied to fit nitrogenase-versus-irradiance curves (6, 11, 12, 16) in order to calculate daily integrals of N₂ fixation, which were then compared with daily integrals of photosynthesis (6, 11, 12). The Webb model has been modified to account for inhibition of nitrogenase activity at high irradiances by including an inhibition term ß (11). However, it was subsequently demonstrated that in heterocystous cyanobacteria, inhibition of nitrogenase activity at high irradiances was an incubation artifact, and therefore no such term was needed (10).

In this study we tested the fit results of four different models for N₂ fixation-versus-irradiance curves. The curves were recorded from laboratory cultures of Nodularia spumigena, a heterocystous cyanobacterium isolated from the Baltic Sea and from natural populations of heterocystous cyanobacteria, directly collected from that sea. The aim of this study was to arrive at a recommendation for a model that fits N₂ fixation-versus-irradiance curves best and to propose a nomenclature of the parameters derived from these curves and to discuss their meaning in a physiological sense.

Measurements for 40 nitrogenase activity-versus-irradiance curves of natural populations of N₂-fixing cyanobacteria were performed during a cruise on the Baltic Sea, 14 to 29 June 1999, on board the RV Valdivia. Samples were collected with a 100-µm-pore-size plankton net, towed vertically through the 0- to 10-m-deep water column and filtered on a GF-F glass-fiber filter (Whatman) (diameter, 47 mm). The filters were incubated at seawater temperature (12 to 15°C, depending on the location) in a temperature-controlled incubator for on-line measurements of N₂ fixation (9). The phytoplankton in the samples was dominated by the N₂-fixing, heterocystous cyanobacteria Aphanizomenon sp. and N. spumigena.

A culture of N. spumigena isolated from the Baltic Sea was obtained from P. K. Hayes (Bristol University, Bristol, United Kingdom). The organism was grown in a mixture of 1 part of artificial seawater medium (ASN3) and 2 parts of freshwater medium (BG11) (9). The medium did not contain a source of combined nitrogen. Batch cultures were grown at 20°C and continuous light (incident photon irradiance, 40 µmol m^-2 s^-1) in 250-ml Erlenmeyer flasks, containing 100 ml of medium, incubated in an orbital-shaking incubator (Sanyo Gallenkamp, Loughborough, United Kingdom) at 120 rpm. Nineteen light-response curves were recorded from samples taken from exponentially growing cultures.

Nitrogenase activity was measured by the acetylene reduction assay, using an on-line technique (10). The gas flow through the incubator was 1 liter h^-1 and consisted of 0.036% CO₂, 10% C₂H₂, 20% O₂, and 70% N₂. When anaerobic conditions were required, O₂ was omitted and N₂ was increased to 90%. Ethylene was measured using a gas chromatograph (Shimadzu GC-14A), equipped with a flame ionization detector and a 1-ml stainless steel sample loop. The temperatures of injector, detector, and oven were set at 90, 120, and 55°C, respectively. The carrier gas used was He (highest purity available) at a flow rate of 10 ml min^-1. The supply rates of H₂ and air for the flame ionization detector were 30 and 300 ml min^-1, respectively. The column used was a 25-m-long wide-bore silica fused column (inner diameter, 0.53 mm) packed with Porapak U (Varian-Chrompack, Middelburg, The Netherlands).

The gas chromatograph was programmed to automatically inject every 4 min via the sample loop. After injection, the gas chromatograph sent a signal to a personal computer that triggered the change of a neutral density filter in a Leica slide projector with a 250-W halogen lamp, resulting in a change of irradiance in the measuring cell. A set of 10 neutral density filters (Balzers, Sint-Truiden, Belgium) was used, with sufficiently high attenuation to obtain good resolution at the low irradiance levels. This allowed automatic recording of light-response curves, increasing the photon irradiance exponentially from 0 to 1,600 µmol m^-2 s^-1. Light-response curves were always preceded by three injections in the dark at the start of the experiment. The light-response curve was recorded running from low to high irradiance. The total recording time of a light-response curve took 56 min.

Photosynthetically active radiation was measured by a quantum sensor (LiCor model 250), put in place of the measuring cell and covered by the glass window of the incubation cell.

After the N₂ fixation rate was measured, the filters containing the samples were lyophilized and subsequently stored at -80°C until analysis. Chlorophyll a was extracted with 90% acetone in the dark and subsequently analyzed by high-pressure liquid chromatography (10).

Light-response curves were fitted using four different models originating from photosynthesis research (Table 1). The respiration term R_d was replaced by N_d, denoting nitrogenase activity in the dark. The parameter P_m was replaced by N_m, indicating the maximum nitrogenase activity in the light, minus N_d. The light affinity coefficient is the derivative of the curve at irradiances approaching zero. Models 1 and 2 were both derived from the Michaelis-Menten equation for enzyme kinetics. In model 1, I_k stands for the light saturation coefficient, which equals N_m/, and replaces K_m, a measure for the substrate affinity of an enzyme. Model 2 is the same as model 1, except that the two terms in the denominator are squared and the square root of the whole denominator is taken. Models 3 and 4 represent, respectively, the linear and quadratic approximation of the model that describes the rate of change of nitrogenase activity versus irradiance as a function of nitrogenase activity (2). In this study, the models did not include a term to describe photoinhibition of nitrogenase because this was not observed. In order to derive the total maximum nitrogenase activity, N_d must be added to N_m, resulting in the parameter N_tot.

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TABLE 1. Equations of the four models used to describe the nitrogenase-versus-irradiance relationship, their dimensionless NIk/Nm ratios, and the average N2 fixation coefficients at 20% O2 from cultured N. spumigena estimated by the different modelsa

Fitting of the different models to the measured light-response curves was done with Microcal Origin 6.0 (Microcal Software Inc.) by nonlinear least-squares fitting using the Levenberg-Marquardt algorithm. The program estimates the parameters and their errors as well as the r² value. The latter was used as an indicator of fit quality of the fitted line through the measured points.

Nitrogenase activity-versus-irradiance curves showed a similar response to light as photosynthesis (Fig. 1), except that N₂ fixation also takes place in the dark and hence a positive term, N_d, had to be included, while respiration in a photosynthesis curve results in O₂ uptake in the dark (R_d). Fitting nitrogenase-versus-light-response curves (at 20% O₂) with the rectangular hyperbola (model 1 [Table 1]) gave activity in the dark representing 34% ± 9.8% (n = 40) and 43% ± 11.6% (n = 19) of the total maximum activity measured with saturating light in natural field populations and laboratory cultures of N. spumigena, respectively.

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FIG. 1. Photosynthesis (O2 evolution) (A) and nitrogenase acetylene reduction (ARA) (B) light-response curves for N. spumigena. Both curves were fitted with the model proposed by Webb et al. (15). The parameters fitted by this model are indicated (Pm or Nm, Rd or Nd, and ) as well as the parameters Ik and Ntot. chl-a, chlorophyll a.

The shape of the fitted light-response curve differed slightly, depending on the model used (Fig. 2). When r² for the whole curve was taken as a measure for the quality of the fit (Table 1), the differences that were found between the models were not significant (analysis of variance [ANOVA], P > 0.05).

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FIG. 2. The fit results of the four different models, given in Table 1, to a measured light-response curve of nitrogenase activity (acetylene reduction assay [ARA]). chla, chlorophyll a.

All models estimated the parameters N_m, N_d, and . The fit results between the different models did not result in different values for nitrogenase activity in the dark, and hence, the value of N_d was estimated independently of the models used. The models also estimated approximately the same N_m, with the exception of the rectangular hyperbola, which gave a higher value for this parameter. Nevertheless, N_m values estimated by the models were not significantly different (ANOVA, P > 0.05). The models gave significantly different values for (ANOVA, P < 0.05) (Table 1), which were consistent for all measured curves and were related to the shapes of the modeled curves. The ratio of the nitrogenase activity at irradiance I_k and N_m (/N_m) was taken as an indicator for the shape of the curve. There was a good correlation between the model used (expressed as /N_max) and the estimated value of I_k (fitted with linear regression; r² = 0.99, n = 4, P < 0.01) (Fig. 3A) and with (fitted with the inverse of a linear regression 1/(ax + b); r² = 0.99, n = 4, P < 0.01) (Fig. 3B). It was therefore possible to convert I_k and values in the models. In order to quantify the relationship between the model and the and I_k parameters, it was assumed that the different models fitted the points equally well and therefore should give approximately the same values for N_d and N_m. Because of similarity of fit quality for the different models, it was also assumed that the light intensity at which the light-dependent part of nitrogenase activity reached 0.5 N_m (I_1/2) was equal for all models. The relationship of I_1/2 to I_k then can be derived for each model (Table 1) resulting in factors allowing the conversion of I_k values derived from one model to the I_k value of any of the other models. When I_k and values from one model were converted to another model, they differed by less than 15% from the derived values obtained directly using the fit routine of that model. The similarity in trend between the average fitted and I_k values versus /N_m compared to the calculated conversion factors is striking, underscoring that our assumptions were correct (Fig. 3). This is not the case for photosynthesis-versus-irradiance curves (5). However, now that we have shown that the and I_k values found for N₂ fixation can be converted to the model used for fitting the photosynthesis curves, both processes can be compared.

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FIG. 3. The average Ik (A) (open circles) and (B) (open triangles) values from batch cultures of N. spumigena (n = 19) as well as the conversion factors (left y axes) for Ik (closed squares) (A) and (closed triangles) (B) (see Table 1) plotted against the theoretical /Nm ratio. This ratio is used to specify the different models for fitting the nitrogenase light-response curves (acetylene reduction assay [ARA]).

Mathematically, the photosynthesis parameters P_m, R_d, I_k, and equal, respectively, N_m, N_d, I_k, and for N₂ fixation. However, the physiological meanings of these parameters are not the same. P_m represents the maximum attainable gross rate of photosynthesis at saturating light. Net photosynthesis equals P_m + R_d (R_d is negative), but it should be taken into account that R_d (respiration in the dark) might differ with irradiance. It is important to note that respiration in the heterocyst continues in the light in order to keep the O₂ levels low within the heterocyst and that therefore N_d must be subtracted from the measured nitrogenase activity in the light in order to obtain the activity that is supported by light-mediated ATP generation. Hence, the sum of N_m + N_d, which we denote as N_tot, represents the maximum attainable rate of N₂ fixation. In photosynthesis, and I_k are parameters that mainly give information on the number and size of the photosynthetic reaction centers, while in nitrogenase activity, these parameters are also influenced by the ATP demand of nitrogenase, e.g., the amount of active nitrogenase complexes and the availability of the other substrates of this complex. The and I_k parameters are sometimes used as indicators of photoacclimation in photosynthesis, in which a lower I_k or a higher indicate acclimation to lower growth irradiances (5). The same appears to be true for N₂ fixation (4)

The great advantage of I_k is that it is independent of the units used to express N₂ fixation or photosynthesis. It can therefore be used for comparison of light acclimation of both processes. It does not make a difference which technique was used for determining the light-response curves for N₂ fixation (e.g., ¹⁵N₂ fixation or C₂H₂ reduction) or how the activities are expressed (e.g., as protein, chlorophyll, carbon, cell number etc.), as long as the same model is used to derive the parameters. The same is true for the N_m/N_d and N_tot/N_d ratios. This is convenient, because N₂ fixation rates are usually expressed as biomass, which includes vegetative cells that do not fix N₂. Hence, biomass-independent parameters of N₂ fixation are superior when describing physiological processes in the heterocyst.

Henley (5) concluded that the models of Jassby and Platt (7) or Webb et al. (15) give the best fit for photosynthesis-versus-irradiance curves. While the fit quality of the different models for nitrogenase-versus-irradiance curves is equal, we propose to use the rectangular hyperbola. The rationale for this choice is that the rectangular hyperbola originates from enzyme kinetics, while the other models are empirical. Nitrogenase-versus-irradiance curves represent in fact the activity of the enzyme in dependence of its limiting substrate (ATP), which is described by the Michaelis-Menten model. Because we assume a linear relationship for ATP production per photon, light-response curves as shown here can be regarded as ATP production versus enzyme activity. Under dark anaerobic incubation conditions, no ATP would be generated and hence nitrogenase activity would be zero (N_d = 0). When light-response curves of nitrogenase activity were measured at air saturation levels of O₂, respiration provided considerable amounts of ATP covering a significant part of the demand of nitrogenase (34 and 43% for natural communities and cultured N. spumigena, respectively; see above). The N_d/N_tot ratio determines where the light-dependent part of the curve starts, which has some influence on the tangent of the curve () (Fig. 4). Other factors that influence the tangent are the amount of nitrogenase and the quantum efficiency. It is unlikely that these factors change during the recording of the light-response curve. The kinetics of nitrogenase with respect to its limiting substrate ATP are independent of the way ATP is generated (oxidative phosphorylation or photophosphorylation), which means that the affinity of nitrogenase (I_k) (equals K_m in Michaelis-Menten enzyme kinetics) will not change, as long as other substrates for nitrogenase (i.e., reducing equivalents) remain in excess at saturating ATP levels. Theoretically, I_k does not change when N_d changes as long as N_tot remains constant (Fig. 4). This was tested experimentally by removing O₂ from the gas flow after the light-response curves were finished in the N. spumigena incubations. Thereafter, the light-response curves were repeated under anaerobic conditions, which resulted in N_d = 0 without affecting N_tot (mostly, N_tot changed less than 10%). However, N_m and increased with decreasing respiratory ATP production (decreasing O₂). These observations agree with the predictions and indicated that the assumptions made were valid. Hence, when I_k and N_tot do not change in response to variation of O₂, the conclusion must be that at saturating irradiances, nitrogenase activity is not limited by any of its substrates (ATP or reducing equivalents). Interestingly, when field samples were incubated under decreased O₂ levels, changes in I_k and N_tot were frequently observed. In these cases, probably another substrate was limiting for nitrogenase under saturating irradiances. Hence, a combination of light-response curves at different oxygen concentrations gives important information on the physiological condition of the N₂-fixing cyanobacteria in the environment.

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FIG. 4. Two theoretical nitrogenase activity-versus-irradiance curves (acetylene reduction assay [ARA]) generated with a Michaelis-Menten equation. The curve of open triangles is the curve at anoxic conditions when only light-mediated ATP generation occurs. The curve of the closed circles represents the situation that ATP originates both from oxidative phosphorylation and photophosphorylation (respiration and photosynthesis). The parameters Nm, Nd, and were fitted by the rectangular hyperbola model. Ntot (Nm + Nd) was the same in both curves. The parameter Ik was calculated by Nm/. Both curves gave the same Ik, but Nm and were different. The substrate concentration is given in arbitrary units (A.U.).

 
This work was supported in part by the European Commission Environment RTD contract ENV4-CT97-0571 and the Dutch Science Foundation (STW) contract NNS44.3404.

 
* Corresponding author. Mailing address: NIOO-KNAW, Postbus 140, 4400 NT Yerseke, The Netherlands. Phone: 31 (0)113 577479. Fax: 31 (0)113 573616. E-mail: staal{at}cemo.nioo.knaw.nl.

Publication no. 3009 of NIOO-CEMO.

Top Abstract Introduction References

 

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Applied and Environmental Microbiology, September 2002, p. 4679-4683, Vol. 68, No. 9
0099-2240/02/$04.00+0     DOI: 10.1128/AEM.68.9.4679-4683.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

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This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Reprints and Permissions Copyright Information Books from ASM Press MicrobeWorld Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Staal, M. Articles by Stal, L. J. Search for Related Content PubMed PubMed Citation Articles by Staal, M. Articles by Stal, L. J. Agricola Articles by Staal, M. Articles by Stal, L. J.