NITROGEN UTILIZATION AND METABOLISM RELATIVE TO PATTERNS OF N2 FIXATION IN CULTURES OF TRICHODESMIUM NIBB1067

We measured uptake kinetics for four combined N sources, ambient rates of N uptake and N₂ fixation, glutamine synthetase activity (transferase and biosynthetic), and concentrations of intracellular pools of glutamate (glu) and glutamine (gln) in cultures of Trichodesmium NIBB1067. N dynamics and metabolism were examined to assess the relative importance of N₂ fixation and N uptake to Trichodesmium nutrition. Comparisons were made between cultures grown on medium without added N, with excess NO, or with excess urea. Of the combined N sources tested, Trichodesmium NIBB1067 had the highest affinity for NH; high uptake capacities for NH, urea, and glu; and little capacity for NO uptake. In cultures grown on medium without added N, NH accumulated in the medium during growth, resulting in high NH uptake rates relative to rates of N₂ fixation. Glu uptake rates were low but consistent throughout the diel period. In cultures grown on excess NO or urea, uptake of these compounds supplied the majority of the daily N demand, although some N₂ fixation occurred during the light period. NO uptake rates were reduced when N₂-fixation rates were high. In all of the cultures, the highest gln/glu ratios and the lowest glutamine synthetase transferase/biosynthetic ratios were observed during the period when rates of total N uptake were highest. In cultures growing exponentially on medium without added N, N₂ fixation accounted for 14%– 16% of the total daily N uptake. Uptake of NH and glu, presumably regenerated within the culture vessels, represented 84%–86% of the daily N uptake. Because these systems were closed, net growth was constrained by the rate at which N₂ could be fixed into the system. However, total daily N turnover was greater than that necessary to accommodate the observed increase in culture biomass. The rapid N turnover rates observed in these cultures may support gross productivity and balance the high rates of C fixation observed in natural populations of Trichodesmium.     

Modeling the Dynamic Regulation of Nitrogen Fixation in the Cyanobacterium Trichodesmium sp.

A physiological, unbalanced model is presented that explicitly describes growth of the marine cyanobacterium Trichodesmium sp. at the expense of N₂ (diazotrophy). The model involves the dynamics of intracellular reserves of carbon and nitrogen and allows the uncoupling of the metabolism of these elements. The results show the transient dynamics of N₂ fixation when combined nitrogen (NO₃⁻, NH₄⁺) is available and the increased rate of N₂ fixation when combined nitrogen is insufficient to cover the demand. The daily N₂ fixation pattern that emerges from the model agrees with measurements of rates of nitrogenase activity in laboratory cultures of Trichodesmium sp. Model simulations explored the influence of irradiance levels and the length of the light period on fixation activity and cellular carbon and nitrogen stoichiometry. Changes in the cellular C/N ratio resulted from allocations of carbon to different cell compartments as demanded by the growth of the organism. The model shows that carbon availability is a simple and efficient mechanism to regulate the balance of carbon and nitrogen fixed (C/N ratio) in filaments of cells. The lowest C/N ratios were obtained when the light regime closely matched nitrogenase dynamics.     

NUTRIENT CONTROLS ON NITROGEN UPTAKE AND METABOLISM BY NATURAL POPULATIONS AND CULTURES OF TRICHODESMIUM (CYANOBACTERIA)

The effects of inorganic nutrient (ammonium [NH₄ ⁺ ] and nitrate [NO₃ ⁻ ]) and amino acid (glutamate [glu] and glutamine [gln]) additions on rates of N₂ fixation, N uptake, glutamine synthetase (GS) activity, and concentrations of intracellular pools of gln and glu were examined in natural and cultured populations of Trichodesmium. Additions of 1 μM glu, gln, NO₃ ⁻ , or NH₄ ⁺ did not affect short-term rates of N₂ fixation. This may be an important factor that allows for continued N₂ fixation in oligotrophic areas where recycling processes are active. N₂ fixation rates decreased when nutrients were supplied at higher concentrations (e.g. 10 μM). Uptake of combined N (NH₄ ⁺ , NO₃ ⁻ , and amino acids) by Trichodesmium was stimulated by increased concentrations. For NO₃ ⁻ , proportional increases in NO₃ ⁻ uptake and decreases in N₂ fixation were observed when additions were made to cultures before the onset of the light period. GS activity did not change much in response to the addition of NH₄ ⁺ , NO₃ ⁻ , glu, or gln. GS is necessary for N metabolism, and the bulk of this enzyme pool may be conserved. Intracellular pools of glu and gln varied in response to 10 μM additions of NH₄ ⁺ , glu, or gln. Cells incubated with NH₄ ⁺ became depleted in intracellular glu and enriched with intracellular gln. The increase in the gln/glu ratio corresponded to a decrease in the rate of N₂ fixation. Although the gln/glu ratio decreased in cells exposed to the amino acids, there was only a corresponding decrease in N₂ fixation after the gln addition. The results presented here suggest that combined N concentrations on the order of 1 μM do not affect rates of N₂ fixation and metabolism, although higher concentrations (e.g. 10 μM) can. Moreover, these effects are exerted through products of NH₄ ⁺ assimilation rather than exogenous N, as has been suggested for other species. These results may help explain how cultures of Trichodesmium are able to simultaneously fix N₂ and take up NH₄ ⁺ and how natural populations continue to fix N₂ once combined N concentrations increase within a bloom.     

The regulation of nodulation,nitrogen fixation and ammonium assimilation under a carbohydrate shortage stress in the Discaria trinervis-Frankia symbiosis

N₂-fixation is sensitive to limitation in the availability of newly synthesised carbohydrates for the nodules. We decided to explore the response of the D. trinervis - Frankia symbiosis to a transient decrease in carbohydrate supply to nodules. Feedback inhibition of nodulation as well as nodule growth was not released by a 6-day dark stress in D. trinervis nodulated plants. However, nitrogen fixation and assimilation were affected by the imposed stress. Nitrogenase activity was totally inhibited after 4 days of darkness although high levels of nitrogenase components were still detected at this time. Degradation of FeMo and Fe nitrogenase subunits – both at similar rates – was observed after 6 days of dark stress, revealing the need for inactivation to precede enhancement of protein turnover. Glutamine synthetase (GS), malate dehydrogenase (MDH) and asparagine synthetase (AS) polypeptides were also degraded during the dark stress, although at a lower rate than nitrogenase. ARA and nitrogenase were totally recovered 8 days after resuming normal illumination. It seems that current nitrogenase activity and ammonium assimilation are not, or are only weakly linked with the feedback control of nodulation in D. trinervis. These observations give support to the persistence of an autoregulatory signal in mature nodules that is not sensitive to transient shortages of carbon supply and sustains the inhibition of nodulation in the transient absence of N₂ fixation.     

Enzymes of ammonia assimilation and their regulation inAzospirillum lipoferum strain D-2

Azospirillum lipoferum strain D-2 possesses the following enzymes for the assimilation of N₂ and NH ₄ ⁺ : nitrogenase, glutamine synthetase, NADPH-dependent glutamate synthase, NADH-/NADPH-dependent glutamate dehydrogenase, and NADH-dependent alanine dehydrogenase. Nitrogenase and glutamine synthetase are repressed, whereas glutamate dehydrogenase and alanine dehydrogenase are induced by NH ₄ ⁺ . Glutamine synthetase activity is modulated by both repression and depression and also by adenylylation.     

Elevated CO2 enhances nitrogen fixation and growth in the marine cyanobacterium Trichodesmium

The increases in atmospheric pCO₂ over the last century are accompanied by higher concentrations of CO₂(aq) in the surface oceans. This acidification of the surface ocean is expected to influence aquatic primary productivity and may also affect cyanobacterial nitrogen (N)‐fixers (diazotrophs). No data is currently available showing the response of diazotrophs to enhanced oceanic CO₂(aq). We examined the influence of pCO₂ [preindustrial∼250 ppmv (low), ambient∼400, future∼900 ppmv (high)] on the photosynthesis, N fixation, and growth of Trichodesmium IMS101. Trichodesmium spp. is a bloom‐forming cyanobacterium contributing substantial inputs of ‘new N’ to the oligotrophic subtropical and tropical oceans. High pCO₂ enhanced N fixation, C : N ratios, filament length, and biomass of Trichodesmium in comparison with both ambient and low pCO₂ cultures. Photosynthesis and respiration did not change significantly between the treatments. We suggest that enhanced N fixation and growth in the high pCO₂ cultures occurs due to reallocation of energy and resources from carbon concentrating mechanisms (CCM) required under low and ambient pCO₂. Thus, in oceanic regions, where light and nutrients such as P and Fe are not limiting, we expect the projected concentrations of CO₂ to increase N fixation and growth of Trichodesmium. Other diazotrophs may be similarly affected, thereby enhancing inputs of new N and increasing primary productivity in the oceans.     

Combined effects of different CO2 levels and N sources on the diazotrophic cyanobacterium Trichodesmium

To predict effects of climate change and possible feedbacks, it is crucial to understand the mechanisms behind CO₂ responses of biogeochemically relevant phytoplankton species. Previous experiments on the abundant N₂ fixers Trichodesmium demonstrated strong CO₂ responses, which were attributed to an energy reallocation between its carbon (C) and nitrogen (N) acquisition. Pursuing this hypothesis, we manipulated the cellular energy budget by growing Trichodesmium erythraeum IMS101 under different CO₂ partial pressure (pCO₂) levels (180, 380, 980 and 1400 µatm) and N sources (N₂ and NO₃^?). Subsequently, biomass production and the main energy‐generating processes (photosynthesis and respiration) and energy‐consuming processes (N₂ fixation and C acquisition) were measured. While oxygen fluxes and chlorophyll fluorescence indicated that energy generation and its diurnal cycle was neither affected by pCO₂ nor N source, cells differed in production rates and composition. Elevated pCO₂ increased N₂ fixation and organic C and N contents. The degree of stimulation was higher for nitrogenase activity than for cell contents, indicating a pCO₂ effect on the transfer efficiency from N₂ to biomass. pCO₂‐dependent changes in the diurnal cycle of N₂ fixation correlated well with C affinities, confirming the interactions between N and C acquisition. Regarding effects of the N source, production rates were enhanced in NO₃^? grown cells, which we attribute to the higher N retention and lower ATP demand compared with N₂ fixation. pCO₂ effects on C affinity were less pronounced in NO₃^? users than N₂ fixers. Our study illustrates the necessity to understand energy budgets and fluxes under different environmental conditions for explaining indirect effects of rising pCO₂.     

Phosphoenolpyruvate carboxylase activity,fixation of14C in amino acids and nitrogen transport in stem nodules ofSesbania rostrata

Thein vivo ¹⁴CO₂ fixation assay and xylem sap analysis showed that inSesbania rostrata the transport of fixed nitrogen from stem nodules was in the amide form. The majority of nitrogen was transported as asparagine. The close relationship between nodule phosphoenolpyruvate carboxylase and nitrogenase activities suggested that nodule CO₂ fixation contributed directly to nitrogen assimilation in stem nodules ofS. rostrata.     

Correlation between nitrogenase and glutamine synthetase expression in the cyanobacterium Anabaena cylindrical

Distribution pattern and levels of nitrogenase (EC 1.7.99.2) and glutamine synthetase (GS, EC 6.3.1.2) were studied in N₂-, NO₃^? and NH₄⁺ grown Anabaena cylindrica (CCAP 1403/2a) using immunogold electron microscopy. In N₂- and NO₃^? grown cultures, heterocysts were formed and nitrogenase activity was present. The nitrogenase antigen appeared within the heterocysts only and showed an even distribution. The level of nitrogenase protein in the heterocysts was identical with both nitrogen sources. In NO₃^? grown cells the 30% reduction in the nitrogenase activity was due to a corresponding decrease in the heterocyst frequency and not to a repressed nitrogenase synthesis. In NH₄^? grown cells, the nitrogenase activity was almost zero and new heterocysts were formed to a very low extent. The heterocysts found showed practically no nitrogenase protein throughout the cytoplasm, although some label occurred at the periphery of the heterocyst. This demonstrates that heterocyst differentiation and nitrogenase expression are not necessarily correlated and that while NH₄⁺ caused repression of both heterocyst and nitrogenase synthesis, NO₃^? caused inhibition of heterocyst differentiation only. The glutamine synthetase protein label was found throughout the vegetative cells and the heterocysts of all three cultures. The relative level of the GS antigen varied in the heterocysts depending on the nitrogen source, whereas the GS level was similar in all vegetative cells. In N₂- and NO₃⁺ grown cells, where nitrogenase was expressed, the GS level was ca 100% higher in the heterocysts compared to vegetative cells. In NH₄⁺ grown cells, where nitrogenase was repressed, the GS level was similar in the two cell types. The enhanced level of GS expressed in heterocysts of N₂ and NO₃^? grown cultures apparently is related to nitrogenase expression and has a role in assimilation of N₂derived ammonia.     

Combined Effects of CO2 and Light on the N2-Fixing Cyanobacterium Trichodesmium IMS101: A Mechanistic View

The marine diazotrophic cyanobacterium Trichodesmium responds to elevated atmospheric CO₂ partial pressure (pCO₂) with higher N₂ fixation and growth rates. To unveil the underlying mechanisms, we examined the combined influence of pCO₂ (150 and 900 μatm) and light (50 and 200 μmol photons m⁻² s⁻¹) on Trichodesmium IMS101. We expand on a complementary study that demonstrated that while elevated pCO₂ enhanced N₂ fixation and growth, oxygen evolution and carbon fixation increased mainly as a response to high light. Here, we investigated changes in the photosynthetic fluorescence parameters of photosystem II, in ratios of the photosynthetic units (photosystem I:photosystem II), and in the pool sizes of key proteins involved in the fixation of carbon and nitrogen as well as their subsequent assimilation. We show that the combined elevation in pCO₂ and light controlled the operation of the CO₂-concentrating mechanism and enhanced protein activity without increasing their pool size. Moreover, elevated pCO₂ and high light decreased the amounts of several key proteins (NifH, PsbA, and PsaC), while amounts of AtpB and RbcL did not significantly change. Reduced investment in protein biosynthesis, without notably changing photosynthetic fluxes, could free up energy that can be reallocated to increase N₂ fixation and growth at elevated pCO₂ and light. We suggest that changes in the redox state of the photosynthetic electron transport chain and posttranslational regulation of key proteins mediate the high flexibility in resources and energy allocation in Trichodesmium. This strategy should enable Trichodesmium to flourish in future surface oceans characterized by elevated pCO₂, higher temperatures, and high light.The marine filamentous N₂-fixing (diazotrophic) cyanobacteria Trichodesmium spp. bloom extensively in the oligotrophic subtropical and tropical oceans (Carpenter and Capone, 2008). Trichodesmium contributes 25% to 50% of the estimated rates of N₂ fixation in these areas, where the new nitrogen inputs stimulate carbon and nitrogen cycling (Capone and Subramaniam, 2005; Mahaffey et al., 2005). The increases in atmospheric CO₂ partial pressure (pCO₂) and the subsequent impacts on ocean acidification are predicted to influence diazotrophs and specifically Trichodesmium.The reported sensitivity of Trichodesmium to changes in pCO₂ prompted further investigation into the cellular responses and underlying mechanisms, specifically when combined with other environmental parameters such as temperature, nutrient availability, and light. Elevated pCO₂ significantly increased growth and N₂ fixation rates of Trichodesmium cultures (Barcelos é Ramos et al., 2007; Hutchins et al., 2007; Levitan et al., 2007, 2010). The physiological response was also characterized by changes in inorganic carbon acquisition, limited flexibility of carbon-nitrogen ratios, and conservation of photosynthetic activities with increased pCO₂. These manifestations suggested that ATP and reductants [ferredoxin, NAD(P)H] are reallocated in the cells (Levitan et al., 2007, 2010; Kranz et al., 2009, 2010).In Trichodesmium, as in all cyanobacteria, the metabolic pathways of respiration and photosynthesis share several cellular complexes/proteins such as the plastoquinone (PQ) pool, succinate dehydrogenase, and ferredoxin (Fig. 1; Kana, 1993; Bergman et al., 1997; Lin et al., 1998). Energetic currencies [reduced ferredoxin, ATP, NAD(P)H] are also shared and can be allocated and utilized according to cellular requirements. N₂ fixation by nitrogenase and the subsequent assimilation of NH₄⁺ by Gln synthetase requires carbon skeletons from the tricarboxylic acid reactions. Moreover, linear and pseudocyclic photosynthesis can also generate additional ATP and reductants essential for N₂ fixation (Fig. 1; Berman-Frank et al., 2001).Open in a separate windowFigure 1.Schematic representation of major cellular complexes involved in energy flow [electron, ATP, NAD(P)H, carbon skeletons] in Trichodesmium IMS101. Dashed arrows represent movement direction of electrons, and solid arrows represent directions of protons, ATP, and NAD(P)H. Measured protein subunits are represented by gray diamonds. See Kranz et al. (2010) for measurements of O₂ evolution, inorganic carbon fixation, and fluxes of N₂ fixation.To understand the regulation of these metabolic pathways in Trichodesmium under varying pCO₂ levels and light intensities, we designed an experiment to characterize changes in the fluxes of carbon, nitrogen, and oxygen (O₂), related protein pool sizes, and variable fluorescence parameters of PSII. Elevated atmospheric pCO₂ combined with enhanced sea surface temperatures are forecast to stabilize thermal stratification, resulting in a shallower, more acidified, upper mixed layer characterized by higher mean light intensities (Doney, 2006). Thus, Trichodesmium IMS101 cultures were acclimated to past and future pCO₂ levels (150 and 900 μatm) at low and high light (50 and 200 μmol photons m⁻² s⁻¹).In the first part of this combined report (Kranz et al., 2010), we examined the physiological responses to the different acclimation conditions. The combination of elevated pCO₂ and light enhanced the production of particulate organic carbon and nitrogen (270% and 390% increase, respectively) as well as growth rates (180% increase; percentages are calculated from Kranz et al., 2010). Generally, the pCO₂-dependent stimulation was higher in cultures acclimated to low light. The pCO₂ effect was also reflected in other measured physiological parameters, particularly the diel patterns of N₂ fixation and the integrated N₂ fixation rates during the day, which increased approximately 30-fold between the low-pCO₂/low-light and the high-pCO₂/high-light acclimations (Kranz et al., 2010). While at high light, elevated pCO₂ extended the period of high N₂ fixation, which lasted from 5 h after the onset of light throughout the end of the photoperiod, the high-pCO₂ contribution to the integrated N₂ fixation was more significant at low light (Kranz et al., 2010). Light, but not pCO₂, influenced gross photosynthesis as measured by PSII O₂ evolution, which increased by approximately 250% in high-light-acclimated cultures. To supply the Calvin cycle with sufficient CO₂, Trichodesmium possesses a CO₂-concentrating mechanism mainly based on HCO₃⁻ uptake (Kranz et al., 2009, 2010). When Trichodesmium was acclimated to elevated pCO₂ (900 μatm), a decline in the cellular affinity to dissolved inorganic carbon was observed (Kranz et al., 2009), while the specific uptake of CO₂ showed a 9-fold increase between the low-pCO₂/low-light and the high-pCO₂/high-light acclimations (Kranz et al., 2010).Proteins are fundamental cellular components that influence the underlying mechanisms subsequently reflected in the cells’ physiology. In this study, we extend the experimental results presented by Kranz et al. (2010) by examining the influence of pCO₂ at different light regimes on the photosynthetic fluorescence parameters of PSII and on the pool sizes of key proteins involved in carbon and nitrogen fixation and their subsequent assimilation processes.     

Immunochemical Localization of Nitrogenase in Marine Trichodesmium Aggregates: Relationship to N2 Fixation Potential

Colonial aggregation among nonheterocystous filaments of the planktonic marine cyanobacterium Trichodesmium is known to enhance N₂ fixation, mediated by the O₂-sensitive enzyme complex nitrogenase. Expression of nitrogenase appears linked to the formation of O₂-depleted microzones within aggregated bacterium-associated colonies. While this implies a mechanism by which nonheterocystous N₂ fixation can take place in an oxygenated water column, both the location and regulation of the N₂-fixing apparatus remain unknown. We used an antinitrogenase polyclonal antibody together with postsection immunocolloidal gold staining and transmission electron microscopy to show that (i) virtually all Trichodesmium cells within a colony possessed nitrogenase, (ii) nitrogenase showed no clear intracellular localization, and (iii) certain associated bacteria contained nitrogenase. Our findings emphasize the critical role coloniality plays in regulating nitrogenase expression in nature. We interpret the potential for a large share of Trichodesmium cells to fix N₂ as an opportunistic response to the dynamic nature of the sea state; during quiescent conditions, aggregation and consequent expression of nitrogenase can proceed rapidly.     

Iron-Stimulated N2 Fixation and Growth in Natural and Cultured Populations of the Planktonic Marine Cyanobacteria Trichodesmium spp

In light of recent proposals that iron (Fe) availability may play an important role in controlling oceanic primary production and nutrient flux, its regulatory impact on N₂ fixation and production dynamics was investigated in the widespread and biogeochemically important diazotrophic, planktonic cyanobacteria Trichodesmium spp. Fe additions, as FeCl₃ and EDTA-chelated FeCl₃, enhanced N₂ fixation (nitrogenase activity), photosynthesis (CO₂ fixation), and growth (chlorophyll a production) in both naturally occurring and cultured (on unenriched oligotrophic seawater) Trichodesmium populations. Maximum enhancement of these processes occurred under FeEDTA-amended conditions. On occasions, EDTA alone led to enhancement. No evidence for previously proposed molybdenum or phosphorus limitation was found. Our findings geographically extend support for Fe limitation of N₂ fixation and primary production to tropical and subtropical oligotrophic ocean waters often characterized by Trichodesmium blooms.     

SPATIAL SEGREGATION OF CO2 FIXATION IN TRICHODESMIUM SPP.: LINKAGE TO N2 FIXATION POTENTIAL1

The aggregate-forming, nonheterocystous, filamentous blue-green alga (cyanobacteria) Trichodesmium spp. is a widespread and important planktonic N₂ fixer and primary producer in tropical and subtropical oceans. It is unique among nonheterocystous genera because it conducts N₂ and CO₂ fixation (O₂ evolution) simultaneously; a notable achievement, because O₂ is a potent inhibitor of N₂ fixation. Spatial and temporal CO₂ fixation patterns were examined in trichomes and aggregates from natural and cultured populations, utilizing microautoradiographic detection of ¹⁴CO₂ incorporation. Parallel N₂ fixation (acetylene reduction) measurements were also made. Diel N₂ and CO₂ fixation patterns were similar, with co-optimization of both processes near midday. Microautoradiographs revealed several trichome-level ¹⁴CO₂ incorporation patterns: 1)uniform, heavy labeling, 2)uniform, light labeling, 3) heavier labeling in distal as opposed, to proximal regions, and 4) virtually no labeling throughout. Similar patterns were observed in natural and cultured populations. Given previous immunochemical findings that N₂ fixation potential is widespread in Trichodesmium spp. trichomes and aggregates, current results suggest a high degree of individuality, and possibly a “division of labor” in terms of CO₂ fixation, among trichomes comprising active N₂-fixing aggregates. Segregation of photosynthesis within and among trichomes facilitates simultaneous N₂ and CO₂ fixation in Trichodesmium spp. trichomes and aggregates.     

Metal limitation of cyanobacterial N2 fixation and implications for the Precambrian nitrogen cycle

Nitrogen fixation is a critical part of the global nitrogen cycle, replacing biologically available reduced nitrogen lost by denitrification. The redox‐sensitive trace metals Fe and Mo are key components of the primary nitrogenase enzyme used by cyanobacteria (and other prokaryotes) to fix atmospheric N₂ into bioessential compounds. Progressive oxygenation of the Earth's atmosphere has forced changes in the redox state of the oceans through geologic time, from anoxic Fe‐enriched waters in the Archean to partially sulfidic deep waters by the mid‐Proterozoic. This development of ocean redox chemistry during the Precambrian led to fluctuations in Fe and Mo availability that could have significantly impacted the ability of prokaryotes to fix nitrogen. It has been suggested that metal limitation of nitrogen fixation and nitrate assimilation, along with increased rates of denitrification, could have resulted in globally reduced rates of primary production and nitrogen‐starved oceans through much of the Proterozoic. To test the first part of this hypothesis, we grew N₂‐fixing cyanobacteria in cultures with metal concentrations reflecting an anoxic Archean ocean (high Fe, low Mo), a sulfidic Proterozoic ocean (low Fe, moderate Mo), and an oxic Phanerozoic ocean (low Fe, high Mo). We measured low rates of cellular N₂ fixation under [Fe] and [Mo] estimated for the Archean ocean. With decreased [Fe] and higher [Mo] representing sulfidic Proterozoic conditions, N₂ fixation, growth, and biomass C:N were similar to those observed with metal concentrations of the fully oxygenated oceans that likely developed in the Phanerozoic. Our results raise the possibility that an initial rise in atmospheric oxygen could actually have enhanced nitrogen fixation rates to near modern marine levels, providing that phosphate was available and rising O₂ levels did not markedly inhibit nitrogenase activity.     

The relationship between the state of adenylylation of glutamine synthetase I and the export of ammonium in free-living,N2-fixing Rhizobium

The relationship between ammonium assimilation and ammonium export has been studied in free-living, N₂-fixing Rhizobium sp. 32H1. After 55 to 67 h of microaerobic growth under a gas phase of 0.2% O₂ – 1.0% CO₂ – 98.8% Ar high levels of nitrogenase were observed concomitant with a slightly adenylylated glutamine synthetase (GSI) and some glutamine synthetase (GSII) activity. However, after growth of 89 h, or longer, GSI became adenylylated and the level of GSII had decreased. When the gas phase was shifted to 0.2% O₂ – 1.0% CO₂ – 98.8% N₂, a lag was observed before ammonium export could be detected in the 55 to 67 h cultures. No lag in ammonium export was observed in the cultures previously grown for 89 h. The onset of ammonium export in the 55 to 67 h cultures was found to correlate with the adenylylation state of GSI. There appeared to be no correlation between the level of GSII and the export of ammonium. Neither an increase in the adenylylation level of GSI nor ammonium export was observed when the 55 to 67 h cultures were maintained under the Ar gas mixture.Abbreviations GOGAT Glutamate synthase - GS glutamine synthetase - BES [N,N-bis(2-hydroxyethyl)-2-aminoethanesulfonic acid] - CTAB cetyltrimethylammonium bromide - MES [2-(N-morpholino)-ethane sulfonic acid]     

Nitrogenase activity and dark CO2 fixation in the lichen Peltigera aphthosa Willd

The lichen Peltigera aphthosa consists of a fungus and green alga (Coccomyxa) in the main thallus and of a Nostoc located in superficial packets, intermixed with fungus, called cephalodia. Dark nitrogenase activity (acetylene reduction) of lichen discs (of alga, fungus and Nostoc) and of excised cephalodia was sustained at higher rates and for longer than was the dark nitrogenase activity of the isolated Nostoc growing exponentially. Dark nitrogenase activity of the symbiotic Nostoc was supported by the catabolism of polyglucose accumulated in the ligh and which in darkness served to supply ATP and reductant. The decrease in glucose content of the cephalodia paralleled the decline in dark nitrogenase activity in the presence of CO₂; in the absence of CO₂ dark nitrogenase activity declined faster although the rate of glucose loss was similar in the presence and absence of CO₂. Dark CO₂ fixation, which after 30 min in darkness represented 17 and 20% of the light rates of discs and cephalodia, respectively, also facilitated dark nitrogenase activity. The isolated Nostoc, the Coccomyxa and the excised fungus all fixed CO₂ in the dark; in the lichen most dark CO₂ fixation was probably due to the fungus. Kinetic studies using discs or cephalodia showed highest initial incorporation of ¹⁴CO₂ in the dark in to oxaloacetate, aspartate, malate and fumarate; incorporation in to alanine and citrulline was low; incorporation in to sugar phosphates, phosphoglyceric acid and sugar alcohols was not significant. Substantial activities of the enzymes phosphoenolpyruvate (PEP) carboxylase (EC 4.1.1.31) and carbamoyl-phosphate synthase (EC 2.7.2.5 and 2.7.2.9) were detected but the activities of PEP carboxykinase (EC 4.1.1.49) and PEP carboxyphosphotransferase (EC 4.1.1.38) were negligible. In the dark nitrogenase activity by the cephalodia, but not by the free-living Nostoc, declined more rapidly in the absence than in the presence of CO₂ in the gas phase. Exogenous NH ₄ ⁺ inhibited nitrogenase activity by cephalodia in the dark especially in the absence of CO₂ but had no effect in the light. The overall data suggest that in the lichen dark CO₂ fixation by the fungus may provide carbon skeletons which accept NH ₄ ⁺ released by the cyanobacterium and that in the absence of CO₂, NH ₄ ⁺ directly, or indirectly via a mechanism which involves glutamine synthetase, inhibits nitrogenase activity.Abbreviations CP carbamoyl phosphate - EDTA ethylenedi-amine tetraacetic acid - PEP phosphoenolpyruvate - RuBP ribulose 1,5 bisphosphate     

Regulation of ammonium uptake and metabolism by nitrogen fixing bacteria. III. Clostridium pasteurianum

Addition of ammonium salts to N₂ fixing continuous cultures of Clostridium pasteurianum caused immediate stop of nitrogenase synthesis, while the levels of glutamine synthetase, glutamate dehydrogenase and asparagine synthetase remained constant. No evidence for an interconversion of the glutamine synthetase was found. The activities of glutamate synthase in crude extracts were inversely related to the nitrogenase levels. The intracellular glutamine pool rapidly expanded during nitrogenase repression and decreased as fast during derepression while the pool sizes of all other amino acids were not strongly related to the rate of nitrogenase formation. These investigations suggest glutamine as corepressor of nitrogenase synthesis.     

DIAZOTROPHIC GROWTH OF THE MARINE CYANOBACTERIUM TRICHODESMIUM IMS101 IN CONTINUOUS CULTURE: EFFECTS OF GROWTH RATE ON N2‐FIXATION RATE,BIOMASS, AND C:N:P STOICHIOMETRY1

Trichodesmium N₂ fixation has been studied for decades in situ and, recently, in controlled laboratory conditions; yet N₂‐fixation rate estimates still vary widely. This variance has made it difficult to accurately estimate the input of new nitrogen (N) by Trichodesmium to the oligotrophic gyres of the world ocean. Field and culture studies demonstrate that trace metal limitation, phosphate availability, the preferential uptake of combined N, light intensity, and temperature may all affect N₂ fixation, but the interactions between growth rate and N₂ fixation have not been well characterized in this marine diazotroph. To determine the effects of growth rate on N₂ fixation, we established phosphorus (P)–limited continuous cultures of Trichodesmium, which we maintained at nine steady‐state growth rates ranging from 0.27 to 0.67 d^?1. As growth rate increased, biomass (measured as particulate N) decreased, and N₂‐fixation rate increased linearly. The carbon to nitrogen ratio (C:N) varied from 5.5 to 6.2, with a mean of 5.8 ± 0.2 (mean ± SD, N = 9), and decreased significantly with growth rate. The N:P ratio varied from 23.4 to 45.9, with a mean of 30.5 ± 6.6 (mean ± SD, N = 9), and remained relatively constant over the range of growth rates studied. Relative constancy of C:N:P ratios suggests a tight coupling between the uptake of these three macronutrients and steady‐state growth across the range of growth rates. Our work demonstrates that growth rate must be considered when planning studies of the effects of environmental factors on N₂ fixation and when modeling the impact of Trichodesmium as a source of new N to oligotrophic regions of the ocean.     

BACTERIAL ASSOCIATIONS WITH MARINE OSCILLATORIA SP. (TRICHODESMIUM SP.) POPULATIONS: ECOPHYSIOLOGICAL IMPLICATIONS1

On three separate occasions we investigated morphological and physiological aspects of bacterial associations with planktonic aggregates of the ubiquitous marine N₂ fixing cyanobacterium Trichodesmium sp. Close associations generally characterized Trichodesmium blooms; associations were present during day- and night-time. Colonization by both rod-shaped and filamentous heterotrophic bacteria occurred on Trichodesmiun aggregates actively fixing N₂ (acetylene reduction). Scanning electron and optical microscopy showed bacteria located both around and within aggregates. Microautoradiography demonstrated that associated bacteria largely mediated utilization of trace additions of ³H-labeled carbohydrates (fructose, glucose, mannitol) and amino acids, whereas Trichodesmium utilized amino acids only. Oxygen measurements using microelectrodes revealed high localized oxygen consumption among aggregates, with rapid (within a minute) changes from supersaturated to subsaturated oxygen following the transition from photosynthetic illuminated to dark periods. Stab culturing techniques confirmed the presence of heterotrophic N₂ fixers among aggregate-associated bacteria. Parallel deployment of oxygen microelectrodes, the tetrazolium salt 2,3,5 triphenyl tetrazolium chloride (TTC) and acetylene reduction assays demonstrated microaerophilic requirements for expression of nitrogenase activity among cultured bacteria. Trichodesmium aggregates are characterized by dynamic nutrient and oxygen regimes, which promote and maintain simultaneous and contiguous oxygenic photosynthesis and N₂ fixation. In part, the above-mentioned consortial interactions with a variety of heterotrophic bacteria facilitate Trichodesmium biomass production and bloom formation in nitrogen depleted, oligotrophic tropical/subtropical waters.     

Effect of divalent cations on the short-term NH 4 + inhibition of nitrogen fixation in Azotobacter chroococcum

Incubation of Azotobacter chroococcum in the presence of micromolar concentrations of MnCl₂, but not MgCl₂, prevented nitrogenase activity from NH ₄ ⁺ inhibition. Mg(II), at a 100-fold concentration with respect to Mn(II), counteracted the protective effect of Mn(II) on nitrogenase activity. When Mn(II) was added to cells that had been given NH₄Cl, stopping of NH ₄ ⁺ uptake and recovery of nitrogenase activity took place, and a raise of NH ₄ ⁺ concentration in medium developed. Furthermore, incubation of A. chroococcum cells with 20 M Mn(II) under air, but not under an argon: oxygen (79%:21%) gas mixture, resulted in NH ₄ ⁺ excretion to the external medium. The Mn(II)-mediated uncoupling of nitrogen fixation from ammonium assimilation leads us to conclude that Mn(II) may act as a physiological inhibitor of glutamine synthetase.Abbreviations Hepes N-2-Hydroxyethylpiperazine-N-ethanesulfonic acid - Mops 3-(N-Morpholino)propanesulfonic acid