Age-dependent conversion of nitrate reductase to cytochrome c reductase species in barley leaf extracts

The stability of nitrate reductase (NR) in extracts from 4-, 5- and 6-day-old primary leaves of barley was examined. The half-time of loss of NR activity was found to be 358, 107 and 70 min, respectively. Bovine serum albumin (BSA) and phenylmethylsulphonylfluoride (PMSF) stabilized NR in extracts from 5- and 6-day-old primary leaves, but BSA was much more effective. The increased instability of NR with age correlated with increased conversion of the MW 203 000 NR complex to smaller NADH cytochrome c reductase (CR) species of MW 163 000, 61 000 and 40 000. The MW 163 000 CR species also possessed NR activity. BSA prevented and PMSF retarded the conversion of NR to the smaller CR species. The increased instability of NR in extracts from older tissue may be due to increased conversion of NR to smaller CR species. The ability of PMSF and BSA to stabilize NR and inhibit conversion of NR to the smaller CR species indicates that these phenomena are probably due to proteolytic degradation of NR. This suggestion is supported by the observation that trypsin cleaved NR to 3–4 S CR species and that cleavage was retarded by the presence of BSA. Endogenous proteinase attack at specific sites between domains of the barley NR complex may generate the CR species seen in barley extracts. The MW 40 000 CR species probably carries at least the FAD domain.     

Light-, nitrogen-, and phosphorus-limited growth of Phaeodactylum tricornutum Bohlin strain TFX-1: Chemical composition,carbon partitioning,and the diel periodicity of physiological processes

Phaeodactylum tricomutum Bohlin (strain TFX-1) was grown under light-, nitrogen-, and phosphorus-limited conditions in continuous or semicontinuous cultures under a 12L-12D light regime. The C, N, and P contents were determined at each steady state, as was the partitioning of cellular organic carbon into protein, lipids, polysaccharides, and metabolic intermediates. All determinations were made at the beginning and again at the end of the light period. The rates of nutrient assimilation and of synthesis of biochemical constituents during the light and dark periods were calculated from the above data, and the periodicities of these processes characterized. The elemental composition of the cells was different under each limitation. In particular, phosphorus limitation severely restricted the ability of the cell to store nitrogen in non-protein forms. Biochemical composition and the diel periodicity of cellular processes also differed between limitations. Nutrient uptake was most strongly periodic under light limitation. Protein synthesis showed increased periodicity under nitrogen limitation, relative to the other limitations, while the periodicity of lipid synthesis was reduced under phosphate limitation. Polysaccharide was synthesized at high rates during the light period and consumed in the dark under all limitations.     

Activation of nitrate reductase by extracts from corn scutella

NADH-nitrate reductase (NR) from the primary leaves and root tips of corn seedlings (var. W64A × W182E) were activated by extracts from corn scutella. The activator extracted in potassium phosphate buffer (pH 7.5) or 80% (v/v) ethanol and fractionated by Dowex 1 (acetate) and Dowex 50 (H⁺) resins was recovered in the cationic fraction. The activator was not detected in extracts from shoots, roots, or endosperm of the seedlings. It activated the nitrate-induced cytochrome c reductase of NR complex but had slight inhibitory effects on the activities of FMNH₂-NR and reduced methylviologen-NR. In addition the activator inhibited the activities of purified NR-inactivating proteins from corn roots (var. Wf9 × 38-11) and rice cell cultures.     

Deconstructing the electron transfer chain in a complex molybdoenzyme: Assimilatory nitrate reductase from Neurospora crassa

Nitrate reductase (NR) from the fungus Neurospora crassa is a complex homodimeric metallo-flavoenzyme, where each protomer contains three distinct domains; the catalytically active terminal molybdopterin cofactor, a central heme-containing domain, and an FAD domain which binds with the natural electron donor NADPH. Here, we demonstrate the catalytic voltammetry of variants of N. crassa NRs on a modified Au electrode with the electrochemically reduced forms of benzyl viologen (BV²⁺) and anthraquinone sulfonate (AQS^?) acting as artificial electron donors. The biopolymer chitosan used to entrap NR on the electrode non-covalently and the enzyme film was both stable and highly active. Electrochemistry was conducted on two distinct forms; one lacking the FAD cofactor and the other lacking both the FAD and heme cofactors. While both enzymes showed catalytic nitrate reductase activity, removal of the heme cofactor resulted in a more significant effect on the rate of nitrate reduction. Electrochemical simulation was carried out to enable kinetic characterisation of both the NR:nitrate and NR:mediator reactions.     

Abscisic Aldehyde Is an Intermediate in the Enzymatic Conversion of Xanthoxin to Abscisic Acid in Phaseolus vulgaris L. Leaves

The enzymatic conversion of xanthoxin to abscisic acid by cell-free extracts of Phaseolus vulgaris L. leaves has been found to be a two-step reaction catalyzed by two different enzymes. Xanthoxin was first converted to abscisic aldehyde followed by conversion of the latter to abscisic acid. The enzyme activity catalyzing the synthesis of abscisic aldehyde from xanthoxin (xanthoxin oxidase) was present in cell-free leaf extracts from both wild type and the abscisic acid-deficient molybdopterin cofactor mutant, Az34 (nar2a) of Hordeum vulgare L. However, the enzyme activity catalyzing the synthesis of abscisic acid from abscisic aldehyde (abscisic aldehyde oxidase) was present only in extracts of the wild type and no activity could be detected in either turgid or water stressed leaf extracts of the Az34 mutant. Furthermore, the wilty tomato mutants, sitiens and flacca, which do not accumulate abscisic acid in response to water stress, have been shown to lack abscisic aldehyde oxidase activity. When this enzyme fraction was isolated from leaf extracts of P. vulgaris L. and added to extracts prepared from sitiens and flacca, xanthoxin was converted to abscisic acid. Abscisic aldehyde oxidase has been purified about 145-fold from P. vulgaris L. leaves. It exhibited optimum catalytic activity at pH 7.25 in potassium phosphate buffer.     

Stabilization of nitrate reductase in maize roots by chymostatin

Nitrate reductase (NR) in maize (Zea mays cv W64A × W182E) roots has been stabilized in vitro by the addition of chymostatin to extraction buffer. Contrary to previous observations, levels of NR were higher in the mature root than in root tip sections when chymostatin was included in the extraction buffer. Two forms of NR were identified, an NADH monospecific NR found mainly in the 1cm root tip and an NAD(P)H bispecific NR found predominantly in mature regions of the root. During the first 10 days of seedling growth, NR activity in the root ranged from 50 to 80% of the activities found in the leaf (a maximum of 2.4 micromoles NO⁻₂ produced per hour per gram fresh weight was measured at 4 days).     

The simultaneous assimilation of ammonium and l-arginine by the marine diatom Phaeodactylum tricornutum Bohlin

Nitrogen-replete cells of Phaeodactylum tricomutum Bohlin assimilated ammonium and the amino acid l-arginine simultaneously. Arginine was taken up at rates expected to supply at least 30% of the cells' requirement for nitrogen; arginme-carbon mainly entered protein but, when uptake was in darkness, ≈40% was respired. Cells grown in a 12:12 h light:dark cycle with ammonium as the sole nitrogen source took up ammonium throughout the growth cycle, whereas cells grown with the addition of arginine took up little ammonium during the dark phase. The uptake of ammonium over the course of the cycle was reduced by 30% when arginine was present. Cells grown with arginine as the sole nitrogen source took up the amino acid at the rate required for growth. In contrast, cells grown on ammonium, while growing at the same rate as those on arginine, assimilated nitrogen at twice the rate. Cells grown with both sources of nitrogen present, took up arginine at the same rate as before, but more of the arginine-carbon was respired (60% as compared with 40% when ammonium was absent). The uptake of ammonium was reduced by 30%, but the total nitrogen assimilation again exceeded immediate requirements. A high uptake rate of arginine was indicative of cells assimilating ammonium only; a low uptake rate of ammonium during the dark phase of growth was indicative of cells assimilating arginine. It is not known whether the findings with P. tricomutum are applicable to other marine phytoplankton. If they are, arginine may be of greater significance as a natural source of nitrogen for phytoplankton than is generally thought.     

Immunochemical Characterization of Nitrate Reductase Forms from Wild-Type (cv Williams) and nr(1) Mutant Soybean

Soybean (Glycine max L. Merr.) leaves contain two forms of nitrate reductase (NR)—NAD(P)H:NR and NADH:NR. Wild-type (cv Williams), nr₁ mutant and an unrelated cultivar (Prize) were grown with either no N source or with nitrate. Crude extracts were assayed for NR activities and the enzyme forms were purified on blue Sepharose. Analyses were done by polyacrylamide gel electrophoresis and `Western blotting' using antibodies specific for NR. NAD(P)H:NR was identified as the constitutive NR present in wild-type and Prize, but was absent from the mutant. All three soybean lines contained nitrate-inducible NADH:NR with highest activity at pH 7.5. The results showed that NAD(P)H:NR and constitutive NR were one in the same and confirmed the presence of NADH:NR with pH 7.5 optimum.     

Evaluation of antibacterial activity of crude protein extracts from seeds of six different medical plants against standard bacterial strains

A huge group of natural antimicrobial compounds are active against a large spectrum of bacterial strains causing infectious threat. The present study was conducted to investigate the crude extracts of antimicrobial protein and peptide efficacy from six medicinal plant seeds. Extraction was carried out in Sodium phosphate citrate buffer, and Sodium acetate buffer using different pH. Antimicrobial activities of these plants were determined by the microbiological technique using Agar well diffusion Assay. Extremely strong activity was observed in the seed extracts of Allium ascolinicum extracted in sodium phosphate citrate buffer at pH (5.8) against Proteus vulgaris, Escherichia coli and Staphylococcus aureus with zone of inhibition 17 mm, 17 mm and 15 mm and Rumex vesicarius at pH (7.6), Ammi majus at pH (6.8), Cichorium intybus at pH (7.4) and Cucumis sativus at pH (7.8) also showed better sensitivity against the bacterial strains with zone of inhibition ranges 16–10 mm and some of the strains were found to be resistant. Antibacterial activity pattern of different plant extracts prepared in sodium acetate buffer pH (6.5), among all the plant seed extracts used Foeniculum vulgare had shown good inhibition in all the bacterial strains used, with zone of inhibition ranges 11–12.5 mm, The extracts of C. intybus and C. sativus were found to be effective with zone of inhibition 11–6 mm and some of the strains were found to be resistant. Most of the strains found to have shown better sensitivity compared with the standard antibiotic Chloramphenicol (25 mcg). Our results showed that the plants used for our study are the richest source for antimicrobial proteins and peptides and they may be used for industrial extraction and isolation of antimicrobial compounds which may find a place in medicine industry as constituents of antibiotics.     

Temperature dependence of nitrate reductase activity in marine phytoplankton: biochemical analysis and ecological implications

The temperature dependence of NADH:NR activity was examined in several marine phytoplankton species and vascular plants. These species inhabit divergent thermal environments, including the chromophytes Skeletonema costatum (12–15° C), Skeletonema tropicum (18–25° C), Thalassiosira antarctica (?2 to 4° C), and Phaeocystis antarctica (?2 to 4° C), the green alga Dunaliella tertiolecta (14–28° C), and the vascular plants Cucurbita maxima (20–35° C) and Zea mays (20–25° C). Despite the difference in growth habitats, similar temperature response curves were observed among the chromophytic phytoplankton, with temperatures optimal for NR activity being between 10–20° C. In contrast, the chlorophyll b‐containing alga and vascular plants exhibited optimal temperatures for NR activity above 30° C. Such dramatic differences in NR thermal characteristics from the two taxonomic groups reflect a divergence in NR structure that may be associated with the evolutionary diversification of chromophytes and chlorophytes. Further, it suggests a potential contribution of the thermal performance of NR to the geographic distributions, seasonal abundance patterns, and species composition of phytoplankton communities. NR partial activities, which assess the individual functions of Mo‐pterin and FAD domains, were evaluated on NR purified from S. costatum to determine the possible causes for high temperature (>20° C) inactivation of NR from chromophytes. It was found that the FAD domain and electron transport among redox centers were sensitive to elevated temperatures. S. costatum cells grown at 5, 15, and 25° C exhibited an identical optimal temperature (15° C) for NADH:NR activity, whereas the maximal NR activity and NR protein levels differed and were positively correlated with growth temperature and growth rate. These findings demonstrate that thermal acclimation of NO₃^? reduction capacity is largely at the level of NR protein expression. The consequences of these features on NO₃^? utilization are discussed.     

Activation and stabilization of nitrate reductase by NADH in wheat and maize

Preincubation of nitrate reductase (NR) extracted from wheat shoot tips with NADH in vitro, activated and stabilized activity at both O° and 25°. However, preincubation with potassium ferricyanide inactivated the NR in vitro. NADH also stabilized the NR activity in extracts from maize shoot tips. It was observed that NR from both wheat and maize was active at low temperatures.     

Development of NAD(P)H: and NADH:Nitrate Reductase Activities in Soybean Cotyledons

The cotyledons of soybean begin to develop photosynthetic capacity shortly after emergence. The cotyledons develop nitrate reductase (NR) activity in parallel with an increase in chlorophyll and a decrease in protein. In crude extracts of 5- to 8-day-old cotyledons, NR activity is greatest with NADH as electron donor. In extracts of older cotyledons, NR activity is greatest with NADPH. Blue-Sepharose was used to purify and separate the NR activities into two fractions. When the blue-Sepharose was eluted with NADPH, NR activity was obtained which was most active with NADPH as electron donor. Assays of the NADPH-eluted NR with different concentrations of nitrate revealed that the highest activity was obtained in 80 millimolar KNO₃. Thus, this fraction has properties similar to the low nitrate affinity NAD(P)H:NR of soybean leaves. When 5- to 8-day-old cotyledons were extracted and purified, further elution of the blue-Sepharose with KNO₃, subsequent to the NADPH elution, yielded an NR fraction most active with NADH. Assays of this fraction with different nitrate concentrations revealed that this NR had a higher nitrate affinity and was similar to the NADH:NR of soybean leaves. The KNO₃-eluted NR fraction which was purified from the extracts of 9- to 14-day-old cotyledons, was most active with NADPH. The analysis of these fractions prepared from the extracts of older cotyledons indicated that residual NAD(P)H:NR contaminated the NADH:NR. Despite this complication, the pattern of development of the purified NR fractions was consistent with the changes observed in the crude extract NR activities. It was concluded that NADH:NR was most active in young cotyledons and that as the cotyledons aged the NAD(P)H:NR became more active.     

Temperature dependence of nitrate reductase in the psychrophilic unicellular alga Koliella antarctica and the mesophilic alga Chlorella sorokiniana

Temperature responses of nitrate reductase (NR) were studied in the psychrophilic unicellular alga, Koliella antarctica, and in the mesophilic species, Chlorella sorokiniana. Enzymes from both species were purified to near homogeneity by Blue Sepharose (Pharmacia, Uppsala, Sweden) affinity chromatography and high-resolution anion-exchange chromatography (MonoQ; Pharmacia; Uppsala, Sweden). Both enzymes have a subunit molecular mass of 100 kDa, and K. antarctica NR has a native molecular mass of 367 kDa. NR from K. antarctica used both NADPH and NADH, whereas NR from C. sorokiniana used NADH only. Both NRs used reduced methyl viologen (MVH) or benzyl viologen (BVH). In crude extracts, maximal NADH and MVH-dependent activities of cryophilic NR were found at 15 and 35 degrees C, respectively, and retained 77 and 62% of maximal activity, respectively, at 10 degrees C. Maximal NADH and MVH-dependent activities of mesophilic NR, however, were found at 25 and 45 degrees C, respectively, with only 33 and 23% of maximal activities being retained at 10 degrees C. In presence of 2 microM flavin adenine dinucleotide (FAD), activities of cryophilic NADH:NR and mesophilic NADH:NR were stable up to 25 and 35 degrees C, respectively. Arrhenius plots constructed with cryophilic and mesophilic MVH:NR rate constants, in both presence or absence of FAD, showed break points at 15 and 25 degrees C, respectively. Essentially, similar results were obtained for purified enzymes and for activities measured in crude extracts. Factors by which the rate increases by raising temperature 10 degrees C (Q10) and apparent activation energy (E(a)) values for NADH and MVH activities measured in enzyme preparations without added FAD differed slightly from those measured with FAD. Overall thermal features of the NADH and MVH activities of the cryophilic NR, including optimal temperatures, heat inactivation (with/without added FAD) and break-point temperature in Arrhenius plots, are all shifted by about 10 degrees C towards lower temperatures than those of the mesophilic enzyme. Transfer of electrons from NADH to nitrate occurs via all three redox centres within NR molecule, whereas transfer from MVH requires Mo-pterin prosthetic group only; therefore, our results strongly suggest that structural modification(s) for cold adaptation affect thermodynamic properties of each of the functional domains within NR holoenzyme in equal measure.     

Properties of nitrate reductase from seedling leaves of selected barley genotypes

Crude extracts from leaves of 6-day barley seedlings of parental genotypes (cv. Aramir and primitive line R567) and selected doubled haploid (DH) lines were not found to have significant differences in the NADH:NR activity, while considerable differences between these genotypes were shown by the NAD(P)H:NR activity. The cv. Aramir and DH lines did not differ by nitrate accumulation in the leaves. However, the primitive line R567, as compared to the remaining genotypes, was characterized by an appreciably lower ability to accumulate nitrates. In partially purified leaf extracts, significant differences in total NADH:NR activity and in distal activity dependent on methyl viologen (MV:NR) were found between the parental genotypes and selected DH lines. The studied genotypes differed also in dehydrogenase NR activity, i.e. cytochrome c reductase activity in crude extracts. In the studied genotypes, the NADH:NR activity in partially purified leaf extracts did not substantially differ by Km values for nitrates. Calculated Vmax values for NADH:NR in these genotypes were similar to total NR activity in partially purified extracts. Significant differences between the parental genotypes and selected DH lines were found in the thermal NADH:NR stability in crude and partially purified leaf extracts. From the performed studies it follows that different NR stability was one of the reasons of revealed differences in total activity and in partial NR activities in the leaf extracts between the studied genotypes of spring barley. Besides, it is suggested that varied NR gene expression in the leaves of these barley genotypes could also influence NR activity.     

Biochemical Characterization of Soybean Mutants Lacking Constitutive NADH:Nitrate Reductase

Two nitrate reductase (NR) mutants were selected for low nitrate reductase (LNR) activity by in vivo NR microassays of M₂ seedlings derived from nitrosomethylurea-mutagenized soybean (Glycine max [L.] Merr. cv Williams) seeds. The mutants (LNR-5 and LNR-6) appeared to have normal nitrate-inducible NR activity. Both mutants, however, showed decreased NR activity in vivo and in vitro compared with the wild-type. In vitro FMNH₂-dependent nitrate reduction and Cyt c reductase activity of nitrate-grown plants, and nitrogenous gas evolution during in vivo NR assays of urea-grown plants, were also decreased in the mutants. The latter observation was due to insufficient generation of nitrite substrate, rather than some inherent difference in enzyme between mutant and wild-type plants. When grown on urea, crude extracts of LNR-5 and LNR-6 lines had similar NADPH:NR activities to that of the wild type, but both mutants had very little NADH:NR activity, relative to the wild type. Blue Sepharose columns loaded with NR extract of urea-grown mutants and sequentially eluted with NADPH and NADH yielded a NADPH:NR peak only, while the wild-type yielded both NADPH: and NADH:NR peaks. Activity profiles confirmed the lack of constitutive NADH:NR in the mutants throughout development. The results provide additional support to our claim that wild-type soybean contains three NR isozymes, namely, constitutive NADPH:NR (c₁NR), constitutive NADH:NR (c₂NR), and nitrate-inducible NR (iNR).     

NADH nitrate reductase and related NADH cytochrome c reductase species in barley

Nitrate and nitrate-less barley (Hordeum vulgare cv Golden Promise) shoot extracts were examined by Sephadex G200 gel filtration and sucrose density gradient analysis and the MWs of NR and CR species present were determined from their Stokes radii and sedimentation coefficients by the method of Siegel and Monty. Nitrate-less plant extracts possessed a CR species of MW 27 800 whilst nitrate-plant extracts possessed CR species of MW 203 000, 61 000, 40 000 and 27 800. The MW 203 000 CR species was associated with NADH-NR, FMNH-NR and MV°-NR activities and represents the NR complex. The MW 40 000 and 61 000 CR species were shown to be derived from the NR complex. We suggest that the MW 40 000 and 61 000 CR species represent either subunits of the NR complex or domains cleaved from the intact NR complex by endogenous proteinases.     

Survey of pyruvate,phosphate dikinase activity of plants in relation to the C3, C4 and CAM mechanisms of CO2 assimilation

The pyruvate, phosphate dikinase activity (PPD, EC 2.7.9.1) associated with crude extracts of leaf tissue of some C₃ and C₄ plants was determined by phosphoenolpyruvate plus PPi-dependent phosphorylation of AMP. The PPD activity of all C₄ plants examined was > 15 nmol/mg protein/min. Several factors contributed to the underestimation of PPD activity in crude extracts of at least some species. Significant PPD activity (> 0.15 nmol/mg protein/min) was not detected in the majority of C₃ species but several C₃ species and the two CAM species studied exhibited activity in the range 0.4–4 nmol/mg protein/min while the C₃ species Avena sativa showed activity up to 8 nmol/mg protein/min. The oat leaf enzyme was partially purified; it exhibited properties similar to those of partially purified PPD from maize. Leaf extracts of the orchids Cymbidium canaliculatum and C. madidum contained high levels of PPD activity similar to the majority of C₄ plants. PPD activity has also been shown in other previously unstudied species.     

Role of sucrose-phosphate synthase in partitioning of carbon in leaves

Variations in leaf starch accumulation were observed among four species (wheat [Triticum aestivum L.], soybean [Glycine max L. Merr.], tobacco [Nicotiana tabacum L.], and red beet [Beta vulgaris L.]), nine peanut (Arachis hypogea L.) cultivars, and two specific peanut genotypes grown under different nutritional regimes. Among the genotypes tested, the activity of sucrose phosphate synthase was correlated negatively with leaf sucrose content in seven of the nine peanut cultivars as well as the two peanut cultivars grown with different mineral nutrition. The peanut cultivars differed in the effect of 10 millimolar sucrose on sucrose phosphate synthase activity in leaf extracts. Enzyme activity in crude leaf extracts was inhibited by sucrose (10-42%) in four of the cultivars tested whereas five cultivars were not. Overall, the results suggest that a correlation exists between the activity of sucrose phosphate synthase and starch/sucrose levels in leaves.     

Nitrate Reductase and Glucose-6-phosphate Dehydrogenase Activities as Influenced by Leaf Age and Addition of Protein to Extraction Media

Lea fage influences the level of activity and the decay rate of the enzymes nitrate reductase (NR: E.C. 1.6.6.1) and glucose-6-phosphate dehydrogenase (G6PD; E.C. 1.1.1.49) extracted with and without protein in the extraction media. Such influence was determined in three plant species: corn (Zea mays L.), oats (Arena sativa L.), and tobacco (Nicotiana tabacum L.). Leaves of different ages were obtained from plants of various ages, or by removal of leaf blades from different positions on a single shoot. NR activity (per g fresh weight) declined as leaves of these plant species became older, especially when extraction was effected with conventional media (i.e. without added protein). The instability of NR in these extracts increased as leaves became older. Decay of NR in vitro was exponential with time. Addition of protein [3 %(w/v) casein or bovine serum albumin] to extraction media markedly increased the level of NR activity and its stability, especially in older leaves of all three plant species. Addition of protein did not affect the level of G6PD extracted from corn leaf blades, but slightly enhanced its activity in extracts from the oldest leaf blade of oats. G6PD activity also declined as leaf blades of corn and oats became older.     

Post-translational control of nitrate reductase activity responding to light and photosynthesis evolved already in the early vascular plants

Regulation of nitrate reductase (NR) by reversible phosphorylation at a conserved motif is well established in higher plants, and enables regulation of NR in response to rapid fluctuations in light intensity. This regulation is not conserved in algae NR, and we wished to test the evolutionary origin of the regulatory mechanism by physiological examination of ancient land plants. Especially a member of the lycophytes is of interest since their NR is candidate for regulation by reversible phosphorylation based on sequence analysis. We compared Selaginella kraussiana, a member of the lycophytes and earliest vascular plants, with the angiosperm Arabidopsis thaliana, and also tested the moss Physcomitrella patens. Interestingly, optimization of assay conditions revealed that S. kraussiana NR used NADH as an electron donor like A. thaliana, whereas P. patens NR activity depended on NADPH. Examination of light/darkness effects showed that S. kraussiana NR was rapidly regulated similar to A. thaliana NR when a differential (Mg²⁺ contra EDTA) assay was used to reveal activity state of NR. This implies that already existing NR enzyme was post-translationally activated by light in both species. Light had a positive effect also on de novo synthesis of NR in S. kraussiana, which could be shown after the plants had been exposed to a prolonged dark period (7 days). Daily variations in NR activity were mainly caused by post-translational modifications. As for angiosperms, the post-translational light activation of NR in S. kraussiana was inhibited by 3-(3,4-dichlorophenyl)-1*1-dimethylurea (DCMU), an inhibitor of photosynthesis and stomata opening. Evolutionary, a post-translational control mechanism for NR have occurred before or in parallel with development of vascular tissue in land plants, and appears to be part of a complex mechanisms for coordination of CO₂ and nitrogen metabolism in these plants.