Glutamine synthetase in Scots pine seedlings and its control by blue light and light absorbed by phytochrome

The appearance of glutamine synthetase (GS. EC 6.3.1.2) in response to light and nitrogen (NO ₃ ^- , NH ₄ ⁺ ) was studied in the organs (roots, hypocotyl, cotyledonary whorl) of the Scots pine (Pinus sylvestris L.) seedling. Although GS activity was found to be mainly (> 80%) located in the whorl where it increased strongly in response to light, a significant GS synthesis was also detected in dark-grown seedlings. Anion-exchange chromatography was used to resolve two GS isoforms which appeared to be regulated differentially in the cotyledonary whorls. The isoform (presumably plastidic GS2) which eluted from the column at 90 mM KCl increased drastically in response to light. The other isoform (presumably cytosolic GS1), which eluted at 200 mM KCl, was not stimulated by light but tended to disappear during the experimental period (4 to 12 d after sowing). Immunoblotting of pine extract yielded a prominent band with a molecular weight of 43 kDa. The linear correlation between GS activity and immunodetectable GS protein could be extrapolated through zero, showing that any increase of GS2 activity is to be attributed to the de-novo synthesis of GS protein. Gelfiltration chromatography yielded a molecular mass for the GS holoenzyme of 340 kDa, a value which supports an octameric quarternary structure as previously suggested for angiosperms. While supplying seedlings with 10 mM NO ₃ ^- stimulated GS synthesis in the whorl by 12%, 10 mM NH ₄ ⁺ caused an incipient ammonium toxicity. Experiments using dischromatic light (simultaneous treatment with two light beams to vary the level of the physiologically active form of phytochrome, Pfr, in blue light) revealed that synthesis of GS2 was controlled by light in the same way as previously shown for ferredoxin-dependent glutamate synthase (Fd-GOGAT; EC 1.4.7.1). Up to 10 d after sowing the strong light effect could be attributed to phytochrome action whereas between 10 and 12 d after sowing phytochrome control of GS-synthesis failed if no blue/ultraviolet-A light was provided. The data show that blue light is required to maintain responsiveness of GS2 synthesis to phytochrome. Both enzymes, GS2 as well as Fd-GOGAT, appear to be regulated coordinately to meet the demands of ammonium assimilation.Abbreviations and Symbols B blue light - D darkness - Fd-GOGAT ferredoxin-dependent glutamate synthase (EC 1.4.7.1); - GS glutamine synthetase (EC 6.3.1.2) - R red light - RG9 long-wavelength far-red light defined by the properties of Schott glass filter RG9 - =Pfr/Ptot far-red absorbing form of phytochrome/total phytochrome, wavelength-dependent photoequilibrium of the phytochrome system Research supported by Deutsche Forschungsgemeinschaft (SFB 46 and Schwerpunkt Physiologie der Bäume). We thank J.M. Penther, (Institut für Biologie II, Freiburg, FRG) for his advice on the chromatographic techniques.     

Coaction of blue/ultraviolet-A light and light absorbed by phytochrome in controlling growth of pine (Pinus sylestris L.) seedlings

Photomorphogenesis is a conspicuous feature in conifers. In the case of the shade-intolerant Scots pine (Pinus sylvestris L.), control of stem growth by light is well expressed at the seedling stage and can readily be studied. The present data show that hypocotyl growth is controlled by the far-red-absorbing form of phytochrome (Pfr). However, the Scots pine seedling requires blue or ultraviolet (UV-A) light to become fully responsive to Pfr. Blue/UV-A light has no direct effect on hypocotyl growth and its action appears to be limited to establishing the responsiveness of the seedling to Pfr. This type of coaction between phytochrome and blue/UV-A light has been observed previously in a number of angiosperm seedlings. With regard to the high irradiance reaction of phytochrome in long-term far-red light the pine seedling deviates totally from what has been observed in etiolated angiosperms since continuous far-red light has no effect on stem growth.Abbreviations B light of wavelength between 500 and 400 nm - FR standard far-red light - HIR high irradiance reaction of phytochrome - R high-fluence-rate red light (_R = 0.8) - RG9-light long-wavelength far-red light defined by the properties of the Schott RG9 glass filter (_RG₉<0.01) - = Pfr/Ptot wavelength-dependent photoequilibrium of the phytochrome system (far-red-absorbing form of phytochrome/total phytochrome) - UV-A near ultraviolet light of wavelength between 400 and 320 nm - W white light Research supported by a grant from the Deutsche Forschungsgemeinschaft (Schwerpunkt Physiologie der Bäume).     

Chloroplast and cytosolic glutamine synthetase are encoded by homologous nuclear genes which are differentially expressed in vivo

We have shown that the individual members of the plant gene family for glutamine synthetase (GS) are differentially expressed in vivo, and each encode distinct GS polypeptides which are targeted to different subcellular compartments (chloroplast or cytosol). At the polypeptide level, chloroplast GS (GS2) and cytosolic GS (GS1 and GSn) are distinct and show an organ-specific distribution. We have characterized full length cDNA clones encoding chloroplast or cytosolic GS of pea. In vitro translation products encoded by three different GS cDNA clones, correspond to the mature GS2, GS1, and GSn polypeptides present in vivo. pGS185 encodes a precursor to the chloroplast GS2 polypeptide as shown by in vitro chloroplast uptake experiments. The pGS185 translation product is imported into the chloroplast stroma and processed to a polypeptide which corresponds in size and charge to that of mature chloroplast stromal GS2 (44 kDa). The 49 amino terminal amino acids encoded by pGS185 are designated as a chloroplast transit peptide by functionality in vitro, and amino acid homology to other transit peptides. The cytosolic forms of GS (GS1 and GSn) are encoded by highly homologous but distinct mRNAs. pGS299 encodes the cytosolic GS1 polypeptide (38 kDa), while pGS341 (Tingey, S. V., Walker, E. L., and Coruzzi, G. M. (1987) EMBO. J. 6, 1-9) encodes a cytosolic GSn polypeptide (37 kDa). The homologous nuclear genes for chloroplast and cytosolic GS show different patterns of expression in vivo. GS2 expression in leaves is modulated by light, at the level of steady state mRNA and protein, while the expression of cytosolic GS is unaffected by light. The light-induced expression of GS2 is due at least in part to a phytochrome mediated response. Nucleotide sequence analysis indicates that chloroplast and cytosolic GS have evolved from a common ancestor and suggest a molecular mechanism for chloroplast evolution.     

Coaction of blue/ultraviolet-A light and light absorbed by phytochrome in controlling the appearance of ferredoxin-dependent glutamate synthase in the Scots pine (Pinus sylvestris L.) seedling

The appearance of NADH- and ferredoxin (Fd)-dependent glutamate synthases (GOGATs) was investigated in the major organs (roots, hypocotyl and cotyledonary whorl) of the Scots pine seedling. It was found that cytosolic NADH-GOGAT (EC 1.4.1.14) dropped to a low level during the experimental period (from 4 to 12 d after sowing) and was not significantly affected by light. On the other hand, plastidic Fd-GOGAT (EC 1.4.7.1) increased strongly in response to light. Whereas similar amounts of NADH-GOGAT were found in the different organs, Fd-GOGAT was mainly found in the cotyledons even in the presence of nitrate. Protein chromatography revealed only a single Fd-GOGAT peak. No isoforms were detected. Experiments to investigate regulation of the appearance of Fd-GOGAT in the cotyledonary whorl yielded the following results: (i) In darkness, neither nitrate (15 mM KNO₃) nor ammonium (15 mM NH₄Cl) had an effect on the appearance of Fd-GOGAT. In the light, nitrate stimulated Fd-GOGAT activity by 30% whereas ammonium had no effect. The major controlling factor is light. (ii) The action of long-term white light (100 W · m^–2) could be replaced quantitatively by blue light (B, 10 W · m^–2). Since the action of long-term far-red light was very weak, operation of the High Irradiance Reaction of phytochrome is excluded. On the other hand, light-pulse experiments with dark-grown seedlings showed the involvement of phytochrome. (iii) Red light, operating via phytochrome, could fully replace B, but only up to 10 d after sowing. Thereafter, there was an absolute requirement for B for a further increase in the enzyme level. It appears that the operation of phytochrome was replaced by the operation of cryptochrome (B/UV-A photoreceptor). (iv) However, dichromatic experiments (simultaneous treatment of the seedlings with two light beams to vary the level of the far-red-absorbing form of phytochrome (Pfr) in blue light) showed that B does not affect enzyme appearance if the Pfr level is low. It is concluded that B is required to maintain responsiveness of Fd-GOGAT synthesis to phytochrome (Pfr) beyond 10 d after sowing.Abbreviations and Symbols B blue light - c continuous - D darkness - Fd-GOGAT ferredoxin-dependent glutamate synthase (EC 1.4.7.1) - FR far-red light - HIR high-irradiance reaction of phytochrome - NADH-GOGAT nicotinamide-dinucleotide-dependent glutamate synthase (EC 1.4.1.14) - R red light - RG9 long-wavelength far-red light defined by the properties of the Schott glass filter (_RG9<0.01) - Pfr/Ptot far-red-absorbing form of phytochrome/total phytochrome, wavelength-dependent photoequilibrium of the phytochrome system Research supported by Deutsche Forschungsgemeinschaft (SFB 46 und Schwerpunkt Physiologie der Bäume). We thank E. Fernbach for his help with the dichromatic experiments.     

Regulation by light of chlorophyll synthesis in the cotyledons of Scots pine (Pinus sylvestris) seedlings

Seedlings of gymnosperms, unlike angiosperms, synthesize chlorophyll(ide) (Chl) in darkness (D). In Scots pine cotyledons ( Pinus sylvestris L.) Chl accumulation ceases in D at a low level but Chl accumulation is strongly increased by light, red light (R) being more effective than blue light (B), whereas in Pinus maritima Chi synthesis is almost light-independent. In Scots pine the capacity to form Chl can be increased by R pulses, fully reversible by far-red light, demonstrating the involvement of phytochrome. However, when B- or R–grown seedlings were transferred to D, Chl accumulation stopped immediately irrespective of the level of P_fr (far-red light absorbing form of phytochrome), indicating that the conversion of protochlorophyllide (PChl) is light-dependent. Dose response curves in R and B and simultaneous irradiation with R and B show that R and B are perceived by separate photoreceptors. The immunodetected NADPH-dependent protochlorophyllide oxidoreductase (POR, EC 1.6.99.1), assumed to regulate light-dependent Chl synthesis in angiosperms, is not correlated with the capacity of gymnosperm Chi accumulation in darkness. While two FOR bands could be separated in extracts from dark grown material (38 and 36 kDa) of Pinus sylvestris and P. maritima , only the 38 kDa band disappeared consistently in the light. However. the significance of the more light resistant 36 kDa band for chlorophyll synthesis remains unclear as well.     

Factors involved in the coordinate appearance of nitrite reductase and glutamine synthetase in the mustard (Sinapis alba L.) seedling

The extent to which the appearances of nitrite reductase (NIR; EC 1.7.7.1) and glutamine synthetase (GS; EC 6.3.1.2) are coordinated was studied in mustard (Sinapis alba L.) seedlings. It was established by immunotitration that the increased activities of NIR and GS in the presence of light and nitrate can be attributed to the de-novo synthesis of enzyme protein. The bulk of the NIR and GS was found in the developing cotyledons. In the absence of nitrate in the growth medium there was no coordinate appearance of NIR and GS. While light strongly stimulated the appearance of GS, the level of NIR was hardly affected and remained low. On the other hand, in the presence of nitrate in the medium the appearances of NIR and GS were strictly coordinated, the GS level being considerably above that of NIR. It is argued that phytochrome-controlled synthesis of GS in the absence of nitrate is part of the mechanism to reassimilate ammonium liberated during proteolysis of storage protein and metabolism of the resulting amino acids, whereas the strictly coordinated synthesis in the presence of light and nitrate indicates the dominance of nitrate assimilation under these circumstances. The fact that the level of GS was always considerably above that of NIR appears to be a safety measure to prevent ammonium accumulation.Abbreviations FR standardized far-red light (3.5 W·m^–2), to drive the high-irradiance reaction of phytochrome - GS glutamine synthetase, EC 6.3.1.2 - NIR nitrite reductase, EC 1.7.7.1 This work was supported by Heidelberger Akademie der Wissenschaften (Forschungsstelle Nitratassimilation).     

Involvement of phytochrome and a blue light photoreceptor in UV-B induced flavonoid synthesis in parsley (Petroselinum hortense Hoffm.) cell suspension cultures

Flavonoid synthesis in cell suspension cultures of parsley (Petroselinum hortense Hoffm.) occurs only after irradiation with ultraviolet light (UV), mainly from the UV-B (280–320 nm) spectral range. However, it is also controlled by phytochrome. A P_fr/P_tot ratio of approximately 20% is sufficient for a maximum phytochrome response as induced by pulse irradiation. Continuous red and far red light, as well as blue light, given after UV, are more effective than pulse irradiations. The response to blue light is considerably greater than that to red and far red light. Continuous red and blue light treatments can be substituted for by multiple pulses and can thus probably be ascribed to a multible induction effect. Continuous irradiations with red, far red and blue light also increase the UV-induced flavonoid synthesis if given before UV. The data indicate that besides phytochrome a separate blue light photoreceptor is involved in the regulation of the UV-induced flavonoid synthesis. This blue light receptor seems to require the presence of P_fr in order to be fully effective.Abbreviations HIR high irradiance response - P_fr far red absorhing form of phytochrome - P_tet total phytochrome - UV ultraviolet light