Detection in Vivo of Very Rapid Red Light-Induced Calcium-Sensitive Protein Phosphorylation in Etiolated Wheat (Triticum aestivum) Leaf Protoplasts

Etiolated wheat (Triticum aestivum cv Mercia) leaf protoplasts respond to brief red-light irradiation by increasing in volume over a 10-min incubation period (M.E. Bossen, H.A. Dassen, R.E. Kendrick, W.J. Vredenberg [1988] Planta 174: 94-100). When the calcium-sensitive dye Fluo-3 was incorporated into these protoplasts, red-light irradiation initiated calcium transients lasting about 2 min (P.S. Shacklock, N.D. Read, A.J. Trewavas [1992] Nature 358: 153-155). Release of calcium in the protoplasts by photolysis of incorporated 1-{2-amino-5-[1-hydroxy-1-(2-nitro-4, 5-methylenedioxyphenyl)-methyl]-phenoxy}-2-(2[prime]-amino-5[prime]-methylp henoxy)-ethane-N,N, N[prime],N[prime] -tetraccetic acid, tetrasodium salt (caged calcium) or caged inositol trisphosphate frequently induced transient increases in intracellular calcium levels, although the kinetics of these changes showed variation between experiments. Upon exposure to red light, a pronounced increase in the phosphorylation of a 70-kD and to a lesser extent a 60-kD peptide was observed, commencing within 15 s and continuing for up to 2 min. Simultaneous far-red and red irradiation attenuated the response. Upon release of incorporated caged calcium by cage photolysis, the labeling of these two peptides was greatly increased. When incorporated caged inositol trisphosphate was photolyzed, only the labeling of the 70-kD peptide was enhanced. Phosphorylation of the 70-kD peptide was also increased when extracellular calcium was elevated, but it decreased with increasing extracellular EGTA. These data thus provide direct evidence for the operation of an in vivo transduction sequence involving red light-dependent, calcium-sensitive protein phosphorylation.     

Phosphorylation and Dephosphorylation of Guard-Cell Proteins from Vicia faba L. in Response to Light and Dark

Phosphorylation and dephosphorylation of proteins were investigated in guard-cell protoplasts from Vicia faba L. When guard-cell protoplasts were incubated with 32Pi in the dark for 80 min, several proteins, with molecular masses of 42, 40, 34, 32, 26, and 19 kD, were phosphorylated. Illumination of the dark-adapted protoplasts with red light caused dephosphorylation of the 26-kD protein, but there was no detectable change in levels of phosphorylation in other proteins. In the dephosphorylation of the 26-kD protein, far-red light of 730 nm was most effective, but when the light was turned off, the protein was phosphorylated to the original level within 10 min. Subcellular fractionation of guard-cell protoplasts indicated that the 26-kD protein was located in the chloroplast. The migration pattern of the 26-kD protein was exactly the same as the light-harvesting Chl a/b protein complex of photosystem II (LHCPII) from Vicia mesophyll cells on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The dephosphorylated 26-kD protein was phosphorylated by adding sodium hydrosulfite, a strong reducing agent, under the far-red illumination of guard-cell protoplasts. The magnitude of dephosphorylation by red light (660 nm) was increased by 3-(3,4-dichlorophenyl)-1,1-dimethylurea, an electron transfer inhibitor of photosystem II (PSII). Light-induced dephosphorylation was inhibited by 1 nM okadaic acid, an inhibitor of serine/threonine protein phosphatase. From these results, it is concluded that the 26-kD protein is LHCPII and that LHCPII is present mostly in the phosphorylated form in the dark and is dephosphorylated by type 2A protein phosphatase under the light absorbed by photosystem I in Vicia guard-cell protoplasts.     

Intracellular protein phosphorylation in oat (Avena sativa L.) protoplasts by phytochrome action. 1. Measurement of action spectra for the protein phosphorylation

The effects of red light and wavelength dependency of the protein phosphorylation in oat protoplasts were investigated by sodium dodecyl sulfate polyacrylamide gel electrophoresis and autoradiography. Red light (660 nm) irradiation of the protoplasts increased the phosphorylation of 15 different proteins, and the phosphorylation of 2 proteins (27 KDa, 32 KDa) out of 15 were observed to be dependent on the wavelength of the irradiating light. The phosphorylation densities of these two proteins increased up to two or three hundred percent during a three-minute period of irradiation. The phosphorylation of these two proteins revealed a red/far-red photoreversibility of phytochrome. When a calcium ion chelator (2 mM EGTA) was added into the cell suspension, the phosphorylations of all the proteins were reduced about 200%. These findings suggest that phytochrome action and Ca2+ influx are certainly involved in the in vivo phosphorylation of proteins in oat protoplasts.     

Insulin stimulates the tyrosine phosphorylation of caveolin

The specialized plasma membrane structures termed caveolae and the caveolar-coat protein caveolin are highly expressed in insulin- sensitive cells such as adipocytes and muscle. Stimulation of 3T3-L1 adipocytes with insulin significantly increased the tyrosine phosphorylation of caveolin and a 29-kD caveolin-associated protein in caveolin-enriched Triton-insoluble complexes. Maximal phosphorylation occurred within 5 min, and the levels of phosphorylation remained elevated for at least 30 min. The insulin-dose responses for the tyrosine phosphorylation of caveolin and the 29-kD caveolin-associated protein paralleled those for the phosphorylation of the insulin receptor. The stimulation of caveolin tyrosine phosphorylation was specific for insulin and was not observed with PDGF or EGF, although PDGF stimulated the tyrosine phosphorylation of the 29-kD caveolin- associated protein. Increased tyrosine phosphorylation of caveolin, its associated 29-kD protein, and a 60-kD protein was observed in an in vitro kinase assay after incubation of the caveolin-enriched Triton- insoluble complexes with Mg-ATP, suggesting the presence of an intrinsic tyrosine kinase in these complexes. These fractions contain only trace amounts of the activated insulin receptor. In addition, these complexes contain a 60-kD kinase detected in an in situ gel kinase assay and an approximately 60 kD protein that cross-reacts with an antibody against the Src-family kinase p59Fyn. Thus, the insulin- dependent tyrosine phosphorylation of caveolin represents a novel, insulin-specific signal transduction pathway that may involve activation of a tyrosine kinase downstream of the insulin receptor.     

Protein phosphorylation in isolated nuclei from etiolated Avena seedlings. Effects of red/far-red light and cholera toxin

We have studied the phosphorylation/dephosphorylation of several nuclear proteins in isolated nuclei from etiolated Avena seedlings as a function of red/far-red light. The effect of stimulatory (ADP-ribosylation by cholera toxin) or inhibitory (GDP beta S) conditions for GTP-binding proteins was also studied. Red or far-red light enhanced the phosphorylation level of 2 nuclear proteins with molecular masses of 75 and 60 kDa. The phosphorylation pattern was affected by the addition of cholera toxin or GDP beta S to the isolated nuclei. At least 2 proteins with molecular masses of 24 and 75 kDa cross-reacted by Western blot with GTP-binding protein antibodies.     

Intracellular localisation of phytochrome and ubiquitin in red-light-irradiated oat coleoptiles by electron microscopy

The intracellular localisation of phytochrome and ubiquitin in irradiated oat coleoptiles was analysed by electron microscopy. We applied indirect immunolabeling with polyclonal antibodies against phytochrome from etiolated oat seedlings or polyclonal antibodies against ubiquitin from rabbit reticulocytes, together with a goldcoupled second antibody, on serial ultrathin sections of resin-embedded material. Immediately after a 5-min pulse of red light-converting phytochrome from the red-absorbing (Pr) to the far-redabsorbing (Pfr) form-the label for phytochrome was found to be sequestered in electron-dense areas. For up to 2 h after irradiation, the size of these areas increased with increasing dark periods. The ubiquitin label was found in the same electrondense areas only after a dark period of 30 min. A 5 min pulse of far-red light, which reverts Pfr to Pr, given immediately after the red light did not cause the electron-dense structures to disappear; moreover, they contained the phytochrome label immediately after the far-red pulse. In contrast, after the reverting far-red light pulse, ubiquitin could only be visualised in the electron-dense areas after prolonged dark periods (i.e. 60 min). The relevance of these data to light-induced phytochrome pelletability and to the destruction of both Pr and Pfr is discussed.Abbreviations FR far-red light; Pfr - Pr far-red-absorbing and red-absorbing forms of phytochrome, respectively - R red light     

Pr-specific phytochrome phosphorylation in vitro by a protein kinase present in anti-phytochrome maize immunoprecipitates

Protein kinase activity has repeatedly been found to co-purify with the plant photoreceptor phytochrome, suggesting that light signals received by phytochrome may be transduced or modulated through protein phosphorylation. In this study immunoprecipitation techniques were used to characterize protein kinase activity associated with phytochrome from maize (Zea mays L.). A protein kinase that specifically phosphorylated phytochrome was present in washed anti-phytochrome immunoprecipitates of etiolated coleoptile proteins. No other substrate tested was phosphorylated by this kinase. Adding salts or detergents to disrupt low-affinity protein interactions reduced background phosphorylation in immunoprecipitates without affecting phytochrome phosphorylation, indicating that the protein kinase catalytic activity is either intrinsic to the phytochrome molecule or associated with it by high-affinity interactions. Red irradiation (of coleoptiles or extracts) sufficient to approach photoconversion saturation reduced phosphorylation of immunoprecipitated phytochrome. Subsequent far-red irradiation reversed the red-light effect. Phytochrome phosphorylation was stimulated about 10-fold by a co-immunoprecipitated factor. The stimulatory factor was highest in immunoprecipitates when Mg2+ was present in immunoprecipitation reactions but remained in the supernatant in the absence of Mg2+. These observations provide strong support for the hypothesis that phytochrome-associated protein kinase modulates light responses in vivo. Since only phytochrome was found to be phosphorylated, the co-immunoprecipitated protein kinase may function to regulate receptor activity.     

Time Dependence of Phytochrome-mediated Carotenoid and Chlorophyll Synthesis in Sorghum bicolor L

In 5-day-old etiolated Sorghum seedlings, red light irradiationfor 1 s enhanced carotenoid and chlorophyll accumulation, and5 min of red light treatment saturated the photoresponse. Thedegree of red/far-red photoreversibility of carotenoid accumulationwas dependent on the age of the plant. No significant escapefrom far-red reversibility was observed up to 30 min after theonset of a saturating red light pulse in 5-day-old etiolatedseedlings. Thereafter, the escape was relatively fast and completedwithin 180 min. Sorghum bicolor L, carotenogenesis, phytochrome, time dependence, chlorophyll synthesis     

A role of G-proteins and calcium in light-regulated primary leaf formation in Sorghum bicolor

Primary leaf development of Sorghum bicolor is a phytochrome-mediated response. Primary leaves are not produced in Sorghum seedlings even after 10 d of germination if grown in darkness. However, 5 min irradiation with white light or red light given to 5 d etiolated seedlings resulted in the formation of etiolated leaves. This effect of red light was reversed by far-red light. When calcium (3-5 mM) was added exogenously, complete leaf formation was obtained in darkness; however, the kinetics of the response was slower than that seen with light irradiation. This effect was also obtained with potassium ions but magnesium ions had no effect. Light- and calcium-mediated leaf development could be arrested at the stage of leaf emergence or leaf expansion by the addition of inhibitors of G-proteins or by calcium channel blockers suggesting a role of G-proteins and calcium in phytochrome signal transduction during primary leaf development.Key words: Leaf formation, G-proteins, calcium, potassium, Sorghum bicolor.      

Regulation of swelling of etiolated-wheat-leaf protoplasts by phytochrome and gibberellic acid

The effect of light on the size of intact protoplasts isolated from the primary leaves of etiolated Triticum aestivum was studied. A 2-min red-light irradiation in the presence of 1 mM KCl was sufficient to cause a swelling of protoplasts compared with those maintained in darkness. The effect was photoreversible by far-red light over two light cycles, indicating the involvement of phytochrome. At 4°C, escape from reversibility occurred between 2 and 5 min after the exposure to red light. In exposure-response experiments, 20 s red light at 27 μmol m^-2s^-1 was sufficient to saturate the response. Exogenous gibberellic acid added in darkness in the presence of KCl also induced protoplast swelling. Gibberellins may act as an intermediate in the phytochrome-induced swelling of protoplasts.     

Phytochrome mediated induction of nitrate reductase activity in etiolated maize leaves

The effects of red and far-red light on the enhancement of in vitro nitrate reductase activity and on nitrate accumulation in etiolated excised maize leaves were examined. Illumination for 5 min with red light followed by a 4-h dark period caused a marked increase in nitrate reductase activity, whereas a 5-min illumination with far-red light had no effect on the enzyme activity. The effect of red light was completely reversed by a subsequent illumination with the same period of far-red light. Continuous far-red light also enhanced nitrate reductase activity. Both photoreversibility by red and far-red light and the operation of high intensity reaction under continuous far-red light indicated that the induction of nitrate reductase was mediated by phytochrome. Though nitrate accumulation was slightly enhanced by red and continuous far-red light treatments by 17% and 26% respectively, this is unlikely to account for the entire increase of nitrate reductase activity. The far-red light treatments given in water, to leaves preincubated in nitrate, enhanced nitrate reductase activity considerably over the dark control. The presence of a lag phase and inhibition of increase in enzyme activity under continuous far-red light-by tungstate and inhibitors of RNA synthesis and protein synthesis-rules out the possibility of activation of nitrate reductase and suggests de novo synthesis of the enzyme affected by phytochrome.     

Phytochrome-mediated light regulation of nitrate reductase expression in squash cotyledons

In etiolated squash (Cucurbita maxima L.) cotyledons, nitrate-inducible NADH:nitrate reductase activity and protein were increased in darkness by red light pulses with red/far-red photoreversibility. Continuous far-red light also led to increased levels of nitrate reductase activity and protein. Poly(A)+RNA, which hybridizes to squash nitrate reductase cDNA, was also increased by light treatments. Thus, we found that after nitrate triggering, nitrate reductase expression appears to be regulated by light via phytochrome.     

Phosphorylation of Avena phytochrome in vitro as a probe of light-induced conformational changes

A polycation-dependent protein kinase was found to be associated with purified phytochrome preparations from etiolated Avena seedlings. This kinase and three mammalian protein kinases, the catalytic subunit of cAMP-dependent protein kinase, cGMP-dependent protein kinase, and a Ca2+-activated phospholipid-dependent protein kinase, were used to probe light-induced conformational changes in 124-kilodalton Avena phytochrome in vitro. The red absorbing form of phytochrome (Pr) was found to be a substrate for all four protein kinases. Although the far-red absorbing form of phytochrome (Pfr) was as good a substrate as Pr with the cAMP-dependent protein kinase, the Pfr form was poorly phosphorylated by the other three protein kinases. Serine is the major amino acid residue phosphorylated on phytochrome regardless of the form of phytochrome used as substrate. Peptide mapping revealed that the sites of phosphorylation catalyzed by the cAMP-dependent protein kinase differ for Pr and Pfr forms of phytochrome. For the Pr form, the preferred site(s) of phosphorylation was near the amino terminus of the 124-kilodalton subunit. Upon photo-conversion to Pfr, this site can no longer be phosphorylated easily and a new phosphorylation site in the COOH-terminal nonchromophore domain of the molecule becomes accessible to the cAMP-dependent protein kinase. These studies of the phosphorylation of phytochrome provide a new means to study the effect of light absorption by phytochrome on the molecular conformation of the protein. The potential physiological implications of differential phosphorylation of Pr and Pfr await elucidation.     

Differences in Photoresponse and Phytochrome Spectrophotometry Between Etiolated and De-etiolated Pea Stem Tissue

Morphologically similar pea plants having a 4-fold difference in spectrophoto-metrically detectable phytochrome can be produced by pretreatment of etiolated plants with red light (R) or with red and far-red light combined (RF). A search for response differences which could be ascribed to differences in phytochrome content has resulted only in the establishment of differences due to de-etiolation. Segments of etiolated plants differ from those of plants de-etiolated by R and RF pretreatments in 2 ways. Segments from etiolated plants appear to respond rapidly to the far-red absorbing form of phytochrome (P_FR), while segments from de-etiolated plants do not respond rapidly to P_FR. This statement is based upon 2 observations: (i) the red light induced growth inhibition in segments from etiolated plants rapidly escapes reversibility by far-red light, while with segments from R or RF pretreated plants, the red light effect is fully reversed by subsequent far-red light for up to 2 hr; and (ii) segments from etiolated plants were inhibited to a greater degree than were segments from RF pretreated plants when various photostationary state levels of P_FR were maintained for 30 or 90 min and then removed by photoconversion to P_R. The in vivo nonphotochemical transformation curves of the phytochrome of etiolated and RF pretreated plants appear to differ in 2 related respects: (i) the amount of phytochrome destroyed in de-etiolated tissue is greater than that in etiolated tissue, perhaps as a result of the fact that (ii) the rate and extent of apparent reversion of P_FR to P_R in etiolated tissue is about twice that in de-etiolated tissue.     

Spinach Leaf Sucrose-Phosphate Synthase and Nitrate Reductase Are Phosphorylated/Inactivated by Multiple Protein Kinases in Vitro

The regulation of sucrose-phosphate synthase (SPS) and nitrate reductase (NR) activities from mature spinach (Spinacia oleracea L.) leaves share many similarities in vivo and in vitro. Both enzymes are light/dark modulated by processes that involve, at least in part, reversible protein phosphorylation. Experiments using desalted crude extracts show that the ATP-dependent inactivation of spinach SPS and NR is sensitive to inhibition by glucose-6-phosphate. Also, a synthetic peptide homolog of the spinach SPS phosphorylation site inhibits the ATP-dependent inactivation of both enzymes with a similar concentration dependence. We have addressed the possibility that SPS and NR are regulated by the same protein kinase by partially purifying the protein kinases involved. Three unique kinase activities can be separated by anion-exchange and size-exclusion chromatography. Each peak of activity has a different substrate specificity. By gel filtration, they have apparent molecular masses of approximately 45, 60, and 150 kD. Additionally, the activities of the two smaller kinases are dependent on micromolar concentrations of Ca2+, whereas the 150-kD kinase is not. Finally, the 150-kD kinase has a subunit molecular mass of about 65 kD as determined by renaturing the kinase activity in situ following sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Phytochrome and Calcium Regulated Protein Phosphorylation in Sorghum bicolor

Irradiation with red light of Sorghum bicolor seedlings stimulated in vitro phosphorylation of 55 kD and several other soluble polypeptides in a development-dependent manner. The red light stimulated phosphorylation of 55 kD polypeptide was more in 6-day-old etiolated plants as compared to 5-day-old plants. The in vitro phosphorylation of 55 kD polypeptide was enhanced further when calcium was added to the extracts obtained from red light irradiated tissues of 6-day-old seedlings. This effect was inhibited in the presence of calmodulin inhibitors. There was no significant stimulation in the phosphorylation of this polypeptide by calcium in 5-day-old and 7-day-old etiolated plants. Besides 55 kD, the phosphorylation of several other polypeptides was either stimulated or inhibited by light, calcium and calmodulin inhibitors suggesting involvement of both kinases and phosphatases in light-mediated phosphorylation.     

Light- and carbon-signaling pathways. Modeling circuits of interactions

Here, we report the systematic exploration and modeling of interactions between light and sugar signaling. The data set analyzed explores the interactions of sugar (sucrose) with distinct light qualities (white, blue, red, and far-red) used at different fluence rates (low or high) in etiolated seedlings and mature green plants. Boolean logic was used to model the effect of these carbon/light interactions on three target genes involved in nitrogen assimilation: asparagine synthetase (ASN1 and ASN2) and glutamine synthetase (GLN2). This analysis enabled us to assess the effects of carbon on light-induced genes (GLN2/ASN2) versus light-repressed genes (ASN1) in this pathway. New interactions between carbon and blue-light signaling were discovered, and further connections between red/far-red light and carbon were modeled. Overall, light was able to override carbon as a major regulator of ASN1 and GLN2 in etiolated seedlings. By contrast, carbon overrides light as the major regulator of GLN2 and ASN2 in light-grown plants. Specific examples include the following: Carbon attenuated the blue-light induction of GLN2 in etiolated seedlings and also attenuated the white-, blue-, and red-light induction of GLN2 and ASN2 in light-grown plants. By contrast, carbon potentiated far-red-light induction of GLN2 and ASN2 in light-grown plants. Depending on the fluence rate of far-red light, carbon either attenuated or potentiated light repression of ASN1 in light-grown plants. These studies indicate the interaction of carbon with blue, red, and far-red-light signaling and set the stage for further investigation into modeling this complex web of interacting pathways using systems biology approaches.     

Signaling kinetics of cyanobacterial phytochrome Cph1, a light regulated histidine kinase

Cyanobacterial phytochrome 1 (Cph1) is a red/far-red light regulated histidine kinase, which together with its response regulator (Rcp1) forms a two-component light signaling system in Synechocystis 6803. In the present study we followed the in vitro autophosphorylation of Cph1 and the subsequent phosphotransfer to Rcp1 in different ionic milieus and following different light treatments. Both processes were red/far-red reversible with activity manifested in the Pr ground state (in darkness or after far-red irradiation) and with strongest activities being exhibited in the presence of Mn(2+). In vivo and in vitro assembled holoproteins in the Pr state displayed at least 4-fold higher efficiencies (k(cat)/K(m)) for autophosphorylation and phosphotransfer than the apoprotein or the holoprotein at photoequilibrium in red light. The reduced activities observed following red light treatments were consistent with the Pfr state being enzymatically inactive. Thus, both the rate of kinase autophosphorylation and the rate of phosphotransfer regulate the phosphorylation state of the response regulator, consistent with the rotary switch model regulating accessibility of the histidine target.     

Phytochrome Regulation of Nitrite Reductase--a Chloroplast Enzyme--in Etiolated Maize Leaves

Nitrite reductase in the excised etiolated leaves of maize showedthe photoreversibility by red and far-red light. Five minutesof red light illumination lead to a 130% increase in the enzymeactivity which was reversed by far-red light. The kinetics ofnitrite reductase activity under continuous far-red light showeda lag phase of 1 hr. (Received January 17, 1981; Accepted February 20, 1981)