Effects of Cyclic AMP on the Activity of Soluble Protein Kinases in Lemna paucicostata

Three protein kinases which phosphorylate histone were isolatedfrom cellular extract of Lemna plants. They were separated byelution from DEAE-Sephacel column and referred to as PI, PITand PHI. The PI protein kinase activity was partially inhibitedby 10µM cyclic AMP, cyclic GMP or cyclic IMP, while thePII enzyme was activated in the presence of these cyclic nucleotides.The PIII enzyme was cAMPindependent, but slightly inhibitedby cyclic CMP and cyclic UMP. The molecular weights of thesethree protein kinases were 165,000, 85,000 and 145,000, respectively,as estimated from Sephacryl S-300 gel filtration. A single cyclicAMP-binding protein was detected in the PII enzyme fractionby using the photoaffinity cAMP-analogue, 8-N₃-cAMP. The proteinwhich specifically bound [³H]-8-N₃-cAMP had an apparent molecularweight of 48,000 as determined by SDS-polyacrylamide gel electrophoresis.The phosphorylation of cellular proteins in Lemna was examinedby SDS-polyacrylamide gel electrophoresis. Four phosphorylatedpolypeptides were detected, the phosphorylations of which werestimulated by cAMP. The molecular weights of these four polypeptideswere 59,000, 19,000, 16,000 and 14,000, respectively. (Received January 26, 1983; Accepted April 13, 1983)     

Freezing tolerance, protein composition, and abscisic acid localization and content of pea epicotyl, shoot, and root tissue 3

The freezing tolerance of many plants, such as pea (Pisum sativum),is increased by exposure to low temperature or abscisic acidtreatment, although the physiological basis of this phenomenonis poorly understood. The freezing tolerance of pea shoot tips,root tips, and epicotyl tissue was tested after cold acclimationat 2C, dehydration/rehydration, applications of 10^–4M abscisic acid (ABA), and deacclimation at 25C. Tests wereconducted using the cultivar ‘Alaska’, an ABA-deficientmutant ‘wil’, and its ‘wildtype’. Freezinginjury was determined graphically as the temperature that caused50% injury (T₅₀) from electrical conductivity. Endogenous ABAwas measured using an indirect enzyme-linked immunosorbant assay,and novel proteins were detected using 2-dimensional polyacrylamidegel electrophoresis. The maximum decrease in T₅₀ for root tissuewas 1C for all genotypes, regardless of treatment. For ‘Alaska’shoot tips and epicotyl tissue, exogenous ABA increased thefreezing tolerance by –1.5 to –4.0C, while coldtreatment increased the freezing tolerance by –7.5 to–14.8C. Cold treatment increased the freezing toleranceof shoot tips by –9 and –15C for ‘wil’and ‘wild-type’, respectively. Cold acclimationincreased endogenous ABA concentrations in ‘Alaska’shoot tips and epicotyls 3- to 4-fold. Immunogold labeling increasednoticeably in the nucleus and cytoplasm of the epicotyl after7 d at 2C and was greatest after 30 d at the time of maximumfreezing tolerance and soluble ABA concentration. Cold treatmentinduced the production of seven, three, and two proteins inshoot, epicotyl, and root tissue of ‘Alaska’, respectively.In ‘Alaska’ shoot tissue, five out of seven novelproteins accumulated in response to both ABA and cold treatment.However, only a 24 kDa protein was produced in ‘wil’and ‘wild-type’ shoot and epicotyl tissues aftercold treatment. Abscisic acid and cold treatment additivelyincreased the freezing tolerance of pea epicotyl and shoot tissuesthrough apparently independent mechanisms that both resultedin the production of a 24 kDa protein. Key words: Pisum sativum, cold acclimation, immuno-localization     

Developmental control of xylem hydraulic resistances and vulnerability to embolism in Fraxinus excelsior L.: impacts on water relations

The freezing tolerance of many plants, such as pea (Pisum sativum),is increased by exposure to low temperature or abscisic acidtreatment, although the physiological basis of this phenomenonis poorly understood. The freezing tolerance of pea shoot tips,root tips, and epicotyl tissue was tested after cold acclimationat 2C, dehydration/rehydration, applications of 10^–4M abscisic acid (ABA), and deacclimation at 25C. Tests wereconducted using the cultivar ‘Alaska’, an ABA-deficientmutant ‘wil’, and its ‘wildtype’. Freezinginjury was determined graphically as the temperature that caused50% injury (T₅₀) from electrical conductivity. Endogenous ABAwas measured using an indirect enzyme-linked immunosorbant assay,and novel proteins were detected using 2-dimensional polyacrylamidegel electrophoresis. The maximum decrease in T₅₀ for root tissuewas 1C for all genotypes, regardless of treatment. For ‘Alaska’shoot tips and epicotyl tissue, exogenous ABA increased thefreezing tolerance by –1.5 to –4.0C, while coldtreatment increased the freezing tolerance by –7.5 to–14.8C. Cold treatment increased the freezing toleranceof shoot tips by –9 and –15C for ‘wil’and ‘wild-type’, respectively. Cold acclimationincreased endogenous ABA concentrations in ‘Alaska’shoot tips and epicotyls 3- to 4-fold. Immunogold labeling increasednoticeably in the nucleus and cytoplasm of the epicotyl after7 d at 2C and was greatest after 30 d at the time of maximumfreezing tolerance and soluble ABA concentration. Cold treatmentinduced the production of seven, three, and two proteins inshoot, epicotyl, and root tissue of ‘Alaska’, respectively.In ‘Alaska’ shoot tissue, five out of seven novelproteins accumulated in response to both ABA and cold treatment.However, only a 24 kDa protein was produced in ‘wil’and ‘wild-type’ shoot and epicotyl tissues aftercold treatment. Abscisic acid and cold treatment additivelyincreased the freezing tolerance of pea epicotyl and shoot tissuesthrough apparently independent mechanisms that both resultedin the production of a 24 kDa protein. Key words: Pisum sativum, cold acclimation, immuno-localization     

Characterization and Intracellular Distribution of Pea Phytochrome I Polypeptides Expressed in E. coli

The pea phytochrome I (PI) cDNA clone, pPP1001, was expressedin E. coli. The plasmid pPP1001 contains pea PI cDNA which coversthe entire coding region with the Shine-Dalgarno consensus sequencejoined upstream of the cDNA in an expression vector pNUT6. ThepPP1001 transformants formed typical inclusion bodies when culturedat 32?C. However, when cultured at 37?C or in the presence ofisopropyl-ß-D-thiogalactopyranoside (IPTG) at 32?C,the bacteria lysed before inclusion body formation. Immuno-stainingwith anti-PI monoclonal antibody, mAP5, of transformants fixedby cold methanol showed that stainable materials were distributedin whole cytoplasmic region. When the inclusion bodies wereobserved clearly, the regions corresponding to the inclusionbodies became difficult to stain. Western blot analysis, however,showed that a ca. 100 kDa PI polypeptide was detected in thefraction from inclusion bodies and a ca. 90 kDa PI polypeptidefrom the soluble fraction. The amino acid sequence analysisof purified 100 kDa PI sample indicated that its amino terminusis blocked. However, minor signals in one experiment yieldeda sequence corresponding to the expected amino terminus of peaPI except for the initiation methionine. One of the anti-peaPI monoclonal antibodies, mAP9, that recognizes the near N-terminusof pea phytochrome was reactive to the 100 kDa polypeptide. (Received June 22, 1990; Accepted November 18, 1990)     

Some Characteristics of Protein Kinases in Lemna paucicostata

The three protein kinases of Lemna paucicostata that are separableby DEAE-Sephacel chromatography have been designated PI, PIIand PIII [Kato et al. (1983) Plant & Cell Physiol. 24: 841].The optimum pH for the PI and PII enzymes was 7.5 and for thePHI enzyme 7.0. The activities of these enzymes were stimulatedby divalent cations, the maximum stimulation being producedby 5 nw Mg^{2 $} for PI, by 3 mM Co^{2 $} for PII and by 1 mM Mn^2$ for PIII. The cytokinins; benzyladenine, kinetin and zeatin,inhibited the activity of the PIII enzyme. The molecular weightsof the PI and PII enzymes did not change after incubation withcAMP even though their activities were regulated by this compound. (Received October 17, 1983; )     

Membrane-bound geranylgeranyl diphosphate phosphatases: purification and characterization from Croton stellatopilosus leaves

Geranylgeranyl diphosphate phosphatase is an enzyme catalyzing the dephosphorylation of geranylgeranyl diphosphate (GGPP) to form geranylgeraniol (GGOH). The enzyme activity of GGPP phosphatase was detected in leaves of Croton stellatopilosus, a Thai medicinal plant containing plaunotol, a commercial anti-peptic acyclic diterpenoid. Enzymological studies of GGPP phosphatase in C. stellatopilosis leaves revealed that the enzyme is a membrane-bound protein that could be removed from 20,000g pellet by 0.1% Triton X-100 without significant loss of enzyme activity. The solubilized enzyme preparation was separated into two activity peaks, PI and PII, by BioGel A gel filtration chromatography. PI and PII were both partially purified and characterized. PI appeared to be a tetrameric enzyme with its native molecular mass of 232kDa and subunit size of 58kDa, whereas PII was a monomeric enzyme with a molecular mass of 30-34kDa. Both phosphatases utilized GGPP as the preferred substrate over farnesyl and geranyl diphosphates. The apparent K(m) values for GGPP of PI and PII appeared to be 0.2 and 0.1mM, respectively. Both activities were Mg(2+) independent and exhibited slightly acidic pH optima, 6.0-6.5 for PI and 6.5-7.0 for PII. The catalytic activities of PII was strongly inhibited by 1.0mM of Zn(2+), Mn(2+) and Co(2+), whereas that of PI was not affected. Both enzyme preparations were very stable upon storage at -20 degrees C for 45 days without significant loss of phosphatase activity. The presence of GGPP phosphatase enzymes in C. stellatopilosus is consistent with its putative involvement in the biosynthetic pathway of plaunotol although whether PI or PII is the actual enzyme involved in the pathway remains to be clarified.     

Molecular Structure of a High-Potential Form of Thylakoid Cytochrome b-559 as Determined by Radiation Inactivation

Cytochrome b-559 in photosystem II can be characteristicallyconverted from a high- to a low-potential form. Taking thisresponse of Cyt b-559 as evidence for the denaturation of proteinmolecules, the sizes of the structures that stabilize the high-potentialform of Cyt b-559 in PS II membranes and thylakoids from spinachwere determined by radiation inactivation. When a target of26 kDa was inactivated in PS II membranes, Cyt b-559 was convertedto the low-potential form. The size was consistent with a molecularweight of Cyt b-559 in a proposed tetrameric structure thatconsists of two sets of 9.2-kDa and 4.3-kDa subunits [Widgeret al. (1985) FEBS Lett. 191: 186–190]. In contrast tothe functional size of 26 kDa in the PS II membranes, the functionalsize was 116 kDa in thylakoid membranes. The results suggestthe presence of an extra 90-kDa electron carrier between a redoxtitrator outside the membranes and the Cyt b-559, which maynot expose its active site to the surface of the thylakoids. (Received March 9, 1989; Accepted June 23, 1989)     

Growth and Photosynthesis of Mutant Pea Seedlings

The recessive of gene, producing tendrils in place of leaves,and the recessive st gene, reducing stipule size, produce phenotypesof pea that are termed leafless (afafstst) and semi-leafless(afafStSt). Photosynthesis and growth of these two types werecompared with the conventional phenotype (AfAfStSt) during thefirst 9 days of post-emergent growth. The conventional seedlingshowed faster net photosynthesis per unit dry weight than theleafless phenotype, whilst the semi-leafless seedlings wereintermediate. Differences in dark respiration were small butleafless seedlings had significantly higher rates soon afteremergence. Where the three phenotypes used were isogenic, except for ofand st, the rates of shoot growth were in the same ranking orderas net CO₂ uptake. With three other genotypes, representingthe three phenotypes, more similar shoot growth was found betweenthe conventional and semi-leafless phenotype, possibly becauseof compensating differences in embryonic axis size. The ratesof growth of roots and the rates of dry weight loss from thecotyledons showed no consistent differences between phenotypes. The results are discussed in relation to the potential for thesemi-leafless phenotype as an alternative to the conventionalphenotype for the dried pea crop. Pea seedling, Pisum sativum, leafless pea, photosynthesis, seedling growth     

Effect of germination temperature on characteristics of phytase production from barley

The effects of germination temperature on the growth of barley seedlings for phytase production were studied at 15, 20 and 25 degrees C for 6-10 days. The growth rate of the barley seedlings was increased as the germination temperature was increased. The initial rate of total protein production was closely coupled to that of the barley growth, and the rate of total protein production tended to increase as the germination temperature was increased. SDS-PAGE analysis of total protein from the barley seedlings showed time-dependent appearance and disappearance of protein bands. Although no significant phytase activity was detected at zero time of germination, a significant increase in phytase activity up to 7.9-fold occurred during the first several days of germination then decreased. Phosphate production (viz. phytate degradation) in the barley seedlings occurred rapidly at the beginning of germination. However, the rate of production continued to decrease with further germination. A time lag of about 1-2 days between the rate of total protein production and that of phytase production was observed. Unlike the extent of total protein production, that of phytase production was similar irrespective of germination temperature. Partial purification of a crude enzyme extract by hydrophobic interaction chromatography resulted in two phytase fractions (PI and PII). Zymogram analysis demonstrated that PI had two bands with molecular masses of about 66 and 123 kDa while PII had one band corresponding to a molecular mass of about 96 kDa. The optimal temperature for PI was found to be 55 degrees C, while it was 50 degrees C for PII. The enzyme fraction PI had a pH optimum at 6.0, whereas the optimum pH for PII was found to be 5.0. Addition of 0.1% (v/v) Tween 80 was found to increase enzyme activity significantly (i.e., 167% for PI and 137% for PII). Phytate in cereals including barley, rice, corn and soybean degraded effectively by the treatment of the barley phytases.     

Changes in levels of Proteases and Their Inhibitors during Development of the Seeds of Job's Tears (Coix lacryma-jobi L. var. Ma-yuen Stapf) and Their Localization and Interactions

Changes in levels and localization of proteases and a trypsininhibitor (JBTI) in the developing seeds of Job's tears (Coixlacryma-jobi L. var. Ma-yuen Stapf) were followed, and theirinteractions were examined. The JBTI was induced from the middlestage of development (12 DAF, i.e., 12 days after flowering)and increased until the late stage of development (24 DAF),and was localized in the germ. Two groups of proteases (A, thosewith molecular weights of 55–70 kDa; and B, those withmolecular weights greater than 94 kDa) were detected by activestaining of substrate-containing SDS-polyacrylamide gels. Thegroup of larger proteases seems to consist of three members(B₁, B₂₎ B₃, with increasing molecular weights). Band A wasobserved only in the early stage of development (until DAF 9),band B₂ persisted during all stages, while bands B, and B₃ werepresent only during early and late stages, respectively. Thegroup A proteases and one of the group B proteases (probablyB₁) were inhibited by diisopropyl-fluorophosphate (DFP), bytrypsin inhibitors from soybean and rice, and by JBTI. The proteasesthat were present in the seeds of Job's tears at a late stageseemed to be localized in the germ. (Received September 9, 1988; Accepted April 19, 1989)     

Influence of Bud Position and Plant Ontogeny on the Morphology of Branch Shoots in Pea (Pisum sativum L. cv. Alaska)

The morphology of axillary shoots of pea plants (Pisum sativumL. cv. Alaska) was analysed as a function of the position ofthe bud on the plant axis and the stage of plant developmentwhen the buds began to grow. Buds from the three most basalnodes were stimulated to develop by decapitating the main shootwhen buds were still growing (4 d plants), shortly after budsbecame dormant (7 d plants) or after the initiation of floweringon the main shoot (post-flowering plants, about 21 d after sowing).Branch shoots were scored for node of floral initiation (NFI),shoot length, and node of multiple leaflets (NML), a measureof leaf complexity. Shoots that developed spontaneously fromupper nodes (nodes 5-9) on intact post-flowering plants werescored for NFI. NFI for basal buds on 4 and 7 d plants variedas a function of nodal position and ranged from 5 to 6·7nodes. NFI on these plants was not influenced by bud size orwhether a bud was growing or dormant when the plant was decapitated.NFI for shoots derived from basal buds on decapitated post-floweringplants and upper nodes on intact post-flowering plants was about4. Reduced NFI on post-flowering plants may be due to depletionof a cotyledon-derived floral inhibitor. Basal axillary shootson 4 d plants were about 20% longer than those on 7 d plantsand about five times longer than those on post-flowering plants.These differences may be due to depletion of gibberellic acidsfrom the cotyledons. NFI and NML for the main shoot and forbasal axillary shoots were similar under some experimental conditionsbut different under other conditions, so it is likely that eachdevelopmental transition is regulated independently.Copyright1995, 1999 Academic Press Apical dominance, bud development, garden pea, initiation of flowering, Pisum sativum L., shoot morphology     

Sunflower (Helianthus annuus) Leaves Contain Compounds that Reduce Nuclear Propidium Iodide Fluorescence

Sunflower leaves have unidentified compounds that interferewith propidium iodide (PI) intercalation and/or fluorescence.Independently prepared pea leaf nuclei show greater PI fluorescencethan nuclei from pea leaves simultaneously processed (co-chopped)with sunflower leaves. Differences in fluorescence persist aftermixing the PI-stained pea and the co-chopped pea/sunflower samples,i.e. PI staining protects the nuclei from the effects of theinhibitor. The current results are significant to practicalflow cytometric determination of plant nuclear DNA content.They show: (1) simultaneous processing of nuclear samples fromthe target and the standard species is necessary to obtain reliableDNA estimates; (2) a test for the presence of inhibitors shouldbe conducted; and (3) when inhibitors are present caution shouldbe taken in interpreting differences in estimated DNA content.The previously reported environmentally-induced variation inDNA content in sunflower populations is most simply explainedby variation in the amount of environmentally-induced inhibitorthat interferes with intercalation and/or fluorescence of PI.Intraspecific variation of DNA content for Helianthus annuusneeds to be re-evaluated using best practice techniques comparingphysiologically uniform tissues that are free of inhibitors.The best estimate for 2C DNA content of H. annuus used in thisstudy is 7.3 pg. Copyright 2000 Annals of Botany Company Helianthus annuus, DNA content, flow cytometry, propidium iodide, endogenous inhibitors     

Properties of a protein-linked glucuronoxylan formed in the plant Golgi apparatus

Radiolabelled glucuronoxylan was formed by incubation of a Golgimembrane fraction from pea seedlings with UDP-(¹⁴C)GlcA andUDP-Xyl. Chelator-soluble glucuronoxylan was analysed by gelfiltration on Sepharose CL-6B and CL-2B, and was resolved intoa very high molecular weight peak (at least 7000 kDa) and apartially-excluded peak (50-75 kDa). Treatment of the latterpeak with proteinase K caused a change in elution behaviourcorresponding to the removal of a protein of 36-45 kDa. Theassociation between poly-saccharide and protein was not disruptedby high temperature or by high salt concentration, and was probablycovalent. When radioactive glucuronoxylan was formed using endoplasmicreticulum rather than Golgi membranes, protease treatment causeda decrease in molecular weight of approximately 20 kDa. Thechelator-insoluble glucuronoxylan produced by pea membraneswas also partly susceptible to protease treatment, since almosthalf of it was solubilized by incubation with proteinase K. Key words: Glucuronoxylan, Golgi apparatus, endoplasmic reticulum, Pisum     

Morphology and Cytology of Pea Embryos During Histogenesis

Cytological examination showed that day 3 pea embryo cells wereundifferentiated in terms of morphological or gross cytologicalappearance. Histogenesis had commenced by day 4 and was accompaniedby cytological differentiation with a gradient in vacuolationapparent along the root/shoot axis. Day 3 embryonic cells werecytologically different from meristematic (day 4 and 5) cellsof the shoot apex. Cells of the embryo base appeared to havean intimate association with the middle suspensor cells. Pisum sativum L. cv. ‘Alaska’, pea, morphology, cytology, histogenesis, development     

Purification and Molecular Properties of the Thylakoid-Bound Ascorbate Peroxidase in Spinach Chloroplasts

The hydrogen peroxide that is photoproduced in thylakoids isscavenged by the thylakoid-bound ascorbate peroxidase (tAPX)[Miyake and Asada (1992) Plant Cell Physiol. 33: 541]. tAPXwas purified from spinach thylakoids to homogeneity as judgedby SDS-polyacrylamide gel electrophoresis, and its molecularproperties were studied. Spinach tAPX was a monomer with a molecularweight of 40,000, which is about 10,000 higher than that ofthe stromal ascorbate peroxidase (sAPX) from spinach chloroplasts.tAPX cross-reacted with the antibody raised against sAPX fromtea leaves, as determined by Western blotting, which also providedevidence for the higher molecular weight of tAPX from spinachthylakoids than that of tea sAPX. The amino acid sequence ofthe amino-terminal region of tAPX showed a low degree of homologyto those of cytosolic APXs from spinach, pea and Arabidopsisthaliana, but a high degree of homology to that of stromal APXfrom tea. Thus, the amino-terminal region of tAPX seems notto be a domain required for binding of the enzyme to the thylakoidmembranes. tAPX contained protoheme IX, as identified by itspyridine hemochromogen, and gave a Soret peak at 403 nm and433 nm with an a band at 555 nm in its oxidized and reducedforms, respectively. Resembling sAPX but differing from cytosolicAPX, tAPX showed high specificity for ascorbate as the electrondonor. tAPX was inhibited by cyanide, thiol-modifying reagents,thiols and several suicide inhibitors, such as hydroxyurea andp-aminophenol. ¹Present address: Beijing Vegetable Research Centre, PO Box2443, Beijing, China.     

Dependence of intracellular proteolytic enzymes in growing and sporulating cells ofBacillus megaterium on Ca2+ concentration

Intracellular proteolytic activities of growing and sporulating cells ofBacillus megaterium were compared after their separation by size-exclusion high-performance liquid chromatography. In both types of cells four soluble proteolytic activities, PI, PII, PIII and E, were found withM of more than 300, about 62, 36, and 20 kDa, respectively. PI was probably a complex of enzyme(s) or an enzyme associated with some structure. It was activated by Ca²⁺ but not by Mg²⁺ and stabilized by both divalent cations. PII, a major proteinase in both types of cells, was a serine enzyme with the same Ca²⁺ and Mg²⁺ dependence as PI. PIII was a divalent-cation-independent enzyme with a very low activity. E corresponded to the extracellular metalloenzyme produced by this organism. Possible regulation of proteolytic activity and protein degradationin vivo by Ca²⁺ during sporulation is discussed.     

Profiiles of Proteins in Guard-cell and Mesophyll Protoplasts from Vicia faba L. Fractionated by Sodium Dodecylsulfate-Polyacrylamide Gel Electrophoresis

Polypeptides of low molecular weight unique to protoplasts ofVicia guard cells were found by sodium dodecylsulfate-polyacrylamidegel electrophoresis. The polypeptides were 16 kDa (2 species),15 kDa and 12.5 kDa, and were concentrated in membrane-richfractions. The large subunit and holoenzyme of ribulose bisphosphatecarboxylase were identified in guard-cell protoplasts by immunoblotting. ³Present address: Biological Laboratory, College of GeneralEducation, Kyushu University, Ropponmatsu, Fukuoka, 810 Japan. (Received January 25, 1989; Accepted April 24, 1989)     

TheAfGene Regulates Timing and Direction of Major Developmental Events during Leaf Morphogenesis in Garden Pea (Pisum sativum)

The wildtype leaf of the garden pea possesses proximal pairsof leaflets and distal pairs of tendrils in the blade region.Theafila (af) mutation causes leaflets to be replaced by compound(branched) tendrils. We characterized the morphological variationin leaf form along the plant axis and leaf development in earlyand late postembryonic leaves onafilaplants to infer the roleof theAfgene. Leaf forms are more diverse early in shoot ontogenyonafilaplants.Afinfluences pinna length and pinna branchingin addition to pinna type. Pinna initiation in the proximalregion ofafilaleaf primordia is basipetal and delayed comparedto wildtype plants. In addition, pinna development in the proximalregion ofafilaleaves occurs for a longer period of time thanon wildtype leaf primordia. Therefore,Afregulates the timingand direction of leaf developmental processes in the proximalregion of the leaf, but has little effect on the distal region.These data support the heterochronic model of pea leaf morphogenesisproposed by Luet al. (International Journal of Plant Science157:311–355, 1996).Copyright 1999 Annals of Botany Company. afila,Fabaceae, garden pea, heterochrony, leaf morphogenesis,Pisum sativum.