Specific induction of secondary product formation in transgenic plant cell cultures using an inducible promoter

This paper describes the artificial induction of secondary metabolite production in transgenic plant cell cultures using a recombinant, inducible plant promoter. The bacterial gene ubiC from Escherichia coli encodes the enzyme chorismate pyruvate lyase (CPL) which catalyses the conversion of chorismate to 4-hydroxybenzoate (4HB). This gene was fused to the tetracycline-inducible plant promoter Triple-Op. After transformation into Nicotiana tabacum W38 TET, transgenic cell cultures were established. Addition of chlorotetracycline to the medium led to specific induction of CPL activity. The optimal chlorotetracycline concentration was approximately 2 mg/l medium. Three to 5 h after induction, the ubiC mRNA concentration reached a maximum, while highest specific CPL activity was detected after 8 days. The artificial secondary metabolite 4HB was converted to glucosides, and their accumulation reached maximum levels after 5 weeks of subculture. The induction was reversible. Received: 31 May 1997 / Revision received: 22 August 1997 / Accepted: 30 September 1997     

Mechanisms of the acido- and thermo-phily of Cyanidium caldarium Geitler II. Physiological role of the cell wall

1) A partially disintegrated cell preparation of Cyanidium caldarium(i.e. the 100G fraction; cells from which the outer parts ofthe cell wall had been removed) was obtained by differentialcentrifugation of a cell suspension treated with a French press.2) The 100G fraction cells had completely lost the outer partsof their cell walls, but retained their subcellular structureunchanged and had Hill activity that was equally as high asthat of the intact cells. 3) The Hill activity of the 100G fractionshowed an optimum at pH 7.0 and at 35°C. This activity waslost under acid and high temperature conditions (e.g. pH 3,50°C) under which intact cells showed high activity. 4)The Hill activity of the 100G fraction was lost by heat treatment(55°C, 10min), acid-treatment (pH 3.0, 10 min) or pre-illumination(3xl0⁵lux, 30 min) though intact cells were not inactivatedby these treatments. However, no remarkable difference in sensitivitytowards inhibitors was found between the 100G fraction and intactcells. 5) We thus concluded that the cell wall plays an importantrole in the acido- and thermo-phily of Cyanidium cells. (Received August 19, 1974; )     

Effect of cycloheximide and cordycepin on auxin-induced elongation and {beta}-glucan degradation of noncellulosic polysaccharides of Avena coleoptile cell wall

The effect of cycloheximide (10^–5 M) and cordycepin (10^–4M) used as protein and RNA synthesis inhibitors, respectively,on auxin action in noncellulosic ß-glucan degradationof Avena coleoptile cell wall was investigated. Both depressedauxin-induced ßglucan degradation of the cell wallas well as auxin-induced elongation and cell wall loosening,suggesting that the process of ß-glucan degradationof the cell wall is closely associated with cell wall looseningand that auxin enhances the activity of an enzyme for ß-glucandegradation through de novo synthesis of RNA and protein butnot through activation of the enzyme in situ. Kinetic studywith the inhibitors showed that RNA metabolism involved in ß-glucandegradation was stimulated by auxin treatment of only 15 minwhile a longer lag phase (about 1 hr) existed for the synthesisof the enzyme. (Received December 16, 1978; )     

Induction of Phenylalanine Ammonia-Lyase Activation and Isoflavone Glucoside Accumulation in Suspension-Cultured Cells of Red Bean, Vigna angularis, by Phytoalexin Elicitors, Vanadate, and Elevation of Medium pH

Treatment of suspension-cultured cells of red bean, Vigna angularis,with nigeran resulted in an accumulation of isoflavone glucosides,such as daidzein 7-O-ß-D-glucoside, daidzein 7,4'-di-O-ß-D-glucoside,and 2'-hydroxydaidzein 7,4'-di-O-ß-D-glucoside, whichwas accompanied by a transient increase in the activity of phenylalanineanimonia-lyase (PAL). Similar effects were also seen with otherphytoalexin elicitors, such as RNase A and cell wall componentsof Phytophthora megasperma var. sojae. Interestingly, the accumulation of isoflavone glucosides andthe transient increase in PAL activity were induced also byvanadate, a specific inhibitor of plasma membrane adenosinetriphosphatase. K₃PO₄ showed similar effects, but this was ascribedto the elevation of medium pH caused by adding this basic salt.In fact, merely raising the pH of the medium was found to besufficient for the induction of PAL activity. Experiments usinginhibitors showed that the induction depends on RNA and proteinsyntheses. The results are discussed in relation to the possiblemechanism of action of phytoalexin elicitors. ¹ Present address: Laboratory of Biochemistry, Faculty of Agriculture,Nagoya University, Furocho, Chikusa, Nagoya 464, Japan.     

{beta}-1,4-Glucan occurring in homogenate of Phaseolus aureus seedlings. Possible nascent stage of cellulose biosynthesis in vivo

A small amount of cytoplasmic ß-1,4-glucan, whichmight be involved in the synthesis of cellulose in the cellwall, was found in the homogenate prepared from the hypocotylsof seedlings of Phaseolus aureus. Upon hydrolysis by cellulaseof the 20,000?g pellet from the cytoplasmic fraction of segmentsincubated in a [¹⁴C]-glucose solution, [¹⁴C]-cellobiose wasproduced, with specific radioactivities 3 to 10 times greaterthan those of the cellobiose from cellulose in the cell wallat various incubation periods. The incoporation of radioactivityfrom [¹⁴C]-glucose into this cytoplasmic ß-1,4-glucanwas therefore faster than that into cellulose constituting thecell wall. Hence, it seemed that the former ß-1,4-glucancould be turned over. To examine whether the- cytoplasmic ß-1,4-glucanis carried by some subcellular components, cytoplasmic ß-1,4-glucanin the cell was fractionated by differential centrifugation,two enzyme activities being measured as the markers of subcellularcomponents. The distribution of ß-1,4-glucan was similarto that of UDPG-glucosyltransferase activity but not to thatof IDP-ase activity. The result suggests that the cytoplasmicß-1,4-glucan has some relation to plasma membranes. Coumarin, known as a specific inhibitor for the biosynthesisof cellulose in plant cells, was shown to inhibit the incorporationof radiocarbon from [¹⁴C]-glucose into cytoplasmic ß-1,4-glucanto the same extent as that into cellulose in the cell wall ofthe hypocotyls. ¹ Present address: Department of Biological Science, TohokuUniversity, Kawauchi, Sendai 980, Japan. (Received May 31, 1976; )     

Changes in hemicellulose-degrading enzymes during development and ripening of Japanese pear fruit

Seasonal changes in some hemicellulose-degrading enzymes inJapanese pear fruit were studied in connection with fruit development,softening and over-ripening. These enzyme activities per fruitfresh weight were very high during the cell division and preenlargementstages, and greatly decreased in the enlargement stage. Thereafter,they again exhibited clear increase with ripening. These enzymeactivities per cell (DNA content basis), however, were roughlyconstant throughout the cell division, pre-enlargement and enlargementstages. These cell wall degrading enzymes were divided intothe following three groups by their alteration patterns withripening, i.e. the first group including polygalacturonase,exocellulase and mannanase which seems to be associated withfruit softening, the second one including arabanase, ß-glucosidaseand endocellulase and the third one including xylanase, ß-xylosidaseand ß-galactosidase, both of which seem to functionin cellular breakdown with over-ripening. ¹ This paper is contribution A-87, Fruit Tree Research Station. (Received August 4, 1978; )     

Biosynthesis of Xyloglucan in Suspension-cultured Soybean Cells. Evidence that the Enzyme System of Xyloglucan Synthesis does not Contain {beta}-1,4-Glucan 4-{beta}-D-Glucosyltransferase Activity (EC 2.4.1.12)

Xyloglucan 4-ß-D-glucosyltransferase, an enzyme responsiblefor the formation of the xyloglucan backbone, in a particulatepreparation of soybean cells has been compared with ß-1,4-glucan4-ß-D-glucosyltransferase of the same origin. Thefollowing observations indicate that the enzyme system of xyloglucansynthesis does not contain ß-1,4-glucan 4-ß-D-glucosyltransferaseactivity, although both enzymes transfer the glucosyl residuefrom UDP-glucose to form the ß-1,4-glucosidic linkage:1. The incorporation of [¹⁴C]glucose into xyloglucan dependedon the presence of UDP-xylose in the incubation mixture. 2.No measurable amount of radioactivity was incorporated fromUDP-[¹⁴C]xylose into the cello-oligosaccharides, although theincorporation of [¹⁴C]xylose into xyloglucan depended on thepresence of UDP-glucose in the incubation mixture (Hayashi andMatsuda 1981b). 3. The activity of xyloglucan 4-ß-D-glucosyltransferasewas stimulated more strongly by Mn²⁺ than by Mg²⁺, whereas Mg²⁺was the most active stimulator for the activity of ß-1,4-glucan4-ß-D-glucosyltransferase. 4. An addition of GDP-glucose(100 µM) to the incubation mixture inhibited the activityof xyloglucan 4-ß-D-glucosyltransferase by 17%, whereasthe activity of ß-1,4-glucan 4-ß-D-glucosyltransferasewas inhibited 56% under the same conditions. 5. Irpex exo-cellulasedid not hydrolyze the xyloglucan synthesized in vitro. 6. Theß-1,4-glucan synthesized in vitro was not a branchedxyloglucan because it gave no 2,3-di-O-methyl glucose derivativeon methylation analysis. 7. Pulse-chase experiments indicatedthat the ß-1,4-glucan was not transformed into thexyloglucan. The subcellular distribution of the xyloglucan synthase, however,was similar to that of the ß-1,4-glucan synthase (Golgi-located1,4-ß-D-glucan 4-ß-D-glucosyltransferase).Thus, it appears that the latter enzyme is located at a siteclose to xyloglucan synthase and is set aside for the assemblyof these polysaccharides into the plant cell surface. (Received May 21, 1981; Accepted October 13, 1981)     

Glycosidases in pear pollen tube development

During the in vitro germination of pear pollen, several hydrolaseswere released into the medium. They were apparently eluted fromthe pollen grain, since the activity was the same when germinationwas inhibited. These enzymes, once released, had no role intube growth, since resuspension of pollen in fresh medium after1.5 hr of incubation did not result in a change of the subsequenttube growth. Homogenates of the pollen suspension at differentstages of development showed no significant changes in phosphatase,ß-glucosidase, or ß-galactosidase activity.However, patent ß-glucosidase activity measured directlyin suspensions of intact pollen did increase after germinationin proportion to tube wall development. Nojirimycin, a specificinhibitor of glucosidases, reduced this ß-glucosidaseactivity by 75% at 10^–5M and significantly reduced growthrate at 10^–4 M. (Received December 19, 1978; )     

Human melanoma and Chinese hamster ovary cells galactosylate n-alkyl-{beta}-glucosides using UDP gal:GlcNAc {beta}1,4 galactosyltransferase

We previously showed that human melanoma, CHO and other cellscan convert ß-xylosides into structural analogs ofganglioside G_M3. We have investigated several potential acceptorsincluding a series of n-alkyl-ß-D-glucosides (n =6–9). All were labeled with ³H-galactose when incubatedwith human melanoma cells. Octyl-ß-D-glucoside (GlcßOctyl)was the best acceptor, whereas neither octyl--D-glucoside norN-octanoyl-methylglucamine (MEGA 8) were labeled. Analysis ofthe products by a combination of chromatographic methods andspecific enzyme digestions showed that the acceptors first receiveda single Galß1,4 residue followed by an 2,3 linkedsialic acid. Synthesis of these products did not affect cellviability, adherence, protein biosynthesis, or incorporationof radio-labeled precursors into glycoprotein, glycolipid orproteoglycans. To determine which ß1,4 galactosyltransferase synthesized Galß1,4GlcßOctyl,we analyzed similar incubations using CHO cells and a mutantCHO line (CHO 761) which lacks GAG-core specific ß1,4galactosyltransferase. The mutant cells showed the same levelof incorporation as the control, eliminating this enzyme asa candidate. Thermal inactivation kinetics using melanoma cellmicrosomes and rat liver Golgi to galactosylate GlcßOctylshowed the same half-life as UDP-Gal:GlcNAc ß1,4 galactosyltransferase,whereas LacCer synthase was inactivated at a much faster rate.We show that GlcßOctyl is a substrate for purifiedbovine milk UDP-Gal:GlcNAc ß1,4 galactosyltransferaseFurthermore, the galactosylation of GlcßOctyl by CHOcell microsomes can be competitively inhibited by GlcNAc orGlcNAcßMU . These results indicate that UDP-Gal:GlcNAcß1,4 galactosyltransferase is the enzyme used forthe synthesis of the alkyl lactosides when cells or rat liverGolgi are incubated with alkyl ß glucosides. alkylglucosides galactosyltransferase glycolipid artificial acceptors     

Studies on the Growth and Respiration of Roots: I. THE EFFECTS OF STIMULATORY AND INHIBITORY CONCENTRATIONS OF {beta}-INDOLYLACETIC ACID ON ROOT SECTIONS OF PISUM SATIVUM

Simultaneous observations on extension growth and respirationrate (oxygen consumption) of 2-mm. sections excised from theextension zone of roots of pea (Pisum sativum) growing in distilledwater and 0·5 per cent. sucrose have yielded resultsclosely similar to those of Brown and Sutcliffe (1950). Respirationrate is not obviously correlated with growth rate either inwater or in sucrose, but it is strongly correlated with sectionlength. Respiration rate per unit section length (¬per unitfresh weight) shows a marked downward drift during extensionand is affected little by growth conditions. Tentative suggestionsare advanced to account for the small differences between driftsin o·5 per cent. sucrose and those in distilled water. Medium agitation produces an immediate and sustained stimulationof growth but no stimulation of oxygen uptake until the latergrowth stages. Thus respiration per unit section length is unaffectedby agitation at any stage. A typical growth response to ß-indolylacetic acid(IAA) was obtained, with a maximum stimulation (of about 35per cent.) at 1 part in 10¹¹ and inhibitions increasing progressivelywith concentration beyond the threshold of about i part in 10⁹.Both percentage stimulation and percentage inhibition of growthwere independent of the presence of sucrose. Respiratory responses to ß-indolylacetic acid werecomplex. In water no immediate response could be detected witheither a growth-stimulatory (10^–11) or a growth-inhibitory(10^–-8) concentration, while in 0·5 per cent. sucrosethe inhibitory concentration prevented the small immediate respiratoryrise due to the sucrose, probably by impeding sugar entry. Duringthe subsequent period of rapid growth (up to 36 hours) the smallrespiratory responses observed closely followed the small growthresponses to both concentrations of IAA, suggesting that theformer are the direct result of the differences in section lengthinduced by the auxin. When growth ceases (at 48 hours) sectionswhich have grown considerably in sucrose show respiratory ratesstill closely correlated with section length, whereas in waterboth concentrations of auxin induce marked depressions in respirationrate. It is concluded that ß-indolylacetic acid in bothgrowth-stimulatory and growth- inhibitory concentrations hasno direct effect on the activity of the respiratory enzyme systemof growing root cells. The small respiratory responses are bestexplained as resulting from differential changes in sectionsize and correlated changes in the enzyme complements of thegrowing cell.     

Trichodermin: Effects on plants

Trichodermin, 4ß-acetoxy-12,13-epoxy-⁹ -trichothecene,a fungal metabolite from Trichoderma viride, is a potent inhibitorof plant growth and produces other phytotoxic effects. It inhibitswheat coleoptile growth, is phytotoxic to tobacco at high concentrationsand inhibits growth at lower concentrations. Bean and corn plantsare also affected by the metabolite. (Received June 22, 1977; )     

Secondary metabolites in transgenic tobacco and potato: high accumulation of 4-hydroxybenzoic acid glucosides results from high expression of the bacterial gene ubiC

The bacterial gene ubiC encodes chorismate pyruvate-lyase (CPL), which converts chorismate to 4-hydroxybenzoate (4HB). The ubiC gene was expressed in tobacco (Nicotiana tabacum L., Solanaceae) and potato (Solanum tuberosum L., Solanaceae) under the control of the very strong constitutive plant promotor (ocs₃) mas. High accumulation of 4HB glucosides as new, artificial secondary metabolites was observed in the transgenic plants. 4HB glucoside content reached 5.1% of dry weight in tobacco cell cultures and 4.0% of dry weight in the leaves of potato shoots. This is the highest content of an artificial secondary metabolite produced by genetic engineering of plants reported so far. Surprisingly, no growth retardation and no phenotypical changes were observed in the transgenic cell cultures and plants. Glucosylation of 4HB was achieved by endogeneous, constitutively expressed glucosyltransferases. The total amount of 4HB glucoside acccumulated showed a strict linear dependence on the expression level of ubiC.     

A new approach to mapping co-localization of multiple glycosyl transferases in functional Golgi preparations

We have developed a new method to co-localize multiple glycosyltransferases in different Golgi compartments. The approach relieson the proven ability of intact, sealed rat liver Golgi preparationsto concentrate exogenous labeled sugar nucleotides into thelumen where they glycosylate either endogenous or artificialacceptors. The premise is that if two glycosyl transferasesare co-localized within the same compartment, they will competefor the limited amount of transported donor. If the donor isconsumed in glycosylating a permeable artificial glycoside withina Golgi compartment, it will be unavailable to glycosylate endogenousproducts within that same compartment. The greater the degreeof transferase co-localization, the greater the potential decreasein glycosylation of endogenous acceptors. We provide an exampleconsistent with these predictions. Adding 1 µM UDP[³H]Galto Golgi preparations followed by a chase with a cocktail ofunlabeled sugar nucleotides labels mostly endogenous N-linkedoligosaccharides containing both ß1,3- and ß1,4[³H]Galresidues with and without sialic acid. Addition of increasingamounts of 4-methylumbelliferyl-ß-xyloside (XylßMU)produces [³H]Gal1ß,4XylßMU and leads toa reciprocal decrease in labeling of a restricted set of theendogenous acceptors. This decrease is preferential for [³H]Galß1     

Carotenoid synthesis in a suspension culture of carrot cells

Biosynthesis of carotenoid in cultured carrot cells was studiedin relation to cell growth and acetate metabolism. Of the twostrains tested, one (GD-1) predominantly produces ß-caroteneand the other (GD-2) lycopene. In both strains, carotenoid wasproduced in parallel with cell growth. Incorporations of acetate-¹⁴Cinto carotenoids, organic acids and amino acids were acceleratedby increasing the concentration of 2,4-D in the medium. (Received November 17, 1970; )     

Trimming and solubilization of xyloglucan after deposition in the walls of cultured rose cells

A pulse-chase technique involving the in vivo feeding of L-[1-³H]arabinoseto suspension-cultured rose (Rosa) cells at 4 d and 9 d aftersubculture (fast- and slow-growing, respectively) was used tocreate a population of [³H]xyloglucan molecules and to followtheir subsequent fate. The weight-average relative molecu larmass (M_w) of [³H]xyloglucan freshly deposited in the cell wallwas 160 000 and 240 000 in the fast- and slow-growing cells,respectively. The wall-bound [³H]xyloglucan of both culturesunderwent a decrease in M_w of 40 000 during the first 2 d afterthe pulse-labelling. At the same time, 20–30% of the initially-deposited[³H]xyloglucan disappeared from the cell wall, and a similaramount appeared in solution in the culture medium. Its failureto remain bound to the cell wall and its low M_w (39 000) indicatedthat this soluble extracellular ( was derived from partial degradationof segments of wall-bound xyloglucan that were not directlyhydrogen-bonded to microfibrils (‘loose ends’ and‘tethers’). The possible enzymic basis and biologicalroles of the degradation are discussed. Key words: Cell expansion, cell wall, hemicellulose, sloughing, xyloglucan     

Effects of Fluorogibberellins on Plant Growth and Gibberellin 3r{beta}-Hydroxylases

3rß-Fluorogibberellin A₉ (3rß-fluoro-GA₉),3rßfluoro-GA₂₀, 3rß-fluorodeoxygibberellinC (3rß-fluoro-DGC) and 13-fluoro-GA₉ were prepared,and their effects on plant growth and gibberellin (GA) 3rß-hydroxyIaseswere examined. 3rß-Fluoro-GA₉ and 3rß-fluoro-GA₂₀promoted the growth of dwarf rice (Oryza sativa L. cv. Tan-ginbozu)seedlings to three times higher than the control seedlings ata dosage of 3 µ plant^–1, and 3rßfluoro-DGCto twice higher at the same dosage. 3rßg-Fluoro-GA₉was active in cucumber (Cucumis sativus L.) hypocotyl assay,its activity being about one-thirtieth as much as that of GA₄.3rß-Fluoro-GAs were active per se in promoting theshoot elongation of rice. 3rß-Fluoro-DGC inhibitedthe 3rß-hydroxylation of [³H₂]GA₉ to [³H]GA₄ by GArß-hydroxylase from bean (Phaseolus vulgaris L.),but 3rß-fluoro-GA₉ and 3rß-fluoro-GA₂₀ didnot show any effects on the enzyme activity. These 3rß-fluoro-GAsalso showed no or only a weak inhibitory effect on the rß-hydroxylasefrom pumpkin (Cucurbita maxima L.). 13-Fluoro-GA₉ promoted growthof rice and cucumber seedlings, and inhibited the 3rß-hydroxylasesfrom both bean and cucumber. 13-Fluoro-GA₉was converted into13-fluoro-GA₄ and 2,3-didehydro-13-fluoro-GA₉, in a cell-freesystem from bean, and conversion of 13-fluoro-GA₉ into 13-fluoro-GA₄was also observed in a cell-free system from pumpkin. Theseresults suggest that 13-fluoro-GA₉ is one of the substratesof GA 3rß-hydroxy-lases, and that 13-fluoro-GA₉ isactive as a result of the conversion to 13-fluoro-GA₄ in riceand cucumber seedlings. (Received October 27, 1997; Accepted March 13, 1998)     

Aminopeptidases Isolated from Cotyledons of Cowpea, Vigna unguiculata

Three aminopeptidases have been separated from cotyledon extractsfrom cowpea, Vigna unguiculata (L.) Walp., and numbered in orderof decreasing affinity for the anion exchange medium DEAE-Sephacel.API showed a wide acceptance of model substrates, with highestactivity under standard conditions against arginyl ß-naphthylamide(NA). AP2 did not act on basic substrates and preferred phenylalanylß-NA. AP3 displayed the narrowest substrate specificity,with strong activity against only alanyl ß-NA andglycyl ß-NA. The chelator 1,10-phenanthroline completelyor almost completely inhibited forms AP1 and AP3, whereas AP2was insensitive to phenanthroline at the same concentration(5 mM). All three aminopeptidases were totally inhibited byAg⁺ or Zn²⁺ ( 0.5 mM). Vigna unguiculata (L.) Walp., aminopeptidase, cotyledon, cowpea, isoenzyme, 1, 10-phenanthroline     

Physiology of a Microgravity Environment: Selected Contribution: PKC activation inhibits Ca2+ signaling in tracheal epithelial cells kept in simulated microgravity

Microgravity has been shown to alterprotein kinase C (PKC) activity; therefore, we investigated whethermicrogravity influences mechanically stimulated Ca²⁺signaling and ATP-induced Ca²⁺ oscillations, both of whichare modulated by PKC. Rabbit tracheal epithelial outgrowth cultures orsuspended epithelial sheets were rotated in bioreactors to simulatemicrogravity. Mechanical stimulation of a single cell increased thecytosolic Ca²⁺ concentration in 35-55 cells of bothoutgrowth cultures and epithelial sheets kept at unit gravity (G) or insimulated microgravity (sµG). In outgrowth cultures,12-O-tetradecanoylphorbol-13-acetate (TPA; 80 nM), a PKCactivator, restricted Ca²⁺ "waves" to about 10 cells inunit G and to significantly fewer cells in sµG. TPA only slightlyreduced the spread of Ca²⁺ waves in epithelial sheets keptin sµG but did not inhibit Ca²⁺ waves of sheets kept inunit G. In both cell preparations from both conditions, TPA inhibitedATP-induced Ca²⁺ oscillations; however, the effect was morepronounced in cells kept in sµG. These results suggest that PKCactivation is more robust in cells subjected to sµG.