Coniferyl alcohol, sinapyl alcohol and scopoletin in tobacco callus tissue during growth of a subculture

Coniferyl and sinapyl alcohols were isolated, identified and quantitatively determined as unbound (or weakly bound) phenylpropanoids in neutral hot-water extracts of Nicotiana tabacum L. callus tissue. This is the first identification of these alcohols in cultured tobacco callus. Scopoletin was also detected in these extracts, and it was the most abundant of these three phenylpropanoids with concentrations that ranged from 50–119 μg/g dry wt. Coniferyl alcohol (17–34 μg/g dry wt.) and sinapyl alcohol (23–35 μg/g dry wt.) were present in nearly equimolar concentration ratios and at levels which were about half those determined for unbound (or weakly bound) scopoletin. The amount of scopoletin extracted increased about 10 times when 1 M HCl-50% methanol - 0.3% ascorbic acid was used as the extractant. This indicated that most scopoletin moieties were strongly bound, perhaps by acid-hydrolyzable linkage. Coniferyl alcohol and sinapyl alcohol were not found in the acid extracts, presumably because they were acid-labile. In general, the concentration of each endogenous unbound (or weakly bound) phenylpropanoid appeared to remain relatively constant throughout the growth phase of the subculture. The only exceptions to this were the relatively higher concentrations of scopoletin and coniferyl alcohol present during the initial 0–2 weeks of subculture.     

The overexpression of an alternative oxidase gene triggers ozone sensitivity in tobacco plants

The alternative oxidase (AOX) of plant mitochondria transfers electrons from the ubiquinione pool to oxygen without energy conservation and prevents the formation of reactive oxygen species (ROS) when the ubiquinone pool is over-reduced. Thus, AOX may be involved in plant acclimation to a number of oxidative stresses. To test this hypothesis, we exposed wild-type (WT) Xanthi tobacco plants as well as Xanthi plants transformed with the Bright Yellow tobacco AOX1a cDNA with enhanced (SN21 and SN29), and decreased (SN10) AOX capacity to an acute ozone (O3) fumigation. As a result of 5 h of O3 exposition (250 nL L(-1)), SN21 and SN29 plants surprisingly showed localized leaf damage, whereas SN10, similarly to WT plants, was undamaged. In keeping with this observation, WT and SN21 plants differed in their response to O3)for the expression profiles of catalase 1 (CAT1), catalase 2 (CAT2), glutathione peroxidase (GPX) and ascorbate peroxidase (APX) genes, and for the activity of these antioxidant enzymes, which were induced in WT. Concomitantly, although ozone induced H2O2 accumulation in WT and in all transgenic lines, only in transgenics with high AOX capacity the H2O2 level in the post-fumigation period was high. The alternative pathway of WT plants was strongly stimulated by O3, whereas in SN21 plants, the respiratory capacity was always high across the treatment. The present results show that, far from exerting a protective role, the overexpression of AOX triggers an increased O3 sensitivity in tobacco plants. We hypothesize that the AOX overexpression results in a decrease of mitochondrial ROS level that in turn alters the defensive mitochondrial to nucleus signalling pathway that activates ROS scavenging systems.     

Changes in isoperoxidases during shoot formation in tobacco callus

Summary Shoot formation in tobacco (Nicotiana tabacum L.) callus is accompanied by an increase in peroxidase activity which takes a form similar to a sigmoid curve. The “stationary” phase coincide with the period of organ formation. Characteristic changes in isoperoxidase pattern are found in the shoot-forming part of the callus. These changes are different from those in the nonshoot-forming part or in gibberellin-treated tissue, which does not form shoots.     

Changes in isoperoxidases during shoot formation in tobacco callus

Shoot formation in tobacco (Nicotiana tabacum L.) callus is accompanied by an increase in peroxidase activity which takes a form similar to a sigmoid curve. The "stationary" phase coincides with the period of organ formation. Characteristic changes in isoperoxidase pattern are found in the shoot-forming part of the callus. These changes are different from those in the nonshoot-forming part or in gibberellin-treated tissue, which does not form shoots.     

Ethylene and ethane release during tobacco protoplast isolation and protoplast survival potential in vitro

Studies on stress ethylene and ethane during protoplast isolation from water-stressed and waterlogged donor plants Nicotiana tabacum L. xanthi-nc, show a correlation between ethane, but not ethylene, release and protoplast survival in vitro. Ethane release shows a high negative correlation with protoplast survival potential from donor plants subjected to both stresses. Ethylene showed a high negative correlation with protoplast survival potential in tissues from water-stressed but not from long-term waterlogged plants. The absence of correlation in the latter may be related to decreased ability to produce ethylene in hyperstressed plants.
The results are discussed in relation to the use of stress ethane release as a parameter of the physiological status of the plant.     

Shoot initiation in light- and dark-grown tobacco callus: the role of ethylene

Shoot-forming tobacco ( Nicotiana tabacum L. cv. Wisconsin 38) callus produces less endogenous ethylene than non-shoot-forming tissue cultured in the light (16 h photoperiod) or the dark. In shoot-forming tissue more ethylene is produced early in culture (days 0–5) than later. Also dark-grown tissue produces much more ethylene than light-grown. On the basis of experiments in which (1) gaseous ethylene was added to or (2) CO₂ removed from the flasks, (3) Ethrel (an ethylene releasing agent) and (4) 1-aminocyclopropane 1-carboxylic acid (an ethylene precursor) were added to the medium, it was determined that this gaseous phytohormone had two contrary effects on shoot initiation (shoot primordium formation). Early in culture (days 0–5) endogenous or exogenous ethylene inhibited organogenesis, but later (days 5–10) exogenous ethylene or increased endogenous ethylene production speeded up primordium formation.     

Morphactin-kinetin interaction on growth and shoot formation in tobacco callus cultures

Pith-derived calluses of Nicotiana tabacum L. cv. Wisconsinno. 38 were inoculated on an RM-1964 medium containing variousconcentrations of a morphactin, chlorflurenol (CFl) and kinetin(KIN). An addition of KIN (0.1–2 mg/liter) alone was effectivefor shoot formation from the calluses, but a high dose (10 mg/liter)resulted in the inhibition of growth and in no differentiation.The inhibitory effect of a high dose of KIN was counteractedwith CFl. Three combinations of KIN and CFl; CFl (0.1 mg/liter)$KIN(2.0 mg/liter); CFl (0.1 mg/liter)$KIN (10.0 mg/liter) and CFl(1.0 mg/liter) $KIN (2.0 mg/liter), were successful for 100%shoot redifferentiation in inoculated calluses. An appropriatebalance between CFl and KIN seems to be involved in shoot formation.The present results can best be interpreted by assuming thatCFl acts as an auxin in cultured tissues. (Received January 16, 1975; )     

Changes in water potential and its components during shoot formation in tobacco callus

Addition of plant growth regulators (5 nM NAA and 5μM BAP) to a defined basal medium stimulated adventitious bud formation of Douglas fir (Pseudotsuga menziesii [Mirb.] Franco) cotyledon explants in culture. Cytoplasmic soluble proteins synthesized during early stages of adventitious bud formation were analyzed by electrophoresis of ³H- and ¹⁴C-leucine labeled proteins on SDS polyacrylamide gels. Increased synthesis of low molecular weight proteins (16,000 to 20,000 daltons) was detected after 2 days in culture and reached a maximal level at day 4. When cotyledon explants cultured on bud medium for 2 days were transferred to callus medium (which suppressed adventitious bud formation), suppression of the synthesis of low molecular weight proteins was also observed, suggesting that these proteins may be associated with early stages of adventitious bud formation.     

Correlation between K+ content, activities of arginine and ornithine decarboxylase, and levels of putrescine and nicotine in cultured tobacco callus

In callus cultures of Nicotiana tabacum L. cv. Burley 21 we have examined the effect of two auxin concentrations (1 and 11.5 μ M α-naphthaleneacetic acid) in the culture medium on K⁺, putrescine and nicotine levels and activities of putrescine-biosyn-thetic enzymes l -arginine decarboxylase (EC 4.1.1.19) and l -ornithine decarboxylase (EC 4.1.1.17). The calli grown on the low-auxin medium (with optimal auxin concentration for nicotine synthesis) had significantly lower concentrations of K⁺ and higher concentrations of nicotine than those grown on the high-auxin medium (with a supraoptimal auxin concentration). Furthermore, in the calli grown on both culture media, there was a positive correlation between the levels of HCIO₄-soluble free putrescine and nicotine, as well as a negative correlation between those of HCIO₄-soluble bound putrescine and the alkaloid. The results suggest that in tobacco callus K⁺ uptake, the accumulation of HCIO₄-soluble free putrescine and nicotine synthesis are related processes that depend upon the concentration of auxin in the culture medium; a concentration of 1 μ M NAA would increase HCIO₄-soluble free putrescine level to a greater degree than that of 11,5 μ M NAA, and consequently lead to a higher production of the alkaloid. Although both putrescine-biosynthetic enzymes are active in our callus cultures, ornithine decarboxylase activity was considerably greater. This interpretation is supported by the enhancement of the 35.5 kDa band and 38.9 kDa band (detected by SDS-PAGE) which showed ornithine and arginine decarboxylase activity, respectively.     

Effects of salt and osmotic shocks on unadapted and adapted callus lines of tobacco

Growth, viability and proline content of adapted and unadapted calluses of Nicotiana tabacum L. var. Jayasri, affected due to osmotic stresses and particularly to stress-shocks treated with different osmotica like NaCl (ionic-penetrating), mannitol (non-ionic-penetrating) and polyethylene glycol, (PEG) (non-ionic-non penetrating) were studied to evaluate the physiological differences of stress effects. The tissues adapted to a low concentration of NaCl (85 mM) showed low growth with high proline content compared to the tissues adapted to a low concentration of mannitol (165 mM). Proline content was similar in tissues adapted to high concentrations of NaCl (171 mM) and mannitol (329 mM) but growth in the latter case was relatively low. Growth and viability were subsequently correlated with the pattern of retention in or diffusion of proline out of the tissues after shock-treatments. The loss of tissue viability of the adapted calluses was comparatively less than the unadapted callus even after shock-treatments with 1282 mM NaCl and 823 mM mannitol. The former calluses retained the capability of regrowth though at a slow rate. Such adapted tissues also retained more proline. The mannitol-adapted tissues, when shocked with PEG (200 g l-1), showed low viability with more diffusion and a very little retention of proline while, in the unadapted tissue, all the proline was leached out. The results indicated that the effects of different osmotica on plant tissue varied depending upon the physico-chemical nature of the compounds used as stress-inducing-agents, and retention and diffusion of proline was altered when the tissues were shocked with high concentrations of all these compounds. This revised version was published online in June 2006 with corrections to the Cover Date.     

Effect of auxin on alkaloids, K+ and free amino acid content in cultured tobacco callus

Callus cultures derived from the petiole of Nicotiana tabacum L. cv. Burley 21 were grown at 25°C in the dark on two different basal media containing: (1) 11.5 μ M α-naphthaleneacetic acid and 1 μ M kinetin, and (2) 1 μ M α-naphthaleneacetic acid and 1 μ M kinetin. The contents of alkaloids, K⁺ and free amino acids of callus tissues were determined. The tissues were also examined microscopically for organization when organogenesis was not apparent. The first medium limited nicotine synthesis and stimulated its N-demethylation to nornicotine. The second medium stimulated nicotine synthesis and limited tissue growth. Although significantly higher concentrations of K⁺ were observed in calli grown on the high-auxin medium, both cultures were K⁺ deficient. The fact that the low-auxin medium limited K⁺ uptake to a higher degree would account for the lower growth observed in calli cultured on this medium, and it is possible that the effect of auxin concentration on nicotine production may be mediated through its effects on K⁺ uptake by cells of the culture. The free amino acid concentration increased in the calli grown on the low-auxin medium. Glutamic acid and proline, known as initial precursors of nicotine, increased significantly. Histological examination showed that the occurrence of meristematic areas in calli without organogenesis promoted nicotine synthesis. The relation between the accumulation of nicotine and formation of roots or shoot-buds is discussed.     

Starch turnover in shoot-forming tobacco callus

Tobacco callus grown under shoot-forming conditions or in the presence of gibberellic acid, which inhibits shoot formation, was incubated in [¹⁴C]-sucrose at three different periods in culture and then replanted. Evolution of ¹⁴CO₂ occurred during the 10 day post-incubation period. Most of the radioactivity was incorporated into the ethanol-soluble fraction, which lost most of its label after 24 h. Starch was the major ethanol-insoluble component and post-incubation synthesis occurred in this fraction for 24 h or longer. Greater net synthesis of starch occurred in shoot-forming tissue and the loss of label from starch began later than in tissue cultured in the presence of gibbe-rellic acid. Newly synthesized starch was not immediately utilised in the organogenic process, but its utilization could be correlated with the shoot-forming process.     

Antioxidant protection during ageing and senescence in chloroplasts of tobacco with modulated life span

We studied changes in antioxidant protection during ageing and senescence in chloroplasts of tobacco (Nicotiana tabacum L., cv. Wisconsin) with introduced SAG(12) promoter fused with ipt gene for cytokinin synthesis (transgenic plants with increased levels of cytokinins, SAG) or without it (control). Old leaves of SAG plants as well as their chloroplasts maintained higher physiological parameters compared to controls; accordingly, we concluded that their ageing was diverted due to increased cytokinin content. The chloroplast antioxidant protection did not decrease as well. Although antioxidant protection usually decreased in whole leaves of senescing control plants, ascorbate peroxidase (APX) and dehydroascorbate reductase (DHAR) activity, which maintained the high redox state of ascorbate, increased in chloroplasts of old control leaves.     

Free and conjugated polyamines during de novo floral and vegetative bud formation in thin cell layers of tobacco

The concentrations of three classes of polyamines, trichloroacetic acid-soluble (free), TCA-soluble conjugated (to small molecules) and TCA-insoluble conjugated (to macromolecules), was examined during de novo floral and vegetative bud formation in thin cell layers of Nicotiana tabacum L. cv. Samsun. Explants (consisting of 5–6 layers of epidermal, subepidermal and parenchyma cells) were excised either from floral pedicels or from stem internodes at the unripe fruit stage and cultured on the same medium. In the former, the first de novo formed flower buds appeared on day 8 of culture, while in the latter the first vegetative domes appeared on day 10. In both cases the number of floral and vegetative buds increased up to day 12 and 15, respectively. Changes in dry weight were determined throughout the culture period. Free and conjugated putrescine titer increased 5–60 times in both types of culture and in the three classes of polyamines examined; spermidine content also increased, while spermine, when present, did not show significant changes. TCA-soluble conjugated polyamines were most abundant, being about 2-fold the TCA-insoluble conjugated ones and 10-fold the free ones. The major increment in putrescine and spermidine content occurred in stem internode explants developing vegetative buds. In pedicel explants the maximum putrescine level was reached before or on day 8 in culture (emergence of the first flower buds with calyx initials), while in stem internode explants the maximum level was reached on day 12, at the emergence of the first vegetative buds with leaf primordia. While spermidine prevailed on day 0, putrescine was the most abundant polyamine during both differentiation processes. The putrescine content rapidly increased immediately after the onset of culture. Thus conjugated polyamines, especially putrescine, and not only the free ones, seem to be involved in both the reproductive and vegetative phases of tobacco growth and development.     

Agar/galactomannan gels applied to shoot regeneration from tobacco leaves

This study concerns the efficacy of partial agar substitution by galactomannans as support in plant regeneration media for Nicotiana tabacum. The production of multiple shoots from leaf-derived callus and their rooting were evaluated. The galactomannans applied were obtained from Cassia fastuosa (cassia) and Cyamopsis tetragonolobus (guar gum — a commercial galactomannan) seeds. The results obtained on media solidified with mixtures of agar/galactomannan (3 g dm⁻³ each) gels were compared with those on media gelled with a standard concentration of agar (6 g dm⁻³). The in vitro performance allowed to conclude that the use of galactomannans raised the number of shoots and improved their quality. Furthermore, the length of roots and the size of leaves were significantly higher in the media solidified with agar/guar galactomannan mixtures.     

Changes in the metabolism of nucleic acids during the growth and senescence of tobacco callus

Changes in DNA and RNA metabolism, DNA composition and RNA species in callus of tobacco ( Nicotiana rustica L. cv. Gansu Yellow Flower) were investigated during the growth and senescence. DNA and RNA contents remained almost unchanged during the callus growth period, but started to decrease synchronously at the time that callus senescence was initiated. Synthesis of DNA and RNA, as measured by incorporation of [³H]-labelled precursor, increased during the growth period and did not decrease until late in senescence. The activities of DNase and RNase (pH 4.5) increased during the early senescence period in accordance with the decrease in the levels of DNA and RNA, but appeared to decrease during late senescence. These results suggest that the decrease in the levels of DNA and RNA in senescing tobacco callus may stem from the increase in the hydrolytic activities of DNase and RNase (pH 4.5) in the early stage of senescence, and that the slowdown of synthesis in the late senescence period may also be a cause. DNA and RNA electrophoresis showed that a low-molecular-weight satellite DNA band disappeared after the onset of senescence and that the nuclear main band DNA gradually decreased, whereas the high-molecular-weight satellite DNA seemed to undergo no significant changes during the senescence period tested. Of the RNA species, 4–5S RNA was far more susceptible to damage during senescence than 25S and 18S rRNA. This suggests different susceptibilities of different DNA and RNA components to damage during the senescence of tobacco callus or alternatively a highly sequenced degradation of DNA and RNA molecules.     

The effect of barban on shoot formation in tobacco callus cultures

Shoot formation in tobacco callus was completely inhibited bythe presence of barban in the media during the first 2 daysof culture. Callus transferred to media containing barban from4th to the 12th day showed progressively less inhibition. Similarresults were obtained with GA₃. ¹Present address: Biology Department, Chung Chi College, TheChinese Univ. of Hong Kong, Shatin, N.T., Hong Kong ²Present address: Plant Hormone & Regulator Pioneering ResearchLab., U.S. Dept. Agric, Crops Res. Div., Beltsville, Md., U.S.A. (Received April 21, 1970; )     

Effect of plant growth substances on the formation of carpelloid structures from tobacco ovules

Excised ovules with placentae developed into carpelloids consisting of stigma-like, style-like and ovule-like structures. Kinetin was necessary for the formation of carpelloids in immature ovules which were excised from the flower buds containing pollen grains at bicellular stage. However, plant growth substances were not necessary for these formations in younger ovules which were excised from the flower buds containing pollen grains at unicellular stage. The morphological characteristics of the stigma-like and style-like structures were similar to those of normal tissues, and their functions were the same.     

Metabolic regulation of leaf respiration and alternative pathway activity in response to phosphate supply

In this study the question whether the alternative respiratory pathway acts as an electron bypass for the cytochrome pathway under conditions of growth on limited phosphorus in leaves of bean (Phaseolus vulgaris L.), tobacco (Nicotiana tabacum L.) and Gliricidia sepium Walp was investigated. The oxygen isotope fractionation technique was used to assess the in vivo activities of the cytochrome and alternative respiratory pathways in the absence of added inhibitors. The response of respiration to low phosphorus supply varied among species. Growth at low phosphorus reduced cytochrome pathway activity in bean and tobacco. Alternative pathway activity increased only in bean leaves in response to low phosphorus and not in tobacco. In the case of G. sepium, cytochrome pathway activity remained unchanged whereas the alternative pathway activity increased with low nutritional phosphorus. At low phosphorus, alternative oxidase protein levels increased in the leaves of bean and G. sepium but not in tobacco, suggesting a dependence of alternative pathway activity on protein level. Alternative pathway activity was also not correlated with soluble carbohydrate concentration in bean or tobacco at any phosphorus level. These results show that the alternative pathway does not always act as an electron bypass in response to the downstream restriction of the cytochrome pathway imposed by low phosphorus supply. These results suggest that factors in addition to cellular carbohydrate level and adenylate control can act to regulate alternative pathway activity.