Changes in symplastic permeability during adventitious shoot regeneration in tobacco thin cell layers

Thin cell layer (TCL) explants of tobacco (Nicotiana tabacum L.) were cultured in either a regeneration medium that resulted in formation of adventitious vegetative shoots or a non-regeneration (control) medium that maintained the TCLs but did not promote shoot formation. Microinjections were conducted on epidermal cells at 1- or 2-day intervals during the culture period (14 days) and also on meristematic regions as they appeared in regenerating TCLs. A fluorescein isothiocyanate-labelled peptide (F(Glu)₃ MW 799) was used to assess the permeability of the symplast during adventitious shoot regeneration. A period of increased symplastic movement of F(Glu)₃ was detected during day 2 of culture and was significantly greater in regenerating TCLs than in non-regenerating TCLs. This corresponded to the period of the first cell divisions and represents the re-initiation of a meristematic type of symplastic linkage between epidermal cells. A smaller increase in cell-to-cell movement within non-regenerating TCLs indicated a possible stress response as a factor in these changes. Movement of F(Glu)₃ throughout the epidermal symplast of regenerating TCLs returned to pre-culture levels by the time of shoot primordia formation. F(Glu)₃ movement was further down-regulated in non-regenerating TCLs, with a high degree of cell isolation observed. Within newly formed shoots, symplastic movement of F(Glu)₃ cycled between high and low levels.     

烟草花柄愈伤组织花芽分化的能力(简报)

来源于开花植株的外植体(如花柄、花序轴等)具有在离体培养条件下直接分化花芽的能力,这一现象已在数十种植物的组织培养中得到证实。但是,这种成花能力能否保留在由这些外植体形成的愈伤组织之中?已有报道在风信子、布罗瓦利亚花、石龙芮、大蒜、矮通泉草等值物的愈伤组织中得到无     

Stimulation of root development on buckwheat thin cell-layer explants by pectic fragments from pea stem cell walls

Buckwheat (Fagopyrum esculentum Moench.) thin cell-layers (TCLs) cultured individually in a liquid medium were used to test the root-inducing activity of pectic polysaccharides with a degree of polymerization (DP) of 20–25, isolated from pea (Pisum sativum L.) stem cell walls. These pectic fragments induced more rapid root formation on the explants in comparison with untreated controls. This pectic fragment treatment also promoted root growth as measured by both fresh and dry weights and about doubled the number of roots formed. This buckwheat TCL system is proposed as a new bioassay for oligosaccharins due to its sensitivity, reproducibility and ease of preparation.     

Adventitious rooting is enhanced by methyl jasmonate in tobacco thin cell layers

Adventitious roots (ARs) are induced by auxins. Jasmonic acid (JA) and methyl jasmonate (MeJA) are also plant growth regulators with many effects on development, but their role on ARs needs investigation. To this aim, we analyzed AR formation in tobacco thin cell layers (TCLs) cultured with 0.01–10 μM MeJA, either under root-inductive conditions, i.e., on medium containing 10 μM indole-3-butyric acid (IBA) and 0.1 μM kinetin, or without hormones. The explants were excised from the cultivars Samsun, Xanthii and Petite Havana, and from genotypes with altered AR-forming ability in response to auxin, namely the non-rooting rac mutant and the over-rooting Agrobacterium rhizogenes rolB transgenic line. Results show that NtRNR1 (G1/S) and Ntcyc29 (G2/M) gene activity, cell proliferation and meristemoid formation were stimulated in hormone-cultured TCLs by submicromolar MeJA concentrations. The meristemoids developed either into ARs and xylogenic nodules, or into xylogenic nodules only (rac TCLs). MeJA-induced meristemoid over-production characterized rolB TCLs. No rooting or xylogenesis occurred under hormone-free conditions, independently of MeJA and genotype. Endogenous JA progressively (days 1–4) increased in hormone-cultured TCLs in the absence of MeJA. JA levels were enhanced by 0.1 μM MeJA, on both days 1 and 4. Endogenous IBA was the only auxin detected, both in the free form and as IBA-glucose. Free IBA increased up to day 2, remaining constant thereafter (day 4). Its level was enhanced by 0.1 μM MeJA only on day 1, while IBA conjugation was not affected by MeJA. Taken together, these results show that an interplay between jasmonates and auxins regulates AR formation and xylogenesis in tobacco TCLs.     

In vitro control of de novo flower differentiation from tobacco thin cell layers cultured on a liquid medium

Thin cell layers of tobacco (three to six layers of epidermal and subepidermal cells) were allowed to float on the surface of a liquid medium. Whereas the control on an identical medium solidified by agar gave 100% of explant-forming flowers, no flowers formed in the absence of agar (100% of the explants formed buds). In order to initiate flower formation, various modifications of the liquid medium were tried: different ratios of indolyl-3-butyric acid (IBA) to kinetin (Kin) from 1 to 100, a range of pH from 4.0 to 7.0, and glass beads of different diameters (in an attempt to change the physico-chemical characteristics of the culture substrate itself). On a liquid medium with glass beads, four types of morphogenesis (flowers, buds, a mixed programme of flowers and buds, and a non-morphogenetic programme – i.e. the explants remained unchanged) were separately induced by changing one of the three factors: pH, IBA and Kin in equimolar concentrations, and diameter of the glass beads. Changing only the IBA/Kin ratio failed to provoke flower differentiation. pH of the medium was found to change after autoclaving and the effect of glass beads on morphogenesis was partly related to modification of pH.     

THE CULTURE OF APICAL BUDS OF XANTHIUM AND THEIR USE AS A BIOASSAY FOR FLOWERING ACTIVITY OF ECDYSTERONE

Conditions were developed for the sterile culture of shoot tips of Xanthium pensylvanicum Wallr. for use as a bioassay for flower-controlling chemicals. By using a modified Murashige-Skoog medium (minus the auxin but including kinetin) and light intensity much higher than usual for plant tissue cultures, fast growth and development of the shoot tips was achieved. Under short-day conditions (8 hr day: 16 hr night), the cultures from vegetative shoots flowered and fruited; under noninductive conditions (using a 2 hr light-break in the middle of the dark period), the shoot tips continued vegetative development. Both intact plants and cultured tips could be photoinduced in the first days after germination. Ecdysterone, a potent insect moulting hormone, was tested in the bioassay system. It was without either qualitative or quantitative effect on flowering or vegetative development on either cultured shoot tips or intact plants irrespective of whether they were under inductive or noninductive photoperiodic conditions.     

Effect of light and riboflavin on indolebutyric acid-induced root formation on apple in vitro

Maximum root formation on apple ( Malus ) shoots cultured in vitro occurred after an incubation in the dark on medium containing 3.2 or 10 μ M indolebutyric acid (IBA) plus riboflavin. Omission of riboflavin or culture in light resulted in a significant decrease in the number of roots formed. About 95% of the absorbed IBA was inactivated by conjugation, ca 4% was extracted as the free IBA acid (IBAH) and only 1% as IAAH. It was investigated whether the decrease in root formation caused by exposure to light or omission of riboflavin during culture was parallelled by a shift in the concentrations of the physiologically active auxin compounds (IBAH and IAAH) in the stem base, i.e. the location where the roots emerge. At least 90% of the absorbed ³H-IBA was located in the stem base. Omission of riboflavin, either in the dark or in the light, had no effect on the IBAH and IAAH concentrations, whereas root formation decreased significantly. Incubation in the light on medium containing 10 μ M IBA with or without riboflavin and culture in the dark on medium containing 3.2μ M IBA plus riboflavin resulted in similar IBAH and IAAH concentrations. However, the number of roots was significantly lower after culture in the light. Therefore, we conclude that the synergistic effect of riboflavin and the antagonistic effect of light on IBA-induced root formation are not solely based on changes in the concentrations of the active auxin components resulting from IBA uptake.     

The Effect of Indole-3-Butyric Acid and Riboflavin on the Morphogenesis of Adventitious Roots of Eucalyptus ficifolia F. Muell. Grown In Vitro

Shoot explants from seedling-derived culture of Eucalyptus ficifoliaF. Muell. cultured on a rooting medium free from indole-3-butyricacid (IBA) develop a root system (Type I) consisting of a fewcomparatively long roots and only small amounts of callus. IBAat 5.0 µM in a rooting medium free from riboflavin inducesthe development, on the shoot explants, of a compact root system(Type II) consisting of callus and many short roots. Riboflavinwhen exposed to light, is able to photo-oxidize IBA; the degreeof photo-oxidation depends on the photon fluence of the lightreceived. The rooting response of the cultures reflects thedegree of photo-oxidation of IBA: concentrations of IBA fromabout 10^–4M to 10^–6M in the rooting medium induceformation of the Type II root system whilst photo-oxidationof the auxin to concentrations of about 10^–8M or lowerinduces the formation of the Type I root system. Thus, exogenousriboflavin and exogenous IBA are linked in a distinct light-induced,riboflavin-mediated change in root morphogenesis. The anatomyof root development in the Type I and Type II root systems wasstudied and factors affecting the development were defined.Characteristics of riboflavin and IBA breakdown in various lightregimes were determined and related to root morphogenesis. Theresults and their implications are discussed. Key words: Auxin photo-oxidation, Riboflavin, Root morphogenesis, Tissue culture     

Changes of Endogenous Hormone Contents During Floral Bud and Vegetative Bud Differentiation in Thin Cell Layer Culture of Cichorium intybus L. Explant

The sectioned thin cell layers (TCL) of flower stalk of Cichorium intybus L. were cultured in MS medium supplemented with NAA and BA or IAA and BA where floral and vegetative buds were developed from the explant. Endogenous IAA, DHZ+DHZR, iPA increased significantly during the floral bud formation, while Z+ZR remained changed. The levels of cytokinins, DHZ +DHZR, iPA, and Z-f-ZR all increased significantly during the vegetative bud formation, however IAA level was reduced during the first 7 days of culture and increased to two-thirds of initial values on the day when the bud primordia were formed. The results suggested that the initiation of floral buds was associated with a high IAA/CTK ratio, whereas the induction of vegetative bud differentiation was related to a low IAA/CTK ratio.     

菊苣薄层培养花芽,营养芽分化中内源激素的动态变化

菊苣（Ｃｉｃｈｏｒｉｕｍ ｉｎｔｙｂｕｓＬ．）花梗薄层细胞培养于ＭＳ附加ＮＡＡ 和ＢＡ 或ＩＡＡ 和ＢＡ 的ＭＳ培养基上有花芽或营养芽分化． 花芽分化中内源ＩＡＡ、ＤＨＺ＋ ＤＨＺＲ、ｉＰＡ 含量明显增加,而Ｚ＋ ＺＲ变化不明显．营养芽分化中内源细胞分裂素含量增加明显,而ＩＡＡ 在培养前７ ｄ 含量下降,随后有所增加,在原基形成时含量达原初水平的２／３． 可见,花芽分化比营养芽分化所需内源ＩＡＡ／ＣＴＫ 比值要高     

Culture conditions for induction of green plants from barley microspores by anther culture methods

Summary With barley a large variation in frequency of plant formation from microspores of spikes from the same plant has been observed. The highest frequency of plant formation was obtained when culturing anthers in the dark on a high Ficoll medium containing 2,4-D and kinetin to induce proembryo (or callus) formation. Subsequently the proembryos or calli were cultured in dim light on a high Ficoll-high sugar medium containing IBA and kinetin. Finally the embryos were transferred to a starch agar medium. A maximum of 13 green plants were obtained from microspores of a single anther.The ratios of green to albino microspore derived plants varied from 91 to 19 depending on culture conditions. Under anaerobic conditions, lactic acid and other organic acids may have damaged the organelles in the cells resulting in the formation of albino plants. Thus, direct embryogenesis by using a well-buffered, high Ficoll-high sugar medium and proper aeration are essential for obtaining high frequency of green plants from microspores.Abbreviations 2,4-D 2,4 dichlorophenoxyacetic acid - IBA 3 indolylbutyric acid     

Oligogalacturonides inhibit the formation of roots on tobacco explants

α-1,4-Oligogalacturonides with degrees of polymerization (DPs) ranging from 6 to 18 or 2 to 8 were added to tobacco leaf explants and root formation was evaluated after 15 days of incubation. Auxin-induced formation of roots was inhibited by oligogalacturonides with DPs 6–18 but not by the oligogalacturonides with DPs 2–8. The inhibition of root formation by the larger oligogalacturonides was prevented by increasing the amount of auxin present in the medium. Oligogalacturonides (DPs 6–18) also inhibited root formation when added to tobacco thin cell-layer (TCL) explants in a medium that is known to induce the formation of roots. The addition of size-homogeneous oligogalacturonides, to either tobacco leaf explants or TCLs, established that oligogalacturonides with DPs between 10 and 14 were most active in inhibiting the formation of roots. These data suggest that oligogalacturonides of the same size as those known to elicit plant defense responses, and to affect floral development and membrane functions, also inhibit the induction of root morphogenesis in tobacco.     

In vitro formation and development of floral buds on tobacco stem explants: effects of kinetin and other factors

Stem segments were excised from plants of Wisconsin 38 tobacco (Nicotiana tabacum L.) in three regions differing in their distance below the inflorescence. They were cultured in vitro in 8- or 16-hr days. After 8 weeks, floral and vegetative buds were counted, and extent of floral development was assessed. Kinetin at 10(-5)m inhibited formation and development of floral buds regardless of indoleacetic acid concentration. Supplied at this concentration with adequate auxin, kinetin stimulated vegetative bud formation and may have caused floral bud abortion. Indoleacetic acid (>/= 10(-6)m) inhibited vegetative and floral bud formation when supplied with low kinetin concentration (/= 10(-6)m), it inhibited floral bud formation and stimulated vegetative bud formation. More floral buds were formed in 16-hr days than in 8-hr days. Few formed on explants other than those derived from the region nearest the inflorescence regardless of other treatment.     

In vitro flowering of bitter melon

Flowers were formed from shoot tips of bitter melon (Momordica charantia L.) cultured on Murashige and Skoog medium supplemented with 90 mM sucrose, 0.05 mM Fe²⁺ and 4 µM N⁶-benzyladenine (BA). The addition of 0.05 mM Fe²⁺ to the medium prevented chlorosis of the explant and promoted normal flowering. Increasing the ratio of carbon to nitrogen promoted male flower formation but intensively inhibited vegetative growth. The influence of cytokinin on the morphogenesis of the explant was highly notable. Flowers could be formed after a 15- to 20-day exposure to kinetin (Kin) or BA. Kin and BA had opposite effects with regard to the development of the explant. Kin promoted flower formation, especially female, but inhibited branch bud formation. Conversely, BA promoted branch bud formation and also promoted male flower formation when present at a concentration of 1-2 µM, but completely inhibited flower formation at 4-8 µM. Fluorescein diacetate staining and in vitro germination showed that in vitro pollen were of a fairly high viability.     

Direct differentiation of ears and tassels from cultured shoot apices of maize

In vitro morphogenesis of inflorescences from the cultured corn seedling shoot tips was obtained on modified Murashige and Skoog (MS) medium in complete darkness. Some shoot tip meristems excised from seedlings of inbred line 515, inbred line 8112 and their filial generations would directly give rise to florets on modified MS medium supplemented with 2.0 mg/L N6-bezyladenine (6-BA) in five or six weeks. On the medium with 1.0 mg/L 6-BA and 0. 2 mg/L 2, 4-dichlorophenoxy acetic acid (2, 4-D), the explants swelled first, and produced multiple shoot clumps, then the culture of the shoot tips from all of the six inbred lines in experiment would ultimately initiate to develop ears and tassels accompanied by multiple shoot clumps developing on the medium with 1.0 mg/L 6-BA and 0. 2 mg/Lin-dole-3-butyric acid (IBA). The developmental patterns of the corn inflorescences were similar to the controls of normal plants in the field, but the number of the ears was much more than that of the tassels in vitro. It seem     

The protein of rolB gene enhances shoot formation in tobacco leaf explants and thin cell layers from plants in different physiological states

The objective was to determine whether the protein of rolB affects shoot formation and whether this potential relationship depends on the developmental stages of the plant and/or on the culture conditions. Thin cell layers (TCL) and leaf explants were excised from tobacco plants in the vegetative and flowering stages and cultured under various hormonal conditions. In TCLs of vegetative-stage plants, the expression of rolB enhanced the formation of the shoot buds under hormone-free conditions and with specific concentrations of auxin and/or cytokinin. Histological examination showed that the induction of the shoot meristemoids was particularly enhanced by rolB protein and that meristemoid growth was accelerated. In leaf explants from vegetative-stage plants, the expression of rolB increased the formation of shoot buds in the presence of 1 M IAA plus 1 or 10 M cytokinin. With BA alone, at a 0.1 M concentration, shoot formation occurred in the transgenic explants only, whereas with concentrations ranging from 0.5 to 10 M, it was higher in these explants than in controls.RolB protein enhanced the formation of shoot buds in TCLs from flowering plants under all hormonal conditions. In the presence of 1 M IAA and kinetin, the protein also increased the flowering response. In leaf explants from flowering plants, the expression of rolB increased the number of shoot buds in the presence of 1 M IAA with 10 M BA.In conclusion, rolB protein promotes shoot formation; it seems to have a positive interaction with cytokinin and an effect on the induction of the meristematic condition.     

Growth stimulation by catecholamines in plant tissue/organ cultures

Addition of catecholamines at micromolar concentrations caused a dramatic stimulation of growth of tobacco (Nicotiana tabacum) thin cell layers (TCLs) and Acmella oppositifolia “hairy” root cultures. A threefold increase in the rate of ethylene evolution was observed in the catecholamine-treated explants. Aminooxyacetic acid and silver thiosulfate, inhibitors of ethylene biosynthesis and action, respectively, reduced the growth-promoting effect of dopamine. However, these compounds alone could also inhibit the growth of the TCL explants. When ethylene in the culture vessel was depleted by trapping with mercuric perchlorate, dopamine-stimulated growth was still obtained, suggesting that ethylene does not mediate the dopamine effect. Dopamine potentiated the growth of TCLs grown in Murashige and Skoog medium supplemented with indoleacetic acid (IAA) and kinetin. When IAA was replaced by 2,4-dichlorophenoxyacetic acid, dopamine addition showed no growth-promoting effect. Instead, 2,4-dichlorophenoxyacetic acid stimulated the growth of TCL explants to the same extent as that obtained with IAA plus dopamine. Because synthetic auxins do not appear to be substrates for IAA oxidizing enzymes, we hypothesized that catecholamines exert their effect by preventing IAA oxidation. Consistent with this explanation, dopamine (25 micromolar) inhibited IAA oxidase activity by 60 to 100% in crude enzyme extracts from tobacco roots and etiolated corn coleoptiles, but had no effect on peroxidase activity in the same extracts. Furthermore, addition of dopamine to TCL cultures resulted in a fourfold reduction in the oxidative degradation of [1-¹⁴C]IAA fed to the explants. Because the growth enhancement by catecholamines is observed in both IAA-requiring and IAA-independent cultures, we suggest that these aromatic amines may have a role in the regulation of IAA levels in vivo.     

Rooting and the Metabolism of Nicotine in Tobacco Callus Cultures

The usefulness of exogenous nicotine as a factor in the induction of morphogenesis in a tobacco tissue culture medium has been demonstrated. Nicotiana rustica callus cell cultures were grown on a modified Murashige and Skoog medium with 2 mg/l indoleacetic acid (IAA) and 0.2 mg/l kinetin (MMS). Root morphogenesis was induced in roller tube callus cell cultures and solid callus cell cultures grown on MMS without kinetin supplemented with 10–100 mg/l nicotine. Optimal nicotine concentration for root induction was 50 mg/l. Other tests using varying combinations of IAA, kinetin and nicotine produced no obvious morphogenesis, although some changes in the amount of callus growth and endogenous protein concentration did correlate with nicotine concentration relative to the presence of IAA and/or kinetin. In liquid MMS medium, ¹⁴C-nicotine was primarily incorporated into the protein fraction of cultured cells while primarily incorporated into the cell wall and/or cell membrane fraction of cells cultured on MMS without kinetin in the medium. In MMS without IAA and MMS without both IAA and kinetin, there was incorporation, but to a lesser extent in both the protein and the cell wall and/or cell membrane fractions.