Analysis of Cytokinin Metabolism in ipt Transgenic Tobacco by Liquid Chromatography-Tandem Mass Spectrometry

The endogenous levels of the major, naturally occurring cytokinins in Pisum sativum ribulose-1,5-bisphosphate carboxylase small subunit promoter-isopentenyl transferase gene (Pssu-ipt)-transformed tobacco (Nicotiana tabacum L.) callus were quantified using electrospray-liquid chromatography-tandem mass spectrometry during a 6-week subcultivation period. An ipt gene was expressed under control of a tetracycline-inducible promoter for a more detailed study of cytokinin accumulation and metabolism. Activation of the ipt in both expression systems resulted in the production of mainly zeatin-type cytokinins. No accumulation of isopentenyladenine or isopentenyladenosine was observed. In Pssu-ipt-transformed calli, as well as in the tetracycline-inducible ipt leaves, metabolic inactivation occurred through O-glucoside conjugation. No significant elevation of cytokinin N-glucosides levels was observed. Side-chain reduction to dihydrozeatin-type cytokinins was observed in both systems. The levels of the endogenous cytokinins varied in time and were subject to homeostatic regulatory mechanisms. Feeding experiments of ipt transgenic callus with [3H]isopentenyladenine and [3H]isopentenyladenosine mainly led to labeled adenine-like compounds, which are degradation products from cytokininoxidase activity. Incorporation of radioactivity in zeatin riboside was observed, although to a much lesser extent.     

Growth habit and sugar accumulation in sugarbeet (Beta vulgaris L.) transformed with a cytokinin biosynthesis gene

Expression of a bacterial cytokinin biosynthesis gene fused to a patatin gene promoter was studied in sugarbeet (Beta vulgaris L.). Two independent transformants, Pat-ipt 1 and 2, exhibited a number of distinguishable morphological alterations commonly induced by cytokinins, i.e. less root growth, reduced leaf surface area, and increased axillary shoot development. Concentrations of the cytokinins zeatin and zeatin riboside were increased by twofold in taproots and 7- to 18-fold in leaves. Leaf sucrose and glucose concentrations were not significantly different from those in control plants except in Pat-ipt 2 where glucose levels were elevated ninefold. Since normal taproot development was severely inhibited, sucrose concentrations in the taproots were significantly reduced.     

Potato transformation by T-DNA Cytokinin synthesis gene

Potato plants were transformed by the A.tumefaciens vector which integrates into the plant genome two foreign genes only: pTi C58 T-DNA gene 4 (ipt) responsible for elevated synthesis of cytokinins and kanamycin resistance gene. Three teratoma clones studied showed approximately 3 times, 6 times and 9 times increased levels of zeatin riboside and zeatin in comparison with untransformed controls and slight increase of the IAA level. Shoots formed roots in agar cultures sporadically, if the increase of zeatin riboside and zeatin levels was not higher than 6 times the control level. The chlorophyll content and net photosynthetic rate decreased with increasing levels of zeatin and zeatin riboside.     

Altered morphology in transgenic tobacco plants that overproduce cytokinins in specific tissues and organs.

An auxin-inducible bidirectional promoter from the soybean SAUR gene locus was fused to a reporter gene in one direction and a cytokinin biosynthetic gene in the opposite direction and the expression of these fused genes was examined in transgenic tobacco. The Escherichia coli uidA gene, which encodes the enzyme beta-glucuronidase (GUS), was used as the reporter gene and the Agrobacterium tumefaciens ipt gene, which encodes the enzyme isopentenyl transferase, was used as the cytokinin biosynthetic gene. These constructs allowed the overproduction of cytokinins in tobacco in a tissue- and organ-specific manner. Localized overproduction of cytokinins was monitored using the GUS reporter gene and measured by an ELISA assay. The tissue- and organ-specific overproduction of cytokinins produced a number of morphological and physiological changes, including stunting, loss of apical dominance, reduction in root initiation and growth, either acceleration or prolonged delayed senescence in leaves depending on the growth conditions, adventitious shoot formation from unwounded leaf veins and petioles, altered nutrient distribution, and abnormal tissue development in stems. While some of these morphological changes result directly from the localized overproduction of cytokinins, other changes probably result from the mobilization of plant nutrients to tissues rich in cytokinins.     

Efficient shoot regeneration from internodal explants of Populus angustifolia, Populus balsamifera and Populus deltoids

In the present study, interactions between the duration of treatment with auxin and different cytokinins and their effect on shoot regeneration were evaluated with the aim to establish a rapid and efficient in vitro regeneration method applicable to a variety of Populus species. Three different species, Populus angustifolia, P. balsamifera, and P. deltoids, were chosen for that purpose. We were successful in regenerating plantlets from stem and petiole explants from all three chosen species using a four-step simple procedure. The first step was callus induction when the explants were exposed to an auxin-rich medium for 0-20 days. During the second step, they were transferred onto a cytokinin-rich medium for shoot bud induction. In the third step, the shoots regenerated were transferred onto a medium with reduced levels of cytokinins to promote shoot proliferation and elongation; finally, in the fourth step, the shoots were rooted and acclimated. A short period (6-10 days) of time of exposure to auxin was sufficient for shoot regeneration. A culture time longer than ten days in callus induction medium drastically reduced the efficiency of shoot regeneration. Besides, cytokinin type and concentration also affected the frequency of shoot induction. A 0.2 mg/l concentration of 2,4-D for callus induction followed by 0.02 mg/l of Thidiazuron for shoot formation proved to be the best treatment for adventitious shoot bud multiplication, generating a maximum of 10-13 shoots of P. balsamifera and P. angustifolia in ten weeks. In contrast, for P. deltoids, a combination of 1.1mg/l 2,4-D, 1.0mg/l NAA, 0.1mg/l zeatin for callus induction followed by a combination of 1mg/l zeatin plus 1.0mg/l BA for shoot bud induction was found to be the most effective, generating on average 15 shoots over a period of ten weeks.     

Inhibitory effects of elevated endogenous cytokinins on nitrate reductase in ipt-expressing tobacco are eliminated by short-term exposure to benzyladenine

Using a novel system for expressing ipt gene from Agrobacterium tumefaciens in tobacco ( Nicotiana tabacum L., cv. Petit Havana SR1), we were able to grow seedlings and teratoma-like tissue with increased content of cytokinins. This material enabled us to investigate new regulatory aspects of nitrate reduction. We grew control plants and plants with elevated cytokinins on MS media, with or without nitrate and benzyladenine (BA). We determined in vitro nitrate reductase (EC 1.6.6.1) activity (NRA) in this plant material. Initially, we found that ipt -expressing plants always displayed lowered levels of NRA when compared to wild-type SR1 plants. We determined that long-term exposure of tobacco plants and tissue to cytokinins caused up to 60% decrease in NRA. Exposure to 40 m M nitrate was able to induce the activity in such plants 3-fold, increasing the activity in SR1 plants more than 5-fold. We were able to restore wild-type levels of NRA in ipt -expressing plants by simultaneous induction of NR with BA and nitrate. Our results suggest that regulation of NR by nitrate and cytokinin is a result of overlaying cytokinin-driven regulatory processes, with those acting in the short-term having a positive effect on NRA, and those acting over extended periods of time having inhibitory effects on NRA.     

Phenotypes of Tobacco Plants Expressing Genes for the Synthesis of Growth Regulators

The expression of genes for synthesis of auxin (iaaM and iaaH) and cytokinins (ipt) was studied in tobacco plants transformed by two Agrobacterium tumefaciens strains C 58 and LBA 4404. The strain LBA 4404 carried binary vector plasmid pCB 1334 (ipt gene) and plasmid pCB 1349 (iaaM, iaaH and ila genes). Both plasmids carried reportered gene for npt II. Obtained plants expressed incorporated genes. New proteins with molecular masses of about 74, 40, 26, 25, 21 and 17 kDa for wild plasmid pTi C58; 60, 36, 31.5, 27, 26 and 17 kDa for binary vector plasmid pCB 1334 and 74, 49, 36, 31.5, 26 and 25 kDa for binary vector plasmid pCB 1349 were found in the patterns of soluble proteins. Significant changes in the content of chlorophylls, especially chlorophyll a, were detected in the plants carrying ipt gene and in plants transformed by the wild strain C58 of A. tumefaciens. Tobacco plants expressing ipt gene and genes from T-DNA of pTi C58 plasmid were dwarf, and in comparison to the controls, they had thicker stems, and the surface of the leaf blades was reduced to 20 - 50 %. Adventitious roots, growing from the stem, were typical for transformants overproducing auxins. Regenerants and transformants expressing genes from T-DNA of plasmid pTi C58 differed in the shape of the flowers and their fertility. This revised version was published online in July 2006 with corrections to the Cover Date.     

Inducible isopentenyl transferase as a high-efficiency marker for plant transformation.

Overexpression of the isopentenyltransferase gene (ipt) from the Ti-plasmid of Agrobacterium tumefaciens increases cytokinin levels, leading to generation of shoots from transformed plant cells. When combined with a dexamethasone-inducible system for controlling expression, ipt expression can be used to select for transgenic regenerants without using an antibiotic-resistance marker. The combined system allows efficient cointroduction of multiple genes (in addition to ipt) and produces transgenic plants without morphological or developmental defects.     

种子特异表达ipt转基因棉花根和纤维的改变

将种子特异表达的菜豆蛋白启动子（Ｐｈ／Ｐ）与ｉｐｔ基因融合,构建了植物表达载体。该载体含有由３５Ｓ启动子驱动的ｇｕｓ报告基因。应用该载体通过花粉管通道法转化棉花（Ｇｏｓｓｙｐｉｕｍ ｈｉｒｓｕｔｕｍ Ｌ．）,种子萌发后剪取幼根进行ＧＵＳ染色,获得ＧＵＳ阳性植株２３棵。ＰＣＲ检测证明有３棵ＧＵＳ阳性植株中含有Ｐｈ／Ｐ－ｉｐｔ基因,并进一步用地高辛标记的ＤＮＡ探针作杂交验证了上述结果。分析表明２棵转基     

Influence of benzimidazole on callus growth and shoot formation on callus cultures

The influence of benzimidazole on callus growth and shoot formationin vitro was examined. At concentrations of 8.5 x 10^–4mMto 8.5 x 10^–1mM benzimidazole failed to stimulate callusgrowth or shoot formation. Concentrations of 0.85 mM and 1.7mM inhibited kinetin-dependent callus growth while lower concentrationswere without effect. It may be inferred that benzimidazole hasno cell division properties such as is associated with the cytokinins,though it mimics, in appearance, cytokinins actions in severalphysiological processes. (Received August 12, 1975; )     

The molecular path to in vitro shoot regeneration

Plant regeneration through de novo shoot organogenesis in tissue culture is a critical step in most plant transformation and micropropagation procedures. Establishing an efficient regeneration protocol is an empirical process and requires optimization of multiple factors that influence the regeneration capacity. Here, we review the molecular process of shoot induction in a two-step regeneration protocol and focus on the role of auxins and cytokinins. First, during incubation on an auxin-rich callus induction medium (CIM), organogenic callus is produced that exhibits characteristics of a root meristem. Subsequent incubation on a cytokinin-rich shoot induction medium (SIM) induces root to shoot conversion. Through a detailed analysis of the different aspects of shoot regeneration, we try to reveal hinge points and novel candidate genes that may be targeted to increase shoot regeneration capacity in order to improve transformation protocols.     

Effects of cytokinins and injury on the formation of shoot buds by leaves of Dendrophthoe falcata

Summary A number of cytokinins induce shoot buds on leaves obtained from embryonal tissue (diploid) or endosperm tissue (triploid) of Dendrophthoe falcata cultured in vitro. The buds develop either by division of an epidermal cell which finally is organized into a shoot meristem; or the epidermal cell first produces a callus which subsequently gives rise to shoot buds. Buds do not develop in the absence of cytokinins. Injury to the leaf plays a major role in the distribution and number of shoot buds formed. Normal leaves on the plant do not regenerate buds even in the presence of a cytokinin.     

Adventitious shoot regeneration from immature embryos of sorghum

Eleven genotypes of sorghum were examined for their response in tissue culture, and the tissue culture system was optimized. The cultures were initiated from immature embryos taken approximately two weeks after flowering. The response of immature embryos varied with the genotype. `C. Kafir' and `PE932 025' showed the highest frequency of callus induction and regenerable callus formation under appropriate culture conditions. Regeneration occurred at high frequencies when cytokinins (kinetin or 6-benzyladenine) had been added in the callus induction medium, followed by regeneration medium devoid of growth regulators. The addition of proline and polyvinylpyrrolidone also enhanced shoot formation, but the addition of cytokinins to regeneration media did not improve shoot formation. On the revised culture medium, plants were regenerated from up to 100% of sorghum immature embryos.     

Cytokinin Differences in In Vitro Cultures and Inflorescences from Normal and Mantled Oil Palm (Elaeis guineensis Jacq.)

The mantled abnormality phenotype of the oil palm affects fruit development and thus jeopardizes oil yield. Cytokinins have been implicated in the development of the mantled phenotype. Endogenous cytokinin levels in the normal and mantled phenotypes were compared to determine whether levels of specific cytokinins are associated with mantling. Endogenous cytokinins were identified and quantified in in vitro cultures and inflorescences from normal and mantled oil palms. Twenty-two isoprenoid cytokinins, comprising the zeatin, dihydrozeatin, and isopentenyladenine types, were quantified. Total cytokinin levels, particularly of trans-zeatin and isopentenyladenine types, increased during the in vitro culture process, with the highest levels detected at the proliferating polyembryoid stages. The cytokinins were present mainly in their inactive 9-glucoside forms during in vitro culture. On the other hand, the predominant trans-zeatin cytokinins in inflorescences were present mainly in their ribotide forms, suggesting a metabolic pool of cytokinins for conversion to biologically active free bases or ribosides. Levels of specific cytokinins were significantly different in tissues at different stages. Mantled developed inflorescences contained higher levels of isopentenyladenine 9-glucoside compared with normal inflorescences. Mantled-derived callus tissues had higher isopentenyladenine levels but significantly lower levels of trans-zeatin 9-glucoside, dihydrozeatin riboside, and dihydrozeatin riboside 5′-monophosphate cytokinins compared with normal-derived callus. It would be of considerable interest to verify these specific cytokinin differences in more callus cultures and clones.