An improved bioassay for cytokinins using cucumber cotyledons

The cucumber cotyledon greening bioassay is frequently used for detecting cytokinins. Beneficial modifications of the original technique included using 5-day-old cucumber (Cucumus sativus L., cv. National Pickling) cotyledons treated with combinations of 40 millimolar KCl and various concentrations of cytokinins. A dark incubation period of 20 hours was followed by an exposure to light for 3.5 hours. Under these conditions, extremely low (0.0001 milligram per liter) concentrations of N⁶-benzyladenine, zeatin, kinetin, or zeatin riboside can be detected. Of the four cytokinins tested, kinetin appeared to be the least active. With these improvements, the assay is 10 times more sensitive than is the previously described cucumber cotyledon greening bioassay for cytokinins.     

Development of transgenic tobacco harboring a zeatin O-glucosyltransferase gene from Phaseolus

Summary Zeatin and its derivatives are major consituents of higher plant cytokinins. Metabolic steps modifying the isoprenoid side chain, such as O-glycosylation, are expected to have a direct bearing on cytokinin-mediated processes. To examine this possibility, transgenic tobacco plants were generated harboring a gene (ZOG1) encoding a zeatin O-glucosyltransferase from Phaseolus lunatus under the control of a constitutive (35S) and an inducible (Tet) promoter. The presence of the transgene resulted in elevated enzyme production and conversion of exogenous zeatin to its O-glucoside, confirming the expression of the ZOG1 gene in transgenic plants. Endogenous O-glucosylzeatin was increased from less than 1 pmol per g fresh weight in leaves and roots of controls to 26 and 68 pmol per g fresh weight in leaves and roots of 35S-ZOG1 transformants, respectively. In cytokinin/auxin interaction experiments, Tet-ZOG1 leaf discs, in the presence of tetracycline, required 10-fold higher zeatin concentrations for the formation of shoots and callus than the controls. In 35S-ZOG1 plants, developmental changes included adventitious root formation on the lower stems, shorter stature, and axillary shoot growth. Thus, increased zeatin O-glucosylation in detached, cytokinin-dependent tissues leads to a shift in the response to exogenous zeatin indicative of cytokinin sequestering. In whole plants the effect can simulate a reduction or a rise in cytokinin activity depending on the tissue and stage of development. The use of tissue- and stagespecific promoters in the future will allow more precise analyses and targeted growth alterations.     

Isolation of Legume Glycosyltransferases and Active Site Mapping of the <Emphasis Type="Italic">Phaseolus lunatus</Emphasis> Zeatin O-glucosyltransferase ZOG1

O-Glycosides of the cytokinin zeatin are found in many plant tissues. They provide protection against degradative enzymes and may serve as cytokinin reserves. Two zeatin glycosyltransferase (GT) genes, an O-glucosyltransferase (ZOG1) from Phaseolus lunatus and an O-xylosyltransferase (ZOX1) from P. vulgaris, were previously isolated. Five novel bean and soybean GT genes with high sequence identity to ZOG1 were isolated, sequenced, and expressed, along with two such genes from rice and one from tomato. None of the recombinant proteins showed GT activity with zeatin. By comparing the ZOG1 sequence to the 3D model of Medicago truncatula UGT71G1, four regions possibly important to zeatin binding were identified, and mutation studies identified one amino acid within each region (R59, D87, L127, and F149) whose mutation strongly impaired enzyme activity. The new bean and soybean GTs differ from ZOG1 in one (PlGT2 and GmGT2) to three (GmGT1) of these residues. Mutation of one such GT (PlGT2) to render it identical to ZOG1 at the four implicated residues conferred low enzyme activity, providing further support for the importance of these amino acids in recognizing zeatin as substrate. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Substrate specificity and domain analyses of zeatin O-glycosyltransferases

The substrate specificity of two recombinant enzymes, zeatin O-glucosyltransferase 1 (ZOG1) and zeatin O-xylosyltransferase 1 (ZOX1), was further characterised. ZOG1 utilises zeatin (Z), UDPG, and UDPX as substrates to form O-glucosylzeatin (OGZ) and O-xylosylzeatin (OXZ) but has higher affinity to UDPG than UDPX. ZOX1 uses only UDPX, converting Z to OXZ. Dihydrozeatin (DHZ) is also a substrate for both enzymes, but only in combination with UDPX, giving rise to O-xylosyldihydrozeatin (OXDHZ). O-Glucosyldihydrozeatin (OGDHZ) is not formed by ZOG1, possibly due to steric hindrance. Regions relevant to UDPG/UDPX affinity and competition were identified using hybrid enzymes derived from domain exchanges of parental genes. The N-terminal half of the enzyme is important in this respect. The BstEII-BstAPI segment of ZOG1 correlates with inhibition of O-xylosyltransferase activity by UDPG while the BstAPI-Eco0109 segment of ZOG1 is required for utilisation of UDPG as the sugar donor.     

Phytohormones,Rhizobium mutants,and nodulation in legumes. VII. Identification and quantification of cytokinins in effective and ineffective pea root nodules using radioimmunoassay

Radioimmunoassays (RIA), employing antisera raised in rabbits against bovine serum albumin conjugates of zeatin riboside, dihydrozeatin riboside, and isopentenyladenosine, were used to estimate levels of these cytokinins and their corresponding bases in samples of effective (nitrogen-fixing, Fix⁺), ineffective (nonnitrogen-fixing, Fix^–) pea root nodules and uninoculated roots. Assays were done on extracts of nodule tissue, 1–2 g fresh weight, or approximately 10 g fresh weight of root tissue, and high specific activity [³H]zeatin riboside was added during preparation of the extract for use as a recovery marker. Two different purification procedures were employed, each involving several purification steps. High performance liquid chromatography (HPLC) was the final step in both procedures. Fractions from HPLC were analyzed by RIA using the appropriate antiserum. The cytokinins, zeatin, zeatin riboside, dihydrozeatin riboside, isopentenyl adenine, and isopentenyladenosine were detected and quantified in nodule tissue, and similarly, in root tissue (with the exception of zeatin, which we were unable to quantify in root tissue). Cytokinin levels in nodule tissue were higher than those in root tissue. The major cytokinins detected in nodule tissue were zeatin, followed by zeatin riboside and then dihydrozeatin riboside. The levels of zeatin and zeatin riboside estimated in nodules in the present study by RIA were of the same order of magnitude, though tending to be a little higher, than values obtained previously by bioassay. Dihydrozeatin riboside was identified with confidence for the first time in nodule tissue. There was a general decline with age in cytokinin levels in nodules, but no major qualitative change in nodule cytokinins with age. For theRhizobium strains examined, the data did not indicate a clear correlation between nodule cytokinin levels and the effectiveness of nodules in nitrogen fixation.     

Changes in Concentrations of Cytokinins (CKs) in Root and Axillary Bud Tissue of Miniature Rose Suggest that Local CK Biosynthesis and Zeatin-Type CKs Play Important Roles in Axillary Bud Growth

Involvement of cytokinins (CKs) in axillary bud growth of miniature rose was studied. Variation in root formation and axillary bud growth was induced by two indole 3-butyric acid (IBA) pretreatments in two cutting sizes. At six physiological developmental stages around the onset of axillary bud growth, concentrations of CKs were determined in both root and axillary bud tissue by liquid chromatography combined with electrospray tandem mass spectrometry (LC-ESP-MS/MS). Chronological early onset of axillary bud growth occurred in long cuttings pretreated at low IBA concentration, whereas physiological early root formation was associated with long cuttings and high IBA concentration. The CKs zeatin (Z), isopentenyl adenine (iP), zeatin riboside (ZR), dihydrozeatin riboside (DHZR), isopentenyl adenosine (iPA), zeatin O-glucoside (ZOG), zeatin riboside O-glucoside (ZROG), zeatin riboside 5′-monophosphate (ZRMP), and isopentenyl adenosine 5′-monophosphate (iPAMP) were detected. Concentrations of CKs in axillary bud tissue far exceeded those in root tissue. Indole 3-butyric acid pretreatment influenced the concentration of CKs in axillary bud tissue more than did cutting size, whereas pretreatments only slightly affected CKs in root tissue. The dominant CKs found were iPAMP and ZR. An early and large increase in iPAMP indicated rapid CK biosynthesis in rootless cuttings, suggesting that green parts, including the axillary bud, can synthesize CKs. At the onset of axillary bud growth an increase in concentration of Z, ZR, ZRMP, ZOG, and ZROG was largely coincident with a decrease in iPAMP, iPA, iP, and DHZR. After the onset of axillary bud growth, CK content largely decreased. These results strongly indicate a positive role for CKs in axillary bud growth, and presumably ZRMP, ZR, and Z are active in miniature rose.     

6-(2, 3, 4-Trihydroxy-3-methylbutylamino)purine,a cytokinin with high biological activity

6-(2, 3, 4-Trihydroxy-3-methylbutylamino)purine, isolated from the oxidation of cis- zeatin with potassium permanganate, has been identified by ¹H NMR and high resolution mass spectrometry. Its activity as a cell division factor, when examined by the soybean callus assay in the concentration range 10^?11–10^?5 M, equalled that of the parent compound.     

Phytohormones, Rhizobium mutants, and nodulation in legumes : v. Cytokinin metabolism in effective and ineffective pea root nodules

[³H]Zeatin riboside was supplied to intact pea (Pisum sativum) plants either onto the leaves or onto the root nodules. When applied directly to nodules, approximately 70% of recovered radioactivity remained in the nodules, approximately 15% was detected in the root system, and 15% was in the shoot. However, when supplied to the leaves, little ³H was transported, with approximately 0.05% of recovered radioactivity being found in the root system and nodules. On a fresh weight basis, nodules accumulated more ³H than the parent root. In both types of studies, metabolites with an intact zeatin moiety were detected in root nodules.

In all experiments, two-dimensional thin layer chromatography revealed that little ³H remained as zeatin riboside in root or nodule tissue at the end of the labeling period. Nodules metabolized [³H]zeatin riboside to the following cytokinins/cytokinin metabolites: zeatin, adenosine, adenine, the O-glucosides of zeatin and zeatin riboside, lupinic acid, nucleotides of adenine and zeatin, and the dihydro derivatives of many of these compounds.

Although a few small differences were observed, there were no major differences between root and nodule tissue in their metabolism of [³H] zeatin riboside. Furthermore, any differences between effective and ineffective nodules were generally minor.

     

Phytohormones,Rhizobium mutants,and nodulation in legumes. VI. Metabolism of zeatin riboside applied via the tips of nodulated pea roots

[³H]zeatin riboside was supplied in physiological quantities to pea (Pisum sativum L. cv Greenfeast) plants by replacing the root tip with a small vial containing [³H]zeatin riboside, to simulate the normal supply of cytokinin. Radioactivity was transported to the root nodules. Analysis by two-dimensional thin layer chromatography revealed that little³H remained as zeatin riboside in root or nodule tissue at the end of the labeling period (2, 5, or 8 d) and suggested that the following compounds were metabolites of [³H]zeatin riboside: zeatin, adenosine, adenine, the O-glucosides of zeatin and zeatin riboside, nucleotides of adenine and zeatin, and the dihydro-derivatives of many of these compounds. The O-glucosides (and in particular, O-β-D-glucopyranosyl-9-β-D-ribofuranosylzeatin) appeared to be more prominent metabolites in the effective nodules formed by strain ANU897 than in the ineffective nodules produced by strain ANU203. However, no other appreciable differences were detected between effective and ineffective nodules in their metabolism of zeatin riboside. There were few marked differences between root and nodule tissue; however, in some experiments, the nodules contained a higher proportion of O-glucoside metabolites, and generally root tissue contained a greater proportion of zeatin and/or dihydro-zeatin, zeatin riboside and/or dihydrozeatin riboside, adenine and the nucleotides of zeatin and adenine, as metabolites.     

Changes in Cytokinins before and during Early Flower Bud Differentiation in Lychee (Litchi chinensis Sonn.)

Lychee (Litchi chinensis) has been analyzed for cytokinins in buds before and after flower bud differentiation, using reversephase high performance liquid chromatography in combination with Amaranthus bioassay and gas chromatography-mass spectrometry-selected ion monitoring. Four cytokinins, zeatin, zeatin riboside, N⁶-(δ²-isopentenyl)adenine, and N⁶-(δ⁶-isopentenyl) adenine riboside, were detected in buds. There was an increase of cytokinin activity in the buds during flower bud differentiation. In dormant buds, the endogenous cytokinin content was low, and the buds did not respond to exogenous cytokinin application. Application of kinetin promotes flower bud differentiation significantly after bud dormancy. These results are interpreted as an indication that the increase in endogenous cytokinin levels during flower bud differentiation may be correlative rather than the cause of flower bud initiation.     

Active cytokinins: photoaffinity labeling agents to detect binding

Four series of azidopurines have been synthesized and tested for cytokinin activity in the tobacco callus bioassay: 2- and 8-azido-N⁶-benzyladenines, -N⁶-(Δ²-isopentenyl)adenines, and -zeatins, and N⁶-(2- and 4-azidobenzyl)adenines. The compounds having 2-azido substitution on the adenine ring are as active as the corresponding parent compounds, while those with 8-azido substitution are about 10 or more times as active. The 8-azidozeatin, which is the most active cytokinin observed, exhibited higher than minimal detectable activity at 1.2 × 10⁻⁵ micromolar, the lowest concentration tested. The shape of the growth curve indicates that even a concentration as low as 5 × 10⁻⁶ micromolar would probably be effective. By comparison, the lowest active concentration ever reported for zeatin has been 5 × 10⁻⁵ micromolar, representing a sensitivity rarely attained.     

Bioassay and attributes of a growth factor associated with crown gall tumors

An improved bioassay is described for a factor that promotes tumor growth which was first obtained from extracts of pinto bean leaves with crown gall tumors. Sixteen primary pinto bean leaves per sample are inoculated with sufficient Agrobacterium tumefaciens to initiate about 5 to 10 tumors per leaf and treated with tumor growth factor at day 3 after inoculation. The diameters of 30 to 48 round tumors (no more than 3 randomly selected per leaf) are measured per test sample at day 6. Mean tumor diameter increased linearly with the logarithm of the concentration of tumor growth factor applied. The tumor growth factor was separated by column chromatography from an ultraviolet light-absorbing compound previously reported to be associated with fractions having maximal tumor growth factor activity. Partly purified tumor growth factor showed no activity in a cytokinin bioassay or an auxin bioassay, and negligible activity in gibberellin bioassays. Representatives of these three classes of growth factors did not promote tumor growth. Extracts from crown gall tumors on primary pinto bean leaves, primary castor bean leaves, Bryophyllum leaves, carrot root slices, and tobacco stems showed tumor growth factor activity, whereas extracts from healthy control tissues did not. Extracts from actively growing parts of healthy pinto beans, Bryophyllum, and tobacco, however, showed tumor growth factor activity. Tumor growth factor is proposed to be a normal plant growth factor associated with rapidly growing tissues. Its synthesis may be activated in nongrowing tissues by infection with Agrobacterium sp.     

Ceramide in Rice Grain

A rice lamina inclination test that is simple and specific for brassinosteroids was used as a micro-quantitative bioassay for brassinolide 1 and its 6-keto congener, castasterone 2, in the concentration range of 5 x 10^–5 /ig/ml to 5 x 10^–3μg/ml, when uniform seedlings of the rice cultivars Arborio J-l and Nihonbare were selected. A phytohormone, indole-3-acetic acid (IAA), showed similar activity in this bioassay. Its lowest effective concentration, however, was 50 /ig/μl, about five orders of magnitude greater than that of brassinolide. Other phytohormones, abscisic acid (ABA) and the cytokinins kinetin and A⁶-benzyladenine, inhibited the lamina inclination of rice seedlings. The addition of a cytokinin reduced the promoting effect of brassinolide. Thus, the rice lamina inclination test can be used both as a micro-quantitative bioassay for brassinosteroids and as a method for detecting antibrassinolide compouds.     

Mass spectrometric measurement of zeatin glycoside levels in Vinca rosea L. crown gall tissue

The range of zeatin glycosides found in crown gall tissue of Vinca rosea L. has been quantified using a mass spectrometric isotope dilution procedure. Problems in the quantitative analysis of cytokinins in plant extracts are discussed.Abbreviations GC/MS coupled gas chromatography-mass spectrometry - HPLC high-performance liquid chromatography - Me methyl - Z zeatin - Z9G zeatin 9-glucoside - ZOG zeatin O-glucoside - ZR zeatin 9-riboside - ZROG zeatin 9-riboside O-glucoside     

Cytokinins in the Phloem Sap of White Lupin (Lupinus albus L.)

Cytokinin-like activity in samples of xylem and phloem sap collected from field-grown plants of white lupin (Lupinus albus L.) over a period of 9 to 24 weeks after sowing was measured using the soybean hypocotyl callus bioassay following paper chromatographic separation. The phloem sap was collected from shallow incisions made at the base of the stem, the base of the inflorescence (e.g. stem top), the petioles, and the base and tip of the fruit. Xylem sap was collected as root exudate from the stump of plants severed a few centimeters above ground level. Concentration of cytokinin-like substances was highest in phloem sap collected from the base of the inflorescence and showed an increase over the entire sampling period (from week 10 [61 nanogram zeatin equivalents] to week 24 [407 nanogram zeatin equivalents]). Concentrations in the xylem sap and in the other phloem saps were generally lower. Relatively high concentrations of cytokinin-like substances in petiole phloem sap (70 to 130 nanogram zeatin equivalents per milliliter) coincided in time with high concentrations in sap from the base of the inflorescence (see above). Concentrations in sap (phloem or xylem) from the base of the stem were very much lower. This finding is consistent with movement of cytokinins from leaves into the developing inflorescence and fruit, rather than direct input to the fruit from xylem sap. However, an earlier movement of cytokinins from roots into leaves via the xylem cannot be ruled out. Sap collected at an 18-week harvest was additionally separated by sequential C₁₈ reversed-phase high performance liquid chromatography → NH₂ normal phase high performance liquid chromatography, bioassayed, and then analyzed by electron impact gas chromatography-mass spectrometry. Identification of zeatin riboside and dihydrozeatin as two of the major cytokinins in combined sap samples was accomplished by gas chromatography-mass spectrometry-selected ion monitoring.     

Physiology and biochemistry of theAmaranthus cytokinin bioassay and its applications

The influence of some substances on the amaranthin biosynthesis inAmaranthus-seedlings was investigated with regard to the accuracy and sensitivity of theAmaranthus cytokinin bioassay. 1) The herbicide glyphosate inhibited plgment formation in a concentration of 10^-4 mol 1^-1 in most cases only slightly (approximately 10–25 %). 2) Shikimic acid does not seem to be a precursor, in many experiments it was slightly inhibitory. 3) Jasmonic acid promoted slightly the plgment formation with a distinct maximum at about 5 x 10^-4 mol 1^1-. 4) The oxidation product of zeatin (with KMnO₄) is not active in theAmaranthus bioassay; only weak activity was recorded at very high concentrations. 5) Glucosides, extracted fromGinkgo biloba leaves, stimulate amaranthin synthesis, as we could conclude from applications of this bioassay to senescing, abscisingGinkgo leaves. Presented at the International Symposium “Plant Growth Regulators” held on June 18–22, 1984 at Liblice, Czechoslovakia.     

The metabolism of 6-(2,3,4-trihydroxy-3-methylbutylamino) purine by soybean callus

6-(2,3,4-trihydroxy-3-methylbutylamino) purine (trihydroxyzeatin) applied to soybean callus is metabolised slowly. After 48 h only one peak of biological activity which co-eluted with the applied cytokinin was detected. When the callus was incubated on a medium which contained 10^–5 M trihydroxyzeatin, spiked with 8 {¹⁴C} trihydroxyzeatin, for 28 days, three peaks of biological activity and three peaks of radioactivity were detected. One of the biologically active and radioactive peaks co-eluted with zeatin. Another of the radioactive peaks co-eluted with N-(purin-6-yl) glycine. From the data obtained it apears that trihydroxyzeatin can be both oxidized and reduced by soybean callus. The potential to be converted to zeatin may explain why trihydroxyzeatin and its parent compound, which is usually rapidly metabolised by living material, are equally active in the soybean callus bioassay. From the radioactive data obtained it appears that trihydroxyzeatin is susceptible to oxidation to form N-(purin-6-yl) glycine.     

Investigation on the role of nodule cytokinins in regulation of nitrate reductase activity ofPhaseolus mungo (L.)

The effects of some nodular cytokinis, zeatin (Z), zeatin riboside (ZR), N⁶ (Δ²-isopentenyl) adenine (IPA), and N⁶ (Δ²-isopentenyI) adenosine (IPAS) on nitrate reductase (E.C 1.9.6.1) activity of root nodules ofPhaseolus mungo were investigated. The cytokinis were also tested for their effect on nitrate uptake by nodules. The results show that IPAS is the most effective of all the four cytokinins tested. Z and IPA, which caused higherin vivo activity than ZR and IPAS, stimulated uptake of nitrate by nodules. The other two (ZR and IPAS) while inhibiting uptake showed greaterin vitro activity than Z and IPA. It may be concluded that some cytokinins, in addition to their direct effects on the enzyme, may increase the substrate availability to it, whereas others may have only an direct effect on the enzyme activation or degradation.     

Phytohormones,Rhizobium mutants, and nodulation in legumes. VI. Metabolism of zeatin riboside applied via the tips of nodulated pea roots

[³H]zeatin riboside was supplied in physiological quantities to pea (Pisum sativum L. cv Greenfeast) plants by replacing the root tip with a small vial containing [³H]zeatin riboside, to simulate the normal supply of cytokinin. Radioactivity was transported to the root nodules. Analysis by two-dimensional thin layer chromatography revealed that little³H remained as zeatin riboside in root or nodule tissue at the end of the labeling period (2, 5, or 8 d) and suggested that the following compounds were metabolites of [³H]zeatin riboside: zeatin, adenosine, adenine, the O-glucosides of zeatin and zeatin riboside, nucleotides of adenine and zeatin, and the dihydro-derivatives of many of these compounds.The O-glucosides (and in particular, O--D-glucopyranosyl-9--D-ribofuranosylzeatin) appeared to be more prominent metabolites in the effective nodules formed by strain ANU897 than in the ineffective nodules produced by strain ANU203. However, no other appreciable differences were detected between effective and ineffective nodules in their metabolism of zeatin riboside. There were few marked differences between root and nodule tissue; however, in some experiments, the nodules contained a higher proportion of O-glucoside metabolites, and generally root tissue contained a greater proportion of zeatin and/or dihydro-zeatin, zeatin riboside and/or dihydrozeatin riboside, adenine and the nucleotides of zeatin and adenine, as metabolites.     

Cytokinins of the Developing Mango Fruit : Isolation, Identification, and Changes in Levels during Maturation

The cytokinin activity has been isolated and identified from extracts of immature mango (Mangifera indica L.) seeds. The structures of zeatin, zeatin riboside, and N⁶-(Δ²-isopentenyl)adenine riboside were confirmed on the basis of their chromatographic behavior and mass spectra of trimethylsilyl derivatives. Both trans and cis isomers of zeatin and zeatin riboside were also identified by the retention times of high performance liquid chromatography. In addition, an unidentified compound appeared to be a cytokinin glucoside.

The concentration of cytokinins in the panicle and pulp of mango reached a maximum 5 to 10 days after full bloom and decreased rapidly thereafter. The cytokinin level in the seed remained high until the 28th day after full bloom. The quantity of cytokinins in pulp per fruit increased from the 10th day after full bloom, the maximum being attained around the 50th day after full bloom. Similarly, the amount of cytokinins per seed increased from the 10th day after full bloom, reaching a peak on the 40th day and decreasing gradually thereafter.

A high percentage of fruit set in mango was persistently maintained by supplying 6-benzylaminopurine (1.5 × 10³ micromolar) onto the panicle at the anthesis stage and by supplying gibberellic acid (7.2 × 10² micromolar) and naphthalene acetamide (3.1 × 10 micromolar) at the young fruit stage.