Effect of cytokinins supplied via the xylem at multiples of endogenous concentrations on transpiration and senescence in derooted seedlings of oat and wheat

This study was conducted lo determine whether naturally occurring xylem cytokinins, when supplied to leaves via the xylem at approximately endogenous concentrations, increase transpiration and delay senescence in selected monocot species (oat and wheat). The concentrations of some of the major cytokinins (zeatin, dihydrozeatin, ciszeatin and their ribosides, the O-glucosides and nucleotides) were determined in the xylem exudate of oat and wheat seedlings by radioimmunoassay. Evidence is presented that the small volume of exudate (4–5 mm³) collected per plant was xylem sap in transit at the time of shoot excision. Using the data on cytokinin levels, the individual bases and ribosides (and a base/riboside mixture), at multiples of concentrations determined in xylem sap, were tested in transpiration and senescence bioassays. The individual O-glucosides (and mixtures of the O-glucosides) were similarly tested at (i) multiples of the molar concentrations of the corresponding bases and ribosides, and/or at (ii) multiples of the endogenous concentrations. Similarly, zeatin and dihydrozeatin nucleotides were tested at multiples of the molar concentration of zeatin riboside and, in some instances, at multiples of endogenous concentrations. Our results suggest that, at least in oat and possibly in wheat, zeatin-type bases, ribosides and O-glucosides supplied to the leaf in xylem sap are likely to play a role in regulating transpiration in vivo. O-glucosides in oat xylem sap may be important regulators of leaf senescence in the intact plant. The nucleotides were present in xylem sap at lower concentrations than most of the bases, ribosides and O-glucosides. The nucleotides appear likely to play a lesser role than the bases, riboside and O-glucosidcs in controlling transpiration and senescence in the intact plant.     

Hormonal Control of the Shoot-to-Root Ratio Is Not Related to Water Deficiency in Wheat Plants under Mineral Deficiency

We measured the content of hormones, the rate of growth, and some parameters of water regime (water content, transpiration, and stomatal and hydraulic conductivities) one and two days after wheat plant transfer from 10 to 1% Hoagland-Arnon nutrient medium. It was shown that, a day after dilution of nutrient solution, the content of various cytokinin forms decreased in the xylem sap, shoots, and roots. This decrease was most pronounced in the case of zeatin in the xylem sap and zeatin riboside in the mature zone of the first leaf. ABA was found to accumulate in shoots. A day after dilution of nutrient solution, we observed root elongation evidently induced by mineral nutrient deficiency, and this accelerated root growth was maintained later. Two days after dilution of nutrient solution, we observed the slowing of shoot weight accumulation, whereas root weight remained unchanged. Plant growth response could be related to ABA accumulation in shoots and cytokinin depletion in the whole plant. A reduced hydraulic conductivity and water content in the growing leaf zone was detected only two days after dilution of nutrient solution. Thus, changes in the growth rates and hormone contents could not result from disturbances in water regime induced by mineral nutrient deficiency.     

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.     

The Metabolism and Translocation of Zeatin in Intact Radish Seedlings

After the roots of intact radish seedlings had taken up [³H]zeatinfor 1 h, the seedlings were transferred to nutrient lackingzeatin and extracted at intervals. After 23 h in the absenceof zeatin, 6 per cent of the radioactivity extracted per seedlingwas recovered from the de-ribbed cotyledon laminae, 4 per centfrom the hypocotyls, and 87 per cent from the roots. Per unitweight of tissue, the radioactivity extracted from the rootwas about 40 times that recovered from any other region. Zeatin was rapidly metabolized by the root tissue, and 4 to9 h after transfer of the seedlings to nutrient lacking zeatin,accounted for a negligible proportion of the radioactivity.Initially zeatin riboside 5'-monophosphate was the principalroot metabolite, but after 9 h, 7-glucosylzeatin (raphanatin)was the dominant metabolite. Conversion of zeatin to dihydrozeatinwas not detected. Raphanatin was also the major metabolite inthe cotyledon laminae where some free zeatin was detectable.The principal metabolites in hypocotyl extracts were AMP andzeatin riboside 5'-monophosphate but zeatin riboside was theonly significant source of radioactivity in the xylem sap. When [³H]zeatin was applied directly to cotyledon laminae, 99per cent of the radioactivity was localized in the treated laminae;however traces of zeatin were detected in the roots. In radish seedlings, zeatin riboside appears to be the translocationalform of zeatin, while raphanatin may be a storage form.     

Effect of partial rootzone drying on the concentration of zeatin-type cytokinins in tomato (Solanum lycopersicum L.) xylem sap and leaves

Decreased cytokinin (CK) export from roots in drying soil might provide a root-to-shoot signal impacting on shoot physiology. Although several studies show that soil drying decreases the CK concentration of xylem sap collected from the roots, it is not known whether this alters xylem CK concentration ([CK(xyl)]) in the leaves and bulk leaf CK concentration. Tomato (Solanum lycopersicum L.) plants were grown with roots split between two soil columns. During experiments, water was applied to both columns (well-watered; WW) or one (partial rootzone drying; PRD) column. Irrigation of WW plants aimed to replace transpirational losses every day, while PRD plants received half this amount. Xylem sap was collected by pressurizing detached leaves using a Scholander pressure chamber, and zeatin-type CKs were immunoassayed using specific antibodies raised against zeatin riboside after separating their different forms (free zeatin, its riboside, and nucleotide) by thin-layer chromatography. PRD decreased the whole plant transpiration rate by 22% and leaf water potential by 0.08 MPa, and increased xylem abscisic acid (ABA) concentration 2.5-fold. Although PRD caused no detectable change in [CK(xyl)], it decreased the CK concentration of fully expanded leaves by 46%. That [CK(xyl)] was maintained and not increased while transpiration decreased suggests that loading of CK into the xylem was also decreased as the soil dried. That leaf CK concentration did not decline proportionally with CK delivery suggests that other mechanisms such as CK metabolism influence leaf CK status of PRD plants. The causes and consequences of decreased shoot CK status are discussed.     

Cytokinin biochemistry in relation to leaf senescence. VIII. Translocation, metabolism and biosynthesis of cytokinins in relation to sequential leaf senescence of tobacco

Cytokinin bases (zeatin and dihydrozeatin) and ribosides (zeatin riboside and dihydrozeatin riboside) were identified as major cytokinins in tobacco xylem sap by radioimmunoassay. When ³H-labelled zeatin riboside or dihydrozeatin riboside were supplied to tobacco plants via the xylem, leaves of differing maturity did not differ appreciably in level of radioactivity or in metabolism of the cytokinin. The major metabolites of zeatin riboside in leaves were adenine, adenosine and adenine nucleotides, whereas that of dihydrozeatin riboside was dihydrozeatin 7-glucoside. Incorporation of [¹⁴C]adenine into zeatin was evident in upper green leaves. indicating that young leaves have the capacity to synthesize cytokinins in situ. In contrast, fully expanded green leaves and senescing tobacco leaves exhibited little or no incorporation of [¹⁴C]adenine into cytokinins. This difference in cytokinin biosynthetic capacity may contribute to the differing cytokinin levels in leaves of different matirity, and may participate in control of sequential leaf senescence in tobacco.     

Radioimmunoassay for quantifying the cytokininscis-zeatin andcis-zeatin riboside and its application to xylem sap samples

An antiserum against the cytokinincis-zeatin riboside was raised in rabbits and characterized for use in radioimmunoassays. Cross-reactivity studies demonstrated the specificity of the selected antiserum forcis-zeatin riboside andcis-zeatin in preference to a range of cytokinins and other purines. HPLC systems were developed that separatedcis-zeatin andcis-zeatin riboside from zeatin/dihydrozeatin and zeatin riboside/dihydrozeatin riboside, respectively. These systems enabled the separation of these compounds in xylem sap samples of wheat and oats and their quantification using radioimmunoassay. A TLC system for the separation ofcis-zeatin andcis-zeatin riboside from zeatin/dihydrozeatin and zeatin riboside/dihydrozeatin riboside, respectively, is also described.     

Identification and quantitation by GC-MS of zeatin and zeatin riboside in xylem sap from rootstock and scion of grafted apple trees

Zeatin and zeatin riboside were identified by full-scan gas chromatography-mass spectrometry (GC-MS) in xylem sap of clonal apple rootstocks (M.27, M.9 and MM.106). These rootstocks exhibit a wide range of control over tree size when grafted to a common scion. The concentrations of zeatin and zeatin riboside were measured by GC-MS selected ion monitoring (SIM) in shoot xylem sap and root pressure exudate obtained from these rootstocks and from trees of Fiesta scion grafted onto the rootstocks. Zeatin was the predominant cytokinin in xylem sap from the dwarfing rootstocks, M.27 and M.9, while zeatin riboside was the predominant cytokinin in xylem sap from the more invigorating rootstock MM.106. Cytokinin concentrations (ng ml^–1) in root pressure exudate and shoot xylem sap, (i.e. from above the graft union in composite trees), increased with increasing vigour of the rootstock, irrespective of whether the plants were non-grafted rootstocks, or were composite plants of Fiesta scion grafted onto the rootstocks. Cytokinin content (ng shoot^–1) of shoot sap differed with rootstock; the more invigorating (MM.106) had greater amounts of cytokinins than the more dwarfing (M.9 and M.27) rootstocks. These results are discussed in relation to possible influences of roots on the growth of shoots via cytokinin supplies in the xylem sap.     

Cytokinins in the vascular saps of Ricinus communis

Roots are recognised as the major sites of cytokinin synthesis and shoots receive a continuous supply of cytokinins from the roots. Although reports are available on the xylem mobility of putative free bases and their ribosides, relatively few studies on the phloem mobility of cytokinins have been reported. The origin of phloem-mobile cytokinins is uncertain but there is evidence which implicates a recirculation from the root source. This study is the first report in which zeatin and zeatin riboside from the root pressure exudate and phloem sap of Ricinus have been identified by full-scan GC-MS and quantified by GC-MS selective-ion-monitoring. In this study, the concentration of cytokinins in root pressure exudate was similar, but lower, and in the phloem sap higher than that reported previously. The concentration of cytokinins quantified in the phloem sap confirms their transport in the sieve tubes. The relatively high concentration of zeatin riboside detected in the root pressure exudate and of zeatin detected in the phloem sap indicate a possible vascular recirculation of these hormones.     

Feedback regulation of xylem cytokinin content is conserved in pea and Arabidopsis

Increased-branching mutants of garden pea (Pisum sativum; ramosus [rms]) and Arabidopsis (Arabidopsis thaliana; more axillary branches) were used to investigate control of cytokinin export from roots in relation to shoot branching. In particular, we tested the hypothesis that regulation of xylem sap cytokinin is dependent on a long-distance feedback signal moving from shoot to root. With the exception of rms2, branching mutants from both species had greatly reduced amounts of the major cytokinins zeatin riboside, zeatin, and isopentenyl adenosine in xylem sap compared with wild-type plants. Reciprocally grafted mutant and wild-type Arabidopsis plants gave similar results to those observed previously in pea, with xylem sap cytokinin down-regulated in all graft combinations possessing branched shoots, regardless of root genotype. This long-distance feedback mechanism thus appears to be conserved between pea and Arabidopsis. Experiments with grafted pea plants bearing two shoots of the same or different genotype revealed that regulation of root cytokinin export is probably mediated by an inhibitory signal. Moreover, the signaling mechanism appears independent of the number of growing axillary shoots because a suppressed axillary meristem mutation that prevents axillary meristem development at most nodes did not abolish long-distance regulation of root cytokinin export in rms4 plants. Based on double mutant and grafting experiments, we conclude that RMS2 is essential for long-distance feedback regulation of cytokinin export from roots. Finally, the startling disconnection between cytokinin content of xylem sap and shoot tissues of various rms mutants indicates that shoots possess powerful homeostatic mechanisms for regulation of cytokinin levels.     

Evidence for Cytokinin Involvement in Rhizobium (IC3342)-Induced Leaf Curl Syndrome of Pigeonpea (Cajanus cajan Millsp.)

A uniquely abnormal shoot development (shoot tip-bending, leaf curling, release from apical dominance, and stunted growth) in pigeonpea (Cajanus cajan Millsp) induced by a nodulating Rhizobium strain, IC3342, is thought to be due to a hormonal imbalance. Amaranthus betacyanin bioassay indicated that xylem exudate and leaf extracts from pigeonpea plants with Rhizobium-induced leaf curl symptoms contained high concentrations of cytokinin relative to those in normal plants. Radioimmunoassay (RIA) of samples purified with high performance liquid chromatography revealed that zeatin riboside (ZR) and dihydrozeatin riboside (DZR) concentrations in xylem sap from plants with leaf curl symptoms were 7 to 9 times higher than those in the sap from symptomless, nodulated plants. The sap from symptomless plants nodulated by a Curl⁻ mutant had ZR and DZR concentrations comparable to those in the normal plant sap. RIA indicated that the respective concentrations of zeatin and N⁶-isopenteny-ladenine in culture filtrates of the curl-inducing strain IC3342 were 26 and 8 times higher than those in filtrates of a related normal nodulating strain (ANU240). Gas chromatographic-mass spectrometric analyses revealed similar differences. Gene-specific hybridization and sequence comparisons failed to detect any homology of IC3342 DNA to Agrobacterium tumefaciens or Pseudomonas savastanoi genetic loci encoding enzymes involved in cytokinin biosynthesis.     

Fruit set and cytokinin-like activity in the xylem sap of sweet cherry (Prunus avium) as affected by rootstock

Using a trace-enrichment procedure involving solvent partitioning and high pressure liquid chromatography, followed by bioassay, two cytokinin-like substances believed to be zeatin and zeation riboside were detected in the xylem sap of sweet cherry ( Prunus avium L.). The levels of cytokinin varied between rootstocks with the higher yielding and fruit setting rootstocks producing the highest cytokinin levels. Most of the cytokinin activity occurred in the spring during bloom and early fruit set. A relationship between cytokinin level in the xylem sap and fruit set is proposed.     

Root hypoxia reduces leaf growth : role of factors in the transpiration stream

This study examined the potential role of restricted phloem export, or import of substances from the roots in the leaf growth response to root hypoxia. In addition, the effects of root hypoxia on abscisic acid (ABA) and zeatin riboside (ZR) levels were measured and their effects on in vitro growth determined. Imposition of root hypoxia in the dark when transpirational water flux was minimal delayed the reduction in leaf growth until the following light period. Restriction of phloem transport by stem girdling did not eliminate the hypoxia-induced reduction in leaf growth. In vitro growth of leaf discs was inhibited in the presence of xylem sap collected from hypoxic roots, and also by millimolar ABA. Disc growth was promoted by sap from aerated roots and by 0.1 micromolar ZR. The flux of both ABA and ZR was reduced in xylem sap from hypoxic roots. Leaf ABA transiently increased twofold after 24 hours of hypoxia exposure but there were no changes in leaf cytokinin levels.     

Correlation of xylem sap cytokinin levels with monocarpic senescence in soybean

Cytokinins (CKs) coming from the roots via the xylem are known to delay leaf senescence, and their decline may be important in the senescence of soybean (Glycine max) plants during pod development (monocarpic senescence). Therefore, using radioimmunoassay of highly purified CKs, we quantified the zeatin (Z), zeatin riboside (ZR), the dihydro derivatives (DZ, DZR), the O-glucosides, and DZ nucleotide in xylem sap collected from root stocks under pressure at various stages of pod development. Z, ZR, DZ, and DZR dropped sharply during early pod development to levels below those expected to retard senescence. Pod removal at full extension, which delayed leaf senescence, caused an increase in xylem sap CKs (particularly ZR and DZR), while depodding at late podfill, which did not delay senescence, likewise did not increase the CK levels greatly. The levels of the O-glucosides and the DZ nucleotide were relatively low, and they showed less change with senescence or depodding. The differences in the responses of individual CKs to senescence and depodding suggest differences in their metabolism. Judging from their activity, concentrations and response to depodding, DZR and ZR may be the most important senescence retardants in soybean xylem sap. These data also suggest that the pods can depress CK production by the roots at an early stage and this decrease in CK production is required for monocarpic senescence in soybean.     

Dependence of cytokinin distribution in plants on their physical and chemical properties and transpiration rate

The effect of transpiration on cytokinin accumulation and distribution in 7-day-old wheat (Triticum durum Desf.) seedlings grown on nutrient medium supplemented with zeatin or its riboside was studied. The content of cytokinins in plants and nutrient medium was measured by the immunoenzyme analysis; cytokinin distribution between root cells was assessed immunohistochemically using antibodies against zeatin derivatives. The rate of transpiration was reduced 20-fold by plant placing in humid chamber. At normal transpiration, after 6 h of plant incubation on the solution of zeatin, the level of cytokinins in plant tissues increased stronger than after incubation on the solution of zeatin riboside (by 7.3 and 3.5 times, respectively, as compared with control), although the rates of both cytokinin uptake were equal. Most portions of cytokinins were retained in the roots, which was stronger expressed in the case of free zeatin uptake. A decrease in the rate of transpiration did not affect substantially the zeatin absorption from nutrient medium and the total level of cytokinin accumulation in plants, but these indices were sharply decreased in the case of zeatin riboside. In the zone of absorption of both control roots and roots treated with cytokinins, more intense cytokinin immunostaining was observed in the cells of the central cylinder. The interrelation between cytokinin distribution between the cells and apoplast, their inactivation, and transport over the plant and their form (zeatin or zeatin riboside) used for treatment is discussed.     

Quantification of the export of cytokinins from roots to shoots of Rosa hybrida and their degradation rate in the shoot

Cytokinins from the roots may be involved in regulating rose ( Rosa hybrida ) shoot growth and development. The objective of this study was to estimate the export of cytokinins from the roots and their degradation rate in the shoot, which were expected to be correlated with plant development. Hence, the total cytokinin content of the shoot, the concentration of zeatin riboside (ZR) in bleeding sap, and the transpiration rates in three stages of development were determined. The estimations performed are based on the assumption that the cytokinin concentration in bleeding sap is representative for the cytokinin concentration in xylem sap in situ. This was verified by comparing the ZR concentration in bleeding sap and in sap obtaíned after pressurizing the root system to a level equivalent to the leaf water potential; no significant differences could be found. The import of cytokinins could not be correlated with plant development, as it increased linearly with time. The estimated relative degradation rate of cytokinins in the shoot decreased as the plants matured. The half-life of cytokinins in the shoot was found to be approximately 1 day, indicating that cytokinins are rapidly metabolized in the shoot.     

PRIMARY PHLOEM REGENERATION WITHOUT CONCOMITANT XYLEM REGENERATION: ITS HORMONE CONTROL IN COLEUS

Phloem regeneration in the absence of xylem regeneration was evoked in number 5 internodes of Coleus blumei Benth. by severing xylemless phloem bundles. Its quantitative extent was estimated. To determine whether phloem regeneration is directly affected by auxin, or whether it is a secondary consequence of the auxin-dependent xylem regeneration which usually accompanies it, phloem regeneration was measured in decapitated plants from which auxin-producing leaves and buds had been removed (i.e., in “plant stumps”). In these stumps, 1% IAA in lanolin completely restored phloem regeneration to the intact plant level. In such stumps from which roots had been excised, and in excised internodes, IAA failed to restore it to this level. However, zeatin or zeatin riboside in aqueous solution applied to the bases of excised internodes receiving IAA at their apical ends restored phloem regeneration to the level of that in whole plants. When similarly tested, other cytokinins (kinetin, kinetin riboside, 2iP, and 2iPA), gibberellic acid (GA₃), glutamine, proline, sucrose, and a mixture of mineral salts failed to promote phloem regeneration. Glutamic acid, tested only once, was slightly promotive of it.     

Re-evaluation of the role of ureides in the xylem transport of nitrogen in Arachis species

There are conflicting reports in the literature of the possible role of the ureides, allantoin and allantoic acid, in the nitrogen economy of Arachis species. Therefore, xylem sap composition in food peanut ( Arachis hypogaea L.), and two forage peanuts ( A. pintoi L. and A. glabrata Benth.) has been studied in detail. Xylem saps were collected from peanuts grown under different nutritional regimes and environmental conditions in the glasshouse and field in Australia, Malaysia and Indonesia, and the N-containing solutes analysed. The relative amounts and concentrations of ureides in these peanut exudates were compared with those of soybean ( Glycine max [L.] Merr.) – a species known to export ureides in its xylem stream as the major product of N₂ fixation.
Xylem concentrations of ureides in soybean were high in N₂-fixing plants (2.9 to 3.7 μmol ml⁻¹), representing 60 to 88% of xylem solute nitrogen, but it contributed only 9% (0.7 μmol ml⁻¹) if plants were unnodulated and supplied nitrate. In all species of peanut, concentrations of ureides measured in xylem sap were generally much smaller (0.02 to 0.37 μmol ml⁻¹; 1–7% of xylem nitrogen) and were unaffected by peanut species or cultivar, rhizobial strain, plant size, growth rate, or stage of development, and were not related to N₂ fixation (less than 0.1% of currently fixed nitrogen exported as ureides) or the assimilation of nitrate. Apparently high levels of ureides in sap from some field-grown plants were shown to be due to interference with the ureide colorimetric assay by some contaminating compound rather than represent increased ureides per se.     

The shoot controls zeatin riboside export from pea roots. Evidence from the branching mutant rms4

The rms4 mutant of pea ( Pisum sativum L.) was used in grafting studies and cytokinin analyses of the root xylem sap to provide evidence that, at least for pea, the shoot can modify the import of cytokinins from the root. The rms4 mutation, which confers a phenotype with increased branching in the shoot, causes a very substantial decrease (down to 40-fold less) in the concentration of zeatin riboside (ZR) in the xylem sap of the roots. Results from grafts between wild-type (WT) and rms4 plants indicate that the concentration of cytokinins in the xylem sap of the roots is determined almost entirely by the genotype of the shoot. WT scions normalize the cytokinin concentration in the sap of rms4 mutant roots, whereas mutant scions cause WT roots to behave like those of self-grafted mutant plants. The mechanism whereby rms4 shoots of pea cause a down-regulation in the export of cytokinins from the roots is unknown at this time. However, our data provide evidence that the shoot transmits a signal to the roots and thereby controls processes involved in the regulation of cytokinin biosynthesis in the root.