Hormonal Control of Xylogenesis in Pith Parenchyma Explants of Lactuca

The time course of xylem differentiation was determined in explantsof lettuce pith parenchyma (Lactuca sativa L. cv. Romana) culturedon Murashige and Skoog (1962) medium using different concentrationsof auxin (IAA) and one cytokinin (zeatin or kinetin). Increasinglevels of auxin from I mg 1^–1 to 15 mg 1^–1 in thepresence of a constant level of a cytokinin (zeatin or kinetin)yielded up to 10 mg 1^–1 IAA, an increase in the numberof tracheary element formations. Cytokinin concentrations aboveand below o.1 mg 1^–1 interacting with an optimal xylogenicamount of auxin inhibited xylogenesis. The IAA (10 mg 1^–1)-zeatin(0.1 mg ^1–1) treatment produced the greatest number oftracheids, while kinetin compared to zeatin did not producesuch an effect. The different effectiveness of zeatin and kinetinin inducing tracheary element formations was not due to a differentcapacity of the two cytokinins to stimulate cell division butit seems likely that zeatin, because of interaction with IAA,is more active than kinetin in the determination of the dividingcells in a specific type of cytodifferentiation. The IAA (10mg 1^–1)-zeatin (0.1 mg 1^–1) treatment produced about6.9 per cent tracheids with respect to cell division while IAA(10 mg 1^–1)-kinetin (0.1 mg 1^–1) produced 4.2 percent. These results are discussed with reference to the problemsof hormonal control of xylem differentiation.     

Effects of Sequential Exposure to Auxin and Cytokinin on Xylogenesis in Cultured Explants of Jerusalem Artichoke (Helianthus tuberosus L.)

During the course of a 4-d culture period, explants of Jerusalemartichoke tuber were exposed to auxin (0.2 mg 1^–1 2, 4-dichlorophenoxyaceticacid), and cytokinin (5.0 mg 1^–1 benzyl-amino purine),under a range of sequential regimes, to study the influenceof each hormone on tracheary element formation. The resultsindicate that auxin was necessary early in the culture periodand was primarily involved in cell proliferation. Cytokininstimulated xylogenesis when present late in the culture period,concomitant with the phase of cytodifferentiation, but not whenrestricted to the early period. The implications for a sustainedperiod of commitment to differentiation are discussed. Xylem differentiation, Jerusalem artichoke, auxin, cytokinin, tissue culture     

Effects of auxin on the spatial distribution of cell division and xylogenesis in lettuce pith explants

Summary Cylinders of pith parenchyma were tissue-cultured with their opposite ends on media which differed only in content of the morphogens auxin (IAA), sucrose, or zeatin. A range of concentrations of each of these morphogens applied at one end (none at the other end) resulted in distribution patterns of cell division and xylogenesis that were attributable to interaction between inductive levels and morphogen mobility. Auxin was crucial for tracheary patterns: large tracheary elements formed by direct differentiation of pith cells near the auxin source, smaller but still roughly isodiametric tracheary elements formed after cell division, and tracheary strands developed where, presumably, auxin transport had become polarized and then canalized. Xylogenesis was confined to regions within millimeters of the auxin source, and [¹⁴C]IAA studies showed a steep logarithmic concentration gradient along the cylinder. Patterns of tracheary strands and rings revealed that the pith explants retained some polarity from the stem from which they had been excised. However, the direction of flow of applied auxin was more effective than original polarity in controlling the orientation of tracheary strands and their constituent tracheary elements. It seems that, in tissues with little or no polarity, diffusive flow of auxin gradually induces polar flow in the same direction, together with an associated bioelectric current, and that this orients the cortical microtubules that in turn determine the orientations of cell elongation and of the secondary wall banding in tracheary elements.Abbreviations IAA indoleacetic acid - NAA naphthaleneacetic acid - TIBA triiodobenzoic acid Dedicated to the memory of Professor John G. Torrey     

DNA synthesis, cell division and specific cytodifferentiation in cultured pea root cortical explants

Pea root segments cut 10–11 mm behind the tip of germinating seedlings were prepared by removal of the central cylinders with a tissue punch. These cortical explants were cultured aseptically on nutrient medium containing auxin with and without added cytokinin. In the absence of kinetin, the cortical cells enlarged and separated but failed to show DNA synthesis, mitosis, cell division or subsequent cytodifferentiation. In the presence of 1 ppm kinetin, cortical nuclei showed ³H-thymidine incorporation beginning between 24 and 32 hr; mitoses began about 48 hr, reaching a maximum of 6% at 60 hr. From an initial number of 8000 cells per segment, the cell count increased to 37,000 by day 7 and 140,000 by day 21. At the outset all mitoses were tetraploid; with time the proportion of tetraploid mitotic cells decreased and an octaploid population increased. A frequency of less than 10% diploid mitoses was observed after day 5. Only 25% of the cortical cells showed initial labeling. Beginning on day 7 tracheary elements differentiated from cortical derivatives. By day 14 about 25% and by day 21 about 35% of the total cell population had formed tracheary elements. As a system for analysis in biochemical and cytological terms, pea cortical explants represent an excellent system for the study of cytodifferentiation.     

A tracheid-differentiation factor from pine needles

Exogenous indol-3yl-acetic acid (IAA), alone and together with several cytokinins, was ineffective in promoting the complete differentiation into tracheids of cambial derivatives of Pinus contorta Dougl.; IAA alone promoted cambial cell division and primary-wall growth in cambial derivatives throughout the stem's length. In contrast, a single pair of needles on a stem cutting in light promoted neither cambial cell division nor primary-wall growth in cambial derivatives but did promote complete differentiation of cambial cells into tracheids; tracheids differentiated only near the junction of the foliated short shoot with the stem. Clear inter-and intracellular differences in the extent of tracheid differentiation occurred in response to a single needle pair and have suggested the hypothesis that a specific tracheid-differentiation factor regulates the differentiation of cells into proto-, meta-, or secondary-xylem tracheary elements through an interaction with IAA.Abbreviations IAA indol-3yl acetic acid - K kinetin - BAP 6-benzylaminopurine - Z zeatin - ZR zeatin riboside - FAA formalin: acetic acid: ethanol: water (10:5:50:35, by vol.)     

Tracheary Element Differentiation Induced in Isolated Cylinders of Lettuce Pith: a Bipolar Gradient Technique

To study the influence of morphogenetic gradients on vasculardifferentiation patterns, a new technique was developed whichallows different substances to be applied at opposite ends ofa tissue block. It yielded information on the mobility of particularmorphogens and on the dependence of callus formation and trachearyelement differentiation on their presence. Application of indol-3ylacetic acid (1AA) (10 mg l^–1), zeatin (0.1 mg l^–1)and sucrose (3 per cent, w/v) in various combinations to theends of cylindrical explants of lettuce pith (Lactuca sativaL.) showed that (a) callus formation was stimulated by IAA,whereas induction of tracheary elements required both IAA andzeatin; (b) callus was confined to a few millimetres at theends of the explants, and tracheary elements occurred mainlywithin the callus; (c) sucrose or its metabolic products diffusedthe 10 mm length of the explants, while IAA and zeatin wereeffective only close to the application site; and (d) some callusand tracheary elements formed when no sucrose was applied, butboth increased with sucrose application, though inhibition oftracheary elements formation occurred with high sucrose concentrations. differentiation, pith explant, tissue culture, xylogenesis, indol-3yl acetic acid, sucrose, zeatin, lettuce, Lactuca sativa     

Effects of Auxin Concentration on the Dimensions and Patterns of Tracheary Elements Differentiating in Pith Explants

The optimal concentration of IAA (0.03 mM) for tracheary elementdifferentiation in lettuce pith explants was about ten timesgreater than the optimal concentration for callus proliferation.Related to this, the mean volume per tracheary element increasedwith increasing IAA concentration, 18-fold between 0.001 mMand 0.3 mM IAA. At the highest concentrations, some pith cellsappeared to differentiate directly into tracheary elements,without cell division, resulting in especially large trachearyelements. Tracheary strands developed at intermediate concentrationsof IAA, and led to a small increase in the mean length/breadthratio of tracheary elements. For tracheary elements differentiating from stem cambial derivatives,a reassessment of previous studies indicates that increase inauxin concentration brings greater tracheary element size atconcentrations up to the 0.03 mM optimum. Above this optimum,however, further increase in auxin concentration brings progressivelysmaller tracheary elements, as the high auxin curtails enlargementof the differentiating cells. This contrasts with the pith explants,in which tracheary element size increases with IAA concentrationmost markedly above the optimum concentration. The interpretationof these relations requires an understanding of the effectsof auxin concentration on interacting quantities such as initialsize of cells, rate of enlargement, and rate of differentiation. Lactuca sativa, lettuce, IAA concentration, pith explants, tracheary element dimensions     

Determination of Tracheary Element Differentiation in Lettuce Pith Explants

Transfer experiments with lettuce pith explants revealed thatprovision of inductive concentrations of both cytokinin andauxin in the culture medium for the first 3 and 5 d respectivelywas sufficient to cause determination of tracheary elementsas shown by their subsequent differentiation in substantialnumbers in explants removed from the inductive hormonal stimuli. Determination, differentiation, tissue culture, IAA, zeatin, tracheary elements, lettuce, Lactuca     

CELL DIVISION IN RELATION TO CYTODIFFERENTIATION IN CULTURED PEA ROOT SEGMENTS

One mm-thick segments cut 10–11 mm proximal to the root tip of germinating seeds of garden pea Pisum sativum were cultured in sterile nutrient medium containing auxin in the presence and absence of kinetin. In the absence of added cytokinin, pericyclic proliferation occurred, the cortical tissues showed no proliferation and were sloughed off, and a callus tissue of diploid cells was formed. In the presence of kinetin concentrations from 0.1–1.0 ppm cortical cells of the segments were induced to divide, beginning at the third day. From experiments with ³H-thymidine incorporation at different times of culture, from cytological squash preparations and from histological sections it was shown that the cortical cells stimulated to divide by cytokinin underwent DNA synthesis prior to division, were polyploid, and following cell division rapidly underwent cytodifferentiation at 5–7 days to form mature tracheary elements. At 10 days, when over 300,000 new cells had been formed per segment about 16% of these cells had formed tracheary elements. It was concluded that cytokinin, together with auxin, was essential for the initiation of DNA synthesis in the cortical cells, for their subsequent division, and finally for their specific cytodifferentiation.     

Effects of N-1-naphthylphthalamic acid on the growth and bud formation of tobacco callus grown in vitro

The effect of N-1 -naphthylphthalamic acid (NPA), indole-3-aceticacid (IAA) and kinetin on callus growth and bud formation wasstudied mainly by a tobacco callus culture method. Callus producedfrom Nicotiana tabacum var. Wisconsin 38 was used as the testplant material. Callus growth on nutrient agar containing 2mg/liter of IAA was promoted by NPA added at a concentrationof 0.5 mg/liter with 0.4 mg/liter of kinetin or by NPA addedat 5 mg/liter in the absence of kinetin. At a high concentrationof 50 mg/liter, however, NPA inhibited growth on the mediumcontaining 2 mg/liter IAA and no kinetin. Kinetin reduced thisNPA inhibition. In the presence of 0.4 mg/liter kinetin and2 mg/liter IAA, when the concentration of NPA was 50 mg/liter,buds were initiated after calluses were grown on the test mediumfor 7 weeks in dim light, but no buds formed when NPA was omittedfrom the above medium. The control of callus growth and bud initiation is based onthe active ratio of auxin (IAA) to cytokinin (kinetin) in themedium and NPA added to the medium can promote or inhibit callusgrowth and induce bud formation. Therefore, it is proposed thatNPA can itself reduce auxin activity or enhance cytokinin activityand hence change the active ratio of the two regulators. NPAmay enhance the activity of cytokinin (here supplied as kinetin)but cannot substitute for it. ¹Present address: Department of Biology, Wisconsin State University,Oshkosh, Wisconsin 54901, U. S. A. (Received March 10, 1969; )     

The Role of Benzyladenine in the Differentiation of Tracheary Elements in Jerusalem Artichoke Tuber Explants Cultured in vitro

The role of benzyladenine (BA) in the differentiation of trachearyelements in Jerusalem artichoke (Helianthus tuberosus L.) tuberexplants was studied. For maximum differentiation of trachearyelements (25–30% of the cell population), treatment withoptimal concentrations of benzyladenine (5.0 mg dm^–3)in the presence of -naphthaleneacetic acid |NAA| (1.0 mg dm^–3)for the first 6 d was as effective as its continued presenceduring the entire 14 d period of study. A majority of the differentiatedtracheary element appeared between the 10th and 14th days ofculture. It was further observed that concentrations of activecytokinins in the tissue were considerably reduced within 2d after transfer from the BA-containing medium to a BA-freemedium. This was shown in three different ways: (1) monitoringthe amount of ethanol-soluble radioactivity at various timesafter transfer from |14C|-BA containing medium to BA-free medium;(2) bioassay of various cytokinin fractions from tissue extractseparated by thin layer chromatography; (3) indirect assay oftissue cytokinin activity through its interaction with abscisicacid for the promotion of auxin-induced cell division in thistissue. Both gibberellic acid (5.0 mg dm^–3) and abscisic acid(2–0 mg dm^–3) effectively inhibited the differentiationof tracheary elements even if provided after 6 d of pre-incubationin a high tracheid inducing medium. However, the appearanceof differentiated cells for the first 2 d after transfer wasnot significantly affected. A hypothetical scheme for the role of benzyladenine in the differentiationof tracheary elements in this tissue is discussed. It is suggestedthat during one or more critical cell divisions in the presenceof optimal levels of benzyladenine, a proportion of cells areinduced or committed for later differentiation into trachearyelements. The high concentrations of benzyladenine requiredduring induction are not needed during the intervening celldivisions, nor for the actual differentiation of the trachearyelements. Key words: Tracheary element differentiation, Jerusalem artichoke (Heliantlus tuberosus), Benzyladenine, Gibberellic acid, Abscisic acid     

Patterns of Tracheary Differentiation in Lettuce Pith Explants: Positional Control and Temperature Effects

When lettuce pith explants were cultured for 14 d on a xylogenicmedium, tracheary elements differentiated in greatest numbersbetween 25 and 30 °C. Numbers were depressed at lower temperaturesby slower development and at higher temperatures by adverseprocesses. The data did not support previous suggestions ofa great stimulation of xylogenesis above 30 °C and of aspecial sensitivity to low temperatures. Tracheary elements differentiated in various spatial patterns:as clumps in the peripheral callus, as strands which extendedradially and longitudinally from some of these clumps, as individuallarge tracheids especially at the more extreme temperatures,and as short strands associated with nodules and roots thatformed at favourable temperatures. We suggest that indoleacetic acid (IAA) has various roles inthe positional control of these tracheary patterns: (1) IAAdestruction at the explant surface leads to concentration gradientsthat inhibit tracheary induction close to the surface; (2) IAAtransport from the source in the culture medium to sinks especiallyat the explant surface, coupled with autocatalytic flow facilitation,leads to canalization along pathways that become meristematicand then trachcary strands; (3) the IAA flux (and associatedproton flux) along these pathways tend to orient cortical microtubulesat right angles to the flow, by some mechanism as yet unknown,and hence to control the orientation of tracheary element elongationand secondary wall banding. These suggestions, supported bymorphometric studies of tracheary element dimensions and orientations,and by experiments with localized IAA application, lead to ageneral interpretation of the development of polarity in plants. IAA, Lactuca sativa, lettuce, pith explants, positional control, temperature effects, tracheary element differentiation     

Establishment of an Experimental System for the Study of Tracheary Element Differentiation from Single Cells Isolated from the Mesophyll of Zinnia elegans

Single cells were isolated mechanically from the mesophyll of adult plants and of seedlings of Zinnia elegans L. cv. Canary bird. When single cells isolated from the first leaves of seedlings were cultured in a liquid medium in the dark with rotation, they differentiated to tracheary elements with a reasonable degree of synchrony in the 24-hour period between days 2 and 3 after culture. The proportion of tracheary elements as a percentage of total cells reached nearly 30% 3 days after culture. Factors favoring cytodifferentiation were certain optimum levels of both α-naphthalene-acetic acid (0.1 milligram per liter) and benzyladenine (1 milligram per liter), a low concentration of ammonium chloride (0 to 1 millimolar), and an initial cell population density in the range 0.4 to 3.8 × 10⁵ cells/ml. It was possible to follow analytically the sequence of cytodifferentiation in individual cells in this system.     

Is DNA synthesis required for the induction of differentiation in quiescent root cortical parenchyma?

Cortical parenchyma of pea roots normally does not divide nor differentiate as tracheary elements. After excision from the root these cells can be induced to undergo cell division followed by differentiation of tracheary elements in the presence of cytokinin. 5-Fluorodeoxyuridine prevents cell replication and cytodifferentiation. The thymidine analog, 5-bromodeoxyuridine, specifically prevents cytodifferentiation with little or no effect on the rate of cell replication. Thymidine can also prevent cytodifferentiation with little effect on cell replication. Thymidine reverses the effect of 5-bromodeoxyuridine (BrdU) or 5-fluorodeoxyuridine (FdU) when given simultaneous with or subsequent to either BrdU or FdU. BrdU given with FdU allows up to one round of cell replication but no cytodifferentiation. Differentiation is rarely observed unless the entire cell population has undergone the equivalent of two cell generations. These results are combined with those of other investigators to present an hypothesis that implicates DNA replication but not cytokinesis in the regulation of certain types of differentiation.     

Introduction of xylem differentiation in lactuca by ethylene

Evidence was obtained to support the hypothesis that ethylene is involved in xylem differentiation in primary pith explants of Lactuca sativa L. cv Romaine cultured in vitro. Xylem elements differentiated when explants were supplied indole-3-acetic acid (IAA) in combination with either the ethylene biosynthetic precursor 1-aminocyclopropane-1-carboxylic acid (ACC), the ethylene-releasing agent 2-chloroethylphosphonic acid (CEPA), or kinetin. In contrast, no xylem elements differentiated in the presence of IAA, kinetin, ACC, or CEPA alone, or when kinetin was supplied together with ACC or CEPA. These results show that ethylene will substitute qualitatively for cytokinin during auxin-induced xylogenesis, and suggest that both ethylene and auxin are required for xylem differentiation in Lactuca.     

The Effect of Triacontanol on Peroxidase, IAA, and Plant Growth in Pisum sativum var.'Alaska' and 'Little Marvel'

The present study investigates the effects of triacontanol (CH₃(CH₂)₂₈CH₂OH),on plant growth (root and stem), peroxidase activity (apicalmeristem tissue), and auxin destruction (apical meristem tissue)in ‘Little Marvel’ dwarf (LM) and ‘Alaska’peas (AP). Triacontanol inhibited root growth in LM comparedto untreated controls. However, root growth in AP tissue wasenhanced by 1.0 mg I^–1 triacontanol and inhibited by allother treatments, in comparison to untreated controls. Wateruptake in triacontanol-treated AP plants was greater than inuntreated controls, with the converse being the case for LM.Triacontanol treatment caused an increase in peroxidase activityin both LM and AP plants compared to untreated controls. Interms of (1–¹⁴C)IAA destruction, GA₃ + 0.01 mg 1^–1triacontanol caused appreciable auxin breakdown (40%) in LMtissue, with GA₃ + 0.1 mg 1^–1 triacontanol giving a 43%decrease compared to untreated controls. In AP tissue, 10 µMGA3 increased auxin destruction by 188% whereas 0.1 mg I^–1triacontanol caused a 20% decrease compared to untreated controls.The effects of triacontanol on root and stem growth, peroxidaseactivity, and auxin destruction appear to be cultivar-specific,with respect to LM and AP varieties of peas.     

Inhibition of xylogenesis by morphactin in pith parenchyma explants of Lactuca

Pith parenchyma explants of Romaine lettuce (Lactuca salivaLinn. var. Roman?) incubated in the dark for 7 days at 25?Con a nutrient medium containing sucrose, IAA. and kinetin exhibitedextensive differentiation of tracheary elements. The additionof CFL to the medium strongly inhibited tracheary element formation.The lack of tracheary strand formation in the CFL-treated explantssuggests the inhibition of auxin transport. Conclusive evidencethat CFL influences the anatomy of differentiating xylem elementswas lacking. The addition of CFL to various combinations ofxylogenic media was not stimulatory to xylem element formationbeyond the differentiation response observed in the absenceof CFL. Unique patterns of tracheary element formation producedby cytokinin media containing IAA, 2,4-D, and NAA, respectively,were abolished by CFL. As indicated by counts of total trachearyelements formed per explant, the addition of cysteine to a CFL-containingmedium reversed the inhibitory effect of CFL. Tracheary strandformation was not re-established in the explants cultured onthe cysteine+CFL medium. Tracheary element formation was completelysuppressed by TIBA. Cysteine had a slight effect on the inhibitionof differentiation by TIBA. These observations suggest thatCFL inhibits some sulfhydryl- containing system involved eitherin the process of xylem differentiation or in some prerequisiterole necessary for the induction of tracheary element formation. (Received December 27, 1972; )     

Tracheary Element Formation from Single Isolated Cells in Culture

Friable callus tissue of Centaurea cyanus L. was grown on a solidified synthetic nutrient medium (EBM-1) to produce a tissue with a low frequency of differentiated tracheary elements. Tissues were then suspended in liquid nutrient medium with agitation to produce a suspension which was filtered and the single-cell suspension resulting was used as inoculum for either cell suspension cultures or for plating of cells into solidified medium in Petri plates. Media for the suspension cultures were selected to favor cytodifferentiation of tracheary elements. Differentiated tracheary elements formed as early as 10 days and numbers of tracheary elements increased with time roughly in relation to the increase in total cell number. From plating experiments it was shown conclusively that single isolated parenchyma cells differentiated directly into single isolated tracheary elements, although this event was rare. More usual was the division of isolated cells to form small colonies and then the differentiation of one, several or all of the cells into tracheary elements. Comparisons are made between results with cell plating experiments and cell suspension cultures. Optimism is expressed for finding a cell suspension culture system for studying cytodifferentiation.     

Cytokinin and Ethylene Affect Auxin Transport-Dependent Rhizogenesis in Hypocotyls of Common Ice Plant (<Emphasis Type="Italic">Mesembryanthemum crystallinum</Emphasis> L<Emphasis Type="Italic">.</Emphasis>)

Hypocotyl explants of Mesembryanthemum crystallinum regenerated roots when cultured vertically with either the apical end (AE) or basal end (BE) in media containing indole-3-acetic acid (IAA). IAA alone induced roots regularly from the basal end of the explants, either from the cut surface immersed in the medium or from the opposite side. The inhibitors of auxin efflux carriers, α-naphthylphthalamic acid (NPA) and 2,3,5-triiodobenzoic acid (TIBA), inhibited rhizogenesis only from AE-cultured explants, indicating the role of polar auxin transport in root regeneration in this system. Cytokinin (zeatin, kinetin, BAP) added to auxin-containing medium reduced rhizogenesis from the explants maintained with BE and AE and additionally changed the IAA-induced pattern of rooting in AE-cultured explants by favoring rooting from the apical end and middle part of the hypocotyl with its concomitant reduction from the basal end. The addition of kinetin did not influence the content of IAA in the explants maintained with AE, suggesting that the cytokinin effect on root patterning was not dependent on auxin biosynthesis. Kinetin, however, strongly enhanced ethylene production. The importance of ethylene in regulating PAT-dependent rhizogenesis was tested by using an ethylene antagonist AgNO₃, an inhibitor of ethylene synthesis aminoethoxyvinylglycine (AVG), and a precursor of ethylene, 1-aminocyclopropane-1-carboxylic acid (ACC). AgNO₃ applied together with IAA or with IAA and kinetin strongly reduced the production of ethylene, inhibited rhizogenesis, and induced nonregenerative callus from BE, suggesting the need for ethylene signaling to elicit the rhizogenic action of auxin. A reduction of rhizogenesis and decrease of ethylene biosynthesis was also caused by AVG. In addition, AVG at 10 μM reversed the effect of cytokinin on root patterning, resulting in roots emerging only from BE on the medium with IAA and kinetin. Conversely, ACC at 200 μM markedly enhanced the production of ethylene and partly mimicked the effect of cytokinin when applied with IAA alone, thus confirming that in cultured hypocotyls of ice plant, cytokinin affects IAA-induced rhizogenesis through an ethylene-dependent pathway.     

The accumulation and metabolism of plant growth regulators during organogenesis in cultures of thin cell layers of Nicotiana tabacum

The accumulation and metabolism of exogenously applied and endogenously produced auxins and cytokinins were studied in relation to organogenesis in thin cell layers of Nicotiana tabacum L. It was shown that, in order to obtain maximal flower bud formation, both exogenous auxin and cytokinin needed to be present during the first 4 days of culture (to the formation of a subepidermal meristematic zone) whereas cytokinins needed to be present for at least 4 days more (until formation of organogenic centres). Explants taken from floral branches have higher endogenous indole-3-acetic acid (IAA) levels compared with explants from the basal part of the stem which form only vegetative buds. This might be related to a different IAA metabolism in these two types of explants as was shown by the different accumulation of exogenously applied IAA. Both 'floral' and 'vegetative' cells layers contained comparable amounts of zeatin riboside (ZR) as their major cytokinin. Free bases, zeatin (Z) and dihydrozeatin [(diH)Z], given exogenously, were largely metabolised to their respective ribosides. The observation that Z was less effective than (diH)Z in the induction of flower buds could be related to (diH)ZR apparently not being a substrate for cytokinin oxidase.