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     

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     

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     

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; )     

IAA Amino Acid Conjugates Induce Differentiation of Tracheary Strands in Lettuce Pith Explants

Each of four amino acid conjugates of IAA was able to replacethe IAA requirement for xylogenesis in lettuce pith explants,when supplied at concentrations ten to 100 times those optimalfor IAA. Tracheary development induced by these conjugates tendedto be slightly slower and less in amount than with IAA, andthe tracheary strands shorter and less regular. Responses differedsomewhat among the four conjugates: IAA-D, L-aspartate gavedevelopment most like that with free IAA, and IAA-D, L-phenylalanineoften yielded the weakest tracheary development, while responsesto IAA-L-alanine and IAA-glycine were intermediate. The resultsare interpreted in terms of the ‘bound’ IAA conjugatesdiffusing into the pith explants and becoming xylogenic onlyon hydrolysis to ‘free’ IAA. As tracheary strandformation is believed to result from IAA fluxes, it seems thatthe free IAA also moved through the discs, presumably towardsthe surfaces where it degrades rapidly. Tracheary strand formationin these explants can be compared with vascular strand formationin the normal shoot tip, where IAA conjugates (auxin ‘precursors’)move acropetally and are hydrolysed to free IAA especially inthe young leaf primordia, we suggest, yielding local sourcesof IAA which may contribute both to the phyllotactic spacingof primordia and, moving basipetally, to the definition of theauxin pathways that develop as procambial strands behind individualleaf primordia. Lactuca sativa, lettuce, IAA conjugates, tracheary element differentiation, pith explants, xylem strands     

Exogenous Methionine as a Nutrient Supplement for the Induction of Xylogenesis in Lettuce Pith Explants

The induction of xylogenesis in explants of lettuce pith parenchymawas greatly influenced by the presence of exogenous methionine(0·025 to 0·05 µM) in the culture medium.At the various concentrations of methionine tested, trachearyelement differentiation was stimulated in the majority of theexplants. Differentiation, however, was markedly depressed ina small number of explants grown under the same cultural conditionsin the presence of methionine. Cytodifferentiation in controlexplants, cultured on a similar medium lacking methionine, gaveconsistent tracheary cell counts with little variation. Thesedata are consistent with the hypothesis that theenhanced productionof ethylene, due to the presence of methionine as a substrate,plays a role in the initiation of xylem differentiation. Theconcentration of ethylene in the cultured tissue may be a criticalfactor in determining whether the hormone will stimulate orsuppress the initiation of cytodifferentiation. Some thick-walledand pitted cells were observed, and these may represent partially-differentiatedxylem elements.     

Stimulatory and Inhibitory Effects of Sucrose Concentration on Xylogenesis in Lettuce Pith Explants; Possible Mediation by Ethylene Biosynthesis

Numbers of tracheary elements differentiating in lettuce pithexplants rose with increase in concentration of sucrose in themedium up to an optimal concentration of 0·2%, and fellwith further increase in concentration to about one-tenth maximalat 3% sucrose. Although a few tracheary elements formed withoutexogenous sucrose, a very low concentration of sucrose (0·001%)was sufficient to stimulate additional xylogenesis. Pretreatmentof explants with 3% sucrose caused a persisting inhibition ofxylogenesis, especially in tissue that had been near the siteof sucrose application (sandwich technique). The requirementfor adequate, but not inhibitory, concentrations of sucrosefor xylogenesis may underlie the development of xylem alongsidethe sucrose-rich phloem in normal apical morphogenesis. For callus growth the response to sucrose was different: theoptimal concentration was 3%, with a broad plateau from 1 to4% sucrose. Sucrose concentrations of 2 to 3%, used in manytissue culture media, are thus roughly optimal for callus growth,but ten times the optimum for xylogenesis in lettuce pith explants. It is surprising that 0·001% (0·03 mM) sucrose,applied exogenously, can stimulate xylogenesis: endogenous sugarconcentrations are normally higher. Perhaps the stimulationis mediated by ethylene biosynthesis, which is known to be xylogenic.Rates of ethylene production per explant rose with increasingsucrose concentration from about 0·1 nl h^-1 at 0% sucroseto a slightly (significantly) higher level at 0·004%sucrose and to about 0·5 nl h^-1 at 3% sucrose. D -glucoseresembled sucrose in its effects on xylogenesis and ethyleneproduction, but L-glucose yielded no xylogenesis and littlestimulation of ethylene biosynthesis.Copyright 1994, 1999 AcademicPress Lactuca sativa, Coleus blumei, Nicotiana tabacum, lettuce pith explants, tracheary element differentiation, sucrose, glucose, ethylene     

Kinetics of Determination in the Differentiation of Isolated Mesophyll Cells of Zinnia elegans to Tracheary Elements

Mechanically isolated mesophyll cells of Zinnia elegans L. cv Envy differentiate to tracheary elements when cultured in inductive medium containing 0.5 micromolar α-naphthaleneacetic acid and 0.5 micromolar benzyladenine. The cells do not differentiate when cultured in medium in which the concentration of auxin and/or cytokinin has been reduced to 0.005 micromolar. Cells require an initial 24-hour exposure to inductive cytokinin and 56-hour exposure to inductive auxin for differentiation at 72 hours of culture. Freshly isolated Zinnia cells can be maintained in medium having low concentrations of both auxin and cytokinin for only 1 day without significant loss of potential to differentiate upon transfer to inductive medium. Initial culture for up to 2 days in medium having high auxin and low cytokinin, or low auxin and high cytokinin, allows full differentiation on the third day after transfer to inductive medium and potentiates the early differentiation of some cells.     

Characterization of Mitotic Cycles Preceding Xylogenesis in Cultured Explants of Helianthus tuberosus L.

The number of mitotic cycles intervening between the transferof dormant Helianthus tuberosus (Jerusalem artichoke) tuberexplants to culture medium and the differentiation of the firsttracheary elements at 48 h was investigated by a pulse-labellingtechnique employing quantitative autoradiography. Silver-graincounts indicated that differentiation was preceded by threemitotic cycles Duration of the cell cycle phases were estimatedby a pulse-labelling method. From calculation of the phase durationsit was estimated that the first visible signs of tracheary elementdifferentiation occurred from 7–10 h after the last mitosis. Helianthus tuberosus L., Jerusalem artichoke, tracheary elements, cultured explants, tissue culture, mitotic cycles, cell cycle, tritiated thymidine, autoradiography     

Secondary wall deposition in tracheary elements of cucumber grown in vitro

It is a matter of controversy whether secondary wall deposition is dependent on lignification during the development of tracheary elements. To understand this, tracheary element differentiation was studied in the homogeneous calli obtained from the cotyledonary explants of Cucumis sativus subsequent to treatment with plant growth regulators, such as naphthalene acetic acid (NAA) and benzylamino purine (BAP), which are necessary for the induction of tracheary elements, along with metabolic blockers such as 2-aminoindan-2-phosphonic acid (AIP), 2,3,5-triiodobenzoic acid (TIBA) and nifedipine. Calli treated with AIP, a potential inhibitor of L-phenylalanine ammonia-lyase (PAL), have no PAL activity at any time during the culture period. There was a complete inhibition of lignification although secondary wall deposition was unaltered. Similar results were obtained using TIBA, an inhibitor of auxin transport, and nifedipine, a known calcium channel blocker. Thus the present study suggests that secondary wall deposition in the course of tracheary element differentiation need not to be dependent on lignification. This revised version was published online in July 2006 with corrections to the Cover Date.     

Rapid differentiation of tracheary elements in cultured explants of Jerusalem artichoke

the culture of Jerusalem artichoke (Helianthus tuberosus L.) tuber explants on filter paper discs moistened with liquid medium resulted in rapid and consistent xylem differentiation. The number of tracheary elements increased in discrete steps, the first at 48 h with a second at 56–58 h, following partially synchronous mitoses at 20 and 30 h. Factors favouring xylem cell differentiation were optimum levels of both an auxin and a cytokinin, low medium nitrogen concentrations, small volumes of medium, and high culture temperatures. A cell counting method employing Feulgen-stained nuclei and suitable for quantifyings small numbers of immature tracheary elements is described.Abbreviations 2,4-D 2,4-Dichlorophenoxyacetic acid - NAA -naphthalene acetic acid - BAP benzylaminopurine - GA₃ gibberellic acid     

Some inhibitory effects of gentamicin on plant tissue cultures

Summary Tracheary element differentiation in cultured explants of pith parenchyma isolated from heads of romaine lettuce (Lactuca sativa L. var. Romana) was strongly inhibited by concentrations of gentamicin sulfate recommended for tissue culture media (50 to 100 μg/ml). Similar results were obtained with cultured explants of Jerusalem artichoke tuber (Helianthus tuberosus L.). Callus formation was suppressed in the presence of increasing levels of gentamicin sulfate in both tissue systems. Plant tissue culture media employed in studies on cell division and xylem differentiation should be supplemented with this antibiotic in concentrations of 10 μg/ml or less according to these results.     

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     

Brassinosteroid levels increase drastically prior to morphogenesis of tracheary elements

As the first step toward understanding the involvement of endogenous brassinosteroids (BRs) in cytodifferentiation, we analyzed biosynthetic activities of BRs in zinnia (Zinnia elegans L. cv Canary Bird) cells differentiating into tracheary elements. The results of feeding experiments suggested that both the early and late C6-oxidation pathways occur during tracheary element differentiation. Gas chromatography-mass spectrometry analysis revealed that five BRs, castasterone, typhasterol, 6-deoxocastasterone, 6-deoxotyphasterol, and 6-deoxoteasterone, actually existed in cultured zinnia cells and culture medium. Quantification of endogenous BRs in each stage of tracheary element differentiation by gas chromatography-mass spectrometry exhibited that they increased dramatically prior to the morphogenesis, which was consistent with the idea that BRs are necessary for the initiation of the final stage of tracheary element differentiation. Moreover, the proportion of each BR in culture medium was quite different from that in cells, suggesting that specific BRs are selectively secreted into medium and may function outside the cells.     

Activity of cell-wall degradation associated with differentiation of isolated mesophyll cells of Zinnia elegans into tracheary elements

Cell walls were prepared from cultured mesophyll cells of Zinnia elegans L. that were transdifferentiating into tracheary elements and incubated in a buffer to undergo autolysis. The rate of autolysis of cell walls was determined by measuring the amount of carbohydrate released from the cell walls into the buffer during incubation. During the course of culture of mesophyll cells, the autolysis rate increased markedly at the time when thickenings of secondary cell walls characteristic of tracheary elements became visible (after 48-72 h of culture), and thereafter the rate remained at a high level. Comparative studies on the autolysis rate of cell walls using various control cultures, in which tracheary element differentiation did not take place, revealed a close relationship between the autolysis rate around the 60th hour of culture and differentiation. Sugar analysis by colorimetric assays and gas chromatography of carbohydrates released from the cell walls detected uronic acid, arabinose, galactose, glucose, xylose, rhamnose, fucose, and mannose. Among these sugars, uronic acid was the most abundant, and accounted for approximately half of the total released sugars. The decrease of acidic polysaccharides in the primary cell walls during tracheary element differentiation was visualized by staining cultured cells with alcian blue at pH 2.5. These results suggest that active degradation of components of primary cell walls, including pectin, is integrated into the program of tracheary element differentiation.     

Hormonal induction and antihormonal inhibition of tracheary element differentiation in Zinnia cell cultures

Mechanically isolated mesophyll cells of Zinnia elegans L. cv Envy differentiate to tracheary elements when cultured in inductive medium containing sufficient auxin and cytokinin. Tracheary element differentiation was induced by the three auxins (alpha-naphthaleneacetic acid, indole-3-acetic acid, and 2,4-dichlorophenoxyacetic acid) and four cytokinins (6-benzyladenine, kinetin, 2-isopentenyladenine and zeatin) tested. Tracheary element formation is inhibited or delayed if the inductive medium is supplemented with an anticytokinin, antiauxin, or inhibitor of auxin transport.     

Characteristics of the Inhibitory Effect of 5-Fluorodeoxyuridine on Cytodifferentiation into Tracheary Elements of Isolated Mesophyll Cells of Zinnia elegans

The inhibitory effect of 5-fluorodeoxyuridine (FdU) on the differentiationinto tracheary elements was characterized in isolated mesophyllcells of Zinnia elegans. Both thymidine and uridine counteracted the inhibitory effectof FdU on the differentiation into tracheary elements, whileonly thymidine was effective in counteracting the effect ofFdU on cell division. Higher concentrations of thymidine wereneeded for the restoration of the differentiation that was blockedby FdU than for the restoration of cell division. These resultssuggest that FdU prevents the differentiation via a mechanismthat is different from the inhibition of thymidylate (dTMP)synthase by fluorodeoxyuridine monophosphate (FdUMP), derivedfrom FdU, to which the blockage of cell division by FdU shouldbe attributable. The differentiation into tracheary elements was prevented whenFdU was added earlier than the 36th hour of culture, and thymidineovercame the inhibitory effect of FdU only when added withinthe first 4 h of culture. Pretreatment with FdU before applicationof 6-benzyladenine (BA) and 1-naphthaleneacetic acid (NAA),which are essential for the formation of tracheary elements,also inhibited the differentiation. Thus, the aspect of thedifferentiation that is the target of inhibition by FdU appearsto occur between the 4th hour and the 36th hour of culture andto begin even in the absence of exogenous plant growth regulators. (Received April 3, 1989; Accepted October 27, 1989)     

The effect of collagen on the cyclic AMP content of embryonic somites.

Previous studies have demonstrated that collagen substrates stimulate in vitro somite chondrogenesis, and that agents that elevate intracellular cyclic AMP levels in hibit the ability of somites to respond to the inductive influence of collagen. In the present investigation, radiommunoassay was utilized to compare the cyclic AMP content of somite explants cultured on purified Type I collagen substrates with control explants cultured on Millipore filters. During the period of culture, the cyclic AMP content of collagen-treated explants is significantly lower than the cyclic AMP content of control explants. The cyclic AMP content of collagen-treated explants is 66% of control values as early as one hour following the initiation of culture, and the cyclic AMP content of collagen-treated explants remains lower than controls throughout the 3-day cultured period. The greatest difference in the cyclic AMP content of collagen-treated and control explants is observed at the seventeenth hour of culture, at which time the cyclic AMP content of collagen-treated explants is 56% of controls. These results combined with previous studies provides support for the hypothesis that collagen elicits a reduction in the cyclic AMP content of embroyic somites and that this reduction is necessary to trigger chondrogenic differentiation.     

Tracheary element differentiation is correlated with inhibition of cell expansion in xylogenic mesophyll suspension cultures.

To test the hypothesis that xylogenesis is coupled to cell growth suppression, cell expansion in Zinnia elegans L. var. Envy mesophyll suspension cultures was manipulated by varying the extracellular osmolarity and the effect on xylogenesis was examined. Cell expansion and tracheary element differentiation were inversely related along a gradient of extracellular osmolarity ranging from 200 to 400 mOsm, supporting the hypothesis that tracheary element differentiation is coupled to cessation of cell expansion. Above 300 mOsm, reduction in the number of cells that differentiated into tracheary elements coincided with an increase in the number of plasmolyzed cells as extracellular osmolarity was increased, indicating that plasmolysis inhibits tracheary element differentiation, although not specifically. Using the plasmolysis method we showed that cellular osmolarity within populations of isolated Zinnia mesophyll cells ranges from 250 to 600 mOsm with a mean of 425 mOsm. The broad range in cellular osmolarity within Zinnia mesophyll cell populations, coupled with inhibition of differentiation in the low range due to cell expansion and in the high range due to plasmolysis, may help explain why tracheary element differentiation in Zinnia suspension cultures is never complete nor perfectly synchronous and enable further optimization of this culture system.