Relationship between tracheary element differentiation and the cell cycle in single cells isolated from the mesophyll of Zinnia elegans

A relationship between tracheary element differentiation and the cell cycle was studied in single cells isolated from the mesophyll of Zinnia elegans L. cv. Canary bird. Almost all nuclei of isolated mesophyll cells were at the 2 C level of DNA, indicating that almost all cells were initially in the G₁ phase and that somatic polyploidy was absent. Cultured cells underwent partially synchronous DNA replication at 42 h and mitosis at 54 h of culture, and the first cell cycle time was approximately 58 h.
The occurrence and timing of DNA replication and mitosis during cytodifferentiation to tracheary elements were investigated using microspectrophotometry, microfluorometry, tritiated thymidine autoradiography, and serial observation. More than 55% of the nuclei of the immature tracheary elements were at the 2 C level of DNA and were not labeled by continuous feeding with tritiated thymidine, providing clear evidence that these cells differentiated without interventing DNA replication. Some tracheary elements (approximately 30%) were formed after one round of the cell cycle, and others (less than 5%) were formed after passing through the S phase, but without intervening mitosis. All types of tracheary elements appeared simultaneously after 58 h of culture, and their patterns of increase in number were similar. From the results, we propose a hypothesis concerning the relationship between cytodifferentiation and the cell cycle.     

Hormonal Control of Cell Proliferation and Xylem Differentiation in Cultured Tissues of Glycine max var. Biloxi

The relationship between tracheary element differentiation, cell proliferation and growth hormones was examined in agar-grown soybean callus. The time course of cell division and tracheary element formation in tissues grown on a medium containing 5 x 10(-7)m kinetin and 10(-5)m NAA was determined by means of maceration technique. After a slight lag period, a logarithmic increase in cell number was observed through the twelfth day of the culture period. Cell numbers increased at a considerably slower rate after the twelfth day. The rate of tracheary element formation varied with the rate of cell proliferation. Tracheary elements increased logarithmically during the log phase of growth. As the rate of cell division decreased after the twelfth day of culture, the rate of tracheary element formation also decreased. In the presence of 10(-5)m NAA, cell number increased as the kinetin concentration was increased between 10(-9) and 10(-6)m. However, tracheary element formation was not initiated unless the kinetin concentration was 5 x 10(-8)m or above. When the Biloxi callus was subcultured repeatedly on media containing 10(-8)m kinetin, a tracheary element-free population of cells was obtained. This undifferentiated tissue produced tracheary elements upon transfer to a medium containing 5 x 10(-7)m kinetin. In the presence of 5 x 10(-7)m kinetin, NAA stimulated cell proliferation between 10(-7) and 10(-5)m, but no tracheary elements were formed without auxin, or with 10(-7)m NAA. Neither NAA nor kinetin at any concentration tested stimulated tracheary element formation in the absence of an effective level of the other hormone. However, 2,4-D at 10(-7) or 10(-6)m promoted both cell proliferation and tracheary element differentiation in the absence of an exogenous cytokinin.     

Galactoglucomannan oligosaccharides are assumed to affect tracheary element formation via interaction with auxin in Zinnia xylogenic cell culture

Key message

Galactoglucomannan oligosaccharides seem to interact with auxin in xylogenic cell culture, thus influencing mainly metaxylem-like tracheary element differentiation depending on timing with hormones and the process kinetics.

Abstract

Complex mapping of Zinnia mesophyll cell transdifferentiation into tracheary elements with or without prior cell division was documented after palisade and spongy parenchyma cell immobilization during the first 4 days of culture. Here, we report a positive effect of galactoglucomannan oligosaccharides on cell viability and density and higher metaxylem-like tracheary element formation in xylogenic cell culture. The maximal positive effect was achieved by the simultaneous addition of the oligosaccharides and growth hormones (auxin, cytokinin) to the cell culture medium. Moreover, a large number of metaxylem-like tracheary elements were observed in a low-auxin medium supplemented with oligosaccharides, but not in a low-cytokinin medium, suggesting a close relationship between auxin and the oligosaccharides during tracheary element formation.     

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     

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     

Transition of G1 to early S phase may be required for zinnia mesophyll cells to trans-differentiate to tracheary elements

We have used the Zinnia elegans mesophyll cell system, in which single isolated leaf mesophyll cells can be induced to trans-differentiate into tracheary elements in vitro, to study the relationship between the cell division cycle and cell differentiation. Almost all cells go through several rounds of division before characteristic features of tracheary element formation are observed. The addition of aphidicolin, a DNA synthesis inhibitor, blocks cell division but not cell differentiation in the zinnia system. Low concentrations of aphidicolin, which possibly delay cells in the early S phase, can significantly enhance levels of tracheary element formation. In contrast, roscovitine, an inhibitor of cyclin-dependent kinase activity, decelerates the cell division cycle and inhibits tracheary element formation with similar dose responses. Cells blocked in S phase and then transferred to roscovitine-containing medium can divide once, indicating that roscovitine may target the G1/S transition, but do not differentiate. Cells inhibited in G1/S in roscovitine-containing medium that are subsequently blocked in S phase by transfer to aphidicolin-containing medium, do not divide but do differentiate. Taken together, our results indicate that cells may be required to transit the G1/S checkpoint and enter early S phase to acquire competence to trans-differentiate to tracheary elements.     

A possible role of cyclic AMP on tracheary element formation in cultured carrot-root slices

When the root-phloem slices ofDaucus carota cv. Hokkaidô-gosun were cultured on a Murashige and Skoog's medium containing 2,4-dichlorophenoxyacetic acid (2,4-D medium) and cyclic AMP or its analogues, tracheary elements were formed in the dark, while they were not formed on the medium containing only 2,4-D in the dark. The number of tracheary elements induced by cyclic AMP was far less than that induced by cytokinin or 8-bromo-cyclic AMP. But when theophylline, an inhibitor of cyclic AMP phosphodiesterase, was used in combination with cyclic AMP in the culture, the number of tracheary elements was significantly increased. A remarkable increase in cytokinin activity was found in the hydrolyzate of soluble RNA extracted from the slices cultured on the 2,4-D medium containing 8-bromo-cyclic AMP, but only negligible cytokinin activity was detected in the hydrolyzate of soluble RNA extracted from the slices cultured on the 2,4-D medium without 8-bromo-cyclic AMP. Since cytokinin production occurred in the slices cultured in the light, it was supposed that light irradiation might induce cyclic AMP production. The mechanism of cytokinin production leading to tracheary element formation mediated by cyclic AMP level is discussed.     

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     

In vitro induction of secondary xylem-like tracheary elements in calli of hybrid poplar (Populus sieboldii × P. grandidentata)

The formation of tracheary elements was induced in calli derived from petioles of hybrid poplar (Populus sieboldii × P. grandidentata) after 10 days of culture on medium that lacked auxin but contained 1 μM brassinolide. Some differentiated cells formed broad regions of cell walls and bordered pits, which are typical features of tracheary elements of secondary xylem. Other differentiated cells resembled tracheary elements of primary xylem, with spiral or reticulate thickening of cell walls. The tracheary elements that developed in calli were formed within cell clusters. This induction system provides a new model for studies of the mechanism of differentiation of secondary xylem cells in vitro.     

Effects of Nutrient Limitation and {gamma}-Irradiation on Tracheary Element Differentiation and Cell Division in Single Mesophyll Cells of Zinnia elegans

The effects of nutrient limitation and -irradiation on trachearyelement differentiation and cell division were investigatedusing single cells isolated from the mesophyll of Zinnia elegans.When the phosphate concentration of the medium was reduced to10 µM (1/50 of Fukuda and Komamine's medium, 1980a), thefrequency of cell division during 4 days of culture decreased,while the frequency of tracheary element differentiation wasunaffected. -Irradiation with a dose of 92 Gy at 36 h of culturepreferentially and thoroughly suppressed cell division withoutreducing the number of tracheary elements formed. The appearanceof secondary cell wall thickenings was delayed by irradiation,but synchrony was maintained. Thus the Zinnia system previouslyreported [Fukuda and Komamine (1980a) Plant Physiol. 65: 57]was improved to give a more useful system for the study of cytodifferentiation,in which tracheary element formation occurred from single cellswithout cell division. ¹Present address: Biological Institute, Faculty of Science,Tohoku University, Sendai, Miyagi 980, Japan. (Received November 28, 1985; Accepted February 22, 1986)     

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.     

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.     

Effect of high salinity on tracheary element differentiation in light-grown callus of Mesembryanthemum crystallinum

This study investigated the inhibitory effects of NaCl on tracheary element (TE) differentiation in light-grown callus of ice plant Mesembryanthemum crystallinum L., a halophyte which adaptes well to saline environments. When ice plant callus was grown in a modified Linsmaier-Bednar and Skoog culture medium containing no NaCl (control medium), up to 20% of ice plant cells differentiated into tracheary elements during in vitro culture. Close examination of callus tissues stained with potassium permanganate revealed that tracheary elements were aggregated as discrete nodules. Some strikingly elongated tracheary elements were found in the macerated tissues. Experimental results indicated that adding 200 mM NaCl to the control medium reversibly inhibited the formation of tracheary element in the halophytic cells. The rate of tracheary element formation increased accordingly as the rate of cell growth in control medium. In the presence of high salt, the degree of tracheary element differentation remained low through the growth cycle. The inhibitory effect of salt on tracheary element differentiation was overcome by adding 10 mg l⁻¹ salicylic acid, a known signaling compound that induces a diverse group of defense-related genes, including genes involved in reinforcing the host cell wall. Furthermore, microscopic examination revealed that most tracheary elements formed under this treatment (200 mM NaCl plus 10 mg l⁻¹ salicylic acid) were round shaped. The results suggest that high salt inhibits both the biosynthesis of secondary wall components and cell elongation ice plant in vitro culture. This revised version was published online in June 2006 with corrections to the Cover Date.     

Autolysis during in vitro tracheary element differentiation: formation and location of the perforation

Tracheary elements differentiated from isolated Zinnia: mesophyll cells were observed at various times of culture under a scanning electron microscope. Perforation occurred on the primary wall at one of the longitudinal ends in single tracheary elements. In double tracheary elements, which both of two cells derived from a single cell differentiated into, the pore opened on the primary walls both at the junction of the two tracheary elements and at a longitudinal end of one of the two tracheary elements. These results suggest not only that a single tracheary element has its own program to form a perforation at one end without being affected by neighboring cells, but also that isolated cells indeed hold some traces of polarity and cell-cell communication.     

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)     

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.     

Role of auxin and sucrose in the differentiation of sieve and tracheary elements in plant tissue cultures

The differentiation of sieve and tracheary elements was studied in callus culture of Daucus carota L., Syringa vulgaris L., Glycine max (L.) Merr., Helianthus annuus L., Hibiscus cannabinus L. and Pisum sativum L. By the lacmoid clearing technique it was found that development of the phloem commenced before that of the xylem. In not one of the calluses was differentiation of tracheary elements observed in the absence of sieve elements. The influence of indole-3-acetic acid (IAA) and sucrose was evaluated quantitatively in callus of Syringa, Daucus and Glycine. Low IAA levels resulted in the differentiation of sieve elements with no tracheary cells. High levels resulted in that of both phloem and xylem. IAA thus controlled the number of sieve and tracheary elements, increase in auxin concentration boosting the number of both cell types. Changes in sucrose concentration, while the IAA concentration was kept constant, did not have a specific effect on either sieve element differentiation, or on the ratio between phloem and xylem. Sucrose did, however, affect the quantity of callose deposited on the sieve plates, because increase in the sucrose concentration resulted in an increase in the amount of callose. It is proposed that phloem is formed in response to auxin, while xylem is formed in response to auxin together with some added factor which reaches it from the phloem.     

Interaction of auxin, cytokinin, and gibberellin on cell division and xylem differentiation in cultured explants of Jerusalem artichoke.

Dark-cultured explants of parenchymatous cells isolated fromJerusalem artichoke tubers were induced to divide and differentiateas tracheary elements on Murashige and Skoog medium containingdifferent combinations of plant growth-hormones such as auxin(IAA), cytokinin (zeatin), and gibberellin (GA₃). Addition ofauxin to the growth-medium induced after a short lag period,very rapid cell division which was followed by differentiationof some of the divided cells as tracheary elements. At the optimallevel of IAA (5.0 mg/liter), the percentage of tracheids differentiatedwith respect to the total number of cell population was 13.54.When the explants were cultured in the presence of both auxin(IAA 5.0 mg/liter) and one cytokinin (zeatin 0.1 mg/liter),not only a strong interaction on cell division and trachearyelement formation was observed but also an increase in the percentageof tracheids differentiated in relation to the total cell population.Auxin-gibberellin and auxin-gibberellin-cytokinin treatmentsalso produced interaction on cell division and cytodifferentiation.In explants treated with the three growth-hormones about 20%of the total cell population differentiated as tracheary elements.Further, all the hormonal treatments gave different patternsof cytodifferentiation which reflected meristematic patterns. ¹ This research was supported by a grant from C. N. R. Italy. (Received April 18, 1973; )     

Specific peroxidase isoenzymes are correlated with organogenesis

We have examined isoperoxidase patterns obtained from buffer-, salt-, and enzyme-extractable fractions and correlated them with histological changes in tobacco (Nicotiana tabacum L., cv Wisc. 38) `epidermal' explants induced to produce either callus, vegetative buds, or floral buds. By utilizing a combination of extraction and electrophoretic procedures different from any hitherto used for this kind of investigation, we were able to resolve 47 isoperoxidases distributed between the three types of fractions. The majority of these isoperoxidases were common to all explants regardless of their developmental fate. Correspondingly, a number of histological changes were observed in all explants (e.g. the initiation of cell division by day 2, lignin deposition by day 4, and the formation of clustered tracheary elements by day 8). We have made correlations between 25 isoperoxidases and specific developmental events based on the time when certain isoperoxidases were detected relative to observed histological changes: 3 were correlated with desuppressed/sustained cell division, 3 to 6 with lignification/tracheary element maturation, 7 with callus formation, 1 with localized suppression of growth, 3 with determinate axial organization, 4 with leaf development, and 1 with stamen development. These results suggest that a continued investigation using this system could lead to a better understanding of the role of specific isoperoxidases in different developmental processes.     

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.