Changes in the activity and mRNA of cinnamyl alcohol dehydrogenase during tracheary element differentiation in zinnia.

Changes in the enzymatic activity of cinnamyl alcohol dehydrogenase (CAD) and in the expression of a gene for CAD during tracheary element (TE) differentiation were investigated in cultures of single cells isolated from the mesophyll of zinnia (Zinnia elegans). In cultures in which TE differentiation was induced (TE-inductive cultures), CAD activity increased from h 36 after the start of culture (12 h before the start of thickening of the secondary cell wall) and peaked at h 72, when lignin was actively being deposited. In control cultures in which TE differentiation was not induced, CAD activity remained at a very low level for 5 d. Some isoforms of CAD were detected only in the TE-inductive cultures by native gel electrophoresis and subsequent staining for CAD activity. A cDNA clone for CAD, ZCAD1, was isolated from Z. elegans using a cDNA clone for CAD from Aralia cordata as the probe. RNA gel-blot analysis revealed that in the TE-inductive cultures the level of ZCAD1 mRNA increased from h 36 and peaked at h 48 to 60. No such increases were observed in control cultures. These results indicated that both the gene expression and the activity of CAD are strictly regulated, in association with lignification, during TE differentiation in Z. elegans.     

Involvement of extracellular dilignols in lignification during tracheary element differentiation of isolated Zinnia mesophyll cells

During differentiation of isolated Zinnia mesophyll cells into tracheary elements (TEs), lignification on TEs progresses by supply of monolignols not only from TEs themselves but also from surrounding xylem parenchyma-like cells through the culture medium. However, how lignin polymerizes from the secreted monolignols has not been resolved. In this study, we analyzed phenol compounds in culture medium with reversed-phase HPLC, gas chromatography-mass spectrometry and nuclear magnetic resonance spectrometry, and found 12 phenolic compounds including coniferyl alcohol and four dilignols, i.e. erythro-guaiacylglycerol-beta-coniferyl ether, threo-guaiacylglycerol-beta-coniferyl ether, dehydrodiconiferyl alcohol and pinoresinol, in the medium in which TEs were developing. Coniferyl alcohol applied to TE-inductive cultures during TE formation rapidly disappeared from the medium, and caused a sudden increase in dilignols. Addition of the dilignols promoted lignification of TEs in which monolignol biosynthesis was blocked by an inhibitor of phenylalanine anmmonia-lyase (PAL), L-alpha-aminooxy-beta-phenylpropionic acid (AOPP). These results suggested that dilignols can act as intermediates of lignin polymerization.     

In-vitro tracheary element formation: structural studies and the effect of tri-iodobenzoic acid

The process of tracheary element formation by cultured isolated mesophyll cells of Zinnia elegans has been investigated by the use of scanning and transmission electron microscopy. Freshly isolated cells are typified by a thin primary wall, starch-filled chloroplasts and a nucleus with a small nucleolus and peripherally located chromatin. During culture the nucleolus expands and becomes vacuolate, and the chromatin in the nucleus is dispersed. Wall thickening is accompanied by a localisation of microtubules over the thickenings and a slight increase in dictyosome activity. Wall hydrolysis appears to proceed by a previously undescribed mechanism, and gives rise to a granularparticulate appearance in the hydrolysed wall. Tri-iodobenzoic acid inhibits the process of differentiation and induces a polar pattern of growth in the cultured cells.Abbreviation TIBA Tri-iodobenzoic acid     

Separation and characterization of the isoenzymes of wall-bound peroxidase from cultured Zinnia cells during tracheary element differentiation

Cell wall-bound peroxidase (EC 1.11.1.7) isoenzymes (P1-P5) from cells of Zinnia elegans L. that were differentiating into tracheary elements were separated and characterized to obtain information about the relationships between these isoenzymes and the biosynthesis of lignin. Fractionation of Zinnia cells by centrifugation in solutions of Percoll revealed that P1, P2, and P5 were present in differentiated tracheary elements. These peroxidase isoenzymes were separated by several column-chromatographic steps. During hydrophobic chromatography on Phenyl Superose, P5 activity was separated into activities P5A and P5B. Enzymatically pure preparations of P1, P3, P5A, and P5B were finally obtained and used for the characterization of each isoenzyme. The optimum pH was 5.5–6.0 for P1, 5.0–7.5 for P3, 5.0 for P5A, and 4.0 for P5B. Each of the isoenzymes oxidized coniferyl alcohol efficiently, whereas p-coumaryl alcohol and sinapyl alcohol were poor substrates for all the isoenzymes. An absolute requirement for Ca²⁺ ions was demonstrated for P3. Based on these results, possible roles of peroxidase isoenzymes in the formation of lignin during the differentiation of tracheary elements are discussed.Abbreviations DAB diaminobenzidine - GTA equal proportions of 3,3-dimethylglutaric acid, tris(hydroxymethyl)aminomethane, and 2-amino-2-methyl-1,3-propanediol - TE tracheary element The authors are very grateful to Professor M. Tanahashi of Gifu University for providing hydroxycinnamyl alcohols. This work was supported in part by Grants-in-Aid from the Ministry of Education, Science and Culture of Japan to H.F.     

Role of Arabidopsis RabG3b and autophagy in tracheary element differentiation

The vascular system of plants consists of two conducting tissues, xylem and phloem, which differentiate from procambium cells. Xylem serves as a transporting system for water and signaling molecules and is formed by sequential developmental processes, including cell division/expansion, secondary cell wall deposition, vacuole collapse and programmed cell death (PCD). PCD during xylem differentiation is accomplished by degradation of cytoplasmic constituents, and it is required for the formation of hollow vessels, known as tracheary elements (TEs). Our recent study revealed that the small GTPase RabG3b acts as a regulator of TE differentiation through its autophagic activation. By using an Arabidopsis in vitro cell culture system, we showed that autophagy is activated during TE differentiation. Overexpression of a constitutively active RabG3b (RabG3bCA) significantly enhances both autophagy and TE differentiation, which are consistently suppressed in transgenic plants overexpressing a dominant negative form (RabG3bDN) or RabG3b RNAi (RabG3bRNAi), a brassinosteroid-insensitive mutant bri1-301 and an autophagy mutant atg5-1. On the basis of our results, we propose that RabG3b functions as a component of autophagy and regulates TE differentiation by activating the process of PCD.     

Establishing in vitro Zinnia elegans cell suspension culture with high tracheary element differentiation

The Zinnia elegans mesophyll cell culture is a useful system for xylogenesis studies. The system is associated with highly synchronous tracheary element (TE) differentiation, making it more suitable for molecular studies requiring larger amounts of molecular isolates, such as mRNA and proteins and for studying cellulose synthesis. There is, however, the problem of non-uniformity and significant variations in the yields of TEs (%TE). One possible cause for this variability in the %TE could be the lack of a standardized experimental protocol in various research laboratories for establishing the Zinnia culture. Mesophyll cells isolated from the first true leaves of Z. elegans var Envy seedlings of approximately 14 days old were cultured in vitro and differentiated into TEs. The xylogenic culture medium was supplied with 1 mg/l each of benzylaminopurine (BA) and α-naphthalene acetic acid (NAA). Application of this improved culture method resulted in stable and reproducible amounts of TE as high as 76% in the Zinnia culture. The increase was mainly due to conditioning of the mesophyll cell culture and adjustments of the phytohormonal balance in the cultures. Also, certain biochemical and cytological methods have been shown to reliably monitor progress of TE differentiation. We conclude that, with the adoption of current improvement in the xylogenic Z. elegans culture, higher amounts of tracheary elements can be produced. This successful outcome raises the potential of the Zinnia system as a suitable model for cellulose and xylogenesis research.     

Competitive action between Brassinosteroid and tracheary element differentiation inhibitory factor in controlling xylem cell differentiation

For permanent secondary growth in plants, cell proliferation and differentiation should be strictly controlled in the vascular meristem consisting of (pro)cambial cells. A peptide hormone tracheary element differentiation inhibitory factor (TDIF) functions to inhibit xylem differentiation, while a plant hormone brassinosteroid (BR) promotes xylem differentiation in (pro)cambial cells. However, it remains unclear how TDIF and BR cooperate to regulate xylem differentiation for the proper maintenance of the vascular meristem. In this study, I developed an easy evaluation method for xylem differentiation frequency in a vascular induction system Vascular cell Induction culture System Using Arabidopsis Leaves (VISUAL) by utilizing a xylem-specific luciferase reporter line. In this quantitative system, TDIF suppressed and BR promoted xylem differentiation in a dose-dependent manner, respectively. Moreover, simultaneous treatment of TDIF and BR with (pro)cambial cells revealed that they can cancel their each other’s effect on xylem differentiation, suggesting a competitive relationship between TDIF and BR. Thus, mutual inhibition of “ON” and “OFF” signal enables the fine-tuned regulation of xylem differentiation in the vascular meristem.     

Flow cytometric analysis of tracheary element differentiation in Zinnia elegans cells.

BACKGROUND: Tracheary element (TE) differentiation in single cells in culture isolated from Zinnia elegans leaves involves programmed cell death (PCD) co-ordinated with key morphological developments. We have used flow cytometry to analyze physiological and nuclear changes in the differentiating cells. Flow cytometry allows the identification of subpopulations, thereby removing the obscuring effect of population heterogeneity that occurs with the use of other techniques. METHODS: Cell viability, plasma membrane integrity, oxidative activity, intracellular calcium and pH, cell wall thickening, the possible role of microtubule rearrangement, chromatin condensation, and DNA breakdown were followed by flow cytometry from the first stages of TE induction. RESULTS: TE differentiation could be enhanced and made more synchronous by a centrifugation step at 72 h after cell isolation. Size and shape changes were the first changes identified in differentiating cells, and these properties could be used to isolate differentiating populations by back-gating. Chromatin condensation and nDNA breakdown followed patterns characteristic of programmed cell death. CONCLUSIONS: We have used flow cytometry to characterize the morphological and physiological changes that occur during TE differentiation, and our findings indicate that this process is a form of autophagic PCD in which microtubule rearrangement appears to play a role.     

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.     

A simplified medium for in vitro tracheary element differentiation in mesophyll suspension cultures from Zinnia elegans L.

A simplified medium has been developed for the differentiation of tracheary elements in suspension cultures of mesophyll cells of Zinnia elegans L. All inorganic salts contained in media used previously were retained in the simplified medium, but most were reduced in concentration. The only organic supplements required for optimum differentiation were thiamine and nicotinic acid, in addition to the plant growth regulators N6-benzylaminopurine and -naphthyleneacetic acid, and sucrose as a carbon source. Mannitol, an osmoticum, was necessary for rapid, synchronous differentiation. This simplified medium is particularly suitable for studies of the role of Ca²⁺ in tracheary element differentiation due to the elimination of myo-inositol, an intermediate in the phosphatidyl inositol signal transduction pathway and reduction in the concentrations of Mg²⁺ and Mn²⁺, which block calcium channels. It is also possible to eliminate EDTA from the medium, enabling studies using specific calcium chelators. Additional culture variables for the optimization of differentiation are discussed.Abbreviation TE tracheary element     

Regulation of secondary cell wall development by cortical microtubules during tracheary element differentiation in Arabidopsis cell suspensions

Cortical microtubules participate in the deposition of patterned secondary walls in tracheary element differentiation. In this study, we established a system to induce the differentiation of tracheary elements using a transgenic Arabidopsis (Arabidopsis thaliana) cell suspension stably expressing a green fluorescent protein-tubulin fusion protein. Approximately 30% of the cells differentiated into tracheary elements 96 h after culture in auxin-free media containing 1 mum brassinolide. With this differentiation system, we have been able to time-sequentially elucidate microtubule arrangement during secondary wall thickening. The development of secondary walls could be followed in living cells by staining with fluorescein-conjugated wheat germ agglutinin, and the three-dimensional structures of the secondary walls could be simultaneously analyzed. A single microtubule bundle first appeared beneath the narrow secondary wall and then developed into two separate bundles locating along both sides of the developing secondary wall. Microtubule inhibitors affected secondary wall thickening, suggesting that the pair of microtubule bundles adjacent to the secondary wall played a crucial role in the regulation of secondary wall development.     

Involvement of gibberellin in tracheary element differentiation and lignification in Zinnia elegans xylogenic culture

Summary. Gibberellin (GA) is considered an important growth regulator involved in many aspects of plant development. However, little is known about the relationship between GA and lignification. In this study, we analyzed the role of GA in tracheary element (TE) differentiation and lignification using a Zinnia elegans xylogenic culture. When gibberellic acid-3 (GA₃) was exogenously supplied, a slight increase in the frequency of TE differentiation and a remarkable increase in lignin content were observed. Computer image analysis of individual TEs showed that the lignification level of each TE was significantly increased in the culture treated with GA₃ compared with those of the control. In contrast, suppression of TE differentiation and lignification was observed when GA biosynthesis was inhibited by ancymidol, paclobutrazol, or uniconazole. This suppression was restored by the addition of GA₃. These results suggest that GA plays an important role in TE differentiation, and even more so in lignification. When conditioned medium obtained after 120 h of control culture was analyzed by high-performance liquid chromatography, many lignin precursors were detected. However, these lignin precursors were greatly reduced in the GA-treated culture. This result suggests that GA promotes lignification by activating the polymerization of lignin precursors. Correspondence and reprints: Department of Biology, Faculty of Science, Ehime University, Matsuyama 790-8577, Japan.     

Rise in chlorotetracycline fluorescence accompanies tracheary element differentiation in suspension cultures ofZinnia

Summary Developing tracheary elements in suspension cultures ofZinnia elegans fluoresce intensely relative to non-differentiating cells when stained with chlorotetracycline (CTC), a fluorescent chelate probe for membrane associated calcium. This suggests that a change in calcium uptake or subcellular distribution accompanies the onset of tracheary element differentiation. A few cells in early differentiating cultures were brightly fluorescent, but did not have visible cell wall thickenings, suggesting that a rise in sequestered calcium may precede visible differentiation. Diffuse CTC fluorescence in early differentiation most likely results from sequestration of calcium in the endoplasmic reticulum. Late in differentiation, CTC fluorescence becomes punctate in appearance, probably due to loss of plasma membrane integrity occurring at the onset of autolysis.Zinnia suspension culture cells were found to be very sensitive to CTC and low concentrations (10 M) were used to assure accurate localization of membrane-associated calcium in healthy cells.Abbreviations CTC chlorotetracycline - DIC differential interference contrast - DiOC₆ 3,3-dihexyloxacarbocyanine iodide - ER endoplasmic reticulum - EGTA ethylene glycol bis-(amino-ethyl ether) N,N,N¹N¹-tetraacetic acid - NPN n-phenylnaphthylamine - OsFeCN osmium tetroxide and potassium ferricyanide - TE tracheary element - TEM transmission electron microscopy     

Gene expression patterns associated with in vitro tracheary element formation in isolated single mesophyll cells of Zinnia elegans.

Tracheary element formation from isolated Zinnia leaf mesophyll cells is an excellent system for the dissection of patterned secondary cell wall thickening and lignification. We used mRNAs from cells cultured for 48 h in the induction medium to isolate differentially regulated genes. Thirteen unique cDNA clones were isolated using a subtractive hybridization method. These clones can be divided into three distinct groups according to their characteristic gene expression in different media. The first group includes those genes whose expression is induced in the basal medium without 1-naphthaleneacetic acid (NAA) and benzyladenine; this indicates that the expression of these genes is regulated by chemical and physical factors other than these hormones. Three of these clones, p48h-229, p48h-114, and p48h-102, show significant homology to a pathogenesis-related protein II, a serine proteinase inhibitor, and a sunflower anther-specific proline-rich protein, respectively. The second group includes those genes whose expression is mainly NAA induced. One of these clones, p48h-10, shows high protein sequence homology to a barley aleurone-specific cDNA, B11E. The p48h-10-encoded protein shares some common characteristics of plant nonspecific lipid transfer proteins (low molecular weight, the secretion signal peptide, eight conserved cysteine residues, and a basic protein), although no significant protein sequence homology is found between p48-10 and other plant nonspecific lipid transfer proteins. The third group includes those genes whose expression is induced primarily in the induction medium; this indicates that the expression of these genes is closely associated with the process of tracheary element formation. Two of these clones, p48h-107 and p48h-17, show high homology to adenylate kinase and papaya proteinase I, respectively. The possible roles of these differentiation-specific genes during tracheary element formation are discussed.     

Xylogenesis in tissue culture III: Continuing wall deposition during tracheary element development

Summary DifferentiatingZinnia cultures have two bursts of tracheary element (TE) formation which resemble the production of proto- and metaxylem in higher plants. TEs in the first burst have annular, spiral or reticulate secondary wall patterns while those in the second burst have reticulate, scalariform or pitted walls. Continuing wall deposition in TEs results in the transformation of annular or spiral patterns into scalariform or pitted. Indirect immunofluorescent observation of TE microtubules (MTs) during continuing wall deposition indicates an annular/spiral pattern is deposited first followed by the introduction of new arrays of MTs which guide later, in-filling wall deposition.Abbreviations TE Tracheary element - MTs Microtubules     

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.     

Progress of lignification mediated by intercellular transportation of monolignols during tracheary element differentiation of isolated Zinnia mesophyll cells

Tracheary element (TE) differentiation is a typical example of programmed cell death (PCD) in higher plants, and maturation of TEs is completed by degradation of all cell contents. However, lignification of TEs progresses even after PCD. We investigated how and whence monolignols are supplied to TEs which have undergone PCD during differentiation of isolated Zinnia mesophyll cells into TEs. Higher densities of cell culture induced greater lignification of TEs. Whereas the continuous exchanging of culture medium suppressed lignification of TEs, further addition of coniferyl alcohol into the exchanging medium reduced the suppression of lignification. Analysis of the culture medium by HPLC and GC-MS showed that coniferyl alcohol, coniferaldehyde, and sinapyl alcohol accumulated in TE inductive culture. The concentration of coniferyl alcohol peaked at the beginning of secondary wall thickening, decreased rapidly during secondary wall thickening, then increased again. These results indicated that lignification on TEs progresses by supply of monolignols from not only TEs themselves but also surrounding xylem parenchyma-like cells through medium in vitro.     

Involvement of phosphoinositide turnover in tracheary element differentiation in Zinnia elegans L. cells

Mesophyll cells of Zinnia elegans L., cultured in the presence of phytohormones, will transdifferentiate and undergo programmed cell death to become tracheary elements, thick-walled cells of the xylem. This system is a model system for study of plant cell development and differentiation. We report that a high concentration of extracellular Ca(2+) is necessary during the first 6 h of culturing for tracheary elements to form. Extracellular Ca(2+) is still required at later times, but at a much lower concentration. When cells transdifferentiate in adequate Ca(2+), microsomal phospholipase C activity increases and levels of inositol 1,4,5-trisphosphate rise at about hour 4 of culturing. The production of inositol 1,4,5-trisphosphate appears to be important for tracheary element formation, since inhibitors of phospholipase C inhibit both inositol 1,4,5-trisphosphate production and tracheary element formation. Pertussis toxin, an inhibitor of GTP-binding proteins, inhibits transdifferentiation and eliminates inositol 1,4,5-trisphosphate production. Tracheary element formation was not completely abolished by inhibitors that eliminated inositol 1,4,5-trisphosphate production, suggesting the involvement of other pathways in regulating transdifferentiation.     

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.