Tracheary element differentiation in Zinnia mesophyll cell cultures

Mechanically isolated mesophyll cells of Zinnia elegans differentiate into tracheary elements (TEs) when cultured in a medium containing adequate auxin and cytokinin. Differentiation in this culture system is relatively synchronous, rapid (occuring within 3 days of cell isolation) and efficient (with up to 65% of the mesophyll cells differentiating into TEs), and does not require prior mitosis. The Zinnia system has been used to investigate (a) cytological and ultrastructural changes occurring during TE differentiation, such as the reorganization of microtubules controlling secondary wall deposition, (b) the influences of calcium and of various plant hormones and antihormones on TE differentiation, and (c) biochemical changes during differentiation, including those occurring during secondary wall deposition, lignification and autolysis. This review summarizes experiments in which the Zinnia system has served as a model for the study of TE differentiation.     

Proteasome Inhibitors Prevent Tracheary Element Differentiation in Zinnia Mesophyll Cell Cultures

To determine whether proteasome activity is required for tracheary element (TE) differentiation, the proteasome inhibitors clasto-lactacystin β-lactone and carbobenzoxy-leucinyl-leucinyl-leucinal (LLL) were used in a zinnia (Zinnia elegans) mesophyll cell culture system. The addition of proteasome inhibitors at the time of culture initiation prevented differentiation otherwise detectable at 96 h. Inhibition of the proteasome at 48 h, after cellular commitment to differentiation, did not alter the final percentage of TEs compared with controls. However, proteasome inhibition at 48 h delayed the differentiation process by approximately 24 h, as indicated by examination of both morphological markers and the expression of putative autolytic proteases. These results indicate that proteasome function is required both for induction of TE differentiation and for progression of the TE program in committed cells. Treatment at 48 h with LLL but not clasto-lactacystin β-lactone resulted in partial uncoupling of autolysis from differentiation. Results from gel analysis of protease activity suggested that the observed incomplete autolysis was due to the ability of LLL to inhibit TE cysteine proteases.     

Tracheary element differentiation

Differentiation of tracheary elements (TEs), characterized by formation of a visible secondary cell wall and autolysis, has been regarded as a model system for cytodifferentiation in plants. Fukuda and Komamine (Plant Physiol 65:57–60, 1980a) established an efficient experimental system for TE differentiation from isolated single mesophyll cells of Zinnia elegans. Physiological, cytological, and biochemical analyses of this system have revealed multiple aspects of TE differentiation regarding cell division, DNA synthesis, the cytoskeleton, autolysis, phytohormones, and cell wall components. In addition, molecular biological approaches have identified a number of Zinnia genes associated with TE-specific events. The knowledge obtained in the Zinnia system has been expanded to studies in other plants including Arabidopsis, leading to the identification of key regulators of TE differentiation.     

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.     

Cytodifferentiation in isolated single cells

Isolated mesophyll cells ofZinnia elegans synchronously differentiate to tracheary elements at a high frequency when cultured in a liquid medium containing naphth-aleneacetic acid and benzyladenine. An experimental system with the isolatedZinnia mesophyll cells has been extensively used as an efficient model system for the study of cytodifferentiation in higher plants, providing many valuable results on cytodifferentiation. In this review, I introduce the results obtained with theZinnia system and discuss the induction and the sequence of differentiation. Recipient of the Botanical Society Award for Young Scientists, 1987.     

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.     

Induction of cysteine and serine proteases during xylogenesis in Zinnia elegans

The terminal process of xylogenesis, autolysis, is essential for the formation of a tubular system for conduction of water and solutes throughout the whole plant. Several hydrolase types are implicated in autolysis responsible for the breakdown of cytoplasm. Here, we characterize p48h-17 cDNA from in vitro tracheary elements (TEs) of Zinnia elegans which encodes a preproprotein similar to papain. The putative mature protein, a cysteine protease, has a molecular mass of 22,699 Da with a pI of 5.7. DNA gel blot analysis indicated that p48h-17 is likely encoded by one or two genes. The p48h-17 mRNA accumulated markedly in in vitro differentiating TEs, whereas it appeared not to be induced in response to senescence and wounding in the leaves or H₂O₂ challenge in the cultured mesophyll cells. In stems, the expression of the p48h-17 gene was preferentially associated with differentiating xylem. Activity gel assays demonstrated that a cysteine and a serine protease, which had apparent molecular masses of 20 kDa and 60 kDa, respectively, were markedly induced during in vitro TE differentiation. The cysteine protease activity was also preferentially present in the xylem of Zinnia stems. Transient expression of the p48h-17 cDNA in tobacco protoplasts resulted in the production of a 20 kDa cysteine protease. Taken together, the results indicate that the p48h-17 gene appears to be preferentially associated with xylogenesis, and both the cysteine and serine proteases might be involved in autolysis during xylogenesis.     

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.     

Involvement of Poly(ADP-Ribose) Synthesis in Transdifferentiation of Isolated Mesophyll Cells of Zinnia elegans into Tracheary Elements

The relationship between poly(ADP-ribose) synthesis and cytodifferentiationwas studied in the well characterized Zinnia system, in whichisolated mesophyll cells of Zinnia elegans transdifferentiateinto tracheary elements (TE) in a suspension culture in thepresence of both auxin and cytokinin. The rate of poly(ADP-ribose)synthesis was measured in nuclei isolated from cells that hadbeen induced to undergo transdifferentiation, and activationof such synthesis was observed before the appearance of TE duringculture. In cultures without auxin or cytokinin, poly-(ADP-ribose)synthesis appeared to proceed much more slowly. Treatment of cells with a potent inhibitor of poly-(ADP-ribose)polymerase, namely, 6(5H)-phenanthridinone (PT), resulted inthe blockage of TE formation and a decrease in the frequencyof cell division. PT was very effective in interfering withtransdifferentiation, in particular, when supplied between the24th hour and the 36th hour of culture. Repair-type DNA synthesis,which has been proposed to participate in transdifferentiation,was suppressed by the treatment with PT. These results suggestthat poIy(ADP-ribose) synthesis and subsequent repair-type DNAsynthesis might play a critical role in the transdifferentiationof Zinnia cells. ³Present address: Botanical Gardens, Faculty of Science, Universityof Tokyo, Hakusan, Bunkyo-ku, Tokyo, 112 Japan. ⁴Present address: Department of Chemical and Biological Sciences,Faculty of Science, Japan Women's University, Mejirodai, Bunkyo-ku,Tokyo, 112 Japan.     

Dynamic changes in cell surface molecules are very early events in the differentiation of mesophyll cells from Zinnia elegans into tracheary elements

The Zinnia mesophyll cell system consists of isolated leaf mesophyll cells in culture that can be induced, by auxin and cytokinin, to transdifferentiate semi-synchronously into tracheary elements (TEs). This system has been used to establish the precise time point at which the TE cell fate becomes determined, and then changes have been looked for in cell-wall composition and architecture that are associated with the establishment of competence, determination, and differentiation with the transition from primary to secondary cell wall formation. At very early stages in this time course, changes in the repertoire of proteins and polysaccharides both in the cell wall and secreted into the culture medium were found. Changes in the secretion of pectic polysaccharides, xyloglucans and arabinogalactan proteins (AGPs) have been detected using the monoclonal antibodies JIM 7, CCRC-M1 and JIM 13, that recognize these three classes of cell-wall molecule, respectively. Twenty-four hours before secondary thickenings are visible, an AGP is present in the primary walls of a subpopulation of cells, and is secreted into the culture medium. This molecule is present in the secondary thickenings of mature TEs but not in their surrounding primary walls. Methyl-esterified pectic polysaccharides are present in all cell walls and are secreted into the culture medium throughout the time course of differentiation, though at an increased rate in inductive medium. However, sugar and linkage analysis of culture media shows that a relatively unbranched rhamnogalacturonan is enriched in inductive medium around the time of determination and increases rapidly in concentration. The amount of fucosylated xyloglucan in cell walls increases during the time course, but appears in inductive medium 24 h earlier than in control medium and may have a subtly different structure. The fucose-containing epitope on the xyloglucan disappears abruptly and entirely from inductive medium 6 h before any secondary thickenings are visible in the cells. The disappearance of the epitope is correlated with secretion of several hydrolytic enzyme activities. In Zinnia leaves, the mesophyll cell walls contain neither the fucosylated xyloglucan nor the AGP, although methylesterified pectin is present. All three epitopes are expressed in the vascular bundles, and the AGP is specifically localized in the xylem cells. Fucosylated xyloglucan is also present in the epidermal tissue, and the AGP is present in guard cells. The dynamic behaviour of these specific cell-wall molecules is tightly correlated with differentiation events in vitro, and can be clearly distinguished from the production of new wall material found in expanding and elongating cells. The precise timing of the appearance and disappearance of these proteins and polysaccharides compared with the point of cell-fate determination provides us with a series of cell-surface markers for cell states at very early times in the transdifferentiation pathway.     

Isolation and characterization of cDNAs encoding xylogenesis-associated and wounding-induced ribonucleases in Zinnia elegans

The study of plant ribonuclease (RNase) functions is complicated by a complex profile of RNase activities detected in tissues. Thus, isolation of individual RNase genes will be desirable for the further understanding of function of each RNase. Here, we describe the isolation of cDNAs encoding two RNases, ZRNaseI and ZRNaseII, in differentiating tracheary elements (TEs) induced from isolated mesophyll cells of Zinnia elegans. Both the ZRNaseI and ZRNaseII exhibit putative secretion signal sequences at the amino-terminal ends with predicted molecular masses of 24 247 Da and 22 448 Da as mature proteins, respectively. DNA gel blot analysis showed that both RNases in Zinnia appear to be encoded by a small gene family. RNA gel blot analysis showed that the expression of the ZRNaseI gene was associated with the late stage of in vitro TE differentiation, whereas the ZRNaseII gene was mainly induced in response to stress. Neither RNase gene was induced in response to phosphate starvation, or to H₂O₂ challenge in the cultured mesophyll cells, or to senescence in the leaves. In young leaves, the ZRNaseI gene was not induced in response to wounding. But the ZRNaseII gene was markedly induced by 6 h after wounding. Tissue print hybridization showed that the expression of the ZRNaseI gene was preferentially associated with the differentiating TEs in Zinnia stems, while the ZRNaseII mRNA was not detected in unwounded Zinnia organs. Taken together, the results indicate that the ZRNaseI gene is expressed during the process of xylogenesis both in vitro and in the plant, whereas the ZRNaseII gene is predominantly induced in response to wounding. The identification of these RNase genes provides molecular tools for the dissection of the process of autolysis during xylogenesis, and for the dissection of the role of RNase in wounding response.Dedicated to Dr Joseph Elmer Varner.     

Molecular cloning of BPL1, a pectate lyase-like gene in Brassica napus

Pectate lyase (EC 4.2.2.2) is an enzyme involved in the maceration and soft rotting of plant tissue via degradation of cell wall in organisms. Plants as well as bacteria and fungi are capable of producing pectate lyases. Here we report the cloning of a novel full-length cDNA of pectate lyase gene, designated BPL1, from Brassica napus by rapid amplification of cDNA ends. BPL1 cDNA is 1787 bp containing a 1503 bp ORF encoding a 500 amino acid protein precursor. The protein precursor has a potential signal peptide with 22 amino acids. Alignment of sequences shows that there are some extremely conserved amino acids among pectate lyase-like proteins from different plant species, and novel C-terminal domains are found in Arabidopsis and Brassica. Phylogenetic analysis of 50 pectate lyase-like proteins from various species demonstrates the obvious distinction among pectate lyase-like proteins from plants, bacteria and fungi, which are subsequently clustered into three groups. The cloning of BPL1 enables us to explore its diverse roles in higher plants and potential application in crop improvement.     

Arg<Superscript>235</Superscript> is an essential catalytic residue of <Emphasis Type="Italic">Bacillus pumilus</Emphasis> DKS1 pectate lyase to degum ramie fibre

After 24 h of incubation with only purified pectate lyase isolated from Bacillus pumilus DKS1 (EF467045), the weight loss of the ramie fibre was found to be 25%. To know the catalytic residue of pectate lyase the pel gene encoding a pectate lyase from the strain Bacillus pumilus DKS1 was cloned in E. coli XL1Blue and expressed in E. coli BL21 (DE3) pLysS. The pel gene was sequenced and showed 1032 bp length. After purification using CM-Sepharose the enzyme showed molecular weight of 35 kDa and maximal enzymatic activity was observed at 60°C and a pH range of 8.5–9.0. Both Ca²⁺ and Mn²⁺ ions were required for activity on Na-pectate salt substrates, while the enzyme was strongly inhibited by Zn²⁺ and EDTA. The deduced nucleotide sequence of the DKS1 pectate lyase (EU652988) showed 90% homology to pectate lyases from Bacillus pumilus SAFR-032 (CP000813). The 3D structure as well as the catalytic residues was predicted using EasyPred software and Catalytic Site Atlas (CSA), respectively. Site directed mutagenesis confirmed that arginine is an essential catalytic residue of DKS1 pectate lyase.     

Involvement of local intercellular communication in the differentiation of zinnia mesophyll cells into tracheary elements

The transdifferentiation of isolated mesophyll cells of zinnia (Zinnia elegans L.) into tracheary elements (TEs) has been well studied as a model of plant cell differentiation. In order to investigate intercellular communication in this phenomenon, two types of culture method were developed, in which mesophyll cells were embedded in a thin sheet of agarose gel and cultured on solid medium, or embedded in microbeads of agarose gel and cultured in liquid medium. A statistical analysis of the two-dimensional distribution of TEs in the thin-sheet cultures demonstrated their aggregation. In the microbead cultures, the frequency of TE differentiation was shown to depend on the local cell density (the cell density in each microbead): TE differentiation required local cell densities of more than 10⁵ cells ml⁻¹. These results suggest that TE differentiation involves cell-cell communication mediated by a locally acting diffusible factor. This presumptive factor was characterized by applying a modified version of the sheet culture, which used two sheets of different cell densities, a low-density sheet and a high-density sheet. Differentiation of TEs in the former could be induced only by bringing it into contact with the latter. Insertion of a 25-kDa-cutoff membrane between the high-density and low-density sheets severely suppressed such induction of TEs in the low-density sheet while a 300-kDa-cutoff membrane suppressed induction only slightly. Insertion of agarose sheets containing immobilized pronase E or trypsin also interfered with the induction of TEs in the low-density sheets. Thus, a proteinaceous macromolecule of 25–300 kDa in molecular weight was assumed to mediate the local intercellular communication required for TE differentiation. This substance was designated “xylogen” with reference to its xylogenic activity. The time of requirement for xylogen during TE differentiation was assessed by experiments in which cells in the low-density sheet were separated from xylogen produced in the high-density sheet at various times by insertion of a 25-kDa-cutoff membrane between the two sheets, and was estimated to be from the 36th hour to the 60th hour of culture (12–36 h before visible thickening of secondary cell walls of TEs). Received: 13 July 2000 / Accepted: 4 October 2000     

Cloning,Expression, Purification and Initial Analysis of a Novel Pectate Lyase Pcpel1 from Phytophthora capsici

Phytophthora capsici inflicts damage on numerous crop plants by secreting a series of pectinase including pectate lyase (PEL). Here, we report a pectate lyase gene (Pcpel1) from a genomic library of a highly virulent P. capsici strain SD33. Pcpel1 was identified as an open reading frame of 1233 bp encoding a protein of 410 amino acids with a predicted amino‐terminal signal sequence of 21 amino acids. The predicted protein of Pcpel1 has a calculated molecular mass of 43.8 kDa and a pI value of 6.8. Analysis of the amino acid sequence suggested that it was a member of the polysaccharide lyase family 1 that shows pectate lyase activity. Moreover, heterologous expression of Pcpel1 in Pichia pastoris produced proteins with molecular mass 66 kDa, very likely due to differential glycosylation by the yeast. By western blotting and northern blotting analysis, Pcpel1 was strongly expressed during interaction of P. capsici with the host plant, suggesting its involvement in the process of host infection. The role of Pcpel1 in cell wall disassembly and host/parasite interaction is discussed.