Stabilization of cortical microtubules by the cell wall in cultured tobacco cells

Cortical microtubules (MTs) in protoplasts prepared from tobacco (Nicotiana tabacum L.) BY-2 cells were found to be sensitive to cold. However, as the protoplasts regenerated cell walls they became resistant to cold, indicating that the cell wall stabilizes cortical MTs against the effects of cold. Since poly-l-lysine was found to stabilize MTs in protoplasts, we examined extensin, an important polycationic component of the cell wall, and found it also to be effective in stabilizing the MTs of protoplasts. Both extensin isolated from culture filtrates of tobacco BY-2 cells and extensin isolated in a similar way from cultures of tobacco XD-6S cells rendered the cortical MTs in protoplasts resistant to cold. Extensin at 0.1 mg·ml⁻¹ was as effective as the cell wall in this respect. It is probable that extensin in the cell wall plays an important role in stabilizing cortical MTs in tobacco BY-2 cells.     

Sugar acts as a regulatory signal on the wound-inducible expression of<Emphasis Type="Italic"> SbHRGP3</Emphasis>::<Emphasis Type="Italic">GUS</Emphasis> in transgenic plants

SbHRGP3 encodes an HRGP whose expression is correlated with the cessation of root elongation in soybean. The wound-inducible expression of SbHRGP3 interestingly requires sucrose although wounding alone induces the expression of many HRGP genes. To examine whether sugar serves as a specific signal on the wound-inducible expression or whether sugar is required to provide ATP, we examined SbHRGP3::GUS expression in transgenic tobacco plants. Various oligosaccharides including non-metabolizable sugar induced SbHRGP3::GUS expression in transgenic plants. The inhibitors of photosynthesis and of cellular respiration did not affect the wound-inducible expression of SbHRGP3::GUS. However, the induction was significantly affected by PCMBS, an inhibitor of active apoplastic phloem loading of sucrose, suggesting that SbHRGP3::GUS expression in phloem tissues requires translocated sucrose. We therefore propose that sugar acts as a specific regulatory signal on the wound-inducible expression of SbHRGP3, rather than acting as a simple provider of ATP.Abbreviations ATP Adenosine triphosphate - DCMU 3-(3,4-Dichlorophenyl)-1,1-dimethylurea - DTT Dithiothreitol - HRGP Hydroxyproline-rich glycoprotein - GUS -Glucuronidase - MU 4-Methylumbelliferone - MUG 4-Methylumbelliferyl ß-glucuronide - PCMBS p-Chloromercuribenzenesulphonic acidCommunicated by I.S. Chung     

Expression of the Tobacco Ext 1.4 Extensin Gene Upon Mechanical Constraint and Localization of Regulatory Regions

Abstract: The regulation of the Ext 1.4 gene encoding a tobacco ( Nicotiana tabacum L.) extensin was studied in response to mechanical constraints. Transgenic plants carrying chimeric Ext 1.4 promoter/GUS (β-glucuronidase)/ nos terminator or Ext 1.4 3'-end constructs were obtained. Expression of gene fusions was found in tissues where mechanical stresses occur, e.g., during germination, as well as in root and stem tissues. Chimeric genes were successively and transiently expressed in different tissues during germination, i.e., at the tip of the root and then in the hypocotyl, during their growth through the seed coat. Moreover, they were expressed in cortical cells surrounding the emergence of adventitious and lateral roots and developmentally-regulated in nodes. The expression of Ext 1.4 could be induced by imposing mechanical constraints due to curving of either the stems or roots. Expression then occurred in cells where it does not normally occur, i.e., in cortical cells of internodes and in the distal piliferous zone of roots. Accumulation of RNAs occurs several days after the start of the constraint. Promoter regions involved in regulation of expression of Ext 1.4 in stems, roots, and in seedlings upon mechanical constraint could be localized. Moreover, the 3' non-coding region was shown to modulate expression in roots. These results suggest that the regulation of Ext 1.4 following mechanical stress is dependent on both tissue-specific and mechanical-responsive elements.     

Antibody localization of extensin in cell walls of carrot storage roots

The accumulation and cross-linking of hydroxyproline-rich glycoproteins (HRGPs) in cell walls of dicotyledonous plants has been correlated with a number of wall-strengthening phenomena. Polyclonal antibodies raised against glycosylated extensin-1, the most abundant HRGP in carrot (Daucus carota L.) cell walls, recognize this antigen on gel and dot blots and on thin sections of epoxy-embedded carrot-root cell walls. Since wall labeling can be largely reduced by preincubating the antibodies with purified extensin-1, most labeling can be attributed to recognition of this antigen. The remaining label may be the result of recognition of extensin-2, a second carrot HRGP, or other wall components (cellulose, hemicellulose and pectin are not recognized). Extensin-1 label was distributed quite uniformly across the cell wall but was absent from the expanded middle lamella at the intersection of three or more cells and was reduced in the narrow middle lamella between two cells. This distribution is essentially the same as that of cellulose. Because of limitations of this labeling technique, it is not possible to construct a complete model of the structure of the cross-linked extensin matrix. Nonetheless, short, linear arrays of gold particles may represent small portions of the extensin matrix or of individual extensin molecules as they are exposed on the surface of sections. These and other results presented here indicate that: a) newly synthesized extensin is added to the wall by intussusception; b) extensin cannot cross the middle lamella separating the walls of adjacent cells; and c) incorporation of extensin is a late event in the development of phloem-parenchyma cell walls in carrot.Abbreviations dE-1 antibodies antibodies raised against deglycosylated extensin 1 - ELISA enzyme-linked immunosorbant assay - gE-1 antibodies antibodies raised against glycosylated extensin 1 - HRGP hydroxyproline-rich glycoprotein - PAGE polyacrylamide gel electrophoresis - RG-1 rhamnogalacturonan I - SDS sodium dodecyl sulfate     

An extensin-rich matrix lines the carinal canals in Equisetum ramosissimum, which may function as water-conducting channels

Background and Aims

The anatomy of Equisetum stems is characterized by the occurrence of vallecular and carinal canals. Previous studies on the carinal canals in several Equisetum species suggest that they convey water from one node to another.

Methods

Cell wall composition and ultrastructure have been studied using immunocytochemistry and electron microscopy, respectively. Serial sectioning and X-ray computed tomography were employed to examine the internode–node–internode transition of Equisetum ramosissimum.

Key Results

The distribution of the LM1 and JIM20 extensin epitopes is restricted to the lining of carinal canals. The monoclonal antibodies JIM5 and LM19 directed against homogalacturonan with a low degree of methyl esterification and the CBM3a probe recognizing crystalline cellulose also bound to this lining. The xyloglucan epitopes recognized by LM15 and CCRC-M1 were only detected in this lining after pectate lyase treatment. The carinal canals, connecting consecutive rings of nodal xylem, are formed by the disruption and dissolution of protoxylem elements during elongation of the internodes. Their inner surface appears smooth compared with that of vallecular canals.

Conclusions

The carinal canals in E. ramosissimum have a distinctive lining containing pectic homogalacturonan, cellulose, xyloglucan and extensin. These canals might function as water-conducting channels which would be especially important during the elongation of the internodes when protoxylem is disrupted and the metaxylem is not yet differentiated. How the molecularly distinct lining relates to the proposed water-conducting function of the carinal canals requires further study. Efforts to elucidate the spatial and temporal distribution of cell wall polymers in a taxonomically broad range of plants will probably provide more insight into the structural–functional relationships of individual cell wall components or of specific configurations of cell wall polymers.     

Purification of extensin from cell walls of tomato (hybrid of Lycopersicon esculentum and L. peruvianum) cells in suspension culture

Extensin, a hydroxyproline-rich glycoprotein comprising substantial amounts of -l-arabinose-hydroxyproline glycosidic linkages is believed to be insolubilized in the cell wall during host-pathogen interaction by a peroxidase/hydroperoxide-mediated cross-linking process. Both extensin precursor and extensin peroxidase were ionically eluted from intact water-washed tomato (hybrid) of Lycopersicon esculentum Mill. and L. peruvianum L. (Mill.) cells in suspension cultures and purified to homogeneity by a rapid and simple procedure under mild and non-destructive experimental conditions. The molecular weight of native extensin precursor was estimated to be greater than 240–300 kDa by Superose-12 gel-filtration chromatography. Extensin monomers have previously been designated a molecular weight of approximately 80 kDa. Our results indicate that salt-eluted extensin precursor is not monomeric. Agarose-gel electrophoresis, Superose-12-gel-filtration, extensin-peroxidase-catalysed cross-linking, Mono-S ion-exchange fast protein liquid chromatography (FPLC), and peptide-sequencing data confirmed the homogeneity of the extensin preparation. Evidence that the purified protein was extensin is attributed to the presence of the putative sequence motif — Ser (Hyp)₄ — within the N-terminal end of the protein. Treatment of extensin with trifluoroacetic acid demonstrated that arabinose was the principal carbohydrate. The amino-acid composition of the purified extensin was similar to those reported in the literature. The cross-linking of extensin in vitro upon incubation with extensin peroxidase and exogenous H₂O₂ was characteristic of other reported extensins. Furthermore, Mono-S ion-exchange FPLC of native extensin precursor resolved it into two isoforms, A (90%) and B (10%). The amino-acid compositions of extensin A and extensin B were found to be similar to each other and both extensins were cross-linked in vitro by extensin peroxidase.Abbreviations CM-cellulose carboxymethyl-cellulose - FPLC fast protein liquid chromatography - HF hydrogen fluoride - HRGP hydroxyproline-rich glycoprotein - Hyp hydroxyproline - V_c retention volume - TCA trichloroacetic acid - TFA tri-fluoroacetic acid This work was supported by a A.F.R.C. postdoctoral assistantship to Michael D. Brownleader. We thank Dr. Anthony K. Allen (Department of Biochemistry, Charing Cross and Westminster Hospital, London, UK) for performing the amino-acid analysis and Mrs. Margaret Pickering (Department of Biochemistry, Royal Holloway) for performing the peptide-sequence analysis of extensin. We also express our gratitide to Dr. A. Mort (Oklahoma State University) for performing the HF-deglycosylation of extensin.     

An epitope of rice threonine- and hydroxyproline-rich glycoprotein is common to cell wall and hydrophobic plasma-membrane glycoproteins

A monoclonal antibody, LM1, has been derived that has a high affinity for an epitope of hydroxyproline-rich glycoproteins (HRGPs). In suspension-cultured rice (Oryza sativa L.) cells the epitope is carried by three major proteins with different biochemical properties. The most abundant is the 95-kDa extracellular rice extensin, a threonine- and hydroxyproline-rich glycoprotein (THRGP) occurring in the cell wall and secreted into the medium. This THRGP can be selectively oxidatively cross-linked in the presence of hydrogen peroxide and an endogenous peroxidase with the result that it does not enter a protein gel. A second polypeptide with the LM1 epitope (180 kDa), also occurring in the suspension-cultured cells and medium, is not oxidatively cross-linked. Three further polypeptides (52, 65 and 110 kDa) with the characteristics of hydrophobic proteins of the plasma-membrane also carry the LM1 epitope as determined by immuno-blotting of detergent/aqueous partitions of a plasma-membrane preparation and immuno-fluorescence studies with rice protoplasts. At the rice root apex the LM1 epitope is carried by four glycoproteins and is developmentally regulated. The major locations of the epitope are at the surface of cells associated with the developing protoxylem and metaxylem in the stele, the longitudinal radial walls of epidermal cells and a sheath-like structure at the surface of the root apex.Abbreviations AGP arabinogalactan protein - ELISA enzyme-linked immunosorbent assay - HRGP hydroxyproline-rich glycoprotein - THRGP threonine- and hydroxyproline-rich glycoprotein This work was supported by The Leverhulme Trust. We also acknowledge support from The Royal Society and thank Prof. L.A. Staehelin for the carrot extensin, N. Stacey for the rice cell culture and Dr. J. Keen for protein sequencing.     

Site-specific binding of a nuclear factor to the carrot extensin gene is influenced by both ethylene and wounding

Experiments conducted in vitro using the electrophoretic mobility shift assay have shown that a single region of the extensin gene of carrot (Daucus carota L.) interacts with a protein factor designated Extensin Gene Binding Factor-1 (EGBF-1) present in nuclear extracts obtained from carrot roots. This interaction is sequence-specific as judged by the failure of other plant gene sequences to compete with the extensin gene for EGBF-1 binding. The EGBF-1 activity is organspecific, not being expressed in nuclear extracts obtained from carrot leaves or stems. Both ethylene treatment and wounding of roots are shown to have a controlling influence on the expression of EGBF-1 activity in nuclear extracts. These results demonstrate that at least three distinct signals: ethylene treatment, wounding, and development, are important in determining the activity of EGBF-1 in nuclear extracts, and indicate a role for EGBF-1 in stress-related signal transduction and the regulation of extensin-gene expression.Abbreviations bp base pair(s) - EGBF extensin-gene binding factor - EMSA electrophoretic mobility shift assay - HRGP hydroxyproline-rich glycoprotein - kb kilobase     

Organelles involved in the synthesis and transport of hydroxyproline-containing glycoproteins in carrot root discs

Isopycnic sucrose density gradients of homogenates from carrot root tissue were analyzed radiochromatographically, radiochemically, and photometrically for the presence of hydroxyproline residues. Significant amounts were found in endoplasmic reticulum (ER), Golgi apparatus (GA) and plasma membrane (PM) fractions as designated by the presence of marker enzymes for these membranes. Some hydroxyproline-containing macromolecules could be detected in the soluble cytoplasm (cytosol) but this was interpreted as an artefact due to homogenization. Hydroxyproline-rich polymers can be released from a mixed ER/PM fraction by freezing and thawing in water. The PM-associated hydroxyproline polymer is suggested to be an arabinogalactan protein rather than cell wall extensin. Nevertheless, the polypeptides of both glycoproteins are considered as being synthesized at the ER and transported via the GA to the PM.Abbreviations BSA Bovine serum albumin - CCO cytochrome c-oxidase - CCR cytochrome c-reductase - DTT dithiothreitol - EDTA ethylene diaminotetracetic acid - ER endoplasmic reticulum - GA Golgi apparatus - GS I/II glucan synthetase I/II - IDP(ase) inosine diphosphat(ase) - PM plasma membrane - RNA ribonucleic acid - TCA trichloracetic acid - Tris tris-(hydroxymethyl)-aminomethane - UDPG uridine diphosphoglucose