The immunolocation of a xyloglucan endotransglucosylase/hydrolase specific to elongating tissues in Cicer arietinum suggests a role in the elongation of vascular cells

In a previous work, a Cicer arietinum cDNA clone (CaXTH1) encoding a xyloglucan endotransglucosylase/hydrolase (XTH1) protein was isolated and characterized. CaXTH1 showed an expression pattern specific to growing tissue: mostly epicotyls and the upper growing internodes of adult stems. CaXTH1 mRNA was not detected in any other organs of either seedlings or adult plants, suggesting an involvement of the putative XTH encoded by CaXTH1 in the chickpea cell expansion process. After the generation of polyclonal antibodies by using the XTH1 recombinant protein and the analysis of the specificity of the antibodies for XTH proteins, here the specific location of the chickpea XTH1-cross-reacting protein in cell walls of epicotyls, radicles, and stems is reported, evaluated by western blot and immunocytochemical studies. The results indicate a function for this protein in the elongation of parenchyma cells of epicotyls and also in developing vascular tissue, suggesting a role in the elongation of vascular cells.     

Relation of cell wall peroxidase activity with growth in epicotyls of Cicer arietinum. Effects of calmodulin inhibitors

Sánchez, O.J., Pan, A., Nicolás, G. and Labrador, E. 1989. Relation of cell wall peroxidase activity with growth in epicotyls of Cicer arietinum. Effects of calmodulin inhibitors.
Peroxidases are bound ionically to cell walls in epicotyls of Cicer arietinum L. cv. Castellana. The cell wall peroxidase activity increases during the growth of epicotyls, being the lowest in 3-day-old epicotyls with high growth capacity. The cell wall phenolic compounds, postulated natural substrates of cell wall peroxidases, also increase during growth.
The calmodulin inhibitors chlorpromazine and trifluoperazine decrease the elongation rate of epicotyls of Cicer arietinum. These inhibitors also cause an increase in the cell wall peroxidase activity and in the level of phenolic compounds. A possible regulatory effect of calmodulin on peroxidase activity is postulated.     

Effect of osmotic stress on the growth of epicotyls of Cicer arietinum in relation to changes in the autolytic process and glycanhydrolytic cell wall enzymes

Simulation of drought by polyethylene glycol (PEG) inhibited elongation of epicotyls of Cicer arietinum L. cv. Castellana but had no effect on growth capacity since growth was restored once the inhibitory condition had been removed. The amount of proteins in the cell wall was correlated with the elongation of the epicotyls and decreased when elongation was inhibited. PEG-induced inhibition of elongation had different effects on the various glycanhydrolytic cell wall enzymes. Only α-galactosidase (EC 3. 2. 1. 22) seemed related to the lack of elongation, increasing its activity when elongation was inhibited. The β-galactosidase (EC 3. 2. 1. 23) and β-glucosidase (EC 3. 2. 1. 21) studied did not show changes in their specific activities during the inhibition of elongation. β-Galactosidase is responsible for the autolytic process in Cicer arietinum . This enzyme hydrolyzes specified linkages in the cell wall, releasing sugar constituents. Our present results show that β-galactosidase is not directly related with elongation because no changes could be observed during inhibition of elongation. The autolytic process is related with chemical processes taking place in the cell wall and preceding elongation of the epicotyls, i. e. the loosening process. Cell wall loosening is necessary for elongation to take place but elongation does not necessarily follow loosening if the osmotic conditions are unfavorable     

Increased expression of two cDNAs encoding metallothionein‐like proteins during growth of Cicer arietinum epicotyls

The present study was undertaken to identify and characterize clones whose expression increase during Cicer arietinum epicotyl growth. Two cDNAs encoding two different plant metallothionein (MT)‐like proteins have been isolated from a cDNA library from epicotyls of Cicer arietinum L. cv. Castellana. The CanMT‐1 deduced protein appears to have the typical structure of type 1 MT where all Cys residues are in Cys‐X‐Cys motifs, while the CanMT‐2 has the typical structure of type 2 MT having Cys‐Cys and Cys‐X‐X‐Cys motifs within the N‐terminal domain. Both chickpea CanMTs are up‐regulated during epicotyl growth, showing increased expression in mature tissues, mostly CanMT‐1, which is undetectable in young epicotyls. Accordingly, stem of chickpea plants displayed the highest level of CanMT‐1 expression in the basal internode, with reduced growth, decreasing towards the apex. Osmotic stress by PEG, which inhibited growth, and ABA treatment induced the expression of MT‐like genes, which points to a relationship between chickpea MTs and ABA‐mediated stress response. Unlike CanMT‐2, CanMT‐1 is induced in chickpea epicotyls by cadmium indicating a different function for both clones. We conclude that these MT‐like proteins, in particular CanMT‐1, are regulated by the developmental stage and may participate in cell maturation process.     

Differential Expression of Two Soybean (Glycine max L.) Proline-Rich Protein Genes after Wounding

We have investigated the wound-induced expression of two members of the soybean (Glycine max L.) proline-rich cell wall protein gene family and show that SbPRP1 and SbPRP2 exhibit unique patterns of expression after physical damage. SbPRP1 mRNA can be detected in the hook of soybean seedlings within 2 h after wounding and is present at high levels in the hook and elongating hypocotyl 20 h after wounding. In contrast, SbPRP2 mRNA increases transiently and rapidly throughout the soybean seedling after wounding. SbPRP2 is also induced by wounding in soybean leaves, but the pattern of mRNA accumulation in leaves is distinct from that seen in seedlings and reaches high levels of expression 20 h after physical damage. SbPRP2 mRNA levels were also found to increase in the mature hypocotyl and roots of seedlings in response to treatment with 10 [mu]M indoleacetic acid and naphthalene-1-acetic acid. These data indicate that the wound-induced expression of PRPs in soybean is tissue specific and that the regulation of these genes after physical damage may operate through different signal transduction pathways.     

Inhibition of cell wall autolysis and auxin-induced elongation of Cicer arietinum epicotyls by β-galactosidase antibodies

Polyclonal antibodies were raised in response to βIII-galactosidase purified from cell wall of Cicer arietinum epicotyls. The antibody preparation generated, bound to βIII protein giving a major protein band in the zone corresponding to M_r 45 000, the molecular mass previously estimated for βIII-galactosidase. These antibodies clearly suppress autolytic reactions in isolated walls of Cicer arietinum epicotyl segments, while the preimmune serum had no effect on autolytic reaction. The results strongly support the idea that the autolytic degradation of the cell wall is carried out by the βIII-galactosidase.
The antibodies against β-galactosidase were also able to inhibit cell wall hydrolysis mediated by both total cell wall protein extracted by LiCl and cell wall hydrolysis mediated by βIII-galactosidase.
Since autolysis is thought to be related to the process of cell wall loosening, the effects of the antibodies against the autolytic enzyme was also tested on epicotyl growth. β-galactosidase antibodies consistently inhibited IAA-induced elongation.     

Cloning of a Cicer arietinum beta-galactosidase with pectin-degrading function

The cDNA clone (CanBGal-3) encoding a cell wall pectin-degrading beta-galactosidase (beta III-Gal) from Cicer arietinum L. cv. Castellana has been identified. The identification was carried out by comparing the deduced amino acid sequences of several isolated chickpea beta-galactosidase clones with the purified beta III-Gal protein sequence. The expression pattern of the gene corresponding to CanBGal-3 was in concordance with the fluctuations of the enzyme beta III-Gal in different seedling organs, being specific to elongating organs such as epicotyls and roots. Transformation of Solanum tuberosum plants with the chickpea CanBGal-3 clone indicated that the beta-galactosidase encoded by this clone is a pectin-degrading enzyme. The authors propose an important role for chickpea beta III-Gal in pectin degradation in cell walls of vegetative organs such as epicotyls and roots. The degradation of galactan carried out by this enzyme may determine structural changes and affect cell wall porosity. It is suggested that the increase in the size of cell wall pores could permit access of other cell wall-modifying enzymes to their substrate.     

Copper amine oxidase expression in defense responses to wounding and Ascochyta rabiei invasion

Wounding chickpea (Cicer arietinum) internodes or cotyledons resulted in an increase in the steady-state level of copper amine oxidase (CuAO) expression both locally and systemically. Dissection of the molecular mechanisms controlling CuAO expression indicated that jasmonic acid worked as a potent inducer of the basal and wound-inducible CuAO expression, whereas salicylic acid and abscisic acid caused a strong reduction of the wound-induced CuAO expression, without having any effect on the basal levels. Epicotyl treatment with the CuAO mechanism-based inhibitor 2-bromoethylamine decreased hydrogen peroxide (H(2)O(2)) levels in all the internodes, as evidenced in vivo by 3,3'-diaminobenzidine oxidation. Moreover, inhibitor pretreatment of wounded epicotyls resulted in a lower accumulation of H(2)O(2) both at the wound site and in distal organs. In vivo CuAO inhibition by 2-bromoethylamine after inoculation of resistant chickpea cv Sultano with Ascochyta rabiei resulted in the development of extended necrotic lesions, with extensive cell damage occurring in sclerenchyma and cortical parenchyma tissues. These results, besides stressing the fine-tuning by key signaling molecules in wound-induced CuAO regulation, demonstrate that local and systemic CuAO induction is essential for H(2)O(2) production in response to wounding and indicate the relevance of these enzymes in protection against pathogens.     

Expression of genes for cell-wall proteins in dividing and wounded tissues ofZea mays L.

Hydroxyproline-rich glycoproteins (HRGPs) fromZea mays have been immunolocalized in the cell wall of root tip cells using ultrathin sections and antibodies ellicited against the purified protein. The accumulation of mRNA corresponding to this protein was studied using the cDNA probe. Maximum accumulation of the mRNA was found in tissues with a high proportion of dividing cells such as those in the root tip of young maize seedlings and a close relationship with cellular division was also observed in in-vitro cultures. However, the level of the mRNA in elongating tissues was minimal, as shown by studies carried out on the elongation zones of root tips and coleoptiles. The mRNA was induced by stress conditions, particularly by wounding young leaves and coleoptiles. It is concluded that in maize this group of proline-rich cell-wall proteins accumulates during cell division and not during cell elongation or differentiation, and participates in the stress-response mechanisms of the plant.     

Purification and characterization of a poly(A)-binding protein from chickpea (Cicer arietinum) epicotyl

A poly(A)-binding protein (PABP) with mol wt 72,000 has been purified from chickpea (Cicer arietinum) epicotyls by ammonium sulfate fractionation, Cibacron blue F3-GA and poly(A) agarose chromatography. The binding properties and the specificity of binding show that the purified protein is an analogue of PABPs in other eukaryotes. This PABP is highly susceptible to proteolysis and upon degradation forms a polypeptide fragment of mol wt 21,000 which has an independent poly(A) binding activity.