The complete apoplastic enzymatic antioxidant system, composed by class I ascorbate peroxidases (class I APXs), class III ascorbate peroxidases (class III APXs), ascorbate oxidases (AAOs), and other class III peroxidases (PRX), of wood-forming tissues has been studied in Populus alba, Citrus aurantium, and Eucalyptus camaldulensis. The aim was to ascertain whether these enzymatic systems may regulate directly (in the case of APXs), or indirectly (in the case of AAOs), apoplastic H 2 O 2 levels in lignifying tissues, whose capacity to produce and to accumulate H 2 O 2 is demonstrated here. Although class I APXs are particularly found in the apoplastic fraction of P. alba (poplar), and class III APXs are particularly found in the apoplastic fraction of C. aurantium (bitter orange tree), the results showed that the universal presence of AAO in the extracellular cell wall matrix of these woody species provokes the partial or total dysfunction of apoplastic class I and class III APXs, and of the whole plethora of nonenzymatic redox shuttles in which ascorbic acid (ASC) is involved, by the competitive and effective removal of ASC. In fact, the redox state (ASC/ASC+DHA) in intercellular wash fluids (IWFs) of these woody species was zero, and thus strongly shifted towards DHA (dehydroascorbate), the oxidized product of ASC. This imbalance of the apoplastic antioxidant enzymatic system apparently results in the accumulation of H 2 O 2 in the apoplast of secondary woodforming tissues, as can be experimentally observed. Furthermore, it is hypothesized that since AAO uses O 2 to remove ASC, it could regulate O 2 availability in the lignifying xylem and, thorough this mechanism, AAO could also control the activity of NADPH oxidase (the enzyme A. Ros-Barceló ( ) · responsible for H 2 O 2 production in lignifying tissues) at substrate level, by controlling the tension of O 2 . That is, the presence of AAO in the extracellular cell wall matrix appears to be essential for finely tuning the oxidative performance of secondary wood-forming tissues.
Zinnia elegans constitutes one of the most useful model systems for studying xylem differentiation, which simultaneously involves secondary cell wall synthesis, cell wall lignification, and programmed cell death. Likewise, the in vitro culture system of Z. elegans has been the best characterized as the differentiation of mesophyll cells into tracheary elements allows study of the biochemistry and physiology of xylogenesis free from the complexity that heterogeneous plant tissues impose. Moreover, Z. elegans has emerged as an excellent plant model to study the involvement of peroxidases in cell wall lignification. This is due to the simplicity and duality of the lignification pattern shown by the stems and hypocotyls, and to the basic nature of the peroxidase isoenzyme. This protein is expressed not only in hypocotyls and stems but also in mesophyll cells transdifferentiating into tracheary elements. Therefore, not only does this peroxidase fulfil all the catalytic requirements to be involved in lignification overcoming all restrictions imposed by the polymerization step, but also its expression is inherent in lignification. In fact, its basic nature is not exceptional since basic peroxidases are differentially expressed during lignification in other model systems, showing unusual and unique biochemical properties such as oxidation of syringyl moieties. This review focuses on the experiments which led to a better understanding of the lignification process in Zinnia, starting with the basic knowledge about the lignin pattern in this plant, how lignification takes place, and how a sole basic peroxidase with unusual catalytic properties is involved and regulated by hormones, H2O2, and nitric oxide.
Xylem differentiation in plants is under strict hormonal regulation. Auxins and cytokinins, together with brassinosteroids (BRs), appear to be the main hormones controlling vascular differentiation. In this report, we study the effect of these hormones on the basic peroxidase isoenzyme from Zinnia elegans (ZePrx), an enzyme involved in lignin biosynthesis. Results showed that auxins and cytokinins induce ZePrx, similarly to the way in which they induce seedling secondary growth (in particular, metaxylem differentiation). Likewise, the exogenous application of BR reduces the levels of ZePrx, in a similar way to their capacity to inhibit seedling secondary growth. Consistent with this notion, the exogenous application of BR reverses the auxin/cytokinin-induced ZePrx expression, but has no effect on the auxin/cytokinin-induced secondary growth. This differential hormonal response is supported by the analysis of the ZePrx promoter, which contains (a) cis-elements directly responsive to these hormones and (b) cis-elements targets of the plethora of transcription factors, such as NAC, MYB, AP2, MADS and class III HD Zip, which are up-regulated during the auxin- and cytokinin-induced secondary growth. Taken together, these results suggest that ZePrx is directly and indirectly regulated by the plethora of hormones that control xylem differentiation, supporting the role of ZePrx in xylem lignification.
Cytotoxic Effect of Natural trans-Resveratrol Obtained from Elicited Vitis vinifera Cell Cultures on Three Cancer Cell Lines
trans-Resveratrol (trans-R) has been reported to be a potential cancer chemopreventive agent. Although its cytotoxic activity against different cancer cell lines has been tested, its effect on human acute leukemia cell lines has scarcely been investigated, and only a few in vitro studies were performed using human breast epithelial cell lines. Due to its potential value for human health, demand for trans-R has rapidly increased, and new biotechnological strategies to obtain it from natural edible sources have been developed. Thus, grapevine cell cultures represent a reliable system of trans-R production since they biosynthesize trans-R constitutively or in response to elicitation. In addition, there are no studies deepen on the inhibitory effect of trans-R, produced by elicited grapevine cell cultures, on growth of human tumor cell lines. In this work, the effect of trans-R extracted from the culture medium, after elicitation of grapevine cell cultures, was tested on two human acute lymphocytic and monocytic leukemia cell lines, and one human breast cancer cell line. The effect of trans-R on cell proliferation was not only dose- and time-dependent but also cell type-dependent, as seen from the different degrees of susceptibility of cancer cell lines tested. As regards the effect of trans-R on cell cycle distribution, low trans-R concentrations increased cells in the S phase whereas a high trans-R concentration increased G₀/G₁ phase in all cell lines. Perturbation of the cell cycle at low trans-R concentrations did not correlate with the induction of cell death, whereas a high trans-R concentration, cell proliferation decreased as a result of increasing apoptosis in the three cell lines. In leukemia cells, trans-R up-regulated the expression of caspase-3 while trans-R-induced apoptosis in breast cells occur through a caspase-3-independent mechanism mediated by a down-regulation of Bcl-2.
Post-translational modifications of the basic peroxidase isoenzyme from Zinnia elegans
The major basic peroxidase (ZePrx) from Zinnia elegans suspension cell cultures was purified and cloned. The purification resolved ZePrxs in two isoforms (ZePrx33.44 and ZePrx34.70), whose co-translational and post-translational modifications are characterized. Based on the N-terminal sequence obtained by Edman degradation of mature ZePxs, it may be expected that the immature polypeptides of ZePrxs contain a signal peptide (N-terminal pro-peptide) of 30 amino acids, which directs the polypeptide chains to the ER membrane. These immature polypeptides are co-translationally processed by proteolytic cleavage, and modeling studies of digestions suggested that the processing of the N-terminal pro-peptide of ZePrxs is performed by a peptidase from the SB clan (S8 family, subfamily A) of serine-type proteases. When the post-translational modifications of ZePrxs were characterized by trypsin digestion, and tryptic peptides were analyzed by reverse phase nano liquid chromatography (RP-nanoLC) coupled to MALDI-TOF MS, it was seen that, despite the presence in the primary structure of the protein of several (disulphide bridges, N-glycosylation, phosphorylation and N-myristoylation) potential post-translational modification sites, ZePrxs are only post-translationated modified by the formation of N-terminal pyroglutamate residues, disulphide bridges and N-glycosylation. Glycans of ZePrxs belong to three main types and conduce to the existence of at least ten different molecular isoforms. The first glycans belong to both low and high mannose-type glycans, with the growing structure Man(3-9)(GlcNAc)(2). Low mannose-type glycans, Man(3-4)(GlcNAc)(2), coexist with the truncated (paucimannosidic-type) glycan, Man(3)Xyl(1)Fuc(1)(GlcNAc)(2), in the G(3) and G(4 )sub-isoforms of ZePrx33.44. In ZePrx34.70, on the other hand, the complex-type biantennary glycan, Man(3)Xyl(1)Fuc(3)(GlcNAc)(5), and the truncated (paucimannosidic-type) glycan, Man(3)Xyl(1)Fuc(1)(GlcNAc)(2), appear to fill the two putative sites for N-glycosylation. Since the two N-glycosylation sites in ZePrxs are located in an immediately upstream loop region of helix F'' (close to the proximal histidine) and in helix F'' itself, and are flanked by positive-charged amino acids that produce an unusual positive-net surface electrostatic charge pattern, it may be expected that glycans not only affect reaction dynamics but may well participate in protein/cell wall interactions. These results emphasize the complexity of the ZePrx proteome and the difficulties involved in establishing any fine structure-function relationship.
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