Matı́as López-Serrano scite author profile

The major basic peroxidase from Zinnia elegans (ZePrx) suspension cell cultures was purified and cloned, and its properties and organ expression were characterized. The ZePrx was composed of two isoforms with a M r (determined by matrix-assisted laser-desorption ionization time of flight) of 34,700 (ZePrx34.70) and a M r of 33,440 (ZePrx33.44). Both isoforms showed absorption maxima at 403 (Soret band), 500, and 640 nm, suggesting that both are high-spin ferric secretory class III peroxidases. M r differences between them were due to the glycan moieties, and were confirmed from the total similarity of the N-terminal sequences (LSTTFYDTT) and by the 99.9% similarity of the tryptic fragment fingerprints obtained by reverse-phase nano-liquid chromatography. Four full-length cDNAs coding for these peroxidases were cloned. They only differ in the 5#-untranslated region. These differences probably indicate different ways in mRNA transport, stability, and regulation. According to the k cat and apparent K m RH values shown by both peroxidases for the three monolignols, sinapyl alcohol was the best substrate, the endwise polymerization of sinapyl alcohol by both ZePrxs yielding highly polymerized lignins with polymerization degrees $87. Western blots using anti-ZePrx34.70 IgGs showed that ZePrx33.44 was expressed in tracheary elements, roots, and hypocotyls, while ZePrx34.70 was only expressed in roots and young hypocotyls. None of the ZePrx isoforms was significantly expressed in either leaves or cotyledons. A neighbor-joining tree constructed for the four full-length cDNAs suggests that the four putative paralogous genes encoding the four cDNAs result from duplication of a previously duplicated ancestral gene, as may be deduced from the conserved nature and conserved position of the introns.

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Peroxidase: a multifunctional enzyme in grapevines

Barceló

Pomar

López-Serrano

et al. 2003

Functional Plant Biol.

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Peroxidases are heme-containing enzymes that catalyse the one-electron oxidation of several substrates at the expense of H 2 O 2 . They are probably encoded by a large multigene family in grapevines, and therefore show a high degree of polymorphism. Grapevine peroxidases are glycoproteins of high thermal stability, whose molecular weight usually ranges from 35 to 45 kDa. Their visible spectrum shows absorption bands characteristic of high-spin class III peroxidases. Grapevine peroxidases are capable of accepting a wide range of natural compounds as substrates, such as the cell wall protein extensin, plant growth regulators such as IAA, and phenolics such as benzoic acids, stilbenes, flavonols, cinnamyl alcohols and anthocyanins. They are located in cell walls and vacuoles. These locations are in accordance with their key role in determining the final cell wall architecture, especially regarding lignin deposition and extensin insolubilization, and the turnover of vacuolar phenolic metabolites, a task that also forms part of the molecular program of disease resistance. Although peroxidase is a constitutive enzyme in grapevines, its levels are strongly modulated during plant cell development and in response to both biotic and abiotic environmental factors. To gain an insight into the metabolic regulation of peroxidase, several authors have studied how grapevine peroxidase and H 2 O 2 levels change in response to a changing environment. Nevertheless, the results obtained are not always easy to interpret. Despite such difficulties, the response of the peroxidase-H 2 O 2 system to both UV-C radiation and Trichoderma viride elicitors is worthy of study. Both UV-C and T. viride elicitors induce specific changes in peroxidase isoenzyme/H 2 O 2 levels, which result in specific changes in grapevine physiology and metabolism. In the case of T. viride-elicited grapevine cells, they show a particular mechanism for H 2 O 2 production, in which NADPH oxidase-like activities are apparently not involved. However, they offer a unique system whereby the metabolic regulation of peroxidase by H 2 O 2 , with all its cross-talks and downstream signals, may be elegantly dissected.

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Basic peroxidases: The gateway for lignin evolution?

Barceló

Ros

Gabaldón

et al. 2004

Phytochemistry Reviews

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Purification and characterization of α‐3′,4′‐anhydrovinblastine synthase (peroxidase‐like) from Catharanthus roseus (L.) G. Don

et al. 1998

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An H P O P -dependent enzyme capable of coupling catharanthine and vindoline into K K-3P,4P-anhydrovinblastine (AVLB) was purified to apparent homogeneity from Catharanthus roseus leaves. The enzyme shows a specific AVLB synthase activity of 1.8 nkat/mg, and a molecular weight of 45.40 kDa (SDS-PAGE). In addition to AVLB synthase activity, the purified enzyme shows peroxidase activity, and the VIS spectrum of the protein presents maxima at 404, 501 and 633 nm, indicating that it is a high spin ferric heme protein, belonging to the plant peroxidase superfamily. Kinetic studies revealed that both catharanthine and vindoline were substrates of the enzyme, AVLB being the major coupling product.z 1998 Federation of European Biochemical Societies.

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Characterization of the last step of lignin biosynthesis in Zinnia elegans suspension cell cultures

Gabaldón

López-Serrano

Pomar³

et al. 2006

FEBS Letters

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The last step of lignin biosynthesis in Zinnia elegans suspension cell cultures (SCCs) catalyzed by peroxidase (ZePrx) has been characterized. The k 3 values shown by ZePrx for the three monolignols revealed that sinapyl alcohol was the best substrate, and were proportional to their oxido/reduction potentials, signifying that these reactions are driven exclusively by redox thermodynamic forces. Feeding experiments demonstrate that cell wall lignification in SCCs is controlled by the rate of supply of H 2 O 2 . The results also showed that sites for monolignol b-O-4 cross-coupling in cell walls may be saturated, suggesting that the growth of the lineal lignin macromolecule is not infinite.

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