Activity and isoforms of peroxidases, lignin and anatomy, during adventitious rooting in cuttings of Ebenus cretica L

Adventitious rooting of Ebenus cretica cuttings was studied in order to examine a) the rooting ability of different genotypes in relation to electrophoretic patterns of peroxidases. b) the activity and electrophoretic patterns of soluble and wall ionically bound peroxidases, the lignin content and anatomical changes in the control and IBA treated cuttings of and genotypes in the course of adventitious root formation. In addition, a fraction of soluble cationic peroxidases was separated by gel filtration chromatography from the total soluble peroxidases of a genotype. No rooting occurred in cuttings without IBA-treatment. In both genotypes, electrophoretic patterns of soluble anionic peroxidases revealed two common peroxidase isoforms, while a fast-migrating anionic peroxidase isoform (A3) appeared only in genotypes. Both genotypes showed similar patterns of soluble, as well as wall ionically bound cationic peroxidase isoforms. The number of isoforms was unchanged during the rooting process (induction, initiation and expression phase) but an increase in peroxidase activity (initiation phase) followed by decrease has been found in IBA-treated cuttings. During initiation phase the lignin content was almost similar to that on day 0 in genotype while it was reduced at by about 50% in genotype at the respective time. Microscopic observations revealed anatomical differences between genotypes. According to this study, the and genotypes display differences in anatomy, lignin content, activity of soluble peroxidases and the electrophoretic patterns of soluble anionic peroxidase isoforms. The A3-anionic peroxidase isoform could be used as biochemical marker to distinguish and genotypes of E. cretica and seems to be correlated to lignin synthesis in rooting process.     

Differences in compounds released by embryogenic and non-embryogenic suspension cultures of Euphorbia pulcherrima

Media from embryogenic and non-embryogenic cell suspension cultures were analysed for protein content, electrophoretic protein patterns, glycoproteins and activity of peroxidases and β-glucosidases in order to characterize the physiological status of the cultures. On a dry mass basis the amount of extracellular proteins per cell was greater in embryogenic suspensions than in non-embryogenic suspensions. Non-embryogenic suspensions contained unidentified slimy compounds which were not present inembryogenic cultures. The extracellular Concanavalin A-specific glycoproteins gave different isoelectric focussing patterns and thus enabled embryogenic and non-embryogenic cultures to be differentiated. The extracellular peroxidase activity per cell dry mass was far greater in embryogenic than in non-embryogenic cultures. The isoenzymes differed in number and composition of the anionic bands. β-glucosidases were found in the same range of activity in both culture types, but the time course of enzyme activity during cultivation was significantly different. In the embryogenic culture the activity was correlated with dry mass increase, whereas in the non-embryogenic suspension the activity reached maximum during the linear growth phase. Polyphenoloxidase which was recently recognized as an intracellular marker for embryogenic stages was not released into culture media. This revised version was published online in July 2006 with corrections to the Cover Date.     

Extracellular peroxidases of suspension culture cells of spruce (Picea abies): fungal elicitor-induced inactivation

Extracellular peroxidases of suspension cultures of spruce (Picea abies) (L.) (Karst) become inactivated when the cell suspension is elicited with a cell wall preparation of the spruce pathogenic fungus Rhizosphaera kalkhoffii. In contrast, cellular peroxidases are induced under these conditions. Both changes of activity are reflected in the isoenzyme profiles.Inactivation of the extracellular peroxidases is caused by an effector, arising from the cells after contact with the elicitor. Formation of the effector is limited to the beginning of elicitation, showing maximal activity at this period of time. Subsequently it becomes increasingly ineffective, probably due to inactivation. The effector is able to also inactivate commercial (horseradish) peroxidase. Inactivation was not the result of the action of a protease present in the medium.The elicitor exerts two different effects on the spruce cell suspension culture. It induces synthesis of enzymes correlated with lignin synthesis and an accumulation of lignin-like material. It also induces secretion of the negative effector which inactivates extracellular peroxidases.The elicitor-induced inactivation is not specific for peroxidases. Other extracellular enzymes, -glucosidase and acid phosphatase (secreted by the cells into the medium) and -amylase and pectinase (from Aspergillus strains) are also inactivated.     

综述与专论: 二维过渡金属硫化物纳米复合材料的模拟酶特性及应用

纳米酶是一个非常令人兴奋和有希望的领域,旨在模仿使用各种纳米材料的天然酶的一般原理,并在许多领域提供了大量实际应用。 天然酶具有一些内在的缺点,如成本高,稳定性低,储存困难,以及催化活性对环境条件的敏感性。 而纳米酶显示出低成本,高稳定性和高效活性。 各种过氧化物酶和/或氧化酶模拟物已经取得了很大的进展。本综述介绍了关于二维过渡金属硫化物纳米复合材料的纳米酶特性的最新研究进展。     

Membrane peroxidases

Summary It is well known that the partial reduction of oxygen can result in the formation of highly reactive oxygen products. Hydrogen peroxide is one of these metabolites of oxygen. Peroxidases utilize this metabolite for a variety of functions. It is the purpose of this treatise to review the nature and function of various membrane peroxidases in the body.     

The impact of thiol peroxidases on redox regulation

The biology of glutathione peroxidases and peroxiredoxins is reviewed with emphasis on their role in metabolic regulation. Apart from their obvious function in balancing oxidative challenge, these thiol peroxidases are not only implicated in orchestrating the adaptive response to oxidative stress, but also in regulating signaling triggered by hormones, growth factors and cytokines. The mechanisms presently discussed comprise dampening of redox-sensitive regulatory processes by elimination of hydroperoxides, suppression of lipoxygenase activity, committing suicide to save H₂O₂ for signaling, direct binding to receptors or regulatory proteins in a peroxidase activity-independent manner, or acting as sensors for hydroperoxides and as transducers of oxidant signals. The various mechanistic proposals are discussed in the light of kinetic data, which unfortunately are scarce. Taking into account pivotal criteria of a meaningful regulatory circuit, kinetic plausibility and specificity, the mechanistic concepts implying a direct sensor/transducer function of the thiol peroxidases appear most appealing. With rate constants for the reaction with hydroperoxide of 10⁵–10⁸ M^{? 1} s^{? 1}, thiol peroxidases are qualified as kinetically preferred hydroperoxide sensors, and the ability of the oxidized enzymes to react with defined protein thiols lends specificity to the transduction process. The versatility of thiol peroxidases, however, allows multiple ways of interaction with regulatory pathways.     

Screening of sorghum genotypes and biochemical changes for resistance to damage caused by Macrophomina phaseolina

Charcoal rot, caused by Macrophomina phaseolina, is the most common yield reducing constraint in sorghum. In the present study, eight cultivars of Sorghum bicolor were screened against M. phaseolina to determine its effects on several growth parameters as well as the content of phenols, salicylic acid (SA), total protein and peroxidase activity and were examined for their relationship, with disease resistance. Out of the eight cultivars tested, PJ-1430 was the most resistant and SU-1080, the most susceptible. The roots of plants were more affected by the pathogen than the shoots. The cultivar PJ-1430 produced a higher plant root and shoot dry mass and was associated with higher polyphenols, SA, peroxidases and thus sustained less oxidative damage whereas SU-1080 experienced maximum oxidative damage, so was considered susceptible to charcoal rot. A positive relationship was observed among various biochemical parameters and disease resistance of cultivars PJ-1430 and SU-1080.     

Relationships between peroxidases and in vitro bulbification in garlic (Allium sativum L.)

Summary The relationship between in vitro bulbification and peroxidase activities of garlic (Allium sativum L.) was studied. Two stages could be distinguished during in vitro bulb formation characterized by the peroxidase activity, isoenzymatic patterns especially of the soluble fractions, dry weight, and bulbification index (BI). The first stage, called the morphogenic stage, started after planting until 30d of culture with a maximum soluble peroxidase activity, BI=1–0.5 and low dry weight. At that time axillary buds preformed at the base of the leaves grew and the in vitro bulb was generated. The second stage (filling in and bulb maturation) started when the BI reached 0.5 at 30 d of the ontogenic cycle, as a result of the bulb assimilate accumulation phenomenon. During the morphogenic stage the soluble peroxidase activity was maximum and the zymograms showed higher intensity bands. The second stage presented anodic ionic peroxidases and substantial increase in staining of the anodic covalent peroxidase fraction. The putative role of the different isoforms of peroxidases in relation to the bulbification process is discussed.     

Sensitivity and specificity of phenoloxidase reactions of 1059 strains and species of Micromycetes cultivated on malt/agar medium

The phenoloxidase (POx) activities of 1059 strains and species of micromycetes were determined on malt/agar medium. Overall, 600 (57%) of the isolates produced one or more POx. The sensitivity and specificity of the POx activities towards various substrates were used to group the isolates. Some 187 strains (31% of those producing POx) produced well-defined enzymes, 236 (39%) produced incompletely identified enzymes and 177 (30%) produced other, unidentified POx.     

Expression profiles of genes involved in apoptosis and selenium metabolism in articular cartilage of patients with Kashin–Beck osteoarthritis

Kashin–Beck disease (KBD) is a special type of endemic osteoarthritis. It has been suggested that alterations in selenium metabolism and apoptosis play a role in KBD. However, the underlying molecular mechanism remains largely unclear. We performed a microarray analysis using RNA isolated from cartilages of KBD patients and healthy controls, through Significance Analysis of Microarray (SAM) software. Functional gene networks and crucial molecules associated with differentially expressed genes were investigated via Ingenuity Pathway Analysis (IPA) and hub gene analysis. Quantitative real-time PCR was used to check the validation of chip test. We identified 52 up-regulated apoptosis-related genes and 26 down-regulated selenium-related genes between KBD and controls, and these genes associated with the “MYC-mediated apoptosis signaling pathway”. We confirmed the results from array studies with quantitative real-time PCR analysis. Our results suggest that abnormal regulation of selenium metabolism and apoptosis through the MYC mediated signaling pathway contributes to the pathogenesis of KBD, but the relationship between apoptosis gene and selenium gene was not found.