p38 MAPK regulates group IIa phospholipase A2 expression in interleukin-1beta -stimulated rat neonatal cardiomyocytes.

Group IIa phospholipase A(2) (GIIa PLA(2)) is released by some cells in response to interleukin-1beta. The purpose of this study was to determine whether interleukin-1beta would stimulate the synthesis and release of GIIa PLA(2) from cardiomyocytes, and to define the role of p38 MAPK and cytosolic PLA(2) in the regulation of this process. Whereas GIIa PLA(2) mRNA was not identified in untreated cells, exposure to interleukin-1beta resulted in the sustained expression of GIIa PLA(2) mRNA. Interleukin-1beta also stimulated a progressive increase in cellular and extracellular GIIa PLA(2) protein levels and increased extracellular PLA(2) activity 70-fold. In addition, interleukin-1beta stimulated the p38 MAPK-dependent activation of the downstream MAPK-activated protein kinase, MAPKAP-K2. Treatment with the p38 MAPK inhibitor, SB202190, decreased interleukin-1beta stimulated MAPKAP-K2 activity, GIIa PLA(2) mRNA expression, GIIa PLA(2) protein synthesis, and the release of extracellular PLA(2) activity. Infection with an adenovirus encoding a constitutively active form of MKK6, MKK6(Glu), which selectively phosphorylates p38 MAPK, induced cellular GIIa PLA(2) protein synthesis and the release of GIIa PLA(2) and increased extracellular PLA(2) activity 3-fold. In contrast, infection with an adenovirus encoding a phosphorylation-resistant MKK6, MKK6(A), did not result in GIIa PLA(2) protein synthesis or release by unstimulated cardiomyocytes. In addition, infection with an adenovirus encoding MKK6(A) abrogated GIIa PLA(2) protein synthesis and release by interleukin-1beta-stimulated cells. These results provide direct evidence that p38 MAPK activation was necessary for interleukin-1beta-induced synthesis and release of GIIa PLA(2) by cardiomyocytes.

A putative spectrin-containing membrane skeleton in hyphal tips of Neurospora crassa.

The apical plasma membrane (PM) is important in hyphal tip growth, where it may regulate tip extensibility via its association with an appropriate membrane skeleton (MS). By cell fractionation and immunocytochemistry we show that proteins with characteristics of actin, spectrin, and integrin are associated in a MS-like manner with the PM of Neurospora crassa hyphae. The spectrin-like protein in particular is highly concentrated at the PM in the region of maximum apical expansion. This protein shares with other spectrins immunoreactivity, molecular weight, PM association, and actin binding capacity. Its distribution in hyphae suggests that it is a dominant component of the MS in true fungi and is critical to hyphal tip growth.

Measurement of thermally produced volatile alkanes: an assay for plant hydroperoxy fatty acid evaluation.

A new method designed to monitor lipid peroxidation in plants has been set up with soybean hypocotyl/radicles. The hydroperoxy fatty acids present in situ are converted by rapid thermal treatment (80 s and 210 J g-1) of the biological sample into ethane and n-pentane, which are analyzed by gas chromatography. The method has been directly calibrated by quantification of the hydroperoxy fatty acids by silica-phase HPLC analysis of their reduced hydroxy derivatives. Hypocotyl/radicles from the two soybean cultivars Argenta and Soriano were submitted to various chemical oxidative treatments and were analyzed for both thermally produced volatile alkanes and hydroperoxy fatty acid levels. Our results showed that ethane and n-pentane production are in both cases closely correlated with linolenic as well as linoleic acid hydroperoxide levels (P < 0.001). Within a given plant material, thermal conversion of both hydroperoxides into alkanes occurred with yields which were not dependent on the oxidative treatment. These yields are however functions of the biological material since in Soriano and Argenta cultivars they were around 6 and 25%, respectively. Taking into account the last point, the alkane test cannot be used to directly quantify the absolute lipid hydroperoxide levels of plant tissues but it is convenient to monitor the peroxidative phenomenon as it occurs. The assay is easy and rapid to perform (analysis of 50 samples per day) since no sample preparation is needed, and the low detection limit (20 pmol of alkane g-1) permits the analysis of small samples.

Accumulation of reactive oxygen species and oxidation of cytokinin in germinating soybean seeds.

Seed germination is an important developmental switch when quiescent seed cells initiate oxidative phosphorylation for further development and differentiation. During early imbibition of soybean seeds (Glycine max L. cv. Weber), a superoxide dismutase (SOD) activity peak was observed, in embryonic axes, after 6 h imbibition. Peroxidase activities, including catalase, were significantly increased after 12 h inhibition and during germination phase III. Catalase was the most efficient enzyme in catabolizing H2O2 in embryonic axes. When stored at 42 degrees C and 100% relative humidity, seeds were stressed and lost their viability in a time-dependent manner. A significant increase in the Cu, Zn-superoxide-dismutase activity, and to a lesser extent, Mn superoxide dismutase activity was observed during germination in low-viability (stressed) seeds as compared to high-viability (unstressed) seeds. Northern blot analysis confirmed that superoxide dismutase induction resulted from an accumulation of its transcripts in response to the production of O2-. The induction of catalase did not occur in low-viability seeds, resulting in dramatic accumulation of H2O2. Using capillary electrophoresis, HPLC and NMR we found that the endogenous cytokinin, zeatin riboside, was present in large quantities in the high-viability seeds, but it was oxidized into adenine in the low-viability seeds. In vitro superoxide anion could also oxidize the cytokinin. Zeatin riboside, but not adenine, was found to act as a scavenger of superoxide anions and may help to maintain seed viability by detoxifying reactive oxygen species. Germination of stressed seeds was partially restored by the addition of exogenous cytokinin (zeatin riboside). Protection against oxidative stress by cytokinin seemed to be a general phenomenon, as Escherichia coli cells were also protected against superoxide stress in the presence of cytokinin.

Involvement of Oxidative Processes in the Signaling Mechanisms Leading to the Activation of Glyceollin Synthesis in Soybean (Glycine max).

The efficiency of hydroperoxides (tert-butyl hydroperoxide, hydrogen peroxide) and sulfhydryl reagents (iodoacetamide, p-chloromercuribenzene sulfonic acid) as glyceollin elicitors was examined in relation to sulfhydryl oxidation, or alteration, and to lipid peroxidation, in 3-d-old soybean hypocotyl/radicle, Glycine max. These oxidative events were investigated as possible early steps in the transduction mechanisms leading to phytoalexin synthesis. Free protein sulfhydryl groups were not modified after any of the eliciting treatments, thus indicating that immediate massive protein oxidation or modification cannot be considered a signal transduction step. Unlike sulfhydryl reagents, which led to a decrease of the free nonprotein sulfhydryl group (free np-SH) pool under all of the eliciting conditions, the results obtained with hydroperoxides indicated that immediate oxidation of the np-SH is not required for the signal transduction. Moreover, elicitation with 10 mM tertbutyl hydroperoxide did not lead to further oxidation or to changes in np-SH level during the critical phase of phenylalanine ammonialyase activation (the first 20 h), suggesting that np-SH modifications are probably not involved in hydroperoxide-induced elicitation. On the other hand, all treatments leading to significant glyceollin accumulation were able to trigger a rapid (within 2 h) lipid peroxidation process, whereas noneliciting treatments did not. In addition, transition metals, such as Fe2+ and Cu+, were shown to stimulate both hydrogen peroxide-induced lipid peroxidation and glyceollin accumulation, again emphasizing that the two processes are at least closely linked in soybean. Among the oxidative processes triggered by activated oxygen species, oxidation of sulfhydryl compounds, or lipid peroxidation, our results suggest that lipid peroxidation is sufficient to initiate glyceollin accumulation in soybean. This further supports the hypothesis that lipid peroxidation could be involved as a step in the signal cascade that leads to induction of plant defenses.