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Reactive oxygen species (ROS) play a prominent role in early and later stages of the plant pathogenesis response, putatively acting as both cellular signaling molecules and direct antipathogen agents. A single-cell assay, based on the fluorescent probe dichlorofluorescein, was used to scrutinize the generation and movement of ROS in tobacco epidermal tissue. ROS, generated within cells, quickly moved apoplastically as H2O2 into neighboring cells. Two classes of rapidly elicited intracellular ROS, originating from distinct sources, were distinguished. Cryptogein, the fungal elicitor from Phytophthora cryptogea, induced ROS from a flavin-containing oxidase source. ROS accumulation could be inhibited by a number of pharmacological agents, suggesting induction through an active signal transduction pathway. The insensitivity of the increase in ROS to the external addition of enzymes that dissipate ROS suggests that this exidative increase is primarily intracellular. In contrast, amines and polyamines, compounds that form during wounding and pathogenesis, induced ROS at an apoplastic site from peroxidase- or amine oxidase-type enzyme(s). Salicylic acid, a putative inhibitor of cellular catalases and peroxidases, did not induce cellular ROS, as messured by dichlorofluorescein fluorescence. The physiological relevance of ROS-generated signals was indicated by the rapid alteration of the epidermal cell glutathione pool and the cellular redox state. In addition, induction of ROS by all elicitors was correlated with subsequent cell death

Although silicon (Si) has been widely reported to alleviate plant nutrient deficiency, the alleviating effect of Si on potassium (K) deficiency and its underlying mechanism are poorly understood. Here, we examined whether Si-regulated putrescine (Put) metabolisms are involved in Si-alleviated K deficiency. Sorghum seedlings were grown in K deficiency solution with and without Si for 15 d. The influence of K deficiency and Si on leaf chlorosis symptoms, K(+) concentration, polyamine (PA) levels, amine oxidase activities, the transcription of Put synthesis genes, antioxidant enzyme activities and H2O2 accumulation were measured. Under K-sufficient conditions, plant growth was not affected by Si application. Si application significantly alleviated the growth inhibition induced by K-deficient stress, however. K deficiency induced leaf chlorosis and reduction in several leaf chlorosis-related metrics, including photosynthesis, efficiency of photosystem II photochemistry, chlorophyll content and chlorophyll a/b ratio; all of these changes were moderated by Si application. Si application did not influence the K(+) concentration in leaves under K-sufficient or K-deficient conditions. It did, however, decrease the excessive accumulation of Put that was otherwise induced by K deficiency. Simultaneously, Put synthesis gene transcription and activation of amine oxidases were down-regulated by Si application under K-deficient conditions. In addition, Si reduced K-deficiency-enhanced antioxidant enzyme activities and decreased K-deficiency-induced H2O2 accumulation. These results indicate that Si application could reduce K-deficiency-induced Put accumulation by inhibiting Put synthesis and could decrease H2O2 production via PA oxidation. Decreased H2O2 accumulation contributes to the alleviation of cell death, thereby also alleviating K-deficiency-induced leaf chlorosis and necrosis.

There has been a resurgence of interest in recent years in monoamine oxidase inhibitors, primarily because of the demonstrated neuroprotective and/ or neurorescue properties of several of these drugs in a variety of toxic situations in vivo and in vitro. The consequence has been an increased interest in possible neuroprotective effects of psychiatric drugs in general, an improved understanding of glia-neuron interactions, and the provision of important clues to development of future drugs for treating psychiatric and neurological disorders. A brief overview of some relevant studies in this area is provided in this editorial. Monoamin oksidaz inhibitörleri ve nöroprotektif mekanizmalar Son yıllarda monoamin oksidaz inhibitörleri üzerindeki ilgide bir canlanma gözlenmektedir. Bunun başlıca nedeni in vivo ve in vitro çeşitli toksik durumlarda bu ilaçların bazılarının nöroprotektif ve / veya sinir kurtarıcı (neurorescue) etkileri olduğunun gösterilmesidir. Psikiyatrik ilaçların nöroprotektif etkilerine yönelik ilginin artması, glia-nöron etkileşimlerinin daha iyi anlaşılmasını sağlamış ve gerek psikiyatrik gerekse nörolojik bozuklukların tedavisine yönelik yeni ilaçların geliştirilmesi için önemli ipuçları elde edilmiştir. Bu editoryalde bu alanla ilgili bazı çalışmaların kısa özeti sunulmuştur.

A comprehensive study which was undertaken on the effect of three polyamines (PAs) on stomatal closure was examined in relation to nitric oxide (NO) and reactive oxygen species (ROS) levels in guard cells of Arabidopsis thaliana. Three PAs—putrescine (Put), spermidine (Spd), and spermine (Spm)—induced stomatal closure, while increasing the levels of NO as well as ROS in guard cells. The roles of NO and ROS were confirmed by the reversal of closure by cPTIO (NO scavenger) and catalase (ROS scavenger). The presence of L-NAME (NOS-like enzyme inhibitor) reversed PA-induced stomatal closure, suggesting that NOS-like enzyme played a significant role in NO production during stomatal closure. The reversal of stomatal closure by diphenylene iodonium (DPI, NADPH oxidase inhibitor) or 2-bromoethylamine (BEA, copper amine oxidase inhibitor) or 1,12 diaminododecane (DADD, polyamine oxidase inhibitor) was partial. In contrast, the presence of DPI along with BEA/DADD reversed completely the closure by PAs. We conclude that both NO and ROS are essential signaling components during Put-, Spd-, and Spm-induced stomatal closure. The PA-induced ROS production is mediated by both NADPH oxidase and amine oxidase. The rise in ROS appears to be upstream of NO. Ours is the first detailed study on the role of NO and its dependence on ROS during stomatal closure by three major PAs.

In this work, we report cloning of two full-length 1-aminocyclopropane-1-carboxylate oxidase (ACO) cDNAs (ACO1 and ACO2) from potato (Solanum tuberosum) and their expression in potato tissues. The sequence data indicate that the two cDNAs share a high degree of homology with each other, and with known ACO genes from other plant species, including monocots and dicots. However, these potato genes lack homology at the 5' and 3' ends, despite similarities in their open reading frames and encoded amino acids. Phylogenetic analysis places them in two subfamilies of ACOs. The genes are tissue specific: expression is high in leaves and low in roots and tubers. In sprouts and tubers, ACO1 is induced by heat (40 degrees C) and cold (0 degrees C) stresses, whereas ACO2 is induced only by cold (0 degrees C). ACO1 is markedly induced in leaves by wounding, soil-flooding, and exogenous application of 1-aminocyclopropane-1-carboxylic acid (ACC). In contrast, ACO2 induction is lower under these treatments. ACO1 and ACO2 are regulated very differently in potato leaves with respect to senescence. ACO2 expression is unaffected by senescence, whereas that of ACO1 is closely related to the age and senescence in both attached and detached leaves. Exogenous ACC not only induces ACO1, but also accelerates leaf senescence. ACO1 transcripts are induced significantly in leaves, stems, and tubers in the Potato virus A (PVA)-resistant potato cultivar Shepody when graft inoculated with PVA.

Research spurred by the discovery of pyrroloquinoline quinone (PQQ) in 1979 led to the discovery of four additional oxidation-reduction (redox) cofactors, all of which result from transmogrification of amino acyl side chains in respective enzymes. These cofactors are (a) topa quinone in copper-containing amine oxidases, enzymes found in nearly all forms of life, including human; (b) lysyl topa quinone of the copper protein lysyl oxidase, an enzyme required for proper cross-linking of collagen and elastin; (c) tryptophan tryptophylquinone of alkylamine dehydrogenases from gram-negative soil bacteria; and (d) the copper-complexed cysteinyl-tyrosyl radical of fungal galactose oxidase. Originally, PQQ was thought to be a covalently bound cofactor in numerous enzymes from eukaryotes and prokaryotes. Today, PQQ is only found as a noncovalent cofactor in bacterial enzymes. The ubiquity of PQQ in the environment and its ready accessibility in the human diet has raised questions concerning its role as a vitamin, or an essential or helpful nutrient. The relevance to nutrition, medicine, and pharmacology of PQQ, topa quinone, lysyl topa quinone, tryptophan trytophylquinone, the galactose oxidase cofactor, and the enzymes harboring these cofactors are discussed in this review

Taste and color, which are important organoleptic qualities of grape berry, undergo rapid and substantial changes during development and ripening. In this study, we used two cultivars ‘Summer Black’ and its bud sport ‘Nantaihutezao’ to explore and identify differentially expressed genes associated with total soluble solid and anthocyanin during developmental stages using RNA-Seq. Overall, substantial differences in expression were observed across berry development between the two cultivars. 5388 genes were detected by weighted gene co-expression network analysis (WGCNA) associated with the total soluble solid (TSS) and anthocyanin contents variations. Several of these genes were significantly enriched in the phenylalanine metabolism pathway; two hub genes 4-coumarate-CoA ligase (VIT_02s0109g00250) and copper amine oxidase (VIT_17s0000g09100) played the most essential roles in relating to the total soluble solid and total anthocyanin variations induced by bud sport through Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment and co-expression network analysis. These findings provide insights into the molecular mechanism responsible for the bud sport phenotype.

Plant growth-promoting rhizobacteria often play a significant role in alleviating drought stress in plants by colonizing the rhizosphere through myriad mechanisms. We have previously reported that the drought-mitigating rhizobacterium, Pseudomonas putida GAP-P45, modulates polyamine biosynthetic gene expression and cellular accumulation of polyamines (putrescine, spermidine, and spermine) in water-stressed Arabidopsis thaliana (Sen et al. in Plant Physiol Biochem 129:180–188, 2018). In continuation, here, we report the effect of the aforementioned strain on the expression of polyamine catabolic genes (CuAO1-3, PAO1-5), activities of catabolic enzymes (copper amine oxidase and polyamine oxidase), and accumulation of catabolic by-product, γ-amino butyric acid (GABA) in water-stressed A. thaliana. Similar to the previously reported increase in polyamine biosynthesis and accumulation, P. putida GAP-P45 inoculation under water stress led to significant upregulation of most polyamine catabolic genes at most time points of study. GAP-P45 inoculation of water-stressed A. thaliana increased mostly copper amine oxidase activity in the plants, while polyamine oxidase activity showed either similar or slightly increased levels as compared to the non-inoculated, water-stressed seedlings. The accumulation of GABA in A. thaliana was differentially impacted under these conditions. We conclude that P. putida GAP-P45 tightly regulates polyamine metabolism at least at the transcriptional level under water stress. Taken together with our previous study, the data obtained from the current study point towards GAP-P45 mediated enhanced putrescine turnover and a possible feedback inhibition of polyamine back-conversion due to net accumulation of free putrescine in A. thaliana under water stress.

Screening immediate-early responding genes during the hypersensitive response (HR) against tobacco mosaic virus infection in tobacco (Nicotiana tabacum) plants, we identified a gene encoding ornithine decarboxylase. Subsequent analyses showed that other genes involved in polyamine biosynthesis were also up-regulated, resulting in the accumulation of polyamines in apoplasts of tobacco mosaic virus-infected leaves. Inhibitors of polyamine biosynthesis, α-difluoromethyl-ornithine, however, suppressed accumulation of polyamines, and the rate of HR was reduced. In contrast, polyamine infiltration into a healthy leaf induced the generation of hydrogen peroxide and simultaneously caused HR-like cell death. Polyamine oxidase activity in the apoplast increased up to 3-fold that of the basal level during the HR, and its suppression with a specific inhibitor, guazatine, resulted in reduced HR. Because it is established that hydrogen peroxide is one of the degradation products of polyamines, these results indicate that one of the biochemical events in the HR is production of polyamines, whose degradation induces hydrogen peroxide, eventually resulting in hypersensitive cell death.