拟南芥金属蛋白酶FtSH4通过生长素与活性氧调控叶片衰老

植物金属蛋白酶Ft SH基因家族在拟南芥(Arabidopsis thaliana)中有12个成员,目前各基因的功能还不清楚。该文利用细胞生物学和遗传学方法初步分析了拟南芥FtSH4在叶片衰老中的功能。ftsh4-4突变体叶片中H_2O_2含量及细胞死亡率增加,叶绿素含量降低;此外,突变体中过氧化物酶基因表达上调,过氧化物酶活性增加,出现早衰表型。外源抗氧化剂As A、内源和外源生长素能够通过降低ftsh4-4体内H_2O_2含量、过氧化物酶基因的表达及过氧化物酶活性,恢复ftsh4-4叶片的衰老表型。ftsh4-4突变体中生长素响应因子基因ARF2和ARF7上调表达,外源生长素和抗氧化剂能够降低ARF2和ARF7的表达,并且ARF2突变能够降低ftsh4-4的H_2O_2含量并恢复其早衰表型。以上结果表明,FtSH4基因通过生长素与活性氧在调控植物叶片衰老中起重要作用。     

Reactive Oxygen and Nitrogen Species Regulate Mitochondrial Ca2+ Homeostasis and Respiration

The reduction of molecular oxygen to water provides most of the biologically useful energy. However, oxygen reduction is a mixed blessing because incompletely reduced oxygen species such as superoxide or peroxides are quite reactive and can, when out of control, cause damage. In mitochondria, where most of the oxygen utilized by eukaryotic cells is reduced, the dichotomy of oxygen shows itself best. Thus, reactive oxygen is a threat to them, as is evident from oxidative damage to mitochondrial lipids, proteins, and nucleic acids. Reactive oxygen, in the form of peroxides, also serves useful functions in mitochondria. This is exemplified by the control of mitochondrial and cellular calcium homeostasis, whose understanding has improved greatly during the last few years. An exciting new aspect is the discovery that nitric oxide and congeners have an enormous impact on mitochondria. Physiological concentrations of nitrogen monoxide (NO) at physiological cellular oxygen pressure inhibit cytochrome oxidase and thereby respiration. A transient inhibition of cytochrome oxidase by NO appears to be used in at least some forms of cell signalling. Peroxynitrite, the product of the reaction between superoxide and NO, can stimulate the specific calcium release pathway from mitochondria by oxidizing some vicinal thiols in mitochondria. There is evidence mounting that mitochondrial calcium handling and its modulation by reactive oxygen and nitrogen species is important for necrotic and apoptotic cell death.     

Sensitivity of Ca2+ Transport of Mitochondria to Reactive Oxygen Species

The relationship between Ca²⁺ transport and energy transduction of myocardial mitochondria in the presence of reactive oxygen species was investigated. Following treatment with oxygen free radicals [superoxide(O ₂ ) or hydroxyl radical ()OH], lipid free radicals in myocardial mitochondrial membrane could be detected by using the method of EPR spin trap. Simultaneously there were obvious alterations in the free Ca²⁺ ([Ca²⁺]_m) in the mitochondrial matrix; the physical state of membrane lipid; the efficiency of oxidative phosphorylation (ADP/O); the value of the respiratory control ratio (RCR); and the membrane potential of the inner membrane of myocardial mitochondria. If the concentrations of reactive oxygen species were reduced by about 30%, the alterations in the physical state of the membrane lipid and energy transduction of myocardial mitochondria were not observed, but the changes in Ca²⁺ homeostasis remained. We conclude that Ca²⁺ transport by myocardial mitochondria is more sensitive to agents such as (O ₂ ) or OH, etc. than are oxidation phosphorylation and the respiratory chain.     

Ca2+-Activated Reactive Oxygen Species Production by Arabidopsis RbohH and RbohJ Is Essential for Proper Pollen Tube Tip Growth

In flowering plants, pollen germinates on the stigma and pollen tubes grow through the style to fertilize the ovules. Enzymatic production of reactive oxygen species (ROS) has been suggested to be involved in pollen tube tip growth. Here, we characterized the function and regulation of the NADPH oxidases RbohH and RbohJ (Respiratory burst oxidase homolog H and J) in pollen tubes in Arabidopsis thaliana. In the rbohH and rbohJ single mutants, pollen tube tip growth was comparable to that of the wild type; however, tip growth was severely impaired in the double mutant. In vivo imaging showed that ROS accumulation in the pollen tube was impaired in the double mutant. Both RbohH and RbohJ, which contain Ca²⁺ binding EF-hand motifs, possessed Ca²⁺-induced ROS-producing activity and localized at the plasma membrane of the pollen tube tip. Point mutations in the EF-hand motifs impaired Ca²⁺-induced ROS production and complementation of the double mutant phenotype. We also showed that a protein phosphatase inhibitor enhanced the Ca²⁺-induced ROS-producing activity of RbohH and RbohJ, suggesting their synergistic activation by protein phosphorylation and Ca²⁺. Our results suggest that ROS production by RbohH and RbohJ is essential for proper pollen tube tip growth, and furthermore, that Ca²⁺-induced ROS positive feedback regulation is conserved in the polarized cell growth to shape the long tubular cell.     

Chitosan-Induced Stomatal Closure Accompanied by Peroxidase-Mediated Reactive Oxygen Species Production in Arabidopsis

Chitosan induced stomatal closure in wild type-plants and NADPH oxidase knock-out mutants (atrbohD atrbohF), and reactive oxygen species (ROS) production in wild-type guard cells. Closure and production were completely abolished by catalase and a peroxidase inhibitor. These results indicate that chitosan induces ROS production mediated by peroxidase, resulting in stomatal closure.     

Dopamine Induces Ca2+ Signaling in Astrocytes through Reactive Oxygen Species Generated by Monoamine Oxidase

Dopamine is a neurotransmitter that plays a major role in a variety of brain functions, as well as in disorders such as Parkinson disease and schizophrenia. In cultured astrocytes, we have found that dopamine induces sporadic cytoplasmic calcium ([Ca²⁺]_c) signals. Importantly, we show that the dopamine-induced calcium signaling is receptor-independent in midbrain, cortical, and hippocampal astrocytes. We demonstrate that the calcium signal is initiated by the metabolism of dopamine by monoamine oxidase, which produces reactive oxygen species and induces lipid peroxidation. This stimulates the activation of phospholipase C and subsequent release of calcium from the endoplasmic reticulum via the inositol 1,4,5-trisphosphate receptor mechanism. These findings have major implications on the function of astrocytes that are exposed to dopamine and may contribute to understanding the physiological role of dopamine.     

Reactive Oxygen Species Production in Wheat Roots Is Not Linked with Changes in H+ Fluxes During Acidic and Aluminium Stresses

Aluminium stress induces peroxidation of lipids in the plasma membrane, the effect akin to that caused by reactive oxygen species (ROS). ROS have recently been proposed as regulators of redox-dependent ion transport across the plasma membrane during biotic and abiotic stresses, thus contributing to the plant defence system. The aim of this study was to discover whether ROS production is linked to redox-dependent H⁺ transport system located at the plasma membranes of two near-isogenic lines of wheat (Triticum aestivum L., ET8 = Al-resistant, ES8 = Al-sensitive).The activities of NADPH-dependent ROS synthase and SOD were increased in both wheat lines 15 and 30 min after Al treatments. However, the ROS production was also increased under acidic stress. There was no difference between the two wheat lines in the root-cell plasma membrane capacity to efflux H⁺ in response to potassium ferricyanide after Al and acidic treatments. In ET8, both stresses led to increases in ROS production and H⁺ influx.ROS production in wheat seedlings was activated primarily by low pH exposure rather than by the Al stress. ROS production and breakdown in wheat seedlings under Al and acidic stresses appear to be linked to the intracellular metabolic changes rather than to the increased activity of plasma membrane-based NADPH-dependent ROS synthase.Key Words: ion fluxes, reactive oxygen species (ROS), redox system, superoxide dismutase (SOD), Triticum aestivum L., wheat     

The Regulation of Reactive Oxygen Species Production during Programmed Cell Death

Reactive oxygen species (ROS) are thought to be involved in many forms of programmed cell death. The role of ROS in cell death caused by oxidative glutamate toxicity was studied in an immortalized mouse hippocampal cell line (HT22). The causal relationship between ROS production and glutathione (GSH) levels, gene expression, caspase activity, and cytosolic Ca²⁺ concentration was examined. An initial 5–10-fold increase in ROS after glutamate addition is temporally correlated with GSH depletion. This early increase is followed by an explosive burst of ROS production to 200–400-fold above control values. The source of this burst is the mitochondrial electron transport chain, while only 5–10% of the maximum ROS production is caused by GSH depletion. Macromolecular synthesis inhibitors as well as Ac-YVAD-cmk, an interleukin 1β–converting enzyme protease inhibitor, block the late burst of ROS production and protect HT22 cells from glutamate toxicity when added early in the death program. Inhibition of intracellular Ca²⁺ cycling and the influx of extracellular Ca²⁺ also blocks maximum ROS production and protects the cells. The conclusion is that GSH depletion is not sufficient to cause the maximal mitochondrial ROS production, and that there is an early requirement for protease activation, changes in gene expression, and a late requirement for Ca²⁺ mobilization.     

Synergistic Triggering of Superoxide Flashes by Mitochondrial Ca2+ Uniport and Basal Reactive Oxygen Species Elevation

Mitochondrial superoxide flashes reflect a quantal, bursting mode of reactive oxygen species (ROS) production that arises from stochastic, transient opening of the mitochondrial permeability transition pore (mPTP) in many types of cells and in living animals. However, the regulatory mechanisms and the exact nature of the flash-coupled mPTP remain poorly understood. Here we demonstrate a profound synergistic effect between mitochondrial Ca²⁺ uniport and elevated basal ROS production in triggering superoxide flashes in intact cells. Hyperosmotic stress potently augmented the flash activity while simultaneously elevating mitochondrial Ca²⁺ and ROS. Blocking mitochondrial Ca²⁺ transport by knockdown of MICU1 or MCU, newly identified components of the mitochondrial Ca²⁺ uniporter, or scavenging mitochondrial basal ROS markedly diminished the flash response. More importantly, whereas elevating Ca²⁺ or ROS production alone was inefficacious in triggering the flashes, concurrent physiological Ca²⁺ and ROS elevation served as the most powerful flash activator, increasing the flash incidence by an order of magnitude. Functionally, superoxide flashes in response to hyperosmotic stress participated in the activation of JNK and p38. Thus, physiological levels of mitochondrial Ca²⁺ and ROS synergistically regulate stochastic mPTP opening and quantal ROS production in intact cells, marking the flash as a coincidence detector of mitochondrial Ca²⁺ and ROS signals.     

Mechanisms of Rapid Reactive Oxygen Species Generation in Response to Cytosolic Ca2+ or Zn2+ Loads in Cortical Neurons

Excessive “excitotoxic” accumulation of Ca²⁺ and Zn²⁺ within neurons contributes to neurodegeneration in pathological conditions including ischemia. Putative early targets of these ions, both of which are linked to increased reactive oxygen species (ROS) generation, are mitochondria and the cytosolic enzyme, NADPH oxidase (NOX). The present study uses primary cortical neuronal cultures to examine respective contributions of mitochondria and NOX to ROS generation in response to Ca²⁺ or Zn²⁺ loading. Induction of rapid cytosolic accumulation of either Ca²⁺ (via NMDA exposure) or Zn²⁺ (via Zn²⁺/Pyrithione exposure in 0 Ca²⁺) caused sharp cytosolic rises in these ions, as well as a strong and rapid increase in ROS generation. Inhibition of NOX activation significantly reduced the Ca²⁺-induced ROS production with little effect on the Zn²⁺- triggered ROS generation. Conversely, dissipation of the mitochondrial electrochemical gradient increased the cytosolic Ca²⁺ or Zn²⁺ rises caused by these exposures, consistent with inhibition of mitochondrial uptake of these ions. However, such disruption of mitochondrial function markedly suppressed the Zn²⁺-triggered ROS, while partially attenuating the Ca²⁺-triggered ROS. Furthermore, block of the mitochondrial Ca²⁺ uniporter (MCU), through which Zn²⁺ as well as Ca²⁺ can enter the mitochondrial matrix, substantially diminished Zn²⁺ triggered ROS production, suggesting that the ROS generation occurs specifically in response to Zn²⁺ entry into mitochondria. Finally, in the presence of the sulfhydryl-oxidizing agent 2,2''-dithiodipyridine, which impairs Zn²⁺ binding to cytosolic metalloproteins, far lower Zn²⁺ exposures were able to induce mitochondrial Zn²⁺ uptake and consequent ROS generation. Thus, whereas rapid acute accumulation of Zn²⁺ and Ca²⁺ each can trigger injurious ROS generation, Zn²⁺ entry into mitochondria via the MCU may do so with particular potency. This may be of particular relevance to conditions like ischemia in which cytosolic Zn²⁺ buffering is impaired due to acidosis and oxidative stress.     

Lactate Regulates Rat Male Germ Cell Function through Reactive Oxygen Species

Besides giving structural support, Sertoli cells regulate the fate of germ cells by supplying a variety of factors. These factors include hormones, several pro- and anti-apoptotic agents and also energetic substrates. Lactate is one of the compounds produced by Sertoli cells, which is utilized as an energetic substrate by germ cells, particularly spermatocytes and spermatids. Beyond its function as an energy source, some studies have proposed a role of lactate in the regulation of gene expression not strictly related to the energetic state of the cells. The general hypothesis that motivated this investigation was that lactate affects male germ cell function, far beyond its well-known role as energetic substrate. To evaluate this hypothesis we investigated: 1) if lactate was able to regulate germ cell gene expression and if reactive oxygen species (ROS) participated in this regulation, 2) if different signal transduction pathways were modified by the production of ROS in response to lactate and 3) possible mechanisms that may be involved in lactate stimulation of ROS production. In order to achieve these goals, cultures of germ cells obtained from male 30-day old rats were exposed to 10 or 20 mM lactate. Increases in lactate dehydrogenase (LDH) C and monocarboxylate transporter (MCT)2 expression, in Akt and p38-MAPK phosphorylation levels and in ROS production were observed. These effects were impaired in the presence of a ROS scavenger. Lactate stimulated ROS production was also inhibited by a LDH inhibitor or a NAD(P)H oxidase (NOX) inhibitor. NOX4 expression was identified in male germ cells. The results obtained herein are consistent with a scenario where lactate, taken up by germ cells, becomes oxidized to pyruvate with the resultant increase in NADH, which is a substrate for NOX4. ROS, products of NOX4 activity, may act as second messengers regulating signal transduction pathways and gene expression.     

植物中活性氧的产生及清除机制

环境胁迫使植物细胞中积累大量的活性氧,从而导致蛋白质、膜脂、DNA及其它细胞组分的严重损伤。植物体内有效清除活性氧的保护机制分为酶促和非酶促两类。酶促脱毒系统包括超氧化物歧化酶(SOD)、抗坏血酸过氧化物酶(APX)、过氧化氢酶(CAT)和谷胱甘肽过氧化物酶(GPX)等。非酶类抗氧化剂包括抗坏血酸、谷胱甘肽、甘露醇和类黄酮。利用基因工程策略增加这些物质在植物体内的含量,从而获得耐逆转基因植物已取得一定的进展。     

Reactive Oxygen Species during Plant-microorganism Early Interactions

Reactive Oxygen Species (ROS) are continuously produced as a result of aerobic metabolism or in response to biotic and abiotic stresses. ROS are not only toxic by-products of aerobic metabolism, but are also signalling molecules involved in several developmental processes in all organisms. Previous studies have clearly shown that an oxidative burst often takes place at the site of attempted invasion during the early stages of most plant-pathogen interactions. Moreover, a second ROS production can be observe...     

Reactive Oxygen Species during Plant-microorganism Early Interactions

Reactive Oxygen Species (ROS) are continuously produced as a result of aerobic metabolism or in response to biotic and abiotic stresses. ROS are not only toxic by-products of aerobic metabolism, but are also signalling molecules involved in several developmental processes in all organisms. Previous studies have clearly shown that an oxidative burst often takes place at the site of attempted invasion during the early stages of most plant-pathogen interac-tions. Moreover, a second ROS production can be observed during certain types of plant-pathogen interactions, which triggers hyper-sensitive cell death (HR). This second ROS wave seems absent during symbiotic interactions. This difference between these two responses is thought to play an important signalling role leading to the establishment of plant defense. In order to cope with the deleterious effects of ROS, plants are fitted with a large panel of enzymatic and non-enzymatic antioxidant mechanisms. Thus, increasing numbers of publications report the characterisation of ROS producing and scavenging systems from plants and from microorganisms during interactions. In this review, we present the current knowledge on the ROS signals and their role during plant-microorganism interactions.     

PEG and ABA Trigger the Burst of Reactive Oxygen Species to Increase Tanshinone Production in Salvia miltiorrhiza Hairy Roots

Salvia miltiorrhiza is one of the most popular traditional Chinese medicinal plants because of its excellent performance in treating coronary heart disease. Tanshinones, a group of active compounds in S. miltiorrhiza, are derived from two biosynthetic pathways: the mevalonate (MVA) pathway in the cytosol and the 2-C-methyl-D-erythritol-4-phosphate (MEP) pathway in the plastids. Water stress is well known to stimulate the accumulation of secondary metabolites in plants. Reactive oxygen species (ROS) serve as important secondary messengers in water stress-induced signal transduction pathways. In this study, the effects of polyethylene glycol (PEG) and abscisic acid (ABA) on tanshinone production in S. miltiorrhiza hairy roots were investigated and the roles of ROS in PEG- and ABA-induced tanshinone production were further elucidated. The results showed that contents and yields of four tanshinones in S. miltiorrhiza hairy roots were significantly enhanced by 2 % PEG and 200?μM ABA. Simultaneously, the mRNA levels and activities of two key enzymes (3-hydroxy-3-methylglutaryl coenzyme A reductase and 1-deoxy-D-xylulose 5-phosphate synthase) involved in tanshinone biosynthesis were upregulated. Both PEG and ABA were able to trigger the burst of H₂O₂ and O₂ ^?. The PEG- and ABA-induced increases of tanshinone production, gene expression, and enzyme activity were all dramatically suppressed by two ROS scavengers, catalase and superoxide dismutase. In addition, ROS treatments resulted in a significant increase in tanshinone production. These results demonstrated that the MVA and MEP pathways were activated by PEG and ABA to stimulate tanshinone biosynthesis, and the increase of tanshinone production was probably via ROS signaling.     

Rac1 Modulates Stimulus-evoked Ca2+ Release in Neuronal Growth Cones via Parallel Effects on Microtubule/Endoplasmic Reticulum Dynamics and Reactive Oxygen Species Production

The small G protein Rac regulates cytoskeletal protein dynamics in neuronal growth cones and has been implicated in axon growth, guidance, and branching. Intracellular Ca²⁺ is another well known regulator of growth cone function; however, effects of Rac activity on intracellular Ca²⁺ metabolism have not been well characterized. Here, we investigate how Rac1 activity affects release of Ca²⁺ from intracellular endoplasmic reticulum (ER) stores stimulated by application of serotonin (5-hydroxytriptamine). We also address how Rac1 effects on microtubule assembly dynamics affect distribution of Ca²⁺ release sites. Multimode fluorescent microscopy was used to correlate microtubule and ER behavior, and ratiometric imaging was used to assess intracellular Ca²⁺ dynamics. We report that Rac1 activity both promotes Ca²⁺ release and affects its spatial distribution in neuronal growth cones. The underlying mechanism involves synergistic Rac1 effects on microtubule assembly and reactive oxygen species (ROS) production. Rac1 activity modulates Ca²⁺ by 1) enhancing microtubule assembly which in turn promotes spread of the ER-based Ca²⁺ release machinery into the growth cone periphery, and 2) by increasing ROS production which facilitated inositol 1,4,5-trisphosphate-dependent Ca²⁺ release. These results cast Rac1 as a key modulator of intracellular Ca²⁺ function in the neuronal growth cone.