Nitric oxide regulation of leaf phosphoenolpyruvate carboxylase-kinase activity: implication in sorghum responses to salinity

Nitric oxide (NO) is a signaling molecule that mediates many plant responses to biotic and abiotic stresses, including salt stress. Interestingly, salinity increases NO production selectively in mesophyll cells of sorghum leaves, where photosynthetic C₄ phosphoenolpyruvate carboxylase (C₄ PEPCase) is located. PEPCase is regulated by a phosphoenolpyruvate carboxylase-kinase (PEPCase-k), which levels are greatly enhanced by salinity in sorghum. This work investigated whether NO is involved in this effect. NO donors (SNP, SNAP), the inhibitor of NO synthesis NNA, and the NO scavenger cPTIO were used for long- and short-term treatments. Long-term treatments had multifaceted consequences on both PPCK gene expression and PEPCase-k activity, and they also decreased photosynthetic gas-exchange parameters and plant growth. Nonetheless, it could be observed that SNP increased PEPCase-k activity, resembling salinity effect. Short-term treatments with NO donors, which did not change photosynthetic gas-exchange parameters and PPCK gene expression, increased PEPCase-k activity both in illuminated leaves and in leaves kept at dark. At least in part, these effects were independent on protein synthesis. PEPCase-k activity was not decreased by short-term treatment with cycloheximide in NaCl-treated plants; on the contrary, it was decreased by cPTIO. In summary, NO donors mimicked salt effect on PEPCase-k activity, and scavenging of NO abolished it. Collectively, these results indicate that NO is involved in the complex control of PEPCase-k activity, and it may mediate some of the plant responses to salinity.     

In vivo target sites of nitric oxide in photosynthetic electron transport as studied by chlorophyll fluorescence in pea leaves

The role of nitric oxide (NO) in photosynthesis is poorly understood as indicated by a number of studies in this field with often conflicting results. As various NO donors may be the primary source of discrepancies, the aim of this study was to apply a set of NO donors and its scavengers, and examine the effect of exogenous NO on photosynthetic electron transport in vivo as determined by chlorophyll fluorescence of pea (Pisum sativum) leaves. Sodium nitroprusside-induced changes were shown to be mediated partly by cyanide, and S-nitroso-N-acetylpenicillinamine provided low yields of NO. However, the effects of S-nitrosoglutathione are inferred exclusively by NO, which made it an ideal choice for this study. Q(A)(-) reoxidation kinetics show that NO slows down electron transfer between Q(A) and Q(B), and inhibits charge recombination reactions of Q(A)(-) with the S(2) state of the water-oxidizing complex in photosystem II. Consistent with these results, chlorophyll fluorescence induction suggests that NO also inhibits steady-state photochemical and nonphotochemical quenching processes. NO also appears to modulate reaction-center-associated nonphotochemical quenching.     

硝酸镧提高黑麦草种子活力和幼苗生物量的生理效应

研究了不同浓度硝酸镧对黑麦草种子萌发和幼苗生长的影响及其生理生化变化。结果表明,低浓度硝酸镧（1000mg·L^-1）处理能够提高黑麦草种子的活力和萌发种子的淀粉酶、蛋白酶和脂肪酶活性及IAA、GA和CTK含量;促进幼苗光合速率提高和干物质积累,这可能与硝酸镧提高幼苗叶片叶绿素含量和叶绿体希尔反应活力,促进光合电子传递和磷酸化反应及激活Rubisco羧化活性、PEP羧化酶活性有密切关系,其中以30mg．L^-1浓度处理的效果最佳;高浓度硝酸镧（70-100mg·L-1）处理则降低种子活力和抑制幼苗生长。而10-100mg．L-1硝酸镧对种子的萌发率、ABA含量和Rubisco的加氧活性影响不大。由此可见,低浓度硝酸镧可通过参与萌发和光合过程的调控提高黑麦草种子的活力,促进幼苗生长。     

The flavoprotein Tah18-dependent NO synthesis confers high-temperature stress tolerance on yeast cells

Nitric oxide (NO) is a ubiquitous signaling molecule involved in the regulation of a large number of cellular functions. In the unicellular eukaryote yeast, NO may be involved in stress response pathways, but its role is poorly understood due to the lack of mammalian NO synthase (NOS) orthologues. Previously, we have proposed the oxidative stress-induced l-arginine synthesis and its physiological role under stress conditions in yeast Saccharomyces cerevisiae. Here, our experimental results indicated that increased conversion of l-proline into l-arginine led to NO production in response to elevated temperature. We also showed that the flavoprotein Tah18, which was previously reported to transfer electrons to the Fe–S cluster protein Dre2, was involved in NO synthesis in yeast. Gene knockdown analysis demonstrated that Tah18-dependent NO synthesis confers high-temperature stress tolerance on yeast cells. As it appears that such a unique cell protection mechanism is specific to yeasts and fungi, it represents a promising target for antifungal activity.     

The nitric oxide pathway in the cardiovascular system

The present review analyzes the role nitric oxide (NO) plays in the homeostasis of the cardiovascular system. By regulating vascular smooth muscle cell and myocyte contractility, myocardial oxygen consumption and renal tubular transport, this simple molecule plays a central role in the control of vascular tone, cardiac contractility and short and long term regulation of arterial pressure. Fifteen years ago, all we knew about NO is that it had very similar properties as those of endothelium-derived relaxing factor and that its action was probably mediated by cGMP. An enormous amount of knowledge has since been amassed on the biochemical pathways that NO follows from the moment it is synthesized from L-arginine until the physiological or pathological actions take place in the effector cells. This review intends to organize this knowledge in a fashion that is easy to understand. We will dissect the NO pathway in different steps, focusing on the physiological and pathophysiological actions of the isoenzymes which synthesize NO, the molecules involved in this synthesis such as caveolins, protein kinases and cofactors, the situations in which endogenous inhibitors of NO synthase are formed from L-arginine instead of NO, the way in which NO exerts its physiological actions through cGMP-dependent protein kinases and finally, the pathological routes NO may follow when the oxidative status of the cell is high.     

Does nitric oxide modulate mitochondrial energy generation and apoptosis?

The physiological role of nitric oxide (NO) in the maintenance of vascular tone, in synaptic transmission and in cellular defence is now firmly established. Recent evidence indicates that NO can also affect mitochondrial function. Here, we review findings indicating that NO through its interaction with components of the electron-transport chain might function not only as a physiological regulator of cell respiration, but also to augment the generation of reactive oxygen species by mitochondria, and thereby trigger mechanisms of cell survival or death.     

Regulation of neuronal growth cone filopodia by nitric oxide

Nitric oxide (NO) has been proposed to play an important role during neuronal development. Since many of its effects occur during the time of growth cone pathfinding and target interaction, we here test the hypothesis that part of NO's effects might be exerted at the growth cone. We found that low concentrations of the NO-donors DEA/NO, SIN-1, and SNP caused a rapid and transient elongation of filopodia as well as a reduction in filopodial number. These effects resulted from distinct changes in filopodial extension and retraction rates. Our novel findings suggest that NO could play a physiological role by temporarily changing a growth cone's morphology and switching its behavior from a close-range to a long-range exploratory mode. We subsequently dissected the pathway by which NO acted on growth cones. The effect of NO donors on filopodial length could be blocked by 1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one, an inhibitor of soluble guanylyl cyclase (sGC), indicating that NO acted via sGC. Supporting this idea, injection of cyclic GMP (cGMP) mimicked the effect of NO donors on growth cone filopodia. Moreover, application of NO-donors as well as injection of cGMP elicited a rapid and transient rise in intracellular calcium in growth cones, indicating that NO acted via cGMP to elevate calcium. This calcium rise, as well as the morphological effects of SIN-1 on filopodia, were blocked by preventing calcium entry. Given the role of filopodia in axonal guidance, our new data suggest that NO could function at the neuronal growth cone as an intracellular and/or intercellular signaling molecule by affecting steering decisions during neuronal pathfinding.     

Nitric Oxide Signalling In Plants

Nitric oxide (NO) is an important molecule that acts in many tissues to regulate a diverse range of physiological processes. It is becoming apparent that NO is a ubiquitous signal in plants. Since the discovery of NO emission by plants in the 1970s, this gaseous compound has emerged as a major signalling molecule involved in multiple physiological functions. Research on NO in plants has gained significant awareness in recent years and there is increasing indication on the role of this molecule as a key-signalling molecule in plants. The investigations about NO in plants have been concentrated on three main fields: The search of NO or any source of NO generation, effects of exogenous NO treatments, NO transduction pathways. However we have limited information about signal transduction procedures by which NO interaction with cells results in altered cellular activities. This article reviews recent advances in NO synthesis and its signalling functions in plants. First, different sources and biosynthesis of NO in plants, then biological processes involving NO signalling are reviewed. NO signalling relation with cGMP, protein kinases and programmed cell death are also discussed. Besides, NO signalling in plant defense response is also examined. Especially NO signalling between animal and plant systems is compared.     

Interplay between ascorbic acid and lipophilic antioxidant defences in chloroplasts of water-stressed Arabidopsis plants

Nitric oxide (NO) is a bioactive molecule involved in diverse physiological functions in plants. Here we demonstrate that NO is capable of regulating the activity of photophosphorylation in chloroplasts. The electron transport activity in photosystem II determined from chlorophyll a fluorescence was inhibited by NO. NO also inhibited light-induced DeltapH formation across the thylakoid membrane. High concentrations of nitrite and nitrate did not show such inhibitory effects, suggesting that the inhibition is not due to uncoupling effects of the oxidized products of NO. ATP synthesis activity upon illumination was severely inhibited by NO (IC(50)=0.7 microM). The inhibition was found to be temporary and the activity was completely recovered by removing NO. Bovine hemoglobin and bicarbonate were effective in preventing NO-dependent inhibition of photophosphorylation. These results indicate that NO is a reversible inhibitor of photosynthetic ATP synthesis.     

AtNOS/AtNOA1 is a functional Arabidopsis thaliana cGTPase and not a nitric-oxide synthase

AtNOS1 was previously identified as a potential nitric-oxide synthase (NOS) in Arabidopsis thaliana, despite lack of sequence similarity to animal NOSs. Although the dwarf and yellowish leaf phenotype of Atnos1 knock-out mutant plants can be rescued by treatment with exogenous NO, doubts have recently been raised as to whether AtNOS1 is a true NOS. Moreover, depending on the type of physiological responses studied, Atnos1 is not always deficient in NO induction and/or detection, as previously reported. Here, we present experimental evidence showing that AtNOS1 is unable to bind and oxidize arginine to NO. These results support the argument that AtNOS1 is not a NOS. We also show that the renamed NO-associated protein 1 (AtNOA1) is a member of the circularly permuted GTPase family (cGTPase). AtNOA1 specifically binds GTP and hydrolyzes it. Complementation experiments of Atnoa1 mutant plants with different constructs of AtNOA1 show that GTP hydrolysis is necessary but not sufficient for the physiological function of AtNOA1. Mutant AtNOA1 lacking the C-terminal domain, although retaining GTPase activity, failed to complement Atnoa1, suggesting that this domain plays a crucial role in planta. cGTPases appear to be RNA-binding proteins, and the closest homolog of AtNOA1, the Bacillus subtilis YqeH, has been shown to participate in ribosome assembly and stability. We propose a similar function for AtNOA1 and discuss it in the light of its potential role in NO accumulation and plant development.     

The role of nitrite in nitric oxide homeostasis: A comparative perspective

Nitrite is endogenously produced as an oxidative metabolite of nitric oxide, but it also functions as a NO donor that can be activated by a number of cellular proteins under hypoxic conditions. This article discusses the physiological role of nitrite and nitrite-derived NO in blood flow regulation and cytoprotection from a comparative viewpoint, with focus on mammals and fish. Constitutive nitric oxide synthase activity results in similar plasma nitrite levels in mammals and fish, but nitrite can also be taken up across the gills in freshwater fish, which has implications for nitrite/NO levels and nitrite utilization in hypoxia. The nitrite reductase activity of deoxyhemoglobin is a major mechanism of NO generation from nitrite and may be involved in hypoxic vasodilation. Nitrite is readily transported across the erythrocyte membrane, and the transport is enhanced at low O₂ saturation in some species. Also, nitrite preferentially reacts with deoxyhemoglobin rather than oxyhemoglobin at intermediate O₂ saturations. The hemoglobin nitrite reductase activity depends on heme O₂ affinity and redox potential and shows species differences within mammals and fish. The NO forming capacity is elevated in hypoxia-tolerant species. Nitrite-induced vasodilation is well documented, and many studies support a role of erythrocyte/hemoglobin-derived NO. Vasodilation can, however, also originate from nitrite reduction within the vessel wall, and at present there is no consensus regarding the relative importance of competing mechanisms. Nitrite reduction to NO provides cytoprotection in tissues during ischemia-reperfusion events by inhibiting mitochondrial respiration and limiting reactive oxygen species. It is argued that the study of hypoxia-tolerant lower vertebrates and diving mammals may help evaluate mechanisms and a full understanding of the physiological role of nitrite.     

固定化过程对聚球藻生理生化特性的影响

【背景】聚球藻(Synechococcus)是一类生长于海水中的单细胞蓝细菌,因生长迅速被用来净化污水。为了降低成本,生产上采用了固定化措施,但聚球藻固定化后,细胞内的生理生化变化尚未见报道。【目的】研究聚球藻固定化后生理生化及净化能力的变化,为促进聚球藻的应用提供科学依据。【方法】以海藻酸钠和氯化钙为主要原料固定聚球藻;利用显微观察法计算聚球藻的生长速率;利用溶氧仪检测聚球藻的净光合效率;利用荧光法检测一氧化氮(NO)含量;利用分光光度计法检测叶绿素含量、蛋白含量、硝酸还原酶(NR)活性、Rubisco羧化酶活性及水质指标。【结果】固定化过程使聚球藻的最大比生长速率降低24.30%。固定化后聚球藻的净光合速率降低范围为9.10%-29.10%,但固定化过程对叶绿素含量没有明显的影响。固定化使聚球藻Rubisco羧化酶活性、NO含量和NR活性分别降低25.70%、32.10%和40.00%,使聚球藻去除红鳍东方鲀养殖废水中总氮、总磷、氨氮和亚硝酸盐的能力分别降低30.00%、17.70%、20.20%和21.20%,但对去除硝酸盐及化学需氧量(Chemical oxygen demand,COD)的能力没有影响。【结论】固定化过程抑制了聚球藻NR的活性,使其NO产量减少,NO通过转录后修饰的方式降低了光合作用关键酶Rubisco的活性。Rubisco的活性降低使光合效率降低,导致固定化聚球藻的比生长速率和净化污水的能力降低。     

Nitric oxide production by arsenite

Arsenic can either enhance or reduce nitric oxide (NO) production, depending on the type of cell, the species and dose of arsenical tested. The mechanisms of how arsenic increases or decreases NO production remain unclear. Because NO is associated with many pathological conditions, it is conceivable that in those arsenic-target tissues, the NO production may be upregulated by continuous arsenic exposure, and a prolonged over-production of NO may cause inflammation hence a pathological condition. A prolonged interference with the normal physiological level of NO may also play a role in the initiation, promotion, and progression of arsenic-related human cancers. Suppression of NO production has been shown to reduce arsenite-induced oxidative DNA damage, inhibition of pyrimidine dimer excision, and micronuclei. However, a completely reliable story on how NO is involved in arsenic-related human disease is still lacking.     

Pollen generates nitric oxide and nitrite: a possible link to pollen-induced allergic responses

Reactive nitrogen species (RNS), such as nitric oxide (NO), are ubiquitous and diverse signalling molecules involved in a wide range of physiological and pathophysiological processes in both animals and plants. Nitrite, a metabolite of NO turnover, has also been recently characterised as an important mediator of fundamental physiological mechanisms in mammalian cells, and is a substrate for NO production in several plant cell signalling processes. A previous study demonstrated that during plant reproductive processes, intracellular NO is produced by pollen, and that such NO could be important in signalling interactions between pollen and stigma. The aim of this study was to establish whether pollen releases NO and nitrite, using a wide range of plant species. Using a fluorimetric assay in conjunction with electron paramagnetic resonance (EPR) spectroscopy, the present study demonstrated that all hydrating pollen examined released NO, although some appeared to have more activity than others. Additionally, gas phase ozone-based chemiluminescence data showed that nitrite is also released from hydrating pollen. Given that pollen has interactions with other cells, for example in allergenic rhinitis (hay fever) in humans, it suggests that NO might be involved in mediating the responses of both plant and animal cells to pollen. These findings may have important implications for future allergy research, as it is possible that pollen-derived NO and nitrite may impact on mammalian cells during pollen-induced allergic responses.     

Bacterial nitric-oxide synthases operate without a dedicated redox partner

Bacterial nitric-oxide (NO) synthases (bNOSs) are smaller than their mammalian counterparts. They lack an essential reductase domain that supplies electrons during NO biosynthesis. This and other structural peculiarities have raised doubts about whether bNOSs were capable of producing NO in vivo. Here we demonstrate that bNOS enzymes from Bacillus subtilis and Bacillus anthracis do indeed produce NO in living cells and accomplish this task by hijacking available cellular redox partners that are not normally committed to NO production. These "promiscuous" bacterial reductases also support NO synthesis by the oxygenase domain of mammalian NOS expressed in Escherichia coli. Our results suggest that bNOS is an early precursor of eukaryotic NOS and that it acquired its dedicated reductase domain later in evolution. This work also suggests that alternatively spliced forms of mammalian NOSs lacking their reductase domains could still be functional in vivo. On a practical side, bNOS-containing probiotic bacteria offer a unique advantage over conventional chemical NO donors in generating continuous, readily controllable physiological levels of NO, suggesting a possibility of utilizing such live NO donors for research and clinical needs.     

Differential requirement for NO during ABA-induced stomatal closure in turgid and wilted leaves

Abscisic acid (ABA)-induced stomatal closure is mediated by a complex, guard cell signalling network involving nitric oxide (NO) as a key intermediate. However, there is a lack of information concerning the role of NO in the ABA-enhanced stomatal closure seen in dehydrated plants. The data herein demonstrate that, while nitrate reductase (NR)1-mediated NO generation is required for the ABA-induced closure of stomata in turgid leaves, it is not required for ABA-enhanced stomatal closure under conditions leading to rapid dehydration. The results also show that NO signalling in the guard cells of turgid leaves requires the ABA-signalling pathway to be both capable of function and active. The alignment of this NO signalling with guard cell Ca²⁺-dependent/independent ABA signalling is discussed. The data also highlight a physiological role for NO signalling in turgid leaves and show that stomatal closure during the light-to-dark transition requires NR1-mediated NO generation and signalling.     

The physiological role of nitric oxide

The review is devoted to exposition of a physiological role of a nitric oxide (NO), free radical gas, in various physiological functions. The number of those NO involvements is extremely high: bacteriocidal, cytotoxic and antitumor leukocyte effects, a relaxation of smooth-muscle cells of both vessels and gastrointestinal tract, the name just a few. The scheme of NO formation in various biological systems and its targets were shown and neuromodulator functions of NO in a brain were analyzed by the review presented. The findings of own researches on a role of NO in function of neuro-muscular synapse were included by the authors.     

水淹对狗牙根营养繁殖植株的生理生态学效应

通过控制实验,测定了经过水淹处理的狗牙根营养繁殖体在恢复阶段的光合作用及其相关的生理生化指标的变化。结果显示,水淹时间对恢复阶段营养繁殖体的蒸腾作用和叶片温度的影响达到显著水平,水淹深度对该时期营养繁殖体的光合作用、气孔导度、胞间二氧化碳浓度和叶片温度有显著影响。水淹还导致了恢复期间植株叶片光合色素含量的显著变化。经过水淹的植株的各类光合色素含量以及色素总含量都显著高于对照植株,其中全淹处理的植株显著高于半淹处理的植株,叶绿素a与叶绿素b的比例也是全淹处理的植株显著高于半淹处理的植株。结果表明狗牙根营养繁殖体具有较强的恢复生长和生理活动的能力,是一种适宜于水电工程库区消落带生态恢复的物种。     

Imaging of nitric oxide in a living vertebrate using a diamino-fluorescein probe

Numerous approaches have been described to identify nitric oxide (NO), a free radical involved in various physiological and pathophysiological processes. One of these approaches is based on the use of chemical probes whose transformation by NO generates highly fluorescent derivatives, permitting detection of NO down to nanomolar concentrations. Here, we show that the cell-permeant diamino-fluorophore 4-amino-5-methylamino-2'-7'-difluoro-fluorescein diacetate (DAF-FM-DA) can be used to detect NO production sites in a living vertebrate, the zebrafish Danio rerio. The staining pattern obtained in larvae includes the bulbus arteriosus, forming bones, the notochord, and the caudal fin. The specificity of the signal was confirmed by its decrease in animals exposed to a NO scavenger or a NO synthase inhibitor and its increase in the presence of a NO donor. Using this method, NO production was observed to change along development in the notochord and the caudal fin whereas it remained stable in the bulbus arteriosus. Local changes in NO production in response to stressful conditions were also detected by this method. Altogether, labeling with DAF-FM DA is an efficient method to monitor changes in NO production in live zebrafish under physiological as well as pathophysiological conditions, suggesting applications to drug screening and molecular pharmacology.