Synchronicity of thermogenic activity, alternative pathway respiratory flux, AOX protein content, and carbohydrates in receptacle tissues of sacred lotus during floral development

The relationships between heat production, alternative oxidase(AOX) pathway flux, AOX protein, and carbohydrates during floraldevelopment in Nelumbo nucifera (Gaertn.) were investigated.Three distinct physiological phases were identified: pre-thermogenic,thermogenic, and post-thermogenic. The shift to thermogenicactivity was associated with a rapid, 10-fold increase in AOXprotein. Similarly, a rapid decrease in AOX protein occurredpost-thermogenesis. This synchronicity between AOX protein andthermogenic activity contrasts with other thermogenic plantswhere AOX protein increases some days prior to heating. AOXprotein in thermogenic receptacles was significantly higherthan in post-thermogenic and leaf tissues. Stable oxygen isotopemeasurements confirmed that the increased respiratory flux supportingthermogenesis was largely via the AOX, with little or no contributionfrom the cytochrome oxidase pathway. During the thermogenicphase, no significant relationship was found between AOX proteincontent and either heating or AOX flux, suggesting that regulationis likely to be post-translational. Further, no evidence ofsubstrate limitation was found; starch accumulated during theearly stages of floral development, peaking in thermogenic receptacles,before declining by 89% in post-thermogenic receptacles. Whilstcoarse regulation of AOX flux occurs via protein synthesis,the ability to thermoregulate probably involves precise regulationof AOX protein, most probably by effectors such as -keto acids. Key words: Alternative oxidase, alternative pathway respiration, Nelumbo nucifera, plant thermogenesis, starch Received 11 November 2007; Accepted 28 November 2007     

Leaf respiration and alternative oxidase in field-grown alpine grasses respond to natural changes in temperature and light

? We report the first investigation of changes in electron partitioning via the alternative respiratory pathway (AP) and alternative oxidase (AOX) protein abundance in field-grown plants and their role in seasonal acclimation of respiration. ? We sampled two alpine grasses native to New Zealand, Chionochloa rubra and Chionochloa pallens, from field sites of different altitudes, over 1 yr and also intensively over a 2-wk period. ? In both species, respiration acclimated to seasonal changes in temperature through changes in basal capacity (R??) but not temperature sensitivity (E?). In C. pallens, acclimation of respiration may be associated with a higher AOX : cytochrome c oxidase (COX) protein abundance ratio. Oxygen isotope discrimination (D), which reflects relative changes in AP electron partitioning, correlated positively with daily integrated photosynthetically active radiation (PAR) in both species over seasonal timescales. Respiratory parameters, the AOX : COX protein ratio and D were stable over a 2-wk period, during which significant temperature changes were experienced in the field. ? We conclude that respiration in Chionochloa spp. acclimates strongly to seasonal, but not to short-term, temperature variation. Alternative oxidase appears to be involved in the plant response to both seasonal changes in temperature and daily changes in light, highlighting the complexity of the function of AOX in the field.     

Partitioning of respiratory electrons in the dark in leaves of transgenic tobacco with modified levels of alternative oxidase

This study examined tobacco ( Nicotiana tabacum cv. Petit Havana SR1) leaf respiration in the dark, utilizing both wild-type plants and transgenic plants with increased or decreased levels of alternative oxidase (AOX) protein. AOX represents a non-energy-conserving branch in mitochondrial electron transport. Inhibitor studies showed that the maximum possible flux of electrons to AOX (AOX capacity) correlated with the level of AOX protein present in the different plant lines. A comparison of the plants using online ¹⁸O isotope discrimination was done to determine whether AOX protein level would impact the actual steady-state partitioning of electrons to AOX (AOX engagement). Under a range of pretreatment and measurement conditions, there was little if any effect of AOX protein level on the degree of engagement. This suggests that the metabolic conditions inherent to a particular growth condition and/or the biochemical regulatory properties of AOX itself are the critical factors that control partitioning. Interestingly, we found that measurement temperature and water status are parameters that may have some influence over AOX engagement.     

Regulation of thermogenesis in flowering Araceae: the role of the alternative oxidase

The inflorescences of several members of the Arum lily family warm up during flowering and are able to maintain their temperature at a constant level, relatively independent of the ambient temperature. The heat is generated via a mitochondrial respiratory pathway that is distinct from the cytochrome chain and involves a cyanide-resistant alternative oxidase (AOX). In this paper we have used flux control analysis to investigate the influence of temperature on the rate of respiration through both cytochrome and alternative oxidases in mitochondria isolated from the appendices of intact thermogenic Arum maculatum inflorescences. Results are presented which indicate that at low temperatures, the dehydrogenases are almost in full control of respiration but as the temperature increases flux control shifts to the AOX. On the basis of these results a simple model of thermoregulation is presented that is applicable to all species of thermogenic plants. The model takes into account the temperature characteristics of the separate components of the plant mitochondrial respiratory chain and the control of each process. We propose that 1) in all aroid flowers AOX assumes almost complete control over respiration, 2) the temperature profile of AOX explains the reversed relationship between ambient temperature and respiration in thermoregulating Arum flowers, 3) the thermoregulation process is the same in all species and 4) variations in inflorescence temperatures can easily be explained by variations in AOX protein concentrations.     

An alternative respiratory pathway on Candida krusei: implications on susceptibility profile and oxidative stress

Our aim was to detect the presence of an alternative oxidase (AOX) in Candida krusei clinical strains and its influence on fluconazole susceptibility and in reactive oxygen species (ROS) production. Candida krusei clinical isolates were tested to evaluate the presence of AOX. Debaromyces hansenii 2968 (AOX positive) and Saccharomyces cerevisiae BY4742 (AOX negative) were used as control strains. Measurements of oxygen consumption were performed in the presence of 1?mM KCN, an inhibitor of the classical respiratory chain, and 5?mM salicylhydroxamic acid (SHAM). AOX expression was monitored by Western blotting using an AOX monoclonal antibody. Interactions between fluconazole and SHAM were performed using checkerboard assay. ROS production was evaluated in the presence of SHAM plus fluconazole, H(2) O(2) , menadione, or plumbagin. AOX was present in all C.?krusei tested. The combination of fluconazole with SHAM resulted in an indifferent effect. In the presence of SHAM, the treatment with ROS inductors or fluconazole increased ROS production, except in the AOX-negative strain. An alternative respiratory pathway resistant to cyanide is described for the first time as a characteristic of C.?krusei species. This AOX is unrelated to fluconazole resistance; however, it protects C.?krusei from oxidative stress.     

高等植物的交替氧化酶研究进展

交替氧化酶(Alternative Oxidase,AOX)广泛存在于高等植物、藻类和原生生物线粒体内膜。从主呼吸链的辅酶Q分岔,是氧化辅酶Q、还原氧分子生成水的另一终端氧化酶。氧化过程没有质子穿膜运动、热量以产热方式散发。产热植物中交替氧化产生的热量使花粉发出芳香味吸引虫传粉。推测植物AOX使植物在环境胁迫下维持呼吸,调节能量平衡,抵抗氧化胁迫,保持三羧酸循环的运行。AOX是首次发现的双铁羧酸蛋白质成员中的膜蛋白质,AOX与膜分离后容易失活,至今尚未有三级结构的报导,只有二级结构的2种假设模式,最新的模式AOX为膜界面蛋白质而不是跨膜蛋白。最近我们的研究表明有2个途径可获得适量有活性的AOX:建立优化的pFLAG-1-AOX大肠杆菌超量表达系统;从产热植物如斑叶阿若母(Arum maculatum)花序组织线粒体分离纯化有活性的AOX。     

Distinct roles of the cytochrome pathway and alternative oxidase in leaf photosynthesis

In illuminated leaves, mitochondria are thought to play roles in optimizing photosynthesis. However, the roles of the cytochrome pathway (CP) and alternative oxidase (AOX) in photosynthesis, in particular in the redox state of the photosynthetic electron transport chain, are not separately characterized. We examined the effects of specific inhibition of two respiratory pathways, CP and AOX, on photosynthetic oxygen evolution and the redox state of the photosynthetic electron transport chain in broad bean (Vicia faba L.) leaves under various light intensities. Under saturating photosynthetic photon flux density (PPFD; 700 micromol photon m(-2) s(-1)), inhibition of either pathway caused a decrease in the steady-state levels of the photosynthetic O(2) evolution rate and the PSII operating efficiency, Phi(II). Because these inhibitors, at the concentrations applied to the leaves, had little effect on photosynthesis in the intact chloroplasts, two respiratory pathways are essential for maintenance of high photosynthetic rates at saturating PPFD. CP or AOX inhibition affected to Chl fluorescence parameters (e.g. photochemical quenching and non-photochemical quenching) differently, suggesting that CP and AOX contribute to photosynthesis in different ways. At low PPFD (100 micromol photon m(-2) s(-1)), only the inhibition of AOX, not CP, lowered the photosynthetic rate and Phi(II). AOX inhibition also decreased the Phi(II)/Phi(I) ratio even at low PPFD levels. These data suggest that AOX inhibition caused the over-reduction of the photosynthetic electron transport chain and induced the cyclic electron flow around PSI (CEF-PSI) even at the low PPFD. Based on these results, we discuss possible roles for CP and AOX in the light.     

Respiratory chain network in mitochondria of Candida parapsilosis: ADP/O appraisal of the multiple electron pathways.

In this study we demonstrated that mitochondria of Candida parapsilosis contain a constitutive ubiquinol alternative oxidase (AOX) in addition to a classical respiratory chain (CRC) and a parallel respiratory chain (PAR) both terminating by two different cytochrome c oxidases. The C. parapsilosis AOX is characterized by a fungi-type regulation by GMP (as a stimulator) and linoleic acid (as an inhibitor). Inhibitor screening of the respiratory network by the ADP/O ratio and state 3 respiration determinations showed that (i) oxygen can be reduced by the three terminal oxidases through four paths implying one bypass between CRC and PAR and (ii) the sum of CRC, AOX and PAR capacities is higher than the overall respiration (no additivity) and that their engagement could be progressive according to the redox state of ubiquinone, i.e. first cytochrome pathway, then AOX and finally PAR.     

烟草叶片中呼吸电子传递途径在缓解叶绿体PSⅡ光抑制中的作用

前期研究发现线粒体交替氧化酶(AOX)呼吸途径对叶绿体光系统II(PSII)的光抑制有明显的缓解作用。线粒体内另一条呼吸途径——细胞色素氧化酶(COX)呼吸途径是否也具有光保护作用尚不清楚。该文通过荧光快速诱导动力学和荧光淬灭分析,解析了烟草(Nicotiana tabacum)叶片中COX途径对PSII光保护的贡献及其与AOX途径的关系。结果表明,强光处理后PSII活性在所有叶片中均下降。AOX途径受抑明显加速了叶片PSII活性的下降。而当COX途径受抑后,叶片PSII活性的下降与水处理的对照叶片无明显差异。当AOX途径与COX途径同时受抑时,叶片PSII活性的下降比单独抑制AOX途径时更严重。此外,呼吸电子传递受抑均导致叶片非光化学淬灭(NPQ)增加,AOX途径受抑导致的NPQ上调比COX途径受抑时更明显,AOX和COX途径同时受抑时NPQ的增幅最大。上述结果表明,烟草叶片中COX途径和AOX途径均参与PSⅡ的光保护。当COX途径受抑时,其光保护功能可以被AOX途径和NPQ补偿,而AOX途径的光保护作用不能被COX途径和NPQ完全补偿。     

H2O2和水杨酸对陈化马铃薯切片交替呼吸途径影响的比较

外源5.0 mmol/L H2O2和0.1 mmol/L 水杨酸(salicylic acid, SA)处理均可明显提高陈化24 h的马铃薯切片的交替呼吸途径容量(Valt)及其与总呼吸的比值(Valt/Vt).应用交替氧化酶的单克隆抗体进行Western杂交的结果表明,H2O2和SA处理均可明显提高陈化马铃薯切片中交替氧化酶的表达水平.用氧同位素分辨法研究,结果表明:H2O2处理对陈化马铃薯切片中交替呼吸途径的实际运行没有影响,而SA处理对交替呼吸途径的实际运行具有明显的促进作用.上述结果表明,H2O2和SA对植物组织交替呼吸途径的影响存在差异,二者均可促进交替氧化酶的表达从而诱导交替呼吸途径容量的发生,但H2O2不影响其实际运行,而SA还可同时诱导其实际运行.     

Mechanisms of thermoregulation in plants

Endothermic heating of floral tissues and even thermoregulation is known to occur in a number of plant species across a wide taxonomic range. The mechanisms by which flowers heat, however, are only just beginning to be understood, and even less is known about how heating is regulated in response to changes in ambient temperature. We have recently demonstrated that the alternative pathway of respiration, in which the alternative oxidase (AOX) rather than cytochrome C (COX) acts as terminal electron acceptor, is responsible for heat generation in one thermoregulating species, the sacred lotus (Nelumbo nucifera). In the March issue of the Journal of Experimental Botany we further demonstrated that AOX-mediated heat production in this species is regulated at both the level of gene expression and also post-translationally. Similarly, AOX has also been implicated in heat production in other thermogenic species. In this addendum we discuss the central role of AOX in heat production and how post-translational mechanisms may provide the fine control necessary for thermoregulation.Key words: alternative oxidase, Nelumbo nucifera, thermogenic plants, uncoupling proteins     

Contribution of the alternative pathway to respiration during thermogenesis in flowers of the sacred lotus

We report results from in vivo measurements, using oxygen isotope discrimination techniques, of fluxes through the alternative and cytochrome respiratory pathways in thermogenic plant tissue, the floral receptacle of the sacred lotus (Nelumbo nucifera). Fluxes through both pathways were measured in thermoregulating flowers undergoing varying degrees of thermogenesis in response to ambient temperature. Significant increases in alternative pathway flux were found in lotus receptacles with temperatures 16 degrees C to 20 degrees C above ambient, but not in those with lesser amounts of heating. Alternative pathway flux in the hottest receptacles was 75% of the total respiratory flux. In contrast, fluxes through the cytochrome pathway did not change significantly during thermogenesis. These data support the hypothesis that increased flux through the alternative pathway is responsible for heating in the lotus and that it is unlikely that uncoupling proteins, which would have produced increased fluxes through the cytochrome pathway, contribute significantly to heating in this tissue. Comparisons of actual flux, with capacity determined using inhibitors, suggested that the alternative pathway was operating at close to maximum capacity in heating tissues of lotus. However, in nonheating tissues the inhibitor data significantly overestimated the alternative pathway flux. This confirms that isotopic measurements are necessary for accurate determination of fluxes through the two pathways.     

Changes in mitochondrial electron partitioning in response to herbicides inhibiting branched-chain amino acid biosynthesis in soybean

The adaptation of the respiratory metabolism in roots of soybean (Glycine max L. Merr. cv Ransom) treated with herbicides that inhibit the enzyme acetolactate synthase (ALS) was analyzed. A new gas phase dual-inlet mass spectrometry system for simultaneous measurement of 34O2 to 32O2 and O2 to N2 ratios has been developed. This system is more accurate than previously described systems, allows measurements of much smaller oxygen gradients, and, as a consequence, works with tissues that have lower respiration rates. ALS inhibition caused an increase of the alternative oxidase (AOX) protein and an accumulation of pyruvate. The combination of these two effects is likely to induce the activation of the alternative pathway and its participation in the total respiration. Moreover, the start of the alternative pathway activation and the increase of AOX protein were before the decline in the activity of cytochrome pathway. The possible role of AOX under ALS inhibition is discussed.     

An Off-Line Implementation of the Stable Isotope Technique for Measurements of Alternative Respiratory Pathway Activities

In situ measurements of alternative respiratory pathway activity are needed to provide insight into the energy efficiency of plant metabolism under various conditions in the field. The only reliable method at present to measure alternative oxidase (AOX) activity is through measurement of changes in delta(18)O(O(2)), which to date has only been used in laboratory environments. We have developed a cuvette system to measure partitioning of electrons to AOX that is suitable for off-line use and for field experiments. Plant samples are enclosed in airtight cuvettes and O(2) consumption is monitored. Gas samples from the cuvette are stored in evacuated gas containers until measurement of delta(18)O(O(2)). We have validated this method using differing plant material to assess AOX activity. Fractionation factors were calculated from delta(18)O(O(2)) measurements, which could be measured with an accuracy and precision to 0.1 per thousand and 0.3 per thousand, respectively. Potential sources of error are discussed and quantified. Our method provides results similar to those obtained with laboratory incubations on-line to a mass spectrometer but greatly increases the potential for adoption of the stable isotope method.     

A field-compatible method for measuring alternative respiratory pathway activities in vivo using stable O₂ isotopes

Plants can alter rates of electron transport through the alternative oxidase (AOX) pathway in response to environmental cues, thus modulating respiratory efficiency, but the (18)O discrimination method necessary for measuring electron partitioning in vivo has been restricted to laboratory settings. To overcome this limitation, we developed a field-compatible analytical method. Series of plant tissue subsamples were incubated in 12 mL septum-capped vials for 0.5-4 h before aliquots of incubation air were injected into 3.7 mL evacuated storage vials. Vials were stored for up to 10 months before analysis by mass spectrometry. Measurements were corrected for unavoidable contamination. Additional mathematical tools were developed for detecting and addressing non-linearity (whether intrinsic or due to contamination) in the data used to estimate discrimination values. Initial contamination in the storage vials was 0.03 ± 0.01 atm; storing the gas samples at -17 °C eliminated further contamination effects over 10 months. Discrimination values obtained using our offline incubation and computation method replicated previously reported results over a range of 10-31‰, with precision generally better than ±0.5‰. Our method enables large-scale investigations of plant alternative respiration along natural environmental gradients under field conditions.     

Mitochondrial complex I impairment and differential carbon monoxide sensitivity of cytochrome c oxidase in wild type and CMS II mutants of Nicotiana sylvestris

Plant mitochondria unlike their animal counterpart have some unique features with highly branched respiratory chain. The present work was undertaken in order to investigate the effect of loss/dysfunction of plant mitochondrial complex I on the relative flux of electrons through alternative oxidase (AOX) and cytochrome oxidase. Loss of a major subunit of mitochondrial complex I in cytoplasmic male sterile II (CMS II) mutant of Nicotiana sylvestris caused respiratory redox perturbations, as evident from the differential CO sensitivity of cytochrome oxidase. The leaf segments of CMS II mutant when exposed to CO under dark aerobic condition were insensitive to the inhibition of cytochrome oxidase, as against the wild type (WT). The differential CO response of WT and CMS II mutants appeared to be due to differences in the redox state of cytochrome a3 (cyt a3), the terminal electron acceptor during in situ respiration. Cyt a3 appeared to be more in its oxidized form in CMS II and hence unable to form cyt a3-CO complex. Pre-treatment of CMS II leaves with 2,4-dinitrophenol, an uncoupler of oxidative phosphorylation increased the CO response. The slight increase in rotenone-insensitive respiration of CMS II could be attributed partly to enhanced flux of electrons through cytochrome pathway to compensate for the loss of phosphorylation site and partly through AOX, which was induced by nitrate.     

Variation in floral morphology within a population of Aster hispidus var. tubulosus (Asteraceae,Astereae)

The family Asteraceae has a particular inflorescence, the capitulum, consisting of ray florets and disc florets. The ray florets function as petals that attract pollinators. Marked variation in the ray floret morphology is known in a natural population of Aster hispidus var. tubulosus (Asteraceae). We analyzed the variation and found two distinct types in the ray florets, the long tubular ray floret and the ligulate ray floret. In this species, therefore, the variation in floral morphology among capitula, each of which is the basic pollination unit, is caused by the variation in the composition of the two ray floret types among capitula. We evaluated the sources of the observed variation in the floral morphology among capitula within a population using a hierarchical analysis that separated within‐individual (i.e. among capitula within each individual) and between‐individual components of the variation. We found that the main source of the variation lay at the between‐individual level, not at the between‐capitulum level nested within individuals. This finding will provide the basic knowledge that enables future study exploring whether the between‐individual variation in floral morphology caused by the compositional variation of the ray floret types leads to differential pollination success of individual plants in species of Asteraceae.