Differential Expression of Alternative Oxidase Genes in Soybean Cotyledons during Postgerminative Development

The expression of the alternative oxidase (AOX) was investigated during cotyledon development in soybean (Glycine max [L.] Merr.) seedlings. The total amount of AOX protein increased throughout development, not just in earlier stages as previously thought, and was correlated with the increase in capacity of the alternative pathway. Each AOX isoform (AOX1, AOX2, and AOX3) showed a different developmental trend in mRNA abundance, such that the increase in AOX protein and capacity appears to involve a shift in gene expression from AOX2 to AOX3. As the cotyledons aged, the size of the mitochondrial ubiquinone pool decreased. We discuss how this and other factors may affect the alternative pathway activity that results from the developmental regulation of AOX expression.     

The Role of the Alternative Oxidase in Stabilizing the in Vivo Reduction State of the Ubiquinone Pool and the Activation State of the Alternative Oxidase

A possible function for the alternative (nonphosphorylating) pathway is to stabilize the reduction state of the ubiquinone pool (Q_r/Q_t), thereby avoiding an increase in free radical production. If the Q_r/Q_t were stabilized by the alternative pathway, then Q_r/Q_t should be less stable when the alternative pathway is blocked. Q_r/Q_t increased when we exposed roots of Poa annua (L.) to increasing concentrations of KCN (an inhibitor of the cytochrome pathway). However, when salicylhydroxamic acid, an inhibitor of the alternative pathway, was added at the same time, Q_r/Q_t increased significantly more. Therefore, we conclude that the alternative pathway stabilizes Q_r/Q_t. Salicylhydroxamic acid increasingly inhibited respiration with increasing concentrations of KCN. In the experiments described here the alternative oxidase protein was invariably in its reduced (high-activity) state. Therefore, changes in the reduction state of the alternative oxidase cannot account for an increase in activity of the alternative pathway upon titration with KCN. The pyruvate concentration in intact roots increased only after the alternative pathway was blocked or the cytochrome pathway was severely inhibited. The significance of the pyruvate concentration and Q_r/Q_t on the activity of the alternative pathway in intact roots is discussed.     

Relationship of Alternative Respiratory Capacity and Alternative Oxidase Amount during Soybean Seedling Growth

In soybean (Glycine max [L.] Merr.) axis tissue and light- anddark-grown cotyledons 3 to 9 days of age, increasing amountof alternative oxidase corresponded with the increasing alternativepathway capacity of isolated mitochondria from these tissues.From 9 to 12 days of age, however, little or no change in amountof alternative oxidase occurred in cotyledons even though therewere substantial changes in capacity. This suggests that, whereasalternative oxidase content may be important in determiningthe capacity of the alternative pathway in young cotyledonsand in axis tissue, other factors regulate capacity in oldercotyledons. Both the presence or absence of light and tissuetype (cotyledon or axis) were found to influence the observedpattern on immunoblots of proteins believed to constitute thealternative oxidase. ³Present address: Sandoz Ltd., Agrobiological Research Station,41098 Witterswil, Switzerland (Received March 5, 1990; Accepted July 2, 1990)     

Expression of a Soybean Hydroxyproline-Rich Glycoprotein Gene Is Correlated with Maturation of Roots

A novel extensin gene has been identified in soybean (Glycine max L.) that encodes a hydroxyproline-rich glycoprotein (SbHRGP3) with two different domains. In this study expression of SbHRGP3 was investigated during soybean root development. SbHRGP was expressed in roots of mature plants, as well as seedlings, and showed a distinct pattern of expression during root development. The expression of SbHRGP3 increased gradually during root development of seedlings and reached a maximum while the secondary roots were maturing. The maximum expression level was contributed mainly by the secondary roots rather than by the primary root. Furthermore, expression of SbHRGP3 was preferentially detected in the regions undergoing maturation of the primary and secondary roots. These results imply that the expression of SbHRGP3 is regulated in an organ- and development-specific manner and that in soybean SbHRGP3 expression may be required for root maturation, presumably for the cessation of root elongation. Wounding and sucrose in combination enhanced expression of SbHRGP3 in roots, whereas both wounding and sucrose were required for the expression of SbHRGP3 in leaves.     

Regulation of Alternative Oxidase Activity by Pyruvate in Soybean Mitochondria

The regulation of alternative oxidase activity by the effector pyruvate was investigated in soybean (Glycine max L.) mitochondria using developmental changes in roots and cotyledons to vary the respiratory capacity of the mitochondria. Rates of cyanide-insensitive oxygen uptake by soybean root mitochondria declined with seedling age. Immunologically detectable protein levels increased slightly with age, and mitochondria from younger, more active roots had less of the protein in the reduced form. Addition of pyruvate stimulated cyanide-insensitive respiration in root mitochondria, up to the same rate, regardless of seedling age. This stimulation was reversed rapidly upon removal of pyruvate, either by pelleting mitochondria (with succinate as substrate) or by adding lactate dehydrogenase with NADH as substrate. In mitochondria from cotyledons of the same seedlings, cyanide-insensitive NADH oxidation was less dependent on added pyruvate, partly due to intramitochondrial generation of pyruvate from endogenous substrates. Cyanide-insensitive oxygen uptake with succinate as substrate was greater than that with NADH, in both root and cotyledon mitochondria, but this difference became much less when an increase in external pH was used to inhibit intramitochondrial pyruvate production via malic enzyme. Malic enzyme activity in root mitochondria declined with seedling age. The results indicate that the activity of the alternative oxidase in soybean mitochondria is very dependent on the presence of pyruvate: differences in the generation of intramitochondrial pyruvate can explain differences in alternative oxidase activity between tissues and substrates, and some of the changes that occur during seedling development.     

植物交替氧化酶(AOX)在大肠杆菌中优化表达

植物交替氧化酶(Alternative Oxidase,AOX)位于高等植物线粒体内膜,从细胞色素途径的辅酶Q分岔,催化4个电子还原氧分子形成水的另一终端氧化酶。分离纯化有活性的AOX比较困难。本文研究AOX原核表达,选择pFLAG-1分泌表达载体,用异丙基硫代-β-D-半乳糖苷(IPTG)诱导AOX优化表达,pFLAG-1-AOX大肠杆菌优化表达条件为:宿主DH5α、温度37℃、细胞密度OD600=0.6、IPTG浓度0.2mmol/L,诱导后60min收获细胞;获得少量可溶的细胞外周质AOX和大量不溶的AOX,为深入研究AOX打下基础,同时为研究膜蛋白原核表达提供依据。     

Alternative Oxidase Expression in the Mouse Enables Bypassing Cytochrome c Oxidase Blockade and Limits Mitochondrial ROS Overproduction

Cyanide-resistant non-phosphorylating respiration is known in mitochondria from plants, fungi, and microorganisms but is absent in mammals. It results from the activity of an alternative oxidase (AOX) that conveys electrons directly from the respiratory chain (RC) ubiquinol pool to oxygen. AOX thus provides a bypath that releases constraints on the cytochrome pathway and prevents the over-reduction of the ubiquinone pool, a major source of superoxide. RC dysfunctions and deleterious superoxide overproduction are recurrent themes in human pathologies, ranging from neurodegenerative diseases to cancer, and may be instrumental in ageing. Thus, preventing RC blockade and excess superoxide production by means of AOX should be of considerable interest. However, because of its energy-dissipating properties, AOX might produce deleterious effects of its own in mammals. Here we show that AOX can be safely expressed in the mouse (MitAOX), with major physiological parameters being unaffected. It neither disrupted the activity of other RC components nor decreased oxidative phosphorylation in isolated mitochondria. It conferred cyanide-resistance to mitochondrial substrate oxidation and decreased reactive oxygen species (ROS) production upon RC blockade. Accordingly, AOX expression was able to support cyanide-resistant respiration by intact organs and to afford prolonged protection against a lethal concentration of gaseous cyanide in whole animals. Taken together, these results indicate that AOX expression in the mouse is innocuous and permits to overcome a RC blockade, while reducing associated oxidative insult. Therefore, the MitAOX mice represent a valuable tool in order to investigate the ability of AOX to counteract the panoply of mitochondrial-inherited diseases originating from oxidative phosphorylation defects.     

Oxidative Stress Alters Syndecan-1 Distribution in Lungs with Pulmonary Fibrosis

Idiopathic pulmonary fibrosis (IPF) is an interstitial lung disease characterized by severe, progressive fibrosis. Roles for inflammation and oxidative stress have recently been demonstrated, but despite advances in understanding the pathogenesis, there are still no effective therapies for IPF. This study investigates how extracellular superoxide dismutase (EC-SOD), a syndecan-binding antioxidant enzyme, inhibits inflammation and lung fibrosis. We hypothesize that EC-SOD protects the lung from oxidant damage by preventing syndecan fragmentation/shedding. Wild-type or EC-SOD-null mice were exposed to an intratracheal instillation of asbestos or bleomycin. Western blot was used to detect syndecans in the bronchoalveolar lavage fluid and lung. Human lung samples (normal and IPF) were also analyzed. Immunohistochemistry for syndecan-1 and EC-SOD was performed on human and mouse lungs. In vitro, alveolar epithelial cells were exposed to oxidative stress and EC-SOD. Cell supernatants were analyzed for shed syndecan-1 by Western blot. Syndecan-1 ectodomain was assessed in wound healing and neutrophil chemotaxis. Increases in human syndecan-1 are detected in lung homogenates and lavage fluid of IPF lungs. Syndecan-1 is also significantly elevated in the lavage fluid of EC-SOD-null mice after asbestos and bleomycin exposure. On IHC, syndecan-1 staining increases within fibrotic areas of human and mouse lungs. In vitro, EC-SOD inhibits oxidant-induced loss of syndecan-1 from A549 cells. Shed and exogenous syndecan-1 ectodomain induce neutrophil chemotaxis, inhibit alveolar epithelial wound healing, and promote fibrogenesis. Oxidative shedding of syndecan-1 is an underlying cause of neutrophil chemotaxis and aberrant wound healing that may contribute to pulmonary fibrosis.Idiopathic pulmonary fibrosis (IPF)² is an interstitial lung disease characterized by severe and progressive fibrosis. IPF patients have a mean survival of 3–5 years (1, 2) and no effective therapies (3, 4), other than orthotopic lung transplantation, have proven to improve survival. The pathogenesis of IPF is poorly understood; however, inflammation and oxidant/antioxidant imbalances in the lung are thought to play important roles (5–7). A better understanding of the molecular mechanisms involved in oxidative injury and fibrosis could lead to the development of novel therapeutic targets.Extracellular superoxide dismutase (EC-SOD) is an antioxidant enzyme bound to heparan sulfate in the lung extracellular matrix (8–10), which can inhibit inflammation (11, 12) and prevent subsequent development of fibrosis (13–16). Despite its beneficial role, the mechanisms through which EC-SOD protects the lung remain unknown.The extracellular matrix (ECM) is essential for tissue homeostasis and changes in the ECM microenvironment can be detrimental to cell function during inflammation and wound healing. Heparan sulfate proteoglycans (HSPG) contain a membrane-bound core protein and extracellular carbohydrate side chains. Syndecans are the most abundant HSPG in humans; there are 4 isoforms with variable cell expression (17, 18). Both syndecan-1 and -4 are expressed in the lung, with epithelial cell and ubiquitous expression, respectively (19). Syndecans are essential for ECM homeostasis by binding cytokines and growth factors, acting as co-receptors and soluble effectors. They also have potential roles in inflammation (18, 20, 21), fibrosis (22, 23), and wound healing (24–26). Syndecans are shed under physiological and pathological conditions but the function of shed syndecans is poorly understood (22). Reactive oxygen species (ROS) are capable of fragmenting HSPG (27) and other ECM components. Notably, EC-SOD has been shown to prevent oxidative damage to many ECM components (23, 28, 29). Within the lung, EC-SOD binds to syndecan-1 on the cell surface via a heparin-binding domain (8, 30). Because of the known functions of syndecans and its close interaction with EC-SOD, syndecan-1 is a key target that may contribute to the anti-inflammatory and anti-fibrotic effects of EC-SOD in the lung and in the pulmonary fibrosis.This study was conducted to determine the role of EC-SOD in protecting the ECM from oxidative stress and to investigate our hypothesis that EC-SOD protects the lung from inflammation and fibrosis by inhibiting oxidant-induced shedding of syndecan-1. Our findings suggest that a loss of EC-SOD in the lung leaves syndecan-1 vulnerable to oxidative stress and that oxidatively shed syndecan-1 ectodomain induces neutrophil chemotaxis, impairs epithelial wound healing, and promotes fibrogenesis. The discovery that oxidative stress alters the distribution of syndecan-1 in the lung microenvironment is a novel finding in the context of pulmonary fibrosis. These findings advance the understanding of the pathogenesis of idiopathic pulmonary fibrosis and provide a potential new therapeutic target for intervention in IPF.     

Penetration and Development of Meloidogyne incognita on Roots of Resistant Soybean Genotypes

Meloidogyne incognita penetration and development were studied in roots of highly resistant (PI 96354, PI 417444), resistant (Forrest), and susceptible (Bossier) soybean genotypes. Although more second-stage juveniles (J2) had penetrated roots of PI 96354 and PI 417444 than roots of Forrest and Bossier by 2 days after inoculation, fewer J2 were present in roots of PI 96354 at 4 days after inoculation. Juvenile development in all genotypes was evident by 6 days after inoculation, with the highest number of swollen J2 present in roots of Bossier. At 16 days after inoculation, roots of PI 96354 had 87%, 74%, and 53% fewer J2 than were present in roots of Bossier, Forrest, and PI 417444, respectively. Differential emigration of J2, not fewer invasion sites, was responsible for the low number of nematodes in roots of the highly resistant PI 96354. Some 72% of the J2 penetrating the roots of this genotype emerged within 5 days after inoculation, whereas 4%, 54%, and 83% emerged from roots of Bossier, Forrest, and PI 417444, respectively. Penetration of roots of PI 96354 decreased the ability of J2 emerging from these roots to infect other soybean roots.     

Molecular Cloning and Functional Expression of Alternative Oxidase from Candida albicans

The AOX1 gene, which encodes an alternative oxidase, was isolated from the genomic DNA library of Candida albicans. The gene encodes a polypeptide consisting of 379 amino acids with a calculated molecular mass of 43,975 Da. The aox1/aox1 mutant strain did not show cyanide-resistant respiration under normal conditions but could still induce cyanide-resistant respiration when treated with antimycin A. The measurement of respiratory activity and Western blot analysis suggested the presence of another AOX. When C. albicans AOX1 was expressed in alternative oxidase-deficient Saccharomyces cerevisiae, it could confer cyanide-resistant respiration on S. cerevisiae.     

番茄交替氧化酶基因的克隆和表达

利用简并PCR扩增产物做探针筛选番茄cDNA基因文库获得一个全长交替氧化酶cDNA基因LeAoxlau.经序列分析得出,该基因全长1 418bp,编码区序列长1 077 bp,编码约40 kD的前体蛋白.该蛋白在转运到线粒体时被加工成32kD的成熟蛋白.Southern印迹杂交分析结果显示该基因以单拷贝形式存在于番茄的基因组中RT-PCR显示,该基因在在番茄植株的根、茎、叶和子叶中表达.重组表达实验表明该基因能在大肠杆菌中表达.     

单克隆抗体和抗合成多肽抗体检测烟草愈伤组织中交替氧化酶表达的比较

单克隆抗体和抗合成多肽抗体检测烟草愈伤组织中交替氧化酶表达的比较 晏婴才 林宏辉* 梁厚果 杜林方 （四川大学生命科学学院,成都610064I）     

Differential Expression of Peroxidase Isoenzymes in Soybean Roots Treated with the Benzothiadiazole

The protection compound benzo-(1,2,3)-thiadiazole-7-carbothioic acid S-methyl ester (BTH) was applied to soybean roots or leaves in a dose of 20 cm³ of a solution containing 25 μg g⁻¹ of the active ingredient. Electrophoretic profiles of chitinase and superoxide dismutase were not altered by the product. Increased activity of two root anionic peroxidases and three differential isoforms of these enzymes were observed in plants with roots treated by BTH, which can be used as biochemical markers of the BTH effect. This revised version was published online in July 2006 with corrections to the Cover Date.