工业真菌中的交替氧化酶

真菌是现代微生物发酵产业的主力军之一。交替呼吸途径(Alternative respiration pathway,ARP),以其非磷酸化电子传递途径,起到了能量溢流(Energy overflow)的作用,调节细胞能量代谢,平衡碳代谢和电子传递,有利于代谢产物的积累。此外,交替呼吸对真菌的抗逆反应和条件致病菌的生理作用也都具有非常重要的影响。交替氧化酶(Alternative oxidase,AOX)是线粒体中交替呼吸途径的末端氧化酶,广泛存在于高等植物及部分真菌和藻类中。由于交替氧化酶对水杨氧肟酸(Salicylhydroxamic acid,SHAM)敏感而对细胞色素呼吸抑制剂氰化物不敏感,交替氧化酶AOX介导的交替呼吸途径又被称为抗氰呼吸途径(Cyanide-resistant respiration,CRR)。近年来,研究交替呼吸途径和交替氧化酶已成为细胞呼吸代谢领域的热门课题。本文主要对真菌交替呼吸途径和交替氧化酶的结构与其在工业真菌体内功能的最新研究进展作一简要的综述。     

环境胁迫与植物抗氰呼吸

抗氰呼吸广泛存在于高等植物、一些真菌和藻类中。抗氰呼吸的发生和运行程度除与植物自身发育和内在生理状态有关外,还受到许多外界条件（逆境因子）的影响。目前,有关植物抗氰呼吸的环境调节以及环境胁迫条件下植物抗氰交替途径运行的生理学意义已成为植物呼吸代谢领域的研究热点。本研究综述了环境胁迫与植物抗氰呼吸的研究进展。     

交替氧化酶抑制剂研究进展及应用前景

交替氧化酶(alternative oxidase,AOX)是线粒体呼吸电子传递链中抗氰呼吸途径的末端氧化酶,它广泛存在于高等植物、藻类、部分真菌及原生生物中。同时,AOX也被发现存在于某些人体寄生虫中,如布氏锥虫(Trypanosoma brucei)等。布氏锥虫可引起人类"嗜睡病",不经治疗往往有致命的危险。据统计,在非洲地区每年有高达7 000多万人存在感染布氏锥虫病的风险。值得注意的是,人类细胞中不含有AOX。因此,AOX可能是治疗该类疾病最有效的潜在靶标。现主要就布氏锥虫交替氧化酶的特点及其抑制剂的设计和作用效果进行阐述,并展望AOX抑制剂的应用前景及研究挑战。     

交替氧化酶和解偶联蛋白在植物线粒体中的作用及其相互关系

植物线粒体不仅含有细胞色素C呼吸途径相关蛋白,也包括交替氧化酶（抗氰交替途径）和解偶联蛋白（解偶联途径）,这些途径中的蛋白都直接影响植物线粒体能量代谢。本文介绍了交替氧化酶和解偶联蛋白在植物线粒体能量代谢中的作用及其相互关系的研究进展。     

干旱与条锈病复合胁迫对小麦的生理影响

以抗旱性和抗病性不同的小麦为材料,以正常生长为对照,观察了病原菌和水分复合胁迫对小麦叶片相对含水量、活性氧代谢以及对抗氰呼吸的发生、运行的影响。讨论了在干旱与病原菌侵染复合胁迫下,抗氰呼吸在植物抗逆机制中所扮演的角色。复合胁迫下,抗病小麦显然具备更强的水分调控能力,而感病品种不能有效控制病叶水分散失。水分胁迫能引起抗氰呼吸的下降,但不能抵消因病原菌侵染引起的抗氰呼吸的增强,条锈菌侵染对小麦抗氰呼吸的影响远远大于水分胁迫。病原菌侵染和水分复合胁迫下,活性氧产生的速率表现出累加效应,而抗氰呼吸表现出和基质抗氧化酶的活性互补。植物交替氧化酶在干旱与病原菌侵染复合胁迫中具有重要的抗氧化功能,并可能调节着逆境下物质与能量需求间的矛盾。     

交替氧化酶在番茄种子萌发中的作用研究

交替氧化酶(AOX)是植物体线粒体抗氰呼吸途径的末端氧化酶。本研究表明,番茄种子吸水后,AOX及其介导的抗氰呼吸快速上升,并在第3天达到峰值。当用AOX抑制剂处理后,番茄种子萌发减慢,呼吸作用减弱,乙烯的释放量减少,活性氧(ROS)增多。此外,外施乙烯也能促进番茄种子的萌发,但不能促进AOX受抑制种子的萌发,表明乙烯对种子萌发的诱导作用依赖于AOX的表达。因此,本实验推测AOX在番茄种子萌发过程中起关键作用,并与调节ROS代谢及乙烯作用有关。     

内源乙烯对陈化马铃薯切片交替氧化酶表达的诱导作用

抗氰呼吸是植物线粒体区别于动物线粒体的主要功能特征之一,其本质是一条以交替氧化酶（ａｌｔｅｒｎａｔｉｖｅｏｘｉｄａｓｅ,ＡＯＸ）为末端氧化酶,被称为“交替途径”的呼吸电子传递链（ＭｃＩｎｔｏｓｈ１９９４）。该呼吸途径经常发生于产热植物开花、果实成熟、切片陈化、低温胁迫、机械损伤以及病原体侵染等一些较特殊的环境条件或生理过程中,并受乙烯等一些效应剂的诱导（Ｓｏｌｏｍｏｓ和Ｌａｔｉｅｓ１９７６,Ｄａｙ等１９７８,Ｇｕｄｅ和ｖａｎｄｅｒＰｌａｓ１９８５,Ｍａｒｉｓｓｅｎ等１９８６,Ｙｉｐ和Ｈｅｗ１９８…     

亚铁氧化酶Hephaestin的研究进展

Hephaestin(HP)作为铜蓝蛋白的同系物,是近年来发现的铁转运蛋白。HP具有一个位于羧基末端的跨膜结构域,主要分布于肠、肾、肺、皮肤、肝、胎盘等组织。目前已知HP在肠上皮细胞中与ferroportin1协同作用介导铁的跨膜转运。HP属亚铁氧化酶家族成员,具有亚铁氧化酶的活性,参与体内铁代谢。HP的表达可受铁、铜及锌等金属离子的调节。     

不同低温胁迫对烟草愈伤组织抗氰交替途径诱导和交替氧化酶表达影响的比较

比较了不同低温(14℃和4℃)胁迫对烟草(Nicotiana rusticaL．)愈伤组织抗氰交替途径诱导和交替氧化酶表达的影响。结果显示,不同低温胁迫处理能显著诱导烟草愈伤组织交替途径容量和实际运行的增加,且都呈现出基本相同的变化模式：在胁迫的初期(1—3d)持续增加,在3d时达到最高,而后下降到一个相对恒定的水平。但交替途径容量增加的幅度与温度下降的程度密切相关,而交替途径实际运行量的诱导程度在不同低温胁迫下的差异却很小。表明交替途径容量和实际运行对低温胁迫的响应是不同的。免疫印迹分析结果表明：低温胁迫明显诱导了交替氧化酶总蛋白的增加,且其随低温胁迫进程的变化与交替途径容量的变化基本一致;而对交替氧化酶单体与二聚体在低温胁迫下的含量变化检测结果则显示,烟草愈伤组织中交替氧化酶主要以二聚体形式存在,且这一存在形式并不随低温胁迫程度的加深而发生改变。两种形式的交替氧化酶蛋白含量都能被低温胁迫诱导增加,但其单体水平在两种不同的低温胁迫下并无明显差别,而4℃低温胁迫诱导的二聚体交替氧化酶蛋白含量明显高于14℃。表明不同程度低温对抗氰交替途径发生的不同影响主要是由于对交替氧化酶蛋白二聚体形式的不同诱导程度所致;而高活性的交替氧化酶单体形式则不因低温胁迫程度的加重而被明显诱导升高,使得抗氰交替途径的运行程度在两种不同的低温胁迫处理条件下无显著差异。     

棉花种子萌发过程中抗氰呼吸的变化及乙烯的诱导作用

抗氰呼吸是高等植物体内普遍存在的一种呼吸氧化电子传递途径。它对氧有较大的亲和力。早在1958年,Poliakoff-mayoer和Evenorl就发现莴苣(Lactucasativa)种子萌发过程中呼吸氧化除细胞色素     

A revised model of the active site of alternative oxidase

The plant mitochondrial protein alternative oxidase catalyses dioxygen dependent ubiquinol oxidation to yield ubiquinone and water. A structure of this protein has previously been proposed based on an assumed structural homology to the di-iron carboxylate family of proteins. However, these authors suggested the protein has a very different topology than the known structures of di-iron carboxylate proteins. We have re-examined this model and based on comparison of recent sequences and structural data on di-iron carboxylate proteins we present a new model of the alternative oxidase which allows prediction of active site residues and a possible membrane binding motif.     

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。     

Cyanide-resistant respiration in Streptomyces citreofluorescens

The capacity of Streptomycetes to carry out cyanide-resistant respiration was investigated. With the model strain, Streptomyces citreofluorescens, it was shown that deprivation of glucose followed by transition from exponential to stationary growth was coupled with declining sensitivity of cellular respiration to cyanide ions. Cyanide-resistant oxidase is located within the cytoplasmic membrane. The occurrence of the cyanide-resistant oxidase did not correspond to qualitative changes of cytochrome spectrum. Cytochrome d is involved neither in cyanide-sensitive nor in cyanide-resistant respiratory chain.     

Function of the alternative oxidase: is it still a scavenger?

The alternative oxidase is a respiratory chain protein found in all higher plants, fungi, non-fermentative yeasts and trypanosomes. Its primary structure suggests that it is a new member of the di-iron carboxylate protein family. Recent sequence analysis indicates an evolutionary relationship between primitive members of this protein family and the alternative oxidase, suggesting that its early function was to scavenge di-oxygen. However, modelling of plant growth kinetics suggests a different function.     

Cyanide-resistant respiration of Pseudomonas aeruginosa bacteria]

The transition of the bacterial culture into the stationary growth phase is accompanied by an appearance of cyanide-resistant respiration. Chloramphenicol inhibits the development of cyanide-resistant respiration. The cyanide-resistant oxidase is localized in the bacterial membrane. Its appearance is not due to the quantitative and qualitative changes of flavins, non-heme iron, ubiquinone and cytochromes of the b and c types, but is accompanied by an increase in the copper content of the membrane preparations. Neither cyanide-sensitive, nor cyanide-resistant chains of the bacterial electron transfer contain cytochromes of the a type. The cyanide-resistant oxidase accepts electrons at the ubiquinone--cytochrome b level of the main respiratory chain. The cyanide-resistant respiration is not accompanied by a formation of hydrogen peroxide. Cytochrome o performs the function of cyanide-sensitive oxidase. The nature of cyanide-resistant oxidase still remains obscure.     

The mitochondrial cyanide-resistant oxidase: structural conservation amid regulatory diversity

Mitochondria from all plants, many fungi and some protozoa contain a cyanide-resistant, alternative oxidase that functions in parallel with cytochrome c oxidase as the terminal oxidase on the electron transfer chain. Characterization of the structural and potential regulatory features of the alternative oxidase has advanced considerably in recent years. The active site is proposed to contain a di-iron center belonging to the ribonucleotide reductase R2 family and modeling of a four-helix bundle to accommodate this active site within the C-terminal two-thirds of the protein has been carried out. The structural features of this active site are conserved among all known alternative oxidases. The post-translational regulatory features of the alternative oxidase are more variable among organisms. The plant oxidase is dimeric and can be stimulated by either alpha-keto acids or succinate, depending upon the presence or absence, respectively, of a critical cysteine residue found in a conserved block of amino acids in the N-terminal region of the plant protein. The fungal and protozoan alternative oxidases generally exist as monomers and are not subject to organic acid stimulation but can be stimulated by purine nucleotides. The origins of these diverse regulatory features remain unknown but are correlated with sequence differences in the N-terminal third of the protein.     

Effect of growth at low temperature on the alternative pathway respiration in Acanthamoeba castellanii mitochondria

Mitochondria of amoeba Acanthamoeba castellanii in addition to the conventional cytochrome pathway possess, like plant mitochondria, a cyanide-resistant alternative quinol oxidase. In mitochondria isolated from amoeba batch culture grown temporarily at low temperature (6 degrees C), higher respiration was accompanied by lower coupling parameters as compared to control culture (grown at 28 degrees C). In the presence of benzohydroxamate, respiratory rates and coupling parameters were similar in both types of mitochondria indicating that growth in cold conditions did not disturb the cytochrome pathway. Increased contribution of alternative oxidase in total mitochondrial respiration in low-temperature-grown amoeba cells was confirmed by calculation of its contribution using ADP/O measurements. Furthermore, in mitochondria from low-temperature- grown cells the content of the alternative oxidase was increased and correlated with the increase in the unstimulated and GMP-stimulated cyanide-resistant respiratory activity. A possible physiological role of higher activity of alternative oxidase as response to growth at a low temperature in unicellular organisms, such as amoeba, is discussed.     

Cyanide-Resistant Respiration in Neurospora crassa

Cell respiration in wild type and poky was studied as part of a long-term investigation of cyanide-resistant respiration in Neurospora. Respiration in wild type proceeds via a cytochrome chain which is similar to that of higher organisms; it is sensitive to antimycin A or cyanide. Poky, on the other hand, respires by means of two alternative oxidase systems. One of these is analogous to the wild-type cytochrome chain in that it can be inhibited by antimycin A or cyanide; this system accounts for as much as 15% of the respiration of poky f(-) and 34% of the respiration of poky f(+). The second oxidase system is unaffected by antimycin A or cyanide at concentrations which inhibit the cytochrome chain maximally. It can, however, be specifically inhibited by salicyl hydroxamic acid. The cyanide-resistant oxidase is not exclusive to poky, but is also present in small quantities in wild type grown under ordinary circumstances. These quantities may be greatly increased (as much as 20-fold) by growing wild type in the presence of antimycin A, cyanide, or chloramphenicol.     

Effect of glutamic acid oversynthesis on the development of cyanide-resistant respiration in the bacterium Corynebacterium glutamicum

The composition of the respiratory chains of the wild stain Corynebacterium glutamicum and of its mutant differing in their ability for the glutamic acid oversynthesis in a medium with melassa was studied. Under excess of biotine and the parent strain is incapable of acid oversynthesis, while the mutant forms and excretes the acid. Both bacterial strains contain menaquinone and equal sets of cytochromes C550, b556, b563, and a600. The membrane-bound dehydrogenases of the parent strain are represented by NADH-, NADPH- and succinate dehydrogenases. Unlike the parent strain, the mutant membrane preparation does not oxidize NADPH. Both strains do not practically differ in their menaquinone content. The cyanide-resistant oxidase of a non-cytochrome nature appears in the wild strain during its transfer to the stationary growth phase. Induction of glutamic acid oversnythesis by addition of penicilline prevents the formation of the cyanide-resistant oxidase. On the contrary, the mutant transfer to the stationary growth phase is not accompanied by a formation of cyanide-resistant oxidase, which appears only after cessation of glutamic acid oversynthesis. Induction of the cyanide-resistant respiration by addition of cyanide inhibits the acid oversynthesis. Oxidation of substrates by membrane preparations of both bacterial strains in the absence and presence of cyanide is not followed by the hydrogen peroxide formation. It is assumed that there exist competitive interactions between the supersynthesis of glutamic acid and the cyanide-resistant respiration. The possible structure of the respiratory chain of Cor. glutamicum is discussed.