Zumft Walter G, Kroneck Peter M H
Institute of Applied Biosciences, Division of Molecular Microbiology, University of Karlsruhe, D-76128 Karlsruhe, Germany.
Adv Microb Physiol. 2007;52:107-227. doi: 10.1016/S0065-2911(06)52003-X.
N2O is a potent greenhouse gas and stratospheric reactant that has been steadily on the rise since the beginning of industrialization. It is an obligatory inorganic metabolite of denitrifying bacteria, and some production of N2O is also found in nitrifying and methanotrophic bacteria. We focus this review on the respiratory aspect of N2O transformation catalysed by the multicopper enzyme nitrous oxide reductase (N2OR) that provides the bacterial cell with an electron sink for anaerobic growth. Two types of Cu centres discovered in N2OR were both novel structures among the Cu proteins: the mixed-valent dinuclear Cu(A) species at the electron entry site of the enzyme, and the tetranuclear Cu(Z) centre as the first catalytically active Cu-sulfur complex known. Several accessory proteins function as Cu chaperone and ABC transporter systems for the biogenesis of the catalytic centre. We describe here the paradigm of Z-type N2OR, whose characteristics have been studied in most detail in the genera Pseudomonas and Paracoccus. Sequenced bacterial genomes now provide an invaluable additional source of information. New strains harbouring nos genes and capability of N2O utilization are being uncovered. This reveals previously unknown relationships and allows pattern recognition and predictions. The core nos genes, nosZDFYL, share a common phylogeny. Most principal taxonomic lineages follow the same biochemical and genetic pattern and share the Z-type enzyme. A modified N2OR is found in Wolinella succinogenes, and circumstantial evidence also indicates for certain Archaea another type of N2OR. The current picture supports the view of evolution of N2O respiration prior to the separation of the domains Bacteria and Archaea. Lateral nos gene transfer from an epsilon-proteobacterium as donor is suggested for Magnetospirillum magnetotacticum and Dechloromonas aromatica. In a few cases, nos gene clusters are plasmid borne. Inorganic N2O metabolism is associated with a diversity of physiological traits and biochemically challenging metabolic modes or habitats, including halorespiration, diazotrophy, symbiosis, pathogenicity, psychrophily, thermophily, extreme halophily and the marine habitat down to the greatest depth. Components for N2O respiration cover topologically the periplasm and the inner and outer membranes. The Sec and Tat translocons share the task of exporting Nos components to their functional sites. Electron donation to N2OR follows pathways with modifications depending on the host organism. A short chronology of the field is also presented.
一氧化二氮(N₂O)是一种强效温室气体和平流层反应物,自工业化开始以来其含量一直在稳步上升。它是反硝化细菌的一种必需无机代谢产物,在硝化细菌和甲烷氧化细菌中也发现有一定量的N₂O产生。本综述聚焦于由多铜酶一氧化二氮还原酶(N₂OR)催化的N₂O转化的呼吸方面,该酶为细菌细胞提供了一个用于厌氧生长的电子汇。在N₂OR中发现的两种类型的铜中心在铜蛋白中都是新结构:酶电子进入位点处的混合价双核铜(A)物种,以及作为已知首个具有催化活性的铜 - 硫复合物的四核铜(Z)中心。几种辅助蛋白作为铜伴侣和ABC转运系统参与催化中心的生物合成。我们在此描述Z型N₂OR的范例,其特性在假单胞菌属和副球菌属中得到了最详细的研究。已测序的细菌基因组现在提供了一个宝贵的额外信息来源。正在发现携带nos基因且具有N₂O利用能力的新菌株。这揭示了以前未知的关系,并允许进行模式识别和预测。核心nos基因nosZDFYL具有共同的系统发育关系。大多数主要的分类谱系遵循相同的生化和遗传模式,并共享Z型酶。在琥珀酸沃林氏菌中发现了一种经过修饰的N₂OR,间接证据也表明某些古菌存在另一种类型的N₂OR。目前的情况支持在细菌域和古菌域分离之前N₂O呼吸就已进化的观点。有人提出趋磁螺菌和芳香脱氯单胞菌的nos基因是从作为供体的ε - 变形菌横向转移而来的。在少数情况下,nos基因簇是质粒携带的。无机N₂O代谢与多种生理特征以及生物化学上具有挑战性的代谢模式或生境相关,包括卤呼吸作用、固氮作用、共生、致病性、嗜冷性、嗜热性、极端嗜盐性以及直至最深深度的海洋生境。N₂O呼吸的组分在拓扑结构上覆盖周质以及内膜和外膜。Sec和Tat转运子共同承担将Nos组分输出到其功能位点的任务。向N₂OR的电子供体遵循的途径会根据宿主生物体而有所不同。本文还简要介绍了该领域的发展历程。
