1.
Multicopper oxidases: Biocatalysts in microbial pathogenesis and stress management.
Kaur, K, Sharma, A, Capalash, N, Sharma, P
Microbiological research. 2019;:1-13
Abstract
The acquisition of metal ions such as iron, copper and manganese is essential for the survival of microorganisms as these are constituents of metalloproteins including enzymes, storage proteins, structural elements, transcription factors and antimicrobial factors in various biological processes. However, excess of these metal ions is associated with significant toxicity due to spontaneous redox cycling of ions and obstruction of normal metabolic pathways. To overcome this, microbes have developed a variety of metal regulatory systems allowing them to adapt to the changing biotic and abiotic environments. Multi-copper oxidases (MCOs) such as ceruloplasmins, ferroxidases, laccases and nitrite reductases are such regulatory systems employed by microbes to resist the toxicity of metal ions by controlling their oxidation states under aerobic conditions. MCOs help pathogens survive during an infection by evasion of the toxic environment generated by the host immune system and thus are considered necessary determinants of virulence. This review summarizes the role of MCOs in metal homeostasis under stressful conditions and the extent to which these MCOs contribute to microbial virulence within the host that might prove as an esteemed avenue for the development of novel antimicrobial therapies.
2.
Cytochrome bd oxidase and bacterial tolerance to oxidative and nitrosative stress.
Giuffrè, A, Borisov, VB, Arese, M, Sarti, P, Forte, E
Biochimica et biophysica acta. 2014;(7):1178-87
Abstract
Cytochrome bd is a prokaryotic respiratory quinol:O2 oxidoreductase, phylogenetically unrelated to the extensively studied heme-copper oxidases (HCOs). The enzyme contributes to energy conservation by generating a proton motive force, though working with a lower energetic efficiency as compared to HCOs. Relevant to patho-physiology, members of the bd-family were shown to promote virulence in some pathogenic bacteria, which makes these enzymes of interest also as potential drug targets. Beyond its role in cell bioenergetics, cytochrome bd accomplishes several additional physiological functions, being apparently implicated in the response of the bacterial cell to a number of stress conditions. Compelling experimental evidence suggests that the enzyme enhances bacterial tolerance to oxidative and nitrosative stress conditions, owing to its unusually high nitric oxide (NO) dissociation rate and a notable catalase activity; the latter has been recently documented in one of the two bd-type oxidases of Escherichia coli. Current knowledge on cytochrome bd and its reactivity with O2, NO and H2O2 is summarized in this review in the light of the hypothesis that the preferential (over HCOs) expression of cytochrome bd in pathogenic bacteria may represent a strategy to evade the host immune attack based on production of NO and reactive oxygen species (ROS). This article is part of a Special Issue entitled: 18th European Bioenergetic Conference.
3.
Cytochrome bd oxidase and nitric oxide: from reaction mechanisms to bacterial physiology.
Giuffrè, A, Borisov, VB, Mastronicola, D, Sarti, P, Forte, E
FEBS letters. 2012;(5):622-9
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Abstract
Experimental evidence suggests that the prokaryotic respiratory cytochrome bd quinol oxidase is responsible for both bioenergetic functions and bacterial adaptation to different stress conditions. The enzyme, phylogenetically unrelated to the extensively studied heme-copper terminal oxidases, is found in many commensal and pathogenic bacteria. Here, we review current knowledge on the catalytic intermediates of cytochrome bd and their reactivity towards nitric oxide (NO). Available information is discussed in the light of the hypothesis that, owing to its high NO dissociation rate, cytochrome bd confers resistance to NO-stress, thereby providing a strategy for bacterial pathogens to evade the NO-mediated host immune attack.
4.
Spectroscopic characterization of heme iron-nitrosyl species and their role in NO reductase mechanisms in diiron proteins.
Moënne-Loccoz, P
Natural product reports. 2007;(3):610-20
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Abstract
Nitric oxide (NO) plays an important role in cell signalling and in the mammalian immune response to infection. On its own, NO is a relatively inert radical, and when it is used as a signalling molecule, its concentration remains within the picomolar range. However, at infection sites, the NO concentration can reach the micromolar range, and reactions with other radical species and transition metals lead to a broad toxicity. Under aerobic conditions, microorganisms cope with this nitrosative stress by oxidizing NO to nitrate (NO3−). Microbial hemoglobins play an essential role in this NO-detoxifying process. Under anaerobic conditions, detoxification occurs via a 2-electron reduction of two NO molecules to N2O. In many bacteria and archaea, this NO-reductase reaction is catalyzed by diiron proteins. Despite the importance of this reaction in providing microorganisms with a resistance to the mammalian immune response, its mechanism remains ill-defined. Because NO is an obligatory intermediate of the denitrification pathway, respiratory NO reductases also provide resistance to toxic concentrations of NO. This family of enzymes is the focus of this review. Respiratory NO reductases are integral membrane protein complexes that contain a norB subunit evolutionarily related to subunit I of cytochrome c oxidase (CcO). NorB anchors one high-spin heme b3 and one non-heme iron known as FeB, i.e., analogous to CuB in CcO. A second group of diiron proteins with NO-reductase activity is comprised of the large family of soluble flavoprotein A found in strict and facultative anaerobic bacteria and archaea. These soluble detoxifying NO reductases contain a non-heme diiron cluster with a Fe–Fe distance of 3.4 Å and are only briefly mentioned here as a promising field of research. This article describes possible mechanisms of NO reduction to N2O in denitrifying NO-reductase (NOR) proteins and critically reviews recent experimental results. Relevant theoretical model calculations and spectroscopic studies of the NO-reductase reaction in heme/copper terminal oxidases are also overviewed.