ROS Defense Systems and Terminal Oxidases in Bacteria

Borisov, Vitaliy B.; Siletsky, Sergey A.; Nastasi, Martina R.; Forte, Elena

doi:10.3390/antiox10060839

Cited by 75 publications

(66 citation statements)

References 132 publications

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“…It is suggested that H 2 S prevents oxidative DNA damage in bacteria via the following cytoprotective mechanisms: (i) direct reduction of H 2 O 2 into H 2 O; (ii) depletion of Fe 2+ , a catalyst of the Fenton reaction; (iii) transient depletion of free cysteine, a reducing agent that fuels the Fenton reaction; and (iv) stimulation of the activities of superoxide dismutase (SOD) and catalase [ 15 ]. The latter two enzymes are the well-known ROS scavenging systems [ 16 ]. It should be noted, however, that Shatalin et al [ 15 ] did not suggest a mechanism for the depletion of Fe 2+ and free cysteine by H 2 S.…”

Section: Introductionmentioning

confidence: 99%

Impact of Hydrogen Sulfide on Mitochondrial and Bacterial Bioenergetics

Borisov

Forte

2021

IJMS

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This review focuses on the effects of hydrogen sulfide (H2S) on the unique bioenergetic molecular machines in mitochondria and bacteria—the protein complexes of electron transport chains and associated enzymes. H2S, along with nitric oxide and carbon monoxide, belongs to the class of endogenous gaseous signaling molecules. This compound plays critical roles in physiology and pathophysiology. Enzymes implicated in H2S metabolism and physiological actions are promising targets for novel pharmaceutical agents. The biological effects of H2S are biphasic, changing from cytoprotection to cytotoxicity through increasing the compound concentration. In mammals, H2S enhances the activity of FoF1-ATP (adenosine triphosphate) synthase and lactate dehydrogenase via their S-sulfhydration, thereby stimulating mitochondrial electron transport. H2S serves as an electron donor for the mitochondrial respiratory chain via sulfide quinone oxidoreductase and cytochrome c oxidase at low H2S levels. The latter enzyme is inhibited by high H2S concentrations, resulting in the reversible inhibition of electron transport and ATP production in mitochondria. In the branched respiratory chain of Escherichia coli, H2S inhibits the bo3 terminal oxidase but does not affect the alternative bd-type oxidases. Thus, in E. coli and presumably other bacteria, cytochrome bd permits respiration and cell growth in H2S-rich environments. A complete picture of the impact of H2S on bioenergetics is lacking, but this field is fast-moving, and active ongoing research on this topic will likely shed light on additional, yet unknown biological effects.

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Section: Introductionmentioning

confidence: 99%

Impact of Hydrogen Sulfide on Mitochondrial and Bacterial Bioenergetics

Borisov

Forte

2021

IJMS

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“…HCOs catalyze the transfer of electrons from quinols or cytochromes to oxygen with the formation of water coupled to the generation of proton motive force [ 2 , 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 , 15 , 16 , 17 , 18 , 19 , 20 , 21 , 22 ]. In contrast to bd -type oxidases, HCOs generate the proton motive force not only by the transfer of electrons and protons to the catalytic center from different sides of the membrane but also due to the unique ability for redox-coupled directed proton pumping through the membrane [ 23 ].…”

Section: Introduction: General Properties Of Terminal Respiratory Oxidasesmentioning

confidence: 99%

“…Members of the other two families use cytochrome c and possibly another electron donor different than quinol [ 4 ]. Notwithstanding, to date all the biochemically characterized bd -type cytochromes appeared to be quinol oxidases [ 14 , 78 , 79 , 80 ]. Further research is required to obtain and characterize a bd enzyme that would use an electron donor other than quinol.…”

Section: Introduction: General Properties Of Terminal Respiratory Oxidasesmentioning

confidence: 99%

“…Based on general considerations, the organization of the proton-conducting input pathways in bd -type oxidases should be simpler since the major function of the A family HCOs is a generation of the proton motive force whereas the bd enzymes do not pump additional protons across the membrane. Instead, cytochromes bd play essential roles in bacterial physiology and pathogenesis [ 14 , 80 , 84 , 85 , 86 , 87 , 88 ]. The mechanism of transfer of pumped protons along the same pathway (at least a significant part of it) as is used for the transfer of substrate protons (D channel in the A family oxidases; K channel in oxidases of the B and C families) requires a special device to prevent access of pumped protons to the oxygen-reductase center.…”

Section: Introduction: General Properties Of Terminal Respiratory Oxidasesmentioning

confidence: 99%

“…In accordance with the important physiological role of the bd -type oxidases, there is accumulating evidence that cytochromes bd make bacteria resistant to nitric oxide (NO) [ 93 , 94 , 95 , 96 , 97 , 98 , 99 , 100 , 101 , 102 ], peroxynitrite [ 85 , 103 ], H 2 O 2 [ 14 , 104 , 105 , 106 , 107 ], cyanide [ 108 , 109 , 110 ], sulfide [ 110 , 111 , 112 , 113 ], and ammonia [ 114 ]. The ability of the bd oxidases to degrade these hazardous compounds is provided not only by the efficiency of their binding to the reaction center and the transfer of electrons to it, but also by the supply of protons through the proton-conducting input pathways.…”

Section: Introduction: General Properties Of Terminal Respiratory Oxidasesmentioning

confidence: 99%

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Proton Pumping and Non-Pumping Terminal Respiratory Oxidases: Active Sites Intermediates of These Molecular Machines and Their Derivatives

Siletsky

Borisov

2021

IJMS

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Terminal respiratory oxidases are highly efficient molecular machines. These most important bioenergetic membrane enzymes transform the energy of chemical bonds released during the transfer of electrons along the respiratory chains of eukaryotes and prokaryotes from cytochromes or quinols to molecular oxygen into a transmembrane proton gradient. They participate in regulatory cascades and physiological anti-stress reactions in multicellular organisms. They also allow microorganisms to adapt to low-oxygen conditions, survive in chemically aggressive environments and acquire antibiotic resistance. To date, three-dimensional structures with atomic resolution of members of all major groups of terminal respiratory oxidases, heme-copper oxidases, and bd-type cytochromes, have been obtained. These groups of enzymes have different origins and a wide range of functional significance in cells. At the same time, all of them are united by a catalytic reaction of four-electron reduction in oxygen into water which proceeds without the formation and release of potentially dangerous ROS from active sites. The review analyzes recent structural and functional studies of oxygen reduction intermediates in the active sites of terminal respiratory oxidases, the features of catalytic cycles, and the properties of the active sites of these enzymes.

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Photoactive Dye‐Loaded Polymer Materials: A New Cutting Edge for Antibacterial Photodynamic Therapy

Elian,

Méallet,

Versace

2024

Adv Funct Materials

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Healthcare‐associated infections remain a significant health concern, particularly with the emergence of antibiotic resistance. While these antibiotics have saved countless lives, their overuse reduces their efficacy promoting the emergence of multidrug‐resistant (MDR) bacteria. This prompts researchers to explore new alternatives for treating bacteria proliferation. In this context, antibacterial photodynamic therapy (aPDT) has emerged as a promising approach for treating localized infections. It utilizes reactive oxygen species (ROS) as oxidative stress agents, thereby minimizing the risk of developing MDR. The success of aPDT significantly hinges on the careful selection of photosensitizers (PSs) and polymer matrices for the synthesis of polymer‐based photoactive materials. Various light‐absorbing PSs are therefore designed for enhancing ROS production and antimicrobial efficacy. By incorporating PSs into polymer matrices, these materials can harness the light power to generate ROS, destroying bacterial cells upon irradiation. This review aims to provide a comprehensive overview of advancements in this field, specifically focusing on the use of polymer‐based materials. The mechanism of the four main ROS generated in aPDT, the methods used for their detection, and their mode of action against bacteria has been outlined. The recent improvement in polymer‐based aPDT materials and their antibacterial efficacy have been also addressed.

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ROS Defense Systems and Terminal Oxidases in Bacteria

Cited by 75 publications

References 132 publications

Impact of Hydrogen Sulfide on Mitochondrial and Bacterial Bioenergetics

Impact of Hydrogen Sulfide on Mitochondrial and Bacterial Bioenergetics

Proton Pumping and Non-Pumping Terminal Respiratory Oxidases: Active Sites Intermediates of These Molecular Machines and Their Derivatives

Photoactive Dye‐Loaded Polymer Materials: A New Cutting Edge for Antibacterial Photodynamic Therapy

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