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1. Manganese Is Required for the Rapid Recovery of DNA Synthesis following Oxidative Challenge in Escherichia coli

   https://doi.org/10.1128/JB.00426-19  

   Hutfilz, Corinne R.; Wang, Natalie E.; Hoff, Chettar A.; Lee, Jessica A.; Hackert, Brandy J.; Courcelle, Justin; Courcelle, Charmain T.; Metcalf, William W. (December 2019, Journal of Bacteriology)

   ABSTRACT Divalent metals such as iron and manganese play an important role in the cellular response to oxidative challenges and are required as cofactors by many enzymes. However, how these metals affect replication after oxidative challenge is not known. Here, we show that replication in Escherichia coli is inhibited following a challenge with hydrogen peroxide and requires manganese for the rapid recovery of DNA synthesis. We show that the manganese-dependent recovery of DNA synthesis occurs independent of lesion repair, modestly improves cell survival, and is associated with elevated rates of mutagenesis. The Mn-dependent mutagenesis involves both replicative and translesion polymerases and requires prior disruption by H 2 O 2 to occur. Taking these findings together, we propose that replication in E. coli is likely to utilize an iron-dependent enzyme(s) that becomes oxidized and inactivated during oxidative challenges. The data suggest that manganese remetallates these or alternative enzymes to allow genomic DNA replication to resume, although with reduced fidelity. IMPORTANCE Iron and manganese play important roles in how cell’s cope with oxygen stress. However, how these metals affect the ability of cells to replicate after oxidative challenges is not known. Here, we show that replication in Escherichia coli is inhibited following a challenge with hydrogen peroxide and requires manganese for the rapid recovery of DNA synthesis. The manganese-dependent recovery of DNA synthesis occurs independently of lesion repair and modestly improves survival, but it also increases the mutation rate in cells. The results imply that replication in E. coli is likely to utilize an iron-dependent enzyme(s) that becomes oxidized and inactivated during oxidative challenges. We propose that manganese remetallates these or alternative enzymes to allow genomic DNA replication to resume, although with reduced fidelity. 

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2. Manganese transporters regulate the resumption of replication in hydrogen peroxide-stressed Escherichia coli

   https://doi.org/10.1007/s10534-023-00523-8  

   Wang, Natalie E.; Courcelle, Eleanor J.; Coltman, Samantha M.; Spolek, Raymond L.; Courcelle, Justin; Courcelle, Charmain T. (July 2023, BioMetals)

   Following hydrogen peroxide treatment, ferrous iron (Fe2+) is oxidized to its ferric form (Fe3+), stripping it from and inactivating iron-containing proteins. Many mononuclear iron enzymes can be remetallated by manganese to restore function, while other enzymes specifically utilize manganese as a cofactor, having redundant activities that compensate for iron-depleted counterparts. DNA replication relies on one or more iron-dependent protein(s) as synthesis abates in the presence of hydrogen peroxide and requires manganese in the medium to resume. Here, we show that manganese transporters regulate the ability to resume replication following oxidative challenge in Escherichia coli. The absence of the primary manganese importer, MntH, impairs the ability to resume replication; whereas deleting the manganese exporter, MntP, or transporter regulator, MntR, dramatically increases the rate of recovery. Unregulated manganese import promoted recovery even in the absence of Fur, which maintains iron homeostasis. Similarly, replication was not restored in oxyR mutants, which cannot upregulate manganese import following hydrogen peroxide stress. Taken together, the results define a central role for manganese transport in restoring replication following oxidative stress. 

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3. Biochemical changes and phytoextraction potential of quinoa and wheat for their resilience to salt stress

   https://doi.org/10.1038/s41598-025-17012-2  

   Hosseini, Sepideh; Moogouei, Roxana; Teymoori, Shahla; Moogouei, Roshanak; Borghei, Mehdi; Latinwo, Ololade; Katam, Keyura (December 2025, Scientific Reports)

   Phytoextraction presents a promising alternative for desalinating saline environments. Our study investigated the phytoremediation efficiency and ion uptake mechanisms of Chenopodium quinoa (Quinoa) and Triticum aestivum (wheat) in response to salt stress. The plants were subjected to NaCl-induced salinity levels of 5, 10, and 15 dS m⁻1 in a hydroponic system, and we measured the remediation efficiency for sodium, potassium, calcium, magnesium, and chloride ions. The solutions incubated with wheat plants exhibited higher ion concentrations than those with quinoa. Chenopodium showed significantly higher bioaccumulation of ions (Mg2⁺, Ca2⁺, Na⁺, Cl⁻, K⁺) in its roots and leaves compared to Triticum. Chenopodium demonstrated greater ion uptake efficiency than Triticum. Under control conditions, both plants effectively contributed to desalination, as indicated by their translocation factor values. In contrast, Chenopodium showed higher TF under salt stress than Triticum for the measured ions. Salinity did not significantly affect potassium accumulation in quinoa shoots, which helped maintain membrane integrity compared to wheat. The analysis of the oxidative status revealed that wheat accumulated higher levels of hydrogen peroxide and lipid peroxidation, especially in the roots. The activities of antioxidative enzymes superoxide dismutase, peroxidase, catalase, ascorbic peroxidase, and glutathione reductase showed a significant increase in the roots and leaves of Chenopodium under salt stress, providing essential protection against reactive oxygen species and lipid peroxidation. Additionally, the increase in leaf area and dry weight in quinoa indicates a more significant accumulation of ions at higher concentrations, demonstrating its superior phytoremediation efficiency compared to wheat 

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4. Naphthoquinones Oxidize H2S to Polysulfides and Thiosulfate, Implications for Therapeutic Applications

   https://doi.org/10.3390/ijms232113293  

   Olson, Kenneth R.; Clear, Kasey J.; Derry, Paul J.; Gao, Yan; Ma, Zhilin; Cieplik, Nathaniel M.; Fiume, Alyssa; Gaziano, Dominic J.; Kasko, Stephen M.; Narloch, Kathleen; et al (November 2022, International Journal of Molecular Sciences)

   1,4-Napththoquinones (NQs) are clinically relevant therapeutics that affect cell function through production of reactive oxygen species (ROS) and formation of adducts with regulatory protein thiols. Reactive sulfur species (RSS) are chemically and biologically similar to ROS and here we examine RSS production by NQ oxidation of hydrogen sulfide (H2S) using RSS-specific fluorophores, liquid chromatography-mass spectrometry, UV-Vis absorption spectrometry, oxygen-sensitive optodes, thiosulfate-specific nanoparticles, HPLC-monobromobimane derivatization, and ion chromatographic assays. We show that NQs, catalytically oxidize H2S to per- and polysulfides (H2Sn, n = 2–6), thiosulfate, sulfite and sulfate in reactions that consume oxygen and are accelerated by superoxide dismutase (SOD) and inhibited by catalase. The approximate efficacy of NQs (in decreasing order) is, 1,4-NQ ≈ juglone ≈ plumbagin > 2-methoxy-1,4-NQ ≈ menadione >> phylloquinone ≈ anthraquinone ≈ menaquinone ≈ lawsone. We propose that the most probable reactions are an initial two-electron oxidation of H2S to S0 and reduction of NQ to NQH2. S0 may react with H2S or elongate H2Sn in variety of reactions. Reoxidation of NQH2 likely involves a semiquinone radical (NQ·−) intermediate via several mechanisms involving oxygen and comproportionation to produce NQ and superoxide. Dismutation of the latter forms hydrogen peroxide which then further oxidizes RSS to sulfoxides. These findings provide the chemical background for novel sulfur-based approaches to naphthoquinone-directed therapies. 

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5. Caenorhabditis elegans processes sensory information to choose between freeloading and self-defense strategies

   https://doi.org/10.7554/eLife.56186  

   Schiffer, Jodie A; Servello, Francesco A; Heath, William R; Amrit, Francis Raj; Stumbur, Stephanie V; Eder, Matthias; Martin, Olivier MF; Johnsen, Sean B; Stanley, Julian A; Tam, Hannah; et al (May 2020, eLife)

   null (Ed.)

   Cells of all kinds often wage chemical warfare against each other. Hydrogen peroxide is often the weapon of choice on the microscopic battlefield, where it is used to incapacitate opponents or to defend against attackers. For example, some plants produce hydrogen peroxide in response to infection to fight off disease-causing microbes. Individual cells have also evolved defenses to prevent or repair ‘injuries’ caused by hydrogen peroxide. These are similar across many different species. They include enzymes called catalases, which break down hydrogen peroxide, and others to repair damage. However, scientists still do not fully understand how animals and other multicellular organisms might coordinate these defenses across their cells. Caenorhabditis elegans is a microscopic species of worm that lives in rotting fruits. It often encounters the threat of cellular warfare: many types of bacteria in its environment generate hydrogen peroxide, and some can make enough to kill the worms outright. Like other organisms, C. elegans also produces catalases to defend itself against hydrogen peroxide attacks. However, it must activate its defenses at the right time; if it did so when they were not needed, this would result in a detrimental energy ‘cost’ to the worm. Although C. elegans is a small organism containing only a defined number of cells, exactly why and how it switches its chemical defenses on or off remains unknown. Schiffer et al. therefore set out to determine how C. elegans controls these defenses, focusing on the role of the brain in detecting and processing information from its environment. Experiments looking at the brains of genetically manipulated worms revealed a circuit of sensory nerve cells whose job is to tell the rest of the worm’s tissues that they no longer need to produce defense enzymes. Crucially, the circuit became active when the worms sensed E. coli bacteria nearby. Bacteria in the same family as E. coli are normally found in in the same habitat as C. elegans and these bacteria are also known to make enzymes of their own to eliminate hydrogen peroxide around them. These results indicate that C. elegans can effectively decide, based on the activity of its circuit, when to use its own defenses and when to ‘freeload’ off those of neighboring bacteria. This work is an important step towards understanding how sensory circuits in the brain can control hydrogen peroxide defenses in multicellular organisms. In the future, it could help researchers work out how more complex animals, like humans, coordinate their cellular defenses, and therefore potentially yield new strategies for improving health and longevity. 

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