Probing in vivo Mn<sup>2+</sup>speciation and oxidative stress resistance in yeast cells with electron-nuclear double resonance spectroscopy

McNaughton, Rebecca L.; Reddi, Amit R.; Clement, Matthew H. S.; Sharma, Ajay; Barnese, Kevin; Rosenfeld, Leah; Gralla, Edith Butler; Valentine, Joan Selverstone; Culotta, Valeria C.; Hoffman, Brian M.

doi:10.1073/pnas.1009648107

Cited by 109 publications

(152 citation statements)

References 41 publications

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“…Phosphate signaling through Pho4p is not responsible for the aerobic lethality of sod1D pho80D mutants A loss of phosphate control in S. cerevisiae through disruption of PHO80 or PHO85 renders sod1Δ cells inviable in air and unable to effectively utilize Mn for oxidative stress suppression (Reddi et al 2009;McNaughton et al 2010;Rosenfeld et al 2010). As seen in Figure 1A, Mn supplements to the growth medium only partly restore aerobic growth to a sod1Δ pho80Δ double mutant.…”

Section: Resultsmentioning

confidence: 87%

“…A number of Mn-carboxylato complexes (Archibald and Fridovich 1982b), as well as Mn-orthophosphate (Pi) (Barnese et al 2008), have been shown to exhibit superoxide scavenging activity in vitro, and the extreme radioresistance of Deinococcus radiodurans is associated with certain Mn-Pi and -peptide complexes (Daly et al 2010). Moreover, our in vivo studies in the Baker's yeast have demonstrated a role for Mn-Pi as an important backup for Cu/Zn containing SOD (SOD1) (McNaughton et al 2010).…”

mentioning

confidence: 96%

“…Deletion of either pho80 or pho85 rendered sod1Δ mutants lacking Cu/Zn SOD1 inviable in air and cells seemed nearly devoid of Mn antioxidant protection (Reddi et al 2009). By ENDOR spectroscopy, Mn-Pi levels were lowered in this strain (McNaughton et al 2010), although not to a degree expected for the profound oxygen toxicity observed. Ablation of Pho80/Pho85p inhibited Mn antioxidant activity through a mechanism other than simple loss of Mn-Pi.…”

mentioning

confidence: 97%

“…Using ENDOR spectroscopy to monitor Mn speciation in intact yeast cells, we observed a close correlation between the cellular level of Mn-Pi in various yeast strains and their resistance to oxygen toxicity (McNaughton et al 2010;Szuromi 2010). Of the strains tested, the most severe oxygen toxicity was observed when phosphate control was disrupted through mutations in the phosphate-sensing kinase complex Pho80p/ Pho85p (Kaneko et al 1982;Ogawa et al 2000;Wykoff and O'shea 2001;Carroll and O'shea 2002;Lee et al 2007;Wykoff et al 2007).…”

mentioning

confidence: 98%

“…Total cellular phosphates (orthophosphate and polyphosphates) were measured using the molybdate reactivity method (Ames 1966;Reddi et al 2009;McNaughton et al 2010). Cells were lysed by glass bead homogenization in 500 ml of 0.1% Triton X-100.…”

Section: Biochemical Assaysmentioning

confidence: 99%

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Regulation of Manganese Antioxidants by Nutrient Sensing Pathways in Saccharomyces cerevisiae

Reddi

Culotta

2011

Genetics

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In aerobic organisms, protection from oxidative damage involves the combined action of enzymatic and nonproteinaceous cellular factors that collectively remove harmful reactive oxygen species. One class of nonproteinaceous antioxidants includes small molecule complexes of manganese (Mn) that can scavenge superoxide anion radicals and provide a backup for superoxide dismutase enzymes. Such Mn antioxidants have been identified in diverse organisms; however, nothing regarding their physiology in the context of cellular adaptation to stress was known. Using a molecular genetic approach in Bakers' yeast, Saccharomyces cerevisiae, we report that the Mn antioxidants can fall under control of the same pathways used for nutrient sensing and stress responses. Specifically, a serine/threonine PASkinase, Rim15p, that is known to integrate phosphate, nitrogen, and carbon sensing, can also control Mn antioxidant activity in yeast. Rim15p is negatively regulated by the phosphate-sensing kinase complex Pho80p/Pho85p and by the nitrogen-sensing Akt/S6 kinase homolog, Sch9p. We observed that loss of either of these upstream kinase sensors dramatically inhibited the potency of Mn as an antioxidant. Downstream of Rim15p are transcription factors Gis1p and the redundant Msn2/Msn4p pair that typically respond to nutrient and stress signals. Both transcription factors were found to modulate the potency of the Mn antioxidant but in opposing fashions: loss of Gis1p was seen to enhance Mn antioxidant activity whereas loss of Msn2/4p greatly suppressed it. Our observed roles for nutrient and stress response kinases and transcription factors in regulating the Mn antioxidant underscore its physiological importance in aerobic fitness.

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Section: Resultsmentioning

confidence: 87%

mentioning

confidence: 96%

mentioning

confidence: 97%

mentioning

confidence: 98%

Section: Biochemical Assaysmentioning

confidence: 99%

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Regulation of Manganese Antioxidants by Nutrient Sensing Pathways in Saccharomyces cerevisiae

Reddi

Culotta

2011

Genetics

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Assembly of Dimanganese and Heterometallic Manganese Proteins

Berggren

Lundin

Sjöberg

2017

Encyclopedia of Inorganic and Bioinorganic Chemistry

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Manganese is an essential trace element in all domains of life, and manganese‐dependent enzymes catalyze a wide range of reactions including hydrolysis, phosphorylation, water oxidation, nucleotide reduction, and protection against oxidative stress. Dinuclear manganese‐containing cofactors are both homonuclear and heteronuclear centers. Due to its rich redox chemistry, manganese is found in a number of redox‐active enzymes, where the oxidation state of the metal ion ranges from Mn II to Mn IV . Non‐redox‐active metal sites are found in, for example, sweet potato purple acid phosphatase (Mn II Fe III ), concanavalin A (Mn II Ca II ), arginase (Mn II 2 ), and prolidase (Mn II 2 ). Proteins with redox‐active Mn‐containing dinuclear centers generally belong to the ferritin‐like superfamily. Whereas most members of the superfamily have an Fe 2 center, Mn‐containing metal sites are found in Mn catalase (Mn 2 ), some RNR β subunits (subclasses Ib and Id have Mn 2 , and subclass Ic has MnFe), and R2lox (MnFe). In addition, a member of DNA‐binding protein from starved cells ( Dps ) can form an MnFe center. No manganese chaperones are known and Mn‐dependent enzymes plausibly acquire their metals directly from the intracellular pool of Mn 2+ , which is balanced via different import and efflux transporter systems: Mn catalase catalyzes the disproportionation of the reactive species hydrogen peroxide by alternating between Mn III 2 and Mn II 2 in two consecutive reactions, detoxifying two hydrogen peroxide molecules to oxygen and water. RNR subclass Ib β subunit has an oxidized metal center and a tyrosyl radical. It initially binds Mn 2+ and forms a complex with a specific flavodoxin‐like protein that oxidizes the metal center to a transient Mn IV/III species, which converts to the active Mn III 2 ‐Tyr • cofactor. RNR subclass Ic β subunit has an Mn IV Fe III cofactor. It is formed by O 2 oxidation of a Mn II Fe II center, and the initial transient Mn IV Fe IV center is reduced to the active cofactor via an external electron transfer pathway. RNR subclass Id β subunit is suggested to contain an oxidized Mn 2 center formed in the absence of a flavodoxin‐like maturase and lacks the tyrosyl radical. R2‐like ligand‐binding oxidase (R2lox) has an Mn III Fe III cofactor that is generated from Mn II Fe II by O 2 oxidation. It is assumed that an Mn IV Fe IV intermediate generates a valine–tyrosine cross‐link adjacent to the metal site. Despite the apparent simplicity of manganese cofactor assembly, nature has developed a number of different methods to control the metalation of manganese proteins and activate the relatively redox‐inert Mn II ion.

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Living Cells Directly Growing on a DNA/Mn₃(PO₄)₂‐Immobilized and Vertically Aligned CNT Array as a Free‐Standing Hybrid Film for Highly Sensitive In Situ Detection of Released Superoxide Anions

Kang

et al. 2015

Adv Funct Materials

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It is important to detect reactive oxygen species (ROS) in situ for investigation of various critical biological processes, and this is however very challenging because of the limited sensitivity or/and selectivity of existing methods that are mainly based on sensing ROS released by cells with short lifetimes and low concentrations in a culture medium. Here, a new approach is reported to directly grow living cells on DNA/Mn3(PO4)2‐immobilized and vertically aligned carbon nanotube (VACNT) array nanostructure as a smart free‐standing hybrid film, of which the DNA/Mn3(PO4)2 and VACNT provide high electroactivity and excellent electron transport, respectively, while the directly grown cell on the nanostructure offers short diffusion distance to reaction sites, thus constructing a highly sensitive in situ method for detection of cancer‐cell‐released ROS under drug stimulations. Compared to the measured ROS released by cells in a culture medium, the detection sensitivity with this constructed hybrid film increases by more than six times, which implies that ROS molecules (superoxide anions) secreted from living cells are immediately captured by this smart structure without diffusion process or with extremely short diffusion distance. This design considerably reduces the time from release to detection of the target molecules, minimizing the potential molecular decay due to the short lifetime or high reactivity.

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Probing in vivo Mn²⁺speciation and oxidative stress resistance in yeast cells with electron-nuclear double resonance spectroscopy

Cited by 109 publications

References 41 publications

Regulation of Manganese Antioxidants by Nutrient Sensing Pathways in Saccharomyces cerevisiae

Regulation of Manganese Antioxidants by Nutrient Sensing Pathways in Saccharomyces cerevisiae

Assembly of Dimanganese and Heterometallic Manganese Proteins

Living Cells Directly Growing on a DNA/Mn₃(PO₄)₂‐Immobilized and Vertically Aligned CNT Array as a Free‐Standing Hybrid Film for Highly Sensitive In Situ Detection of Released Superoxide Anions

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Probing in vivo Mn2+speciation and oxidative stress resistance in yeast cells with electron-nuclear double resonance spectroscopy

Cited by 109 publications

References 41 publications

Regulation of Manganese Antioxidants by Nutrient Sensing Pathways in Saccharomyces cerevisiae

Regulation of Manganese Antioxidants by Nutrient Sensing Pathways in Saccharomyces cerevisiae

Assembly of Dimanganese and Heterometallic Manganese Proteins

Living Cells Directly Growing on a DNA/Mn3(PO4)2‐Immobilized and Vertically Aligned CNT Array as a Free‐Standing Hybrid Film for Highly Sensitive In Situ Detection of Released Superoxide Anions

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Resources

About

Probing in vivo Mn²⁺speciation and oxidative stress resistance in yeast cells with electron-nuclear double resonance spectroscopy

Living Cells Directly Growing on a DNA/Mn₃(PO₄)₂‐Immobilized and Vertically Aligned CNT Array as a Free‐Standing Hybrid Film for Highly Sensitive In Situ Detection of Released Superoxide Anions