Metal Binding Studies and EPR Spectroscopy of the Manganese Transport Regulator MntR

Golynskiy, Misha; Gunderson, William A.; Hendrich, Michael P.; Cohen, Seth M.

doi:10.1021/bi0607406

Cited by 96 publications

(126 citation statements)

References 67 publications

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“…The new EPR methodology presented herein will also be useful for the analysis of EPR spectra from other dinuclear Mn metalloenzymes, for example, the 3′-5′ exonuclease DNA proofreading activity from Escherichia coli ( Figure S1, Supporting Information), 58 the glycerophophodiesterase GpdQ from Enterobacter aerogenase, 33 and the manganese transport regulator protein from Bacillus subtilis. 59 …”

Section: Discussionmentioning

confidence: 99%

Metal-Ion Mutagenesis: Conversion of a Purple Acid Phosphatase from Sweet Potato to a Neutral Phosphatase with the Formation of an Unprecedented Catalytically Competent Mn^IIMn^II Active Site

et al. 2009

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Abstract:The currently accepted paradigm is that the purple acid phosphatases (PAPs) require a heterovalent, dinuclear metal-ion center for catalysis. It is believed that this is an essential feature for these enzymes in order for them to operate under acidic conditions. A PAP from sweet potato is unusual in that it appears to have a specific requirement for manganese, forming a unique Fe III -µ-(O)-Mn II center under catalytically optimal conditions (Schenk et al. Proc. Natl. Acad. Sci. U.S.A. 2005, 102, 273). Herein, we demonstrate, with detailed electron paramagnetic resonance (EPR) spectroscopic and kinetic studies, that in this enzyme the chromophoric Fe III can be replaced by Mn II , forming a catalytically active, unprecedented antiferromagnetically coupled homodivalent Mn II -µ-(H)OH-µ-carboxylato-Mn II center in a PAP. However, although the enzyme is still active, it no longer functions as an acid phosphatase, having optimal activity at neutral pH. Thus, PAPs may have evolved from distantly related divalent dinuclear metallohydrolases that operate under pH neutral conditions by stabilization of a trivalent-divalent metal-ion core. The present Mn II -Mn II system models these distant relatives, and the results herein make a significant contribution to our understanding of the role of the chromophoric metal ion as an activator of the nucleophile. In addition, the detailed analysis of strain broadened EPR spectra from exchange-coupled dinuclear Mn II -Mn II centers described herein provides the basis for the full interpretation of the EPR spectra from other dinuclear Mn metalloenzymes.

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Section: Discussionmentioning

confidence: 99%

Metal-Ion Mutagenesis: Conversion of a Purple Acid Phosphatase from Sweet Potato to a Neutral Phosphatase with the Formation of an Unprecedented Catalytically Competent Mn^IIMn^II Active Site

et al. 2009

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“…The fluorescent dye mag-fura-2 (MF-2) (Invitrogen) was used to analyze the metal binding affinities of AztD for manganese and zinc as described previously (29). All fluorescence measurements were made using a Varian Cary Eclipse fluorescence spectrophotometer with entrance and exit slits set to 10 nm.…”

Section: Methodsmentioning

confidence: 99%

“…All fluorescence measurements were made using a Varian Cary Eclipse fluorescence spectrophotometer with entrance and exit slits set to 10 nm. Protein concentration was measured before each experiment, and MF-2 concentration was determined using an extinction coefficient at 369 nm of 22,000 M Ϫ1 cm Ϫ1 (29). In each experiment, 15.0 M apo-AztD and 0.5 M MF-2 were titrated with increasing concentrations of MnCl 2 or ZnSO 2 , keeping the total volume of titrant added to less than 10%.…”

Section: Methodsmentioning

confidence: 99%

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AztD, a Periplasmic Zinc Metallochaperone to an ATP-binding Cassette (ABC) Transporter System in Paracoccus denitrificans

Handali¹,

Roychowdhury²,

Neupane

et al. 2015

Journal of Biological Chemistry

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“…Although Fura2 was originally designed as a molecular sensor for Ca(II), this chelator has also been used for determining the affinity of several proteins for various transition metals including Co(II) (36,37). The chelator forms a 1:1 complex with Co(II) that can be detected by the decrease in absorbance at 368 nm.…”

Section: Co(ii) Binding To Slydmentioning

confidence: 99%

Metal Selectivity of the Escherichia coli Nickel Metallochaperone, SlyD

et al. 2011

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SlyD is a Ni(II)-binding protein that contributes to nickel homeostasis in Escherichia coli. The Cterminal domain of SlyD contains a rich variety of metal-binding amino acids, suggesting broader metal-binding capabilities, and previous work demonstrated that the protein can coordinate several types of first row transition metals. However, the binding of SlyD to metals other than Ni(II) has not been previously characterized. To further our understanding of the in vitro metal-binding activity of SlyD and how it correlates with the in vivo function of this protein, the interactions between SlyD and the series of biologically relevant transition metals Mn(II), Fe(II), Co(II), Cu(I) and Zn(II) were examined by using a combination of optical spectroscopy and mass spectrometry. Tables S1-S3 containing a summary of metal concentrations used for metal toxicity studies, a list of primers used for qRT-PCR analysis and summary of Mn(II), Co(II) and Ni(II) stoichiometries of SlyD; Figure S2 shows representative spectra of a Ni(II) titrations analyzed via ESI-MS; Figures S3-S4 shows a graphical representation of the PAR competition assay used for determining the average K D (Zn(II)-SlyD) and a comparison of CD spectra for Ni(II) and Zn(II) bound SlyD. Figure S5 is a representative data set for a Cu(I) titration of SlyD analyzed via electronic absorption spectroscopy. Figure S6-S7 are competition titrations with Bca and Bcs used for determining copper stoichiometry and affinity, respectively. Figure S8-S10 are a graphical representation of Co(II) titrations analyzed via ESI-MS, competition titrations with Fura2 for determining average K D (Co(II)-SlyD) and titration of a cobalt saturated SlyD sample with Zn(II). Figure S11 is spectroscopy data obtained for titration of Ni(II) compared with a similar titration carried out in the presence of excess Fe(II). Figure S12 depicts representative growth curves of WT and ΔslyD strains conducted in minimal media supplemented with various amounts of metal. Figure S13 is relative mRNA levels measured for various metal transporters under aerobic conditions. Figure S14-S15 are relative mRNA levels measured for various metal transporters under anaerobic conditions. This material is available free of charge via the Internet at http://pubs.acs.org.

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Metal Binding Studies and EPR Spectroscopy of the Manganese Transport Regulator MntR

Cited by 96 publications

References 67 publications

Metal-Ion Mutagenesis: Conversion of a Purple Acid Phosphatase from Sweet Potato to a Neutral Phosphatase with the Formation of an Unprecedented Catalytically Competent Mn^IIMn^II Active Site

Metal-Ion Mutagenesis: Conversion of a Purple Acid Phosphatase from Sweet Potato to a Neutral Phosphatase with the Formation of an Unprecedented Catalytically Competent Mn^IIMn^II Active Site

AztD, a Periplasmic Zinc Metallochaperone to an ATP-binding Cassette (ABC) Transporter System in Paracoccus denitrificans

Metal Selectivity of the Escherichia coli Nickel Metallochaperone, SlyD

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Metal Binding Studies and EPR Spectroscopy of the Manganese Transport Regulator MntR

Cited by 96 publications

References 67 publications

Metal-Ion Mutagenesis: Conversion of a Purple Acid Phosphatase from Sweet Potato to a Neutral Phosphatase with the Formation of an Unprecedented Catalytically Competent MnIIMnII Active Site

Metal-Ion Mutagenesis: Conversion of a Purple Acid Phosphatase from Sweet Potato to a Neutral Phosphatase with the Formation of an Unprecedented Catalytically Competent MnIIMnII Active Site

AztD, a Periplasmic Zinc Metallochaperone to an ATP-binding Cassette (ABC) Transporter System in Paracoccus denitrificans

Metal Selectivity of the Escherichia coli Nickel Metallochaperone, SlyD

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Metal-Ion Mutagenesis: Conversion of a Purple Acid Phosphatase from Sweet Potato to a Neutral Phosphatase with the Formation of an Unprecedented Catalytically Competent Mn^IIMn^II Active Site

Metal-Ion Mutagenesis: Conversion of a Purple Acid Phosphatase from Sweet Potato to a Neutral Phosphatase with the Formation of an Unprecedented Catalytically Competent Mn^IIMn^II Active Site