1qnm

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==Overview==
==Overview==
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Structural and biochemical characterization of the nonliganding residue, glutamine 143 near the manganese of human Mn superoxide dismutase, (hMnSOD), a homotetramer of 22 kDa, reveals a functional role for this, residue. In the wild-type protein, the side-chain amide group of Gln 143, is about 5 A from the metal and is hydrogen-bonded to Tyr 34, which is a, second prominent side chain adjacent to the metal. We have prepared the, site-specific mutant of hMnSOD with the conservative replacement of Gln, 143 --> Asn (Q143N). The crystal structure of Q143N shows that the, side-chain amide nitrogen of residue 143 is 1.7 A more distant from the, manganese than in the wild-type enzyme. The Tyr 34 side-chain hydroxyl in, Q143N is also moved to become 0.6 A more distant from the metal due to an, additional water molecule. Differential scanning calorimetry showed that, Q143N is slightly more stable than the wild-type enzyme with Tm for the, main unfolding transition increased by 2 degrees C to 90.7 degrees C., Pulse radiolysis and stopped-flow spectrophotometry reveal that unlike, wild-type hMnSOD, which is strongly inhibited by peroxide, Q143N MnSOD, exhibits no product inhibition even at concentrations of O2. - in the, millimolar range, and its catalysis follows Michaelis kinetics with no, evidence of cooperativity. However, the overall catalytic activity of this, mutant was decreased 2-3 orders of magnitude compared with the wild-type, MnSOD, which can account for its lack of product inhibition. Q143N MnSOD, lacked the visible absorption spectrum typical of wild-type Mn(III)SOD., Also, unlike the wild-type Mn(III)SOD, which is electron paramagnetic, resonance (EPR) silent, Q143N MnSOD has a complex EPR spectrum with many, resonances in the region below 2250 G. We conclude that the Gln 143 -->, Asn mutation has increased the reduction potential of manganese to, stabilize Mn(II), indicating that Gln 143 has a substantial role in, maintaining a reduction potential favorable for the oxidation and, reduction cycles in the catalytic disproportionation of superoxide. A, solvent hydrogen isotope effect near 2 for kcat in catalysis by Q143N, hMnSOD indicates rate-contributing proton transfers to form product, hydroperoxide anion or hydrogen peroxide. The data demonstrate a prominent, role for Gln 143 in maintaining the microenvironment of the manganese and, in efficient catalysis of superoxide dismutation to oxygen and hydrogen, peroxide.
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Structural and biochemical characterization of the nonliganding residue glutamine 143 near the manganese of human Mn superoxide dismutase (hMnSOD), a homotetramer of 22 kDa, reveals a functional role for this residue. In the wild-type protein, the side-chain amide group of Gln 143 is about 5 A from the metal and is hydrogen-bonded to Tyr 34, which is a second prominent side chain adjacent to the metal. We have prepared the site-specific mutant of hMnSOD with the conservative replacement of Gln 143 --> Asn (Q143N). The crystal structure of Q143N shows that the side-chain amide nitrogen of residue 143 is 1.7 A more distant from the manganese than in the wild-type enzyme. The Tyr 34 side-chain hydroxyl in Q143N is also moved to become 0.6 A more distant from the metal due to an additional water molecule. Differential scanning calorimetry showed that Q143N is slightly more stable than the wild-type enzyme with Tm for the main unfolding transition increased by 2 degrees C to 90.7 degrees C. Pulse radiolysis and stopped-flow spectrophotometry reveal that unlike wild-type hMnSOD, which is strongly inhibited by peroxide, Q143N MnSOD exhibits no product inhibition even at concentrations of O2. - in the millimolar range, and its catalysis follows Michaelis kinetics with no evidence of cooperativity. However, the overall catalytic activity of this mutant was decreased 2-3 orders of magnitude compared with the wild-type MnSOD, which can account for its lack of product inhibition. Q143N MnSOD lacked the visible absorption spectrum typical of wild-type Mn(III)SOD. Also, unlike the wild-type Mn(III)SOD, which is electron paramagnetic resonance (EPR) silent, Q143N MnSOD has a complex EPR spectrum with many resonances in the region below 2250 G. We conclude that the Gln 143 --> Asn mutation has increased the reduction potential of manganese to stabilize Mn(II), indicating that Gln 143 has a substantial role in maintaining a reduction potential favorable for the oxidation and reduction cycles in the catalytic disproportionation of superoxide. A solvent hydrogen isotope effect near 2 for kcat in catalysis by Q143N hMnSOD indicates rate-contributing proton transfers to form product hydroperoxide anion or hydrogen peroxide. The data demonstrate a prominent role for Gln 143 in maintaining the microenvironment of the manganese and in efficient catalysis of superoxide dismutation to oxygen and hydrogen peroxide.
==About this Structure==
==About this Structure==
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[[Category: Superoxide dismutase]]
[[Category: Superoxide dismutase]]
[[Category: Guan, Y.]]
[[Category: Guan, Y.]]
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[[Category: Tainer, J.A.]]
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[[Category: Tainer, J A.]]
[[Category: MN]]
[[Category: MN]]
[[Category: hmnsod]]
[[Category: hmnsod]]
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[[Category: oxidoreductase]]
[[Category: oxidoreductase]]
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''Page seeded by [http://oca.weizmann.ac.il/oca OCA ] on Thu Feb 21 14:41:50 2008''

Revision as of 12:41, 21 February 2008

Image:1qnm.jpg

1qnm, resolution 2.3Å

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HUMAN MANGANESE SUPEROXIDE DISMUTASE MUTANT Q143N

Overview

Structural and biochemical characterization of the nonliganding residue glutamine 143 near the manganese of human Mn superoxide dismutase (hMnSOD), a homotetramer of 22 kDa, reveals a functional role for this residue. In the wild-type protein, the side-chain amide group of Gln 143 is about 5 A from the metal and is hydrogen-bonded to Tyr 34, which is a second prominent side chain adjacent to the metal. We have prepared the site-specific mutant of hMnSOD with the conservative replacement of Gln 143 --> Asn (Q143N). The crystal structure of Q143N shows that the side-chain amide nitrogen of residue 143 is 1.7 A more distant from the manganese than in the wild-type enzyme. The Tyr 34 side-chain hydroxyl in Q143N is also moved to become 0.6 A more distant from the metal due to an additional water molecule. Differential scanning calorimetry showed that Q143N is slightly more stable than the wild-type enzyme with Tm for the main unfolding transition increased by 2 degrees C to 90.7 degrees C. Pulse radiolysis and stopped-flow spectrophotometry reveal that unlike wild-type hMnSOD, which is strongly inhibited by peroxide, Q143N MnSOD exhibits no product inhibition even at concentrations of O2. - in the millimolar range, and its catalysis follows Michaelis kinetics with no evidence of cooperativity. However, the overall catalytic activity of this mutant was decreased 2-3 orders of magnitude compared with the wild-type MnSOD, which can account for its lack of product inhibition. Q143N MnSOD lacked the visible absorption spectrum typical of wild-type Mn(III)SOD. Also, unlike the wild-type Mn(III)SOD, which is electron paramagnetic resonance (EPR) silent, Q143N MnSOD has a complex EPR spectrum with many resonances in the region below 2250 G. We conclude that the Gln 143 --> Asn mutation has increased the reduction potential of manganese to stabilize Mn(II), indicating that Gln 143 has a substantial role in maintaining a reduction potential favorable for the oxidation and reduction cycles in the catalytic disproportionation of superoxide. A solvent hydrogen isotope effect near 2 for kcat in catalysis by Q143N hMnSOD indicates rate-contributing proton transfers to form product hydroperoxide anion or hydrogen peroxide. The data demonstrate a prominent role for Gln 143 in maintaining the microenvironment of the manganese and in efficient catalysis of superoxide dismutation to oxygen and hydrogen peroxide.

About this Structure

1QNM is a Single protein structure of sequence from Homo sapiens with as ligand. Active as Superoxide dismutase, with EC number 1.15.1.1 Known structural/functional Site: . Full crystallographic information is available from OCA.

Reference

Probing the active site of human manganese superoxide dismutase: the role of glutamine 143., Hsieh Y, Guan Y, Tu C, Bratt PJ, Angerhofer A, Lepock JR, Hickey MJ, Tainer JA, Nick HS, Silverman DN, Biochemistry. 1998 Apr 7;37(14):4731-9. PMID:9537988

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