Engineering oxidative stability in human hemoglobin based on the Hb providence (βK82D) mutation and genetic cross-linking

Michael Brad Strader; Rachel Bangle; Claire J. Parker Siburt; Cornelius L. Varnado; Jayashree Soman; Andres S. Benitez Cardenas; Premila P. Samuel; Eileen W. Singleton; Alvin L. Crumbliss; John S. Olson; Abdu I. Alayash

doi:10.1042/BCJ20170491

Engineering oxidative stability in human hemoglobin based on the Hb providence (βK82D) mutation and genetic cross-linking

Michael Brad Strader
, Rachel Bangle
, Claire J. Parker Siburt
, Cornelius L. Varnado
, Jayashree Soman
, Andres S. Benitez Cardenas
, Premila P. Samuel
, Eileen W. Singleton
, Alvin L. Crumbliss
, John S. Olson
, Abdu I. Alayash

Chemistry

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

Previous work suggested that hemoglobin (Hb) tetramer formation slows autoxidation and hemin loss and that the naturally occurring mutant, Hb Providence (HbProv; βK82D), is much more resistant to degradation by H2O2. We have examined systematically the effects of genetic cross-linking of Hb tetramers with and without the HbProv mutation on autoxidation, hemin loss, and reactions with H2O2, using native HbA and various wildtype recombinant Hbs as controls. Genetically cross-linked Hb Presbyterian (βN108K) was also examined as an example of a low oxygen affinity tetramer. Our conclusions are: (a) at low concentrations, all the cross-linked tetramers show smaller rates of autoxidation and hemin loss than HbA, which can dissociate into much less stable dimers and (b) the HbProv βK82D mutation confers more resistance to degradation by H2O2, by markedly inhibiting oxidation of the β93 cysteine side chain, particularly in cross-linked tetramers and even in the presence of the destabilizing Hb Presbyterian mutation. These results show that cross-linking and the βK82D mutation do enhance the resistance of Hb to oxidative degradation, a critical element in the design of a safe and effective oxygen therapeutic.

Original language	English
Pages (from-to)	4171-4192
Number of pages	22
Journal	Biochemical Journal
Volume	474
Issue number	24
DOIs	https://doi.org/10.1042/BCJ20170491
State	Published - Dec 15 2017

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10.1042/BCJ20170491

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Strader, M. B., Bangle, R., Siburt, C. J. P., Varnado, C. L., Soman, J., Cardenas, A. S. B., Samuel, P. P., Singleton, E. W., Crumbliss, A. L., Olson, J. S., & Alayash, A. I. (2017). Engineering oxidative stability in human hemoglobin based on the Hb providence (βK82D) mutation and genetic cross-linking. Biochemical Journal, 474(24), 4171-4192. https://doi.org/10.1042/BCJ20170491

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title = "Engineering oxidative stability in human hemoglobin based on the Hb providence (βK82D) mutation and genetic cross-linking",

abstract = "Previous work suggested that hemoglobin (Hb) tetramer formation slows autoxidation and hemin loss and that the naturally occurring mutant, Hb Providence (HbProv; βK82D), is much more resistant to degradation by H2O2. We have examined systematically the effects of genetic cross-linking of Hb tetramers with and without the HbProv mutation on autoxidation, hemin loss, and reactions with H2O2, using native HbA and various wildtype recombinant Hbs as controls. Genetically cross-linked Hb Presbyterian (βN108K) was also examined as an example of a low oxygen affinity tetramer. Our conclusions are: (a) at low concentrations, all the cross-linked tetramers show smaller rates of autoxidation and hemin loss than HbA, which can dissociate into much less stable dimers and (b) the HbProv βK82D mutation confers more resistance to degradation by H2O2, by markedly inhibiting oxidation of the β93 cysteine side chain, particularly in cross-linked tetramers and even in the presence of the destabilizing Hb Presbyterian mutation. These results show that cross-linking and the βK82D mutation do enhance the resistance of Hb to oxidative degradation, a critical element in the design of a safe and effective oxygen therapeutic.",

author = "Strader, \{Michael Brad\} and Rachel Bangle and Siburt, \{Claire J. Parker\} and Varnado, \{Cornelius L.\} and Jayashree Soman and Cardenas, \{Andres S. Benitez\} and Samuel, \{Premila P.\} and Singleton, \{Eileen W.\} and Crumbliss, \{Alvin L.\} and Olson, \{John S.\} and Alayash, \{Abdu I.\}",

year = "2017",

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doi = "10.1042/BCJ20170491",

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T1 - Engineering oxidative stability in human hemoglobin based on the Hb providence (βK82D) mutation and genetic cross-linking

AU - Strader, Michael Brad

AU - Bangle, Rachel

AU - Siburt, Claire J. Parker

AU - Varnado, Cornelius L.

AU - Soman, Jayashree

AU - Cardenas, Andres S. Benitez

AU - Samuel, Premila P.

AU - Singleton, Eileen W.

AU - Crumbliss, Alvin L.

AU - Olson, John S.

AU - Alayash, Abdu I.

PY - 2017/12/15

Y1 - 2017/12/15

N2 - Previous work suggested that hemoglobin (Hb) tetramer formation slows autoxidation and hemin loss and that the naturally occurring mutant, Hb Providence (HbProv; βK82D), is much more resistant to degradation by H2O2. We have examined systematically the effects of genetic cross-linking of Hb tetramers with and without the HbProv mutation on autoxidation, hemin loss, and reactions with H2O2, using native HbA and various wildtype recombinant Hbs as controls. Genetically cross-linked Hb Presbyterian (βN108K) was also examined as an example of a low oxygen affinity tetramer. Our conclusions are: (a) at low concentrations, all the cross-linked tetramers show smaller rates of autoxidation and hemin loss than HbA, which can dissociate into much less stable dimers and (b) the HbProv βK82D mutation confers more resistance to degradation by H2O2, by markedly inhibiting oxidation of the β93 cysteine side chain, particularly in cross-linked tetramers and even in the presence of the destabilizing Hb Presbyterian mutation. These results show that cross-linking and the βK82D mutation do enhance the resistance of Hb to oxidative degradation, a critical element in the design of a safe and effective oxygen therapeutic.

AB - Previous work suggested that hemoglobin (Hb) tetramer formation slows autoxidation and hemin loss and that the naturally occurring mutant, Hb Providence (HbProv; βK82D), is much more resistant to degradation by H2O2. We have examined systematically the effects of genetic cross-linking of Hb tetramers with and without the HbProv mutation on autoxidation, hemin loss, and reactions with H2O2, using native HbA and various wildtype recombinant Hbs as controls. Genetically cross-linked Hb Presbyterian (βN108K) was also examined as an example of a low oxygen affinity tetramer. Our conclusions are: (a) at low concentrations, all the cross-linked tetramers show smaller rates of autoxidation and hemin loss than HbA, which can dissociate into much less stable dimers and (b) the HbProv βK82D mutation confers more resistance to degradation by H2O2, by markedly inhibiting oxidation of the β93 cysteine side chain, particularly in cross-linked tetramers and even in the presence of the destabilizing Hb Presbyterian mutation. These results show that cross-linking and the βK82D mutation do enhance the resistance of Hb to oxidative degradation, a critical element in the design of a safe and effective oxygen therapeutic.

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Engineering oxidative stability in human hemoglobin based on the Hb providence (βK82D) mutation and genetic cross-linking

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