Your search keyword '"Khairallah, George N."' showing total 5 results

1. Radical formation in the gas-phase ozonolysis of deprotonated cysteine

Author

Khairallah, George N, Maccarone, Alan T, Pham, Huong T, Benton, Timothy M, Ly, Tony, da Silva, Gabriel, Blanksby, Stephen J, O'Hair, Richard A. J, Khairallah, George N, Maccarone, Alan T, Pham, Huong T, Benton, Timothy M, Ly, Tony, da Silva, Gabriel, Blanksby, Stephen J, and O'Hair, Richard A. J

Abstract

Although the deleterious effects of ozone on the human respiratory system are well-known, many of the precise chemical mechanisms that both cause damage and afford protection in the pulmonary epithelial lining fluid are poorly understood. As a key first step to elucidating the intrinsic reactivity of ozone with proteins, its reactions with deprotonated cysteine [Cys−H]− are examined in the gas phase. Reaction proceeds at near the collision limit to give a rich set of products including 1) sequential oxygen atom abstraction reactions to yield cysteine sulfenate, sulfinate and sulfonate anions, and significantly 2) sulfenate radical anions formed by ejection of a hydroperoxy radical. The free-radical pathway occurs only when both thiol and carboxylate moieties are available, implicating electron-transfer as a key step in this reaction. This novel and facile reaction is also observed in small cys-containing peptides indicating a possible role for this chemistry in protein ozonolysis.

Published

2015

2. Radical formation in the gas-phase ozonolysis of deprotonated cysteine

Author

Khairallah, George N, Maccarone, Alan T, Pham, Huong T, Benton, Timothy M, Ly, Tony, da Silva, Gabriel, Blanksby, Stephen J, O'Hair, Richard A. J, Khairallah, George N, Maccarone, Alan T, Pham, Huong T, Benton, Timothy M, Ly, Tony, da Silva, Gabriel, Blanksby, Stephen J, and O'Hair, Richard A. J

Abstract

Although the deleterious effects of ozone on the human respiratory system are well-known, many of the precise chemical mechanisms that both cause damage and afford protection in the pulmonary epithelial lining fluid are poorly understood. As a key first step to elucidating the intrinsic reactivity of ozone with proteins, its reactions with deprotonated cysteine [Cys−H]− are examined in the gas phase. Reaction proceeds at near the collision limit to give a rich set of products including 1) sequential oxygen atom abstraction reactions to yield cysteine sulfenate, sulfinate and sulfonate anions, and significantly 2) sulfenate radical anions formed by ejection of a hydroperoxy radical. The free-radical pathway occurs only when both thiol and carboxylate moieties are available, implicating electron-transfer as a key step in this reaction. This novel and facile reaction is also observed in small cys-containing peptides indicating a possible role for this chemistry in protein ozonolysis.

Published

2015

3. Radical formation in the gas-phase ozonolysis of deprotonated cysteine

Author

Khairallah, George N, Maccarone, Alan T, Pham, Huong T, Benton, Timothy M, Ly, Tony, da Silva, Gabriel, Blanksby, Stephen J, O'Hair, Richard A. J, Khairallah, George N, Maccarone, Alan T, Pham, Huong T, Benton, Timothy M, Ly, Tony, da Silva, Gabriel, Blanksby, Stephen J, and O'Hair, Richard A. J

Abstract

Although the deleterious effects of ozone on the human respiratory system are well-known, many of the precise chemical mechanisms that both cause damage and afford protection in the pulmonary epithelial lining fluid are poorly understood. As a key first step to elucidating the intrinsic reactivity of ozone with proteins, its reactions with deprotonated cysteine [Cys−H]− are examined in the gas phase. Reaction proceeds at near the collision limit to give a rich set of products including 1) sequential oxygen atom abstraction reactions to yield cysteine sulfenate, sulfinate and sulfonate anions, and significantly 2) sulfenate radical anions formed by ejection of a hydroperoxy radical. The free-radical pathway occurs only when both thiol and carboxylate moieties are available, implicating electron-transfer as a key step in this reaction. This novel and facile reaction is also observed in small cys-containing peptides indicating a possible role for this chemistry in protein ozonolysis.

Published

2015

4. Synthesis, Structural Elucidation, And Biochemical Analysis of Immunoactive Glucuronosyl Diacylglycerides of Mycobacteria and Corynebacteria

Author

Cao, Benjamin, Chen, Xingqiang, Yamaryo-Botte, Yoshiki, Richardson, Mark B, Martin, Kirstee L, Khairallah, George N, Rupasinghe, Thusita W T, O'Flaherty, Roisin, O'Hair, Richard A J, Ralton, Julie E, Crellin, Paul K, Coppel, Ross L, McConville, Malcolm J, Williams, Spencer J, Cao, Benjamin, Chen, Xingqiang, Yamaryo-Botte, Yoshiki, Richardson, Mark B, Martin, Kirstee L, Khairallah, George N, Rupasinghe, Thusita W T, O'Flaherty, Roisin, O'Hair, Richard A J, Ralton, Julie E, Crellin, Paul K, Coppel, Ross L, McConville, Malcolm J, and Williams, Spencer J

Abstract

Glucuronosyl diacylglycerides (GlcAGroAc2) are functionally important glycolipids and membrane anchors for cell wall lipoglycans in the Corynebacteria. Here we describe the complete synthesis of distinct acyl-isoforms of GlcAGroAc2 bearing both acylation patterns of (R)-tuberculostearic acid (C19:0) and palmitic acid (C16:0) and their mass spectral characterization. Collision-induced fragmentation mass spectrometry identified characteristic fragment ions that were used to develop “rules” allowing the assignment of the acylation pattern as C19:0 (sn-1), C16:0 (sn-2) in the natural product from Mycobacterium smegmatis, and the structural assignment of related C18:1 (sn-1), C16:0 (sn-2) GlcAGroAc2 glycolipids from M. smegmatis and Corynebacterium glutamicum. A synthetic hydrophobic octyl glucuronoside was used to characterize the GDP-mannose-dependent mannosyltransferase MgtA from C. glutamicum that extends GlcAGroAc2. This enzyme is an Mg2+/Mn2+-dependent metalloenzyme that undergoes dramatic activation upon reduction with dithiothreitol.

Published

2013

5. Synthesis, Structural Elucidation, And Biochemical Analysis of Immunoactive Glucuronosyl Diacylglycerides of Mycobacteria and Corynebacteria

Author

Cao, Benjamin, Chen, Xingqiang, Yamaryo-Botte, Yoshiki, Richardson, Mark B, Martin, Kirstee L, Khairallah, George N, Rupasinghe, Thusita W T, O'Flaherty, Roisin, O'Hair, Richard A J, Ralton, Julie E, Crellin, Paul K, Coppel, Ross L, McConville, Malcolm J, Williams, Spencer J, Cao, Benjamin, Chen, Xingqiang, Yamaryo-Botte, Yoshiki, Richardson, Mark B, Martin, Kirstee L, Khairallah, George N, Rupasinghe, Thusita W T, O'Flaherty, Roisin, O'Hair, Richard A J, Ralton, Julie E, Crellin, Paul K, Coppel, Ross L, McConville, Malcolm J, and Williams, Spencer J

Abstract

Glucuronosyl diacylglycerides (GlcAGroAc2) are functionally important glycolipids and membrane anchors for cell wall lipoglycans in the Corynebacteria. Here we describe the complete synthesis of distinct acyl-isoforms of GlcAGroAc2 bearing both acylation patterns of (R)-tuberculostearic acid (C19:0) and palmitic acid (C16:0) and their mass spectral characterization. Collision-induced fragmentation mass spectrometry identified characteristic fragment ions that were used to develop “rules” allowing the assignment of the acylation pattern as C19:0 (sn-1), C16:0 (sn-2) in the natural product from Mycobacterium smegmatis, and the structural assignment of related C18:1 (sn-1), C16:0 (sn-2) GlcAGroAc2 glycolipids from M. smegmatis and Corynebacterium glutamicum. A synthetic hydrophobic octyl glucuronoside was used to characterize the GDP-mannose-dependent mannosyltransferase MgtA from C. glutamicum that extends GlcAGroAc2. This enzyme is an Mg2+/Mn2+-dependent metalloenzyme that undergoes dramatic activation upon reduction with dithiothreitol.

Published

2013