Detection of electrophile-sensitive proteins

Wall, Stephanie; Smith, M. R.; Ricart, Karina; Zhou, Fen; Vayalil, Praveen K.; Oh, Joo–Yeun; Landar, Aimee

doi:10.1016/j.bbagen.2013.09.003

Cited by 29 publications

(21 citation statements)

References 122 publications

(135 reference statements)

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“…Protein thiol alkylation with NEM is faster than other low molecular mass thiol-modifying reagents, resulting in the selective reaction toward the thiols at physiological pH. 40,41) Under the employed reaction conditions, the protein thiol content after the reaction with NEM decreased to 4.38±2.29% (n=4) of that before the reaction. Thus, the reactive protein thiols appeared to be mostly probed by the NEM alkylation.…”

Section: Resultsmentioning

confidence: 99%

A Comprehensive Analysis of Selenium-Binding Proteins in the Brain Using Its Reactive Metabolite

Yoshida

Hori

Ura

et al. 2016

CHEMICAL & PHARMACEUTICAL BULLETIN

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The intracellular metabolism of selenium in the brain currently remains unknown, although the antioxidant activity of this element is widely acknowledged to be important in maintaining brain functions. In this study, a comprehensive method for identifying the selenium-binding proteins using PenSSeSPen as a model of the selenium metabolite, selenotrisulfide (RSSeSR, STS), was applied to a complex cell lysate generated from the rat brain. Most of the selenium from L-penicillamine selenotrisulfide (PenSSeSPen) was captured by the cytosolic protein thiols in the form of STS through the thiol-exchange reaction (R-SH PenSSeSPen→R-SSeSPen PenSH). The cytosolic protein species, which reacted with the PenSSeSPen mainly had a molecular mass of less than 20 kDa. A thiol-containing protein at m/z 15155 in the brain cell lysate was identified as the cystatin-12 precursor (CST12) from a rat protein database search and a tryptic fragmentation experiment. CST12 belongs to the cysteine proteinase inhibitors of the cystatin superfamily that are of interest in mechanisms regulating the protein turnover and polypeptide production in the central nervous system and other tissues. Consequently, CST12 is suggested to be one of the cytosolic proteins responsible for the selenium metabolism in the brain.

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Section: Resultsmentioning

confidence: 99%

A Comprehensive Analysis of Selenium-Binding Proteins in the Brain Using Its Reactive Metabolite

Yoshida

Hori

Ura

et al. 2016

CHEMICAL & PHARMACEUTICAL BULLETIN

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“…These weak electrophiles, which are usually eicosanoids, modify proteins regulating biological function and pathological events such as cancer and inflammation. 368–370 …”

Section: Mitochondria-targeted Probes and Sensors For Reactive Oxymentioning

confidence: 99%

Mitochondria-Targeted Triphenylphosphonium-Based Compounds: Syntheses, Mechanisms of Action, and Therapeutic and Diagnostic Applications

Zielonka¹,

Joseph²,

et al. 2017

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Mitochondria are recognized as one of the most important targets for new drug design in cancer, cardiovascular, and neurological diseases. Currently, the most effective way to deliver drugs specifically to mitochondria is by covalent linking a lipophilic cation such as an alkyltriphenylphosphonium moiety to a pharmacophore of interest. Other delocalized lipophilic cations, such as rhodamine, natural and synthetic mitochondria-targeting peptides, and nanoparticle vehicles, have also been used for mitochondrial delivery of small molecules. Depending on the approach used, and the potentials of cell and mitochondrial membranes, more than 1000-fold higher mitochondrial concentration can be achieved. Mitochondrial targeting has been developed to study mitochondrial physiology and dysfunction and the interaction between mitochondria and other subcellular organelles and for treatment of a variety of diseases such as neurodegeneration and cancer. In this review, we discuss efforts to target small-molecule compounds to mitochondria for probing mitochondria function, as diagnostic tools and potential therapeutics. We describe the physicochemical basis for mitochondrial accumulation of lipophilic cations, synthetic chemistry strategies to target compounds to mitochondria, mitochondrial probes and sensors, and examples of mitochondrial targeting of bioactive compounds. Finally, we review published attempts to apply mitochondria-targeted agents for the treatment of cancer and neurodegenerative diseases.

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“…Also, many studies linked protein modifications by 4-HNE to the etiology of several pathologies and diseases (Petersen and Doorn, 2004). The discovery that lipidderived electrophiles modify the structure and function of numerous proteins have led to the definition of oxilipidome and electrophile responsive proteome in cells and argues for ascertaining their impact on the survival and functions of cells under physiological or stressful conditions (Higdon et al, 2012b;Wall et al, 2014).…”

Section: Detrimental Effects Of 4-hnementioning

confidence: 99%

Hormetic and regulatory effects of lipid peroxidation mediators in pancreatic beta cells

Maulucci

Daniel

Cohen

et al. 2016

Molecular Aspects of Medicine

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Detection of electrophile-sensitive proteins

Cited by 29 publications

References 122 publications

A Comprehensive Analysis of Selenium-Binding Proteins in the Brain Using Its Reactive Metabolite

A Comprehensive Analysis of Selenium-Binding Proteins in the Brain Using Its Reactive Metabolite

Mitochondria-Targeted Triphenylphosphonium-Based Compounds: Syntheses, Mechanisms of Action, and Therapeutic and Diagnostic Applications

Hormetic and regulatory effects of lipid peroxidation mediators in pancreatic beta cells

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