Profiling Protein Sâ Sulfination with Maleimideâ Linked Probes

Cysteine residues are susceptible to oxidation to form Sâ sulfinyl (Râ SO2H) and Sâ sulfonyl (Râ SO3H) postâ translational modifications. Here we present a simple bioconjugation strategy to label Sâ sulfinated proteins by using reporterâ linked maleimides. After alkylation of free thiols with iodoacetamide, Sâ sulfinated cysteines react with maleimide to form a sulfone Michael adduct that remains stable under acidic conditions. Using this sequential alkylation strategy, we demonstrate differential Sâ sulfination across mouse tissue homogenates, as well as enhanced Sâ sulfination following pharmacological induction of endoplasmic reticulum stress, lipopolysaccharide stimulation, and inhibitors of the electron transport chain. Overall, this study reveals a broadened profile of maleimide reactivity across cysteine modifications, and outlines a simple method for profiling the physiological role of cysteine Sâ sulfination in disease.Maleimide, but not iodoacetamide, reacts with aryl and alkyl sulfinic acid standards and Sâ sulfinated proteins to give a sulfonylâ succinimide adduct that is stable under acidic conditions. This sequential alkylation strategy can be used for selective sulfinic acid labeling in biological samples. This study reveals a broadened profile of maleimide reactivity across cysteine modifications in proteins.Peer Reviewedhttps://deepblue.lib.umich.edu/bitstream/2027.42/138861/1/cbic201700137_am.pdfhttps://deepblue.lib.umich.edu/bitstream/2027.42/138861/2/cbic201700137.pdfhttps://deepblue.lib.umich.edu/bitstream/2027.42/138861/3/cbic201700137-sup-0001-misc_information.pd

Chlorophyllin Derivatives as Photosensitizers: Synthesis and Photodynamic Properties

Two new photosensitizers (PSs) derived from copper-chlorophyllin were designed to have excitation wavelengths appropriate for the use in photodynamic therapy (PDT) and to have amphiphilic character with positive charge, which favors binding to cell membranes and walls and the intracellular localization in mitochondria. Herein we describe the synthesis and characterization of several properties of these two new PS, i.e., photophysical (absorption, fluorescence and singlet oxygen emission quantum yields, Φf and ΦΔ, respectively), physical-chemical (aggregation) and photobiological (binding, incorporation and cell killing). As expected, the aggregation affected not only the absorption spectra but also lowered considerably the values of Φf and ΦΔ, which could be controlled by the interaction of the PS with aqueous micelles. In vitro studies were performed in cells, mitochondria, and vesicles to determine uptake, membrane binding, cytotoxicity, phototoxicity, and intracellular localization. The positively charged derivatives showed to be considerably more efficient for cell killing than methylene blue

Harnessing Redox Cross-Reactivity To Profile Distinct Cysteine Modifications

Cysteine <i>S</i>-nitrosation and <i>S</i>-sulfination are naturally occurring post-translational modifications (PTMs) on proteins induced by physiological signals and redox stress. Here we demonstrate that sulfinic acids and nitrosothiols react to form a stable thiosulfonate bond, and leverage this reactivity using sulfinate-linked probes to enrich and annotate hundreds of endogenous <i>S</i>-nitrosated proteins. In physiological buffers, sulfinic acids do not react with iodoacetamide or disulfides, enabling selective alkylation of free thiols and site-specific analysis of <i>S</i>-nitrosation. In parallel, <i>S</i>-nitrosothiol-linked probes enable enrichment and detection of endogenous <i>S</i>-sulfinated proteins, confirming that a single sulfinic acid can react with a nitrosothiol to form a thiosulfonate linkage. Using this approach, we find that hydrogen peroxide addition increases <i>S</i>-sulfination of human DJ-1 (PARK7) at Cys106, whereas Cys46 and Cys53 are fully oxidized to sulfonic acids. Comparative gel-based analysis of different mouse tissues reveals distinct profiles for both <i>S</i>-nitrosation and <i>S</i>-sulfination. Quantitative proteomic analysis demonstrates that both <i>S</i>-nitrosation and <i>S</i>-sulfination are widespread, yet exhibit enhanced occupancy on select proteins, including thioredoxin, peroxiredoxins, and other validated redox active proteins. Overall, we present a direct, bidirectional method to profile select redox cysteine modifications based on the unique nucleophilicity of sulfinic acids