Lun K. Tsou scite author profile

Proteins in nature fold into native conformations in which combinations of peripherally projected aliphatic, aromatic and ionic functionalities direct a wide range of properties. Alpha-helices, one of the most common protein secondary structures, serve as important recognition regions on protein surfaces for numerous protein-protein, protein-DNA and protein-RNA interactions. These interactions are characterized by conserved structural features within the alpha-helical domain. Rational design of structural mimetics of these domains with synthetic small molecules has proven an effective means to modulate such protein functions. In this tutorial review we discuss strategies that utilize synthetic small-molecule antagonists to selectively target essential protein-protein interactions involved in certain diseases. We also evaluate some of the protein-protein interactions that have been or are potential targets for alpha-helix mimetics.

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Tandem fluorescence imaging of dynamic S -acylation and protein turnover

Zhang

Tsou

Charron

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

106

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The functional significance and regulation of reversible S-acylation on diverse proteins remain unclear because of limited methods for efficient quantitative analysis of palmitate turnover. Here, we describe a tandem labeling and detection method to simultaneously monitor dynamic S-palmitoylation and protein turnover. By combining S-acylation and cotranslational fatty acid chemical reporters with orthogonal clickable fluorophores, dual pulse-chase analysis of Lck revealed accelerated palmitate cycling upon T-cell activation. Subsequent pharmacological perturbation of Lck palmitate turnover suggests yet uncharacterized serine hydrolases contribute to dynamic S-acylation in cells. In addition to dually fatty-acylated proteins, this tandem fluorescence imaging method can be generalized to other S-acylated proteins using azidohomoalanine as a methonine surrogate. The sensitivity and efficiency of this approach should facilitate the functional characterization of cellular factors and drugs that modulate protein S-acylation. Furthermore, diverse protein modifications could be analyzed with this tandem imaging method using other chemical reporters to investigate dynamic regulation of protein function.bioorthogonal ligation | chemical reporters | click chemistry | S-palmitoylation | fatty acylation P rotein S-palmitoylation (S-acylation) targets proteins to discrete intracellular membrane compartments, controls protein stability, and mediates protein-protein interactions (1, 2). Furthermore, the reversibility of S-acylation offers spatial and temporal control of protein function akin to protein phosphorylation (Fig. 1A). Notably, the differential S-palmitoylation and membrane targeting of H-and N-Ras isoforms have been shown to activate discrete signaling pathways for cellular growth and differentiation (3-6). Accelerated deacylation of G-protein subunits and G-protein coupled receptors upon receptor stimulation (7,8) suggest active mechanisms regulating S-acylation/deacylation cycles. In addition, receptor activity-regulated palmitate turnover of PSD-95 is proposed to modulate synaptic strength and plasticity in postsynaptic neurons by mediating receptor clustering (9). Development of the acyl-biotinyl exchange protocol (10-12) and fatty acid chemical reporters (13-16) enabled improved detection and identification of many S-palmitoylated proteins from diverse biological pathways in eukaryotes (17). Nonetheless, it remains to be determined if S-acylation is dynamic and regulated for identified fatty-acylated proteins.Quantitative analysis of S-acylation/deacylation cycle on proteins would provide further insight into the biological significance and function of dynamic S-palmitoylation, but tools to efficiently visualize palmitate turnover on proteins are limited. While photoactivation/bleaching of S-palmitoylated proteins fused to fluorescent reporters allow visualization of protein dynamics in cells (4,5,18), these methods yield indirect readouts of protein S-acylation. Acyl-biotinyl exchange enables nonradioactive det...

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Simple Cation−π Interaction between a Phenyl Ring and a Protonated Amine Stabilizes an α-Helix in Water

2002

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Cation-pi interactions have been proposed to be important contributors to protein structure and function. In particular, these interactions have been suggested to provide significant stability at the solvent-exposed surface of a protein. We have investigated the magnitude of cation-pi interactions between phenylalanine (Phe) and lysine (Lys), ornithine (Orn), and diaminobutanoic acid (Dab) in the context of an alpha-helix and have found that only the Phe...Orn interaction provides significant stability to the helix, stabilizing it by -0.4 kcal/mol. This interaction energy is in the same range as a salt bridge in an alpha-helix, and equivalent to the recently reported Trp...Arg interaction in an alpha-helix, despite the fact that Trp...guanidinium interactions have been proposed to be stronger than Phe...ammonium interactions. These results indicate that even the simplest cation-pi interaction can provide significant stability to protein structure and demonstrate the subtle factors that can influence the observed interaction energies in designed systems.

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Alkynyl-farnesol reporters for detection ofproteinS-prenylation in cells

et al. 2011

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Protein S-prenylation is a lipid modification that regulates membrane-protein and protein-protein interactions in cell signaling. Though sites of protein S-prenylation can be predicted based upon conserved C-terminal CaaX or CC/CXC motifs, biochemical detection of protein S-prenylation in cells is still challenging. Herein, we report an alkynyl-isoprenol chemical reporter (alk-FOH) as an efficient substrate for prenyltransferases in mammalian cells that enables sensitive detection of S-farnesylated and S-geranylgeranylated proteins using bioorthogonal ligation methods. Fluorescent detection alleviates the need to deplete cellular isoprenoids for biochemical analysis of S-prenylated proteins and enables robust characterization of S-prenylated proteins, such as effectors that are injected into host cells by bacterial pathogens. This alkynyl-prenylation reporter provides a sensitive tool for biochemical analysis and rapid profiling of prenylated proteins in cells.

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Antibacterial Flavonoids from Medicinal Plants Covalently Inactivate Type III Protein Secretion Substrates

et al. 2016

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Traditional Chinese Medicines (TCMs) have been historically used to treat bacterial infections. However, the molecules responsible for these anti-infective properties and their potential mechanisms of action have remained elusive. Using a high-throughput assay for type III protein secretion in Salmonella enterica serovar Typhimurium, we discovered that several TCMs can attenuate this key virulence pathway without affecting bacterial growth. Amongst the active TCMs, we discovered that baicalein, a specific flavonoid from Scutellaria baicalensis, targets S. Typhimurium pathogenicity island-1 (SPI-1) type III secretion system (T3SS) effectors and translocases to inhibit bacterial invasion of epithelial cells. Structurally related flavonoids present in other TCMs, such as quercetin also inactivated the SPI-1 T3SS and attenuated S. Typhimurium invasion. Our results demonstrate that specific plant metabolites from TCMs can directly interfere with key bacterial virulence pathways and reveals a previously unappreciated mechanism of action for anti-infective medicinal plants.

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Lun K. Tsou

Synthetic non-peptide mimetics of α-helices

Tandem fluorescence imaging of dynamic S -acylation and protein turnover

Simple Cation−π Interaction between a Phenyl Ring and a Protonated Amine Stabilizes an α-Helix in Water

Alkynyl-farnesol reporters for detection ofproteinS-prenylation in cells

Antibacterial Flavonoids from Medicinal Plants Covalently Inactivate Type III Protein Secretion Substrates

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