Cysteine | EPFL Graph Search

Cysteine (symbol Cys or C; ˈsɪstɪiːn) is a semiessential proteinogenic amino acid with the formula . The thiol side chain in cysteine often participates in enzymatic reactions as a nucleophile. Cysteine is chiral, only L-cysteine is found in nature. The thiol is susceptible to oxidation to give the disulfide derivative cystine, which serves an important structural role in many proteins. In this case, the symbol Cyx is sometimes used. The deprotonated form can generally be described by the symbol Cym as well. When used as a food additive, cysteine has the E number E920. Cysteine is encoded by the codons UGU and UGC. Structure Like other amino acids (not as a residue of a protein), cysteine exists as a zwitterion. Cysteine has chirality in the older / notation based on homology to - and -glyceraldehyde. In the newer R/S system of designating chirality, based on the atomic numbers of atoms near the asymmetric carbon, cysteine (and selenocysteine) have R chir

A new non-toxic chemically cross-linked ELP hydrogel for in situ protein delivery

Karine Ciapala

Proteins play an essential role in all biological processes and have been attracting more and more attention as drug candidates due to their high specificity and activity. However, their use as therapeutics has been seriously held back given that their ability to be effectively and conveniently delivered is problematic. Indeed, simple oral administration is ineffective since proteins are degraded in the digestive tract. Until now, these therapeutic agents were delivered by infusions or frequent injections. But this causes serious problems, as the compound does not get delivered in a prolonged continuous manner. Additionally, injections are also problematic as patients are reluctant to use needles unless there illness is life threatening. That is why focus has grown over the last years on developing novel delivery systems for proteins. Amongst the various types of delivery systems that exist, hydrogel based ones are very promising, as they possess remarkable biomimetic properties. The hydrogels that are chemically cross-linked are stronger than their counterparts, the physical hydrogels. An appealing approach to protein delivery that is more and more sought is to form the hydrogel in situ from an injected aqueous polymer solution and to use the formed gel as a depot for the sustained release of the protein. Oxygen sensitive gellation is an interesting stimulus to form these gels, but has not been successfully developed, as the gelling kinetics are too slow. Therefore, research groups have turned to the use of toxic chemicals to speed up the reaction. Elastin-like poylpeptides (ELP) are artificial biopolymers that are composed of a pentapeptide repeat. This repeat consists of Val-Pro-Gly-Xaa-Gly, where Xaa denotes a guest residue. An interesting characteristic of ELPs is that they are thermally responsive. Meaning, that when in solution they go through a lower critical solution temperature (LCST) transition. Below their LCST they are soluble in water and above their LCST they are insoluble. ELPs are well suited for drug delivery applications for many reasons such as their biocompatibility. The ELP that is studied is ELP9 Gel. Its guest residues are Val, Ala and Cys in a ratio of 1:14:1 respectively. As this ELP has cysteines it has the capacity to form a gel via cross-linking of the thiols groups by oxidation. The rheological tests that were carried out showed that this ELP9 Gel has all the characteristics of a gel. Furthermore, its gelling kinetics were greatly increased by heating it, but still remain too long for in situ applications. This suggests that the LCST behaviour of ELPs seems to play some role in favouring the cross-linking. But further controls remain to be done to confirm this hypothesized tandem process. A delivery strategy that involved this ELP9 Gel and Blue Fluorescent Proteins (BFP) with added cysteines was not successful as the molecular biology to obtain the modified proteins failed. However, the elaboration of a fusion peptide between Glucagon-Like-Peptide-1 (GLP-1) and ELP9 Gel was accomplished. The preliminary activity assay showed a reduced activity in comparison to the GLP-1 peptide alone. Unfortunately this ELP9 Gel has a setback due to its slow gelling time. Therefore, before continuing the research on the delivery strategies, it would be wiser to create a better ELP. If a new ELP with a higher cysteine concentration and lower transition temperature can be created, its gelling kinetics may be favourable for in situ protein delivery applications and thus, a chemically cross-linked hydrogel that does not require any toxic cross-linker would be available. This would be a big step in creating a very robust hydrogel for protein delivery applications but also for tissue regeneration

2009

Application of Hypervalent Iodine Reagents for Novel Cysteine Labeling

Romain Gaëtan Tessier

Selective functionalization of peptides and proteins has always been a valuable tool for the study and manipulation of biological processes. In this context, cysteines are of particular interest. Their intrinsic high nucleophilicity makes these amino acids excellent targets for peptides and proteins modification. As a result, cysteine labeling techniques have been extensively investigated. Nevertheless, while bioconjugation requires high efficiency, selectivity and kinetic under mild and aqueous conditions, most of the reported methodologies exhibit significant limitations. For instance, lack of chemoselectivity, as well as low or uncontrolled reactivity, are frequently reported. Furthermore, many of these methods rely on reagents challenging to prepare, store and use. In this regard, hypervalent iodine reagents are attractive. Heterocyclic Î»3-iodanes demonstrated high reactivity and selectivity, together with great stability and low toxicity. Nevertheless, applications to peptides and proteins modification remain rare. Employing ethynylbenziodoxolone reagents (EBXs), we previously described an efficient and chemoselective alkynylation of organosulfur compounds. The process was performed under âopen-flaskâ conditions, at room temperature, without any metal- or additive-assistance. In collaboration with Dr. Adibekian and co-workers, we then employed this methodology to intracellular proteomic profiling of cysteine residues. Nevertheless, only the most reactive cysteines were efficiently labeled. Accordingly, the goal of my thesis was to investigate the reactivity between any cysteine residues and EBX reagents, under mild and aqueous conditions. We started our investigations with treatment of glutathione, a naturally occurring tripeptide, with an azide-containing EBX reagent. Although a complete conversion of the starting material was observed, the corresponding thioalkyne product was not formed. Instead, we observed thiol-yne reactivity and selective thiol trans-addition in Î²-position of the EBX reagent, leading to vinylbenziodoxolone product (VBX). This efficient cysteine labeling exhibited high selectivity, fast kinetic and great robustness. Various cysteine-containing peptides and proteins, along with diverse EBX reagents, were well tolerated. When an azide-containing EBX reagent was employed, strain-promoted azide-alkyne cycloadditions (SPAAC) were successfully achieved. Alternatively, the hypervalent iodine function was engaged in aqueous Suzuki-Miyaura cross-couplings. Various boronic acids, containing electron-rich and âdeficient aryls, heteroaryls and vinyls, were successfully subjected to this palladium-promoted process. Remarkably, both SPAAC and cross-coupling were orthogonal to each other. We then investigated the singular reactivity of the TMS-EBX reagent. Under basic aqueous conditions, we observed fast desilylation of the hypervalent iodine reagent. Upon glutathione treatment, the resulting EBX substrate was engaged in a thiol-yne reaction. Nevertheless, the corresponding VBX product exhibited a low stability and led to alkynylated glutathione. Further optimization furnished an efficient, selective and rapid ethynylation of numerous cysteine-containing peptides.

EPFL2019

Ethynylation of Cysteine Residues: From Peptides to Proteins in Vitro and in Living Cells

Raj Kumar Nandi, Charlotte Marie Sornay, Romain Gaëtan Tessier, Jérôme Waser

Current approaches to introduce terminal alkynes for bioorthogonal reactions into biomolecules still present limitations in terms of either reactivity, selectivity, or adduct stability. We present a method for the ethynylation of cysteine residues based on the use of ethynylbenziodoxolone (EBX) reagents. The acetylene group is directly introduced onto the thiol group of cysteine and can be used for copper-catalyzed alkyne-azide cycloaddition (CuAAC) without further processing. Labeling proceeded with reaction rates comparable to or higher than the most often used iodoacetamide on peptides or maleimide on the antibody trastuzumab, and high cysteine selectivity was observed. The reagents were also used in living cells for cysteine proteomic profiling and displayed improved coverage of the cysteinome compared to previously reported iodoacetamide or hypervalent iodine reagents. Fine-tuning of the EBX reagents allows optimization of their reactivity and physical properties.

2020