Fmoc-S-ethyl-L-cysteine
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Fmoc-S-ethyl-L-cysteine

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Category
Fmoc-Amino Acids
Catalog number
BAT-003832
CAS number
200354-34-3
Molecular Formula
C20H21NO4S
Molecular Weight
371.50
Fmoc-S-ethyl-L-cysteine
IUPAC Name
(2R)-3-ethylsulfanyl-2-(9H-fluoren-9-ylmethoxycarbonylamino)propanoic acid
Synonyms
Fmoc-L-Cys(Et)-OH; (2R)-3-ethylsulfanyl-2-(9H-fluoren-9-ylmethoxycarbonylamino)propanoic acid
Appearance
White powder
Purity
≥ 99% (HPLC)
Melting Point
130.5-132.5 °C
Storage
Store at 2-8 °C
InChI
InChI=1S/C20H21NO4S/c1-2-26-12-18(19(22)23)21-20(24)25-11-17-15-9-5-3-7-13(15)14-8-4-6-10-16(14)17/h3-10,17-18H,2,11-12H2,1H3,(H,21,24)(H,22,23)/t18-/m0/s1
InChI Key
OUXUHWHQQLGDQE-SFHVURJKSA-N
Canonical SMILES
CCSCC(C(=O)O)NC(=O)OCC1C2=CC=CC=C2C3=CC=CC=C13

Fmoc-S-ethyl-L-cysteine, a versatile chemical reagent, finds widespread applications in peptide synthesis and various biochemical studies. Here are four key applications of Fmoc-S-ethyl-L-cysteine:

Peptide Synthesis: Serving as a cornerstone in solid-phase peptide synthesis, Fmoc-S-ethyl-L-cysteine acts as a pivotal building block. The Fmoc (9-fluorenylmethyloxycarbonyl) group acts as a protective shield for amino acids, enabling selective reactions at specific sites. This reagent facilitates the precise and efficient synthesis of peptides, playing a critical role in crafting therapeutic peptides and peptide-based research tools with exquisite accuracy.

Protein Engineering: Amidst the domain of protein engineering, Fmoc-S-ethyl-L-cysteine emerges as a potent tool for introducing tailored cysteine residues into protein sequences. Through these modifications, scientists can delve into protein structure and function by incorporating cysteine residues amenable to post-synthesis modifications, such as the formation of disulfide bonds or covalent attachment of probes. This strategic approach lies at the nucleus of unraveling protein dynamics and intricate interactions.

Bioconjugation: Within bioconjugation techniques, Fmoc-S-ethyl-L-cysteine stands out as a pivotal component facilitating the attachment of diverse functional groups or molecules to peptides and proteins. The ethyl group present on cysteine serves as a conduit for further chemical tweaks, enabling the conjugation of drugs, fluorescent dyes, or other bioactive molecules. This methodology underpins the development of targeted drug delivery systems and advanced diagnostic tools.

Chemical Biology: In the realm of chemical biology research, Fmoc-S-ethyl-L-cysteine plays a pivotal role in shaping the design and synthesis of peptide-based probes and inhibitors. By incorporating this reagent into peptides, researchers can engineer molecules that selectively interact with target proteins or enzymes. This tailored approach aids in unraveling intricate biological pathways, pinpointing potential drug targets, and fostering the development of novel therapeutic agents with unprecedented precision.

1. Protein chemical synthesis by α-ketoacid-hydroxylamine ligation
Thibault J Harmand, Claudia E Murar, Jeffrey W Bode Nat Protoc. 2016 Jun;11(6):1130-47. doi: 10.1038/nprot.2016.052. Epub 2016 May 26.
Total chemical synthesis of proteins allows researchers to custom design proteins without the complex molecular biology that is required to insert non-natural amino acids or the biocontamination that arises from methods relying on overexpression in cells. We describe a detailed procedure for the chemical synthesis of proteins with the α-ketoacid-hydroxylamine (KAHA ligation), using (S)-5-oxaproline (Opr) as a key building block. This protocol comprises two main parts: (i) the synthesis of peptide fragments by standard fluorenylmethoxycarbonyl (Fmoc) chemistry and (ii) the KAHA ligation between fragments containing Opr and a C-terminal peptide α-ketoacid. This procedure provides an alternative to native chemical ligation (NCL) that could be valuable for the synthesis of proteins, particularly targets that do not contain cysteine residues. The ligation conditions-acidic DMSO/H2O or N-methyl-2-pyrrolidinone (NMP)/H2O-are ideally suited for solubilizing peptide segments, including many hydrophobic examples. The utility and efficiency of the protocol is demonstrated by the total chemical synthesis of the mature betatrophin (also called ANGPTL8), a 177-residue protein that contains no cysteine residues. With this protocol, the total synthesis of the betatrophin protein has been achieved in around 35 working days on a multimilligram scale.
2. Preparation of protected peptidyl thioester intermediates for native chemical ligation by Nalpha-9-fluorenylmethoxycarbonyl (Fmoc) chemistry: considerations of side-chain and backbone anchoring strategies, and compatible protection for N-terminal cysteine
C M Gross, D Lelièvre, C K Woodward, G Barany J Pept Res. 2005 Mar;65(3):395-410. doi: 10.1111/j.1399-3011.2005.00241.x.
Native chemical ligation has proven to be a powerful method for the synthesis of small proteins and the semisynthesis of larger ones. The essential synthetic intermediates, which are C-terminal peptide thioesters, cannot survive the repetitive piperidine deprotection steps of N(alpha)-9-fluorenylmethoxycarbonyl (Fmoc) chemistry. Therefore, peptide scientists who prefer to not use N(alpha)-t-butyloxycarbonyl (Boc) chemistry need to adopt more esoteric strategies and tactics in order to integrate ligation approaches with Fmoc chemistry. In the present work, side-chain and backbone anchoring strategies have been used to prepare the required suitably (partially) protected and/or activated peptide intermediates spanning the length of bovine pancreatic trypsin inhibitor (BPTI). Three separate strategies for managing the critical N-terminal cysteine residue have been developed: (i) incorporation of N(alpha)-9-fluorenylmethoxycarbonyl-S-(N-methyl-N-phenylcarbamoyl)sulfenylcysteine [Fmoc-Cys(Snm)-OH], allowing creation of an otherwise fully protected resin-bound intermediate with N-terminal free Cys; (ii) incorporation of N(alpha)-9-fluorenylmethoxycarbonyl-S-triphenylmethylcysteine [Fmoc-Cys(Trt)-OH], generating a stable Fmoc-Cys(H)-peptide upon acidolytic cleavage; and (iii) incorporation of N(alpha)-t-butyloxycarbonyl-S-fluorenylmethylcysteine [Boc-Cys(Fm)-OH], generating a stable H-Cys(Fm)-peptide upon cleavage. In separate stages of these strategies, thioesters are established at the C-termini by selective deprotection and coupling steps carried out while peptides remain bound to the supports. Pilot native chemical ligations were pursued directly on-resin, as well as in solution after cleavage/purification.
3. A viable synthesis of N-methyl cysteine
Erik L Ruggles, Stevenson Flemer Jr, Robert J Hondal Biopolymers. 2008;90(1):61-8. doi: 10.1002/bip.20889.
While a number of methods exist for the production of N-methyl amino acid derivatives, the methods for the production of N-methyl cysteine (MeCys) derivatives are suboptimal as they either have low yields or lead to significant sulfhydryl deprotection during the synthetic protocol. This article focuses on the generation of MeCys and its subsequent use in Fmoc solid-phase peptide synthesis for the generation of N-methyl cystine containing peptides. Various methods for amino methylation of cysteine, in the presence of acid labile or acid stable sulfhydryl protecting groups, are compared and contrasted. Production of MeCys is best attained through formation of an oxazolidinone precursor obtained via cyclization of Fmoc--Cys(StBu)--OH. Following oxazolidinone ring opening, iminium ion reduction generates Fmoc--MeCys(StBu)--OH with an overall yield of 91%. The key to this procedure is using an electronically neutral Cys-derivative, as other polar Cys-derivatives gave poor results using the oxazolidinone procedure. Subsequently, the Fmoc--MeCys(StBu)--OH building block was used to replace a Cys residue with a MeCys residue in two peptide fragments that correspond to the active sites of glutaredoxin and thioredoxin reductase. The examples used here highlight the use of a MeCys(StBu) derivative, which allows for facile on-resin conversion to a MeCys(5-Npys) residue that can be subsequently used for intramolecular disulfide bond formation with concomitant cleavage of the peptide from the solid support. (c) 2007 Wiley Periodicals, Inc. Biopolymers (Pept Sci) 90: 61-68, 2008. This article was originally published online as an accepted preprint. The "Published Online" date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com.
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