3614-08-2

Basic information

• Product Name: Selenocysteine
• Synonyms: 3-Selenyl-DL-alanine;DL-Selenocysteine; Selenocysteine
• CAS NO: 3614-08-2
• Molecular Formula: C₃H₇NO₂Se
• Molecular Weight: 168.05
• Mol File: 3614-08-2.mol

Chemical Properties

• Boiling Point: 397.7°Cat760mmHg
• Flash Point: 194.3°C
• Appearance: /
• Density: g/cm³
• Vapor Pressure: 5.59E-09mmHg at 25°C
• PKA: 2.16±0.10(Predicted)
• CAS DataBase Reference: Selenocysteine(CAS DataBase Reference)
• NIST Chemistry Reference: Selenocysteine(3614-08-2)
• EPA Substance Registry System: Selenocysteine(3614-08-2)

Safety Data

• Hazardous Substances Data: 3614-08-2(Hazardous Substances Data)

Usage

Uses

Used in Pharmaceutical Industry:
Selenocysteine is used as a therapeutic agent for its antioxidant properties, playing a crucial role in the proper functioning of several selenoproteins. These selenoproteins are involved in essential biological processes such as immune response, thyroid hormone metabolism, and protection against oxidative stress.
Used in Nutritional Supplements:
Selenocysteine is used as a dietary supplement to support overall health and well-being. It contributes to the maintenance of adequate selenium levels in the body, which is essential for the synthesis of selenoproteins and their subsequent roles in various physiological functions.
Used in Research and Development:
Selenocysteine is utilized as a research tool in the field of biochemistry and molecular biology. It aids in the study of selenium's role in cellular processes and the development of new drugs and therapies targeting selenoproteins or selenium-dependent pathways.
Used in Agricultural Industry:
Selenocysteine can be used in the agricultural industry to enhance the selenium content of crops, which can contribute to improved nutritional value and health benefits for consumers.

InChI:InChI=1/C3H7NO2Se/c4-2(1-7)3(5)6/h2,7H,1,4H2,(H,5,6)

Synthetic route

[(Me2Im)2Au](1+) + selenocysteine (3614-08-2) → [Au(selenocysteine(-1H))2](1-)

Conditions	Yield
In further solvent(s) Kinetics; byproducts: C3H3N2(CH3)2(1+); monitored by NMR at 37°C in phosphate buffered saline (pH 7.2); not isolated;

bis(1,3-di-isopropylimidazol-2-ylidene)gold(I) chloride + selenocysteine (3614-08-2) → [Au(selenocysteine(-1H))2](1-)

Conditions	Yield
In further solvent(s) Kinetics; byproducts: C3H3N2(CH(CH3)2)2(1+); monitored by NMR at 37°C in phosphate buffered saline (pH 7.2); not isolated;

selenocysteine (3614-08-2) → 3-selenohydroxy-2-amino-1-hydroxypropylene-1,1-diphosphonic acid

Conditions	Yield
Stage #1: selenocysteine With benzo[1,3,2]dioxaborole In tetrahydrofuran for 2h; Stage #2: With tris(trimethylsilyl) phosphite In tetrahydrofuran for 2h;

Upstream product

• 1464-43-3 seleno-L-cystine 
• 97801-57-5 selenodjenkolic acid 
• 13345-95-4 1,5-dihydro-riboflavin 

Downstream Products

• 19641-75-9 bis(α-aminopropionic acid)selenide 
• 1849-36-1 para-nitrobenzenethiol 
• 13345-95-4 1,5-dihydro-riboflavin 
• 1464-43-3 seleno-L-cystine 
• 56-41-7 L-alanin 
• 146552-76-3 Se-(4-methoxybenzyl)-L-selenocysteine 

Relevant articles and documents

Studies on the reaction between reduced riboflavin and selenocystine

Selenocysteine (Sec) is a crucial component of mammalian thioredoxin reductase (TrxR) where it serves as a nucleophile for disulfide bond rupture in thioredoxin (Trx). Generation of the reduced state of Sec in TrxR requires consecutive two electron transfer steps, namely: (i) from NADPH to flavin adenine dinucleotide, (ii) from reduced flavin to the disulfide bond Cys59-S-S-Cys64, and finally (iii) from Cys59 and Cys64 to the selenosulfide bond Cys497-S-Se-Sec498. In this work, we studied the reaction between reduced riboflavin (RibH2) and selenocystine (Sec-Sec), an oxidized form of Sec. The interaction between RibH2 and Sec-Sec proceeded relatively slowly in comparison with its reverse reaction, that is, reduction of riboflavin (Rib) by Sec. The rate constant for the reaction between RibH2 and Sec-Sec was (7.9?±?0.1)?×?10?2?M?1 s?1 (pH 7.0, 25.0°C). The reaction between Rib and Sec proceeded via two steps, namely, a rapid reversible binding of Rib to Sec having a protonated selenol group to form a Sec-Rib complex, followed by nucleophilic attack of Sec-Rib by a second Sec molecule harboring a deprotonated selenol group. The equilibrium constant for the overall reduction process of Rib by Sec is (1.2?±?0.1)?×?106?M?1 (25.0°C). The finding that the interaction of RibH2 with oxidized selenol is reversible with its equilibrium favored toward the reverse reaction provides an additional explanation for the exceptional mechanism of the mammalian Trx/TrxR system involving transient reduction of a disulfide bond.

Generation of Recombinant Mammalian Selenoproteins through Genetic Code Expansion with Photocaged Selenocysteine

Selenoproteins contain the amino acid selenocysteine (Sec) and are found in all domains of life. The functions of many selenoproteins are poorly understood, partly due to difficulties in producing recombinant selenoproteins for cell-biological evaluation. Endogenous mammalian selenoproteins are produced through a noncanonical translation mechanism requiring suppression of the UGA stop codon and a Sec insertion sequence (SECIS) element in the 3′ untranslated region of the mRNA. Here, recombinant selenoproteins are generated in mammalian cells through genetic code expansion, circumventing the requirement for the SECIS element and selenium availability. An engineered orthogonal E. coli leucyl-tRNA synthetase/tRNA pair is used to incorporate a photocaged Sec (DMNB-Sec) at the UAG amber stop codon. DMNB-Sec is successfully incorporated into GFP and uncaged by irradiation of living cells. Furthermore, DMNB-Sec is used to generate the native selenoprotein methionine-R-sulfoxide reductase B1 (MsrB1). Importantly, MsrB1 is shown to be catalytically active after uncaging, constituting the first use of genetic code expansion to generate a functional selenoprotein in mammalian systems. The ability to site-specifically introduce Sec directly in mammalian cells, and temporally modulate selenoprotein activity, will aid in the characterization of mammalian selenoprotein function.

Selenomelanin: An Abiotic Selenium Analogue of Pheomelanin

Melanins are a family of heterogeneous biopolymers found ubiquitously across plant, animal, bacterial, and fungal kingdoms where they act variously as pigments and as radiation protection agents. There exist five multifunctional yet structurally and biosynthetically incompletely understood varieties of melanin: Eumelanin, neuromelanin, pyomelanin, allomelanin, and pheomelanin. Although eumelanin and allomelanin have been the focus of most radiation protection studies to date, some research suggests that pheomelanin has a better absorption coefficient for X-rays than eumelanin. We reasoned that if a selenium enriched melanin existed, it would be a better X-ray protector than the sulfur-containing pheomelanin because the X-ray absorption coefficient is proportional to the fourth power of the atomic number (Z). Notably, selenium is an essential micronutrient, with the amino acid selenocysteine being genetically encoded in 25 natural human proteins. Therefore, we hypothesize that selenomelanin exists in nature, where it provides superior ionizing radiation protection to organisms compared to known melanins. Here we introduce this novel selenium analogue of pheomelanin through chemical and biosynthetic routes using selenocystine as a feedstock. The resulting selenomelanin is a structural mimic of pheomelanin. We found selenomelanin effectively prevented neonatal human epidermal keratinocytes (NHEK) from G2/M phase arrest under high-dose X-ray irradiation. Provocatively, this beneficial role of selenomelanin points to it as a sixth variety of yet to be discovered natural melanin.

Dehalogenation of Halogenated Nucleobases and Nucleosides by Organoselenium Compounds

Halogenated nucleosides, such as 5-iodo-2′-deoxyuridine and 5-iodo-2′-deoxycytidine, are incorporated into the DNA of replicating cells to facilitate DNA single-strand breaks and intra- or interstrand crosslinks upon UV irradiation. In this work, it is shown that the naphthyl-based organoselenium compounds can mediate the dehalogenation of halogenated pyrimidine-based nucleosides, such as 5-X-2′-deoxyuridine and 5-X-2′-deoxycytidine (X=Br or I). The rate of deiodination was found to be significantly higher than that of the debromination for both nucleosides. Furthermore, the deiodination of iodo-cytidines was found to be faster than that of iodo-uridines. The initial rates of the deiodinations of 5-iodocytosine and 5-iodouracil indicated that the nature of the sugar moiety influences the kinetics of the deiodination. For both the nucleobases and nucleosides, the deiodination and debromination reactions follow a halogen-bond-mediated and addition/elimination pathway, respectively.

A Photochemically Generated Selenyl Free Radical Observed by High Energy Resolution Fluorescence Detected X-ray Absorption Spectroscopy

Selenium-based selenyl free radicals are chemical entities that may be involved in a range of biochemical processes. We report the first X-ray spectroscopic observation of a selenyl radical species generated photochemically by X-ray irradiation of low-temperature solutions of l-selenocysteine. We have employed high energy resolution fluorescence detected X-ray absorption spectroscopy (HERFD-XAS) and electron paramagnetic resonance (EPR) spectroscopy, coupled with density functional theory calculations, to characterize and understand the species. The HERFD-XAS spectrum of the selenyl radical is distinguished by a uniquely low-energy transition with a peak energy at 12659.0 eV, which corresponds to a 1s → 4p transition to the singly occupied molecular orbital of the free radical. The EPR spectrum shows the broad features and highly anisotropic g-values that are expected for a selenium free radical species. The availability of spectroscopic probes for selenyl radicals may assist in understanding why life chooses selenium over sulfur in selected biochemical processes.

Preparation method for L-selenocysteine

The invention belongs to the field of chemical synthesis, and concretely relates to a synthetic method for L-selenocysteine. The method comprises the following steps: a, chloridizing L-serine hydrochloride to obtain 3-chloro-L-alanine hydrochloride; b, performing seleno-reaction of 3-chloro-L-alanine hydrochloride prepared by step a under alkaline condition to obtain L-selenocystine; and c, performing reduction reaction of L-selenocystine to obtain L-selenocysteine. The method has simple steps, high yield, low cost, and good application prospect.

Detection of Intracellular Selenol-Containing Molecules Using a Fluorescent Probe with Near-Zero Background Signal

Selenocysteine (Sec), encoded as the 21st amino acid, is the predominant chemical form of selenium that is closely related to various human diseases. Thus, it is of high importance to identify novel probes for sensitive and selective recognition of Sec and Sec-containing proteins. Although a few probes have been reported to detect artificially introduced selenols in cells or tissues, none of them has been shown to be sensitive enough to detect endogenous selenols. We report the characterization and application of a new fluorogenic molecular probe for the detection of intracellular selenols. This probe exhibits near-zero background fluorescence but produces remarkable fluorescence enhancement upon reacting with selenols in a fast chemical reaction. It is highly specific and sensitive for intracellular selenium-containing molecules such as Sec and selenoproteins. When combined with flow cytometry, this probe is able to detect endogenous selenols in various human cancer cells. It is also able to image endogenous selenol-containing molecules in zebrafish under a fluorescence microscope. These results demonstrate that this molecular probe can function as a useful molecular tool for intracellular selenol sensing, which is valuable in the clinical diagnosis for human diseases associated with Sec-deficiency or overdose.

Peptide Tyrosinase Activators

Peptides that increase melanin synthesis are provided. These peptides include pentapeptides YSSWY, YRSRK, and their variants. The peptides may activate the enzymatic activity of tyrosinase to increase melanin synthesis. The pharmaceutical, cosmetic, and other compositions including the peptides are also provided. The methods of increasing melanin production in epidermis of a subject are provided where the methods include administering compositions comprising an amount of one or more peptides effective to increase the melanin production. The methods also include treating vitiligo or other hypopigmentation disorders with compositions including one or more peptides.

Kinetics of reaction of peroxynitrite with selenium- and sulfur-containing compounds: Absolute rate constants and assessment of biological significance

Peroxynitrite (the physiological mixture of ONOOH and its anion, ONOO-) is a powerful biologically-relevant oxidant capable of oxidizing and damaging a range of important targets including sulfides, thiols, lipids, proteins, carbohydrates and nucleic acids. Excessive production of peroxynitrite is associated with several human pathologies including cardiovascular disease, ischemic-reperfusion injury, circulatory shock, inflammation and neurodegeneration. This study demonstrates that low-molecular-mass selenols (RSeH), selenides (RSeR') and to a lesser extent diselenides (RSeSeR') react with peroxynitrite with high rate constants. Low molecular mass selenols react particularly rapidly with peroxynitrite, with second order rate constants k2 in the range 5.1×105-1.9×106 M-1 s-1, and 250-830 fold faster than the corresponding thiols (RSH) and many other endogenous biological targets. Reactions of peroxynitrite with selenides, including selenosugars are approximately 15-fold faster than their sulfur homologs with k2 approximately 2.5×103 M-1 s-1. The rate constants for diselenides and sulfides were slower with k2 0.72-1.3×103 M-1 s-1 and approximately 2.1×102 M-1 s-1 respectively. These studies demonstrate that both endogenous and exogenous selenium-containing compounds may modulate peroxynitrite-mediated damage at sites of acute and chronic inflammation, with this being of particular relevance at extracellular sites where the thiol pool is limited.

Investigation of peptide thioester formation via N→Se acyl transfer

Native chemical ligation is widely used for the convergent synthesis of proteins. The peptide thioesters required for this process can be challenging to produce, particularly when using Fmoc-based solid-phase peptide synthesis. We have previously reported a route to peptide thioesters, following Fmoc solid-phase peptide synthesis, via an N→S acyl shift that is initiated by the presence of a C-terminal cysteine residue, under mildly acidic conditions. Under typical reaction conditions, we occasionally observed significant thioester hydrolysis as a consequence of long reaction times (~48h) and sought to accelerate the reaction. Here, we present a faster route to peptide thioesters, by replacing the C-terminal cysteine residue with selenocysteine and initiating thioester formation via an N→Se acyl shift. This modification allows thioester formation to take place at lower temperatures and on shorter time scales. We also demonstrate how application of this strategy also accelerates peptide cyclization, when a linear precursor is furnished with an N-terminal cysteine and C-terminal selenocysteine.