Disulfides symmetrical

Estevez, M.C., R. Galve, F. Sanchez-Baeza, et al. 2008. Disulfide symmetric dimers as stable pre-hapten forms for bioconjugation A strategy to prepare immunoreagents for the detection of sulfophenyl car-boxylate residues in environmental samples. Chem. Eur. J. 14 1906-1917. 

Oxidation. Disulfides are prepared commercially by two types of reactions. The first is an oxidation reaction uti1i2ing the thiol and a suitable oxidant as in equation 18 for 2,2,5,5-tetramethyl-3,4-dithiahexane. The most common oxidants are chlorine, oxygen (29), elemental sulfur, or hydrogen peroxide. Carbon tetrachloride (30) has also been used. This type of reaction is extremely exothermic. Some thiols, notably tertiary thiols and long-chain thiols, are resistant to oxidation, primarily because of steric hindrance or poor solubiUty of the oxidant in the thiol. This type of process is used in the preparation of symmetric disulfides, RSSR. The second type of reaction is the reaction of a sulfenyl haUde with a thiol (eq. 19). This process is used to prepare unsymmetric disulfides, RSSR such as 4,4-dimethyl-2,3-dithiahexane. Other methods may be found in the Hterature (28). 

Thiazolidines have been prepared from /3-aminothiols—for example, cysteine—to protect the —SH and — NH groups during syntheses of peptides, including glu-tathione. Thiazolidines are oxidized to symmetrical disulfides with iodine they do not react with thiocyanogen in a neutral solution. 

A thiol can be protected by oxidation (with O2 H2O2 I2. - ) to the corresponding symmetrical disulfide, which subsequently can be cleaved by reduction [Sn/HCl Na/xylene, Et20, or NH3 LiAlH4 NaBH4 or thiols such as HO(CH2)2SH]. Un-symmetrical disulfides have also been prepared and are discussed. 

A 1 1 mixture of thiols (7 and 2), on treatment with oxygen in the presence of a catalytic amount of Et3N, gives one unsymmetrical (4) and two symmetrical disulfides (3 and 5) (Eq. 4). As a measure of the degree of the recognition between 7 and 2 in the oxidation, the selectivity (r) is employed which is represented by the logarithmic ratio of the yield of 4 to twice that of 3 (Eq. 5). The r is so defined as to become zero when oxidation yields the three disulfides in a 1 2 1 ratio. In the present case, the recognition process is followed by covalent bond formation. 

In the oxidative Eschenmoser sulfide contraction (Scheme 11), thioamide 59 is oxidized by benzoyl peroxide to give either a symmetrical disulfide or the O-benzoate of the thiolactam-S-oxide. In any event, the once-nucleophilic thioamide sulfur atom is now forced to adopt the role of electrophile a reactivity umpolung has, in effect, been achieved.13 The nucleophilic enamide 65 attacks the sulfur atom leading to the formation of sulfur-bridged intermediate 66. The action of a phosphine or a phosphite thiophile on the putative episulfide then gives vinylogous amidine 67. 

Radial distribution curves for carbon disulfide and carbon oxysulfide (treated by the usual method by Cross and Brockway11) are shown in Fig. 5. For carbon disulfide the maxima of the two peaks occur at 1.60 and 3.07 A. In this symmetrical linear molecule the C-S distance is just one-half the S-S distance the values found deviate from this ratio by 4%. Similarly in carbon oxysulfide the sum of two interatomic distances equals the third. The values C-S = 1.60 A. and O-S = 2.70 A. given by the two maxima differ by 1.10 A. 

Salts of dithiocarbamic acid can be prepared by the addition of primary or secondary amines to carbon disulfide. This reaction is similar to 16-9. Hydrogen sulfide can be eliminated from the product, directly or indirectly, to give isothiocyanates (RNCS). Isothiocyanates can be obtained directly by the reaction of primary amines and CS2 in pyridine in the presence of DCC. ° In the presence of diphenyl phosphite and pyridine, primary amines add to CO2 and to CS2 to give, respectively, symmetrically substituted ureas and thioureas ... 

In a KI matrix the electronic absorption maximum of 82 - is observed at 400 nm, and the 88 stretching vibration by a Raman line at 594 cm k 83 shows a Raman line at 546 cm and an infrared absorption at 585 cm which were assigned to the symmetric and antisymmetric stretching vibrations, respectively. The bromides and iodides of Na, K, and Rb have also been used to trap 82 - but the wavenumbers of the 88 stretching vibration differ by as much as 18 cm- from the value in KI. The anion S3- has been trapped in the chlorides, bromides and iodides of Na, K, and Rb [120]. While the disulfide monoanion usually occupies a single anion vacancy [116, 122], the trisulfide radical anion prefers a trivacancy (one cation and two halide anions missing) [119]. 

In 2001, Braga et al. reported the synthesis of new chiral C2-symmetric oxazolidine disulfide ligands from (R)-cysteine and successfully applied them as catalysts in the asymmetric addition of ZnEt2 to various aldehydes (Scheme 3.23). In the presence of 2mol% of ligand, excellent enantioselectivities of up to >99% ee were obtained even with aliphatic aldehydes such as n-decanal or n-hexanal. These authors proposed that the active catalyst did not maintain its C2-symmetry during the reaction. The disulfide bond was probably cleaved in situ by ZnEt2. 

In 2002, Braga el al. employed a chiral C2-symmetric oxazolidine disulfide as a ligand for the enantioselective synthesis of propargylic alcohols by direct addition of alkynes to aldehydes (Scheme 3.64). Good yields but moderate enantioselectivities (<58% ee) were obtained for the enantioselective alkyny-lation of aldehydes in the presence of ZnEt2. 

Rabenstein and Yamashita [52] determined penicillamine and its symmetrical and mixed disulfides by HPLC in biological fluids. Plasma and urine were deproteinized with trichloroacetic acid, and HPLC was performed on a column (25 cm x 4.6 mm) or Biophase ODS (5 pm) with a mobile phase comprising 0.1 M phosphate buffer (pH 3) and 0.34 mM Na octylsulfate at 1 mL/min. Detection was with a dual Hg-Au amalgam electrode versus a Ag-AgCl reference electrode. (z>)-penicillamine and homocysteine were determined at the downstream electrode at +0.15 V, and homocystine, penicillamine-homocysteine, and penicillamine disulfides were first reduced... 

Reaction of carbon disulfide with primary amines, using MCM-41-TBD (mesoporous MCM-41 silica, TBD l,5,7-triazabicyclo[4.4.0]dec-5-ene) as catalyst, has given symmetrical thioureas under heterogeneous conditions. The MCM-41-TBD could be reused as a catalyst (Scheme 43).123... 

Reaction of carbon disulfide with primary amine hydrochloride in the presence of dimethyl aminopyridine (DMAP) and A,A -dicyclohexylcarbodii-mide (DCC) affords symmetrical thioureas (Scheme 44).124,125... 

FIGURE 6.22 Disulfide interchange.92 (A) Discovered in synthesis when hydrazinolysis of an unsymmetrical derivative of cystine gave two symmetrical products instead of the expected monohydrazide at the urethane-protected cysteine moiety of the derivative.95 (B) Mechanism for interchange catalyzed by strong acid,94 which is suppressed by thiols. (C) Mechanism for interchange catalyzed by weak alkali, which is enhanced by thiols. 

In an aprotic solution, the mechanism of oxidation of diaryl disulfides was shown to be more complex than a direct cleavage of the S—S linkage [116,117,123], The occurrence of two consecutive reactions being of second kinetic order if potential-determined and of first order if current-determined, was established for the two-electron transfer steps. Dimerization of the cation radicals occurs on the ArS fragment, whose contribution to the HOMO is more important, and produces an intermediate disulfonium dication. The subsequent cleavage of the latter results in two ArS+ cations and a molecule of a disulfide (the same as a starting disulfide in the case of symmetrical compounds). This mechanism, EC2C1E (E = electrochemical, C = Chemical), has... 

Psammaplin A (208) Symmetrical bromotyrosine- derived disulfide Panobinostat (LBH-589) (209) Oncology Inhibits histone deacetylase (HDAC) Phase T/IT/ITT Novartis 945,946... 

Selected entries from Methods in Enzymology [vol, page(s)] Acetylthiocholine as substrate, 251, 101-102 assay by ESR, 251, 102-105 inhibitors, 251, 103 modification by symmetrical disulfide radical, 251, 100 thioester substrate, 248, 16 transition state and multisubstrate analogues, 249, 305 enzyme receptor, similarity to collagen, 245, 3. 

At the time of the earlier review (66HC1155), it was already known that combinations of arenes with sulfur, or with sulfur mono- or dichlorides in the presence of Lewis acids (IV,B,1), or of aryl thiols, diaryl sulfides, or disulfides (IV,B,2 and 3) again heated with Lewis acid catalysts, generate thianthrenes, sometimes in acceptable preparative yields. A complimentary method is the treatment of aryl thiols with c. H2SO4. Routes from arenes and aryl thiols almost certainly involve the initial formation of diaryl sulfides. All these methods inevitably give symmetrical thianthrenes carrying identical substituents on each benzene ring (Scheme 9), unless the second sulfur is introduced in a controlled fashion into a preformed, unsymmetrical diphenyl sulfide. 

It has been shown that the transformation 254 - 251 -t- 253 proceeds with first-order kinetics and that increase in solvent polarity is associated with an increase in the rate. It is proposed that the reaction involves a novel unimolecular heterolytic scission of the sulfur—sulfur bond in the symmetrical disulfide (254). The kinetics of the alkaline hydrolysis of anhydro-2-mercapto-4,5-diphenyl-l,3,4-thiadiazolium... 

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