Iodine thiol group reaction

Reductive oxidation of />-nitrotoluene to -aminobenzaldehyde, 31, 6 Reformatsky reaction, 37, 38 Reissert s compound, 38, 58 Reissert reaction, 38, 58 Replacement, benzenesulfonate groups by bromine atoms, 31, 82 bromine, by a thiol group, 30, 35 by fluorine, 36, 40 chlorine, by an amino group, 31,45 by a thiol group, 32, 101 by iodine, 30, 11 by methoxyl, 32, 79 by nitrile, 36, 50 in an imido-chloride group by an anilino group, 31, 48 chlorine and nitro by ethoxyl radicals, 32,68... 

In order to make more soluble systems, we prepared molecular wire 16 by Pd/Cu-catalyzed coupling reactions of 8, 12, and 13 (Scheme 3.21). 8 was synthesized by the coupling reaction of 6 with phenylacetylene followed by an iodination with CH3I. 9 was coupled with 10 to afford dimer 11. Deprotection of the terminal alkyne with TBAF provided intermediate 12 that was coupled with 13 to afford tetramer 14 which, upon deprotection and coupling with aryl iodide 8, alforded 16. 16 has dodecyl chains on the two central units that allow this system to be soluble in many organic solvents but the chains point in the opposite direction of thiol group that serves as a... 

A reasonable mechanism for the iodine oxidation of 5-Trt cysteine peptides is given in Scheme 6. 45 Reaction of iodine with the divalent sulfur atom leads to the iodosulfonium ion 5 which is then transformed to the sulfenyl iodide 6 and the trityl cation. Sulfenyl iodides are also postulated as intermediates in the iodine oxidation of thiols to disulfides. The disulfide bond is then formed by disproportionation of two sulfenyl iodides or by reaction between the electrophilic sulfur atom of R -S-I and the nucleophilic S-atom of a second R -S-Trt molecule. The proposed mechanism suggests that any sulfur substitution (i.e., thiol protecting group) capable of forming a stabilized species on cleavage, such as the trityl cation, can be oxidatively cleaved by iodine. 

A general procedure for the iodine reaction in the solid phase is shown in Scheme 9. Both Boc and Fmoc chemistry can be used to assemble the linear S-protected bis-cysteine peptides and for thiol protection the well-established Acm and Trt groups are usually used. Suitable solvents for the thiol-deprotection/oxidation step by iodine to form the disulfide are CH2C12, DMF, or aqueous AcOH. The final deblocking and cleavage from the resin is carried out under standard conditions. Modification at sensitive amino acid residues caused... 

Various p-amino thiols are synthesized from the corresponding P-amino alcohols 1 by activation of the hydroxy group to form a tosylate intermediate 2 and then conversion into a thioester 3 5 or direct thioacetylation of the hydroxy group of 1 using the Mitsunobu reaction with diisopropyl azodicarboxylate, triphenylphosphine, and thiolacetic acid as reagents (Scheme l). 6,7 The thioesters 3 are then hydrolyzed and the corresponding disulfide derivatives 4 are produced by iodine oxidation. 7 ... 

If the arsinic acid is sjmringly solutfie its sodium salt may be used, and with nitro-compounds tlie reaction is conducted in the cold to minimise rciduction of tlio nitro-group by the thiol-compound. The thioarsinites arc rccrystallised from hot water or dilute acetic acid, and may be estimated rajndly by direct titration with standard iodine solution ... 

Also the trityl group was applied for the masking of SH functions. The sulfides were prepared by the reaction of the thiol with trityl chloride (75% yield) or from trityl alcohol and the thiol in the presence of anhydrous TFA (85-90% yield). The cleavage of this group can be carried out under several conditions (Scheme 58). It is sensitive to acids (e.g. trifluoroacetic acid/ethanethiol 1 1) and to heavy metals. Thiocyanogen (SCN)2 oxidizes 5-trityl ethers to the disulfides and iodine converts 5-tritylcy -teine derivatives to cystine structures. 

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