Nuclear magnetic resonance studies of the acid–base chemistry of amino acids and peptides. IV. Mixed disulfides of cysteine, penicillamine, and glutathione

Theriault, Yvon; Cheesman, Bruce V.; Arnold, Arthur P.; Rabenstein, Dallas L.

doi:10.1139/v84-220

Cited by 16 publications

(6 citation statements)

References 12 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Protonation constants of GSSG (Scheme ) were obtained by potentiometry at four temperature values, 19, 25, 30, and 37 °C, to enable calculations of thermochemical parameters of protonation phenomena. These constants are presented in Table and are in good agreement with the previous determinations at 25 °C ,− and at 37 °C. , The constants determined at 25 °C were published previously in our study on Ni(II) complexes of GSNO and GSSG . A reliable determination of the sixth most acidic constant by potentiometry was impossible under our experimental conditions.…”

Section: Resultssupporting

confidence: 91%

“…Values of protonation macroconstants of GSSG, as mentioned above, agree well with those determined previously. ,,,, The value of p K 6 , determined by NMR, is in excellent agreement with the most recent reports. , This value is lower than a practical acidic limit for determinations using pH-metric titrations of millimolar compounds, ca. 2.0.…”

Section: Discussionsupporting

confidence: 90%

See 1 more Smart Citation

Zn(II) Complexes of Glutathione Disulfide: Structural Basis of Elevated Stabilities

et al. 2010

View full text Add to dashboard Cite

Glutathione disulfide (GSSG), a long disregarded redox partner of glutathione (GSH), is thought to participate in intracellular zinc homeostasis. We performed a concerted potentiometric and NMR spectroscopic study of protonation and Zn(II) binding properties of GSSG ((γECG)(2)) and a series of its nine analogs with C-terminal modifications, tripeptide disulfides: (γECS)(2), (γECE)(2), (γECG-NH(2))(2), (γECG-OEt)(2), and (γEcG)(2); dipeptide disulfides, (γEC)(2) and (γEC-OEt)(2); and mixed disulfides, γECG-γEC and γECG-γEC-OEt. The acid-base and Zn(II) complexation properties in this group of compounds are strictly correlated to average C-terminal electrostatic charges. In particular, it was demonstrated that GSSG assumes a bent (head-to-tail) conformation in solution at neutral pH, which is controlled by electrostatic attraction between the protonated γ-amino groups of the Glu residue and the deprotonated C-terminal Gly carboxylates. This interaction modulates the ability of GSSG to coordinate Zn(II), both indirectly, by affecting the basicities of the amino groups, and directly, through the participation of the Gly carboxylates in the outer coordination sphere of the Zn(II) ion. A specific coiled structure of the major [Zn-GSSG](2-) complex is additionally stabilized by the formation of hydrogen bonds between glycinyl carboxylates and two Zn(II)-coordinated water molecules. The elevated stability of Zn(II)-GSSG complexes was demonstrated by competition with FluoZin-3, a fluorescent sensor with high Zn(II) affinity, commonly used in in vitro and in vivo studies. The potential biological functions and reactivity of GSSG complexes of Zn(II) ions are discussed.

show abstract

Section: Resultssupporting

confidence: 91%

Section: Discussionsupporting

confidence: 90%

Zn(II) Complexes of Glutathione Disulfide: Structural Basis of Elevated Stabilities

et al. 2010

View full text Add to dashboard Cite

show abstract

“…The exchange-averaged 'H resonances observed for solutions containing selenol and diselenide are in sharp contrast with the separate resonances observed for thiol and for disulfide in both 'H and I3C spectra of solutions containing thiol and disulfide (18)(19)(20), indicating that selenol/diselenide exchange is much faster than thiol/disulfide exchange.…”

Section: Discussionmentioning

confidence: 63%

“…By analogy with results from 'H and 13C nmr studies of thiol/disulfide exchange reactions (18)(19)(20), we expected to observe separate resonances for selenol and diselenide. However, 'H resonances were either broadened or exchange-averaged, depending on pH and the relative concentrations of selenol and diselenide, and 77Se resonances could not be detected for selenol/diselenide mixtures.…”

Section: Diselenidesmentioning

confidence: 56%

Selenium-77 nuclear magnetic resonance studies of selenols, diselenides, and selenenyl sulfides

Tan¹,

Arnold²,

Rabenstein³

1988

Can. J. Chem.

Self Cite

View full text Add to dashboard Cite

KHOON-SIN TAN, ALAN P. ARNOLD, and DALLAS L. RABENSTEIN. Can. J. Chem. 66, 54 (1988).77Se and 'H nuclear magnetic resonance spectra have been measured for selenols (RSeH), diselenides (RSeSeR), and selenenyl sulfides (RSeSR'), including selenenyl sulfides formed by reaction of glutathione and penicillamine with selenocystine and related diselenides. Exchange processes strongly affect the 77Se and 'H nuclear magnetic resonance spectra of all three classes of compounds. Sharp, exchange-averaged resonances are observed in the 'H nuclear magnetic resonance spectra of selenols; however, selenol proton exchange causes the 77Se resonances to be extremely broad over the pH range where the selenol group is titrated. Selenol/diselenide exchange he^ + RSeSeR K S~S~R + RSeH) also results in exchange-averaged 'H resonances for solutions containing RSeH and RSeSeR; however, the 77Se resonances were too broad to detect. Exchange reactions have similar effects on nuclear magnetic resonance spectra of solutions containing selenols and seleneny l sulfides. The results indicate selenol/diselenide exchange is much faster than thiol/disulfide exchange. The 77Se chemical shift depends on the chemical state of the selenium, e.g., titration of the selenol group of selenocysteamine causes the 77Se resonance to be shielded by 164 ppm, oxidation of.th+e selenol to form the diselfnide selenocystamine causes a deshielding of 333 ppm, and oxidation to form the selenenyl sulfide H3NCH2CH2SeSCH2CH2NH3 results in a deshielding of 404 ppm. 77Se chemical shifts were found to be in the range -240 to -270 ppm (relative to (CH3)2Se) for selenolates, approximately -80 ppm for selenols, 230-360 ppm for diselenides, and 250-340 ppm for selenenyl sulfides. The 77Se chemical shift is also affected by titration of neighboring carboxylic acid and ammonium groups, and their pKA values can be calculated from 77Se chemical shift data. On a dCterminC les spectres en resonance magnCtique nuclkaire du 7 7~e et du 'H de sClCnols (RSeH), de disClCnures (RSeSeR) et de disulfures de sClCnCnyles (RSeSR'), y compris des sulfures de sClCnCnyles qui se foment au cours de la reaction du glutathion et de la pCnicillamine avec la sClCnocystCine et des disClCnures apparentks. Les processus d'kchange affectent beaucoup les spectres en resonance magnCtique nuclCaire du 77Se et du 'H de ces trois classes de composCs. Avec les sCICnols, les spectres en resonance magnCtique nucleaire du 'H prCsentent des raies bien dCfinies qui rCsultent de moyennes; toutefois, 1'Cchange du proton du sClCnol fait que les rCsonances du 77Se sont extremement larges 1 tous les pH oC1 le groupement sClCnol peut Stre titrC. Dans le cas des solutions qui contiennent du RSeH et du RSeSeR, 1'Cchange sC1Cnol/disC1Cnure (R*SeH + RSeSeR R*SeSeR + RSeH) conduit aussi 1 des rksonances du 'H qui resultent de moyennes; toutefois, les rCsonances du 77Se sont trop Clargies pour &tre dCtectCes. Les rCactions d'Cchange ont des effets semblables sur les spectres en resonance magnktique nucl~airede solutions contena...

show abstract

“…4.4ppm) (Lift et al, 1996). A characteristic feature (Theriault et al, 1984;Calcagni et al, 1996) of the 13C-NMR spectrum of 6 is represented by the resonances of the two Cys fl-carbon atoms (28.15 and 28.80 vppm) which are shifted at higher field as compared with the corresponding atoms in the disulfde precursor 5 (49.92 and 45.77 6 ppm). The electrospray mass spectrum (ES-MS) of 5 shows the formation of both M + H + and 2M + H + species.…”

Section: Resultsmentioning

confidence: 99%

Novel glutathione analogues containing the dithiol and disulfide form of the Cys-Cys dyad

Calcagni

Lucente²,

Luisi³

et al. 1999

Amino Acids

View full text Add to dashboard Cite

show abstract

Nuclear magnetic resonance studies of the acid–base chemistry of amino acids and peptides. IV. Mixed disulfides of cysteine, penicillamine, and glutathione

Cited by 16 publications

References 12 publications

Zn(II) Complexes of Glutathione Disulfide: Structural Basis of Elevated Stabilities

Zn(II) Complexes of Glutathione Disulfide: Structural Basis of Elevated Stabilities

Selenium-77 nuclear magnetic resonance studies of selenols, diselenides, and selenenyl sulfides

Novel glutathione analogues containing the dithiol and disulfide form of the Cys-Cys dyad

Contact Info

Product

Resources

About