The influence of acid−base interactions on the gas-phase dissociation of a series of protonated peptides was investigated. Peptides containing both acidic residues [aspartic (D), glutamic (E), and cysteic acid (C*)] and basic residues [arginine (R)] were dissociated by different activation methods that allow different time frames for dissociation. The synthetic peptides investigated differ systematically in the number and position of arginine residue(s) and include R LDIFSDF R , R LEIFSEF R , R LDIFSDF, LDIFSDF R , LEIFSEF R , LDIFSDF, R LCIFSCF R , R LAIFSCF R , R LCIFSAF R , R LC*IFSC*F R , R LAIFSC*F R , and R LC*IFSAF R (where C* denotes cysteic acid). It was observed that the number of ionizing protons relative to the number of basic residues in peptides containing acidic residues is a contributing factor in the fragmentation behavior. Nonselective cleavages along the peptide backbone occur when the number of ionizing protons exceeds the number of arginine residues, while dominant cleavages adjacent to the acidic residues predominate when the number of ionizing protons equals the number of arginine residues. In particular, enhanced b7/y2, and y6, y2 singly charged fragment ions were detected for the doubly protonated R LDIFSDF R and singly protonated LDIFSDF R precursor ions, respectively. These are the result of enhanced cleavage of the DF bond in the doubly protonated R LDIFSDF R and the DI plus DF bonds in the singly protonated LDIFSDF R . Abundant d and b-H2SO3 product ions indicative of specific cleavages adjacent to C* were observed in the cysteic acid-containing peptides when the number of ionizing protons equaled the number of arginine residues. Dominant cleavages at glutamic acid(s) were also observed for doubly protonated R LEIFSEF R and singly protonated LEIFSEF R when longer dissociation times were available. Preferential cleavage(s) at the acidic residue(s) occurs on the microsecond time scale for aspartic acid and greater than microsecond time scale for glutamic acid. This different behavior for aspartic vs glutamic acid is likely to have important implications in mass spectrometry-based sequencing strategies. However, the product ion spectra of most of the peptides investigated ( R LDIFSDF R , R LDIFSDF, LDIFSDF R , LEIFSEF R , and LDIFSDF) were found to be very similar under the array of activation methods used. These included surface-induced dissociation in a quadrupole tandem mass spectrometer, high-energy collision-induced dissociation in a hybrid sector/time-of flight mass spectrometer, and sustained off-resonance irradiation in a Fourier transform mass spectrometer. The unique fragmentation of peptides containing basic and acidic residues is rationalized as evidence for the existence of gas-phase intramolecular solvation that strongly influences their fragmentation. We propose that it is the available acidic proton(s) on the acidic residue(s) not involved in solvating the protonated arginine that is initiating the dominant cleavage(s). Electrospray ionization/SID frag...
A Mechanistic Investigation of the Enhanced Cleavage at Histidine in the Gas-Phase Dissociation of Protonated Peptides
Enhanced gas-phase cleavage of peptides adjacent to histidine was investigated. The peptides examined were angiotensins III (RVYIHPF) and IV (VYIHPF) as well as synthetic peptide analogues with altered key residues ((R)VYI-X-Z-F; X = F or H and Z = A, P, or Sar) or a fixed charge M3P(+)CH(2)C(O)-VYIHPF. While all singly protonated peptide ions containing both histidine and arginine fragment nonselectively, the doubly protonated peptide ions with arginine and histidine, and the singly protonated peptides containing histidine but not arginine, cleave in a selective manner. In particular, dominant complementary b+/y+ product ions resulting from cleavage between the HP amide bond are observed. For the fixed-charge derivative, selective cleavage occurs only if a proton is added to produce a doubly charged precursor. The results are consistent with involvement of a protonated histidine in the selective cleavage. The ratio of b+/y+ is determined by the identity of the residue C-terminal to histidine and by the ability of protonated histidine to transfer a proton to the C-terminal leaving fragment. This was probed further by systematically changing the residue C-terminal to histidine and by alkylating histidine. The results indicate that while b+/y+ complementary ion pairs dominate in doubly protonated RVYIHPF, b5(2+) and b6(2+) product ions dominate the spectra of doubly protonated RVYIHAF. Also, dominant b5(2+) product ions are observed when the histidine side chain is alkylated (H) in doubly protonated RVYIHPF. Based on all of the results, a selective fragmentation mechanism for enhanced cleavage at histidine involving an atypical b ion structure is proposed.
Molecular Design of Single Site Catalyst Precursors for the Ring-Opening Polymerization of Cyclic Ethers and Esters. 2. Can Ring-Opening Polymerization of Propylene Oxide Occur by a Cis-Migratory Mechanism?
From the reactions between 2,2′-ethylidenebis(4,6-di-tert-butylphenol) and 2,2′-methylidenebis(4-dimethyl-6-di-tert-butylphenol) and Et 2AlCl the biphenoxide complexes [(O∼∼CHMe∼∼O)AlCl]2, 1, and [(O∼∼CH2∼∼O)AlCl]2, 2, have been isolated and characterized. These dimers are broken up by donor ligands, and the molecular structure of ethylidenebis(4,6-di-tert-butylphenoxide)AlCl(THF), 3, has been structurally characterized. Racemic 5,5′-6,6′-tetramethyl-3,3′-di-tert-butyl-1,1′-biphen-2,2′-diol and Et2AlCl react in hexane to give [(O∼∼O)AlCl]2, compound 6, as a hydrocarbon insoluble white precipitate. In the donor solvent THF monomeric species are formed, and (O∼∼O)AlX(THF) has been crystallographically characterized, X ) 20% Cl and 80% Et occupancy. Refluxing in THF favors X ) Cl, compound 4. The reaction of Et2Al(OEt) with the biphenol gives (O∼∼O)AlEt(THF), 5, in the presence of THF by displacement of one ethyl and one ethoxide ligand. Compounds 1, 2, 3, 4, 5, 6, [(O∼∼CHMe∼∼O)Al-(O i Pr-d7)]2, and [Cp2Zr(OEt)(OEt2)] + [HB(C6F5)3]act as propylene oxide, PO, polymerization catalyst precursors. The polymers have been examined by MS techniques and NMR spectroscopy, and these results are compared with polypropylene oxide, PPO, formed by base catalysis and by porphyrin-and salen-AlCl catalyst precursors. The new Al compounds and the cationic zirconium alkoxide give close to 50:50 HH to TT junctions with end groups C-Cl, OH, and )CH 2 being identified by MS and NMR. Polymerizations employing [(O∼∼CHMe∼∼O)Al(O i Pr-d7)]2 give HO-(PO)n-O i Pr-d7 oligomers, in addition to vinylterminated species. Polymerization of S-PO and 50:50 mixtures of S-PO and rac-PO reveals that the stereoirregular polymer is formed by a stereoselective ring-opening step. An analysis of the HH and TT junctions at the triad level is made, extending the earlier assignments of Tonelli and Schilling. This analysis leads us to suggest that polymerization occurs by a cationic coordinate mechanism wherein ring opening occurs by backside attack on an activated PO molecule which leads to inversion at the methine carbon. The rac-biphenoxide-Al complexes show a preference for ii and i linkages in (HT)(HT)(HT) units. These results are compared to coordinate catalysis polymerizations of PO employing the Union Carbide calcium amide-alkoxide system and (porphyrin)AlCl and lead us to predict that a cis-migratory ringopening polymerization process is not likely to be developed for polymerization of PO. † Dedicated to Dr. Walter Reichle, Corporate Research Fellow, Union Carbide, on the occasion of his retirement. * Corresponding author. E-mail Chisholm@chemistry. ohio-state.edu.
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