Menthols as Chiral Auxiliaries for Asymmetric Cycloadditive Oligomerization: Syntheses and Studies of ß-Proline Hexamers.

To produce a novel class of structurally ordered poly-ß-prolines, an emergent method for synthesizing chiral ß-peptide molecular frameworks was developed based on 1,3-dipolar cycloaddition chemistry of azomethine ylides. Functionalized short ß-peptides with up to six monomeric residues were efficiently synthesized in homochiral forms using a cycloadditive oligomerization approach. X-ray, NMR, and CD structural analyses of the novel ß-peptides revealed secondary structure features that were generated primarily by Z/E-ß-peptide bond isomerism. Anticancer in cellulo activity of the new ß-peptides toward hormone-refractory prostate cancer cells was observed and was dependent on the absolute configuration of the stereogenic centers and the chain length of the ß-proline oligomers.

Calcium ions inhibit reduction of heme a in bovine cytochrome c oxidase.

The effect of Ca(2+) on the rate of heme a reduction by dithionite and hexaammineruthenium (RuAm) was studied in the cyanide-complexed bovine cytochrome oxidase (CcO). The rate of heme a reduction is proportional to RuAm concentration below 300 µM with kv of 0.53×10(6) M(-1) s(-1). Ca(2+) inhibits the rate of heme a reduction by dithionite by ∼25%. As the reaction speeds up with increased concentrations of RuAm, the inhibition by Ca(2+) disappears. The inhibition of heme a reduction may contribute to recently described partial inhibition of CcO by Ca(2+) in the enzymatic assays. The inhibitory effect of Ca(2+) on heme a reduction indicates that ET through heme a may be coupled to proton movement in the exit part of the proton channel H.

Circular dichroism spectra of cytochrome c oxidase.

Circular dichroism spectra of bovine heart aa(3)-type cytochrome c oxidase have been studied with a major focus on the Soret band π → π* transitions, B(0(x,y)), in the two iron porphyrin groups of the enzyme. The spectra of the fully reduced and fully oxidized enzyme as well as of its carbon monoxide and cyanide complexes have been explored. In addition, CD spectra of the reduced and oxidized ba(3)-type cytochrome c oxidase from Thermus thermophilus were recorded for comparison. An attempt is made to interpret the CD spectra of cytochrome c oxidase with the aid of a classical model of dipole-dipole coupled oscillators taking advantage of the known 3D crystal structure of the enzyme. Simultaneous modeling of the CD and absorption spectra shows that in the bovine oxidase, the dipole-dipole interactions between the hemes a and a(3), although contributing significantly, cannot account either for the lineshape or the magnitude of the experimental spectra. However, adding the interactions of the hemes with 22 aromatic amino acid residues located within 12 Å from either of the two heme groups can be used to model the CD curves for the fully reduced and fully oxidized oxidase with reasonable accuracy. Interaction of the hemes with the peptide bond transition dipoles is found to be insignificant. The modeling indicates that the CD spectra of cytochrome oxidase in both the reduced and oxidized states are influenced significantly by interaction with Tyr244 in the oxygen-reducing center of the enzyme. Hence, CD spectroscopy may provide a useful tool for monitoring the redox/ionization state of this residue. The modeling confirms wide energy splitting of the orthogonal B(x) and B(y) transitions in the porphyrin ring of heme a.