Role of metals in the reaction catalyzed by protein farnesyltransferase.

Protein farnesyltransferase catalyzes the posttranslational farnesylation of several proteins involved in signal transduction, including Ras, and is a target enzyme for antitumor therapies. Efficient product formation catalyzed by protein farnesyltransferase requires an enzyme-bound zinc cation and high concentrations of magnesium ions. In this work, we have measured the pH dependence of the chemical step of product formation, determined under single-turnover conditions, and have demonstrated that the prenylation rate constant is enhanced by two deprotonations. Substitution of the active site zinc by cadmium demonstrated that one of the ionizations reflects deprotonation of the metal-coordinated thiol of the peptide "CaaX" motif, pK(a1) = 6.0. These data provide additional evidence for the direct involvement of a metal-coordinated sulfur nucleophile in catalysis. The second ionization was assigned to a hydroxyl on the pyrophosphate moiety of farnesyl pyrophosphate, pK(a2) = 7.4. Deprotonation of this group is important for binding of magnesium. This second ionization is not observed for catalysis in the absence of magnesium or when the substrate is farnesyl monophosphate. These data indicate that the maximal rate constant for prenylation requires formation of a zinc-coordinated thiolate nucleophile and enhancement of the electrophilic character at C1 of the farnesyl chain by magnesium ion coordination of the pyrophosphate leaving group.

Biophysical characterization of betabellin 16D: a beta-sandwich protein that forms narrow fibrils which associate into broad ribbons.

The betabellin structure is a de novo designed beta-sandwich protein consisting of two 32-residue beta sheets packed against one another by hydrophobic interactions. Betabellin 16S (B16S), a 32-residue peptide chain (HSLTAKIakLTFSIAahTYTCAVakYTAKVSH, where a is DAla, h is DHis, and k is DLys), did not have beta structure in water at pH 6.5. Air oxidation of B16S furnished betabellin 16D (B16D), a 64-residue disulfide-bridged two-chain protein, which also did not fold in water at pH 6.5. However, the extent of beta structure observed for B16D increased with pH and ionic strength of the solution and the B16D concentration as observed by circular dichroism spectropolarimetry. Transmission electron microscopy showed that B16D formed narrow fibrils that associated into broad ribbons in 5.0 mM Mops and 0.25 M NaCl at pH 6.9.

Metal-ion binding and limited proteolysis of betabellin 15D, a designed beta-sandwich protein.

Betabellin 15D is a 64-residue, disulfide-bridged homodimer. When folded into a beta structure, the protein is predicted to have two clusters of three histidine residues, each cluster able to bind a divalent metal ion. When the protein was incubated with Cu2+, Zn2+, Co2+, or Mn2+, metal complexes of betabellin 15D were observed by electrospray-ionization mass spectrometry. The relative abundances of the ionic complexes suggested an order of affinities of Cu2+ > Zn2+ > Co2+ > Mn2+, consistent with solution-phase affinities for nitrogen- or sulfur-containing ligands. Limited proteolysis of betabellin 15D by immobilized pepsin, as measured by nanoelectrospray-ionization mass spectrometry, showed that the Phe12-Ser13 peptide bond of betabellin 15D was cleaved more slowly in the presence of Cu2+ than in its absence. Because Cu2+ has little or no effect on the catalytic rate of pepsin, the slower cleavage of the Phe12-Ser13 peptide bond may be due to its decreased accessibility caused by Cu(2+)-induced folding of betabellin 15D.

Engineering of betabellin-15D: a 64 residue beta sheet protein that forms long narrow multimeric fibrils.

The betabellin target structure is a beta-sandwich protein consisting of two 32 residue beta-sheets packed against one another by interaction of their hydrophobic faces. The 32 residue chain of betabellin-15S (HSLTAKIpkLTFSIAphTYTCAV pkYTAKVSH, where p=DPro, k=DLys, and h=DHis) did not fold in water at pH 6.5. Air oxidation of betabellin-15S provided betabellin-15D, the 64 residue disulfide bridged two-chain molecule, which also remained unfolded in water at pH 6.5. By circular dichroic spectropolarimetry, the extent of beta structure observed for betabellin-15D increased with the pH and ionic strength of the solution and the betabellin-15D concentration. By electron microscopy, in 5.0 mM MOPS and 0.25 M NaCl at pH 6.9, betabellin-15D formed long narrow multimeric fibrils. A molecular model was constructed to show that the dimensions of these betabellin-15D fibrils are consistent with a single row of beta-sandwich molecules joined by multiple intersheet H-bonds.

Photochemical energy conversion in a helical oligoproline assembly.

A general method is described for constructing a helical oligoproline assembly having a spatially ordered array of functional sites protruding from a proline-II helix. Three different redox-active carboxylic acids were coupled to the side chain of cis-4-amino-L-proline. These redox modules were incorporated through solid-phase peptide synthesis into a 13-residue helical oligoproline assembly bearing in linear array a phenothiazine electron donor, a tris(bipyridine)ruthenium(II) chromophore, and an anthraquinone electron acceptor. Upon transient 460-nm irradiation in acetonitrile, this peptide triad formed with 53% efficiency an excited state containing a phenothiazine radical cation and an anthraquinone radical anion. This light-induced redox-separated state had a lifetime of 175 ns and stored 1.65 eV of energy.