Macrocyclic statine-based inhibitors of BACE-1.

Minimal sequence requirements for binding of substrate-derived statine peptides to the aspartyl enzyme were established on the basis of the X-ray cocrystal structure of the hydroxyethylene-octapeptide OM00-3 in complexation with BACE-1. With this information to hand, macrocyclic compounds that conformationally restrict and preorganize the peptide backbone for an entropically favoured binding to the enzyme active site cleft were designed. By means of a side chain-to-side chain ring closure between two aspartyl residues in the P2 and P3' positions through phenylene-1,3-dimethanamine, a 23-membered ring structure was obtained; this structure retained an extended conformation of the peptide backbone, including the transition state analogue statine for tight interactions with the two aspartyl residues of the active centre. The conformational preorganization of the inhibitor molecule was verified by NMR structural analysis and was then confirmed by the crystal structure of the BACE-1/inhibitor complex. Detailed insights into the binding mode of this macrocyclic inhibitor explained its moderate binding affinity in cell-free assays (K(i)=2.5 microM) and yielded precious information for possible structural optimization in view of the lack of steric clashes of the macrocycle with the flap domain of the enzyme.

Aminoacyl-anthraquinone conjugates as telomerase inhibitors: synthesis, biophysical and biological evaluation.

The telomerase-telomere complex is a prospective anticancer target. To inhibit enzyme activity by induction of G-quadruplex in human telomeres, we have synthesized a small library of 2,6- and 2,7-amino-acyl/ peptidyl anthraquinones with diverse connecting linkers, charge, lipophilicity and bulk. The test compounds modulated G-quadruplex stability to different extents and showed clear preference for quadruplex over duplex DNA. Telomerase inhibition correlated with G-quadruplex stabilization. A SAR analysis showed that type of linkage between the linker and the anthraquinone, together with the position of the side chains and the nature of the amino acid components play a major role both in stabilizing G-quadruplex and producing telomerase inhibition. Short-term cytotoxic activity was poor. However, after prolonged exposure to effective G-quadruplex binders, cells became senescent. These results are of help in the rational design of more efficient G-quadruplex stabilizers, possibly endowed with cancer cell-selective antiproliferative effects.

Photocontrol of the collagen triple helix: synthesis and conformational characterization of bis-cysteinyl collagenous peptides with an azobenzene clamp.

For the photomodulation of the collagen triple helix with an azobenzene clamp, we investigated various collagenous peptides consisting of ideal (Gly-Pro-Hyp) repeats and containing cysteine residues in various positions for a side chain-to-side chain crosslink with a suitable chromophore derivative. Comparative conformational analysis of these cysteine peptides indicated an undecarepeat peptide with two cysteine residues located in the central portion in i and i+7 positions and flanked by (Gly-Pro-Hyp) repeat sequences as the most promising for the cross-bridging experiments. In aqueous alcoholic solution the azobenzene-undecarepeat peptide formed a stable triple helix in equilibrium with the monomeric species as a trans-azobenzene isomer, whereas photoisomerization to the cis isomer leads to unfolding of at least part of the triple helix. Furthermore, the residual supercoiled structure acts like an intermolecular knot, thus making refolding upon cis-to-trans isomerization a concentration-independent fast event. Consequently, these photoswitchable collagenous systems should be well suited for time-resolved studies of folding/unfolding of the collagen triple helix under variable thermodynamic equilibria.

Copper binding and conformation of the N-terminal octarepeats of the prion protein in the presence of DPC micelles as membrane mimetic.

The prion protein is usually pictured as globular structured C-terminal domain that is linked to an extended flexible N-terminal tail. However, in its physiological form, it is a glycoprotein tethered to the cell surface via a C-terminal GPI anchor. The low solubility of PrP even without GPI anchor and its strong tendency for aggregation has forced most structural investigations to be performed at low pH and mostly with N-terminally truncated variants. In the present study, we have used a synthetic peptide related to the PrP tetra-octarepeat region, i.e., the sequence (Pro-His-Gly-Gly-Gly-Trp-Gly-Gln)(4), for NMR structural analysis of its preferred conformation in DPC micelles as membrane mimic. Well-defined and identical loops are observed between the four octarepeats that are linked by flexible Gly-Gly-Gly sequences. Interaction with the micelles is mainly through the tryptophan residues that appear to act as anchors. Copper binding to the peptide in the presence of DPC micelles revealed marked conformational rearrangements although binding to the micelles is preserved. Interestingly, titration experiments point to cooperative effects for the four binding sites. A destabilization of the DPC micelles by the peptide parallels the destabilizing effect of the prion protein on membranes so that the octarepeat region appears to be very membrane-active. How the physico-chemical properties reported here are linked to the function and significance of the prion protein remains a puzzle as long as the functional mechanism of the prion protein is not precisely elucidated. Nevertheless, our results emphasize the strong influence of the (membrane) environment on the PrP properties.

The Tim21 binding domain connects the preprotein translocases of both mitochondrial membranes.

Proteins destined for the mitochondrial matrix are imported by the translocase of the outer membrane--the TOM complex--and the presequence translocase of the inner membrane--the TIM23 complex. At present, there is no structural information on components of the presequence translocase. Tim21, a subunit of the presequence translocase consisting of a membrane anchor and a carboxy-terminal domain exposed to the intermembrane space, directly connects the TOM and TIM23 complexes by binding to the intermembrane space domain of the Tom22 receptor. We crystallized the binding domain of Tim21 of Saccharomyces cerevisiae and determined its structure at 1.6 A resolution. The Tim21 structure represents a new alpha/beta-mixed protein fold with two alpha-helices flanked by an extended eight-stranded beta-sheet. We also identified a core sequence of Tom22 that binds to Tim21. Furthermore, negatively charged amino-acid residues of Tom22 are important for binding to Tim21. Here we suggest a mechanism for the TOM-TIM interaction.