Eurico J. Cabrita

This paper describes for the first time the intimate molecular details of the association between a platinated oligonucleotide and a zinc-finger peptide. Site-specific platination of the guanine in a ss hexanucleotide gave {[Pt(dien)d(5’-TACGCC-3’)], Pt(dien)(6-mer)}, II, characterized by mass spectrometry and 1H-NMR spectroscopy. The work extends the study of platinum-nucleobase complex-zinc finger interactions using small molecules such as [Pt(dien)(9-EtGua)]2+, I . The structure of the (34-52) C-terminal finger of the HIV nucleocapsid protein HIVNCp7 (ZF1) was characterized by 1H-NMR spectroscopy and compared with that of the N-terminal single finger and the 2-finger “intact” NCp7. Interaction of II with ZF1 results in significant changes in comparison to the “free” uncomplexed hexanucleotide – the major shifts occur for Trp37 resonances are broadened and shifted upfield and other major shifts are for Gln45 (H21, H3, Q), Met46 (NH, H2), Lys47 (NH, Q) and Glu50 (H2, H3). The Zn-Cys/His chemical shifts show only marginal deviations. The solution structure of ZF1, the 6-mer/ZF1 and II/ZF1 adducts were calculated from the NOESY-derived distance constraints. The DNA position in II/ZF1 is completely different than in the absence of platinum. Major differences are the appearance of new Met46-Cyt6H5 and Trp37-Cyt5H5 contacts but severe weakening of the Trp37-Gua4 contact, attributed to the steric effects caused by Gua4 platination, accompanied by a change in the position of the aromatic ring. The results demonstrate the feasibility of targetting specific ZF motifs with DNA-tethered coordination compounds, such as Pt compounds and Co-macrocycles – with implications for drug targetting and indeed the intimate mechansims of DNA repair of platinated DNA.

The function of prion-like protein Doppel was suggested to be related to male fertility. In this study, the importance of ovine Doppel polypeptide on spermatozoa capacitation and fertilization was evaluated. After refolding, recombinant Doppel (rDpl) was supplemented with different concentrations (40, 80 or 190 ng/ml) to ovine spermatozoa during the capacitation process. In experiment 1, post-thawed ovine spermatozoa were incubated with different concentrations of rDpl during 1 h for swim-up, and changes in sperm motility, concentration, vigour, viability and capacitation were monitored (10 replicates). In experiment 2, the fertilization ability of post-swim-up spermatozoa incubated as above was tested through heterologous fertilization of bovine in vitro matured oocytes (n = 423, three replicates). Regardless of dosage, rDpl improved (p = 0.03) spermatozoa viability. Sperm individual motility and vigour were the highest (p = 0.04) for the group receiving 190 ng/ml rDpl. Sperm supplemented with the highest doses of rDpl achieved higher (p = 0.02) fertilization rates (56.0 +/- 3.0%) than control (39.1 +/- 2.2%) and 40 ng/ml rDpl (39.8 +/- 2.7%). Preliminary data suggest that Doppel protein may enhance in vitro spermatozoa fertilizing ability.

The preferential binding of anions and cations in aqueous solutions of the ionic liquids (ILs) 1-butyl- 3-methylimidazolium ([C₄mim]⁺) and 1-ethyl-3-methylimidazolium ([C₂mim]⁺) chloride and dicyanamide (dca^-) with the small alpha-helical protein Im7 was investigated using a combination of differential scanning calorimetry, NMR spectroscopy and molecular dynamics (MD) simulations. Our results show that direct ion interactions are crucial to understand the effects of ILs on the stability of proteins and that an anion effect is dominant. We show that the binding of weakly hydrated anions to positively charged or polar residues leads to the partial dehydration of the backbone groups, and is critical to control stability, explaining why dca^- is more denaturing than Cl^-. Direct cation–protein interactions also mediate stability; cation size and hydrophobicity are relevant to account for destabilisation as shown by the effect of [C₄mim]⁺ compared to [C₂mim]⁺. The specificity in the interaction of IL ions with protein residues established by weak favourable interactions is confirmed by NMR chemical shift perturbation, amide hydrogen exchange data and MD simulations. Differences in specificity are due to the balance of interaction established between ion pairs and ion-solvent that determine the type of residues affected. When the interaction of both cation and anion with the protein is strong the net result is similar to a non-specific interaction, leading ultimately to unfolding. Since the nature of the ions is a determinant of the level of interaction with the protein towards denaturation or stabilisation, ILs offer a unique possibility to modulate protein stabilisation or even folding events.