NMR structure determination of a synthetic analogue of bacillomycin Lc reveals the strategic role of L-Asn1 in the natural iturinic antibiotics.

Iturins are a group of antifungal produced by Bacillus subtilis. All are cyclic lipopeptides with seven alpha-amino acids of configuration LDDLLDL and one beta-amino fatty acid. The bacillomycin L is a member of this family and its NMR structure was previously resolved using the sequence Asp-Tyr-Asn-Ser-Gln-Ser-Thr. In this work, we carefully examined the NMR spectra of this compound and detected an error in the sequence. In fact, Asp1 and Gln5 need to be changed into Asn1 and Glu5, which therefore makes it identical to bacillomycin Lc. As a consequence, it now appears that all iturinic peptides with antibiotic activity share the common beta-amino fatty acid 8-L-Asn1-D-Tyr2-D-Asn3 sequence. To better understand the conformational influence of the acidic residue L-Asp1, present, for example in the inactive iturin C, the NMR structure of the synthetic analogue SCP [cyclo (L-Asp1-D-Tyr2-D-Asn3-L-Ser4-L-Gln5-D-Ser6-L-Thr7-beta-Ala8)] was determined and compared with bacillomycin Lc recalculated with the corrected sequence. In both cases, the conformers obtained were separated into two families of similar energy which essentially differ in the number and type of turns. A detailed analysis of both cyclopeptide structures is presented here. In addition, CD and FTIR spectra were performed and confirmed the conformational differences observed by NMR between both cyclopeptides.

NMR reveals a novel glutaredoxin-glutaredoxin interaction interface.

Glutaredoxins (Grx) represent a large family of glutathione (GSH)-dependent oxidoreductases that catalyse the reduction of disulfides or glutathione mixed disulfide. Grx domains from pathogenic bacteria and plant Grxs have been recently reported to target specific peroxiredoxins (Prxs). The specificity that triggers the interaction between Grx and Prx is poorly understood and is only based on the structure of Haemophilus influenzae Prx-Grx hybrid (hyPrx5). We report here an NMR study of the Populus tremula Grx C4 that targets a P.tremula D-type II Prx. We show that Grx C4 specifically self-associates in a monomer-dimer equilibrium with an apparent K(d) of ca 2.6 mM. Grx C4 homodimer was docked under experimental restraints. The results reveal a novel Grx-Grx interface that is unrelated to the hyPrx5 Grx-Grx dimer interface. Chemical-shift perturbations and 15N spin-relaxation measurements show that the auto-association surface comprises both the active site and the GSH binding site. Reduced GSH is demonstrated to bind reduced Grx with a K(d) of ca 8.6 mM. The potential biological significance of the new Grx-Grx interaction interface is discussed.