Site-directed mutagenesis of rat α-parvalbumin: replacement of canonical CD-site residues with their non-consensus counterparts from rat ß-parvalbumin.

Rat ß-parvalbumin (ß-PV) displays low divalent-ion affinity. Its CD site is distinguished by six non-consensus residues--the "CD-loop residues"--at positions 49, 50, 57-60. Additionally, leucine occupies position 85, rather than phenylalanine, the ß-lineage-consensus residue. Replacement of the CD-loop residues in rat ß with the canonical residues was previously found to have little effect on divalent-ion affinity, unless L85 is replaced by phenylalanine. Herein, we replace the canonical CD-loop residues in rat α-PV with their rat ß-PV counterparts. Although the mutations have a generally modest impact on affinity, E59D confers Ca(2+)-specificity on the CD site, in the presence or absence of the other mutations. Despite their minimal impact on ΔG, several CD-loop mutations markedly alter ΔH, evidently by perturbing the apo-protein conformation. The L85F mutation was also examined. In wild-type rat α, L85F increases EF-site Ca(2+) affinity. In the CD-loop variants, the mutation leaves the ΔG for Ca(2+)-binding largely unaffected. However, several variants display highly exothermic binding enthalpies, indicative of ligation-linked protein-folding. Consistent with that idea, scanning-calorimetry data confirm that L85F has significantly destabilized those proteins.

Chemical shift assignments of domain 4 from the phosphohexomutase from Pseudomonas aeruginosa suggest that freeing perturbs its coevolved domain interface.

A domain needed for the catalytic efficiency of an enzyme model of simple processivity and domain-domain interactions has been characterized by NMR. This domain 4 from phosphomannomutase/phosphoglucomutase (PMM/PGM) closes upon glucose phosphate and mannose phosphate ligands in the active site, and can modestly reconstitute activity of enzyme truncated to domains 1-3. This enzyme supports biosynthesis of the saccharide-derived virulence factors (rhamnolipids, lipopolysaccharides, and alginate) of the opportunistic bacterial pathogen Pseudomonas aeruginosa. (1)H, (13)C, and (15)N NMR chemical shift assignments of domain 4 of PMM/PGM suggest preservation and independence of its structure when separated from domains 1-3. The face of domain 4 that packs with domain 3 is perturbed in NMR spectra without disrupting this fold. The perturbed residues overlap both the most highly coevolved positions in the interface and residues lining a cavity at the domain interface.

Solution structures of polcalcin Phl p 7 in three ligation states: Apo-, hemi-Mg2+-bound, and fully Ca2+-bound.

Polcalcins are small EF-hand proteins believed to assist in regulating pollen-tube growth. Phl p 7, from timothy grass (Phleum pratense), crystallizes as a domain-swapped dimer at low pH. This study describes the solution structures of the recombinant protein in buffered saline at pH 6.0, containing either 5.0 mM EDTA, 5.0 mM Mg(2+), or 100 µM Ca(2+). Phl p 7 is monomeric in all three ligation states. In the apo-form, both EF-hand motifs reside in the closed conformation, with roughly antiparallel N- and C-terminal helical segments. In 5.0 mM Mg(2+), the divalent ion is bound by EF-hand 2, perturbing interhelical angles and imposing more regular helical structure. The structure of Ca(2+)-bound Phl p 7 resembles that previously reported for Bet v 4-likewise exposing apolar surface to the solvent. Occluded in the apo- and Mg(2+)-bound forms, this surface presumably provides the docking site for Phl p 7 targets. Unlike Bet v 4, EF-hand 2 in Phl p 7 includes five potential anionic ligands, due to replacement of the consensus serine residue at -x (residue 55 in Phl p 7) with aspartate. In the Phl p 7 crystal structure, D55 functions as a helix cap for helix D. In solution, however, D55 apparently serves as a ligand to the bound Ca(2+). When Mg(2+) resides in site 2, the D55 carboxylate withdraws to a distance consistent with a role as an outer-sphere ligand. (15)N relaxation data, collected at 600 MHz, indicate that backbone mobility is limited in all three ligation states.