Altered channel properties of porins from Haemophilus influenzae: isolates from cystic fibrosis patients.

Changes in amino-acid sequence of the unique pore-forming protein of H. influenzae (OmpP2; porin) have been associated with increased antimicrobial resistance in H. influenzae strains isolated from cystic fibrosis patients. From patients who were subjected to long-term antimicrobial therapy, H. influenzae strains 67d and 69a (patient 27) and strains 77a and 77f (patient 30) were isolated. Strains 67d and 77a were previously shown to have elevated values for minimal inhibitory concentrations of antibiotics compared to strains 69a and 77f. Porins were extracted from all four H. influenzae strains by detergent treatment and purified to homogeneity by ion exchange chromatography. By reconstitution of the clinical Hi porins into planar lipid bilayers, single-channel conductance, ionic selectivity, and voltage-gating characteristics were assessed. Porins 77a and 77f displayed similar single-channel conductance and ionic selectivity. Current-voltage relationships were determined for the different porins: porin 77f displayed substantial voltage gating at both positive and negative polarity; porin 77a gated at negative polarity only. Porins 67d and 69a showed substantial differences in their pore-forming properties: the single-channel conductance of porin 69a was significantly increased (1.05 nS) relative to porin 67d (0.73 nS). Porin 67d was twice as permeable to cations as porin 69a, and at both positive and negative polarities the extent of voltage gating was greater for porin 67d relative to porin 69a. Expression of the porins in an isogenic, porin-deleted H. influenzae background allowed for assessment of the contribution of each porin to the minimum inhibitory concentrations of various antimicrobial compounds. Porin 67d was found to have a decreased susceptibility to the antimicrobials novobiocin and streptomycin. This decreased susceptibility of porin 67d to novobiocin and streptomycin correlates with its decrease in single-channel conductance.

Mutagenesis identifies amino acid residues in extracellular loops and within the barrel lumen that determine voltage gating of porin from Haemophilus influenzae type b.

Porin (341 amino acids; M(r) 37 782) of Haemophilus influenzae type b mediates exchange of solutes between the external environment and the periplasm of this Gram-negative bacterium. Positively charged residues in the extracellular loops have been shown to be involved in the voltage gating of this protein. To further elucidate our observations on the functional properties of this channel, we mutated seven lysines (Lys(48), Lys(161), Lys(165), Lys(170), Lys(248), Lys(250), and Lys(253)) to glutamic acid. The selected residues were previously shown to be accessible to chemical modification, and they map to three locations: loop 4 and loop 6, and within the barrel lumen. The seven mutant proteins were purified, and each was reconstituted into planar lipid bilayers to characterize its channel forming properties. The single substitution mutant porins displayed increased single channel conductances in 1 M KCl ranging between 134 and 178% of the single channel conductance for wild-type Hib porin. Six of the seven mutant porins also displayed altered current-voltage relationships when compared to wild-type Hib porin. Whereas Lys(170)Glu had activity similar to wild-type Hib porin, Lys(48)Glu, Lys(248)Glu, and Lys(253)Glu showed substantial voltage gating at both positive and negative polarities. Lys(161)Glu and Lys(250)Glu gated only at negative potentials, and Lys(165)Glu gated only at positive potentials. Rather than ascribing one specific loop in gating, our analyses of these mutant Hib porins suggest that voltage gating can be attributed to contributions from loops 4 and 6 and a residue within the barrel lumen.

Charged residues in surface-located loops influence voltage gating of porin from Haemophilus influenzae type b.

Porin of Haemophilus influenzae type b (341 amino acids; M(r) 37782) determines the permeability of the outer membrane to low molecular mass compounds. Purified Hib porin was subjected to chemical modification of lysine residues by succinic anhydride. Electrospray ionization mass spectrometry identified up to 12 modifications per porin molecule. Tryptic digestion of modified Hib porin followed by reverse phase chromatography and matrix assisted laser desorption ionization time-of-flight mass spectrometry mapped the succinylation sites. Most modified lysines are positioned in surface-located loops, numbers 1 and 4 to 7. Succinylated porin was reconstituted into planar lipid bilayers, and biophysical properties were analyzed and compared to Hib porin: there was an increased average single channel conductance compared to Hib porin (1.24 +/- 0.41 vs. 0.85 +/- 0.40 nanosiemens). The voltage-gating activity of succinylated porin differed considerably from that of Hib porin. The threshold voltage for gating was decreased from 75 to 40 mV. At 80 mV, steady-state conductance for succinylated porin was 50-55% of the instantaneous conductance. Hib porin at 80 mV showed a decrease to 89-91% of the instantaneous current levels. We propose that surface-located lysine residues are determinants of voltage gating for porin of Haemophilus influenzae type b.