While
antimicrobial peptides (AMPs) have been widely investigated
as potential therapeutics, high-resolution structures obtained under
biologically relevant conditions are lacking. Here, the high-resolution
structures of the homologous 22-residue long AMPs piscidin 1 (p1)
and piscidin 3 (p3) are determined in fluid-phase 3:1 phosphatidylcholine/phosphatidylglycerol
(PC/PG) and 1:1 phosphatidylethanolamine/phosphatidylglycerol (PE/PG)
bilayers to identify molecular features important for membrane destabilization
in bacterial cell membrane mimics. Structural refinement of 1H–15N dipolar couplings and 15N chemical
shifts measured by oriented sample solid-state NMR and all-atom molecular
dynamics (MD) simulations provide structural and orientational information
of high precision and accuracy about these interfacially bound α-helical
peptides. The tilt of the helical axis, τ, is between 83°
and 93° with respect to the bilayer normal for all systems and
analysis methods. The average azimuthal rotation, ρ, is 235°,
which results in burial of hydrophobic residues in the bilayer. The
refined NMR and MD structures reveal a slight kink at G13 that delineates
two helical segments characterized by a small difference in their
τ angles (<10°) and significant difference in their
ρ angles (∼25°). Remarkably, the kink, at the end
of a G(X)4G motif highly conserved among members of the
piscidin family, allows p1 and p3 to adopt ρ angles that maximize
their hydrophobic moments. Two structural features differentiate the
more potent p1 from p3: p1 has a larger ρ angle and less N-terminal
fraying. The peptides have comparable depths of insertion in PC/PG,
but p3 is 1.2 Å more deeply inserted than p1 in PE/PG. In contrast
to the ideal α-helical structures typically assumed in mechanistic
models of AMPs, p1 and p3 adopt disrupted α-helical backbones
that correct for differences in the amphipathicity of their N- and
C-ends, and their centers of mass lie ∼1.2–3.6 Å
below the plane defined by the C2 atoms of the lipid acyl chains.
Piscidins were the first antimicrobial peptides discovered in the mast cells of vertebrates. While two family members, piscidin 1 (p1) and piscidin 3 (p3), have highly similar sequences and α-helical structures when bound to model membranes, p1 generally exhibits stronger antimicrobial and hemolytic activity than p3 for reasons that remain elusive. In this study, we combine activity assays and biophysical methods to investigate the mechanisms underlying the cellular function and differing biological potencies of these peptides, and report findings spanning three major facets. First, added to Gram-positive (Bacillus megaterium) and Gram-negative (Escherichia coli) bacteria at sublethal concentrations and imaged by confocal microscopy, both p1 and p3 translocate across cell membranes and colocalize with nucleoids. In E. coli, translocation is accompanied by nonlethal permeabilization that features more pronounced leakage for p1. Second, p1 is also more disruptive than p3 to bacterial model membranes, as quantified by a dye-leakage assay and (2)H solid-state NMR-monitored lipid acyl chain order parameters. Oriented CD studies in the same bilayers show that, beyond a critical peptide concentration, both peptides transition from a surface-bound state to a tilted orientation. Third, gel retardation experiments and CD-monitored titrations on isolated DNA demonstrate that both peptides bind DNA but p3 has stronger condensing effects. Notably, solid-state NMR reveals that the peptides are α-helical when bound to DNA. Overall, these studies identify two polyreactive piscidin isoforms that bind phosphate-containing targets in a poised amphipathic α-helical conformation, disrupt bacterial membranes, and access the intracellular constituents of target cells. Remarkably, the two isoforms have complementary effects; p1 is more membrane active, while p3 has stronger DNA-condensing effects. Subtle differences in their physicochemical properties are highlighted to help explain their contrasting activities.
At first we were confused. The East thought that we were West, while the West considered us to be East. Some of us misunderstood our place in this clash of currents, so they cried that we belong to neither side, and others that we belong exclusively to one side or the other. But I tell you, Irinej, we are doomed by fate to be the East on the West, and the West on the East, to acknowledge only heavenly Jerusalem beyond us, and here on earth-no one.–St. Sava to Irinej, 13th centurySince the early 1980s, the crisis of Yugoslav society has been brought to public awareness through discussions in the mass media, both within Yugoslavia and outside of the country. While the causes of the crisis were initially analyzed within the framework of the ideology of Yugoslav self-management socialism, the past several years have seen increasing use by politicians and writers from the northwestern parts of the country of an orientalist rhetoric that relies for its force on an ontological and epistemological distinction between (north)west and (south)east
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