Piscidins 1 and 3 (P1 and P3) are potent antimicrobial peptides isolated from striped bass. Their mechanism of action involves formation of amphipathic α-helices on contact with phospholipids and destabilization of the microbial cytoplasmic membrane. The peptides are active against both Gram-positive and Gram-negative bacteria, suggesting easy passage across the outer membrane. Here, we performed a comparative study of these two piscidins at the air–water interface on lipopolysaccharide (LPS) monolayers modeling the outer bacterial surface of Gram-negative organisms and on phospholipid monolayers, which mimic the inner membrane. The results show that P1 and P3 are highly surface active (log K AW ∼ 6.8) and have similar affinities to phospholipid monolayers (log K lip ≈ 7.7). P1, which is more potent against Gram negatives, exhibits a much stronger partitioning into LPS monolayers (log K LPS = 8.3). Pressure–area isotherms indicate that under increasing lateral pressures, inserted P1 repartitions from phospholipid monolayers back to the subphase or to a more shallow position with in-plane areas of ∼170 Å2 per peptide, corresponding to fully folded amphipathic α-helices. In contrast, peptide expulsion from LPS occurs with areas of ∼35 Å2, suggesting that the peptides may not form the similarly oriented, rigid secondary structures when they avidly intercalate between LPS molecules. Patch-clamp experiments on Escherichia coli spheroplasts show that when P1 and P3 reach the outer surface of the bacterial cytoplasmic membrane, they produce fluctuating conductive structures at voltages above 80 mV. The data suggests that the strong activity of these piscidins against Gram-negative bacteria begins with the preferential accumulation of peptides in the outer LPS layer followed by penetration into the periplasm, where they form stable amphipathic α-helices upon contact with phospholipids and attack the energized inner membrane.
is an enormous protein essential for hearing, balance, and proper eyesight. There are over 100 mutations in CDH23 that affect these processes with varying severity, some leading to deafness, balance disorders, and progressive blindness (Usher Syndrome). In the inner ear, CDH23 makes up the upper half of a proteinaceous filament known as the tip link, which is essential for hearing. Upon stimulation by sound or head movements, the tip link is stretched and conveys force to open the ion channels in the inner ear, thereby leading to the conversion of vibrational stimulus into electrical signals interpreted by the brain as sound. CDH23 is a non-classical cadherin with 27 extracellular cadherin (EC) repeats and a membrane adjacent domain (MAD28). The EC repeats are connected by a linker region containing highly conserved residues that bind calcium ions essential for tip-link function. Electron microscopy images suggest that CDH23 exists as a cis-homodimer within the tip link, however, the structural elements mediating this dimerization are not well determined. To better understand innerear mechanotransduction at the molecular level, we have solved high-resolution X-ray crystal structures of 18 CDH23 EC repeats along with 13 of the 26 EC linker regions (Jaiganesh et al., 2018). Here, we present several biochemical experiments that suggest potential sites of parallel dimerization on the extracellular domain of CDH23. Additionally, we present structures of various fragments of CDH23 allowing for closer analysis of deafness causing mutations. These results provide information on the cis-homodimerization of CDH23 and provide deeper insights about how mutations can result in inherited deafness.
Mechanosensitive channel MscS, the major bacterial osmolyte release valve, shows a characteristic adaptive behavior. With a sharp onset of activating tension, the channel population readily opens, but under prolonged action of moderate near-threshold tension, it inactivates. The inactivated state is non-conductive and tension-insensitive, which suggests that the gate gets uncoupled from the lipid-facing domains. The kinetic rates for tension-driven opening-closing transitions are 4-6 orders of magnitude higher than the rates for inactivation and recovery. Here we show that inactivation is augmented and recovery is slowed down by depolarization. Hyperpolarization, conversely, impedes inactivation and speeds up recovery. We then address the question of whether protein-lipid interactions may set the rates and influence voltage dependence of inactivation and recovery. Mutations of conserved arginines 46 and 74 anchoring the lipid-facing helices to the inner membrane leaflet to tryptophans do not change the closing transitions, but instead change the kinetics of both inactivation and recovery and essentially eliminate their voltage-dependence. Uncharged polar substitutions (S or Q) for these anchors produce functional channels but increase the inactivation and reduce the recovery rates. The data suggest that it is not the activation and closing transitions, but rather the inactivation and recovery pathways that involve substantial rearrangements of the protein-lipid boundary associated with the separation of the lipid-facing helices from the gate. The discovery that hyperpolarization robustly assists MscS recovery indicates that membrane potential can regulate osmolyte release valves by putting them either on the ‘ready’ or ‘standby’ mode depending on the cell’s metabolic state.
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