The amyloidoses consist of human and animal chronic, progressive, and sometimes fatal diseases that are characterized by the deposition of insoluble proteinaceous amyloid fibrils in various tissues. Despite the biochemical diversity of amyloids, they share certain properties. The amphipathic and the charged nature of many amyloid-forming peptides point to their intrinsic ability to form diverse beta-sheet-based aggregates and channel types in negatively charged membranes. We hypothesize that the formation of heterogeneous channels represents a common cytotoxic mechanism that accentuates the changes in the signal transduction that underlie amyloid-induced cell malfunction. One group of amyloid-forming peptides that could mediate their action via the formation of heterogeneous channels includes the extensively examined prions and amyloid beta protein that are associated with conformational neurodegenerative diseases. The aim of this study is to examine heterogeneous channels formed in bilayers with amyloid-forming peptides as a common mechanism of malfunction of signal transduction. The observed amyloid-formed channel types include the following. (1) Natriuretic peptides: (i) 68-pS H2O2- and Ba2+-sensitive channel with fast kinetics. The fast channel had three modes (spike mode, burst mode, and open mode), which differ in their kinetics but not in their conductance properties; (ii) a 273-pS inactivating large conductance channel; and (iii) a 160-pS transiently activated channel. (2) Prions: (i) a 140-pS GSSG- and TEA-sensitive channel with fast kinetics; (ii) a 41-pS dithiothreitol (DTT)-sensitive channel with slow kinetics; (iii) a 900 to 1444-pS large channel. (3) Amyloid beta protein: (i) a 17 to 63-pS AbetaP[1-40]-formed "bursting" fast cation channel, (ii) the AbetaP[1-40]-formed "spiky" fast cation channel with a similar kinetics to the "bursting" fast channel except for the absence of the long intraburst closures, (iii) 275-pS AbetaP[1-40]-formed medium conductance channel, and (iv) 589- to 704-pS AbetaP[1-40]-formed inactivating large conductance channel. This heterogeneity is one of the most common features of these charged cytotoxic amyloid-formed channels, reflecting these channels' ability to modify multiple cellular functions. Although the diversity of these aggregated-peptide-formed channels may indicate that a stochastic mechanism governs their formation, the fact that certain channel types are often observed point to preferential channel protein conformations. In addition, the fact that other amyloids have similar structural properties (e.g. hydrophobicity, charged residues, and beta-structural linkages, suggests that, despite the intrinsic ability to form diverse conformations, certain conformations and, hence, certain channel types could be a common pathologic conformation among these amyloid-forming peptides. It is concluded that conformation-based channel diversity is an important mechanism for enhancing the toxicity of amyloid-forming peptides. The cytotoxic nature of these self-associated beta...
1. The lipid bilayer technique was used to characterize the biophysical and pharmacological properties of several ion channels formed by incorporating amyloid beta protein fragment (AbetaP) 1-40 into lipid membranes. Based on the conductance, kinetics, selectivity, and pharmacological properties, the following AbetaP[1-40]-formed ion channels have been identified: (i) The AbetaP[1-40]-formed "bursting" fast cation channel was characterized by (a) a single channel conductance of 63 pS (250/50 mM KCl cis/trans) at +140 mV. 17 pS (250/50 mM KCl cis/trans) at -160 mV, and the nonlinear current-voltage relationship drawn to a third-order polynomial, (b) selectivity sequence PK > PNa > PLi = 1.0:0.60:0.47, (c) Po of 0.22 at 0 mV and 0.55 at +120 mV, and (d) Zn2+-induced reduction in current amplitude, a typical property of a slow block mechanism. (ii) The AbetaP[1-40]-formed "spiky" fast cation channel was characterized by (a) a similar kinetics to the "bursting" fast channel with exception for the absence of the long intraburst closures, (b) single channel conductance of 63 pS (250/50 KCl) at +140 mV 17 pS (250/50 KCl) at -160 mV, the current-voltage relationship nonlinear drawn to a third-order polynomial fit, and (c) selectivity sequence PRb > (iii) The AbetaP[1-40]-formed medium conductance channel was charcterized by (a) 275 pS (250/50 mM KCl cis/trans) at +140 mV and 19 pS (250/50 mM KCl cis/trans) at -160 mV and (b) inactivation at Vms more negative than -120 and more positive than +120 mV. (iv) The AbetaP[1-40]-formed inactivating large conductance channel was characterized by (a) fast and slow modes of opening to seven multilevel conductances ranging between 0-589 pS (in 250/50 mM KCI) at +140 mV and 0-704 pS (in 250/50 mM KCl) at -160 mV. (b) The fast mode which had a conductance of <250 pS was voltage dependent. The inactivation was described by a bell-shaped curve with a peak lag time of 7.2 s at +36 mV. The slow mode which had a conductance of >250 pS was also voltage dependent. The inactivation was described by a bell-shaped curve with a peak lag time of 7.0 s at -76 mV, (c) the value of PK/Pcholine for the fast mode was 3.9 and selectivity sequence PK > PCs > PNa > PLi = 1.0:0.94:0.87:0.59. The value of PK/Pcholine for the slow mode was 2.7 and selectivity sequence PK > FNa > PLi > PCs = 1.0:0.59:0.49:0.21, and (d) asymmetric blockade with 10 mM Zn2+-induced reduction in the large conductance state of the slow mode mediated via slow block mechanism. The fast mode of the large conductance channel was not affected by 10 mM Zn2+. 2. It has been suggested that, although the "bursting" fast channel, the "spiky" fast channel and the inactivating medium conductance channel are distinct, it is possible that they are intermediate configurations of yet another configuration underlying the inactivating large conductance channel. It is proposed that this heterogeneity is one of the most common features of these positively-charged cytotoxic amyloid-formed channels reflecting these channels ability to modify multiple ...
A major prion protein (PrP) mutant that forms amyloid fibrils in the diseased brain of patients with Gerstmann-Sträussler-Scheinker syndrome (GSS) is a fragment of 7 kDa spanning from residues 81-82 to 144-153 of PrP. Analysis of ionic membrane currents, recorded with a lipid bilayer technique, revealed that the wild-type fragment PrP(82-146) WT and the partially scrambled PrP(82-146) (127-146) SC are capable of forming heterogeneous ion channels that are similar to those channels formed with PrP(106-126). In contrast, PrP(82-146) peptides in which the region from residue 106 to 126 had been scrambled (SC) showed a reduction in interaction with lipid membranes and did not form channels. The PrP(82-146) WT- and PrP(82-146) (127-146) SC-formed cation channels with fast kinetics are Cu2+ sensitive and rifampicin (RIF) insensitive, whereas the time-dependent inactivating channels formed by these same peptides are both Cu2+ and RIF insensitive. The presence of RIF in the solution before the addition of PrP(82-146) WT or PrP(82-146) (127-146) SC affected their incorporation into the lipid bilayers. PrP(82-146) WT and PrP(82-146) (127-146) SC fast cation channels formed in the presence of RIF appeared in an electrically semisilent state or an inactivated state. Increasing [Cd2+]cis enhanced the incorporation of PrP(82-146) WT and PrP(82-146) (127-146) SC channels formed in the presence of RIF. We conclude that the major PrP mutant fragment in the diseased brain of GSS patients is prone to form channels in neuronal membranes, causing their dysfunction. We propose that Cd2+ may accentuate the neurotoxicity of this channel-forming PrP fragment by enhancing its incorporation into the membrane.
Using the lipid bilayer technique, we have found that age-related derivatives, PrP[106-126] (L-Asp108) and PrP[106-126] (L-iso-Asp108), of the prion protein fragment 106-126 (PrP[106-126] (Asn108)) form heterogeneous ion channels. The deamidated isoforms, PrP[106-126] (L-Asp108) and PrP[106-126] (L-iso-Asp108), showed no enhanced propensity to form heterogeneous channels compared with PrP[106-126] (Asn108). One of the PrP[106-126] (L-Asp108)- and PrP[106-126] (L-iso-Asp108)-formed channels had three kinetic modes. The current-voltage (I-V) relationship of this channel, which had a reversal potential, E(rev), between -40 and -10 mV close to the equilibrium potential for K+ (E(K)-35 mV), exhibited a sigmoidal shape. The value of the maximal slope conductance (g(max)) was 62.5 pS at positive potentials between 0 and 140 mV. The probability (P(o)) and the frequency (F(o)) of the channel being open had inverted and bell-shaped curves, respectively, with a peak at membrane potential (V(m)) between -80 and +80 mV. The mean open and closed times (T(o) and T(c)) had inverted bell-shaped curves. The biophysical properties of PrP[106-126] (L-Asp108)- and PrP[106-126] (L-iso-Asp108)-formed channels and their response to Cu(2+) were similar to those of channels formed with PrP[106-126] (Asn108). Cu(2+) shifted the kinetics of the channel from being in the open state to a "burst state" in which rapid channel activities were separated by long durations of inactivity. The action of Cu(2+) on the open channel activity was both time-dependent and voltage-dependent. The fact that Cu(2+) induced changes in the kinetics of this channel with no changes in the conductance of the channel indicated that Cu(2+) binds at the mouth of the channel. Consistently with the hydrophilic and structural properties of PrP[106-126], the Cu(2+)-induced changes in the kinetic parameters of this channel suggest that the Cu(2+) binding site could be located at M(109) and H(111) of this prion fragment.
We found that the amyloid  peptide A(1-42) is capable of interacting with membrane and forming heterogeneous ion channels in the absence of any added Cu 2ϩ or biological redox agents that have been reported to mediate A(1-42) toxicity. binds to the histidine residues located at the mouth of the channel. It is proposed that the Cu 2ϩ -binding site of the A(1-42)-formed channels is modulated with Cu 2ϩ in a similar way to those of channels formed with the prion protein fragment PrP(106-126), suggesting a possible common mechanism for Cu 2ϩ modulation of A and PrP channel proteins linked to neurodegenerative diseases. neurodegenerative diseases; transitional metals; ion channel pathologies; membrane injuries; calcium homeostasis ALZHEIMER'S DISEASE (AD) is a neurodegenerative disorder that affects the cognitive function of the brain. Pathological changes in AD are characterized by the formation of amyloid plaques and neurofibrillary tangles as well as extensive neuronal loss. The plaques, which accumulate extracellularly in the brain, are composed of aggregates and cause direct neurotoxic effects and/or increase neuronal vulnerability to excitotoxic insults. The major components of the extracellular neurofibrillar bundles are polymerized amyloid  (A) peptides A(1-40), A(1-42), and A(1-43). It has been shown that A familial AD-linked mutations of the amyloid protein precursors presenilin-1 and presenilin-2 increase the concentration of A(1-42) (53), which has been shown to be toxic in primary neuronal culture at micromolar concentrations (56). The major mechanisms proposed for A-induced cytotoxicity involve the loss of Ca 2ϩ homeostasis (see Refs. 46 and 47) and the generation of reactive oxygen species (see Refs. 9,11,12,and 25). The changes in Ca 2ϩ homeostasis could be the result of 1) alterations in endogenous ion transport systems and 2) formation of heterogeneous ion channels (see Refs. 32,33,and 35). Several laboratories have found that A(1-40) and other fragments of amyloid precursor protein that contain A also possess the ability to form ion channels in both artificial and biological membranes. Electrophysiological studies have shown that A fragments, e.g., A(25-35), A(1-40), and A(1-42), elicit cation-selective currents when reconstituted into lipid bilayers (1-4, 23, 24, 30, 35, 37, 41, 55) and in the plasma membrane of neurons (28,29,48) as well as in Xenopus oocytes (21). A(1-42) and A(1-40) increase Ca 2ϩ uptake in liposomes in a dose-dependent manner (38, 49), and soluble As induce Ca 2ϩ influx in neurons and nonneuronal cells (10,50,51,57).In addition to the A being linked to AD, a role for transition metals has also been recognized. Cu 2ϩ and Zn 2ϩ have been implicated in AD (11,12,42), Parkinson's disease (54), prion protein (PrP) (26), and immunoglobulin light chain amyloidosis (17). The mechanisms underlying the interaction between A and these metals may mediate their role in neurotoxicity. There is also evidence to show that A, and also PrP, binds Cu 2ϩ (5, 6) to a si...
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