Amyloid peptide channels.

At least 16 distinct clinical syndromes including Alzheimer's disease (AD), Parkinson's disease (PD), rheumatoid arthritis, type II diabetes mellitus (DM), and spongiform encephelopathies (prion diseases), are characterized by the deposition of amorphous, Congo red-staining deposits known as amyloid. These "misfolded" proteins adopt beta-sheet structures and aggregate spontaneously into similar extended fibrils despite their widely divergent primary sequences. Many, if not all, of these peptides are capable of forming ion-permeable channels in vitro and possibly in vivo. Common channel properties include irreversible, spontaneous insertion into membranes, relatively large, heterogeneous single-channel conductances, inhibition of channel formation by Congo red, and blockade of inserted channels by Zn2+. Physiologic effects of amyloid, including Ca2+ dysregulation, membrane depolarization, mitochondrial dysfunction, inhibition of long-term potentiation (LTP), and cytotoxicity, suggest that channel formation in plasma and intracellular membranes may play a key role in the pathophysiology of the amyloidoses.

The channel hypothesis of Huntington's disease.

Extended tracts of polyglutamine (PG) have been implicated in the pathogenicity of the mutant protein huntingtin and have been shown to form ion channels in planar lipid bilayers. These lines of evidence suggest that huntingtin and other PG mutant proteins may damage cells via a channel mechanism. This mechanism could cause damage to the plasma membrane by running down ionic gradients, discharging membrane potential; or allowing influx of toxic ions such as Ca(2+). PG damage to intracellular membranes such as the lysosomal membrane or the mitochondrial membrane could also injure cells via leakage of toxic enzymes or triggering of apoptosis. The channel mechanism is well-established for microbial toxins, and the existence of at least six other "amyloid" channels relevant to diseases such as Alzheimer's and Creutzfeld-Jakob, suggests that this may be a widespread pathogenic mechanism.

Polyglutamine-induced ion channels: a possible mechanism for the neurotoxicity of Huntington and other CAG repeat diseases.

CAG repeats resulting in long polyglutamine tracts have been implicated in the pathogenesis of at least eight neurodegenerative diseases including Huntington. Expression of polyglutamine repeats is required for disease and increasing length of the repeats leads to earlier onset of illness (anticipation). Expression of polyglutamine repeats in cultured neurons leads to deposition of intracellular aggregates resembling those found in amyloid diseases, and to neurotoxicity. We report here that polyglutamine can induce large (19-220 pS), long-lived, (lifetime = 6 sec), non-selective (P(cation) = P(anion)) ion channels in planar phospholipid bilayer membranes, and that channel formation is enhanced by acidic pH. We propose that channel formation may be a mechanism of cellular toxicity in Huntington and other CAG repeat disease.

Pore-forming properties of proteolytically nicked staphylococcal alpha-toxin: the ion channel in planar lipid bilayer membranes.

Staphylococcal alpha-toxin is a single-chain protein with a molecular mass of 33.2 kDa, which can form large water-filled pores both in lipid bilayers and in erythrocyte membranes. Limited proteolysis of the purified toxin with proteinase K led to time-dependent changes of all the functional features of the channels formed by the toxin. Single-channel conductance in planar bilayers was decreased about threefold. The anion selectivity of the channel was replaced with cation selectivity and the asymmetry in the current-voltage relationship of the channel became more pronounced. At the same time the nicked toxin kept its full ability to form ion channels in lipid bilayers, although it lost a considerable part of its hemolytic activity. In planar bilayers and in erythrocyte membranes, the proteolytically nicked toxin actually formed channels with a slightly smaller diameter (approximately 1.2 times) than that formed by the native toxin. This decrease was not marked enough to explain changes in the biological effects of the nicked toxin. The change in channel selectivity induced by the cleavage is considered to be the major determinant of the changes in the biological effects of the nicked toxin.