Prion protein binds copper within the physiological concentration range.

The prion protein is known to be a copper-binding protein, but affinity and stoichiometry data for the full-length protein at a physiological pH of 7 were lacking. Furthermore, it was unknown whether only the highly flexible N-terminal segment with its octarepeat region is involved in copper binding or whether the structured C-terminal domain is also involved. Therefore we systematically investigated the stoichiometry and affinity of copper binding to full-length prion protein PrP(23-231) and to different N- and C-terminal fragments using electrospray ionization mass spectrometry and fluorescence spectroscopy. Our data indicate that the unstructured N-terminal segment is the cooperative copper-binding domain of the prion protein. The prion protein binds up to five copper(II) ions with half-maximal binding at approximately 2 microm. This argues strongly for a direct role of the prion protein in copper metabolism, since it is almost saturated at about 5 microm, and the exchangeable copper pool concentration in blood is about 8 microm.

Selection and characterization of single chain Fv fragments against murine recombinant prion protein from a synthetic human antibody phage display library.

We describe the selection of single chain Fv fragments (scFv) against recombinant murine prion protein (mPrP) from a synthetic human antibody phage display library. Six different antibodies were isolated after three rounds of panning against full-length mPrP. All antibodies recognized a truncated form of mPrP containing residues (121-231). The amino acid sequence of the CDR3 of the scFv fragments has been determined. Five of the antibodies have been over-expressed, purified and their affinity for full-length mPrP determined by ELISA. The observed binding affinities vary from 30 nM to 2.7 microM.

Extremely rapid folding of the C-terminal domain of the prion protein without kinetic intermediates.

The kinetics of folding of mPrP(121-231), the structured 111-residue domain of the murine cellular prion protein PrP(C), were investigated by stopped-flow fluorescence using the variant F175W, which has the same overall structure and stability as wild-type mPrP(121-231) but shows a strong fluorescence change upon unfolding. At 22 degrees C and pH 7.0, folding of mPrP(121-231)-F175W is too fast to be observable by stopped-flow techniques. Folding at 4 degrees C occurs with a deduced half-life of approximately 170 micros without detectable intermediates, possibly the fastest protein-folding reaction known so far. Thus, propagation of the abnormal, oligomeric prion protein PrP(Sc), which is supposed to be the causative agent of transmissible spongiform encephalopathies, is unlikely to follow a mechanism where kinetic folding intermediates of PrP(C) are a source of PrP(Sc) subunits.

Influence of amino acid substitutions related to inherited human prion diseases on the thermodynamic stability of the cellular prion protein.

Transmissible spongiform encephalopathies (TSEs) are caused by a unique infectious agent which appears to be identical with PrPSc, an oligomeric, misfolded isoform of the cellular prion protein, PrPC. All inherited forms of human TSEs, i.e., familial Creutzfeldt-Jakob disease, Gerstmann-Sträussler-Scheinker syndrome, and fatal familial insomnia, segregate with specific point mutations or insertions in the gene coding for human PrP. Here we have tested the hypothesis that these mutations destabilize PrPC and thus facilitate its conversion into PrPSc. Eight of the disease-specific amino acid replacements are located in the C-terminal domain of PrPC, PrP(121-231), which constitutes the only part of PrPC with a defined tertiary structure. Introduction of all these replacements into PrP(121-231) yielded variants with the same spectroscopic characteristics as wild-type PrP(121-231) and similar to full-length PrP(23-231), which excludes the possibility that the exchanges a priori induce a PrPSc-like conformation. The thermodynamic stabilities of the variants do not correlate with specific disease phenotypes. Five of the amino acid replacements destabilize PrP(121-231), but the other variants have the same stability as the wild-type protein. These data suggest that destabilization of PrPC is neither a general mechanism underlying the formation of PrPSc nor the basis of disease phenotypes in inherited human TSEs.

Transmissible spongiform encephalopathies.

Scrapie, bovine spongiform encephalopathy (BSE), and the Creutzfeldt-Jakob disease (CJD) belong to a group of lethal neurodegenerative disorders in mammals. Prion diseases or transmissible spongiform encephalopathies (TSEs) are characterized by the accumulation of an abnormal isoform (PrPSc) of the host-encoded cellular prion protein (PrPC) in the brain. The infectious agent, the 'prion,' is believed to be devoid of informational nucleic acid and to consist largely, if not entirely, of PrPSc. The PrP isoforms contain identical amino acid sequences yet differ in their overall secondary structure with the PrPSc isoform possessing a higher beta-sheet and lower alpha-helix content than PrPC. Elucidation of the three-dimensional structure of PrPC has provided important clues on the molecular basis of inherited human TSEs and on the species barrier phenomenon of TSEs. Nevertheless, the molecular mechanism of the conformational rearrangement of PrPC into PrPSc is still unknown, mainly due to the lack of detailed structural information on PrPSc. Within the framework of the 'protein only' hypothesis, two plausible models for the self-replication of prions have been suggested, the conformational model and the nucleation-dependent polymerization model.

The calcium-dependent binding of annexin V to phospholipid vesicles influences the bilayer inner fluidity gradient.

The fluidity of the hydrophobic interior of phospholipid vesicles after calcium-dependent binding of human annexin V (AVH) was studied using EPR spectroscopy. Vesicles (SUVs) composed of PC or PE and an acidic phospholipid (alternatively PS, PA, or CL) were probed at different bilayer depths by either phosphatidylcholine, or the accompanying acidic phospholipid, bearing a spin label probe at position C-5, C-12, or C-16 of the sn-2 acyl chain. Alternatively, the vesicle surface was probed with a polar head spin labeled PE (PESL). The EPR spectra of annexin-bound bilayer domain(s) were obtained by computer spectral subtraction. The order parameter values (S) from the resulting difference spectra revealed that the bilayer hydrophobic interior has a greatly altered fluidity gradient, with an increased rigidity up to the C-12 position. Thereafter, the rigidification progressively vanished. The effect is not linked to the phospholipid class, since all the acidic phospholipid spectra, as well as phosphatidylcholine, shared the same sensitivity to the bound protein. The observed membrane rigidification appears to parallel the "crystallizing" tendency of vesicle-bound annexin V, but may not be involved in the calcium channeling activity of this protein.

Prion protein expression in different species: analysis with a panel of new mAbs.

By immunizing prion knockout mice (Prnp-/-) with recombinant murine prion protein (PrPc), we obtained a panel of mAbs specific for murine PrPc. These mAbs can be applied to immunoblotting, cell surface immunofluorescent staining, and immunohistochemistry at light and electron microscopy. These mAbs recognize both the normal (PrPc) and protease-resistant (PrPres) isoforms of PrP. Some mAbs are species restricted, while others react with PrP from a broad range of mammals including mice, humans, monkeys, cows, sheep, squirrels, and hamsters. Moreover, some of the mAbs selectively recognize different PrP glycoforms as well as the metabolic fragments of PrPc. These newly generated PrPc antibodies will help to explore the biology of PrPc and to establish the diagnosis of prion diseases in both humans and animals.

Crystal structure of the C-terminal tetrad repeat from synexin (annexin VII) of Dictyostelium discoideum.

Synexin (annexin VII) is a cytosolic Ca(2+)-binding protein that promotes membrane fusion and forms voltage-regulated ion channels in artificial and natural membranes. The crystal structure of the C-terminal tetrad repeat from recombinant synexin (annexin VII) of Dictyostelium discoideum was solved to 2.45 A resolution. The protein crystallized in a dimeric form with two molecules joined face-to-face by their convex sides. Mainly hydrogen bonds and van der Waals contacts are involved in dimer formation, while not Ca2+ is bound to the conserved Ca(2+)-binding sites. The truncated N terminus is folded into a short antiparallel beta-sheet, from which the side-chain of Tyr111 penetrates sideways into the central, hydrophilic pore and may directly affect the ion channel activity. In order to investigate the structure of the missing N-terminal domain, we synthesized a 37-membered peptide of the N-terminal tail, (GYPPQQ)6G. CD and NMR studies showed a random coil conformation of the peptide in solution, suggesting for the synexin N terminus the lack of a well-ordered, three-dimensional fold.

Three-dimensional structure of annexins.

Annexins constitute a family of structurally related calcium- and phospholipid-binding proteins whose molecular structure has been investigated in detail in the crystalline and membrane-bound form. Their polypeptide chain is folded into four or eight alpha-helical domains of similar structure with a central hydrophilic pore. Bound to phospholipid membranes, the four-domain arrangement of the annexin molecule is conserved. A peripheral binding mode has been well documented by electron microscopy and a variety of other techniques.

Annexin V and vesicle membrane electroporation.

The method of membrane electroporation (ME) has been used as an analytical tool to quantify the effect of membrane curvature on transient electric pore formation, and on the adsorption of the protein annexin V (M(r)= 35,800) to the outer surface of unilamellar lipid vesicles (of radii 25 < or = a/nm < or = 200). Relaxation kinetic studies using optical membrane probes of the diphenylhexatriene type suggest that electric pore formation is induced by ionic interfacial polarization causing entrance of the (more polarizable) water into the lipid bilayer membrane yielding (hydrophobic and hydrophilic) pore states with a mean stationary pore radius rp = 0.35 (+/-0.05) nm. Extent and rate of ME, compared at the same induced transmembrane voltage, were found to decrease both with increasing vesicle radius and with increasing protein concentration. This 'inhibitory' effect of annexin V is apparently allosteric and saturates at about [ANT]sat = 4 microM annexin V for vesicles of a = 100 nm at 1 mM total lipid concentration, 0.13 mM total Ca2+ concentration and at T = 293 K. Data analysis in terms of Gibbs area-difference-elasticity energy suggests that the bound annexin V reduces the gradient of the lateral pressure across the membrane. At [ANT]sat, about 20% of the vesicle surface is covered by the bound protein, but it is only 0.01% of the surface of the outer lipid leaflet in which a part of the protein, perhaps the aromatic residue of the tryptophan (W 187), is inserted. Insertion leads to a denser packing of the lipid molecules in the outer membrane leaflet. As a consequence, the radius of the electropores in the remaining membrane part, not covered by annexin V decreases (rp/nm = 0.37, 0.36 and 0.27) with increasing adsorption of the protein ([ANT] = 0, 2 and 4 microM, respectively).

Voltage dependent binding of annexin V, annexin VI and annexin VII-core to acidic phospholipid membranes.

Annexin V, VI and VII-core (delta1-107) are members of the annexin protein family and bind to acidic phospholipid membranes in a calcium dependent manner. They also show ion channel activity under certain conditions. As annexins bind peripherally to lipid membranes, ion channel formation must consist of at least two steps: An adsorption reaction regulating the binding of annexin to the membrane surface and the opening and closing of the active species controlling the channel activity. By using the baseline current through the patch clamp seal as a probe for unoccupied binding sites at the membrane, we show that the adsorption of annexins to membranes is not only calcium dependent but also strongly voltage dependent. Whereas the free transfer energies at low calcium concentrations are similar for all three annexins, the binding of annexin V becomes much tighter with higher calcium levels, compared to annexin VI and VII-core. This correlates with the finding that annexin VI and VII-core display channel activity much more often than annexin V if one assumes that a high coverage of the membrane surface with annexins stabilizes the bilayer. At higher protein concentrations weaker binding is observed in agreement with the previously reported anti-cooperativity of membrane binding.

The structure of recombinant human annexin VI in crystals and membrane-bound.

The crystal structure of calcium-free recombinant human annexin VI was solved at a resolution of 3.2 A by using the annexin I model for Patterson search and refined to an R-factor of 19.0%. The molecule consists of two similar halves closely resembling annexin I connected by an alpha-helical segment and arranged perpendicular to each other. The calcium and membrane binding sites assigned by structural homology are therefore not located in the same plane. Analysis of the membrane-bound form of annexin VI by electron microscopy shows the two halves of the molecule coplanar with the membrane, but oriented differently to the crystal structure and suggesting a flexible arrangement. Ion channel activity has been found for annexin VI and the half molecules by electrophysiological experiments.

Structural and functional characterisation of the voltage sensor in the ion channel human annexin V.

The ion channel properties of human annexin V, a calcium- and phospholipid-binding protein of the annexin family, have been structurally and functionally investigated by analysing the mutant Glu112 -->Gly. Glu112 forms a salt bridge with Arg271 located in the interior of the hydrophilic pore of the molecule which is conserved within the annexin family. The crystal structures of the mutant and wild-type proteins are very similar and show only marginal conformational changes around the mutation site. Electron microscopic images show a conserved four-domain structure upon membrane binding as in the wild-type annexin V. The channel properties of the mutant are drastically changed, as the mutant has lost the voltage-dependent channel gating and the selectivity for calcium ions over monovalent cations. These results strongly support the hypothesis that the central, hydrophilic pore is the ion-conducting pathway.

The crystal structure and ion channel activity of human annexin II, a peripheral membrane protein.

Annexin II binds in a calcium-dependent manner to acidic phospholipids and is a substrate of some protein kinases. An N-terminally shortened form of human annexin II was crystallized and its molecular structure determined. It is very similar to two previously described members of this protein family, annexin I and annexin V. The protein structure is nearly completely alpha-helical organized as four compact domains which consist of five alpha-helices each. The domains surround a hydrophilic pore. The calcium binding sites are located at the convex side of the structure as in annexin V. Recombinant and natural porcine annexin II are active as ion channel with characteristics similar to annexin V, while N-terminally shortened annexin II and the heterotetramer (annexin II-p11)2 are inactive. Two cysteine residues, Cys133 and Cys262, form a disulphide bridge connecting domains II and III, adding further weight to the notion that ion channel activity does not require major structural rearrangements.

Annexins: a novel family of calcium- and membrane-binding proteins in search of a function.

Although the annexins have been extensively studied and much detailed structural information is available, their in vivo function has yet to be established.

Annexin V: the key to understanding ion selectivity and voltage regulation?

Annexin V is a Ca(2+)-dependent membrane-binding protein that forms voltage-dependent Ca2+ channels in phospholipid bilayers and is the first ion channel to be structurally and functionally characterized. Data outlined here indicate that key amino acid residues act as selectivity filters and voltage sensors, thereby regulating the permeability of the channel pore to ions.