Brain copper content and cuproenzyme activity do not vary with prion protein expression level

Glycan chains modulate prion protein binding to immobilized metal ions

PrP(c) is the normal isoform of the prion protein which can be converted into PrP(Sc), the pathology-associated conformer in prion diseases. It contains two N-linked glycan chains attached to the C-proximal globular domain. While the biological functions of PrP(c) are still unknown, its ability to bind Cu(2+) is well documented. The main Cu(2+)-binding sites are located in the N-proximal, unstructured region of the molecule. Here we report that PrP(c) glycans influence the capacity of PrP(c) from sheep brain or cultured Rov cells to bind IMAC columns loaded with Cu(2+) or Co(2+). Using different anti-PrP antibodies and PrP(c) glycosylation mutants, we show that the full length non-glycosylated form of PrP(c) has a higher binding efficiency for column-bound Cu(2+) and Co(2+) than the corresponding glycosylated form. Our findings raise the possibility that the accessibility of the PrP(c) metal ion-binding sites might be controlled by the glycan chains.

Copper deficiency and neurological disorders in man and animals

Copper metabolism in the brain is far from being completely understood and further studies are needed on the role of copper in the CNS, starting with careful measurements, metal and biological speciation of metabolites on the molecular level, and combining copper concentration in different brain areas with morphological as well as biochemical alteration after Cu-depletion/deficiency. So far a pathological role for copper has been clearly demonstrated in some human genetic diseases (e.g., Menkes' and Wilson's diseases), but other pathological features connected with metal depletion are under investigation in several laboratories. The metabolic interaction between copper and other metal ions in some neurological disorders is also discussed in this contribution.

Copper is required for prion protein-associated superoxide dismutase-l activity in Pichia pastoris

The prion protein (PrP) is the key protein implicated in transmissible spongiform encephalopathies. It is a metalloprotein that binds manganese and copper. The latter is involved in the physiological function of the protein. We have previously found that PrP expression in Pichia pastoris affects intracellular metal ion concentrations and that formation of protease-resistant PrP is induced by additional copper and/or manganese. In this study, we show that heterologously expressed PrP is post-translationally modified and transported to the cell wall. We found by combining three different test systems that PrP itself had gained superoxide dismutase-like activity in P. pastoris. However, this activity could not be inhibited by KCN and depended on additional copper in the medium. Thus, this study defines the conditions under which PrP exhibits superoxide dismutase-like activity by showing that copper must be present for the protein to participate in scavenging and detoxification of reactive oxygen species.

Decreased brain copper due to copper deficiency has no effect on bovine prion proteins

Copper (Cu) is believed to be integral in prion biology and the lack of Cu or replacement by other metal ions on prions may be involved in prion diseases. This theory has not been evaluated in the bovine. Thus, mature cows were used to determine the effects of Cu deficiency on brain Cu concentrations and prion functional characteristics. Two Cu states were induced, Cu-adequate (n=4) and Cu-deficient (n=4). Copper deficiency resulted in decreased (44%) brain Cu concentrations but had no effect on prion concentrations. Based on Western blot analysis, the molecular weights, glycoform distributions, and elution profiles of brain prions were not affected by Cu status. Importantly, Cu status did not affect prion proteinase degradability as all prions were completely degraded by proteinase K. In conclusion, Cu status affected bovine brain Cu concentrations but had no detectable effects on brain prion protein characteristics.

Multiple forms of copper (II) co-ordination occur throughout the disordered N-terminal region of the prion protein at pH 7.4

Although the physiological function of the prion protein remains unknown, in vitro experiments suggest that the protein may bind copper (II) ions and play a role in copper transport or homoeostasis in vivo. The unstructured N-terminal region of the prion protein has been shown to bind up to six copper (II) ions, with each of these ions co-ordinated by a single histidine imidazole and nearby backbone amide nitrogen atoms. Individually, these sites have micromolar affinities, which is weaker than would be expected of a true cuproprotein. In the present study, we show that with subsaturating levels of copper, different forms of co-ordination will occur, which have higher affinity. We have investigated the copper-binding properties of two peptides representing the known copper-binding regions of the prion protein: residues 57-91, which contains four tandem repeats of the octapeptide GGGWGQPH, and residues 91-115. Using equilibrium dialysis and spectroscopic methods, we unambiguously demonstrate that the mode of copper co-ordination in both of these peptides depends on the number of copper ions bound and that, at low copper occupancy, copper ions are co-ordinated with sub-micromolar affinity by multiple histidine imidazole groups. At pH 7.4, three different modes of copper co-ordination are accessible within the octapeptide repeats and two within the peptide comprising residues 91-115. The highest affinity copper (II)-binding modes cause self-association of both peptides, suggesting a role for copper (II) in controlling prion protein self-association in vivo.

Prions and their partners in crime

Prions, the infectious agents of transmissible spongiform encephalopathies (TSEs), have defied full characterization for decades. The dogma has been that prions lack nucleic acids and are composed of a pathological, self-inducing form of the host's prion protein (PrP). Recent progress in propagating TSE infectivity in cell-free systems has effectively ruled out the involvement of foreign nucleic acids. However, host-derived nucleic acids or other non-PrP molecules seem to be crucial. Interactions between TSE-associated PrP and its normal counterpart are also pathologically important, so the physiological functions of normal PrP and how they might be corrupted by TSE infections have been the subject of recent research.

A spectroscopic and voltammetric study of the pH-dependent Cu(II) coordination to the peptide GGGTH: relevance to the fifth Cu(II) site in the prion protein

The GGGTH sequence has been proposed to be the minimal sequence involved in the binding of a fifth Cu(II) ion in addition to the octarepeat region of the prion protein (PrP) which binds four Cu(II) ions. Coordination of Cu(II) by the N- and C-protected Ac-GGGTH-NH(2) pentapeptide (P(5)) was investigated by using potentiometric titration, electrospray ionization mass spectrometry, UV-vis spectroscopy, electron paramagnetic resonance (EPR) spectroscopy and cyclic voltammetry experiments. Four different Cu(II) complexes were identified and characterized as a function of pH. The Cu(II) binding mode switches from NO(3) to N(4) for pH values ranging from 6.0 to 10.0. Quasi-reversible reduction of the [Cu(II)(P(5))H(-2)] complex formed at pH 6.7 occurs at E (1/2)=0.04 V versus Ag/AgCl, whereas reversible oxidation of the [Cu(II)(P(5))H(-3)](-) complex formed at pH 10.0 occurs at E (1/2)=0.66 V versus Ag/AgCl. Comparison of our EPR data with those of the rSHaPrP(90-231) (Burns et al. in Biochemistry 42:6794-6803, 2003) strongly suggests an N(3)O binding mode at physiological pH for the fifth Cu(II) site in the protein.

Truncated prion protein and Doppel are myelinotoxic in the absence of oligodendrocytic PrPC

The cellular prion protein PrP(C) confers susceptibility to transmissible spongiform encephalopathies, yet its normal function is unknown. Although PrP(C)-deficient mice develop and live normally, expression of amino proximally truncated PrP(C) (DeltaPrP) or of its structural homolog Doppel (Dpl) causes cerebellar degeneration that is prevented by coexpression of full-length PrP(C). We now report that mice expressing DeltaPrP or Dpl suffer from widespread leukoencephalopathy. Oligodendrocyte-specific expression of full-length PrP(C) under control of the myelin basic protein (MBP) promoter repressed leukoencephalopathy and vastly extended survival but did not prevent cerebellar granule cell (CGC) degeneration. Conversely, neuron-specific PrP(C) expression under control of the neuron-specific enolase (NSE) promoter antagonized CGC degeneration but not leukoencephalopathy. PrP(C) was found in purified myelin and in cultured oligodendrocytes of both wild-type and MBP-PrP transgenic mice but not in NSE-PrP mice. These results identify white-matter damage as an extraneuronal PrP-associated pathology and suggest a previously unrecognized role of PrP(C) in myelin maintenance.

Mouse brain synaptosomes accumulate copper-67 efficiently by two distinct processes independent of cellular prion protein

The prion protein (PrPC) is a copper-binding, cell-surface protein that plays an essential role in the etiology of transmissible spongiform encephalopathies. Atomic absorption spectroscopy studies have established that synaptosomal copper content is reduced in PrPC-deficient mice as compared with wild-type (WT) or PrP- overexpressing mice. To address the question of whether this is the result of a loss of function of PrPC in copper transport across the plasma membrane at the synapse, we have used synaptosomes incubated with 67Cu as a model system to characterize the mechanism of copper accumulation in nerve terminals. Our results demonstrate that mouse brain synaptosomes accumulate copper efficiently by at least two distinct mechanisms. In the presence of 1 mM EDTA, copper was taken up via a saturable high-affinity process that was moderately susceptible to competition by high concentrations of NiCl2. Uptake characteristics were clearly different in the presence of 400 microM histidine, with the most noticeable dissimilarities being considerably elevated uptake rates and moderate competition by ZnCl2 rather than NiCl2. No significant differences in copper uptake capability between WT and PrPC-knockout synaptosomes were observed under any of the experimental conditions tested in this study. Furthermore, preincubation of synaptosomes with an antibody binding to the copper-binding repeat region of the prion protein had no effect on copper uptake either. Taken together, our data indicate that synaptosomal copper uptake is independent of PrPC.

A survey of diamagnetic probes for copper2+binding to the prion protein.1H NMR solution structure of the palladium2+bound single octarepeat

The prion protein (PrP(C)) is a copper binding cell surface glycoprotein which when misfolded causes transmissible spongiform encephalopathies. The cooperative binding of Cu2+ to an unstructured octarepeat sequence within PrP(C) causes profound folding of this region. The use of NMR to determine the solution structure of the octarepeat region of PrP with Cu2+ bound has been hampered by the paramagnetic nature of the Cu2+ ions. Using NMR we have investigated the binding of candidate diamagnetic replacement ions, to the octarepeat region of PrP. We show that Pd2+ forms diamagnetic complexes with the peptides HGGG, HGGGW and QPHGGGWGQ with 1:1 stoichiometry. The 1H NMR spectra indicate that these peptides are in slow-exchange between free and bound Pd2+ on the chemical-shift time-scale. We demonstrate that the Pd-peptide complex forms slowly with a time taken to reach half-maximal signal of 3 hours. Other candidate metal ions, Ni2+, Pt2+ and Au3+, were investigated but only the Pd2+ complexes gave resolvable 1H NMR spectra. We have determined the solution structure of the QPHGGGWGQ-Pd 1:1 complex using 71 NOE distance restraints. A backbone RMSD of 0.30 A was observed over residues 3 to 7 in the final ensemble. The co-ordinating ligands consist of the histidine imidazole side chain N epsilon, the amide N of the second and third glycines with possibly H2O as the fourth ligand. The co-ordination geometry differs markedly from that of the HGGGW-Cu crystal structure. This survey of potential replacement metal ions to Cu2+ provides insight into the metal specificity and co-ordination chemistry of the metal bound octarepeats.

Recombinant prion protein does not possess SOD-1 activity

A considerable body of evidence now shows that PrP (prion protein) binds metal ions with high affinity and it has been claimed that the binding of copper (II) ions to PrP confers SOD (superoxide dismutase) activity. In turn, it has been suggested that PrP is a synaptic dismutase and that loss of this function, as a result of the conversion of PrP(C) into PrP(Sc), results in pathology and hence morbidity associated with prion disease. However, contrary to previous reports, in the present study we have found that PrP exhibits no detectable dismutase activity above baseline levels measured for copper (II) ions in water when assayed using a reliable procedure with a detection limit of at least 2 units of activity/mg of protein. This was true when the assay was performed with either PrP refolded from a denatured state in the presence of copper, as in previous studies, or native PrP loaded with copper. Thus if PrP has any role in oxidative stress, it must be indirect as a regulator of protective cellular responses.

High Affinity Binding between Copper and Full-length Prion Protein Identified by Two Different Techniques

The cellular prion protein is known to be a copper-binding protein. Despite the wide range of studies on the copper binding of PrP, there have been no studies to determine the affinity of the protein on both full-length prion protein and under physiological conditions. We have used two techniques, isothermal titration calorimetry and competitive metal capture analysis, to determine the affinity of copper for wild type mouse PrP and a series of mutants. High affinity copper binding by wild type PrP has been confirmed by the independent techniques indicating the presence of specific tight copper binding sites up to femtomolar affinity. Altogether, four high affinity binding sites of between femto- and nanomolar affinities are located within the octameric repeat region of the protein at physiological pH. A fifth copper binding site of lower affinity than those of the octameric repeat region has been detected in full-length protein. Binding to this site is modulated by the histidine at residue 111. Removal of the octameric repeats leads to the enhancement of affinity of this fifth site and a second binding site outside of the repeat region undetected in the wild type protein. High affinity copper binding allows PrP to compete effectively for copper in the extracellular milieu. The copper binding affinities of PrP have been compared with those of proteins of known function and are of magnitudes compatible with an extracellular copper buffer or an enzymatic function such as superoxide dismutase like activity.

The octarepeat domain of the prion protein binds Cu(II) with three distinct coordination modes at pH 7.4

The prion protein (PrP) binds Cu2+ in its N-terminal octarepeat domain. This unusual domain is comprised of four or more tandem repeats of the fundamental sequence PHGGGWGQ. Previous work from our laboratories demonstrates that at full copper occupancy, each HGGGW segment binds a single Cu2+. However, several recent studies suggest that low copper occupancy favors different coordination modes, possibly involving imidazoles from histidines in adjacent octapeptide segments. This is investigated here using a combination of X-band EPR, S-band EPR, and ESEEM, along with a library of modified peptides designed to favor different coordination interactions. At pH 7.4, three distinct coordination modes are identified. Each mode is fully characterized to reveal a series of copper-dependent octarepeat domain structures. Multiple His coordination is clearly identified at low copper stoichiometry. In addition, EPR detected copper-copper interactions at full occupancy suggest that the octarepeat domain partially collapses, perhaps stabilizing this specific binding mode and facilitating cooperative copper uptake. This work provides the first complete characterization of all dominant copper coordination modes at pH 7.4.

Prion protein (PrPc) promotes β-amyloid plaque formation

Prion protein (PrP) has been localized to amyloid-beta (Abeta) senile plaques in aging and Alzheimer disease, but it is unknown whether PrP is directly involved in plaque formation or represents a reaction to amyloid deposition. To evaluate possible functional effects of PrP in Abeta plaque formation, we analyzed bigenic mice (TgCRND8/Tg7), carrying mutant human amyloid precursor protein (APP) 695 (APP(Swed+Ind), TgCRND8) as well as the wild-type Syrian hamster prion protein gene (sHaPrP, Tg7), showing Abeta plaques at 3 months of age as well as highly increased HaPrP(c) levels. Compared to the control group, consisting of animals carrying only mutant APP, bigenic mice showed a higher number of senile plaques in the cerebral cortex, while APP transcription and Abeta40/Abeta42 levels were unchanged. Double-labelling immunofluorescence showed co-localization of Abeta and PrP in virtually all plaques in the brains of both control and experimental animals. Our data suggest that PrP promotes plaque formation, and that this hitherto unknown functional role of PrP appears to be mediated by increased Abeta aggregation rather than by altered APP transcription or processing.

Fragmentation and dimerization of copper-loaded prion protein by copper-catalysed oxidation

Prion protein consists of an N-terminal domain containing a series of octapeptide repeats with the consensus sequence PHGGGWGQ and a C-terminal domain composed of three alpha-helices and two short beta-strands. Several studies have shown that the N-terminal domain binds five Cu2+ ions. In the present study, we have investigated copper-catalysed oxidation of a recombinant mouse prion protein, PrP23-231. The copper-loaded PrP23-231 was found to be carbonylated by incubation with dopamine. Besides the formation of carbonyls, a cross-linked species with the dimeric size and C-terminally truncated species were generated. These reactions were retarded in the presence of Cu+- and Cu2+-specific copper chelators, catalase, and SOD (superoxide dismutase), but not in the presence of various bivalent metal ions. Together, these results indicate that the copper bound to prion protein undergoes catalytic cycling in the presence of catecholamines and causes the oxidation of the protein.

Cell-autonomous PrP–Doppel interaction regulates apoptosis in PrP gene-deficient neuronal cells

The Prnd-encoded prion protein (PrP)-like protein, Doppel (Dpl), is a homologue of Prnp-encoded PrP, and is N-glycosylated protein with glycosylphosphatidylinositol anchor like PrP. Recently, ectopic expressions of Prnp/Prnd chimeric mRNAs have been identified as the cause of late-onset ataxia observed in several lines of Prnp-knockout mice such as ZrchII, Ngsk, Rcm0, and Rikn mice. However, it remains unclear whether the toxic effect of Dpl expression is a cell-autonomous mechanism but rather reflect a systemic process of heterogeneous cell population in the brain. In this study, the cell-autonomous role of Dpl was estimated by investigating PrP-deficient cells (HpL3-4)-the SV40 large T-antigen immortalized and Rikn Prnp(-/-) mice-derived neuronal cell line expressing Prnp/Prnd chimeric mRNAs. The reverse transcription polymerase chain reaction revealed that serum deprivation did not increase Prnp/Prnd chimeric mRNAs, which in fact was translated into a small amount of Dpl in HpL3-4 cells, whereas serum deprivation induced apoptotic cell death of HpL3-4 cells. Dpl overexpression enhanced apoptotic cell death, whereas the toxic effect of Dpl on apoptotic cell death was neutralized by PrP expression. These results indicate that Dpl elicited dose-dependently toxic effects on PrP-deficient cells without affecting on PrP-expressing cells, suggesting that the PrP-Dpl interaction can regulate cell death in a cell-autonomous manner.

Probing Copper2+ Binding to the Prion Protein Using Diamagnetic Nickel2+ and 1H NMR: The Unstructured N terminus Facilitates the Coordination of Six Copper2+ Ions at Physiological Concentrations

The prion protein (PrP) is a Cu2+ binding cell surface glyco-protein. Misfolding of PrP into a beta-sheet rich conformation is associated with transmissible spongiform encephalopathies. Here we use Ni2+ as a diamagnetic probe to further understand Cu2+ binding to PrP. Like Cu2+, Ni2+ preferentially binds to an unstructured region between residues 90 and 126 of PrP, which is a key region for amyloidogenicity and prion propagation. Using both 1H NMR and visible-circular dichroism (CD) spectroscopy, we show that two Ni2+ ions bind to His96 and His111 independently of each other. 1H NMR indicates that both Ni2+ binding sites form square-planar diamagnetic complexes. We have previously shown that Cu2+ forms a paramagnetic square-planar complex in this region, suggesting that Ni2+ could be used as a probe for Cu2+ binding. In addition, competition studies show that two Cu2+ ions can displace Ni2+ from these sites. Upon Ni2+ addition 1H NMR changes in chemical shifts indicate the imidazole ring and amide nitrogen atoms to the N terminus of both His96 and His111 act as coordinating ligands. Use of peptide fragments confirm that PrP(92-96) and PrP(107-111) represent the minimal binding motif for the two Ni2+ binding sites. Analysis of Cu2+ loaded visible-CD spectra show that as with Ni2+, PrP(90-115) binds two Cu2+ ions at His96 and His111 independently of each other. Visible CD studies with PrP(23-231Delta51-90), a construct of PrP(23-231) with the octarepeat region deleted to improve solubility, confirm binding of Ni2+ to His96 and His111 in octarepeat deleted PrP(23-231). The structure of the Cu/Ni complexes is discussed in terms of the implications for prion protein function and disease.

Fine tuning the structure of the Cu2+ complex with the prion protein chicken repeat by proline isomerization

The interaction between the single hexarepeat unit of chicken prion protein [ChPrP(54-59)] and Cu(II) was investigated by NMR, finding different coordination modes for the trans/trans and cis/trans isomers.

Cellular prion protein regulates intracellular hydrogen peroxide level and prevents copper-induced apoptosis

The function of cellular prion protein (PrPC), which is a copper binding protein, remains unclear. To elucidate the mechanisms in which PrPC is involved in neuroprotection, we compared death signals in prion protein gene-deficient (Prnp-/-) primary cerebellar granular neurons (CGNs) to those with wild-type (WT) CGNs. When copper was exposed to these CGNs, ZrchI, and Rikn Prnp-/- CGNs were more sensitized and underwent apoptotic cell death more readily than WT CGNs. Furthermore, the level of intracellular hydrogen peroxide (H2O2) in WT CGNs increased by copper toxicity, whereas those in ZrchI and Rikn Prnp-/- CGNs did not. These results suggest that PrPC modulates the intracellular H2O2 level as a copper-binding protein to protect CGNs from apoptotic cell death possibly due to inhibiting a Fenton reaction.

Antiprion immunotherapy: to suppress or to stimulate?

Although human prion diseases are rare, they are invariably fatal, and treatments remain elusive. Hundreds of iatrogenic prion transmissions have occurred in the past two decades, and the bovine spongiform encephalopathy epidemic has raised concerns about prion transmission from cattle to humans. Research into therapeutics for prion disease is being pursued in several centres and prominently includes immunological strategies. Currently, the options that are being explored aim either to mobilize the innate and adaptive immune systems towards prion destruction or to suppress or dedifferentiate the lymphoreticular compartments that replicate prions. This article reviews the pathophysiology of prion diseases in mouse models and discusses their relevance to immunotherapeutic and immunoprophylactic antiprion strategies.

Cell Surface Expression of the Prion Protein in Yeast Does Not Alter Copper Utilization Phenotypes

Prion diseases are fatal neurodegenerative disorders that result from conversion of a normal, cell surface glycoprotein (PrP(C)) into a conformationally altered isoform (PrP(Sc)) that is thought to be infectious. Although a great deal is known about the role of PrP(Sc) in the disease process, the physiological function of PrP(C) has remained enigmatic. In this report, we have used the yeast Saccharomyces cerevisiae to test one hypothesized function of PrP(C), as a receptor for the uptake or efflux of copper ions. We first modified the PrP signal peptide by replacing its hydrophobic core with the signal sequence from the yeast protein dipeptidyl aminopeptidase B, so that the resulting protein was targeted cotranslationally to the secretory pathway when synthesized in yeast. PrP molecules with the modified signal peptide were efficiently glycosylated, glycolipid-anchored, and localized to the plasma membrane. We then tested whether PrP expression altered the growth deficiency phenotypes of yeast strains harboring deletions in genes that encode key components of copper utilization pathways, including transporters, chaperones, pumps, reductases, and cuproenzymes. We found that PrP did not rescue any of these mutant phenotypes, arguing against a direct role for the protein in copper utilization. Our results provide further clarification of the physiological function of PrP(C), and lay the groundwork for using PrP-expressing yeast to study other aspects of prion biology.

Neuroprotective functions of prion protein

The normal function of prion protein (PrP) is usually disregarded at the expense of the more fascinating role of PrP in transmissible prion diseases. However, the normal PrP may play an important role in cellular function in the central nervous system, since PrP is highly expressed in neurons and motifs in the sequence of PrP are conserved in evolution. The finding that prion null mice do not have a significant overt phenotype suggests that the normal function of PrP is of minor importance. However, the absence of PrP in cells or in vivo contributes to an increased susceptibility to oxidative stress or apoptosis-inducing insults. An alternative explanation is that the PrP normal function is so important that it is redundant. Probing into the characteristics of PrP has revealed a number of features that could mediate important cellular functions. The neuroprotective actions so far identified with PrP are initiated through cell surface signaling, antioxidant activity, or anti-Bax function. Here, we review the characteristics of the PrP and the evidence that PrP protects against neurodegeneration and neuronal cell death.

Transgene-driven expression of the Doppel protein in Purkinje cells causes Purkinje cell degeneration and motor impairment

The Doppel (Dpl) and Prion (PrP) proteins show 25% sequence identity and share several structural features with only minor differences. Dpl shows a PrP-like fold of its C-terminal globular domain and lacks the flexible N-terminal tail. The physiological functions of both proteins are unknown. However, ubiquitous Dpl overexpression in the brain of PrP knockout mice correlated with ataxia and Purkinje cell degeneration in the cerebellum. Interestingly, a similar phenotype was reported in transgenic mice expressing an N-terminally truncated PrP (DeltaPrP) in Purkinje cells by the L7 promoter (TgL7-DeltaPrP). Coexpression of full-length PrP rescued both the neurological syndromes caused by either Dpl or DeltaPrP. To evaluate whether the two proteins caused cerebellar neurodegeneration by the same mechanism, we generated transgenic mice selectively expressing Dpl in Purkinje cells by the same L7 promoter. Such mice showed ataxia and Purkinje cell loss that depended on the level of Dpl expression. Interestingly, the effects of high levels of Dpl were not counterbalanced by the presence of two Prnp alleles. By contrast, PrP coexpression was sufficient to abrogate motor impairment and to delay the neurodegenerative process caused by moderate level of Dpl. A similar situation was reported for the corresponding TgL7-DeltaPrP mice supporting the concept that Dpl and DeltaPrP cause cell death, possibly by interfering with a common signaling cascade essential for cell survival.

Prion protein suppresses perturbation of cellular copper homeostasis under oxidative conditions

Prion protein (PrP) binds copper and exhibits superoxide dismutase-like activity, while the roles of PrP in copper homeostasis remain controversial. Using Zeeman graphite furnace atomic absorption spectroscopy, we quantified copper levels in immortalized PrP gene (Prnp)-deficient neuronal cells transfected with Prnp and/or Prnd, which encodes PrP-like protein (PrPLP/Dpl), in the presence or absence of oxidative stress induced by serum deprivation. In the presence of serum, copper levels were not significantly affected by the expression of PrP and/or PrPLP/Dpl, whereas serum deprivation induced a decrease in copper levels that was inhibited by PrP but not by PrPLP/Dpl. The inhibitory effect of PrP on the decrease of copper levels was prevented by overexpression of PrPLP/Dpl. These findings indicate that PrP specifically stabilizes copper homeostasis, which is perturbed under oxidative conditions, while PrPLP/Dpl overexpression prevents PrP function in copper homeostasis, suggesting an interaction of PrP and PrPLP/Dpl and distinct functions between PrP and PrPLP/Dpl on metal homeostasis. Taken together, these results strongly suggest that PrP, in addition to its antioxidant properties, plays a role in stabilizing cellular copper homeostasis under oxidative conditions.

Mammalian prion biology: one century of evolving concepts

Prions have been responsible for an entire century of tragic episodes. Fifty years ago, kuru decimated the population of Papua New Guinea. Then, iatrogenic transmission of prions caused more than 250 cases of Creutzfeldt-Jakob disease. More recently, transmission of bovine spongiform encephalopathy to humans caused a widespread health scare. On the other hand, the biology of prions represents a fascinating and poorly understood phenomenon, which may account for more than just diseases and may represent a fundamental mechanism of crosstalk between proteins. The two decades since Stanley Prusiner's formulation of the protein-only hypothesis have witnessed spectacular advances, and yet some of the most basic questions in prion science have remained unanswered.

Copper binding in the prion protein

A conformational change of the prion protein is responsible for a class of neurodegenerative diseases called the transmissible spongiform encephalopathies that include mad cow disease and the human afflictions kuru and Creutzfeldt-Jakob disease. Despite the attention given to these diseases, the normal function of the prion protein in healthy tissue is unknown. Research over the past few years, however, demonstrates that the prion protein is a copper binding protein with high selectivity for Cu(2+). The structural features of the Cu(2+) binding sites have now been characterized and are providing important clues about the normal function of the prion protein and perhaps how metals or loss of protein function play a role in disease. The link between prion protein and copper may provide insight into the general, and recently appreciated, role of metals in neurodegenerative disease.

PrPc on the road: trafficking of the cellular prion protein

The glycosylphosphatidylinositol (GPI)-anchored cellular prion protein (PrPc) has a fundamental role in prion diseases. Intracellular trafficking of PrPc is important in the generation of protease resistant PrP species but little is known of how endocytosis affects PrPc function. Here, we discuss recent experiments that have illuminated how PrPc is internalized and what are the possible destinations taken by the protein. Contrary to what would be expected for a GPI-anchored protein there is increasing evidence that clathrin-mediated endocytosis and classical endocytic organelles participate in PrPc trafficking. Moreover, the N-terminal domain of PrPc may be involved in sorting events that can direct the protein during its intracellular journey. Indeed, the concept that the GPI-anchor determines PrPc trafficking has been challenged. Cellular signaling can be triggered or be regulated by PrPc and we suggest that endocytosis of PrPc may influence signaling in several ways. Definition of the processes that participate in PrPc endocytosis and intracellular trafficking can have a major impact on our understanding of the mechanisms involved in PrPc function and conversion to protease resistant conformations.

Prion protein and the molecular features of transmissible spongiform encephalopathy agents

Transmissible spongiform encephalopathy (TSE) diseases, or prion diseases, are neurodegenerative diseases found in a number of mammals, including man. Although they are generally rare, TSEs are always fatal, and as of yet there are no practical therapeutic avenues to slow the course of disease. The epidemic of bovine spongiform encephalopathy (BSE) in the UK greatly increased the awareness of TSE diseases. Although it appears that BSE has not spread to North America, chronic wasting disease (CWD), a TSE found in cervids, is causing significant concern. Despite decades of investigation, the exact nature of the infectious agent of the TSEs is still controversial. Although many questions remain, substantial efforts have been made to understand the molecular features of TSE agents, with the hope of enhancing diagnosis and treatment of disease, as well as understanding the fundamental nature of the infectious agent itself. This review summarizes the current understanding of these molecular features, focusing on the role of the prion protein (PrP(c)) and its relationship to the disease-associated isoform (PrP(Sc)).

Copper Chelation Delays the Onset of Prion Disease

The prion protein (PrP) binds copper and under some conditions copper can facilitate its folding into a more protease resistant form. Hence, copper levels may influence the infectivity of the scrapie form of prion protein (PrPSc). To determine the feasibility of copper-targeted therapy for prion disease, we treated mice with a copper chelator, D-(-)-penicillamine (D-PEN), starting immediately following intraperitoneal scrapie inoculation. D-PEN delayed the onset of prion disease in the mice by about 11 days (p = 0.002), and reduced copper levels in brain by 29% (p < 0.01) and in blood by 22% (p = 0.03) compared with control animals. Levels of other metals were not significantly altered in the blood or brain. Modest correlation was observed between incubation period and levels of copper in brain (p = 0.08) or blood (p = 0.04), indicating that copper levels are only one of many factors that influence the rate of progression of prion disease. In vitro, copper dose-dependently enhanced the proteinase K resistance of the prion protein, and this effect was counteracted in a dose-dependent manner by co-incubation with D-PEN. Overall, these findings indicate that copper levels can influence the conformational state of PrP, thereby enhancing its infectivity, and this effect can be attenuated by chelator-based therapy.

Prion protein expression modulates neuronal copper content

The prion protein is a copper (Cu)-binding protein. The abnormal isoform of this protein is associated with the transmissible spongiform encephalopathies or prion diseases. In prion diseases, the prion protein loses its Cu binding capacity. The effect of prion protein expression on the Cu content of the brain was investigated. Transgenic mice, either overexpressing the prion protein or expressing a mutant form lacking the Cu-binding region of the protein, were compared with wild-type mice and mice in which expression of the protein was knocked out. Age-dependent differences in Cu content of the brain were detected. Also, synaptosomal fractions from the brains of the mice showed different Cu content depending on the expression of the prion protein. Mice expressing prion protein, but without the Cu-binding domain showed reduced Cu content. Mice overexpressing the prion protein showed little difference in Cu in the brain compared with wild type but also the prion protein expressed by the mice showed a reduction in the level of Cu bound. These results confirm that prion protein expression modulates the Cu level found at the synapse and this effect is dependent on its Cu binding capacity. Loss of normal Cu binding by the prion protein altered age-related increases in metals in the brain. This may explain why many forms of human prion disease do not develop until late in life.

Regulation of intrinsic prion protein by growth factors and TNF-alpha: the role of intracellular reactive oxygen species

Function and regulation of the intrinsic prion protein (PrPc) are largely unknown. In the present study the regulation of PrPc expression by growth factors and cytokines that increase intracellular reactive oxygen species (ROS) levels was studied in glioma and neuroblastoma cells grown as multicellular tumor spheroids. PrPc protein was significantly increased when glioma spheroids were treated with either ATP, nerve growth factor (NGF), epidermal growth factor (EGF), or tumor necrosis factor alpha (TNF-alpha), whereas mRNA levels as evaluated by Reverse Transcriptase-Polymerase Chain Reaction (RT-PCR) remained unchanged. ATP, NGF, EGF, and TNF-alpha raised intracellular ROS levels as evaluated using the redox-sensitive fluorescence dye 2'7'-dichlorodihydrofluorescein diacetate (H2DCFDA). The observed elevation in PrPc was completely abolished in the presence of the free radical scavengers vitamin E and ebselen, as well as following pretreatment with the NADPH-oxidase inhibitor diphenylen iodonium chloride (DPI), indicating that PrPc levels are regulated by intracellular ROS. The correlation of PrPc expression to the intracellular ROS levels was investigated by the use of neuroblastoma cells overexpressing either mutant V210I PrP, or wild-type PrPc. It was observed that the intracellular redox state was significantly reduced in PrPc as well as V210I PrP overexpressing cells as compared to non-transfected cells. Consequently, the observed elevation of ROS following treatment with ATP was completely abolished in PrP overexpressing cells. Our data are in line with the assumption that PrPc plays a role as free radical scavenger and/or sensor molecule for oxidative stress.

Copper and zinc cause delivery of the prion protein from the plasma membrane to a subset of early endosomes and the Golgi

The cellular isoform of prion protein (PrPC) is a plasma membrane glycoprotein whose conformational conversion into PrPSc is the central molecular event in the propagation of infectious prions. However, the physiological function of PrPC has remained uncertain. The finding that PrPC binds copper ions with low micromolar affinity, coupled with several other observations, has led to the proposal that the protein plays a role in copper homeostasis. Using biochemical techniques, we had shown previously that copper ions rapidly and reversibly stimulate endocytosis of PrPC from the cell surface. In this report, we employ immunofluorescence microscopy to further investigate the specificity and kinetics of metal effects on PrPC trafficking and to identify the intracellular compartments to which internalized PrPC is delivered in response to copper and zinc. We find that both of these metals stimulate redistribution of surface PrPC to a subset of transferrin-containing early endosomes as well as to Golgi compartments. These results are consistent with models in which PrPC plays a role in the cellular uptake or efflux of transition metals.

Impairment of superoxide dismutase activation by N-terminally truncated prion protein (PrP) in PrP-deficient neuronal cell line

Previous studies have reported a neuroprotective role for cellular prion protein (PrP(C)) against apoptosis induced by serum deprivation in an immortalized prion protein gene (Prnp)-deficient neuronal cell line, but the mechanisms remain unclear. In this study, to investigate the mechanisms by which PrP(C) prevents apoptosis, the authors compared apoptosis of Prnp(-/-) cells with that of Prnp(-/-) cells expressing the wild-type PrP(C) or PrP(C) lacking N-terminal octapeptide repeat region under serum-free conditions. Re-introduction of Prnp rescued cells from apoptosis, upregulated superoxide dismutase (SOD) activity, enhanced superoxide anion elimination, and inhibited caspase-3/9 activation. On the other hand, N-terminally truncated PrP(C) enhanced apoptosis accompanied by potentiation of superoxide production and caspase-3/9 activation due to inhibition of SOD. These results suggest that PrP(C) protects Prnp(-/-) cells from apoptosis via superoxide- and caspase-3/9-dependent pathways by upregulating SOD activity. Furthermore, the octapeptide repeat region of PrP(C) plays an essential role in regulating apoptosis and SOD activity.

Cellular prion protein function in copper homeostasis and redox signalling at the synapse

The fundamental physiological function of native cellular prion (PrPC) remains unknown. Herein, the most salient observations as regards prion physiology are critically evaluated. These include: (i) the role of PrPC in copper homeostasis, particularly at the pre-synaptic membrane; (ii) involvement of PrPC in neuronal calcium disturbances; and (iii) the neuroprotective properties of PrPC in response to copper and oxidative stress. Ultimately, a tentative hypothesis of basic prion function is derived, namely that PrPC acts as a sensor for copper and/or free radical stimuli, thereby triggering intracellular calcium signals that finally translate into modulation of synaptic transmission and maintenance of neuronal integrity.

The prion protein and neuronal zinc homeostasis

Although the prion protein (PrP) is known to be the causative agent of the neurodegenerative transmissible spongiform encephalopathies, its normal cellular function remains elusive. Octapeptide repeats in the N terminus of PrP bind metal ions and are required for the endocytosis of PrP upon exposure of cells to copper or zinc. As the concentration of zinc in the extracellular spaces of the brain is higher than that for copper, we put forward the hypothesis that PrP is involved in neuronal zinc homeostasis; PrP might be involved in transport of zinc into the cell or might act as a zinc sensor. In prion disease, when the protein undergoes a conformational change to the infectious form, this function of PrP in zinc homeostasis might be compromised.

Deletion of N-terminal residues 23-88 from prion protein (PrP) abrogates the potential to rescue PrP-deficient mice from PrP-like protein/doppel-induced Neurodegeneration

Accumulating evidence has suggested that prion protein (PrP) is neuroprotective and that a PrP-like protein/Doppel (PrPLP/Dpl) is neurotoxic. A line of PrP-deficient mice, Ngsk Prnp0/0, ectopically expressing PrPLP/Dpl in neurons, exhibits late-onset ataxia because of Purkinje cell death that is prevented by a transgene encoding wild-type mouse PrP. To elucidate the mechanisms of neurodegeneration in these mice, we introduced five types of PrP transgene, namely one heterologous hamster, two mouse/hamster chimeric genes, and two mutants, each of which encoded PrP lacking residues 23-88 (MHM2.del23-88) or with E199K substitution (Mo.E199K), into Ngsk Prnp0/0 mice. Only MHM2.del23-88 failed to rescue the mice from the Purkinje cell death. The transgenic mice, MHM2.del23-88/Ngsk Prnp0/0, expressed several times more PrP than did wild-type (Prnp+/+) mice and PrPLP/Dpl at an equivalent level to Ngsk Prnp0/0 mice. Little difference was observed in the pathology and onset of ataxia between Ngsk Prnp0/0 and MHM2.del23-88/Ngsk Prnp0/0. No detergent-insoluble PrPLP/Dpl was detectable in the central nervous system of Ngsk Prnp0/0 mice even after the onset of ataxia. Our findings provide evidence that the N-terminal residues 23-88 of PrP containing the unique octapeptide-repeat region is crucial for preventing Purkinje cell death in Prnp0/0 mice expressing PrPLP/Dpl in the neuron.

Copper coordination in the full-length, recombinant prion protein

The prion protein (PrP) binds divalent copper at physiologically relevant conditions and is believed to participate in copper regulation or act as a copper-dependent enzyme. Ongoing studies aim at determining the molecular features of the copper binding sites. The emerging consensus is that most copper binds in the octarepeat domain, which is composed of four or more copies of the fundamental sequence PHGGGWGQ. Previous work from our laboratory using PrP-derived peptides, in conjunction with EPR and X-ray crystallography, demonstrated that the HGGGW segment constitutes the fundamental binding unit in the octarepeat domain [Burns et al. (2002) Biochemistry 41, 3991-4001; Aronoff-Spencer et al. (2000) Biochemistry 39, 13760-13771]. Copper coordination arises from the His imidazole and sequential deprotonated glycine amides. In this present work, recombinant, full-length Syrian hamster PrP is investigated using EPR methodologies. Four copper ions are taken up in the octarepeat domain, which supports previous findings. However, quantification studies reveal a fifth binding site in the flexible region between the octarepeats and the PrP globular C-terminal domain. A series of PrP peptide constructs show that this site involves His96 in the PrP(92-96) segment GGGTH. Further examination by X-band EPR, S-band EPR, and electron spin-echo envelope spectroscopy, demonstrates coordination by the His96 imidazole and the glycine preceding the threonine. The copper affinity for this type of binding site is highly pH dependent, and EPR studies here show that recombinant PrP loses its affinity for copper below pH 6.0. These studies seem to provide a complete profile of the copper binding sites in PrP and support the hypothesis that PrP function is related to its ability to bind copper in a pH-dependent fashion.

Is loss of function of the prion protein the cause of prion disorders?

Transmissible spongiform encephalopathies are fatal neurodegenerative diseases that involve misfolding of the prion protein. Recent studies have provided evidence that normal prion protein might have a physiological function in neuroprotective signaling, suggesting that loss of prion protein activity might contribute to the pathogenesis of prion disease. However, studies using knockout animals do not support the loss-of-function hypothesis and argue that prion neurodegeneration might be associated with a gain of a toxic activity by the misfolded prion protein. Thus, the mechanism of neurodegeneration in spongiform encephalopathies remains enigmatic.

Supplying copper to the cuproenzyme peptidylglycine alpha-amidating monooxygenase

We explored the role of known copper transporters and chaperones in delivering copper to peptidylglycine-alpha-hydroxylating monooxygenase (PHM), a copper-dependent enzyme that functions in the secretory pathway lumen. We examined the roles of yeast Ccc2, a P-type ATPase related to human ATP7A (Menkes disease protein) and ATP7B (Wilson disease protein), as well as yeast Atx1, a cytosolic copper chaperone. We expressed soluble PHMcc (catalytic core) in yeast using the yeast pre-pro-alpha-mating factor leader region to target the enzyme to the secretory pathway. Although the yeast genome encodes no PHM-like enzyme, PHMcc expressed in yeast is at least as active as PHMcc produced by mammalian cells. PHMcc partially co-migrated with a Golgi marker during subcellular fractionation and partially co-localized with Ccc2 based on immunofluorescence. To determine whether production of active PHM was dependent on copper trafficking pathways involving the CCC2 or ATX1 genes, we expressed PHMcc in wild-type, ccc2, and atx1 mutant yeast. Although ccc2 and atx1 mutant yeast produce normal levels of PHMcc protein, it lacks catalytic activity. Addition of exogenous copper yields fully active PHMcc. Similarly, production of active PHM in mouse fibroblasts is impaired in the presence of a mutant ATP7A gene. Although delivery of copper to lumenal cuproproteins like PAM involves ATP7A, lumenal chaperones may not be required.

Expression of prion protein increases cellular copper binding and antioxidant enzyme activities but not copper delivery

The N-terminal region of the prion protein PrP(C) contains a series of octapeptide repeats. This region has been implicated in the binding of divalent metal ions, particularly copper. PrP(C) has been suggested to be involved in copper transport and metabolism and in cell defense mechanisms against oxidative insult, possibly through the regulation of the intracellular CuZn superoxide dismutase activity (CuZn-SOD) or a SOD-like activity of PrP(C) itself. However, up to now the link between PrP(C) expression and copper metabolism or SOD activity has still to be formally established; particularly because conflicting results have been obtained in vivo. In this study, we report a link between PrP(C), copper binding, and resistance to oxidative stress. Radioactive copper ((64)Cu) was used at a physiological concentration to demonstrate that binding of copper to the outer plasma cell membrane is related to the level of PrP(C) expression in a cell line expressing a doxycycline-inducible murine PrP(C) gene. Cellular PIPLC pretreatment indicated that PrP(C) was not involved in copper delivery at physiological concentrations. We also demonstrated that murine PrP(C) expression increases several antioxidant enzyme activities and glutathione levels. Prion protein may be a stress sensor sensitive to copper and able to initiate, following copper binding, a signal transduction process acting on the antioxidant systems to improve cell defenses.

Stability and Cu(II) binding of prion protein variants related to inherited human prion diseases

All inherited forms of human prion diseases are linked with mutations in the prion protein (PrP) gene. Here we have investigated the stability and Cu(II) binding properties of three recombinant variants of murine full-length PrP(23-231)-containing destabilizing point mutations that are associated with human Gerstmann-Sträussler-Scheinker disease (F198S), Creutzfeld-Jakob disease (E200K), and fatal familial insomnia (D178N) by electron paramagnetic resonance and circular dichroism spectroscopy. Furthermore, we analyzed the variants H140S, H177S, and H187S of the isolated C-terminal domain of murine PrP, mPrP(121-231), to test a role of the histidine residues in Cu(II) binding. The F198S and E200K variants of PrP(23-231) differed in Cu(II) binding from the wild-type mPrP(23-231). However, circular dichroism spectroscopy indicated that the variants and the wild type did not undergo conformational changes in the presence of Cu(II). The D178N variant showed a high tendency to aggregate at pH 7.4 both with and without Cu(II). At lower pH values, it showed the same Cu(II) binding behavior as the wild type. The analysis allowed for a better location of the Cu(II) binding sites in the C-terminal part of the protein. Our present data indicate that hereditary forms of prion diseases cannot be rationalized on the basis of altered Cu(II) binding or mutation-induced protein destabilization alone.

Three-dimensional structures of the prion protein and its doppel

This article discussed the implications of the structures of PrP and Dpl--with their unusual folds containing N-terminal flexible tails and C-terminal globular domains--to the physiologic functions of PrPC and Dpl, and investigations of a possible structural basis of familial human TSEs. Further relations between TSEs and the PrP structure would include the species barrier of TSEs (which seems to be associated with species-specific structural characteristics of PrPC [25,39,67]), and the conformational transition from PrPC to PrPSc using, for example, molecular dynamic simulations [68,69]. Due to the lack of knowledge on physiologic functions of PrPC, however, and the remaining uncertainty about the exact role of the PrP in TSE pathology, it appears that most or all of the physiologically relevant structure-function correlations of PrPC have yet to be identified.

Copper binding to the octarepeats of the prion protein. Affinity, specificity, folding, and cooperativity: insights from circular dichroism

The prion protein (PrP) is a Cu(2+) binding cell surface glycoprotein. There is increasing evidence that PrP functions as a copper transporter. In addition, strains of prion disease have been linked with copper binding. We present here CD spectroscopic studies of Cu(2+) binding to various fragments of the octarepeat region of the prion protein. We show that glycine and l-histidine will successfully compete for all Cu(2+) ions bound to the PrP octapeptide region, suggesting Cu(2+) coordinates with a lower affinity for PrP than the fm dissociation constant reported previously. We show that each of the octarepeats do not form an isolated Cu(2+) binding motif but fold up cooperatively within multiple repeats. In addition to the coordinating histidine side chain residues, we show that the glycine residues and the proline within each octarepeat are also necessary to maintain the coordination geometry. The highly conserved octarepeat region in mammals is a hexarepeat in birds that also binds copper but with different coordination geometry. Finally, in contrast to other reports, we show that Mn(2+) does not bind to the octarepeat region of PrP.

No Superoxide Dismutase Activity of Cellular Prion Protein in vivo

Prion diseases are characterized by the deposition of PrP(Sc), an abnormal form of the cellular prion protein PrP(C), which is encoded by the Prnp gene. PrP(C) is highly expressed on neurons and its function is unknown. Recombinant PrP(C) was claimed to possess superoxide dismutase (SOD) activity, and it was hypothesized that abrogation of this function may contribute to neurodegeneration in prion diseases. We tested this hypothesis in vivo by studying copper/zinc and manganese SOD activity in genetically defined crosses of mice lacking the Sod1 gene with mice lacking PrP(C), and with hemizygous or homozygous tga20 transgenic mice overexpressing various levels of PrP(C). We failed to detect any influence of the Prnp genotype and gene dosage on SOD1 or SOD2 activity in heart, spleen, brain, and synaptosome-enriched brain fractions. Control experiments included crosses of mice lacking or overexpressing PrPc with mice overexpressing human Cu2+/Zn2+-superoxide dismutase, and confirmed that SOD enzymatic activity correlated exclusively with the gene dosage of bona fide human or murine SOD. We conclude that PrP(C) in vivo does not discernibly contribute to total SOD activity and does not possess an intrinsic dismutase activity.

Prions and the immune system: a journey through gut, spleen, and nerves

For more than two decades it has been contended that prion infection does not elicit immune responses: transmissible spongiform encephalopathies do not go along with conspicuous inflammatory infiltrates, and antibodies to the prion protein are typically undetectable. Why is it, then, that prions accumulate in lymphoid organs, and that various states of immune deficiency prevent peripheral prion infection? This review revisits the current evidence of the involvement of the immune system in prion diseases, while attempting to trace the elaborate mechanisms by which peripherally administered prions invade the brain and ultimately cause damage. The investigation of these questions leads to unexpected detours, including the neurophysiology of lymphoid organs, and even the function of a prion protein homolog in male fertility.

Putative functions of PrP(C)

While the exact function of the cellular prion protein (PrP(C)) remains unknown, there are several leads due to increasing knowledge on the localisation and interaction of PrP(C) with other molecules. This chapter will concentrate on these aspects. Identified ligands of PrP(C) mainly belong to the categories of heat-shock proteins, membrane-bound receptors, or heparan sulphates. The possible synaptic role of PrP(C) has been exemplified by electrophysiological findings in PrP(o/o) mice and the studies of PrP(C) as a copper-binding molecule that could regulate the copper content of the synaptic cleft. The latter property of PrP(C) may also endow PrP(C) with the activity of a copper-dependent superoxide dismutase. Binding of PrP(C) to signalling molecules suggests a role as a transmitter of information from the extracellular milieu to the cell and a trigger for a molecular cascade. This agrees with new data on PrP(C) receptors and the role of PrP(C) in cell survival.