The cellular prion protein colocalizes with the dystroglycan complex in the brain

The function of PrP(C), the cellular prion protein (PrP), is still unknown. Like other glycophosphatidylinositol-anchored proteins, PrP resides on Triton-insoluble, cholesterol-rich membranous microdomains, termed rafts. We have recently shown that the activity and subcellular localization of the neuronal isoform of nitric oxide synthase (nNOS) are impaired in adult PrP(0/0) mice as well as in scrapie-infected mice. In this study, we sought to determine whether PrP and nNOS are part of the same functional complex and, if so, to identify additional components of such a complex. To this aim, we looked for proteins that coimmunoprecipitated with PrP in the presence of detergents either that completely dissociate rafts, to identify stronger interactions, or that preserve the raft structure, to identify weaker interactions. Using this detergent-dependent immunoprecipitation protocol we found that PrP interacts strongly with dystroglycan, a transmembrane protein that is the core of the dystrophin-glycoprotein complex (DGC). Additional results suggest that PrP also interacts with additional members of the DGC, including nNOS. PrP coprecipitated only with established presynaptic proteins, consistent with recent findings suggesting that PrP is a presynaptic protein.     

Microtubules-associated intracellular localization of the NH2-terminal cellular prion protein fragment

By utilizing double-labeled fluorescent cellular prion protein (PrPC), we revealed that the NH2-terminal and COOH-terminal PrPC fragments exhibit distinct distribution patterns in mouse neuroblastoma neuro2a (N2a) cells and HpL3-4, a hippocampal cell line established from prnp gene-ablated mice [Nature 400 (1999) 225]. Of note, the NH2-terminal PrPC fragment, which predominantly localized in the intracellular compartments, congregated in the cytosol after the treatment with a microtubule depolymerizer (nocodazole). Truncated PrPC with the amino acid residues 1-121, 1-111, and 1-91 in mouse (Mo) PrP exhibited a proper distribution profile, whereas those with amino acid residues 1-52 and 1-33 did not. These data indicate the microtubules-associated intracellular localization of the NH2-terminal PrPC fragment containing at least the 1-91 amino acid residues.     

The role of glycophosphatidylinositol anchor in the amplification of the scrapie isoform of prion protein in vitro

Transmissible spongiform encephalopathies are associated with an autocatalytic conversion of normal prion protein, PrP^C, to a protease-resistant form, PrPres. This autocatalytic reaction can be reproduced in vitro using a procedure called protein misfolding cyclic amplification (PMCA). Here we show that, unlike brain-derived PrP^C, bacterially-expressed recombinant prion protein (rPrP) is a poor substrate for PrPres amplification in a standard PMCA reaction. The differences between PrP^C and rPrP appear to be due to the lack of the glycophosphatidylinositol anchor in the recombinant protein. These findings shed a new light on prion protein conversion process and have important implications for the efforts to generate synthetic prions for structural and biophysical studies.     

Immunological characterization of the sheep prion protein expressed as fusion proteins in Escherichia coli

The prion protein (PrP) from sheep was produced in large quantities of entire protein in Escherichia coli after fusion with a carboxy-terminal hexahistidine sequence. In contrast, amino-terminal fusion with glutathione S-transferase (GST) revealed a high susceptibility toward cleavage of the protein. Both recombinant proteins were recognised, at variable levels, in Western blots using a panel of antibodies against the 40-56, 89-104, 98-113 and 112-115 sequences of the prion protein, similarly to the abnormal prion protein extracted from scrapie-infected sheep. Interestingly, monoclonal antibody 3F4 was found to react with these three proteins in Western blot.     

Proteolytic processing of the ovine prion protein in cell cultures

The cellular compartment and purpose of the proteolytic processing of the prion protein (PrP) are still under debate. We have studied ovine PrP constructs expressed in four cell lines; murine neuroblastoma cells (N2a), human neuroblastoma cells (SH-SY5Y), dog kidney epithelial cells (MDCK), and human furin-deficient colon cancer cells (LoVo). Cleavage of PrP in LoVo cells indicates that the processing is furin independent. Neither is it reduced by some inhibitors of lysosomal proteinases, proteasomes or zinc-metalloproteinases, but incubation with bafilomycin A1, an inhibitor of vacuolar H+/ATPases, increases the amount of uncleaved PrP in the apical medium of MDCK cells. Mutations affecting the putative cleavage site near amino acid 113 reveal that the cleavage is independent of primary structure at this site. Absence of glycosylphosphatidylinositol anchor and glycan modifications does not influence the proteolytic processing of PrP. Our data indicate that PrP is cleaved during transit to the cell membrane.     

Concealment of epitope by reduction and alkylation in prion protein

Conversion of the cellular prion protein (PrP(C)) into its pathological isoform (PrP(Sc)), the key molecular event in the pathogenesis of prion diseases, is accompanied by a conformational transition of alpha-helix into beta-sheet structures involving alpha-helix 1 (alpha1) domain from residues 144 to 154 of the protein. Reduction and alkylation of PrP(C) have been found to inhibit the conversion of PrP(C) into PrP(Sc) in vitro. Here we report that while antibody affinity of epitopes in the N- and C-terminal domains remained unchanged, reduction and alkylation of the PrP molecule induced complete concealment of an epitope in alpha1 for anti-PrP antibody 6H4 that is able to cure prion infection in the cell model. Mass spectrometric analysis of recombinant PrP showed that the alkylation reaction takes place at reduced cysteines but no modification was observed in this cryptic epitope. Our study suggests that reduction and alkylation result in local or global rearrangement of PrP tertiary structure that is maintained in both liquid and solid phases. The implications in the conversion of PrP(C) into PrP(Sc) and the therapeutics of prion diseases are discussed.     

Use of capillary sodium dodecyl sulfate gel electrophoresis to detect the prion protein extracted from scrapie-infected sheep

Scrapie in sheep and in goats is the prototype of a group of transmissible spongiform encephalopathies (TSE). A feature of these diseases is the accumulation in the brain of rod shaped fibrils that form from an aggregated protein that is a protease-resistant form of a modified normal host cell protein. In this study, we compared SDS gel capillary electrophoresis to conventional SDS-PAGE and Western blot to detect the monomer of this aggregated protein. This prion protein was extracted from the sheep brain by homogenizing the brain stem (10%, w/v) in 0.32 M sucrose and by using a series of ultracentrifugation steps and treatment with sodium lauroyl sarcosine and proteinase K. After the final centrifucation step, the pellet was resuspended in 0.01 M Tris pH 7.4 in a volume equivalent to 0.1 ml/g of brain used. This resuspended pellet was treated with 1% SDS and 5% 2-mercaptoethanol and boiled for 10 min. The analysis was done in a Beckman P/ACE 5500 using a SDS gel capillary (eCap SDS14-200 Beckman capillary). In infected sheep brain samples, but not normal sheep, a major peak at a molecular mass of 16.1 kDa and a minor peak with a leading shoulder were observed. Since the molecular mass determined for this protein was lower than that estimated on Western blot (22.4 kDa), a Ferguson plot was made to determine if there were abberations in the molecular mass determination. After correction, the major peak was estimated to be 19.2 kDa. This has a better correlation with that determined by SDS-PAGE and Western blot. The equivalent amount of brain sample in the capillary was 50 μg. For Western blot, the amount of brain sample was 20 mg. For this assay, this is 100 times less than that needed for Western blot for sheep samples.     

Comparison studies of the structural stability of rabbit prion protein with human and mouse prion proteins

Background: Prion diseases are fatal and infectious neurodegenerative diseases affecting humans and animals. Rabbits are one of the few mammalian species reported to be resistant to infection from prion diseases isolated from other species (I. Vorberg et al., Journal of Virology 77 (3) (2003) 2003-2009). Thus the study of rabbit prion protein structure to obtain insight into the immunity of rabbits to prion diseases is very important.Findings: The paper is a straight forward molecular dynamics simulation study of wild-type rabbit prion protein (monomer cellular form) which apparently resists the formation of the scrapie form. The comparison analyses with human and mouse prion proteins done so far show that the rabbit prion protein has a stable structure. The main point is that the enhanced stability of the C-terminal ordered region especially helix 2 through the D177-R163 salt-bridge formation renders the rabbit prion protein stable. The salt bridge D201-R155 linking helixes 3 and 1 also contributes to the structural stability of rabbit prion protein. The hydrogen bond H186-R155 partially contributes to the structural stability of rabbit prion protein.Conclusions: Rabbit prion protein was found to own the structural stability, the salt bridges D177-R163, D201-R155 greatly contribute and the hydrogen bond H186-R155 partially contributes to this structural stability. The comparison of the structural stability of prion proteins from the three species rabbit, human and mouse showed that the human and mouse prion protein structures were not affected by the removing these two salt bridges. Dima et al. (Biophysical Journal 83 (2002) 1268-1280 and Proceedings of the National Academy of Sciences of the United States of America 101 (2004) 15335-15340) also confirmed this point and pointed out that “correlated mutations that reduce the frustration in the second half of helix 2 in mammalian prion proteins could inhibit the formation of PrP^Sc”.     

Direct interaction between prion protein and tubulin

Recently published data show that the prion protein in its cellular form (PrP(C)) is a component of multimolecular complexes. In this report, zero-length cross-linking with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) allowed us to identify tubulin as one of the molecules interacting with PrP(C) in complexes observed in porcine brain extracts. We found that porcine brain tubulin added to these extracts can be cross-linked with PrP(C). Moreover, we observed that the 34 kDa species identified previously as full-length diglycosylated prion protein co-purifies with tubulin. Cross-linking of PrP(C) species separated by Cu(2+)-loaded immobilized metal affinity chromatography confirmed that only the full-length protein but not the N-terminally truncated form (C1) binds to tubulin. By means of EDC cross-linking and cosedimentation experiments, we also demonstrated a direct interaction of recombinant human PrP (rPrP) with tubulin. The stoichiometry of cosedimentation implies that rPrP molecules are able to bind both the alpha- and beta-isoforms of tubulin composing microtubule. Furthermore, prion protein exhibits higher affinity for microtubules than for unpolymerized tubulin.     

The octarepeat region of prion protein, but not the TM1 domain, is important for the antioxidant effect of prion protein

The cellular prion protein (PrP(c)) plays a crucial role in the pathogenesis of prion diseases, but its physiological function is far from understood. Several candidate functions have been proposed including binding and internalization of metal ions, a superoxide dismutase-like activity, regulation of cellular antioxidant activities, and signal transduction. The transmembrane (TM1) region of PrP(c) (residues 110-135) is particularly interesting because of its very high evolutionary conservation. We investigated a possible role of TM1 in the antioxidant defense, by assessing the impact of overexpressing wt-PrP or deletion mutants in N(2)A mouse neuroblastoma cells on intracellular reactive oxygen species (ROS) levels. Under conditions of oxidative stress, intracellular ROS levels were significantly lowered in cells overexpressing either wild-type PrP(c) (wt-PrP) or a deletion mutant affecting TM1 (Delta8TM1-PrP), but, as expected, not in cultures overexpressing a deletion mutant lacking the octapeptide region (Deltaocta-PrP). Overexpression of wt-PrP, Delta8TM1-PrP, or Deltaocta-PrP did not affect basal ROS levels. Interestingly, the mitochondrial membrane potential was significantly lowered in Deltaocta-PrP-transfected cultures in the absence of oxidative stress. We conclude that the protective effect of PrP(c) against oxidative stress involves the octarepeat region but not the TM1 domain nor the high-affinity copper binding site described for human residues His96/His111.     

Stimulation of cellular prion protein expression by TSH in human thyrocytes

The cellular isoform of prion protein (PrP(C)) is a cell-surface glycosyl-phosphatidylinositol-anchored protein which is ubiquitously expressed on the cell membrane. It may function as a cell receptor or as a cell adhesion molecule. Thyroid follicles, obtained from patients with Graves' disease at thyroidectomy, were cultured in F-12/RPMI-1640 medium supplemented with 0.5% fetal bovine serum and bovine thyroid stimulating hormone (bTSH). Northern blot analyses revealed that bTSH increased the steady-state expression levels of PrP mRNA in a time- and dose-dependent manner. This increase was reproduced by dibutyryl-cAMP and 12-decanoylphorbol-13-acetate. The mRNA expression was greater in thyroid follicles in suspension culture than in thyrocytes cultured in a monolayer. These findings suggest that TSH stimulates PrP mRNA expression in thyrocytes through the protein kinase A and C pathways. The greater mRNA expression in thyroid follicles than in monolayer cells suggests that PrP(C) may be involved in structure formation or maintenance of thyroid follicles.     

Strain-specified relative conformational stability of the scrapie prion protein

Studies of prion biology and diseases have elucidated several new concepts, but none was more heretical than the proposal that the biological properties that distinguish different prion strains are enciphered in the disease-causing prion protein (PrP(Sc)). To explore this postulate, we examined the properties of PrP(Sc) from eight prion isolates that propagate in Syrian hamster (SHa). Using resistance to protease digestion as a marker for the undenatured protein, we examined the conformational stabilities of these PrP(Sc) molecules. All eight isolates showed sigmoidal patterns of transition from native to denatured PrP(Sc) as a function of increasing guanidine hydrochloride (GdnHCl) concentration. Half-maximal denaturation occurred at a mean value of 1.48 M GdnHCl for the Sc237, HY, SHa(Me7), and MT-C5 isolates, all of which have approximately 75-d incubation periods; a concentration of 1.08 M was found for the DY strain with a approximately 170-d incubation period and approximately 1.25 M for the SHa(RML) and 139H isolates with approximately 180-d incubation periods. A mean value of 1.39 M GdnHCl for the Me7-H strain with a approximately 320-d incubation period was found. Based on these results, the eight prion strains segregated into four distinct groups. Our results support the unorthodox proposal that distinct PrP(Sc) conformers encipher the biological properties of prion strains.     

The number of octapeptide repeat affects the expression and conversion of prion protein

The human prion protein (PrP) has five copies of an octapeptide repeat (OR). The mutant PrP with 6-14 OR causes the genetic form of Creutzfeldt-Jakob disease (CJD). To determine the influence of OR on the conversion of PrP, we examined the conversion efficiency of mouse mutant PrP molecules with 1-16 OR in scrapie-infected cells. The expression level of mutant PrP and the glycoform ratio of the abnormal isoform of PrP (PrP^Sc) were affected by the number of OR. The conversion efficiency was almost equivalent among mutant PrP molecules with 5-16 OR, whereas that of mutant PrP with 1-4 OR was decreased. The present study suggests that CJD patients with the longer extra OR, who usually show only a trace of PrP^Sc in the brain, can produce the authentic triplet PrP^Sc if secondary prion infection occurs.     

Identification of the internal ribosome entry sites (IRES) of prion protein gene

Many studies demonstrated that there are several type bands of prion protein in cells. However, the formation of different prion protein bands is elusive. After several low molecular weight bands of prion protein appeared in SMB-S15 cells infected with scrapie agent Chandler, we think that IRES-dependent translation mechanism induced by prion is involved in the formation of prion protein bands. Then we designed a series of pPrP-GFP fusing plasmids and bicistronic plasmids to identify the IRES sites of prion protein gene and found 3 IRES sites inside of PrP mRNA. We also demonstrated that cap-independent translation of PrP was associated with the ER stress through Tunicamycin treatment. We still found that only IRE1 and PERK pathway regulated the IRES-dependent translation of PrP in this study. Our results indicated, we found that PrP gene had an IRES-dependent translation initiation mechanism and we successfully identified the IRESs inside of the prion protein gene.     

Traffic of prion protein between different compartments on the neuronal surface, and the propagation of prion disease

The key mechanism in prion disease is the conversion of cellular prion protein into an altered, pathogenic conformation, in which cellular mechanisms play a poorly understood role. Both forms of prion protein are lipid-anchored and reside in rafts that appear to protect the native conformation against conversion. Neurons rapidly traffic their cellular prion protein out of its lipid rafts to be endocytosed via coated pits before recycling back to the cell surface. It is argued in this review that understanding the mechanism of this trafficking holds the key to understanding the cellular role in the conformational conversion of prion protein.     

Chicken antibody against a restrictive epitope of prion protein distinguishes normal and abnormal prion proteins

Recently, we reported the application of a recombinant chicken IgY monoclonal antibody, Ab3-15, against mammalian prion protein (PrP), for the diagnosis of bovine spongiform encephalopathy in cattle. In this study, we have characterized a soluble, single-chain variable fragment (scFv) form of this antibody, sphAb3-15 using brain homogenates from mice. This sphAb3-15 antibody recognized denatured forms of both PrP(C) and PrP(Sc), and PrP(Sc) after PK-treatment, on Western blotting. In sandwich ELISAs, on dot blots and by immunoprecipitation, sphAb3-15 efficiently bound to PrP from normal brain homogenates, but weakly bound PrP from scrapie-infected brain homogenates. These results suggest that sphAb3-15 selectively recognizes PrP(C) under native conditions and that the epitope recognized by sphAb3-15 may undergo conformational changes during the conversion of PrP(C) into PrP(Sc).     

The cellular prion protein: biochemistry,topology, and physiologic functions

Studies on the transmission from man to animals of Creutzfeld-Jacob disease (CJD) led Prusiner to identify a proteinaceous infectious particle lacking nucleic acid, which was called prion. The identification of the infectious prion (PrPsc) then led to the discovery of the normal cellular counterpart (PrPc). One of the still enigmatic aspects regarding prion diseases is actually how, where, and when the transformation PrPc/PrPsc is occurring, this being due to the result of a large extent to the fact that so far most studies have been dedicated to the formation and transmission of PrPsc, whereas the understanding of physiologic roles of PrPc are in their infancy. In this review, we hope to identify the most reliable hypotheses for future experiments on PrPc. This is relevant not only for the understanding of PrPc functions but also to unravel the enigmatic nature of PrPc/PrPsc conversion.     

Generating recombinant C-terminal prion protein fragments of exact native sequence

Transmissibility and distinctive neuropathology are hallmark features of prion diseases differentiating them from other neurodegenerative disorders, with pathogenesis and transmission appearing closely linked to misfolded conformers (PrP(Sc)) of the ubiquitously expressed cellular form of the prion protein (PrP(C)). Given the apparent pathogenic primacy of misfolded PrP, the utilisation of peptides based on the prion protein has formed an integral approach for providing insights into misfolding pathways and pathogenic mechanisms. In parallel with studies employing prion peptides, similar approaches in other neurodegenerative disorders such as Alzheimer Disease, have demonstrated that differential processing of parent proteins and quite minor variations in the primary sequence of cognate peptides generated from the same constitutive processing (such as Aβ1-40 versus Aβ1-42 produced from γ-secretase activity) can be associated with very different pathogenic consequences. PrP(C) also undergoes constitutive α- or β-cleavage yielding C1 (residues 112-231 human sequence) or C2 (residues 90-231), respectively, with the full cell biological significance of such processing unresolved; however, it is noteworthy that in prion diseases, such as Creutzfeldt-Jakob disease (CJD) and murine models, the moderately extended C2 fragment predominates in the brain suggesting that the two cleavage events and the consequent C-terminal fragments may differ in their pathogenic significance. Accordingly, studies characterising biologically relevant peptides like C1 and C2, would be most valid if undertaken using peptides completely free of any inherent non-native sequence that arises as a by-product of commonly employed recombinant production techniques. To achieve this aim and thereby facilitate more representative biophysical and neurotoxicity studies, we adapted the combination of high fidelity Taq TA cloning with a SUMO-Hexa-His tag-type approach, incorporating the SUMO protease step. This technique consistently produced sufficient yields (～10 mg/L) of high purity peptides (>95%) equating to C1 and C2 of exact native primary sequence in the α-helical conformation suitable for biological and biophysical investigations.     

Dividing roles of prion protein in staurosporine-mediated apoptosis

Prion protein (PrPC) is a normal cellular glycoprotein that is expressed in almost all tissues including the central nervous system. Much attention has been focused on this protein because conversion of the normal PrPC to the diseased form (PrPSc) plays an essential role in transmissible spongiform encephalopathies such as mad cow disease and Creutzfeldt-Jakob disease. In spite of the extensive effort, the normal physiological function of PrPC remains elusive. Emerging evidence suggests that PrPC plays a protective role against cellular stresses including apoptosis induced by various pro-apoptotic agents such as Bax and staurosporine (STS), however, other reports showed overexpression of PrPC enhances STS-mediated apoptosis. In this study, we took a different approach by depleting endogenous PrPC using specific interfering RNA technique and compared the depleting and overproducing effects of PrPC on STS-induced apoptosis in neuro-2a (N2a) cells. We demonstrate here that down-regulation of PrPC sensitizes N2a cells to STS-induced cytotoxicity and apoptosis. The enhanced apoptosis induced by STS was shown by increased DNA fragmentation, immunoreactivity of Bax, and caspase-3 cleavage. We also showed that overproduction of PrPC had little or no effect on STS-mediated DNA fragmentation in N2a cells but it augments STS-mediated apoptosis in HEK293 cells, suggesting a cell line-specific effect. In addition, the inhibitory effect of PrPC on STS-mediated cellular stress appears to be modulated in part through induction of cell cycle G2 accumulation. Together, our data suggest that physiological level of endogenous PrPC plays a protective role against STS-mediated cellular stress. Loss of this protection could render cells more prone to cellular insults such as STS.     

朊病毒对中枢神经系统的影响及其作用机制

本文着重叙述了以几个问题：（１）朊病毒能否从牛转移感染到人;（２）朊病毒的感感染途径是怎样的;（３）朊病毒感染有何条件;（４）正常的朊病毒蛋白在神经元和胶质细胞表面表达有何重要功能;（５）朊病毒蛋白功能的结构基因;（６）朊病毒的可能作用机制。最后,分析了朊病毒影响中枢神经系统的两条可能途径,即破坏正常朊病毒蛋白的功能和与小神经胶质细胞共同作用提高神经元对自由基的敏感性及增加氧化自由基的含量。