Hippocampal slices from prion protein null mice: disrupted Ca(2+)-activated K+ currents

Involvement of caveolae and caveolae-like domains in signalling, cell survival and angiogenesis

Caveolae, the flask-shaped membrane invaginations abundant in endothelial cells, have acquired a prominent role in signal transduction. Evidence, that events occurring in caveolae participate in cell survival and angiogenesis, has been recently substantiated by the identification of two novel caveolar constituents: prostacyclin synthase (PGIS) and the cellular form of prion protein (PrP(c)). We have shown that PGIS, previously described as an endoplasmic reticulum component, is bound to caveolin-1 (cav-1) and localized in caveolae in human endothelial cells. By generating prostacyclin, PGIS is involved in angiogenesis. Previous observations regarding the localization of PrP(c) in caveolae-like membrane domains (CLDs) have been recently confirmed and extended. It has been demonstrated that PrP(c) is bound to cav-1 and, by recruiting Fyn kinase, can participate in signal transduction events connected to cell survival and differentiation. The new entries of PGIS and PrP(c) in caveolar components place caveolae and CLDs at the centre of a network, where cells decide whether to proliferate or differentiate and whether to survive or to suicide by apoptosis.

Sleep deprivation in prion protein deficient mice sleep deprivation in prion protein deficient mice and control mice: genotype dependent regional rebound

We have previously reported a larger and more prolonged increase of slow wave activity (SWA) in NREM sleep after sleep deprivation (SD) in prion protein deficient mice (PrP) compared to wild-type mice. Regional differences in the SWA increase were investigated by comparing the effect of 6 h SD on a frontal and occipital derivation in PrP deficient mice and wild-type mice. The larger increase of SWA after SD in PrP deficient mice was restricted to the occipital derivation. The difference appeared after the waking-NREM sleep transitions, making it unlikely that PrP is involved in the mechanisms enabling the transition to sleep. Our findings may reflect differences between the genotypes in the need for recovery in this particular brain region.

Lack of prion protein expression results in a neuronal phenotype sensitive to stress

The prion protein is a highly conserved glycoprotein expressed most highly in the synapse. Evidence has recently been put forward to suggest that the prion protein is an antioxidant. However, the functional importance of the prion protein has been disputed; it is claimed that mice genetically ablated to lack prion protein expression are normal and have no specific phenotype. We have reexamined the phenotype of prion protein knockout mice and found that there are multiple biochemical changes in the mice, including increased levels of nuclear factor NF-kappaB and Mn superoxide dismutase, COX-IV decreased levels of Cu/Zn superoxide dismutase activity, decreased p53, and altered melatonin levels. Additionally, cultured cells from these mice are more sensitive to a range of insults, all linked to increased neuronal sensitivity to oxidative stress. These results imply that prion protein knockout mice are more sensitive to oxidative stress and have an altered phenotype that must be taken into account when considering the additional effects of increased levels of proteins such as Doppel. The implication of these results is that the consequence of genetic ablation of genes must include biochemical analysis as well as analyses of possible developmental and behavioral changes.

Prion protein fragment 106-126 potentiates catecholamine secretion from PC-12 cells

The toxic actions of scrapie prion protein (PrP(sc)) are poorly understood. We investigated the ability of the toxic PrP(sc) fragment 106-126 to interfere with evoked catecholamine secretion from PC-12 cells. Prion protein fragment 106-126 (PrP106-126) caused a time- and concentration-dependent augmentation of exocytosis due to the emergence of a Ca(2+) influx pathway resistant to Cd(2+) but sensitive to other inorganic cations. In control cells, secretion was dependent on Ca(2+) influx through L- and N-type Ca(2+) channels, but after exposure to PrP106-126, secretion was unaffected by N-type channel blockade. Instead, selective L-type channel blockade was as effective as Cd(2+) in suppressing secretion. Patch-clamp recordings revealed no change in total Ca(2+) current density in PrP106-126-treated cells or in the contribution to total current of L-type channels, but a small Cd(2+)-resistant current was found only in PrP106-126-treated cells. Thus PrP106-126 augments secretion by inducing a Cd(2+)-resistant Ca(2+) influx pathway and alters coupling of native Ca(2+) channels to exocytosis. These effects are likely contributory factors in the toxic cellular actions of PrP(sc).

Mechanisms of prion-induced modifications in membrane transport properties: implications for signal transduction and neurotoxicity

Prion-related encephalopathies are associated with the conversion of a normal cellular isoform of prion protein (PrP(c)) to an abnormal pathologic scrapie isoform (PrP(Sc)). The conversion of this single polypeptide chain involves a reduction in the alpha-helices and an increase in beta-sheet content. This change in the content ratio of alpha-helices to beta-sheets may explain the diversity in the proposed mechanisms of action. Many of the pathogenic properties of PrP(Sc), such as neurotoxicity, proteinase-resistant properties and induction of hypertrophy and proliferation of astrocytes, have been attributed to the peptide fragment corresponding to residues 106-126 of prion (PrP[106-126]). In particular, the amyloidogenic and hydrophobic core AGAAAAGA has been implicated in modulation of neurotoxicity and the secondary structure of PrP[106-126]. Because of some similarities between the properties of PrP[106-126] and PrP(Sc), the former is used as a useful tool to characterize the pharmacological and biophysical properties of PrP(Sc) in general and of that domain in particular, by various laboratories. However, it is important to note that by no means can PrP[106-126] be considered a complete equivalent to PrP(Sc) in function. Several hypotheses have been proposed to explain prion-induced neurodegenerative diseases. These non-exclusive hypotheses include: (i) changes in the membrane microviscosity; (ii) changes in the intracellular Ca(2+) homeostasis; (iii) superoxide dismutase and Cu(2+) homeostasis; and (iv) changes in the immune system. The prion-induced modification in Ca(2+) homeostasis is the result of: (1) prion interaction with intrinsic ion transport proteins, e.g. L-type Ca(2+) channels in the surface membrane, and IP(3)-modulated Ca(2+) channels in the internal membranes, and/or (2) formation of cation channels. These two mechanisms of action lead to changes in Ca(2+) homeostasis that further augment the abnormal electrical activity and the distortion of signal transduction causing cell death. It is concluded that the hypothesis of the interaction of PrP[106-126] with membranes and formation of redox-sensitive and pH-modulated heterogeneous ion channels is consistent with: (a) PrP-induced changes in membrane fluidity and viscosity; (b) PrP-induced changes in Ca(2+) homeostasis (and does not exclude changes in endogenous Ca(2+) transport pathways and Cu(2+) homeostasis); (c) PrP role as an antioxidant; and (d) the PrP structural properties, i.e. beta sheets, protein aggregation, hydrophobicity, functional significance of specific amino acids (e.g. methionine, histidine) and regulation with low pH.

Prion diseases: what is the neurotoxic molecule?

A great deal of effort has been devoted during the past 20 years to defining the chemical nature of prions, the infectious agents responsible for transmissible spongiform encephalopathies. In contrast, much less attention has been paid to elucidating how prions actually damage the central nervous system. Although it is commonly assumed that PrP(Sc), the protein constituent of infectious prions, is the primary culprit, increasing evidence indicates that this may not be the case. Several alternative molecular forms of PrP are reasonable candidates for the neurotoxic species in prion diseases, although it is still too early to tell whether these or other ones will turn out to be the true instigating factors. The cellular pathways activated by neurotoxic forms of PrP that ultimately result in neuronal death are also being investigated, and several possible mechanisms have been uncovered, including the operation of quality control processes in the endoplasmic reticulum. Elucidating the distinction between the infectious and neurotoxic forms of PrP has important implications for designing therapy of prion diseases, as well as for understanding pathogenic mechanisms operative in other neurodegenerative disorders and the role of prion-like states in biology.

Prion diseases of humans and animals: their causes and molecular basis

Prion diseases are transmissible neurodegenerative conditions that include Creutzfeldt-Jakob disease (CJD) in humans and bovine spongiform encephalopathy (BSE) and scrapie in animals. Prions appear to be composed principally or entirely of abnormal isoforms of a host-encoded glycoprotein, prion protein. Prion propagation involves recruitment of host cellular prion protein, composed primarily of alpha-helical structure, into a disease specific isoform rich in beta-sheet structure. The existence of multiple prion strains has been difficult to explain in terms of a protein-only infections agent, but recent studies suggest that strain specific phenotypes can be encoded by different prion protein conformations and glycosylation patterns. The ability of a protein to encode phenotypic information has important biological implications. The appearance of a novel human prion disease, variant CJD, and the clear experimental evidence that it is caused by exposure to BSE has highlighted the need to understand the molecular basis of prion propagation, pathogenesis, and the barriers limiting intermammalian transmission. It is unclear if a large epidemic of variant CJD will occur in the years ahead.

Function of PrP(C) as a copper-binding protein at the synapse

The prion protein (PrP(C)) shows cooperative copper binding of the N-terminal octarepeat (PHGGGWGO) x4. In brain homogenates, PrP(C) is found in highest concentration in synaptosomal fractions. Mice devoid of PrP(C) (Prnp0/0 mice) show synaptosomal copper concentrations diminished by 50% as compared to normal mice. PrP(C) in the synaptic cleft may serve as a copper buffer. Alternatively it may play a role in the re-uptake of copper into the presynapse or may be of structural importance for the N-terminus and thus may influence binding of PrP(C) to other proteins.

Prion protein affects Ca2+-activated K+ currents in cerebellar purkinje cells

The prion protein (PrPC) has a primary role in the pathogenesis of transmissible spongiform encephalopathies. Its physiological function is not known yet. Altered late afterhyperpolarization has been observed in hippocampal CA1 pyramidal cells of prion protein-deficient mice (Prnp(0/0) mice) presumably caused by a disruption of Ca2+-activated K+ currents. An alteration of these currents has been recently described in scrapie-infected animals, and loss of function of PrPC has been put forward as one possible pathophysiological mechanism in prion diseases. This work focuses on patch-clamp studies of Ca2+-activated K+ currents in cerebellar Purkinje cells in the slice preparation of Prnp(0/0) mice as well as of transgenic mice. A significant correlation between PrPC expression in Purkinje cells and the maximal amplitude of TEA-insensitive Ca2+-activated K+ currents was observed, with reduced current amplitudes in Prnp(0/0) mice and a rescue of the phenotype in transgenic mice where PrPC had been reintroduced. Further studies of the intracellular free calcium concentration revealed an alteration of the maximal increase of intracellular calcium concentration with depolarization in the Prnp(0/0) mouse Purkinje cells. These data provide strong evidence that Ca2+-activated K+ currents in Prnp(0/0) mice are reduced due to an alteration of intracellular calcium homeostasis.

Prion and prejudice: normal protein and the synapse

The word prion has become synonymous with unusual diseases, such as bovine spongiform encephalopathy and Creutzfeldt-Jakob disease. However, there is also a normal prion protein that does not cause disease. Until recently this highly conserved and widely expressed glycoprotein has been overshadowed by its rogue isoform. Now it is emerging that not only is this protein important for understanding prion disease but it is also important for a healthy brain. The normal cellular isoform of the prion protein is expressed at high levels at synapses suggesting an important role in neuronal function. There is increasing evidence that the normal prion protein binds copper and the resulting complex possesses anti-oxidant activity, and that this, in turn, might have vital implications for synaptic homeostasis.

Antioxidant activity related to copper binding of native prion protein

We have developed a method to affinity-purify mouse prion protein (PrP(c)) from mouse brain and cultured cells. PrP(c) from mouse brain bound three copper atoms; PrP(c) from cultured cells bound between one and four copper atoms depending on the availability of copper in the culture medium. Purified PrP(c) exhibited antioxidant activity, as determined by spectrophotometric assay. Incubation of PrP(c) with the neurotoxic peptide, PrP106-126, inactivated the superoxide dismutase-like activity. Culture experiments showed that PrP(c) protects cells against oxidative stress relative to the amount of copper it binds. These results suggest that PrP(c) is a copper-binding protein which can incorporate varying amounts of copper and exhibit protective antioxidant activity.

Altered intracellular calcium homeostasis in cerebellar granule cells of prion protein-deficient mice

Previous studies have indicated that recombinant cellular prion protein (PrP(C)), as well as a synthetic peptide of PrP(C), affects intracellular calcium homeostasis. To analyze whether calcium homeostasis in neurons is also affected by a loss of PrP(C), we performed microfluorometric calcium measurements on cultured cerebellar granule cells derived from prion protein-deficient (Prnp(0/0)) mice. The resting concentration of intracellular free calcium [Ca(2+)](i) was found to be slightly, but significantly, reduced in Prnp(0/0) mouse granule cell neurites. Moreover, we observed a highly significant reduction in the [Ca(2+)](i) increase after high potassium depolarization. Pharmacological studies further revealed that the L-type specific blocker nifedipine, which reduces the depolarization-induced [Ca(2+)](i) increase by 66% in wild-type granule cell somas, has no effect on [Ca(2+)](i) in Prnp(0/0) mouse granule cells. Patch-clamp measurements, however, did not reveal a reduced calcium influx through voltage-gated calcium channels in Prnp(0/0) mice. These data clearly indicate that loss of PrP(C) alters the intracellular calcium homeostasis of cultured cerebellar granule cells. There is no evidence, though, that this change is due to a direct alteration of voltage-gated calcium channels.

Synaptic prion protein immuno-reactivity in the rodent cerebellum

The cellular prion protein PrP(c) is a neurolemmal glycoprotein essential for the development of the transmissible spongiform encephalopathies. In these neurodegenerative diseases, host PrP(c) is converted to infectious protease-resistant isoforms PrP(res) or prions. Prions provoque predictable and distinctive patterns of PrP(res) accumulation and neurodegeneration depending on the prion strain and on regional cell-specific properties modulating PrP(c) affinity for infectious PrP(res) in the host brain. Synaptolysis and synaptic accumulation of PrP(res) during PrP-related diseases suggests that the synapses could be primary sites able to propagate PrP(res) and neurodegeneration in the central nervous system. In the rodent cerebellum, the present light and electron microscopic immuno-cytochemical analysis shows that distinct types of synapses display differential expression of PrP(c), suggesting that synapse-specific parameters could influence neuroinvasion and neurodegeneration following cerebral infection by prions. Although the physiological functions of PrP(c) remain unknown, the concentration of PrP(c) almost exclusively at the Purkinje cell synapses in the cerebellum suggests its critical involvement in the synaptic relationships between cerebellar neurons in agreement with their known vulnerability to PrP deficiencies.

Immunolocalization of the cellular prion protein in normal brain

We examined the localization of PrP(c) in normal brain using free-floating section immunohistochemistry and monclonal antibody 3F4. In the mature hamster and baboon brain, PrP(c) is localized to the neuropil with a synaptic distribution and the PrP(c) immunoreactivity is denser in regions known for ongoing plasticity. Cell bodies and major fiber tracts have little or no PrP(c) immunoreactivity. At the electron microscopic level, PrP(c) immunoreactivity decorates synaptic profiles, both pre- and postsynaptically. Results obtained with two additional antibodies, 3B5 and Pri-304, showed similar patterns of PrP(c) bands on Western blots, although Pri-304 was less sensitive. On sections through the adult hamster hippocampus, 3B5 and Pri-304 both stained the synaptic neuropil while cell bodies in the pyramidal and dentate granule cell layers were not immunoreactive. Pri-304 differentiated between synaptic layers in the hippocampus and closely resembled the pattern of staining obtained with 3F4. Preliminary results of developing brain showed that PrP(c) is initially localized along fiber tracts in the neonate brain. These results show that PrP(c) has a synaptic distribution in the adult brain and suggest that there are important changes in its distribution during brain development. These results also characterize two additional reagents for studies of PrP(c) localization.

Creutzfeldt-Jakob disease, new variant creutzfeldt-jakob disease, and bovine spongiform encephalopathy

Creutzfeldt-Jakob disease (CJD) is a subacute spongiform encephalopathy (SSE) that is manifested by a variety of neurologic signs that usually include dementia, myoclonus, and an abnormal electroencephalogram (EEG). In 1996, a new variant of CJD (nvCJD) with a somewhat distinctive clinical presentation and neuropathology was reported in adolescents and young adults, a cohort of patients not normally affected with CJD. The appearance of nvCJD coincided temporally and geographically with the emergence of an SSE in cattle known as bovine spongiform encephalopathy (BSE), or mad cow disease. This article discusses the clinical syndrome, pathology, and pathogenesis of classical CJD, nvCJD, and other human SSEs, as well as the link between BSE and nvCJD.

Intrinsic physiological and morphological properties of principal cells of the hippocampus and neocortex in hamsters infected with scrapie

Scrapie is a transmissible spongiform encephalopathy, or "prion disease." We investigated the effects of intracerebral Sc237 scrapie inoculation in hamsters on the physiology and morphology of principal cells from neocortical and hippocampal slices. Scrapie inoculation resulted in increased branching of basal dendrites of hippocampal CA1 pyramidal cells (Sholl analysis), reduced amplitudes of medium and late afterhyperpolarizations (AHPs) in CA1 pyramidal cells and layer V neocortical cells, loss of frequency potentiation of depolarizing afterpotentials (DAPs), and double action potentials in synaptically evoked CA1 pyramidal cell responses. Postsynaptic double action potentials could also be evoked in normal hamster CA1 pyramidal cells by acute pharmacological block of AHPs, suggesting that the depressed AHPs in scrapie-infected hamsters caused the action potential doublets. Both the AHP and the DAP potentiations depend on increased intracellular calcium, which suggests that the underlying deficit, in hamsters infected with Sc237 scrapie, may lie in calcium entry and/or homeostasis. Fast IPSPs, passive membrane properties, and density of dendritic spines remained unchanged. These last two results differ markedly from recent studies on mice infected with ME7 scrapie, indicating diversity of pathophysiology in this group of diseases, perhaps associated with the progressive and substantial neuronal loss found in the ME7, and not the Sc237, model.

Cellular biology of prion diseases

Prion diseases are fatal neurodegenerative disorders of humans and animals that are important because of their impact on public health and because they exemplify a novel mechanism of infectivity and biological information transfer. These diseases are caused by conformational conversion of a normal host glycoprotein (PrPC) into an infectious isoform (PrPSc) that is devoid of nucleic acid. This review focuses on the current understanding of prion diseases at the cell biological level. The characteristics of the diseases are introduced, and a brief history and description of the prion hypothesis are given. Information is then presented about the structure, expression, biosynthesis, and possible function of PrPC, as well as its posttranslational processing, cellular localization, and trafficking. The latest findings concerning PrPSc are then discussed, including cell culture systems used to generate this pathogenic isoform, the subcellular distribution of the protein, its membrane attachment, proteolytic processing, and its kinetics and sites of synthesis. Information is also provided on molecular models of the PrPC-->PrPSc conversion reaction and the possible role of cellular chaperones. The review concludes with suggestions of several important avenues for future investigation.

Prion protein: a role in sleep regulation?

The prion protein (PrP) is a glycoprotein anchored to cell membranes and expressed in most cell types. Its structural features indicate possible relations to signal peptidases (Glockshuber et al. 1998). Since mutations in this protein lead to severe neurodegeneration and death in humans and animals, it is possible that the loss of its normal function contributes to the development of the pathology. Little is known about its normal function, but there are indications that it may play a role in circadian rhythm and sleep regulation in mice. We explored further whether PrP plays a role in sleep regulation by comparing sleep and the effects of 6 h sleep deprivation in PrP knockout mice and isogenic wild-type mice of the 129/Ola strain. The mice did not differ in the amount and distribution of the vigilance states or in the power spectra. The most remarkable difference was the larger and long-lasting increase of slow-wave activity (mean EEG power density 0.75-4.0 Hz) in non-rapid-eye-movement (NREM) sleep during recovery from sleep deprivation in the null mice. The results confirm our previous findings in mice with a mixed background. This observation applies also to slow-wave activity in NREM sleep episodes following spontaneous waking bouts of different duration. Sleep fragmentation in both genotypes was larger than in mice with the mixed background. A new aspect was revealed by the spectral analysis of the EEG, where the null mice had a lower peak frequency within the theta band in REM sleep and waking, and not in NREM sleep. Behavioural observations concomitant with the EEG indicated that the EEG difference in waking may be attributed to the smaller amount of exploratory behaviour in the null mice. The difference between the genotypes in theta peak frequency was not an overall effect on the EEG, since it was absent in NREM sleep. PrP therefore may be affecting the theta-generating mechanisms in the hippocampus during waking and REM sleep. It remains unresolved whether PrP plays a role in sleep consolidation, nevertheless the data suggest that it is involved in sleep regulation. A passive avoidance test showed a difference between the genotypes. It is not probable that this was due to memory differences, since the genotypes reacted similarly in a delayed T-maze alternation procedure. The behavioural differences need to be pursued further.

Copper stimulates endocytosis of the prion protein

Prion diseases result from conformational alteration of PrPC, a cell surface glycoprotein expressed in brain, spinal cord, and several peripheral tissues, into PrPSc, a protease-resistant isoform that is the principal component of infectious prion particles. Although a great deal is known about the pathogenic role of PrPSc, the physiological function of PrPC has remained a mystery. Several lines of evidence have recently suggested the possibility that PrPC may play a role in the metabolism of copper. To further investigate the interaction of PrPC and copper, we have analyzed the effect of this metal ion on the endocytic trafficking of PrPC in cultured neuroblastoma cells. We report here that copper rapidly and reversibly stimulates endocytosis of PrPC from the cell surface. This effect may be physiologically relevant and suggests the hypothesis that PrPC could serve as a recycling receptor for uptake of copper ions from the extracellular milieu.

Human keratinocytes express cellular prion-related protein in vitro and during inflammatory skin diseases

Prion diseases are transmissible spongiform encephalopathies of humans and animals characterized by the accumulation of a proteinase-resistant isoform of the cellular prion-related protein (PrPc) within the central nervous system. In the present report we demonstrate for the first time the presence of PrPc on squamous epithelia of normal and diseased human skin and show that inflammatory cytokines regulate PrPc expression in cultured human keratinocytes (KCs). By immunohistochemistry, only little expression of PrPc, which was mainly confined to KCs, was detected in normal skin. In contrast, in inflammatory skin diseases including psoriasis and contact dermatitis, PrPc was strongly present on both KCs and infiltrating mononuclear cells. Strong PrPc expression was also observed in squamous cell carcinomas and viral warts whereas basal cell carcinomas were mostly negative. In mucous membranes of the upper digestive tract and the genital region, distinct PrPc expression by basal squamous epithelial cells was a constant feature. In tissue culture, primary KCs constitutively expressed PrPc mRNA and protein. Exposure of these cells to transforming growth factor (TGF)-alpha or interferon (IFN)-gamma led to an increase of PrPc protein expression. The presence of PrPc on epithelial cells of skin and mucous membranes suggests that these cells represent possible first targets for peripheral infection with prions.

Prion diseases

Although the nature of the infectious agent causing prion diseases is still debated, several of its molecular characteristics have been clarified in remarkable detail. The transmissibility of bovine spongiform encephalopathy to humans dramatically highlights the need for research focused at interference with prion replication and spread, and at prevention of brain damage. Precondition to achieving these goals is a thorough understanding of prion biology, and in particular of its protein chemistry.

Expression of amino-terminally truncated PrP in the mouse leading to ataxia and specific cerebellar lesions

The physiological role of prion protein (PrP) remains unknown. Mice devoid of PrP develop normally but are resistant to scrapie; introduction of a PrP transgene restores susceptibility to the disease. To identify the regions of PrP necessary for this activity, we prepared PrP knockout mice expressing PrPs with amino-proximal deletions. Surprisingly, PrP lacking residues 32-121 or 32-134, but not with shorter deletions, caused severe ataxia and neuronal death limited to the granular layer of the cerebellum as early as 1-3 months after birth. The defect was completely abolished by introducing one copy of a wild-type PrP gene. We speculate that these truncated PrPs may be nonfunctional and compete with some other molecule with a PrP-like function for a common ligand.

T-lymphocyte activation and the cellular form of the prion protein

The transmissible spongiform encephalopathies are neurodegenerative disorders which include Creutzfeldt-Jakob disease in humans, and scrapie and bovine spongiform encephalopathy in animals. A major component of the infectious agent responsible for these diseases is considered to be a post-translationally modified form of a host-encoded glycoprotein PrPc, termed PrPSc. While PrPc is abundantly expressed in tissues of the central nervous system (CNS), little is known about its normal function. The expression of PrPc is not restricted to the CNS, as this protein can also be detected in the lymphoid tissues of mice and sheep. In this report we demonstrate that resting murine splenic lymphocytes express PrPc protein on their cell membranes. Furthermore, expression of PrPc was significantly enhanced following in vitro stimulation with the non-specific T-cell mitogen concanavalin A (Con A). Genetically engineered mice with an inactive PrPc gene (PrP-/- mice), were utilized to investigate the involvement of PrPc in lymphocyte activation. Experiments revealed that the Con A-induced proliferation of lymphocytes from PrP-/- mice was significantly reduced to approximately 50-80% that of wild-type (PrP+/+) mice 48 hr post-stimulation. These findings demonstrate an important role for PrPc in extra-neuronal tissues and suggest that PrPc is a lymphocyte surface molecule that participates in T-cell activation.

Mossy fibre reorganization in the hippocampus of prion protein null mice

Mice lacking prion protein (PrP-null) are resistant to transmissible spongiform encephalopathies. However, the normal functions of this highly conserved protein remain controversial. This study examines whether PrP-null mice develop normal neuronal pathways, specifically the mossy fibre pathway, within the hippocampus. Timm stained hippocampal sections from the PrP-null group had more granules than the controls in: the granule cell layer, the inner molecular layer of the dentate gyrus, and the infrapyramidal region of CA3. This resembles the mossy fibre collateral and terminal sprouting seen in certain epilepsies. The abnormal connectivity might be predicted to promote epileptiform activity, but extracellular electrophysiological recordings from the granule cell layer revealed a reduced excitability in the PrP-null group, both with and without blockade of GABA(A) receptor-mediated inhibition. We propose that reorganization of neuronal circuity is a feature of PrP-null mice.