Rico Frigg

A crucial role for B cells in neuroinvasive scrapie

Although prion proteins are most efficiently propagated through intracerebral inoculation, peripheral administration has caused the diseases kuru, iatrogenic Creutzfeldt–Jakob disease (CJD), bovine spongiform encephalopathy (BSE) and new-variant CJD,. The development of neurological disease after peripheral inoculation depends on prion expansion within cells of the lymphoreticular system,. Here we investigate the identity of these cells by using a panel of immune-deficient mice inoculated with prions intraperitoneally: we found that defects affecting only T lymphocytes had no apparent effect, but that all mutations that disrupted the differentiation and response of B lymphocytes prevented the development of clinical scrapie. As an absence of B cells and of antibodies correlates with severe defects in follicular dendritic cells, a lack of any of these three components may prevent the development of clinical scrapie. However, we found that scrapie developed after peripheral inoculation in mice expressing immunoglobulins that were exclusively of the M subclass and without detectable specificity for the normal form of the prion PrPc, and in mice which had differentiated B cells but no functional follicular dendritic cells. We conclude that differentiated B cells are crucial for neuroinvasion by scrapie, regardless of the specificity of their receptors.

PrP expression in B lymphocytes is not required for prion neuroinvasion

Prion diseases are typically initiated by infection of peripheral sites, as in the case of bovine spongiform encephalopathy, new variant Creutzfeldt-Jakob disease, kuru and most cases of iatrogenic Creutzfeldt-Jakob disease. In mouse scrapie, prion infectivity accumulates in lymphoid organs, and the absence of mature B lymphocytes prevents peripherally administered prions from inducing central nervous system disease. We have now assessed whether expression of the cellular prion protein, PrPC, is required for B lymphocytes to mediate neuroinvasion. We found that repopulation of SCID and Rag-1-/- mice with fetal liver cells from either PrP-expressing or PrP-deficient mice and from T-cell deficient mice, but not from B-cell deficient mice, is equally efficient in restoring neuroinvasion after intraperitoneal inoculation of scrapie prions. These results indicate that cells whose maturation depends on B cells or their products, such as follicular dendritic cells, may enhance neuroinvasion. Alternatively, B cells may transport prions to the nervous system by a PrP-independent mechanism.

Aggravation of ischemic brain injury by prion protein deficiency : Role of ERK-1/-2 and STAT-1

The cellular isoform of prion protein, PrPc, may confer neuroprotection in the brain, according to recent studies. To elucidate the role of PrPc in stroke pathology, we subjected PrPc-knockout (Prnp(0/0)), wild-type and PrPc-transgenic (tga20) mice to 30 min of intraluminal middle cerebral artery occlusion, followed by 3, 24 or 72 h reperfusion, and examined how PrPc levels influence brain injury and cell signaling. In immunohistochemical experiments and Western blots, we show that PrPc expression is absent in the brains of Prnp(0/0) mice, detectable in wild-type controls and approximately 4.0-fold elevated in tga20 mice. We provide evidence that PrPc deficiency increases infarct size by approximately 200%, while transgenic PrPc restores tissue viability, albeit not above levels in wild-type animals. To elucidate the mechanisms underlying Prnp(0/0)-induced injury, we performed Western blots, which revealed increased activities of ERK-1/-2, STAT-1 and caspase-3 in ischemic brains of Prnp(0/0)mice. Our data suggest a role of cytosolic signaling pathways in Prnp(0/0)-induced cell death.

PrP-dependent association of prions with splenic but not circulating lymphocytes of scrapie-infected mice.

An intact immune system, and particularly the presence of mature B lymphocytes, is crucial for mouse scrapie pathogenesis in the brain after peripheral exposure. Prions are accumulated in the lymphoreticular system (LRS), but the identity of the cells containing infectivity and their role in neuroinvasion have not been determined. We show here that although prion infectivity in the spleen is associated with B and T lymphocytes and to a lesser degree with the stroma, no infectivity could be detected in lymphocytes from blood. In wild‐type mice, which had been irradiated and reconstituted with PrP‐deficient lymphohaematopoietic stem cells and inoculated with scrapie prions, infectivity in the spleen was present in the stroma but not in lymphocytes. Therefore, splenic B and T lymphocytes can either synthesize prions or acquire them from another source, but only when they express PrP.

Analysis of the retinal gene expression profile after hypoxic preconditioning identifies candidate genes for neuroprotection

BackgroundRetinal degeneration is a main cause of blindness in humans. Neuroprotective therapies may be used to rescue retinal cells and preserve vision. Hypoxic preconditioning stabilizes the transcription factor HIF-1α in the retina and strongly protects photoreceptors in an animal model of light-induced retinal degeneration. To address the molecular mechanisms of the protection, we analyzed the transcriptome of the hypoxic retina using microarrays and real-time PCR.ResultsHypoxic exposure induced a marked alteration in the retinal transcriptome with significantly different expression levels of 431 genes immediately after hypoxic exposure. The normal expression profile was restored within 16 hours of reoxygenation. Among the differentially regulated genes, several candidates for neuroprotection were identified like metallothionein-1 and -2, the HIF-1 target gene adrenomedullin and the gene encoding the antioxidative and cytoprotective enzyme paraoxonase 1 which was previously not known to be a hypoxia responsive gene in the retina. The strongly upregulated cyclin dependent kinase inhibitor p21 was excluded from being essential for neuroprotection.ConclusionOur data suggest that neuroprotection after hypoxic preconditioning is the result of the differential expression of a multitude of genes which may act in concert to protect visual cells against a toxic insult.

Transgenic and Knockout Mice in Research on Prion Diseases

Since the discovery of the prion protein (PrP) gene more than a decade ago, transgenetic investigations on the PrP gene have shaped the field of prion biology in an unprecedented way. Many questions regarding the role of PrP in susceptibility of an organism exposed to prions have been elucidated. For example mice with a targeted disruption of the PrP gene have allowed the demonstration that an organism that lacks PrPc is resistant to infection by prions. Reconstitution of these mice with mutant PrP genes allowed investigations on the structure‐activity relationship of the PrP gene with regard to scrapie susceptibility. Unexpectedly, transgenic mice expressing PrP with specific amino‐proximal truncations spontaneously develop a neurologic syndrome presenting with ataxia and cerebellar lesions. A distinct spontaneous neurologic phenotype was observed in mice with internal deletions in PrP. Using ectopic expression of PrP in PrP knockout mice has turned out to be a valuable approach towards the identification of host cells that are capable of replicating prions. Transgenic mice have also contributed to our understanding of the molecular basis of the species barrier for prions. Finally, the availability of PrP knockout mice and transgenic mice overexpressing PrP allows selective reconstitution experiments aimed at expressing PrP in neurografts or in specific populations of hemato‐ and lymphopoietic cells. Such studies have shed new light onto the mechanisms of prion spread and disease pathogenesis.

Neuroinvasion of Prions: Insights from Mouse Models

The prion was defined by Stanley B. Prusiner as the infectious agent that causes transmissible spongiform encephalopathies. A pathological protein accumulating in the brain of scrapie‐infected hamsters was isolated in 1982 and termed prion protein (PrPSc). Its cognate gene Prnp was identified more than a decade ago by Charles Weissmann, and shown to encode the host protein PrPC. Since the latter discovery, transgenic mice have contributed many important insights into the field of prion biology, including the understanding of the molecular basis of the species barrier for prions. By disrupting the Prnp gene, it was shown that an organism that lacks PrPC is resistant to infection by prions. Introduction of mutant PrP genes into PrP‐deficient mice was used to investigate the structure‐activity relationship of the PrP gene with regard to scrapie susceptibility. Ectopic expression of PrP in PrP knockout mice proved a useful tool for the identification of host cells competent for prion replication. Finally, the availability of PrP knockout mice and transgenic mice overexpressing PrP allows selective reconstitution experiments aimed at expressing PrP in neurografts or in specific populations of haemato‐ and lymphopoietic cells. The latter studies have allowed us to clarify some of the mechanisms of prion spread and disease pathogenesis.

Studies on Prion Replication in Spleen

Some of the early events following scrapie infection take place in the lymphoreticular system (LRS) and result in significant replication of prions in lymphoid organs. The identity of the cells in the LRS that produce prions and their role in neuroinvasion are still unknown. We find that in the spleen of scrapie-infected mice, prions are associated with T and B cells and to a somewhat lesser degree with the stroma, which contains the follicular dendritic cells (FDCs); curiously, no infectivity was found in lymphocytes from blood of the same mice. Thus, splenic lymphocytes either replicate prions or acquire them from another source. Studies on PrP knockout mice with ectopic expression of PrP restricted to only B or T lymphocytes suggest that neither of these by themselves are competent for prion replication. To determine whether B and T cells are able to pick up prions from other sources, irradiated wild-type mice were reconstituted with PrP-deficient lymphohaematopoietic stem cells. Following intraperitoneal inoculation of these mice, no infectivity was found on splenic lymphocytes whereas the stroma (comprising the radiation-resistant, PrP-expressing FDCs) contained prions. These results imply that splenic lymphocytes can acquire prions, possibly from FDCs, but only if they express PrP.

Transgene und Knockout-Mäuse für das Studium von neurodegenerativen Erkrankungen

Um detaillierte Analysen der Mechanismen, die den menschlichen, neurodegenerativen Erkrankungen zugrundeliegen, durchfuhren zu konnen, sind geeignete Tiermodelle unabdingbar. Zusatzlich stellen sie Paradigmen fur die Entwicklung und Evaluation neuer therapeutischer Strategien dar. Wir fassen die gebrauchlichsten Techniken zur Modifikation des Saugetiergenoms zusammen und bieten eine kritische Evaluation der erhaltlichen transgenen Mausmodelle fur verschiedene neurologische Krankheitsbilder wie Prionerkrankungen, menschliche Retroviruserkrankungen, die Alzheimer-Erkrankung und Motoneuronerkrankungen.