Re-evaluation of neuronal P2X7 expression using novel mouse models and a P2X7-specific nanobody.

The P2X7 channel is involved in the pathogenesis of various CNS diseases. An increasing number of studies suggest its presence in neurons where its putative functions remain controversial for more than a decade. To resolve this issue and to provide a model for analysis of P2X7 functions, we generated P2X7 BAC transgenic mice that allow visualization of functional EGFP-tagged P2X7 receptors in vivo. Extensive characterization of these mice revealed dominant P2X7-EGFP protein expression in microglia, Bergmann glia, and oligodendrocytes, but not in neurons. These findings were further validated by microglia- and oligodendrocyte-specific P2X7 deletion and a novel P2X7-specific nanobody. In addition to the first quantitative analysis of P2X7 protein expression in the CNS, we show potential consequences of its overexpression in ischemic retina and post-traumatic cerebral cortex grey matter. This novel mouse model overcomes previous limitations in P2X7 research and will help to determine its physiological roles and contribution to diseases.

Endogenous Apolipoprotein E (ApoE) Fragmentation Is Linked to Amyloid Pathology in Transgenic Mouse Models of Alzheimer's Disease.

The epsilon 4 allele of the apolipoprotein E (ApoE4) gene is the most important risk factor implicated in Alzheimer's disease (AD) etiology. ApoE4 is more susceptible to proteolysis, and ApoE fragments have been shown to promote tau hyperphosphorylation and exert neurotoxic properties. While a plethora of studies deals with the effect of ApoE and its fragments on amyloid-ß peptide (Aß) deposition and clearance, it is largely unknown whether Aß in turn influences human or murine ApoE expression and its proteolysis. The present study is the first to show that endogenous murine ApoE becomes proteolytically processed in a way reminiscent of human ApoE fragmentation in different AD mouse models, including APP/PS1KI or 5XFAD. Murine ApoE fragments were demonstrated to accumulate mainly in synaptic fractions in AD mouse models. In vitro experiments, as well as analysis of mouse models at different time points, suggest that the amount of total ApoE is associated with extracellular Aß while the amount of its fragments is linked to intracellular Aß levels. Murine ApoE fragmentation is a common feature in different AD transgenic mouse models and could be directly associated with intraneuronal Aß accumulation. Extracellular amyloid induces an elevation in full-length ApoE expression, which might present a protective mechanism toward Aß clearance. The demonstrated fragments of murine ApoE in vitro and in vivo might therefore play a crucial role in the progression of AD pathology in murine AD models.

Accelerated tau pathology with synaptic and neuronal loss in a novel triple transgenic mouse model of Alzheimer's disease.

There is pivotal evidence that tau pathology can be triggered by amyloid-ß (Aß) pathology in experimental systems. On the other side, studies on human brain specimen have elucidated that tau pathology may occur before amyloid pathology is present indicating that in principle tau pathology could also trigger Aß aggregation. To address this question, we have crossed 5XFAD mice coexpressing human mutant APP695 with the Swedish, Florida, and London mutations and human mutant presenilin-1 (PS1) with the M146L and L286V mutations with the PS19 model overexpressing human mutant tau with the P301S mutation. The resulting triple transgenic model 5XFAD/PS19 has been characterized at 3 and 9 months of age. A dramatic aggravation of hyperphosphorylated tau pathology together with a dramatically increased inflammatory response and a loss of synapses and hippocampal CA1 neurons in aged 5XFAD/PS19 mice were observed. Extracellular amyloid deposits were unaltered. These data support the assumption of tau pathology being downstream of amyloid pathology, suggesting that both pathologies together trigger the severe neuron loss in the hippocampus in the 5XFAD/PS19 mouse model.

Abundant pyroglutamate-modified ABri and ADan peptides in extracellular and vascular amyloid deposits in familial British and Danish dementias.

Familial British and familial Danish dementia (FDD) are progressive neurodegenerative disorders characterized by cerebral deposition of the amyloidogenic peptides ABri and ADan, respectively. These amyloid peptides start with an N-terminal glutamate residue, which can be posttranslationally converted into a pyroglutamate (pGlu) modified form, a mechanism which has been extensively described to be relevant for amyloid-beta (Aß) peptides in Alzheimer's disease. Like pGlu-Aß peptides, pGlu-ABri peptides have an increased aggregation propensity and show higher toxicity on human neuroblastoma cells as their nonmodified counterparts. We have generated novel N-terminal specific antibodies detecting the pGlu-modified forms of ABri and ADan peptides. With these antibodies we were able to identify abundant extracellular amyloid plaques, vascular, and parenchymal deposits in human familial British dementia and FDD brain tissue, and in a mouse model for FDD. Double-stainings using C-terminal specific antibodies in human samples revealed that highly aggregated pGlu-ABri and pGlu-ADan peptides are mainly present in plaque cores and central vascular deposits, leading to the assumption that these peptides have seeding properties. Furthermore, in an FDD-mouse model ADan peptides were detected in presynaptic terminals of the hippocampus where they might contribute to impaired synaptic transmission. These similarities of ABri and ADan to Aß in Alzheimer's disease suggest that the posttranslational pGlu-modification of amyloid peptides might represent a general pathological mechanism leading to increased aggregation and toxicity in these forms of degenerative dementias.

Heteromeric assembly of P2X subunits.

Transcripts and/or proteins of P2X receptor (P2XR) subunits have been found in virtually all mammalian tissues. Generally more than one of the seven known P2X subunits have been identified in a given cell type. Six of the seven cloned P2X subunits can efficiently form functional homotrimeric ion channels in recombinant expression systems. This is in contrast to other ligand-gated ion channel families, such as the Cys-loop or glutamate receptors, where homomeric assemblies seem to represent the exception rather than the rule. P2XR mediated responses recorded from native tissues rarely match exactly the biophysical and pharmacological properties of heterologously expressed homomeric P2XRs. Heterotrimerization of P2X subunits is likely to account for this observed diversity. While the existence of heterotrimeric P2X2/3Rs and their role in physiological processes is well established, the composition of most other P2XR heteromers and/or the interplay between distinct trimeric receptor complexes in native tissues is not clear. After a description of P2XR assembly and the structure of the intersubunit ATP-binding site, this review summarizes the distribution of P2XR subunits in selected mammalian cell types and the biochemically and/or functionally characterized heteromeric P2XRs that have been observed upon heterologous co-expression of P2XR subunits. We further provide examples where the postulated heteromeric P2XRs have been suggested to occur in native tissues and an overview of the currently available pharmacological tools that have been used to discriminate between homo- and heteromeric P2XRs.