Co-expression of truncated and full-length tau induces severe neurotoxicity.

Abundant tau inclusions are a defining hallmark of several human neurodegenerative diseases, including Alzheimer's disease. Protein fragmentation is a widely observed event in neurodegenerative proteinopathies. The relevance of tau fragmentation for the neurodegenerative process in tauopathies has yet remained unclear. Here we found that co-expression of truncated and full-length human tau in mice provoked the formation of soluble high-molecular-weight tau, the failure of axonal transport, clumping of mitochondria, disruption of the Golgi apparatus and missorting of synaptic proteins. This was associated with extensive nerve cell dysfunction and severe paralysis by the age of 3 weeks. When the expression of truncated tau was halted, most mice recovered behaviorally and functionally. In contrast, co-expression of full-length tau isoforms did not result in paralysis. Truncated tau thus induces extensive but reversible neurotoxicity in the presence of full-length tau through the formation of nonfilamentous high-molecular-weight tau aggregates, in the absence of tau filaments. Targeting tau fragmentation may provide a novel approach for the treatment of human tauopathies.

[Mechanisms of Alzheimer's disease : Neuronal hyperactivity and hypoactivity as new therapeutic targets]. / Mechanismen der Alzheimer-Krankheit : Neuronale Hyper- und Hypoaktivität als neue Therapieziele.

Alzheimer's disease (AD) is characterized by the pathological accumulation of amyloid-beta (Abeta) and tau peptides in the brain. Recent evidence suggests that the soluble peptide amyloid-eta (Aeta) may have an additional role in the pathogenesis of AD. The detailed investigation of the cellular and neurophysiological mechanisms underlying AD has revealed surprising results that may become highly relevant for the early diagnosis and treatment of the disease. By analyzing the function of single neurons and large-scale networks in intact brains in vivo it has been shown that A-beta, tau and A-eta abnormally modulate brain activity and obviously unfold contrasting effects: while A-beta promotes neuronal hyperactivity as well as epileptiform activity, tau and A-eta reduce the activity of neurons. Promising new evidence from animal studies and humans with AD indicates that the treatment of hyperactivity may improve cognitive dysfunctions and even slow the underlying disease process.

Assembly of protein 4.1 during chicken erythroid differentiation.

Protein 4.1 is a peripheral membrane protein that strengthens the actin-spectrin based membrane skeleton of the red blood cell and also serves to attach this structure to the plasma membrane. In avian erythrocytes it exists as a family of closely related polypeptides that are differentially expressed during erythropoiesis. We have analyzed the synthesis and assembly onto the membrane skeleton of protein 4.1 and in this paper we show that its assembly is extremely rapid and highly efficient since greater than 95% of the molecules synthesized are assembled in less than 1 min. The remaining minor fraction of unassembled protein 4.1 differs kinetically and is either degraded or assembled with slower kinetics. All protein 4.1 variants exhibit a similar kinetic behavior irrespective of the stage of erythroid differentiation. Thus, the amount and the variants ratio of protein 4.1 assembled are determined largely at the transcriptional or at the translational level and not posttranslationally. During erythroid terminal differentiation the molar amounts of protein 4.1 and spectrin assembled change. In postmitotic cells, as compared with proliferative cells, far more protein 4.1 than spectrin is assembled onto the membrane-skeleton. This modulation may permit the assembly of an initially flexible membrane skeleton in mitotic erythroid cells. As cells become postmitotic and undergo the final steps of maturation the membrane skeleton may be gradually stabilized by the assembly of protein 4.1.

Preparation of nuclear matrices from cultured cells: subfractionation of nuclei in situ.

Analyses of the different structural systems of the nucleus and the proteins associated with them pose many problems. Because these systems are largely overlapping, in situ localization studies that preserve the in vivo location of proteins and cellular structures often are not satisfactory. In contrast, biochemical cell fractionation may provide artifactual results due to cross-contamination of extracts and structures. To overcome these problems, we have developed a method that combines biochemical cell fractionation and in situ localization and leads to the preparation of a residual cellular skeleton (nuclear matrix and cytoskeletal elements) from cultured cells. This method's main feature is that cell fractionation is performed in situ. Therefore, structures not solubilized in a particular extraction step remain attached to the substrate and retain their morphology. Before and after each extraction step they can be analyzed for the presence and location of the protein under study by using immunological or cytochemical techniques. Thereby the in vivo origin of a protein solubilized in a particular extraction step is determined. The solubilized protein then may be further characterized biochemically. In addition, to allow analyses of proteins associated with the residual cellular skeleton, we have developed conditions for its solubilization that do not interfere with enzymatic and immunological studies.

Age-dependent time course of cerebral brain-derived neurotrophic factor, nerve growth factor, and neurotrophin-3 in APP23 transgenic mice.

Neurotrophins, including brain-derived neurotrophic factor (BDNF), nerve growth factor (NGF), and neurotrophin-3 (NT-3), have repeatedly been shown to be involved in the pathophysiology of Alzheimer's disease (AD). Recent studies have claimed that these neurotrophic factors are important tools for therapeutic intervention in neurodegenerative diseases. So far, little is known about the age- and disease-modulated time course of cerebral neurotrophins. Therefore, we have studied protein concentrations of BDNF, NGF, and NT-3 in different brain areas and sciatic nerve, a neurotrophin-transporting peripheral nerve, in a well-characterized AD model of amyloid precursor protein-overexpressing rodents (APP23 mice) at the ages of 5.0, 10.5, and 20.0 months. In APP23 mice, there was a significant increase of BDNF and NGF in the frontal and occipital cortices (for BDNF also in the striatum) of old 20.0-month-old mice (with respect to median values up to 8.2-fold), which was highly correlated with amyloid concentrations of these brain areas. Median values of NGF and NT-3 showed up to a 6.0-fold age-dependent increase in the septum that was not detectable in APP23 mice. Hippocampus, olfactory bulb, and cerebellum (except NT-3) did not show substantial age- or genotype-related regulation of neurotrophins. In the sciatic nerve, BDNF and NGF levels are increased in5-month-old APP23 mice and decrease with age to control levels. In conclusion, APP23 mice show a genotype-dependent increase of cortical BDNF and NGF that is highly correlated with amyloid concentrations and may reflect an amyloid-related glia-derived neurotrophin secretion or an altered axonal transport of these neurotrophic factors.

Amyloid beta interacts with the amyloid precursor protein: a potential toxic mechanism in Alzheimer's disease.

Amyloid beta protein (Abeta) deposition in the brain is a hallmark of Alzheimer's disease (AD). The fibrillar form of Abeta is neurotoxic, although the mechanism of its toxicity is unknown. We showed that conversion of Abeta to the fibrillar form markedly increased binding to specific neuronal membrane proteins, including amyloid precursor protein (APP). Nanomolar concentrations of fibrillar Abeta bound cell-surface holo-APP in cortical neurons. Reduced vulnerability of cultured APP-null neurons to Abeta neurotoxicity suggested that Abeta neurotoxicity involves APP. Thus Abeta toxicity may be mediated by the interaction of fibrillar Abeta with neuronal membrane proteins, notably APP. An Abeta-APP interaction reminiscent of the pathogenic mechanism of prions may thus contribute to neuronal degeneration in AD.

Aged APP23 mice show a delay in switching to the use of a strategy in the Barnes maze.

Spatial learning and memory deficits in the APP23 transgenic mice have mainly been studied using the Morris water maze (MWM). However learning in the MWM relies on swimming abilities and may be confounded by the stressful nature of this test. We have therefore assessed spatial learning and memory in 12-month-old APP23 using a dry-land maze test developed by Barnes. Mice were given daily learning trials for a total of 41 successive days. After a 12-day interval the mice were re-tested for 4 additional days in order to examine the spatial memory retention. Immediately following this phase, reversal learning was examined for 13 additional days by moving the escape tunnel to the opposite position. During the initial learning phase, APP23 mice showed a significantly longer latency to find the escape tunnel as well as an increased number of errors compared to non-transgenic littermates. These deficits appeared to be due to a delay in switching from a "no strategy" to a spatial strategy. Indeed, this same delay in the use of spatial strategy was observed in the reversal phase of the study. Our results suggest that impairments in APP23 mice in learning and memory maze tests may be due to a specific deficit in the use of spatial strategy.

Ankyrin-bound fatty acid turns over rapidly at the erythrocyte plasma membrane.

The membrane skeletal protein ankyrin was shown to be continuously acylated and deacylated with long-chain fatty acids in mature erythrocytes. At least a fraction of the lipid bound to ankyrin turned over rapidly (half-life, approximately 50 min) compared with the polypeptide backbone, which was stable throughout the erythrocyte life. This indicates a regulatory significance of the fatty acid modification for the function of ankyrin.

Membrane interactions of simian virus 40 large T-antigen: influence of protein sequences and fatty acid acylation.

To sort out possible influences of protein sequences and fatty acid acylation on the plasma membrane association of simian virus 40 large T-antigen, we have analyzed the membrane interactions of carboxy-terminal fragments of large T-antigen, encoded by the adenovirus type 2 (Ad2+)-simian virus 40 hybrid viruses Ad2+ND1 and Ad2+ND2. The 28,000 (28K)-molecular-weight protein of Ad2+ND1 as well as the 42K and 56K proteins of Ad2+ND2 associate preferentially with membranous structures and were found in association with the membrane system of the endoplasmic reticulum and with plasma membranes. Neither the endoplasmic reticulum membrane- nor the plasma membrane-associated 28K protein of Ad2+ND1 is fatty acid acylated. We, therefore, conclude that fatty acid acylation is not necessary for membrane association of this protein and suggest that an amino acid sequence in this protein is responsible for its membrane interaction. In contrast, the 42K and 56K proteins of Ad2+ND2 in plasma membrane fractions contain fatty acid. However, the interaction of these proteins with the plasma membrane differs from that of the 28K protein of Ad2+ND1: whereas the 28K protein of Ad2+ND1 interacts stably with Nonidet P-40-soluble constituents of the plasma membrane, the 42K and 56K proteins of Ad2+ND2 are tightly bound to the Nonidet P-40-insoluble plasma membrane lamina. Thus, an amino acid sequence in the amino-terminal region of the 28K protein confers membrane affinity to these proteins, whereas a region between the amino-terminal end of the 42K protein of Ad2+ND2 and the amino-terminal end of the 28K protein of Ad2+ND1 contains a reactive site for fatty acid acylation. This posttranslational modification correlates with the stable association of the 42K and 56K proteins with the plasma membrane lamina. We suggest that the same sequences also mediate the proper plasma membrane association of large T-antigen in simian virus 40-transformed cells.

Cerebral amyloid induces aberrant axonal sprouting and ectopic terminal formation in amyloid precursor protein transgenic mice.

A characteristic feature of Alzheimer's disease (AD) is the formation of amyloid plaques in the brain. Although this hallmark pathology has been well described, the biological effects of plaques are poorly understood. To study the effect of amyloid plaques on axons and neuronal connectivity, we have examined the axonal projections from the entorhinal cortex in aged amyloid precursor protein (APP) transgenic mice that exhibit cerebral amyloid deposition in plaques and vessels (APP23 mice). Here we report that entorhinal axons form dystrophic boutons around amyloid plaques in the entorhinal termination zone of the hippocampus. More importantly, entorhinal boutons were found associated with amyloid in ectopic locations within the hippocampus, the thalamus, white matter tracts, as well as surrounding vascular amyloid. Many of these ectopic entorhinal boutons were immunopositive for the growth-associated protein GAP-43 and showed light and electron microscopic characteristics of axonal terminals. Our findings suggest that (1) cerebral amyloid deposition has neurotropic effects and is the main cause of aberrant sprouting in AD brain; (2) the magnitude and significance of sprouting in AD have been underestimated; and (3) cerebral amyloid leads to the disruption of neuronal connectivity which, in turn, may significantly contribute to AD dementia.

Spontaneous hemorrhagic stroke in a mouse model of cerebral amyloid angiopathy.

A high risk factor for spontaneous and often fatal lobar hemorrhage is cerebral amyloid angiopathy (CAA). We now report that CAA in an amyloid precursor protein transgenic mouse model (APP23 mice) leads to a loss of vascular smooth muscle cells, aneurysmal vasodilatation, and in rare cases, vessel obliteration and severe vasculitis. This weakening of the vessel wall is followed by rupture and bleedings that range from multiple, recurrent microhemorrhages to large hematomas. Our results demonstrate that, in APP transgenic mice, the extracellular deposition of neuron-derived beta-amyloid in the vessel wall is the cause of vessel wall disruption, which eventually leads to parenchymal hemorrhage. This first mouse model of CAA-associated hemorrhagic stroke will now allow development of diagnostic and therapeutic strategies.

Conformations of synthetic beta peptides in solid state and in aqueous solution: relation to toxicity in PC12 cells.

The secondary structures of peptides beta 25-35 (the active toxic fragment) and beta 35-25 (reverse sequence and non-toxic fragment), as well as of the amidated beta (25-35)-NH2 peptide were investigated in aqueous solution and in the solid state by means of Fourier-transformed infrared spectroscopy and circular dichroism spectroscopy. The conformations of the beta 25-35 and beta 35-25 in solid state were identical and contained mostly beta-sheet structures. In solid state the amidated beta (25-35)-NH2 peptide also contained mostly beta-sheet structures. Freshly prepared aqueous solutions of the beta 25-32 (0.5 - 3.8 mM) contained a mixture of beta-sheet and random coil structures. Within 30-60 min incubation at 37 degrees C in water or in phosphate-buffered saline solution (PBS), beta 25-35 was almost fully converted to a beta-sheet structure. Decreasing the temperature from 37 degrees C to 20 degrees C decreased the rate of conversion from random coil to beta-sheet structures, 1-2 h being required for complete conversion. In contrast beta 35-25 in water or in PBS buffer had mostly a random coil structure and remained so for 6 days. The amidated beta(25-35)-NH2 peptide in water (2.7 mM) was also mostly random coil. However, when this peptide (2-2.7 mM) was dissolved in PBS (pH 7.4) or in 140 mM NaCl, a gel was formed and its conformation was mostly beta-sheet. Decreasing the concentration of beta (25-35)-NH2 peptide in 140 mM NaCl aqueous solution from 2 mM to 1 mM or below favored the conversion from beta-sheet structures to random coil structures. The beta 25-35 was toxic to PC12 cells while beta 35-25 was not. The amidated peptide beta (25-35)-NH2 was at least 500-fold less toxic than beta 25-35. Structural differences between these beta peptides in aqueous solutions may explain the difference in their respective toxicities.

The LPS receptor (CD14) links innate immunity with Alzheimer's disease.

To rapidly respond to invading microorganisms, humans call on their innate immune system. This occurs by microbe-detecting receptors, such as CD14, that activate immune cells to eliminate the pathogens. Here, we link the lipopolysaccharide receptor CD14 with Alzheimer's disease, a severe neurodegenerative disease resulting in dementia. We demonstrate that this key innate immunity receptor interacts with fibrils of Alzheimer amyloid peptide. Neutralization with antibodies against CD14 and genetic deficiency for this receptor significantly reduced amyloid peptide induced microglial activation and microglial toxicity. The observation of strongly enhanced microglial expression of the LPS receptor in brains of animal models of Alzheimer's disease indicates a clinical relevance of these findings. These data suggest that CD14 may significantly contribute to the overall neuroinflammatory response to amyloid peptide, highlighting the possibility that the enormous progress currently being made in the field of innate immunity could be extended to research on Alzheimer's disease.

Neurobehavioral characterization of APP23 transgenic mice with the SHIRPA primary screen.

The SHIRPA primary screen comprises 40 measures covering various reflexes and basic sensorimotor functions. This multi-test battery was used to compare non-transgenic controls with APP23 transgenic mice, expressing the 751 isoform of human beta-amyloid precursor protein and characterized by amyloid deposits in parenchyma and vessel walls. The APP23 mice were distinguishable from controls by pathological limb reflexes, myoclonic jumping, seizure activity, and tail malformation. In addition, this mouse model of Alzheimer's disease was also marked by a crooked swimming trajectory. APP23 mice were also of lighter weight and were less inclined to stay immobile during a transfer arousal test. Despite the neurologic signs, APP23 transgenic mice were not deficient in stationary beam, coat-hanger, and rotorod tests, indicating intact motor coordination abilities.

Nuclear matrix preparations from liver tissue and from cultured vertebrate cells: differences in major polypeptides.

The major polypeptides of nuclear matrix preparations from vertebrate tissues are rather similar. However, nuclear matrix fractions isolated from cultured vertebrate cells of different origin show variations in their major polypeptides. We demonstrate that cytoplasmic intermediate filaments copurify with nuclear matrices from these cells. Because of their abundance, their subunit proteins form major bands on SDS-polyacrylamide gels. The tissue specificity of the intermediate filament proteins then gives rise to the variations observed. To explain the differences in major proteins of nuclear matrices isolated from vertebrate cells grown in tissue and in culture we have analyzed the distribution of intermediate filaments during isolation of nuclei from liver tissue. We show that during homogenization of liver intermediate filaments are torn off and can be separated from the nuclei. Nuclear matrix preparations from these nuclei, therefore, do not contain intermediate filaments and true nuclear matrix proteins (e.g. lamins) are the major protein species. Our results suggest that the major nuclear matrix polypeptides (lamins) are similar in all vertebrate cells, since lamin like proteins were identified in cultured cells, too. Using antisera we demonstrate an immunological difference between lamins A/C and lamin B.

3D-Reconstruction of microglia and amyloid in APP23 transgenic mice: no evidence of intracellular amyloid.

Microglia cells are closely associated with compact amyloid plaques in Alzheimer's disease (AD) brains. Although activated microglia seem to play a central role in the pathogenesis of AD, mechanisms of microglial activation by beta-amyloid as well as the nature of interaction between amyloid and microglia remain poorly understood. We previously reported a close morphological association between activated microglia and congophilic amyloid plaques in the brains of APP23 transgenic mice at both the light and electron microscopic levels [25]. In the present study, we have further examined the structural relationship between microglia and amyloid deposits by using postembedding immunogold labeling, serial ultrathin sectioning, and 3-dimensional reconstruction. Although bundles of immunogold-labeled amyloid fibrils were completely engulfed by microglial cytoplasm on single sections, serial ultrathin sectioning and three-dimensional reconstruction revealed that these amyloid fibrils are connected to extracellular amyloid deposits. These data demonstrate that extracellular amyloid fibrils form a myriad of finger-like channels with the widely branched microglial cytoplasm. We conclude that in APP23 mice a role of microglia in amyloid phagocytosis and intracellular production of amyloid is unlikely.

Distinct processing of endogenous and overexpressed recombinant presenilin 1.

The presenilin 1 (PS1) gene has been identified by positional cloning. More than 30 mutations were detected in this gene which cosegregate with Alzheimer's disease (AD). Understanding their role in disease pathogenesis requires a characterization of the PS1 protein. We have generated a set of antibodies against the three major hydrophilic domains of the deduced amino acid sequence. Analyzing cultured cells and brain samples, we identified the endogenous PS1 polypeptide as well as amino- and carboxy-terminal fragments. These metabolites were much more abundant than the full-length molecule, indicating substantial processing. Overexpression of human PS1 markedly increased the full-length polypeptide but hardly altered the amount of the metabolites. Instead, additional proteolytic fragments appeared suggesting a different metabolism of the excess PS1, which may impede studies in transfected cells. Our results indicate a tight regulation of the endogenous PS1 metabolites. PS1 and its fragments are shown to be integral membrane proteins of the endoplasmic reticulum. The mechanisms regulating the generation of the metabolites, their potential function, and role in AD remain to be studied.

Expression of APP in transgenic mice: a comparison of neuron-specific promoters.

The beta-amyloid precursor protein (APP) carries mutations in codons 717 or 670/671, which cosegregate with familial forms of Alzheimer's disease (AD). As an initial step to study the related pathogenetic mechanisms in vivo we have generated transgenic mice expressing APP with these mutations. Several neuron-specific promoters were used to drive expression of human APP cDNAs. Only the Thy-1 promoter yielded transgene expression levels comparable to or above the endogenous mouse levels. Deletion of a 121 bp sequence from the 3' untranslated region of APP appeared to increase mRNA levels. Transgene mRNA was found throughout the brain with highest levels in hippocampus and cerebral cortex. Accordingly, human APP was detected in these regions by Western blotting. Protein levels paralleled mRNA levels reaching or exceeding the amount of endogenous APP. Variable reactivity of human APP in cell bodies was shown by immunocytochemistry. Although our initial histological examinations did not reveal any alterations characteristic of AD, further studied will be required.

Progressive age-related impairment of cognitive behavior in APP23 transgenic mice.

Transgenic APP23 mice expressing human APP(751) with the K670N/M671L mutation, were compared at ages 3, 18 or 25 months to non-transgenic littermates in passive avoidance and in a small and large Morris maze. The task in the smaller pool habituated their flight response to the platform. Impairments in passive avoidance and small pool performance in APP23 mice were clearly age-related. In the larger Morris maze APP23 mice at all ages were impaired in latency and distance swum before finding the platform. Identical performance of 18-month APP23 and controls in a visible platform condition indicates that the Morris maze performance deficit was not due to sensory, motor or motivational alterations. At age 3 months both groups initially unexpectedly avoided the visible platform, suggesting that in young mice neophobia may contribute significantly to performance in cognitive tests. In conclusion, APP23 mice exhibit both early behavioral impairment in the large Morris maze as well as impairments in passive avoidance and small pool performance that are marked only in old age.

Transgenic approaches to model Alzheimer's disease.

Two transgenic mouse lines were generated which express human APP751 containing familial Alzheimer's disease (AD) mutations in brain neurons. These mice develop pathological features reminiscent of AD. The degree of pathology depends on both expression levels and specific mutations. In mice with more advanced pathology (APP 23), typical plaques appear at six months which increase with age and are Congo Red positive at first detection. These congophilic plaques are accompanied by neuritic changes and dystrophic cholinergic fibers. Furthermore, inflammatory processes indicated by a massive glial reaction are apparent. Most notably, plaques are immunoreactive for hyperphosphorylated tau, reminiscent of early tau pathology. A quantitative analysis of degenerative changes by state-of-the-art unbiased stereological methods revealed a significant reduction in neuronal cell bodies of the CA1 field of the hippocampus when compared to controls. This reduction is directly related to plaque load. When subjected to analysis in the Morris water maze, 18 month old APP 23 mice show a significant increase in platform finding latency throughout the entire trial when compared to non-transgenic littermates.