Characterisation of cytoskeletal abnormalities in mice transgenic for wild-type human tau and familial Alzheimer's disease mutants of APP and presenilin-1

To study the role of Abeta amyloid deposits in the generation of cytoskeletal lesions, we have generated a transgenic mouse line coexpressing in the same neurons a wild-type human tau isoform (0N3R), a mutant form of APP (751SL) and a mutant form of PS1 (M146L). These mice developed early cerebral extracellular deposits of Abeta, starting at 2.5 months. A somatodendritic neuronal accumulation of transgenic tau protein was observed in tau only and in tau/PS1/APP transgenic mice, including in neurons adjacent to Abeta deposits. The phosphorylation status of this somatodendritic tau was similar in the two transgenic lines. The Abeta deposits were surrounded by a neuritic reaction composed of axonal dystrophic processes, immunoreactive for many phosphotau epitopes and for the human tau transgenic protein. Ultrastructural observation showed in these dystrophic neurites a disorganisation of the microtubule and the neurofilament network but animals that were observed up to 18 months of age did not develop neurofibrillary tangles. These results indicate that overexpression of mutant PS1, mutant APP and of wild-type human tau were not sufficient per se to drive the formation of neurofibrillary tangles in a transgenic model. The Abeta deposits, however, were associated to marked changes in cytoskeletal organisation and in tau phosphorylation in adjacent dystrophic neurites.     

Hyperphosphorylated tau and paired helical filament-like structures in the brains of mice carrying mutant amyloid precursor protein and mutant presenilin-1 transgenes

Senile plaques composed mainly of beta-amyloid (Abeta) and neurofibrillary tangles principally composed of hyperphosphorylated tau are the major pathological features of Alzheimer's disease (AD). Despite the fact that increased expression of amyloid precursor protein (APP) and presenilin-1 (PS1) transgenes in mice lead to increased Abeta deposition in plaquelike structures in the brain, little is known about the nature and distribution of tau in these mice. Therefore the relationship between Abeta and hyperphosphorylated tau was investigated in mice carrying mutant APP and mutant PS1 transgenes using both light (LM) and electron microscopy (EM) with immunocytochemistry. LM immunocytochemistry revealed cerebral Abeta deposits to be present from 8 weeks of age, whereas hyperphosphorylated tau was not detected until 24 weeks of age, when it appeared as punctate deposits in close association with the Abeta deposits in the cortex and hippocampus. However, dystrophic neurites were not as heavily immunolabeled as they are in AD brain. EM revealed that aggregations of straight filaments (10-12 nm wide) were present in some cellular processes at the periphery of Abeta plaques in 8-month-old APP/PS1 mice. In one such mouse, single filaments and paired filaments showing a helical configuration (50-55 nm half-period, 25 nm max. width) were present in a dark, atrophic hippocampal neuron. Immunogold labeling of APP/PS1 mouse brain revealed hyperphosphorylated tau epitopes in some dystrophic neurites from 24 weeks of age that were similar to those present in AD. These results suggest that hyperphosphorylated tau appears in APP/PS1 mouse brain after the onset of Abeta deposition and although it is associated with Abeta deposits, its distribution is not identical to that in AD.     

Ibuprofen suppresses plaque pathology and inflammation in a mouse model for Alzheimer's disease.

The brain in Alzheimer's disease (AD) shows a chronic inflammatory response characterized by activated glial cells and increased expression of cytokines and complement factors surrounding amyloid deposits. Several epidemiological studies have demonstrated a reduced risk for AD in patients using nonsteroidal anti-inflammatory drugs (NSAIDs), prompting further inquiries about how NSAIDs might influence the development of AD pathology and inflammation in the CNS. We tested the impact of chronic orally administered ibuprofen, the most commonly used NSAID, in a transgenic model of AD displaying widespread microglial activation, age-related amyloid deposits, and dystrophic neurites. These mice were created by overexpressing a variant of the amyloid precursor protein found in familial AD. Transgene-positive (Tg+) and negative (Tg-) mice began receiving chow containing 375 ppm ibuprofen at 10 months of age, when amyloid plaques first appear, and were fed continuously for 6 months. This treatment produced significant reductions in final interleukin-1beta and glial fibrillary acidic protein levels, as well as a significant diminution in the ultimate number and total area of beta-amyloid deposits. Reductions in amyloid deposition were supported by ELISA measurements showing significantly decreased SDS-insoluble Abeta. Ibuprofen also decreased the numbers of ubiquitin-labeled dystrophic neurites and the percentage area per plaque of anti-phosphotyrosine-labeled microglia. Thus, the anti-inflammatory drug ibuprofen, which has been associated with reduced AD risk in human epidemiological studies, can significantly delay some forms of AD pathology, including amyloid deposition, when administered early in the disease course of a transgenic mouse model of AD.     

Intracellular mechanisms of amyloid accumulation and pathogenesis in Alzheimer’s disease

Cell-culture studies have revealed some of the fundamental features of the interaction of amyloid Abeta with cells and the mechanism of amyloid accumulation and pathogenesis in vitro. A(beta)1-42, the longer isoform of amyloid that is preferentially concentrated in senile plaque (SP) amyloid deposits in Alzheimer's disease (AD), is resistant to degradation and accumulates as insoluble aggregates in late endosomes or lysosomes. Once these aggregates have nucleated inside the cell, they grow by the addition of aberrantly folded APP and amyloidgenic fragments of APP, that would otherwise be degraded, onto the amyloid lattice in a fashion analogous to prion replication. This accumulation of heterogeneous aggregated APP fragments and Abeta appears to mimic the pathophysiologyof dystrophic neurites, where the same spectrum of components has been identified by immunohistochemistry. In the brain, this residue appears to be released into the extracellular space, possibly by a partially apoptotic mechanism that is restricted to the distal compartments of the neuron. Ultimately, this insoluble residue may be further digested to the protease-resistant A(beta)n-42 core, perhaps by microglia, where it accumulates as senile plaques. Thus, the dystrophic neurites are likely to be the source of the immediate precursors of amyloid in the senile plaques. This is the opposite of the commonly held view that extracellular accumulation of amyloid induces dystrophic neurites. Many of the key pathological events of AD may also be directly related to the intracellular accumulation of this insoluble amyloid. The aggregated, intracellular amyloid induces the production of reactive oxygen species (ROS) and lipid peroxidation products and ultimately results in the leakage of the lysosomal membrane. The breakdown of the lysosomal membrane may be a key pathogenic event, leading to the release of heparan sulfate and lysosomal hydrolases into the cytosol. Together, these observations provide the novel view that amyloid deposits and some of the early events of amyloid pathogenesis initiate randomly within single cells in AD. This pathogenic mechanism can explain some of the more enigmatic features of Alzheimer's pathogenesis, like the focal nature of amyloid plaques, the relationship between amyloid, dystrophic neurites and neurofibrillary-tangle pathology, and the miscompartmentalization of extracellular and cytosolic components observed in AD brain.     

Deposition of mouse amyloid beta in human APP/PS1 double and single AD model transgenic mice

The deposition of amyloid beta (Abeta) peptides and neurofibrillary tangles are the two characteristic pathological features of Alzheimer's disease (AD). To investigate the relation between amyloid precursor protein (APP) production, amyloid beta deposition and the type of Abeta in deposits, i.e., human and/or mouse, we performed a histopathological analysis, using mouse and human specific antibodies, of the neocortex and hippocampus in 6, 12 and 19 months old APP/PS1 double and APP and PS1 single transgenic mice. There was a significant correlation between the human amyloid beta deposits and the intrinsic rodent amyloid beta deposits, that is, all plaques contained both human and mouse Abeta, and the diffuse amyloid beta deposits also colocalized human and mouse Abeta. Furthermore, some blood vessels (mainly leptomeningeal vessels) show labeling with human Abeta, and most of these vessels also label with mouse Abeta. Our findings demonstrate that the human amyloid deposits in APP/PS1 transgenic mice are closely associated with mouse Abeta, however, they do not precisely overlap. For instance, the core of plaques consists of primarily human Abeta, whereas the rim of the plaque contains both human and mouse amyloid beta, similarly, human and mouse Abeta are differentially localized in the blood vessel wall. Finally, as early as amyloid beta deposits can be detected, they show the presence of both human and mouse Abeta. Together, these data indicate that mouse Abeta is formed and deposited in significant amounts in the AD mouse brain and that it is deposited together with the human Abeta.     

Regression stage senile plaques in the natural course of Alzheimer's disease

Resolution process of cerebroparenchymal amyloid beta-protein (Abeta) deposition has become of increasing interest in the light of recent advance in the Abeta-vaccination therapy for Alzheimer's disease (AD). However, the neuropathological features of degraded and disappearing senile plaque remain poorly characterized, especially in the natural course of the disease. To clarify the natural removal processes of Abeta burden in the brain with AD, we devised a triple-step staining method: Bodian for dystrophic neurites, anti-glial fibrillary acidic protein for astrocytes, and anti-Abeta. We thus examined 24 autopsied AD brains. A novel form of senile plaques, termed 'remnant plaques', was identified. Remnant plaques were characterized by mesh-like astroglial fibrils within the entire plaque part, Abeta deposit debris exhibiting weak Abeta immunoreactivity, and only a few slender dystrophic neurites. In remnant plaques, amyloid burden was apparently decreased. The density of remnant plaques increased significantly with disease duration. Dual-labelling immunohistochemistry revealed many Abeta-immunoreactive granules in astrocytes and a modest number in microglia, both of which accumulated in senile plaques. We consider amyloid deposits of diffuse and neuritic plaques to be shredded by astrocytic processes from the marginal zone of plaques, and to gradually disintegrate into smaller compartments. Cerebroparenchymal Abeta deposits undergo degradation. After a long-standing resolution process, diffuse and neuritic plaques may finally proceed to remnant plaques. Astrocytes are actively engaged in the natural Abeta clearance mechanism in advanced stage AD brains, which may provide clues for developing new therapeutic strategies for AD.     

Association of apolipoprotein J-positive beta-amyloid plaques with dystrophic neurites in Alzheimer's disease brain

Apolipoprotein J (apoJ), also known as clusterin and SP-40,40, binds soluble beta-amyloid (Abeta and is up-regulated in the Alzheimer's disease (AD) brain. In the present study we classified apoJ-immunopositive Abeta deposits in AD temporal cortex, and found apoJ-immunoreactive plaques were often associated with dystrophic neurites. Quantitative immunohistochemical analysis of five AD brains showed that 29% of Abeta deposited in the parenchyma was associated with apoJ. Of Abeta deposits with apoJ immunopositivity, 71% were associated with phospho-tau-positive dystrophic neurites in the surrounding tissue. Conversely, 64% of phospho-tau-labeled neuritic deposits were labeled with apoJ. ApoJ was found at the core of these deposits, and co-localized with the amyloid staining agent thioflavine-S. To test the direct effects of apoJ on tau metabolism, we treated cells in culture with apoJ-containing conditioned media, and we injected apoJ-containing media into the rat hippocampus. Using both systems, we observed increases in levels of tau and phosphorylated tau. Our findings demonstrate that apoJ immunopositivity strongly correlates with the presence of amyloid and associated neuritic dystrophy in the neuropil of AD temporal cortex, and supports a model where extracellular apoJ facilitates the conversion of diffuse Abeta deposits into amyloid and enhances tau phosphorylation in neurites surrounding these of plaques.     

Comparative study of histopathology changes between the PS1/APP double transgenic mouse model and Aβ1-40 -injected rat model of Alzheimer disease

Objective To identify the genetype of the PS1/APP double transgenie mouse model, then to analyse the histopathological changes in the brain and compare the differences between the transgenie mice models and Aβ1-40-injeeted rats models of Alzheimer disease. Methods The modified congo red staining, Nissl＇s staining and immunohistology staining was used to observe the Aβ deposits, activation of astrocyte respectively. Results ①The PS1/APP transgenic mouse extensively displayed Aβ deposits in the cortex and hippocampal structures, and GFAP positive cells were aggregated in mass and surrounded the congo red-positive plaque. ②The Aβ1-40-intrahippocmnpal-injeeted rat model showed the Aβ plaque deposits in the dentate gyrus of the hippocampus, with the astrocyte surrounded. The neurons loss was significant in the injection point and pin hole of injection with Nissl＇s staining methods. GFAP-positive cells increased significantly compared with the uninjected lateral of the hippocampus. Conclusion Although Aβ1-40-injected rat models could simulate some characteristic pathological features of human Alzheimer diseases, Aβ deposits and neurons loss in partial hippocampal, it would not simulate the progressive degenenration in the brain of AD. The double transgenie PS1/APP mice could simulate the specific pathogenesis and progressive changes of AD, mainly is Aβ deposits and the spongiocyte response , while no neurons loss were observed in this model.     

Relationship between beta amyloid peptide generating molecules and neprilysin in Alzheimer disease and normal brain

beta-Amyloid peptide (Abeta) is generated by two cleavages of amyloid precursor protein (APP). The initial cleavage by BACE is followed by gamma-secretase cleavage of the C-terminal APP fragment. Presenilin-1 (PS-1) is intimately related to gamma-secretase. Once formed, Abeta is mainly broken down by neprilysin. To estimate vulnerability to Abeta senile plaque formation, we measured the relative mRNA levels of APP695, APP751, APP770, BACE, presenilin-1 (PS-1) and neprilysin in nine brain areas and in heart, liver, spleen and kidney in a series of Alzheimer disease (AD) and control cases. Each of the mRNAs was expressed in every tissue examined. APP695 was the dominant APP isoform in brain. Compared with controls, APP695 and PS-1 mRNA levels were significantly elevated in high plaque areas of AD brain, while neprilysin mRNA levels were significantly reduced. BACE levels were not significantly different in AD compared with control brain. In peripheral organs, there were no significant differences in any of the mRNAs between AD and control cases. APP isoforms were differently expressed in the periphery than in brain, with APP 751>770>695. Neprilysin mRNA levels were much higher, while APP695 and PS-1 mRNA levels were much lower in the periphery than in brain. The data suggest that, in the periphery, the capacity to degrade Abeta is srong, accounting for the failure of Abeta deposits to form. In plaque prone areas of AD brain, the capacity to degrade Abeta is weak, while the capacity to generate Ab is upregulated. In plaque resistant areas of brain, a closer balance exists, but there is some tendency towards lower degrading and higher synthesizing capacity in AD brain compared with control brain. Overall, the data indicate that effectiveness of degradation by neprilysin may be a key factor in determining whether Abeta deposits develop.     

Activation of the cell stress kinase PKR in Alzheimer''s disease and human amyloid precursor protein transgenic mice

Accumulation of amyloid beta peptides (Abeta) in the brain, which is a hallmark of Alzheimer's disease (AD), is associated with progressive damage to neuronal processes resulting in extensive neuritic dystrophy. This process may contribute to cognitive decline, but it is not known how Abeta elicits neuritic injury. Our analysis of AD brains and related transgenic mouse models suggests an involvement of the interferon-induced serine-threonine protein kinase, PKR, which is best known for its activation upon binding to double-stranded RNA. PKR activation is a component of stress-activated pathways that mobilize somatic cell death programs, but its roles in neurological disease largely remain to be defined. An antibody specific to the activated form of PKR (phosphorylated at T451) was used to determine the pattern of PKR activation in postmortem brain tissues from humans or from transgenic mice that express high levels of familial AD-mutant human amyloid precursor protein (hAPP) and hAPP-derived Abeta in neurons. In contrast to nondemented controls, AD cases showed prominent granular phospho-PKR immunoreactivity in association with neuritic plaques and pyramidal neurons in the hippocampus and neocortex. The distribution of phospho-PKR matched the distributions of abnormally phosphorylated tau and active p38 MAP kinase in adjacent sections. Compared with nontransgenic controls, hAPP transgenic mice also showed strong increases in phospho-PKR in the brain, primarily in association with plaques and dystrophic neurites. These findings support a role for PKR activation in the pathogenesis of AD.     

Normal cognitive behavior in two distinct congenic lines of transgenic mice hyperexpressing mutant APP SWE

Amyloid deposition appears to be an early and crucial event in Alzheimer's disease (AD). To generate animal models of AD, mice expressing full-length amyloid precursor protein (APP), with mutations linked to FAD, have been created. These animals exhibit abnormalities characteristic of AD, including deposits of beta-amyloid (Abeta), neuritic plaques, and glial responses. In studies of cognition in these animals, there have been several reports of memory disturbances well before the appearance of amyloid deposits. We have developed two distinct lines of transgenic mice (C3-3 and E1-2) that express the "Swedish" variant of APP (APP(SWE)) at levels that are approximately three-fold higher than endogenous mouse APP. Both lines have been backcrossed to C57BL/6J mice for 10 generations. Here, we use longitudinal and cross-sectional studies to evaluate the cognitive performance of our animals, where the concentration of Abeta1-42 in brain increases with aging from low levels (2-10 pmol/g) at 6-14 months of age to relatively high levels (60-100 pmol/g) at 24-26 months, when deposits of Abeta were beginning to form. When 12-month-old mice were tested in tasks that assess reference and working memory, transgenic mice from both lines could not be distinguished from nontransgenic littermates. Further study of 24- to 26-month-old transgenic mice (C3-3 line) found no evidence of memory impairment despite the presence of high levels of human Abeta (60-100 pmol/g). Thus, the expression of APP(SWE) at approximately three-fold over endogenous levels, which is sufficient to induce amyloid deposition at advanced ages, does not significantly erode cognitive performance in aged mice.     

Cotton wool plaques in non-familial late-onset Alzheimer disease.

Cotton wool plaques (CWP) are large, ball-like plaques lacking dense amyloid cores that displace adjacent structures. They were first described in a Finnish kindred with early-onset Alzheimer disease (AD) with spastic paraparesis due to a presenilin-1 delta9 mutation. We describe a case of sporadic late-onset AD with numerous neocortical CWP as well as severe amyloid angiopathy and marked leukoencephalopathy, compared with 16 cases of late-onset AD with similar degrees of amyloid angiopathy and leukoencephalopathy. The cases were studied with histologic methods and with single and double immunostaining for beta-amyloid (Abeta), paired helical filaments-tau (PHF-tau), neurofilament (NF), glial fibrillary acidic protein (GFAP), HLA-DR, and amyloid precursor protein (APP). We found that CWP were well-circumscribed amyloid deposits infiltrated by ramified microglia and surrounded by dystrophic neurites that were immunopositive for APP, but only weakly for NF and PHF-tau. Abeta1-12 was diffuse throughout the CWP, while Abeta37-42 was peripherally located and Abeta20-40 more centrally located. Two of the 16 late-onset AD cases also had CWP, but they were also admixed with diffuse plaques and plaques with dense amyloid cores. Pyramidal tract degeneration was not a consistent finding or a prominent feature in any case. The results suggest that CWP are not specific for early-onset familial AD with spastic paraparesis.     

Early intraneuronal Abeta deposition in the hippocampus of APP transgenic mice

Increasing evidence suggests that intraneuronal amyloid-beta (Abeta) accumulation may be an early event in Alzheimer's disease (AD) pathogenesis. However direct in vivo evidence regarding initial Abeta seeding is missing. Using an APP transgenic mouse model, our sensitive immunocytochemical procedures revealed a novel intraneuronal Abeta deposition in the somas of hippocampal CA1/subiculum neurons far in advance of the occurrence of extracellular Abetaplaques. These deposits increased exponentially with age and were elevated approximately 4-fold (p < 0.001) by high fat/high cholesterol diet. Abeta40 and Abeta42 were the major constituents of these deposits and were co-localized with lysosomal markers. Our results are consistent with the notion that the earliest Abeta deposition occurs intraneuronally, prior to extracellular amyloid plaque formation.     

Brain trauma in aged transgenic mice induces regression of established abeta deposits

Traumatic brain injury (TBI) increases susceptibility to Alzheimer's disease (AD), but it is not known if TBI affects the progression of AD. To address this question, we studied the neuropathological consequences of TBI in transgenic (TG) mice with a mutant human Abeta precursor protein (APP) mini-gene driven by a platelet-derived (PD) growth factor promoter resulting in overexpression of mutant APP (V717F), elevated brain Abeta levels, and AD-like amyloidosis. Since brain Abeta deposits first appear in 6-month-old TG (PDAPP) mice and accumulate with age, 2-year-old PDAPP and wild-type (WT) mice were subjected to controlled cortical impact (CCI) TBI or sham treatment. At 1, 9, and 16 weeks after TBI, neuron loss, gliosis, and atrophy were most prominent near the CCI site in PDAPP and WT mice. However, there also was a remarkable regression in the Abeta amyloid plaque burden in the hippocampus ipsilateral to TBI compared to the contralateral hippocampus of the PDAPP mice by 16 weeks postinjury. Thus, these data suggest that previously accumulated Abeta plaques resulting from progressive amyloidosis in the AD brain also may be reversible.     

Stress kinases involved inTau phosphorylation in alzheimer’s disease, tauopathies and APP transgenic mice

Hyperphosphorylation and accumulation of tau in neurons (and glial cells) is one of the main pathologic hallmarks in Alzheimer's disease (AD) and other tauopathies, including Pick's disease (PiD), progressive supranuclear palsy, corticobasal degeneration, argyrophilic grain disease and familial frontotemporal dementia and parkinsonism linked to chromosome 17 due to mutations in the tau gene (FTDP-17-tau). Recent studies have shown increased expression of select active kinases, including stress-activated kinase, c-Jun N-terminal kinase (SAPK/JNK) and kinase p38 in brain homogenates in all the tauopathies. Strong active SAPK/JNK and p38 immunoreactivity has been observed restricted to neurons and glial cells containing hyperphosphorylated tau, as well as in dystrophic neurites of senile plaques in AD. Moreover, SAPK/JNK- and p38-immunoprecipitated sub-cellular fractions enriched in abnormal hyperphosphorylated tau have the capacity to phosphorylate recombinat tau and c-Jun and ATF-2 which are specific substrates of SAPK/JNK and p38 in AD and PiD. Interestingly, increased expression of phosphorylated SAPK/JNK and p38 in association with hyperphosphorylated tau containing neurites have been observed around betaA4 amyloid deposits in the brain of transgenic mice (Tg2576)carrying the double APP Swedish mutation. These findings suggest that betaA4 amyloid has the capacity to trigger the activation of stress kinases which, in turn, phosphorylate tau in neurites surrounding amyloid deposits. Reduction in the amyloid burden and decreased numbers of amyloid plaques but not of neurofibrillary degeneration has been observed in the brain of two AD patients who participated in an amyloid-beta immunization trial. Activation of stress kinases SAPK/JNK and p38 were reduced together with decreased tau hyperphosphorylation of aberrant neurites in association with decreased amyloid plaques. These findings support the amyloid cascade hypothesis of tau phosphorylation mediated by stress kinases in dystrophic neurites of senile plaques but not that of neurofibrillary tangles and neuropil threads in AD.     

Plaque biogenesis in brain aging and Alzheimer’s disease. II. Progressive transformation and developmental sequence of dystrophic neurites

Plaque-associated dystrophic neurites are a common pathological feature in the brains of patients with Alzheimer’s disease (AD). In the present study, we investigated the relative abundance and progressive transformation of the amyloid precursor protein (APP), neurofilament (NF) and paired helical filament (PHF) tau-positive dystrophic neurites, within plaques in non-demented controls versus plaque-associated dystrophic neurites in mild or severe AD using double and triple immunolabeling. We also determined the argentophilia of the various sub-populations of dystrophic neurites. In aged non-demented brain, approximately half of the APP-positive plaques contained NF-immunopositive dystrophic neurites; rarely were PHF/tau-positive dystrophic neurites detectable. In contrast, in the AD brain, three-fourths of the APP-positive plaques contained NF-positive dystrophic neurites and half contained PHF/tau neurites. We also observed focal patches of hyper-phosphorylated NF and/or PHF/tau within APP-immunopositive dystrophic neurites, which appeared similar to retrograde degeneration, whereas we never observed focal accumulations of APP within NF- or PHF/tau-positive fibers. We hypothesize that plaque-associated dystrophic neurites within plaques develop in a particular sequence: APP-positive dystrophic neurites appear first and are non-argentophilic. This is followed by the appearance of NF-positive dystrophic neurites, where a subset of NF-positive dystrophic neurites are lightly argentophilic. Over time, PHF/tau-positive dystrophic neurites develop and are strongly argentophilic. These data suggest that dystrophic neurites can develop retrogradely from focal plaque damage to induce somatic and dendritic degeneration and potentially contribute to neurofibrillary tangle formation. Received: 22 September 1997 / Revised, accepted: 15 April 1998     

Hyperhomocysteinemic Alzheimer's mouse model of amyloidosis shows increased brain amyloid beta peptide levels

Recent epidemiological and clinical data suggest that elevated serum homocysteine levels may increase the risk of developing Alzheimer's disease (AD), but the underlying mechanisms are unknown. We tested the hypothesis that high serum homocysteine concentration may increase amyloid beta-peptide (Abeta) levels in the brain and could therefore accelerate AD neuropathology. For this purpose, we mated a hyperhomocysteinemic CBS(tm1Unc) mouse carrying a heterozygous dominant mutation in cystathionine-beta-synthase (CBS*) with the APP*/PS1* mouse model of brain amyloidosis. The APP*/PS1*/CBS* mice showed significant elevations of serum homocysteine levels compared to the double transgenic APP*/PS1* model of amyloidosis. Results showed that female (but not male) APP*/PS1*/CBS* mice exhibited significant elevations of Abeta40 and Abeta42 levels in the brain. Correlations between homocysteine levels in serum and brain Abeta levels were statistically significant. No increases in beta secretase activity or evidence of neuronal cell loss in the hyperhomocysteinemic mice were found. The causes of neuronal dysfunction and degeneration in AD are not fully understood, but increased production of Abeta seems to be of major importance. By unveiling a link between homocysteine and Abeta levels, these findings advance our understanding on the mechanisms involved in hyperhomocysteinemia as a risk factor for AD.     

Accumulation of cellular prion protein within dystrophic neurites of amyloid plaques in the Alzheimer's disease brain

Amyloid plaques, a well‐known hallmark of Alzheimer's disease (AD), are formed by aggregated β‐amyloid (Aβ). The cellular prion protein (PrPc) accumulates concomitantly with Aβ in amyloid plaques. One type of amyloid plaque, classified as a neuritic plaque, is composed of an amyloid core and surrounding dystrophic neurites. PrPc immunoreactivity reminiscent of dystrophic neurites is observed in neuritic plaques. Proteinase K treatment prior to immunohistochemistry removes PrPc immunoreactivity from amyloid plaques, whereas Aβ immunoreactivity is enhanced by this treatment. In the present study, we used a chemical pretreatment by a sarkosyl solution (0.1% sarkosyl, 75 mM NaOH, 2% NaCl), instead of proteinase K treatment, to evaluate PrPc accumulation within amyloid plaques. Since PrPc within amyloid plaques is removed by this chemical pretreatment, we can recognize that the PrP species deposits within amyloid plaques were PrPc. We could observe that PrPc accumulation in dystrophic neurites occurred differently compared with Aβ or hyperphosphorylated tau aggregation in the AD brain. These results could support the hypothesis that PrPc accumulation in dystrophic neurites reflects a response to impairments in cellular degradation, endocytosis, or transport mechanisms associated with AD rather than a non‐specific cross‐reactivity between PrPc and aggregated Aβ or tau.     

Neuropathology of mice carrying mutant APP(swe) and/or PS1(M146L) transgenes: alterations in the p75(NTR) cholinergic basal forebrain septohippocampal pathway

Cholinergic basal forebrain (CBF) projection systems are defective in late Alzheimer's disease (AD). We examined the brains of 12-month-old singly and doubly transgenic mice overexpressing mutant amyloid precursor protein (APP(swe)) and/or presenilin-1 (PS1(M146L)) to investigate the effects of these AD-related genes on plaque and tangle pathology, astrocytic expression, and the CBF projection system. Two types of beta-amyloid (Abeta)-immunoreactive (ir) plaques were observed: type 1 were darkly stained oval and elongated deposits of Abeta, and type 2 were diffuse plaques containing amyloid fibrils. APP(swe) and PS1(M146L) mouse brains contained some type 1 plaques, while the doubly transgenic (APP(swe)/PS1(M146L)) mice displayed a greater abundance of types 1 and 2 plaques. Sections immunostained for the p75 NGF receptor (p75(NTR)) revealed circular patches scattered throughout the cortex and hippocampus of the APP(swe)/PS1(M146L) mice that contained Abeta, were innervated by p75(NTR)-ir neurites, but displayed virtually no immunopositive neurons. Tau pathology was not seen in any transgenic genotype, although a massive glial response occurred in the APP(swe)/PS1(M146L) mice associated with amyloid plaques. Stereology revealed a significant increase in p75(NTR)-ir medial septal neurons in the APP(swe) and PS1(M146L) singly transgenic mice compared to the APP(swe)/PS1(M146L) mice. No differences in size or optical density of p75(NTR)-ir neurons were observed in these three mutants. p75(NTR)-ir fibers in hippocampus and cortex were more pronounced in the APP(swe) and PS1(M146L) mice, while the APP(swe)/PS1(M146L) mice showed the least p75(NTR)-ir fiber staining. These findings suggest a neurotrophic role for mutant APP and PS1 upon cholinergic hippocampal projection neurons at 12 months of age.     

A comparative assessment of gamma-secretase activity in transgenic and non-transgenic rodent brain

Amyloid-beta (Abeta) deposits are one of the hallmarks of the neuropathological degeneration observed in Alzheimer's disease (AD) and Abeta concentrations have been reported to vary in different brain regions of AD patients. Abeta is produced by the sequential cleavage of amyloid precursor protein (APP) by beta-secretase and gamma-secretase, respectively. Previous studies have shown that over-expression of the gamma-secretase complex leads to increased gamma-secretase proteolytic activity increasing Abeta production. However, it is not known whether brain regions with highest Abeta concentration also express relatively higher levels of gamma-secretase activity. Accordingly, the relationship between Abeta levels and gamma-secretase activity across brain regions was investigated and correlated in the brains of transgenic and non-transgenic rodents commonly used in AD research. The data demonstrated that Abeta levels do vary in different brain regions in both transgenic and non-transgenic mice but are not correlated with regional gamma-secretase activity. Furthermore, this study demonstrated that while mutations in the APP and PS1 sequences affect the absolute Abeta levels this is not reflected in an increase in gamma-secretase proteolytic activity. The data in the current paper indicate that this assay is able to measure the level of gamma-secretase activity in rodent species. Using this methodology will aid our understanding of physiological gamma-secretase function.