Alzheimer's disease-affected brain: presence of oligomeric A beta ligands (ADDLs) suggests a molecular basis for reversible memory loss

A molecular basis for memory failure in Alzheimer's disease (AD) has been recently hypothesized, in which a significant role is attributed to small, soluble oligomers of amyloid beta-peptide (A beta). A beta oligomeric ligands (also known as ADDLs) are known to be potent inhibitors of hippocampal long-term potentiation, which is a paradigm for synaptic plasticity, and have been linked to synapse loss and reversible memory failure in transgenic mouse AD models. If such oligomers were to build up in human brain, their neurological impact could provide the missing link that accounts for the poor correlation between AD dementia and amyloid plaques. This article, using antibodies raised against synthetic A beta oligomers, verifies the predicted accumulation of soluble oligomers in AD frontal cortex. Oligomers in AD reach levels up to 70-fold over control brains. Brain-derived and synthetic oligomers show structural equivalence with respect to mass, isoelectric point, and recognition by conformation-sensitive antibodies. Both oligomers, moreover, exhibit the same striking patterns of attachment to cultured hippocampal neurons, binding on dendrite surfaces in small clusters with ligand-like specificity. Binding assays using solubilized membranes show oligomers to be high-affinity ligands for a small number of nonabundant proteins. Current results confirm the prediction that soluble oligomeric A beta ligands are intrinsic to AD pathology, and validate their use in new approaches to therapeutic AD drugs and vaccines.

Femtomole Immunodetection of Synthetic and Endogenous Amyloid-β Oligomers and Its Application to Alzheimer's Disease Drug Candidate Screening

Alzheimer's disease (AD) is a fatal, progressive dementia for which there is no cure and for which a molecular basis has yet to be established. However, considerable evidence suggests that AD is linked to neurotoxic assemblies of the 42-amino-acid peptide amyloid beta (Abeta). There is now a clear body of evidence that shows this neurotoxicity resides not only in insoluble fibrils of Abeta but also in soluble Abeta ADDLs (Abeta-derived diffusible ligands) and larger protofibrils. Further, anti-Abeta antibodies have been reported to reverse memory failure in human amyloid precursor protein (hAPP)-expressed transgenic mice in a manner that suggests symptom reversal is attributable to targeting of ADDLs. Clearly, a search for drugs targeting the assembly of these soluble Abeta species represents a new and potentially important approach to the treatment of AD. In this work we describe the development of a dot-blot immunoassay to measure ADDL at the femtomole level, its use in defining the time course of ADDL formation, and its use in determining the presence of ADDLs in the hAPP transgenic mouse brain. Discussion of a protocol to screen agents for inhibition of neurotoxic ADDLformation both in vivo and in vitro is also presented. The methods are suitable for screening combinatorial libraries and, importantly, provide the potential for simultaneous information on candidate transport across the blood-brain barrier.

Selective neuronal degeneration induced by soluble oligomeric amyloid beta protein

The prevailing amyloid hypothesis for Alzheimer's disease (AD) holds that amyloid beta-protein (Abeta) causes neuronal degeneration by forming neurotoxic fibrillar structures. Yet, many aspects of AD pathology and symptoms are not well explained by this hypothesis. Here, we present evidence that neurotoxicity of soluble oligomeric Abeta closely corresponds to the selective neurodegeneration so distinctly manifest in AD. Selectivity was first observed in vitro, where only the human central nervous system neuronal cells were susceptible to soluble oligomeric Abeta. Furthermore, in mouse cerebral slice treated with soluble oligomeric Abeta, selective regiospecific toxicity was evident in the hippocampal CA1, a division important for memory, but not in the CA3 subfield. The fibrillar Abeta, however, killed neurons in all regions of the cerebral slice cultures and also in cerebellar slices. Remarkably, even at the highest soluble oligomeric Abeta concentrations, cerebellar neurons were completely spared, consistent with one of the hallmark features of AD pathology. Our observation of the selective neurodegeneration of soluble oligomeric Abeta to neurons involved in cognitive function may provide a new opportunity for the development of an effective AD therapy as well as elucidating the pathological mechanism of AD.

Abeta toxicity in Alzheimer's disease: globular oligomers (ADDLs) as new vaccine and drug targets

Over the past several years, experiments with synthetic amyloid-beta peptide (Abeta) and animal models have strongly suggested that pathogenesis of Alzheimer's disease (AD) involves soluble assemblies of Abeta peptides (Trends Neurosci. 24 (2001) 219). These soluble neurotoxins (known as ADDLs and protofibrils) seem likely to account for the imperfect correlation between insoluble fibrillar amyloid deposits and AD progression. Recent experiments have detected the presence of ADDLs in AD-afflicted brain tissue and in transgenic-mice models of AD. The presence of high affinity ADDL binding proteins in hippocampus and frontal cortex but not cerebellum parallels the regional specificity of AD pathology and suggests involvement of a toxin receptor-mediated mechanism. The properties of ADDLs and their presence in AD-afflicted brain are consistent with their putative role even in the earliest stages of AD, including forms of mild cognitive impairment.

Per-6-substituted beta-cyclodextrin libraries inhibit formation of beta-amyloid-peptide (A beta)-derived, soluble oligomers

Alzheimer's disease is the most common cause of dementia in older individuals with compelling evidence favoring neuron dysfunction and death triggered by assembled forms of A beta(1-42). While large neurotoxic amyloid fibrils have been known for years, recent studies show that soluble protofibril and A beta(1-42)-derived diffusible ligands (ADDLs) may also be involved in neurotoxicity. In the present work, dot-blot immunoassays discriminating ADDLs from monomers were used to screen libraries of per-substituted beta-cyclodextrin (beta-CD) derivatives for inhibition of ADDLs formation. Libraries were prepared from per-6-iodo-beta-CD by treatment with various amine nucleophiles. The most active library tested (containing >2000 derivatives) was derived from imidazole, N, N-dimethylethylenediamine and furfurylamine, which at 10 microM total library, inhibited ADDLs formation (10 nM A beta(1-42)) over a period of 4 hours. The latter was confirmed by a western blot assay showing decreased amounts of the initially formed A beta(1-42) tetramer. These preliminary experiments suggest that derivatized forms of beta-CD can interfere with the oligomerization process of A beta(1-42).

Soluble oligomers of beta amyloid (1-42) inhibit long-term potentiation but not long-term depression in rat dentate gyrus

The dementia in Alzheimer disease (AD) is usually attributed to widespread neuronal loss in conjunction with the pathologic hallmarks of intracellular neurofibrillary tangles and extracellular plaques containing amyloid (A beta) in fibrillar form. Recently it has been demonstrated that non-fibrillar assemblies of A beta possess electrophysiologic activity, with the corollary that they may produce dementia by disrupting neuronal signaling prior to cell death. We therefore examined the effects of soluble oligomers of A beta(1-42) on long-term potentiation (LTP) and long-term depression (LTD), two cellular models of memory, in the dentate gyrus of rat hippocampal slices. Compared with vehicle controls, slices pre-incubated 60 min in the presence of A beta-derived diffusible ligands (ADDLs) showed no differences in threshold intensity to evoke a synaptic response, slope of field excitatory post-synaptic potentials (EPSPs), or the input/output function. Tetanus-induced LTP and reversal of LTD were strongly inhibited in ADDLs-treated slices whereas LTD was unaffected. These data suggest that soluble non-fibrillar amyloid may contribute to the pathogenesis of AD both by impairing LTP/memory formation at the cellular level and by creating 'neuroplasticity imbalance' manifested by unopposed LTD in the setting of impaired capacity for neural repair via reversal of LTD or LTP.

Vaccination with soluble Abeta oligomers generates toxicity-neutralizing antibodies

In recent studies of transgenic models of Alzheimer's disease (AD), it has been reported that antibodies to aged beta amyloid peptide 1-42 (Abeta(1-42)) solutions (mixtures of Abeta monomers, oligomers and amyloid fibrils) cause conspicuous reduction of amyloid plaques and neurological improvement. In some cases, however, neurological improvement has been independent of obvious plaque reduction, and it has been suggested that immunization might neutralize soluble, non-fibrillar forms of Abeta. It is now known that Abeta toxicity resides not only in fibrils, but also in soluble protofibrils and oligomers. The current study has investigated the immune response to low doses of Abeta(1-42) oligomers and the characteristics of the antibodies they induce. Rabbits that were injected with Abeta(1-42) solutions containing only monomers and oligomers produced antibodies that preferentially bound to assembled forms of Abeta in immunoblots and in physiological solutions. The antibodies have proven useful for assays that can detect inhibitors of oligomer formation, for immunofluorescence localization of cell-attached oligomers to receptor-like puncta, and for immunoblots that show the presence of SDS-stable oligomers in Alzheimer's brain tissue. The antibodies, moreover, were found to neutralize the toxicity of soluble oligomers in cell culture. Results support the hypothesis that immunizations of transgenic mice derive therapeutic benefit from the immuno-neutralization of soluble Abeta-derived toxins. Analogous immuno-neutralization of oligomers in humans may be a key in AD vaccines.

Targeting small Abeta oligomers: the solution to an Alzheimer's disease conundrum?

Amyloid beta (Abeta) is a small self-aggregating peptide produced at low levels by normal brain metabolism. In Alzheimer's disease (AD), self-aggregation of Abeta becomes rampant, manifested most strikingly as the amyloid fibrils of senile plaques. Because fibrils can kill neurons in culture, it has been argued that fibrils initiate the neurodegenerative cascades of AD. An emerging and different view, however, is that fibrils are not the only toxic form of Abeta, and perhaps not the neurotoxin that is most relevant to AD: small oligomers and protofibrils also have potent neurological activity. Immuno-neutralization of soluble Abeta-derived toxins might be the key to optimizing AD vaccines that are now on the horizon.

Increased Protein Tyrosine Phosphorylation in Apoptotic Neural Cell Death Due to Microtubule Perturbations

The microtubule-perturbing drugs colchicine and taxol have been found to induce apoptosis in a CNS neuronal cell line. Apoptosis in drug-treated rat B103 neuroblastoma cells was evident in characteristic morphological changes, internucleosomal DNA fragmentation, and loss of nuclear content. Since colchicine and taxol have opposite actions on microtubule integrity, disruption of the active turnover of the microtubule network appears to be a crucial step for apoptosis to occur. It has been suggested that the basis for apoptosis by these drugs derives from their known block of the cell cycle at G₂/M, but this does not appear the sole reason as both colchicine and taxol were able to evoke high levels of apoptosis in cells differentiated by Bt₂cAMP or serum withdrawal. Further tests of cellular consequences of microtubule perturbation revealed a specific impact on signal transduction involving protein tyrosine phosphorylation. Immunoprecipitation with antibodies against tyrosine phosphorylated proteins showed a striking increase in the phosphorylation of a Triton-insoluble ~90 kDa protein, roughly concurrent with the onset of internucleosomal DNA fragmentation. Cycloheximide and genistein significantly reduced cell death and blocked appearance of the ~90 kDa tyrosine phosphorylated protein. Data suggest the hypothesis that signal transduction leading to apoptosis can be triggered by anomalous microtubule turnover and that the mechanism involves tyrosine phosphorylation of a ~90 kDa Triton-resistant protein.

Reversible inactivation of superoxide-sensitive aconitase in Abeta1-42-treated neuronal cell lines

The activity of the superoxide-sensitive enzyme aconitase was monitored to evaluate the generation of superoxide in neuronal cell lines treated with beta-amyloid (Abeta) peptide 1-42. Treatment of differentiated and undifferentiated rat PC12 and human neuroblastoma SK-N-SH cells with soluble Abeta1-42 (Abeta-derived diffusible ligands) or fibrillar Abeta1-42 caused a 35% reversible inactivation of aconitase, which preceded loss of viability and was correlated with altered cellular function. Aconitase was reactivated upon incubation of cellular extracts with iron and sulfur, suggesting that Abeta causes the release of iron from 4Fe-4S clusters. Abeta neurotoxicity was partially blocked by the iron chelator deferoxamine. These data suggest that increased superoxide generation and the release of iron from 4Fe-4S clusters are early events in Abeta1-42 neurotoxicity.

Diffusible, nonfibrillar ligands derived from Abeta1-42 are potent central nervous system neurotoxins

Abeta1-42 is a self-associating peptide whose neurotoxic derivatives are thought to play a role in Alzheimer's pathogenesis. Neurotoxicity of amyloid beta protein (Abeta) has been attributed to its fibrillar forms, but experiments presented here characterize neurotoxins that assemble when fibril formation is inhibited. These neurotoxins comprise small diffusible Abeta oligomers (referred to as ADDLs, for Abeta-derived diffusible ligands), which were found to kill mature neurons in organotypic central nervous system cultures at nanomolar concentrations. At cell surfaces, ADDLs bound to trypsin-sensitive sites and surface-derived tryptic peptides blocked binding and afforded neuroprotection. Germ-line knockout of Fyn, a protein tyrosine kinase linked to apoptosis and elevated in Alzheimer's disease, also was neuroprotective. Remarkably, neurological dysfunction evoked by ADDLs occurred well in advance of cellular degeneration. Without lag, and despite retention of evoked action potentials, ADDLs inhibited hippocampal long-term potentiation, indicating an immediate impact on signal transduction. We hypothesize that impaired synaptic plasticity and associated memory dysfunction during early stage Alzheimer's disease and severe cellular degeneration and dementia during end stage could be caused by the biphasic impact of Abeta-derived diffusible ligands acting upon particular neural signal transduction pathways.

Rapid impact of beta-amyloid on paxillin in a neural cell line

Beta-amyloid1-42 (Abeta) is a naturally occuring peptide whose accumulation in the brain is putatively coupled to Alzheimer's disease pathogenesis. Deleterious effects of Abeta on neurons have been linked to the inappropriate activation of signaling pathways within the cell (reviewed in Yankner, 1996), including tyrosine phosphorylation of focal adhesion kinase (FAK) (Zhang et al., 1994, 1996a,b). Here we have investigated the effects of Abeta on paxillin in a neural cell line. Paxillin, a substrate for FAK, is thought to act as a signal "integrator," functioning to link other proteins into multi-molecular signaling complexes (reviewed in Turner, 1994). Treatment of the rat central nervous system B103 cell line with aggregates of Abeta was found to induce the tyrosine phosphorylation of paxillin within 30 min, nearly 24 hr prior to significant cell death. Particularly striking was a subsequent "mobilization" of paxillin to the cytoskeleton in Abeta-treated cells. The amount of paxillin associated with the cytoskeleton in Abeta-treated cells was increased 10-fold over controls. The Abeta-induced paxillin accumulation could be visualized immunocytochemically, with an increase in number and size of paxillin-labeled focal contacts upon treatment with Abeta. This effect was specific, in that vinculin, another focal contact protein, was unaffected by Abeta. Disruption of f-actin, which inhibits both Abeta-induced neurotoxicity (Furukawa and Mattson, 1995) and focal contact signaling in B103 cells (Zhang et al., 1996b) was found to block the cytoskeletal paxillin accumulation. The rapid tyrosine phosphorylation and cytoskeletal mobilization of paxillin links Abeta to the activation of focal contact signaling events that may influence neuronal cytoskeletal architecture, gene expression, synaptic plasticity and cell viability.

CNS neuronal focal adhesion kinase forms clusters that co-localize with vinculin

Focal adhesion kinase (FAK) is a non-receptor protein tyrosine kinase that appears to play a central role in integrin-mediated signal transduction in non-neuronal cells, linking the extracellular matrix to the actin-based cytoskeleton at focal adhesion contacts. Biochemical analysis has revealed the presence of FAK immunoreactivity in cells of neuronal lineage (Zhang et al., 1994) and in the CNS (Burgaya et al. 1995; Grant et al., 1995). In the current work, we have examined the immunodistribution of FAK in nerve cell cultures and tissue sections from the rat CNS. Cultures of B103 CNS neuroblastoma cells and primary cultures of hippocampal neurons both showed abundant FAK immunoreactivity in nerve cell bodies. Immunoreactivity also extended into neurites and growth cones. The most striking feature of FAK distribution was the presence of short, punctate clusters of high FAK concentration. These FAK clusters were maintained in triton-extracted cell ghosts, indicating association with the cytoskeleton. Double-label confocal imaging showed that clusters of FAK coincided with clusters of vinculin, another actin-associated signal transduction molecule implicated in control of growth cone motility. Data from hippocampal sections verified the presence of FAK in adult neurons where it was enriched in somato-dendritic domains and showed a non-uniform distribution. Quantitative FAK immunoprecipitation to compare adult with embryonic brain showed a 7-fold developmental down-regulation of FAK and a 21-fold down-regulation of FAK TyrP. The data suggest that neuronal FAK may participate in signal transduction complexes relevant to neuronal morphogenesis and plasticity.

A beta peptide enhances focal adhesion kinase/Fyn association in a rat CNS nerve cell line

Neurotoxicity of the amyloid beta protein (A beta) is known to correlate with a selective change in protein tyrosine phosphorylation (Tyr(P)) of focal adhesion kinase (FAK) (Zhang et al., J. Biol. Chem., 269 (1994) 25247-25250). The current work has found that exposure of neuronal cells to A beta upregulates the stable association of FAK with Fyn, a neuronally-enriched protein tyrosine kinase of the Src-family. In cells incubated with aged A beta 1-42, the amount of immunoprecipitable FAK-Fyn complex increased approximately 280%. Equivalent results were obtained whether anti-FAK or anti-Fyn was used to precipitate the complex. Cells incubated with non-toxic A beta 17-42, which makes aggregates and attaches to cells but does not upregulate FAK Tyr(P), exhibited no increase in FAK-Fyn complex. Aberrant Fyn activity due to the A beta evoked association with FAK could play a role in neuronal degeneration and also cause anomalies in synaptic plasticity. These possibilities are of particular significance because of the reported increase in Fyn immunoreactivity in Alzheimer's-afflicted neurons (Shirazi and Wood, NeuroReport, 4 (1993) 435-437).

Protein kinase C and F-actin are essential for stimulation of neuronal FAK tyrosine phosphorylation by G-proteins and amyloid beta protein

Focal adhesion kinase (FAK) is a protein tyrosine kinase implicated in signal transduction pathways for integrins, neuropeptides, and lysophosphatidic acid. FAK, first discovered in non-neuronal cells, recently has been reported to occur in neurons, where its tyrosine phosphorylation is upregulated by fibronectin and by the Alzheimer's Abeta peptide. The current work has elucidated molecular events leading to tyrosine phosphorylation of FAK in the rat B103 CNS nerve cell line. Activation of receptor-coupled G-proteins by Mas-7 was found to evoke rapid upregulation of FAK tyrosine phosphorylation (Tyr(P)). Upregulation by Mas-7 was blocked by GF109203X, a potent inhibitor of protein kinase C (PKC). Phorbol ester also upregulated FAK-YP, verifying a role for PKC in the transduction cascade. Upregulation of FAK-YP by activation of G-proteins and PKC was dependent upon intact F-actin, as cytochalasin D abolished stimulation by Mas-7 and by phorbol ester. The relatively slow increase in FAK-YP evoked by chronic exposure to Abeta also was abolished by GF109203X and by cytochalasin D. The results show that tyrosine phosphorylation of FAK in neurons is regulated positively by PKC, functioning down-stream from G-proteins through an F-actin-dependent mechanism. The Alzheimer's Abeta peptide is capable of activating elements of this same signal transduction pathway, via membrane events that remain to be determined.

Delivery of membrane-impermeant fluorescent probes into living neural cell populations by lipotransfer

Use of fluorescent probes to monitor f-actin in living cells typically relies on difficult microinjection procedures. The current work has developed cationic lipotransfer of membrane-impermeant probes as an alternative to microinjection. BODIPY FL-phallacidin, a fluorescent f-actin probe, was packaged into 40-50 nm cationic liposomes. Packaging, verified by gel filtration, enabled delivery of the probe into living nerve cells and provided an image of f-actin that was identical to that seen in fixed, permeabilized cells. Phallacidin alone did not enter living cells, nor was its uptake stimulated by the presence of empty liposomes. All predicted f-actin structures were fluorescent in living cells, indicating a high efficacy of delivery. Cationic lipotransfer of fluorescent probes was rapid, not disruptive to cells, and delivered a probe en masse to a large sample population. Lipotransfer appears to be a promising alternative to microinjection for introducing membrane-impermeant probes and reagents into living cells.

Cholesterol modulates alpha-secretase cleavage of amyloid precursor protein

Amyloid precursor protein (APP) and cholesterol metabolism are genetically linked to Alzheimer's disease, the latter through apolipoprotein E, a lipid and cholesterol transport protein. We have examined the hypothesis that the processing of APP is disrupted by elevated cholesterol, which is known to modulate the activity of several transmembrane proteins. In the current study, cholesterol, solubilized by methyl- beta-cyclodextrin or ethanol, was added to the culture media of APP 751 stably transfected HEK 293 cells. Radiolabeled APP and APPsol (the soluble N-terminal derivative following alpha-secretase cleavage) were precipitated from lysates and conditioned media of stably transfected HEK 293 cells; the relative levels were determined by quantitative densitometry following separation by SDS-polyacrylamide gel electrophoresis. The data show that cholesterol, solubilized by methyl-beta-cyclodextrin, greatly reduced the levels of APPsol. Low doses of ethanol-solubilized cholesterol similarly caused a dramatic reduction of APPsol. By contrast, levels of APP holoprotein remained the same or increased. The large decrease seen in APPsol production was not due to nonspecific inhibition of secretion because several secreted proteins increased in level. Cholesterol, which impedes membrane fluidity, may lower APPsol production by impeding the interaction of the substrate with its protease(s). If APPsol were to function trophically, as suggested by other studies, the current conclusion suggests that changes in cellular cholesterol levels in Alzheimer's disease could contribute to neuronal degeneration by decreasing the production of APPsol.

Constitutive Alzheimer's-type tau epitopes in a neuritogenic rat CNS cell line

Paired helical filaments (PHFs) of Alzheimer's disease (AD) largely comprise hyperphosphorylated forms of the cytoskeletal protein tau. AD-type tau phosphoepitopes, detected by various monoclonal antibodies, are absent from normal adult neurons, but recent studies have shown that their expression may contribute to neuritogenesis and axon differentiation in the developing nervous system. Therefore, we have examined a brain nerve cell line that is spontaneously neuritogenic for possible expression of AD-type tau epitopes. The neuritogenic rat brain cell line B103 was found to constitutively produce two-AD related epitopes of tau, detected by cellular immunofluorescence studies with the PHF-1 and Alz-50 monoclonal antibodies. Biochemical studies showed that the antibodies bound to proteins within the molecular, weight range expected for phosphorylated tau isoforms. Further verification was established by use of tau antisense oligomers, which eliminated cellular immunofluorescence due to the AD-related monoclonals and polyclonal anti-tau but did not eliminate fluorescence due to anti-tubulin. Cells treated with tau antisense were not neurite-free. Neurites that remained, however, were abnormal, generally short and wavy in appearance. Cellular distribution of the tau epitopes was found to be particularly interesting. Alz-50 recognized only cytoplasmic tau whereas PHF-1 recognized nuclear tau as well as cytoplasmic. Thus, the two epitopes, are morphologically segregated within the cell. Because subcellular segregation of tau is compromised in Alzheimer's disease, mechanisms that segregate AD-type phosphotau epitopes in B103 cells may have relevance to this neurodegenerative disorder.

Alzheimer's-associated phospho-tau epitope in human neuroblastoma cell cultures: up-regulation by fibronectin and laminin

Alzheimer's-afflicted neurons contain phosphorylated forms of tau that are not present in healthy adults. these can be recognized with great specificity by monoclonal antibodies such as paired helical filament-1 (PHF-1) [Greenberg S. G. and Davies P. (1990) Proc. natn. Acad. Sci. U.S.A. 87, 5827-5831; Greenberg S. G. et al. (1992) J. biol. Chem. 267, 564-569]. The PHF-1 phospho-tau epitope is also present in immature neurons undergoing axodendritic differentiation [Pope W. B. et al. (1993) Expl Neurol. 120, 106-113]. Analogous to its presence in immature neurons, we report here that the PHF-1 tau epitope spontaneously occurs in the human neuroblastoma cell line SHSY5Y, where its level can be regulated by differentiation and by molecules found in the extracellular matrix. Confocal immunofluorescence studies showed PHF-1 epitope to be constitutively expressed in the somatic cytoplasm as well as in short neurites typical of undifferentiated SHSY5Y cells. Induction of differentiation with retinoic acid produced cells with a neuronal morphology and a redistribution of the expression of PHF-1 tau in the long neurites. Protracted exposure to retinoic acid decreased the levels of PHF-1 immunofluorescence without a loss of neurites, similar to the developmental down-regulation seen in situ. The effects of retinoic acid on PHF-1 immunofluorescence were modifiable by fibronectin, which can be released by some neuroblastoma cell lines [Ciccarone V. et al. (1989) Cancer Res. 49, 219-225; Yoshihara T. et al. (1992) Int. J. Cancer 51, 620-626]. Exogenous human fibronectin caused a marked up-regulation of PHF-1 immunofluorescence. Quantitative analysis of 15 multicellular areas, from six different cultures, per experimental condition showed a 16-fold increase compared to untreated controls. Up-regulation by fibronectin was also evident in undifferentiated cells. Cell counts indicated no proliferative effects of the fibronectin under the conditions used. Laminin also caused an increase of PHF-1 tau in retinoic acid-treated cells. Data obtained from immunoblots verified the results observed with immunofluorescence. The data show that the PHF-1 tau epitope is spontaneously expressed by non-degenerating human neuroblastoma cells, down-regulated by cellular differentiation, induced by retinoic acid and up-regulated by the extracellular matrix components fibronectin and laminin. One explanation of the data is that fibronectin maintains a population of SHSY5Y cells in a biochemical state of differentiation in which PHF-1 tau is expressed.(ABSTRACT TRUNCATED AT 400 WORDS)

Particulate forms of APP in the extracellular milieu of cultured cells

The principle externalized forms of amyloid precursor protein (APP) are soluble and well-characterized, but some evidence has suggested the additional presence of externalized APP in a nonsoluble form. To further assess this possibility, the current study has applied high resolution microscopy protocols in addition to immunoprecipitation to characterize externalized APP in three commonly used cell culture models (SH-SY5Y human neuroblastoma cells, fetal rat brain cells, and HEK 293 human embryonic kidney cells). Confocal immunofluorescence microscopy, using an antiserum against the c-terminal domain of APP, showed typical cell-associated APP, but hot spots of APP also were evident in cell-free areas, apparently associated with the culture substrata. These hot-spots were examined for evidence of cellular deterioration by whole mount transmission electron microscopy. Neither cell debris nor disrupted cells were present. Instead, the hot spots of substratum-bound APP comprised discrete microparticles, approximately 50-100 nm across. These microparticles also could be found near cells and in some cases were attached to cell surface fibrils. Substratum-bound APP also could be found clustered within the extracellular matrix made by primary cell cultures. Occurrence of APP in extracellular microparticles was verified by centrifugation-immunoprecipitation analysis of media conditioned by APP-transfected cells. Radiolabeling data showed that particulate APP was from metabolically active cells. Metabolic labeling of particle-associated APP, as well as the absence of cellular debris near the APP-containing particles, suggests that the occurrence of nonsoluble APP in the extracellular milieu derives from a physiologically active process.

Interaction of beta-amyloid peptides with integrins in a human nerve cell line

beta-Amyloid accumulates as extracellular aggregates in Alzheimer's-afflicted brain tissue, but it also is secreted by healthy tissue, for reasons not yet established. One possibility is that beta-amyloid, which contains a sequence (RHDS) homologous to the cell-binding domain of fibronectin, may modulate integrin function, a possibility supported by previous data from non-neuronal cells (Ghiso et al., Biochem. J., 288 (1992) 1053-1059). The current work shows that functional interaction with beta-amyloid peptides is also supported by integrins in neuronal cells. Experiments used the SH-SY5Y human neuroblastoma cell line, which was shown to contain integrins that mediated cell adhesion to substratum-bound fibronectin. Adhesion to fibronectin was partially blocked by synthetic beta-amyloid peptides containing the RHDS sequence. beta-Amyloid sequences adsorbed to substratum themselves were found to mediate cell adhesion, although less effectively than fibronectin. Anti-integrin blocked the peptide-mediated adhesion, at doses commensurate with those blocking fibronectin-mediated adhesion. The data support the hypothesis that beta-amyloid peptides could physiologically, and perhaps pathogenically, modulate the activity of neuronal integrins, important cell surface receptors known to control protein kinase activities, Ca2+ levels, gene expression and organization of the cytoskeleton.

Iron levels modulate alpha-secretase cleavage of amyloid precursor protein

The amyloid precursor protein (APP) is a membrane-spanning glycoprotein that is the source of beta A4 peptides, which aggregate in Alzheimer's disease to form senile plaques. APP is cleaved within the beta A4 sequence to release a soluble N-terminal derivative (APPsol), which has a wide range of trophic and protective functions. In the current study we have examined the hypothesis that iron availability may modulate expression or processing of APP, whose mRNA contains, based on sequence homology, a putative iron response element (IRE). Radiolabeled APP and its catabolites were precipitated from lysates and conditioned medium of stably transfected HEK 293 cells using antibodies selective for C-terminal, beta A4, and N-terminal domains. The relative abundance of the different APP catabolites under different conditions of iron availability was determined by quantitative densitometry after separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The data show a specific effect on the production of APPsol. Using standard conditions previously established for IRE studies, it was found that iron chelation reduces APPsol production, whereas iron level elevation augments it. No changes were observed in levels of immature and mature APP holoprotein or in the C-terminal alpha-secretase derivative C83, beta A4, and p3 peptides. The specificity for modulatory changes in APPsol suggests that iron acts at the level of alpha-secretase activity. In addition to its modulatory effects, iron at very high levels was found to inhibit maturation of APP and production of its downstream catabolites without blocking formation of immature APP. The data establish a potential physiological role for iron in controlling the processing of APP.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence against a role for the Kunitz domain in amyloidogenic and secretory processing of the amyloid precursor protein

The effect of the Kunitz proteinase inhibitor (KPI) on potential beta-amyloid precursor protein (beta PP)-processing activities from control and Alzheimer's disease (AD) brains was examined using fluorogenic substrates designed to mimic the secretory and amyloidogenic cleavages in beta PP. In addition, the level of secretion of KPI-containing beta PP751 and KPI-lacking beta PP695 from transfected cells was examined to assess the effect of the KPI on beta PP secretion. beta PP751 and beta PP695, obtained from conditioned media of transfected cells, had no effect on proteinase activities against the secretory and amyloidogenic substrates in extracts from control and AD brains. At similar concentrations beta PP751, but not beta PP695, completely inhibited the activity of trypsin against these substrates. Serine proteinase inhibitors had only modest effects on activities from brain, whereas cysteine modification completely inhibited them, indicating that these proteinase activities were not of the serine type. Thus, the results do not support a role for the KPI in the secretion of beta PP or in the amyloidogenic cleavage of beta PP. The amounts of beta PP695 and beta PP751 collected from the media of transfected cells after 48 h of growth were similar, indicating an equal rate of secretion. This result suggests that the KPI domain in beta PP751 did not inhibit the secretory cleavage in transfected cells.

Beta/A4-evoked degeneration of differentiated SH-SY5Y human neuroblastoma cells

beta/A4 peptides are known to induce neurodegeneration in cultures of rat brain cells and rat neural cell lines (Yankner et al: Science 250:279-282, 1990; Behl et al: Biochem Biophys Res Commun 186:944-950, 1992). The current data show that these peptides induce similar neurodegeneration in SH-SY5Y neuroblastoma cells, extending characterization of beta/A4 toxicity to a human nerve cell line. Human SH-SY5Y cells respond to aggregated beta/A4 with changes in cell shape, membrane blebbing, antigenic modification, loss of attachment to the substrate, and cell death. beta/A4 peptides require aggregation for maximum toxic effects, as cellular degeneration is evoked by aggregated beta/A4 1-42 and 4-41 cysteine but not by monomeric beta/A4 1-40. Aged (pre-aggregated) beta/A4 1-40 also evoked neurodegeneration. Antigenic changes comprise upregulation of Alzheimer's-type tau epitopes, recognized by the PHF-1 and Alz-50 monoclonals. These particular changes in tau support the connectivity between this in vitro model and mechanisms leading to neurodegeneration in Alzheimer's disease. A significant feature of the SH-SY5Y response is that cells must be differentiated before they become sensitive to the degeneration evoked by beta/A4. Signaling pathways leading to beta/A4-evoked neurodegeneration thus are under experimental control, becoming complete only when proliferating cells withdraw from the cell cycle and develop a postmitotic phenotype.