Junichi Shioi

A presenilin-1/γ-secretase cleavage releases the E-cadherin intracellular domain and regulates disassembly of adherens junctions

E‐cadherin controls a wide array of cellular behaviors including cell–cell adhesion, differentiation and tissue development. Here we show that presenilin‐1 (PS1), a protein involved in Alzheimers disease, controls a γ‐secretase‐like cleavage of E‐cadherin. This cleavage is stimulated by apoptosis or calcium influx and occurs between human E‐cadherin residues Leu731 and Arg732 at the membrane–cytoplasm interface. The PS1/γ‐secretase system cleaves both the full‐length E‐cadherin and a transmembrane C‐terminal fragment, derived from a metalloproteinase cleavage after the E‐cadherin ectodomain residue Pro700. The PS1/γ‐secretase cleavage dissociates E‐cadherins, β‐catenin and α‐catenin from the cytoskeleton, thus promoting disassembly of the E‐cadherin–catenin adhesion complex. Furthermore, this cleavage releases the cytoplasmic E‐cadherin to the cytosol and increases the levels of soluble β‐ and α‐catenins. Thus, the PS1/γ‐secretase system stimulates disassembly of the E‐cadherin– catenin complex and increases the cytosolic pool of β‐catenin, a key regulator of the Wnt signaling pathway.

A CBP Binding Transcriptional Repressor Produced by the PS1/ϵ-Cleavage of N-Cadherin Is Inhibited by PS1 FAD Mutations

Presenilin1 (PS1), a protein implicated in Alzheimers disease (AD), forms complexes with N-cadherin, a transmembrane protein with important neuronal and synaptic functions. Here, we show that a PS1-dependent gamma-secretase protease activity promotes an epsilon-like cleavage of N-cadherin to produce its intracellular domain peptide, N-Cad/CTF2. NMDA receptor agonists stimulate N-Cad/CTF2 production suggesting that this receptor regulates the epsilon-cleavage of N-cadherin. N-Cad/CTF2 binds the transcription factor CBP and promotes its proteasomal degradation, inhibiting CRE-dependent transactivation. Thus, the PS1-dependent epsilon-cleavage product N-Cad/CTF2 functions as a potent repressor of CBP/CREB-mediated transcription. Importantly, PS1 mutations associated with familial AD (FAD) and a gamma-secretase dominant-negative mutation inhibit N-Cad/CTF2 production and upregulate CREB-mediated transcription indicating that FAD mutations cause a gain of transcriptional function by inhibiting production of transcriptional repressor N-Cad/CTF2. These data raise the possibility that FAD mutation-induced transcriptional abnormalities maybe causally related to the dementia associated with FAD.

PS1 activates PI3K thus inhibiting GSK‐3 activity and tau overphosphorylation: effects of FAD mutations

Phosphatidylinositol 3‐kinase (PI3K) promotes cell survival and communication by activating its downstream effector Akt kinase. Here we show that PS1, a protein involved in familial Alzheimers disease (FAD), promotes cell survival by activating the PI3K/Akt cell survival signaling. This function of PS1 is unaffected by γ‐secretase inhibitors. Pharmacological and genetic evidence indicates that PS1 acts upstream of Akt, at or before PI3K kinase. PS1 forms complexes with the p85 subunit of PI3K and promotes cadherin/PI3K association. Furthermore, conditions that inhibit this association prevent the PS1‐induced PI3K/Akt activation, indicating that PS1 stimulates PI3K/Akt signaling by promoting cadherin/PI3K association. By activating PI3K/Akt signaling, PS1 promotes phosphorylation/inactivation of glycogen synthase kinase‐3 (GSK‐3), suppresses GSK‐3‐dependent phosphorylation of tau at residues overphosphorylated in AD and prevents apoptosis of confluent cells. PS1 FAD mutations inhibit the PS1‐dependent PI3K/Akt activation, thus promoting GSK‐3 activity and tau overphosphorylation at AD‐related residues. Our data raise the possibility that PS1 may prevent development of AD pathology by activating the PI3K/Akt signaling pathway. In contrast, FAD mutations may promote AD pathology by inhibiting this pathway.

Presenilin-1 forms complexes with the cadherin/catenin cell-cell adhesion system and is recruited to intercellular and synaptic contacts.

In MDCK cells, presenilin-1 (PS1) accumulates at intercellular contacts where it colocalizes with components of the cadherin-based adherens junctions. PS1 fragments form complexes with E-cadherin, beta-catenin, and alpha-catenin, all components of adherens junctions. In confluent MDCK cells, PS1 forms complexes with cell surface E-cadherin; disruption of Ca(2+)-dependent cell-cell contacts reduces surface PS1 and the levels of PS1-E-cadherin complexes. PS1 overexpression in human kidney cells enhances cell-cell adhesion. Together, these data show that PS1 incorporates into the cadherin/catenin adhesion system and regulates cell-cell adhesion. PS1 concentrates at intercellular contacts in epithelial tissue; in brain, it forms complexes with both E- and N-cadherin and concentrates at synaptic adhesions. That PS1 is a constituent of the cadherin/catenin complex makes that complex a potential target for PS1 FAD mutations.

Presenilin-1 binds cytoplasmic epithelial cadherin, inhibits cadherin/p120 association, and regulates stability and function of the cadherin/catenin adhesion complex

Here we show that presenilin-1 (PS1), a protein involved in Alzheimers disease, binds directly to epithelial cadherin (E-cadherin). This binding is mediated by the large cytoplasmic loop of PS1 and requires the membrane-proximal cytoplasmic sequence 604–615 of mature E-cadherin. This sequence is also required for E-cadherin binding of protein p120, a known regulator of cadherin-mediated cell adhesion. Using wild-type and PS1 knockout cells, we found that increasing PS1 levels suppresses p120/E-cadherin binding, and increasing p120 levels suppresses PS1/E-cadherin binding. Thus PS1 and p120 bind to and mutually compete for cellular E-cadherin. Furthermore, PS1 stimulates E-cadherin binding to β- and γ-catenin, promotes cytoskeletal association of the cadherin/catenin complexes, and increases Ca2+-dependent cell–cell aggregation. Remarkably, PS1 familial Alzheimer disease mutant ΔE9 increased neither the levels of cadherin/catenin complexes nor cell aggregation, suggesting that this familial Alzheimer disease mutation interferes with cadherin-based cell–cell adhesion. These data identify PS1 as an E-cadherin-binding protein and a regulator of E-cadherin function in vivo.

Ligand binding and calcium influx induce distinct ectodomain/γ-secretase processing pathways of EPHB2 receptor

Binding of EphB receptors to ephrinB ligands on the surface of adjacent cells initiates signaling cascades that regulate angiogenesis, axonal guidance, and neuronal plasticity. These functions require processing of EphB receptors and removal of EphB-ephrinB complexes from the cell surface, but the mechanisms involved are poorly understood. Here we show that the ectodomain of EphB2 receptor is released to extracellular space following cleavage after EphB2 residue 543. The remaining membrane-associated fragment is cleaved by the presenilin-dependent γ-secretase activity after EphB2 residue 569 releasing an intracellular peptide that contains the cytoplasmic domain of EphB2. This cleavage is inhibited by presenilin 1 familial Alzheimer disease mutations. Processing of EphB2 receptor depends on specific treatments: ephrinB ligand-induced processing requires endocytosis, and the ectodomain cleavage is sensitive to peptide inhibitor N-benzyloxycarbonyl-Val-Leu-leucinal but insensitive to metalloproteinase inhibitor GM6001. The ligand-induced processing takes place in endosomes and involves the rapid degradation of the extracellular EphB2. EphrinB ligand stimulates ubiquitination of EphB2 receptor. Calcium influx- and N-methyl-d-aspartic acid-induced processing of EphB2 is inhibited by GM6001 and ADAM10 inhibitors but not by N-benzyloxycarbonyl-Val-Leu-leucinal. This processing requires no endocytosis and promotes rapid shedding of extracellular EphB2, indicating that it takes place at the plasma membrane. Our data identify novel cleavages and modifications of EphB2 receptor and indicate that specific conditions determine the proteolytic systems and subcellular sites involved in the processing of this receptor.

Overexpression in Neurons of Human Presenilin-1 or a Presenilin-1 Familial Alzheimer Disease Mutant Does Not Enhance Apoptosis

Programmed cell death, or apoptosis, has been implicated in Alzheimer’s disease (AD). DNA damage was assessed in primary cortical neurons infected with herpes simplex virus (HSV) vectors expressing the familial Alzheimer’s disease (FAD) gene presenilin-1 (PS-1) or an FAD mutant of this gene, A246E. After infection, immunoreactivity for PS-1 was shown to be enhanced in infected cells. The infected cells exhibited no cytotoxicity, as evaluated by trypan blue exclusion and mitochondrial function assays. Quantitative analysis of cells that were immunohistochemically labeled using a Klenow DNA fragmentation assay or the TUNEL method revealed no enhancement of apoptosis in PS-1-infected cells. This result was confirmed using assays for chromatin condensation and for DNA fragmentation. Expression of PS-1 protected against induction of apoptosis in the cortical neurons by etoposide or staurosporine. The specificity of this phenotype was demonstrated by the fact that cortical cultures infected with recombinant HSV vectors expressing the amyloid precursor protein (APP-695) showed, in contrast, a significant increase in the number of apoptotic cells and an increase in DNA fragmentation for all parameters tested. Our results indicate that overexpression of wild-type or A246E mutant PS-1 does not enhance apoptosis in postmitotic cortical cells and suggest that the previously reported enhancement of apoptosis by presenilins may be dependent on cell type.

Cyclooxygenase (COX)-2 and COX-1 potentiate β-amyloid peptide generation through mechanisms that involve γ-secretase activity

In previous studies we found that overexpression of the inducible form of cyclooxygenase, COX-2, in the brain exacerbated β-amyloid (Aβ) neuropathology in a transgenic mouse model of Alzheimers disease. To explore the mechanism through which COX may influence Aβ amyloidosis, we used an adenoviral gene transfer system to study the effects of human (h)COX-1 and hCOX-2 isoform expression on Aβ peptide generation. We found that expression of hCOXs in human amyloid precursor protein (APP)-overexpressing (Chinese hamster ovary (CHO)-APPswe) cells or human neuroglioma (H4-APP751) cells resulting in 10-25 nm prostaglandin (PG)-E2 concentration in the conditioned medium coincided with an ∼1.8-fold elevation of Aβ-(1-40) and Aβ-(1-42) peptide generation and an ∼1.8-fold induction of the C-terminal fragment (CTF)-γ cleavage product of the APP, an index of γ-secretase activity. Treatment of APP-overexpressing cells with the non-selective COX inhibitor ibuprofen (1 μm, 48 h) or with the specific γ-secretase inhibitor L-685,458 significantly attenuated hCOX-1- and hCOX-2-mediated induction of Aβ peptide generation and CTF-γ cleavage product formation. Based on this evidence, we next tested the hypothesis that COX expression might promote Aβ peptide generation via a PG-E2-mediated mechanism. We found that exposure of CHO-APPswe or human embryonic kidney (HEK-APPswe) cells to PG-E2 (11-deoxy-PG-E2) at a concentration (10 nm) within the range of PG-E2 found in hCOX-expressing cells similarly promoted (∼1.8-fold) the generation of the CTF-γ cleavage product of APP and commensurate Aβ-(1-40) and Aβ-(1-42) peptide elevation. The study suggests that expression of COXs may influence Aβ peptide generation through mechanisms that involve PG-E2-mediated potentiation of γ-secretase activity, further supporting a role for COX-2 and COX-1 in Alzheimers disease neuropathology.

Extracellular progranulin protects cortical neurons from toxic insults by activating survival signaling.

To reduce damage from toxic insults such as glutamate excitotoxicity and oxidative stresses, neurons may deploy an array of neuroprotective mechanisms. Recent reports show that progranulin (PGRN) gene null or missense mutations leading to inactive protein, are linked to frontotemporal lobar degeneration (FTLD), suggesting that survival of certain neuronal populations needs full expression of functional PGRN. Here we show that extracellular PGRN stimulates phosphorylation/activation of the neuronal MEK/extracellular regulated kinase (ERK)/p90 ribosomal S6 kinase (p90RSK) and phosphatidylinositol-3 kinase (PI3K)/Akt cell survival pathways and rescues cortical neurons from cell death induced by glutamate or oxidative stress. Pharmacological inhibition of MEK/ERK/p90RSK signaling blocks the PGRN-induced phosphorylation and neuroprotection against glutamate toxicity while inhibition of either MEK/ERK/p90RSK or PI3K/Akt blocks PGRN protection against neurotoxin MPP(+). Inhibition of both pathways had synergistic effects on PGRN-dependent neuroprotection against MPP(+) toxicity suggesting both pathways contribute to the neuroprotective activities of PGRN. Extracellular PGRN is remarkably stable in neuronal cultures indicating neuroprotective activities are associated with full-length protein. Together, our data show that extracellular PGRN acts as a neuroprotective factor and support the hypothesis that in FTLD reduction of functional brain PGRN results in reduced survival signaling and decreased neuronal protection against excitotoxicity and oxidative stress leading to accelerated neuronal cell death. That extracellular PGRN has neuroprotective functions against toxic insults suggests that in vitro preparations of this protein may be used therapeutically.

FAD mutants unable to increase neurotoxic Aβ 42 suggest that mutation effects on neurodegeneration may be independent of effects on Aβ

Strong support for a primary causative role of the Aβ peptides in the development of Alzheimer’s disease (AD) neurodegeneration derives from reports that presenilin familial AD (FAD) mutants alter amyloid precursor protein processing, thus increasing production of neurotoxic Aβ 1–42 (Aβ 42). This effect of FAD mutants is also reflected in an increased ratio of peptides Aβ 42 over Aβ 1–40 (Aβ 40). In the present study, we show that several presenilin 1 FAD mutants failed to increase production of Aβ 42 or the Aβ 42/40 ratio. Our data suggest that the mechanism by which FAD mutations promote neurodegeneration and AD may be independent of their effects on Aβ production.