Background
The severity of neurodegeneration in Alzheimer’s disease (AD) correlates with the soluble amyloid beta (Aβ) level in the brain [
1]. Aβ binds selectively and with high affinity to neuronal α7 nicotinic acetylcholine receptors (α7nAChRs), leading to intraneuronal Aβ
42 accumulation, tau phosphorylation, and cholinergic dysfunction [
2‐
5]. Therefore, chronic perturbation of the α7nAChRs by Aβ may contribute to neuronal dysfunctions and neurodegeneration leading to the formation of Aβ-rich plaque and neurofibrillary pathologies, which may be reduced by treatments that disrupt the Aβ
42-α7nAChR interaction. This hypothesis is supported by data showing that S 24795, an α7nAChR partial agonist, blocks the Aβ
42-α7nAChR interaction, Aβ
42 internalization into neuronal cells, and Aβ
42-induced tau phosphorylation [
4,
5]. The critical role of α7nAChR in the Aβ-driven AD pathogenesis and cognitive deficits is further substantiated by the report showing that deletion of the α7nAChR gene reduces cognitive deficits and synaptic pathology in a mouse model of AD [
6]. Despite evidence of increased Aβ
42-α7nAChR complex levels in lymphocytes from AD subjects [
7], it remains ambiguous whether an increased Aβ
42-α7nAChR complex level in lymphocytes may be a reliable AD biomarker. It is also unknown whether an increase in Aβ
42-α7nAChR complexes is related to the apolipoprotein E (
APOE) genotype, especially the ε4 subclass that is regarded as a prominent genetic risk factor for AD [
8].
ApoE regulates lipid metabolism and cholesterol transport in the brain. Among three apoE isoforms, apoE4 is the least metabolically stable and is a recognized risk factor for developing both familial and late-onset sporadic AD by promoting various neuropathological effects [
9,
10]. Proteolytic fragments of apoE are elevated in AD brains [
11] and some synthetic apoE fragments are neurotoxic [
12,
13]. In a postmortem brain study, apoE4 was strongly correlated with vascular Aβ deposition and Aβ plaque density [
14]. Biochemical, cell biological, and transgenic animal studies have indicated that apoE4 can promote AD pathogenesis by altering Aβ deposition and clearance to increase intraneuronal Aβ accumulation and plaque formation [
15‐
19]. ApoE negatively affects the redox system [
20], signaling cascades and Ca
2+ homeostasis in neurons [
21,
22] as well as cytoskeletal structure and function [
23,
24], but it enhances tau phosphorylation and consequent formation of neurofibrillary tangles (NFTs) [
25‐
28]. However, the underlying mechanisms responsible for these apoE4-mediated deteriorating effects and the cause-effect relationships remain largely unclear.
More recently, apoE low-density lipoprotein (LDL) receptor binding domain-containing peptide fragments were shown to inhibit α7nAChRs by interacting directly with the receptors [
29‐
31]. α7nAChR ligands and Aβ
12–28, the α7nAChR binding domain of Aβ
42, all reduce the Aβ
42-α7nAChR association [
5,
32,
33], and Aβ
42 promotes tau phosphorylation via activating α7nAChRs [
3,
5,
7]. We therefore examined the effects of these apoE fragments, and more importantly the apoE subtypes, on the Aβ
42-α7nAChR interaction and on the consequent Aβ
42-induced, α7nAChR-dependent tau phosphorylation.
Since
APOE ε4 is a prominent late-onset AD risk factor, the Aβ
42-α7nAChR complexes in lymphocytes derived from patients enrolled in the CL2-NEURO-003 study (ROSAS cohort) [
34] with diverse
APOE genotypes who gave blood samples at two time-points at least 1 year apart were examined to determine whether Aβ
42-α7nAChR complexes in lymphocytes are correlated with
APOE genotype (
APOE ε4 specifically). Our results indicate that apoE4 increases the abundance of Aβ
42-α7nAChR complexes in the brain and lymphocytes. More importantly, we show that exogenous Aβ
42 increases Aβ
42-α7nAChR complex levels in lymphocytes of controls and subjects with mild cognitive impairment (MCI) to the heightened levels of AD lymphocytes. Hence, we explored whether the elevated Aβ
42-α7nAChR complex levels and the magnitude of reduction by exogenous Aβ
42 in promoting the Aβ
42-α7nAChR association (reflected by +Aβ
2/-Aβ
42 ratios) may be used as AD diagnostic biomarkers that depict the severity of AD pathologies.
Methods
Materials and chemicals
HISTOPAQUE-1077, Leupeptin, aprotinin, phenylmethylsulfonyl fluoride (PMSF), pepstatin A, soybean trypsin inhibitor, NaF, sodium vanadate, β-glycerophosphate, 2-mercaptoethanol, NMDA, glycine, Tween-20, and NP-40 were all purchased from Sigma. Aβ1–42 was obtained from Invitrogen. Biotinated Aβ1–42 and FITC-conjugated Aβ1–42 were obtained from Anaspec (San Jose, CA, USA). Anti-α7nAChR (SC-5544, SC-58607), CHRFAM7A (SC-133458), -actin (SC-7210) and -β-actin (SC-47778) were all purchased from Santa Cruz biotechnology. Anti-Aβ42 antibody (Ab5078P) was purchased from EMD Millipore. Reacti-Bind™ NeutrAvidin™ High binding capacity coated 96-well plates, covalently conjugated protein A/G-agarose beads, Pierce cell surface protein isolation kit, antigen elution buffer, and chemiluminescent reagents were purchased from Pierce Thermo Scientific. Recombinant human apoE2 (#350-12), apoE3 (#350-02), and apoE4 (#350-04) that produced in E. coli (>90% purity) were purchased from Peprotech. Aβ1–42 peptide (trifluoroacetic acid; TFA salt) was dissolved in 50 mM Tris, pH 9.0 containing 10% dimethyl sulfoxide (DMSO) and stored at –80 °C. Biotinated Aβ1–42 and fluorescein isothiocyanate (FITC)-conjugated Aβ1–42, both ammonium salts, were dissolved in 50 mM Tris, pH 8.0 containing 10% DMSO and stored at –80 °C. All test agents were made fresh according to the manufacturer’s recommendation. If DMSO was used as the solvent, the highest DMSO concentration in the incubation medium was 1%.
LDL receptor binding domain of apoE
Six apoE LDL receptor binding domain-containing peptide fragments that showed differential α7nAChRs inhibition [
29‐
31] were synthesized and dissolved in 10% DMSO containing 50 mM Tris HCl, pH 8.8. These peptides were amide-capped at the carboxyl terminus and acetylated at the amino terminus, except for apoE
133–140 which has a free amino terminus.
-
apoE133–149: LRVRLASHLRKLRKRLL apoE133–149 (K → L): LRVRLASHLRLLRLRLL
-
apoE141–148 scrambled: RLKKLRLR apoE133–140: LRVRLASH
-
apoE141–148: LRKLRKRL apoE141–148 (K → E): LRELRERL
Animals
Eight- to 10-week-old male Sprague-Dawley rats from Taconic (Germantown, NY, USA) were maintained on a 12-h light/dark cycle with food and water ad libitum. Rats were rapidly decapitated and brain frontal cortices (FCXs) were extracted on ice immediately.
All animal procedures comply with the National Institutes of Health Guide for Care Use of Laboratory Animals and were approved by the City College of New York Animal Care and Use Committee (IACUC), Protocol No. 836.1.
Clinical samples
AD and MCI patients as well as control subjects were selected from the population of the ROSAS cohort (CL2-NEURO-003 study, sponsored by SERVIER laboratories, performed at Alzheimer’s Disease Research and Clinical Center, Inserm U1027, Toulouse University Hospital, Toulouse, France). Human participants and their informed caregiver took part in the study on a voluntary basis, and they gave their written informed consent at selection. The ethics committee of Toulouse University Hospital approved the study protocol and all its amendments (registration number DGS 20060500).
Four hundred and eight (408) subjects aged 65 years and older were enrolled in the study, and they were divided into three groups and followed for 4 years: 110 normal controls (Mini-Mental State Examination (MMSE) ≥26, Clinical Dementia Rating (CDR) = 0); 100 patients with memory impairment without dementia (MCI; MMSE ≥24, CDR = 0.5, memory impairment (Rey Auditory Verbal Learning Test (RAVLT), but not Diagnostic and Statistical Manual of Mental Disorders, version IV (DSM IV) criteria for AD); and 196 patients with dementia of the Alzheimer’s type (AD; 12 ≤ MMSE ≤ 26, CDR ≥0.5, DSM IV criteria). Participants and their informed caregiver participated on a voluntary basis, and gave their written informed consent at inclusion. The ethics committee of Toulouse University Hospital approved the study protocol. For details, see de Mauleon et al. [
34].
Selection of APOE genotype subpopulations
We selected patients and their matched controls from four of the most represented APOE genotypes: APOE ε2/ε3, APOE ε3/ε3, APOE ε3/ε4, and APOE ε4/ε4. Within each of the four APOE genotypes selected, AD and MCI patients as well as controls must have at least two sets of plasma and blood ‘buffy coat’ samples taken 1 year apart (e.g., at visit M0 and M12 or M12 and M24 that are designated as visit 1 and visit 2). The potential study subjects were then selected and matched according to their age, gender, and level of education using a SAS® iterative algorithm. In each triad/pair selected, the absolute difference between the youngest and the oldest must not exceed 5 years.
A total of 86 subjects including 24 controls (11 females/13 males, 77.91 ± 0.86 years), 30 MCI (19 females/11 males, 77.53 ± 0.84 years), and 32 AD (18 females/14 males, 77.38 ± 0.80 years) patients, paired per age, level of education, and gender for the four most represented genotypes. The APOE ε2/ε3 group has 5 AD (3 females/2 males, 78.20 ± 2.62 years), 3 MCI (1 female/2 males, 81.67 ± 1.21 years), and 5 control (1 female/4 males, 78.40 ± 3.21 years) subjects. The ApoE3/E3 group has 10 AD (7 females/3 males, 79.00 ± 1.08 years), 10 MCI (6 females/4 males, 79.00 ± 1.08 years), and 10 control (7 females/3 males, 79.00 ± 1.08 years) subjects, the ApoE3/E4 group has 10 AD (5 females/5 males, 76.80 ± 1.37 years), 10 MCI (4 females/6 males, 77.00 ± 1.30 years), and 9 control (3 females/6 males, 76.44 ± 1.49 years) control subjects, and the ApoE4/E4 group has 10 AD (3 females/4 males, 75.29 ± 2.16 years) and 10 MCI (1 female/6 males, 74.43 ± 2.05 years) subjects.
Preparation of the synaptosomes
Rats were sedated by CO
2 inhalation and killed by decapitation. FCXs were immediately dissected, homogenized, and processed immediately after harvesting to obtain synaptosomes (P2 fraction), as described previously [
3] for neuropharmacological assessments. Synaptosomes were washed twice and suspended in 2 ml ice-cold oxygenated Krebs-Ringer (K-R), containing (in mM): 25 HEPES, pH 7.4, 118 NaCl, 4.8 KCl, 25 NaHCO
3, 1.3 CaCl
2, 1.2 MgSO
4, 1.2 KH
2PO
4, 10 glucose, 0.1 ascorbic acid, and a mixture of protease and protein phosphatase inhibitors (Roche Diagnostics) that had been aerated for 10 min with 95% O
2/5% CO
2. The protein concentration was determined using the Bradford method (Bio-Rad).
Preparation of the lymphocytes
Lymphocytes were prepared from blood ‘buffy coat’ samples using Histopaque 1077 (Sigma) according to the manufacturer’s instruction [
7]. Briefly, blood ‘buffy coat’ (approximately 250 μl) were layered onto 250 μl HISTOPAQUE-1077 at 25 °C. The entire contents were centrifuged at 400 × g for 30 min at 25 °C to obtain the lymphocyte-free plasma (top layer) and opaque interface containing lymphocytes. The lymphocytes were mixed with 1 ml of oxygenized K-R and then centrifuged at 250 × g for 10 min twice. The resultant lymphocyte pellet was resuspended in 250 μl oxygenized K-R and used as the tissue source for the assessment of the Aβ42-α7nAChR complex level. The protein contents of the lymphocyte suspension were estimated using the Bradford method (Bio-Rad).
Ex vivo Aβ42 treatment and determination of Aβ42-α7nAChR association
To test the effect of the ApoE subtype on the Aβ42-α7nAChR interaction, rat cortical synaptosomes (200 μg) were incubated either simultaneously at 37 °C with 0.1 μM Aβ
42 and 0.01–100 μM of apoE fragments, or with ApoE isoforms for 10 min and then 30 min following the addition of 0.1 μM Aβ
42. To assess the impact of ApoE in plasma from human subjects as a bioassay, 200 μg of rat cortical synaptosomes were incubated at 37 °C with K-R, 0.1 μM Aβ
42 or 0.1 μM Aβ
42 + 25 μl of plasma for 30 min. In a separate set of experiments, human lymphocytes (200 μg) were incubated at 37 °C with K-R or 0.1 μM Aβ
42 for 30 min (total incubation volume: 250 μl). The reaction was terminated by adding ice-cold Ca
2+-free K-R containing protease and protein phosphatase inhibitors and centrifuged. The obtained synaptosomes or lymphocytes were homogenized in 250 μl ice-cold immunoprecipitation buffer containing 25 mM HEPES, pH 7.5, 200 mM NaCl, 1 mM EDTA, 0.2% 2-mercaptoethanol, and protease and protein phosphatase inhibitors by sonication for 10 s on ice and solubilized by nonionic detergents: 0.5% NP-40/0.2% Na cholate/0.5% digitonin for 60 min (4 °C) with end-to-end rotation. The obtained lysate was cleared by centrifugation at 20,000 × g for 30 min (4 °C) and the resultant supernatant (0.25 ml) was diluted fourfold with 0.75 ml immunoprecipitation buffer. The Aβ
42-α7nAChR complexes were immunoprecipitated with immobilized anti-Aβ
42 antibodies on protein A-conjugated agarose beads. The resultant immunocomplexes were pelleted by centrifugation (4 °C), washed three times with ice-cold phosphate-buffered saline (PBS), pH 7.2, containing 0.1% NP-40, and centrifuged. The resultant immunocomplexes were solubilized by boiling for 5 min in 100 μl SDS-PAGE sample preparation buffer (62.5 mM Tris-HCl, pH 6.8; 10% glycerol, 2% SDS; 5% 2-mercaptoethanol, 0.1% bromophenol blue) and centrifuged to remove antibody-protein A/G agarose beads. The contents of α7nAChRs and actin were determined by Western blotting with the level of actin serving as the indicator of immunoprecipitation efficiency and gel loading [
4,
5,
7].
Determination of CHRFAM7A-α7nAChR association in membranes of lymphocytes
To assess the association of CHRFAMA7 and α7nAChR on the lymphocyte membranes, lymphocytes (200 μg) obtained from ROSAS cohort were ruptured by sonicated on ice in 250 μl hypotonic lysis buffer containing (in mM): 25 HEPES, pH 7.4, 11.8 NaCl, 0.48 KCl, 2.5 NaHCO3, 0.13 CaCl2, 0.12 MgSO4, 0.12 KH2PO4, and a mixture of protease and protein phosphatase inhibitors. Following centrifugation at 50,000 × g for 30 min at 4 °C, the resultant lymphocytic cell membranes were homogenized by sonication for 10 s on ice and solubilized by nonionic detergents: 0.5% NP-40/0.2% Na cholate/0.5% digitonin for 60 min (4 °C) with end-to-end rotation. The resultant lysate was cleared of debris by centrifugation at 20,000 × g for 30 min (4 °C) and the resultant supernatant (0.25 ml) was diluted fourfold with 0.75 ml immunoprecipitation buffer. The Aβ42-α7nAChR complexes were then immunoprecipitated with immobilized anti-CHRFAM7A on protein A-conjugated agarose beads. The resultant immunocomplexes were pelleted by centrifugation (4 °C), washed three times with ice-cold 0.1% NP-40 containing PBS, and centrifuged. The resultant immunocomplexes were solubilized by boiling for 5 min in 100 μl SDS-PAGE sample preparation buffer and then centrifuged to remove antibody-protein A agarose beads. The abundance of α7nAChRs in the anti-CHRFAM7A immunoprecipitate was determined by Western blotting with anti-α7nAChR (SC-58607). The blot was then stripped, blocked with 10% nonfat milk containing 0.1% PBST for 1 h and incubated with anti-CHRFAM7A overnight at 4 °C to validate equal efficiency of the immunoprecipitation and gel loading.
Western blot analysis
Solubilized immunoprecipitates size-fractionated by 10% or 10–16% SDS-PAGE was electrophoretically transferred to nitrocellulose membranes. The membranes were washed with PBS three times and blocked overnight (4 °C) with 10% milk in 0.1% Tween-20-containing PBS (PBST). The membranes were washed with 0.1% PBST three times, incubated at 25 °C for 2 h or at 4 °C overnight with 1:500–1:1000 dilutions of selected antibodies including (α7nAChR (SC-58607), β-actin (SC-47778), and CHRFAM7A (SC-133458). After three 0.1% PBST washes, membranes were incubated for 1 h with anti-species IgG-HRP (1:5000–7500 dilution) and washed three times with 0.1% PBST (2 min each). The signals were detected using a chemiluminescent method and visualized by exposure to X-ray film. Specific bands were quantified by densitometric scanning (GS-800 calibrated densitometer; Bio-Rad).
In vitro assessment of Aβ42-α7nAChR and Aβ42-Aβ42 interaction
The effect of apoE fragments and ApoE isoform on Aβ42-α7nAChR interaction was measured in vitro with 2 nM biotinated α7nAChRs trapped on streptavidin-coated plate (Reacti-Bind™ NeutrAvidin™ High binding capacity coated 96-well plate; Pierce). Biotinylation of the cell surface proteins was performed using the Pierce cell surface protein isolation kit according to the manufacturer’s protocol. Briefly, T75 cm2 flasks of 95% confluent SK-N-MC cells were quickly washed with ice-cold PBS. Biotinylation of the cell surface proteins was performed using sulfo-NHS-SS-Biotin. Following termination of the reaction, cells were scraped into PBS and collected by centrifugation. The cells were then lyzed by brief sonication and centrifuged to obtain cell membranes. The resultant cell membranes were solubilized using 0.5% NP-40/0.2% sodium cholate/0.5% digitonin. The biotinylated α7nAChRs were isolated by immunoaffinity column with immobilized anti-α7nAChR antibodies. The plate was washed, blocked with 20% superblock (Pierce-Thermo), and incubated with K-R or 0.01–100 μM apoE fragments for 10 min followed by 60 min with 20 nM FITC-tagged Aβ42 at 30 °C. The plate was washed extensively and the residual FITC-Aβ42 signals were determined by multimode plate reader (DTX880; Beckman).
The effect of apoE fragments on Aβ42-α7nAChR interaction was measured in vitro with 2 nM biotinated Aβ42 trapped on streptavidin-coated 96-well plate, washed, and incubated with 0.01–100 μM of apoE fragments for 10 min prior to incubation with 20 nM FITC-tagged Aβ42 for 60 min at 30 °C. The plate was then washed five times with 50 mM Tris HCl, pH 7.5. The FITC-Aβ42 signals were detected using a multi-mode plate reader (DTX-880). Negligible FITC-Aβ42 was noted when either biotinated Aβ42 peptides or α7nAChRs were omitted.
Ex vivo determination of Aβ42-induced tau phosphorylation
The effect of apoE fragments on Aβ
42-induced tau phosphorylation was examined using experimental procedure described previously [
3,
5,
7]. Briefly, well-washed rat FCX synaptosomes (500 μg) were incubated in oxygenated K-R with 0.01–100 μM apoE fragment and/or 0.1 μM Aβ
42 at 37 °C for 30 min. The total tau proteins were immunoprecipitated with anti-tau and the phosphorylated serine
202-tau (pS
202tau), threonine
231-tau (pT
231tau), and threonine
181-tau (pT
181tau) contents were determined by Western blotting (Pierce-Thermo).
Statistical analyses
All data are presented as mean ± standard error from the mean (SEM). Treatment effects were evaluated by analysis of variance (ANOVA). Specifically, the apoE fragment and subtype effects of the Aβ42-α7nAChR association and tau phosphorylation in animal experiments were evaluated using one-way ANOVAs followed by Newman-Keul’s for multiple comparisons.
To analyze the biochemical data in the human studies, a mixed linear model was used (with pairing identifier as a random effect) in order to test paired differences among the three diagnostic groups as well as among the four ApoE genotypes. P values were corrected for multiple testing using the Dunnett’s approach. The threshold for significance was p < 0.05.
Correlations between criteria were evaluated using the Spearman correlation coefficient (with 95% confidence interval). SAS 9.2 and R 3.1.2 software were used to perform these analyses.
Discussion
The present study shows that apoE4 interacts with α7nAChRs via the apoE LDL receptor binding domain, apoE
141–148, to increase Aβ
42-α7nAChR association and Aβ
42-elicited, α7nAChR-dependent tau phosphorylation. Plasma from
APOE ε4 carriers increased Aβ
42-α7nAChR complex levels in rat synaptosomes. The relevance of these in vitro and ex vivo results to AD pathogenesis is supported by higher abundance of Aβ
42-α7-like nAChR complexes in AD and MCI lymphocytes, correlating with the
APOE ε4 genotype in hetero- and homozygous
APOE ε4 carriers. Underscoring the more rapid cognitive decline in
APOE ε4 carriers, we present a novel mechanism through which apoE4 may facilitate the Aβ
42-driven AD pathogenesis in both brain and peripheral cells. Conspicuously, plasma from all AD subjects (independent of
APOE ε4 status) has a greater effect on promoting the Aβ
42-α7nAChR association, and lymphocytes of AD subjects have more abundant Aβ
42-α7-like nAChR complexes. These findings suggest that other factor(s) in addition to
APOE ε4 may be present in AD. Neurotoxic apoE proteolytic products can be formed by neurons in
APOE ε4 transgenic mice and in the brains and cerebrospinal fluid from AD patients, with the highest level found in
APOE ε4 carriers [
11,
27,
36‐
38]. Some synthetic apoE fragments are neurotoxic [
12,
13]. Since the neurotoxic apoE fragments retain the LDL binding domain [
36,
39], the increased Aβ
42-α7nAChR interaction in AD may result from higher apoE toxic fragments that presumably increase with duration of disease, although their presence in the plasma of AD subjects is currently not known.
APOE ε4 accelerates the onset of both familial and late-onset sporadic AD with greater deleterious cognition effects and neurodegeneration in women than in men [
40‐
45].
APOE ε4 is associated with worse clinical outcome in traumatic brain injury [
46], multiple sclerosis [
47], Parkinson’s disease [
48], frontotemporal dementia [
49], and stroke [
50]. ApoE fragments increase NFT-like intraneuronal inclusions in cultured neurons [
27]. Peptide fragments derived from the apoE LDL receptor binding domain interact with, and inhibit, α7nAChR [
29‐
31]. However, these data do not directly support the known apoE4 role in promoting AD pathogenesis, even though α7nAChR is a receptor for Aβ and contributes to Aβ
42-mediated AD pathologies [
4‐
7,
32,
33]. Our data showing that apoE4 promotes the Aβ
42-α7nAChR association provides an essential link to AD pathogenesis. This hypothesis is supported by the AD-like neurodegeneration and behavioral deficits in transgenic mice expressing carboxyl-terminal truncated apoE4 [
36]. Although the apoE LDL receptor binding domain is common to all apoE subtypes, recombinant human apoE4 preferentially increases the Aβ
42-α7nAChR association. This finding suggests that the conformation of apoE4, but not apoE3 or apoE2, exposes the apoE LDL receptor binding domain to α7nAChRs since the amino acid sequences of apoE subtypes are almost virtually identical. This hypothesis is supported by an earlier report that suggests that apoE4 is structurally different from apoE3 based on differences in hydrogen-deuterium exchange and site-directed mutations [
51].
ApoE appears to regulate Aβ aggregation and deposition. Deletion of the
APOE gene dramatically reduces fibrillar Aβ deposits in an AD transgenic mouse model [
52] as well as apoE immunoreactivity in amyloid plaques in human AD brains [
53]. By increasing the Aβ
42-α7nAChR association, apoE4 can promote internalization of the Aβ
42-α7nAChR complexes to facilitate formation of intraneuronal Aβ aggregates and amyloid plaques [
2]. The elevated intraneuronal Aβ oligomers can impair intraneuronal mitochondria and lysosomes to drive neurodegeneration [
18]. In agreement, Aβ-rich amyloid plaques are more abundant and commonly found in
APOE ε4 carriers and AD patients with positive amyloid scans [
14,
54‐
56]. Increased Aβ
42-α7nAChR interaction by apoE4 suggests that amyloid plaques may form early and more readily in
APOE ε4 carriers [
57,
58]. Indeed, fibrillar Aβ deposits, the hallmark of AD and revealed by florbetapir (PiB) imaging, are more abundant and detected earlier in AD and even in cognitively normal
APOE ε4 carriers versus noncarriers [
57,
59]. Cognitively normal
APOE ε4 carriers with positive amyloid imaging decline cognitively much earlier than noncarriers [
59]. Compared to
APOE ε4,
APOE ε2 appears to associate with cognitive intactness in >90-year-old individuals even though
APOE ε2 is also linked to higher amyloid plaque loads [
60]. This reported
APOE ε2 association with amyloid plaque levels is, however, not supported by our finding that recombinant human apoE2 minimally alters Aβ
42-α7nAChR interaction (Fig.
4).
APOE ε4 is also linked to the magnitude of neurofibrillary lesions. Although apoE is primarily produced by astrocytes and microglia in healthy states, stress or injury induce neuronal apoE expression and produce neurotoxic apoE4 fragments to increase tau hyperphosphorylation, cytoskeletal disruption, and mitochondrial dysfunction, and eventual neurodegeneration [
9,
37,
61,
62]. The notion that
APOE ε4 confers vulnerability to stress and injuries is supported by data demonstrating that neurons in
APOE ε4 carriers with temporal lobe epilepsy are more susceptible to seizure damage and to Aβ toxicities than those harboring
APOE ε3. [
63]. Despite all these linkages, the mechanism responsible for apoE4-induced tau hyperphosphorylation remains unclear. Our earlier reports showed that either incubation of synaptosomes with Aβ
42 or intraventriculary administered Aβ
42 induced robust tau phosphorylation at three proline-directed serine/threonine sites that are found in NFTs [
3,
5,
7]. The parallel reductions in Aβ
42 aggregates and NFT formation by disrupting the Aβ
42-α7nAChR interaction supports the theory that the Aβ
42-α7nAChR association is critical to Aβ
42-induced tau phosphorylation, and that NFTs are related to Aβ
42 internalization, deposition, and plaque formation [
4,
5,
7]. As illustrated here, apoE4 can promote the Aβ
42-α7nAChR interaction via apoE
141–148 to exacerbate Aβ
42-induced tau hyperphosphorylation that presumably leads to more extensive neurofibrillary lesions. The dose-dependency in the apoE
141–148 enhancement of Aβ
42-induced tau phosphorylation suggests that concentrations of apoE
141–148 are near saturation or that the Aβ
42 effect is near its maximum. The differential effects of astrocyte-derived versus neuron-derived apoE4 on excitotoxic damage (the former protecting against and the latter enhancing) indicate that very different apoE proteolytic pathways exist in these two cell types [
64].
The α7nAChRs in lymphocytes regulate the development and activation of these cells [
65‐
67]. However, the α7nAChR expression in lymphocytes from AD subjects either increased [
68] or did not change [
69] compared to their neurologically normal peers. Similarly, we did not find
APOE genotype- or AD-related changes in α7nAChR-like protein levels in lymphocytes (Fig.
8). These studies suggest that changes in α7nAChR and CHRFAM7A expression are likely unrelated to the increased pathogenic Aβ
42-α7-like nAChR interaction in lymphocytes from AD subjects. The fact that markedly elevated Aβ
42-α7nAChR complexes in the brain parallels the increased Aβ
42-α7-like nAChR association in lymphocytes of AD patients suggests that this association in lymphocytes could potentially serve as a noninvasive, blood-based AD diagnostic biomarker [
4,
7]. A heightened Aβ
42-α7-like nAChR interaction in lymphocytes is also observed in this cohort of AD subjects. The magnitude of the increase in the Aβ
42-α7-like nAChR association in lymphocytes is significantly greater in
APOE ε4 carriers than with other
APOE genotypes, even in AD cases. ApoE4 and perhaps neurotoxic apoE(4) fragments originating from neurons likely intensify the Aβ
42-α7nAChR interaction to promote Aβ
42-mediated AD pathogenesis. Aβ
42-α7nAChR complex levels correlate with the rate of cognitive decline in the
APOE ε4 carriers (Fig.
6c), and our current data suggest that enhancing the Aβ
42-α7nAChR interaction may contribute to apoE4-induced AD pathologies. Hence, the Aβ
42-α7-like nAChR complex level in lymphocytes may serve as a peripheral AD biomarker to indicate the presence of more extensive AD pathologies. Unlike the recent report using a plasma lipid profile to identify an early AD degenerative trait [
70], blood samples in this study were only obtained from two time points. Future experiments with different timeframes, particularly including presymptomatic time points, are needed to assess the utility of Aβ
42-α7nAChR complex levels in lymphocytes as a biomarker for AD dementia.
In addition to α7nAChRs, expression of the α7nAChR chimeric gene, CHRFAM7A, was also found in the lymphocytes of humans [
35]. CHRFAM7A functions as a dominant-negative modulator of α7nAChRs in a coexpression study [
35] and retains the binding site for Aβ [
5,
32], although it is unclear whether Aβ binds to CHRFAM7A with similarly high affinity as for the α7nAChRs. Our data show that the expression levels of α7nAChRs and CHRFAM7A in lymphocytes are similar in three diagnostic groups regardless of
APOE genotype. Further, we found CHRFAM7A forms complexes with α7nAChR in vivo in the membranes of lymphocytes, although the levels of α7nAchR/CHRFAM7A complexes are comparable in different
APOE genotypes and diagnostic groups. Importantly, the increased Aβ
42 association with α7nAChRs and/or CHRFAM7As in lymphocytes from AD subjects agrees with previous findings in postmortem human brains and in human lymphocytes [
4,
7,
32].
The immune system interacts with the brain bidirectionally through common receptors and ligands, such as interleukin-1β and other proinflammatory cytokines [
71,
72]. We showed that the induction of plasticity-related phenomena in the brain similarly affects lymphocyte function [
73]. Moreover, lymphocytes from senescent mice transferred to young mice decreased the learning abilities of these mice to the level of senescent mice and produced senescence-like serum-brain reactivity [
74]. As in postmortem brains, lymphocytes derived from AD patients and ex vivo incubation of lymphocytes from normal controls with Aβ
42 showed substantially higher α7nAChR-TLR4-filamin A complexes [
7]. Our finding that Aβ
42-α7-like nAChR complexes in lymphocytes correlate with effects on the synaptic Aβ
42-α7nAChR interaction by plasma from
APOE ε4 carriers and AD patients suggests similar apoE4 influences in the brain and the periphery. We therefore believe that the Aβ
42-α7-like nAChR complex level in lymphocytes may be used as an antecedent biomarker to gauge AD neuropathogenic progression during the prodromal phase of the disease given that pathological changes occur considerably earlier than cognitive impairments. This novel potential biomarker holds a higher pathogenic rationale than many other blood-based biomarkers such as lipid profiling [
70] and autoantibody panels [
75]. Neuroinflammation is intimately involved in AD, and certain systemic leukocytes are relatively long lived; it is then possible these immune cells detect neuronal pathological changes and respond by altering molecules within themselves such as T-cell activation markers or their phenotypes [
76]. Together with our current finding of AD-related changes in lymphocytes, these data suggest that, during AD progression, brain pathologies may lead to systematic and long-term immunological changes in lymphocytes and other blood cells. Changes induced by apoE4 in peripheral immune cells such as increased Aβ
42-α7nAChR interaction may be potential AD biomarkers.
Finally, apoE is required for deposition of Aβ fibrils in amyloid mouse models [
52]. Genetic knockdown of human apoE reduces amyloid plaque loads in transgenic AD mouse models, regardless of apoE isoform [
77]. Interestingly, Aβ
12–28, which prevents the Aβ
42-α7nAChR interaction [
4,
32], also blocks apoE-driven Aβ deposition and ameliorates memory deficits in AD transgenic mouse models with elevated amyloid [
78]. Agents that reduce Aβ
42-α7nAChR complex levels decrease Aβ
42 aggregates, hyperphosphorylated tau (NFTs), and synaptic pathology in AD mouse models [
5‐
7,
79]. Because apoE(4) promotes the Aβ
42-α7nAChR interaction, blocking this interaction may prevent apoE4 and its toxic fragments from promoting Aβ-mediated, α7nAChR-dependent AD pathogenesis in
APOE ε4 carriers.
A few limitations warrant caution in drawing conclusions from this study. First, because clinical diagnosis is based mainly on cognitive symptoms, the precise brain AD pathologies are not known. Second, despite well-matched pairs, the number of cases in this study is small, especially in the APOE ε2/ε3 cohort. Third, the apoE peptides were used primarily to illustrate the phenomenon rather than to provide quantitative measurements. Last, although the increased Aβ42-α7nAChR complex levels correlate with progression of cognitive decline in AD, whether the Aβ42-α7nAChR association enhancement by apoE accelerates AD pathology is ambiguous. Further research is needed to fully elucidate the contribution of the apoE4-induced increase in the Aβ42-α7nAChR interaction to AD pathogenesis.