The neuroprotective N-terminal amyloid-β core hexapeptide reverses reactive gliosis and gliotoxicity in Alzheimer’s disease pathology models

The number of reactive astrocytes did not significantly change with age in slices from the B6SJL mouse line (Fig. 1A, C, E; Additional file 1: Appendix, Fig. S1A, B), nor was there any effect with 1 μM N-Aβcore treatment. These data indicate a stable astrocyte phenotypic morphology out to 7 months of age in B6SJL mice. Similarly, no significant alteration in microglial morphology was observed in aged B6SJL slice cultures (Fig. 1B, D, F), though there was an increase in the number of Iba1^High/CD68^High expressing microglia in slice cultures from 7-month-old compared to 1.5-month-old mice (Additional file 1: Appendix, Fig. S1C, D). Unlike the B6SJL slice cultures, a dramatic increase in astrogliosis and microgliosis was observed in media only treated (Control) aged 5xFAD slice cultures (Fig. 1; Additional file 1: Appendix, Fig S1), which was partially rescued by daily treatment for 7 days with 1 μM N-Aβcore. N-Aβcore treatment did mitigate the increase in astrocyte and microglial cell and soma area, respectively (Fig. 1C, D), and the decrease in astrocytic and microglial process number (Fig. 1E, F) in slice cultures from the 7-month-old mice. Moreover, treatment with N-Aβcore substantially reduced the number of GFAP^High expressing cortical astrocytes in aged 5xFAD slices (Fig. 1A; Additional file 1: Appendix, Fig S1A). However, N-Aβcore treatment did not significantly affect the number of hippocampal GFAP^High expressing astrocytes (Additional file 1: Appendix, Fig. S1B) nor cortical or hippocampal Iba1^High CD68^High expressing microglia in 7-month-old 5xFAD slices (Fig. 1B; Additional file 1: Appendix, Fig. S1C, D), perhaps due to the relatively short treatment timeframe. In contrast, the neuronal population, notably reduced in aged 5xFAD [37], was increased in the cortical and hippocampal regions of 5xFAD slice cultures on treatment with the N-Aβcore (Additional file 1: Fig. S2), indicating reversal of this deficit. Together, these data suggest that a short treatment with N-Aβcore can reverse the morphology of reactive astrocytes and microglia in the presence of pathological Aβ accumulation into a morphology more typical of ‘resting’ astrocytes and microglia, in parallel to reversal by N-Aβcore of neuron loss in the same ex vivo familial AD model.

Aβ is a naturally occurring molecule in the brain under homeostatic conditions [3], with potential neuromodulatory activity at picomolar concentrations [34, 40, 41] and toxic properties at higher concentrations [9, 42–44]. Yet, its action on glial cells at various, and especially lower, concentrations is not well understood. To determine whether lower concentrations (pM–nM) are sufficient to evoke changes in glial intracellular calcium responses and to study whether the N-Aβ fragments elicit differential calcium responses compared to Aβ, primary mixed glia cultures were used to measure the induced calcium responses in morphologically identified astrocytes and microglia during perfusion with either Aβ_1-42, N-Aβ fragment or N-Aβcore at increasing concentrations (100 pM, 100 nM, 1 μM or 2.5 μM) in live-cell imaging (Additional file 1: Appendix, Fig. S3A, B). Application of all Aβ peptides tested elicited similar weak, sustained calcium responses at 100 pM (Additional file 1: Appendix, Fig. S3A, B). A similar weak, but sustained, calcium response with the application of 100 nM Aβ_1–42, no response with 100 nM N-Aβ fragment and an attenuated response with 100 nM N-Aβcore was observed. These findings are in sharp contrast to that found for regulation of [Ca²⁺]_i in neurons and presynaptic nerve terminals, where 100 pM–1 nM stimulation by Aβ_1–42 triggers maximum calcium responses [34], and thus indicate that glia are decidedly lower in sensitivity to Aβ as compared to neurons.

On the other hand, increasing the concentration of Aβ_1–42 to pathological levels (μM) induced notable prolonged, robust calcium responses, especially with acute 2.5 μM treatment, (Additional file 1: Appendix, Fig. S3A, B). Interestingly, application of 1 μM N-Aβ fragment or N-Aβcore evoked an attenuated response compared to Aβ_1–42 at the same concentration and a transient or no response, respectively, at the highest concentration tested, 2.5 μM (Additional file 1: Appendix, Fig. S3A, B). Importantly, the removal of Ca²⁺ ions from the media attenuated the calcium responses induced by application of 1 μM Aβ_1–42, in agreement with the findings of other studies [45–47], 1 μM N-Aβ fragment or 1 μM N-Aβcore (Additional file 1: Appendix, Fig. S3C), suggesting that the various Aβ peptide-induced increases in [Ca²⁺]_i were triggered by the influx of extracellular Ca²⁺ ions.

The observation of attenuated calcium responses elicited by 1 μM concentrations of the N-Aβ fragments (Additional file 1: Appendix, Fig. S3A, B) prompted an investigation into whether the N-Aβ fragment or N-Aβcore could mitigate the robust calcium response induced by 2.5 μM Aβ_1–42 in astrocytes and microglia. To address this question, we measured the [Ca²⁺]_i induced by live-cell co-perfusion with 2.5 μM Aβ_1–42 + 1 μM N-Aβ fragment or 1 μM N-Aβcore compared to 2.5 μM Aβ_1–42 alone in morphologically identified astrocytes and microglia in mixed glia cultures. In agreement with our previous results using a hybrid neuroblastoma cell line [35], the N-Aβ fragment completely abolished and the N-Aβcore attenuated the robust, prolonged intracellular calcium response induced by perfusion with 2.5 μM Aβ_1–42 (Additional file 1: Appendix, Fig. S3D). All together, these results suggest the N-Aβ fragments differentially regulate intracellular calcium responses compared to Aβ_1–42 and may directly attenuate the action of full-length Aβ_1–42 at known Aβ target receptors in astrocytes and microglia.

The weak elicited calcium responses in primary astrocytes and microglia to 100 pM concentrations of all the Aβ peptides tested and the attenuated responses of the N-Aβ fragments compared to Aβ_1–42 at 1 μM concentrations (Additional file 1: Appendix, Fig. S3A, B) prompted an investigation into whether 100 pM treatment with these Aβ peptides could induce an activation of primary astrocytes and microglia, and whether co-treatment of either of the N-Aβ fragments could mitigate the phenotypic shift and activation of these glial cells induced by Aβ_1–42 at 1 μM concentrations. Unsurprisingly, 100 pM treatment with all Aβ peptides tested, alone or in combination, did not induce reactive astrocytes or microglia after 1–3 days of treatment (Additional file 1: Fig. S4), once again in contrast to the regulatory action of 100 pM Aβ on neuronal systems [34, 40, 41].

Microglia were double labeled with Iba1 (yellow) and CD68 (red), as the dual expression of these increases in activated phagocytic microglia [38, 39]. The microglia from each group were then scored into three separate categories: (1) no synaptic interaction, (2) synaptic interaction, (3) containing synaptophysin-positive (Syn +) inclusions (see “Materials and methods”). The population of microglia interacting with, but not engulfing, Syn + elements remained similar between the 5xFAD and B6SJL slices and was not altered by N-Aβcore treatment (Fig. 5B). However, interestingly, there was a significant increase in population of microglia containing Syn + inclusions in the control 5xFAD slices compared to the control B6SJL slices (Fig. 5C), which was attenuated by 1 μM N-Aβcore treatment.

To examine the population of Syn + containing microglia in more detail, the microglia containing Syn + inclusions were further scored in two different categories based on the size of the Syn + inclusions (see “Materials and methods”). Scoring the population of Syn + inclusion containing microglia in this manner revealed that the population of microglia containing small Syn + inclusions remained similar between the 5xFAD and B6SJL strains treated with or without N-Aβcore (Fig. 5D). Interestingly, the average diameter of the small Syn + synaptic inclusions (1.44 μm ± 0.37) and the Syn + synaptic puncta scored within the synaptic interaction group (1.65 μm ± 0.50) are not significantly different (p = 0.1417), suggesting these small Syn + synaptic inclusions may be individual Syn + puncta. By contrast, a dramatic increase in the population of microglia containing large Syn + inclusions (> 1 SD over the average Syn + inclusion size) in the 5xFAD slice cultures was observed compared to the B6SJL slices (Control groups; Fig. 5E), with substantial colocalization with the CD68 (evident as brown staining). This enhanced microglial synaptic engulfment was mitigated by 1 μM N-Aβcore treatment (Fig. 5E, F). In a preliminary experiment, N-Aβcore treatment also significantly reduced the observed increase in overall C3 protein expression in 5xFAD organotypic slices compared to the genetic background B6.SJL (Additional file 1: Fig. S8). Altogether, these results suggest exogenous application of the N-Aβcore attenuates Aβ-induced synaptotoxicity and loss, possibly involving a reduction in the expression of the complement protein C3 and mitigating ongoing Aβ-induced synaptic loss by direct microglial engulfment.

To mimic the cytotoxicity and cellular changes in astrocytes and microglia induced by high pathogenic levels of Aβ, while residing within a proinflammatory environment leading to cytotoxicity, an in vitro model was developed in which primary cortical astrocytes and microglia in mixed glial cultures were exogenously treated with Aβ_1–42 over a prolonged period (Additional file 1: Fig. S9). Populations of astrocytes can become functionally impaired in AD, with deficits in gene or protein expression [24, 65], and treatment of cultured astrocytes with the toxic C-terminal Aβ sequence, Aβ_25–35, induced intracellular peroxide formation and decreased cell viability in a concentration-dependent manner [66]. In addition, Aβ_1–42-treated microglia release fragmented and dysfunctional mitochondria into the neuronal milieu, activating nearby astrocytes into the A1 reactive state and triggering neuronal death [67, 68]. Oxidative stress, as the percentage of ROS-positive cells in the mixed glial population, was utilized to determine the concentration necessary to induce cytotoxicity in primary cortical astrocytes and microglia. The two highest concentrations tested, 2.5 μM and 5 μM Aβ_1–42, induced a significant increase in the percentage of ROS-positive cells after 3 days of daily treatment compared to the untreated control (Additional file 1: Appendix, Fig. S9A). Furthermore, it was determined daily treatments with 2.5 μM Aβ_1–42 for 2, 3, and 5 days induced significant oxidative stress, mitochondrial dysfunction and apoptosis in primary cortical astrocytes and microglia, respectively (Additional file 1: Appendix, Fig. S9B, D).

To examine the limits of the protective effects of the N-Aβ fragment and N-Aβcore against full-length Aβ_1–42-induced oxidative stress in primary cortical astrocytes and microglia, the cells were co-treated with 2.5 μM Aβ_1–42 and a series of dilutions of either the N-Aβ fragment or the N-Aβcore (Fig. 6G). Co-treatment with the lowest concentration tested, 0.01 μM of either the N-Aβ fragments did not prevent the Aβ_1–42-induced oxidative stress (Fig. 6G). Surprisingly, however, treatment with an 8.3-fold lower concentration of N-Aβ fragment, 0.3 μM, on a molar basis, compared to full-length Aβ_1–42 at 2.5 μM was able to significantly mitigate the oxidative stress induced by full-length Aβ_1–42 in morphologically identified primary astrocytes and microglia (Fig. 6G). The same trend was observed with co-treatment of 2.5 μM Aβ_1–42 and 0.3 μM N-Aβcore, although the p-value did not reach significance (p = 0.05; Fig. 6G), suggesting the N-Aβ fragment is more potent than the N-Aβcore.

Finally, we sought to investigate potential mechanism(s) underlying the protective effects of the N-Aβ fragments. The major receptors regulated by Aβ on neurons include cellular prion (PrP^C), nicotinic acetylcholine receptors (nAChRs) and NMDA-type glutamate receptors (reviewed in [69]). Under normal conditions, astrocytes and microglia express NMDA receptors, PrP^C, as well as α7- and α4-subtypes of nAChRs [70–75]. As a preliminary experiment to determine the mechanism(s) through which the N-Aβ fragment and N-Aβcore exert their protective effects, we examined the capability of these N-Aβ fragments to mitigate the Aβ_1–42-induced increase in oxidative stress in primary astrocytes and microglia utilizing selective antagonists for PrP^C, α7-nAChaRs or α4-nAChRs (Additional file 1: Fig. S11). In agreement with other studies [76, 77], the inhibition of PrP^C, α7-nAChRs or α4-nAChRs all significantly decreased the extent of Aβ_1–42-induced oxidative stress in primary astrocytes and microglia (Additional file 1: Fig. S11). Inhibition of these receptors also partially reversed the protective functions of the N-Aβ fragment and the N-Aβcore (Additional file 1: Fig. S11, Table S1). Interestingly, the application of the anti-PrP^C antibody 6D11 significantly increased the amount of oxidative stress present in astrocytes and microglia in the Control group treated with media only compared to the Control group without any antibody or drug present (p = 0.0083; Additional file 1: Fig. S11), suggesting the PrP^C receptor and the pathways it regulates may be important to the reduction of oxidative stress within astrocytes and microglia. Collectively, these results suggest the N-Aβ fragment or N-Aβcore mitigate full-length Aβ-induced oxidative stress via interaction with PrP^C and α4- or 7-nAChRs.

All animal procedures (handling, use and euthanasia) were performed in accordance of an Institutional Animal Care and Use Committee-approved protocol (Ethical approval reference: 16-2282-4/5), compliant with National Institutes of Health (NIH) and Society for Neuroscience guidelines for the use of vertebrate animals in neuroscience research. The human APP/presenilin 1 (PSEN1) mutant transgenic mouse line, 5xFAD (Tg6799), on the B6SJLF1/J background (B6SJL-Tg(APPSwFlLOn,PSEN1*M146L*L286V) 6799Vas/Mmjax (from JAX stock #100012, MMRRC034840, Homozygous) was used as an extensively characterized model for Aβ-based pathology and neurodegeneration [37], along with age-matched genetic background (control wild-type) mice (B6SJL; MMRRC034840 Non-carrier). Mice were housed in ventilated cages with environmental enrichment in the John A. Burns School of Medicine (JABSOM) AAALAC-accredited Vivarium with ad libitum access to food and water. Roughly equal numbers of male and female mice were used and there were no apparent differences by sex. Mice were killed at the age of 0–2 days, 1 month, 2.5 months or 6.5 months. Inclusion/exclusion criteria were based on animal health.

Coronal slices containing cortices and hippocampi were prepared from 1-, 2.5- or 6.5-month-old human APP/PSEN1 mouse line, 5xFAD (Tg6799), or control (B6SJL background) mice, as described [109]. Following cervical dislocation and rapid decapitation, brains were isolated and subsequently sliced coronally into 200 μm sections using a vibratome (Leica VT 1200S SN# 10021) in ice-cold, sterile-filtered Slicing medium [Minimum Essential Medium (MEM) containing 13 mM NaHCO₃, 25 mM HEPES, 5 mM Tris, 1.7 mM glucose and 3 mM MgCl₂—pH 7.2]. Only slices containing fully intact dorsal hippocampi were selected for this study. Whole coronal slices containing cortex and hippocampi were plated onto membrane inserts (VWR catalog# 353090 or Millipore catalog #PICM0RG50) within 6-well plates containing 1.2 mL/well Feeding medium [Basal Medium Eagle (BME) containing 3% (v/v) Earle Balanced Salts Solution (EBSS), 20 mM NaCl, 5 mM NaHCO₃, 0.2 mM CaCl₂, 1.7 mM MgSO₄, 48 mM glucose, 26.7 mM HEPES, 5% (v/v) heat-inactivated horse serum, 1% (v/v) penicillin/streptomycin, 0.255 mM ascorbic acid, 0.066% (v/v) human insulin—pH 7.2] and maintained in culture for 3 days in a 37 °C, 5% CO₂, humidified environment prior to treatment. Media were changed after 48 h with fresh Feeding Medium. All treatments were performed in Feeding Medium without horse serum. Slice cultures were treated daily for 7 days with media only (untreated control) or 1 μM N-Aβcore.

Cortical mixed glial cultures were prepared from neonatal BJSJL mouse pups (0–2 day old; one litter of 6–10 mice/preparation of either gender in roughly equivalent numbers) obtained from established colonies of wild-type B6SJL mice housed in the JABSOM AAALAC-accredited Vivarium, based on a modification of the protocol described in ref. 36 and similar to several other methods reviewed in ref. 110. Following rapid decapitation, brains were removed into sterile ice-cold HBSS for mixed glia cultures or Neurobasal A medium containing B-27 supplement, 5% fetal bovine serum and Gentamicin (Serum NB) for neuron/glia cultures. Cortices were then isolated under a stereomicroscope, minced and digested with papain in Hanks buffer with 10 mM cysteine at 37 °C for 15 min. The preparations were washed by centrifugation in sterile HBSS for mixed glia cultures or Serum NB for neuron/glia cultures. The isolated cell pellet was dissociated using sequential trituration with polished Pasteur pipettes of decreasing diameter and collected by low-speed centrifugation. The dissociated cells were resuspended and diluted to 1.9 × 10⁵ cells/mL.

To obtain a mixed glia-enriched cell population, the dissociated cells were plated in HBSS for 10–15 min at 37 °C in standard tissue culture dishes to separate out the non-adherent neuronal cells, which were removed by gentle washing. The glia-enriched adherent cells were then resuspended in 10% heat-inactivated horse serum in DMEM (Dulbecco’s modified Eagle media) containing 4.5 g/L glucose, without l-glutamine and with sodium pyruvate (Glia media) prior to being diluted to 1.9 × 10⁵ cells/mL in Glia media and plated into poly-d-lysine-coated 6-. 12-, or 24-well plates or coated glass coverslips (Horse serum is toxic to neurons). The glial cultures were maintained in Glia media for 7 days prior to the application of various treatments in a 37 °C, 5% CO₂, humidified environment. Media were changed every 2–3 days with fresh Glia media. Analysis of the mixed glia cultures via immunostaining for glial (GFAP; Iba1/CD68) and neuron (NeuN) markers revealed a typical composition of 54% astrocytes, 37% microglia and 9% other cells (including neurons: < 2%).

For neuron/glia cultures, the dissociated cortical cells plated onto poly-d-lysine-coated glass coverslips were carefully washed once with Neurobasal A medium containing B-27 supplement and Gentamicin (Plain NB) prior to exchanging the culture medium for Plan NB supplemented with 10% glia conditioned media (CM) obtained from confluent mixed glia cultures. The cultures were maintained in Plain NB supplemented with 10% CM for 14 days prior to treatment in a 37 °C, 5% CO₂, humidified environment. Media were exchanged every 2–3 days with fresh Plain NB supplemented with 10% CM.

CM recovered from mixed glia cultures was cooled on ice prior to centrifugation for 10 min at 1000 rpm at 4 °C to pellet any cells. Supernatants were removed and stored at -20 °C until needed.

Murine BV2 microglial cells (RRID:CVCL_0182; courtesy of Dr. Jefferson Kinney, University of Nevada at Las Vegas) were used as a homogeneous model microglial cell system. The BV2 line was derived from mouse brain microglia that were retrovirally immortalized [55]. The cells were cultured in Dulbecco’s Modified Eagle Media (DMEM) with 10% fetal bovine serum (FBS) and 1% penicillin/streptomycin. Media were changed every 2–3 days and cells were maintained in a 37 °C, 5% CO₂, humidified environment. BV2 microglial cells were immunostained according to the protocol for isolated cortical mixed glial cultures (see next section) using anti-rat CD68 (1:500; Abcam catalog # ab31630; RRID:AB_1141557), rabbit anti-TNFα (1:500; Abcam catalog # ab183218; RRID: AB_2889388), or rabbit monoclonal anti-iNOS (D6B6S) (1:200; Cell Signaling catalog # 13120; RRID:AB_2687529) primary antibodies.

The quantification of the number of glial cells in a particular phenotypic state and neurons were determined via immunocytochemistry using fluorescently tagged antibodies to cell-type-specific markers in coronal slice cultures from B6SJL or 5xFAD mice or isolated cortical mixed glial cultures after Aβ treatments, as imaged using confocal microscopy. Coronal slice cultures isolated from 1-, 2.5- or 6.5-month-old mice (for glial markers), 10-month-old mice (for neuron markers) or isolated cortical mixed glial cultures (glial markers) were subjected to various treatments for 7 (slices) or 1–15 days (mixed glial cultures), respectively. Immunocytochemistry of slice cultures was performed according to the protocol described in [109]. In brief, cultures were fixed with freshly prepared 4% paraformaldehyde in phosphate-buffered saline (PBS; slice cultures: 5 min, primary cultures: 40 min). Slice cultures were subsequently incubated in 20% methanol in PBS for 5 min and washed once in PBS. Thereafter, cultures were permeabilized using Triton-X in Tris-buffered saline (TBS; slice culture: 0.05% Triton-X overnight at 4 °C, primary cultures: 0.1% Triton-X at room temp. for 30 min). Slices and adjacent surrounding membrane were carefully removed from the membrane inserts. Non-specific binding sites were blocked by incubation in a blocking buffer (slice culture: 20% bovine serum albumin (BSA) in PBS, primary culture: 5% BSA and 10% normal goat serum in TBS) overnight at 4 °C. Next, proteins of interest were labeled by an overnight incubation at 4 °C with primary antibodies in a blocking buffer containing 5% BSA (with the addition of 10% normal goat serum for primary cultures) in PBS. Primary antibodies utilized were anti-rat CD68 (1:200; Abcam), anti-mouse GFAP (1:200; Cell Signaling Technology catalog # 3670S; RRID:AB_561049), anti-rabbit Iba1 (1:200; Abcam catalog # ab178847; RRID:AB_2832244) and anti-NeuN (1:1,000; EMD Millipore, cat # ABN90; RRID:AB_11205592). The cultures were washed with 5% BSA in PBS for 30 min and incubated with the appropriate fluorophore-conjugated secondary antibody and DAPI to label cell nuclei for at room temperature (slice cultures: 4 h, primary cultures: 1 h), protected from light. Cultures were subsequently washed with PBS for 30 min, plated onto glass microscope slides, and sealed with Vectashield anti-fade mounting media (Vector Laboratories, catalog # H-1200; RRID: SCR_000821). The immunostained preparations were subsequently visualized using a Leica TCS SP8 confocal imaging system (for glia) using a 5×, 20×, 40× or 63× objective or a Leica Thunder wide-field microscope (for neurons).

The concentration of the proinflammatory cytokine IL-1β and the neurotrophin BDNF released into the BV2 microglial cell culture media after various treatments were determined via ELISA using the Mouse IL-1β ELISA Kit (Abcam, catalog # ab229440) and a dot-blot immunoassay, respectively. In brief, BV2 microglial cells were subject to various treatments for 5–6 days. The medium for each condition was changed daily. At the end of each treatment period, the medium for each condition was recovered and immediately placed on ice prior to centrifugation for 10 min at 2000 rpm at 4 °C to pellet any cells. Supernatants were removed and stored at − 20 °C until needed. Protein concentrations in the supernatants were measured using the BCA assay.

For IL-1β, protein standards were prepared in double-distilled water to a final concentration of 0–200 pg/mL. 50 μL of sample or protein standard and 50 μL Antibody Cocktail were added to the appropriate wells of the microplate. The microplate was sealed and incubated for 1 h at RT on a plate shaker at 400 rpm. The wells of the microplate were subsequently washed three times in 350 μL/well 1× Wash Buffer PT. 100 μL/well CatchPoint HRP Developer solution was added to the appropriate wells and allowed to incubate for 10 min at RT on a plate shaker at 400 rpm, protected from light. Finally, the fluorescence readout was recorded on a SpectraMax M3 microplate reader at excitation/cutoff/emission of 530/570/590 nm using SoftMax Pro.

For BDNF, 8 μL of each supernatant was applied 1 μL at a time to a gridded nitrocellulose membrane and allowed to dry. A parallel set was produced as control. The membranes were incubated in 10% BSA and then processed for immunostaining using mouse anti-BDNF antibody (Abcam, cat #: ab205067; lot #GR3217060-14) at 1:10,000 final dilution in blocking buffer with 5% BSA, followed by washing with TBS-Triton. The membranes were then incubated with IRdye^® 680LT goat anti-mouse secondary IgG antibody (LI-COR, cat # 926-68020) in blocking buffer with 5% BSA and then extensively washed with TBS-Triton. The control membrane was incubated with secondary antibody only. The membranes were imaged on a LI-COR Odyssey IR imager. Immunostaining intensities were extracted from the scans using Image J. Intensity values for each sample were background (control)-subtracted and then normalized to total supernatant protein concentration.

Oxidative stress was determined via the production of reactive oxygen species (ROS) in individual cells using the Image iT LIVE Reactive Oxygen Species (ROS) Detection Kit (Invitrogen, catalog # I36007; RRID: SCR_008452) [111]. In brief, isolated cortical mixed glial cultures were subjected to various treatments for 1–3 days. The medium for each condition was changed daily. At the end of each treatment period, the cells were incubated with carboxy-H2DCFDA (component A) at 37 °C for 30 min. During the last 5 min of incubation, 2 μg/mL of Hoechst 33342 stain (component B) was added to assess, in parallel, the integrity of the cell nuclei. The cells were then washed with HBS. Finally, the cells were maintained in HBS and imaged live using an Olympus IX71 epifluorescence microscope at excitation/emission of 495/529 nm (ROS) and 350/461 nm (Hoechst 33342), respectively. Acquired images were analyzed via Image J (NIH, Bethesda, MD, USA), verifying the proportion of the fluorescent signals due to ROS via the use of N-acetylcysteine.

The mitochondrial membrane potential was measured using TMRE (tetramethylrhodamine ethyl ester)—mitochondrial membrane potential assay kit (Invitrogen, catalog # T669; RRID: SCR_008452) [35]. Briefly, isolated cortical mixed glial cultures were subjected to various treatments for 1–4 days. The medium for each condition was changed daily. At the end of the treatment periods, the cells were incubated with 50 nM TMRE and 2 μg/mL Hoechst 33342 stain in HBS for 20 min at 37 °C. The cells were subsequently washed with and maintained in HBS throughout live imaging using an Olympus IX71 epifluorescence microscope at excitation/emission of 549/575 nm (TMRE) and 350/461 nm (Hoechst 33342), respectively. Images were analyzed via Image J.

Apoptosis was measured via TUNEL staining using the Click-iT^® TUNEL Alexa Fluor^® Imaging Assay (Invitrogen, catalog # C10245; RRID: SCR_00845) in accordance with the manufacturer’s protocol (see ref [111]). In brief, isolated cortical mixed glial cultures were subjected to various treatments for 3–7 days. The medium for each condition was changed daily. At the end of the treatment periods, the cells were fixed with freshly prepared 4% paraformaldehyde in PBS for 15 min and permeabilized with Triton X-100 (0.25% in PBS) for another 20 min. The cultures were then washed twice with de-ionized water and incubated with 50 μL of terminal deoxynucleotidyl transferase reaction buffer (Component A) for 10 min. The buffer was replaced with a TUNEL reaction mixture containing terminal deoxynucleotidyl transferase and incubated in a humidified chamber at 37 °C for 60 min. The cells were subsequently washed three times with 3% bovine serum albumin in PBS for 2 min per wash and thereafter, incubated with 50 μL of Click-iT reaction mixture (containing Alexa 488 azide) for 30 min at RT, protected from light. Afterwards, the cells were again washed with 3% bovine serum albumin in PBS and the cell nuclei were counterstained with 2 μg/mL Hoechst 33342 for 15 min at RT, protected from light exposure. The coverslips were finally washed twice with PBS before mounting onto a slide with Vectashield anti-fade mounting media and subsequently visualized using an Olympus IX71 epifluorescence microscope at excitation/emission of 495/519 nm (TUNEL) and 350/461 nm (Hoechst 33342), followed by analysis via Image J, verifying the proportion of apoptosis via the use of DNase I.

Full-length human Aβ_1–42, the N-Aβ fragment and Aβ_42-1 were obtained from Bachem or AnaSpec as hydrochloride salts (Aβ_1–42: catalog # 4045866.1; N-Aβ fragment: AS-61798; Aβ_42-1: catalog # AS27076). The N-Aβcore (Aβ_10-15: YEVHHQ) and the inactive substituted N-Aβcore (SEVAAQ) were custom-ordered from Peptide 2.0. All peptides were synthesized and isolated at > 98% purity, as assessed by mass spectrometry. Aβ (1–42), the N-Aβ fragment (1–15), and the N-Aβ core (10–15) and mutant forms were solubilized in double-distilled water and used at pM to μM final concentration in buffered saline as previously described [111]. All Aβ stock solutions were prepared as aliquots at 0.4 mM and stored at − 20 °C until use. Under these conditions the Aβ_1–42 peptide is present as low-molecular-weight oligomers, whereas the N-Aβ fragment (Aβ_1-15), and N-Aβcore are present in monomeric form. The reverse peptides Aβ_42-1, Aβ_15-1 and the inactive triple mutant (SEVAAQ) were utilized as additional controls, as noted in figure legends.

All standard reagents (buffers, salts, tissue culture media and substrates, paraformaldehyde, Triton X-100, etc.) were obtained from Sigma Aldrich, ThermoFisher or VWR and were of the highest grade available (> 98% purity). Heat-inactivated horse serum was purchased from Gibco (Catalog # 26080-088 Lot # 2180552). Tetrodotoxin was purchased from Abcam (Catalog # ab120054, Lot # GR169765). BD Cell-Tak was obtained from VWR (Catalog # 47743-684, Lot # 7100009). Papain was purchased from Worthington Biochemical (Catalog # LS003126 Lot # 30J20403). Poly-d-lysine was purchased from Sigma Aldrich (Catalog # A-003-E Lot # 90829-1).

Digitized images obtained on the Leica TCS SP8 confocal microscope or Olympus IX71 fluorescent microscope were analyzed via ImageJ. Integrated fluorescence intensity values were extracted from individual cells from 3 randomly chosen fields of view, setting the black level to the same level obtained in an image of a culture incubated with secondary antibody alone for each paired condition using a primary and secondary antibody. Presynaptic boutons were identified by the localization of immunostaining for the presynaptic marker Bassoon apposed to postsynaptic dendrites visualized by immunostaining for Drebrin in merged images. All 0.5–2 μm puncta associated with primary, secondary or tertiary branches of dendrites in the plane of focus, clearly emanating from neuronal somata were counted per measured length. C3 expression was calculated using mean fluorescence intensity values obtained from the total hippocampal area from three individual organotypic slice cultures (2 hippocampi per slice) prepared from three separate mice. Microglia from each treatment group from 3-month-old 5xFAD or B6SJL (wild-type) were scored into three separate categories: (1) no synaptic interaction, (2) synaptic interaction, (3) containing synaptophysin-positive (Syn+) inclusions using the Leica LAS-X 3D Image Analysis software to visualize 3D projected images from compressed z-stacks. Co-labeling of Iba1 and CD68 (denoted as Iba1 + CD68 + microglia) using antibodies (rabbit and rat monoclonals, respectively) was used to label activated, phagocytic microglia [38, 39] and an antibody (mouse monoclonal) for the commonly used marker, synaptophysin was used to label presynaptic elements.

Microglia were scored based on the vicinity of and colocalization with Syn + presynaptic elements. Iba1 + CD68 + microglia with any number of Syn + presynaptic elements > 2 μm away were categorized as no synaptic interaction, any number of Syn + presynaptic elements ≤ 2 μm, but not colocalized with a Iba1 + CD68 + microglia were scored as “synaptic interaction”, while colocalization of any number of Syn + presynaptic elements and a Iba1 + CD68 + microglia were categorized as one microglia containing “Syn + inclusions”. Microglia containing Syn + inclusions were further separated into two categories based on the size of the Syn + inclusion: (1) small inclusions and (2) large inclusions. Large Syn + inclusions were defined as any single Syn + inclusion with a diameter greater than one standard deviation (SD) above the mean Syn + inclusion diameter. The values for the number of cells scored in each category were averaged for each of three experiments.

Treatment and units were randomized as to order for all assays and experiments. Biological replicates were based on independent samples (n). All experiments were repeated at least three times. For cell/soma area, process number, TMRE staining, and immunostaining fluorescence intensity experiments, image analysis was automated to reduce bias. For ROS staining and synaptic density experiments, image analysis was confirmed by a blinded observer. Quantitative results are presented as boxplots (5–95% confidence intervals), where appropriate, or means ± SD with overlaid raw data points. Statistical analyses were performed using Prism (GraphPad v5.0b; RRID:SCR_002798). Multiple comparisons were made using one-way ANOVA with Dunnett post hoc tests, or two-way ANOVA using Tukey post hoc tests, unless otherwise indicated. Paired comparison was made using Student’s t-tests. The minimum criterion for assessing changes in signals will be values that fall outside of the nominal variance of any background or baseline. p-values < 0.05 were considered the minimum for significance (as rejection of the null hypothesis).

Additional file 1: Extended Materials and Methods. Table S1: Adjusted P values from oxidative stress in the presence of selective antagonists of PrPc, α7-nAChR or α4-nAChR pathways. Fig. S1. Treatment with 1 μM Aβcore reduces Aβ_1-42-induced GFAP upregulation in astrocytes but not Iba1/CD68 upregulation in microglia from 7-month-old 5XFAD mice. Fig. S2. Treatment with 1 μM Aβcore increases neuronal populations in organotypic slice cultures from aged 5XFAD mice. Fig. S3: The N-Aβ fragment and N-Aβcore attenuate the Aβ_1-42 calcium response in primary cortical astrocytes and microglia. Fig.S4. Treatment with 100 pM Aβ peptides does not induce an upregulation of GFAP expression in astrocytes or Iba1 andCD68 expression in microglia. Fig. S5. The N-Aβ fragment and N-Aβcore mitigate the upregulation of GFAP expression in astrocytes and Iba1/CD68 expression in microglia induced by 1 μM Aβ_1-42. Fig.S6. N-Aβcore co-treatment reverses Aβ_1-42-induced secretion of the neurotrophin BDNF in BV2 cells. Fig. S7. N-Aβcore co-treatment attenuates Aβ_1-42-induced morphological changes and increased expression of CD68 in BV2 cells. Fig. S8. N-Aβcore mitigates complement C3 expression in organotypic slice cultures from 5xFAD mice. Fig. S9. Treatment with Aβ_1-42 induces oxidative stress, mitochondrial dysfunction and apoptosis in primary cortical astrocytes and microglia in a dose- and time dependent manner. Fig. S10. N-Aβ fragment and N-Aβcore mitigate Aβ_1-42-induced oxidative stress, mitochondrial dysfunction and cellular death in primary cortical astrocytes and microglia. Fig. S11. Selective antagonists of PrPc, α7-nAChR or α4-nAChR pathways partially compromise the protective functions of the N-Aβ fragment or N-Aβcore against the oxidative stress induced by full-length Aβ_1-42 in primary cortical astrocytes and microglia.