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Neuroprotective effects of apigenin against inflammation, neuronal excitability and apoptosis in an induced pluripotent stem cell model of Alzheimer’s disease

Scientific Reports volume 6, Article number: 31450 (2016) | Download Citation

Abstract

Alzheimer’s disease (AD) is one of the most prevalent neurodegenerative diseases, yet current therapeutic treatments are inadequate due to a complex disease pathogenesis. The plant polyphenol apigenin has been shown to have anti-inflammatory and neuroprotective properties in a number of cell and animal models; however a comprehensive assessment has not been performed in a human model of AD. Here we have used a human induced pluripotent stem cell (iPSC) model of familial and sporadic AD, in addition to healthy controls, to assess the neuroprotective activity of apigenin. The iPSC-derived AD neurons demonstrated a hyper-excitable calcium signalling phenotype, elevated levels of nitrite, increased cytotoxicity and apoptosis, reduced neurite length and increased susceptibility to inflammatory stress challenge from activated murine microglia, in comparison to control neurons. We identified that apigenin has potent anti-inflammatory properties with the ability to protect neurites and cell viability by promoting a global down-regulation of cytokine and nitric oxide (NO) release in inflammatory cells. In addition, we show that apigenin is able to protect iPSC-derived AD neurons via multiple means by reducing the frequency of spontaneous Ca2+ signals and significantly reducing caspase-3/7 mediated apoptosis. These data demonstrate the broad neuroprotective action of apigenin against AD pathogenesis in a human disease model.

Introduction

Alzheimer’s disease (AD) is a neurodegenerative disorder involving the progressive loss of neurons in the brain1. The precise etiology is unknown for the majority of AD patients, who suffer from sporadic or late-onset AD; however, advanced age and inheritance of the ε4 allele of the apolipoprotein E gene are significant risk factors2. For a subset of patients, who suffer from the familial or early-onset form of the disease, specific genetic mutations have been identified. These include mutations in the presenilin-1 or -2 genes (PSEN1, PSEN2), as well as the amyloid precursor protein (encoded by APP)3,4. These mutations directly contribute to the accumulation of one of the pathogenic protein hallmarks of AD, β-amyloid (Aβ), which aggregates to form extracellular plaques that can disrupt a multitude of cellular functions4. For example, amyloid peptide accumulation has been reported to cause disruptions to the tightly regulated neuronal calcium (Ca2+) signalling systems during the progression of AD, affecting synaptic plasticity, memory and learning5, and contributing to a wide range of downstream pathogenic effects, such as the generation of reactive oxygen and nitrogen species6. Furthermore, accumulation of Aβ has been shown to cause inflammation, leading to the activation of microglia around Aβ plaques7. These activated microglia likely contribute to the increased levels of cytokines and chemokines, including interleukin-1 (IL-1), IL-6, and tumour necrosis factor α (TNF-α), observed in AD brains7,8. The second major pathogenic hallmark of AD is the accumulation of intracellular neurofibrillary tangles, which form when the microtubule associated protein tau becomes hyperphosphorylated, destabilising microtubules9. It has been reported that inflammation and reactive nitrogen species, which can cause the nitration of tau tyrosine residues, can further contribute to the aggregation of tau10. The combined action of these pathogenic factors likely contributes to the loss of synapses, neurite retraction and ultimately the death of neurons.

The rate of neurodegeneration in AD, from the initial pathogenic changes in neuronal signalling, to the presentation of clinical symptoms and the subsequent cognitive decline, differs between individuals1. This has led to suggestions that both genetic and environmental factors play a significant role in the progression of this neurodegenerative disease1. This concept is supported by epidemiological studies that have positively correlated environmental and behavioral aspects, such as diet and lifestyle, with incidents of AD and other forms of dementia (reviewed in refs 11,12). The combination of these factors indicates that the most effective treatments for AD might be pre-emptive, targeting the prevention or delay of onset rather than attempting to reverse pathogenic mechanisms once symptoms have developed.

Research has indicated that dietary based neuroprotective, anti-inflammatory and anti-oxidant agents may successfully reduce the risk or delay the onset or progression of AD13. Indeed non-steroidal anti-inflammatory drugs (NSAIDs) decrease the risk of AD14, though their serious side effects prevent long-term use15. Our previous studies have used macrophage and microglial cell lines to systematically screen compounds for their anti-inflammatory activity16 and cytoprotective properties in inflammation and oxidative stress-induced cell death in astrocyte17 and neuronal cell lines18. From these studies we have identified the polyphenolic compound apigenin, which is present in celery, parsley and artichoke, as able to reduce both tumour necrosis factor-α (TNFα) and NO release from RAW264.7 macrophages, following activation with lipopolysaccharide19, however in these studies only a limited cytokine repertoire was assessed. These data suggest that apigenin could possess neuroprotective properties in the pro-inflammatory setting of AD.

Several groups have reported the anti-inflammatory action of apigenin in a number of human and animal inflammatory cell lines and animal models20,21,22. Furthermore, analysis of the neuroprotective potential of apigenin in a double transgenic mouse model of AD (APP/PS1) indicated that apigenin could ameliorate AD-associated memory impairment, reduce the Aβ plaque burden and inhibit oxidative stress23. Several groups have reported anti-apoptotic effects of apigenin in murine HT2224 and human SH-SH5Y cell lines25 and shown that apigenin can reduce glutamate-induced Ca2+ signalling in murine cortical neurons26. Collectively, these results indicate that apigenin may have potent neuroprotective properties. However its contribution to neuroprotective mechanisms in human AD neurons is currently unknown.

Studying the temporal and cellular responses of neurons from AD patients to novel therapeutics has been difficult. A primary setback in the development of effective treatments for AD is the disparity between the outcomes in multiple cell and animal based models in comparison to clinical trials27. These models often over-express the pathogenic protein hallmarks of AD to induce the disease phenotype, while failing to fully recapitulate vital aspects of pathogenesis, such as gross synaptic loss and neuronal death28,29. The advent of induced pluripotent stem cell (iPSC) models has provided the opportunity to interrogate AD pathogenesis in human disease-specific neurons30 that express endogenous levels of disease-relevant proteins31.

We carried out a comprehensive and complementary analysis of the anti-inflammatory and neuroprotective activity of apigenin in human iPSC-derived neurons from familial, sporadic AD or healthy individuals. The iPSC-derived AD neurons used in the present study have shortened neurites and reduced neuronal viability, as well as elevated levels of nitrite and apoptosis. In addition, we identified a hyper-excitable Ca2+ signalling phenotype in the iPSC-derived AD neurons, which demonstrated spontaneous Ca2+ signals in the absence of stimulus. By developing a co-culture model using iPSC-derived neurons together with activated murine macrophages, we show that inflammation and oxidative stress lead to reduced neurite length and neuronal viability within AD patient-derived neurons, and that this effect can be prevented with apigenin. We show that apigenin is able to protect neurons from apoptosis (but not cytotoxicity), as well as reduce the hyper-excitable Ca2+ signalling phenotype in AD neurons and glutamate signalling in healthy neurons. Together our data highlight a broad neuroprotective action of apigenin via multiple mechanisms against AD pathogenesis in a human disease model.

Results

Apigenin protects familial AD neurons from inflammatory stress

Inflammatory signalling molecules from activated glia can cause neuronal death7,8,18. To identify whether apigenin could protect against inflammation-induced neuronal death in our cellular model, we first carried out a comprehensive analysis of the anti-inflammatory activity of apigenin in the murine macrophage cell line RAW264.7, microglial cell line C8-B4, and primary microglia, all of which are commonly used as cellular models of inflammation18. In each of these cell types apigenin is able to down-regulate NO and a range of pro-inflammatory cytokines with IC50 values between 10 and 100 μM (Supp. Tables 1–3), consistent with previous studies20,21.

In order to determine whether these anti-inflammatory effects would lead to neuroprotection in a human neuronal model of AD, we first generated iPSCs from a patient with familial AD, bearing a mutation in PSEN1 (P117R), and an age-matched control. This mutation has a symptomatic age of onset around 35 years of age32 and leads to an aggressive phenotype that we hypothesised would generate a robust cellular AD model. As shown previously30,33, the iPSCs expressed Oct3/4 and grew in colonies (Fig. 1). The iPSCs could be differentiated into neurons with extended neurites (Fig. 1). Western blot analysis of familial AD and control neurons at 35 days of differentiation identified the expression of synapse markers PSD-95 and Synapsin I, both of which are required for formation and maturation of synapses34 (Supp. Fig. 1), in addition to the dendrite marker MAP2 (Supp. Fig. 1). However, after 75 days of differentiation, the iPSC-derived neurons from the familial AD patient displayed reduced neurite length, compared to control neurons (Fig. 2A,B).

Figure 1
Figure 1

Neuronal differentiation timeline (A) with (BD) control and (EG) AD derived iPSC cells. (B,E) immunostaining of pluripotent stem cell marker Oct3/4, (C,F) brightfield images of stem cell colonies and (D,G), cells after differentiation into neurons.

Figure 2
Figure 2

Apigenin treatment regime for familial AD iPSC-derived neurons (A). Neurons were generated from iPSCs from a familial AD patient carrying a PSEN1 (P117R) mutation or an age-matched control. (B) Length of neurites from familial AD or control neurons was measured using HCA-vision software. All neurites were measured in >10 images per experiment, n = 3. **indicates significant difference (p ≤ 0.01), paired t-test. (C) Neurons were treated with vehicle control or 100 μM H2O2 for 24 h and viability of AD or control neurons was measured. (D) Neuronal viability and (E) neurite length were measured in AD neurons or those cultured in media taken from activated microglia under inflammatory conditions (Infl; microglia activated with LPS (50 μg/ml) and IFN-γ (20 U/ml) for 48 h ± 50 μM Apigenin (Apg; 24 hour pre-incubation). (F) Nitrite formation in cell culture medium in the absence of cells treated with SNAP (0, 1, 10, 100, 1000 μM) and apigenin (0, 5, 10, 50 μM). Data shown are mean ± standard error of the mean from 3 independent experiments.

Using this disease model, treatment with H2O2 (100 μM) for 24 h to induce oxidative stress led to neuronal death, causing a greater reduction in neuronal viability in neurons from the familial AD patient (32 fold) than the control (4 fold; Fig. 2C; p < 0.01).

Our current results and previously published work16 show that inflammatory activation of microglia and macrophages increases NO and cytokine release. As inflammation and elevated levels of nitrosative and oxidative stress are associated with neurodegeneration during AD7,35, we then investigated the effect of conditioned media from activated primary microglia on AD neurons in combination with the neuroprotective effect of apigenin. Exposure of the iPSC-derived AD neurons to conditioned medium for 48 h led to a reduction in both neuronal viability (Fig. 2D) and neurite length (Fig. 2E). We used a concentration of 50 μM apigenin, in line with our previous IC50 values, to test the neuroprotective activity of apigenin. Pre-incubation (24 h) with apigenin (50 μM) protected against both neuronal death and neurite shortening in AD neurons (Fig. 2E,F).

To investigate whether the neuroprotective mechanism of apigenin was due to its ability to scavenge the high levels of NO produced by activated glial cells, nitrite formation was measured by Griess assay following treatment with the NO donor, S-Nitroso-N-acetyl-DL-penicillamine (SNAP), in cell medium in the absence of cells. There was no significant difference in nitrite levels across all concentrations of apigenin and SNAP treatments (Fig. 2F), suggesting that apigenin does not directly scavenge NO in the cell medium.

Together, these data demonstrate reduced neurite length and cell viability in familial AD neurons, which was exacerbated by exposure to oxidative and inflammatory stresses. Treatment with apigenin protected neurons against the inflammatory stress induced neurite retraction and death.

Apigenin reduces apoptosis in sporadic AD and control neurons

Familial AD neurons provide a good model to understand early-onset AD, however since sporadic, late-onset AD is the most common form of the disease and is difficult to model using animals36, we focused the remainder of our study on sporadic AD neurons. In order to further interrogate the potential neuroprotective effects of apigenin, we differentiated iPSCs derived from a sporadic AD patient and an age and gender matched control. As shown previously25, these iPSCs form stem cell colonies, express markers of pluripotency and form teratomas following implantation into immune-compromised mice (data not shown). For the present study these sporadic AD and control iPSCs were differentiated into neurons with extended neurites, with immunocytochemistry demonstrating the expression of the synaptic maturation protein Synapsin I, the post-synaptic marker PSD-95 (Fig. 3A–F) and the neuronal microtubule marker MAP2 (Fig. 3G–L), as well as GFAP-positive neural precursors/cells (Fig. 3G–L). The iPSC-derived neurons from the sporadic AD patient released 2.6 fold higher levels of Aβ42 compared to neurons from the control patient (t(4) = 3.426, p < 0.05), however there was no significant difference in Aβ40 release (Supp. Fig. 2), which is in accordance with the results of several other studies31,37,38.

Figure 3: Neurons were generated from iPSCs from a sporadic AD patient or an age-matched control.
Figure 3

Immunostaining of neurons in culture with (A,D) Synapsin I (SYN-1) and (B,E) PSD-95, (C,F) overlay or (G,J) GFAP and (H,K) MAP2, (I,L) overlay. (M) Length of neurites from sporadic AD or control neurons presented as mean ± SEM of three independent experiments. ***Indicates significant difference (p ≤ 0.001), paired t-test.

As the loss of synapses from neurite retraction is one of the strongest pathological correlates with cognitive decline in AD39, we assessed neurite length. Similar to familial AD iPSC-derived neurons, the neurites of sporadic AD neurons were 54% shorter at 52 days of differentiation, in comparison to control neurons (t(39) = 8.15, p < 0.001; Fig. 3M). This result is further supported by western blot analysis of iPSC-derived neurons, which identified a significant decrease in the dendrite marker and microtubule associated protein, MAP-2C, in sporadic AD neurons in comparison to the control, at 52 days of differentiation (t(12) =  2.276, p < 0.05; Supp. Fig 3). However, there was no difference in the expression levels of the neuronal markers, neuron specific enolase (NSE) and NeuN, nor synaptic marker, synapsin-1, or axonal marker, neurofilament heavy chain, between control and sporadic AD neurons, suggesting there was no difference in the number of neurons present in the cultures.

Central to neurodegeneration is the loss of neurons by cell death pathways, due to multiple contributing factors in AD, potentially including oxidative and nitrosative stress1. We therefore used our cellular model to assess the effects of apigenin on the levels of cytotoxicity and apoptosis. In the brain, NO can be both neuroprotective and neurotoxic, depending on the local concentration; we have previously shown that exogenous application of high levels of NO is neurotoxic to cell lines like Neuro2a19, however at low concentrations NO can be neuroprotective (reviewed in ref. 35). Neurons were differentiated for 75 days, prior to 50 μM apigenin or vehicle control pre-treatment (24 h), followed by 300 μM H2O2 or 10 μM SNAP treatment for 24 h prior to analysis (Fig. 4A). Sporadic AD neurons had a significantly higher basal level of nitrite (F(1, 8) = 64.69, p < 0.001), used as a downstream marker of NO, present in cell culture medium, compared to control neurons (p < 0.05, Fig. 4B). Pre-treatment of the cells for 24 h with 50 μM apigenin caused a small but non-significant reduction in basal nitrite levels (F(1, 8) = 4.89, n.s.), in comparison to vehicle treatment in both healthy control and sporadic AD cells. This is consistent with our previous results that suggest that apigenin does not scavenge NO in cell culture medium (Fig. 2). The sporadic AD neurons exhibited a significantly higher level of caspase-3/7 activation (F(5, 24) = 11.16) than healthy control neurons, used as a marker of apoptosis (p < 0.001, Fig. 4C,D). Pre-treatment with apigenin (50 μM) for 24 h significantly reduced caspase-3/7 activity levels of sporadic AD neurons (p < 0.001) to the level of control neurons (Fig. 4C). Consistent with our previous experiments showing that neurons from a familial AD patient displayed reduced viability following H2O2 treatment (Fig. 2), levels of cytotoxicity (F(5, 24) = 8.26, p < 0.001) were higher in the sporadic AD neurons than controls and cytotoxicity increased following treatment with H2O2, promoting oxidative stress (p < 0.001; Fig. 4D). Although apigenin protected both sporadic AD and control neurons against apoptosis it had no effect on cytotoxicity (Fig. 4D).

Figure 4
Figure 4

(A) Apigenin treatment regime for sporadic AD and control neurons. (B) Nitrite concentration in the cell medium was measured by Griess assay in the presence of vehicle control or apigenin (50 μM treatment for 24 h). (C) Apoptosis and (D) cytotoxicity were simultaneously measured using an Apotox Glo kit. Control or AD neurons were treated with vehicle control or apigenin (50 μM), H2O2 (300 μM) or SNAP (10 μM) for 24 h. Data are presented as mean ± SEM of three independent experiments. Significant differences from matched treatment are indicated by *p ≤ 0.05 and ***p ≤ 0.001, with significant difference from control treatment indicated by ###p ≤ 0.001 using two-way ANOVA with Tukey’s multiple comparisons test.

To establish the effect of exogenous NO on these neurons, the cells were treated with the NO donor SNAP (10 μM). Treatment with SNAP caused a small but significant reduction in apoptosis (F(5, 24) = 249.5, p < 0.001) for both sporadic AD (p < 0.01) and control neurons (p < 0.05), but did not affect cytotoxicity (Fig. 4C,D). Collectively, these data identify significantly increased levels of apoptosis, cytotoxicity and nitrite, in conjunction with reduced neurites in sporadic AD neurons and that apigenin and low levels of exogenous NO are able to reduce apoptosis.

Apigenin treatment limits apoptosis in sporadic AD and control neurons

In order to further interrogate the potential neuroprotective effects of apigenin against oxidative stress, we differentiated iPSCs derived from a sporadic AD patient and an age and gender matched control into neurons with extended neurites in hypoxic conditions. After 75 days differentiation, neurons were transferred to atmospheric oxygen 24 h prior to apigenin (10 μM) treatment. AD and control neuronal cultures showed similar caspase 3/7 activity (993.7 vs 715.8 substrates/mm2 respectively, p > 0.9, Fig. 5A,B) at the beginning of the normoxic culturing period. Increasing O2 from 3 to 19% triggered a steady increase in caspase 3/7 substrates (AD: 136.1 ± 8.60%, Control: 125.3 ± 5.15%; Fig. 5A). Apigenin (10 μM) treatment slowed the production of caspase 3/7 substrates (AD: 101.3 ± 1.66%, Control: 116.3 ± 6.66% difference vs −22 h–0 h; Fig. 5A) for 24 h. The number of caspase 3/7 substrates significantly rose again for the following 24 h period (AD: 149.3 ± 13.28%, p < 0.001 vs 0 h–24 h; Control: 146.6 ± 6.1%, p < 0.01 vs 0 h–24 h; Fig. 5A), with more substrates produced by the AD neuronal cultures than control cultures (p < 0.01). Propidium iodide binding was not affected by the increase in O2 (Fig. 5C,D), with 2.62 ± 0.13 times more propidium iodide positive cells, as a marker of dead cells, in sporadic AD cultures than control cultures (1018.3 ± 40.9 vs 393.2 ± 39.3, respectively, p < 0.001; Fig. 5C). Caspase 3/7 substrates showed high colocalization with propidium iodide signal for sporadic AD and control neuronal cultures before and after apigenin treatment (Fig. 5E,G), with a trend for higher correlation in sporadic cultures than control cultures (p = 0.07, Fig. 5E,G). This data was further confirmed using Annexin V and propidium iodide (Supp. Fig. 4); together this data provided evidence for AD neuronal cell death via apoptosis in oxidative stress conditions, with protection from apoptosis afforded by apigenin.

Figure 5: iPSC-derived neurons were generated from a sporadic AD patient or an age-matched control.
Figure 5

Apoptosis and cell viability were simultaneously assessed after increasing oxygen from 3 to 19% 22 h prior to apigenin (10 μM) treatment. Apoptosis was assessed through quantifying caspase 3/7 substrates (A), number of substrates per mm2, n = 8) % of change between −22 h and 0 h, 0 h and 24 h and 24 h and 44 h indicated through dotted lines. Dead cells were quantified through counting of propidium iodide (C), number of cells per mm2, n = 4). Representative microscopy images of caspase 3/7 substrates (B) and propidium iodide (D) at 10×, scale = 200 μm. (E) Colocalization was determined through Pearson’s correlation coefficient for caspase 3/7 substrate signal with propidium iodide signal (1 = 100% colocalization, 0 = no colocalization). (F) Merged microscopy images of caspase 3/7 and propidium iodide signal at 10×, scale = 200 μm. (G) Representative 2D intensity histogram for green (y-axis, caspase 3/7 substrates) and red (x-axis, propidium iodide signal) pixels. Data presented as mean ± SEM; **p < 0.01, ***p < 0.001, ****p < 0.0001 as compared to % change between 0 h and 24 h time points; #Tp = 0.07, ##p < 0.01, ###p < 0.001 difference between AD and control cultures.

Apigenin reduces hyper-excitability in sporadic AD neurons

We hypothesised that Ca2+ dysfunction, as a major disease phenotype accompanying AD5,40, could be contributing to the increased apoptosis observed in the sporadic AD neurons. Strikingly, through live cell Ca2+ imaging we observed that the sporadic AD neurons displayed a hyper-excitable phenotype, demonstrating multiple spontaneous Ca2+ responses in the absence of stimulus, whereas control neurons remained inactive in the absence of stimulus (Fig. 6A,B). Exposure to apigenin reduced the hyper-excitable phenotype observed in sporadic AD neurons, significantly reducing the frequency of spontaneous Ca2+ signalling (Fig. 6C,D).

Figure 6
Figure 6

Representative images of Ca2+ imaging traces in (A) control, (B) sporadic AD derived neurons and (C) sporadic AD derived neurons exposed to apigenin. Neurons were loaded with fluorescent Ca2+ indicator Fluo3-AM and data are represented as mean change in fluorescence from baseline (F/F0) over time. Application of 60 mM KCl (high K+) or 50 μM apigenin is represented as the light or dark shaded area, respectively. Mean relative change in fluorescence was calculated from (D) control and (E) sporadic AD derived neurons. Loaded neurons were perfused with 50 μM apigenin, 300 μM H2O2, or 10 μM SNAP prior to 200 μM glutamate or 60 mM high K+. Data are presented as mean ± SEM of three independent experiments from >30 cells. Significant difference from basal response was calculated using two-way ANOVA with Tukey’s multiple comparisons test and is indicated by ***p ≤ 0.001.

Treatment with glutamate induced an influx of Ca2+ into both control and sporadic AD neurons (Fig. 6E,F). Exposure to apigenin (F(3, 159) = 31.05, p < 0.001) prior to glutamate significantly reduced the amplitude of the Ca2+ response in control neurons (P < 0.05) but not in sporadic AD neurons (Fig. 6E,F). Exposure of neurons to the NO donor, SNAP, prior to glutamate had no effect on the amplitude of the Ca2+ response in either control or sporadic AD neurons, while H2O2 significantly increased the glutamate induced Ca2+ response in control neurons only (p < 0.001).

Similar to glutamate, treatment with high K+ induced an influx of Ca2+ into both control and sporadic AD neurons. Exposure to apigenin or SNAP prior to high K+ had no effect on the amplitude of the Ca2+ response in either control or sporadic AD neurons. However, exposure to H2O2 prior to high K+ significantly increased the amplitude of the Ca2+ response in both control (p < 0.001) and sporadic AD neurons (p < 0.001).

Taken together, these data indicate a hyper-excitable phenotype in sporadic AD neurons that can be moderated by apigenin, and that apigenin is able to decrease glutamate-induced Ca2+ influx in healthy neurons.

Discussion

Through the use of iPSC-based AD modelling, we performed a comprehensive analysis of the neuroprotective effects of apigenin against mediators of AD: inflammation, oxidative stress, disruption to neuronal Ca2+ signalling patterns, neurite retraction and apoptosis. For the first time in an iPSC model of AD we demonstrated a hyper-excitable phenotype in neuronal Ca2+ signalling. In addition, we also showed that AD neurons had a shorter neurite length, increased nitrite levels and increased cytotoxicity and apoptosis. Loss of neuronal viability was further enhanced in AD neurons following challenge with inflammatory or oxidative stress. Importantly, our results show that apigenin is able to protect these human neurons from neurite retraction and apoptosis, as well as reduce the hyper-excitable Ca2+ signalling phenotype.

Neuroprotective potential of apigenin: anti-inflammatory activity

Patients who suffer from AD display higher levels of inflammation, oxidative and nitrosative stress, as evidenced by high levels of cytokines, chemokines and nitrated tyrosines present in patient brain tissue and cerebrospinal fluid41,42. As the development of AD is hypothesised to occur over several decades, this suggests that successful treatments need to be pre-emptive to prevent or delay disease onset, rather than reversing the pathogenic mechanisms once symptoms have developed, in addition to being suitable for long-term use. The dietary accessibility of plant-based polyphenolic compounds, like apigenin, makes them a suitable candidate as they have been shown to prevent microglial activation and may be potentially protective against AD progression43.

We first wanted to determine whether apigenin could protect against inflammatory-mediated neurite retraction, as one of the strongest pathogenic correlates with cognitive decline in AD is the loss of neurons from the retraction of neurites and neuronal death39. We demonstrated that iPSC-derived neurons generated from AD patients displayed a significant reduction in neurite length, which was exacerbated by exposure to media from activated inflammatory cells, in addition to elevated levels of nitrite, used as a downstream marker of NO. By using activated murine macrophage and microglial cells, our results indicate that apigenin has broad anti-inflammatory activity, which protects neurites by preventing activation of inflammatory pathways and reducing the release of NO. Potential mechanisms mediating neuroprotection by apigenin may involve the regulation of pro-inflammatory cytokines, such as IL-6, IL-1β and TNF-α by preventing NF-kB activation20.

The involvement of NO in the pathogenesis of AD is highly complex35. As our results, and reports from the literature suggest, activated glial cells can produce high concentrations of NO, which is generated by the enzyme inducible NO synthase (iNOS), while neurons produce much lower concentrations by the Ca2+ activated enzyme neuronal NO synthase (nNOS)44. When produced at low concentrations, NO plays an important role in synaptic plasticity and as a second messenger in the brain45. Indeed we found that low concentrations of NO protected neurons from apoptosis. However, at high concentrations NO can become neurotoxic, due to its propensity to react with the superoxide anion to form aggressive oxidants, such as peroxynitrite46. Studies using the N2a/Peuht39 neuroblastoma line have demonstrated that peroxynitrite can induce the nitration and aggregation of tau, which could potentially contribute to AD pathology10. Our results suggest that apigenin is able to protect neurons by reducing NO levels from activated glia, using a mechanism distinct from NO scavenging. However, our results also show that apigenin does not significantly reduce nitrite levels in neurons. Together, this indicates that the mechanism of action for apigenin may be specific to pathways associated with iNOS activation, as it was able to reduce nitrite levels in glial cells. The targeted action of apigenin towards iNOS generated NO is important in the physiological context of the brain as apigenin may reduce the potentially cytotoxic levels of NO produced by activated glia, without global scavenging of NO, allowing the lower concentrations of NO produced in neurons by nNOS (and in endothelial cells by eNOS) to continue mediating vital cellular functions and protection.

The suppressive effect of apigenin on iNOS activity has been recently reported in a diabetes-associated cognitive decline rat model47. This group also demonstrated that apigenin was able to reduce the activity of both nNOS and eNOS. Although we did not identify a reduction in nitrite in our cultures after apigenin treatment, under certain conditions the mechanism could involve reducing intracellular Ca2+, which is required for the function of calmodulin, an essential co-factor for nNOS and eNOS.

Understanding the action of apigenin on the different NOS enzymes is important due to the complex and often concentration dependent role of NO in the brain. High levels of reactive oxygen and nitrogen species mediating cytotoxic and apoptotic mechanisms in neuronal cell lines have previously been shown48,49. However low concentrations of NO, applied via a NO donor, were protective in our cells, significantly reducing apoptosis in both the AD and control neurons. In the brain, induction of the soluble guanylate cyclase and the cyclic guanosine monophosphate cGMP pathway by NO in neurons promotes vasodilation, increasing the cerebral blood supply to neurons and decreasing the potential for oxidative stress50,51. This complex and concentration dependent role of NO in the brain highlights the need to understand the specific action of apigenin in regards to inhibition of NO production by the different NOS enzymes and in different cell types.

The murine RAW264.7 macrophage cell line, along with the C8B4 microglial cell line, is often used as a model for inflammatory cells18. Activation of these cells with LPS and IFNγ results in the release of cytokines, chemokines and a synergistic and potent up-regulation of iNOS, leading to an increase in NO release18. For this reason RAW264.7 and C8B4 cells, along with primary microglia, were used to assess the anti-inflammatory properties of apigenin. However, an ideal model for understanding the effects of inflammatory activation on AD neurons would be to use microglia differentiated from iPSCs. Although there are protocols for generating microglia-like cells from mouse iPSCs52, these cells (and similarly for human iPSCs) do not release the comprehensive panel of cytokines and chemokines of primary microglia. An important future direction is therefore to develop human iPSC-derived microglia that can release the full complement of cytokines and chemokines upon activation.

Development of human iPSC-derived microglia is important as our data suggest that there are differences in the panel of cytokines and chemokines that are released from the different cell lines used in this study53. Activation of microglia is a relatively early pathogenic event in AD patients (prior to neuropil destruction), while transgenic AD mouse studies suggest that cytokines may also influence plaque deposition/degradation54. Pro-inflammatory mediators, such as TNFα and IL-1β, in combination with IFN-γ, can be directly cytotoxic to neurons when chronically produced at high concentrations55 and stimulate the production of Aβ peptides56. Conversely upon activation with Aβ, microglial cells produce the pro-inflammatory cytokines IL-1, IL-6 and TNFα and the chemokines MIP-1 and MCP-157. This pathogenic and cyclical relationship between inflammatory cytokines and Aβ formation highlights the fundamental role of inflammation in AD and the need to develop human disease models to accurately understand the multiple and interconnected pathways.

Collectively, our results in the macrophage and microglial cells suggest that apigenin has broad anti-inflammatory activity, preventing activation of inflammatory pathways and NO release. Apigenin may therefore delay the onset or slow the progression of AD, targeting multiple pathogenic components associated with the early stages of disease progression by reducing the inflammatory response. Our data further suggests the activation of microglia could contribute to neurite retraction, synapse loss and neuronal death.

Neuroprotective potential of apigenin: anti-apoptotic activity in neurons

The loss of neurons during AD is one of the strongest pathological correlates with cognitive decline, yet is a disease phenotype that has been difficult to recapitulate in animal models28,58. The AD neurons generated in this study demonstrated significantly higher levels of caspase-3/7 activity, two cysteine-aspartic proteases that play an essential role in apoptosis, highlighting the biological relevance of our iPSC-derived model of AD. Several groups have confirmed a significant increase in caspase-3/7 activity at the onset of cognitive decline during AD, closely correlating this change with synaptic loss and neuronal death59,60. Increases in caspase-3 and 7 activity were specifically associated with synaptic dysfunction in a mouse model of AD60, suggesting that therapeutic compounds aimed at protecting neurons against caspase-3/7 activation would be particularly beneficial against synaptic loss and cognitive decline.

We show that in a human iPSC-derived model of AD that apigenin is able to significantly reduce caspase-3/7 activity, protecting cells from apoptosis. Conversely, apigenin was unable to protect neurons from cytotoxicity, suggesting its mechanism of action may be caspase-specific. These findings are in accordance with previous studies showing that apigenin protects against caspase-3 induced apoptosis in SH-SY5Y cells by inhibiting the release of cytochrome c and thus preventing the activation of the caspase-3 cascade25.

The specific mechanisms triggering the observed increase of caspase-3/7 activity in AD neurons may be the result of AD mediated pathogenesis. Studies regarding the activation of caspase-3 in a number of AD transgenic mouse models have demonstrated that ROS, generated by toxic Aβ1–42 oligomers, can induce the release of cytochrome c from mitochondria, which then activates caspase-324,61.

Together, these results demonstrate increased cytotoxicity and apoptosis in iPSC-derived sporadic AD neurons, which has been difficult to recapitulate in animal models of the disease. Furthermore, we showed that treatment with apigenin could significantly reduce caspase-3/7 meditated apoptosis in AD neurons, highlighting the potential therapeutic application of apigenin.

Neuroprotective mechanism for apigenin: reducing neuronal hyper-excitability and Ca2+ dysfunction

Perturbed Ca2+ homeostasis may play a key role in AD pathogenesis, by stimulating the production of inflammatory cytokines, reactive nitrogen and oxygen species62 in neurons and glia, and as a central underlying mechanism in the activation of many downstream pathways40. Recently, a shift in the understanding of how Ca2+ dysfunction manifests and contributes to the functional impairment of neurons has begun to emerge. Increasing experimental evidence from mouse models and human patients with AD is suggesting that neuronal networks are hyperactive, especially in the early stages of disease progression63. In order to improve cell modelling of these complex phenotypes in neurodegenerative disorders, it is increasingly important to validate the differentiation of disease relevant cells from iPSCs by identifying and investigating disease phenotypes using functional assays (reviewed in ref. 64). The Ca2+ imaging experiments reported in this study demonstrate an endogenous hyper-excitability phenotype in iPSC-derived AD neurons. This provides a novel in vitro human model with which to investigate this emerging contributing factor of AD pathogenesis and a platform to test potential therapeutic compounds.

Imaging experiments on hippocampus CA1 neurons in double transgenic AD mice (APPswe/PS1M146V) have shown increased neuronal firing rates in association with reduced neurite length65. These results are in accordance with the AD neurons generated in this study, which had a hyper-excitable phenotype in the absence of stimulus and reduced dendrite length. In addition, although networks of hyperactive neurons have been found clustered around Aβ plaques, two-photon calcium imaging in young double transgenic mice (APP23/PS45) found populations of hyperactive CA1 neurons, prior to plaque formation, suggesting this is an early occurrence in AD pathogenesis66. The relatively short maturation time for the neurons generated in this study (i.e., weeks, in comparison to years in the human brain), in conjunction with the elevated levels of secreted Aβ42 could act as a proxy for earlier stages of AD progression. Our results also suggest that culturing neurons at atmospheric O2 promotes oxidative stress that is able to drive pathogenesis and disease phenotype in the cells. A potential mechanism driving the hyper-excitable phenotype is that elevated levels of Aβ, as measured in the AD neurons, have the capacity to modify receptors involved in Ca2+ signalling, such as NMDA receptors, increasing intracellular Ca2+ and altering signalling patterns40.

Exposure to apigenin reduced the frequency (but not amplitude) of Ca2+ signals in the AD neurons. This is the first report of apigenin modulating hyper-excitability in a model of AD, demonstrating a further neuroprotective mechanism against AD pathogenesis. Intriguingly, apigenin reduced the mean Ca2+ response to glutamate in control neurons but not in AD neurons; the loss of this regulatory mechanism in AD neurons remains unidentified and will be the subject of future research. There are conflicting reports in the literature regarding the effect of apigenin on receptors involved in Ca2+ signalling. In cultured rat cortical neurons apigenin has been shown to decrease NMDA receptor function, with no effect on AMPA receptor activity26, however in cultured rat hippocampal neurons, apigenin was shown to inhibit both NMDA and AMPA receptors67. Identifying the specific effect of apigenin on these important signalling channels in human neurons should be investigated to better understand the protective mechanism of apigenin.

The iPSC-derived neurons used in this study express NMDA receptor subunits (data not shown), indicating that the observed effects in these human cells could be mediated via NMDA receptors. There are a number of potential mechanisms facilitating the observed reduction in neuronal hyper-excitability by apigenin. The reported anti-oxidative and anti-amyloidogenic properties of apigenin in transgenic APP mouse models of AD23, in conjunction with the ability of apigenin to reduce NO production, may protect against oxidative modification of NMDA receptors, as a result of reactive oxygen species generated by Aβ42. In addition, apigenin protection could be mediated through inhibition of protein kinase C (PKC) phosphorylation of the NMDA receptor. Phosphorylation of the core NR1 subunit of the NMDA receptor potentiates Ca2+ influx through the receptor68. Studies have shown that the polyphenolic compound, curcumin, is able to inhibit PKC phosphorylation of NMDA receptors in primary rat cerebral cortex cells68, and that apigenin and curcumin can inhibit PKC activity in NIH3T3 cells69. However, it has yet to be confirmed if apigenin alters PKC activity in neurons and should be the focus of future studies.

The decreased glutamate-induced Ca2+ response to apigenin suggest a potential protective effect through a reduction in Ca2+ signalling, with the associated benefits of reduced Ca2+ signalling widely reported for AD (reviewed in ref. 70). For example, NMDA receptor antagonists, such as Memantine, are among the limited pharmacological compounds currently available for AD71. Attenuation of increased Ca2+ signalling may reduce some of the widespread downstream consequences, such as the activation of glial cells, the production of inflammatory cytokines and even a reduction in the formation of toxic Aβ oligomers, which can ultimately lead to neuronal death72.

The neuronal hyper-excitability observed in the AD neurons used in this study was also accompanied by significantly elevated levels of nitrite, used as a downstream marker of NO production. This suggested that the iPSC-derived AD neurons had a higher level of basal NO production. In post-synaptic neurons, the generation of NO is Ca2+ dependent, with nNOS co-localised with glutamate activated NMDA receptors73. The hyper-excitability in the AD neurons could be contributing to the elevated levels of nitrite. A recent study using the triple transgenic AD mouse model (3xTg-AD) suggested that elevated levels of NO may be a compensatory mechanism employed by neurons to boost synaptic transmission in the early stages of AD74. However, the sustained generation of NO due to neuronal hyper-excitability could lead to the formation of damaging reactive nitrogen and oxygen species, resulting in a pathogenic shift from a neuroprotective mechanism to a mediator of neurodegeneration. The hyper-excitable phenotype and elevated levels of nitrite present in this iPSC-derived model of AD provide a disease and species-relevant platform to investigate and confirm this proposed mechanism.

Conclusion

Collectively, we report a hyper-excitable Ca2+ signalling phenotype in an iPSC-derived model of AD, as well as significantly elevated levels of apoptosis and nitrite, in association with decreased neurite length. We showed that treatment of AD neurons with apigenin reduces neuronal hyper-excitability and apoptosis. Furthermore, through the use of activated inflammatory cells we demonstrated that apigenin could inhibit the activation of cytokines and NO production, protecting AD neurons from inflammatory induced stress and neurite retraction.

Human iPSC-derived neuronal models provide opportunities to understand the neuronal functions and mechanisms of disease. Findings from our study suggest that the flavonoid apigenin has broad neuroprotective effects against a suite of pathogenic factors mediating AD progression, highlighting its potential as a therapeutic agent.

Materials and Methods

Derivation of control and AD-specific iPSCs

Skin samples were collected from patients and healthy individuals (all male), including: a 39-year old early-onset familial AD patient (PSEN1P117R; APOE3/3); a 29-year old healthy individual (APOE4/4); a 65-year old late-onset sporadic AD patient (APOE3/4); a 57-year old healthy individual (APOE3/3). All experimental protocols were approved by the University of Wollongong and University of New South Wales Human Research Ethics Committees (HE13/299 and HREC08037, respectively). The methods were carried out in accordance with the guidelines as set out in the National Statement on Ethical Conduct in Research Involving Humans and informed consent was obtained from all donors. Generation of human feeder-free iPSCs was carried out as previously described (Chung et al., 2012). The iPSCs were considered pluripotent by teratoma assay and were karyotyped to confirm the lack of chromosomal changes during reprogramming. The iPSCs were cultured on Matrigel (Corning) coated tissue culture plates in mTeSR1 (Stem Cell Technologies) containing 25 U/mL Penicillin-streptomycin at 37 °C, 5% CO2 in a humidified incubator.

Differentiation of control and AD-specific iPSCs to neurons

Differentiation of iPSCs was performed via neurospheres as per75. On day 29, neurospheres were dissociated with accutase, re-suspended in neural expansion media (DMEM/F12) supplemented with N2, B-27, Minimum Essential Medium (MEM) nonessential amino acids and heparin (1 mg/mL)) and triturated into single cells. Cells were plated out on laminin-coated 18 mm glass coverslips for Ca2+ imaging or in 24 well tissue culture plates for assays in neural expansion media at a density of 25,000 cells / well.

All growth factors were from R&D systems. Following overnight incubation, media was aspirated and replaced with media supplemented with 100 ng/mL of sonic hedgehog (SHH) and fibroblast growth factor 8 (FGF-8). On day 36, media was supplemented with 200 μM ascorbic acid in addition to SHH and FGF-8. On day 44 media was supplemented with 100 ng/mL each of cyclic adenosine monophosphate (cAMP), brain-derived neurotrophic factor, glial-derived neurotrophic factor and insulin-like growth factor 1, in addition to SHH, FGF-8 and ascorbic acid until day 75. Partial media changes were performed every other day for the entire culture period. For inflammation-based assays, neurons were treated with 50 μM apigenin or vehicle for 24 h, prior to complete media changes with conditioned media from activated microglia for 48 h. For all other assays neurons were treated with apigenin 50 μM or vehicle for 24 h, prior to complete media changes containing either 10 μM SNAP or 300 μM hydrogen peroxide (H2O2) for 24 h.

Immunocytochemistry

Samples of iPSCs and neurons were stained for specific markers to confirm pluripotency and differentiation into mature neurons, respectively. Both iPSCs and neurons were plated on poly-L lysine (BD Biosciences) laminin-coated 8 mm coverslips. Cells were fixed with 4% (v/v) paraformaldehyde, permeabilised with 0.5% (v/v) TritonX-100 in phosphate buffered saline (PBS) and blocked with 5% (w/v) bovine serum albumin in PBS.

The iPSC colonies were stained with Oct3/4 (mouse 1:500, Stem Cell Technologies) primary antibody and anti-mouse Alexa Fluor 488 (1:1000, Life Technologies) secondary antibody. Neurons were stained with primary antibodies to microtubule-associated protein 2 (MAP2, 1:500), glial fibrillary acidic protein (GFAP, 1:250), synapsin-1 (SYN-1, 1:500) and postsynaptic density protein 95 (PSD-95, 1:500). Antibodies were from Millipore unless otherwise stated and were incubated with cells in blocking solution overnight at 4 °C. Anti-mouse/anti-rabbit isotype controls (Life Technologies) were used as negative controls. Anti-rabbit Alexa Fluor 488 and anti-mouse Alexa Fluor 633 secondary antibodies were used at 1:1000 in blocking solution for 1 h at room temperature. Cells were mounted in SlowFade Gold antifade reagent with DAPI (Life Technologies). Immunocytochemical preparations were imaged with a Leica DMI6000B confocal microscope and acquired using LAS AF 2.6 (Leica microsystems).

Primary microglia isolation and cell line culture

RAW264.7 and C8B4 cells were maintained in Dulbecco’s Modified Eagle’s Medium (DMEM) supplemented with 200 U/ml penicillin, 200 μg/ml streptomycin and 10% foetal bovine serum (FBS) and incubated at 37 °C in 5% CO2. For primary microglial culture, brains were removed from murine E18 embryos from C57/Bl6 mice and meninges were removed. Cell cultures were washed twice with phosphate buffered saline (PBS; pH 7.2) followed by a 5 min incubation with 2 ml of 0.05% TrypLE Express (Life technologies) at 37 °C. Dislodged cells were resuspended in 10 ml of ice-cold separation buffer (PBS, pH 7.2, 0.5% bovine serum albumin (BSA) and 2 mM EDTA). The buffer was degassed in an ultrasound water bath (Unisonics, Brookvale, Australia), to prevent air bubbles from blocking the column. Cells were centrifuged at 300 g for 10 min and the supernatant discarded. Up to 1 × 107 cells were resuspended in 90 μl of separation buffer (Miltenyi Biotec). The cells were incubated with 20 μl CD11b magnetic beads on a MS column (Miltenyi Biotec) for 15 min at 4 °C, washed with 2 ml separation buffer and centrifuged at 300 g for 10 min. The supernatant was removed completely and the cells were resuspended in 500 μl of separation buffer. Cells were passed through a 40 μm nylon mesh to remove cell clumps and plated into a T25 flask.

Activation of microglia with LPS and IFN-γ and treatment with apigenin

Immediately after CD11b magnetic bead isolation primary microglia cells were seeded into 96 well Primaria tissue culture plates (Bio-Rad) at a density of 3 × 105 cells per well. The conditioned media from the mixed culture was diluted 1:2 with fresh medium (total volume in each well 100 μl). Primary microglia, RAW264.7 and C8B4 cells were plated 24 h before incubation with apigenin for 1 h. Lipopolysaccharide (LPS; 50 μg/ml) and Interferon-γ (IFN-γ; 20 U/ml) were added, followed by incubation for 48 h. The supernatant of three wells was combined, spin filtered (0.22 μm Corning Costar Spin-X spin filter with a cellulose acetate membrane) and 0.4 μl protease inhibitor cocktail containing Aprotinin, Bestatin, E-64, Leupeptin and Pepstatin A was added. Of the supernatant 50 μl were immediately used for Griess assay and the remainder was stored at −80 °C for the cytokine assay.

Resazurin-based assay for determination of cell viability

Cell viability of activated inflammatory cells or iPSC-derived neurons was assessed in terms of the metabolic capability of cells to convert the non-fluorescent redox indicator, resazurin, into its highly fluorescent product, resorufin. Briefly, 100 μl DMEM containing 0.125 mg/l resazurin (Sigma-Aldrich) was added to each well of a 96-well plate and incubated for 90 min at 37 °C. Fluorescence was measured at 560 nm excitation / 590 nm emission using a POLARstar Omega fluorescent plate reader (BMG LABTECH).

Nitrite determination by Griess assay

The nitrite concentration in the culture medium of activated inflammatory cells or iPSC-derived neurons was used as an indicator of NO production using the Griess reaction. Cell culture medium in the absence of cells was also assessed to investigate the scavenging action of apigenin, with fresh media exposed to SNAP (0, 1, 10, 100, 1000 μM) and apigenin (0, 5, 10, 50 μM). The supernatant (50 μl from each well) was transferred to a fresh 96 well plate with 50 μl Griess reagent (25 μl of 1% sulphanilamide and 25 μl of 0.1% napthyethylene-diamine in 5% HCl). After 10 min incubation at room temperature, the absorbance of each well was measured at 540 nm. Nitrite concentration was calculated with reference to a standard curve of sodium nitrite generated by known concentrations, ranging from 0-100 μM.

Neuron and neurite length measurements

Analyses were performed with High Content Analysis software HCA-Vision (CSIRO) to assess the neuronal images: Neuron Body Detection, Neurite Detection and Neurite Analysis. Images were background corrected and analysis was performed as in ref. 76.

Apoptosis and cytotoxicity assay

The ApoTox-Glo Triplex assay (Promega) was performed according to the manufacturer’s guidelines to assess apoptosis, cytotoxicity and cell viability in parallel. Differentiated iPSC-derived neurons were pre-treated in the presence or absence of apigenin (10 μM) for 24 h at 37 °C and 5% CO2. Neurons were exposed to vehicle control, H2O2 (300 μM) or SNAP (10 μM) for 24 h at 37 °C and 5% CO2. All measurements were taken after 30 min incubation using a Polarstar Omega plate reader (BMG Labtech).

Apoptosis and cytotoxicity assay over time

Differentiated iPSC-derived neurons were transferred to normoxic (37 °C, 5% CO2 and atmospheric O2) conditions after differentiation in hypoxic (3% O2) conditions. The culture media was supplemented with caspase 3/7 NucView 488 enzyme substrate (2.5 μM final concentration, Biotium #10402) and either CF594 Annexin V (2.5 μM final concentration, Biotium #30067) or propidium iodide (1 μg/ml final concentration, Sigma #P4884) 24 h prior to apigenin treatment (10 μM). Phase contrast and fluorescent images were captured using an IncuCyte Zoom (Essen Bioscience) at 2 h intervals and 10× magnification. Caspase substrates, propidium iodide-positive cells and annexin V confluence were quantified using the in-built basic analyser algorithm (Table 1) from a minimum of 8 images per well and time point after removing green (8%) and red (5%) channel bleed through. The colocalization of caspase 3/7 substrates with propidium iodide was analysed using the Coloc 2 ImageJ plugin (NIH). Pearson’s correlation coefficient and Manders split coefficients were used to determine colocalization of caspase 3/7 substrates with propidium iodide signal.

Table 1: Mask parameters for Incucyte Basic analyser image analysis.

Calcium imaging

To confirm the differentiation of functional neurons from iPSCs and compare differences in Ca2+ responses between iPSC derived neurons following treatments with acute application of apigenin, SNAP, H2O2 and glutamate, live cell fluorescence Ca2+ imaging experiments were performed. Images were captured at a rate of 1 frame per 0.112 s using a Leica confocal SP5 microscope and excitation at 488 nm with a 10× objective.

Neurons (day 75) were loaded with 3 μM Fluo3-AM (Life Technologies) and 0.04 μM pluronic acid (Biotium) in standard bath solution (SBS), containing 160 mM NaCl, 2.5 mM KCl, 5 mM CaCl2, 1 mM MgCl2, 10 mM HEPES, and 5 mM glucose, pH 7.4, for 15 min at 37 °C in the dark. Neurons were washed for 5 min in SBS at room temperature in the dark.

Neurons were perfused with 5 mL SBS at 2.2 mL/min using a Scintilla EpiPump to attain a baseline reading of fluorescence intensity (F0). Treatment regimes included 50 μM apigenin, 10 μM SNAP or 300 μM H2O2 prior to 200 μM glutamate and 60 mM KCl. Cells were considered for further analysis if they responded to 60 mM KCl (90% of cells responded to KCl, and there was no significant difference in the % responders among control or AD neurons). During post imaging analysis more than 30 individual cells were selected as regions of interest (ROIs) from three independent differentiation experiments, with fluorescence data background subtracted. Evoked Ca2+ responses for ROIs were expressed as the relative change in fluorescence intensity (F) to the baseline fluorescence signal of the cell (ΔF/F0).

Statistical analysis

Paired T-test, one-way and two-way ANOVAs, as appropriate, were used to analyse the effects and interactions between treatments, followed by Tukey’s multiple comparisons test, results were considered significantly different at p < 0.05.

Additional Information

How to cite this article: Balez, R. et al. Neuroprotective effects of apigenin against inflammation, neuronal excitability and apoptosis in an induced pluripotent stem cell model of Alzheimer’s disease. Sci. Rep. 6, 31450; doi: 10.1038/srep31450 (2016).

References

  1. 1.

    , & Epidemiology of Alzheimer disease. Nat. Rev. 27, 204–206 (2011).

  2. 2.

    et al. Apolipoprotein E polymorphism and Alzheimer’s disease. Lancet 342, 697 (1993).

  3. 3.

    et al. The Swedish mutation causes early-onset Alzheimer’s disease by [beta]-secretase cleavage within the secretory pathway. Nat Med 1, 1291–1296 (1995).

  4. 4.

    , & Presenilins and -Secretase: Structure, Function, and Role in Alzheimer Disease. Cold Spring Harb. Perspect. Med. 2, a006304–a006304 (2012).

  5. 5.

    , , & Alterations in synaptic transmission and long-term potentiation in hippocampal slices from young and aged PDAPP mice. Brain Res . 840, 23–35 (1999).

  6. 6.

    et al. Cu (II) potentiation of Alzheimer Aβ neurotoxicity correlation with cell-free hydrogen peroxide production and metal reduction. J. Biol. Chem. 274, 37111–37116 (1999).

  7. 7.

    et al. Inflammation and Alzheimer’s disease. Neurobiol. Aging 21, 383–421 (2000).

  8. 8.

    , , & β-Amyloid stimulation of microglia and monocytes results in TNFα-dependent expression of inducible nitric oxide synthase and neuronal apoptosis. J. Neurosci. 21, 1179–1188 (2001).

  9. 9.

    , , , & τ is phosphorylated by GSK-3 at several sites found in Alzheimer disease and its biological activity markedly inhibited only after it is prephosphorylated by A-kinase. FEBS Lett. 436, 28–34 (1998).

  10. 10.

    , , , & Nitration and oligomerization of tau induced by peroxynitrite inhibit its microtubule-binding activity. FEBS Lett. 579, 2421–2427 (2005).

  11. 11.

    Emerging role of polyphenolic compounds in the treatment of neurodegenerative diseases: a review of their intracellular targets. Eur. J. Pharmacol. 545, 51–64 (2006).

  12. 12.

    , , , & Benefits from dietary polyphenols for brain aging and Alzheimer’s disease. Neurochem. Res. 33, 2390–2400 (2008).

  13. 13.

    , , , & Fruit and vegetable juices and Alzheimer’s disease: the Kame Project. Am. J. Med. 119, 751–759 (2006).

  14. 14.

    et al. Anti-inflammatory drugs protect against Alzheimer disease at low doses. Arch. Neurol. 57, 1586–1591 (2000).

  15. 15.

    et al. COX-2 selective non-steroidal anti-inflammatory drugs and risk of serious coronary heart disease. The Lancet 360, 1071–1073 (2002).

  16. 16.

    et al. Determination of anti-inflammatory activities of standardised preparations of plant-and mushroom-based foods. Eur. J. Nutr. 53, 335–343 (2014).

  17. 17.

    et al. Cytoprotective properties of traditional Chinese medicinal herbal extracts in hydrogen peroxide challenged human U373 astroglia cells. Neurochem. Int. 62, 522–529 (2013).

  18. 18.

    et al. Neuroprotection of Neuro2a cells and the cytokine suppressive and anti-inflammatory mode of action of resveratrol in activated RAW264.7 macrophages and C8-B4 microglia. Neurochem. Int. doi: 10.1016/j.neuint.2015.10.013 (2015).

  19. 19.

    et al. Effects of plant‐derived polyphenols on TNF‐α and nitric oxide production induced by advanced glycation endproducts. Mol. Nutr. Food Res. 54, S141–S150 (2010).

  20. 20.

    , , & Flavonoid apigenin inhibits lipopolysaccharide-induced inflammatory response through multiple mechanisms in macrophages. PLoS One 9, e107072 (2014).

  21. 21.

    et al. Apigenin and luteolin modulate microglial activation via inhibition of STAT1-induced CD40 expression. J Neuroinflammation 5, 41 (2008).

  22. 22.

    et al. Suppression of inducible cyclooxygenase and inducible nitric oxide synthase by apigenin and related flavonoids in mouse macrophages. Carcinogenesis 20, 1945–1952 (1999).

  23. 23.

    et al. Neuroprotective, anti-amyloidogenic and neurotrophic effects of apigenin in an Alzheimer’s disease mouse model. Molecules 18, 9949–9965 (2013).

  24. 24.

    et al. Apigenin protects HT22 murine hippocampal neuronal cells against endoplasmic reticulum stress-induced apoptosis. Neurochem. Int. 57, 143–152 (2010).

  25. 25.

    , , , & Neuroprotective effects of flavones on hydrogen peroxide-induced apoptosis in SH-SY5Y neuroblostoma cells. Bioorg. Med. Chem. Lett. 14, 2261–2264 (2004).

  26. 26.

    , , , & Apigenin modulates GABAergic and glutamatergic transmission in cultured cortical neurons. Eur. J. Pharmacol. 502, 41–46 (2004).

  27. 27.

    & Alzheimer’s therapeutics: continued clinical failures question the validity of the amyloid hypothesis—but what lies beyond? Biochem. Pharmacol. 85, 289–305 (2013).

  28. 28.

    , , , & Alzheimer’s disease models and functional genomics-How many needles are there in the haystack. Front Physiol 3, 320 (2012).

  29. 29.

    , & Modeling neurological disorders by human induced pluripotent stem cells. BioMed Res. Int. 2011 (2011).

  30. 30.

    et al. Induced pluripotent stem cells as tools for disease modelling and drug discovery in Alzheimer’s disease. J. Neural Transm. 120, 103–111 (2013).

  31. 31.

    et al. Probing sporadic and familial Alzheimer/’s disease using induced pluripotent stem cells. Nature 482, 216–220 (2012).

  32. 32.

    et al. Mutations in presenilin 1, presenilin 2 and amyloid precursor protein genes in patients with early-onset Alzheimer’s disease in Poland. Exp. Neurol. 184, 991–996 (2003).

  33. 33.

    et al. Human induced pluripotent stem cells derived under feeder-free conditions display unique cell cycle and DNA replication gene profiles. Stem Cells Dev . 21, 206–216 (2011).

  34. 34.

    , , , & The cytoskeletal architecture of the presynaptic terminal and molecular structure of synapsin 1. J. Cell Biol. 108, 111–126 (1989).

  35. 35.

    & Getting to NO Alzheimer’s Disease: Neuroprotection versus Neurotoxicity Mediated by Nitric Oxide. Oxid. Med. Cell. Longev. 2016, 3806157 (2016).

  36. 36.

    & Alzheimer’s disease modeling: ups, downs, and perspectives for human induced pluripotent stem cells. J. Alzheimers Dis. 34, 563–588 (2013).

  37. 37.

    et al. Modeling familial Alzheimer’s disease with induced pluripotent stem cells. Hum. Mol. Genet. 20, 4530–4539 (2011).

  38. 38.

    et al. Modeling Alzheimer’s disease with iPSCs reveals stress phenotypes associated with intracellular Aβ and differential drug responsiveness. Cell Stem Cell 12, 487–496 (2013).

  39. 39.

    , , & Neuropathological alterations in Alzheimer disease. Cold Spring Harb. Perspect. Med . 1, a006189 (2011).

  40. 40.

    & Neuronal calcium mishandling and the pathogenesis of Alzheimer’s disease. Trends Neurosci . 31, 454–463 (2008).

  41. 41.

    , & Neuronal DNA damage precedes tangle formation and is associated with up-regulation of nitrotyrosine in Alzheimer’s disease brain. Brain Res . 774, 193–199 (1997).

  42. 42.

    et al. Electrochemical analysis of protein nitrotyrosine and dityrosine in the Alzheimer brain indicates region-specific accumulation. J. Neurosci. 18, 8126–8132 (1998).

  43. 43.

    et al. The role of polyphenols in the modulation of sirtuins and other pathways involved in Alzheimer’s disease. Ageing Res. Rev. 12, 867–883 (2013).

  44. 44.

    iNOS-mediated nitric oxide production and its regulation. Life Sci . 75, 639–653 (2004).

  45. 45.

    , & Nitric oxide signaling in brain function, dysfunction, and dementia. The Neuroscientist 16, 435–452 (2010).

  46. 46.

    et al. A redox-based mechanism for the neuroprotective and neurodestructive effects of nitric oxide and related nitroso-compounds. Nature 364, 626–632 (1993).

  47. 47.

    , , & Apigenin attenuates diabetes-associated cognitive decline in rats via suppressing oxidative stress and nitric oxide synthase pathway. Int. J. Clin. Exp. Med. 8, 15506 (2015).

  48. 48.

    , , , & Nitric oxide induces oxidative stress and apoptosis in neuronal cells. Biochim. Biophys. Acta BBA-Mol. Cell Res. 1498, 72–79 (2000).

  49. 49.

    , & Mechanism of nitric oxide-induced apoptosis in human neuroblastoma SH-SY5Y cells. FEBS Lett. 484, 253–260 (2000).

  50. 50.

    , , & Cyclic guanosine monophosphate signalling pathway plays a role in neural cell adhesion molecule‐mediated neurite outgrowth and survival. J. Neurosci. Res. 85, 703–711 (2007).

  51. 51.

    , , , & Pharmacological shift of the ambiguous nitric oxide action from neurotoxicity to cyclic GMP-mediated protection. Neurol. Res. 32, 938–944 (2010).

  52. 52.

    , , , & Generation of microglial cells from mouse embryonic stem cells. Nat. Protoc. 5, 1481–1494 (2010).

  53. 53.

    et al. Cytokines associated with amyloid plaques in Alzheimer’s disease brain stimulate human glial and neuronal cell cultures to secrete early complement proteins, but not C1-inhibitor. Exp. Neurol. 160, 289–299 (1999).

  54. 54.

    et al. Neuroinflammation in Alzheimer’s disease and prion disease. Glia 40, 232–239 (2002).

  55. 55.

    , , , & Synergistic neurotoxic effects of combined treatments with cytokines in murine primary mixed neuron/glia cultures. J. Neuroimmunol. 85, 1–10 (1998).

  56. 56.

    , , , & TNFα plus IFNγ induce the production of Alzheimer β-amyloid peptides and decrease the secretion of APPs. FASEB J. 13, 63–68 (1999).

  57. 57.

    et al. Inflammatory repertoire of Alzheimer’s disease and nondemented elderly microglia in vitro. Glia 35, 72–79 (2001).

  58. 58.

    et al. Physical basis of cognitive alterations in Alzheimer’s disease: synapse loss is the major correlate of cognitive impairment. Ann. Neurol. 30, 572–580 (1991).

  59. 59.

    , & Changes in caspase expression in Alzheimer’s disease: comparison with development and aging. Biochem. Biophys. Res. Commun. 256, 381–384 (1999).

  60. 60.

    et al. Caspase-3 triggers early synaptic dysfunction in a mouse model of Alzheimer’s disease. Nat. Neurosci. 14, 69–76 (2011).

  61. 61.

    , , , & The neuroprotective effects of phytoestrogens on amyloid β protein-induced toxicity are mediated by abrogating the activation of caspase cascade in rat cortical neurons. J. Biol. Chem. 276, 5287–5295 (2001).

  62. 62.

    Oxidative stress, perturbed calcium homeostasis, and immune dysfunction in Alzheimer’s disease. J. Neurovirol. 8, 539–550 (2002).

  63. 63.

    & Neuronal hyperactivity–a key defect in Alzheimer’s disease? Bioessays 37, 624–632 (2015).

  64. 64.

    , , & Common pitfalls of stem cell differentiation: a guide to improving protocols for neurodegenerative disease models and research. Cell. Mol. Life Sci. 1–17, doi: 10.1007/s00018-016-2265-3 (2016).

  65. 65.

    et al. Dendritic structural degeneration is functionally linked to cellular hyperexcitability in a mouse model of Alzheimer’s disease. Neuron 84, 1023–1033 (2014).

  66. 66.

    et al. Critical role of soluble amyloid-β for early hippocampal hyperactivity in a mouse model of Alzheimer’s disease. Proc. Natl. Acad. Sci . 109, 8740–8745 (2012).

  67. 67.

    et al. Effects of Apigenin on Glutamate-induced [Ca2+] i Increases in Cultured Rat Hippocampal Neurons. Korean J. Physiol. Pharmacol. 12, 43–49 (2008).

  68. 68.

    et al. Distinct mechanisms underlie distinct polyphenol-induced neuroprotection. FEBS Lett. 580, 6623–6628 (2006).

  69. 69.

    , , & Suppression of protein kinase C and nuclear oncogene expression as possible molecular mechanisms of cancer chemoprevention by apigenin and curcumin. J. Cell. Biochem. 67, 39–48 (1997).

  70. 70.

    , & Calcium dysregulation in Alzheimer’s disease: from mechanisms to therapeutic opportunities. Prog. Neurobiol. 89, 240–255 (2009).

  71. 71.

    Failures and successes of NMDA receptor antagonists: molecular basis for the use of open-channel blockers like memantine in the treatment of acute and chronic neurologic insults. NeuroRx 1, 101–110 (2004).

  72. 72.

    & The dysregulation of intracellular calcium in Alzheimer disease. Cell Calcium 47, 183–189 (2010).

  73. 73.

    & Neuronal nitric oxide synthase: structure, subcellular localization, regulation, and clinical implications. Nitric Oxide 20, 223–230 (2009).

  74. 74.

    , , , & Nitric oxide signaling is recruited as a compensatory mechanism for sustaining synaptic plasticity in Alzheimer’s disease mice. J. Neurosci. 35, 6893–6902 (2015).

  75. 75.

    , & Derivation, propagation, and characterization of neuroprogenitors from pluripotent stem cells (hESCs and hiPSCs). Methods Mol. Biol. 873, 237–246 (2012).

  76. 76.

    et al. HCA-Vision Automated Neurite Outgrowth Analysis. J. Biomol. Screen. 15, 1165–1170 (2010).

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Acknowledgements

This research was supported by the National Health and Medical Research Council (NHMRC) of Australia (APP1071250 and APP1079995 awarded to LO), a Cooper Foundation grant awarded to LO, a Brain Foundation research gift awarded to LO and an industry grant awarded to GM by Nutrafur SA (Spain). We thank Prof Brett Garner and A/Prof Ron Sluyter (University of Wollongong) for helpful discussions and assistance.

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Affiliations

  1. Illawarra Health and Medical Research Institute, School of Biological Sciences, University of Wollongong, Wollongong, NSW, 2522, Australia

    • Rachelle Balez
    • , Martin Engel
    • , Sonia Sanz Muñoz
    •  & Lezanne Ooi
  2. School of Medicine, Western Sydney University, Locked bag 1797, Penrith, NSW, Australia

    • Nicole Steiner
    • , Michael O’Connor
    •  & Gerald Münch
  3. Illawarra Health and Medical Research Institute, School of Medicine, University of Wollongong, Wollongong, NSW, 2522, Australia

    • Jeremy Stephen Lum
    •  & Yizhen Wu
  4. CSIRO Informatics and Statistics, Locked Bag 17, North Ryde, NSW 1670, Australia

    • Dadong Wang
    •  & Pascal Vallotton
  5. Centre for Healthy Brain Ageing School of Medicine, University of New South Wales, High Street, Kensington,. NSW, 2052, Australia

    • Perminder Sachdev
    •  & Kuldip Sidhu
  6. Molecular Medicine Research Group, Western Sydney University, Locked bag 1797, Penrith, NSW, Australia

    • Michael O’Connor
  7. Centre of Complementary Medicine Research (CompleMed), Western Sydney University, Locked bag 1797, Penrith, NSW, Australia

    • Gerald Münch

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Contributions

R.B., N.S., S.S.M., M.E., J.S.L. and Y.W. performed experiments and prepared Figures. D.W. and P.V. provided HCA-vision software and training. P.S. and K.S. provided patient cells. MO’C provided technical advice and training. L.O. and G.M. designed experiments. R.B. and L.O. wrote the main manuscript text with contributions from all authors.

Competing interests

The authors declare no competing financial interests.

Corresponding author

Correspondence to Lezanne Ooi.

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DOI

https://doi.org/10.1038/srep31450

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