Pathological manifestation of the induced pluripotent stem cell‐derived cortical neurons from an early‐onset Alzheimer's disease patient carrying a presenilin‐1 mutation (S170F)

Abstract Objectives Alzheimer's disease (AD) is the most common neurodegenerative disease which is characterized by the formation of amyloid beta (Aβ) plaques and neurofibrillary tangles. These abnormal proteins induce disturbance in mitochondrial dynamics and defect in autophagy system. Since presenilin‐1 (PS1) is a core component in γ‐secretase complex, the mutations of PS1 gene cause the interference of γ‐secretase activity and lead to the increased Aβ42 secretion. We aimed to characterize the patient‐specific induced pluripotent stem cell (iPSC) line carrying PS1‐S170F mutation. Furthermore, we tested whether disease‐modifying drug can reduce AD pathology in the AD iPSC‐derived neurons. Materials and methods Mononuclear cells (MNCs) were isolated freshly from the peripheral blood of an autosomal dominant AD (ADAD) patient carrying presenilin‐1 (PS1) mutation (Ser170Phe; PS1‐S170F) and a cognitively normal control. We generated induced pluripotent stem cell (iPSC) lines, which were differentiated into functional cortical neurons. Then, we measured the markers indicative of AD pathogenesis using immunocytochemistry and Western blot. We also investigated the mitochondrial dynamics in the AD iPSC‐derived neurons using Mito‐tracker. Results We observed that both extracellular and intracellular Aβ levels were dramatically increased in the PS1‐S170F iPSC‐derived neurons, compared with the control iPSC‐derived neurons. Furthermore, PS1‐S170F iPSC‐derived neurons showed high expression levels of p‐Tau, which were detected both in the soma and neurites. The mitochondrial velocity in the PS1‐S170F iPSC‐derived neurons was much reduced, compared with that of the control. We also found a significant decrease of fusion‐related protein Mfn1 (membrane proteins mitofusin 1) and an increase of fission‐related protein DRP1 (dynamin‐related protein 1) in the PS1‐S170F iPSC‐derived neurons. We further observed the defects of autophagy‐related clearance in the PS1‐S170F iPSC‐derived neurons. Finally, we demonstrated the levels of Aβ and p‐Tau can be dramatically reduced by the treatment of LY‐2886721, a BACE1 inhibitor. Conclusions Taken together, we have established and characterized the pathological features of an AD patient carrying PS1‐S170F mutation using iPSC technology, which will be the first case on this mutation and this iPSC line will serve as a useful resource for studying AD pathogenesis and drug screening in the future.


| INTRODUC TI ON
Alzheimer's disease (AD) is the most common cause of dementia, which is pathologically defined by the accumulation of extracellular amyloid plaques and intraneuronal hyperphosphorylated tau aggregates associated with neuronal loss in the cerebral cortex. 1,2 Autosomal dominant AD (ADAD) is associated with mutations in presenilin-1 (PS1), presenilin-2 (PS2) or amyloid precursor protein (APP) genes. Amyloid beta (Aβ) peptides consist of 38-43 amino acid residues and are generated from APP by beta (β)-and gamma (γ)-secretase-dependent sequential cleavages. PS1 gene acts as a core component in γ-secretase complex, and the mutations in the PS1 gene interfere with γ-secretase activity, resulting in the increase of Aβ42 secretion. The S170F in the PS1 gene is a wellknown mutation causing AD at very young age (ie third decade of life) with a rapid progression. [3][4][5] We chose this mutation to generate iPSCs, because it is one of the most aggressive forms of AD both clinically and pathologically. Thus, we speculated that the iPSC-derived neurons from this patient would exhibit AD pathology, including significant defects in mitochondrial and autophagy systems.
Induced pluripotent stem cell (iPSC) technology provides an excellent method for elucidating the molecular basis of human diseases. 6,7 An increasing number of studies have employed disease-specific iPSCs in neurological diseases including AD, 8,9 and lots of them have investigated the phenotypes to model the AD in vitro. [10][11][12][13][14] Previous researches demonstrated that extracellular Aβ or phosphorylated tau-induced impairment of synapses, 15 disturbed mitochondrial dynamics [16][17][18][19] and defective autophagy system, [20][21][22] and these compounding features of AD cannot be represented easily in other cellular model systems than iPSC system. Moreover, iPSC-based disease modelling has the great potential towards personalized treatment as each iPSC line is patient-specific and the response of drug treatments can be accurately monitored prior to human treatment. 7,10 In this study, we generated patient-specific iPSCs from an AD patient carrying PS1-S170F mutation for the first time using freshly isolated peripheral blood mononuclear cells (PBMCs). Then, we aimed to characterize the typical pathological features in the iP-SC-derived neurons from AD patients, compared with the normal control iPSC line which has been fully characterized in our previous study. 23 We further investigated whether disease-modifying candidate drug can reduce the pathological features of AD iPSC-derived neuron.

| Participants
We collected blood samples from a 33-year-old Korean man who visited Samsung Medical Center in Seoul, Korea. He was clinically diagnosed as AD according to the criteria of National Institute on Aging-Alzheimer's Association. 24 The patient underwent neuropsychological test, 25,26 brain MRI and fluorodeoxyglucose (FDG)-PET. As the patient had a strong family history of earlyonset dementia ( Figure 1A), we screened for PS1 and performed apolipoprotein E (APOE) genotyping. As a parallel study, we also collected a blood sample from a healthy 72-year-old Korean man.
He was proven to be cognitively normal on neuropsychological test. 25,26 He also underwent brain MRI, 18 F-florbetaben amyloid PET and APOE genotyping.

| Reverse transcriptional polymerase chain reaction
We isolated total RNAs manually using the TRIzol reagent (Life Technologies) lysis and isopropyl alcohol precipitation.

| Electrophysiological analysis
Whole-cell patch recordings were performed as previously described, 30 and we performed patch recording between 8 and 13 weeks after neural differentiation from the AD-iPSCs. Briefly, before recordings, cells were transferred to a Nikon FN2 (Optical Apparatus) upright microscope fitted with a 40× water-immersion objective, differential interference contrast (DIC), and infra- were expressed as mean ± standard error of the mean. Statistical analyses were performed using the 2-tailed unpaired Student's t test and analysis of variance (ANOVA), respectively, with P < .05 considered significant.

| Extracellular and intracellular amyloid-β ELISA
We collected conditioned media (CM) from cultured neuronal cells (1 × 10 5 ) at 48 hours after the last medium change from 4 to

| Immunocytochemistry and Western blot
Immunocytochemistry and Western blot analysis were performed as we described before. 27,28 The following primary antibod-

| Live cell imaging and mitochondrial dynamics analysis
We incubated the 10-week-differentiated neurons using the Mitotracker red (Thermo Fisher Scientific Cat.M7512) for 15 minutes before live cell imaging (LCI). Neurons were maintained at 37°C and were supplied with the atmosphere of 5% CO 2 /95% air (Live Cell Instrument) during imaging. Time-lapse image recordings were acquired in 2-second interval, and the duration was maintained up to 3.5 minutes. Quantitative analysis of mitochondria velocity was performed using KymographClear and KymographDirect. [27][28]31 All procedures were essentially same as described before. 27,28

| Drug treatment
LY-2886721 (Selleck Chemicals) was prepared fresh from frozen stocks before administration and was dissolved in the differentiation medium, at 5 µmol/L as working concentration, as described previously. 27,28 Then, we treated the 6-week-differentiated iPSC-derived neurons with LY-2886721 for 5 days and investigated the effects on Aβ and p-Tau levels.

| Statistical analyses
All statistical analyses were performed using the one-factor analysis of variance (ANOVA) following the Fisher's LSD (Least Significant Difference) in the Statistical Analysis System (Enterprise 4.1; SAS Korea). Significance was accepted at the 95% probability level. Data in graphs were presented as mean ± SEM. Statistical significance (ie P value) in the graphs were presented as follows: P < .05 (*), P < .01 (**) and P < .001 (***).  (Table 1). He had a strong family history of early-onset dementia on his mother's side ( Figure 1). His mother was diagnosed to have dementia in her twenties and died at the age of 29 ( Figure 1A, II-1). His aunt was also demented in her thirties but did not visit the hospital ( Figure 1A, II-3). His grandfather was demented as he used to get lost in the neighbourhood in his forties ( Figure 1A, I-1). In genetic analysis, a known mutation in PSEN1 (p.S170F, c.509C>T) was identified as heterozygous. The APOE genotype was ε3/ε3. The patient's brain MRI showed an atrophy in the bilateral parietal areas ( Figure 1C), and FDG-PET showed hypometabolism in the bilateral temporo-parietal area, suggestive of AD ( Figure 1D). He showed a rapid cognitive decline and scored 19 on MMSE 6 months after his first visit. He also developed gait disturbance and action induced myoclonus on the bilateral legs. Two years later, he entered nursing home as he became fully dependent on basic daily activities and died at the age of 34. We collected the patient's blood sample when he was 33 years old.

| Case description
The cognitively normal control showed no atrophy on brain MRI ( Figure 1C), and his 18 F-florbetaben amyloid PET showed no significant amyloid deposition in the brain. His APOE genotype was e3/e4. This study was approved by the Institutional Review Board of Samsung Medical Center [1044308-201612-BR-031-05]. We obtained a written consent from each participant and his next of kin.

| Generation of an iPSC line from the AD patient carrying PS1-S170F mutation and differentiation into cortical neurons
Isolated MNCs were reprogrammed using Sendai virus vector (SeVdp) which expresses four reprogramming factors (OCT3/4, SOX2, cMYC and KLF4). 23,29 In our iPSC generation procedure, we routinely pick more than three individual clones and select the best growing clone among them for further analyses, including neuronal differentiation experiments. We generated and characterized a patient-specific iPSC line from the AD patient carrying PS1 mutation (Ser170Phe; PS1-S170F) for the first time ( Figure   S1A-G). In this study, we compared the PS1-S170F iPSC line with the normal control iPSC line which has been fully characterized in our previous study. 23 PS1-S170F patient-derived iPSC line exhibited the typical expression of undifferentiated pluripotent stem cell markers, such as OCT4, SOX2, SSEA4 and TRA-1-81 ( Figure   S1A), which did not carry a SeV integration ( Figure S1F), compared TA B L E 1 Neuropsychological test result of the patient with PS1-S170F mutation with the control iPSC line. Genotyping of the established iPSC line was confirmed using a conventional sequencing method ( Figure 1B). Differentiation potential of iPSC lines was assessed in vitro by three-germ layer marker expression ( Figure S1B) and in vivo by teratoma formation (Figure S1C).
To characterize the cortical neurons derived from the iPSC lines, we

| Increased extracellular and intracellular Aβ levels in PS1-S170F iPSC-derived neurons
To investigate the Aβ levels in the control and PS1-S170F iPSCderived cortical neurons, we measured Aβ 40  However, PS1-S170F iPSC-derived neurons exhibited a dramatic increase in Aβ 42 levels (over 2-fold) from 4 weeks after differentiation.
To detect the Aβ deposits, the iPSC-derived neurons were stained with anti-Aβ 42 antibody at 10 weeks of neuronal differentiation. Notably, confocal microscopy images showed a robust increase in extracellular Aβ 42 deposits in the PS1-S170F iPSC-derived neurons, compared with the control ( Figure 2B).
To measure the insoluble Aβ, we extracted TBS-insoluble/SDS- Taken together, we demonstrated that the PS1-S170F patient iP-

SC-derived neurons exhibited significant increases in extracellular
Aβ levels from 4 weeks of neuronal differentiation, as well as TBSinsoluble/SDS-soluble intracellular Aβ levels at 10 weeks of neuronal differentiation.

| Elevated phospho-tau levels in the PS1-S170F iPSC-derived neurons
In mature neurons, tau protein normally exists as a soluble form in axons. However, in AD the tau protein is hyperphosphorylated and phosphorylated tau (p-Tau) protein is abnormally accumulated in dendrites and cell bodies. 34,35 To detect the p-Tau levels in the iPSCderived neurons, we performed immunocytochemical analysis using antibodies against AT8 (phosphorylated at Ser202/Thr205) and found that PS1-S170F iPSC-derived neurons exhibited significant increase of AT8 expression in neurites and soma, compared with the control (Figure 2D-F). Subsequently, we performed Western blot analysis to measure the AT8 and Tau5 (total tau) expression. We detected the typical bands of AT8 in the fractions from the PS1S170F iPSC-derived neurons, and the AT8 levels (>50 kDa) were strongly increased in the PS1-S170F iPSC-derived neurons compare with the control ( Figure 2G-I).
These results demonstrated that there are high levels of hyperphosphorylated tau which localizes to the cell bodies in the PS1-S170F iPSC-derived neurons compared with the control at 10 weeks of neuronal differentiation.

| Impaired axonal transport of mitochondria and the balance of mitochondrial fusion and fission in the PS1-S170F iPSCderived neurons
Recent studies reported that high levels of Aβ and p-Tau were found to impair axonal transport of mitochondria. 36 To investigate the mitochondrial dynamics, we performed the live cell imaging using Mitotracker (Ds-Red) at 10 weeks of neuronal differentiation. We found that the PS1-S170F iPSC-derived neurons showed a reduced mitochondrial movement, compared with that of the control (Movies S1 and S2). Kymograph analysis on mitochondria was performed using KymographClear, and the quantification analysis of mitochondria velocity was conducted using KymographDirect ( Figure 3A). Both the anterograde and retrograde velocities exhibited a significant F I G U R E 2 Elevated Aβ and p-Tau levels in the PS1-S170F iPSC-derived neurons. A, ELISA detection of Aβ 40 and Aβ 42 secreted from the control and PS1-S170F iPSC-derived neurons into the medium (extracellular), B, Immunocytochemical analysis showing the expression of Aβ deposits using an antibody against Aβ 42 (red), co-stained with Tuj1 (green) and DAPI (blue) at 10 wk of neuronal differentiation. The bottom panels of right side show the z-stack images of the Aβ 42 -positive Aβ deposits (indicated as arrow) in PS1-S170F iPSC-derived neurons. Scale bar: 10 µm. C, TBS-insoluble/SDS-soluble intracellular Aβ 42 and Aβ 40 levels were measured in a total of 1 µg proteins using ELISA from 10-wk-differentiated neurons. D, Immunocytochemical analysis showing the expression of AT8 (p-Tau) (red) and MAP2 (green), counterstained with DAPI (blue) in the iPSC-derived neurons at 10 wk of neuronal differentiation. Expression of AT8 (p-Tau) was indicated in the soma (arrow) and the neurites (arrowhead). Scale bar: 10 µm. E, F, Quantification of the immunocytochemical analysis, normalized against MAP2-positive cells. G-I, Western blot analysis showing an increase of AT8 and the ratio of AT8/ Tau5 in the PS1-S170F iPSC-derived neurons. p <.05 (*), p <.01 (**) and p <.001 (***) F I G U R E 3 Impaired mitochondrial dynamics and autophagy in PS1-S170F iPSC-derived neurons. A, Representative kymographs for mitochondrial movements. Cells were live stained using Mito-tracker at 10 wk of neuronal differentiation. Average of (B) anterograde and (C) retrograde velocity were analysed separately in motile mitochondria from iPSC-derived neurons. In both cases, significant decrease was observed in the PS1-S170F iPSC-derived neurons compared with the control. D, Representative Western blot images from three independent experiments. E, Quantification of marker proteins associated with mitochondrial fusion (Mfn1 and Mfn2) and fission (DRP1 and Fis1). Note that fusion-related protein Mfn1 was decreased, whereas fission-related protein DRP1 was increased in PS1-S170F iPSC-derived neurons compared with the control. F, Immunocytochemical staining showing the expression of LC3b (red), Tuj1 (green) and DAPI (blue) in control and AD iPSC-derived neurons at 10 wk of neuronal differentiation. Note that AD patient iPSC-derived neurons exhibit a dramatic increase of LC3b in the periphery of soma area (arrow), compared with the control group. Scale bar: 10 µm. G, Representative Western blot images from three independent experiments. H, Quantification of the expression of ubiquitination (Ub) and autophagy-related proteins (p62, Beclin1, LC3B, LAMP1 and LAMP2). Note that levels of p62, Beclin1 and LC3b were increased in PS1-S170F iPSC-derived neurons. p <.05 (*) and p <.001 (***) decrease in the PS1-S170F iPSC-derived neurons, compared with the control (Figure 3B,C). The mitochondrial dynamics is determined by the constant process of fusion and fission, and this process is tightly regulated by the balance of fusion and fission-related proteins. 18,37 Therefore, we investigated the expression patterns of mitochondrial fusion and fission-related proteins, including mitochondria fusionrelated protein Mfn1 (membrane proteins mitofusin 1), Mfn2 (membrane proteins mitofusin 2), mitochondria fission-related proteins DRP1 (dynamin-related protein 1) and Fis1 (mitochondrial fission 1 protein). Western blot analysis revealed that Mfn1 expression was dramatically reduced in the PS1-S170F iPSC-derived neurons. On the other hand, DRP1 expression levels were significantly increased in the PS1-S170F iPSC-derived neurons, compared with that of the control ( Figure 3D,E). These results strongly suggest that high levels of Aβ and p-Tau may disrupt the mitochondrial transport, through impaired balance of mitochondrial fusion and fission in the PS1-S170F iPSC-derived neurons.

| Defective autophagy-related clearance in the PS1-S170F iPSC-derived neurons
Autophagy is essential for neuronal survival, as it has an important role in degradative pathway for proteins and organelles. In AD, defective autophagy is evident as the autophagy vacuoles (AVs) are accumulated in the brain tissues of AD patients, which are correlated with the presence of neuritic plaques and filamentous tau. 22,38 Also, it has been reported that increased autophagy induction and defective clearance of Aβ generating AVs results in Aβ accumulation. [20][21]39 Therefore, to investigate whether the autophagosome is also abnormally accumulated in the PS1-S170F iPSC-derived neurons, we performed immunocytochemical analysis at 10 weeks of neuronal differentiation which showed very high levels of Aβ 42 production and p-Tau. We found that the PS1-S170F iPSC-derived neurons exhibited a dramatic increase of LC3b in the periphery of soma area, compared with the control ( Figure 3F). In addition, we measured expression levels of autophagy-related proteins, including Ub (Ubiquitin), p62 (SQSTM1, sequestosome 1; cargo protein marker), Beclin1 (autophagosome membrane formation-related protein), LC3b (light chain 3; autophagosome formation marker), LAMP1 (lysosome-associated membrane protein1) and LAMP2 at 10 weeks of neuronal differentiation. Western blot and its quantification analysis revealed that p62, Beclin1 and the canonical autophagosome marker LC3b were significantly increased in the PS1-S170F iPSCderived neurons ( Figure 3G,H), suggesting that LC3b-dependent autophagy was activated at 10 weeks of neuronal differentiation.
However, there was no change in the lysosomal markers, including LAMP1 and LAMP2 ( Figure 3G,H). Taken together, even if the LC3b-based autophagy system was activated, PS1-S170F iPSC-derived neurons showed very high levels of Aβ 42 and p-Tau expression, implying that the PS1-S170F iPSC-derived neurons are impaired in autophagy-related clearance system at 10 weeks of neuronal differentiation.

| Reduction of Aβ and p-Tau levels by diseasemodifying drug candidate (BACE1 inhibitor)
Aβ is produced by the sequential cleavage of APP by β-site APP cleaving enzyme 1 (BACE1) and γ-secretase. Therefore, these two enzymes are regarded as the most important targets for candidate drugs of AD, and previous studies have shown the rescue effects on Aβ production when the familial AD patient iPSC-derived neurons were treated with BSI (BACE1 inhibitor). 12,40 For candidate drug treatment, we treated the PS1-S170F iPSC-derived neurons with 5 µmol/L LY-2886721, a BACE1 inhibitor, for 5 days after 6 weeks of neuronal differentiation and investigated the effects on Aβ and p-Tau levels ( Figure 4A). Importantly, the levels of Aβ 42 and the ratio of Aβ 42 /Aβ 40 were shown to be decreased significantly after LY2884721 treatment ( Figure 4B-D). Furthermore, the expression of p-Tau (AT8) was also shown to be decreased dramatically in the PS1-S170F iPSC-derived neurons after LY2884721 treatment ( Figure 4E-G). These results demonstrate that our PS1-S170F iPSC-derived neurons are suitable for AD drug screening, and as such, they can serve as a useful resource in the future.

| D ISCUSS I ON
In an attempt to understand AD pathogenesis, we have established and characterized the patient iPSC line from an AD patient carrying PS1-S170F mutation. PS1-S170F mutation has been identified in several independent families with very early-onset dementia in the late 20s. [3][4][5] An autopsy study from three AD patients carrying PS1 S170F mutation showed extensive neuronal loss, abundant neuritic plaques and neurofibrillary tangles involving the entire neocortex. 5 Another autopsy study from a 28-year-old AD patient with PS1 S170F mutation also showed severe Aβ deposition with neurofibrillary tangles in the cerebral cortex. 4 Although we could not obtain brain tissue from our patient, we could assume AD pathology in the patient's brain as he showed PS1-S170F mutation, rapid cognitive decline, family history of early-onset dementia and abnormal neuroimaging findings (cortical atrophy especially in the bilateral parietal areas and hypometabolism in the bilateral temporo-parietal areas). Although PS1-S170F is a well-known mutation causing familial AD, iPSC generation and characterization results have not been reported previously.
We found that the differentiated neurons exhibited the spontaneous repetitive AP of currents clamp mode at 10-12 weeks after differentiation in all of the iPSC-derived neurons ( Figure S2D-H).
These results strongly suggest that the differentiated neurons generated the neuronal signal responses and were matured into functional neurons in vitro at the 10 weeks of neuronal differentiation.
We also found that the PS1-S170F iPSC-derived neurons showed a  Tau (>50 kDa), compared with the controls. 32 We also detected the abnormally accumulated p-Tau (AT8) in the cell bodies and multi-bands of AT8 in the fractions (>50 kDa) that may indicate the hyperphosphorylated-tau 32,37,41 in the PS1-S170F iPSC-derived neurons. In addition, the AT8 levels (>50 kDa), which are maybe related to the localization in the cell bodies were strongly increased in the PS1-S170F iPSC-derived neurons, compared with the control (Figure 2D-I) at 10 weeks of neuronal differentiation.
These results support the hypothesis that accumulation of Aβ peptides may result in the aggregation of hyperphosphorylated-tau proteins in the cell bodies. [27][28]32 Mitochondrial dysfunction is a prominent feature of AD.
Mitochondria are a highly dynamic organelle, and the intracellular population at any time point is derived from a balance between fission and fusion. 17, 36 We observed dramatic decrease in movement of anterograde and retrograde mitochondrial velocity in the PS1-S170F iPSC-derived neurons ( Figure 3A-C and Movies S1 and S2. Western blot analysis revealed that fission associated markers were increased, whereas fusion-related markers were markedly decreased in PS1-S170F iPSC-derived neurons compared with the control ( Figure 3D,E). As extracellular Aβ and phosphorylated tau are implicated in mitochondrial fission and fusion in humans, we speculated that the increased secretion and aggregation of Aβ and phosphorylated forms of tau protein caused this defective mitochondrial axonal transport and imbalance of mitochondrial fission and fusion.
Many reports suggest the possibility of defective autophagy in AD.
It has been demonstrated that autophagy vacuoles (AVs) accumulate in human AD brains and are related to the presence of neuritic plaques and filamentous tau. 22,38 In this study, we observed significantly increased active forms of LC3b-II in the PS1-S170F iPSC-derived neurons at 10 weeks of neuronal differentiation ( Figure 3F-H), which strongly suggests that high levels of Aβ and p-Tau may impair the autophagy-related clearance system at 10 weeks of neuronal differentiation. considered as a more preferable target for anti-Aβ drugs, and several pharmaceutical companies are currently undergoing clinical trials for BACE1 inhibitors (BSIs). 12,40 As AD is heterogenous and drug response may vary in each individual, we need a reliable screening system using patient-specific human cells for investigating the therapeutic effects of the candidate drugs on each individual. Therefore, after we confirmed that PS1-S170F iPSC-derived neuron exhibited the typical AD pathological features, we performed a proof-of-concept experiment to demonstrate the suitability of our AD patient-derived iPSC lines for candidate drug screening. In this study, we selected LY-2886721, a BACE1 inhibitor, to study its effects on Aβ 42 and p-Tau levels. First of all, levels of Aβ 42 and the ratio of Aβ 42 /Aβ 40 showed a significant decrease after 5 µmol/L of LY2884721 treatment, compared with vehicle (VC) neurons ( Figure 4B-D). Interestingly, p-Tau (AT8) also showed a dramatic decrease in the PS1-S170F iPSC-derived neurons after LY2884721 treatment ( Figure 4E-G). However, there was no significant rescue effect on mitochondria and autophagy dysfunction after LY2884721 treatment (data not shown). Taken together, these results strongly suggest that, although clinical trials using BACE1 inhibitor have not succeeded yet, the ADAD patients with PS1-S170F might benefit from this drug treatment.
In summary, we generated an induced iPSC line from AD patient carrying PS1-S170F mutation and then differentiated them into functional cortical neurons. We found high levels of extracellular/ intracellular Aβ and p-Tau in the PS1-S170F iPSC-derived neurons compare with the control. We next investigated impaired mitochondrial dynamics and balance of fusion and fission in PS1-S170F iPSC-derived neurons. Furthermore, we also demonstrated defects of autophagy-related clearance PS1-S170F iPSC-derived neurons.
In addition, levels of Aβ and p-Tau exhibited dramatic reduction by LY-2886721 (BACE1 inhibitor) treatment in the PS1-S170F iPSC-derived neurons. Taken together, we have characterized the pathological features of AD patient carrying mutation for PS1-S170F using iPSC technology and observed a good response to a candidate drug.
Our study is worthwhile as we demonstrated that iPSC-derived neuron may serve as a disease model and drug screening which may pave way for personalized therapy for AD patients in the future.

ACK N OWLED G EM ENTS
We are grateful to TOKIWA-Bio, Ajinomoto and Matrixome for providing the SeVdp vectors, StemFit ® medium and iMatrix-511, respectively, for our iPSC research, and to Drs. John C. Morris and Chang-Seok Ki for their valuable comments on this study.

CO N FLI C T O F I NTE R E S T
JS is the founder and CEO of iPS Bio, Inc.

DATA AVA I L A B I L I T Y S TAT E M E N T
The data that support the findings of this study are available from the corresponding author upon reasonable request.