Dynamin‐like protein 1 cleavage by calpain in Alzheimer’s disease

Abstract Abnormal mitochondrial dynamics contributes to mitochondrial dysfunction in Alzheimer's disease (AD), yet the underlying mechanism remains elusive. In the current study, we reported that DLP1, the key mitochondrial fission GTPase, is a substrate of calpain which produced specific N‐terminal DLP1 cleavage fragments. In addition, various AD‐related insults such as exposure to glutamate, soluble amyloid‐β oligomers, or reagents inducing tau hyperphosphorylation (i.e., okadaic acid) led to calpain‐dependent cleavage of DLP1 in primary cortical neurons. DLP1 cleavage fragments were found in cortical neurons of CRND8 APP transgenic mice which can be inhibited by calpeptin, a potent small molecule inhibitor of calpain. Importantly, these N‐terminal DLP1 fragments were also present in the human brains, and the levels of both full‐length and N‐terminal fragments of DLP1 and the full‐length and calpain‐specific cleavage product of spectrin were significantly reduced in AD brains along with significantly increased calpain. These results suggest that calpain‐dependent cleavage is at least one of the posttranscriptional mechanisms that contribute to the dysregulation of mitochondrial dynamics in AD.

familial AD APP mutations or exposure to soluble Aβ oligomers induced profound mitochondrial fragmentation, ultrastructural damage, and reduced mitochondrial distribution in neuronal processes in neuronal culture (Du et al., 2010;Manczak et al., 2010;Wang et al., 2009;Wang, Su, Siedlak, et al., 2008). These deficits are causally involved in Aβ-induced mitochondrial dysfunction and synaptic abnormalities in primary hippocampal or cortical neurons in vitro . Mitochondrial damage in the form of irregular distribution and round and engorged mitochondria are also documented in AD mouse models (Trushina et al., 2012;Wang et al., 2017). Mitochondrial numbers were reduced and became dystrophic and fragmented in the vicinity of plaques in APP/PS1 mice revealed by real-time imaging study (Xie et al., 2013). Similarly, swollen mitochondria with extensive ultrastructural damage and abnormal distribution are also observed in the brain of AD patients (Hirai et al., 2001;Wang et al., 2009).
Mitochondria are dynamic organelles that undergo fusion and fission controlled by large GTPases: Mitochondrial fission is regulated by cytosolic protein dynamin-like protein 1 (DLP1) which translocates to mitochondrial outer membrane during fission with the assistance of mitochondrial outer membrane proteins such as Fis1 or Mff1 (Mishra & Chan, 2014). Mitochondrial fusion is regulated by mitofusin 1 and 2 (MFN1/2) on the outer mitochondrial membrane and OPA1 on the inner mitochondrial membrane (Mishra & Chan, 2014). Mitochondrial dynamics is critical for maintaining the homeostasis of mitochondria including the tight regulation of their morphology and distribution according to the metabolic need of the cells. Changes in mitochondrial dynamics significantly impact almost all aspects of mitochondrial function, and defects in the large GTPases involved in mitochondrial fission/fusion cause human neurological diseases. Interestingly, our prior studies revealed that all these large GTPase involved in mitochondrial fission (DLP1) and fusion (Mfn1/2 and OPA1) are decreased in the fibroblasts and brain of AD patients and in soluble Aβ oligomer-treated cells Wang et al., 2009). It appears that these changes not only result in mitochondrial fragmentation, but also lead to mitochondrial abnormal distribution since DLP1 overexpression could rescue Aβ-induced depletion of mitochondria in the neuronal processes . Our results were consistent with a prior study where DLP1 knockdown led to depletion of mitochondria in the dendrites and its overexpression helps to repopulate dendrites and synapse with mitochondria (Li, Okamoto, Hayashi, & Sheng, 2004). Reduced levels of fusion GTPases in AD brain were consistently replicated by other groups (Kandimalla & Reddy, 2016;, and our recent study demonstrated that Mfn2 ablation caused neurodegeneration and other ADrelated deficits in the hippocampus and cortex (Jiang et al., 2018).
However, there were inconsistent reports on the levels of DLP1, the fission GTPase, in AD: Several groups confirmed our results of reduced DLP1 in AD brain or fibroblasts (Bossy et al., 2010;Wang, Song, Tan, Albers, & Jia, 2012) but other group demonstrated increased levels of DLP1 in AD brain (Kandimalla & Reddy, 2016;Reddy et al., 2011). While it remains to resolve how DLP1 is changed in AD brain, it was demonstrated that DLP1 interacts with tau and/or Aβ Manczak & Reddy, 2012), which likely plays a critical role in mitochondrial fragmentation observed in AD.
To understand the mechanism(s) underlying the changes in the expression of these fission/fusion GTPases, we investigated the potential involvement of aberrant calcium signaling since calcium dyshomeostasis has been well documented in AD as many of the clinical mutations in the presenilin (PS1/PS2) genes have been shown to disrupt the calcium signaling cascade (LaFerla, 2002). The aberrant calcium signaling leads to excitotoxicity and may be a mechanism of neuronal death in AD. It is well established that Aβ oligomers induce a rapid and sustained increase in intracellular calcium in neurons and Aβ induces neuronal abnormalities including spine loss and synaptic dysfunction likely through the activation of calcium-dependent signaling molecules such as calpain (Li et al., 2011). Interestingly, there is evidence that calpain activation leads to cleavage of the dynamin protein in an AD cell model (Kelly, Vassar, & Ferreira, 2005). Given the similarity between dynamin and dynamin-related proteins involved in mitochondrial fission and fusion, we hypothesized that calpain activation may be involved in the reduction of these mitochondrial fission/fusion proteins in AD. Therefore, in this study we aimed to investigate the posttranscriptional regulation of mitochondrial fission/fusion GTPases with a focus on the effects of calpain activation and reduced levels of DLP1, the key protein involved in mitochondrial fission and distribution. We observed the cleavage of DLP1 by calpain into several fragments at~65 kDa and 50 kDa in size. This cleavage can be triggered by AD-relevant insults such as exposure to glutamate, soluble Aβ oligomers, or agents inducing tau phosphorylation. Cleavage fragments of DLP1 as well as the cytoskeletal protein, spectrin, along with increased active calpain are observed in AD patient brains supporting our theory that calpain is a protease that plays a role in the reduction of mitochondrial proteins seen in AD.

| Cleavage of recombinant DLP1 by calpain
To investigate whether DLP1 is directly cleaved by calpain, we incubated recombinant N-terminal GST-tagged DLP1 with calpain-1 in reaction buffer for various times and concentrations and examined the DLP1 levels by Western Blot analysis. Using a C-terminal DLP1 antibody (i.e., DLP1 C5 antibody against amino acids 560-736 region of DLP1), a significant reduction in the level of full-length GST-DLP1 is observed with 0.05 units (0.05 U) of calpain-1 after a 30-min treatment, which became more significantly reduced with higher units of calpain-1 (Figure 1a). In fact, 30-min treatment with 0.25 or 0.5 units of calpain-1 resulted in total loss of full-length GST-DLP1, reflecting a dose-dependent effect. We also used a GST antibody to detect GST-DLP1 after cleavage by calpain. Interestingly, in addition to the dose-dependent reduction in the level of full-length GST-DLP1, we also observed the appearance of a specific band around 75 kDa with the 30-min treatment of 0.05 units of calpain-1 which peaked with the treatment of 0.25 units of calpain-1 but then decreased with the treatment of 0.5 units of calpain-1. Since the DLP1 was N-terminally tagged with GST, this~75 kDa band likely reflects a~50 kDa N-terminal cleavage fragment of DLP1. The reduction of full-length GST-DLP1 and appearance of cleavage fragments were completely prevented when calpeptin, a specific calpain inhibitor, was present along with calpain, demonstrating the specificity of the calpain cleavage reaction. Treatment with 0.25 units of calpain-1 led to gradual reduction of full-length GST-DLP1 with time until its full cleavage after 10 min as revealed by the C-terminal DLP1 antibody (Figure 1b). Similarly, we also observed the appearance of the 75 kDa fragment as early as 1 min which peaked at 10 min and was completely gone at 15 min ( Figure 1b).
To further investigate this calpain-dependent cleavage of DLP1, whole cell lysate from M17 neuroblastoma cells was incubated with calpain-1 at varying concentrations for 30 min. Using an antibody against N-terminal DLP1 (i.e., DLP1 D6C7 antibody), we confirmed the dose-dependent reduction of full-length DLP1 by calpain-1 (Figure 1c). Importantly, accompanying the reduced full-length DLP1, there was an accumulation of a major band around 50 kDa after calpain-1 treatment. In fact, the accumulation of this band even persisted with up to 4 hr of 1 unit calpain-1 treatment (not shown).
There was also a weak band around 65 kDa in the lysate treated with 0.2 units calpain which was gone in the lysate treated with 0.5 units calpain, likely reflecting a transient intermediate DLP1 fragment generated by calpain cleavage. In fact, these two cleavage products were also present in the M17 lysate at basal condition as faint bands, suggesting such cleavage likely occurs endogenously.
The concurrent treatment with calpeptin abolished both the reduction of full-length DLP1 and the appearance/accumulation of DLP1 N-terminal fragments. These results suggest that DLP1 is a substrate of calpain and that calpain cleavage of DLP1 yields N-terminal fragments of 65 and 50 kDa in size. We therefore used DLP1 N-terminal F I G U R E 1 Dose-and time-dependent cleavage of recombinant DLP1 tagged with GST at N-terminal by calpain-1 and DLP1 cleavage by calpain in M17 neuroblastoma cells. (a) 160 ng recombinant GST-DLP1 was incubated with calpain-1 at 30°C at the indicated concentration for 30 min in the absence/presence of calpeptin, and the remaining GST-DLP1 was visualized by Western Blotting with a C-terminal specific DLP1 antibody (upper panel) or a GST antibody (lower panel). (b) 160 ng recombinant GST-DLP1 was incubated with 0.25 units calpain-1 at 30°C for the indicated duration, and the remaining GST-DLP1 was visualized by Western Blotting with a C-terminal specific DLP1 antibody (upper panel) or a GST antibody (lower panel). (c) Representative Western Blot of DLP1 N-terminal specific antibody (i.e., DLP1 D6C7) in whole cell lysates from M17 cells incubated with calpain-1 at 30°C at the indicated concentrations for 30 min in the absence/presence of calpeptin. Similar data were obtained with three independent experiments antibody to detect these calpain-dependent N-terminal DLP1 fragments in later studies.

| DLP1 cleavage by calpain in glutamate-treated neurons
To investigate calpain-dependent DLP1 cleavage in cells, we examined the DLP1 protein levels in rat primary neurons treated with glutamate, which induces calcium dyshomeostasis and excitotoxicity through the activation of the NMDA and AMPA receptors and is believed to be involved in AD. Under this condition, glutamate treatment led to activation of calpain activity as revealed by the almost complete loss of 250 kDa full-length spectrin protein and the appearance of a major 150 kDa spectrin cleavage product which is specific to calpain activity (Figure 2a

| DLP1 cleavage by calpain in Aβ-treated neurons
To investigate a potential mechanism underlying DLP1 reduction in AD, we examined DLP1 levels in rat primary neurons treated with soluble Aβ oligomers. As expected, treatment with Aβ oligomers led to decreased full-length spectrin and a significant increase in the

| DLP1 cleavage by calpain in okadaic acidtreated neurons
Hyperphosphorylation of tau protein is also involved in the pathogenesis of AD. We further analyzed the impact of phosphorylated tau on calpain cleavage of DLP1. To mimic the neurotoxicity of phosphorylated tau in cell cultures, we treated primary rat neurons with okadaic acid which is an inhibitor of serine/threonine phosphatases 1 and 2A and induces hyperphosphorylation of tau (Kamat, Rai, & Nath, 2013). Interestingly, okadaic acid treatment induced dose-dependent degradation of both full-length spectrin and DLP1 proteins in cultured neurons and the appearance of calpain cleavage products of 150 kDa spectrin fragment and 50 kDa DLP1 fragment

| DLP1 cleavage by calpain is not a general response during mitochondrial fragmentation
It is known that a variety of stresses that disrupt mitochondrial function also cause mitochondrial fragmentation (De Vos, Allan, Grierson, & Sheetz, 2005). To investigate whether calpain-dependent DLP1 is F I G U R E 2 Calpain-dependent cleavage of spectrin and DLP1 in glutamate-treated rat primary cortical neurons. (a) Representative Western Blots of DLP1 in primary cortical neurons (DIV12) treated with 50 µM glutamate in the absence/ presence of 50 µM calpeptin for 4 hr. Spectrin was probed as a positive control for calpain activation; β-tubulin was probed as an internal loading control. (b, c) Quantitative analysis of levels of 150 kDa cleavage fragment (CF) of spectrin CF (b) and 50 kDa cleavage fragment (CF) of DLP1 (c). The expression levels of all proteins were normalized to tubulin and expressed as a relative to nontreated control values of each respective protein.
Data are presented as the mean ± SEM of three independent experiments (*p < 0.05, **p < 0.001) a general response during mitochondrial fragmentation when mitochondrial function is disrupted, we treated rat primary cortical neurons with rotenone (10-100 nM), a specific inhibitor of complex I, and FCCP (0.5-2 µM), a widely used mitochondrial protonophore that uncouples electron transport and oxidative phosphorylation, at a range of concentrations that disrupt mitochondrial function and cause mitochondrial fragmentation (Barsoum et al., 2006;De Vos et al., 2005) and investigated the calpain-dependent cleavage of spectrin and DLP1 by Western Blot analysis. Our results indicated that neither rotenone nor FCCP caused any changes in the 150 k Da calpain-dependent cleavage product of spectrin or increase in the 50 kDa cleavage product of DLP1 (Supporting Information Figure S1), suggesting that DLP1 cleavage by calpain is not a general response during mitochondrial fragmentation.

| Calpain-dependent cleavage of DLP1 in neurons of APP transgenic mouse model
We next investigated whether the calpain-dependent cleavage of DLP1 is present in neurons of CRND8 mice, a widely used APP transgenic (Tg) mouse model expressing the APP Swedish (KM670/ 671NL) and APP Indiana (V717F) mutations that shows early signs of memory impairment as well as striking amyloid plaque pathology (Yin et al., 2018). In the primary cortical neurons isolated from CRND8 mice, we observed significant presence of the 150 kDa calpain-dependent cleavage fragment of spectrin compared to neurons from their nonTg littermate controls (Figure 5a,c), suggesting a higher calpain activity in the CRND8 neurons. In conjunction with activated calpain, we also observed a significant presence of the 65 and 50 kDa cleavage fragments of DLP1 (Figure 5a,b). Furthermore, treatment with calpeptin inhibited the increased levels of 150 kDa cleavage fragment of spectrin as well as the 65 and 50 kDa DLP1 cleavage fragments (Figure 5a-c).

| DLP1 cleavage in AD brains
Our prior studies demonstrated that protein levels of DLP1 are significantly reduced but mRNA levels of DLP1 are not changed in the brain of human AD patients compared to age-matched control patients (Wang et al., 2009), suggesting the involvement of posttranscriptional regulation of DLP1 expression. To investigate whether calpain activation is involved in the reduced expression of DLP1 in AD brain, we first investigated the levels and activity of calpain in brain homogenates from AD and age-matched control patients by performing Western Blot analysis of calpain and calpaindependent cleavage products of spectrin. As an 80 kDa protease, calpain is activated by its autoproteolytic cleavage into 76-and 58-kDa fragments. As reported previously (Atherton et al., 2014), the calpain antibody used in this study only recognized a single prominent band around 76 kDa in both AD and control brain homogenates, corresponding to its active form. Quantification analysis revealed that the level of this active form of calpain is significantly increased in AD brain (Figure 6a,b). Both the full-length and calpaindependent 150 kDa cleavage fragments of spectrin were present in both AD and control samples. There was a trend (p = 0.07) of decrease in the level of full-length spectrin and a significant decrease in the level of 150 kDa cleavage product in the brain tissues from AD patients as compared to that from the age-matched nonAD  (Figure 6a,c,d). We also probed the DLP1 cleavage products in these brain homogenates. Similarly, our N-terminal DLP1 antibody revealed that both full-length and the two cleavage fragments (i.e., 65 and 50 kDa bands) of DLP1 were also present in AD and control sample (Figure 6a). Consistent with our previous report (Wang et al., 2009), there was a significant decrease in the level of full-length DLP1 (Figure 6e). Moreover, the levels of the cleavage fragments of DLP1 decreased in the AD samples as compared to the age-matched nonAD controls samples (Figure 6f). Relative levels of DLP1 and calpain were also compared in hippocampal neurons in adjacent serial sections of AD and control cases using immunocytochemistry ( Figure 6g). Neuronal staining for DLP1 was highest in the control cases and very weak staining was seen in the AD cases (Figure 6g). Conversely, very little calpain was detected in the same neurons in the control cases, while the AD cases had more neurons with calpain staining, and at higher levels than was found in the controls (Figure 6g).

| DISCUSSION
In this study, we investigated the association between DLP1 levels and calpain activation in the context of AD models and AD brain. By employing the in vitro calpain cleavage assay using GST-DLP1 recombinant protein and cell lysate from M17 neuroblastoma cells, we demonstrated that DLP1 is indeed a substrate of calpain which produced specific N-terminal DLP1 fragments. Furthermore, various AD-related insults such as exposure to glutamate, soluble Aβ oligomers, or reagents inducing tau hyperphosphorylation (i.e., okadaic acid) led to DLP1 cleavage accompanied by calpain activation in primary cortical neurons. DLP1 cleavage fragments were also present in cortical neurons of CRND8 APP transgenic mice. Importantly, calpeptin, a potent small molecule inhibitor of calpain, prevented DLP1 cleavage in all these models, demonstrating the specific involvement of calpain activation in DLP1 cleavage in these models. Lastly, we found the presence of N-terminal DLP1 fragments in the human brains and the levels of both full-length and N-terminal fragments of DLP1 were significantly reduced in AD brains. These results suggest that calpain activation is at least one of the posttranscriptional mechanisms that contribute to the changes in the levels of large GTPases involved in mitochondrial fission/fusion and dysregulation of mitochondrial dynamics in AD.
The major finding in this study is that we firmly established Calpain activation has been closely linked with AD as it has been shown to cleave: APP that regulates Aβ production (Morales- Corraliza et al., 2012), tau leading to production of neurotoxic fragments (Ferreira & Bigio, 2011), synaptic proteins like dynamin-1 (Kelly et al., 2005), and NMDA receptor subunit NR2B important for synaptic health (Simpkins et al., 2003). Our results thus added reduced DLP1 as a victim of enhanced calpain activation in AD which affect mitochondrial dynamics and contribute to mitochondrial dysfunction during AD pathogenesis. Calpain inhibition has been pursued as a therapeutic target for AD (Medeiros et al., 2012) which therefore could also potentially have positive impact on mitochondrial dynamics. Imbalance in kinase and phosphatase results in tau hyperphosphorylation and plays an important role in the pathogenesis of AD. Fission activity of DLP1 is also regulated by phosphorylation at several sites, and cytosolic calcium signaling could either increase DLP1 phosphorylation at Ser616 by Ca 2+ /calmodulin-dependent kinase II (Xu et al., 2016) or decreased DLP1 phosphorylation at Ser637 through calcineurin (Cereghetti et al., 2008). While it was demonstrated that DLP1 phosphorylation at Ser616 is increased in AD brain (Wang et al., 2009), how phosphorylation of DP1 at Ser637 is changed in AD is not clear. Furthermore, whether and how the phosphorylation at these sites affects or relates to calpain cleavage of DLP1 remains to be determined.
Previous studies of postmortem AD patient brains show increased calpain activity in end-stage AD brain (Atherton et al., 2014;Jin et al., 2015;Saito, Elce, Hamos, & Nixon, 1993) as well as elevated levels of cleaved products of several calpain substrates (Atherton et al., 2014;Liu et al., 2005). In the current study, while we also observed increased levels of active calpain in AD brain, we observed clear reduction, sometimes a complete depletion, in the levels of full-length spectrin or DLP1 in the brains from AD patients, and also found significantly reduced levels of calpain-specific 150 kDa fragment of spectrin along with reduced levels of two Nterminal fragments of DLP1. This complete depletion of DLP1 fulllength and N-terminal fragments in nearly all of the AD samples we examined, in our opinion, implicated excessive calpain activation that resulted in more complete degradation of DLP1 in AD. Along this reasoning, it was demonstrated that calpain activation is associated with disease progression through various Braak stages and the levels of full-length and calpain-dependent cleavage products of certain substrates such as CAST peaked at earlier stages but both declined at later stage (Kamat et al., 2013). It is therefore of interest to further determine how the levels of DLP1 and its cleavage fragments change along different stages during the course of AD. Nevertheless, our study does not preclude the potential involvement of other proteases in the cleavage of DLP1. For example, studies have shown that caspases may indirectly regulate cleavage of mitochondrial GTPases such as OPA1 (Loucks et al., 2009) and DLP1 during apoptosis (Estaquier & Arnoult, 2007).
The presence of 65 and 50 kDa DLP1 fragments at physiological conditions, especially in the brain of elderly controls, may be interesting. The function of DLP1 has been thoroughly explored in both yeast and mammals as it is similar to the classic dynamins in membrane scission and remodeling of mitochondria (Sesaki, Adachi, F I G U R E 5 Calpain-dependent cleavage of spectrin and DLP1 in primary cortical neurons isolated from CRND8 APP transgenic mice. (a) Representative Western Blots of DLP1 in primary cortical neurons (DIV12) isolated from either CRND8 mice or littermate control mice treated with/without 50 µM calpeptin for 4 hr. Spectrin was probed as a positive control for calpain activation; actin was probed as an internal loading control. (b, c) Quantitative analysis of levels of 150 kDa cleavage fragment (CF) of spectrin (c) and 50 kDa cleavage fragment (CF) of DLP1 (b). The protein levels were normalized to actin and expressed as a relative to nontreated control values of each respective protein. Data are presented as the mean ± SEM of three independent experiments (*p < 0.05, **p < 0.001) Kageyama, Itoh, & Iijima, 2014). It is a cytosolic protein that forms dimers and tetramers and is recruited to the mitochondrial surface through interactions with various outer mitochondrial proteins such as mitochondrial fission factor (Mff), Fis1, and mitochondrial elongation factor (MIEF1/2; Sesaki et al., 2014). Crystal structures show that DLP1 assembles into spirals which mediates mitochondrial scission (Mears et al., 2011). DLP1 contains four domains: an N-terminal GTPase domain, middle domain, variable domain, and C-terminal GTPase effector domain (GED; Otera, Ishihara, & Mihara, 2013). The middle domain is important in the regulation of DLP1 self-assembly into dimers and tetramers (Frohlich et al., 2013). So it can stand to reason that cleavage of DLP1 somewhere in the middle domain resulting in 50 kDa and 65 kDa fragments as shown in our data could lead to dysfunctional oligomerization of DLP1 and therefore affect its function in regulating mitochondrial fission. While DLP1 knockdown could lead to abnormal mitochondrial distribution, how DLP1 cleavage fragments may affect mitochondrial transport and distribution is not clear. Further studies will be needed to map the specific cleavage sites and their impact on DLP1 functions.
In conclusion, this study established DLP1 as a calpain substrate and suggested that calpain activation could contribute to reduced DLP1 levels and mitochondrial dynamics abnormalities and mitochondrial dysfunction in AD.

| Human brain tissues
Samples were obtained at autopsy and, following approved IRB protocols, were received from the Brain Bank at Case Western Reserve University and from the NIH Neurobiobank in accordance with the institutional bioethics guidelines. The diagnosis of Alzheimer's F I G U R E 6 Decreased level of DLP1 in Alzheimer's disease (AD) brain. (a) Expression of DLP1 and spectrin in AD and age-matched control brains was analyzed by Western Blotting with antibodies to calpain, spectrin, and DLP1. Calpain antibody only recognizes a specific band around 76 kDa corresponding to active calpain. GAPDH or actin blot was used as internal loading control. (b-e) Quantitative analysis of levels of 76 kDa active calpain (b), full-length (c), or 150 kDa cleavage fragment (d) of spectrin and full-length (e) or 50 kDa cleavage fragment (f) of DLP1. The protein levels were normalized to GAPDH or actin and expressed as a relative to control values of each respective protein. Data are presented as the mean ± SEM of three independent experiments (*p < 0.05, **p < 0.001). (g) Representative immunocytochemistry of DLP1 and calpain in the hippocampus in adjacent serial sections of AD (N = 6) and control cases (N = 5) revealed reduced neuronal DLP1 immunoreactivity associated with increased neuronal calpain immunoreactivity in AD hippocampus compared to age-matched control cases. *The landmark vessel in adjacent sections of AD or control disease was obtained according the NINCDS-ADRDA group criteria (McKhann et al., 1984)

| Primary rat and CRND8 mouse neuronal culture
Primary cultures of both rat and mouse cortical neurons were prepared from the brains of embryonic pups at day 18 and day 16, respectively, as previously reported (Kaech & Banker, 2006;Zhao et al., 2017) with some modification. In brief, the cerebral cortices were dissected from the embryonic brain and dissociated by trypsinization for 10 min at room temperature. The resulting cell suspensions were resuspended in neurobasal medium supplemented with B27 (Gibco-BRL, Waltham, MA, USA) and penicillinstreptomycin (Thermo Fisher Scientific, Waltham, MA, USA) and plated onto poly-D-lysine (Sigma, St. Louis, MO, USA) coated plastic plates. Neurons were maintained at 37°C in 5% CO 2 for 12 days prior to chemical treatment. After 12 days in vitro (DIV), the neuron culture medium was replaced with fresh medium containing treatments of Aβ, glutamate, and calpeptin as described in the paper. Arbor, MI, USA) were added to neuronal cultures at the indicated final concentrations. Aβ oligomers were prepared as previously described (Song et al., 2014). Briefly, lyophilized Aβ peptides were dissolved in dimethyl sulfoxide, diluted in neurobasal without phenol red (Gibco-BRL) to a final concentration of 1 μM, and incubated at 4°C for 16 hr. Prepared Aβ oligomers were added to neuronal cultures for the indicated times.

| Western Blotting
Samples of frozen cortical gray matter of AD (N = 7), and age-and gender-matched control cases (N = 7) were homogenized and lysed with RIPA Buffer (Abcam) plus 1 mM phenylmethylsulfonyl fluoride (Sigma) and Protease Inhibitor Cocktail (Sigma) and centrifuged for 10 min at 16,000 × g at 4°C. Protein concentrations of the lysates from total cortical gray matter homogenates were determined by the bicinchoninic acid assay method (Pierce, Rockford, IL, USA). Equal amounts of proteins (20 μg) were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and transferred to immobilon membranes. After blocking with 10% nonfat dry milk, primary and secondary antibodies were applied and the blots developed with enhanced chemiluminescence (Santa Cruz).

| Immunocytochemical procedures
Hippocampus samples from AD (n = 6) and neuropathologically normal cases (n = 5) were fixed in formalin and paraffin embedded. Tissue sections 6 micron thick were used for immunostaining as described previously (Jiang et al., 2018). Antigen retrieval was performed in a pressure cooker using acetate buffer (Biocare Medical).
Serial adjacent sections were immunostained for DLP1 and calpain-1 with identical conditions for all cases used. Images of the CA2 neurons were obtained on a Zeiss Axioskop and densitometric analysis performed using Axiovision software to determine staining intensity.

| Statistical analysis
Data are presented as means ± standard error of the mean (SEM) of at least three independent experiments and, where appropriate, were analyzed using one-way analysis of variance (ANOVA) or Student's t test. p < 0.05 was considered statistically significant.

ACKNOWLEDG MENTS
The work was supported in part by the National Institutes of Health (NS083385, AG049479 and AG056363 to X.Z., and AG058015 to W.W.); Dr. Robert M. Kohrman Memorial Fund to X.Z.; Alzheimer's Association (AARG-16-443584 to X.Z.); and S.J was supported by training grant NS077888. Some Alzheimer's disease tissue samples were obtained from the NIH Neurobiobank at the University of Maryland.

CONF LICT OF I NTEREST
None declared.

AUTHOR CONTRIBU TI ONS
X.Z. conceived and directed the project, analyzed/interpreted the results, and wrote the manuscript. S.J., C.S., F.T, and W.W. designed and carried out experiments, analyzed results, and generated figures.
S.J. and W.W. drafted manuscript. All authors read and commented on manuscript drafts.