RCAN1 Inhibits BACE2 Turnover by Attenuating Proteasome-Mediated BACE2 Degradation

Qiu, Kaixin; Wang, Shuai; Wang, Xin; Wang, Fengting; Wu, Yili

doi:https://doi.org/10.1155/2020/1920789

BioMed Research International

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Abstract Introduction Materials and Methods Results Discussion Conclusions Data Availability Conflicts of Interest Authors’ Contributions Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2020 | Article ID 1920789 | https://doi.org/10.1155/2020/1920789

RCAN1 Inhibits BACE2 Turnover by Attenuating Proteasome-Mediated BACE2 Degradation

Kaixin Qiu,^1,2,3Shuai Wang,^2,3Xin Wang,^2,3Fengting Wang,^2,3and Yili Wu^2,3

Academic Editor: Anna Chiarini

Received04 Jan 2020

Accepted22 May 2020

Published05 Jun 2020

Abstract

Amyloid-β protein (Aβ) is the main component of neuritic plaques, the pathological hallmark of Alzheimer’s disease (AD). β-site APP cleaving enzyme 1 (BACE1) is a major β-secretase contributing to Aβ generation. β-site APP cleaving enzyme 2 (BACE2), the homolog of BACE1, is not only a θ-secretase but also a conditional β-secretase. Previous studies showed that regulator of calcineurin 1 (RCAN1) is markedly increased by AD and promotes BACE1 expression. However, the role of RCAN1 in BACE2 regulation remains elusive. Here, we showed that RCAN1 increases BACE2 protein levels. Moreover, RCAN1 inhibits the turnover of BACE2 protein. Furthermore, RCAN1 attenuates proteasome-mediated BACE2 degradation, but not lysosome-mediated BACE2 degradation. Taken together, our work indicates that RCAN1 inhibits BACE2 turnover by attenuating proteasome-mediated BACE2 degradation. It advances our understanding of BACE2 regulation and provides a potential mechanism of BACE2 dysregulation in AD.

1. Introduction

Alzheimer’s disease (AD) is the most common neurodegenerative disease in the elderly. Neuritic plaques are the major pathological hallmark of AD, while amyloid-β protein (Aβ) is the main component of neuritic plaques [1]. Aβ is derived from amyloid-β precursor protein (APP) by sequential cleavage of β- and γ-secretase [2–4]. β-site APP cleaving enzyme 1 (BACE1) is the major β-secretase contributing to Aβ generation [2]. Sun et al. reported that β-site APP cleaving enzyme 2 (BACE2), the homolog of BACE1 cleaves APP at the Phe20 site to yield a C-terminal fragment (CTF) with 80 amino acids (CTFθ or C80), which is further cleaved by γ-secretase to release a truncated Aβ [3, 5, 6]. Thus, BACE2 is considered as a θ-secretase. Consistently, overexpression of BACE2 in primary neurons derived from Swedish mutant APP transgenic mice significantly reduces Aβ generation [6]. Moreover, BACE2 prevents neuronal apoptosis by cleaving a potassium channel at the surface of the neuronal plasma membrane [7].

However, growing evidence indicates that BACE2 may be implicated in the pathogenesis of AD. First, our recent study demonstrated that the binding of clusterin to the juxtamembrane helix (JH) of APP triggers BACE2-mediated β-cleavage of APP, indicating that BACE2 has comparable β-secretase activity to that of BACE1. Both BACE2 and clusterin are elevated in aged mouse brains, indicating that increased clusterin in the elderly may facilitate the β-secretase activity of BACE2, contributing to the pathogenesis of AD [8]. In addition, increased BACE2 expression and activity are detected in the neurons of AD brains [9]. Genetic data shows that BACE2 is associated with AD risk [10]. For example, the BACE2 haplotype associates with AD, while SNPs in BACE2 (e.g., rs2252576, rs2837990, and rs7281733) predispose to early onset of AD in Down syndrome. Recently, the association between SNPs in BACE2 and AD was reported in APOE ε4 noncarriers, which may be mediated by altered BACE2 expression-mediated Aβ generation and clearance [11].

Regulator of calcineurin 1 (RCAN1), also called Down syndrome critical region 1 (DSCR1), is highly expressed in the human brain and heart [12]. By alternative splicing and alternative promoter usage, two major transcripts are generated, transcript 1 and transcript 4, RCAN1.1 and RCAN1.4 [13–15]. Transcript 1 encodes two isoforms by alternative usage of two translational start sites, the long isoform of RCAN1.1 (RCAN1.1L) and the short isoform of RCAN1.1 (RCAN1.1S), which consist of 252 and 197 amino acids, respectively [16]. RCAN1.1L is the major isoform of RCAN1.1, which is upregulated in AD. However, RCAN1.1S is hard to be detected. Transcript 4 encodes RCAN1.4 with 197 amino acids. RCAN1.1L (hereinafter referred to as RCAN1) is highly expressed in the brains and is upregulated in AD brains. Increased RCAN1 plays a pivotal role in AD pathogenesis [15] including neuronal loss [17, 18], tau hyperphosphorylation [19, 20], and synaptic dysfunction [21, 22]. Previous study showed that RCAN1 significantly increases BACE1 expression, while BACE1 and BACE2 share an approximate 75% similarity of amino acids. However, the role of RCAN1 in BACE2 regulation remains elusive. In this study, we reported that RCAN1 increases BACE2 protein levels. Moreover, RCAN1 inhibits the turnover of BACE2 protein. Furthermore, RCAN1 attenuates proteasome-mediated BACE2 degradation, but not lysosome-mediated BACE2 degradation. Taken together, our work indicates that RCAN1 inhibits BACE2 turnover by attenuating proteasome-mediated BACE2 degradation, leading to the upregulation of BACE2. It advances our understanding of BACE2 regulation and provides a potential mechanism of BACE2 dysregulation in AD.

2. Materials and Methods

2.1. Cell Culture and Transfection

Human embryonic kidney HEK293 cells and HRNLM cells obtained from Dr. Weihong Song’s lab were cultured in high-glucose DMEM containing 10% fetal bovine serum and 1% penicillin-streptomycin. HRNLM cells are derived from HEK293 cells, which stably overexpress RCAN1 with a C-terminal myc tag. All cells were maintained at 37°C with 5% CO₂ in an incubator as described previously [16, 23, 24]. pBACE2-mycHis refers to pZ-BACE2mycHis in this study, which is constructed previously [25]. Transient transfection was performed by using the polyetherimide (PEI) method as described previously [26, 27]. Briefly, HEK293 and HRNLM cells were seeded 24 h prior to transfection. The regular culture medium was replaced with high-glucose DMEM without serum 1 h prior to transfection. 6 h after transfection, the medium was replaced with regular culture medium.

2.2. Pharmacological Treatments

HEK293 cells and HRNLM cells were transiently transfected with pBACE2-mycHis. 24 h after transfection, the cells were equally seeded into 6 cm culture dishes. 48 h after transfection, the cells were treated with different drugs, respectively. To measure the half-life of BACE2, 100 μg/mL cycloheximide (CHX) was used to treat cells as described previously [16, 23, 24]. After treatment, the cells were harvested at 0, 2, 4, 8, and 12 h time points, respectively. The lysosomal inhibitor NH₄Cl was applied to determine the involvement of the lysosome pathway in BACE2 degradation, while the proteasomal inhibitor N-carbobenzoxy-L-leucinyl-L-leucinyl-L-leucinal (MG-132) was applied to determine the involvement of proteasome pathway in BACE2 degradation, respectively [16, 23, 28–30]. MG-132 and NH₄Cl were purchased from Sigma.

2.3. Western Blotting

Cells were lysed with RIPA-Doc buffer (Tris-HCl, 50 mM; NaCl, 150 mM; Triton X-100, 1%; deoxycholate, 1%; and SDS, 0.1%; supplemented with 1/100 protease inhibitors). Cell lysates were separated by 10% Tris-glycine SDS-PAGE gels and transferred to PVDF membranes. The membranes were blocked in 5% nonfat milk for 1 h, then incubated overnight at 4°C with anti-myc (9E10), anti-GFP, anti-RCAN1, and anti-β-actin (AC-15) antibodies, respectively [23]. The membranes were washed in TBST with 0.1% Tween-20 and incubated with HRP-labeled goat anti-mouse or HRP-labeled goat anti-rabbit antibodies at room temperature for 1 h. Anti-myc antibody 9E10 was obtained from Abcam. β-Actin antibody AC-15, HRP-labeled goat anti-rabbit antibody, and HRP-labeled goat anti-mouse antibody were obtained from ZSGB-BIO. Anti-GFP antibody was purchased from Proteintech Group. Anti-RCAN1 antibody was purchased from Sigma. The image was obtained by using FluorChem R imaging system.

2.4. Statistical Analysis

The protein expression was quantified by using ImageJ. Student’s test or two-way ANOVA was used for data analysis with three or more independent experiments. was considered as a significant difference.

3. Results

3.1. RCAN1 Increases BACE2 Expression

To explore the effect of RCAN1 on BACE2 regulation, HEK293 cells and HRNLM cells (i.e., HEK293 cells stably overexpressing myc-tagged RCAN1) were cotransfected with plasmids pEGFP and pBACE2-mycHis at the ratio of 1 : 5. Exogenous GFP was used as a control for transfection efficiency in both cell lines. We found that the level of BACE2 protein was significantly higher in HRNLM cells than in HEK293 cells, while the levels of GFP were similar in HEK293 cells and HRNLM cells (Figure 1(a)). After normalization to the level of GFP, BACE2 was significantly increased to -fold in HRNLM cells comparing with that in HEK293 cells (Figure 1(b)). It indicated that RCAN1 significantly upregulated BACE2 expression.

(a)

(b)

3.2. RCAN1 Inhibits BACE2 Turnover

Protein degradation plays an important role in protein homeostasis. To determine whether RCAN1 affects BACE2 turnover rate contributing to its upregulation, the degradation rate of BACE2 was examined in HEK293 and HRNLM cells. HEK293 cells and HRNLM cells were transfected with the plasmid pBACE2-mycHis. 24 hours after transfection, cells were divided equally into five dishes. 48 hours after transfection, the cells were treated with 100 μg/mL cycloheximide (CHX), a potent inhibitor of protein synthesis, to block BACE2 synthesis [16, 23, 29, 31]. The cells were harvested at 0, 2, 4, 8, and 12 h after CHX treatment, and western blot analysis was performed to determine the level of remaining BACE2 protein relative to the BACE2 level at 0 h time point. BACE2 level was decreased to , , , and at 2, 4, 8, and 12 h time points in HEK293 cells (Figures 2(a) and 2(c)). It indicated that the half-life of BACE2 was approximately 6 h in HEK293 cells. In HRNLM cells, BACE2 level was decreased to , , , and at 2, 4, 8, and 12 h time points, respectively, indicating that the half-life of BACE2 was approximately 12 h in HRNLM cells (Figures 2(b) and 2(c)). Our data indicated that RCAN1 inhibited BACE2 turnover by prolonging its half-life.

(a)

(b)

(c)

3.3. RCAN1 Has No Effect on Lysosome-Mediated BACE2 Degradation

As the previous study showed that BACE2 degradation is mediated by the lysosome pathway, the effect of RCAN1 on lysosome-mediated BACE2 degradation was examined. HEK293 cells and HRNLM cells were transfected with pBACE2-mycHis, respectively. 24 hours after transfection, cells were divided equally into four dishes. 48 hours after transfection, the lysosomal inhibitor NH₄Cl was applied to the two cell lines. The cells were treated with 0, 10, 25, or 50 mM NH₄Cl for 24 h. Western blot analysis showed that NH₄Cl treatment significantly increased BACE2 levels to -, -, and -fold, respectively, compared with those of the control in HEK293 cells, (Figures 3(a) and 3(c)). In HRNLM cells, the level of BACE2 protein was increased to -, -, and -fold, respectively, , when the cells were treated with 10, 25, or 50 mM NH₄Cl (Figures 3(b) and 3(c)). However, no significant difference of relative BACE2 changes was detected between HEK293 cells and HRNLM cells when the same dose of NH₄Cl was applied (Figures 3(a)–3(c)). It indicated that the increase of RCAN1 has no effect on lysosome-mediated BACE2 degradation.

(a)

(b)

(c)

3.4. RCAN1 Attenuates Proteasome-Mediated BACE2 Degradation

As the previous study showed that BACE2 is also degraded via the proteasome pathway, the effect of RCAN1 on proteasome-mediated BACE2 degradation was further investigated [32]. HEK293 cells and HRNLM cells were transfected with pBACE2-mycHis, respectively. 24 hours after transfection, cells were divided equally into four dishes. 48 hours after transfection, the proteasomal inhibitor MG-132 was applied to two cell lines. The cells were treated with 0, 10, 15, and 20 μM MG-132 for 12 h, respectively. MG-132 treatment significantly increased BACE2 levels to -, -, and -fold, respectively, compared with those of the control in HEK293 cells, (Figures 4(a) and 4(c)). In HRNLM cells, the level of BACE2 protein was increased to -, -, and -fold, respectively, , when the cells were treated with 10, 15, and 20 μM MG-132 (Figures 4(b) and 4(c)). Importantly, the increase of BACE2 in HEK293 cells was much higher than that in HRNLM cells when same dose of MG-132 was applied, - vs. -fold at the dose of 10 μM, - vs. -fold at the dose of 15 μM, and - vs. -fold at the dose of 20 μM, (Figures 4(a)–4(c)). It indicated that the increase of RCAN1 attenuates proteasome-mediated BACE2 degradation.

(a)

(b)

(c)

4. Discussion

The dysregulation of BACE2 is observed in AD. However, the underlying mechanisms remain elusive. Our data showed that RCAN1 increases BACE2, while RCAN1 upregulation in AD is mediated by different mechanisms. It indicates that multiple stresses and risk factors of AD may implicate in the increase of BACE2 in AD, which is mediated by RCAN1 upregulation. For example, the stress hormone glucocorticoids are increased in AD, which are stimulated to be released by various stressful risk factors of AD [33]. The glucocorticoid significantly increases RCAN1 transcription mediated by a glucocorticoid response element in the RCAN1 promoter region [24, 34 ,35], indicating that stress hormone may contribute to the BACE2 upregulation. In addition, ApoE allele4, a known risk factor of AD, markedly increases RCAN1 expression, indicating that it may also promote BACE2 expression [36]. NF-κB promotes RCAN1 transcription, indicating that inflammation may play a key role in the upregulation of RCAN1 and subsequent BACE2 upregulation in AD [37]. The putative transcription factor HIF-1 binding site within the RCAN1 promoter region may mediate the alteration of RCAN1 expression under hypoxia, ischemia, and stroke conditions, promoting AD development. It is also supported by the fact that hypoxia, ischemia, and stroke are also risk factors of AD. Moreover, chronic hyperglycemia, the characteristic of diabetes, increases RCAN1 expression in pancreatic β cells, suggesting that chronic hyperglycemia may also contribute to RCAN1 elevation in the brain [38]. As both stroke and diabetes are age-associated diseases, their role in RCAN1 regulation may also be affected by the aging process [39]. The above evidence suggests that stroke and diabetes may promote the upregulation of BACE2 mediated by increased RCAN1 expression. In fact, inhibition of BACE2 counteracts IAPP-induced β cell loss and functional defects [40, 41]. Furthermore, calcineurin and GSK3β activities are significantly altered in AD brains, which are involved in regulating RCAN1 degradation rate by modulating its phosphorylation status [42–48]. It indicates that the dysregulation of calcineurin and GSK3β may be implicated in the increase of BACE2 in AD, which is mediated by RCAN1 upregulation, although further investigation is needed.

Our data showed that RCAN1-induced increase of BACE2 expression is caused by attenuating proteasome-mediated BACE2 degradation. Although the mechanism of RCAN1 attenuating proteasome-mediated BACE2 degradation is not clear, the following mechanisms may be implicated in RCAN1 attenuating the proteasome-mediated BACE2 degradation. Previous studies showed that RCAN1.1S could stabilize oligosaccharyltransferase (OST) by interacting with the OST component ribophorin I (RPN I) [49]. It is possible that RCAN1 may stabilize BACE2 by directly interacting with BACE2. In addition, RCAN1.1S promotes the N-glycosylation of BACE1 and BACE2, a type of protein posttranslational modification, which is associated with their upregulation [49]. It is possible that RCAN1 may also facilitate BACE2 N-glycosylation contributing to the increase of BACE2 expression. Moreover, RCAN1 not only regulates the activity of various transcriptional factors, e.g., NFAT, but also shows RNA binding activity, which may be implicated in the increase of BACE2 by regulating the expression of OST components or ubiquitin-proteasome system- (UPS-) associated molecules.

5. Conclusions

In conclusion, our work indicates that RCAN1 inhibits BACE2 turnover by attenuating proteasome-mediated BACE2 degradation, leading to the upregulation of BACE2. It advances our understanding of BACE2 regulation and provides a potential mechanism of BACE2 dysregulation in AD. Moreover, it provides a novel insight that RCAN1 dysregulation promotes the pathogenesis of AD through BACE2 7in addition to other known mechanisms. It suggests that RCAN1 and BACE2 may be potential targets for AD treatment.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare no conflict of interest.

Authors’ Contributions

Kaixin Qiu and Shuai Wang contributed equally to this work.

Acknowledgments

This research was funded by the National Natural Science Foundation of China (NSFC), Grant 81771147 to YW, and the Natural Science Foundation of Shandong Province, Grant ZR2019PC038 to SW.

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Copyright © 2020 Kaixin Qiu et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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