BACE2 suppression in mice aggravates the adverse metabolic consequences of an obesogenic diet

Objective Pancreatic β-cell dysfunction is a central feature in the pathogenesis of type 2 diabetes (T2D). Accumulating evidence indicates that β-site APP-cleaving enzyme 2 (BACE2) inhibition exerts a beneficial effect on β-cells in different models of T2D. Thus, targeting BACE2 may represent a potential therapeutic strategy for the treatment of this disease. Here, we aimed to investigate the effects of BACE2 suppression on glucose homeostasis in a model of diet-induced obesity. Methods BACE2 knock-out (BKO) and wild-type (WT) mice were fed with a high-fat diet (HFD) for 2 or 16 weeks. Body weight, food intake, respiratory exchange ratio, locomotor activity, and energy expenditure were determined. Glucose homeostasis was evaluated by glucose and insulin tolerance tests. β-cell proliferation was assessed by Ki67-positive nuclei, and β-cell function was determined by measuring glucose-stimulated insulin secretion. Leptin sensitivity was evaluated by quantifying food intake and body weight after an intraperitoneal leptin injection. Neuropeptide gene expression and insulin signaling in the mediobasal hypothalamus were determined by qPCR and Akt phosphorylation, respectively. Results After 16 weeks of HFD feeding, BKO mice exhibited an exacerbated body weight gain and hyperphagia, in comparison to WT littermates. Glucose tolerance was similar in both groups, whereas HFD-induced hyperinsulinemia, insulin resistance, and β-cell expansion were more pronounced in BKO mice. In turn, leptin-induced food intake inhibition and hypothalamic insulin signaling were impaired in BKO mice, regardless of the diet, in accordance with deregulation of the expression of hypothalamic neuropeptide genes. Importantly, BKO mice already showed increased β-cell proliferation and glucose-stimulated insulin secretion with respect to WT littermates after two weeks of HFD feeding, before the onset of obesity. Conclusions Collectively, these results reveal that BACE2 suppression in an obesogenic setting leads to exacerbated body weight gain, hyperinsulinemia, and insulin resistance. Thus, we conclude that inhibition of BACE2 may aggravate the adverse metabolic effects associated with obesity.

strategies targeting b-cell function and expansion can be essential for reestablishing glucose homeostasis in T2D associated with obesity.
The pathophysiology of T2D is complex and, in addition to b-cell function, the control of glucose and energy homeostasis involves the action of several hormones in peripheral tissues such as the liver, skeletal muscle, and adipose tissue, as well as in regulatory regions of the brain. In this regard, leptin is an adipocyte-derived hormone that communicates fuel availability to the central nervous system by suppressing appetite and increasing energy expenditure [3]. Together with insulin, both hormones exert their effects on body weight and fuel metabolism through their actions in specific neuronal populations within the arcuate nucleus of the hypothalamus [4]. Early after the administration of a high-fat diet (HFD), the sustained increase of caloric intake induces hyperphagia and glucose intolerance [5], which are followed by a compensatory increase in leptin and insulin secretion prior to the onset of obesity and diabetes [6,7]. BACE2 (b-site APP-cleaving enzyme 2) is a type I transmembrane protease [8] that has been involved in the control of glucose metabolism [9,10]. Its close homolog BACE1 (b-site APP-cleaving enzyme 1) is highly expressed in the brain and responsible for initiating the amyloid cascade in Alzheimer's disease (AD) [11,12]. BACE2 transcripts have been reported to be expressed at very low levels in different brain regions [10,13,14]. Nevertheless, BACE2 is expressed in discrete subsets of neurons and glia throughout the adult mouse brain and rat brain regions [13,15], although its contribution to the pathogenesis of AD remains controversial [16]. BACE2 is expressed at low levels in most peripheral tissues. Importantly, the highest relative expression of BACE2 has been found in pancreatic islets [10,14], where it is expressed solely in the insulin-producing pancreatic b-cells in both humans and mice [10,17]. We previously demonstrated that inhibition of the b-secretase enzymatic function of BACE2 in pancreatic b-cells affects the intracellular trafficking of the insulin receptor as well as insulin gene expression and content, suggesting that this protease plays an important role maintaining b-cell function [18]. In the same line, the genetic inhibition of BACE2 improves the deficient secretory response of insulin in rat pancreatic b-cell line INS1E transfected with human islet amyloid polypeptide (hIAPP) [14]. Moreover, our group demonstrated that in a mouse model of b-cell dysfunction induced by the overexpression of hIAPP in b-cells, BACE2 suppression reverts glucose intolerance and improves b-cell survival [9]. Of interest, BACE2 was identified as the sheddase of the pro-proliferative plasma membrane protein TMEM27 in murine and human b-cells [10].
Accordingly, insulin-resistant mice treated with a BACE2 inhibitor displayed augmented b-cell mass and improved control of glucose homeostasis due to increased insulin levels [10]. Collectively, these studies suggest that BACE2 inhibition may have a therapeutic potential for T2D treatment. Pharmacological inhibition of BACE1 is being intensively pursued as a therapeutic approach to treat patients with AD [19]. Although significant progress has been made in the last years, the majority of current BACE1 inhibitors lack selectivity and can also target BACE2 [20,21]. Interestingly, it has been reported that BACE1 suppression decreases body weight, protects against diet-induced obesity and enhances insulin sensitivity in mice [22,23]. The beneficial effects that BACE2 inhibition exerts on b-cell mass and function in different models of T2D suggests that selective BACE2 inhibitors may be potentially a new path for the treatment of this disease [24]. However, the effects of BACE2 inhibition on glucose metabolism under an obesogenic regime has not yet been explored. This prompted us to explore the impact of BACE2 suppression on the regulation of glucose and energy homeostasis in a model of diet-induced obesity. We found that BACE2 knock-out (BKO) mice fed with a HFD presented an exacerbated body weight gain, hyperphagia, hyperinsulinemia, and insulin resistance compared to their wild-type (WT) littermates, indicating that BACE2 suppression aggravates the adverse metabolic effects induced by obesogenic diets.

Animals
Bace2 DE6 mice were purchased from The Jackson Laboratory and continued in the B6; 129P2 background [25]. Bace2 DE6 mice were crossed to obtain WT and Bace2 DE6/DE6 (BKO) male mice. Mouse genotyping was performed by PCR amplification of ear DNA samples. Mice at 8 weeks of age were individually caged and fed ad libitum either with pre-weight chow diet (CD, A04 type, Safe diets, Augy, France) or HFD (45% kcal derived from fat; Research Diets, New Brunswick, NJ, USA) for 2 or 16 weeks. Food intake and animal weight were controlled weekly. Epididymal and subcutaneous inguinal white adipose depots, gastrocnemius muscle and liver were dissected and weighed. Protocols were approved by the Animal Ethics Committee of the Universitat de Barcelona, and the Principles of Laboratory Animal Care were followed.

Indirect calorimetry
Indirect calorimetry was carried out using a 16-chamber TSE Phenomaster monitoring system (TSE Systems GmbH, Bad Homburg, Germany). Individually caged mice were placed into the measuring room one week before the onset of the experiment for acclimation. Mice were fed with CD or HFD as indicated. In the HFD group, the time of indirect calorimetry experiments coincided with the sixteenth week of the diet period. Determination of different parameters was carried out over a period of 48e72 h. Oxygen consumption and CO 2 production were directly measured. From these data, respiratory exchange ratio (RER) and energy expenditure (EE) were calculated as follows:

Locomotor activity
Locomotor activity was simultaneously monitored together with calorimetry parameters. Ambulatory movement in their cages was continuously registered every hour over a period of 48e72 h using an infrared photocell beam grid and is represented as the averaged of the total number of beam breaks in the x-and y-axis during the light and dark periods.

Histochemistry
The left liver lobe was fixed in 4% paraformaldehyde overnight at 4 C, then was transferred to 30% sucrose in phosphate-buffered saline (PBS) for 24 h at 4 C and embedded in tissue freezing medium (Leica, Wetzlar, Germany). We obtained 8-mm-thick sections with a CM1860 cryostat (Leica) and applied them to poly-lysine coated slides. Liver sections were stained with Oil red O as described elsewhere [26]. Images were taken with Nikon Eclipse E600 fluorescence microscope and collected with Olympus CellD software v3.4.

Glucose and insulin tolerance tests
For intraperitoneal glucose tolerance tests (GTTs), mice were fasted for 12 h and were intraperitoneally injected with D-glucose ( 2.7. Glucose-stimulated insulin secretion (GSIS) Pancreatic islets were isolated from WT and BKO males following the dietary intervention by collagenase digestion and handpicked after a density gradient using Histopaque (SigmaeAldrich, St Louis, MO, USA), as previously described [27]. The same day of isolation, islets were preincubated with KrebseRinger bicarbonate HEPES buffer solution (115 mmol/L NaCl, 24 mmol/L NaHCO 3 , 5 mmol/L KCl, 1 mmol/ LMgCl 2 $6H 2 O, 1 mmol/L CaCl 2 $2H 2 O, 20 mmol/L HEPES, and 0.5% BSA, pH 7.4) containing 2.8 mmol/L glucose for 30 min at 37 C. Eight islets per assay were then incubated with either 2.8 mmol/L glucose or 16.7 mmol/L glucose. After 1 h, supernatants were collected and cellular insulin contents were recovered in acid-ethanol solution. Insulin concentration was determined by Insulin Mouse ELISA (Crystal Chem).

Leptin sensitivity test
Mice were individually housed and acclimatized by handling and sham injections for a week. Ten-week-old WT and BKO mice on HFD for two weeks were intraperitoneally injected with either vehicle or 5.5 mg/kg of recombinant mouse leptin (R&D Systems, Minneapolis, MN, USA) 1 h before lights-out. Food intake and body weights were recorded every 12 h.

Central insulin signaling test
Mice were fasted for 12 h and anesthetized by an intraperitoneal injection of ketamine and xylazine (100 mg/kg and 10 mg/kg, respectively). We injected 100 mL of a 0.9% saline solution with or without 5 U of regular human insulin (Humulin R, Eli Lilly) into the inferior cava vein. After 10 min, the mediobasal hypothalamus (MBH) was isolated using a coronal brain matrix. Insulin signaling was analyzed by determining phosphorylated and total Akt levels by western blot.

Gene expression analysis
Total RNA from adipose tissue and mediobasal hypothalamus (MBH) was isolated using Trizol (SigmaeAldrich) reagent and reversetranscribed using SuperScript (Invitrogen). qPCR was conducted using SYBR Green (Invitrogen) in ABI Prism 7900 HT Sequence Detection System (Applied Biosystems, Foster City, CA, USA). The primers used were as follows: Hprt sense 5 0 -GGTTAAGCAGTACAGCCCCA-3 0 , Hprt1 Expression levels were normalized to the expression of an endogenous house-keeping gene (Hprt1).

Statistical analysis
All results are expressed as mean AE standard error of mean (SEM). The D'Agostino & Pearson omnibus normality test was carried out to test whether the variables followed a normal distribution (alpha ¼ 0.05). Statistical significance was determined by a paired two-tailed Student's t-test or two-way ANOVA with Tukey's or Fisher's least significant difference (LSD) post hoc analysis as indicated. A value of P < 0.05 was considered statistically significant. All figures and statistical analyses were generated using GraphPad Prism 8 (Graphpad Software, La Jolla, CA, USA).

RESULTS
3.1. BKO mice develop exacerbated obesity and hyperphagia with altered energy metabolism after long-term HFD feeding To study the implication of BACE2 in the regulation of energy homeostasis under obesogenic conditions, we monitored the body weight and food intake of WT and BKO mice fed either with chow diet (CD) or HFD for 16 weeks. Both HFD groups gained more weight than the groups on CD, but remarkably, BKO-HFD mice gained more weight than WT-HFD mice ( Figure 1A). Thus, HFD administration induced a body weight gain of 92.5 AE 4.3% in BKO mice as compared to only 66.2 AE 6.9% in WT mice ( Figure 1A). Both HFD groups displayed a similar increase in adiposity, measured as the percentage of the weight of epididymal white adipose tissue and subcutaneous adipose tissue with respect to body weight. Liver weight was significantly higher in BKO-HFD mice than in the other groups, which was accompanied by enhanced accumulation of hepatic lipid droplets as demonstrated by Oil Red O staining of liver sections (Supplementary Figure S1). In parallel, we also measured the energy intake (EI) on a weekly basis. Importantly, BKO-HFD mice exhibited increased hyperphagia compared to WT-HFD mice, which presented similar values to mice under CD feeding ( Figure 1B). This increase in food intake was observed shortly after initiating the dietary treatment and prior to a significant weight gain, suggesting an early deregulation of food intake in BKO mice when challenged with a HFD. Subsequently, we performed indirect calorimetry to gain insights into the metabolic status of mice. Under CD conditions, both groups presented similar oscillations in RER ( Figure 1C,D). HFD groups showed a lower RER than CD mice with a reduced oscillatory pattern, consistent with a preference for lipid oxidation as a source of fuel. Remarkably, RER was significantly lower in BKO-HFD mice compared to WT-HFD mice during the active dark cycle. These results show a metabolic profile that is consistent with the enhanced body weight observed in BKO-HFD mice. Importantly, no significant differences were observed in locomotor activity ( Figure 1E) and energy expenditure normalized to body weight ( Figure 1F) during the dark and light periods. Taken together, these results indicate that the increased body weight observed in BKO-HFD mice is mainly due to enhanced energy intake rather than a decrease in activity or energy expenditure.

BKO mice exhibit enhanced insulin secretion under long-term HFD feeding
To determine the effects of BACE2 suppression on whole-body glucose homeostasis, mice were challenged with an intraperitoneal glucose tolerance test (GTT). As expected, long-term HFD administration resulted in a decrease in glucose tolerance when compared with CD groups (Figure 2A,B). Interestingly, BKO-HFD mice displayed a similar impairment in glucose tolerance compared to WT-HFD mice, despite the higher weight gain observed in BKO-HFD mice. Plasma insulin levels were determined at basal conditions and 15 min after glucose challenge. Remarkably, basal insulin levels were much higher in BKO-HFD in comparison to that of the other groups ( Figure 2C). Glucose administration induced insulin secretion in all groups, although it was more pronounced in WT-HFD mice and especially in BKO-HFD mice. These results revealed an exacerbated hyperinsulinemia in BKO-HFD mice at fasting conditions and in response to glucose. We subsequently evaluated insulin sensitivity by an ITT. Insulin sensitivity was decreased in both HFD-fed mice groups compared with their respective CD groups ( Figure 2D). Despite similar levels of glucose intolerance between the two HFD groups, BKO-HFD mice were more insulin-resistant than the WT-HFD mice, in line with the increased insulin levels. Of note, BKO-CD mice showed lower levels of fasting glucose than their WT-CD littermates ( Figure 2E), with the same insulin sensitivity, which could be attributable to the slightly increased basal insulin levels in BKO-CD mice (0.25 AE 0.04 ng/mL) as compared to WT-CD mice (0.16 AE 0.02 ng/mL).

Pancreatic islets from BKO mice under HFD feeding display an exacerbated insulin secretion and b-cell proliferation
To assess the impact of BACE2 suppression on the secretory profile of the pancreatic b-cells, we isolated pancreatic islets and performed glucose-stimulated insulin secretion (GSIS) tests. Islets from all groups had a similar secretory response to high glucose except those from BKO-HFD mice, which displayed a higher basal insulin secretion and a relatively reduced response to high glucose, even though the total amount of insulin released was higher than that of any other group ( Figure 3A).
Morphometric analysis of pancreas sections revealed that the b-cell mass and the frequency of large islets were increased in BKO-HFD mice as compared to BKO-CD and WT-HFD mice ( Figure 3B,C). In line with these results, the number of proliferating b-cells, identified by double staining of insulin and Ki67, was also increased in the BKO-HFD Original Article mice ( Figure 3D,E). Thus, the increased plasma insulin levels in BKO mice following 16 weeks of HFD feeding were associated with an enhanced expansion of the b-cell mass.
3.4. BKO mice show impaired leptin response and hypothalamic insulin signaling with altered neuropeptide expression Having observed that BKO-HFD mice display increased body weight, hyperphagia, and hyperinsulinemia in comparison to WT-HFD after 16 weeks of HFD feeding, we next sought to study these mice following a short HFD regime. In fact, BKO-HFD presented enhanced energy intake shortly after the start of the dietary treatment ( Figure 1B), suggesting that the mechanisms underlying this phenotype would be early events. First, we evaluated circulating levels of leptin after two weeks on HFD. In fasting conditions, the levels of leptin were similarly increased in both HFD-fed mice groups ( Figure 4A). Consistently, the mRNA expression of leptin in the epididymal white adipose tissue was also increased in both groups ( Figure 4B). These results ruled out the possibility that differences in energy intake may be explained by differences in circulating leptin levels. Given that energy intake is regulated in part by leptin and insulin at the hypothalamus, we next sought to assess how the action of these hormones was affected in the absence of BACE2. First, a leptin sensitivity test was performed following two weeks of HFD feeding, corresponding to 10 weeks of mice age. As expected, leptin administration led to an anorexigenic effect in WT-CD mice, as shown by a reduction in food intake ( Figure 4C) and body weight ( Figure 4D), and this response was attenuated in WT-HFD mice. Remarkably, BKO mice were totally unresponsive to leptin, regardless of the dietary treatment ( Figure 4C,D). Because leptin synergistically acts with insulin to induce its anorexigenic actions, and considering that hypothalamic insulin resistance has been show to underlie deregulation in food intake [4], we wondered whether insulin signaling in the hypothalamus may be affected after a short-term HFD feeding. To test this, an intravenous bolus of insulin or saline was administered to mice in order to analyze the activation of Akt, a proxy for insulin signaling, in the mediobasal hypothalamus (MBH). As expected, insulin administration resulted in Akt activation in WT-CD mice ( Figure 4E). Conversely, the basal phosphorylation of Akt was already increased in the WT-HFD mice and in both BKO groups and hence insulin was unable to further activate Akt. Collectively, these results revealed an impaired anorexigenic response to leptin and insulin signaling in the MBH of BKO mice, even when fed on CD, which may trigger the increase in food intake and body weight observed in BKO mice fed on HFD. Next, we assessed the expression of appetite-regulating neuropeptide genes in the MBH. For this, we determined the expression of the genes encoding the orexigenic peptides, neuropeptide Y (Npy) and agoutirelated protein (Agrp), and the anorexigenic peptide proopiomelanocortin (Pomc) after an overnight fasting. The Npy and Agrp expression was significantly increased in the BKO mice, whereas Pomc levels were increased in WT-HFD mice in comparison to WT-CD mice; however, this transition between diets was not observed in BKO mice (Supplementary Figure S2). In order to estimate the anorexigenic/ orexigenic tone, the ratios between Pomc mRNA, and Npy or Agrp mRNAs were calculated, revealing that the anorexigenic/orexigenic balance was potently enhanced in WT mice after two weeks on HFD ( Figure 4F,G). Conversely, the ratios between anorexigenic and orexigenic peptides did not show this transition when BACE2-deficient mice were fed on HFD, suggesting imbalanced orexigenic and anorexigenic outputs in the hypothalamus, in agreement with the enhanced food intake observed in BKO-HFD mice.
3.5. BKO mice show early hyperinsulinemia and insulin resistance following a short-term HFD regime Due to the impairment in leptin and insulin responses in the hypothalamus of BKO mice and the deregulation of appetite regulatory genes shortly after the administration of HFD, we next assessed  Figure 5A,B). As observed after 16 weeks of HFD feeding, both WT-HFD and BKO-HFD mice exhibited the same level of glucose intolerance. Fasting insulinemia in BKO-HFD mice (0.34 AE 0.05 ng/mL) was slightly increased relative to WT-HFD mice (0.24 AE 0.04 ng/mL) and significantly higher compared with BKO-CD (0.14 AE 0.02 ng/mL) mice ( Figure 5C). After glucose administration, plasma insulin levels in the BKO-HFD mice were significantly increased compared with WT-HFD mice and the BKO-CD mice, revealing an early higher secretory response in BKO-HFD mice. The ITT revealed that the HFD groups showed less sensitivity to insulin, implying that BKO-HFD mice are more insulin resistant than their WT HFD littermates ( Figure 5D). HFD groups presented higher fasting glycemia than their respective CD groups ( Figure 5E). These data indicate that early at two weeks of HFD, the BKO mice display an exacerbated insulin secretion both at fasting and after glucose load and insulin resistance.
3.6. Pancreatic islets from BKO mice present a more pronounced b-cell proliferation and insulin secretion following a short HFD feeding Once characterized the metabolic state of mice after two weeks on HFD, we performed GSIS assays in isolated pancreatic islets to further determine the secretory capacity of b-cells. Islets from all groups similarly responded to high glucose, except the WT-HFD mice, whose insulin secretory response was attenuated ( Figure 6A). Remarkably, islets from BKO-HFD mice showed an increased insulin secretory response to high glucose when compared with WT-HFD and BKO-CD islets ( Figure 6A). Morphometric analyses of pancreas sections revealed no significant differences in b-cell mass and islet size frequency between the experimental groups, although there was already a trend toward a higher b-cell mass in BKO-HFD mice ( Figure 6B,C).
Indeed, the frequency of islets with a higher percentage of Ki67positive b-cells was increased in BKO-HFD mice ( Figure 6D,E). All together, these results revealed that suppression of BACE2 function leads to an enhanced b-cell secretory capacity and proliferation early after HFD administration.

DISCUSSION
We previously demonstrated that the absence of BACE2 improves glucose tolerance and insulin secretion in BACE2 KO mice crossed with Tg-hIAPP mice, which display insulin secretory defects due to the aggregation of hIAPP [9]. Here, we aimed to explore whether the absence of BACE2 could affect glucose and energy homeostasis in an obesogenic context. To achieve this objective, WT and BKO mice were challenged with HFD, in order to induce metabolic changes similar to early stages of T2D in humans. This strategy provides a useful tool to study potential therapies for T2D associated with obesity [29,30]. Unexpectedly, we found that, after 16 weeks of HFD feeding, BKO mice gained more weight than the WT mice. The exacerbated increase in body weight was due to a higher energy intake rather than a decrease in activity or energy expenditure. Furthermore, the BKO-HFD mice exhibited a lower RER than the WT-HFD mice, reflecting an increased preference for lipid oxidation as a source of fuel energy. In parallel, we analyzed the influence of the obesogenic diet on glucose homeostasis in BKO mice. Importantly, glucose intolerance was similar in both HFD groups despite the more accentuated obese phenotype of BKO mice in relation to WT littermates. An explanation for this protection against an expected aggravation of glucose tolerance is the fact that BKO-HFD mice exhibited increased circulating insulin levels at fasting conditions and after a glucose challenge. In addition, the insulin secretory response to glucose in isolated pancreatic islets from BKO- analyzed. Data represent the mean AE SEM. *P < 0.05, **P < 0.01, ***P < 0.001, using two-way ANOVA followed by Tukey's post hoc test (A, B, C and E). ## P < 0.01, ### P < 0.001, using Student's paired t-test (A).
Original Article HFD mice was increased compared to those from WT-HFD mice. These results are in agreement with our previous studies showing that BACE2 inhibition in b cells results in enhanced glucose-induced insulin secretion [14]. The more pronounced hyperinsulinemia detected in BKO-HFD mice was associated with increased b-cell mass and proliferation. In this regard, previous studies showed that BACE2 inhibition in genetically obese ob/ob mice leads to increased insulin secretion and improved glucose tolerance [10]. In the present study, we show that challenging BKO mice with an obesogenic diet resulted in increased plasma insulin levels but also in a more pronounced impairment of insulin resistance already after two weeks of HFD feeding, before the onset of obesity. We also focused our attention on understanding the increase in energy intake that leads BKO-HFD mice to gain more weight than control littermates. It is well known that insulin acts as a satiety signal in the brain and reduces food intake, similar to the adipose-derived hormone leptin [4]. Indeed, insulin and leptin synergistically act in the arcuate nucleus via PI3K/Akt [31]. Therefore, we wondered whether the disturbed food intake and glucose homeostasis in BKO mice in the long-term HFD regime may be caused by an early impairment in the central nervous system. For this purpose, we analyzed the anorexigenic response to leptin and the hypothalamic insulin signaling after two weeks of HFD, before the onset of obesity. Surprisingly, our results showed that food intake and body weight reduction in response to leptin administration were attenuated in BKO mice as compared to WT animals, regardless of the diet. Furthermore, we observed that insulin administration was not able to activate Akt in the mediobasal hypothalamus (MBH) in both HFD groups but also in BKO mice fed with CD.
Leptin and insulin mainly exert their anorectic effect in the arcuate nucleus via inhibition of orexigenic NPY/AgRP neurons and activation of anorexigenic POMC neurons resulting in reduced food intake and increased energy expenditure [4]. In this regard, HFD attenuated the expression of the orexigenic Npy and Agrp genes and increased the expression of the anorexigenic gene Pomc, most likely reflecting an attempt to moderate energy intake. Conversely, these transitions favoring an anorexigenic tone were not observed when BKO mice were fed a HFD. Importantly, these effects were already observed after two weeks of HFD treatment, demonstrating an early impairment of the regulation of the expression of hypothalamic neuropeptides controlling food intake, which is in line with the hyperphagia observed in BKO-HFD mice shortly after initiating the diet intervention. Collectively, these results revealed impaired central insulin and leptin responses in the BKO mice under chow diet, suggesting that BACE2 may play a role in hypothalamic areas controlling food intake. It should be noted that although BACE2 expression is highest in pancreatic islets, and at much lower levels in some peripheral tissues, this secretase is expressed in discrete subsets of neurons and glia throughout the adult brain, including the ventromedial hypothalamic nucleus [13,15], and therefore a potential role of BACE2 in the brain requires further investigation. In this regard, it has been shown that proinflammatory TNF induces an increase in BACE2-mediated shedding of vascular cell adhesion molecule 1 in the cerebrospinal fluid from adult mice, illustrating that BACE2 inhibition might become apparent under physiopathological conditions [15]. Furthermore, the effects of BACE2 suppression on hypothalamic signaling and gene regulation also open the possibility that this may impact other regions regulated by hypothalamic outputs. Circulating leptin plasma levels (n ¼ 5e7/group) and (B) leptin mRNA expression in epididymal white adipose tissue (n ¼ 5e6/group) in WT and BKO mice fed either CD or HFD for 2 weeks. (C) Cumulative energy intake and (D) change in body weight 24 h after an intraperitoneal injection of leptin in WT and BKO mice fed CD or HFD for 2 weeks (n ¼ 5e6 mice/group). (E) Representative western blots for phospho-Akt (p-Akt S 473 ) and Akt in the mediobasal hypothalamus from WT and BKO mice fed CD or HFD for 2 weeks after an intraperitoneal injection of insulin. The graphs on the right represent the ratios of p-Akt S 473 to total Akt quantifications normalized to the basal values of WT mice on CD (n ¼ 6e9/group). (F,G) Ratios between Pomc, and Npy (F) or Agrp (G) mRNA levels in the mediobasal hypothalamus of WT and BKO mice fed CD or HFD for 2 weeks (n ¼ 3e6 mice/group). Data represent the mean AE SEM. *P < 0.05, **P < 0.01, ***P < 0.001, using two-way ANOVA followed by Tukey's post hoc test (AeG).
Indeed, the autonomic nervous system modulates the secretory response of pancreatic islets through sympathetic and parasympathetic fibers [33,34], and different hypothalamic areas have been shown to be connected to efferent autonomic fibers innervating pancreatic islets in mice [35]. In the current study, BKO-HFD pancreatic islets ex vivo showed a pattern of exacerbated glucosestimulated insulin secretion similar to that observed in vivo. This, together with the increased b-cell mass, suggests that the enhanced insulin secretion in BKO-HFD mice is mainly attributed to a direct effect of BACE2 suppression on pancreatic islets. area under the curve (AUC) from the GTT, (C) plasma insulin levels before and 15 min after glucose administration (n ¼ 8e12 mice/group), (D) intraperitoneal insulin tolerance test (ITT) (n ¼ 6e7 mice/group) and (E) fasting blood glucose levels (n ¼ 20 mice/group) in WT and BKO mice fed either CD or HFD for 2 weeks. Data represent the mean AE SEM. &&& P < 0.001 (WT-CD vs. WT-HFD); ## P < 0.01, ### P < 0.001 (BKO-CD vs. BKO-HFD); $ P < 0.05 (WT-HFD vs. BKO-HFD); *P < 0.05, **P < 0.01, ***P < 0.001, using two-way ANOVA followed by Tukey's (A, B, C and E) and Fisher's LSD (D) post hoc tests. yy P < 0.01, yyy P < 0.001, using Student's paired t-test (C). Representative images of islets stained for insulin (green), Ki67 (red) and nuclei with Hoechst (blue). The yellow arrows point to Ki-67 positive nuclei in insulin-positive cells. Scale bar, 100 mm. (E) Quantification of b-cell proliferation in pancreas from WT and BKO mice fed either CD or HFD for 2 weeks (n ¼ 3 mice/group). Three sections per animal were analyzed. Data represent the mean AE SEM. *P < 0.05, using two-way ANOVA followed by Tukey's post hoc test (A, B, C and E). # P < 0.05, ## P < 0.01, using Student's paired ttest (A).
Previous studies have demonstrated beneficial effects of BACE1 inhibition on whole-body metabolic homeostasis and neuronal leptin sensitivity under a chronic HFD consumption [22,23], pointing towards distinct roles of BACE1 and BACE2 on metabolism homeostasis. These differences may be explained by the different substrates and tissue expression pattern of each of these secretases. One of the substrates of BACE2 is TMEM27, which is also highly expressed in the pancreatic islets [10]. Nevertheless, other b-cell enriched substrates of BACE2 in b-cells have been identified [32,36]. The molecular mechanisms by which BACE2 deficiency and inhibition promote b-cell function and proliferation are still unresolved, but likely involve the stabilization of TMEM27 as well as other BACE2 substrates yet to be identified that may synergistically contribute to these effects. Hyperinsulinemia is one of the hallmarks of T2D associated with obesity. In fact, the physiological response to insulin resistance in the early stages of obesity is mainly attributed to an increase in pancreatic b-cell mass and insulin secretion. Nevertheless, increased insulin levels may result in adverse effects on glucose metabolism. On the one hand, insulin induces fat storage in adipose tissue [37], and therefore an excess of insulin may exacerbate fat accumulation in obesogenic contexts. Indeed, mild suppression of insulin secretion has been proven as a strategy for preventing and treating obesity [38,39]. On the other hand, hyperinsulinemia may cause insulin resistance even prior to the onset of obesity [2,40,41]. Indeed, our results show that following a short HFD feeding of two weeks, BKO mice already display enhanced hyperinsulinemia, which may underlie the accentuated insulin resistance in these mice. Moreover, it is also important to stress that hyperinsulinemia in obesity impairs insulin sensitivity in the brain [42,43], leading to deregulation of food intake and eventually body weight gain that may also contribute to the aggravation of the obese phenotype in BKO mice challenged with HFD. In summary, the present study shows that BACE2 inhibition in mice under a HFD feeding exacerbates body weight gain, hyperphagia, hyperinsulinemia, and insulin resistance. Thus, we conclude that BACE2 suppression may aggravate the adverse metabolic effects associated with an obesogenic diet. These findings should be considered when considering a potential clinical use of non-selective BACE1/BACE2 or selective BACE2 inhibitors for the treatment of AD or T2D, respectively.