The Laval University animal ethics committee approved all animal experiments. We used the triple transgenic Alzheimer’s disease mouse model (3xTg‐AD), which expresses three mutant genes, coding for the mutant human Aβ precursor protein (APP swe), tau (P301L), and presenilin‐1 (PS1 M146V).⁽¹⁹⁾ The 3xTg‐AD mice were produced at our animal facility, along with nontransgenic (NTg) controls with the same genetic background (C57BL6/129SvJ).^(11,18) Mice received either a control diet (CD; 12% kcal fat) or a HFD (60% kcal fat) for a 9‐month period starting at the age of 6 months (Research Diets, New Brunswick, NJ^(11,18)). Animals were sacrificed at 15 months of age by intracardiac perfusion under deep anesthesia with ketamine/xylazine (100 mg/kg per 10 mg/kg). All groups consisted of 7‐12 animals as mentioned in each figure legend, with a proportion of 70%‐80% female mice (n = 5‐9).

Aspartate aminotransferase (AST) and alanine aminotransferase (ALT) were analyzed in plasma from intracardiac blood (centrifuged 5 minutes, 3,000 rpm) sampled just before intracardiac perfusion at sacrifice with a modular analyzer (Roche, Basel, Switzerland). Histopathological analyses were performed on hematoxylin and eosin liver sections to determine the degree of hepatic steatosis (0, no; 1, mild; 2, moderate; and 3, severe hepatic steatosis) and inflammatory (0, no; 1, mild; 3, moderate; and 4, severe hepatic inflammation) grade. A liver‐specialized pathologist (Dr. Lippman) blindly performed the analysis.

Liver triglyceride (TG) and cholesterol contents were assessed following a modified Folch extraction as described previously⁽²⁰⁾ and enzymatic reactions with commercial kits (Randox Laboratories, Crumlin, United Kingdom).

RNA was extracted using TRIzol, as per the manufacturer’s instructions (Thermo Fisher Scientific, Burlington, Canada). RNA concentration and purity were assessed by measuring absorbance at 260 nm and 280 nm. A total of 2 μg of RNA were reverse‐transcribed to complementary DNA (cDNA) using a cDNA reverse‐transcription kit (Applied Biosystems, Foster City, CA). The cDNA were diluted in DNase free water (1:25). Quantitative polymerase chain reaction (PCR) was performed either with TaqMan probes and primers (Applied Biosystems) or using a SYBR Green Jump‐Start Gene Expression Kit (Sigma‐Aldrich, Oakville, Canada). Primers are detailed in Table 1. Samples were measured in duplicate using a CFX96 or CFX384 touch real‐time PCR (Bio‐Rad, Mississauga, Canada). The relative expression of genes of interest was determined by normalization to two references genes (Hprt and Rpl19 for the SYBR, Hprt and B2m for the TaqMan measurements) using the comparative ΔΔCt method for relative gene expression.

Plasmatic and hepatic human‐specific Aβ42 were measured using a human Aβ enzyme‐linked immunosorbent assay (ELISA) kit (Wako, Osaka, Japan) according to the manufacturer’s instructions. This kit has a detection threshold of 0.1 pM.

Total proteins were lysed from frozen powdered livers in a radio immunoprecipitation assay buffer (50 mM tris(hydroxymethyl)aminomethane, pH = 7.4, 150 mM NaCl, 0.5 mM ethylene diamine tetraacetic acid, 5 mM ethylene glycol tetraacetic acid, 2 mM sodium orthovanadate, 50 mM sodium fluoride, 80 mM sodium β‐glycerophosphate, 5 mM sodium pyrophosphate, 1 mM phenylmethylsulfonyl fluoride, 1% Triton‐X‐100, 0.1% sodium dodecyl sulphate, 1% sodium deoxycholate, and 1% protease inhibitor cocktail⁽²¹⁾). An equal amount of protein of 6‐10 animals/group was separated by sodium dodecyl sulfate–polyacrylamide gel electrophoresis and then electroblotted onto a nitrocellulose membrane. Membranes were blocked in 5% milk powder in tris(hydroxymethyl)aminomethane‐buffered saline Tween 20 for 1 hour and immunoblotted with primary antibodies overnight at 4°C, followed by horseradish peroxidase–coupled secondary antibodies for 1 hour at room temperature. Membranes were exposed to chemiluminescence reagents (EMD Millipore, Burlington, MA) and bands visualized using a BioRad imaging system and quantified with the corresponding software (ImageLab, Bio‐Rad). The list of primary antibodies that were used in our experiments is available in Table 2.

Glucuronidation assays within mouse livers were performed as described by Dr. Barbier’s group.⁽²³⁾ Briefly, enzymatic assays were performed with 24S‐OH‐C (2.5 μM) at 37°C for 1 hour in the presence of 50 μg liver homogenates in a final volume of 100 μL of the previously reported assay buffer. Assays were ended by adding 100 μL of methanol containing 0.02% butylated hydroxytoluene. The formation of 24S‐OH‐C‐24G was ascertained through liquid chromatography–tandem mass spectrometry (LC/MS‐MS).

24S‐OH‐C, 24S‐OH‐C‐3S, 24S‐OH‐C‐24G, and 24S‐OH‐C‐3S,24G were synthesized by the organic synthesis service at the CHU de Québec Research Center (http://pfchem.crchul.ulaval.ca/en/index.html) (Québec, Canada). [²H₇]‐24S‐hydroxycholesterol was purchased from C/D/N Isotopes (Montréal, Canada). [²H₇]‐24S‐hydroxycholesterol‐3S, [²H₇]‐24S‐hydroxycholesterol‐24G, and [²H₇]‐24S‐hydroxycholesterol‐3S, 24G were prepared through in vitro enzymatic assays using liver homogenates or microsomes as reported.⁽²³⁾ Levels of 24S‐OH‐C, 24S‐OH‐C‐24G, and 24S‐OH‐C‐3S,24G in plasma or in vitro enzymatic assays were quantified through LC/MS‐MS. For 24S‐OH‐C quantification, the chromatographic system consisted of a Prominence UltraFast Liquid Chromatograph (Shimadzu Scientific instruments Inc., Columbia, MD), and the chromatographic separation was achieved with a Synergie RP Hydro 2.5‐μm packing material, 50 $\times$ 3.0 mm (Phenomenex, Torrance, CA). Analytes were detected using an API4000 mass spectrometer (AB Sciex, Concord, Canada), operated in multiple reactions monitoring mode (MRM), and equipped with a turbo ion‐spray source. Electrospray ionization was performed in positive ion mode, with voltage held at 5,500 V. 24S‐OH‐C‐24G and 24S‐OH‐C‐3S,24G were detected with an API3200 mass spectrometer (AB Sciex), operated in MRM mode and equipped with a turbo ion‐spray source. For those compounds, the chromatographic system consisted of an Agilent 1200 apparatus (Agilent Technologies, Ville Saint‐Laurent, Canada). The chromatographic separation was achieved using a Gemini C₁₈ 3‐μm packing material, 100 × 4.6 mm (Phenomenex).

Data are expressed as mean ± SEM. Statistical analyses were performed using Prism 7.0a (GraphPad Software Inc., San Diego, CA). The threshold for statistical significance was set to P < 0.05. Homogeneity of variance and normality were determined for all data sets using Shapiro‐Wilk’s normality test. When normality of the residuals was confirmed, two‐group data sets were analyzed using Student t test, and four‐group data sets by a two‐way analysis of variance (ANOVA) to determine the effect of the diet and genotype as well as their interaction. A one‐way ANOVA with Tukey’s post hoc test was performed between HFD groups when main treatment or interaction effects were significant. When normality was not confirmed, data were analyzed using the Mann‐Whitney U test for two‐group comparisons and the Kruskal‐Wallis test followed by Dunn’s multiple comparison for four‐group data sets, as specified in the respective figure legends. Pearson correlation coefficients were determined using simple linear regression.

3xTg‐AD mice were shown in our previous studies to be glucose‐intolerant, a phenotype exacerbated following a HFD and progressing with age along with AD neuropathology.^(11,18,24) Body, liver, and epididymal adipose tissue (eWAT) weights were increased by HFD in both NTg and a 3xTg‐AD mice, whereas no effect of genotype was observed (Table 3). However, a tendency for decreased liver and eWAT weight was observed in obese 3xTg‐AD mice compared with obese controls (Table 3). No changes were found in AST and ALT levels between groups (Fig. 1A,B), suggesting no major liver damage.

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1 Fig.. Hepatic markers and lipid content in CD and HFD‐fed NTg and 3xTg‐AD mice. Circulating AST (A) and ALT (B) levels. Hepatic TG (C) and cholesterol (D) levels. (E) Representative hematoxylin and eosin–stained sections. (F) Histological steatosis score presented as percentage of mice showing the respective score for each experimental group (0, no ; 1, mild; 2, moderate; and 3, severe hepatic steatosis). Data are presented as mean ± SEM (n = 7‐11/group; one‐way ANOVA with Tukey’s post hoc test; **P < 0.01).

Because hepatic lipid metabolism is altered by HFD, thus contributing to impaired glucose homeostasis in this model, we next evaluated hepatic steatosis. Livers of HFD‐fed NTg mice accumulated significantly more TGs than CD controls (31.7 ± 4.1 mg/g tissue vs. NTg CD: 14.9 ± 3.1 mg/g tissue; P < 0.01) (Fig. 1C). This diet‐induced lipid accumulation was not observed in obese 3xTg‐AD mice (18.1 ± 3.5 mg/g tissue vs. 3xTg‐AD CD: 11.2 ± 1.5 mg/g tissue; P > 0.05) (Fig. 1C). Hepatic cholesterol levels increased following HFD in both NTg and 3xTg‐AD mice (Fig. 1D).

To strengthen the liver–brain relationship, we investigated the linear relationship between the previously described liver markers and cerebral concentrations of Aβ in the same animals, previously published by our group.⁽¹¹⁾ Significant linear correlations were found between cortical soluble Aβ40 and Aβ42 and hepatic cholesterol, as well as between cerebral insoluble Aβ40 and Aβ42 and hepatic TGs (Table 4). AST and ALT levels did not correlate with cerebral Aβ.

Histopathological analysis confirmed less severe lipid accretion in HFD‐fed 3xTg‐AD mice, as revealed by the lower abundance of lipid droplets and reduced steatosis scores as compared with HFD‐fed NTg (25% 3xTg‐AD HFD vs. 55% NTg HFD presented grade 3 steatosis) (Fig. 1E,F). Histopathological signs of inflammation were absent or minimal in all groups.

To explore potential underlying mechanisms for reduced lipid storage in the liver of obese 3xTg‐AD mice, we assessed the main hepatic pathways of lipid, glucose, and energy metabolism. Following HFD in NTg animals, protein levels of fatty acid synthase (FAS) decreased by approximately 80%; those of total acetyl‐CoA carboxylase (tACC) decreased by 55%, whereas its phosphorylated form pSer79 ACC decreased by 35% (pACC) (P < 0.001 vs. NTg CD) (Fig. 2A). Following HFD in 3xTg‐AD mice, the same trends were observed at lower percentages (FAS: 90%, tACC: 60%, pACC: 50%, respectively; P < 0.001 vs. 3xTg‐AD CD); genotypic differences did not generate statistical significance (P > 0.05 vs. NTg HFD) (Fig. 2A). The ratio of pACC/tACC was increased only in NTg HFD mice, accounting for increased lipogenesis. Expression of genes involved in fatty acid oxidation (Ppara [peroxisome proliferator–activated receptor alpha], Ppargc1a [peroxisome proliferative activated receptor, gamma, coactivator 1 alpha], and Cpt1a [carnitine palmitoyltransferase 1a]) was not significantly changed, although trends toward a genotype‐diet interaction for Ppara (P = 0.0858) and an HFD‐induced increase for Cpt1a (P = 0.0937; Fig. 2B) were seen. We next investigated the messenger RNA (mRNA) expression of gluconeogenic enzymes Pck1 (phosphoenolpyruvate carboxykinase 1) and G6pc (glucose‐6‐phosphatase) and found that HFD decreased Pck1 and tended to increase G6pc (Fig. 2C), but no genotypic effects were observed.

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2 Fig.. Hepatic lipid and glucose metabolism in CD and HFD‐fed NTg and 3xTg‐AD mice. (A) Representative western blot images and quantification of proteins involved in lipid synthesis. (B) Expression of genes involved in fatty acid oxidation. (C) Expression of genes involved in gluconeogenesis. (D) Representative western blots and quantification of proteins of the mitochondrial respiratory complex. Data are presented as mean ± SEM (n = 7‐11/group; one‐way ANOVA with Tukey’s post hoc test [Ppara, Pck1]; Kruskal‐Wallis test followed by Dunn’s multiple comparison [Ppargc1a, Cpt1a]; *P < 0.05, **P < 0.01, ***P < 0.001). Abbreviations: CI, complex I subunit NDUFB8; CII, complex II subunit 30kDa; CIII, complex III subunit core 2; CIV, complex IV subunit I; CV, ATP synthase subunit alpha; eEF2, eukaryotic elongation factor 2; and ns, not significant.

We next examined mitochondrial function by measuring the expression of mitochondrial OXPHOS proteins, but the expression of each of the complexes was similar between groups, although it tended to be higher in all groups compared with NTg CD (Fig. 2D).

Because the liver is a major clearing organ for Aβ peptides,⁽¹⁴⁾ we investigated how HFD modulates its clearing enzymes. Levels of plasma human Aβ42, induced only in 3xTg‐AD mice, remained unaffected by the HFD (Fig. 3A). We were not able to detect human Aβ42 in the liver of 3xTg‐AD mice by ELISA, nor its precursor APP by western blot or immunofluorescence (data not shown), confirming that the transgene is not expressed in peripheral organs.⁽¹¹⁾ Following HFD, we observed a reduction of insulin degrading enzyme (IDE) and a trend toward lower levels of neprilysin (NEP), the main hepatic enzymes responsible for Aβ clearance, regardless of genotype (Fig. 3B,C). Angiotensin‐converting enzyme 2 (ACE2), also known to play a role in degrading cerebral Aβ,⁽²⁵⁾ and the Aβ receptor low‐density lipoprotein receptor–related protein 1 (LRP1) were unchanged among the groups (Fig. 3B,C).

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3 Fig.. Hepatic Aβ metabolism in 3xTg‐AD mice. (A) Circulating Aβ42 levels. (B) Representative western blot images and quantification of proteins involved in Aβ clearance. (C) Quantification of proteins involved in Aβ clearance. Data are presented as mean ± SEM (n = 7‐11/group; Student t test [plasmatic Aβ42]; one‐way ANOVA with Tukey’s post hoc test).

Circulating cholesterol was significantly increased in HFD‐fed NTg mice compared with CD‐fed controls, but this dietary effect was not observed in 3xTg‐AD mice, which had significantly lower cholesterol levels as compared with their HFD‐fed NTg counterparts (Fig. 4A). HDL cholesterol, the major cholesterol fraction in rodents, was not different among groups (NTg CD: 1.78 ± 0.12 mmol/L vs. 3xTg‐AD CD: 1.31 ± 0.06 mmol/L, NTg HF: 1.94 ± 0.24 mmol/L, 3xTg‐AD HFD: 1.31 ± 0.21 mmol/L, P > 0.05). Although plasma 24S‐OH‐C was similar between groups, 24S‐OH‐C‐24G plasma content was greater than 50% lower in 3xTg‐AD mice without reaching statistical significance (P = 0.06)(Fig. 4B,C). 24S‐OH‐C‐3S,24G plasmatic levels were below the detection limit in most mice. Measurement of the production rate of these metabolites in the liver revealed that formation of 24S‐OH‐C‐24G decreased by 30% and 26%, respectively, in HFD‐fed NTg and 3xTg‐AD mice versus their respective CD‐fed controls (Fig. 4D). However, the production rate remained significantly higher in obese 3xTg‐AD than in obese NTg animals (13.09 ± 0.93 pmol/min/mg in 3xTg‐AD HFD vs. 9.93 ± 0.89 pmol/min/mg in NTg HFD; P < 0.05) (Fig. 4D). The rate of 24S‐OH‐C‐3S,24G production showed similar trends, although at a much lower level compared with 24S‐OH‐C‐24G, and was not detectable in all mice (data not shown).

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4 Fig.. Hepatic 24S‐OH‐C metabolism in NTg and 3xTg‐AD mice fed a CD or HFD. Circulating cholesterol (A), 24S‐OH‐C (B), and 24S‐OH‐C‐24G (C) levels. (D) Hepatic glucuronidation rate of 24S‐OH‐C into 24S‐OH‐C‐24G. (E) Hepatic expression of target genes of 24S‐OH‐C. (F) Representative western blot and quantification of hepatic UGT1A. Data are presented as mean ± SEM (n = 7‐11/group; ANOVA with Tukey’s post hoc test [circulating cholesterol, 24S‐OH‐C, circulating and hepatic 24S‐OH‐C‐24G, Abca1, Srebf2, UGT1A]; Kruskal‐Wallis test followed by Dunn’s multiple comparison [Srebf1, Hmgcr]; *P < 0.05, **P < 0.01, ***P < 0.001).

The mRNA expression of several genes known to be induced by 24S‐OH‐C revealed a differential modulation in the liver: Abca1 (ATP‐binding cassette transporter [member 1 of human transporter subfamily]) and Srebf1 (sterol regulatory element‐binding transcription factor 1) were both up‐regulated by genotype and not by diet, whereas Hmgcr (3‐hydroxy‐3‐methylglutaryl‐CoA reductase) and Srebf2 were regulated by diet and not by genotype (Fig. 4E). Protein expression of UGT1A (UDP glucuronosyltransferase family 1 member A) was not changed (Fig. 4F).

Alterations of the liver–brain axis have been described in liver diseases such as viral hepatitis and liver failure, which lead to a large spectrum of neurological abnormalities.^(27,28) Cognitive impairment in these diseases worsens with age, but significantly improves after liver transplantation,⁽²⁹⁾ strengthening the role of the liver in neurological alterations. Numerous reports have emerged describing patients with NAFLD or animal models with cerebral dysfunction and neuropathology similar to AD.^(6,10) A long‐term HFD in normal mice induced AD‐like neuropathological features in the brain; moreover, 2 months of the same diet was sufficient to accelerate plaque formation in an AD mouse model.⁽³⁰⁾ We found that liver cholesterol and TGs rather than liver markers AST and ALT correlate with cerebral Aβ levels, which indicates that hepatic‐induced lipid alterations, not hepatic function per se, is associated with brain accumulation of Aβ.

Although the relationship of AD with insulin resistance and diabetes is well known,⁽¹⁰⁾ the implication of the liver–brain axis in the AD pathogenesis remains unknown. Altered liver function in patients with AD, indicated by lower albumin, increased prothrombin time and higher AST/ALT compared with control patients, has been reported.⁽⁹⁾ Additionally, the liver function markers AST and ALT were shown to be associated with poor cognitive performance as well as with increased Aβ and p‐tau181 in the cerebrospinal fluid and poor cerebral glucose metabolism in patients with AD.⁽⁸⁾ We noted no change in AST or ALT in 3xTg‐AD mice, exposed or not to a HFD, consistent with previous work,⁽⁷⁾ suggesting that AD neuropathology does not directly induce major hepatocyte damage.

Because lipid metabolism is implicated in the pathogenesis of AD, we investigated the effect of obesity on hepatic lipid metabolism in 3xTg‐AD mice. Challenging animal models with a HFD leads to development of a NAFLD‐like phenotype, with increased hepatic lipid accumulation, increased de novo lipogenesis, and gluconeogenesis affecting energy metabolism. Interestingly, obese 3xTg‐AD mice were protected from the HFD‐induced hepatic accumulation of TGs and cholesterol following modest trends in increased fatty acid oxidation and decreased lipogenesis. These results are consistent with previous studies in the amyloidopathy mouse model APP_SWE/PSEN1dE9, in which HFD‐induced hepatic lipid deposition was diminished by de novo lipogenesis inhibition, thus driving substrate flux toward glucose production and hyperglycemia, as well as hepatic insulin resistance and type 2 diabetes development.⁽¹²⁾ Our previous study showed that circulating TGs are increased in obese 3xTg‐AD mice.⁽¹¹⁾ Interestingly, in normal mice, TGs have been shown to cross the blood–brain barrier and induce central leptin and insulin receptor resistance, while decreasing satiety and possibly impairing cognition.⁽³¹⁾ How this may be affected by peripheral TG alterations or neurodegenerative disease remains to be established. However, the combination of decreased liver and increased circulating TGs that we see in our obese AD mice may suggest a lipid rerouting to other organs such as the brain, but could also represent an underlying mechanism of the metabolic alterations present in these animals.

The current results indicate that hepatic fatty acid oxidation, de novo lipogenesis, and gluconeogenesis were affected by a high intake of saturated fat, but with no significant effect on AD transgenes. Consistent with this result, our previous study showed a similar modulation, only by diet, not by genotype, for hepatic phosphorylation of Akt 5 minutes following an intravenous insulin injection administered before sacrifice.⁽¹¹⁾

HFD in young mice induces an increase in ACC and FAS, enzymes involved in the synthesis of fatty acids,⁽²⁰⁾ and decreased gluconeogenic enzymes Pck1 and G6pc.⁽²¹⁾ Here, we observed a marked decrease in lipogenic enzymes in both HFD groups, and a tendency toward increased G6pc and increased lipid oxidation in 3xTg‐AD mice. Interestingly, several reports suggest that HFD started in older mice has protective effects against obesity compared with HFD started in young mice.^(32,33) Moreover, the presence of physiological and physiopathological factors related to aging, such as weight loss and increased energy consumption due to development of comorbidities, could also play a role in the modulation of these hepatic metabolic enzymes.⁽³³⁾

Metabolomic studies associated changes in circulating lipid compounds with cognitive status in AD, with encouraging but not fully conclusive results.^(34,35) These studies did not take into consideration the peripheral metabolic status of the subjects. Because the liver plays a key role in shaping the circulating metabolome, it is logical to expect that HFD‐induced hepatic changes will be reflected in blood biomarkers.

The 3xTg‐AD mouse model was obtained by co‐injecting the human mutant APP and tau transgene constructs in homozygous PS1M146V knock‐in mice.⁽¹⁹⁾ These mice therefore develop genetically induced Aβ and tau pathologies in the brain, with no expression of the APP/Tau transgenes in the liver, whereas PS1 is ubiquitously expressed.⁽¹⁹⁾ PS1 mice from the same colony do not show alteration in glucose tolerance,⁽²⁴⁾ whereas APP/PS1 mice, not expressing the tau transgene, present impaired glucose tolerance.⁽²⁴⁾ Thus, metabolic effects associated with genotype here are likely only due to central AD pathology. In addition, among the effects of the three transgenes, sustained human Aβ production was shown to play a causal role in the peripheral metabolic impairments of 3xTg‐AD mice.⁽²⁴⁾

The strong relation between type 2 diabetes and Aβ is well described in the literature^(2,3) and is reflected in studies in animal models. Normal mice fed a long‐term HFD accumulate cerebral Aβ,^(30,36) while streptozotocin‐induced diabetic mice also accumulate cerebral Aβ and develop memory dysfunction.⁽³⁷⁾ Inversely, transgenic mouse models overexpressing mutant Aβ are glucose‐intolerant even when fed a normal diet.⁽¹²⁾ Similarly, our group established previously that 3xTg‐AD mice develop glucose intolerance, which is enhanced by HFD⁽¹¹⁾ and worsens with age along with amyloid pathology.⁽²⁴⁾ This effect is partially due to an accumulation of toxic Aβ of cerebral origin in the pancreas, which alters insulin secretion.⁽¹¹⁾ However, pancreatic Aβ is not further enhanced in 3xTg‐AD mice following a HFD, and it is believed that it only potentiates the effect of HFD on β‐cell death.⁽¹¹⁾

The peripheral “sink” hypothesis states that increasing the peripheral clearance of Aβ could ultimately reduce its cerebral load.⁽³⁸⁾ Unfortunately, such strategies have failed in spite of efficient reduction of circulating Aβ: peripherally administered NEP^(39,40) or inhibition of peripheral β‐secretase, an enzyme involved in Aβ production.⁽³⁸⁾ Nevertheless, increased accumulation of Aβ occurs in the brain and is aggravated by HFD,^(11,18) suggesting that peripheral metabolic alterations might affect Aβ degradation.

The liver is considered a major site of Aβ clearance,⁽¹⁴⁾ and in vitro studies have shown that human AD‐derived liver homogenates degrade Aβ at lower rates than control‐derived homogenates.⁽¹⁴⁾ We found that Aβ generated in the brain does not accumulate a detectable amount in the liver following a HFD. Cerebral LRP1 is implicated in Aβ clearance toward the periphery; in the liver, LRP1 is thought to assist other Aβ clearing enzymes, such as NEP, in degrading Aβ.⁽⁴¹⁾ We did not find any changes in liver LRP1 among the groups. However, the two major hepatic Aβ clearing enzymes, NEP and IDE, rather trended toward decreases in the liver of obese mice. This diet‐specific effect suggests that impaired hepatic clearance of Aβ in obese 3xTg‐AD mice—in spite of similar circulating levels as lean 3xTg‐AD mice—may contribute to its cerebral and pancreatic accumulation. The recent study mentioned showed decreased IDE levels and no significant change in NEP in liver samples of patients with AD compared to controls with no AD, in accordance with our data.⁽¹⁴⁾ However, patients in this study were not stratified by the presence of peripheral metabolic alterations.

Overall, our current results in animals combined with previous studies in livers of patients with AD suggest that the contribution of obesity and diabetes on hepatic Aβ‐degrading enzymes and AD pathology deserve to be further investigated.

Lipid species such as cholesterol, oxysterols, fatty acids, sphingolipids, and phospholipids have been investigated as biomarkers or therapeutic targets.^(34,42,43) The fact that the liver is a central organ in lipid metabolism raised the hypothesis that it may play a role in modulating circulating lipids in AD and that liver dysfunction potentially affects lipid biomarkers. Previous reports showing that obesity‐increased hepatic ceramides contribute to the pathogenesis of AD neurodegeneration⁽⁴³⁾ sustain this hypothesis.

Plasma cholesterol reflects hepatic synthesis, whereas cerebrosterol reflects both brain and liver cholesterol metabolism. In lean and obese 3xTg‐AD mice, plasma cholesterol did not differ from NTg controls, although hepatic levels and Hmgcr expression were increased by diet in obese versus lean mice.

Cerebral cerebrosterol in normal mice fed a HFD for 16 weeks did not change, while circulating levels significantly decreased by 50%.⁽⁴⁴⁾ These changes were not accompanied by modifications of bile acids; thus, hepatic glucuronidation might account for this difference. Hepatic metabolism of different oxysterols is altered following HFD⁽⁴⁴⁾; however, our study specifically shows hepatic cerebrosterol glucuronidation to be decreased in obesity. Because 24S‐OH‐C‐3S,24G is formed through sulfonation of 24S‐OH‐C‐24G, its limited formation is believed to reflect limited sulfonation ability in mouse liver.

Cerebrosterol is known to activate the UGT1A3,⁽²²⁾ while UGT1A4 is the main enzyme contributing to its glucuronidation in humans; however, the presence of missense mutations in the murine Ugt1a4 gene leads to the absence of its homolog in the mouse liver (Dr. Barbier’s group, unpublished data). Neither diet nor the triple transgenic genotype had an effect on UGT1A total protein levels, so the role of the different isoforms remains to be elucidated.⁽⁴⁵⁾ Moreover, 24S‐OH‐C plays a minor role in modulating target metabolic genes in the context of obesity, in which numerous other factors are also contributing.^(46,47)

Circulating cerebrosterol is believed to reflect the mass of active neurons and is reduced in neurodegenerative disease proportionally to disease burden.^(15,48) In our study, HFD decreased hepatic cerebrosterol glucuronidation in 3xTg‐AD mice, without affecting its circulating levels. This implies caution when interpreting how blood measurements reflect pathology; specifically, interorgan crosstalk as well as general context should be properly evaluated. Further studies are needed to determine whether the clearance of cerebrosterol into bile acids could contribute to maintaining its circulating levels.

A potential limitation of our study is the ratio between male and female mice in our groups, which favors the latter. We performed an analysis of sex‐driven effects on liver TGs and cholesterol but did not observe major differences (data not shown). Statistical power, however, was very limited for such an analysis. AD features are known to be different between males and females, with females being more susceptible to brain Aβ accumulation.^(24,48) Metabolic features are also different: Young and fertile female mice are protected from NAFLD development, whereas later in life ovarian senescence is strongly associated with severe liver steatosis.⁽⁴⁹⁾ However, in humans, cumulative incidences of dementia calculated based on age, differential mortality, and presence of risk factors are similar in women and men.⁽⁵⁰⁾ Because we debuted the diet assignment at an advanced age and our mice were sacrificed at an old, postmenopausal age and showed no differences in hepatic lipid measures at sacrifice, we included both female and male mice in all analyses.

In conclusion, our study sheds light on the liver–brain axis and strengthens the link between central AD pathology and liver dysfunction, providing potential routes of explanation for peripheral metabolic impairment associated with AD. We show that modulation of hepatic lipid, Aβ, and cerebrosterol metabolism in obese 3xTg‐AD mice differs from control mice, suggesting that long‐time presence of NAFLD can modulate peripheral AD features. These results potentially explain why many biomarkers have not been consistently correlated with AD and why certain therapeutic strategies showed beneficial effects only in particular experimental conditions or patient subgroups. Although these aspects remain to be confirmed in patients with AD, peripheral metabolic context, including liver function, should be taken into consideration when investigating potential markers or therapeutic targets in AD.