Involvement of Huanglian Jiedu Decoction on Microglia with Abnormal Sphingolipid Metabolism in Alzheimer's Disease.

Background: Abnormal sphingolipid metabolism is closely related to the occurrence and development of Alzheimer's disease (AD). With heat-clearing and detoxifying effects, Huanglian Jiedu decoction (HLJDD) has been used to treat dementia and improve learning and memory impairments. Purpose: To study the therapeutic effect of HLJDD on AD as it relates to sphingolipid metabolism.
Methods: The level of sphingolipids in the brains of APP/PS1 mice and in the supernatant of β-amyloid (Aβ)25-35-induced BV2 microglia was detected by HPLC-QTOF-MS and HPLC-QTRAP-MS techniques, respectively. The co-expression of ionized calcium-binding adapter molecule 1 (Iba1) and Aβ as well as four enzymes related to sphingolipid metabolism, including serine palmitoyltransferase 2 (SPTLC2), cer synthase 2 (CERS2), sphingomyelin phosphodiesterase 1 (SMPD1), and sphingomyelin synthase 1 (SGMS1), in the brains of APP/PS1 mice were evaluated by immunofluorescence double labelling. In addition, real-time quantitative reverse transcription-polymerase chain reaction was conducted to determine the mRNA expression of SPTLC2, CERS2, SMPD1, SGMS1, galactosylceramidase (GALC), and sphingosine kinase 2 (SPHK2) in Aβ25-35-stimulated BV2 microglia.
Results: Abnormal sphingolipid metabolism was observed both in APP/PS1 mouse brain tissues and Aβ25-35-stimulated BV2 cells. The levels of sphingosine, sphinganine, sphingosine-1-phosphate, sphinganine-1-phosphate and sphingomyelin were significantly reduced, while the levels of ceramide-1-phosphate, ceramide, lactosylceramide and hexosylceramide significantly increased in Aβ25-35-stimulated BV2 cells. In AD mice, more microglia were clustered in the Aβ-positive region. The decreased level of SGMS1 and increased levels of CERS2, SPTLC and SMPD1 were also found. In addition, the expressions of SPTLC2, CERS2, and SMPD1 in Aβ25-35-stimulated BV2 cells were increased significantly, while the expressions of GALC, SPHK2, and SGMS1 were decreased. These changes all showed a significant correction after HLJDD treatment.
Conclusion: HLJDD is a good candidate for treating AD. This study provides a novel perspective on the potential roles of the sphingolipid metabolism in AD.

Introduction

Alzheimer’s disease (AD) is a primary degenerative disease of the central nervous system that occurs in elderly people1 and has become a major public health problem. Although countless investments have been made in the war against AD, there is currently no known way to prevent or cure this disease. Most of anti-AD drugs have a single molecular target and are mainly acetylcholinesterase inhibitors, which is not an optimal choice for AD patients with multi-pathogenesis.2

Lipid metabolism is closely related to the production, metabolism and aggregation of Aβ, an important pathological product of AD.3 Abnormal sphingolipid metabolism occurs in the urine,4 plasma,5 brain tissue6,7 and cerebrospinal fluid8,9 of AD patients. Sphingolipids are an important class of lipids on cell membranes, mainly including sphingosine (So), sphinganine (Sa), sphingosine-1-phosphate (S1P), sphinganine-1-phosphate (Sa1P), ceramide (Cer), ceramide-1-phosphate (C1P), lactosylceramide (LacCer), hexosylceramide (HexCer) and sphingomyelin (SM). There is a certain correlation between sphingolipid metabolites and the phenotype and function of microglia. A transwell experiments, up-regulation of exosome secretion from neuronal cells by treatment with sphingomyelin synthase 2 (SGMS2) siRNA enhanced Aβ uptake into microglial cells and significantly decreased extracellular levels of Aβ.10 The key enzyme of the sphingosine metabolism pathway, sphingosine kinase 1 (SPHK1) and its receptor, are expressed in mouse BV2 microglia, and SPHK1 can change the expression and production of pro-inflammatory cytokines and nitric oxide in microglia treated with LPS.11 Therefore, the regulation of microglial function by sphingolipid metabolites would be a useful and promising approach in the treatment of AD.

The “toxin damaging brain collaterals” theory by Yong-Yan Wang has been brought out12 and guiding the clinical diagnosis and treatment of brain diseases for decades. This theory refers to the accumulation of toxic, which damages the structure of the brain such as the tiny blood vessels, nerves and brain marrow, and affects the normal physiological function of the brain. In the case of AD, the “brain collaterals” in this theory is equivalent to the “blood brain barrier (BBR) and its carrier function” in modern medicine, and Aβ pertains to “toxicity”. The pathogenesis of AD can be described as the accumulation of Aβ may impair the BBR and its carrier function in the brain, which in turn may promote the accumulation of Aβ in the brain.13 Under the guidance of this theory, the method of detoxification was put forward,12 such as the use of heat-clearing and detoxification drugs.14–18 Heat-clearing is to ameliorate the interior pattern or syndromes of exuberant heat, and detoxicating indicates the measure of reducing the virulence and neutralizing the toxicity of pathogens.19

Huanglian Jiedu decoction (HLJDD), a representative prescription for heat-clearing and detoxicating, is composed of four herbs: Coptis chinensis Franch. (rhizome), Scutellaria baicalensis Georgi (radix), Phellodendron amurense Rupr. (cortex), and Gardenia jasminoides Ellis. (fructus), with a ratio of 3:2:2:3. For centuries, HLJDD has been widely used for the treatment of cerebrovascular diseases, ischaemic stroke, and AD.20–23 The main active components of HLJDD, alkaloids, flavonoids and iridoids improved the central inflammatory status of AD rats by regulating the levels of inflammatory factors.24 In addition, HLJDD suppressed gut dysbiosis and the associated Aβ accumulation, controlled neuro-inflammation and reversed cognitive impairment.2 In our previous study,25 HLJDD-treated APP/PS1 mice showed better performance than vehicle-treated APP/PS1 mice in the Morris water maze test. Meanwhile, in the spatial exploration test, the crossing platform frequency of HLJDD mice was significantly higher than that of model mice. Regulation of microglial activation by HLJDD has also been observed, suggesting that HLJDD inhibits central nervous system inflammation in APP/PS1 mice. The results of blood non-targeted metabolomics suggested that the adjustment of sphingolipid metabolism was accompanied by improved learning and memory in HLJDD-treated APP/PS1 mice. Therefore, we speculate that the therapeutic effect of HLJDD on APP/PS1 mice may be related to microglial sphingolipid metabolism.

At present, few studies have explored the mechanism of HLJDD in the treatment of AD from the perspective of sphingolipid metabolism. Hence, we firstly performed HPLC-QTOF-MS combined with HPLC-QTRAP-MS techniques to determine whether HLJDD improves AD by relating sphingolipids level in vivo and in vitro. Then, immunofluorescence double labelling and real-time quantitative reverse transcription-polymerase chain reaction (qRT-PCR) were conducted to determine the expression of sphingolipid metabolizing enzymes. Our study provides a new idea for the mechanism of HLJDD treatment of AD.

Materials and Methods

Herbal Medicine and Reagents

Coptis chinensis Franch. (rhizome) (batch number, 1711028050), Scutellaria baicalensis Georgi (radix) (batch number, 1709019024), Phellodendron amurense Rupr. (cortex) (batch number, 1709016005), and Gardenia jasminoides Ellis. (fructus) (batch number, 1711018022) were purchased from Anhui Huizhongzhou Traditional Chinese Medicine Pieces Co., Ltd. (Anhui, China) and authenticated by Dr. Qinan Wu (Professor of Pharmacognosy, College of Pharmacy, Nanjing University of Chinese Medicine, Nanjing, China). Voucher specimens were deposited at Nanjing University of Chinese Medicine. A LIPID MAPS internal standard cocktail (internal standards mixture II, 25 µM in ethanol, catalogue LM-6005) was purchased from Avanti Polar Lipids (Alabaster, USA). Aβ peptide (25–35) (Aβ25-35) was obtained from Beijing Bosen Biotechnology Co., Ltd. (Beijing, China). TRIzol total RNA extraction reagent and BeyoRTTM II first strand cDNA synthesis kit were purchased from Biyuntian Biotechnology Co., Ltd. (Shanghai, China). TB Green® Premix Ex TaqTM II was purchased from Baori Biotechnology Co., Ltd. (Beijing, China).

The following primary antibodies were used in these experiments: rabbit anti-CERS2 (Abcam, ab176709, 1:200), rabbit anti-SPTLC2 (Proteintech, 51012-2-AP, 1:200), rabbit anti-SGMS1 (Proteintech, 19050-1-AP, 1:50), rabbit anti-SMPD1 (Proteintech, 14609-1-AP, 1:200), rabbit anti-Aβ polyclonal (Proteintech, 25524-1-AP, 1:200), and goat anti-Iba-1 (Abcam, ab48004, 1:50). Secondary antibodies for the immunofluorescence study were donkey anti-goat IgG H&L (Alexa Fluor® 488) (Abcam, ab150129) and donkey anti-rabbit IgG H&L (Alexa Fluor® 555) (Abcam, ab150074).

Preparation of the Huanglian Jiedu Decoction Extract

HLJDD solution was extracted according to the preferred extraction protocol used in our laboratory.26 Analysis of the constituents of HLJDD was carried out using HPLC with berberine, baicalin and geniposide as standards (Agilent 1260, USA). For reagents and experimental procedures, see the “Determination of the main pharmacodynamic components of HLJDD” section in the . The abundances of berberine, baicalin, and geniposide in the freeze-dried powder of HLJDD were 7.67%, 11.46%, and 2.42%, respectively (, ). The powder was dissolved in 0.5% carboxymethyl cellulose sodium salt (CMC-Na) solution for use.

Non-Targeted Metabolomics Analysis of Sphingolipid Metabolism in APP/PS1 Mouse Brain Tissue

Animals and Drug Treatment

SPF male APP/PS1 (B6C3-Tg (APPswe, PSEN1dE9) 85Dbo/MmJ) double transgenic mice (21 weeks), weighing 27.92±2.00 g, were purchased from the Experimental Animal Center of the Fourth Military Medical University of the People’s Liberation Army and used as the AD model. SPF male C57BL/6 mice (21 weeks), weighing 28.00±2.00 g, were used as blank controls (wild type, WT). The mice were adaptively reared for a week in an environment controlled by light (12/12 h day and night cycle), temperature (25±1°C) and humidity (60±5%) and were randomly divided into 3 groups with 10 mice each: WT group, APP/PS1 group and APP/PS1-HLJDD group (treated with HLJDD at 2.28 g/kg). The HLJDD dosage was calculated using the dosage conversion relationship between mice and humans and the clinical dosage of the HLJDD extract. At the age of 22 weeks, the mice were continuously treated by intragastric administration for 9 weeks. Mice in the WT and APP/PS1 groups were given 0.5% CMC-Na. HLJDD and 0.5% CMC-Na were administered at 0.2 mL/10 g body weight. The study was performed following recommendations provided by the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health (NIH Publication No. 80–23; revised 1978). The Animal Care and Use Committee of Nanjing University of Chinese Medicine approved the protocol and the total number of mice used in this study (No. 202010A022, Item No. 012071001462).

Brain Sample Collection and Processing

After 9 weeks of treatment, 6 mice were randomly selected from each group, brain samples were collected and weighed immediately, and the samples were stored at −80°C until analysis. Brain samples were homogenized by adding 10 volumes of double distilled water. One hundred microlitres of homogenized solution was used to extract the sphingolipid components according to Wang’s27 improved method. The extract was evaporated to dryness in vacuo using a Labconco CentriVap concentrator (Kansas City, USA), and the residues were reconstituted with 100 μL of methanol and vortexed for 120 s. After centrifugation at 14,000 rpm for 10 min at 4°C, the supernatant was transferred to an autosampler vial for further HPLC-QTOF/MS analysis. Five microlitres of brain sample homogenate solution from each group was pooled as quality control (QC) samples and processed according to the above method to obtain quality control samples. During the whole analysis process, QC samples were run every 6 samples to monitor the reproducibility and stability of the LC-MS system throughout the whole operation process.

Liquid Chromatography and Mass Spectrometry

Chromatographic experiments were performed on a Shimadzu LC-20A Series HPLC system (Shimadzu, Japan). A 2 μL aliquot of sample solution was injected into a Poroshell 120 EC-C18 column (2.1 mm × 100 mm, 2.7 μm) maintained at 40°C, and the flow rate was 0.4 mL/min. The mobile phase consisted of solvent A (methanol: H2O: formic acid = 60: 40: 0.2, v/v/v, 10 mM ammonium acetate) and solvent B (methanol: isopropyl alcohol: formic acid = 60: 40: 0.2, v/v/v, 10 mM ammonium acetate). The column was eluted with a gradient of 0 to 10% B at 0–3 min; 10% to 40% B at 3–5 min; 40% to 55% B at 5–5.3 min; 55% to 60% B at 5.3–8 min; 60% to 80% B at 8–8.5 min; 80% B at 8.5–10.5 min; 80% to 90% B at 10.5–16 min; 90% B at 16–19 min; 90% to 100% B at 19–22 min, followed by washing with 100% B and equilibration with 0% B. A typical run time was 20 min.

Mass spectrometry was performed on an AB SCIEX Triple TOFTM 5600 system (AB SCIEX, USA). Nitrogen was used as the atomizing gas and cone gas. The electrospray ion (ESI) source adopted the positive ion scanning mode, and the mass scanning range was 50–1500 m/z. The conditions used for the ESI source were as follows: ion spray voltage of 5.5 kV, electrospray ionization temperature of 550°C, nebulizer gas of 55 psi, drying gas of 55 psi, curtain gas of 35 psi, and decluttering potential of 100 V. Data were collected by the Analyst TF system (version 1.6, AB SCIEX) and analyzed by Peak View software (version 2.0, AB SCIEX).

Data Extraction and Preprocessing

The raw data collected by mass spectrometry were initially processed by AB SCIEX’s Marker View 1.2.1 software. The specific operation flow and parameter settings are as follows: 1) Data reading: wiff format maps were imported into the Marker View software; 2) Chromatographic peak identification: retention time was set to 0–22 min, minimum peak width was set to 25 ppm, minimum retention time peak width was set to 6 scans, and noise threshold was set to 100; 3) Peak alignment: retention time deviation tolerance was set to 0.1 min; 4) Peak filtration: the peaks that did not appear in 80% of the samples were removed, the threshold for extracting the number of peaks was set to 8000; and 5) Normalization: the data were normalized using the total peak area normalization method.

Qualitative Analysis of Sphingolipids and Multivariate Statistical Analysis

The LIPID MAPS () database was searched, the literature was consulted, as many sphingolipid components were selected as possible, and the related molecular formulas, names, structures and classifications were organized to establish the target compound list. Then, PeakView software was used to import original maps, and the primary chromatographic information was extracted through XIC Manager. Qualitative analyses of sphingolipids were performed based on secondary fragmentation information and the cleavage pattern of differently classified SPLs in the literature and database.

Based on the extracted and preprocessed data, the peak areas of the identified sphingolipid components in different groups were extracted and imported into SIMCA 14.1 software for multivariate statistical analysis. Variables with VIP values greater than 1 in orthogonal projection to latent structures discriminant analysis (OPLS-DA) and P values less than 0.05 in the Mann–Whitney U-test were considered to be statistically significant. Then, the variation trend of these variables in each group was analyzed.

Targeted Metabonomic Analysis of Sphingolipid Metabolism in Aβ(25-35) Oligomer-Stimulated BV2 Microglia

Collection of Cerebrospinal Fluid (CSF) Containing HLJDD

SPF male SD rats (7 weeks), weighing 260–280 g (Animal Multiplication Center of Qigong Mountain, Nanjing, China) were housed in an animal laboratory with regulated temperature and humidity of 25±1°C and 60±5%, respectively. Animals were acclimatized for one week and randomly divided into 2 groups with 25 rats each: the control group and HLJDD group (treated with HLJDD at 1.58 g/kg/day). The animals were continuously treated for one week. Rats in the control group were given 0.5% CMC-Na. HLJDD and 0.5% CMC-Na were given by intragastric administration at 0.2 mL/10 g of body weight. The HLJDD dosage was calculated using the dosage conversion relationship between rats and humans and the clinical dosage of the HLJDD extract. After one week of treatment, the CSF of the two groups of rats was collected by the occipital macroscopic puncture method and stored at −80°C until use. The study was carried out following recommendations provided by the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health (NIH Publication No. 80-23; revised 1978). The Animal Care and Use Committee of Nanjing University of Chinese Medicine approved the protocol and the total number of rats used in this study (No. 202011A008, Item No. 012071001462).

CSF samples containing HLJDD have been detected in our previous study.28 Nine active compounds (berberine, berberrubine, jatrorrhizine, palmatine, baicalin, wogonin, oroxylin A, geniposide and gardenin B) could enter the brain tissue through the blood-brain barrier and distribute in CSF. Among them, geniposide (58.16±4.38 ng/mL) was the highest content, followed by berberine (41.07±3.61 ng/mL) and berberrubine (37.44±0.28 ng/mL).

Preparation of Aβ25-35 Oligomers

Aβ25-35 was dissolved in sterile distilled water to obtain an Aβ25-35 solution with a concentration of 1 mM, which was then incubated at 37°C for 72 h.29 The Aβ25-35 oligomers were stored at −20°C for later use.

Cell Culture, Treatment and Morphological Analysis

BV2 microglia were purchased from the China Center for Type Culture Collection (Hubei, China) and cultured in DMEM containing 10% FBS, 100 U/mL of penicillin and 100 μg/mL of streptomycin at 37°C in a humidified incubator with 5% CO2. BV2 microglia were pretreated with 5% CSF containing HLJDD (Aβ-HLJDD group) or CSF from control rats (Aβ group) 1 h, followed by incubation with Aβ25-35 oligomer (20 μM) for 24 h. For morphological analysis, cells were imaged with the inverted microscope (TS2-S-SM, Nikon, Japan) at 200× magnification.

Extraction of Sphingolipid Components in Cell Culture Supernatants

A total of 500 μL cell culture supernatant was placed in a freeze dryer for drying. These samples were processed according to Wang’s27 improved method for extraction of sphingolipid components and brain tissue samples. The extracts were evaporated to dryness in vacuo using a Labconco CentriVap concentrator, and the residues were reconstituted with 250 μL of methanol and vortexed for 120 s. After centrifugation at 14,000 rpm for 10 min at 4°C, the supernatant was transferred to an autosampler vial for further HPLC-QTRAP-MS analysis.

Chromatographic experiments were performed on a Shimadzu LC-20A Series HPLC system (Shimadzu, Japan). Each aliquot of the samples and standard solution (4 μL) was injected into a Poroshell 120 EC-C18 column (2.1 mm × 100 mm, 2.7 μm) maintained at 40°C, and the flow rate was 0.3 mL/min. The mobile phase and gradient elution procedures were identical to those previously described for HPLC-QTOF/MS.

Mass spectrometry was performed on an AB SCIEX Triple QuadTM 5500 linear ion hydrazine mass spectrometer (AB SCIEX, USA) using an ESI source operated in positive mode. The main parameters were set as follows: ion source temperature 550°C, spray voltage 5500 V, curtain gas 241.32 kPa, atomization gas 379.22 kPa, and dry gas 379.22 kPa. The analytes were determined by multiple reactions monitoring mode. The full scan, selective ion scan, and product ion scan modes were used to determine the mass spectrometry parameters of each compound. Data were collected and analyzed by Analyst software (version 1.6, AB SCIEX). The content of each compound under different treatments was calculated by the integrated peak area.

Analysis of Enzymes Related to Sphingolipid Metabolism

Double Immunofluorescence Labelling

Four mice from the WT, APP/PS1 and APP/PS1-HLJDD groups were underwent transcardiac perfusion with saline and then 4% PFA. The brain samples were taken out rapidly and embedded in paraffin blocks using a paraffin embedding station (Leica Biosystems Nussloch GmbH, Leica EG1150H, Germany), and then sectionalized (5 µm) using a rotary microtome (Leica Biosystems Nussloch GmbH, Leica RM2245, Germany). Sections were immersed in xylol for 10 min 3 times and rehydrated in a series of graded alcohol solutions (absolute ethyl alcohol was diluted to 90%, 80%, and 70%) for 5 min each. Antigen retrieval was achieved by dipping the sections in hot citrate buffer (10 mM, pH 6.0) and heating the sections in an autoclave for 8 min. As the sections cooled to room temperature, the sections were rinsed with water and immersed in 3% H2O2 for 10 min to abolish endogenous peroxidase activity. Brain sections from each mouse group were incubated with the following primary antibodies: rabbit anti-CERS2, rabbit anti-SPTLC2, rabbit anti-SGMS1, rabbit anti-SMPD1, rabbit anti-Aβ polyclonal, and goat anti-Iba1 at 4°C overnight. After thorough washing, sections were then incubated for 1 h at room temperature with donkey anti-goat IgG H&L (Alexa Fluor® 488) or donkey anti-rabbit lgG H&L (Alexa Fluor® 555) and then processed with DAPI for 10 min. Five to ten brain sections from individual mice were assessed for each antibody. ImageJ 1.53c was used to calculate the mean integrated density in CA3 region.

Real-Time Quantitative Reverse Transcription-Polymerase Chain Reaction (qRT-PCR)

Total RNA was isolated with TRIzol total RNA extraction reagent according to the manufacturer instructions. NanoDrop One C (Thermo FisherTM, USA) was employed to determine the concentration of RNA. A BeyoRTTM II first strand cDNA synthesis kit was used to reverse transcribe RNA (0.2–1.0 μg) in a 20-μL reaction volume (42°C, 30 min; 95°C, 5 min); then, cDNA (2 μL) was amplified using TB Green® Premix Ex TaqTM II. All tests were performed in duplicate 20 μL reaction mixtures in 96-well plates, and a negative control without cDNA template was included in each run. Visual inspection of the melting curves was used to confirm the specificity of the products during PCR. The expression level of a gene was calculated using the 2−ΔΔCt method30 with glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as the internal control. The primer sequences of serine palmitoyltransferase 2 (SPTLC2), cer synthase 2 (CERS2), galactosylceramidase (GALC), sphingosine kinase 2 (SPHK2), sphingomyelin phosphodiesterase 1 (SMPD1), sphingomyelin synthase 1 (SGMS1) and GAPDH were obtained from primerbank database (), and were described in Table 1. The qRT-PCR amplification reaction conditions were as follows: predenaturation at 95°C for 30s, 40 cycles of denaturation at 95°C for 10s, and annealing at 53°C for 60s.

Table 1

Information of Primer Sequence

Primer	Forward	Reverse
SPTLC2	5ʹAACGGGGAAGTGAGGAACG3’	5ʹCAGCATGGGTGTTTCTTCAAAAG3’
CERS2	5ʹATGCTCCAGACCTTGTATGACT3’	5ʹCTGAGGCTTTGGCATAGACAC3’
GALC	5ʹCGCCTACGTGCTAGACGAC3’	5ʹACGATAGGGCTCTGGGTAATTT3’
SPHK2	5ʹCACGGCGAGTTTGGTTCCTA3’	5ʹCTTCTGGCTTTGGGCGTAGT3’
SMPD1	5ʹTGGGACTCCTTTGGATGGG3’	5ʹCGGCGCTATGGCACTGAAT3’
SGMS1	5ʹGAAGGAAGTGGTTTACTGGTCAC3’	5ʹGACTCGGTACAGTGGGGGT3’
GAPDH	5ʹAGGTCGGTGTGAACGGATTTG3’	5ʹTGTAGACCATGTAGTTGAGGTCA3’

Statistical Analysis

All data were statistically analyzed using GraphPad prism 6.0 (GraphPad Software). The significance of differences was assessed by one-way analysis of variance (ANOVA) followed by Tukey’s post hoc multiple comparisons test. Data were expressed as the mean±SD. Differences were considered to be significant when p<0.05 or p<0.01.

Results

Non-Targeted Metabolomics Analysis of Sphingolipid Metabolism in the Brains of APP/PS1 Mice

The overlapping total ion chromatogram of QC samples in the ESI+ scan mode showed repeatability and stability of HPLC-QTOF/MS analytical methods (Figure 1A). Cer is the simplest sphingolipid composed of sphingosine and a molecule of fatty acid. Galactose/glucose forms a cerebroside at the C-1 position of Cer via a β-glycosidic bond. Since the long-chain base structure contained in Cer and cerebroside in mammals is mainly d18:1, a long-chain base with an m/z of 264 is easily produced; if a dihydrosphingosine backbone is present, an ion fragment with an m/z of 266 is produced; phosphorylcholine or phosphoethanolamine is substituted for the Cer terminal hydroxyl group to form a sphingomyelin, resulting in a choline ion fragment with an m/z of 184.27,31 According to the structure and cleavage rule of sphingolipids (Figure 1B), 45 sphingolipids were identified, including So, Sa, Cer, dihydroceramide, cerebroside, sulfatide and SM (Figure 1C).

Figure 1

Change in sphingolipid metabolism in brain tissues of AD mice and the effects of HLJDD treatment. (A) Overlapping total ion chromatogram of QC samples in positive ion mode. (B) Common structure and lysis of sphingolipids. (C) Primary extraction chromatogram of 45 sphingolipids. (D) OPLS-DA score plots comparing WT (green, circle) and APP/PS1 mice (blue, rectangle). (E) Sphingolipid components that returned to normal levels after HLJDD intervention. Data are shown as the means ± SD (n ≥ 6, WT vs APP/PS1, *p < 0.05, **p < 0.01; APP/PS1 vs APP/PS1-HLJDD, #p < 0.05, ##p < 0.01).

Compared with WT mice, APP/PS1 mice showed significant changes in sphingolipid metabolism (Figure 1D). To further analyze the effect of AD disease status on sphingolipid metabolism, variables with a VIP>1 in OPLS-DA and a P<0.05 in the Mann–Whitney U-test were selected, and these variables were considered to have significant changes in the disease state. A total of 17 metabolites contributed to the grouping (Table 2); among them, 9 sphingolipid metabolites, especially Cer, were adjusted back to normal levels after HLJDD intervention (Figure 1E). These results suggested that Cer may be a critical target for AD therapy.

Table 2

Specific Information and Trends of Sphingolipid Metabolites in Non-Targeted Metabolomics Analysis

No.	Metabolite	Formula	RT (min)	Measured m/z	Error (ppm)	VIP	Trend
1	C16 So	C16H33NO2	4.92	272.2587	1.2	1.02	↑*
2	Sa	C18H39NO2	6.26	302.3067	4.6	1.34	↑*
3	Cer (d18:1/16:0)	C34H67NO3	13.12	538.5209	2.8	1.09	↑*
4	Cer (d18:1/18:0)	C36H71NO3	14.51	566.5512	1.0	1.68	↑**
5	Cer (d18:1/20:1)	C38H73NO3	14.42	592.5640	−3.9	1.50	↑**
6	Cer (d18:1/20:0)	C38H75NO3	12.70	594.5820	0.0	1.11	↑**
7	Cer (d18:1/22:1)	C40H77NO3	15.74	620.5971	−0.9	1.16	↑*
8	Cer (d18:1/22:0)	C40H79NO3	17.16	622.6152	3.2	1.24	↑**
9	Cer (d18:1/23:1)	C41H79NO3	16.39	634.6155	3.5	1.58	↑*
10	Cer (d18:1/24:1)	C42H81NO3	17.15	648.6285	−0.7	1.36	↑*
11	GalCer (d18:1/20:1)	C44H83NO8	14.47	754.6193	0.2	1.23	↑*
12	GalCer (d18:1/22:1)	C46H87NO8	15.73	782.6535	3.9	1.23	↑*
13	GalCer (d18:1/23:1)	C47H89NO8	16.46	796.6669	1.0	1.54	↑*
14	GalCer (d18:1/24:1)	C48H91NO8	17.11	810.6815	−0.3	1.47	↑*
15	SM (d18:1/15:0)	C38H77N2O6P	11.72	689.5595	0.4	1.02	↓*
16	SM (d18:1/18:0)	C41H83N2O6P	13.53	731.6062	0.8	1.21	↑*
17	SM (d18:0/22:0)	C45H93N2O6P	16.72	789.6844	−0.6	1.04	↓*

Notes: (↑/↓indicates higher/lower content, respectively, in the APP/PS1 group compared with the WT group; *p < 0.05, **p < 0.01).

Effects of HLJDD on Microglial Activation

To investigate the effects of HLJDD on the activation of BV2 cells stimulated by Aβ25-35, the morphological changes in BV2 cells were evaluated. As indicated in , resting microglia were spindle-shaped with small cell bodies and long processes. However, Aβ25-35-stimulated BV2 cells presented a typical activated state, which was characterized by cell body enlargement and retracted processes (). These phenomena were attenuated after HLJDD treatment (). The results suggest that HLJDD could reverse the morphological changes induced by Aβ25-35.

Targeted Metabolomics Analysis of Sphingolipid Metabolism in Microglia

The structure of sphingolipids has a very complex molecular composition due to the difference in the length of the fatty acid carbon chain, the number of double bonds, and the number of hydroxyl groups. When sufficient standards cannot be obtained, it is not possible to accurately determine the species of sphingolipids based on precursor ions and characteristic product ion fragments. However, the retention time of sphingolipids species varies with the different molecular weight due to the various length of the carbon chain, the number of double bonds, and the number of hydroxyl groups. Specifically, when the carbon chain of the sphingolipid molecule species is shorter, the double bond and the hydroxyl group are more obvious, the retention time is shorter, and the longer is reverse. The carbon chain length and retention time of the same sphingolipid molecule species with the same double bond and hydroxyl group show a certain degree index relationship.32 Therefore, after inferring the structure from the precursor ion and characteristic product ion fragments, we verified the accuracy by combining the relationship between retention time and structure. The exponential relationship between carbon chain length and retention time was shown in Figure 2A–D. When Cer, LacCer, HexCer and SM have the same double bond and hydroxyl number, the carbon chain length and retention time can be fitted to a good exponential equation (R2>0.99). For the five components (So, Sa, S1P, Sa1P and C1P), the number of these molecules detected was too small, so the numbers were not sufficient to fit the exponential equation, but the retention time of each molecular species of the same sphingolipid component increased with increasing carbon chain length, which also roughly verified its accuracy.

Figure 2

Index equation of fatty acid carbon chain number and retention time of various sphingolipids. Cer (A), LacCer (B), HexCer (C) and SM (D). The n means the number of double bonds.

Finally, 49 sphingolipid molecular species were detected (Figure 3A–F, ). Among them, 30 sphingolipid molecular species showed significant changes (Table 3). The total level of 9 types of sphingolipids () in each cell culture fluid group was obtained after statistical analysis of the levels of various sphingolipid molecules. The levels of So, Sa, S1P, Sa1P and SM were significantly reduced in the model group, while the levels of C1P, Cer, LacCer and HexCer showed an upward trend after Aβ induction, and these changes returned to normal levels after treatment with CSF containing HLJDD (Figure 4A–I). These results suggested that Cer may be a critical target for AD therapy. These results showed that the disorder of sphingolipids metabolism in AD occurs on microglia, which suggests that reprogramming of sphingolipids metabolism in microglia and intervention of HLJDD may be a direction for the treatment of AD.

Figure 3

Extracted ion chromatograms of 49 sphingolipid species. (A) So and Sa, (B) S1P and Sa1P, (C) Cer, (D) LacCer, (E) HexCer and (F) SM. Numbers are the same as those in .

Table 3

Species of Sphingolipids with Significant Changes in Targeted Metabolomics Analysis

No.	Compound	Concentration (nmol/mL Cell Culture Fliud)/(Unexpected Text Node “x”)
		CON	Aβ	Aβ-HLJDD
1	So (d16:1)	351.46±8.02	309.58±13.14**	423.93±38.61##
2	So (d18:1)	106.66±5.54	91.37±3.98**	112.63±5.94##
3	Sa (d16:0)	5098.56±186.85	4360.87±318.85**	7248.34±305.64##
4	Sa (d18:0)	20.76±3.89	9.88±3.95**	18.57±2.59##
5	S1P (d16:1)	10.28±0.77	7.47±0.56**	10.51±2.21##
6	S1P (d19:1)	3.36±0.08	3.10±0.02**	3.56±0.05##
7	Sa1P (d16:0)	5.01±0.27	3.67±0.18**	6.47±0.76##
8	C1P (d18:1/14:0)	1.25±0.21	1.48±0.13*	1.08±0.23##
9	C1P (d18:1/16:0)	0.45±0.32	0.89±0.19*	0.20±0.54#
10	Cer (d18:1/16:0)	240.06±14.00	296.20±11.05**	58.28±7.78##
11	Cer (d18:1/18:0)	56.45±9.20	93.60±14.28**	68.50±10.21##
12	Cer (d18:1/20:0)	6.56±1.30	9.62±0.63**	4.72±0.21##
13	Cer (d18:1/24:0)	22.01±5.50	50.70±14.06**	21.95±3.56##
14	Cer (d18:1/24:1)	18.77±4.78	24.15±1.85*	20.76±0.84##
15	LacCer (d18:1/18:0)	3.55±0.20	3.82±0.15*	3.13±0.23##
16	LacCer (d18:1/20:0)	2.69±0.14	2.86±0.09*	2.74±0.05#
17	LacCer (d18:1/22:0)	4.18±0.22	4.49±0.24*	3.72±0.41##
18	HexCer (d18:1/16:0)	53.88±5.07	65.21±10.18*	45.36±6.06##
19	HexCer (d18:1/18:0)	3.88±0.49	5.18±1.11*	3.26±1.12#
20	HexCer (d18:1/20:0)	3.05±0.47	4.53±1.10*	3.44±0.76#
21	HexCer (d18:1/22:0)	35.72±6.02	44.82±7.54*	31.59±4.73##
22	SM (d18:1/17:0)	14.57±2.08	10.92±1.85**	13.53±2.01#
23	SM (d18:1/18:1)	20.49±1.19	24.86±4.45*	20.04±1.57#
24	SM (d18:1/18:0)	57.42±5.34	47.70±3.26**	53.95±4.69#
25	SM (d18:1/20:0)	26.35±3.55	21.46±2.95*	26.86±4.33#
26	SM (d18:1/22:0)	97.15±7.53	83.64±1.55**	106.27±20.08#
27	SM (d18:1/23:0)	25.18±2.13	22.09±0.87**	23.53±0.80#
28	SM (d18:1/24:0)	88.96±5.33	73.56±3.79**	84.97±3.79##
29	SM (d18:1/25:1)	3.80±0.33	3.35±0.23*	3.77±0.38#
30	SM (d18:1/26:0)	1.51±0.27	1.20±0.12*	1.52±0.08##

Notes: (n=6, CON vs Aβ, *p < 0.05, **p < 0.01; Aβ vs Aβ-HLJDD, #p < 0.05, ##p < 0.01).

Figure 4

Sphingolipid metabolites secreted by Aβ-stimulated BV2 microglia with HLJDD. Total level of So (A), Sa (B), S1P (C), Sa1P (D), C1P (E), Cer (F), LacCer (G), HexCer (H), and SM (I) in BV2 microglia culture medium. Data were shown as the means±SD (n ≥ 6, CON vs Aβ, *p < 0.05, **p < 0.01; Aβ vs Aβ-HLJDD, #p < 0.05, ##p < 0.01).

Double Immunofluorescence Labelling Analysis of Sphingolipid Metabolizing Enzymes in APP/PS1 Mice

Clearly, in CA3 region of APP/PS1 mice, the plaques immune-stained with Aβ were increased relative to WT group, which is the usual pathology of AD (Figure 5A). Microglia were activated in the AD state, which then induces and maintains a chronic inflammatory state, leading to neuronal damage and neurodegeneration.33 As shown in Figure 5A, APP/PS1 mice showed significant microglial aggregation in the Aβ immune-staining region. After HLJDD intervention, the activation of microglia around Aβ plaques was reduced (Figure 5A). In order to observe the effect of HLJDD on microglia sphingolipid metabolism under AD condition, we performed immunofluorescence and we found that HLJDD increased the level of SGMS1 and decreased the level of CERS2, SPTLC and SMPD1 (Figure 5B–E). These results suggest that inhibiting the activation of microglial inflammatory phenotypes may be one of the mechanisms by which HLJDD improves AD. More importantly, HLJDD could regulate the metabolism of sphingolipids in microglia under AD pathological conditions.

Figure 5

The levels of sphingolipid metabolizing enzymes in APP/PS1 mice. Representative immunofluorescence results of Aβ (A), CERS2 (B), SPTLC2 (C), SGMS1 (D), and SMPD1 (E) in microglia in hippocampal CA3 region; scale bar, 50 μm. Six random images per section and n=4 mice per group were analyzed. Data were shown as the means±SD (CON vs APP/PS1, **p < 0.01; APP/PS1 vs APP/PS1-HLJDD, ##p < 0.01).

qRT-PCR Analysis of Sphingolipid Metabolizing Enzymes in Microglia

We also examined the expressions of sphingolipid metabolizing enzymes in Aβ25-35-stimulated BV2 cells. Sphingolipid metabolism-related enzymes were changed significantly after different treatments. The expressions of SPTLC2, CERS2, and SMPD1 in Aβ25-35-stimulated BV2 cells were increased significantly, while the expressions of GALC, SPHK2, and SGMS1 showed the opposite trend, and these changes all showed a significant correction after treatment with 5% CSF containing HLJDD (Figure 6A–F).

Figure 6

Transcription levels of sphingolipid metabolizing enzymes in BV2 microglia. mRNA levels of SPTLC2 (A), CERS2 (B), GALC (C), SPHK2 (D), SMPD1 (E), and SGMS1 (F). Data were shown as the means±SD (n ≥ 6, CON vs Aβ, *p < 0.05, **p < 0.01; Aβ vs Aβ-HLJDD, #p < 0.05, ##p < 0.01).

Sphingolipid components and enzymes related to sphingolipid metabolism that significantly changed after Aβ25-35 oligomer induction and HLJDD intervention were screened, and their changes in the sphingolipid metabolism pathway were labelled to obtain a schematic diagram of the changes in the sphingolipid metabolism pathway (Figure 7).

Figure 7

Diagram of the sphingolipid metabolism pathway in BV2 microglia. The red arrow indicates the sphingolipid components (blue) and sphingolipid metabolism-related enzymes (brown) that are upregulated or downregulated after Aβ25-35 oligomer induction; the green arrow indicates the sphingolipid components (blue) and sphingolipid metabolism-related enzymes (brown) that are upregulated or downregulated after HLJDD treatment.

Discussion

AD is a common neurodegenerative disease. With the increasing prevalence of AD, the demand for drugs to treat AD has become increasingly urgent. Heat clearing and detoxification, as one of the treatment rules of AD, have shown good application prospects in AD treatment in recent years.34 HLJDD, a classic prescription in heat-clearing and detoxifying decoctions, was used in China and Japan to treat stroke and dementia.35,36 A previous experiment25 by our research group found that HLJDD can improve learning and memory impairments in APP/PS1 mice during the Morris water maze test. In addition, the metabolomics results of APP/PS1 plasma samples indicated that neuro-inflammation and lipid metabolism disorders (including sphingolipid metabolism) may be important pathogenic factors in the pathogenesis of AD. In this study, we mainly used non-targeted metabolomics and targeted metabolomics to analyze the changes in sphingolipid metabolism in the brains of APP/PS1 mice after HLJDD treatment and in Aβ25-35-stimulated BV2 microglia treated with CSF containing HLJDD. Through this research, we tried to study the role of HLJDD in AD as it relates to lipid metabolism, especially sphingolipid metabolism.

To avoid the interference of complex components in the serum and to increase the relevancy of the research about the effectiveness of TCM,37–39 medicated CSF was taken for in vitro studies. Nine active components of HLJDD, including berberine, berberrubine, palmatine, jatrorrhizine, baicalin, wogonin, oroxylin A, geniposide, and gardenin B were detected in CSF containing HLJDD, which proved that they could pass the blood-brain barrier to exert effects. The top three ingredients were geniposide, berberine and berberrubine.28 A large number of researches have reported that geniposide may play a role in the treatment of AD by enhancing autophagy and lysosomal clearance of Aβ fibrils,40 inhibiting nuclear factor kappa B,41 enhancing cholinergic neurotransmission,42 suppressing the mitochondrial oxidative damage and increasing the mitochondrial membrane potential and activity of cytochrome c oxidase.43 Berberine could alleviate Aβ-induced mitochondrial dysfunction and synaptic loss,44 target the hyper phosphorylation of tau and the autophagy clearance of tau,45 and activate AMP-activated protein kinase. At present, studies on anti-AD of berberrubine are rare, but its derivatives displayed high antioxidant activity, and had the great ability to inhibit Aβ aggregation.46 There was evidences that most of other ingredients may be candidate drugs for AD, such as palmatine,36 jatrorrhizine,36 baicalin,47 wogonin,48,49 and geniposide.40 It is well known that TCM formula is a complex system, although these components in CSF were low, combinations of them can make the prescriptions more suitable for clinical application through component-component synergic interactions that improve pharmacological activities.

Researches in the past decade have clearly indicated that sphingolipids are not only the structural components of the cell membrane but also act as signal molecules controlling a majority of cellular events, including signal transduction, cell growth, differentiation, and apoptosis.50–52 Studies suggested that even minor changes in sphingolipid balance may play significant roles in the development of AD.53

It was found that with ageing, an increase in various stress factors and the deposition of Aβ, SMPD can hydrolyse SM to produce Cer, which in turn can not only stabilize the activity of APP lyase 1 and promote Aβ production but also induce apoptosis by the recombinant plasma membrane.6,54 The increase level of Cer in AD brains has a toxic effect on neurons; additionally, it can promote the production of cytokines IL-2 and IL-6 and trigger neuro-inflammation.55,56 According to our results, Cers had the most obvious changes, which could be one of the specific biomarkers against AD. Cers, the central molecules in the biosynthesis and catabolism of sphingolipids, are mainly derived from three pathways: the de novo synthesis pathway of serine and palmitoyl CoA, the cyclic pathway of reacylation of So and the biodegradation pathway of sphingolipids57 (Figure 6). All sphingolipids are connected in the phospholipid bilayer by Cer. Analysis of epidemiological evidence of the role of Cer in AD revealed elevated levels of Cer in AD patients. Increased Cer levels prior to the clinical diagnostic stage of AD may be related to the etiopathophysiology of the disease.58–60 Specifically, evidence regarding Cer C16:0 and Cer C24:1 is particularly strong.61–65 SM may be another specific biomarker against AD. However, the changes in SMs are more complex, as the levels of different SMs species are inconsistent in different AD clinical studies.61,66,67 Overall, SMs appears to have a trend toward lower levels associated with AD, although only a few studies have been published. Our results are consistent with the above clinical findings, which at least provide experimental support for identifying which Cer and/or SM species are associated with AD and can serve as biomarkers.

Besides Cer and SM, it was found that the contents of So and Sa were significantly reduced in the urine of AD patients.4 As an intermediate product of sphingolipid metabolism, S1P can not only act as a cell signal molecule to regulate cell proliferation, differentiation, adhesion and migration, but also act as a second messenger to regulate the concentration of intracellular Ca2+ and affect cell growth. A decrease in S1P was found in the brains of AD patients.6,68

Our results suggest that HLJDD has shown significant improvement in disordered sphingolipid metabolism, both in vivo and in vitro. In Japan, HLJDD has been used as a common prescription for the treatment of AD, and its effect on stroke sequelae and cerebrovascular dementia has been recognized.69 Moreover, the addition of orengedoku-to (the same prescription of HLJDD in Japan) to yokukan-san (Kampo prescription) exerted the same efficacy as aripiprazole in controlling aggressiveness in an Alzheimer’s-type dementia patient without any adverse effects.21 Clinically, HLJDD could reduce the level of inflammatory factors in patients with AD, reduce the toxic and side effects caused by pitavastatin, improve the treatment efficiency and ensure medication safety.70 Recently, HLJDD has achieved remarkable efficacy in the treatment of AD with the specific characteristics of anti-inflammation and oxidation resistance, preserving energy metabolism, reducing Aβ production, and improving memory in AD mice.71–74 In summary, based on the current experimental results and existing clinical evidence, HLJDD is a Chinese herbal formula with good prospects for the treatment or adjuvant treatment of AD.

Of note, the levels of Cer and its derivatives were significantly changed in both APP/PS1 mice and Aβ25-35-stimulated microglia, which provides partial support for further research on improving AD by regulating sphingolipids. More attention should be paid to the specific relationship between AD and key sphingolipids, which may help give better insights into the pathogenesis of AD and the potential mechanism of HLJDD treatment in AD.