The role of intestinal endotoxemia in a rat model of aluminum neurotoxicity.

The present study aimed to investigate the effects of intestinal endotoxemia (IETM) in a rat model of aluminum neurotoxicity established by D-galactose and aluminum trichloride (AlCl3). Adult Wistar rats were administered D‑galactose and AlCl3 to create the aluminum neurotoxicity model. The learning and memory abilities of the rats were subsequently observed using a Morris water maze test and the serum levels of lipopolysaccharide (LPS), tumor necrosis factor (TNF)‑α, interleukin (IL)‑1, diamine oxidase (DAO), glutamine (Gln) and glutaminase were measured. The expression of S‑100β in the serum was detected using an enzyme‑linked immunosorbent assay. The expression levels of the amyloid β‑protein (Aβ) precursor (APP), presenilin 1 (PS1), β‑site APP‑cleaving enzyme (BACE), zona occludens protein (ZO)‑1 and Aβ 1‑40 in the brain of rats were detected via reverse‑transcription polymerase chain reaction, western blotting and immunohistochemistry. The levels of LPS, TNF‑α, IL‑1, DAO, Gln and S‑100β in serum and the mRNA and protein expression levels of APP, PS1, BACE and Aβ1‑40 in the brain were markedly increased in the model rats compared with controls. The level of glutaminase in the serum and the expression of ZO‑1 in the brain were decreased in the model rats compared with controls. IETM was present in the rat model of aluminum neurotoxicity established by D‑galactose and AlCl3 and may be important in the development of this neurotoxicity.

Introduction

The first reported case of aluminum toxicity in humans was from the early 1970s and following this, aluminum overexpression has been demonstrated to result in severe brain damage and neurodegeneration (1). Aluminum-induced neuronal injury is associated with the neuroinflammatory response (2,3). Previous studies have indicated that the consumption of anti-inflammatory medication attenuates aluminum-induced functional neurotoxicity in rats (4).

Intestinal endotoxemia (IETM) is involved in liver failure, is associated with lipopolysaccharides (LPS) and has previously been demonstrated to exhibit a pathogenetic mechanism of initiation (5). Typically, mild cases of IETM often result in chronic hepatic failure (6). Inflammation induced by LPS under conditions of IETM is important in the development of numerous diseases (7,8), however, if IETM-induced inflammation occurs during the development of aluminum neurotoxicity, remains to be elucidated.

The aim of the present study was to investigate the effect of inflammation induced by IETM in a rat model of aluminum neurotoxicity established using D-galactose and aluminum trichloride (AlCl3). D-galactose was used due to its known neurotoxic effect (9). Following successful creation of the rat model of aluminum neurotoxicity, the learning and memory abilities of the rats were observed. The serum levels of LPS, tumor necrosis factor (TNF)-α, interleukin (IL)-1, diamine oxidase (DAO), glutamine (Gln) and glutaminase were detected to evaluate the degree of IETM. The expression levels of amyloid β-protein (Aβ) precursor (APP), presenilin 1 (PS1), β-site APP-cleaving enzyme (BACE), zona occludens protein (ZO)-1 and Aβ1-40 in the brain were observed, in addition to the total quantity of lysozyme (LYZ) in the liver and S-100β in the serum of the rats. The results of the present study reveal the underlying role of LPS in the development of aluminum toxicity and thus, may provide novel strategies for the prevention and treatment of associated clinical diseases such as Alzheimer's disease and amyotrophic lateral sclerosis.

Materials and methods

Experimental protocol and ethics statement

Rats were provided by Vital River Experimental Technology Company Ltd. (Beijing, China). A total of 48 adult (age, 9–11 weeks) male Wistar rats, weighing 200–250 g, were housed 6 per cage at 20–25°C with a relative humidity of 50–60%, a 12 h light-dark cycle and free access to food and water. Rats were randomized to either receive vehicle (0.9% NaCl; 85 mg.kg-1.day-1) or D-galactose intraperitoneal injection (60 mg.kg-1.day-1) and AlCl3 (25 mg.kg-1.day-1) for 90 days, to establish the aluminum neurotoxicity model. Following this, the learning and memory abilities of the rats were observed using a Morris water maze. The serum levels of LPS, TNF-α, and IL-1 were determined by the chromogenic Limulus amoebocyte lysate (CLAL) and radioimmunity assays. The level of DAO was measured using a Diamine oxidase colorimetric assay kit (Shanghai Bairui Biotech Co., Ltd., Shanghai, China) according to the manufacturer's instructions. The levels of Gln were measured using a Glutamine Colorimetric Assay kit (Biovision, Inc., Milpitas, CA, USA), according to the manufacturer's instructions, and glutaminase was measured using the Glutaminase ELISA assay kit (cat. no. 201233721; Cusabio Biotech Co., Ltd., Wuhan, Hubei, China) according to the manufacturer's instructions. All experimental animal procedures were approved by the Laboratory Animal Use and Care Committee of Shanxi Medical University (Taiyuan, China; permit no. SXMU-2012-18;) and the Ethics Committee of Animal Experiments of Shanxi Medical University (permit no. 20120623-1). All surgery was performed under sodium pentobarbital anesthesia and all possible efforts were made to minimize the suffering of the experimental rats. The rats were sacrificed via anesthetic overdose.

Morris water maze

The Morris water maze was used to test the learning and memory of the rats for 5 days (n=10/group) and was performed 8 weeks following administration (10). For this experiment, a circular stainless steel tank (155 cm in diameter and 60 cm deep) containing water (24–26°C) to a depth of 40 cm was used; the extramaze cues, which consisted of four uniquely colored and textured inserts (coarse plastic mesh, metal screen, ridged plastic and sandpaper) placed on the arms of the plus-maze, were kept constant. The rats learned to escape from the water by searching for a submerged, and therefore hidden, Plexiglas platform (10 cm in diameter and 38.5 cm high), which was kept in a fixed position. To familiarize them with the experimental situation, prior to the experiment, the rats swam for 90 sec with the platform removed. During each trial, the animal was placed in the water facing the wall at one of five designated starting points. Animals that failed to find the platform within 60 sec were placed onto the platform and kept there for 30 sec, then the rats were removed from the maze until the next repeat of the experiment. The time taken to find the platform, termed the escape latency, was measured. This test was performed once for each of the 5 starting points per day for 5 days.

Clal

The CLAL test kit was obtained from Chromogenix (cat. no. 20120056; Molndal, Sweden). The analysis was conducted according to the manufacturer's protocol. The coefficient of variation was 8% (n=10/group).

Immunohistochemistry

The expression of LYZ in the liver and Aβ1-40 in the brain (hippocampus) were detected via immunohistochemistry (11–13). Rabbit anti-rat/−rabbit LYZ and Aβ1-40 IgG antibodies (Abcam, Shanghai, China) were used. Following the completion of the Morris water maze experiments, 12 rats (6 rats/group) were sacrificed and the whole brain and liver were removed and dissected. Prior to sectioning, liver tissue and hippocampus samples were fixed in 10% formalin for 24 h at room temperature, then embedded in paraffin. The paraffin blocks were cooled to −10°C to ease sectioning. Using the Microm HM340 E microtome (Thermo Fisher Scientific Inc., Waltham, MA, USA), 4-µm sections were generated. The EnVision™ staining kit was used according to the manufacturer's instructions, for immunohistochemical analyses [G|2 Doublestain System, Rabbit/Mouse (DAB+/Permanent RED); cat. no. K5361; Dako DK; Agilent Technologies, Inc., Santa Clara, CA, USA]. The optimal antigen retrieval method and concentration to use were determined per antibody. Following deparaffinization in dimethylbenzene twice at room temperature for 5 min each time, the slides were washed in PBS containing 0.05% Tween-20 prior to antigen retrieval in the microwave (for liver tissues; 2 min 780 W, 10 min 150 W and 10 min 80 W) or in 70% formic acid (for hippocampus samples). The slides were placed in cuvettes, as a part of the capillary gap staining method (Thermo Fisher Scientific, Inc.), which was performed as described previously (14). Endogenous peroxidase activity was blocked by the EnVision™ dual endogenous enzyme block (Agilent Technologies, Inc.). Following washing with PBS containing 0.05% Tween-20, a second blocking step was applied using PBS, 0.1% bovine serum albumin (BSA; Sigma Aldrich; Merck KGaA, Darmstadt, Germany), 1% NHS and 0.2% Triton X-100. Then, the primary antibodies [rabbit anti-rat/−rabbit LYZ (cat. no. 20120789) and Aβ1-40 (cat. no. 20123349) IgG antibodies; Abcam, Shanghai, China; with a 1:3,000 dilution in 0.1% BSA/PBS] were added for 10 min at room temperature, followed by washing with PBS containing 0.05% Tween-20 and the addition of the EnVision™ polymer/horseradish peroxidase (HRP) goat anti-rabbit secondary antibody (cat. no. 201213219; 1:500 dilution; Dako Cytomation; Agilent Technologies, Inc.) for 10 min at room temperature. Following washing with PBS, DAB+ (from EnVision™ staining kit; Dako DK; Agilent Technologies, Inc.) was added to initiate the enzymatic reaction and allow for visualization of the elements. A total of 10 high magnification fields were randomly selected from each slice and the number of positive cells per high magnification field (upright light microscope; CX31-LV320; Olympus Corporation, Tokyo, Japan) were counted. Following this, the average number of positive cells per slice was calculated.

Enzyme-linked immunosorbent assay (ELISA)

The S-100β level was measured using an S-100β ELISA kit (cat. no. 20120166; Neogen Europe, Ltd., Lansing, MI, USA) according to the manufacturer's protocol (n=10/group).

Western blotting

Protein was extracted from fresh brain tissue using a ProteoExtract Subcellular Proteome Extraction kit (Sigma Aldrich; Merck KGaA). Protein concentration in the lysates was evaluated using a bicinchoninic acid protein assay kit according to the manufacturer's instructions (Thermo Fisher Scientific, Inc.). Following 10% sodium dodecyl sulfate polyacrylamide gel electrophoresis (5 µg protein applied) and transfer onto a nitrocellulose membrane, the membranes were blocked with 5% BSA (Sigma Aldrich; Merck KGaA) and 0.05% Tween-20 in Tris-buffered saline (TBST) for 1 h at room temperature. This was followed by overnight incubation at room temperature with the following primary antibodies: Monoclonal rabbit anti-rat ZO-1 antibody (1:200; cat. no. 201212315; Abcam), monoclonal rabbit anti-rat APP antibody (1:500; cat. no. 20121232; Abcam), monoclonal rabbit anti-rat PS-1 antibody (1:1,000; cat. no. 20123343; Abcam), monoclonal rabbit anti-rat BACE1 antibody (1:500; cat. no. 201233561; Abcam) and monoclonal rabbit anti-rat β-actin antibody (1:1,000, cat. no. 201214231; Abcam). Following three washes with TBST, the membranes were incubated with a HRP-conjugated anti-rabbit antibody (1:5,000; Santa Cruz Biotechnology, Inc., Dallas, TX, USA) for 2 h at room temperature. The membranes were exposed to film (Kodak, Rochester, NY, USA) and developed. The films were scanned and analyzed using the Kodak IS440 Automated Digitizing System and image analytical software (ImageQuant TL v2005; GE Healthcare Life Sciences, Uppsala, Sweden) for densitometric analysis. Experiments were repeated 3 times.

Reverse-transcription polymerase chain reaction (RT-PCR)

Primers: APP (295 bp), forward 5′-GGATGCGGAGTTCGGACATG-3′ and reverse 5′-GTTCTGACTCTGCTCAAAG-3′; PS-1 (186 bp), forward 5′-AGATGCCTCCTCTGTCCTCA-3′ and reverse 5′-CCGTCTTTGGGCATACATCT-3′; BACE1 (309 bp), forward 5′-CACCGAGACCGACGAAGAGCC-3′ and reverse 3′-CTAATAGGCTATGGTCATGAGGGT-3′; GAPDH (307 bp), forward 5′-TTGCCAGTTGCTTTAGTGATA-3′ and reverse 5′-CTTTTTCCCCCATTTCATTTC-3′.

Total RNA from fresh brain tissue samples was extracted using the TRIzol® reagent (Takara Biotechnology Co., Ltd., Dalian, China) according to the manufacturer's instructions. RNA was reverse transcribed to cDNA using the Takara PrimeScript 1st Strand cDNA Synthesis kit, according to the manufacturer's instructions, and the obtained cDNA was used as a template to perform PCR amplification. Semi-quantitative RT-PCR was performed with a mixture of the cDNA product, primers, dNTP and Taq DNA polymerase (Invitrogen; Thermo Fisher Scientific, Inc.). The thermocycling conditions used were as follows: 95°C for 30 sec, 55°C for 30 sec and 72°C for 30 sec for 25 cycles, followed by a final extension at 72°C for 5 min. Results were normalized to the APP reference gene. Electrophoresis was performed on 1.5% agarose gel (10 mA; 100 V; 30 min). The images were scanned and then analyzed with Multi-Analyst software (Bio-Rad Laboratories, Inc., Hercules, CA, USA).

Statistical analysis

Data were analyzed using the SPSS software version 22.0 (IBM Corp., Armonk, NY, USA). All values are expressed as the mean ± standard deviation. Statistical analysis was performed using an unpaired Student's t-test, multiple-factor repetitive measurement and one-way repeated measures analysis of variance (for learning and memory abilities). P<0.05 was considered to indicate a statistically significant difference.

Results

Learning and memory abilities

The rat escape latency in the Morris water maze from days 1–5 was 59±22, 52±18, 38±13, 30±11 and 25±9 sec, respectively, in the D-galactose + AlCl3 group and 39±12, 30±10, 24±8, 15±7 and 12±5 sec, respectively, in the control group (Fig. 1A and B). These data are additionally presented in Fig. 1C. There were no differences in the two groups from days 1–3 (P>0.01). However, from days 4–5, the escape latency in the D-galactose + AlCl3 group was increased compared with the control group (30±11 vs. 15±7 sec and 25±9 vs. 12±5 sec, respectively; P<0.01). From days 4–5, the swim path of the control group was altered from a random line to a straight line. However, the swim path of the test group remained random (Fig. 1B). The memory ability was decreased in the rats treated with D-galactose and AlCl3.

Figure 1.

Effect of D-galactose and AlCl3 on cognitive impairment in rats. Swim path of (A) control group and (B) aluminum neurotoxicity model group. (C) Rat escape latency observed in the Morris water maze, from days 1–5. Sec, sec; D, day; AlCl3, aluminum trichloride. **P<0.01 vs. control group.

Levels of TNF-α, IL-1, and LPS

The geometric means of the LPS, TNF-α and IL-1 levels in the normal rats were 0.76±0.08 EU/ml, 1.0±0.11 ng/ml and 23.96±3.39 pg/ml, respectively. However, those in the test group were 0.89±0.07 EU/ml, 1.22±0.16 ng/ml and 38.38±3.48 pg/ml, respectively, with a significant difference observed (P<0.01; Fig. 2).

Figure 2.

Concentrations of the LPS, TNF-α and IL-1 in rat plasma. (A) LPS and TNF-α levels in the control and model groups. (B) Level of IL-1 in the control and model groups. LPS, lipopolysaccharide; TNF-α, tumor necrosis factor-α; IL, interleukin. **P<0.01 vs. control group.

Expression of LYZ in liver

There were numerous brown LYZ cells in the control rat livers (30.6±8.2; n=10), however fewer LYZ cells were present in the livers of the aluminum neurotoxicity model rats (18.1±5.1; n=10; P<0.01 vs. control group; Fig. 3). This observation indicated decreased Kupffer cell function.

Figure 3.

Expression of lysozyme in the liver (indicated by red arrows). Tissue sections obtained from (A) control and (B) aluminum neurotoxicity model rats, detected via immunohistochemistry. Magnification, ×400.

Intestinal mucosal barrier function

The levels of DAO and Gln in the serum and intestinal mucosa of the model rats were significantly greater compared with control rats (P<0.01), whereas the level of glutaminase was decreased in the model rats compared with control rats (P<0.01; Table I).

Table I.

Levels of DAO, glutaminase and Gln in sera and intestinal mucosa.

			Gln
Group	DAO (U/ml)	Glutaminase (mmol/h.g)	Sera (mg/dl)	Intestinal mucosa (mg/g)
Control	0.52±0.13	2.37±0.34	50.37±16.85	3.28±1.24
D-galactose+AlCl3	1.18±0.36[a]	1.24±0.31[a]	196.54±4357[a]	16.54±6.27[a]

Data are presented as the mean ± standard deviation (n=10).

P<0.01 vs. control. DAO, diamine oxidase; Gln, glutamine; AlCl3, aluminum trichloride.

Blood-brain barrier (BBB) function

The expression of S-100β in the serum (0.33±0.18) was increased in the model rats compared with control rats (0.11±0.03; n=10; P<0.01). The expression of ZO-1 in the brain was increased in the control rats (53.3±8.4; ratio of ZO-1/β-Actin) compared with the model rats (26.9±5.6; P<0.01; Fig. 4). These data demonstrated that the BBB function was decreased and permeability was increased in the model group.

Figure 4.

Expression of ZO-1 in the brain, detected via western blotting. (A) Western blotting was performed to evaluate the expression of ZO-1 in the brain. (B) The ratio of ZO-1/β-actin. ZO-1, zona occludens protein; Model, aluminum neurotoxicity model. **P<0.01 vs. control group.

mRNA and protein expression levels of APP, PS and BACE1

As presented in Fig. 5, the addition of D-galactose and AlCl3 resulted in a marked increase in the expression of APP, PS1 and BACE1 mRNA (72±12, 52±10 and 72±15%, respectively) that were ~two-fold increases compared with control rats (30±6, 32±7 and 36±9%, respectively). The protein expression levels of APP, PS1 and BACE1 in the model and control groups demonstrated a similar trend to the aforementioned mRNA results.

Figure 5.

mRNA and protein expression levels of APP, PS1 and BACE1 in the rat brain. Expression of (A) APP, (B) PS1 and (C) BACE1 mRNA in the brain detected via reverse transcription-polymerase chain reaction. (D) Expression of APP, PS1 and BACE1 protein in the brain detected via western blotting. M, DNA molecule marker; 1, control group; 2, aluminum neurotoxicity model group; bp, base pairs. APP, amyloid β-protein precursor; PS1, presenilin 1; BACE, β-site APP-cleaving enzyme.

Expression of Aβ1-40

As presented in Fig. 6, the expression of Aβ1-40 in the hippocampal brain of the aluminum neurotoxicity model rats (24.1±5.1) was increased compared with control rats (8.6±2.2; n=10; P<0.05; Fig. 6C).

Figure 6.

Expression of Aβ1-40 in the rat brain. (A) Control and (B) aluminum neurotoxicity model Aβ1-40 expression, detected via immunohistochemistry. The brown particles indicated by the red arrow are Aβ1-40 positive cells (magnification, ×200). (C) Expression of Aβ1-40 in the rat brain. *P<0.05 vs. control group. Aβ, amyloid β-protein.

Discussion

The pathological presentation of aluminum neurotoxicity involves regionalized neuronal dysfunction/apoptosis, lesions termed neurofibrillary tangles and deposition of Aβ protein (15,16). In previous studies, hypotheses have been proposed to link the lesions and cytopathology of aluminum neurotoxicity with the development of inflammation (2). Inflammation has previously been suggested to act as a marker and potential inducer of aluminum neurotoxicity (17).

Han (5), Han (6) and Zhao and Han (7) first suggested that liver injury may result from increased levels of LPS. Advanced cases of IETM typically result in excessive inflammation with severe hepatic necrosis, hepatitis and acute liver failure. The human endotoxin model, an in vivo model of systemic inflammation in which LPS is injected or infused intravenously into healthy volunteers, may potentially be of use in elucidating the underlying mechanisms involved (18).

Cerebral deposition of Aβ is a feature of aluminum neurotoxicity. Induction of Aβ overexpression via AlCl3 or D-galactose in the rat or mouse brain results in animal models of aluminum neurotoxicity and aging. Aluminum and D-galactose affect the expression of Aβ metabolism-associated molecules, suggesting that this mouse model may be useful for studying the mechanisms and biomarkers of aluminum neurotoxicity (9).

In the present study, the escape latency of rats treated with D-galactose and AlCl3 was increased compared with the control group. The model rats exhibited a longer escape latency to find the platform when compared with the control rats. D-Galactose and AlCl3 resulted in increased mRNA and protein expression levels of APP, PS1 and BACE. The expression of Aβ was additionally increased. These results verify those from previous reports that suggest high doses of D-galactose and AlCl3 are associated with neurotoxicity (9). To the best of our knowledge, the present study demonstrated for the first time that the levels of LPS, TNF-α and IL-1 in the blood of rats treated with D-galactose and AlCl3 were significantly increased compared with the control group.

LPS is a potent inducer of inflammatory cytokines including TNF-α, IL-6 and IL-1β in macrophages and microglia (19–21). Bacterial LPS induces numerous host responses that are beneficial and detrimental (22). Liu et al (23) demonstrated that cluster of differentiation 14 interacts with Aβ fibrils and therefore contributes to microglial phagocytosis of Aβ42 fibrils. Inflammation potentially increases the level of Aβ present in the brain via three potential mechanisms: Increased influx, decreased efflux and increased neuronal production (24).

TNF-α is a primary pro-inflammatory cytokine and its role in the pathogenesis of aluminum neurotoxicity has previously been investigated (25). TNF-α influences the expression or metabolism of various molecules that are involved in the development of aluminum neurotoxicity, including Aβ (26,27). TNF is upregulated in the mouse brain following exposure to aluminum (28).

IL-1, which is an immune regulatory cytokine, may promote the merging and secretion of APP (29) and Aβ (30). Anti-inflammatory drugs have previously been suggested as a treatment for aluminum neurotoxicity. Tsunoda et al (28) suggests that IL-1β may be involved in one of the key disease mechanisms for aluminum neurotoxicity. Of all the numerous inflammatory cytokines associated with aluminum neurotoxicity, IL-1β in particular, has been identified to exhibit an important pathogenic role (27).

Furthermore, the Kupffer cell function in the model rat liver appeared to be decreased and the barrier function of the intestinal mucosa and BBB exhibited damage. A previous study suggested that aluminum may stimulate Fe2+-supported lipid peroxidation by binding to the membrane, thus affecting the BBB permeability (31). During BBB maturation and alteration, the brain endothelia develop a functional polarity and the membrane glycoprotein containing α-D-galactose is downregulated (32). Therefore, the LPS from the intestinal mucosa are able to penetrate the intestinal mucosal barrier and enter the serum. In addition, the impaired function of Kupffer cells leads to decreased removal of plasma LPS. The high level of LPS subsequently activates the Kupffer cells, releasing TNF-α and IL-1 and finally leads to IETM. The BBB damage allows LPS to readily enter the brain and induce inflammation.

In conclusion, the present study demonstrated that IETM was present in the rat model of aluminum neurotoxicity established by D-galactose and AlCl3 and may be important in the development of neurotoxicity.