Neonatal Bacillus Calmette-Guérin vaccination alleviates lipopolysaccharide-induced neurobehavioral impairments and neuroinflammation in adult mice
- Authors:
- Published online on: June 23, 2016 https://doi.org/10.3892/mmr.2016.5425
- Pages: 1574-1586
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Copyright: © Yang et al. This is an open access article distributed under the terms of Creative Commons Attribution License.
Abstract
Introduction
Bacillus Calmette-Guérin (BCG), a vaccine incorporated into routine childhood vaccination schedules globally, is administered to neonates and children worldwide (1). In addition to the prevention of tuberculosis, BCG has been used as an immune modulator and even as immunotherapy in certain non-infectious diseases (2–4). Furthermore, recent clinical and experimental studies have revealed that BCG has a neuroprotective role in several central nervous system (CNS) pathological conditions, including clinically isolated syndrome, multiple sclerosis, Parkinson's disease and experimental autoimmune encephalomyelitis (5–7).
Early-life immune activation has been well-established to regulate the programming of brain development and influence behavior in later life, predominantly using three animal models of early-life immune activation: Polycytidylic acid, Escherichia coli and lipopolysaccharide (LPS) (8,9). However, whether neonatal BCG vaccination as immune pre-conditioning has consequences in the CNS, and its function in adulthood, remains to be elucidated.
There are two patterns through which early-life immune activation may affect behavior in later life (10). In one pattern, early-life immune activation is able to directly modulate or disrupt development (11,12). In the other pattern, early-life immune activation can influence the immune system and alter the neuroimmune response to a subsequent immune challenge in adulthood (13,14). Therefore, direct and indirect later-life effects on the brain and behavior were assessed in the present study.
Adult LPS administration has been demonstrated to induce behavior impairments and neuroinflammation in rodents (15,16), and LPS has also been used for adult immune challenge in early-life-infected rodents (17,18). Therefore, LPS injection was used as an adult immune challenge in the present study to investigate the potential indirect effects of neonatal BCG vaccination.
Sickness, depression and anxiety-like behaviors were observed within 24 h following LPS injection. Additionally, certain molecules associated with behavior and immune activation were examined, including cytokines, neurotrophins, 5-hydroxytryptamine (5-HT) and corticosterone, in the brain and/or serum.
Materials and methods
Animals and study design
The present study was approved by the Sun Yat-Sen University (SYSU) Institute Research Ethics Committee (Guangzhou, China) and was strictly performed according to the UK Animals (Scientific Procedures) Act, 1986 (19). Newborn litters of C57BL/6 mice were obtained from the SYSU Laboratory Animal Center (Guangzhou, China) and were reared under specific pathogen-free conditions. The mice were housed at a temperature of 25°C in 60% relative humidity on a 12-h light/dark cycle (lights on between 6:00 AM and 6:00 PM), and allowed free access to food and water. A total of four groups were used in the study: BCG/LPS, BCG alone, LPS alone and control (CON) groups. The mice were administered with BCG (BCG/LPS and BCG groups) or PBS (LPS and CON groups) at birth. At 12 weeks old, the mice were administered LPS (BCG/LPS and LPS groups) or PBS (BCG and CON groups).
For each of the four behavioral tests, social exploratory behavior test (SEB), open field test (OFT), forced swimming test (FST) and tail suspension test (TST), a total of 16 newborn litters of C57BL/6 mice were used and 64 male pups were selected (4 pups/litter). The pups from each litter were distributed randomly into the 4 groups (1 pup/litter/group; total 16 pups/group). For bodyweight and food intake measurements, a total of 10 newborn litters were used and 40 male pups were selected (4 pups/litter). The pups from each litter were distributed randomly into the 4 groups (1 pup/litter/group; total 10 pups/group). For the remaining experiments, a total of 6 newborn litters were used and 24 male pups were selected (4 pups/litter). The pups from each litter were distributed randomly into the 4 groups (1 pup/litter/group; total 6 pups/group). Pups were weaned at 3 weeks old. In the SEB paradigm, 4-week-old male juvenile conspecifics were used.
Neonatal immunization and adult immune challenge
Freeze-dried living BCG (D2-BP302 strain; Biological Institute of Shanghai, Shanghai, China) was dissolved in PBS. BCG was administered to mice at birth, imitating the age at which vaccination is performed in human infants. Each newborn mouse in the BCG/LPS and BCG groups was injected subcutaneously in the back with 25 µl/mouse of BCG suspension containing 105 colony forming units (CFU), as previously described (20); mice in the LPS and CON groups were injected with PBS in an identical manner. At 12 weeks old, each mouse in the BCG/LPS and LPS groups was injected with 0.33 mg/kg LPS (Sigma-Aldrich, St. Louis, MO, USA) intraperitoneally, and mice in the BCG and CON groups were injected with PBS in an identical manner. This dosage of LPS induces a proinflammatory cytokine response in the peripheral nervous system and brain, resulting in mild transient sickness behavior in adult mice (15).
SEB test
The mice were subjected to the SEB test 30 min prior to, and 4, 8 and 24 h following, LPS injection. The test was performed as described previously (15). To assess the motivation to perform SEB, a novel juvenile conspecific was placed into the home cage of the test subject for 10 min. Behavior was videotaped and the total time spent by the test subject in social investigation (including anogenital sniffing and trailing) was calculated from the video records by a trained observer in a blinded manner. SEB was represented as the quantity of time spent by the test subject investigating the juvenile.
Body weight and food intake measurement
Body weight alteration and food intake of mice within the 24 h following LPS injection were calculated from body weight and food weight measured immediately prior to and 24 h following the LPS injection. Food intake was estimated according to a previously described method (21).
OFT
The OFT tests were performed 2.5 h following the LPS injection. This time interval was selected based on a previous study by Wang et al (22). The animals were individually placed in a plexiglass cubicle (40×40×38 cm). The spontaneous locomotor activity for each animal was recorded for 30 min by the Flex-Field activity system (San Diego Instruments, San Diego, CA, USA). The number of beam breaks by each mouse were counted automatically by the system. The apparatus was thoroughly cleaned with 70% ethanol following each trial.
FST
The mice were subjected to the FST task 30 min prior to, and 4, 8 and 24 h following, LPS injection. The animals were individually forced to swim for 6 min in an open cylindrical container (diameter, 10 cm; height, 30 cm), containing 20 cm of water (depth) at 22±1°C. The total duration of immobility was recorded during the final 5-min period and was analyzed by a video tracking system EthoVision (Noldus Information Technology B.V., Wageningen, Netherlands).
TST
The mice were subjected to the TST task 30 min prior to, and 4, 8, and 24 h following, LPS injection. In a soundproof room, each mouse was suspended upside down by their tails for 6 min. The total duration of immobility was measured during the final 5 min period.
5-Bromo-2-deoxyuridine (BrdU) labeling and tissue preparation
Together with LPS (in BCG/LPS and LPS mice) or PBS (in BCG and CON mice) injection, one dose of BrdU (50 mg/kg; Sigma-Aldrich, St. Louis, MO, USA) was injected into the mice. A repeat dose of BrdU was administered 12 h later. The mice were anesthetized with 10% chloral hydrate (0.3 ml per mouse, i.p.; Melone Pharmaceutical Co., Ltd., Dalian, China) and perfused transcardially with 4% paraformaldehyde a total of 24 h following the initial BrdU injection. The brains were excised and subsequently fixed overnight in 4% paraformaldehyde at 4°C, and dehydrated with 30% sucrose at 4°C for 72 h. Then, following freezing at -20°C, the brains were sliced into serial coronal sections (40 µm) on a freezing microtome (Leica SM2000 R; Leica Microsystems GmBH, Wetzlar, Germany). Serial coronal sections (40 µm) were collected and were stained for BrdU+ cells.
Immunofluorescence and cell quantification
Specimens were incubated in 2-N HCl for 30 min at 37°C and were subsequently blocked with PBS containing 1% bovine serum albumin and 0.3% Triton X-100 (Sigma-Aldrich, St. Louis, MO, USA) for 1 h at 37°C. Sections were subsequently incubated with a primary monoclonal rat anti-BrdU antibody (1:500; catalog no., OBT 0030; AbD Serotec, Raleigh, NC, USA) overnight at 4°C, followed by incubation with the secondary antibody (Alexa Fluor 594-conjugated polyclonal donkey anti-rat; 1:400; Invitrogen; Thermo Fisher Scientific, Waltham, MA, USA; catalog no., A-21209). BrdU+ cells in the unilateral dentate gyrus (DG) of each animal were counted using a Stereo Investigator stereology system (MBF Bioscience, Williston, VT, USA). The actual section thickness was measured, and the top and bottom guard zones were defined to avoid oversampling. Measurements were finished in an equidistant series of six coronal sections spanning the DG in its rostrocaudal extension. Representative confocal micrographs were obtained with a Zeiss LSM 710 confocal laser-scanning microscope (Carl Zeiss AG, Oberkochen, Germany).
ELISA
Serum was separated from trunk blood 24 h following the LPS injection by centrifugation at 4,000 × g for 5 min and was subsequently stored at −20°C until use. Serum corticosterone levels were measured using ELISA kits (Corticosterone ELISA kit; EIAab Science Co, Ltd., Wuhan, China), according to the manufacturer's instructions. The concentrations of interleukin (IL)-1β, interferon (IFN)-γ, tumor necrosis factor (TNF)-α, IL-6, IL-4, IL-10, brain-derived neurotrophic factor (BDNF) and insulin-like growth factor (IGF)-1 in several brain zones were determined using commercially available ELISA assays, according to the instructions supplied by the manufacturer (Mouse IL-1β ELISA set, Mouse IFN-γ (AN-18) ELISA set, Mouse IL-4 ELISA set, Mouse IL-10 ELISA set; all purchased from BD Pharmingen™; BD Biosciences, Franklin Lakes, NJ, USA Mouse TNF-α ELISA kit, Mouse IL-6 ELISA kit, Mouse BDNF ELISA kit, Mouse IGF-1 ELISA kit; all purchased from EIAab Science Co, Ltd.).
High-performance liquid chromatography analyses of 5-HT and 5-hydroxyindoleacetic acid (5-HIAA)
Brain samples were weighed and subsequently homogenized in 0.5 ml ice-cold solution of 0.1 M perchloric acid, containing 0.1% cysteine, and were centrifuged at 20,817 × g for 20 min at 4°C. The standard solution or sample was then injected onto the column (5 µm; 4.6×150 mm2). The separation was performed on a reversed-phase Hypersil BDS-C18 column (Elite Analytical Instruments Co., Ltd., Dalian, China) in an isocratic elution mode using a mobile phase consisting of 85 mM citric acid and 100 mM sodium acetate buffer (pH 4.0), containing 8% methanol, 3 mM sodium heptane-1-sulphonate and 0.2 mM EDTA, at a flow rate of 0.8 ml/min. The levels of 5-HT and 5-HIAA were expressed in ng/mg tissue weight (wet).
Statistical analyses
All the data were processed using SPSS version 17.0 for Windows (SPSS, Inc., Chicago, IL, USA). The data are expressed as mean ± standard error. Data from the SEB, FST and TST were analyzed using three-way (BCGxLPSxtime) repeated measures analysis of variance (ANOVA) followed by Bonferroni post-hoc test. Data from the remaining tests were analyzed using two-way (BCGxLPS) ANOVA followed by Bonferroni post-hoc test. P<0.05 was considered to indicate a statistically significant difference.
Results
Neonatal BCG vaccination alleviates LPS-induced sickness behavior in adulthood
SEB was measured 30 min prior to, and 4, 8 and 24 h following, LPS injection. A three-way ANOVA revealed the significant effects of BCG (F1,60=12.10; P<0.001), LPS (F1,60=141.58; P<0.001) and time (F3,180=52.87; P<0.001), and the significant interactions of BCGxLPS (F1,60=15.13; P<0.001), BCGxtime (F3,180=2.74; P=0.0448), LPSxtime (F3,180=49.12; P<0.001) and BCGxLPSxtime (F3,180= 4.26; P=0.0062). Subsequent analyses revealed that adult LPS treatment decreased the social behavior of mice (LPS vs. CON group, P<0.001) and that neonatal BCG vaccination significantly attenuated LPS-induced sickness behavior (BCG/LPS vs. LPS group, P<0.001; Fig. 1A).
Food intake within the 24 h subsequent to LPS injection was analyzed using two-way (BCGxLPS) ANOVA. There were significant effects of LPS (F1,36=62.35; P<0.001) and interaction of BCGxLPS (F1,36=7.47; P=0.0097). Subsequent analyses revealed that adult LPS treatment decreased the food intake (LPS vs. CON group, P<0.001) and that neonatal BCG vaccination significantly attenuated the LPS-induced decrease (BCG/LPS vs. LPS group, P=0.0019; Fig. 1B).
A two-way ANOVA of body weight change within the initial 24 h following LPS injection revealed a significant effect of BCG (F1,36=561.57; P<0.001), LPS (F1,36=95.25; P<0.001) and interaction of BCGxLPS (F1,36=91.38; P<0.001). Subsequent analyses revealed that adult LPS treatment decreased the body weight of the mice (LPS vs. CON group, P<0.001) and that neonatal BCG vaccination significantly attenuated the LPS-induced decrease (BCG/LPS vs. LPS group, P<0.001; Fig. 1C).
Notably, neonatal BCG vaccination alone had a non-significant impact on social behavior, food intake and body weight in adulthood compared with the CON group (P-values for comparisons between the BCG and CON groups for social behavior: P=0.3212; food intake: P=0.6041; and body weight: P=0.8881; Fig. 1).
Neonatal BCG vaccination weakens LPS-induced depression and anxiety-like behaviors in adulthood
The mice were subjected to the FST and TST tasks 30 min prior to, and 4, 8 and 24 h following, LPS injection. A three-way (BCGxLPSxtime) ANOVA of the FST data revealed significant effects of BCG (F1,60=31.42; P<0.001), LPS (F1,60=125.44; P<0.001) and time (F3,180=36.13; P<0.001), and significant interactions of BCGxLPS (F1,60=28.26; P<0.001), BCGxtime (F3,180=3.01; P=0.0316), LPSxtime (F3,180=36.26; P<0.001) and BCGxLPSxtime (F3,180=4.86; P=0.0028). Subsequent analyses revealed that adult LPS treatment increased the immobility time of mice (LPS vs. CON group, P<0.001) and that neonatal BCG vaccination significantly attenuated the LPS-induced increase (BCG/LPS vs. LPS group, P<0.001; Fig. 2A).
Analyses of the TST data revealed significant effects of BCG (F1,60=11.83, P=0.0011), LPS (F1,60=81.77, P<0.001) and time (F3,180=15.07, P<0.001), and significant interactions of BCGxLPS (F1,60=16.17, P<0.001), BCGxtime (F3,180=3.77, P=0.0117), LPSxtime (F3,180=16.32, P<0.001) and BCGxLPSxtime (F3,180=5.56, P=0.0011). Subsequent analyses revealed that adult LPS treatment increased the immobility time of mice (LPS vs. CON group, P<0.001) and that neonatal BCG vaccination attenuated the LPS-induced increase (BCG/LPS vs. LPS group, P<0.001; Fig. 2B).
The mice were subjected to the OFT task 4 h subsequent to the LPS injection, and locomotor activities, rearing activities and the proportion of center area activities in total were recorded for 30 min. A two-way ANOVA revealed significant effects of BCG (rearing activities, F1,60=7.01; P=0.0103; center proportion, F1,60=4.01; P=0.0497) and LPS (locomotor activities, F1,60=7.86; P=0.0067; rearing activities, F1,60=31.58; P<0.001; center proportion, F1,60=30.61; P<0.001) and interaction of BCGxLPS (center proportion, F1,60=4.25; P= 0.0435). Subsequent analyses revealed that LPS injection alone induced a marginal, but significant, decrease in locomotor activities (LPS vs. CON group, P<0.01) and that neonatal BCG vaccination did not significantly affect the locomotor activities, regardless of adult LPS treatment (BCG vs. CON group, P=0.601; BCG/LPS vs. LPS group, P=0.092). Subsequent analyses for the other indices of OFT revealed that adult LPS treatment induced decreases in locomotion, rearing activities (LPS vs. CON group, P<0.001) and center proportion activities (LPS vs. CON group, P<0.001). Neonatal BCG vaccination attenuated the LPS-induced decreases in rearing activities (BCG/LPS vs. LPS group, P<0.001) and center proportion (BCG/LPS vs. LPS group, P<0.001; Fig. 2C–E).
Notably, neonatal BCG vaccination alone insignificantly impacted these indices in the FST and TST tasks in adulthood compared with the CON group (Fig. 2).
Neonatal BCG vaccination alleviates the LPS-induced impairment in hippocampal cell proliferation
There were significant effects of BCG (F1,20= 6.761; P= 0.0171) and, LPS (F1,20=70.485; P<0.001) and interaction of BCGxLPS (F1,20=6.645; P=0.0180). Subsequent analyses revealed that adult LPS treatment decreased the number of BrdU+ cells (LPS vs. CON group, P<0.001) and that neonatal BCG vaccination attenuated LPS-induced impairment (BCG/LPS vs. LPS group, P=0.0016), although neonatal BCG vaccination alone caused no significant effect (BCG vs. CON group, P=0.9875; Fig. 3).
Neonatal BCG vaccination reduces the LPS-induced proinflammatory cytokine response in serum and the brain
LPS treatment induced proinflammatory cytokine expression in serum and the brain. Neonatal BCG vaccination reduced the LPS-induced proinflammatory responses in the serum and brain, although neonatal BCG vaccination alone resulted in no significant alteration in cytokine expression in serum or the brain (Fig. 4). The statistical analyses of two-way ANOVA for cytokines are presented in Table I.
In the serum, the LPS group exhibited significantly increased levels of IL-1β, IFN-γ, TNF-α and IL-6 compared with the CON group; the BCG/LPS group exhibited significantly reduced levels of IL-1β, IFN-γ and IL-6 and increased levels of IL-10 compared with the LPS group (Fig. 4A). In the hippocampus, the LPS group exhibited significantly increased levels of IL-1β and IL-6 compared with the CON group; the BCG/LPS group exhibited significantly reduced levels of IL-1β and IL-6 and increased levels of IL-10 compared with the LPS group (Fig. 4B). In the prefrontal cortex, the LPS group exhibited significantly increased levels of IL-1β, TNF-α, IL-6 and IL-10 and reduced levels of IL-4 compared with the CON group; the BCG/LPS group exhibited significantly reduced levels of IL-1β, TNF-α and IL-6 and increased levels of IL-4 and IL-10 compared with the LPS group (Fig. 4C). In the striatum, the LPS group exhibited significantly increased levels of IL-1β, TNF-α, IL-6 and IL-10 compared with the CON group; the BCG/LPS group exhibited significantly reduced levels of IL-1β, TNF-α, and IL-6 and increased levels of IL-10 compared with the LPS group (Fig. 4D).
In addition, the levels of IFN-γ in serum, the levels of IL-1β and IL-6 in the hippocampus, the levels of TNF-α, IL-6 in the prefrontal cortex and the levels of TNF-α in the striatum of the BCG/LPS group were as low as their levels in the BCG group (Fig. 4). Therefore, neonatal BCG vaccination completely prevented LPS-induced increased expression of certain proinflammatory cytokines in the serum or specific zones of the brain. In addition, compared with the BCG group, the levels of the anti-inflammatory cytokines, IL-4 and IL-10, in serum and the brain were elevated in the BCG/LPS group, although adult LPS treatment alone had a marginal and inconsistent influence on the levels of IL-4 and IL-10 (Fig. 4).
Neonatal BCG vaccination weakens the LPS-induced decrease in BDNF and IGF-1 levels in the brain
Adult LPS treatment reduced levels of the neurotrophins BDNF and IGF-1 in some or all of the three brain zones investigated. Neonatal BCG vaccination weakened these LPS-induced decreases, although neonatal BCG vaccination alone did not significantly alter the levels of these neurotrophins (Fig. 5). The statistical analysis of two-way ANOVA are presented in Table II.
The LPS group exhibited significantly reduced BDNF levels in the hippocampus, prefrontal cortex and striatum compared with the CON group; the BCG/LPS group exhibited significantly increased BDNF levels in all three zones compared with the LPS group (Fig. 5). The LPS group exhibited significantly reduced IGF-1 levels in prefrontal cortex and striatum compared with the CON group; the BCG/LPS group exhibited significantly increased IGF-1 levels in the prefrontal cortex and striatum compared with the LPS group (Fig. 5). In addition, the levels of BDNF in the hippocampus and IGF-1 in the striatum of the BCG/LPS group were as high as their levels in the BCG group (Fig. 5).
Neonatal BCG vaccination reduces the LPS-induced increased 5-HT turnover and decreased 5-HT levels in the brain
Adult LPS treatment increased 5-HT turnover and decreased 5-HT levels in the brain. Neonatal BCG vaccination lessened these LPS-induced alterations, although neonatal BCG vaccination alone did not result in any significant alteration in these indices (Fig. 6A–F). The statistical analysis of two-way ANOVA are presented in Table II.
The LPS group exhibited a significantly increased ratio of 5-HIAA to 5-HT (5-HIAA/5-HT) and decreased 5-HT levels in the brain compared with the CON group. The BCG/LPS group had significantly decreased 5-HIAA/5-HT and increased 5-HT levels in the brain compared with the LPS group (Fig. 6A–F).
Neonatal BCG vaccination did not affect the LPS-induced increase in corticosterone levels in serum or the brain
A two-way ANOVA for corticosterone levels revealed a significant effect of LPS (F1,20=120.942; P<0.001), non-significant effect of BCG (F1,20=0.842; P=0.3697) and non-significant interaction of BCGxLPS (F1,20=0.092; P=0.7650). Subsequent analyses revealed that the BCG group exhibited no significant alteration in the corticosterone levels in the serum compared with the CON group (Fig. 6G). The LPS group had significantly increased corticosterone levels in the serum compared with the CON group, and no significant differences were observed in the corticosterone levels in the serum between the BCG/LPS and LPS groups (Fig. 6G).
Discussion
The results of the present study reveal that neonatal BCG vaccination alleviates LPS-induced neurobehavioral impairments and neuroinflammation in adult mice. Neonatal BCG vaccination alleviated LPS-induced sickness, depression and anxiety-like behaviors, as well as hippocampal proliferation impairment. Furthermore, LPS-induced decreases in neurotrophins and 5-HT levels in brain were also alleviated by neonatal BCG vaccination. In addition, neonatal BCG vaccination reduced the pro-inflammatory responses induced by adult LPS challenge in the periphery and brain.
Intraperitoneal LPS treatment has been confirmed to induce a series of acute physiopathological and psychological disorders in rodents. Previous studies have demonstrated decreased social exploratory behavior and food intake in rodents intraperitoneally administered with LPS (15,23), while others have reported LPS-induced depression and anxiety-like behaviors (24,25). Furthermore, LPS may acutely inhibit the proliferation of stem cells in the DG in adult rodents (26,27). The results from the LPS group in the present study confirmed these widely reported neurobehavioral impairments.
Immune activation by LPS may induce a large release of cytokines in the periphery and brain, particularly proinflammatory cytokines, including IL-1β, IL-6, TNF-α and IFN-γ (15). These proinflammatory cytokines may affect the functioning of the brain (28) and mediate sickness behavior syndrome (29). For example, Wang et al (22) reported that an intraperitoneal injection of LPS in mice resulted in clear impairments in performance of the OFT task, associated with increased expression of IL-1β, IL-6 and TNF-α in the brain. IL-10 and IL-4 are considered anti-inflammatory cytokines and have neuroprotective effects (30,31). In the present study, LPS treatment induced proinflammatory responses in the serum and brain. The increases in proinflammatory cytokine levels by adult LPS treatment were reduced significantly by neonatal BCG vaccination, and in certain cases cytokine levels in the serum or specific brain zones were completely prevented from increasing. These findings reveal that neonatal priming of the immune system by BCG results in a reduced proinflammatory response to a subsequent LPS challenge in adulthood, possibly explaining why neonatal BCG vaccination alleviates LPS-induced behavior impairments.
Notably, in the present study the levels of IL-10 in the LPS group demonstrated a tendency to increase in serum and all three brain zones compared with the CON group. IL-10 is one of the regulatory T cell (Tregs) associated cytokines that may be released by various immune cells when inflammation occurs (32). Stumhofer et al (33) reported that IL-6 induced signal transducers and activators of transcription 3-mediated T cell production of IL-10. McGeachy et al (34) reported that IL-6 drives the production of IL-10 by T cells and prevents the T helper 17 cell-mediated pathology. The increased IL-10 levels may inhibit inflammatory pathologies and avoid autoimmune impairments (35).
Notably, in the present study the BCG/LPS group exhibited increased IL-10 levels in the periphery and brain compared with the BCG and LPS groups. This observation aids explanation of the reduced levels of proinflammatory cytokines in the BCG/LPS group. How neonatal BCG vaccination increases IL-10 production in response to adult LPS treatment remains to be elucidated. However, studies concerning the non-specific effects of BCG on the immune system support the anti-inflammatory role of BCG (36–38). Epidemiological studies have indicated that BCG vaccination exerted a positive non-specific effect on overall childhood mortality, which cannot be attributed to the prevention of tuberculosis fatalities (39,40). Additionally, the capacity of BCG to induce Tregs in vivo has been widely reported (36). In a study by Madura Larsen et al (37), dendritic cells (DCs) were generated from peripheral blood mononuclear cells and cultured with LPS or LPS/BCG in vitro. The study reported that BCG-exposed DCs were able to induce IL-10-producing T cells. In a separate study, neonatal BCG vaccination was observed to ameliorate allergen-induced local inflammation and increase the number of cluster of differentiation 4 (CD4)+CD25+ Treg cells and IL-10 expression (38). These findings suggest that BCG may interact with DCs directly to result in an accumulation of IL-10-producing T cells.
DCs derived from BCG-infected mononuclear cells produce IL-4, which may be associated with the failure of the BCG vaccination against tuberculosis (41). This suggests that IL-4-producing DCs may have an anti-inflammatory role. In the present study, increased expression of IL-4 was observed in serum and the prefrontal cortex of the BCG/LPS compared with the LPS mice, suggesting that increased IL-4 may contribute to the inhibition of LPS-induced inflammation.
BDNF, IGF-1 and 5-HT in the brain were identified as the most important molecules for maintaining health-mood status, and decreases in their levels, as well as an increase in 5-HT turnover, are associated with depression (42,43). In the present study, behavior impairments and alterations in neurotrophins and 5-HT levels in LPS mice were consistent with these reports. Furthermore, neonatal BCG vaccination improved the LPS-induced neurochemical disorders. This alleviation, together with the changes in proinflammatory cytokine levels, may assist with explaining the effects of BCG on behavior and proliferation observed in the present study.
Activity of the hypothalamic-pituitary-adrenal (HPA) axis is another important aspect of the complicated pathophysiology of sickness-like behavior and depression. HPA axis hyperactivity may be one of the mechanisms underlying depression development (44). Serum levels of corticosterone are one marker of the HPA axis activation in rodents (45). As reported in our previous study, LPS treatment increased serum corticosterone levels in mice (46). However, in the present study neonatal BCG vaccination did not influence the LPS-induced elevation of serum corticosterone levels, suggesting that neonatal BCG vaccination lessened the LPS-induced neurobehavioral impairments through its priming effects on inflammatory responses in the periphery and brain, independent of the HPA axis.
How peripheral cytokines exert their influence on the brain and its function remains to be fully elucidated. Periphery-derived cytokines may permeate across the blood-brain barrier and directly affect the neuronal activities (47). Additionally, crosstalk may occur between cytokines in the brain and resident immune cells (such as microglia), causing the latter to change their phenotype by, for example, altering their secretion of local neuromodulative molecules, including cytokines and neurotrophins (48,49). These neuromodulative molecules and local cells combine to regulate the neuroimmune niche and therefore affect brain functions (43,50).
There are numerous studies reporting the influence of previous exposure to a specific antigen on subsequent immune responses to other antigen(s), including i) the effects of neonatal exposure to immunogen and subsequent autism/schizophrenia-like behavior; ii) the target disease-specific effects of a previous vaccination on the subsequent immune responses to unrelated antigens; and iii) the phenomenon of 'original antigenic sin'. Previous studies have demonstrated that early life immune activation by Escherichia coli led to CNS alterations at behavioral, cellular and molecular levels following adult LPS challenge (10,14,17). It has additionally been observed that these later life consequences were mediated primarily by CNS resident immune cells, including microglia and astrocytes that were primed and thus equipped with altered abilities when responding to subsequent immune stimuli (10,14,17). A previous study revealed that BCG vaccination enhanced the immunogenicity of subsequent influenza vaccination in healthy volunteers through enhanced proinflammatory leukocyte responses (51). Original antigenic sin describes the failure to mount effective antibody responses to virus variants in a previously virus-infected host (52). The similarity of the prior and subsequent antigens and the hyperresponsiveness of memory immune cells are thought to be the underlying reasons for this phenomenon (52). Similar mechanisms to those identified by previous studies may apply in the present study, as BCG-priming altered the expression of cytokines and neurotrophins in the brain, which are produced and/or regulated by microglia and astrocytes (10,14,17). The mechanism concerning mainly peripheral cytokine responses may also underlie the findings of the present study, as indicated by the altered serum cytokines levels (51). However, the present study observed abrogation, rather than enhancement, of immunogenicity. This is understandable as BCG induces a mild, physiological immune activation (unlike early life pathology) and LPS exposure resulted in marked neuroinflammation (unlike later life vaccination) (10,14,17,51). Original antigenic sin may not apply in the present study as it occurs during antibody responses to viral antigens (52).
The present study revealed a neuroprotective role for neonatal BCG vaccination in the presence of later-life neuroinflammation regardless of the lack of direct neurobehavioral effects in adulthood. Notably, there are certain previous studies reporting that rodents receiving BCG in adulthood develop a depression-like phenotype (53–55). In addition, previous studies reporting BCG depression-like effects identified that BCG activated indoleamine 2,3-dioxygenase, which is a tryptophan-catabolizing enzyme, and decreased brain 5-HT levels (54–56). In the present study, BCG/LPS mice exhibited a lower 5-HT turnover and higher levels of 5-HT in the brain compared with the LPS group, suggesting that neonatal BCG vaccination may assist in maintaining normal 5-HT metabolism in adulthood. This plausible inconsistency may result from numerous factors, particularly the dosage and age for vaccination, and the time interval between BCG vaccination and behavioral tests. In the previous studies, doses of ≥107 CFU were used, as these higher doses were able to elicit clear sickness responses (53,55). By contrast, a lower dose (105 CFU) was selected in the present study to avoid inducing health impairment. BCG-induced depressive-like behavior and evident bodyweight loss have been verified as dose-dependent, and are induced only by ≥107 CFU (57). Additionally, sickness and depression-like behaviors were observed in the mice within 1 month of adult BCG vaccination in the previous studies (53–55). In the present study, newborn mice were vaccinated and their behaviors were tested at 12 weeks old. During longer time intervals across the significant postnatal development span, the organism may experience complex and sufficient self-adjustment to reverse the neurobehavioral effects of the neonatal vaccination, and if there are any, they are not detectable. Furthermore, other factors, including vaccination routes (intraperitoneally in previous studies and subcutaneously in the present study) may also contribute. Therefore, no contradiction exists between the current data and previous studies concerning adult models of depression by BCG.
Sirén et al (58) injected adult male Sprague-Dawley rats with BCG through the tail vein. LPS was then injected into the lateral cerebral ventricle 2 weeks later. This previous study reported that the incidence of paralysis and fatality in response to LPS was increased in BCG-primed rats. There are various methodological differences in the study by Sirén et al compared with the present study: The species (rats vs. mice in the present study), the age of vaccination (adult vs. neonates), the time interval between BCG vaccination and LPS injection (2 vs. 12 weeks), the route of injection of BCG (through tail vein vs. subcutaneous) and LPS (into the lateral cerebral ventricle vs. intraperitoneally). Among the differences, the injection route and time interval may be the most responsible for the neurobehavioral effects of BCG/LPS administration in animals. As Sirén et al (58), described, 13% of rats were paralyzed or succumbed following injection of 300 µg LPS into the lateral cerebral ventricle. However, a similar (~1.2 mg/kg) or lower (330 µg/kg, as used in the present study) dosage of LPS injected intraperitoneally does not result in paralysis or fatality (15,59). In addition, Sirén et al (58) stated that no paralysis or fatality resulted from BCG/LPS treatment when the time interval between BCG vaccination and LPS injection was <1 or >4 weeks. All these findings suggest that different dosages and protocols of BCG/LPS treatment may lead to varying effects on neurobehavior.
BCG is administered worldwide to human infants who may then suffer more or less during their later life from bacterial infection, including with LPS-producing bacteria. Therefore, there are numerous individuals who receive neonatal BCG immunization and suffer LPS exposure in adulthood. Mice in the present study also experienced neonatal BCG immunization and LPS-challenge in adulthood, meaning the model used in the present study may be comparable to humans. Furthermore, the BCG used in the present study is identical to the vaccine administered to humans and the age, dosage and route of vaccination in the present study are also similar to those for humans. Therefore, it is worth investigating if neonatal BCG vaccination exerts similar effects on brain development and behavior in humans. These results may not be limited to infection with LPS/LPS-producing bacteria. The present study provides a basis for further examination and provides a useful animal model for investigating the neurobehavioral effects of physiological neonatal immune activation.
In conclusion, the neonatal BCG vaccination alleviated the neurobehavioral impairments and neuroinflammation induced by exposure of adult mice to LPS. The results of the present study reveal the protective effect of BCG on the CNS following exposure to LPS, and encourage further study to investigate the use of immunoregulatory therapy for the treatment of neuropsychiatric disorders.
Abbreviations:
5-HT |
5-hydroxytryptamines |
5-HIAA |
5-hydroxyindoleacetic acid |
BCG |
Bacillus Calmette-Guérin |
BDNF |
brain-derived neurotrophic factor |
BrdU |
5-bromo-2-deoxyuridine |
CFU |
colony forming units |
CNS |
central nervous system |
CON |
control |
DCs |
dendritic cells |
DG |
dentate gyrus |
FST |
forced swimming test |
HPA |
hypothalamic-pituitary-adrenal |
IFN-γ |
interferon-γ |
IGF-1 |
insulin-like growth factor-1 |
IL-1β |
interleukin-1β |
IL-4 |
interleukin-4 |
IL-6 |
interleukin-6 |
LPS |
lipopolysaccharide |
OFT |
open field test |
PBS |
phosphate-buffered saline |
ANOVA |
analysis of variance |
SEB |
social exploratory behavior |
SYSU |
Sun Yat-Sen University |
TNF-α |
tumor necrosis factor-α |
Tregs |
regulatory T cells |
TST |
tail suspension test |
Acknowledgments
The authors would like to thank Dr. Zejie Zuo, Dr. Yingying Wu and Ms. Yunlong Xu (SYSU) for their invaluable comments. The authors would also like to thank Technician Qunfang Yuan (SYSU) for her technical instruction. The present study was supported by the National Natural Science Foundation of China (grant no. 31371130), the Special Foundation of Education Department of Guangdong Province (grant no. 2010-036) and the Medical Scientific Research Foundation of Guangdong Province, China (grant no. 2013-159).
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