Abstract
Proteo-β-glucan from Maitake (PGM) is a strong immune regulator, and its receptor is called Dectin-1. Cumulative evidence suggests that AMPA receptors are important for the treatment of depression. Here, we report that PGM treatment leads to a significant antidepressant effect in the tail suspension test and forced swim test after sixty minutes of treatment in mice. After five consecutive days of PGM treatment, this antidepressant effect remained. PGM treatment did not show a hyperactive effect in the open field test. PGM significantly enhanced the expression of its receptor Dectin-1, as well as p-GluA1(S845) and GluA1, but not GluA2 or GluA3 in the prefrontal cortex (PFC) after five days of treatment. The Dectin-1 inhibitor Laminarin was able to block the antidepressant effect of PGM. At the synapses of PFC, PGM treatment significantly up-regulated the p-GluA1(S845), GluA1, GluA2, and GluA3 levels. Moreover, PGM’s antidepressant effects and the increase of p-GluA1(S845)/GluA1 lasted for 3 days after stopping treatment. The AMPA-specific antagonist GYKI 52466 was able to block the antidepressant effect of PGM. This study identified PGM as a novel antidepressant with clinical potential and a new antidepressant mechanism for regulating prefrontal Dectin-1/AMPA receptor signalling.
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Introduction
Major depression affects millions of people worldwide, it is important to develop a novel and prolonged antidepressant1. Proteo-β-glucan from Maitake (PGM), with its unique and complex structure, containing either β-1,6-linked glucan with β-1,3 branches or β-1,3-linked glucan branched with β-1,6 glucosides as a main polysaccharide backbone where a few uncharacterized protein units are attached to it, is the bioactive component of Maitake mushroom (Grifola frondosa)2. The medicinal properties of PGM include various physiological benefits ranging from immuno-modulatory and antitumor activities to the treatment of hypertension, diabetes, hypercholesterolemia, viral infections and obesity2,3. The specific receptor for PGM is dendritic cell-associated C-type lectin-1 (Dectin-1), which is expressed in microglial cells, dendritic cells, monocytes, macrophages, and neutrophils4,5. Dectin-1 was discovered as the first non-Toll-like receptor. It has been shown that Dectin-1 induces the expression of the anti-inflammatory cytokines IL-2 and IL-10 and stops the inflammation process via Syk-independent pathways6. Cumulative evidence has shown that depression is related to immune regulation7,8. Particularly, the impairment of the normal function of the microglia can lead to depression and impairment of associated neuroplasticity and neurogenesis9. However, whether PGM or/and its receptor Dectin-1 are involved in this antidepressant effect remains unknown.
The most famous rapid antidepressant, ketamine, a non-competitive N-methyl-D-aspartate (NMDA) receptor antagonist, was found to rely on increasing α-amino-3-hydroxy-5-methyl-4-isoxazole-propionic acid (AMPA) signalling to exert its antidepressant efficacy1,10. The AMPA receptor has emerged as a central mediator for the pathophysiology and treatment of depression11,12,13. AMPA receptors, which are tetramers assembled from four subunits, GluA1, GluA2, GluA3 and GluA4, play a key role in the activity-dependent regulation of synaptic strength11,14,15. The mRNA levels of GluA1 and GluA3 in the patients with depression were significantly decreased in the perirhinal cortex and hippocampus16. The AMPA receptor potentiator (LY392098) had an antidepressant effect in animal models17. The phosphorylation of GluA1 at serine 845 [p-GluA1(S845)] was increased following treatment in mice using the antidepressants flouxetine and tianeptine18,19, which suggested that phosphorylation of GluA1 might be associated with the potentiation of AMPA receptor signalling20. Currently, increasing evidence suggests that AMPA receptors serve as central mediators during the development of the pathophysiology and treatment of depression16. However, whether PGM regulates AMPA synaptic plasticity is still unknown.
In this context, we designed a series of behavioural and biochemical experiments to investigate the antidepressant effects of PGM in the animal models of depression. We first studied the effects of various concentrations of PGM on animal models of depression. The expression of Dectin-1 and the role of Dectin-1 in the antidepressant effect were determined after PGM treatment. The phosphorylation of AMPA GluA1 S845 and the expression of AMPA GluA1, GluA2, and GluA3 were also studied in the total protein extract and in the synaptic fraction of the prefrontal cortex (PFC) after PGM treatment. The prolonged effects of PGM after ceasing treatment were also investigated. Moreover, the role of the enhanced AMPA function in the antidepressant effect of PGM was addressed by treatment with an AMPA-specific antagonist, GYKI 52466.
Results
PGM demonstrated a robust antidepressant effect in the tail suspension test (TST) and forced swim test (FST)
Seven-week-old CD-1 mice were intraperitonially (i.p.) injected with a low (5 mg/kg), medium (8 mg/kg), and high (12.5 mg/kg) doses of PGM for 60 minutes or 5 days before testing. Sixty minutes after the treatment, the mice were subjected to either TST or FST (Fig. 1). The data showed that the duration of immobility in the PGM-treated groups was significantly lower than that of the controls (103.0 ± 12.0 sec) in a dose-dependent manner, as low as 60.3 ± 9.2 sec (for 5 mg/kg of PGM), 55.3 ± 10.5 sec (for 8 mg/kg of PGM), and 42.8 ± 11.3 sec (for 12.5 mg/kg of PGM) in the TST (ANOVA, F(4,53) = 6.991, p < 0.01) (Fig. 2A). The positive control imipramine (33.2 ± 8.0 sec) also demonstrated an antidepressant effect (Fig. 2A). To confirm these data, FST was performed under similar conditions. After 60 minutes of treatment with PGM, the data showed that the duration of immobility in the PGM-treated groups was significantly lower than that of the controls (103.8 ± 14.5 sec), as low as 51.0 ± 9.5 sec (for 5 mg/kg of PGM), 52.3 ± 10.0 sec (for 8 mg/kg of PGM), and 50.5 ± 9.1 sec (for 12.5 mg/kg of PGM) for FST, similar to the traditional antidepressant imipramine (51.5 ± 12.2 sec) (ANOVA, F(4,54) = 4.348, p < 0.01) (Fig. 2B). To further examine the antidepressant effect of PGM after long-term treatment, we treated mice with the same doses as mentioned above for 5 consecutive days, and TST and FST were performed after the treatment (Fig. 1). The data showed that the immobility times in the PGM-treated groups were significantly lower than those of the controls (107.3 ± 14.0 sec) in a dose-dependent manner, as low as 60.0 ± 11.6 sec (for 5 mg/kg of PGM), 55.5 ± 11.0 sec (for 8 mg/kg of PGM), and 42.0 ± 11.1 sec (for 12.5 mg/kg of PGM) for TST (ANOVA, F(4,55) = 5.143, p < 0.01) (Fig. 2C). Imipramine (43.1 ± 11.2 sec) also demonstrated an antidepressant effect (Fig. 2C). To confirm these data, FST was performed under similar settings. After 5 days of treatment with PGM, the data showed that the immobility time in the PGM-treated groups was significantly lower than that of the controls (109.1 ± 11.7 sec) in a dose-dependent manner, as low as 61.7 ± 11.1 sec (for 5 mg/kg of PGM), 45.3 ± 11.0 sec (for 8 mg/kg of PGM), and 39.3 ± 9.1 sec (for 12.5 mg/kg of PGM) for FST (ANOVA, F(4,53) = 6.043, p < 0.01) (Fig. 2D). Imipramine (56.3 ± 13.5 sec) also showed a similar antidepressant effect (Fig. 2D).
Mice were acclimatized for at least 1 week. Four independent cohorts of animals were used to test the antidepressant effects of proteo-β-glucan from Maitake (PGM). The animal behavioural tests were performed 60 minutes (mins) after drugs or vehicle were administered. The first independent cohort of animals underwent the tail suspension test (TST) after 60 minutes treatment, open field test (OFT) on the third day, and forced swim test (FST) on the fifth day. To confirm the antidepressant effects of PGM, the second independent cohort of animals was subjected to the FST after 60 minutes of treatment and to the TST on the fifth day under similar conditions. The third independent cohort of animals was used to test the Dectin-1 receptor-specific blocking reagent Laminarin (Lam) in the antidepressant effect of PGM in the TST. The fourth independent cohort of animals was used to test whether the α-amino-3-hydroxy-5-methyl-4-isoxazole-propionic acid (AMPA) receptor-specific antagonist GYKI 52466 (GYKI) was involved in the antidepressant effect of PGM in the TST.
CD-1 mice were i.p. injected with a low dose of PGM (5 mg/kg/day, PGM-L), a medium dose of PGM (8 mg/kg/day, PGM-M), a high dose of PGM (12.5 mg/kg/day, PGM-H), imipramine (15 mg/kg/day, IMI) or saline (Sal). After PGM treatment for sixty minutes (mins) or five days, mice were subjected to the TST or FST. The number (N) of mice per group is indicated in each individual graph. Any experimental data value greater than mean plus 2 × standard deviations (SDs) from a group was considered an outlier and was not considered in the analysis. Data were analysed by one-way ANOVA and presented as the mean ± SE (post hoc Tukey’s test, *p < 0.05, **p < 0.01, ***p < 0.001). (A,B) Sixty minutes after the injection, PGM significantly reduced the immobility time in the TST or FST. (C,D) After 5 consecutive days of injection, PGM significantly reduced the immobility time in the TST or FST.
PGM did not show locomotor hyperactivity in the open field test (OFT)
We performed OFT after 3 consecutive days of treatment with a low, medium, or high doses of PGM (Fig. 1). The total distance travelled showed no significant difference in the PGM-treated groups compared with the controls, which suggested that PGM does not cause locomotor hyperactivity in mice (ANOVA, F(4,35) = 0.4653, p = 0.7607) (Fig. 3A). In addition, the distance travelled in the centre area also showed no significant difference in the PGM-treated groups compared with the control groups (ANOVA, F(4,35) = 0.8818, p = 0.4848) (Fig. 3B). The weights of mice after 5 consecutive days of treatment did not show any significant differences (ANOVA, F(4,35) = 2.448, p = 0.0797) (Fig. 3C).
CD-1 mice were i.p. injected with a low dose of PGM (5 mg/kg/day, PGM-L), a medium dose of PGM (8 mg/kg/day, PGM-M), a high dose of PGM (12.5 mg/kg/day, PGM-H), imipramine (15 mg/kg/day, IMI) or saline (Sal). After 3 days of treatments, mice were subjected to the OFT. The total distance travelled and the distance travelled in the centre area were determined by the automated tracking system. The number (N) of mice per group is indicated in each individual graph. Data were analysed by one-way ANOVA and presented as the mean ± SE. (A) The total distance travelled in the field after PGM treatment. (B) The distance travelled in the centre area of the field after PGM treatment. (C) Body weight of the 5 consecutive days after PGM treatment.
PGM mediated the antidepressant effect through its receptor Dectin-1
Western blot analyses of total proteins from the PFC were performed with an anti-Dectin-1 antibody, and after 5 days of treatment with PGM, the Dectin-1 levels were significantly increased in the PFC after low (5 mg/kg), medium (8 mg/kg), and high (12.5 mg/kg) doses of the PGM treatment by 182.4 ± 14.1%, 202.4 ± 14.7%, and 171.6 ± 19.6% (ANOVA, F(4,35) = 8.043, p < 0.01) (Fig. 4A), respectively. However, the imipramine-treated group did not show this increase (Fig. 4A). The Dectin-1-specific inhibitor Laminarin (Lam) was used to block Dectin-1 activity (Fig. 1). The pre-treatment with Laminarin almost completely blocked the decrease in immobility time caused by PGM (Sal: 115.2 ± 7.7 sec; Laminarin + Sal: 108.1 ± 9.4 sec; Laminarin+ PGM: 103.5 ± 13.7 sec; PGM: 59.1 ± 9.2 sec) (ANOVA, F(3,48) = 7.479, p < 0.01) (Fig. 4B), which suggested that the Dectin-1 receptor might mediate the antidepressant effect of PGM.
(A) The PGM treatments increased its receptor Dectin-1 levels in the prefrontal cortex (PFC) after 5 days of treatment. CD-1 mice were i.p. injected with a low dose of PGM (5 mg/kg/day, PGM-L), a medium dose of PGM (8 mg/kg/day, PGM-M), a high dose of PGM (12.5 mg/kg/day, PGM-H), imipramine (15 mg/kg/day, IMI) or saline (Sal) for 5 days. Western blot analyses of the proteins from the PFC were performed with anti-Dectin-1 antibodies. (B) Dectin-1 receptor specific blocking reagent Laminarin (Lam) was able to block the antidepressant effect of PGM in the tail suspension test (TST). The number (N) of mice per group is indicated in each individual graph. Any experimental data value greater than mean plus 2 × standard deviations (SDs) from a group was considered an outlier and was not considered in the analysis. Data were analysed by one-way ANOVA and presented as the mean ± SE (post hoc Tukey’s Test, *p < 0.05, **p < 0.01, ***p < 0.001).
After 60 minutes of treatment, PGM enhanced AMPA GluA1 S845 phosphorylation in the PFC
Previous studies have shown that the phosphorylation of AMPA GluA1 serine 845 represents an important mechanism for the treatment of depression18,19,21. In this context, we further addressed whether the p-GluA1(S845) levels were changed after treatment with PGM. Sixty minutes after i.p. injection, the p-GluA1(S845) levels were significantly increased in the PFC from low (5 mg/kg), medium (8 mg/kg), and high (12.5 mg/kg) doses of PGM by 148.1 ± 5.1%, 160.5 ± 6.5%, and 125.2 ± 5.0%, respectively, similar to that of the imipramine-treated groups (140.1 ± 6.3%) (ANOVA, F(4,35) = 12.14, p < 0.01) (Fig. 5A). However, the levels of total GluA1 (ANOVA, F(4,35) = 0.8392, p = 0.5097), GluA2 (ANOVA, F(3,35) = 2.179, p = 0.0917) or GluA3 (ANOVA, F(4,30) = 0.9194, p = 0.4636) proteins in the PFC remained unchanged (Fig. 5B–D).
CD-1 mice were i.p. injected with a low dose of PGM (5 mg/kg/day, PGM-L), a medium dose of PGM (8 mg/kg/day, PGM-M), a high dose of PGM (12.5 mg/kg/day, PGM-H), imipramine (15 mg/kg/day, IMI) or saline (Sal) for 60 minutes (mins) or 5 days. Western blot analyses of the proteins from the PFC were performed with anti-p-GluA1(S845), anti-GluA1, anti-GluA2 or anti-GluA3 antibodies. The number (N) of mice per group is indicated in each individual graph. Data were analysed by one-way ANOVA and presented as the mean ± SE (post hoc Tukey’s test, *p < 0.05, **p < 0.01, ***p < 0.001). (A–D) The expression levels of p-GluA1(S845), GluA1, GluA2 or GluA3 levels in the PFC after 60 minutes of treatment with PGM. (E–H) The expression levels of p-GluA1(S845), GluA1, GluA2 or GluA3 in the PFC after 5 days of treatment with PGM.
After 5 consecutive days of treatment, PGM increased both the AMPA p-GluA1 (S845) and GluA1 levels in the PFC
After 5 days of treatment with PGM, the level of p-GluA1(S845) was significantly increased in the PFC after low (5 mg/kg), medium (8 mg/kg), and high (12.5 mg/kg) doses of PGM by 155.0 ± 5.6%, 167.6 ± 5.4%, and 139.7 ± 7.8%, respectively, similar to that of the imipramine-treated group (148.8 ± 7.9%) (ANOVA, F(4,35) = 8.611, p < 0.01) (Fig. 5E). It is noteworthy that the PGM treatment also enhanced the levels of total GluA1 by 144.7 ± 10.1% (in the medium-dose group) and 142.2 ± 7.1% (in the high-dose group) (ANOVA, F(4,35) = 8.401, p < 0.01) (Fig. 5F), but not GluA2 (ANOVA, F(4,35) = 1.076, p = 0.3833) or GluA3 (ANOVA, F(4,25) = 1.801, p = 0.1508) expression in the PFC (Fig. 5G,H); however, imipramine had no effect on the total GluA1, GluA2, or GluA3 expression in the PFC (Fig. 5F–H).
After 60 minutes of treatment, PGM significantly up-regulated AMPA p-GluA1(S845) levels at the synapses in the PFC, similar to imipramine
To further determine whether the p-GluA1(S845), GluA1, GluA2 and GluA3 levels at the synapses in the PFC were increased, we isolated the synaptic fractions from the PFC. Western blot analysis of p-GluA1(S845), GluA1, GluA2, and GluA3 were performed with the synaptic fractions. We found that the levels of GluA1 were significantly enriched at the synapses compared to the control (Fig. 6A). After 60 minutes of treatment with low (5 mg/kg), medium (8 mg/kg) and high (12.5 mg/kg) doses of PGM, the p-GluA1(S845) levels were increased by 178.4 ± 31.9%, 163.5 ± 17.2%, and 177.6 ± 25.4%, respectively, similar to the imipramine-treated groups (204.3 ± 21.1%) (ANOVA, F(4,35) = 3.044, p < 0.05) (Fig. 6B). However, the levels of GluA1 (ANOVA, F(4,35) = 0.3635, p = 0.8329), GluA2 (ANOVA, F(4,35) = 0.4904, p = 0.7427) and GluA3 (ANOVA, F(4,35) = 1.011, p = 0.4152) proteins at the synapses in the PFC still remained unchanged (Fig. 6C–E).
CD-1 mice were i.p. injected with a low dose of PGM (5 mg/kg/day, PGM-L), a medium dose of PGM (8 mg/kg/day, PGM-M), a high dose of PGM (12.5 mg/kg/day, PGM-H), imipramine (15 mg/kg/day, IMI) or saline (Sal) for 60 minutes (mins) or 5 days. Synaptosomal fractions from the PFC were prepared and subjected to western blot analyses with anti-p-GluA1(S845), anti-GluA1, anti-GluA2 or anti-GluA3 antibodies. The number (N) of mice per group is indicated in each individual graph. Data were analysed by two-tailed t-test or one-way ANOVA and presented as the mean ± SE (two-tailed t-test, ###p < 0.001; post hoc Tukey’s test, *p < 0.05, **p < 0.01, ***p < 0.001). (A) Enrichments of GluA1 at synaptosomal (Syn) fractions compared with the control. (B–E) The expression levels of synaptic p-GluA1(S845), GluA1, GluA2, GluA3 in the PFC after 60-minute treatment with PGM. (F–I) After 5 days of treatment, PGM enhanced synaptic p-GluA1(S845), GluA1, GluA2 and GluA3 levels in the PFC.
After 5 days of treatment, PGM significantly increased p-GluA1(S845), GluA1, GluA2, and GluA3 levels at the synapses in the PFC, similar to imipramine
After 5 days of treatment with PGM, low (5 mg/kg), medium (8 mg/kg), and high (12.5 mg/kg) doses increased the p-GluA1(S845) levels by 201.9 ± 11.5%, 183.2 ± 12.7%, and 192.1 ± 20.2%, respectively, in the PFC (ANOVA, F(4,35) = 9.456, p < 0.01) (Fig. 6F). In addition, in the synaptic fraction from the PFC, the GluA1 levels were increased in a dose-dependent manner by 147.7 ± 9.8% (in the low-dose groups), 153.1 ± 12.8% (in the medium-dose groups), and 177.8 ± 21.8% (in the high-dose groups) (ANOVA, F(4,35) = 4.076, p < 0.01); GluA2 levels were increased by 136.8 ± 8.5% (in the medium-dose groups) and 148.8 ± 9.3% (in the high-dose groups) (ANOVA, F(4,35) = 5.518, p < 0.01); GluA3 levels were increased by 141.8 ± 6.9% (in the low-dose groups), 161.5 ± 9.1% (in the medium-dose groups), and 164.2 ± 11.4% (in the high-dose groups) (ANOVA, F(4,35) = 6.702, p < 0.01), which was similar to imipramine (Fig. 6G–I).
The antidepressant effect and increased p-GluA1(S845) and GluA1 levels from PGM lasted at least 3 days after stopping treatment with PGM
Because Burgdorf et al. found that ketamine enhanced GluA1 protein expression and Maeng et al. found that ketamine showed a long-lasting antidepressant effect10,22, we hypothesized that the PGM treatment might also result in a prolonged antidepressant effect. After 5 consecutive days of treatment with a high dose of PGM (12.5 mg/kg) or imipramine (15 mg/kg), we stopped treatment for 3 days or 5 days. After stopping treatment for three days, we found that the antidepressant effect of PGM remained in the TST, with 55.8 ± 9.6 sec for the PGM groups compared to the control groups (100.8 ± 5.0 sec) (ANOVA, F(4,45) = 3.627, p < 0.05) (Fig. 7A). The data were confirmed in the FST that the immobility time in the PGM-treated groups with 57.8 ± 10.8 sec after stopping treatment for 3 days was significantly lower than the control group (107.1 ± 17.4 sec) (ANOVA, F(4,55) = 5.204, p < 0.01) (Fig. 7B). After stopping treatment for 3 days, the imipramine group showed an antidepressant effect, but did not reach significance under the same conditions (Fig. 7A,B). Moreover, 3 days after stopping treatment with PGM, the p-GluA1(S845) and GluA1 levels of the PGM groups also remained increased by 150.8 ± 2.4% (ANOVA, F(4,30) = 10.58, p < 0.01) and 132.2 ± 3.9% (ANOVA, F(4,30) = 14.36, p < 0.01) (Fig. 8A,B), respectively, but not GluA2 (ANOVA, F(4,35) = 0.4412, p = 0.7779) and GluA3 (ANOVA, F(4,35) = 1.417, p = 0.2487) (Fig. 8C,D), which suggested that the antidepressant effect was prolonged. However, after 5 days without treatment, the antidepressant effect of PGM was diminished (ANOVA, F(4,45) = 6.841, p < 0.01) (Fig. 7C).
CD-1 mice were i.p. injected with a high dose of PGM (12.5 mg/kg/day) or imipramine (15 mg/kg/day, IMI) or saline (Sal) for 5 days. Then, the treatment with PGM or imipramine was stopped for 3 days or 5 days. As shown in the figure, the PGM-S and IMI-S indicated the groups that stopped treatment with PGM or imipramine; PGM-C and IMI-C indicated the groups that continued the treatment. The number (N) of mice per group was indicated in each individual graph. Any experimental data value greater than mean plus 2 × standard deviations (SDs) from a group was considered an outlier and was not considered in the analysis. Data were analysed by one-way ANOVA and presented as the mean ± SE (post hoc Tukey’s test, *p < 0.05, **p < 0.01, ***p < 0.001). (A,B) After stopping treatment for 3 days, the animals were subjected to TST or FST. (C) After stopping treatment for 5 days, mice were subjected to FST.
CD-1 mice were i.p. injected with a high dose of PGM (12.5 mg/kg/day) or imipramine (15 mg/kg/day, IMI) or saline (Sal) for 5 days. Then, the treatment with PGM or imipramine was stopped for 3 days. As shown in the figure, the PGM-S and IMI-S indicated the groups that stopped treatment with PGM or imipramine; PGM-C and IMI-C indicated the groups that continued the treatment. Western blot analyses of the proteins from the PFC were performed with anti-p-GluA1(S845), anti-GluA1, anti-GluA2 or anti-GluA3 antibodies. The number (N) of mice per group is indicated in each individual graph. Data were analysed by one-way ANOVA and presented as the mean ± SE (post hoc Tukey’s test, *p < 0.05, **p < 0.01, ***p < 0.001). The expression levels of (A) p-GluA1(S845), (B) GluA1, (C) GluA2, or (D) GluA3 in the PFC were determined.
The antidepressant effect of PGM was blocked by the AMPA receptor-specific antagonist GYKI 52466
We hypothesized that the increase in AMPA receptor signalling is critical for the antidepressant effect of PGM. To test this hypothesis, the AMPA receptor-specific antagonist GYKI 52466 was used to determine whether the antidepressant effect of PGM could be blocked by GYKI 52466. CD-1 mice were i.p. injected with PGM (8 mg/kg) for 60 minutes. GYKI 52466 (10 mg/kg) was administered 30 minutes prior to behavioural testing (Fig. 1). Sixty minutes after the PGM injection, the mice were subjected to TST. The treatment with GYKI 52466 almost completely blocked the decrease of immobility time caused by PGM (Sal: 127.6 ± 11.4 sec; Sal + GYKI: 135.8 ± 12.5 sec; PGM + GYKI: 115.1 ± 11.5 sec; PGM: 62.3 ± 12.8 sec) (ANOVA, F(3,28) = 7.534, p < 0.01) (Fig. 9), which suggested that enhanced AMPA receptor excitability at the synapses might play an important role in the antidepressant effect of PGM.
CD-1 mice were i.p. injected with a medium dose of PGM (8 mg/kg) or saline (Sal) for 60 minutes. GYKI (10 mg/kg) or vehicle (Veh) was administered 30 minutes prior to behavioural testing. Then, the CD-1 mice were subjected to the TST. The immobility time was determined. The number (N) of mice per group is indicated in each individual graph. Data were analysed by one-way ANOVA and presented as the mean ± SE (post hoc Tukey’s test, *p < 0.05, **p < 0.01, ***p < 0.001).
Discussion
This study sought to study the robust and prolonged antidepressant effects of PGM and its underlying mechanisms in regulating Dectin-1/AMPA receptor signalling. We found that: (1) PGM had a robust antidepressant effect in the TST and FST after 60 minutes of treatment, and this effect remained after 5 consecutive days of treatment in the TST and FST; (2) PGM had no hyperactive effect in the OFT; (3) PGM enhanced the expression of its receptor Dectin-1 in the PFC after 5 days of treatment; (4) Dectin-1 inhibitor Laminarin was able to block the antidepressant effect of PGM; (5) PGM increased the p-GluA1(S845) levels in the PFC after 60 minutes of treatment and enhanced p-GluA1(S845) and GluA1 expression in the PFC after 5 days of treatment; (6) at the synapses in the PFC, PGM enriched p-GluA1(S845) expression after 60 minutes of treatment and p-GluA1(S845), GluA1, GluA2, and GluA3 levels after 5 days of treatment, similar to imipramine; (7) the antidepressant effect of PGM lasted for 3 days, but not for 5 days after stopping the treatment; and (8) the AMPA receptor-specific antagonist GYKI 52466 was able to block the robust antidepressant effect of PGM.
The Dectin-1/AMPA receptor signalling pathway demonstrated a novel mechanism that is closely related to the neuroimmune system. Currently, the most famous rapid antidepressant is ketamine, a NMDA receptor antagonist that elicits a rapid antidepressant response in patients with depression23,24 and bipolar depression25,26,27. Evidence suggests that ketamine’s antidepressant properties rely on blocking NMDA receptors, increased AMPA signalling, rapidly induced synaptogenesis1,10 and lasted for a few days to weeks28. Here, we reported a replacement for ketamine, PGM, which showed a robust and prolonged antidepressant effect mediated through the Dectin-1/AMPA receptor signalling pathway. Both PGM and imipramine showed an antidepressant effect in mice (Fig. 2A–D); however, clinical trials are warranted to determine the effective times in humans. Although similar results were found for the 5-day treatment after acute treatment for 60 minutes, a prolonged antidepressant result was observed after stopping the drug treatment for up to three days (Fig. 7A,B). Although PGM showed a prolonged antidepressant effect for 3 days, it was shorter than the weeks-long antidepressant effect of ketamine10.
Other psycho-stimulants, such as cocaine and amphetamine, may also have an antidepressant effect, but these psycho-stimulants usually induce excitatory neural toxicity and drug addiction and lead to the development of depressive symptoms during withdrawal29,30,31. Although PGM demonstrated a strong antidepressant effect, it did not elicit hyperactivity like some other psycho-stimulants (Fig. 3A,B). This is different from the psycho-stimulant amphetamine, which significantly increased the total distance travelled in rats during the OFT32.
PGM is a proteo-β-glucan. It has been shown that glucan can pass through the blood brain barrier via transporters or during the inflammatory process5,33,34. Here, we reported that PGM within a specific dose range (5–12.5 mg/kg) might bind to its receptor Dectin-1 in the brain to exert a robust antidepressant effect. The fact that the Dectin-1 receptor levels were significantly increased after PGM treatment was an indicator of the activation of the Dectin-1 receptors (Fig. 4A). Dectin-1 inhibition almost completely blocked the antidepressant effect of PGM (Fig. 4B). Therefore, the Dectin-1/AMPA pathway could be a newly discovered pathway for the treatment of depression. Binding to Dectin-1 could lead to the activation of Syk/NFκb signalling pathways and regulation of the neuroimmune system35. Targeting Dectin-1 may become a novel strategy for the treatment of mood disorders.
PGM regulated the p-GluA1(S845), GluA1, GluA2, and GluA3 levels at the synapses in the PFC, which suggested a critical role of the AMPA signalling pathway. GluA1 phosphorylation at S845, which is a PKA site, is often viewed as an indicator of GluA1 membrane insertion in neurons and wide channel opening20,36,37,38. Previous studies have shown that the levels of AMPA GluA1 in the PFC in depressed patients were decreased39,40, which was consistent with previous animal experiments41,42,43. AMPA receptors may serve as a common mechanism for the treatment of mood disorders21,44,45,46,47. Consistent with previous findings, we found that PGM was able to enhance p-GluA1(S845) in the total protein preparations or in the synaptic fractions from the PFC within 60 minutes (Figs 5A and 6B). After 5 days of treatment, PGM was able to enhance both the p-GluA1(S845) and GluA1 levels (Figs 5E,F and 6F,G). It is noteworthy that imipramine had no effect on total GluA1 protein expression, but both PGM and ketamine enhanced GluA1 levels22, suggesting a stronger effect in regulating AMPA receptor signalling by PGM (Fig. 5F). Both PGM and imipramine significantly enhanced p-GluA1(S845), GluA1, GluA2, and GluA3 at the synapses in the PFC (Fig. 6F–I). Usually, GluA1/2 and GluA2/3 formed tetramers. Therefore, the three AMPA receptor subunits, GluA1, GluA2, and GluA3, were increased at the synapses after the PGM or imipramine treatment.
As to the mechanisms of regulating AMPA receptors, PGM may go through either direct or indirect mechanism(s). PGM may directly regulate neuronal synapse through the Dectin-1 receptor on the neurons followed by the activation of the signalling cascades (e.g., Syk/NFκb signalling pathway)35. PGM may also modulate cytokine expression, leading to the production of IL-2, TNF-α, and IL-1848,49. It was also reported that cytokines could regulate AMPA receptor signalling50. Further exploration of these mechanisms will be one of our future directions.
Previous studies showed that lithium, cordycepin, and dextromethorphanall exerted a rapid antidepressant effect in mice in the TST and FST via up-regulating the AMPA receptor subunits, and an AMPA inhibitor was able to block the antidepressant effects47,51,52. Recent clinical trials have shown that Org 26576 (ionotropic AMPA-type glutamate receptor enhancer) significantly improved symptoms in depressed patients as revealed by the Montgomery-Asberg Depression Rating Scale53. In addition, the biaryl-propyl-sulphonamide ARPs (LY392098 and LY451616, AMPA receptor potentiators) have antidepressant effects in animal models of depression, in learned-helplessness models of depression, and in animals exposed to chronic mild stress17,54, which suggests that the enhancement of AMPA function was sufficient for the antidepressant effect. We found that PGM up-regulated AMPA receptors at the synapse (Fig. 6G–I), and this effect lasted for 3 days after stopping the treatment (Fig. 8B). The AMPA antagonist GYKI 52466 was able to block the PGM-induced antidepressant effect (Fig. 9), which suggested that enhanced AMPA synaptic transmission is essential for the antidepressant effect.
In this paper, we identified PGM as a strong antidepressant with clinical potential for the treatment of depression. It acts by enhancing novel prefrontal Dectin-1/AMPA receptor signalling. This study suggested that the novel target Dectin-1 may be significant in the development of effective antidepressants with novel mechanism(s) for the treatment of major depression.
Methods
Animals
All animal procedures were carried out in accordance with the Guide for the Care and Use of Laboratory Animals (ISBN: 0-309-05377-3) and were approved by the Institutional Animal Care and Use Committee at Yunnan University School of Medicine (IACUC: MS201402). Male CD-1 mice (6 weeks; starting weight, 22–26 g; Vital River, Beijing, China) were group housed (N = 4/cage) in an animal room with a constant temperature (22 ± 1 °C) and maintained on a 12-hour light/dark cycle (lights on/off at 9:00 A.M./9:00 P.M.), with constant humidity (55 ± 10%) and free access to water and food. After a one-week acclimatization period, the mice were treated with drugs or vehicle in a volume of 10 μl/g by intraperitoneal (i.p.) injection and tested between 9 A.M. and 12 A.M.
Bioactive Proteo-β-Glucan from Maitake (PGM)
The Mataike D-fraction was extracted from Maitake mushrooms, which were prepared in a standardized procedure as described previously by Mushroom Wisdom, Inc.3,55. The D-fraction obtained using this standard method showed a single peak with a MW of 1200–2000 kDa by HPLC analysis and consisted of 98% polysaccharide and 2% peptides. We purchased the supplies from Mushroom Wisdom Inc (East Rutherford, NJ, USA). They labeled their product as containing 30% of the D-fraction solution in water and glycerol. We performed a triple volume of 95% ethanol precipitation procedure to remove the water and glycerol. After incubating the mixture for 60 minutes at room temperature, the samples were centrifuged at 12000rcf/min at 4 °C for 60 minutes35. The precipitate was dried with air and re-dissolved in saline for the animal i.p. injections. After ethanol extraction, the resulting proteo-β-glucan was defined as the proteo-β-glucan from Maitake (PGM).
Animal behavioural studies
To examine the antidepressant effects from PGM, mice were randomly assigned to five treatment groups: saline (sterile 0.9% sodium chloride solution), low dose of PGM (5 mg/kg, dissolved in saline), medium dose of PGM (8 mg/kg, dissolved in saline), high dose of PGM (12.5 mg/kg, in saline), and imipramine (15 mg/kg, in saline; Sigma, St. Louis, MO, USA). The animal behavioural tests were performed 60 minutes after drugs or vehicle were administered, and the TST was performed after 60 minutes, OFT on the third day, and FST on the fifth day. To confirm the antidepressant effects of PGM, another group of mice was subjected to the FST after 60 minutes and to the TST on the fifth day, respectively, under similar conditions.
To examine whether the antidepressant effect of PGM could be blocked by Laminarin (Lam, a specific Dectin-1 blocking reagent, Sigma, St. Louis, MO, USA), CD-1 mice were i.p. injected with Laminarin (10 mg/kg) 2 hours prior to the behavioural testing, followed by the PGM injection one hour later. Sixty minutes after the PGM injection, the mice were subjected to the TST56. The AMPA-specific inhibitor GYKI 52466 (a selective non-competitive AMPA receptor antagonist, TOCRIS Bioscience, R&D, Minneapolis, USA) was used to determine the AMPA effect. CD-1 mice were i.p. injected with PGM (60 minutes before the TST) followed by a GYKI 52466 injection (10 mg/kg in 8%DMSO/92%saline 30 minutes before the TST)47,57. For each drug treatment, the control mice received the vehicle alone via i.p. injection.
Tail suspension test (TST)
The TST was performed according to a previously described procedure58 with minor modifications. A piece of tape 7 cm in length and 2 cm in width was positioned with approximately 2 mm of the tail protruding. Each mouse was individually suspended by the tail from a bar (30 cm high) and videotaped during a 6-minute test session. Immobility time was quantified by a naive observer for the last 4 minutes.
Open field test (OFT)
An activity chamber (60 × 60 × 30 cm) with a black floor was divided into 16 squares of equal area (15 × 15 cm) by white lines and used to study PGM-induced locomotor hyperactivity. Three days after i.p. injection with various concentrations of drugs, the mice were placed in the centre of the chamber and their behaviours were recorded for 60 minutes. The total distance travelled and the distance travelled in the centre area (the 4-square area in the middle of the chamber) were analysed by the ANY-maze system (Stoelting, Wood Dale, USA).
Forced swim test (FST)
The FST was carried out according to previously described procedures59 with minor modifications. Mice were placed in a cylinder (Φ = 20 cm) with water (temperature between 23 ± 1 °C) 20 cm in depth. Mice were videotaped during a 6-minute test session and were later analysed for mobility for the last 4 minutes. Mobility was defined as any movement beyond what was necessary to maintain their head above water. Immobility time was quantified by a naive observer.
Western blot analysis
The PFC tissue was lysed with an ice-cold radioimmunoprecipitation assay (RIPA) buffer [20 mM Tris (pH7.5), 150 mM NaCl, 1% Triton X-100, sodium pyrophosphate, β-glycerophosphate, EDTA, Na3VO4, leupeptin plus a Protease Inhibitor Cocktail Tablet (Roche, Mannheim, Germany), and Phosphatase Inhibitor Cocktail Tablet (Roche, Mannheim, Germany)] in a tissue grinder (Wheaton, Millville, USA). Protein concentrations were determined using a BCA protein assay kit (Pierce Biotechnology, Rockford, USA). Equal amounts of proteins were subjected to 7–10% SDS-PAGE gel electrophoresis and transferred to the polyvinylidene difluoride (PVDF) membranes (Pall, New York, USA). The antibodies against Dectin-1 (Rat mAb, 1:200, Santa Cruz, Dallas, USA), p-GluA1(S845) (Rabbit mAb, 1:1000, Cell Signaling Technology, Boston, USA), GluA1 (Goat pAb, 1:1000, Santa Cruz, Dallas, USA), GluA2 (Rabbit mAb, 1:2000, Abcam, Cambridge, UK), and GluA3 (Rabbit mAb, 1:5000, Abcam, Cambridge, UK) were used. The secondary antibodies were horseradish peroxidase-conjugated goat anti-rat (1:2000, Affinity Bioscience, Cincinnati, USA), goat anti-rabbit (1:5000, Affinity Bioscience, Cincinnati, USA) or donkey anti-goat antibodies (1:5000; Santa Cruz, Dallas, USA). The antibody for β-tubulin (Mouse mAb, 0.2 μg/ml, Affinity Bioscience, Cincinnati, USA) was applied for loading calibration. The immunoreactive bands were visualized using the ECL detection system (Millipore, Billerica, USA). The images were acquired by the FlourChem E image system (FE0511, ProteinSimple, San Jose, USA) and quantified by ImagePro Plus version 6.0 software (Media Cybernetics, Rockville, USA).
Synaptosomal preparation
The synaptosomal fractions were prepared from the PFC tissue using the differential and discontinuous Ficoll gradient centrifugation method44,45,60. Tissue was homogenized by a tissue grinder and then an electronic polytron homogenizer (AutoScience, Tianjin, China) in cold Syn buffer (300 mM mannitol and 1 mM EDTA, pH 7.4). The crude homogenates were centrifuged at 5000× g for 10 minutes, and the supernatants were centrifuged again at 15000× g for 30 minutes. The resuspended pellets were loaded on Ficoll gradient (2%, 8%, 12%, 16%, 20%) tubes and centrifuged at 22000× g for 90 minutes. The 8/12% and 12/16% interfaces were carefully removed, diluted in Syn buffer at a ratio of 1:4, and centrifuged for 20 minutes at 15000× g. The pellets were resuspended and lysed with lysis buffer. All samples were constantly maintained at 4 °C during all steps. Western blot was performed to analyse the synaptic expressions of the p-GluA1(S845), GluA1, GluA2, and GluA3.
Statistical analysis
All data were analysed by one-way analysis of variance (ANOVA) and post hoc Tukey’s tests and presented as the mean ± SE via SPSS version 17. Any experimental data value greater than mean plus 2 × standard deviations (SDs) from a group was considered an outlier and was not considered in the analysis. A p-value less than 0.05 was considered significant. Figures were generated by GraphPad Prism version 5 software.
Additional Information
How to cite this article: Bao, H. et al. The Prefrontal Dectin-1/AMPA Receptor Signaling Pathway Mediates The Robust and Prolonged Antidepressant Effect of Proteo-β-Glucan from Maitake. Sci. Rep. 6, 28395; doi: 10.1038/srep28395 (2016).
References
Caddy, C., Giaroli, G., White, T. P., Shergill, S. S. & Tracy, D. K. Ketamine as the prototype glutamatergic antidepressant: pharmacodynamic actions, and a systematic review and meta-analysis of efficacy. Therapeutic advances in psychopharmacology 4, 75–99 (2014).
Konno, S. Synergistic potentiation of D-fraction with vitamin C as possible alternative approach for cancer therapy. International journal of general medicine 2, 91–108 (2009).
Nanba, H., Hamaguchi, A. & Kuroda, H. The chemical structure of an antitumor polysaccharide in fruit bodies of Grifola frondosa (maitake). Chemical & pharmaceutical bulletin 35, 1162–1168 (1987).
Taylor, P. R. et al. The beta-glucan receptor, dectin-1, is predominantly expressed on the surface of cells of the monocyte/macrophage and neutrophil lineages. J Immunol 169, 3876–3882 (2002).
Shah, V. B. et al. Beta-glucan activates microglia without inducing cytokine production in Dectin-1-dependent manner. J Immunol 180, 2777–2785 (2008).
Rogers, N. C. et al. Syk-dependent cytokine induction by Dectin-1 reveals a novel pattern recognition pathway for C type lectins. Immunity 22, 507–517 (2005).
Liu, Y. N. et al. TNFalpha mediates stress-induced depression by upregulating indoleamine 2,3-dioxygenase in a mouse model of unpredictable chronic mild stress. European cytokine network 26, 15–25 (2015).
Kong, E. et al. STAT3 controls IL6-dependent regulation of serotonin transporter function and depression-like behavior. Scientific reports 5, 9009 (2015).
Yirmiya, R., Rimmerman, N. & Reshef, R. Depression as a microglial disease. Trends in neurosciences 38, 637–658 (2015).
Maeng, S. et al. Cellular mechanisms underlying the antidepressant effects of ketamine: role of alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid receptors. Biological psychiatry 63, 349–352 (2008).
Bonanno, G. et al. Chronic antidepressants reduce depolarization-evoked glutamate release and protein interactions favoring formation of SNARE complex in hippocampus. J Neurosci 25, 3270–3279 (2005).
Krystal, J. H. et al. Glutamate and GABA systems as targets for novel antidepressant and mood-stabilizing treatments. Molecular psychiatry 7 Suppl 1, S71–80 (2002).
Sun, X., Zhao, Y. & Wolf, M. E. Dopamine receptor stimulation modulates AMPA receptor synaptic insertion in prefrontal cortex neurons. J Neurosci 25, 7342–7351 (2005).
Carlezon, W. A. Jr. & Nestler, E. J. Elevated levels of GluR1 in the midbrain: a trigger for sensitization to drugs of abuse? Trends Neurosci 25, 610–615 (2002).
Malenka, R. C. Synaptic plasticity and AMPA receptor trafficking. Ann N Y Acad Sci. 1003, 1–11 (2003).
Freudenberg, F., Celikel, T. & Reif, A. The role of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors in depression: central mediators of pathophysiology and antidepressant activity? Neuroscience and biobehavioral reviews 52, 193–206 (2015).
Li, X. et al. Antidepressant-like actions of an AMPA receptor potentiator (LY392098). Neuropharmacology 40, 1028–1033 (2001).
Svenningsson, P. et al. Involvement of AMPA receptor phosphorylation in antidepressant actions with special reference to tianeptine. The European journal of neuroscience 26, 3509–3517 (2007).
Svenningsson, P. et al. Involvement of striatal and extrastriatal DARPP-32 in biochemical and behavioral effects of fluoxetine (Prozac). Proceedings of the National Academy of Sciences of the United States of America 99, 3182–3187 (2002).
Wang, J. Q. et al. Phosphorylation of AMPA receptors: mechanisms and synaptic plasticity. Molecular neurobiology 32, 237–249 (2005).
Du, J. et al. The anticonvulsants lamotrigine, riluzole, and valproate differentially regulate AMPA receptor membrane localization: relationship to clinical effects in mood disorders. Neuropsychopharmacology: official publication of the American College of Neuropsychopharmacology 32, 793–802 (2007).
Burgdorf, J. et al. GLYX-13, a NMDA receptor glycine-site functional partial agonist, induces antidepressant-like effects without ketamine-like side effects. Neuropsychopharmacology: official publication of the American College of Neuropsychopharmacology 38, 729–742 (2013).
Berman, R. M. et al. Antidepressant effects of ketamine in depressed patients. Biological psychiatry 47, 351–354 (2000).
Price, R. B., Nock, M. K., Charney, D. S. & Mathew, S. J. Effects of intravenous ketamine on explicit and implicit measures of suicidality in treatment-resistant depression. Biol Psychiatry 66, 522–526 (2009).
DiazGranados, N. et al. Rapid resolution of suicidal ideation after a single infusion of an N-methyl-D-aspartate antagonist in patients with treatment-resistant major depressive disorder. J Clin Psychiatry 71, 1605–1611 (2010).
Zarate, C. A. Jr. et al. Replication of ketamine’s antidepressant efficacy in bipolar depression: a randomized controlled add-on trial. Biol Psychiatry 71, 939–946 (2012).
Krystal, J. H., Sanacora, G. & Duman, R. S. Rapid-acting glutamatergic antidepressants: the path to ketamine and beyond. Biological psychiatry 73, 1133–1141 (2013).
Aan Het Rot, M., Zarate, C. A. Jr., Charney, D. S. & Mathew, S. J. Ketamine for depression: where do we go from here? Biological psychiatry 72, 537–547 (2012).
Che, Y. et al. Abstinence from repeated amphetamine treatment induces depressive-like behaviors and oxidative damage in rat brain. Psychopharmacology (Berl) 227, 605–614 (2013).
McCance-Katz, E. F., Kosten, T. R. & Jatlow, P. Concurrent use of cocaine and alcohol is more potent and potentially more toxic than use of either alone–a multiple-dose study. Biological psychiatry 44, 250–259 (1998).
Pierce, R. C. & Kalivas, P. W. A circuitry model of the expression of behavioral sensitization to amphetamine-like psychostimulants. Brain research. Brain research reviews 25, 192–216 (1997).
Labonte, B. et al. Adolescent amphetamine exposure elicits dose-specific effects on monoaminergic neurotransmission and behaviour in adulthood. Int J Neuropsychopharmacol 15, 1319–1330 (2012).
Nagyoszi, P. et al. Expression and regulation of toll-like receptors in cerebral endothelial cells. Neurochemistry international 57, 556–564 (2010).
Dennehy, K. M. et al. Syk kinase is required for collaborative cytokine production induced through Dectin-1 and Toll-like receptors. European journal of immunology 38, 500–506 (2008).
Fang, J. et al. Structure of a beta-glucan from Grifola frondosa and its antitumor effect by activating Dectin-1/Syk/NF-kappaB signaling. Glycoconjugate journal 29, 365–377 (2012).
Roche, K. W., O’Brien, R. J., Mammen, A. L., Bernhardt, J. & Huganir, R. L. Characterization of multiple phosphorylation sites on the AMPA receptor GluR1 subunit. Neuron 16, 1179–1188 (1996).
Lee, H. K., Barbarosie, M., Kameyama, K., Bear, M. F. & Huganir, R. L. Regulation of distinct AMPA receptor phosphorylation sites during bidirectional synaptic plasticity. Nature 405, 955–959 (2000).
Esteban, J. A. et al. PKA phosphorylation of AMPA receptor subunits controls synaptic trafficking underlying plasticity. Nat Neurosci 6, 136–143 (2003).
Duric, V. et al. Altered expression of synapse and glutamate related genes in post-mortem hippocampus of depressed subjects. Int J Neuropsychopharmacol 16, 69–82 (2013).
Beneyto, M., Kristiansen, L. V., Oni-Orisan, A., McCullumsmith, R. E. & Meador-Woodruff, J. H. Abnormal glutamate receptor expression in the medial temporal lobe in schizophrenia and mood disorders. Neuropsychopharmacology: official publication of the American College of Neuropsychopharmacology 32, 1888–1902 (2007).
Kallarackal, A. J. et al. Chronic stress induces a selective decrease in AMPA receptor-mediated synaptic excitation at hippocampal temporoammonic-CA1 synapses. The Journal of neuroscience: the official journal of the Society for Neuroscience 33, 15669–15674 (2013).
Toth, E. et al. Age-dependent effects of chronic stress on brain plasticity and depressive behavior. Journal of neurochemistry 107, 522–532 (2008).
Yuen, E. Y. et al. Repeated stress causes cognitive impairment by suppressing glutamate receptor expression and function in prefrontal cortex. Neuron 73, 962–977 (2012).
Du, J. et al. The role of hippocampal GluR1 and GluR2 receptors in manic-like behavior. The Journal of neuroscience: the official journal of the Society for Neuroscience 28, 68–79 (2008).
Du, J. et al. Modulation of synaptic plasticity by antimanic agents: the role of AMPA glutamate receptor subunit 1 synaptic expression. The Journal of neuroscience: the official journal of the Society for Neuroscience 24, 6578–6589 (2004).
Du, J. et al. A kinesin signaling complex mediates the ability of GSK-3beta to affect mood-associated behaviors. Proceedings of the National Academy of Sciences of the United States of America 107, 11573–11578 (2010).
Gould, T. D. et al. Involvement of AMPA receptors in the antidepressant-like effects of lithium in the mouse tail suspension test and forced swim test. Neuropharmacology 54, 577–587 (2008).
Inoue, A., Kodama, N. & Nanba, H. Effect of maitake (Grifola frondosa) D-fraction on the control of the T lymph node Th-1/Th-2 proportion. Biological & pharmaceutical bulletin 25, 536–540 (2002).
Kodama, N. et al. Maitake D-Fraction enhances antitumor effects and reduces immunosuppression by mitomycin-C in tumor-bearing mice. Nutrition 21, 624–629 (2005).
Kanno, T., Nagata, T., Yamamoto, S., Okamura, H. & Nishizaki, T. Interleukin-18 stimulates synaptically released glutamate and enhances postsynaptic AMPA receptor responses in the CA1 region of mouse hippocampal slices. Brain research 1012, 190–193 (2004).
Li, B. et al. 3′-Deoxyadenosine (Cordycepin) Produces a Rapid and Robust Antidepressant Effect via Enhancing Prefrontal AMPA Receptor Signaling Pathway. Int J Neuropsychopharmacol, 10.1093/ijnp/pyv112 (2016).
Nguyen, L. & Matsumoto, R. R. Involvement of AMPA receptors in the antidepressant-like effects of dextromethorphan in mice. Behavioural brain research 295, 26–34 (2015).
Nations, K. R. et al. Examination of Org 26576, an AMPA receptor positive allosteric modulator, in patients diagnosed with major depressive disorder: an exploratory, randomized, double-blind, placebo-controlled trial. J Psychopharmacol 26, 1525–1539 (2012).
Alt, A., Witkin, J. M. & Bleakman, D. AMPA receptor potentiators as novel antidepressants. Current pharmaceutical design 11, 1511–1527 (2005).
Masuda, Y., Togo, T., Mizuno, S., Konishi, M. & Nanba, H. Soluble beta-glucan from Grifola frondosa induces proliferation and Dectin-1/Syk signaling in resident macrophages via the GM-CSF autocrine pathway. Journal of leukocyte biology 91, 547–556 (2012).
Wang, Y. et al. Inducement of cytokine release by GFPBW2, a novel polysaccharide from fruit bodies of Grifola frondosa, through dectin-1 in macrophages. Journal of agricultural and food chemistry 61, 11400–11409 (2013).
Farley, S., Apazoglou, K., Witkin, J. M., Giros, B. & Tzavara, E. T. Antidepressant-like effects of an AMPA receptor potentiator under a chronic mild stress paradigm. Int J Neuropsychopharmacol 13, 1207–1218 (2010).
Cryan, J. F., Mombereau, C. & Vassout, A. The tail suspension test as a model for assessing antidepressant activity: review of pharmacological and genetic studies in mice. Neuroscience and biobehavioral reviews 29, 571–625 (2005).
Borsini, F. & Meli, A. Is the forced swimming test a suitable model for revealing antidepressant activity? Psychopharmacology 94, 147–160 (1988).
Pozzo-Miller, L. D. et al. Impairments in high-frequency transmission, synaptic vesicle docking, and synaptic protein distribution in the hippocampus of BDNF knockout mice. J Neurosci 19, 4972–4983 (1999).
Acknowledgements
This work was supported by the Yunnan High-level Professional Funding (2012HA004) from Department of Science and Technology of Yunnan Province, Area Scientific Fund (31560274) from National Natural Science Foundation of China, General Program (81372360) from National Natural Science Foundation of China, National Science Fund for Young Scholars (31300891) from the National Natural Science Foundation of China, General Program (2015FB117) from Department of Science and Technology of Yunnan Province, Scientific Research Fund of Yunnan Provincial Education Department (2013Y366), Postgraduate Research Fund from Yunnan Provincial Education Department (2014J004), Innovation Funding for Small and Medium-sized Enterprise (Z10110100191034) from Department of Science and Technology of Beijing.
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J.D., C.X., H.B. and P.R. conceived the idea for the study. J.D., H.B., C.X., M.Z. and X.X. wrote the main manuscript text. H.B., P.R., H.L., S.Z. and L.P.S. prepared Figures 1, 2, 6 and 8. H.B., P.R., L.J.S., B.L., Y.H. and J.N. prepared Figures 3–5, 7 and 9. All authors reviewed the manuscript.
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Bao, H., Ran, P., Zhu, M. et al. The Prefrontal Dectin-1/AMPA Receptor Signaling Pathway Mediates The Robust and Prolonged Antidepressant Effect of Proteo-β-Glucan from Maitake. Sci Rep 6, 28395 (2016). https://doi.org/10.1038/srep28395
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DOI: https://doi.org/10.1038/srep28395
