Survival rate
To observe the effects of combined stress on mortality rate, we recorded survival rate during the experimental period. As shown in Fig. 1, no animals died in the control group (100% for control group). Animal death was observed in the first 4 days following combined stress protocol, but there was no difference in survival rate among groups (P = 0.089). The survival rate was 79.167% in LPS + stress (LS) group and 75% in LS + fluoxetine group.
Hippocampal inflammatory response induced by combined stress was attenuated by fluoxetine treatment
To determine changes in immune response in the hippocampus after combined stress, we performed immunostaining by using antibodies of IBA1 or GFAP, as well as MSD for inflammatory mediator measurements. Relative to control group, the intensity of IBA1 cells in the hippocampus increased significantly in LS group. Similarly, the intensity of hippocampal GFAP cells was significantly increased in LS group compared with control group. For inflammatory mediator measurements, we observed there was a significantly increased IL-6 level in the hippocampus in LS group than that in control group. These results suggested that combined stress induced an enhanced inflammatory reaction. However, chronic treatment with fluoxetine only reversed the intensity of IBA1 (CA1: F(2, 9) = 9.236, P = 0.0066; CA3: F(2, 9) = 5.029, P = 0.0342; DG: F(2, 9) = 11.56, P = 0.0033, Fig. 2) and GFAP (CA1: F(2, 9) = 22.35, P = 0.0003; CA3: F(2, 9) = 5.993, P = 0.0221; DG: F(2, 9) = 0.6033, P = 0.5677, Fig. 3) of the CA1 region. The increased hippocampal IL-6 level in the LS group was also prevented by fluoxetine treatment (F(2, 15) = 4.964, P = 0.0222, Fig. 4G). There was no difference in TNF-α (F(2, 15) = 0.7828, P = 0.4749, Fig. 4B), IL-1β (F(2, 15) = 0.04009, P = 0.9608, Fig. 4C), IL-2 (F(2, 15) = 0.1656, P = 0.8489, Fig. 4D), IL-4 (F(2, 15) = 1.738, P = 0.2094, Fig. 4E), IL-5 (F(2, 15) = 0.3083, P = 0.7393, Fig. 4F), IL-10 (F(2, 15) = 0.341, P = 0.7164, Fig. 4H), IL-12p70 (F(2, 15) = 0.2097, P = 0.8132, Fig. 4I), KC/GRO (F(2, 15) = 0.01621, P = 0.9839, Fig. 4J), or INF-γ (F(2, 15) = 0.1064, P = 0.8997, Fig. 4K) in the hippocampus among groups.
PV interneuron deficit induced by combined stress was attenuated by fluoxetine treatment
To evaluate GABAergic interneuron changes in the hippocampus after combined stress, we performed immunostaining by antibodies raised against PV or SST, two major subgroups of GABAergic interneurons. As shown in Fig. 5, the intensity of PV was significantly decreased in the CA1 and CA3 regions of the hippocampus in LS group compared with control group, which were reversed by fluoxetine treatment (CA1: F(2, 9) = 7.65, P = 0.0115; CA3: F(2, 9) = 7.252, P = 0.0133). There was no difference in PV intensity of DG among groups (F(2, 9) = 0.271, P = 0.7686). Surprisingly, we found combined stress did not affect SST (CA1: t = 0.1253, P = 0.9044; CA3: t = 0.3095, P = 0.7674; DG: t = 0.1282, P = 0.9022, Fig. 6) expression in all regions of the hippocampus. These results suggested this combined stress protocol selectively impaired hippocampal PV interneurons.
Altered hippocampal neural oscillations induced by combined stress were reversed by fluoxetine treatment
To further evaluate the causal role of altered oscillatory activities in the symptoms of PICS, we recorded LFP during novel object exploration test. Power spectral analysis showed that combined stress induced significantly decreased theta and gamma power when compared with control group. However, fluoxetine treatment reversed these deficits (theta: F(2,15) = 9.693, P = 0.002; alpha: F(2,15) = 1.415, P = 0.2735; beta: (2,15) = 1.45, P = 0.2656; gamma power: F(2,15) = 6.607, P = 0.0088, Fig. 7D). In addition, linear regression analysis showed that theta or gamma oscillation was positively correlated with time spent with novel object (theta: r = 0.6921, P = 0.0015; gamma: r = 0.7242, P = 0.001, Fig. 7E-F). These data suggested that deficits in theta and gamma play an important role in cognition impairment.
Abnormal behavioral outcomes induced by combined stress were reversed by fluoxetine treatment
The open field test was performed to investigate locomotor activity and anxiety-like behavior. Although combined stress did not affect time spent in the center of the open arena (F(2,33) = 1.988, P = 0.1531, Fig. 8B), it significantly increased the distance travelled as compared with the control group. This increase was prevented by fluoxetine treatment (F(2,33) = 17.32, P < 0.0001, Fig. 8C). Next, mice were tested in the spontaneous alternation Y-maze paradigm that assesses spatial working memory. The mice in LS group displayed significantly decreased spontaneous alteration than that in control group, which was reversed by fluoxetine treatment (F(2,33) = 8.044, P = 0.0014, Fig. 8D). In the novel object recognition test, combined stress significantly decreased their exploration time with novel object (F(2,33) = 10.35, P = 0.0003, Fig. 8E) and novel object recognition ratio (F(2,33) = 5.674, P = 0.0076, Fig. 8F) compared with control group, while the decreased exploration time with novel object in LS group was prevented by fluoxetine treatment. In the sucrose preference test, mice showed significantly decreased preference for sucrose than controls, which was prevented by fluoxetine treatment (F(2,33) = 5.94, P = 0.0063, Fig. 8G).