Male Sprague-Dawley rats, weighing 200-250g and aged 2-3 months, were obtained from the Laboratory Animal Center of Chongqing Medical University. All rats were housed at standardized laboratory conditions (temperature of 22 ± 2°C, humidity of 62% ± 3% and 12/12 h light-dark cycle). All experiment protocols were approved by the Ethical Committee of the First Affiliated Hospital of Chongqing Medical University and were performed in accordance with the National Institutes of Heathy Guild for the Care and Use of Laboratory Animals.

All the procedures were conducted as previously published method, with minor modification (20). Rats were housed individually in cages and randomized to two stressors per day for 28 days: food deprivation for 24 h, water deprivation for 24 h, tailing pinching for 1 min, continuous lighting for 24 h, 4°C cold water swim for 5 min, 45°C hot water swim for 5 min, shaking for 20 min, damp sawdust for 24 h, cage tilting to 45°C from horizontal for 24h. Anhedonia is defined as one of the core symptoms of depression and can be detected by sucrose preference test As described in previous reports (21, 22), rats with a sucrose preference percentage (SPP) <65% were identified as rats with depression-like behavior rats and were screened for the following experiments.

This test was conducted as previously described (23). Briefly, all rats were required to adapt to sucrose consumption prior to the formal experiment. After 23 h of water and food deprivation, rats were provided with two identical bottles (one with 1% sucrose solution and one containing water) to drink freely for 1 h, swapping the positions of the two bottles at half the test time. The sucrose preference percentage was calculated as the formula: SPP (%) =sucrose consumption (g)/[water consumption (g) +sucrose consumption (g)] × 100%.

Morris water maze is widely used to evaluate spatial learning and memory functions in rats. In our experiment, this test was conducted the day after the completion of ECS or sham ECS treatment. In brief, a circle pool with a submerge platform was artificially divided into four quadrants. Rats were placed gentle from four different quadrants into the water to find the platform. The time to find the platform was calculated and defined as the escape latency If the rats could not find the platform within 60 s, they were guided to platform and the time was recorded as 60 s. The experiment lasts for 5 consecutive days. On the sixth day, the platform was removed and rats were placed from four different quadrants into the water and swam freely for 60 seconds and the time spent exploring the space was recorded and defined as the time spent swimming in the platform quadrant. In addition, the swimming speed of the rats was analyzed to exclude those with motor dysfunction.

All the depressive rats were randomly divided into four groups: depression+sham ECS group (group Sham), depression+sham ECS+ ZD7288 (group Sham+ZD7288), depression+ECS group (group ECS), depression+ECS+ZD7288 (group ECS+ZD7288). Rats in group Sham received sham ECS and rats in group ECS received ECS. Previous studies reported that lateral ventricle injection of 5μg/kg ZD7288 does not affect locomotor activity (24, 25), so rats in group ECS+ZD7288 received 5μg/kg ZD7288 injection through lateral ventricle catheter, and then subjected to ECS 15 min later. Rats in group Sham+ZD7288 received a 5μg/kg ZD7288 injection through a lateral ventricle catheter, and then subjected to sham ECS 15 min later. ECS was performed with bilateral ear clip electrodes through a Niviqure ECS system (Nivique Meditech, Bangalore, India) with the following parameters: bidirectional square wave pulses, 0.8 A in amplitude, 1.5 ms in width, 125 Hz in frequency, 0.8 s in duration, and 120 mc in charge. Sham ECS was conducted as the same procedure with ECS, but without currents. The sham ECS and ECS treatments were conducted once a day for 7 days. These parameters and number of treatment days were determined on previous studies by our research group and others from the literature (26, 27).

Due to the impermeability of ZD7288 to the blood-brain barrier, lateral ventricular injection was adopted in this experiment. Rats were anesthetized with 2% pentobarbital, then the skull was exposed and immobilized in a stereotaxic instrument. Access to lateral ventricular was established with a drill according to coordinates as previously described: AP -1.2mm, ML +1.8mm, DV -4.5mm (28). A sterile cannula was fixed in the position with dental cement and obstructed with a stainless lock. After the surgery, the rats were kept in separate cages and gentamicin was used to prevent infection.

After anesthesia with pentobarbital sodium, the brains of the rats were removed. Hippocampal slices of 400 μm were cut with a vibrating slicer (NVSLM-1, WPI, USA) in a cutting solution at 0°C-4°C under perfusion with a gas mixture of 95% O₂ and 5% CO₂. The solution was formulated as 3 KCl, 1.25 NaH₂PO₄, 26 NaHCO₃, 0.4 vitamin C, 2 sodium pyruvate, 2 sodium lactate, 10 glucose, 220 sucrose, 2 MgCl₂, 0.1 CaCl₂, 4 MgSO₄ (in mM). The slices were transferred into a chamber and incubated with oxygenated recording solution at 34°C for 60 min, then the temperature was adjusted to 24°C kept for 60 min. The recording solution was comprised of 124 NaCl, 3 KCl, 1.25 NaH₂PO₄, 26 NaHCO₃, 0.4 vitamin C, 2 sodium pyruvate, 2 sodium lactate, 10 glucose, 2 CaCl₂, 1.2 MgSO₄ (in mM).

After incubation, the sections were fixed in the chamber with artificial nylon nets mesh and filled with oxygenated recording fluid. Stimulating electrode was placed in the stratum radiatum of the CA3 region and recording electrode (a glass micropipette with a resistance 2-3 MΩ) with filtrated recording solution was placed in the stratum radiatum of CA1 region. The stimulus intensity was set to an intensity that elicited half of maximum response. Firstly, baseline field excitatory postsynaptic potentials (fEPSPs) were recorded for 30 min, then the protocol of the same number pulses (400 pulses) with different frequencies was conducted to explore the LTD/LTP threshold crossover point, the fEPSP of post-stimulation at different frequencies were recorded for 60 min. To assess the magnitude of synaptic transmission, the mean value for the slope of fEPSPs recorded at 20-40 min after stimulation was calculated and expressed as a percentage of the mean value of the initial baseline slope of fEPSPs. The point was defined as the stimulus intensity that evoked a change in synaptic depression to potentiation. To reduce sacrifice in rats, the stimulation frequencies of the crossover point were set according to our previous report (12), and the whole frequency-response curve was not tracked in this experiment.

For the whole-cell recording, the procedure for section preparation was similar to that for field potential recordings, except for the formula of the artificial cerebrospinal fluid (ACSF). Sections were cut in ice-cold NMDG ACSF bubbled with the same O₂/CO₂ gas mixture in a solution formulated as 93 NMDG, 2.5 KCl, 1.2 NaH₂PO₄, 30 NaHCO₃, 20 HEPES, 25 glucose, 5 sodium ascorbate, 2 thiourea, 3 sodium pyruvate, 12 NAC, 10 MgSO_4, 0.5 CaCl₂ (in mM), and the PH adjusted to 7.3-7.4 with HCl. Sections were then incubated for 60 min at 34°C in an oxygenated modified HEPES ACSF with a culture solution consisting of 92 NaCl, 2.5 KCl, 1.2 NaH₂PO₄, 30 NaHCO₃, 20 HEPES, 25 glucose, 5 sodium ascorbate, 2 thiourea, 3 sodium pyruvate, 12 NAC, 10 MgSO_4, 0.5 CaCl₂ (in mM), and the PH was set to 7.3-7.4 by NaOH.

The slices were perfused continuously in the recording chamber with oxygenated ACSF containing (in mM): 124 NaCl, 2.5 KCl, 1.2 NaH₂PO₄, 24 NaHCO₃, 5 HEPES, 12.5 glucose, 2 MgSO_4, 2 CaCl₂, and the PH maintained at 7.3-7.4 with NaOH or HCl as necessary. Whole-cell patch-clamp recordings were made from CA1 pyramidal neurons by infrared visual video with a ×40 water immersion objective. The electrodes were made with a resistance of 4-6 MΩ and filled with pipette solution containing (in mM): 120 K-gluconate, 20 KCl, 10 HEPES, 0.5 EGTA, 2 MgCl₂, 2 Na₂ATP, and the PH was set to 7.3-7.4 by KOH. GΩ resistance sealing was formed between the neuron and pipette, and then the whole-cell recording was achieved by an impulsive suction. The series resistance was monitored during the recording and cells with less than 20 MΩ and in which the resistance varied by less than 20% were included. Spontaneous action potentials (APs) were recorded under current-clamp conditions in the “I=0” model and AP frequencies with a period of 20 s was calculated. Evoked APs were also examined in this experiment, and spike activity was recorded for depolarizing current (200 pA, 650 ms). Similarly, the frequencies of evoked APs were compared. It is well accepted that neuronal excitability is influenced by the active neuronal membrane properties, which is determined by changes in voltage-gated ion channels (29). And AP waveform parameters, such as AP-half width and AP peak, AP time to peak and after hyperpolarization potential (AHP) could reflect the changes of voltage-gated ion channels and neuronal excitability in the neurons. Thus, all the parameters were examined and compared in this experiment. In voltage-clamp condition, I _h current was activated by a series of voltage steps from -120 mV to -60 mV, with steps of 10 mV (1 s duration) and a holding potential of -50 mV. Instantaneous I _h current was identified as the activated current following each test potential immediately, and steady-state I _h current was identified as the current at the end of the potential. Amplitude of instantaneous and steady-state I _h current in response to -120 mV and -90 mV potentials were measured. For all patch clamp recordings, data were recorded and analyzed with Multiclamp 700B amplififier, Digidata 1400 transverter and Pclamp 9.2 software.

All the data were expressed as mean ± SD and analyzed with Graphpad prism software (v.9.1.10). All data, except for escape latency, were analyzed by a two-way ANOVA with ECS and ZD7288 as independent variables. In the experiment of escape latency, time was regarded as another independent variable, so a three-way ANOVA was used to calculate the difference in escape latency and swimming speed between groups. Post-hoc Tukey’s test was used for multiple comparisons. P<0.05 was considered to be statistically significant.

The experiment schedule was exhibited in the Supplementary Figure 1 . There were six rats in each group for behavioral testing. The analysis results of SPP are shown in Figure 1A . Significant results were reported in the analysis of the main effect of ECS (F=60.06, P<0.0001) and ZD7288 (F=12.27, P=0.0022). Furthermore, there was a significant interaction effect between ECS and ZD7288 (F=12.27, P=0.0022). For multiple comparison, the SPP in the ECS, ECS+ZD7288 and Sham+ECS groups was significantly higher than that of the Sham group (P<0.0001, P<0.0001, P=0.0005, respectively). In contrast, the SPP in the Sham+ZD7288 group was lower than that in the ECS and ECS+ZD7288 groups (P=0.0415, P=0.0415, respectively). However, there was no difference between group the ECS and ECS+ZD7288 groups in the comparison of SPP (P>0.9999). Morris water maze test was applied to examine spatial learning and memory in rats in this experiment. Swimming speed was not affected by ECS treatment or ZD7288 injection, the main effect of time (F=0.2858, P=0.8864), ZD7288 (F=0.5135, P=0.4819), and ECS (F=0.1033, P=0.7513) were not significant, and there was no significant interaction effect between those three factors. And there was no difference in swimming speed between the groups (P>0.9999)( Figure 1B ). After two-day acclimation, the results from 3^rd to 5^th days were compared and a three-way ANOVA was tested. The main effect of time (F=766.2, P<0.0001), ZD7288 (F=24.45, P<0.0001) and ECS (F=155.6, P<0.0001) were all significant. The interaction effect of time and ECS (F=5.012, P=0.0012), ZD7288 and ECS (F=11.57, P=0.0028) was significant. However, the interaction effect of time and ZD7288 (F=0.1318, P=0.9703), time, ZD7288 and ECS (F=0.1176, P=0.9759) was not significant. In the 3^rd day, rats receiving ECS treatment (group ECS and ECS+ZD7288) revealed longer time to find the platform compared to group Sham (P<0.0001, P=0.0224, respectively), additionally, the time in group ECS+ZD7288 was shorter than that in group ECS (P=0.0430). However, no difference was found between the Sham and Sham+ZD7288 groups in terms of escape latency (P>0.9999). A similar trend was found in the results on days 4 and 5 ( Figure 1D ). In the experiment of space exploration, the main effect of ECS (F=66.26, P<0.0001) and ZD7288 (F=12.06, P=0.0024) were significant. And positive results were also found in the interaction effect of ECS and ZD7288 (F=4.929, P=0.0381). As shown in Figure 1C , rats in group ECS spent the shortest time swimming in the platform quadrant in the four groups (P<0.0001, P=0.0034, P<0.0001, respectively), while similar time was found between in group Sham and Sham+ZD7288 (P=0.8123). Additionally, group Sham+ZD7288 shown longer time than group ECS+ZD7288 (P=0.0024).

In this experiment of field potential recording, hippocampal slices were counted and more than 8 slices were analyzed in each group. As shown in Figures 2A–C , group Sham shown synaptic depression at 10 Hz (normalized fEPSP slope, 78.7 ± 3.3%, n=8) and synaptic enhancement at 40 Hz (normalized fEPSP slope, 122.5 ± 5.4%, n=8), whereas stimulation at 20 Hz elicited neither synaptic depression nor enhancement (normalized fEPSP slope, 98.5 ± 4.3%, n=8). Results in group ECS revealed that the threshold was between 50 Hz and 80 Hz because of synaptic depression at 50 Hz (normalized fEPSP slope, 87.7 ± 5.3%, n=8) and a lower degree of potentiation at 80 Hz (normalized fEPSP slope, 116.0 ± 5.4%, n=8) ( Figures 2D, E ). With reference to group ECS, group ECS+ZD7288 exhibited lower threshold with synaptic depression at 40 Hz (normalized fEPSP slope, 83.3 ± 5.9%, n=11) and synaptic enhancement at 50 Hz (normalized fEPSP slope, 123.9 ± 5.9%, n=9) ( Figures 2F, G ). However, no effect of ZD7288 on threshold was found in depressed rats without ECS, with synaptic depression and enhancement found at 10 Hz and 40 Hz (normalized fEPSP slope, 76.3 ± 3.8%, n=10, 120.8 ± 6.1%, n=11), and no depression or enhancement was showed at 20 Hz (normalized fEPSP slope, 97.0 ± 8.0%, n=10) ( Figures 2H–J ). The results obtained with the range of different frequencies were shown in Figure 2K . All the results suggested that the LTD/LTP threshold was around at 20 Hz in group Sham and Sham+ZD7288, 50-80 Hz in group Sham+ZD7288 and 40-50 Hz in group ECS+ZD7288, respectively.

Hippocampal CA1 pyramidal neurons were counted in the experiment of whole-cell recording. Difference in the electrophysiological properties of CA1 pyramidal neurons were observed. For membrane resistance, the main effect of ECS (F=168.1, P<0.0001), ZD7288 (F=40.44, P<0.0001) and the interaction effect (F=6.163 P=0.0158)were all significant. Membrane resistance significantly decreased in group ECS (145.58 ± 12.70 MΩ, n=15) compared to group Sham (208.72 ± 10.77 MΩ, n=16, P<0.0001). The resistance increased in group ECS+ZD7288 (181.71 ± 20.52 MΩ, n=18, P<0.0001) compared to group ECS. In addition, the membrane resistance in group Sham+ZD7288 (224.56 ± 19.12 MΩ, n=17, P =0.0464) was higher compare to group Sham. However, no significant main effect of ECS (F=0.0043, P=9474), ZD7288 (F=0.9368, P=0.3369) and the interaction effect (F=3.154, P=0.0807) were exhibited in reference to resting membrane potential, and no significant difference in the post hoc multiple comparisons ( Figures 3A, B ). For spontaneous firing frequency, the main effect of ECS (F=308.7, P<0.0001) and ZD7288 (F=17.44, P<0.0001) was significant, and the interaction effect of ECS and ZD7288 was also significant (F=22.92, P<0.0001). As shown in Figures 4A–E , in group ECS (0.16 ± 0.04 Hz, n=15) and ECS+ZD7288 (0.34 ± 0.08 Hz, n=18), the neurons exhibited a significant decrease in the spontaneous firing frequency as compared to group Sham (0.60 ± 0.10 Hz, n=16, P<0.0001, P<0.0001, respectively). However, no significant difference was found between group Sham and Sham+ZD7288 (0.59 ± 0.07 Hz, n=17, P=0.9986). Spontaneous frequencies in group ECS+ZD7288 and Sham+ZD2788 were higher than group ECS (P<0.0001, P<0.0001, respectively). In addition, there was also a significant difference between group ECS+ZD7288 and Sham+ZD7288 (P<0.0001).

For firing frequency, the main effect of ECS was significant (F=458.3, P<0.0001), the interaction effect of these two interventions was also significant (F=17.84, P<0.0001). However, the main effect of ZD7288 was not significant (F=3.960, P=0.0510). CA1 pyramidal neurons in group ECS (4.13 ± 1.76 Hz, n=15) showed a strong decrease in firing frequency in response to depolarizing current injection as compared to group Sham (16.87 ± 2.62 Hz, n=16, P<0.0001). And ECS with ZD7288 (group ECS+ZD7288, 7.22 ± 1.55 Hz, n=18) could increase the frequency compared to group ECS (P=0.0003). However, no difference was found between group Sham and Sham+ZD7288 (15.76 ± 1.98 Hz, n=17, P=0.5314). In addition, we analyzed differences in AP waveform parameters to further reflect changes in neuronal excitability. For all the parameters, the main effect of ECS and ZD7288, also the interaction effect of these two interventions were all significant. Compared to group Sham, APs in group ECS exhibited a significant decrease in AP-half width (4.27 ± 0.59 ms, n=16 vs. 1.89 ± 0.27 ms, n=15, P<0.0001) and AP peak (37.22 ± 5.34 mV, n=16 vs. 27.76 ± 3.32 mV, n=15, P<0.0001), an increase in AP time to peak (2.55 ± 0.45 ms, n=16 vs. 5.15 ± 0.43 ms, n=15, P<0.0001) and AHP amplitude (-3.07 ± 0.57 mV, n=16 vs. 5.95 ± 0.91 mV, n=15, P<0.0001). Similar trends were found between group Sham and ECS+ZD7288 in the comparison of AP-half width (3.10 ± 0.47 ms, n=18, P<0.0001), AP peak (32.09 ± 4.92 mV, n=18, P =0.0074), AP time to peak (3.77 ± 0.64 ms, n=18, P<0.0001) and AHP amplitude (-4.52 ± 0.61 mV, n=18, P<0.0001). Furthermore, group ECS+ZD7288 exhibited a longer AP-half width (P<0.0001), higher AP peak (P=0.0385), shorter AP time to peak (P<0.0001) and lower AHP amplitude (P<0.0001) as compared to group ECS. However, the AP-half width (4.03 ± 0.64 mV, n=17, P=0.7029), AP peak (36.85 ± 3.58 mV, n=17, P>0.9999), AP time to peak (2.49 ± 0.33 ms, n=17, P=0.9993) and AHP amplitude (-2.94 ± 0.50 mV, n=17, P=0.9954) did not show differences between group Sham and Sham+ZD7288 in the comparison ( Figures 5A–I ).

It is well known that changes in I _h currents are an important mechanism for neuronal excitability-mediated metaplasticity. At the voltage of -120 mV, in the analysis of instantaneous I _h, the main effect of ECS (F=216.9, P<0.0001), ZD7288 (F=5.706, P=0.0199), and the interaction effect (F=10.47, P=0.0019) were all significant. However, in the analysis of steady-state I _h, the interaction effect was negative (F=0.1193, P=0.7309), the main effect of ECS (F=106.6, P<0.0001) and ZD7288 (F=13.52, P=0.0005) were significant. As shown in Figures 6A–H , at the voltage of -120 mV, instantaneous and steady-state I _h current amplitude in group ECS were -1633.27 ± 112.28 pA (n=15) and -2630.22 ± 322.43 pA (n=15). These were significantly higher than those in group Sham (-1148.39 ± 69.78 pA, n=20, P<0.0001; -2156.17 ± 124.74 pA, n=20, P<0.0001). However, ZD7288 partially reversed the changes in I _h current amplitude induced by ECS (group ECS+ZD7288, -1481.42 ± 139.85 pA, n=17, P=0.0014; -2451.50 ± 92.21 pA, n=17, P=0.0036). And there was no difference between group Sham and Sham+ZD7288 (-1171.26 ± 116.00 pA, n=16, P=0.9265; -2008.15 ± 124.70 pA, n=16, P=0.0829).

At the voltage of -90 mV, in the analysis of instantaneous I _h, the main effect of ECS (F=89.03, P<0.0001) and the interaction effect (F=13.91, P=0.0004) were significant. However, the main effect of ZD7288 was not significant (F=1.042, P=0.3112). In the analysis of steady-state I _h, the main effect of ECS (F=102.9, P<0.0001), ZD7288 (F=18.17, P<0.0001) and their interaction effect (F=16.80, P<0.0001) were all significant. At a voltage of -90 mV, the instantaneous and steady-state I _h current amplitude were -519.20 ± 52.15 pA (n=20) and –1027.44 ± 73.34 pA (n=20) for group Sham, -709.52 ± 84.78 pA (n=15) and –1361.93 ± 111.48 pA (n=15) for group ECS, -640.85 ± 45.00 pA (n=17) and –1165.59 ± 111.63 pA (n=17) for group ECS+ZD7288, -558.35 ± 51.68 pA (n=16) and –1023.60 ± 162.42 pA (n=16) for group Sham+ZD7288. At a voltage of -90 mV, the statistical differences between these groups were similar to the comparative trend at the voltage of -120 mV.