Animals used in this study were 8 weeks old male C57BL/6 mice (weighing 18–22 g). Mice were group-housed five per cage in wire-bottomed cages at 20–25°C with 12 h light/12 h dark daily cycle (lights on from 8:00 AM to 8:00 PM), and allowed to consume food and water freely after being obtained from the Fourth Military Medical University Animal Center (Xi’an, China). Experiments were conducted during the light phase in accordance with the National Institutes of Health Guide for the Care and Use of Laboratory Animals and approved by the Animal Use and Protection Committee of the Fourth Military Medical University.

Seven days after acclimatization, mice were randomly assigned to the following three groups: Control (n = 10), CVS + saline (n = 10), and CVS + (S)-Ket (n = 11). Mice in the CVS + saline and CVS + (S)-Ket groups were subjected to the CVS protocol for 21 consecutive days and then received i.p. injections of either saline or 10 mg/kg (S)-ketamine once respectively. Twenty-four hours after the i.p. injections, the depressive-like behaviors were measured through an open field test, novelty suppressed feeding test, forced swimming test, and tail suspension test. After those behavioral tests, the mice were sacrificed, and the PFC and hippocampus tissues were isolated from the mice brain and stored in liquid nitrogen immediately for later lipidomic analysis using high-performance liquid chromatography-mass spectrometry (HPLC-MS).

The depressive-like behavior was produced by a chronic variable stress protocol reported by a previous study (Bittar et al., 2021). Briefly, mice were subjected to three different stressors repeated for 21 days. On day 1, mice were stimulated with 100 foot-shocks at 0.45 mA randomly for 1 h. On day 2, mice were suspended by their tail for a 1-h operation. On day 3, mice were restrained in a 50 ml falcon tube for 1 h. Over 21 days, mice were repeatedly subjected to these stressors once per 3 days.

(S)-ketamine (25 mg/ml, Hengrui Medicine Co., Ltd) was diluted in saline to a working solution of 1.0 mg/ml. Mice were weighed and treated with (S)-ketamine at a 10 mg/kg dose or saline vehicle controls at a dosage of 200 μl per 20 g mouse by intraperitoneal (i.p.) injections.

Behavioral experiments occurred 24 h after the i.p injection in the following order: novelty suppressed feeding test (NSFT), open field test (OFT), tail suspension test (TST), and forced swim test (FST). In order to minimize stress-related anxiety effects, mice were acclimated to the experimental room for at least 60 min prior to tests, and all experiments were conducted under dim lighting conditions, and the testing area was cleaned with 75% ethanol between trials.

All the mice were euthanized by cervical dislocation after the behavioral test. The PFC and hippocampus were isolated and dissected on ice immediately, then precisely weighed, frozen, and stored in liquid nitrogen until lipidomic analysis was performed by high-performance liquid chromatography-mass spectrometry (HPLC-MS).

Lipidome quantification and data analysis were established as the description in a previous study and technically supported by Shanghai Applied Protein Technology Co., Ltd. Lipids were extracted with methyl tert-butyl ether (MTBE) as previously described (Cajka et al., 2017; Jiang et al., 2017). Briefly, 30 mg samples were spiked with appropriate amounts of internal lipid standards which include 13 isotope mixtures of internal lipid standards, SPLASH^® LIPIDOMIX MASS SPRC STANDARD, AVANTI, 330707-1EA, and homogenized with 240 μl of methanol and 200 μl of water. Subsequently, samples were spiked with 800 μl of MTBE and ultrasonicated at 4°C for 20 min, then incubated at 25°C for 30 min. The organic components were separated from the solution by centrifuging at 10°C for 15 min at 14,000× g to the. The upper organic solvent phase was collected and evaporated under nitrogen. Finally, the solutes were stored at −80°C before use.

The ultra-HPLC separation was performed through reverse-phase chromatography by using a CSH C18 column (ACQUITY UPLC CSH C18, 1.7 μm, 2.1 × 100 mm, Waters). The column temperature was 45°C, and the flow rate was 300 μl/min. The extraction of lipid was centrifuged at 14,000 × g for 15 min after re-dissolved in 200 μl of 90% isopropanol/acetonitrile; then, 3 μl of each sample was perfused for analysis. The initial mobile phase was 30% solvent B (consists of acetonitrile–isopropanol (1:9, v/v), 0.1% formic acid, and 0.1 mM ammonium format) at a flow rate of 300 μl/min for 2 min, then linearly increased to 100% solvent B over 23 min, followed by equilibration in 5% solvent B for 10 min. The autosampler was maintained at 10°C. Multiple samples were analyzed concurrently, and signal fluctuations were detected in random order, alsoduring sample analysis, to avoid bias due to instrumentation errors. A sampling of the queue was confirmed every eighth sample using one of the quality control (QC) samples to observe the stability of the analysis and measure the reliability of the experimental data.

Next, samples were analyzed by a Q Exactive^TM plus mass spectrometer (Thermo Fisher Scientific, Waltham, USA) after being separated by ultra-HPLC. The parameters were set as following: positive-ion mode:heater temperature, 300°C; sheath gas flow rate, 45 arbitrary units (arb); auxiliary gas flow rate, 15 arb; sweep gas flow rate, 1 arb; spray voltage, 3.0 kV; capillary temperature, 350°C; S-Lens radio frequency (RF) level, 50%; and MS1 scan range, 200–1,800 m/z; negative-ion mode: heater temperature, 300°C; sheath gas flow rate, 45 arb; auxiliary gas flow rate, 15 arb; sweep gas flow rate, 1 arb; spray voltage, 2.5 kV; capillary temperature, 350°C; S-Lens RF level, 60%; and MS2 scan range, 250–1,800 m/z.

Lipid species were identified with a search engine LipidSearch system (Thermo Fisher Scientific, Walthamcity, country, USA) based on MS/MS database. Over 30 lipid classes and more than 1,500,000 ion fragments were included in this database. The mass tolerances for molecular precursors and fragment ions were set to 5 ppm. The displayed product ion threshold was set at five, and all four grades (A-D) applied in the identification (ID) quality filtering. All 71 sub-species of the lipid classes in the database were selected for identification. Adducts containing H⁺ and NH₄⁺ were chosen for positive-mode searches, and adducts containing H⁻ and CH₃COO⁻ werechosen for negative-mode searches since ammonium acetate was applied for the mobile phases.

The statistical analyses in the current study were confirmed by SPSS v.21.0 software (SPSS Inc., Chicago, IL, USA). All data of behavioral testing and the characterizations of lipid compositions were expressed as mean ± standard deviation (SD), and were evaluated by one-way analysis of variance (ANOVA) with Bonferroni post-hoc test for pairwise comparisons. The two-tailed P-value < 0.05 was considered as statistically significant. The correlations between lipid species levels and behaviors were analyzed using the Pearson correlation.

The peak recognition, lipid-peak extraction (secondary appraisal), peak alignment, and quantitative processing of raw lipidomic data were processed using LipidSearch software. After normalizing to the total peak intensity and integrating with the Pareto scaling method, the processed data were imported into SIMPCA-P 14.1 (Umetrics, Umea, Sweden) for multivariate statistical analysis, including principal component analysis, partial least squares discriminant analysis, and orthogonal partial least squares discriminant analysis. The quality of OPLS-DA was checked using a permutation test. In the same time, the variable importance in the projection (VIP) values was obtained from each lipid variable to examine the contribution of variables, and the Student’s t-test followed by the adjustment of the false discovery rate (FDR) in multiple hypothesis tests was introduced to obtain the P values of each variable. Lipids with significant differences were identified based on a combination of fold change (> 1.5 or < 0.67), Student’s t-test FDR < 0.01, and VIP > 1 in according to the methods from our previous reports (Xue et al., 2020; Zhou et al., 2022).

As illustrated in Figure 1, we first identified the effect of (S)-ketamine on depression-like behaviors. The One-way ANOVA results indicated that there were significant differences in the time spent in the center squares of the OFT (F_{2, 28} = 5.555, P < 0.01), latency to feeding in NSFT (F_{2, 28} = 4.629, P < 0.05), as well as immobility time in both TST (F_{2, 28} = 10.930, P < 0.01) and FST (F_{2, 28} = 4.751, P < 0.05) between the three groups. Post hoc comparisons further revealed that CVS markedly reduced the time spent in the central arena in the OFT, and these behavioral outcomes were ameliorated in (S)-ketamine-treated group [CVS + (S)-Ket vs. CVS + saline, P < 0.05]. Additionally, the CVS + saline group showed a significant increase in latency to feeding as well as immobility time in both TST and FST when compared with the Control group (P < 0.01). Whereas, the increased latency to food, the increased immobility time in FST and TST produced by the CVS procedure were reversed by (S)-ketamine administration [CVS + (S)-Ket vs. CVS + saline, P < 0.05].

Based on the criterion from the International Lipid Classification and Nomenclature Committee, lipid compounds are classified into eight types. Moreover, each class type can be split into different subtypes with polarity as the head of the class (lipid class). Based on the different saturabilities or lengths of the carbon chain, each subgroup was classified into different molecular species (lipid species) to achieve a three-level classification of lipid compounds. As shown in Supplementary Figure 1, we finally identified 1,006 lipid species and 42 lipid classes in the samples of each group.

As shown in Figure 2 and Supplementary Table 1, we identified significant intergroup differences in total lipid levels and the concentrations of 29 lipid classes, such as phosphatidylinositol phosphate (PIP), phosphatidylethanolamine (PE), and gangliosides (GM2). Post hoc analysis revealed that mice in the CVS group exhibited significantly elevated levels of PIP, phosphatidylinositol (PI), phosphatidylethanolamine (PE), phosphatidylserine (PS), lysophosphatidylcholine (LPC), lysophosphatidylethanolamine (LPE) and Ceramides (Cer), but reduced levels of cardiolipin (CL), lysophosphatidylinositol (LPI), stigmasterol ester (StE), ceramides phosphate (CerP), sphingomyelin (SM) sphingomyelin phytosphingosine (phSM), gangliosides (GM1, GM3, GM2, GD3), simple glc series (CerG2NAc1), acyl carnitines (AcCa), monogalactosyldiacylglycerol (MGDG), sulfoquinovosyldiacylglycerol (SQDG), digalactosyldiacylglycerol (DGDG), sulfoquinovosylmonoacylglycerol (SQMG), monogalactosylmonoacylglycerol (MGMG), and coenzyme (Co) (CVS + saline vs. Control, P < 0.05, respectively). Esketamine treatment significantly reduced the levels of PIP, PI, PE, PS, LPC, and LPE, and up-regulated the levels of GM2, AcCa, SQMG, and MGMG [CVS + (S)-Ket vs. CVS + saline, P < 0.05]. However, the changes in CL, LPI, CerP, SM, Cer, phSM, GM1, GM3, CerG2GNAc1, GD3, MGDG, SQDG, DGDG, and Co produced by CVS in the hippocampus were not normalized by the administration of (S)-ketamine.

Correlation analysis indicated that the time spent in the center arena in the OFT was positively in relation tolevels of phosphatidylinositol 3,4,5-trisphosphate (PIP3), GM2, and MGMG but negatively correlated with levels of PIP, PS, LPC, LPS, Cer, and (O-acyl)-1-hydroxy fatty acid (OAHFA). The immobility time in the TST was positively correlated with levels of PIP, PE, PS, LPC, LPE, and Cer but negatively correlated with levels of CerP, phSM, GM2, and MGMG. Moreover, the latency time to feeding in the NSFT was positively correlated with levels of PIP, LPC, and Cer but negatively correlated with levels of PIP3, cholesterol Ester (ChE), CerP, phSM, GM2, MG, SQMG, and MGMG (Figure 3A and Supplementary Table 2).

As shown in Figure 4 and Supplementary Table 1, no statistical intergroup differences were found in total lipid levels in the prefrontal cortex (Figure 4A). However, significant differences were observed in concentrations of 23 lipids between the three groups, such as LPI, SM, and phSM in this structure. The results of post-hoc comparisons showed that mice in the CVS group exhibited significantly increased levels of PIP, PE, PI, and OAHFA, but reduced levels of LPI, PA, ChE, zymosterol (ZyE), stigmasterol ester (StE), CerP, SM, ST, phSM, GD2, CerG2GNAc1, GM3, GD3, AcCa, MGDG, SQDG, DGDG, SQMG, and MGMG CVS + saline vs. Control, P < 0.05). (S)-ketamine administration effectively decreased the levels of PI and increased the levels of LPI, ChE, ZyE, StE, SM, phSM, CerG2GNAc1, GM3, AcCa, and DGDG [CVS + (S)-Ket vs. CVS + saline, P < 0.05]. However, the changes in PIP, PE, PA, CerP, ST, GD2, GD3, OAHFA, MGDG, SQDG, SQMG, and MGMG produced by CVS expose in the prefrontal cortex were not normalized by the treatment of (S)-ketamine.

The results of correlation analysis showed that the time spent in the center arena in the OFT was positively in correlation with levels of LPI, phosphatidylinositol (4,5) bisphosphate (PIP2), ZyE, ChE, StE, SM, phSM, GM3, and AcCa. The immobility time of the TST was positively in correlation with levels of PI but negatively correlated with levels of LPI, ZyE, ChE, and StE. The immobility time in the TST was positively correlated with levels of PE, PI, LPC, Cer, CerG3GNAc1, and OAHFA but negatively correlated with levels of ZyE, ChE, StE, CerP, GD3, DGDG, and SQMG. Moreover, the latency time to feeding in the NSFT was negatively correlated with levels of LPI, PA, ZyE, ChE, StE, CerP, and SM (Figure 3B and Supplementary Table 3).

As illustrated in Figure 5 and Supplementary Table 9, CVS exposure significantly altered lipids’ fatty acyl chain profile in the hippocampus and PFC. In the hippocampus, levels of long-chain fatty acyls with less than 17 carbons (<17C) and 23 carbons (23C), and levels of saturated fatty acyls (Figure 5B) were increased. In contrast, levels of long-chain fatty acyls with 31 carbons (31C) were decreased in CVS + saline group (CVS + saline vs. Control, P < 0.05). (S)-ketamine administration normalized the levels of long-chain fatty acyls with less than 17 carbons and saturated fatty acyls [CVS + (S)-Ketvs. CVS + saline, P < 0.05]. Meanwhile, in the PFC, levels of long-chain fatty acyls with < 16 carbons (16C) and 23 carbons (23C) were increased, while levels of long-chain fatty acyls with 21 carbons (21C), 30 carbons (30C), and 35 carbons (35C) were decreased in CVS + saline group (CVS + saline vs. Control, P < 0.05). (S)-ketamine administration normalized the levels of long-chain fatty acyls with 30 and 35 carbons [CVS + (S)-Ket vs. CVS + saline, P < 0.05]. We did not find significate differences in chain saturation in the PFC between the three groups (Figure 5D).

Additional intergroup changes in the concentrations of lipids both in the hippocampus and PFC were found at the species level according to lipidomic profiling. Data of lipids in the hippocampus and PFC could be well distinguished between the three groups by the characteristics of the PLS-DA model (Supplementary Figures 2A,D). Differential species were determined based to the following criteria: (1) FC > 1.5 or < 0.67; and (2) P value < 0.05. Altogether, 95 lipid species were dysregulated after CVS, and 19 of them were rescued by (S)-ketamine administration in the hippocampus (Supplementary Figures 2B,C). A total of 61 lipid species were dysregulated after CVS, and five of them were normalized after the administration of (S)-ketamine in the PFC (Supplementary Figures 2E,F).

As illustrated in Figure 6 and Supplementary Table 4, the level of 91 lipids such as PC (36:4), MGDG (34:5), and AcCa (14:0) were decreased. Four lipids, including Cer (d17:1/18:0), LPC (14:0), and PE (16:0/20:4), were elevated in the hippocampus in the CVS + Saline group compared with the Control group (Figure 6A). (S)-ketamine treatment increased 44 lipids such as AcCa (14:0), PC (16:0/18:3), and SM (d42:2) and decreased Cer (d17:1/18:0) in the hippocampus in CVS-treated mice (Figure 6B). Especially, 19 of the 95 lipid species changed in the hippocampus of CVS-exposed mice, for example, Cer (d17:1/18:0), AcCa (14:0), and SM (d42:1) normalized after (S)-ketamine supplementation (see Supplementary Table 5 for details).

Furthermore, the result of correlation analysis (Figure 6E) showed that the concentrations of 14 lipids including AcCa (14:0), DG (24:1/20:0), and SM (d18:1/18:4) in the hippocampus were positively correlated with the time spent in the center squares in the OFT, but negatively correlated with immobility time in the TST. Moreover, concentrations of SQDG (31:2e) and WE (6:0/16:3) in the hippocampus were also negatively correlated with the immobility time in the FST (see Supplementary Table 6 for details).

Similar to the results in the hippocampus, the PFC analysis revealed changes in the lipid concentrations in multiple species following the CVS procedure (Figures 6C,D, and Supplementary Table 7). Generally, the levels of 38 lipids including PC (6:0/12:4), ChE (2:0), and SM (d36:2) were decreased, meanwhile, the levels of 23 other lipids, such as Cer (m44:3), LPC (24:0), and PE (11:0/10:1) were increased in the PFC of CVS + saline mice compared with Control (Figure 6C). (S)-ketamine treatment increased the levels of six lipids such as ZyE (35:6), ChE (2:0), and SM (d36:2), and decreased the levels of PI (18:0/20:3) and PE (18:2e/20:1) compared with the CVS + saline group (Figure 6D). Notably, levels of 5 of the 61 lipid molecules in the PFC changed after CVS, including ChE (30:0), SM (d36:2), and ZyE (20:5). However, these dysfunctions were rescued after (S)-ketamine treatment (as shown in Supplementary Table 5 for details).

Correlation analysis further revealed that concentrations of ChE (2:0), ChE (30:0), SM (d36:2), ZyE (20:5), and ZyE (35:6) in the PFC were positively correlated with time spent in the central zone in the OFT, but negatively correlated with immobility time in the TST. In addition, four of those lipids were also negatively correlated with immobility time in the FST (Figure 6E and Supplementary Table 8).