Potential Therapeutic Effects of NAMPT-Mediated NAD Biosynthesis in Depression In Vivo

This study aimed to investigate the potential therapeutic effects of nicotinamide phosphoribosyltransferase (NAMPT)-mediated adenine dinucleotide (NAD) biosynthesis in depression models in vivo. Namptflox/flox mice were used to evaluate the role of NAMPT in depression. NAMPT and NAD levels in the prefrontal cortex (PFC) were measured, and depression-associated behavior, cognitive function, and social interaction were evaluated. The expression levels of BDNF, pCREB, CREB, monoamine neurotransmitters, and corticosterone (CORT) were also detected in the PFC. The contents of NAMPT and NAD decreased in the PFC in Namptflox/flox mice. Namptflox/flox mice showed depression-like behaviors, cognitive function deterioration, decreased social ability, and decreased dominance. Meanwhile, there were decreased expression levels of the pCREB/CREB ratio, but not BDNF, in the PFC. Levels of DA, 5-HT, and NE were decreased, and CORT was activated in the PFC of Namptflox/flox mice. Additionally, the role of NAMPT-NAD was examined in rats treated with nicotinamide riboside (NR) after being exposed to chronic unexpected mild stress (CUMS). NR reversed the decreased NAMPT expression in the PFC and HIP, and the NAD content in the PFC, but not HIP in rats with CUMS-induced depression. NR also improved depressive- and anxiolytic-like behaviors, locomotor activity, and cognitive function. BDNF expression and the pCREB/CREB ratio were significantly increased in both the PFC and HIP after NR treatment. The activation of CORT and decreased content of DA were reversed after NR treatment in the PFC. There was no difference in the 5-HT content among groups in both the PFC and HIP. Taken together, NAD synthesis induced by NAMPT could be associated with depression-like behaviors in mice, and the elevated NAD level by NR improved depression in rats.


Introduction
Approximately 4.4% of the worldwide population suffers from depression, a prevalent mental disorder [1]. However, uncertainty persists regarding the mechanisms underlying the etiology of depression and its therapeutic targets. Clinically, most classic antidepressants target the monoamine neurotransmitter system. However, these agents exhibit side effects, have safety concerns and residual symptoms, and prompt drug tolerance [2], all factors which need to be overcome. Owing to the limited efficacy of depression treatments, it is necessary to investigate new targets and treatment strategies.
The involvement of the prefrontal cortex (PFC) in depression has been previously recognized [3]. Recent studies have begun to explain how the PFC and its circuitry contribute to the symptoms of anxiety and depression. Therefore, the PFC is a significant site for the study of depression [4].
Numerous studies have demonstrated that synaptic plasticity is impaired by changes in neurotransmission, immune system malfunction, metabolic dysfunction, and other factors that collectively cause various functional abnormalities, including a depressed mood [5][6][7]. Lower NAD levels were linked to metabolic and neurodegenerative diseases, etc. In this regard, increasing or restoring intracellular NAD concentrations through NAD precursors, including nicotinamide (NAM) or nicotinamide riboside (NR), and enhancing enzyme activity has proved to be successful [8]. NR, a precursor of NAD, is a micronutrient that promotes energy metabolism and has neuroprotective effects. In depressed patients, energy metabolism is often disturbed in the brain, and NR is a relatively promising therapeutic agent.
Nicotinamide phosphoribosyltransferase (NAMPT) is necessary for the recycling of NAM to NAD, which is part of the salvage pathway of NAD synthesis [9]. Mammals have three NAD synthetase routes, with the salvage pathway being the most significant [10]. NR is the primary metabolite in the NAD salvage pathway whose level can also influence that of NAD, and thus the corresponding signaling pathway. They are all capable of directly influencing NAD levels, which are essential for maintaining cell cycle, metabolism, and cellular senescence [11]. Meanwhile, NAD plays a critical role in many depression-related signaling pathways. For instance, NAD is able to suppress depression by increasing SIRT1 activity. Therefore, numerous neurodegenerative disorders may exhibit decreased NAD levels due to decreased NAMPT expression or activity [12].
However, whether and how NAMPT-mediated NAD biosynthesis affects depression in vivo remains unclear. To obtain a higher specificity and exclude other confounding factors, we chose to use genetic knockout mice, Nampt flox/flox mice, to investigate its role in behavior. Moreover, the PFC function plays an important role in the development of depression. Therefore, we selected the PFC as the site for viral injection. Meanwhile, NR, one of the NAD precursors, was employed to treat the depression model in rats with chronic unpredictable mild stress (CUMS). The therapeutic effects of NR were evaluated using depression-like behavior tests, neurotransmitters, and NAMPT-NAD expression. Hence in this study, Nampt flox/flox mice and rats with a depression model induced by CUMS were treated with NR to explore the role of NAMPT-mediated NAD biosynthesis in depression in vivo.

Animals
Under 1% pentobarbital sodium anesthesia (40 mg/kg, i.p.) adeno-associated viruses with the Cre-recombinant enzyme and green fluorescent protein (GFP) gene (Cre-GFP) were stereotactically injected into the mouse PFC (Original point: Fontanel; AP: +1.9 mm; L: −0.4 mm; R: +0.4 mm; V: 2.2 mm) using a stereoscopic positioner, as presented by Dr. WeiPing Zhang (Zhejiang University). Mice with no green fluorescence in the PFC were excluded after four weeks. Male SD rats weighed 160-180 g at the time of purchase. All animals had free access to water and food in air-conditioned room (20~26 • C, relative humidity 40~50%) on a 12-h light/dark cycle. The Animal Health, Ethics and Research of Hangzhou Medical College approved the study procedures.

Treatment Groups
The mice were assigned to three groups: wild type (Nampt wt/wt ), Nampt flox/wt (Nampt fl/wt ), and Nampt flox/flox (Nampt fl/fl ). After four weeks from Cre-GFP injection, several behavioral and other detections were conducted to evaluate changes in the mice.
The rats were divided into four groups: normal (normal), depression (model), sertraline (sertraline), and NR (NR). Normal and model rats received water devoid of NR, while rats in the NR group were given water containing 12 mM NR as needed. Gavage was used to administer sertraline (10 mg/kg). Dosing with NR or sertraline was continued for 50 days, including the day of the behavioral tests. The water bottles were changed twice a week.

Chronic Unpredictable Mild Stress (CUMS)
A previously published protocol has proven to be useful for inducing CUMS [13]. The stresses included food deprivation for 8 h, water deprivation for 8 h, inversion of the  day/night cycle, forced swimming for 3 min, a 45 • tilted cage for 8 h, soiled cage bedding  for 8 h, and an empty bottle for 8 h. Except for the normal group, each rat in the rest of the groups was exposed randomly to one modest stressor every day following the NR treatment, which lasted for 42 days. Subsequently, the rats were evaluated with a series of behavioral assays. The schedules of the experimental protocol can be seen in Figure 1.
for 50 days, including the day of the behavioral tests. The water bottles were c twice a week.

Chronic Unpredictable Mild Stress (CUMS)
A previously published protocol has proven to be useful for inducing CUM  The stresses included food deprivation for 8 h, water deprivation for 8 h, inversio  day/night cycle, forced swimming for 3 min, a 45° tilted cage for 8 h, soiled cage b  for 8 h, and an empty bottle for 8 h. Except for the normal group, each rat in the res groups was exposed randomly to one modest stressor every day following the N ment, which lasted for 42 days. Subsequently, the rats were evaluated with a s behavioral assays. The schedules of the experimental protocol can be seen in Figu   Figure 1. Schedules of the experimental protocol.

Sucrose Preference Test (SPT)
This test was developed in an earlier study evaluating anhedonia [14]. First, mals were acclimated to two water bottles. Pure water was placed in one bottle, w a 1% sucrose solution was placed in the other. The animals were initially acclim evaluated for two more days, and then tested for 3 h. The positions of the bottle switched throughout the testing period. The percentages of sucrose and total liqu sumed were calculated. The less the sucrose solution was consumed, the more sev depression-like behavior of the animal became.

Open Field Test (OFT)
Individual animals were gently positioned in the central region of a well-li area. The spontaneous activity system continually recorded and evaluated loc paths for five minutes using the VisuTrack system (Xinruan Information Technolo Ltd., Shanghai, China). The total distance and velocity of travel, as well as the tim distance spent in the central region, were documented.

Elevated Plus Maze (EPM)
A labyrinth was used to situate creatures across an open arm. Five minutes o stricted maze exploration was allowed, and the total distances traveled and the d ratios, together with the total time taken, were recorded and calculated. Tracks w orded and analyzed using a video analyzer (Ethovision XT, Noldus, Netherlands)

Novel Object Recognition Test (NORT)
Animals were placed in the empty chamber during habituation to explore fre five minutes. In T1 phase, they were placed into their home cages for five minutes,

Sucrose Preference Test (SPT)
This test was developed in an earlier study evaluating anhedonia [14]. First, the animals were acclimated to two water bottles. Pure water was placed in one bottle, whereas a 1% sucrose solution was placed in the other. The animals were initially acclimatized, evaluated for two more days, and then tested for 3 h. The positions of the bottles were switched throughout the testing period. The percentages of sucrose and total liquid consumed were calculated. The less the sucrose solution was consumed, the more severe the depression-like behavior of the animal became.

Open Field Test (OFT)
Individual animals were gently positioned in the central region of a well-lit, open area. The spontaneous activity system continually recorded and evaluated locomotor paths for five minutes using the VisuTrack system (Xinruan Information Technology Co., Ltd., Shanghai, China). The total distance and velocity of travel, as well as the time and distance spent in the central region, were documented.

Elevated Plus Maze (EPM)
A labyrinth was used to situate creatures across an open arm. Five minutes of unrestricted maze exploration was allowed, and the total distances traveled and the distance ratios, together with the total time taken, were recorded and calculated. Tracks were recorded and analyzed using a video analyzer (Ethovision XT, Noldus, Netherlands).

Novel Object Recognition Test (NORT)
Animals were placed in the empty chamber during habituation to explore freely for five minutes. In T 1 phase, they were placed into their home cages for five minutes, during which two identical objects (familiar object: cubic crude wood with 4 cm diameter) were placed in the chamber oppositely. After a 1.5-h time interval, animals were put into the chamber again for five minutes, when one of the familiar objects was replaced with a novel one (novel object: cylindrical crude wood with 4 cm diameter and height); that was the T 2 phase. Tracks were recorded, and the exploration time and exploration number were analyzed using the VisuTrack system. The computational formula was presented in a study by Ye et al. [13] to calculate the discrimination ratio (DR) and discrimination index (DI). A 1.5-cm window was used to define exploration as the distance between the animal's snout and the object in front of it.

Dominance Tube Test (DTT)
Utilizing the tube test, social dominance was evaluated [15]. A plexiglass tube (length, 30 cm; inner diameter, 3 cm) with two small acrylic boxes (10 cm 3 ) was attached to the end. The mice were trained for three days to move through the tube. In the test, two mice with equivalent body weights were positioned at the tube ends and were allowed to move into the tube and meet at the center. The "winner" of the trial was the animal that ejected the other from the tube, with the winner scoring 2 and the loser scoring 0. If there was no winner or loser, each mouse received a score of 1. The trials lasted for a maximum of 2 min.

Social Interaction Test (SIT)
A SIT was conducted in three chambers as previously described [16]. In the first phase, each mouse was placed into a chamber where there was no other mouse to adapt to the environment for 10 min. In the second phase, a familiar mouse in a cage was placed on the left chamber, and an empty cage was placed on the opposite chamber. In the third phase, an unfamiliar mouse in a cage was placed on the right chamber. Finally, the time that the mice stayed in each chamber was recorded, and the social preference index (SPI) (time stayed with the strange mice in the second phase/total time × 100) and social novelty index (SNI) (time stayed with the strange mice in the third phase/total time × 100) were calculated. The duration of time that the mice stayed in each chamber was recorded with a video camera and analyzed using the VisuTrack system.

Tail Suspension Test (TST)
To create an inescapable, oppressive environment, the tails of the mice were fixed, with their heads facing down in a wooden box (55 cm height × 15 cm width × 11.5 cm depth). The animals tried desperately to escape yet were unable to do so in this environment. The test was measured for 6 min, with the last 4 min recorded with a video camera to evaluate the immobility time, which was analyzed using the VisuTrack system.

Forced Swimming Test (FST)
Each animal was placed into a transparent glass tank (mouse: 60 cm height, 25 cm diameter; rat: 80 cm height, 40 cm diameter) with water at 25 ± 1 • C to adapt to the environment for 15 min. Immobility time was recorded when the animal stopped struggling in the water and was floating with only slight limb movements to keep its head above the water. The next day, the animals were subjected to swimming for 6 min, and the last 4 min were recorded to evaluate the immobility time, which was analyzed using the VisuTrack system.

BDNF, CREB, pCREB, and NAMPT Expression in the PFC and HIP
The PFC and HIP regions of the brain were immediately placed on ice after dissection. After sonication, total protein was extracted and quantified with a kit. Next, 60 µg of total protein was used for electrophoretic analysis for 2 h and transferred to a PVDF membrane at 100 V for 2 h under cooling conditions. pCREB/CREB (1:5000, Cell Signaling Technology), NAMPT (1:500, Abcam), and the membranes were first treated with GAPDH (1:10,000) overnight, followed by incubation with the secondary antibody conjugated to HRP (KangChen Bio-tech, Shanghai, China). Finally, the signal intensity was evaluated with Image J.

Detection of NAD, CORT, DA, 5-HT, and NE Levels
Tissue homogenates were centrifuged at 2000× g at 4 • C, and specialized ELISA kits were used to measure the contents of NAD, CORT, DA, 5-HT, and NE (Shanghai Elisa Biotech Co., Ltd., China). Optical densities were measured using a plate reader, and concentrations were calculated against standard curves.

Statistical Methods
Statistical significance was set at p < 0.05. The results are shown as the mean and SEM. Except for the effects on the NORT and DTT, differences were analyzed through a repeated-measures Bonferroni post hoc test and one-way ANOVA. The NORT was evaluated using a t-test to compare differences in DR in the NORT. The DTT was evaluated using non-parametric analysis with a Mann-Whitney test to compare the difference in winning points. (1:10,000) overnight, followed by incubation with the secondary antibody conjugated to HRP (KangChen Bio-tech, Shanghai, China). Finally, the signal intensity was evaluated with Image J.

Detection of NAD, CORT, DA, 5-HT, and NE Levels
Tissue homogenates were centrifuged at 2000× g at 4 °C, and specialized ELISA kits were used to measure the contents of NAD, CORT, DA, 5-HT, and NE (Shanghai Elisa Biotech Co., Ltd., China). Optical densities were measured using a plate reader, and concentrations were calculated against standard curves.
In Figure 4I, a dominance tube test schematic depicting two mice competing in a cylindrical tube with a 30-mm diameter is shown. The number of victories for each mouse was counted, averaged, and represented using a histogram to determine the winning points. The winning points of Nampt wt/wt mice were higher than those of Nampt flox/flox in Nampt flox/flox mice was lower than that in the T1 phase ( Figure 4H, F(1, 22) = 0.007, p = 0.027).

Levels of NAMPT and NAD in PFC and HIP with NR Treatment in CUMS-induced Depression Rats
Western blot analysis revealed that NAMPT expression in the PFC ( Figure 6A, Figure 5C, F(3, 32) = 104.04, p = 0.000) and HIP ( Figure 6B, Figure 5D, F(3, 32) = 65.649, p = 0.000) was significantly decreased after CUMS compared to that in normal animals. NR treatment reversed the CUMS-induced decrease in NAMPT expression in the PFC ( Figure 6A, Figure 5C, p = 0.000) and HIP ( Figure 6B, Figure 5D, p = 0.000) in animals, especially in the PFC. Sertraline also increased NAMPT expression in the PFC ( Figure 6A, Figure 5C, p = 0.000) but decreased NAMPT expression in the HIP group ( Figure 6B, Figure 5D, p = 0.005).
NAD decreased to 43.59% ( Figure 5E, F(3, 20) = 16.669, p = 0.000) in the PFC of rats with CUMS-induced depression. NR ( Figure 6E, p = 0.006) and sertraline ( Figure 6E, p = 0.004) treatment increased the NAD content in the PFC. The HIP NAD content did not differ between the different groups ( Figure 6F). and HIP ( Figure 6B, 5D, p = 0.000) in animals, especially in the PFC. Sertraline also increased NAMPT expression in the PFC ( Figure 6A, 5C, p = 0.000) but decreased NAMPT expression in the HIP group ( Figure 6B, 5D, p = 0.005).  Figure 6E, p = 0.006) and sertraline ( Figure 6E, p = 0.004) treatment increased the NAD content in the PFC. The HIP NAD content did not differ between the different groups ( Figure 6F).

Amelioration of Depression-and Anxiety-Associated Behavior with NR Treatment in CUMS-Induced Depression Rats
The sucrose preference ratio decreased by 15.27% in the model relative to that in the normal rats ( Figure 7A, F(2, 28) = 2.826, p = 0.040). The sertraline and NR treatments reversed the sucrose preference ratio, reaching 80.07% ( Figure 7A, p = 0.009) and 80.60% ( Figure 7A, p = 0.006), respectively. In the FST, relative to the normal rats, the time spent immobile was longer in the CUMS group ( Figure 7B, F(2, 28) = 5.535, p = 0.018). Treatment with sertraline ( Figure 7B, p = 0.022) and NR ( Figure 7B, p = 0.007) reversed the increase in immobility time after CUMS.

Amelioration of Depression-and Anxiety-Associated Behavior with NR Treatment in CUMS-Induced Depression Rats
The sucrose preference ratio decreased by 15.27% in the model relative to that in the normal rats ( Figure 7A, F(2, 28) = 2.826, p = 0.040). The sertraline and NR treatments reversed the sucrose preference ratio, reaching 80.07% ( Figure 7A, p = 0.009) and 80.60% ( Figure 7A, p = 0.006), respectively. In the FST, relative to the normal rats, the time spent immobile was longer in the CUMS group ( Figure 7B, F(2, 28) = 5.535, p = 0.018). Treatment with sertraline ( Figure 7B, p = 0.022) and NR ( Figure 7B, p = 0.007) reversed the increase in immobility time after CUMS.

Improvement of Locomotor Activity and Cognitive Function with NR Treatment in CUMS-Induced Depression Rats
In the OFT, the total distance decreased ( Figure 8B, F(3, 28) = 7.559, p = 0.030), whereas both the time and distance ratios in the central region were extended ( Figure 8D, F(3, 28)=7.016, p = 0.002; Figure 8E, F(3, 28) = 8.935, p = 0.005) after CUMS. NR treatment increased the total distance relative to the CUMS model animals ( Figure 8B, p = 0.000). The total distance was greater than that in the normal control group after NR treatment ( Figure 8B, p = 0.035). The NR and sertraline treatments reversed the time and distance ratios in the central region ( Figure 8D, p = 0.005; Figure 8E, p = 0.004). However, there was no difference in the distance in the central region after NR treatment ( Figure 8C, F(3, 28) = 4.584, p = 0.125), and this distance decreased with sertraline treatment ( Figure 8C, p = 0.001).

Improvement of Locomotor Activity and Cognitive Function with NR Treatment in CUMS-Induced Depression Rats
In the OFT, the total distance decreased ( Figure 8B, F(3, 28) = 7.559, p = 0.030), whereas both the time and distance ratios in the central region were extended ( Figure 8D, F(3, 28)=7.016, p = 0.002; Figure 8E, F(3, 28) = 8.935, p = 0.005) after CUMS. NR treatment increased the total distance relative to the CUMS model animals ( Figure 8B, p = 0.000). The total distance was greater than that in the normal control group after NR treatment ( Figure  8B, p = 0.035). The NR and sertraline treatments reversed the time and distance ratios in the central region ( Figure 8D, p = 0.005; Figure 8E, p = 0.004). However, there was no difference in the distance in the central region after NR treatment ( Figure 8C Figure 8G,H were analyzed using t-tests. * p < 0.05 vs. T1 in DR ( Figure 8G) and in DI ( Figure 8H).
In the T1 phase of the NORT, there were two objects with identical shapes. The time spent on each object was equal, which was manifested through a similar DR value ( Figure  8F). In the T2 phase, both DI and DR were increased in the normal group ( Figure 8G Figure 8G,H were analyzed using t-tests. * p < 0.05 vs. T 1 in DR ( Figure 8G) and in DI ( Figure 8H).
In the T 1 phase of the NORT, there were two objects with identical shapes. The time spent on each object was equal, which was manifested through a similar DR value ( Figure 8F). In the T 2 phase, both DI and DR were increased in the normal group ( Figure 8G Figure 9J, F(3, 20) = 0.155, p = 1.000) content between the groups in the HIP. There were no differences in 5-HT levels among the groups in rats with CUMS-induced depression ( Figure 9H,K).

Discussion
We utilized Nampt flox/flox mice and long-term treatment with NR in rats with CUMSinduced depression and found that NAMPT-mediated NAD synthesis played a pivotal role in depression. They both led to significant changes in depression-like behaviors, locomotor activity, social behaviors, cognitive function, and social dominance positions. In addition, the levels of NAMPT, NAD, BDNF, pCREB/CREB, monoamine neurotransmitters, and CORT were changed in Nampt flox/flox mice and rats with CUMS-induced depression.
Numerous researchers have focused on the PFC and hippocampus in their efforts to explore the brain function underlying depression since these regions show structural and functional alterations that may be caused by altered brain circuits and neurotransmitters [17]. We targeted the PFC, where NAMPT was inhibited in this study. It was demonstrated that approximately 40% of NAMPT expression, followed by approximately 60% of NAD content, was downregulated. The hippocampus and PFC have been investigated in relation to depression [18]. After NR treatment, the expression of NAMPT in the hippocampus and PFC, as well as NAD in the PFC, all increased, except NAD in the hippocampus, which contributed to the improvement of behavioral deterioration in depression. The different NAD levels between the PFC and hippocampus may be related to their different functions.
NAD functions as an enzyme cofactor in various cellular activities [19] and is a vital component of SIRT1 signaling. The NAD-dependent deacetylase SIRT1 has been linked to depression [20]. Recent studies [21] have shown that NAD, a SIRT1-related pathway, is crucial for controlling emotion-related behaviors. Because of the enhancing mitochondrial activity and bioproduction of NAD, it played a significant role in brain aging and neurodegenerative diseases through reducing damaged mitochondria in models that accelerate premature aging [22].
Three processes can be adopted to create NAD [23]. Mammals most often use the salvage pathway, which starts with NAM [24]. NAMPT catalyzes the first step, producing nicotinamide mononucleotides through a combination of NAM with 5-phosphoribosyl pyrophosphate (NMN). This is followed by the adenylation of NMN to generate NAD. However, NAM is expensive and demonstrates low bioavailability. The NR biosynthetic pathway is distinctly and incredibly effective in rodents and humans [25]. Knock-out of NAMPT in the PFC caused significant depression-like behaviors, locomotor deterioration, and cognitive and social impairment, which was consistent with the results in rats with CUMS-induced depression. NR treatment improved behavioral changes induced by CUMS. These findings demonstrate that NAMPT-mediated NAD synthesis responds to depression.
Thus, we prioritize three abnormalities that have proven the most effective in preclinical models [26]: anhedonia, cognitive impairment, and despair-like behavior. Because of their complexity, depression-related symptoms are challenging to evaluate through only one animal behavioral test. The FST and TST are reportedly used to evaluate depression in rodents, as evidenced by decreased or increased immobility time. These effects were induced by NAMPT knockout in the PFC and reversed by NR treatment. However, they could also be affected by general activity levels. As anhedonia is the primary symptom of depression, the SPT was used to investigate depression-like behavior in mice. The Nampt flox/flox mice showed reduced sucrose preference ratios, which was similar to rats with CUMS-induced depression. Nevertheless, no difference in liquid intake was observed between groups, which indicated that the decrease in sucrose preference ratio did not depend on the decrease in total liquid consumption. All results verified that the depression model adopted in this study was effectively developed with CUMS-induced rats and Nampt flox/flox mice. The NR changed these actions.
In addition to SPT, FST, and TST, OFT, NORT, SIT, and DTT could be used to evaluate behaviors in animals with depression, reflecting locomotor activity [27], cognitive function [13], social active ability, and social dominant position [15], respectively. Our study showed results which were consistent with those of previous reports. NR exerts protective effects against depression.
Previous studies have demonstrated that NAD content affects the level or activity of BDNF, SIRT1, AKT, and CREB, thereby affecting their biological effects. Chang et al. concluded that low NAD levels led to decreased activity-dependent BDNF expression [28]. Treatment with NMN or NAD ameliorated the degeneration of corneal nerve fibers by increasing the activation of SIRT1, CREB, and AKT. This finding is consistent with the results of our previous study. BDNF, the most important neurotropin in the brain, is a candidate target for the treatment of depression. BDNF activates various pathways including CREB, and CREB phosphorylation promotes BDNF transcription. This has been exploited by many antidepressants. Based on our results, it is speculated that NAMPT-NAD is a likely target for increasing BDNF-CREB expression in the PFC and hippocampus and exerts antidepressant effects.
Meanwhile, changes in CORT and monoamine neurotransmitters revealed that Nampt flox/flox and NR both had an impact on the activity of the HPA axis. This was consistent with the results reported by Li et al. [29]. The HPA axis is also an action target of classic clinical antidepressants.
In conclusion, NR, a precursor of NAD, may boost NAD levels and improve the downbeat mood, and the inhibition of NAMPT in the PFC can deteriorate depression-associated behavior and cognitive function in mice. These results lay the groundwork for further investigation of the underlying mechanisms to identify targets to treat depression. It also demonstrates the critical involvement of NAMPT-mediated NAD synthesis in depression.
Author Contributions: Animal model, J.W. and R.S.; behavioral test, J.W. and X.Z.; other detection, R.S., X.Z. and L.X.; data collection and analysis, J.W. and L.X.; writing-original draft preparation, J.W.; writing-review and editing, Y.Y.; project administration, Q.Z.; funding acquisition, Q.Z. and Y.Y. All the authors have read and agreed to the published version of the manuscript. All authors have contributed to the manuscript and approved the submitted version. All authors have read and agreed to the published version of the manuscript.

Data Availability Statement:
The data used to support the findings of this study have been included in this article. The raw data were deposited at the following link: https://www.jianguoyun.com/p/ DVTbJhsQioD3ChjQv9cEIAA (accessed on 11 October 2022).