To determine whether Phen and 5-HTP/CB affect body weight, we measured body weight and 24 h food intake daily. For all groups, rats received injections for seven consecutive days during the light phase between 1430 and 1600 h.

Since Hirai and Nakajima (1979) showed that the highest dose of 5-HTP (LD₅₀ 400 mg/kg) could cause kidney damage, we always administered a fixed dose of CB (75 mg/kg), 30 min before infusion of 5-HTP. Moreover, in a pilot study, we found that CB75 alone did not induce weight loss, but relative to the saline group, it prevented rats from gaining weight ( Supplementary Figure 1 ). Thus, we administrated different doses of 5-HTP/CB using 27 rats that were randomly assigned to 6 groups: Vehicle (n = 5), 5-HTP1/CB (n = 4), 5-HTP12.5/CB (n = 5), 5-HTP25/CB (n = 4), 5-HTP50/CB (n = 5), and 5-HTP100/CB (n = 4), where numbers indicate the dose of 1, 12.5, 25, 50, and 100 mg/kg of 5-HTP, respectively.

For the dose-response curve of Phen, we assigned 30 rats to 6 groups (n = 5): saline, Phen1, Phen3, Phen10, Phen30, and Phen45, where numbers indicate doses of 1, 3, 10, 30, and 45 mg/kg, respectively. In all experiments, rats were given in their homecages 100 g allotment of standard rat chow per day (Purina, Mexico) and ad libitum tap water.

To evaluate if Phen + 5-HTP/CB combination induces greater weight loss than each drug alone, we combined several doses of Phen (hereafter Phen10, Phen15, and Phen20, respectively) with a fixed dose of 5-HTP/CB (31 mg/kg). A total of 63 rats were randomly assigned to eight groups: vehicle (n = 8), 5-HTP/CB (n = 8), Phen10 (n = 5), Phen15 (n = 8), Phen20 (n = 8), Phen10 + 5-HTP/CB (n = 5), Phen15 + 5-HTP/CB (n = 11), and Phen20 + 5-HTP/CB (n = 10). As noted, we always administered a pretreatment injection of CB 30 min before 5-HTP, followed by Phen. Right after the last injection, each animal was placed in an open field arena, for 90 min in order to measure locomotion activity.

For behavioral experiments, locomotor activity was measured in an open field arena (40 cm length x 40 cm width x 40 cm height) coupled with a camera (in top view position). The animal’s position in x and y coordinates was tracked using Ethovision XT10 (Noldus Information Technology, Netherlands). One single video could simultaneously track up to four open fields. The forward locomotion was tracked using the rat’s center mass method and plotted as total distance traveled (cm) during 90 min from the onset of injection. One video was lost on the 3^rd day of treatment, and thus, data from four animals were not included in this analysis (one rat for Phen20 and 5-HTP/CB; and two rats for Phen20 + 5-HTP/CB groups).

The stereotypy, in the form of head weavings, was hand-scored using the Manual Scoring Setting on the Ethovision XT10 software. We focused on head weavings (obvious lateral swaying movement of the head) since this is the most prominent stereotypy induced by Phen (Kalyanasundar et al., 2015). Stereotypy was measured from a 5 min video, around ∼1 h after onset of Phen or 5-HTP/CB injection. This is because Phen stimulates its maximum psychomotor effects around this time (Kalyanasundar et al., 2015). Four behavioral states were measured: head weaving stereotypy, moving, quiet awake, and sleep. In stereotypy, while immobile animals exhibit head weavings. We acknowledge that head weavings could occur during other physiological behaviors such as walking, rearing, and exploration. However, head weavings during these behaviors were not counted as stereotypy. In moving, the animal was moving in the arena or rearing. In quiet awake state, the animal was immobile with their eyes open but without head weavings. While sleeping, the animals were lying immobile, with their eyes closed and without head weaving. The results were displayed as the percentage of the accumulative time spent in each behavioral state.

Electrophysiological experiments were performed in an operant behavioral box (31 cm x 24 cm x 21 cm Med Associates) enclosed in a ventilated and sound-attenuating chamber. Recordings took place at 1100 h daily, and they were coupled to a video camera (in top view position). Recordings were performed using a multichannel acquisition processor (Plexon, Dallas, TX). Voltage signals were sampled at 40 kHz and digitalized at 12 bits resolution, and action potentials were band-passed filter (154 Hz–8.8 kHz). Action potentials with a signal-to-noise ratio larger than 3:1 were analyzed and identified online by mean of voltage-time threshold windows and a three-principal component contour template algorithm (Gutierrez et al., 2010). Spikes were sorted using Off-line Sorter software (Plexon inc). During multichannel recordings, the position of the rat’s center of mass was tracked offline using Ethovision software (Noldus Information Technology, Netherlands). We only included in the analysis videos in which locomotion could be decoded. We note that, during the recording sessions, the stereotypy behavior could not be measured since the cable limited visibility of the head.

Modulation of NAcSh during the injection of Phen, or 5-HTP/CB, or Phen + 5-HTP/CB. We used 10 naïve rats to measure NAcSh neuronal activity [Phen (n = 3), 5-HTP/CB (n = 3), and Phen + 5-HTP/CB (n = 4)]. Each recording session lasted 3 h, and it was divided into four epochs: Baseline (period without drug infusion, BL: 0–59 min), Saline (Sal: 60–89 min), Carbidopa (CB: 90–119 min; when 5-HTP was infused), or Saline (90–119 min; when Phen alone was injected), and Phen followed by infusion of 5-HTP (120–180 min). Before each recording session, the body weight and 24 h food intake were measured during seven consecutive days. We decided to use the ED₅₀ dose of Phen (15 mg/kg) and ED₄₅ for 5-HTP (31 mg/kg). Phen doses were chosen because they are the most commonly used (Baumann et al., 2000; Roth et al., 2008; Kalyanasundar et al., 2015), whereas the selected 5-HTP dose is known to reverse psychomotor effects induced by d-amphetamine (Baumann et al., 2011).

Modulation of NAcSh neurons, in the same animal, during the injection of 5-HTP followed by Phen. To further characterize how 5-HTP and Phen modulate the same NAcSh neuron activity, we used five additional male rats implanted with an electrode array targeting this brain region, each session lasted 3 h, and each drug was infused following the next order: BL (0–29 min), Saline (30–59 min), CB (60–89 min), 5-HTP (90–134 min), and then Phen (135–180 min). Since Phen evoked the largest NAcSh modulation, it was administered at the end.

Histology. Rats were injected with an overdose of sodium pentobarbital (150 mg/kg) and perfused with PBS intracardially, followed by paraformaldehyde at 4%. The brain was removed and placed in a 10% sucrose solution for 24 h, followed by sequential increases in sucrose concentration until reaching 30% wt./v in 72 h. The brain was sliced (50 µm) and stained with cresyl violet to establish the location of the electrodes’ tip.

Behavioral analysis. Data are mean ± sem. Statistical differences between groups were analyzed using repeated measures ANOVA (RM ANOVA) followed by a Tukey post hoc, using GraphPad Prism 6 and StatView software.

The dose-response curve of Phen or 5-HTP/CB. We calculated the effective dose using the equation f = min + ((max-min)/[1 + (EC50/X)^Hill slope]), where f is the expected response to a given dose (X), min and max are the lowest and highest weight loss, and the EC50 is the dose at which 50% of the subjects are expected to show the desired response using the program of Gadagkar and Call (2015).

We used custom made scripts in Matlab (The MathWorks Inc., Natick, MA) to analyzed neuronal responses.

Neurons that increase or decrease their firing rate after Phen, or 5-HTP/CB, or Phen + 5-HTP/CB. Neuronal responses were classified as decreasing or increasing firing rates relative to baseline (BL). After treatment (Phen, or 5-HTP, or Phen + 5-HTP), significant changes in firing rates were identified using a Kruskal Wallis test with an α < 0.05. Neurons with increasing responses during treatment relative to BL were named “Increase,” whereas neurons with decreased activity “Decrease.” Neurons with no significant modulation were not-modulated “NoM.” We used a chi-square test to assess differences in the proportion of neurons recruited by each treatment.

To characterize, in rats, the efficacy of 5-HTP/CB on weight loss, we first performed a dose-response curve. Figure 1A (upper panel) depicts the change in body weight (g) following seven consecutive days after systemic administration of vehicle (open circle) or 5-HTP at doses of 1, 12.5, 25, 50, or 100 mg/kg. As expected, rats treated with the vehicle steadily gained body weight. In contrast, the weight loss induced by 5-HTP/CB followed a nearly dose-dependent response [RM ANOVA; main effect of doses: F _(5,21) = 30.3, p < 0.0001, days 1-7: F _(5,6) = 10.2, p < 0.0001 and doses x days interaction: F _(21,126) = 5.3, p < 0.0001]. Except for 12.5 and 25 mg/kg that changed body weight with the same magnitude (p = 0.85), 5-HTP100/CB induced the maximum weight loss when compared relative with vehicle (see dashed line Figure 1A lower panel). Figure 1A (lower panel) shows the dose-response curve for 5-HTP/CB. From these plots, we then obtained the ED₄₅ of 5-HTP/CB by using the software of Gadagkar and Call (2015), which corresponds to 31 mg/kg. Thus, in all subsequent experiments, we decided to use the ED₄₅ dose, based on a previous study that used a similar 5-HTP dose to evaluate its effects in combination with d-amphetamine (Baumann et al., 2011).

We performed the same experiment but only using different doses of Phen. As expected, body weight gain was observed in the control group (open circles Figure 1B , upper panel), whereas Phen, at 1 mg/kg, induced weight gain (1 mg/kg; see # symbol lower panel), 3 mg/kg was not different relative to vehicle, but 10 mg/kg maintained the same body weight relative to the initial weight in BL and it was significantly different relative to vehicle (p = 0.047). In contrast, higher doses of Phen 30 and 45 mg/kg induced a significant weight loss when compared against both the vehicle and the initial body weight at BL [RM ANOVA; main effect of doses: F _(5,24) = 31.5, p < 0.0001]. For Phen, the dose of 30 mg/kg (rather than 45 mg/kg) induced the maximum body weight loss (see dashed line Figure 1B , lower panel), suggesting that 45 mg/kg accelerated the development of pharmacological tolerance (see days 5–7, upper panel). The lower panel of Figure 1B depicts the ED₄₁ (10 mg/kg), ED₅₀ (15 mg/kg), and ED₅₆ (20 mg/kg) for Phen alone.

To evaluate the effects on weight loss, food intake, and locomotion of the triple-drug combination, we decided to combine the most commonly used concentrations reported in literature of Phen (Baumann et al., 2000; Roth et al., 2008; Kalyanasundar et al., 2015) that correspond to ED_{41, 50, or 56} (Phen10, Phen15, or Phen20, respectively) with a fixed ED₄₅ dose of 5-HTP/CB (31 and 75 mg/kg, respectively).

A visual inspection of the overall pattern of weight loss induced by 5-HTP/CB or Phen alone, revealed a prominent weight loss initially ( Figure 1 ; on days 1–3), whereas, on subsequent days (days 4–7), the weight loss either plateaued or, in some cases, a weight gain was later observed, suggesting the development of pharmacological tolerance. For this reason, in further analysis, we explored data as a function of these two blocks.

Next, we examined whether the triple drug combination induces greater weight loss than either of them alone. Figure 2A indicates the change in body weight (g) on days 1–3 block (left panel). After injections of the vehicle (control), rats exhibited a weight gain (white bar). In contrast, the 5-HTP/CB group lost weight -8.1 ± 1.5 g (orange). Likewise, the weight loss produced by Phen was dose-dependent (blue bars; 0.1 ± 0.7 g, -3.7 ± 0.8, and -5.7 ± 0.5 g for Phen10, 15, and 20, respectively). However, rats treated with the triple combination lost significantly more weight -8.9 ± 1.4 g, -16.2 ± 1.1, and -14.4 ± 1.4 for Phen10 + 5-HTP/CB, Phen15 + 5-HTP/CB, and Phen20 + 5-HTP/CB, respectively [RM ANOVA main effect treatments F _(7,55) = 29.3, p < 0.0001]. A post hoc analysis revealed that Phen15 + 5-HTP/CB and Phen20 + 5-HTP/CB induced greater weight loss than both 5-HTP/CB and Phen alone (All p _s < 0.05; see * Figure 2A ). Thus, our results demonstrate that the triple combination leads to greater weight loss than did either treatment alone.

In the late block days 4–7 ( Figure 2A , right panel), we observed what looks like pharmacological tolerance. This can be seen more clearly in Phen10 and Phen15 as both groups started exhibiting some weight gain. Nevertheless, they still maintained a lower body weight relative to vehicle-treated rats (white bar). In contrast, Phen10 + 5-HTP/CB, Phen15 + 5-HTP/CB, and Phen20 + 5-HTP/CB continued losing weight [RM ANOVA; F _(7,55) = 34.2, p < 0.0001]. Moreover, Phen15 + 5-HTP/CB and Phen20 + 5-HTP/CB groups lost significantly more weight than those treated with each drug alone (All p _s < 0.05).

Appetite suppressants, as its name indicates, induce weight loss, in part, by suppressing food intake (Adan et al., 2008; Valsamakis et al., 2017; Srivastava and Apovian 2018). Thus, as expected, the weight loss was accompanied by suppression of food intake. On days 1–3 ( Figure 2B , left panel), as expected, we found that the administration of the vehicle did not change food intake (i.e., values remained near to zero; 0.5 ± 0.4 g), while 5-HTP/CB suppressed food intake (-7.4 ± 1.3 g). Likewise, Phen reduced food intake in a dose-dependent manner (blue bars: Phen10; -1.6 ± 0.8, Phen15; -5.1 ± 0.6, and Phen20 -7.7 ± 0.6 g, respectively). Moreover, the triple drug combination achieved the maximum suppression of food intake (-10.1 ± 1.6 g, -15.4 ± 8, and -13.8 ± 0.7, for Phen10 + 5-HTP/CB, Phen15 + 5-HTP/CB, and Phen20 + 5-HTP/CB, respectively) [RM ANOVA; treatment: F _(7,55) = 30.8, p < 0.0001]. Both Phen15 + 5-HTP/CB and Phen20 + 5-HTP/CB reduced food intake more than either treatment alone (All p _s < 0.05; see * Figure 2B hatched bars). In the late block, on days 4–7 ( Figure 2B , right panel), all groups increased food intake relative to days 1–3, suggesting the development of pharmacological tolerance. Nevertheless, they still exhibited reduced food intake in comparison with vehicle treated rats [RM ANOVA; F _(7,55) = 8.7, p < 0.0001]. Only Phen15 + 5-HTP/CB suppressed food intake more than both Phen15 (p = 0.0009) and 5-HTP/CB (p = 0.03) groups. These results demonstrate that the triple drug combination suppressed food intake more and for a few more days than either treatment alone.

Since it is well known that in rodents appetite suppressants with dopaminergic action stimulate locomotion and stereotypy (Santamaría and Arias, 2010; Ferragud et al., 2014; Kalyanasundar et al., 2015), we asked whether 5-HTP/CB could antagonize the stimulant properties of Phen. To this end, we analyzed the total distance traveled, on days 1–3, and plotted in Figure 3A (left panel). Both the vehicle and 5-HTP/CB groups exhibited low levels of locomotion; this is because vehicle-treated rats spent most of the time sleeping, while rats treated with 5-HTP/CB were in a quiet awake state ( Supplementary Figure 2 ). In contrast, Phen at 10 mg/kg induced a robust hyper-locomotion, but higher doses, Phen15 and Phen20, resulted in hypo-locomotion, indicating an impairment in movement [RM ANOVA, treatment: F _(7,51) = 5.7, p < 0.0001]. A post hoc test further confirmed that Phen20 showed less locomotion than Phen10 (p = 0.007). For the triple combination, and on days 1–3, we found that Phen10 + 5-HTP/CB group had a lower distance traveled than Phen10, but differences did not achieve significance (p = 0.6). A similar trend was observed for Phen15 + 5-HTP/CB relative to Phen15. In contrast, Phen20 + 5-HTP/CB exhibited more locomotion than Phen20 alone, but no significant differences were found (p = 0.7).

On days 4–7 block ( Figure 3A , right panel), groups treated with Phen15 and 20 further reduced their locomotion, in particular, the immobility was stronger for Phen15 and Phen20 relatives to Phen10 (All p _s < 0.0001). In contrast, Phen20 + 5-HTP/CB displayed more locomotion than Phen20 alone, suggesting that for higher doses (e.g., Phen > 15 mg/kg that elicited hypo-locomotion), the triple combination partially recovered rat’s mobility.

Regarding stereotypy, either vehicle or 5-HTP/CB groups displayed no stereotypy at all ( Figure 3B ), confirming the idea that synaptic release of 5-HT alone is insufficient to stimulate forward locomotion or stereotypic behaviors (Baumann et al., 2011). In contrast, in the first block, Phen evoked the opposite effect on stereotypy than in locomotion. Phen decreased distance traveled ( Figure 3A ) but increased the stereotypy at higher doses ( Figure 3B , left panel; blue bars). In the second block, the stereotypy further increased, especially for Phen15 and Phen20 relative to Phen10 treated group (days 4–7; Figure 3B , right panel). Altogether, our data indicate that the hypo-locomotion evoked by higher doses of Phen was due to a heightened in repetitive movements (i.e., head weavings).

We observed that during the first three days of treatment, the triple drug combination, at doses tested, did not attenuate stereotypy ( Figure 3B see dashed bars). In contrast, on days 4–7 (right panel), Phen15 + 5-HTP/CB and Phen20 + 5-HTP/CB exhibited a significant reduction in stereotypy relative to its corresponding Phen group (Phen15, p = 0.008; Phen20, p = 0.002), substantiating that, as the treatment progress, 5-HTP/CB partially reverses psychomotor side-effects of Phen.

To characterize how these antiobesity drugs modulate NAcSh responses, we recorded extracellular single-unit activity, while rats received, via an intraperitoneal catheter, infusions of the abovementioned appetite suppressants. A total of 423 neurons were recorded in NAcSh while rats were infused with either Phen (15 mg/kg), or 5-HTP/CB (31/75 mg/kg), or Phen + 5-HTP/CB. Supplementary Figure 3 shows the approximate location of electrode tracks targeting the NAcSh. Figure 4A displays the normalized NAcSh neuron activity in color-coded PSTH, where yellow indicates activity above BL, and inhibitions are in blue. Neuronal activity is depicted as a function of the following four epochs: 1) BL, 2) Saline (Sal), 3) Sal/CB, or 4) Drug treatment, which is Phen, or 5-HTP, or Phen + 5-HTP. Two types of modulatory responses were observed: neurons whose activity decreased (Decr; blue color area) and those whose activity increased relative to BL (Incr; yellow color area). Within a few minutes from the onset of treatment, the majority of NAcSh neurons exhibited a large decrease in spiking (see Decr; blue colors after 120 min), while a smaller population increased their responses after the infusion of Phen (see Incr; yellow). After Phen, 73.7% (132/179) of NAcSh neurons were classified as Decr, while 15.6% (28/179) were Incr (χ2 = 48.6, p < 0.0001; Decr vs. Incr): and the other 10.6% were NoM ( Figure 4A , see pie chart). Overall, Phen modulates 89.3% of NAcSh neurons recorded, with the majority exhibiting a long-lasting inhibition for at least 1 h.

Unlike Phen, 5-HTP/CB modulated nearly the same number of neurons with either decreasing 25.4% (33/130) or increasing responses 26.1% (34/130) (χ2 = 0.01, p = 0.9). Thus, this serotonin precursor did not produce any inhibitory imbalance at the population activity level. Nevertheless, more than half (51.5%) of NAcSh neurons were sensitive to 5-HTP/CB.

Similar to Phen, in the case of the triple combination, we also observed a higher proportion of neurons with Decr (66.7%, 76/114) than Incr responses (19.3%, 22/114)(χ2 = 21.4, p < 0.0001), revealing that the infusion of Phen + 5-HTP/CB did not alter the Phen evoked inhibitory imbalance in NAcSh responses.

The normalized population activity (relative to BL) of all neurons pooled together across the first three (1–3) or last four (4–7) days can be seen in Figure 4B (upper panel). For the three groups, and after infusion of saline or CB, the activity did not significantly change relative to BL epoch. Likewise, infusion of 5-HTP/CB alone did not alter the population’s activity balance, and if any, it can be observed a slight increase in neural activity around 30 min after infusion (at time 150 min, purple line; left panel). In contrast, the infusion of Phen (orange) or the triple drug combination (green; Phen + 5-HTP/CB at time 120 min) within minutes evoked a large inhibitory imbalance in population NAcSh activity. The inhibitory imbalance induced by both Phen and the triple combination was of similar magnitude (Kruskal-Wallis test; χ2₍₂₎ = 25, p = n.s.), suggesting that the triple combination did not further enhance, or reduce, the imbalance ( Figure 4C ; left panel, days 1-3). Thus, our results suggest that the greater weight loss induced by the triple drug combination was not explained by the net inhibitory imbalance in the NAcSh population activity.

A similar modulatory pattern was observed on days 4–7. No significant differences were observed between Phen and Phen + 5-HTP/CB groups (Kruskal-Wallis test; χ2₍₂₎ = 43.8, p = n.s.; Figures 4B, C ), confirming once more that the combination did not alter the Phen-induced inhibitory imbalance of NAcSh responses.

We note that on the late block- relative to the first one- the infusion of 5-HTP/CB now induced a slight inhibition in NAcSh responses (purple, Figures 4B, C ), although it was always of less magnitude than that of Phen. The percentage of neurons modulated in each block can be seen in the pie charts below in Figure 4B . We note that the higher the inhibitory imbalance evoked by 5-HTP/CB, on days 4–7, would be rationalized, in part, by a trend towards significance in the drop of neurons with increasing responses from 36.2% (21/58) to 18% (13/72) from first to second block (χ2₍₂₎ = 3.175, p = 0.07).

Since Phen stimulates locomotor activity ( Figure 3A ), we then investigated whether NAcSh responses would correlate with locomotion. Figure 4B (dashed lines) plots the forward locomotion across the session. It can be appreciated that infusion of Phen either alone or in combination induced both an increase in locomotor activity and, in parallel, the inhibitory imbalance in NAcSh responses ( Figure 4B compare dashed lines (i.e., locomotion) vs. solid lines (i.e., population NAcSh activity)). In fact, we found a negative correlation between locomotion and the Phen-induced NAcSh inhibitory imbalance (Pearson correlation on days 1-3: r = -0.91, p < 0.001; on days 4–7: r = -0.92, p <0.001). A similar negative correlation was found for the Phen-5-HTP/CB-induced activity imbalance (days 1–3: r = -0.85, p < 0.001; on days 4–7: r = -0.76, p < 0.001). In contrast, 5-HTP/CB neither stimulated locomotion nor induced any inhibitory imbalance. In that sense, both the locomotion and NAcSh’s inhibitory imbalance always covaried. That said, it could also be seen that its magnitude did not change in the same proportion as the magnitude of forward locomotor activity. For example, on days 1–3, Phen stimulated the strongest locomotor activity, but on days 4–7 locomotion was lower (orange bars, Figure 4C , right panel) (Mann Whitney test; U = 38076, p < 0.0001), while Phen + 5-HTP/CB showed the opposite pattern that is low locomotion on days 1–3 but more on days 4–7 (see green bars)(Mann Whitney test; U = 147306, p < 0.0001). This is despite that Phen and Phen + 5-HTP/CB both evoked a similar NAcSh’s inhibitory imbalance in both blocks (compare early vs. late) ( Figure 4C , left panel). Thus, our data suggest that NAcSh’s inhibitory imbalance gates (or triggers) locomotor activity, rather than directly determines its magnitude.

Finally, we tested whether 5-HTP/CB and Phen targets either the same or different NAcSh ensembles. To this end, we implanted a new group of rats with an electrode array in the NAcSh and administered all these three drugs in the same session but at different time epochs. For this experiment, we record a total of 180 NAcSh neurons. Figure 5A displays a color-coded PSTH of all neurons, exhibiting a selective response to one drug and its sign of modulation. We classified responses either as NoM, meaning not-modulated, Decr, or Incr as a function of 5-HTP or Phen. For example, the first ensemble, in Figure 5A , described a subpopulation of neurons with NoM/Decr (5-HTP/Phen) modulatory pattern, meaning that it did not respond to 5-HTP, but its activity decreased after Phen. In this regard, the Phen-selective population was the largest among neurons with responses selective to one drug (NoM/Decr; 27.8% neurons). In contrast, only a few neurons were selective to 5-HTP/CB (Incr/NoM; 3.3% and Decr/NoM; 2.2%).

Our results showed that it was far more common to record nonselective than selective responses (i.e., responding to both drugs 62.2%, 112/180 vs. those responding selectively to one drug 35.5%, 64/180; Figures 5A, B ), suggesting that both drugs mainly recruited the same NAcSh neurons. The largest group belongs to the Decr/Decr modulatory pattern (43.3%, 78/180). In comparison with the experiment depicted in Figure 4 (5-HTP/CB Decr 25.4%), we noted that the increase in Decr neurons induced by 5-HTP/CB ( Figure 5 , 43.3%) could be explained, in part, by a potential carry-over effect of Phen across consecutive days. Furthermore, we observed that even neurons with increasing responses to 5-HTP/CB were further inhibited by Phen (see Incr/Decr, 29/180; 16.1%). Figure 5C depicts the percentage of neurons belonging to each population. Altogether, our results rationalized how the combination Phen + 5-HTP/CB evokes a change in firing rates (increase/decrease) toward an inhibitory imbalance in NAcSh responses that seems to gate locomotion ( Figure 5D ).

Although the roles of DA and 5-HT in the ventral striatum are well established for feeding and some neuropsychiatric maladies such as addiction and depression, respectively (Zangen et al., 2001; Wang et al., 2002; Wang et al., 2004; Nautiyal and Hen, 2017), it is unclear how they modulate NAcSh ensemble activity (Klawonn and Malenka, 2019). The appetite suppressant, Phen, is a catecholamine agent that elicits NE and DA release in the brain with lower effects on 5-HT (Balcioglu and Wurtman, 1998; Rothman and Baumann, 2009). In contrast, 5-HTP elevates 5-HT concentration in the brain and to a lesser degree DA release (Turner et al., 2006; Baumann et al., 2011). Thus, each appetite suppressant produces a specific neurochemical profile that most likely determines its desirable pharmacological effects but also its adverse side-effects. Previous studies support the idea that DA releasing appetite suppressants (e.g., Phen) and 5-HT precursors (e.g., 5-HTP) can be coadministered without altering their ability to release DA and increase 5-HT levels, respectively (Halladay et al., 2006; Baumann et al., 2011). Thus, it follows that by mixing different doses, we could tune the DA/5-HT ratio to yield optimal pharmacological effects. Our results are in line with this idea, but at the electrophysiological level, since we found that 5-HTP/CB did not interfere with Phen-induced inhibitory imbalance in NAcSh responses.

Furthermore, and for the first time, we observed that Phen recruits more NAcSh neurons than 5-HTP/CB. Notably, the majority of NAcSh neurons that were sensitive to 5-HTP/CB were further suppressed by Phen. Thus, we rationalized how Phen could induce the strongest modulations either alone or in combination. Importantly, we uncovered that a DA releasing agent and a 5-HT precursor both recruited largely overlapping neuronal ensembles, suggesting that NAcSh neurons received convergent influence of DA and 5-HT afferents.

In summary, we provide preclinical evidence, in rats, supporting the use of a triple drug combination for the treatment of obesity, while partially reducing undesirable psychomotor side-effects of Phen. Our findings contribute to the understanding of how DA and 5-HT acting appetite suppressants modulate NAcSh responses.