ABSTRACT
Fragile X syndrome (FXS) is a leading genetic disorder of intellectual disability caused by the loss of the functional fragile X mental retardation protein (FMRP). To date, there is no efficacious mechanism-based medication for FXS. With regard to potential disease mechanisms in FXS, it is widely accepted that the lack of FMRP causes elevated protein synthesis and deregulation of neuronal signaling. Abnormal enhancement of the ERK½ (extracellular signal-regulated kinase ½) and PI3K-Akt (Phosphoinositide 3 kinase-protein kinase B) signaling pathways has been identified in both FXS patients and FXS mouse models. In this study, we show that carbamazepine, which is an FDA-approved drug and has been mainly used to treat seizure and neuropathic pain, corrects cognitive deficits including passive avoidance and object location memory in FXS mice. Carbamazepine also rescues hyper locomotion and social deficits. At the cellular level, carbamazepine dampens the elevated level of ERK½ and Akt signaling as well as protein synthesis in FXS mouse neurons. Together, these results advocate repurposing carbamazepine for FXS treatment.
INTRODUCTION
Fragile X syndrome (FXS) is a leading cause of inherited intellectual disability and autism. Genetic studies have demonstrated that loss of function mutations in the fragile X mental retardation 1 gene (FMR1) that encodes the fragile X mental retardation protein (FMRP) results in FXS 1,2. Although the disease mechanism remains largely elusive, multiple lines of data demonstrate that FMRP interacts with both mRNAs and protein translation machinery 1-3. It has been found that, except for few specific targets 4, FMRP deficiency causes an overall enhancement of protein synthesis 3. There are also lines of clinical and preclinical evidence suggesting altered neuronal signaling in FXS. Previous studies have found that activity of the ERK½ signaling pathway is abnormally enhances in FXS mouse model (i.e. Fmr1 knockout mouse) and human patient samples 5-7. With regards to understanding how alteration of FMRP-regulated translation is linked to elevated ERK1/2 activity, it is found that FMRP binds Adcy1 (type 1 adenylyl cyclase) mRNA 8,9, and ADCY1 protein level is elevated in Fmr1 knockout (KO) mice10. Consistent with the finding that enhancement of ADCY1 expression causes elevated ERK1/2 activity11 and a panel of FXS-associated behavior (e.g. hyperlocomotion and social deficits)12, genetic reduction of Adcy1 attenuates the elevated ERK1/2 signaling and the aforementioned behavioral abnormalities in Fmr1 KO mice10. Intriguingly, genetic reduction of Adcy1 also restores Akt signaling10, the activity of which is elevated in both human patient and FXS mouse samples 7,13,14. These observations suggest that abrrrant hyperfunction of ADCY1 in FXS is a potential therapeutic target, through which the pathological overactivation of both ERK1/2 and Akt signaling pathways can be corrected. However, the potential therapeutic value in clinical application requires examination with practical pharmacological intervention.
Carbamazepine is an FDA-approved drug and is currently used for treatment of seizure and neuropathic pain. Because carbamazepine shows pharmacological activity against ADCY115, we reason that it may elicit therapeutic effects on FXS-associated pathological phenotypes. In contrast to ADCY, which contributes to cAMP production, PDE (phosphodiesterase) possesses enzymatic activity to reduce cAMP level by converting it to AMP. Notably, it is reported that FMRP also regulates the translation of certain PDE subtype (e.g. PDE2A) and the PDE2A protein level is elevated in Fmr1 KO mice 16. Thus, it is intriguing and seemingly possible that FMRP deficiency could concurrently affect signaling molecules with counteracting enzymatic activity.
To better understand this complication and the therapeutic potential through inhibiting ADCY or PDE2, in this study, we compared ADCY1 and PDE2A expression in wild type (WT) and Fmr1 KO mice. Furthermore, we demonstrated that inhibnition of ADCY1 by carbamazepine can correct abnormal ERK1/2 and Akt signaling, protein synthesis, and the core symptoms of cognitive deficits in a mouse model of FXS. However, PDE2A inhibitors can only attenuate the elevated Akt activity but have no effect on correcting the abnormal ERK1/2 activity and protein synthesis. These results provide the first evidence demonstrating differential pathological contributions of emzymatic components in cAMP homeostasis in FXS.
MATERIALS AND METHODS
Animals
WT and Fmr1 KO mice were generated by breeding WT males with Fmr1 heterozygous females. For all behavioral examinations, 2.5- to 3-month old male mice were used. Animals had free access to food and water and were housed in the Campus Animal Research facility under 12h light/dark cycle. All procedures used in the study were approved by the Institutional Animal Care and Use Committee at Michigan State University.
Cell culture
Neurons 17 and glial cells 18 were cultured from postnatal day 0 WT and Fmr1 KO mice. Briefly, the cortex and hippocampus were harvested and digested to obtain dissociated neurons and glial cells. Neurons were grown in Neurobasal A supplemented with B27, 0.5 mM glutamine and antibiotics and one-third of the growth media was replaced with fresh media once every 3 days. For glia culture, the dissociated cells were maintained in DMEM supplemented with 10%FBS and antibiotics for 9 days and then one-third of the media was replaced with fresh media once every 3 days.
Western blot analysis
Samples were first harvested from primary cell cultures on DIV (days in vitro) 14 or from brain tissues of adult (2.5- to 3-month old) mice. After sonication, samples were subjected to 4-20% SDS-PAGE and transferred onto nitrocellulose membranes. The membranes were first incubated with primary antibodies overnight at 4°C, washed with PBST (PBS with 0.1% Triton-X100), incubated with IRDye 800CW goat anti-rabbit or IRDye 680RD goat anti-mouse secondary antibodies (LI-COR Biosciences, Cat#926-32211 and Cat#926-68070, respectively, 1:5000) for 2 hours at room temperature, and washed with PBST. The signals were detected by the Odyssey digital imaging system (LI-COR Biosciences). The primary antibodies were rabbit anti-ADCY1 (Sigma, Cat# SAB4500146, 1:1000), rabbit anti-ERK1/2 (Cell Signaling, Cat#9102, 1:1000), rabbit anti-pERK1/2 (Cell Signaling, Cat#9101, 1:2000), rabbit anti-Akt (Cell Signaling, Cat#7272, 1:1000), rabbit anti-pAkt (Cell Signaling, Cat#13038, 1:1000), and mouse anti-β-actin (Sigma, Cat#A5541, 1:10,000).
In vivo drug administration
Vehicle (10% DMSO) or 20 mg/kg carbamazepine was i.p. injected 1 h before the behavioral examinations. The examination of passive avoidance memory and object location memory involved training and testing; animals received i.p. injection 1 h before training and were tested 24 hours later. For repeated drug administration, the animals received daily injection of vehicle or 20 mg/kg carbamazepine for 8 days, and behavior examinations were performed 1 h after the last injection.
Behavioral examination
For passive avoidance memory test 19, mouse was placed in the lit side of a passive avoidance chamber (Coulbourn Instruments, Whitehall, PA) and allowed to explore for 1 min, following which the trap door was opened. Once the animal crossed over to the dark side, the trap door was closed and a mild foot shock (0.7 mA for 2 sec) was delivered. The mouse remained in the dark side for 30 sec before being returned to its home cage. After 24 h, the trained mouse was reintroduced to the lit side and the crossover latency to the dark side was recorded. A maximum of 300 sec was used as the cutoff crossover latency value.
For object location memory test 20, mouse was first habituated by exposing to the empty training chamber for 10 min daily for 3 consecutive days. On day 4, the mouse was exposed to the chamber with two objects placed at location A and B. After the 10-min training, the mouse was returned to its home cage. Twenty-four hours later on day 5, the trained mouse was re-introduced to the same chamber with the same objects. One object was placed at the old location A and the other object was place at the new location C. The percentage of time that mouse spent with object at location A and B during training or A and C during testing was scored. Discrimination index was calculated as [(time spend with location C – time spent with location A)/total time spent with objects at both location A and C] during testing.
For open field test 19, mouse was placed in the center of an open field arena and allowed to move freely for 1 h. Ambulatory travel distance in the whole arena and in the center area of the arena as well as the number of entry to the center area were recorded by the TurScan Activity System (Coulbourn Instruments, Whitehall, PA).
For social interaction test, we used a 3-chamber paradigm 21 that has been sufficient to detect social deficits in FXS mouse model 22,23. Briefly, mouse was placed in the center of a 3-chamber social interaction box and allowed to freely explore the entire box for 5 min. Then the mouse was briefly restricted in the center compartment and a stimulus mouse was placed in a wire enclosure on one side and an empty wire enclosure on the other side. The time spent in mouse chamber and in sniffing the stimulus mouse was recorded for 10 min.
For light/dark test 19, mouse was placed in the dark side of a light/dark chamber and habituated for 2 min, after which the trap door was opened. The mouse was allowed to move freely between two chambers. The time spent in the lit chamber and the number of crossing to the lit chamber were recorded for 5 min.
Drug effects on protein synthesis and neuronal signaling
Protein synthesis was determined by the SUnSET method, which involves labelling with puromycin 24. To determine the drug effect, DIV 14 hippocampal neurons were pre-treated with carbamazepine (10, 40, 100 μM), BAY607550 (0.2, 1, 5 μM), or forskolin (1 and 5 μM) for 30 min followed by 30 min incubation with 5 μg/ml puromycin. Samples were harvested at the end of treatment, and protein synthesis level was determined by Western blot using anti-puromycin antibody (KeraFAST, Cat#EQ0001, 1:1000). The combined intensity of proteins ranging from 20 to 200 kDa was quantified and normalized to the level of β-actin.
To determine the drug effects on neuronal signaling, DIV 14 hippocampal neurons were treated with various concentrations of carbamazepine, BAY607550, or forskolin for 1 h. The treated neurons were harvested. The level of ERK1/2, pERK1/2, Akt, pAkt, and β-actin was determined by Western Blot.
Statistical analysis
Student’s t-test was used to analyze data between two groups. Two-way ANOVA followed by Holm-Sidak test was used to analyze the genotype effect and treatment effect. Three-way ANOVA followed by Holm-Sidak test was used to analyze the genotype effect, treatment effect, and location effect for data collected from object location memory test. Three-way repeated measures ANOVA was used to analyze the open field data at various time points. Since the crossover latency during testing in passive avoidance is not normally distributed, the numerical values were converted to categorical data (cut-off value is 300 sec) and then analyzed by Fisher’s exact test. All data are presented as average ± SEM.
RESULTS
ADCY1 is expressed in neurons and elevated in the dorsal hippocampus of Frm1 KO mice
Adcy1 is predominantly expressed in the central nervous system (CNS) 25,26, making it an attractive drug target for the treatment of neurological disorders. Here, we further found that ADCY1 is expressed in neurons but not glial cells. The enrichment of neurons or glial cells in our primary cultures was confirmed by immunoblots using antibodies against neuronal and glial-specific marker proteins (Fig.1). Clearly, ADCY1 expression is restricted in neurons enriched of synapsin I (Fig. 1a). Extracts from glial culture show expression of glial fibrillary acidic protein (GFAP) but not ADCY1 (Fig. 1a). Interestingly, while ERK1/2 show robust expression in both cell types, Akt is predominately expressed in neurons, far exceeding that in glial cells (Fig. 1a).
FMRP interacts with Adcy1 mRNA and suppress its translation 8-10. We confirmed that ADCY1 protein level is elevated in the hippocampus of Fmr1 KO mice (Fig. 1b). Interestingly, the elevated ADCY1 expression is brain region specific. It is prefernetilaly elevated in the dorsal hippocampus but not in ventral hippocampus and prefrontal cortex of Fmr1 KO mice (Fig. 1c).
Carbamazepine restores hippocampus-dependent memory in Frm1 KO mice
Recapitulating the intellectual disability in human FXS patients, Fmr1 KO mice display deficits in various learning and memory tasks including the hippocampus-dependent passive avoidance memory 19,27. We administered carbamazepine through i.p. injection followed by passive avoidance training. The carbamazepine- and vehicle-treated WT and Fmr1 KO mice showed comparable crossover latency during training (genotype effect: F1, 39=3.404, p=0.073; treatment effect: F1, 39=1.459, p=0.234; genotype X treatment interaction: F1, 39=1.501, p=0.228) (Fig. 2a). When tested 24 hours later, the vehicle-treated Fmr1 KO mice showed significantly shorter crossover latency than the vehicle-treated WT mice (p=0.009, Fisher exact test). Carbamazepine improved the memory in Fmr1 KO mice to the WT level (p=0.495, Fisher exact test). (Fig. 2a).
We next tested the effects of carbamazepine on object location memory (Fig. 2b1), which mainly depends on dorsal hippocampus 28,29. We found that Fmr1 KO mice are impaired to establish object location memory. While all groups of animals showed comparable preference for objects in location A and B during training (Fig. 2b2) (genotype effect: F1, 62=0.000, p=1.000; treatment effect: F1, 62=0.000, p=1.000; genotype X treatment interaction: F1, 62=3.691, p=0.059), the vehicle-treated WT but not Fmr1 KO mice showed preference for the object in the new location (i.e. location C) over the object in the old location (i.e. location A) during testing (Fig. 2b3) (WT: p=0.018; Fmr1 KO: p=0.991). The carbamazepine-treated WT and Fmr1 KO mice both showed preference for the new location (Fig. 2b3) (genotype X location: F1, 62=6.240, p=0.015; treatment X location: F1, 62=11.310, p=0.001; genotype X treatment X location: F1, 62=0.003, p=0.955; WT: p=0.000; Fmr1 KO: p=0.001). However, a single injection of carbamazepine did not improve object discrimination index in Fmr1 KO mice (Fig. 2b4) (genotype effect: F1, 31=3.12, p=0.087; treatment effect: F1, 31=5.655, p=0.024; genotype X treatment interaction: F1, 31=0.002, p=0.968). Interestingly, Fmr1 KO mice receiving repeated daily administration of carbamazepine for 8 days displayed normal behavior during training (Fig. 2c1) (genotype effect: F1, 62=0.000, p=1.000; treatment effect: F1, 62=0.000, p=1.000; genotype X treatment interaction: F1, 62=0.003, p=0.959). They showed improved object location memory (Fig. 2c2) (vehicle: p=0.299; carbamazepine: p=0.000) and object discrimination index during testing (Fig. 2c3) (genotype effect: F1, 31=0.396, p=0.534; treatment effect: F1, 31=0.846, p=0.365; genotype X treatment interaction: F1, 31=9.819, p=0.004).
Effects of carbamazepine on non-cognitive behavioral abnormalities in Frm1 KO mice
Besides intellectual disability, other core FXS behavioral symptoms include hyperactivity and social deficits. We examined the effects of carbamazepine on locomotion activity. One hour after carbamazepine or vehicle injection, mice were placed in an open field arena. Consistent with previous studies 2,19, vehicle-treated Fmr1 KO mice showed hyper-locomotion than WT mice in the whole arena (Fig. 3a1 and 3a1’; genotype effect: F1, 52=23.814, p=0.000; treatment effect: F1, 52=0.222, p=0.640; genotype X treatment interaction: F1, 52=6.147, p=0.016) and the center area of the arena (Fig. 3a2 and 3a2’; genotype effect: F1, 52=22.069, p=0.000; treatment effect: F1, 52=3.339, p=0.073; genotype X treatment interaction: F1, 52=9.449, p=0.003) (Fig. 3a3 and 3a3’; genotype effect: F1, 52=25.098, p=0.000; treatment effect: F1, 52=0.286, p=0.595; genotype X treatment interaction: F1, 52=9.113, p=0.004). Carbamazepine normalized whole arena locomotion in Fmr1 KO mice to the level observed in WT mice (Fig. 3a1, p=0.089 between the treated Fmr1 KO and WT mice). Carbamazepine also normalized hyper-locomotion in the center area of the open field arena in Fmr1 KO mice (Fig. 3a2; p=0.246 between the treated Fmr1 KO and WT mice) (Fig. 3a3, p=0.156 between the treated Fmr1 KO and WT mice).
In the 3-chamber social interaction test, all groups spent similar total time in the chamber that holds the stranger mouse (Supplementary Fig. 1a) (Fig. 3b1; genotype effect: F1, 30=1.188, p=0.284; treatment effect: F1, 30=0.002, p=0.968; genotype X treatment interaction: F1, 30=2.861, p=0.101). Notably, Fmr1 KO mice spent less time in direct interaction with the stranger mouse than WT mice (Supplementary Fig. 1b, Fig. 3b2). While a single acute treatment with carbamazepine had no significant effect (Supplementary Fig. 1), repeated daily administration for 8 days improved social interaction in both WT and Fmr1 KO mice. The carbamazepine-treated WT and Fmr1 KO mice showed comparable social interaction (Fig. 3b2; genotype effect: F1, 30=19.521, p=0.000; treatment effect: F1, 30=22.184, p=0.000; genotype X treatment interaction: F1, 30=2.620, p=0.116).
Our previous studies found that Fmr1 KO mice made more transitional moves between two chambers in the light/dark test, reflecting hyperactivity and repetitive behavior 10,19. For this specific behavioral abnormality, neither single (Supplementary Fig. 2a1) nor repeated treatment (Supplementary Fig. 2b1) with carbamazepine exerted significant therapeutic effect. Interestingly, repeated carbamazepine increased total time spent in the light chamber in both WT and Fmr1 KO mice (Supplementary Fig. 2b2).
Carbamazepine dampens the elevated protein synthesis in Frm1 KO neurons
Consistent with previous reports, we found that protein synthesis is elevated in Fmr1 KO hippocampal neurons (Fig. 4a; genotype effect: F1, 16=12.898, p=0.002). Carbamazepine dampened protein synthesis in Fmr1 KO neurons in a dose-dependent manner without affecting wild type neurons (Fig. 4a; treatment effect: F3, 16=3.757, p=0.032; genotype X treatment interaction: F3, 16=5.081, p=0.012).
Carbamazepine suppresses both ERK1/2 and Akt activity in neurons
The level of total ERK1/2 (Fig. 4b1 and 4b2; genotype effect: F1, 16=0.027, p=0.871; treatment effect: F3, 16=0.760, p=0.533; genotype X treatment interaction: F3, 16=0.303, p=0.308) and Akt (Fig. 4c1 and 4c2; genotype effect: F1, 16=0.000, p=0.999; treatment effect: F3, 16=0.089, p=0.965; genotype X treatment interaction: F3, 16=0.293, p=0.830) was not affected by genotype and carbamazepine treatment.
As reflected by the levels of phosphorylated ERK1/2 and Akt (i.e. pERK1/2 and pAkt, respectively), the activity of ERK1/2 (Fig. 4b1 and 4b3; genotype effect: F1, 16=8.788, p=0.009) and Akt (Fig. 4c1, and 4c3; genotype effect: F1, 16=57.920, p=0.000) are elevated in Fmr1 KO hippocampal neurons.
Carbamazepine dose-dependently decreases the level of pERK1/2 (Fig. 4b1 and 4b3; treatment effect: F3, 16=129.537, p=0.000; genotype X treatment interaction: F3, 16=21.401, p=0.000) and pAkt (Fig. 4c1 and 4c3; treatment effect: F3, 16=14.840, p=0.000; genotype X treatment interaction: F3, 16=3.233, p=0.050) in both WT and Fmr1 KO neurons. The abnormally elevated pERK1/2 and pAkt in Fmr1 KO neurons were more sensitive to carbamazepine treatment than wild type neurons. Comparing to wild type neurons, pERK1/2 and pAkt in FXS neurons were effectively suppressed by lower concentrations of carbamazepine. While 10 μM carbamazepine was sufficient to dampen pERK1/2 and pAkt in Fmr1 KO neuron, higher concentration (100 μM) was required for WT neurons (Fig. 4b and 4c).
Pharmacological inhibition of PDE2 and activation of ADCY do not correct the elevated protein synthesis in FXS mouse neurons
ADCY and PDE have counteracting enzymatic action on cAMP metabolism and may have different effects on cAMP-regulated signaling molecule such as ERK1/2 11,30. With regard to the consideration of targeting ADCY1-ERK1/2 for potential therapeutic strategy, one complication is that PDE2A was also identified as an FMRP target 16. We found that PDE2A is also primarily expressed in neurons but not glial cells (Fig. 5a). Interestingly, PDE2A protein is not altered in adult Fmr1 KO hippocampus (Fig. 5b). This is consistent with that PDE2A may be affected only in juvenile but not adult FXS mice 16,31.
In contrast to the effects of carbamazepine, BAY607550, which has inhibitory activity against PDE2 32, did not show significant effect on protein translation (Fig. 5c: genotype effect: F1, 28=49.538, p=0.000; treatment effect: F3, 28=1.305, p=0.292; genotype X treatment interaction: F3, 28=1.770, p=0.176). As an alternative approach to increase cAMP, forskolin was used to stimulate multiple ADCY. Interestingly, forskolin increased protein translation in both WT and Fmr1 KO neurons (Fig. 5d; genotype effect: F1, 14=8.788, p=0.009; treatment effect: F2, 14=13.539, p=0.001; genotype X treatment interaction: F2, 14=0.660, p=0.532).
Effects of PDE2 inhibition and ADCY activation on ERK1/2 and Akt signaling
Although the function of ADCY1 in regulating ERK1/2 and Akt signaling has been implicated 10, the overall effect of cAMP through inhibition of PDE2 or non-specific activation of multiple ADCY subtypes has not been investigated. Consistent with that cAMP positively stimulates pERK1/2, we found that, although there is no effect on total ERK1/2 (Supplementary Fig. 3a1), the PDE2 inhibitor BAY607550 upregulated pERK1/2 in both WT and Fmr1 KO neurons (Fig. 5e1 and 5e2; WT: F3, 28=97.854, p=0.000; Fmr1 KO: F3, 28=33.944, p=0.000). Interestingly, BAY607550 caused decrease in pAkt in both WT and Fmr1 KO neurons (Fig. 5e1 and 5e3; WT: F3, 28=4.072, p=0.016; Fmr1 KO: F3, 28=4.970, p=0.007) without affecting the level of total Akt (Supplementary Fig. 3a2).
We found that forskolin causes robust increase of pERK1/2 (Fig. 5f1 and 5f2; WT: F2, 16=36.081, p=0.000; Fmr1 KO: F2, 16=16.800, p=0.000) but decreased pAkt (Fig. 5f1 and 5f3; WT: F2, 16=11.182, p=0.001; Fmr1 KO: F2, 16=20.850, p=0.000) in both WT and Fmr1 KO neurons without affecting total ERK1/2 (Supplementary Fig. 3b1) and total Akt level (Supplementary Fig. 3b2). Together, these results demonstrate that decreasing PDE2A activity or increasing ADCY activity dampens the elevated pAkt but exacerbates the elevated pEK1/2 in FXS mouse neurons.
DISCUSSION
Our data show that the alteration of cAMP enzymes (i.e. ADCY and PDE) in FXS depends on brain region and developmental stage. Treatment with carbamazepine, which has inhibitory action against ADCY1 is sufficient to correct certain aspects of FXS-associated pathology in a mouse model during adulthood.
As carbamazepine is a pharmacological reagent, it is challenging to definitively pinpoint the mechanism of action underlying the therapeutic effects. Nevertheless, our data show that carbamazepine suppresses both ERK1/2 and Akt activity. This outcome recapitulates the effect of genetic reduction of ADCY1 on rescuing the elevated ERK1/2 and Akt signaling in FXS mouse 10. It is also consistent with that carbamazepine show pharmacological inhibition activity against ADCY1 15. It is important to note that carbamazepine also inhibit ADCY5 and ADCY7 15. ADCY7 is not expressed in brain; ADCY5 is predominately expressed in striatum and nucleus accumbens 33. Functionally, ADCY5 deficiency leads to increase in ERK1/2 activity and mGluR5 signaling 33, both of which are associated with cellular pathology in FXS 5,6,34. ADCY5 deficiency also reduces social interaction 33. We expect that the carbamazepine effect on ERK/12 and Akt activity in hippocampal neurons and its effect on correcting the social interaction deficits in Fmr1 KO mice are unlikely mediated through ADCY5 or ADCY7 inhibition.
Along with previous studies, our data show that, while ERK1/2 activity is positively correlated with cAMP level, Akt activity may be specifically regulated by ADCY1 rather than general cAMP level in neurons. It is evident that specific over-expression of ADCY1 11 or general increase of cAMP by forskolin (Fig. 5f) and PDE2 inhibitors (Fig. 5e) can both increase ERK1/2 activity. However, although genetic reduction of ADCY1 10 or carbamazepine treatment decreases Akt activity in FXS samples, general increase of cAMP did not cause increase of Akt activity. Forskolin or PDE2 inhibitor rather decreases Akt activity. Thus, targeting ADCY1 may offer a unique opportunity to concurrently suppress the abnormal ERK1/2 and Akt signaling in FXS.
It is interesting to note that, although ADCY1, ERK1/2, and Akt are pro-learning molecules and their activity is required for memory formation 26,35-37, the elevated activity of these signaling molecules is concurrent with the learning deficits in FXS. It is evident that decrease rather than increase of the activity of ADCY1, ERK1/2 and Akt shows therapeutic efficacy to correct cognitive impairments in FXS mouse 38,39. Although the mechanism remains elusive, it is possible that concurrent increase of ADCY1, ERK1/2 and Akt activity along with other pathological changes in FXS impair rather than facilitate learning.
Treatment strategy through increase of cAMP signaling has been previously proposed 40, although the level of cAMP in crude homogenates has been found to be normal in both human and mouse FXS samples 10,41,42. As cAMP homoeostasis is maintained by counteracting enzymatic activities from multiple subtypes of ADCY and PDE, identification of alterations in specific cAMP enzyme may help to better understand the disease mechanism. Further, whether alteration of ADCY and PDE in specific brain region, sub-cellular domain and developmental stage should also be considered. FMRP binds Adcy1 and Pde2a mRNA and the protein levels of ADCY1 and PDE2A are elevated in Fmr1 KO mice 8-10,16. One complication is that, while elevated ADCY1 is detected in adult FXS mouse samples (Fig. 1), alteration of PDE2A is detected in juvenile samples (i.e. at postnatal day 13) 16. Notably, ADCY1 is enriched at postsynaptic density 43 and PDE2A is substantially expressed at the presynaptic active zone 16. This indicates an age-dependent and compartmentalized alteration of cAMP enzymes in FXS, suggesting tailored therapeutic approaches. Interestingly, it is found that treatment with PDE2 inhibitor BAY607550 rescues social deficits in infant (postnatal day 10-14) and adolescent (postnatal day 30) Fmr1 KO animals 32. Although PDE4D expression has not been compared between normal and FXS samples, chronic treatment with PDE4D negative allosteric modulator (NAM) BPN14770 improves behavioral symptoms associated with social interaction and perseveration 44. The effect of PDE2 and PDE4 inhibition on cognitive function such as learning and memory has not been determined. In regards to how inhibition of PDE affects the known signaling alteration such as ERK/12 and Akt, our data show that targeting PDE2 dampens the elevated Akt activity but further increases the elevated ERK1/2 activity in FXS. Moreover, it is worth mentioning that, while ADCYs contribute to cAMP production, PDE2A degrades both cAMP and cGMP. Examination of the therapeutic effect of cGMP may be considered for future investigation.
In summary, our study revealed the efficacy of carbamazepine on correcting the key cellular disease mechanisms including the elevated protein synthesis and ERK1/2 and Akt signaling. Furthermore, we demonstrated therapeutic efficacy of carbamazepine to correct adult behavioral abnormalities in a mouse model of FXS. As carbamazepine is an FDA-approved drug, it may offer a practical approach and be clinically repurposed for FXS therapy. It is worth noting that carbamazepine has been mainly used to treat seizure and neuropathic pain. The increased risk of seizure is observed in about 18% of the child FXS patients (from as early as 4 months to 9 years of age) but not in adulthood 45,46. As a symptom-rather than mechanism-based treatment, anticonvulsants including carbamazepine, valproic acid, lamotrigine, and oxcabazepine have been used to control seizure in FXS children without severe side effects 47. Nonetheless, our results advocate future tests of clinical efficacy with adult human FXS patients, beyond the anticonvalsant effects in children.
FUNDING AND DISCLOSURE
This work was supported by R01MH119149 (to HW) from the NIH and W81XWH-17-1-0270 (to HW and YF) from the Department of Defense. The authors declare no conflict of interest.
AUTHOR CONTRIBUTIONS
HW, QD, and YF contribute to the conception and design of the study. QD and FZ performed the experiments and analyzed the data. HW, QD, and YF wrote the manuscript.
ADDITIONAL INFORMATION
Supplementary Information accompanies
FIGURE LEGENDS
ACKNOWLEDGEMENTS
We thank Dr. Zhuang Miao for setting up the object location memory paradigm.