Brain-derived neurotrophic factor (BDNF) and serotonin (5-hydroxytryptamine, 5-HT) are two seemingly distinct signaling systems that play regulatory roles in many neuronal functions including survival, neurogenesis, and synaptic plasticity. A common feature of the two systems is their ability to regulate the development and plasticity of neural circuits involved in mood disorders such as depression and anxiety. BDNF promotes the survival and differentiation of 5-HT neurons. Conversely, administration of antidepressant selective serotonin reuptake inhibitors (SSRIs) enhances BDNF gene expression. There is also evidence for synergism between the two systems in affective behaviors and genetic epitasis between BDNF and the serotonin transporter genes.
Brain-derived neurotrophic factor (BDNF) is the most abundant and widely distributed neurotrophin in the central nervous system (CNS). Initially isolated as a secretory protein capable of promoting the survival of peripheral neurons, BDNF is now recognized as a plethoric factor able to regulate a wide repertoire of functions, including neuronal survival, migration, phenotypic differentiation, axonal and dendritic growth, and synapse formation (Huang and Reichardt, 2001; Lewin and Barde, 1996). In addition to its prominent role in neuronal survival and differentiation during development, BDNF has emerged as a key regulator of synaptic plasticity and behavior (McAllister et al, 1999; Poo, 2001; Lu, 2003). Recent evidence strongly implicates a role for BDNF in cognitive functions, notably in memory acquisition and consolidation. (Tyler et al, 2002; Pang et al, 2004; Lu and Woo, 2006). It is now believed that the main function of BDNF in the adult is to regulate synaptic plasticity rather than to mediate cell survival and growth.
Functions of BDNF are mediated by two receptor systems: TrkB and p75NTR. Binding of mature BDNF (mBDNF) to TrkB triggers tyrosine phosphorylation in its cytoplasmic domain, leading to activation of at least three signaling pathways: MEK–MAPK, phosphatidylinositol-3-kinase (PI-3-K) and phospholipase C-γ (PLC-γ) (Kaplan and Miller, 2000; Chao, 2003; Huang and Reichardt, 2003). The majority of BDNF-induced functions have been attributed to signaling through TrkB. Pro-BDNF, which preferentially binds p75NTR, activates a different set of intracellular signaling cascades including nuclear factor-kappa B (NF-κB), c-jun kinase and sphingomyelin hydrolysis (Gentry et al, 2004; Teng et al, 2005). Activation of p75NTR by pro-neurotrophins has been linked to the activation of apoptotic signaling and initiation of N-methyl-D-aspartic acid (NMDA) receptor-dependent synaptic depression in the hippocampus (Ibanez, 2002; Lu and Je, 2003; Barker, 2004; Lu et al, 2005).
BDNF has a complex genomic structure rendering it an ideal target for multiple and complex transcriptional regulation (West et al, 2001; Lu, 2003). Multiple upstream promoters, each individually regulated, drive a short 5′ exon that is alternatively spliced onto a common 3′ exon, which encodes the pre-proBDNF protein. Evidence now indicates that the promoters of individual transcripts are regulated by diverse and varied physiological stimuli, and that these transcripts are distributed in different brain regions, different cell types and even different parts of the cell (eg soma vs dendrites) (Pattabiraman et al, 2005). Compared with other promoters, the rat promoter III is by far the most effectively regulated by neuronal activity in the amygdala, hippocampus, and cortex. Thus, alterations in transcription of BDNF via promoter III have been heavily studied as a mediator of activity-dependent processes including synapse development, plasticity, learning, and memory.
BDNF mRNA is translated in the ER into a precursor protein, which is folded in the trans-Golgi and then packaged into secretory vesicles (Lu, 2003). Upon correct folding, BDNF can be sorted into the constitutive (spontaneous release) or more frequently, into the regulatory (release in response to stimuli) secretory pathway. The trafficking and localization of BDNF appears to be controlled by its pro-domain. A single-nucleotide polymorphism (SNP) in the pro-domain of BDNF, which converts the 66th amino acid valine into methionine (Val66Met), has been identified. The Val66Met polymorphism affects dendritic trafficking and synaptic localization of BDNF as well as impairs its secretion. Human subjects carrying the Val66Met SNP exhibit deficits in short-term episodic memory and show abnormal hippocampal activation (Egan et al, 2003). BDNF is the only neurotrophin that is indisputably secreted in response to neuronal activity. The majority of BDNF is secreted via the regulated pathway and is derived from both pre- and post-synaptic sites.
In addition to its prominent role in hippocampal synaptic plasticity and related learning and memory mechanisms, BDNF signaling has been implicated in the regulation of adult neurogenesis (Lu and Chang, 2005). In BDNF heterozygous (+/−) mice as well as in mice with impaired TrkB activation (trkB.T1-overexpressing mice) the basal proliferation rate of new neurons in the dentate gyrus of the hippocampus is increased, but the 3-week survival of these newborn neuroblasts is significantly decreased. These results suggest that normal BDNF–TrkB signaling is requisite for the long-term survival of newborn neurons in the dentate gyrus (Sairanen et al, 2005). Importantly, antidepressants and the mood stabilizer lithium have been shown to elicit an increase in hippocampal neurogenesis (Chen et al, 2000; Malberg et al, 2000). This antidepressant-induced survival is lost in mice with impaired BDNF signaling (Sairanen et al, 2005). An additional study found evidence for the dependence of BDNF on the enhancement of hippocampal neurogenesis that is observed following environmental enrichment (Rossi et al, 2006).
Further implicating a role for BDNF signaling in depression and anxiety, it has been shown that decreases in hippocampal BDNF levels are correlated with stress-induced depressive behaviors (Nibuya et al, 1995; Smith et al, 1995; Vaidya et al, 1997; Duman, 2004; Duman and Monteggia, 2006), and that antidepressant treatment enhances the expression of BDNF (Nibuya et al, 1995; Russo-Neustadt et al, 1999; Duman and Monteggia, 2006). Moreover, the BDNF gene as well as the Val66Met polymorphism have been associated with increased risk for a number of neuropsychiatric disorders (Neves-Pereira et al, 2002; Sklar et al, 2002; Schumacher et al, 2005; Strauss et al, 2005; Okada et al, 2006).
Depression is characterized by ‘behavioral despair’ as well as the inability to experience pleasure, ie anhedonia. These sets of behaviors are likely controlled by two interacting brain systems: the brain stress system (hippocampus-HPA pathway), and the brain reward system (VTA-NAc, and VTA-prefrontal cortex). The hippocampal circuitry includes functional components for learning and memory as well as negative regulation of the HPA-mediated stress pathway, both of which are altered in depression. The dopaminergic VTA → NAc pathway plays a crucial role in reward and motivation. It appears that BDNF elicits opposite effects on these two systems. Intra-hippocampal infusion of BDNF produces antidepressant effects (Siuciak et al, 1997; Shirayama et al, 2002), while in striking contrast, it appears to play a pro-depressive role in the VTA → NAc reward system (Eisch et al, 2003). Conversely, inhibiting BDNF–TrkB signaling via viral infection of dominant-negative TrkB-T1 in NAc elicits a dramatic anti-depressive effect (Eisch et al, 2003). Using a social defeat paradigm, Berton et al (2006) recently showed that repeated exposure to aggression results in long-lasting social withdrawal in mice. BDNF gene deletion in the NAc via injection of a Cre-recombinase virus to mice carrying a floxed BDNF allele prevents social defeat, mirroring the effect obtained with chronic antidepressant treatment (Berton et al, 2006).
The clear dichotomy of BDNF actions in the hippocampus and VTA-NAc demands separate investigation of the effects of BDNF manipulations on behaviors related to (1) anhedonia and motivation and (2) despair and stress. Inducible and region-specific genetic approaches, which are more precise and cell-type specific will be advantageous. Since the NAc is largely composed of GABAergic interneurons, which presumably do not express BDNF, local BDNF may be primarily derived from glia. Differences in the kinetics of BDNF transcription and/or secretion in neurons and glia may lead to contrasting effects in the hippocampus and NAc.
5-Hydroxytryptamine (5-HT) is produced by neurons located in the brainstem raphe nuclei and is released from the terminals of serotonergic neurons that project from the raphe nucleus. The serotonergic projections innervate multiple cortical brain regions to regulate a wide repertoire of behaviors, as well as cognition and mood. In addition to its prominent role as a neurotransmitter, 5-HT plays an important role in brain development via regulation of neurite outgrowth, synaptogenesis, and cell survival (Gaspar et al, 2003). In the adult, serotonergic neurotransmission modulates many brain functions including emotion, cognition, motor function, and pain sensitivity. Serotonin signaling also influences neuroendocrine functions including food intake, sleep and circadian rhythms, and reproductive activity.
Serotonin has the highest number of receptors of any of the neurotransmitters and the system is one of the phylogeneticaly oldest. Fifteen genes encoding 5-HT receptors have been identified in the mammalian brain (Bockaert et al, 2006). All of the 5-HT receptors are G-protein-coupled receptors except for the 5-HT3 receptor, which uses an ionotropic mechanism (Bockaert et al, 2006). The 5-HT1 receptors (5-HT1A, 5-HT1B, 5-HT1D, 5-HT1E, 5-HT1F) are coupled to Gαi/Gαo signaling proteins; the 5-HT2 receptors (5-HT2A, 5-HT2B, 5-HT2C) are coupled to Gαq signaling proteins; the 5-HT4, 5-HT6, and 5-HT7 receptors are coupled to Gs proteins. The coupling mechanism for the 5-HT5 receptors (5-HT5A and 5HT5B) remains unknown (Raymond et al, 2001). High densities of 5-HT1A receptors have been reported in the limbic areas and these receptors are negatively coupled to adenylyl cyclase (AC) via pertussis-toxin-sensitive Gαi and/ or Gαo proteins (De Vivo and Maayani, 1986; Weiss et al, 1986).
While multiple pre- and post-synaptic 5-HT receptors have been identified, removal of 5-HT from the synaptic cleft is mediated by a single protein, the 5-HT transporter (5-HTT). 5-HTT is able to take up serotonin from the synaptic cleft to the presynaptic terminals, effectively terminating the synaptic action of 5-HT. The 5-HTT determines the size and duration of the serotonergic responses and thus plays a key role in serotonergic neurotransmission (Lesch and Mossner, 1998). Of particular interest, stress is associated with reduced 5-HTT mRNA levels in the raphe nucleus (Vollmayr et al, 2000). Analysis of the promoter region of 5-HTT has revealed a polymorphism that results in allelic variation in functional 5-HTT expression (Lesch et al, 1996). The region containing the polymorphism is located about 1 kb upstream of the transcription initiation site and contains either 14 or 16 repetitive elements. The long (l) allele contains 16 of the elements while the short (s) allele contains 14 of the repetitive elements. Transcription from the l allele results in production of more 5-HTT transcript and hence more functional 5-HT uptake than the s allele (Lesch et al, 1996).
Like BDNF, alterations in 5-HT signaling have demonstrable effects on synaptic plasticity and adult neurogenesis in the hippocampus (Brezun and Daszuta, 1999; Gould, 1999; Santarelli et al, 2003; Djavadian, 2004). In particular, 5-HT1A activation stimulates neurogenesis in the hippocampus and this effect appears to be required for the effects of antidepressants (Brezun and Daszuta, 1999, 2000; Santarelli et al, 2003). Furthermore, one of the most recognized functions of 5-HT in the adult brain is its purported role in depression and anxiety. The 5-HTT polymorphism has been associated with anxiety, depression and aggression-related personality traits (Lesch et al, 1996; Lesch and Mossner, 1998). Disturbances in 5-HT signaling have been implicated in a plethora of psychiatric disorders including obsessive–compulsive disorder, bulimia, chronic impulsivity, aggression, and suicide (Baumgarten and Grozdanovic, 1995; Hen, 1996; Berman et al, 1997; Mann, 1998). Most importantly, administration of selective serotonin reuptake inhibitors (SSRIs), which serve to effectively increase 5-HT concentrations in the synaptic cleft, is one of the most widely used therapies for depression and anxiety. In line with this thinking, it has been shown that 5-HT receptor agonists also have antidepressant effects (Fuller, 1996).
Although 5-HT is mainly secreted from serotonergic neurons in the raphe, transient expression of SERT in thalamocortical fibers has been observed during development, leading to the uptake and regulated release of serotonin from these fibers (Lebrand et al, 1996). While interference with this process may alter the development of sensory circuits, the functional role of 5-HT release from thalamocortical fibers in depression and anxiety has not been investigated. In this context, it is important to note that anxiety-related behavioral deficits in 5HT-1A knockout mice are due to the lack of serotonin action during development, and not in the adult (Gross et al, 2002).
BDNF REGULATION OF 5-HT NEURON DEVELOPMENT AND FUNCTIONS
Substantial evidence suggests that BDNF promotes the development and function of serotonergic neurons. BDNF and its receptor TrkB are co-expressed in serotonergic neurons within the dorsal raphe and median raphe (Merlio et al, 1992; Madhav et al, 2001), and BDNF is retrogradely transported from 5-HT terminals in the striatum and hippocampus to cell bodies in the raphe nuclei (Anderson et al, 1995). BDNF has been shown to promote the survival and morphological differentiation of 5-HT neurons both in culture and in vivo. Treatment of cultured neurons derived from embryonic raphe with BDNF dramatically increases the number of cells that express 5-HT markers and stimulates their morphological complexity (Eaton and Whittemore, 1996; Zhou et al, 2000; Rumajogee et al, 2002; Djalali et al, 2005). Intracerebroventricular infusion of BDNF stimulates sprouting of 5-HT axons, leading to hyperinnervation at the site of injection (Mamounas et al, 1995, 2000).
BDNF also promotes expression of serotonergic markers in raphe neurons. Infusion of BDNF into the brain enhances the expression of tryptophan hydroxylase (TpOH) (the rate-limiting enzyme in 5HT synthesis), upregulates 5-HT uptake and its activity-dependent release, and even modifies the firing patterns of serotonergic neurons in the raphe (Siuciak et al, 1996, 1998; Celada et al, 1996; Zhou et al, 2000; Goggi et al, 2002). In BDNF heterozygous mutant (+/−) mice, levels of forebrain 5-HT, fiber densities of forebrain 5-HT neurons, as well as the 5-HT clearance rate, were significantly impaired (Lyons et al, 1999; Szapacs et al, 2004; Daws et al, 2007). The functions of the 5-HT1A and 5-HT2A receptors also appear to be impaired in a mutant line in which the BDNF gene is deleted later in development (Rios et al, 2006; Hensler et al, 2007).
Mechanistic studies have suggested the existence of an auto/paracrine feedback loop in regulation of the serotonergic phenotype whereby 5-HT upregulates BDNF mRNA, and subsequent BDNF–TrkB signaling is crucial in the phenotypic development of serotonergic properties (Galter and Unsicker, 2000a, 2000b). The BDNF–TrkB mediated induction of the serotonin phenotype appears to be coupled to 5-HT1A-mediated downregulation, which results in increased cAMP production. In this model, BDNF activates TrkB on 5-HT neurons, which results in an upregulation of TpOH and 5-HT uptake. It is conceivable that an increase in cAMP concentration results in activation of protein kinase A (PKA) and the transcription factor CREB, leading to BDNF synthesis. The cycle is completed as synthesized BDNF in turn activates TrkB (Galter and Unsicker, 2000a, 2000b).
5-HT REGULATION OF BDNF GENE EXPRESSION AND SIGNALING
Consistent studies suggest that serotonergic transmission exerts powerful control over BDNF expression, and this may be a key mechanism underlying the therapeutic effects of antidepressants.
5-HT and BDNF Expression
A prevailing hypothesis is that increases in extracellular 5-HT, as would occur upon administration of SSRIs, may increase BDNF levels because inhibition of 5-HTT enhances serotonergic transmission through 5-HT4,6,7 receptor subtypes, which are positively coupled to adenylate cyclase and PKA. Resultant increases in CREB phosphorylation are known to positively regulate transcription of BDNF. Not all results are consistent with this idea. For example, in SERT knockout mice which lack the 5-HTT, and thus have elevated levels of extracellular 5-HT, upregulation of BDNF could not be observed (Szapacs et al, 2004).
Severe, prolonged stress is believed to initiate and exacerbate several psychiatric illnesses particularly depression and post-traumatic stress disorder (PTSD). Exposure to stressful stimuli leads to activation of several neurotransmitter and endocrine systems of which the hypothalamic–pituitary–adrenocortical (HPA) axis is the key hormonal component (Chaouloff, 1993). Acute stress has been shown to reduce the expression of BDNF mRNA in the hippocampus (Smith et al, 1995), while numerous studies have documented that both chronic and acute stress paradigms decrease the expression of hippocampal BDNF mRNA in animals (Smith et al, 1995; Vaidya et al, 1997; Nibuya et al, 1999; Duman, 2004; Duman and Monteggia, 2006). Decreased serum BDNF levels have been found in patients with mood disorder and those under inordinate amounts of stress or in depressed states (Licinio and Wong, 2002; Shimizu et al, 2003; Karege et al, 2005). Moreover, postmortem studies have shown that patients who were depressed at the time of death have decreased levels of BDNF as well as TrkB (Chen et al, 2001b; Dwivedi et al, 2003). Acute behavioral stress has been associated with a decrease in the levels of 5-HTT mRNA in the raphe (Vollmayr et al, 2000). Other studies have shown disturbances in the serotonergic system at the level of their receptors in the hippocampus with different chronic stress paradigms in tree shrews and rodents (Flugge, 1995; Flugge et al, 1998). Since the influence of stress in the downregulation of BDNF is not significantly altered in adrenalectomized rats, it is unlikely that glucocorticoid misregulation alone can fully explain the decrease in BDNF expression by stress (Smith et al, 1995).
Several monoamine systems including serotonin are profoundly influenced by stress. Thus, it has been hypothesized that the stress-induced downregulation of BDNF could be mediated, at least in part, by alterations in the serotonergic system. For example, one study reported that the stress-induced reduction in BDNF mRNA can, at least in part, be prevented by pre-treatment with a 5-HT2A receptor antagonist (Vaidya et al, 1997, 1999). While this may seem counterintuitive since 5-HT2A receptors downregulate cAMP production, which should lead to a decrease in BDNF transcription, the authors propose that the 5-HT2A receptors are located on GABAergic interneurons and that their activation increases inhibitory postsynaptic potentials (IPSPs). The resultant decrease in activity in excitatory neurons could underlie the observed downregulation of BDNF. Moreover, several studies have shown that SSRI treatment, which increases synaptic serotonin levels, can reverse the stress-induced downregulation of BDNF gene expression (Aydemir et al, 2005; Gervasoni et al, 2005; Gonul et al, 2005). In summary, stress generally inhibits BDNF gene expression, and some evidence suggests that this effect is, at least in part, mediated by a reduction in serotonin signaling.
Almost all clinically used antidepressants increase the extracellular concentrations of the monoamines serotonin or norepinephrine either by inhibiting their re-uptake from the synapse of by blocking their degradation by inhibiting the monoamine oxidase (Duman et al, 1997; Nestler et al, 2002; Castren, 2005). Serotonin reuptake inhibiting drugs (SRIs) are commonly used for the treatment of both depression and anxiety. While SRIs immediately prevent the uptake of 5-HT from the extracellular space, it takes several weeks of continuous administration to observe therapeutic effects for these drugs in relieving depression and anxiety (Kreiss and Lucki, 1995; Duman et al, 1997; Hervas and Artigas, 1998; Trillat et al, 1998; Malagie et al, 2001; Nestler et al, 2002). Such observations have helped to generate a hypothesis positing that the therapeutic actions of SRIs necessitate evoking adaptive structural and functional changes at the synapse. In particular, it has been suggested that underlying these changes in plasticity may be changes in the expression, secretion, or downstream functioning of BDNF (Duman et al, 1997; Castren, 2004a, 2004b).
The first clues linking expression of BDNF to the therapeutic actions of SRIs came from studies showing chronic antidepressant treatment leads to elevations in BDNF transcript levels in the rodent in both the hippocampus and the cortex (Nibuya et al, 1995, 1996). In studies extended to humans, it has been shown that expression of BDNF is increased in patients receiving antidepressant mediation at the time of suicidal death (Chen et al, 2001b; Dwivedi et al, 2003; Karege et al, 2005). It has been shown that direct infusions of BDNF protein into the rodent hippocampus mimic some of the antidepressant effects (Siuciak et al, 1997; Shirayama et al, 2002). Recent studies have further supported the idea that BDNF is a mediator of the antidepressant response. For example, mice engineered with a forebrain-specific knockout of BDNF do not show differences in depressive-like behaviors per se, but fail to respond to antidepressants (Monteggia et al, 2004). This effect is phenocopied in mice that are deficient in BDNF or TrkB signaling, further suggesting that BDNF signaling via TrkB is important for mediating a response to antidepressants (Saarelainen et al, 2003). A major unanswered question is to what degree the effects of antidepressants are mediated via BDNF signaling. In order to examine whether the extent with which BDNF mediates antidepressant responses, several key experiments are warranted: (1) can treatment with BDNF mimic any or all antidepressant effects; and (2) can blocking BDNF expression or TrkB signaling completely or partially prevent antidepressant effects. Testing these ideas, however, is not simple. Although the regulation of BDNF mRNA by stress and antidepressants appears to be fairly robust, the quantification of BDNF protein in the brain after these manipulations has lagged (Duman and Monteggia, 2006). Furthermore, proBDNF and mBDNF can elicit different and often opposing effects and currently there is no easy way to distinguish between the two. However, future experiments using mutant mice blocking the downstream signaling of mBDNF (TrkB mutants) and proBDNF (p75NTR mutants) or newly designed more specific mouse models (ie uncleavable proBDNF transgenics) may help to discern the effects of pro- vs mature BDNF in the mediation of depression and the antidepressant response.
While nearly all effective antidepressant therapies have been shown to lead to increases in levels of BDNF mRNA, specific mechanisms underlying regulation of BDNF expression/functions by stress, 5-HT or antidepressants remain largely unknown. One idea postulates that stress and/or antidepressants can alter the expression or activation (phosphorylation) of CREB, a key transcription factor involved in activity-dependent promoter III-mediated BDNF transcription (Nibuya et al, 1996; Conti et al, 2002). Extensive studies have shown that CREB can be activated via phosphorylation at serine 133 by three signaling pathways: cAMP-PKA, Ca2+-CaMKIV, and MAPK pathways (Shaywitz and Greenberg, 1999). It is plausible that antidepressants could enhance BDNF gene expression by activating CREB through one of these pathways. In support of this idea, it has been shown that acute viral vector-mediated overexpression of CREB in the hippocampus resulted in decreased depressive-like behaviors in rats in a number of different behavioral tasks (Chen et al, 2001a). However, not all of the BDNF promoters contain consensus sites for CREB binding, and it has been shown that the increases in BDNF mRNA resulting from antidepressant treatment come from a wide variety of different combinations of individual BDNF transcripts (Dias et al, 2003). Moreover, CREB-deficient mice actually show an antidepressant phenotype, which is counterintuitive if CREB works to upregulate BDNF (Conti et al, 2002). Clearly, further work is necessary to identify additional pathways through which antidepressants work to activate BDNF gene expression and to better understand the relationship between CREB signaling and upregulation of BDNF in relation to antidepressant treatment and depressive-like behaviors.
The mechanisms underlying promoter III-mediated BDNF transcription have been extensively studied (West et al, 2001). Three calcium-responsive DNA elements (CaREs) have been identified within the BDNF III promoter that are requisite for BDNF transcription: the upstream stimulatory factor sequence which binds USF1/2, the Ca2+-responsive sequence 1 (CaRE 1) which binds a novel calcium response factor (CaRF) (Tao et al, 2002), and the cAMP responsive element (CRE) which binds CREB (Shieh et al, 1998; Tao et al, 1998). Mutation of any of the three elements nearly abolishes calcium induction from promoter III. The necessity for cooperation between these three sites may serve to restrict activation until a number of varied signaling events can be integrated in the activation of these three independent sites.
Recent studies have begun to address how epigenetic mechanisms, which modify gene expression without altering the DNA code may have long-lasting effects in mature neurons that could be relevant to complex neurological and neuropsychiatric disorders (Tsankova et al, 2007). Chromatin remodeling mechanisms including DNA methylation, histone acetylation/deacetylation, and histone methylation work to reflect states that are either repressive or permissive for gene transcription. It was recently shown that epigenetic modifications may influence antidepressant upregulation and stress-induced downregulation of BDNF transcription from specific exons (Tsankova et al, 2006). Specifically, it was shown that social defeat stress induced long-lasting downregulation of BDNF transcripts III and IV by increasing repressive histone methylation on the chromatin surrounding their individual promoters. Chronic imipramine treatment was able to reverse this downregulation by inducing permissive histone acetylation at these same promoters. Further, imipramine treatment was associated with downregulation of the histone deacetylase 5 (HDAC5), which helped to promote acetylation at these promoters (Tsankova et al, 2006). Thus, inhibition of HDAC5 may be at least one mechanism underlying the upregulation of BDNF gene expression by antidepressants while a mechanism leading to enrichment of histone dimethylation at histone 3-lysine 27 (H3-K27) could be an important function in the downregulation of BDNF in response to stress.
Interestingly, acute antidepressant treatment is sufficient to exert effects on FST/TST, whereas chronic (21 days) administration is required to elicit many of the clinical benefits of antidepressants, which correlates with the time course of expression of BDNF and TrkB mRNAs in wild-type mice (Nibuya et al, 1995). There is clearly a discrepancy between the time course of increase in 5-HT (min) and that of increase in BDNF gene expression (days), induced by antidepressants. Thus, the rapid effects of antidepressants on FST/TST are likely mediated by an acute increase in BDNF secretion and/or TrkB signaling (Saarelainen et al, 2003), rather than by an enhancement of BDNF/TrkB gene expression. Future experiments should determine the behavioral effects of chronic treatment with antidepressants in BDNF and TrkB mutant mice. Regardless of their time courses or the underlying mechanisms, these data raise the interesting possibility that antidepressants elicit their effects by activating the BDNF–TrkB pathway.
GENETIC INTERACTION BETWEEN BDNF AND 5-HT IN PSYCHIATRIC DISORDERS
BDNF Mutant Mice
BDNF+/− mice develop several behavioral abnormalities, two of which, aggression and hyperphagia, are strikingly similar to those seen in 5-HT1B and 5-HT2C receptor knockout mice, respectively (Hen, 1996). Both phenotypes have been partially attributed to dysfunction of the 5-HT system for several reasons (Lyons et al, 1999). First, levels of postsynaptic 5-HT receptors (1A, 1B, 2A, and 2C) mRNA, as well as serotonergic neurotransmission, are significantly reduced in various brain region of young adult BDNF+/− mice (Lyons et al, 1999). Secondly, c-fos induction in response to increased synaptic serotonin is also reduced (Lyons et al, 1999). Finally, the rate of 5-HT clearance is retarded in BDNF+/− mice, and this effect can be mediated by decreased 5-HTT function (Daws et al, 2007). Thus, endogenous BDNF regulation of aggression and appetite may be mediated by the 5-HT signaling system.
Given that levels of BDNF mRNA in the hippocampus of postmortem brains from depressed patients are reduced, one might predict that BDNF mutant mice would exhibit depressive-like behaviors. However, the bulk of studies addressing this issue have not borne out such a conclusion. BDNF+/− mice do not appear to behave abnormally in a number of depression-related behavioral tests (MacQueen et al, 2001; Saarelainen et al, 2003; Chourbaji et al, 2004). One report claims that BDNF+/− mice are impaired in the learned helplessness paradigm, which is considered a measure of behavioral despair (MacQueen et al, 2001), but this effect could be interpreted as resulting from their decreased pain sensitivity (Duman and Monteggia, 2006). No difference was observed between wild type and BDNF+/− mice in basal immobility in the forced swim test, an additional test of depressive-like behavior (MacQueen et al, 2001; Saarelainen et al, 2003; Chourbaji et al, 2004). In forebrain-specific BDNF knockouts, 5-HT1A receptor function, but not density, was attenuated (Hensler et al, 2007). This functional deficit in 5-HT1A receptor is restricted to the hippocampus and appears to be related to the loss of response to chronic corticosterone treatment. Taken together, while BDNF may be a target of antidepressants, it seems less likely that impairment in BDNF signaling is the major cause of depression. However, it is important to note that behavioral tests to model depression and anxiety are far from perfect and may only be modeling specific facets of these diseases. The lack of better behavioral assays could also be contributing to confounding the ability to determine whether and to what extent BDNF is involved in depression, the antidepressant response and/or in anxiety. It should be noted, however, that two recent studies have shown ‘depressive like’ behaviors in two separate sets of BDNF conditional mouse lines, using the FTS and the TST (Chan et al, 2006; Monteggia et al, 2007). Thus, further studies are necessary to sort out the conflicting results, and establish that BDNF signaling (or lack of) does not contribute directly ‘depressive-like’ behaviors per se.
Further supporting the main role of BDNF as mediating an antidepressant response, enhanced BDNF signaling resulting from overexpression of the full-length TrkB receptor (trkB.TK+), results in an antidepressant-like behavioral response (Koponen et al, 2005). TrkB.TK+ mice display increased latency to immobility in the forced swim test, suggesting an increase in resistance to ‘behavioral despair,’ which is an excellent predictor of antidepressant efficacy. Fluoxetine was able to increase the latency to immobility in wild-type mice to similar levels as the TrkB.TK+ mice. Despite the differences in resistance to behavioral despair observed between the TrkB.TK+ and the wild-type mice, only minor differences in levels of brain monoamines were observed (Koponen et al, 2005).
Clinical depression may not be triggered by deficits in BDNF signaling alone, but rather, may require impairments in multiple pathways. Alternatively, downregulation of BDNF/TrkB could be compensated by upregulation of other neurotrophic or growth factors. Another possibility is that genetic or environmental factors may contribute to the development of depression through mechanisms completely independent of BDNF, and that antidepressants, via activation of BDNF–TrkB signaling, may interfere with these mechanisms to attenuate depressive behaviors. Moreover, it is important to note that antidepressants are used to treat many different psychiatric conditions, including a variety of anxiety disorders. Indeed, another more specific BDNF mutant mouse where the 66th amino acid, valine, is converted into methionine (Val66Met knock-in mice) exhibit increased anxiety-related behaviors (Chen et al, 2006). Treatment with the antidepressant fluoxetine was unable to reverse behavioral anxiety in the Val66Met knock-in mice, suggesting BDNF as a downstream target for the anxiolytic effects of selective serotonin reuptake inhibitors (SSRI) (Chen et al, 2006).
Since the BDNF and serotonergic signaling systems have significant interaction with overlapping functional targets, it might be expected that they would have synergistic effects. This idea was addressed using a double-mutant mouse model (termed sb mice) with one functional allele of BDNF (BDNF+/−) and no functional copies of the 5-HTT (5HTT−/−). Loss of BDNF appears to exacerbate brain monoamine deficiencies and increases stress abnormalities observed in 5-HTT−/− mice (Ren-Patterson et al, 2005). Compared with either wild-type, BDNF+/− or 5HTT−/− mice, the sb mice exhibit lower levels of 5-HT in the hippocampus and hypothalamus, impaired dendritic morphology, and increased anxiogenic behavior. Furthermore, sb mice exhibit much higher levels of the stress hormone ACTH and increased corticosterone in response to stressful stimuli. Interestingly, male mice have more pronounced deficits than females, and the gender difference could be explained, at least in part, by lower levels of TrkB expression in males (Ren-Patterson et al, 2006). These data support the hypothesis that loss of BDNF expression interacts with serotonin and related circuitry that are involved in modulating anxiogenic behaviors as well as the stress-response machinery.
Genetic epistasis between these two systems has also been observed in humans. Two common functional alleles of the 5-HTT gene have been identified in the human genome. The short (‘s’) allele encodes an attenuated promoter segment associated with reduced transcription and function of the serotonin transporter, as compared to the long (‘l’) allele (Lesch et al, 1994). In a recent study, Kaufman et al found that children carrying the met allele of the BDNF gene val66met polymorphism and two short alleles (s/s) of 5-HTTLPR had the highest depression scores, but that this vulnerability was only evident in children with maltreatment history (Kaufman et al, 2006). This result is somewhat surprising, because most reports studying the val66met polymorphism have suggested that the met allele is protective for anxiety (Lang et al, 2005; Hunnerkopf et al, 2007) depression (Schumacher et al, 2005; Strauss et al, 2005; Frodl et al, 2007), but see Jiang et al (2005), and bipolar disorder (Neves-Pereira et al, 2002; Sklar et al, 2002). Indeed, in a separate study, the prevalence of depression due to multiple life events was found to be dramatically increased in s/s elders with one met allele (Kim et al, 2007). Moreover, structural neuroimaging reveals that the met allele of BDNF gene has a protective effect on the impact of 5HTTLPR s allele on amygdale-anterior cingulate cortex circuitry, a neuronal loop that has been implicated in both depression and anxiety (Weinberger DR, personal communication). Interestingly, the met allele also appears to confer better response of patients with s/s or s/l genotype to lithium, a frontline treatment for the treatment of mania and the prevention of recurrent episodes in bipolar mood disorders (Rybakowski et al, 2007). In addition to the protective effects of the met allele, these findings may help to develop effective treatment plans based on the personalized genetic variations of individuals. In sum, genetic interaction between 5-HTT and BDNF represents a fascinating area of research that requires further investigation.
FUTURE RESEARCH DIRECTIONS
In summary, it is clear that the BDNF and serotonin systems interact with each other to regulate the development and plasticity of neural circuits involved in mood disorders such as antidepressant responses. While much research continues on both of the individual systems regarding their effects and roles in neuropsychiatric diseases, it may be helpful to begin to think about the serial and/or parallel relationship between the two systems, the cause and effect scenarios, and how they interact to regulate major circuits involved in affective behaviors. We believe that understanding the interactions between the two systems as well as how they regulate, enhance, and affect each other, will help us to gain deeper insight into the way that depression, anxiety, and the response to antidepressant drugs may be working at a systems level. This approach, rather than looking at their effects on individual cell populations and molecular pathways may yield a more holistic and clearer picture of how the systems work to regulate mood and anxiety. This type of systems approach to mechanisms by which the brain circuits work in concert will hold the key to understanding how these systems are truly affecting the outcome of these illnesses.
Looking forward to future research on the role and relationships of BDNF and 5-HT pathways in mood regulation and affective disorders, we believe there are a number of important issues. First, how does 5-HT signaling enhance BDNF gene expression and through which downstream pathways does it use to upregulate BDNF gene expression? Specifically, does 5-HT act directly on BDNF-expressing neurons? Simple experiments in culture may help us to determine whether application of 5-HT to hippocampal neurons expressing specific 5-HT receptors leads to increases in BDNF mRNA, and if so which specific transcript(s) of BDNF is elevated. We need to understand which receptors involved in mediating the 5-HT response, and what signals downstream of the receptors (eg calcium) lead to upregulation of specific BDNF transcripts. Second, can antidepressants directly control BDNF gene expression? Given the recent findings that antidepressants regulate BDNF gene expression through epigenetic mechanisms, there exists the possibility that antidepressants interact with nuclear transcription regulators directly. For example, antidepressants may directly bind to HDAC5 or other repressors or activators, leading to an increase in BDNF transcription. Should this be the case, our view that SSRIs work by controlling synaptic 5-HT concentrations needs to be drastically changed. Third, why is chronic antidepressant treatment necessary to mount a therapeutic response? This is puzzling because most current behavioral models (eg forced swim test, tail suspension test, and other models of behavioral despair) do not require chronic treatment, and animals exhibit behavioral responses shortly after administration of antidepressants. Antidepressants may modulate BDNF signaling through two different modes: acute regulation of BDNF secretion and/or TrkB signaling, and chronic regulation of BDNF gene expression. A fast-acting serotonin modulation of BDNF signaling may lead to changes in synaptic plasticity. In contrast, the therapeutic effects of antidepressants require chronic administration to enhance BDNF gene expression, to stimulate neurogenesis in the hippocampal dentate gyrus, and to modify the structure or stability of the synapses. Fourth, an interesting idea is that antidepressants do not affect baseline 5-HT function, but serve to boost 5-HT in the presence of a stressor. Similarly, antidepressants may not affect baseline BDNF expression, but stimulate activity-dependent expression of BDNF, possibly through a de-repression mechanism. It has been shown that promoter III is repressed by an epigenetic mechanism. Thus, antidepressants may affect the phosphorylation of MeCP2, a mechanism which serves to control promoter III-mediated, activity-dependent BDNF transcription. Finally, it is interesting that antidepressants can mediate therapeutic responses to both depressive and anxiety symptoms. One may wonder whether they are working through the same or different mechanisms. It will be interesting to separate these two distinct, but often co-morbid illnesses and to examine the role of antidepressants and BDNF in these behaviors.
DISCLOSURE/CONFLICT OF INTEREST
The author(s) declare that, except for income received from my primary employer, no financial support or compensation has been received from any individual or corporate entity over the past three years for research or professional service and there are no personal financial holdings that could be perceived as constituting a potential conflict of interest.
Anderson KD, Alderson RF, Altar CA, DiStefano PS, Corcoran TL, Lindsay RM et al (1995). Differential distribution of exogenous BDNF, NGF, and NT-3 in the brain corresponds to the relative abundance and distribution of high-affinity and low-affinity neurotrophin receptors. J Compar Neurol 357: 296–317.
Aydemir O, Deveci A, Taneli F (2005). The effect of chronic antidepressant treatment on serum brain-derived neurotrophic factor levels in depressed patients: a preliminary study. Prog Neuropsychopharmacol Biol Psychiatry 29: 261–265.
Barker PA (2004). p75NTR is positively promiscuous: novel partners and new insights. Neuron 42: 529–533.
Baumgarten HG, Grozdanovic Z (1995). Psychopharmacology of central serotonergic systems. Pharmacopsychiatry 28(Suppl 2): 73–79.
Berman ME, Tracy JI, Coccaro EF (1997). The serotonin hypothesis of aggression revisited. Clin Psychol Rev 17: 651–665.
Berton O, McClung CA, Dileone RJ, Krishnan V, Renthal W, Russo SJ et al (2006). Essential role of BDNF in the mesolimbic dopamine pathway in social defeat stress. Science (New York, NY) 311: 864–868.
Bockaert J, Claeysen S, Becamel C, Dumuis A, Marin P (2006). Neuronal 5-HT metabotropic receptors: fine-tuning of their structure, signaling, and roles in synaptic modulation. Cell Tissue Res 326: 553–572.
Brezun JM, Daszuta A (1999). Depletion in serotonin decreases neurogenesis in the dentate gyrus and the subventricular zone of adult rats. Neuroscience 89: 999–1002.
Brezun JM, Daszuta A (2000). Serotonin may stimulate granule cell proliferation in the adult hippocampus, as observed in rats grafted with foetal raphe neurons. Eur J Neurosci 12: 391–396.
Castren E (2004a). Neurotrophic effects of antidepressant drugs. Curr Opin Pharmacol 4: 58–64.
Castren E (2004b). Neurotrophins as mediators of drug effects on mood, addiction, and neuroprotection. Mol Neurobiol 29: 289–302.
Castren E (2005). Is mood chemistry? Nat Rev Neurosci 6: 241–246.
Celada P, Siuciak JA, Tran TM, Altar CA, Tepper JM (1996). Local infusion of brain-derived neurotrophic factor modifies the firing pattern of dorsal raphe serotonergic neurons. Brain Res 712: 293–298.
Chan JP, Unger TJ, Byrnes J, Rios M (2006). Examination of behavioral deficits triggered by targeting Bdnf in fetal or postnatal brains of mice. Neuroscience 142: 49–58.
Chao MV (2003). Neurotrophins and their receptors: a convergence point for many signalling pathways. Nat Rev Neurosci 4: 299–309.
Chaouloff F (1993). Physiopharmacological interactions between stress hormones and central serotonergic systems. Brain Res Brain Res Rev 18: 1–32.
Chen AC, Shirayama Y, Shin KH, Neve RL, Duman RS (2001a). Expression of the cAMP response element binding protein (CREB) in hippocampus produces an antidepressant effect. Biol Psychiatry 49: 753–762.
Chen B, Dowlatshahi D, MacQueen GM, Wang JF, Young LT (2001b). Increased hippocampal BDNF immunoreactivity in subjects treated with antidepressant medication. Biol Psychiatry 50: 260–265.
Chen G, Rajkowska G, Du F, Seraji-Bozorgzad N, Manji HK (2000). Enhancement of hippocampal neurogenesis by lithium. J Neurochem 75: 1729–1734.
Chen ZY, Jing D, Bath KG, Ieraci A, Khan T, Siao CJ et al (2006). Genetic variant BDNF (Val66Met) polymorphism alters anxiety-related behavior. Science (New York, NY) 314: 140–143.
Chourbaji S, Hellweg R, Brandis D, Zorner B, Zacher C, Lang UE et al (2004). Mice with reduced brain-derived neurotrophic factor expression show decreased choline acetyltransferase activity, but regular brain monoamine levels and unaltered emotional behavior. Brain Res Mol Brain Res 121: 28–36.
Conti AC, Cryan JF, Dalvi A, Lucki I, Blendy JA (2002). cAMP response element-binding protein is essential for the upregulation of brain-derived neurotrophic factor transcription, but not the behavioral or endocrine responses to antidepressant drugs. J Neurosci 22: 3262–3268.
Daws LC, Munn JL, Valdez MF, Frosto-Burke T, Hensler JG (2007). Serotonin transporter function, but not expression, is dependent on brain-derived neurotrophic factor (BDNF): in vivo studies in BDNF-deficient mice. J Neurochem 101: 641–651.
De Vivo M, Maayani S (1986). Characterization of the 5-hydroxytryptamine1a receptor-mediated inhibition of forskolin-stimulated adenylate cyclase activity in guinea pig and rat hippocampal membranes. J Pharmacol Exp Therap 238: 248–253.
Dias BG, Banerjee SB, Duman RS, Vaidya VA (2003). Differential regulation of brain derived neurotrophic factor transcripts by antidepressant treatments in the adult rat brain. Neuropharmacology 45: 553–563.
Djalali S, Holtje M, Grosse G, Rothe T, Stroh T, Grosse J et al (2005). Effects of brain-derived neurotrophic factor (BDNF) on glial cells and serotonergic neurones during development. J Neurochem 92: 616–627.
Djavadian RL (2004). Serotonin and neurogenesis in the hippocampal dentate gyrus of adult mammals. Acta Neurobiol Exp 64: 189–200.
Duman RS (2004). Role of neurotrophic factors in the etiology and treatment of mood disorders. Neuromol Med 5: 11–25.
Duman RS, Heninger GR, Nestler EJ (1997). A molecular and cellular theory of depression. Arch Gen Psychiatry 54: 597–606.
Duman RS, Monteggia LM (2006). A neurotrophic model for stress-related mood disorders. Biol Psychiatry 59: 1116–1127.
Dwivedi Y, Rao JS, Rizavi HS, Kotowski J, Conley RR, Roberts RC et al (2003). Abnormal expression and functional characteristics of cyclic adenosine monophosphate response element binding protein in postmortem brain of suicide subjects. Arch Gen Psychiatry 60: 273–282.
Eaton MJ, Whittemore SR (1996). Autocrine BDNF secretion enhances the survival and serotonergic differentiation of raphe neuronal precursor cells grafted into the adult rat CNS. Exp Neurol 140: 105–114.
Egan MF, Kojima M, Callicott JH, Goldberg TE, Kolachana BS, Bertolino A et al (2003). The BDNF val66met polymorphism affects activity-dependent secretion of BDNF and human memory and hippocampal function. Cell 112: 257–269.
Eisch AJ, Bolanos CA, de Wit J, Simonak RD, Pudiak CM, Barrot M et al (2003). Brain-derived neurotrophic factor in the ventral midbrain-nucleus accumbens pathway: a role in depression. Biol Psychiatry 54: 994–1005.
Flugge G (1995). Dynamics of central nervous 5-HT1A-receptors under psychosocial stress. J Neurosci 15: 7132–7140.
Flugge G, Kramer M, Rensing S, Fuchs E (1998). 5HT1A-receptors and behaviour under chronic stress: selective counteraction by testosterone. Eur J Neurosci 10: 2685–2693.
Frodl T, Schule C, Schmitt G, Born C, Baghai T, Zill P et al (2007). Association of the brain-derived neurotrophic factor Val66Met polymorphism with reduced hippocampal volumes in major depression. Arch Gen Psychiatry 64: 410–416.
Fuller RW (1996). The influence of fluoxetine on aggressive behavior. Neuropsychopharmacology 14: 77–81.
Galter D, Unsicker K (2000a). Brain-derived neurotrophic factor and trkB are essential for cAMP-mediated induction of the serotonergic neuronal phenotype. J Neurosci Res 61: 295–301.
Galter D, Unsicker K (2000b). Sequential activation of the 5-HT1 (A) serotonin receptor and TrkB induces the serotonergic neuronal phenotype. Mol Cell Neurosci 15: 446–455.
Gaspar P, Cases O, Maroteaux L (2003). The developmental role of serotonin: news from mouse molecular genetics. Nat Rev Neurosci 4: 1002–1012.
Gentry JJ, Barker PA, Carter BD (2004). The p75 neurotrophin receptor: multiple interactors and numerous functions. Prog Brain Res 146: 25–39.
Gervasoni N, Aubry JM, Bondolfi G, Osiek C, Schwald M, Bertschy G et al (2005). Partial normalization of serum brain-derived neurotrophic factor in remitted patients after a major depressive episode. Neuropsychobiology 51: 234–238.
Goggi J, Pullar IA, Carney SL, Bradford HF (2002). Modulation of neurotransmitter release induced by brain-derived neurotrophic factor in rat brain striatal slices in vitro. Brain Res 941: 34–42.
Gonul AS, Akdeniz F, Taneli F, Donat O, Eker C, Vahip S (2005). Effect of treatment on serum brain-derived neurotrophic factor levels in depressed patients. Eur Arch Psychiatry Clin Neurosci 255: 381–386.
Gould E (1999). Serotonin and hippocampal neurogenesis. Neuropsychopharmacology 21: 46S–51S.
Gross C, Zhuang X, Stark K, Ramboz S, Oosting R, Kirby L et al (2002). Serotonin1A receptor acts during development to establish normal anxiety-like behaviour in the adult. Nature 416: 396–400.
Hen R (1996). Mean genes. Neuron 16: 17–21.
Hensler JG, Advani T, Monteggia LM (2007). Regulation of serotonin-1A receptor function in inducible brain-derived neurotrophic factor knockout mice after administration of corticosterone. Biol Psychiatry 62: 521–529.
Hervas I, Artigas F (1998). Effect of fluoxetine on extracellular 5-hydroxytryptamine in rat brain. Role of 5-HT autoreceptors. Eur J Pharmacol 358: 9–18.
Huang EJ, Reichardt LF (2001). Neurotrophins: roles in neuronal development and function. Ann Rev Neurosci 24: 677–736.
Huang EJ, Reichardt LF (2003). Trk receptors: roles in neuronal signal transduction. Annu Rev Biochem 72: 609–642.
Hunnerkopf R, Strobel A, Gutknecht L, Brocke B, Lesch KP (2007). Interaction between BDNF Val66Met and dopamine transporter gene variation influences anxiety-related traits. Neuropsychopharmacology [E-pub ahead of print].
Ibanez CF (2002). Jekyll–Hyde neurotrophins: the story of proNGF. Trends Neurosci 25: 284–286.
Jiang X, Xu K, Hoberman J, Tian F, Marko AJ, Waheed JF et al (2005). BDNF variation and mood disorders: a novel functional promoter polymorphism and Val66Met are associated with anxiety but have opposing effects. Neuropsychopharmacology 30: 1353–1361.
Kaplan DR, Miller FD (2000). Neurotrophin signal transduction in the nervous system. Curr Opin Neurobiol 10: 381–391.
Karege F, Vaudan G, Schwald M, Perroud N, La Harpe R (2005). Neurotrophin levels in postmortem brains of suicide victims and the effects of antemortem diagnosis and psychotropic drugs. Brain Res Mol Brain Res 136: 29–37.
Kaufman J, Yang BZ, Douglas-Palumberi H, Grasso D, Lipschitz D, Houshyar S et al (2006). Brain-derived neurotrophic factor-5-HTTLPR gene interactions and environmental modifiers of depression in children. Biol Psychiatry 59: 673–680.
Kim JM, Stewart R, Kim SW, Yang SJ, Shin IS, Kim YH et al (2007). BDNF genotype potentially modifying the association between incident stroke and depression. Neurobiol Aging [E-pub ahead of print].
Koponen E, Rantamaki T, Voikar V, Saarelainen T, MacDonald E, Castren E (2005). Enhanced BDNF signaling is associated with an antidepressant-like behavioral response and changes in brain monoamines. Cell Mol Neurobiol 25: 973–980.
Kreiss DS, Lucki I (1995). Effects of acute and repeated administration of antidepressant drugs on extracellular levels of 5-hydroxytryptamine measured in vivo. J Pharmacol Exp Ther 274: 866–876.
Lang UE, Hellweg R, Kalus P, Bajbouj M, Lenzen KP, Sander T et al (2005). Association of a functional BDNF polymorphism and anxiety-related personality traits. Psychopharmacology (Berl) 180: 95–99.
Lebrand C, Cases O, Adelbrecht C, Doye A, Alvarez C, El Mestikawy S et al (1996). Transient uptake and storage of serotonin in developing thalamic neurons. Neuron 17: 823–835.
Lesch KP, Balling U, Gross J, Strauss K, Wolozin BL, Murphy DL et al (1994). Organization of the human serotonin transporter gene. J Neural Trans 95: 157–162.
Lesch KP, Bengel D, Heils A, Sabol SZ, Greenberg BD, Petri S et al (1996). Association of anxiety-related traits with a polymorphism in the serotonin transporter gene regulatory region. Science (New York, NY) 274: 1527–1531.
Lesch KP, Mossner R (1998). Genetically driven variation in serotonin uptake: is there a link to affective spectrum, neurodevelopmental, and neurodegenerative disorders? Biol Psychiatry 44: 179–192.
Lewin GR, Barde Y-A (1996). Physiology of the neurotrophins. Annu Rev Neurosci 19: 289–317.
Licinio J, Wong ML (2002). Brain-derived neurotrophic factor (BDNF) in stress and affective disorders. Mol Psychiatry 7: 519.
Lu B (2003). BDNF and activity-dependent synaptic modulation. Learning Memory 10: 86–98.
Lu B, Chang J (2005). Regulation of neurogenesis by neurotrophins: implications in hippocampus-dependent memory. Neuron Glia Biol 1: 377–384.
Lu B, Je HS (2003). Neurotrophic regulation of the development and function of the neuromuscular synapses. J Neurocytol 32: 931–941.
Lu B, Pang PT, Woo NH (2005). The yin and yang of neurotrophin action. Nat Rev Neurosci 6: 603–614.
Lu B, Woo N (2006). Trophic factors in synaptic plasticity and memory. Neuroscientist 12: 43–56.
Lyons WE, Mamounas LA, Ricaurte GA, Coppola V, Reid SW, Bora SH et al (1999). Brain-derived neurotrophic factor-deficient mice develop aggressiveness and hyperphagia in conjunction with brain serotonergic abnormalities. Proc Natl Acad Sci USA 96: 15239–15244.
MacQueen GM, Ramakrishnan K, Croll SD, Siuciak JA, Yu G, Young LT et al (2001). Performance of heterozygous brain-derived neurotrophic factor knockout mice on behavioral analogues of anxiety, nociception, and depression. Behav Neurosci 115: 1145–1153.
Madhav TR, Pei Q, Zetterstrom TS (2001). Serotonergic cells of the rat raphe nuclei express mRNA of tyrosine kinase B (trkB), the high-affinity receptor for brain derived neurotrophic factor (BDNF). Brain Res 93: 56–63.
Malagie I, Trillat AC, Bourin M, Jacquot C, Hen R, Gardier AM (2001). 5-HT1B Autoreceptors limit the effects of selective serotonin re-uptake inhibitors in mouse hippocampus and frontal cortex. J Neurochem 76: 865–871.
Malberg JE, Eisch AJ, Nestler EJ, Duman RS (2000). Chronic antidepressant treatment increases neurogenesis in adult rat hippocampus. J Neurosci 20: 9104–9110.
Mamounas LA, Altar CA, Blue ME, Kaplan DR, Tessarollo L, Lyons WE (2000). BDNF promotes the regenerative sprouting, but not survival, of injured serotonergic axons in the adult rat brain. J Neurosci 20: 771–782.
Mamounas LA, Blue ME, Siuciak JA, Altar CA (1995). Brain-derived neurotrophic factor promotes the survival and sprouting of serotonergic axons in rat brain. J Neurosci 15: 7929–7939.
Mann JJ (1998). The role of in vivo neurotransmitter system imaging studies in understanding major depression. Biol Psychiatry 44: 1077–1078.
McAllister AK, Katz LC, Lo DC (1999). Neurotrophins and synaptic plasticity. Annu Rev Neurosci 22: 295–318.
Merlio JP, Ernfors P, Jaber M, Persson H (1992). Molecular cloning of rat trkC and distribution of cells expressing messenger RNAs for members of the trk family in the rat central nervous system. Neuroscience 51: 513–532.
Monteggia LM, Barrot M, Powell CM, Berton O, Galanis V, Gemelli T et al (2004). Essential role of brain-derived neurotrophic factor in adult hippocampal function. Proc Natl Acad Sci USA 101: 10827–10832.
Monteggia LM, Luikart B, Barrot M, Theobold D, Malkovska I, Nef S et al (2007). Brain-derived neurotrophic factor conditional knockouts show gender differences in depression-related behaviors. Biol Psychiatry 61: 187–197.
Nestler EJ, Barrot M, DiLeone RJ, Eisch AJ, Gold SJ, Monteggia LM (2002). Neurobiology of depression. Neuron 34: 13–25.
Neves-Pereira M, Mundo E, Muglia P, King N, Macciardi F, Kennedy JL (2002). The brain-derived neurotrophic factor gene confers susceptibility to bipolar disorder: evidence from a family-based association study. Am J Hum Genet 71: 651–655.
Nibuya M, Morinobu S, Duman RS (1995). Regulation of BDNF and trkB mRNA in rat brain by chronic electroconvulsive seizure and antidepressant drug treatments. J Neurosci 15: 7539–7547.
Nibuya M, Nestler EJ, Duman RS (1996). Chronic antidepressant administration increases the expression of cAMP response element binding protein (CREB) in rat hippocampus. J Neurosci 16: 2365–2372.
Nibuya M, Takahashi M, Russell DS, Duman RS (1999). Repeated stress increases catalytic TrkB mRNA in rat hippocampus. Neurosci Lett 267: 81–84.
Okada T, Hashimoto R, Numakawa T, Iijima Y, Kosuga A, Tatsumi M et al (2006). A complex polymorphic region in the brain-derived neurotrophic factor (BDNF) gene confers susceptibility to bipolar disorder and affects transcriptional activity. Mol Psychiatry 11: 695–703.
Pang PT, Teng HK, Zaitsev E, Woo N, Sakata K, Zhen S et al (2004). Cleavage of proBDNF by tPA/plasmin is essential for long-term hippocampal plasticity. Science (New York, NY) 306: 487–491.
Pattabiraman PP, Tropea D, Chiaruttini C, Tongiorgi E, Cattaneo A, Domenici L (2005). Neuronal activity regulates the developmental expression and subcellular localization of cortical BDNF mRNA isoforms in vivo. Mol Cell Neurosci 28: 556–570.
Poo MM (2001). Neurotrophins as synaptic modulators. Nat Rev Neurosci 2: 24–32.
Raymond JR, Mukhin YV, Gelasco A, Turner J, Collinsworth G, Gettys TW et al (2001). Multiplicity of mechanisms of serotonin receptor signal transduction. Pharmacol Therap 92: 179–212.
Ren-Patterson RF, Cochran LW, Holmes A, Lesch KP, Lu B, Murphy DL (2006). Gender-dependent modulation of brain monoamines and anxiety-like behaviors in mice with genetic serotonin transporter and BDNF deficiencies. Cell Mol Neurobiol 26: 755–780.
Ren-Patterson RF, Cochran LW, Holmes A, Sherrill S, Huang SJ, Tolliver T et al (2005). Loss of brain-derived neurotrophic factor gene allele exacerbates brain monoamine deficiencies and increases stress abnormalities of serotonin transporter knockout mice. J Neurosci Res 79: 756–771.
Rios M, Lambe EK, Liu R, Teillon S, Liu J, Akbarian S et al (2006). Severe deficits in 5-HT2A -mediated neurotransmission in BDNF conditional mutant mice. J Neurobiol 66: 408–420.
Rossi C, Angelucci A, Costantin L, Braschi C, Mazzantini M, Babbini F et al (2006). Brain-derived neurotrophic factor (BDNF) is required for the enhancement of hippocampal neurogenesis following environmental enrichment. Eur J Neurosci 24: 1850–1856.
Rumajogee P, Madeira A, Verge D, Hamon M, Miquel MC (2002). Up-regulation of the neuronal serotoninergic phenotype in vitro: BDNF and cAMP share Trk B-dependent mechanisms. J Neurochem 83: 1525–1528.
Russo-Neustadt A, Beard RC, Cotman CW (1999). Exercise, antidepressant medications, and enhanced brain derived neurotrophic factor expression. Neuropsychopharmacology 21: 679–682.
Rybakowski JK, Suwalska A, Skibinska M, Dmitrzak-Weglarz M, Leszczynska-Rodziewicz A, Hauser J (2007). Response to lithium prophylaxis: interaction between serotonin transporter and BDNF genes. Am J Med Genet B Neuropsychiatr Genet 144B: 820–823.
Saarelainen T, Hendolin P, Lucas G, Koponen E, Sairanen M, MacDonald E et al (2003). Activation of the TrkB neurotrophin receptor is induced by antidepressant drugs and is required for antidepressant-induced behavioral effects. J Neurosci 23: 349–357.
Sairanen M, Lucas G, Ernfors P, Castren M, Castren E (2005). Brain-derived neurotrophic factor and antidepressant drugs have different but coordinated effects on neuronal turnover, proliferation, and survival in the adult dentate gyrus. J Neurosci 25: 1089–1094.
Santarelli L, Saxe M, Gross C, Surget A, Battaglia F, Dulawa S et al (2003). Requirement of hippocampal neurogenesis for the behavioral effects of antidepressants. Science (New York, NY) 301: 805–809.
Schumacher J, Jamra RA, Becker T, Ohlraun S, Klopp N, Binder EB et al (2005). Evidence for a relationship between genetic variants at the brain-derived neurotrophic factor (BDNF) locus and major depression. Biol Psychiatry 58: 307–314.
Shaywitz AJ, Greenberg ME (1999). CREB: a stimulus-induced transcription factor activated by a diverse array of extracellular signals. Annu Rev Biochem 68: 821–861.
Shieh PB, Hu SC, Bobb K, Timmusk T, Ghosh A (1998). Identification of a signaling pathway involved in calcium regulation of BDNF expression. Neuron 20: 727–740.
Shimizu E, Hashimoto K, Okamura N, Koike K, Komatsu N, Kumakiri C et al (2003). Alterations of serum levels of brain-derived neurotrophic factor (BDNF) in depressed patients with or without antidepressants. Biol Psychiatry 54: 70–75.
Shirayama Y, Chen AC, Nakagawa S, Russell DS, Duman RS (2002). Brain-derived neurotrophic factor produces antidepressant effects in behavioral models of depression. J Neurosci 22: 3251–3261.
Siuciak JA, Boylan C, Fritsche M, Altar CA, Lindsay RM (1996). BDNF increases monoaminergic activity in rat brain following intracerebroventricular or intraparenchymal administration. Brain Res 710: 11–20.
Siuciak JA, Clark MS, Rind HB, Whittemore SR, Russo AF (1998). BDNF induction of tryptophan hydroxylase mRNA levels in the rat brain. J Neurosci Res 52: 149–158.
Siuciak JA, Lewis DR, Wiegand SJ, Lindsay RM (1997). Antidepressant-like effect of brain-derived neurotrophic factor (BDNF). Pharmacol Biochem Behav 56: 131–137.
Sklar P, Gabriel SB, McInnis MG, Bennett P, Lim YM, Tsan G et al (2002). Family-based association study of 76 candidate genes in bipolar disorder: BDNF is a potential risk locus. Brain-derived neutrophic factor. Mol Psychiatry 7: 579–593.
Smith MA, Makino S, Kvetnansky R, Post RM (1995). Stress and glucocorticoids affect the expression of brain-derived neurotrophic factor and neurotrophin-3 mRNAs in the hippocampus. J Neurosci 15: 1768–1777.
Strauss J, Barr CL, George CJ, Devlin B, Vetro A, Kiss E et al (2005). Brain-derived neurotrophic factor variants are associated with childhood-onset mood disorder: confirmation in a Hungarian sample. Mol Psychiatry 10: 861–867.
Szapacs ME, Mathews TA, Tessarollo L, Ernest LW, Mamounas LA, Andrews AM (2004). Exploring the relationship between serotonin and brain-derived neurotrophic factor: analysis of BDNF protein and extraneuronal 5-HT in mice with reduced serotonin transporter or BDNF expression. J Neurosci Methods 140: 81–92.
Tao X, Finkbeiner S, Arnold DB, Shaywitz AJ, Greenberg ME (1998). Ca2+ influx regulates BDNF transcription by a CREB family transcription factor-dependent mechanism. Neuron 20: 709–726.
Tao X, West AE, Chen WG, Corfas G, Greenberg ME (2002). A calcium-responsive transcription factor, CaRF, that regulates neuronal activity-dependent expression of BDNF. Neuron 33: 383–395.
Teng HK, Teng KK, Lee R, Wright S, Tevar S, Almeida RD et al (2005). ProBDNF induces neuronal apoptosis via activation of a receptor complex of p75NTR and sortilin. J Neurosci 25: 5455–5463.
Trillat AC, Malagie I, Mathe-Allainmat M, Anmella MC, Jacquot C, Langlois M et al (1998). Synergistic neurochemical and behavioral effects of fluoxetine and 5-HT1A receptor antagonists. Eur J Pharmacol 357: 179–184.
Tsankova N, Renthal W, Kumar A, Nestler EJ (2007). Epigenetic regulation in psychiatric disorders. Nat Rev Neurosci 8: 355–367.
Tsankova NM, Berton O, Renthal W, Kumar A, Neve RL, Nestler EJ (2006). Sustained hippocampal chromatin regulation in a mouse model of depression and antidepressant action. Nat Neurosci 9: 519–525.
Tyler WJ, Alonso M, Bramham CR, Pozzo-Miller LD (2002). From acquisition to consolidation: on the role of brain-derived neurotrophic factor signaling in hippocampal-dependent learning. Learn Mem 9: 224–237.
Vaidya VA, Marek GJ, Aghajanian GK, Duman RS (1997). 5-HT2A receptor-mediated regulation of brain-derived neurotrophic factor mRNA in the hippocampus and the neocortex. J Neurosci 17: 2785–2795.
Vaidya VA, Terwilliger RM, Duman RS (1999). Role of 5-HT2A receptors in the stress-induced down-regulation of brain-derived neurotrophic factor expression in rat hippocampus. Neurosci Lett 262: 1–4.
Vollmayr B, Keck S, Henn FA, Schloss P (2000). Acute stress decreases serotonin transporter mRNA in the raphe pontis but not in other raphe nuclei of the rat. Neurosci Lett 290: 109–112.
Weiss S, Sebben M, Kemp DE, Bockaert J (1986). Serotonin 5-HT1 receptors mediate inhibition of cyclic AMP production in neurons. Eur J Pharmacol 120: 227–230.
West AE, Chen WG, Dalva MB, Dolmetsch RE, Kornhauser JM, Shaywitz AJ et al (2001). Calcium regulation of neuronal gene expression. Proc Natl Acad Sci USA 98: 11024–11031.
Zhou FC, Sari Y, Zhang JK (2000). Expression of serotonin transporter protein in developing rat brain. Brain Res Dev Brain Res 119: 33–45.
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Martinowich, K., Lu, B. Interaction between BDNF and Serotonin: Role in Mood Disorders. Neuropsychopharmacol 33, 73–83 (2008). https://doi.org/10.1038/sj.npp.1301571
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