Linking Molecules to Mood: New Insight Into the Biology of Depression
Abstract
Major depressive disorder is a heritable psychiatric syndrome that appears to be associated with subtle cellular and molecular alterations in a complex neural network. The affected brain regions display dynamic neuroplastic adaptations to endocrine and immunologic stimuli arising from within and outside the CNS. Depression's clinical and etiological heterogeneity adds a third level of complexity, implicating different pathophysiological mechanisms in different patients with the same DSM diagnosis. Current pharmacological antidepressant treatments improve depressive symptoms through complex mechanisms that are themselves incompletely understood. This review summarizes the current knowledge of the neurobiology of depression by combining insights from human clinical studies and molecular explanations from animal models. The authors provide recommendations for future research, with a focus on translating today's discoveries into improved diagnostic tests and treatments.
Understanding the molecular mechanisms underlying major depressive disorder is essential because one in six individuals in the United States will develop depressive symptoms requiring treatment (1), depression significantly complicates chronic illness (2), and depression is the leading cause of disability worldwide (3). However, exploring the molecular underpinnings of depression brings substantial challenges. In contrast to the clear-cut phenotypes encountered in substance dependence or obesity, the strictest guidelines for diagnosing depression include elements that are difficult to capture in animal models, e.g., “insomnia or hypersomnia nearly every day” (4). Unlike Parkinson's or Alzheimer's disease, depression lacks any clear consensus neuropathology, rare familial genetic causes, or highly penetrant vulnerability genes, providing no obvious starting points for molecular investigations. In spite of its heritability, the search for genetic causes has not been successful to date. Consequently, progress in understanding the molecular biology of depression has been slow, particularly in comparison to other multifactorial syndromes, such as type 2 diabetes mellitus and cancer. Thus, the burden of depression will continue to increase (3), especially during the extra years of life gained from improved outcomes in cardiovascular disease, cancer, and other domains.
Nevertheless, it is an exciting time to be a depression researcher. Advances in molecular tools and ongoing improvements in behavioral techniques have allowed for genuinely novel insights into depression's neurobiological correlates. Methods to capture and artificially stimulate or inhibit the electrophysiological activity of individual types of neurons in the brain in vivo have added new dimensions to available approaches, permitting us for the first time to describe and manipulate the previously enigmatic neurophysiological correlates of concepts such as “reward” and “anxiety.” Coupled with experimental advances in treatment, these developments suggest we can anticipate that developing tomorrow's therapies will no longer rely solely on modifications of existing agents that were discovered by serendipity six decades ago. Our aim in this review is to provide a framework to interpret continuing advances in the basic science of depression.
Insights From Human Studies
While animal experiments offer a unique opportunity to test cellular and molecular hypotheses, human clinical investigation continues to provide insights about depression that are inaccessible in animals. Postmortem studies designed to capture the neuropathology of depression have largely focused on certain cortical and hippocampal regions, which show a number of subtle differences, such as smaller neuronal size, fewer glial cells, shorter dendrites, and lower levels of trophic factors (5–7). These results agree with evidence of volume loss in these regions as shown by structural magnetic resonance imaging (MRI) (8, 9). Molecular techniques such as DNA microarray profiling have been applied to specific regions, including the amygdala and locus ceruleus, to document gene expression alterations associated with depression (10, 11). Within the coming years, we can hope for a more comprehensive list of depression's neuropathological changes, particularly with the advent of centralized brain collections, which are able to furnish larger samples while simultaneously excluding traditional sources of confound, such as suicide, comorbid substance abuse, and a bipolar diagnosis. When elegantly combined with animal models or neuroimaging data, these postmortem depression studies provide the opportunity to demonstrate true causal relationships (12–15).
Functional MRI and positron emission tomography (PET) have shown how depressive behavior can be correlated with hypermetabolism of the subgenual cingulate cortex and amygdala (16) as well as hypometabolism of the dorsal prefrontal cortex and striatal regions (8). In an attempt to integrate these anatomic data, there have been several formulations of a “depression circuit” (Figure 1). After years of largely empirical reports, we now approach the possibility of testing and refining these circuit models in humans, thanks to recent experimental interventional advances such as deep brain stimulation and repetitive transcranial magnetic stimulation (rTMS). For cases of treatment-resistant depression, deep brain stimulation has been successfully applied to the subgenual cingulate cortex (18, 19) and the ventral striatum/nucleus accumbens (20–22) without known permanent adverse effects in the subjects studied to date. Refinements in stimulation variables for rTMS applied to the dorsolateral pre-frontal cortex have significantly improved the magnitude and endurance of observed antidepressant effects (23). While these techniques are safer than earlier rudimentary approaches to “psychosurgery,” the precise mechanisms by which deep brain stimulation and rTMS act are still incompletely understood. It is not known, for example, whether the local effects of deep brain stimulation work through excitation or inhibition or effects on fibers of passage (24). Recently developed optogenetic tools make it possible to activate or inhibit particular neuronal cell types and/or their terminals within defined brain regions (25), allowing for a deeper exploration of the neurophysiological mechanisms underlying the therapeutic effects of deep brain stimulation. Thus, as deep brain stimulation and rTMS are scaled down and characterized in laboratory animals, one can expect clinical improvements in patient selection, technique, and localization.
With heritability estimates of approximately 40% (26), two main techniques have been utilized to explore the genetics of depression. Candidate genes, identified through an investigator's best guess about etiological mechanisms, have been examined through linkage and genetic association studies (27). Single nucleotide polymorphisms (SNPs) in specific genes, such as GNB3 (for guanine nucleotide-binding protein 3) or MTHFR (for methylene tetrahydrofolate reductase), have survived stringent statistical requirements of meta-analyses. While their odds ratios are too weak for diagnostics or risk stratification, these and other genes may offer new clues into disease pathophysiology (28). Genome-wide association studies are inherently unbiased, as they currently can simultaneously examine up to one million SNPs. While such trials have identified SNPs in previously unappreciated molecules, such as Piccolo (a presynaptic nerve terminal protein) or GRM7 (metabotropic glutamate receptor 7), these findings are themselves of relatively poor statistical significance and are not replicated across studies (27). Several explanations have been put forth, including vague DSM diagnostic criteria, considerable disease heterogeneity, and the relatively potent contribution of ongoing life stressors and epigenetic plasticity. We remain hopeful that within the coming decade, that newer technologies will have greater success and replicability, including “whole-exome” studies (which exclude noncoding regions, representing 99% of the genome) as well as whole-genome sequencing. Of course, a key unanswered question is whether these genetic data should be correlated with DSM diagnostic categories, more broadly across several DSM diagnoses, or with more carefully defined behavioral, endocrine, neurochemical, or neuro-imaging phenotypes. Identifying such genes will be hugely beneficial for the generation of bona fide animal models of depression.
An important insight gained from everyday clinical practice is the observation that monoamine reup-take inhibitors and other modulators of monoaminergic function improve symptoms in about 50% of depressed patients and produce a remission in 30%–40% of patients (29). These data illustrate the tremendous genetic heterogeneity of treatment response, and efforts are under way to identify pharmacogenetic predictors of a favorable treatment response to monoaminergic agents (30, 31). Since monoamine enhancers improve depressive symptoms, it was suggested historically that depression is caused by deficits in monoaminergic transmission. This “monoamine hypothesis” continues to be a prominent preoccupation of the field. However, after more than a decade of PET studies (positioned aptly to quantitatively measure receptor and transporter numbers and occupancy) (32), monoamine depletion studies (which transiently and experimentally reduce brain monoamine levels) (33), and genetic association analyses examining polymorphisms in monoaminergic genes (28, 34, 35), there is little evidence to implicate true deficits in serotonergic, noradrenergic, or dopaminergic neurotransmission in the pathophysiology of depression. This is not surprising, as there is no a priori reason that the mechanism of action of a treatment is the opposite of disease patho-physiology (36). Thus, currently available agents likely restore mood by modulating distinct processes that are unrelated to the primary pathology of depression, just as diuretics improve the symptoms of congestive heart failure without affecting cardiac myocytes directly. Similarly, the success of intravenous ketamine in rapidly alleviating depressive symptoms in treatment-resistant depression (37) has prompted an exploration of the cellular and neuroanatomical substrates for ketamine's actions and the search for ketamine-like therapies that lack psychotomimetic side effects. However, formulating a “glutamatergic hypothesis of depression” is grossly simplistic and only fuels inaccurate public misconceptions of depression's “chemical imbalance,” particularly since more than one-half of all neurons in the brain utilize glutamate as a neurotransmitter.
Animal Models of Depression
The design, application, and relative strengths and limitations of depression models have been discussed in several reviews (1, 38). Without definitive knowledge of pathophysiological processes, these models are often evaluated for their face, construct, and pharmacological validity (1), as are models of other clinically defined neuropsychiatric syndromes, such as autism and schizophrenia. Face validity is a model's symptomatic homology to human depression. Today's depression models achieve this goal to a considerable extent: rodent and primate models have successfully recapitulated states of social withdrawal, hypophagia and weight loss, anhedonia, circadian changes, and abnormalities of the HPA axis, although these phenotypes are generally transient and not all present simultaneously.
The more challenging construct validity is the ability of a model to replicate etiological factors implicated in depression, which are themselves not entirely understood. Most paradigms use some form of stress (of a physical or a psychosocial form), given the known association between independent stressful life events and depressive episodes (39). More recently, a greater emphasis has been placed on replicating both environmental risk factors (such as stressful life events) and genetic risk factors (although these remain largely unknown) in the same model.
Pharmacological or predictive validity is met when a model's depression-like behaviors are reversed by currently available antidepressant modalities, and several models in use today display this type of predictability with the therapeutic delay that characterizes antidepressant responses in humans. However, given that all available pharmacological agents are monoamine modulators and only a minority of patients experience remission after first-line therapies (29), the requirement for pharmacological reversibility is perhaps desirable but not mandatory. Since the mechanisms underlying the delayed antidepressant effects of medication and nonmedication treatments (exercise, electroconvulsive seizures, etc.) remain largely unknown, animal models have been employed to dissect these mechanisms (i.e., models of antidepressant action), with the caveat that these therapies are applied to laboratory animals that generally lack depression-like behavior or any particular genetic vulnerability to depression.
A potential fourth criterion that has received considerably less attention is pathological validity, whereby depression-related physiological, molecular, and cellular abnormalities in animals are validated by demonstrating identical changes in postmortem brain samples from depressed humans. This is a genuinely difficult requirement but has been gaining increasing popularity with the more widespread access to postmortem samples (12–15). Ideally, this criterion might be better addressed through functional imaging studies with depressed patients, but this will require substantial improvements in molecular imaging capabilities.
From an evolutionary perspective, depression may be an analogue of the “involuntary defeat strategy,” occurring when an animal perceives defeat in a hierarchical struggle for resources (40). Hyperarousal, psychomotor retardation, reduced motivation, and sleep alterations in the setting of losing are postulated to have an adaptive advantage in that they serve to protect losers from further attack and focus cognitive resources on planning ways out of complex social problems (41, 42). Most behavioral endpoints in depression models aim to quantitatively assay some type of experimentally induced defeat or despair (Figure 2), even though this aspect of mammalian behavior is likely physiological (i.e., adaptive) rather than pathological. Additionally, while despair behavior is often extrapolated as being depression-like, it is clearly a huge inference to make from rodent models, and most stressors also produce anxiety-like changes that are exaggerated manifestations of the fight-or-fight response (reduced exploration, freezing, hyperthermia, HPA axis activation, etc.). For example, repeated social subordination in mice (social defeat) leads to a long-lasting phenotype of reduced social interaction with other mice. This impairment in sociability can be interpreted as a reduced motivation to interact (an abnormality of reward) or as a heightened avoidance of novel social stimuli (a pathological anxiety response). Distinguishing between these alternative hypotheses is difficult and may even be irrelevant, particularly given the poorly defined neurobiological distinctions between anxiety and depression and their highly variable clinical presentation. In either case, the model employs a naturalistic social-stress-induced behavior that is quantifiable and amenable to experimental manipulation (12–14, 43–52).
The forced-swim and tail-suspension tests are the simplest and most widely used models of depression and antidepressant action. While these approaches have been rightly criticized for involving acute stress and acute antidepressant responses, they have permitted the rapid behavioral screening of novel chemical antidepressants and the phenotyping of genetically altered mutant mice. In certain instances, they have directed the field toward fundamentally novel molecular hypotheses. For example, an antidepressant-like phenotype in the forced-swim test (decreased immobility and greater struggling or swimming) was observed in mice deficient in acid-sensing ion channel 1a (ASIC-1a), a pH-sensitive ion channel expressed in the brain (53). Subsequent studies have shown that ASIC-1a expressed in the amygdala participates in eliciting a fear response to a variety of aversive cues culminating in acidemia (53, 54), implicating inhibitors of ASIC-1a (a previously unappreciated target) as potential therapeutics against anxiety and depressive disorders. Analogous approaches have identified several other novel molecular targets, including p11 (a calcium-binding chaperone molecule that promotes serotonin signaling through the serotonin 1B receptor subtype [15]), TREK-1 (a distinct type of potassium channel that is enriched in depression-related limbic brain regions [55, 56]), ghrelin (a stomach-derived endocrine mediator of energy homeostasis [46]), and many others.
In the following sections, we focus on neurobiological themes that exhibit therapeutic promise. The two main values of using rats and mice to study depression are 1) the ability to describe and characterize neuroplasticity with exquisite spatial and temporal precision and 2) the opportunity to utilize molecular innovations to demonstrate the causative effects of those neuroplastic changes on assays of depression- and antidepressant-like behavior.
Neurogenic and Neurotrophic Theories
The first description of continually dividing neuronal progenitors in the adult mammalian brain offered the promise of solutions for a host of neurodegenerative disorders that so far lack definitive cures (57). Exploring the physiologic role of endogenous neurogenesis, particularly that which occurs in the hippocampal dentate gyrus, has important relevance to the study of psychiatric disease (58). The journey from a hippocampal stem cell in the subgranular zone to a mature dentate gyrus granule cell neuron with appropriate synaptic connections occurs in stages defined by specific cellular markers, with the rates of proliferation and survival modulated by numerous stimuli. Unpredictable stressors, glucocorticoids, drugs of abuse, and high-energy electromagnetic radiation negatively infiuence this process, while antidepressants, voluntary exercise, and environmental enrichment accelerate adult hippocampal neurogenesis (59).
Laboratory rodents have been used extensively to explore the regulation of these new hippocampal neurons and their contribution to depression-related phenotypes. In models of antidepressant action, cranial irradiation (which severely impairs the mitotic potential of hippo-campal stem cells) and aging (another robust negative regulator of adult hippocampal neurogenesis) impair some but not all of the effects of monoamine reuptake inhibitors (60–63), suggesting that these agents may function through neurogenesis-dependent and -independent processes (64). Clearly, only the actions of antidepressants that involve hippocampal circuitry could be mediated through enhanced neurogenesis. Indeed, one study was able to demonstrate the antidepressant effect of a direct intracerebral infusion of bone-marrow-derived mesenchymal stem cells, which both themselves transform into neurons and generate diffusible permissive factors that accelerate endogenous neurogenesis (65). These preliminary results support the idea that enhancing hippocampal neurogenesis (pharmacologically or by way of cellular transplantation) can serve to boost or augment the antidepressant response. At the same time, impairments in the rates of neurogenesis do not appear to be involved in the core features of depression. Following cranial irradiation, mice are unimpaired across several indices of depression-related behavior (60, 62). Consistent with its proposed role in hippocampal-dependent learning (57, 59), adult hippo-campal neurogenesis may play a pathological role in the establishment of aversive memories of traumatic stressors and the sequelae of posttraumatic stress (66). As the field struggles to clarify the functional relevance of these new neurons, stress-induced reductions in hippocampal proliferation are best interpreted as a marker of hippocampal plasticity (which may be impaired in some types of depression).
Another widespread endpoint for assaying the effects of stress, antidepressants, and genetic manipulations is the measurement of levels of brain-derived neurotrophic factor (BDNF) in the hippocampus. This practice, stemming from the “neurotrophic hypothesis” of depression (67), is based on three main observations: an impairment of hippocampal BDNF signaling produces certain depression-related behaviors and impairs the actions of antidepressants (68–70), experimental increases in hippocampal BDNF levels produce antidepressant-like effects (71–73), and hippocampal BDNF levels are low in postmortem samples from depressed humans (6). BDNF is one of numerous growth factors that have been implicated in depression, including firoblast growth factor, vascular endothelial growth factor, and nonacronymic VGF (1). Through modulation of their levels and downstream signaling, these growth factors appear to transduce stressors into lowered rates of adult hippocampal neurogenesis, atrophic changes, and impaired synaptic plasticity of hippocampal neurons, which might (in theory) explain the cognitive impairments and hippocampal atrophy seen in depression (67).
Translating these BDNF findings may not be straightforward. Aside from the challenges associated with synthesizing a specific agonist of BDNF, enhancing BDNF function in the nucleus accumbens and amygdala can have detrimental effects on measures of anhedonia, anxiety, and social interaction in rodents (1, 71). A naturally occurring SNP in BDNF (G196A, Val66Met) results in dramatic alterations in intracellular trafficking of BDNF and its activity-dependent release (1). Meta-analyses show that while the Met allele marginally increases the risk for depression in men but not women, it is also associated with a better antidepressant response (74, 75). A hippo-campus-specific increase in BDNF activity may improve certain cognitive symptoms of depression and facilitate hippocampal neurogenesis (60). While we possess the technology to deliver specific genes into the human brain through viral vectors (76), the beneficial effects of BDNF would have to outweigh potential negative effects, i.e., lower seizure threshold, altered indices of learning and memory, and increased likelihood of malignant transformation (77, 78). Nevertheless, understanding the roles of these growth factors in depression's pathophysiology remains an extremely active area of research, with an emphasis now placed on extrahippocampal trophic signaling and exploring downstream signaling pathways (79), which may have greater pharmaceutical application.
Contribution of Epigenetic Modifications
Biological theories of depression's etiology have traditionally focused on the interplay between genetic risks and environmental/social hazards, with gene-environment interactions invoked to explain how relatively weak genetic vulnerabilities combined with the right environmental triggers may lead to significant psychiatric impairment (80). However, the significant discordance of depression between monozygotic twins (who often share the same environment as well as genes), the remarkably slow progress in identifying genetic risk factors, and depression's twofold female predominance suggest the presence of a third, nongenetic and nonenvironmental component to variability (81). Epi-genetic modifications have been implicated as a significant contributor to this third source of variability and are broadly divided into those that modify DNA directly (e.g., DNA methylation), those that alter histones (e.g., histone acetylation or methylation), and those that involve noncoding RNAs (such as microRNAs) that regulate gene expression (82). In changing DNA's tertiary structure, they adjust interactions between DNA and associated proteins such as transcription factors and RNA polymerases, thereby ultimately altering levels of mRNA expressed by given genes. Pathological epigenetic events have been implicated in numerous chronic diseases, most notably cancer, in which aberrant epigenetic changes promote genetic instability (83).
Through combining animal models with an explosion of novel molecular tools, several epigenetic events have been linked to depression-related behavior and antidepressant action. In rats, offspring born to mothers that display low levels of maternal licking and grooming behavior display exaggerated corticosteroid responses to stress and increased anxiety, which are mediated in part by increased methylation (and subsequent repression) of the glucocorticoid receptor gene promoter in the hippocampus. This type of epigenetic mark is stable to adulthood, reversed by chemical inhibitors of DNA methylation, and entirely dependent on the maternal behavior of the fostering, rather than biological, mother (i.e., independent of germ-line transmission) (84). Early life stress applied to mice produces hypomethylation of the arginine vasopressin (AVP) gene in the hypothalamic paraventricular nucleus, resulting in hypersecretion of AVP, pathologically enhanced serum corticosterone level, and increased depression-like behavior (85). Histone acetylation, a mark of active transcription, is increased at certain BDNF promoters when socially defeated mice receive a course of chronic imipramine, and this hyperacetylation event is mediated by the down-regulation of histone deacetylase 5 (HDAC5) (47). While overexpression of HDAC5 in the hippocampus counteracts the effects of antidepressants, mice that are globally deficient in HDAC5 display an enhanced vulnerability to chronic stress (49).
These examples illustrate the complexity in translating these epigenetic changes into clinical phenomena: while certain perturbations robustly alter epigenetic marks on one gene in one brain region, other brain regions may have opposing changes at distinct genes. Furthermore, most enzymes affected by epigenetic changes occur in several isoforms, each with its own tissue specificity and regulatory factors (e.g., HDAC5 is part of a family of 11 HDAC isoforms that are expressed across all major organ systems [86]), further complicating the development of selective small-molecule antagonists. In spite of this complexity, epigenetic modulators show some promise as treatments for depression. In animal models, systemically or locally administered HDAC inhibitors display antidepressant properties without obvious adverse effects on health (12, 82), suggesting that HDAC inhibitors may function by modulating a global acetylation/deacetylation balance across several brain regions. Of course, histone acetylation functions in concert with several other markers of gene repression and activation, including histone methylation, phosphorylation, sumoylation, and ubiquitination (86). Thus, to comprehensively describe and appreciate the intricacies of depression-related epigenetic plasticity, we can expect a continued evolution in molecular and bioinformatic techniques. Rather than examining candidate genes such as those for BDNF and glucocorticoid receptors, the field has begun to transition toward genome-wide approaches to studying chromatin regulation (48), shifting the focus from “epigenetic marks” to “epigenomic signatures.” As these technologies characterized in mouse and rat models begin to be applied to human postmortem tissue from depressed individuals (87), the ultimate goal would be to use transcriptional and epigenetic profiling as biomarkers to distinguish clinical categories of depressive illness, to determine responsivity to various antidepressant classes, and to differentiate treatment-sensitive from treatment-resistant illness. These profiles may offer new insights into subtype-specific pathophysiology and therapies and aid in the validation of our current animal models.
Role of Dopaminergic Reward Circuits
The dramatic reinforcing properties of direct intracranial self-stimulation in rodents led to the appreciation of a series of subcortical regions critical for reward and appetitive behavior (88). The two main structures implicated by intracranial self-stimulation are the lateral hypothalamus and medial forebrain bundle, the latter containing ascending dopaminergic projections from the ventral tegmental area to the nucleus accumbens (88). Under baseline conditions, dopaminergic neurons in the ventral tegmental area oscillate between tonic patterns of activity (low-frequency regular action potentials) and phasic activity patterns (bursts of action potentials) (89). Unexpected rewards produce a transient increase in phasic firing (encoding a “reward prediction error”), which is sufficient to reinforce antecedent behaviors (25). All major classes of abused drugs appear to “signal” a reward, at least in part, by artificially enhancing dopamine transmission in the nucleus accumbens (for example, cocaine blocks the dopamine transporter) (88).
Given depression's prominent features of anhedonia and appetite alterations, this circuit has become an obvious focus of attention for basic molecular and electrophysiological studies. In rodents, long-term antidepressant administration reduces the firing rates of dopamine neurons in the ventral tegmental area (90). In contrast, psychosocial stressors activate firing in the ventral teg-mental area and increase nucleus accumbens dopamine levels (13, 50, 91), and this may represent a positive coping strategy to enhance motivation during stressful situations (88). One mechanism for this enhanced excitability of the ventral tegmental area may be the reduced activation of the protein kinase AKT, which leads to reductions in local inhibitory neurotransmission (14). Variations in the neuroplastic adaptations expressed by these neurons may also contribute to individual differences in the responsiveness to stress. In the mouse social defeat paradigm, while stress-susceptible mice display enhanced activity in the ventral tegmental area and subsequent BDNF release, stress-resilient mice overcome this excitability change by up-regulating potassium channel subunits expressed by dopamine neurons in the ventral tegmental area that maintain normal tonic firing rates (13, 44). Stress-induced increases in nucleus accumbens BDNF may mediate pathological reward learning such that, following a series of aversive social encounters, the positive rewarding value of social interaction is now modified to have a negative valence (1). Enhanced mesolimbic dopaminergic signaling may explain the reported efficacy of antidopaminergic agents as adjunct antidepressants (92), and by enhancing basal dopaminergic and BDNF signaling, this model may also explain the significant comorbidity of substance dependence and depressive disorders (93, 94).
Nucleus accumbens neurons, anatomically situated to integrate reward-related dopaminergic signals as well as glutamatergic input from the prefrontal cortex, hippo-campus, and amygdala (21), themselves display numerous stress- and antidepressant-induced changes (88). One example is the modulation of cAMP response element binding protein (CREB): while prolonged social isolation stress reduces CREB activity and generates a predominantly anxious phenotype (95), active stressors or drugs of abuse increase CREB activity and promote anhedonia in the presence of a host of natural and drug rewards (88). Neuroimaging studies with depressed humans show that quantitative indices of anhedonia are associated with low nucleus accumbens volume (96) as well as hypoactivation during simple tasks of incentive reward (97, 98). In an attempt to reverse this nucleus accumbens hypoactivation, bilateral deep brain stimulation to this and nearby regions has been successfully applied to several cases of treatment-resistant depression (Figure 3). Consistent with the centralized location of the stimulation, responders displayed normalized PET indices of activity in the nucleus accumbens and the larger ventral striatum, in addition to lower activity in the subgenual cingulate cortex and other prefrontal cortical regions (20, 21). In rats, deep brain stimulation applied to the nucleus accumbens with simultaneous electrophysiological recordings from multiple distant sites has suggested that the therapeutically relevant effects are due to the synchronization of inhibition across a network of cortical and subcortical regions (99), possibly explaining anatomically distant effects of deep brain stimulation. In this way, the application and validation of deep brain stimulation in depression models offers opportunities to improve our circuit models (Figure 1) and shed light on the neurobiological correlates of treatment resistance.
Sex, Steroids, and Immunity
The network of neural substrates involved in depression's symptoms displays a remarkable degree of plasticity in response to a host of peripherally derived chemical stimuli, and advancing our understanding of the endocrinology and immunology of depression offers exciting therapeutic avenues. Considerable research in the fild has focused on a central role of a pathologically dysregulated HPA axis (1), whereby stress-induced hypercortisolemia leads to the central down-regulation of glucocorticoid receptors, impairing cortisol's negative feedback and enhancing levels of corticotropin-releasing hormone (CRH) and adrenocorticotrophic hormone (ACTH) (36). This vicious cycle sustains elevated cortisol levels, possibly leading to hippocampal atrophy and reduced rates of neurogenesis, as well as predisposing depressed individuals to insulin resistance and abdominal obesity (100, 101). A large body of clinical and preclinical evidence supports this model. Depressed patients display dexamethasone nonsuppression that is reversed by antidepressant treatment (102), enhanced CSF levels of CRH (103), and alterations in diurnal cortisol rhythms (104). Mice that are treated chronically with glucocorticoids develop anhedonia in conjunction with other molecular correlates of depression (105). In line with these data, chronic glucocorticoid administration reduces hippocampal volume and impairs cognition in humans (106), while the glucocorticoid receptor antagonist mifepristone improves psychotic and depressive symptoms in patients with psychotic major depression (107). Antagonizing CRH signaling, particularly through the CRH1 receptor subtype, leads to strong anxiolytic effects in several rodent models (108). While the validation of CRH1 antagonists for depression and anxiety disorders remains an active area of clinical research, previously tested pharmacological prototypes have failed for a variety of reasons, including off-target hepatotoxicity (109, 110).
This “cortisol hypothesis” represents a vibrant part of the preclinical depression literature: with commercially available glucocorticoid immunoassays, experimental manipulations are often validated as being “prodepressant” or “antidepressant” depending on their effects on baseline or stress-induced glucocorticoid levels. However, several key points argue for a reappraisal of this practice: 1) true hypercortisolemia is rarely observed in outpatient depressed populations and may be associated only with depression severe enough to require hospitalization (111, 112); 2) depressed patients with atypical features and victims of posttraumatic stress tend to display hypocortisolemia (111, 113, 114); and 3) mice designed to display reduced central glucocorticoid receptor signaling (mimicking hypercortisolemic states) and those that centrally overexpress glucocorticoid receptors display identical behavioral and endocrinological phenotypes (115, 116). In spite of the strong immunosuppressant properties of glucocorticoids, levels of circulating proinfiammatory cytokines (taken as a quantitative marker of systemic glucocorticoid-receptor-mediated signaling) are usually elevated in major depression (117); these cytokines include interleukin 1 (IL-1), IL-6, and tumor necrosis factor α. They are themselves sufficient to impair glucocorticoid receptor signaling, and thus, rather than directly affecting HPA function, stress likely leads to glucocorticoid insufficiency through cytokine intermediates (102). Under certain circumstances, this reduced glucocorticoid-receptor-mediated signaling may promote hypercortisolemia, severe insomnia, and hypophagia (melancholic features) but in other conditions may lead to hypocortisolemia, hyperphagia, and fatigue (atypical features). Cytokines themselves play powerful roles in depression-related neuroplasticity: chronic stress produces significant changes in immune function (118), and cytokines induce depression-like behavior when injected into rodents (119). IL-1β is one such cytokine: through the actions of the transcription factor nuclear factor κB, stress-induced increases in IL-1β lead to reductions in hippocampal neurogenesis and anhedonic phenotypes (120).
The greater female predisposition to depression, as well as its greater incidence in postpartum and perimenopausal periods, argue strongly for a thorough understanding of the role of gonadal hormones in affective regulation. The heightened female vulnerability to experience depressive episodes is limited to the postpubertal and premenopausal period, and accordingly, much of the field's emphasis has focused on the neurobiology of estrogen. Studies in rodent models have demonstrated that estrogen has antidepressant properties and also augments antidepressant actions of monoaminergic agents. Conversely, mice lacking aromatase (required for the generation of estrogenic steroids) or estrogen receptor β display aberrant stress-related behavior (121). Consistent with the broad central expression of estrogen receptor β, the antidepressant effects of estrogen signaling have been linked to several neurobiological substrates, including hippocampal neurogenesis, BDNF signaling, serotonergic neurotransmission, and HPA axis function (122).
While this body of evidence may explain how significant fluctuations in hormone levels can trigger depressive episodes, it does not account for the heightened female vulnerability to depression, which is likely as much about female vulnerability factors in responses to depressogenic stimuli as about male resiliency factors. For instance, in comparison to males, female rodents display passive coping strategies and a more pronounced HPA axis activation in response to a variety of stressors. These features can be “masculinized” by providing testosterone during puberty, demonstrating how gender differences in behavioral physiology can be hardwired during certain critical periods (123). Ovariectomy also promotes active stress-related coping, an effect that may be related to estrogen signaling within the nucleus accumbens (124). Aside from hormonal infiuences, it is important to recognize that gender differences also likely arise from numerous genes on sex chromosomes that are unrelated to gonadal function. Through standard genetic engineering techniques, one can create mice that are chromosomally male (i.e., XY) while having female gonads, and vice versa (Figure 4). Studies with this model have shown that while the development and maturation of male copulatory behaviors and sexually dimorphic brain structures depend on gonadal output, other genes on sex chromosomes independently drive other behavioral traits that are relevant to depression, including habit formation, parental and aggressive behaviors, and social interaction (125, 126).
Mediators of Energy Homeostasis
The appetite and metabolic abnormalities associated with depression and depression-related entities range from severe hypophagia and anorexia to binge eating and obesity. A thorough understanding of such complex phenomena requires knowledge about physiological mechanisms of energy homeostasis, which refers to processes that maintain equilibrium between caloric intake and energy expenditure. In mammals, this is achieved largely through the action of circulating hormones that relay information about peripheral energy levels to the brain (127). Two such hormones that have received tremendous attention are leptin and ghrelin (Figure 5). Leptin is synthesized in white adipose tissue and is secreted in times of nutritional excess. Many obese individuals display a hyperleptinemia associated with central leptin resistance (131). In contrast, ghrelin is synthesized by gastric fundus cells and released during times of energy scarcity, and its secretion stimulates caloric intake and energy storage (127). The principal homeostatic site of action of leptin and ghrelin is the hypothalamic arcuate nucleus, where they exert anorexigenic and orexigenic effects, respectively, through a biologically elegant system of neuropeptides. It is interesting that receptors for leptin and ghrelin and receptors for other feeding-related peptides (such as melanin-concentrating hormone, neuropeptide Y, agouti-related peptide, α-melanocyte-stimulating hormone, and orexin [hypo-cretin]) are expressed in several depression-related limbic substrates. In rodents, chronic stress decreases serum leptin levels (132) and increases serum ghrelin (46). The systemic administration of either hormone produces antidepressant effects on the forced-swim test, enhances hippocampal neurogenesis, and improves learning and memory in behavioral and cellular (i.e., long-term potentiation) assays (46, 132–136). Whereas ghrelin and leptin have identical actions in the hippocampus, dopaminergic neurons of the ventral tegmental area are excited by ghrelin and inhibited by leptin (130, 137, 138), which illustrates how their hypothalamic effects on appetite are complemented in the ventral tegmental area through opposite modulation of reward sensitivity.
In addition to persistent deficits in social interaction and anhedonia, mice subjected to chronic social defeat stress display an initial weight loss followed by a prolonged hyperphagic phase, during which they rapidly regain their body weight and eventually gain more weight than do control or stress-resilient animals. This phenomenon is at least partially mediated by both reduced serum leptin levels and central leptin resistance, which ultimately weaken central melanocortinergic signaling, i.e., through the melanocortin 4 receptor (Figure 5). This hypoleptinemia seems to be mediated by enhanced β3-adrenergic signaling, which promotes sympathetically mediated lipolysis. Coadministration of β3-adrenergic antagonists during social defeat prevents the weight gain and reduced leptin but worsens social deficits (51), suggesting that enhanced β3-adrenergic signaling has an adaptive function at the expense of metabolic derangements.
Understanding the hedonic impact of homeostatic signals provides numerous targets for pharmaceutical development in depressive disorders, particularly in cases associated with significant metabolic abnormalities. An obvious example would be in cases of HIV- or cancer-related cachexia, where artificially enhancing ghrelin or attenuating melanocortin signaling would have therapeutic hyperphagic and antidepressant effects. Nonpeptide antagonists of the melanocortin 4 receptor have already been shown to exert antidepressant and anxiolytic effects in animal models (129). Conversely, patients with comorbid depression and obesity (139) might benefit from therapies designed to alleviate central leptin resistance (a challenging objective). Elucidating such therapies will require a deep understanding of the anatomy and physiology of leptin receptor signaling and of numerous other feeding-related peptides. This is an exciting area of active research.
Conclusions and Perspectives on the Future
Today's approaches to dissecting the neurobiology of depression employ an unprecedented array of experimental techniques in humans and animals, including genome-wide DNA sequencing, chromatin immunoprecipitation to study epigenetic factors, functional brain imaging, opto-genetic electrophysiological tools, viral-mediated gene transfer, and an impressive assortment of genetic mutant mice. The list of molecular players involved in depression's phenotypes has now expanded to include genes from diverse aspects of cellular physiology, such as numerous neurotransmitter and neuropeptide systems, steroid hormones, neurotrophic and cytokine signaling cascades, ion channels, histone deacetylases, circadian genes (88, 108), transcription factors (e.g., CREB, nuclear factor κB, and ΔFosB [43]), p11, and many others. Most of the new targets are derived from experiments in rodents and while these studies are scientifically sound, the targets themselves may or may not be therapeutically relevant or feasible for human depression. Beyond the synthetic obstacles to designing safe and effective small-molecule modulators or viral vectors for use in depressed humans, a key challenge will be to prioritize these targets and develop collaborative efforts to rule them in or out at a reasonable pace.
A large and unacceptable divide continues to exist between animal studies and human clinical investigation. An important example involves our appreciation of cortical contributions to depression: while human neuroimaging studies repeatedly implicate cortical subregions, such as the subgenual cingulate and orbitofrontal cortex, the vast majority of rodent studies limit their analyses to the hippocampus or amygdala. While studying cortical circuits in rodents is more challenging, the human findings clearly demonstrate the high priority of this work. Many reports in the basic literature focus on drastic behavioral and neurobiological phenotypes in constitutive knockout mice, even though homozygous human “knockouts” presumably are a negligible contribution to clinical depression. As progress in delineating the genetics of depression continues, it will be crucial to complement knockout studies by examining molecular and epigenetic mechanisms underlying individual variability and understanding the cellular and physiological consequences of psychiatrically relevant human SNPs. Finally, pathological validation using postmortem brain tissue provides a crucial link between our inherently limited laboratory models and the molecular enigmas of human depression.
Human studies must also mature. Observational studies that measure serum BDNF or glucocorticoid levels can expand to include multiple measures such as serum leptin, ghrelin, and thyroid hormone levels and metabolic status, to name just a few, as well as segregating patients into depressive subtypes. Brain imaging experiments continue to largely focus on volume or activity measures of particular brain regions or on monoamine receptor/ transporter occupancy. It is essential to vastly expand the range of proteins that can be assessed in the living brain so that proteins at the heart of pathophysiological models in rodents can at last be analyzed in depressed patients. As informed clinicians and scientists in the field, we have a responsibility to expand the horizon of our investigations and constantly reassess our analytic methods and theoretical paradigms. We should look well beyond monoamines, cortisol, BDNF, and the hippocampus to determine tomorrow's novel medical and surgical therapeutic avenues for depression.
1. : The molecular neurobiology of depression. Nature 2008; 455:894-902Crossref, Medline, Google Scholar
2. : Mood disorders in the medically ill: scientific review and recommendations. Biol Psychiatry 2005; 58:175-189Crossref, Medline, Google Scholar
3. : The global burden of disease, 1990- 2020. Nat Med 1998; 4:1241-1243Crossref, Medline, Google Scholar
4.
5. : Through the looking glass: examining neuroanatomical evidence for cellular alterations in major depression. J Psychiatr Res 2009; 43:947-961Crossref, Medline, Google Scholar
6. : Neurotrophin levels in postmortem brains of suicide victims and the effects of antemortem diagnosis and psychotropic drugs. Brain Res Mol Brain Res 2005; 136:29-37Crossref, Medline, Google Scholar
7. : Association of anxiety and depression with microtubule-associated protein 2- and synaptopodin-immunolabeled dendrite and spine densities in hippocampal Ca3 of older humans. Arch Gen Psychiatry 2010; 67:448-457Crossref, Medline, Google Scholar
8. : Bipolar and major depressive disorder: neuroimaging the developmental-degenerative divide. Neurosci Biobehav Rev 2009; 33:699-771Crossref, Medline, Google Scholar
9. : Hippocampal volume and depression: a meta-analysis of MRI studies. Am J Psychiatry 2004; 161:1957-1966Link, Google Scholar
10. : Altered expression of glutamate signaling, growth factor, and glia genes in the locus coeruleus of patients with major depression. Mol Psychiatry 2010; 4 13 [Epub ahead of print]Medline, Google Scholar
11. : A molecular signature of depression in the amygdala. Am J Psychiatry 2009; 166:1011-1024Link, Google Scholar
12. : Anti-depressant actions of histone deacetylase inhibitors. J Neurosci 2009; 29:11451-11460Crossref, Medline, Google Scholar
13. : Molecular adaptations underlying susceptibility and resistance to social defeat in brain reward regions. Cell 2007; 131:391-404Crossref, Medline, Google Scholar
14. : AKT signaling within the ventral tegmental area regulates cellular and behavioral responses to stressful stimuli. Biol Psychiatry 2008; 64:691-700Crossref, Medline, Google Scholar
15. : Alterations in 5-Ht1b receptor function by P11 in depression-like states. Science 2006; 311:77-80Crossref, Medline, Google Scholar
16. : Targeting abnormal neural circuits in mood and anxiety disorders: from the laboratory to the clinic. Nat Neurosci 2007; 10:1116-1124Crossref, Medline, Google Scholar
17. : Targeted electrode-based modulation of neural circuits for depression. J Clin Invest 2009; 119:717-725Crossref, Medline, Google Scholar
18. : Deep brain stimulation for treatment-resistant depression. Neuron 2005; 45:651-660Crossref, Medline, Google Scholar
19. : Subcallosal cingulate gyrus deep brain stimulation for treatment-resistant depression. Biol Psychiatry 2008; 64:461-467Crossref, Medline, Google Scholar
20. : Nucleus accumbens deep brain stimulation decreases ratings of depression and anxiety in treatment-resistant depression. Biol Psychiatry 2010; 67:110-116Crossref, Medline, Google Scholar
21. : Deep brain stimulation to reward circuitry alleviates anhedonia in refractory major depression. Neuropsychopharmacology 2008; 33:368-377Crossref, Medline, Google Scholar
22. : Deep brain stimulation of the ventral capsule/ventral striatum for treatment-resistant depression. Biol Psychiatry 2009; 65:267-275Crossref, Medline, Google Scholar
23. : Has repetitive transcranial magnetic stimulation (RTMS) treatment for depression improved? a systematic review and meta-analysis comparing the recent vs the earlier RTMS studies. Acta Psychiatr Scand 2007; 116:165-173Crossref, Medline, Google Scholar
24. : Mechanisms of action of deep brain stimulation (DBS). Neurosci Biobehav Rev 2008; 32:388-407Crossref, Medline, Google Scholar
25. : Phasic firing in dopaminergic neurons is sufficient for behavioral conditioning. Science 2009; 324:1080- 1084Crossref, Medline, Google Scholar
26. : A Swedish national twin study of lifetime major depression. Am J Psychiatry 2006; 163:109-114Link, Google Scholar
27. : The genetics of major depression: moving beyond the monoamine hypothesis. Psychiatr Clin North Am 2010; 33:125-140Crossref, Medline, Google Scholar
28. : Meta-analyses of genetic studies on major depressive disorder. Mol Psychiatry 2007; 13:772-785Crossref, Medline, Google Scholar
29.
30. : A genomewide association study of citalopram response in major depressive disorder. Biol Psychiatry 2010; 67:133-138Crossref, Medline, Google Scholar
31. : Genetic predictors of response to antidepressants in the GENDEP project. Pharmacogenomics J 2009; 9:225-233Crossref, Medline, Google Scholar
32. : Molecular tools for assessing human depression by positron emission tomography. Eur Neuropsychopharmacol 2009; 19:611-628Crossref, Medline, Google Scholar
33. : Mood is indirectly related to serotonin, norepinephrine and dopamine levels in humans: a meta-analysis of monoamine depletion studies. Mol Psychiatry 2007; 12:331-359Crossref, Medline, Google Scholar
34. : Genome-wide association study of recurrent major depressive disorder in two European case-control cohorts. Mol Psychiatry 2008; 15:589-601Crossref, Medline, Google Scholar
35. : Interaction between the serotonin transporter gene (5-HTTLPR), stressful life events, and risk of depression: a meta-analysis. JAMA 2009; 301:2462-2471Crossref, Medline, Google Scholar
36. : Neurobiology of depression. Neuron 2002; 34:13-25Crossref, Medline, Google Scholar
37. : A randomized trial of an N-methyl-D-aspartate antagonist in treatment-resistant major depression. Arch Gen Psychiatry 2006; 63:856-864Crossref, Medline, Google Scholar
38. : Animal models of mood disorders: recent developments. Curr Opin Psychiatry 2007; 20:1-7Crossref, Medline, Google Scholar
39. : Causal relationship between stressful life events and the onset of major depression. Am J Psychiatry 1999; 156:837-841Link, Google Scholar
40. : A new comprehensive evolutionary model of depression and anxiety. J Affect Disord 2008; 106:219-228Crossref, Medline, Google Scholar
41. : Is depression an adaptation? Arch Gen Psychiatry 2000; 57:14-20Crossref, Medline, Google Scholar
42. : Toward a revised evolutionary adaptationist analysis of depression: the social navigation hypothesis. J Affect Disord 2002; 72:1-14Crossref, Medline, Google Scholar
43. : Induction of ΔFosB in the periaqueductal gray by stress promotes active coping responses. Neuron 2007; 55:289-300Crossref, Medline, Google Scholar
44. : Essential role of BDNF in the mesolimbic dopamine pathway in social defeat stress. Science 2006; 311:864-868Crossref, Medline, Google Scholar
45. : Orexin signaling mediates the antidepressant-like effect of calorie restriction. J Neurosci 2008; 28:3071-3075Crossref, Medline, Google Scholar
46. : The orexigenic hormone ghrelin defends against depressive symptoms of chronic stress. Nat Neurosci 2008; 11:752-753Crossref, Medline, Google Scholar
47. : Sustained hippocampal chromatin regulation in a mouse model of depression and antidepressant action. Nat Neurosci 2006; 9:519-525Crossref, Medline, Google Scholar
48. : Imipramine treatment and resiliency exhibit similar chromatin regulation in the mouse nucleus accumbens in depression models. J Neurosci 2009; 29:7820- 7832Crossref, Medline, Google Scholar
49. : Histone deacetylase 5 epigenetically controls behavioral adaptations to chronic emotional stimuli. Neuron 2007; 56:517-529Crossref, Medline, Google Scholar
50. : Increased phasic dopa-mine signaling in the mesolimbic pathway during social defeat in rats. Neuroscience 2009; 161:3-12Crossref, Medline, Google Scholar
51. : A beta3-adrenergic-leptin-melanocortin circuit regulates behavioral and metabolic changes induced by chronic stress. Biol Psychiatry 2010; 67:1075-1082Crossref, Medline, Google Scholar
52. : ΔFosB in brain reward circuits mediates resilience to stress and antidepressant responses. Nat Neurosci 2010; 13:745-752Crossref, Medline, Google Scholar
53. : Acid-sensing ion channel-1a in the amygdala, a novel therapeutic target in depression-related behavior. J Neurosci 2009; 29:5381-5388Crossref, Medline, Google Scholar
54. : The amygdala is a chemosensor that detects carbon dioxide and acidosis to elicit fear behavior. Cell 2009; 139:1012-1021Crossref, Medline, Google Scholar
55. : Deletion of the background potassium channel TREK-1 results in a depression-resistant phenotype. Nat Neurosci 2006; 9:1134-1141Crossref, Medline, Google Scholar
56. : Spadin, a sortilin-derived peptide, targeting rodent TREK-1 channels: a new concept in the antidepressant drug design. PLoS Biol 2010; 8(4):e1000355Crossref, Medline, Google Scholar
57. : The neurogenic reserve hypothesis: what is adult hippocampal neurogenesis good for? Trends Neurosci 2008; 31:163-169Crossref, Medline, Google Scholar
58. : Adult hippocampal neurogenesis in depression. Nat Neurosci 2007; 10:1110-1115Crossref, Medline, Google Scholar
59. : Adult neurogenesis, mental health, and mental illness: hope or hype? J Neurosci 2008; 28:11785-11791Crossref, Medline, Google Scholar
60. : High-speed imaging reveals neurophysiological links to behavior in an animal model of depression. Science 2007; 317:819-823Crossref, Medline, Google Scholar
61. : Requirement of hippocampal neurogenesis for the behavioral effects of antidepressants. Science 2003; 301:805-809Crossref, Medline, Google Scholar
62. : Drug-dependent requirement of hippocampal neurogenesis in a model of depression and of antidepressant reversal. Biol Psychiatry 2008; 64:293-301Crossref, Medline, Google Scholar
63. : Ageing abolishes the effects of fluoxetine on neurogenesis. Mol Psychiatry 2009; 14:856-864Crossref, Medline, Google Scholar
64. : Neurogenesis-dependent and -independent effects of fluoxetine in an animal model of anxiety/depression. Neuron 2009; 62:479-493Crossref, Medline, Google Scholar
65. : Mesenchymal stem cells increase hippocampal neurogenesis and counteract depressive-like behavior. Mol Psychiatry 2009; 10 27 [Epub ahead of print]Medline, Google Scholar
66. : Adult hippocampal neurogenesis is functionally important for stress-induced social avoidance. Proc Natl Acad Sci USA 2010; 107:4436-4441Crossref, Medline, Google Scholar
67. : Stress, depression, and neuroplasticity: a convergence of mechanisms. Neuropsychopharmacology 2008; 33:88-109Crossref, Medline, Google Scholar
68. : TrkB regulates hippocampal neurogenesis and governs sensitivity to antidepressive treatment. Neuron 2008; 59:399-412Crossref, Medline, Google Scholar
69. : Brain-derived neurotrophic factor conditional knockouts show gender differences in depression-related behaviors. Biol Psychiatry 2007; 61:187-197Crossref, Medline, Google Scholar
70. : Knockdown of brain-derived neurotrophic factor in specific brain sites precipitates behaviors associated with depression and reduces neurogenesis. Mol Psychiatry 2010; 15:80-92Crossref, Medline, Google Scholar
71. : Transgenic brain-derived neurotrophic factor expression causes both anxiogenic and antidepressant effects. Proc Natl Acad Sci USA 2006; 103:13208-13213Crossref, Medline, Google Scholar
72. : Brain-derived neurotrophic factor produces antidepressant effects in behavioral models of depression. J Neurosci 2002; 22:3251-3261Crossref, Medline, Google Scholar
73. : Central administration of IGFI and BDNF leads to long-lasting antidepressant-like effects. Brain Res 2005; 1037:204-208Crossref, Medline, Google Scholar
74. : Review and meta-analysis of antidepressant pharmacogenetic findings in major depressive disorder. Mol Psychiatry 2010; 15:473-500Crossref, Medline, Google Scholar
75. : Meta-analysis of the BDNF Val66Met polymorphism in major depressive disorder: effects of gender and ethnicity. Mol Psychiatry 2010; 15:260-271Crossref, Medline, Google Scholar
76. : Safety and tolerability of gene therapy with an adeno-associated virus (AAV) borne GAD gene for Parkinson's disease: an open label, phase I trial. Lancet 2007; 369:2097-2105Crossref, Medline, Google Scholar
77. : Peptide immunoreactivity in aged rat cortex and hippocampus as a function of memory and BDNF infusion. Pharmacol Biochem Behav 1999; 64:625-635Crossref, Medline, Google Scholar
78. : Neurotrophin signaling through tropomyosin receptor kinases contributes to survival and proliferation of non-Hodgkin lymphoma. Exp Hematol 2009; 37:1295-1309Crossref, Medline, Google Scholar
79. : Wnt2 expression and signaling is increased by different classes of antidepressant treatments. Biol Psychiatry 2010; 6 4 [Epub ahead of print]Google Scholar
80. : Gene-environment interactions in psychiatry: joining forces with neuroscience. Nat Rev Neurosci 2006; 7:583-590Crossref, Medline, Google Scholar
81. : Molecular studies of major depressive disorder: the epigenetic perspective. Mol Psychiatry 2007; 12:799-814Crossref, Medline, Google Scholar
82. : Epigenetic regulation in psychiatric disorders. Nat Rev Neurosci 2007; 8:355-367Crossref, Medline, Google Scholar
83. : Epigenetics in cancer. Carcino-genesis 2010; 31:27-36Crossref, Medline, Google Scholar
84. : Diet and the epigenetic (re)programming of phenotypic differences in behavior. Brain Res 2008; 1237:12-24Crossref, Medline, Google Scholar
85. : Dynamic DNA methylation programs persistent adverse effects of early-life stress. Nat Neurosci 2009; 12:1559-1566Crossref, Medline, Google Scholar
86. : Epigenetic mechanisms in drug addiction. Trends Mol Med 2008; 14:341-350Crossref, Medline, Google Scholar
87. : Epigenetic regulation in human brain- focus on histone lysine methylation. Biol Psychiatry 2009; 65:198-203Crossref, Medline, Google Scholar
88. : The mesolimbic dopamine reward circuit in depression. Biol Psychiatry 2006; 59:1151-1159Crossref, Medline, Google Scholar
89. : Getting formal with dopamine and reward. Neuron 2002; 36:241-263Crossref, Medline, Google Scholar
90. : Effects of sustained serotonin reuptake inhibition on the firing of dopamine neurons in the rat ventral tegmental area. J Psychiatry Neurosci 2009; 34:223-229Medline, Google Scholar
91. : Social defeat stress selectively alters mesocorticolimbic dopamine release: an in vivo microdialysis study. Brain Res 1996; 721:140-149Crossref, Medline, Google Scholar
92. : Atypical antipsychotic augmentation in major depressive disorder: a meta-analysis of placebo-controlled randomized trials. Am J Psychiatry 2009; 166:980-991Link, Google Scholar
93. : Co-occurring mental and substance use disorders: the neurobiological effects of chronic stress. Am J Psychiatry 2005; 162:1483-1493Link, Google Scholar
94. : Dynamic BDNF activity in nucleus accumbens with cocaine use increases self-administration and relapse. Nat Neurosci 2007; 10:1029-1037Crossref, Medline, Google Scholar
95. : CREB regulation of nucleus accumbens excitability mediates social isolation-induced behavioral deficits. Nat Neurosci 2009; 12:200-209Crossref, Medline, Google Scholar
96. : The role of the nucleus accumbens and rostral anterior cingulate cortex in anhedonia: integration of resting EEG, fMRI, and volumetric techniques. Neuroimage 2009; 46:327-337Crossref, Medline, Google Scholar
97. : fMRI of alterations in reward selection, anticipation, and feedback in major depressive disorder. J Affect Disord 2009; 118:69-78Crossref, Medline, Google Scholar
98. : Reduced caudate and nucleus accumbens response to rewards in unmedicated individuals with major depressive disorder. Am J Psychiatry 2009; 166:702-710Link, Google Scholar
99. : Nucleus accumbens deep brain stimulation produces region-specific alterations in local field potential oscillations and evoked responses in vivo. J Neurosci 2009; 29:5354-5363Crossref, Medline, Google Scholar
100. : A review of the evidence for a neuroendocrine link between stress, depression and diabetes mellitus. Curr Diabetes Rev 2007; 3:252-259Crossref, Medline, Google Scholar
101. : Physiology and neurobiology of stress and adaptation: central role of the brain. Physiol Rev 2007; 87:873-904Crossref, Medline, Google Scholar
102. : Cytokines and glucocorticoid receptor signaling: relevance to major depression. Ann NY Acad Sci 2009; 1179:86-105Crossref, Medline, Google Scholar
103. : Elevated concentrations of CSF corticotropin-releasing factor-like immunoreactivity in depressed patients. Science 1984; 226:1342-1344Crossref, Medline, Google Scholar
104. : Cortisol circadian rhythm alterations in psychotic major depression. Biol Psychiatry 2006; 60:275-281 Crossref, Medline, Google Scholar
105. : Regionally specific regulation of ERK MAP kinase in a model of antidepressant-sensitive chronic depression. Biol Psychiatry 2008; 63:353-359Crossref, Medline, Google Scholar
106. : Effects of glucocorticoids on mood, memory, and the hippocampus: treatment and preventive therapy. Ann NY Acad Sci 2009; 1179:41-55Crossref, Medline, Google Scholar
107. : An 8-week open-label trial of a 6-day course of mifepristone for the treatment of psychotic depression. J Clin Psychiatry 2005; 66:598-602Crossref, Medline, Google Scholar
108. : New approaches to antidepressant drug discovery: beyond monoamines. Nat Rev Neurosci 2006; 7:137-151Crossref, Medline, Google Scholar
109. : Central CRH system in depression and anxiety-evidence from clinical studies with CRH1 receptor antagonists. Eur J Pharmacol 2008; 583:350-357Crossref, Medline, Google Scholar
110. : Emerging targets for antidepressant therapies. Curr Opin Chem Biol 2009; 13:291-302Crossref, Medline, Google Scholar
111. : Thyroid and adrenal axis in major depression: a controlled study in outpatients. Eur J Endocrinol 2005; 152:185- 191Crossref, Medline, Google Scholar
112. : Major depressive disorder and hypothalamic-pituitary-adrenal axis activity: results from a large cohort study. Arch Gen Psychiatry 2009; 66:617-626Crossref, Medline, Google Scholar
113. : Defining the boundaries of atypical depression: evidence from the HPA axis supports course of illness distinctions. J Affect Disord 2005; 86:161-167 Crossref, Medline, Google Scholar
114. : Status of glucocorticoid alterations in post-traumatic stress disorder. Ann NY Acad Sci 2009; 1179:56-69Crossref, Medline, Google Scholar
115. : Acquired deficit of forebrain glucocorticoid receptor produces depression-like changes in adrenal axis regulation and behavior. Proc Natl Acad Sci USA 2005; 102:473-478Crossref, Medline, Google Scholar
116. : Glucocorticoid receptor overexpression in forebrain: a mouse model of increased emotional lability. Proc Natl Acad Sci USA 2004; 101:11851-11856Crossref, Medline, Google Scholar
117. : A meta-analysis of cytokines in major depression. Biol Psychiatry 2010; 67:446-457Crossref, Medline, Google Scholar
118. : Inflammation and its discontents: the role of cytokines in the pathophysiology of major depression. Biol Psychiatry 2009; 65:732-741Crossref, Medline, Google Scholar
119. : Cytokines as mediators of depression: what can we learn from animal studies?. Neurosci Biobehav Rev 2005; 29:891-909Crossref, Medline, Google Scholar
120. : Nuclear factor-κb is a critical mediator of stress-impaired neurogenesis and depressive behavior. Proc Natl Acad Sci USA 2010; 107:2669-2674Crossref, Medline, Google Scholar
121. : Underlying mechanisms mediating the antidepressant effects of estrogens. Biochim Biophys Acta 2009; 11 10 [Epub ahead of print]Medline, Google Scholar
122. : From synapse to nucleus: novel targets for treating depression. Neuropharmacology 2010; 58:683-693Crossref, Google Scholar
123. : Examining the intersection of sex and stress in modelling neuropsychiatric disorders. J Neuroendocrinol 2009; 21:415-420Crossref, Medline, Google Scholar
124. : Role of nuclear factor κb in ovarian hormone-mediated stress hypersensitivity in female mice. Biol Psychiatry 2009; 65:874-880Crossref, Medline, Google Scholar
125. : What does the “four core genotypes” mouse model tell us about sex differences in the brain and other tissues? Front Neuroendocrinol 2009; 30:1-9Crossref, Medline, Google Scholar
126. : Sex chromosome complement regulates habit formation. Nat Neurosci 2007; 10:1398-1400Crossref, Medline, Google Scholar
127. : Homeostatic and hedonic signals interact in the regulation of food intake. J Nutr 2009; 139:629-632Crossref, Medline, Google Scholar
128. : Body weight is regulated by the brain: a link between feeding and emotion. Mol Psychiatry 2005; 10:132-146Crossref, Medline, Google Scholar
129. : Anxiolytic-like and antidepressant-like activities of MCL0129 (1-[(S)-2-(4-fluorophenyl)-2-(4-isopropylpiperadin-1-yl)ethyl]-4-[4-(2-methoxynaphthalen-1-yl)butyl]piperazine), a novel and potent nonpeptide antagonist of the melanocortin-4 receptor. J Pharmacol Exp Ther 2003; 304:818-826Crossref, Medline, Google Scholar
130. : Leptin receptor signaling in midbrain dopamine neurons regulates feeding. Neuron 2006; 51:801-810Crossref, Medline, Google Scholar
131. : Minireview: from anorexia to obesity- the yin and yang of body weight control. Endocrinology 2003; 144:3749-3756Crossref, Medline, Google Scholar
132. : Leptin: a potential novel antidepressant. Proc Natl Acad Sci USA 2006; 103:1593-1598Crossref, Medline, Google Scholar
133. : Leptin increases adult hippocampal neurogenesis in vivo and in vitro. J Biol Chem 2008; 283:18238-18247Crossref, Medline, Google Scholar
134. : Ghrelin regulates hippocampal neurogenesis in adult mice. Endocr J 2009; 56:525-531 Crossref, Medline, Google Scholar
135. : Ghrelin controls hippocampal spine synapse density and memory performance. Nat Neurosci 2006; 9:381-388 Crossref, Medline, Google Scholar
136. : Leptin facilitates learning and memory performance and enhances hippocampal CA1 long-term potentiation and CaMK II phosphorylation in rats. Peptides 2006; 27:2738-2749Crossref, Medline, Google Scholar
137. : Ghrelin modulates the activity and synaptic input organization of midbrain dopamine neurons while promoting appetite. J Clin Invest 2006; 116:3229-3239Crossref, Medline, Google Scholar
138. : Leptin regulation of the mesoaccumbens dopamine pathway. Neuron 2006; 51:811-822Crossref, Medline, Google Scholar
139. : Overweight, obesity, and depression: a systematic review and meta-analysis of longitudinal studies. Arch Gen Psychiatry 2010; 67:220-229Crossref, Medline, Google Scholar