Abstract
Chronic inflammation in physically ill patients is often associated with the development of symptoms of depression. The mechanisms that are responsible for inflammation-associated depression have been elucidated over the last few years. Kynurenine produced from tryptophan in a reaction catabolized by indoleamine 2,3 dioxygenase is transported into the brain where it is metabolized by microglial enzymes into a number of neurotropic compounds including quinolinic acid, an agonist of N-methyl-d-aspartate receptors. Quinolinic acid can synergize with glutamate released by activated microglia. This chain of events opens the possibility to treat inflammation-induced depression using therapies that target the transport of kynurenine through the blood–brain barrier, the production of quinolinic acid and glutamate by activated microglia, or the efflux of glutamate from the brain to the blood.
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Inflammation is associated with an increased prevalence of major depressive disorders
Major depressive disorders are characterized by a combination of symptoms that interfere with the patient’s inability to function normally. These symptoms as defined by the DSM-IV include persistent depressed mood or irritability, decreased interest or pleasure in most activities, changes in appetite, sleep and activity, fatigue or loss of energy, feelings of guilt and worthlessness, diminished ability to think and concentrate, and suicidality. According to the World Health Organization, major depressive disorders are the second largest burden of disease in the developed world and a leading cause of disability (http://www.who.int/mediacentre/factsheets/fs369/en/index.html). The limited knowledge on the pathophysiology of major depressive disorders remains an important obstacle for the development of effective preventive and curative therapies.
Several converging sources of evidence point to a role for inflammation in the development of symptoms of depression. This is particularly the case in physically ill patients with chronic inflammation as the prevalence of depression in this population can be up to three times higher than in the general population (Evans et al. 2005; Goldberg 2010; Benton et al. 2007). In addition, depression in physically ill patients is associated with increased rates of morbidity and mortality. Several lines of evidence confirm the biological nature of the association between inflammation and depression. At the clinical level, symptoms of depression are associated with increased circulating levels of biomarkers of inflammation such as C-reactive protein and interleukin-6 (IL-6) (Irwin and Miller 2007; Miller et al. 2008). The strongest evidence in favor of a causal role of inflammation in the development of depression comes from the observation that cytokine immunotherapy based on chronic administration of interferon-alpha (IFNα) and/or interleukin-2 (IL-2) to patients with kidney cancer or melanoma with metastasis induces an episode of depression in a significant proportion of patients (Denicoff et al. 1987; Renault et al. 1987). The development of depression is gradual, starting with neurovegetative symptoms akin to sickness (fatigue, loss of appetite, sleep disorders) and culminating with psychologic and cognitive symptoms of depression (Capuron et al. 2002a). Further evidence for a role of inflammation in depression comes from the observation that administration of an antagonist of the proinflammatory cytokine tumor necrosis factor-alpha (TNFα) was found to attenuate depressed mood in patients with psoriasis (Tyring et al. 2006) and in patients with major depressive disorders and increased C-reactive protein (Raison et al. 2013).
Inflammation induces depression by activating the tryptophan degrading enzyme indoleamine 2,3 dioxygenase (IDO)
The mechanisms by which inflammation induces depression have been studied at the preclinical level using acute and chronic activation of the immune system in murine models of depression-like behavior (Dantzer et al. 2008). Acute administration of the cytokine inducer lipopolysaccharide (LPS) via the intraperitoneal route increases the duration of immobility in the forced swim test and the tail suspension test; two behavioral tests that are commonly used to detect the antidepressant properties of drugs (Dantzer et al. 2008). LPS also decreases preference for sucrose when rodents are presented with two bottles, one that contains tap water and the other a solution of sucrose at a concentration close to the detection threshold (Dantzer et al. 2008). This decrease in sucrose preference is interpreted as evidence for anhedonia; the inability to experience reward, which is a key feature of depression. The same effects are observed in animals of which the immune system is chronically stimulated such as during infection with the attenuated form of Mycobacterium bovis, Bacillus Calmette–Guerin (Moreau et al. 2008). As activation of the peripheral immune system is typically associated with behavioral signs of sickness including decreased motor activity and reduced food and water intake, it was important to show that depression-like behavior is not just another expression of sickness. In patients treated chronically with cytokines, there is a temporal dissociation between sickness and depression, with symptoms of sickness appearing first in response to inflammation and symptoms of depression developing later (Capuron et al. 2002b). This temporal dissociation also occurs in animal models of inflammation-induced depression. Signs of sickness appear within 1–2 h in LPS-treated mice. They last for several hours and are usually gone by 24 h. However, mice still show at this time depression-like behavior in the form of increased immobility in the forced swim test and in the tail suspension test as well as reduced preference for a sucrose solution when given the choice between water and a normally preferred sucrose solution (Dantzer et al. 2008). Given that sickness is temporally dissociated from depression-like behavior, it is possible to explore the molecular mechanisms that underpin the transition from sickness to depression-like behavior. Proinflammatory cytokines such as IFNγ and TNFα activate IDO (O’Connor et al. 2009a, b, c). This ubiquitous enzyme metabolizes tryptophan along the kynurenine pathway. Activation of IDO leads to a decrease in circulating levels of tryptophan and an increase in circulating levels of kynurenine (Widner et al. 2002). IDO activation is an important mechanism for the down-regulation of the immune response, as cytotoxic T cells need tryptophan to proliferate and exert their cytotoxic activity. Activation of IDO mediates the development of inflammation-induced depression-like behavior but not the occurrence of sickness. Inhibition of activation of IDO by administration of the competitive inhibitor of IDO, 1-methyl tryptophan, abrogated LPS-induced depressive-like behavior but not LPS-induced sickness responses nor LPS-induced cytokine expression (O’Connor et al. 2009c). In the same manner, genetic deletion of ido1, the gene that codes for IDO, blocked the development of depressive-like behavior induced by inoculation of Bacillus Calmette–Guerin but had no influence on sickness (O’Connor et al. 2009).
Clinical studies have also contributed greatly toward exposing IDO activation by cytokines as a primary mechanistic candidate. As mentioned above, there is a temporal dissociation in the development of symptoms of sickness and depression in patients treated with IFNα (Capuron et al. 2002a). Neurovegetative symptoms of sickness develop in response to the very first injections of IFNα, whereas psychological symptoms of depression including anhedonia, feelings of worthlessness, and suicidal ideation take longer to emerge. Secondly, patients treated with IFNα exhibit decreased circulating levels of tryptophan. This association between enhanced tryptophan degradation and depression has been confirmed in several clinical studies in psychiatric as well as in physically ill patients (Gabbay et al. 2012; Elovainio et al. 2011; Sublette and Postolache 2012; Gold et al. 2011; Swardfager et al. 2009a; Kurz et al. 2011; Raison et al. 2010).
Activation of IDO induces depression-like behavior by a glutamatergic-dependent mechanism
IDO-dependent degradation of tryptophan along the kynurenine pathway can lead to depression either via decreased bioavailability of the essential amino acid tryptophan for the synthesis of serotonin or increased formation of cytotoxic kynurenine metabolites. Tryptophan is an essential amino acid, and its bioavailability is a limiting factor for the synthesis of serotonin. It is therefore tempting to speculate that the IDO-dependent decrease in circulating tryptophan leads to reduced brain serotoninergic neurotransmission. However, the decrease in blood tryptophan that takes place during inflammation does not translate into decreased brain tryptophan (Raison et al. 2010; Walker et al. 2013). An increase in brain tryptophan together with an enhanced turnover of serotonin is actually observed instead in rodents of which the peripheral immune system is activated. Another way serotoninergic neurotransmission can be detrimentally affected is via the up-regulation of the brain serotonin transporter SERT. Proinflammatory cytokines increase the expression of SERT via a mitogen-activated protein kinase p38 pathway. Genetic deletion of SERT abrogates the depression-like behavioral effects of LPS (Zhu et al. 2010; van Heesch et al. 2013) although contradictory results concerning the ability of cytokines to stimulate SERT have been reported (Andreetta et al. 2013).
An alternative hypothesis to that of the tryptophan starvation hypothesis is the formation of potentially neurotoxic kynurenine metabolites downstream of IDO (Schwarcz et al. 2012). Kynurenine is further metabolized to 3-hydroxy kynurenine, a potent free radical donor, and quinolinic acid, a NMDA receptor agonist (Fig. 1). Increased levels of quinolinic acid have been associated with low-grade systemic inflammation and suicide attempts in patients with major depression (Steiner et al. 2011; Erhardt et al. 2013).
The possibility that NMDA receptor activation mediates major depressive disorders stems from the many clinical observations of an improvement in the symptoms of depression such as suicidal ideation and a decrease in the severity of scores on several validated depressive inventories in response to intravenous injection of the NMDA receptor antagonist ketamine (Berman et al. 2000; Larkin and Beautrais 2011; Maeng and Zarate 2007). Animal studies confirm that ketamine has antidepressant properties, as demonstrated by the decrease in immobility in rats submitted to the forced swim test (Garcia et al. 2008; Nosyreva et al. 2013).
To test the possibility that NMDA receptor activation also mediates the development of inflammation-induced depression, ketamine was administered at very low doses to mice treated with LPS (Walker et al. 2013). Ketamine was administered at the dose of 6 mg/kg either in a preventive manner, just before LPS, or in a curative manner, 10 h after the administration of LPS. In both cases, ketamine abrogated LPS-induced depression-like behavior without altering the cytokine response to LPS. To confirm that the blockade of the NMDA receptor was responsible for the antidepressant-like effects of ketamine in LPS-treated mice, we conducted a subsequent experiment in which we pretreated mice with the α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) receptor antagonist 2,3-dihydroxy-6-nitro-7-sulfamoyl-benzo(f)quinoxaline-2,3-dione (NBQX). NBQX blocked the increase in AMPA receptor glutamatergic neurotransmission after NMDA receptor antagonism by ketamine and thus restored LPS-induced decreased sucrose preference. These findings indicate that the formation of brain NMDA receptor agonists compounds during systemic inflammation is responsible for the development of LPS-induced depression (Walker et al. 2013).
The blood–brain barrier plays an active role in immune-to-brain communication
The ketamine experiments described in the previous paragraph demonstrate that LPS-induced depression-like behavior is mediated by NMDA receptor activation, but they do not inform on the nature and origin of the compounds that activate NMDA receptors. During systemic immune activation, IDO is activated both at the periphery and in the brain. In studies that were carried out in the late 1980s and early 1990s, Heyes and colleagues already noted that the decrease in blood tryptophan in response to systemic LPS is associated with an increase in brain tryptophan and brain serotonin turnover (Heyes et al. 1989). The decrease in blood tryptophan was caused by IDO and not by hepatic tryptophan 2,3 dioxygenase as the activity of this last enzyme was actually decreased in response to LPS. Increased brain kynurenine was proposed to derive from peripheral kynurenine (Saito et al. 1992). This hypothesis was confirmed by experiments carried out in gerbils using tritiated kynurenine. In the normal brain, up to 78 % of kynurenine derives from the blood. During systemic inflammation, nearly all of brain kynurenine derives from circulating kynurenine (Kita et al. 2002).
The blood–brain barrier (BBB) strictly regulates the transport of blood-borne substances into the brain. This is particularly the case for tryptophan and kynurenine. Whereas kynurenine metabolites are almost exclusively formed in situ (Schwarcz et al. 2012; Fukui et al. 1991), tryptophan and kynurenine enter the brain via a sodium-independent large neutral amino acid transporter known as System L (see Fig. 2) (Omidi et al. 2008; Boado et al. 1999). This transporter is composed of two subunits; a heavy glycoprotein chain, CD98, and one catalytic chain known as large neutral amino acid transporter, LAT-1 (Omidi et al. 2008; Boado et al. 1999). Although it should be theoretically possible to block the entry of kynurenine into the brain by targeting LAT-1 during systemic inflammation to prevent inflammation-induced depression, this has not yet been tested.
The BBB can be circumvented when inflammation develops locally in the brain. This can be mimicked by direct administration of LPS in the brain. LPS administered into the lateral ventricle of the brain was found to activate brain but not peripheral IDO and this was associated with the development of depression-like behavior (Fu et al. 2010). IDO activation was responsible for the development of LPS-induced depression-like behavior as depression-like behavior was abrogated in mice in which ido1 had been genetically deleted as well as in mice treated with the competitive antagonist of IDO, 1-methyl tryptophan (Lawson et al. 2013).
Quinolinic acid might not act alone but require glutamate as a cofactor
Based on the data presented above, inflammation-induced depression should be amenable to treatment by targeting the development of inflammation (e.g., cytokine or cytokine signaling pathways antagonists), the formation of peripheral kynurenine (e.g., IDO antagonist) or the transport of kynurenine into the brain (e.g., competing amino acids). This strategy would certainly work at its best when it is deployed in a preventive manner before depression occurs. Once depression has developed, another strategy aimed at repairing the inflamed brain needs to be put in place.
Quinolinic acid should a priori be a druggable target, by blocking its formation or antagonizing its effect on NMDA glutamatergic receptors. The neurotoxic activity of quinolinic acid has been known for more than 30 years, and its role in the pathophysiology of Huntington’s disease has been explored intensively over the last two decades (Schwarcz et al. 2012). However, it is not clear that inflammation-induced quinolinic acid is the sole culprit in the development of LPS-induced depression as endogenous quinolinic acid is increased but does not reach neurotoxic concentrations during inflammation. According to microdialysis studies, neurotoxicity can be achieved only when quinolinic acid is infused in the brain at concentrations that are tenfold to 100-fold the concentrations that are reached during neuroinflammation (Obrenovitch and Urenjak 2003).
If quinolinic acid alone is not sufficient to induce excitotoxicity, its effect could be potentiated by other endogenous neurotoxic factors. An obvious candidate is the potent radical oxygen species donor 3-hydroxy kynurenine as the brain levels of this metabolite increase considerably in response to LPS (Walker et al. 2013). However, the fact that targeting NMDA receptor activation with ketamine fully abrogates LPS-induced depression does not support a possible role of 3-hydroxy kynurenine in inflammation-induced depression.
Another potential candidate is glutamate. Activated microglia are able to release large quantities of glutamate as demonstrated by Adriano Fontana in the early 1990s (Piani et al. 1992). Activated microglial cells and macrophages uptake extracellular glutamine that is metabolized to glutamate via glutaminase (Takeuchi et al. 2006; Yawata et al. 2008). Microglial glutamate is then released via the connexin hemichannels of gap junctions that form in vivo in response to brain injury and in vitro in response to inflammatory mediators (Fig. 3) (Eugenin et al. 2001).
In the absence of cellular aggregates allowing the formation of gap junctions between microglial cells, the release of microglial glutamate occurs via a transporter known as system x −c that transports cystine into the cell in exchange for glutamate (Takaki et al. 2012; Kigerl et al. 2012). System x −c consists of two protein components, a 4F2 heavy chain and the xCT protein responsible for transport activity. The entry of cystine into the cell is necessary for the intracellular synthesis of glutathione and the preservation of the redox status of the cell. Activation of system x −c during neuroinflammation functions as an endogenous antioxidant response as the cystine influx helps maintain intracellular glutathione concentrations and the shuttling of cystine and cysteine at the membrane supports a redox cycle (Conrad and Sato 2012). Oxidative stress is likely to increase further during IDO activation due to the enhanced production of two kynurenine metabolites that are potent generators of radical oxygen species, 3-hydroxykynurenine (Eastman and Guilarte 1989), and 3-hydroxyanthranilic acid (Smith et al. 2009). This should result in further activation of system x −c and increased extracellular release of glutamate. The enhanced release of glutamate in exchange with cystine would then contribute to excitotoxicity especially if the astrocytic excitatory amino acid transporter (EAAT)1 is down-regulated by inflammation as proposed by Takaki et al. (2012) based on the results of studies carried out on a mixed culture of astrocytes and microglia.
Most of the data concerning the involvement of the system x −c antiporter in the neurotoxic properties of glutamate released by activated microglia have been obtained in vitro. The possibility that system x −c is also activated in vivo by LPS has been recently confirmed (Kigerl et al. 2012). Non-traumatic injections of low doses of LPS with a micropipette into the spinal cord activated microglia, and this was associated with up-regulation of xCT specifically in microglia. The resulting neuronal loss was greatly enhanced when cystine was co-injected with LPS.
Based on these findings, it can be proposed that system x −c converts oxidative stress to excitotoxic stress in the context of IDO activation. This would be the main source for the release of microglial glutamate as microglia aggregates are unlikely to form in a non-injured brain. Blockade of system x −c is probably not the suitable target for breaking the chain of events leading to inflammation-induced depression. It runs the risk of increasing IDO expression and activation as reported in human dendritic cells (Mattox et al. 2012). This would result in an enhanced production of kynurenine and ultimately quinolinic acid. An alternative strategy is to favor the efflux of glutamate from the brain to the blood using the blood glutamate scavenging technique.
Is blood glutamate scavenging a viable strategy to alleviate inflammation-induced depression?
Brain extracellular levels of glutamate are normally in the micromolar range, but they can increase up to 100-fold in conditions of excitotoxicity (Gras et al. 2012). Astrocytes express EAAT1 and EAAT2 that enable them to uptake the excess of glutamate and convert it to glutamine via glutamine synthetase. However, when glutamate is released by activated microglia, this mechanism is not sufficient to compensate for the increased extracellular levels of glutamate in astrocytes (Takaki et al. 2012). The increase in astrocytic glutamate levels results in a decreased expression of astrocytic EAAT1 that leads to further increases in extracellular concentrations of glutamate (Takaki et al. 2012).
Another important mechanism for the clearance of brain extracellular glutamate is represented by the efflux of glutamate from the brain interstitial fluid into the blood. The brain-to-blood efflux of glutamate can be evidenced by the increased circulating levels of glutamate that is observed in response to an intracerebral microinjection of glutamate (Hosoya et al. 1999). The brain-to-blood efflux of glutamate is dependent on the transport of glutamate from the brain extracellular fluid into brain endothelial cells through EAATs that are expressed on the abluminal or brain side of the endothelium (Helms et al. 2012). This process is facilitated by the presence of astrocytes at the BBB level and their ability to release glutamate in close proximity to endothelial cells (Cohen-Kashi-Malina et al. 2012). Glutamate taken up by endothelial cells is then released into the blood by facilitative glutamate transporters present on the luminal or blood side of the endothelium. The efficacy of this mechanism is limited by the relatively high levels of blood glutamate, about 40 µmol/l. An efficient way to substantially enhance the brain-to-blood efflux of glutamate is to accelerate the degradation of glutamate in the blood by administering oxaloacetate that activates glutamic oxaloacetic transaminase (GOT) and transforms glutamate into 2-ketoglutarate and oxaloacetate into aspartate (Teichberg et al. 2009). Blood glutamate scavenging can be enhanced further by adding recombinant GOT to oxaloacetate (Nagy et al. 2010; Ruban et al. 2013). The ability of blood glutamate scavenging to decrease brain glutamate levels was demonstrated in vivo in a model of brain ischemia in the rat using magnetic resonance spectroscopy (Campos et al. 2011). The neuroprotective effect of blood glutamate scavenging has been confirmed in a number of experimental conditions associated with high brain concentrations of glutamate, such as traumatic brain injury, epilepsy, and ischemic stroke (Leibowitz et al. 2012).
Conclusion and perspectives
It would be premature to conclude from the evidence presented in this review that depression can be treated by therapies targeting inflammation. Inflammation is associated with depression but does not always lead to depression. Conversely, depression is not always associated with inflammation (Raison and Miller 2013). The development of depression in inflamed subjects requires the co-occurrence of vulnerability factors including life events such as early physical abuse and genetic factors such as polymorphism in inflammatory genes and in genes regulating sensitivity of the brain to insults. To achieve personalized treatments for depression, it is still necessary to develop suitable biomarkers for identifying those patients who are the most likely to benefit from treatments targeting the chain of events leading from inflammation to depression. Figure 4 shows the key events to be targeted in this chain, which are the transport of kynurenine into the brain, the production and action of kynurenine metabolites in the brain, and probably the increased concentrations of glutamate in the brain interstitial fluids.
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Acknowledgments
This work was supported by the University of Texas MD Anderson Cancer Center and grants from the National Institute of Neurological Diseases and Stroke of the National Institutes of Health (Grants R01 NS073939; R01 NS074999). The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.
Conflict of interest
Robert Dantzer works as a consultant for Ironwood Pharma.
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Dantzer, R., Walker, A.K. Is there a role for glutamate-mediated excitotoxicity in inflammation-induced depression?. J Neural Transm 121, 925–932 (2014). https://doi.org/10.1007/s00702-014-1187-1
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DOI: https://doi.org/10.1007/s00702-014-1187-1