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Vulnerability to depression: what is the role of stress genes in gene × environment interaction?

Published online by Cambridge University Press:  12 February 2009

W. El Hage*
Affiliation:
INSERM U930 ERL CNRS 3106, CHRU de Tours, Université François Rabelais, Tours, France Institute of Psychiatry, King's CollegeLondon, UK
J. F. Powell
Affiliation:
Institute of Psychiatry, King's CollegeLondon, UK
S. A. Surguladze
Affiliation:
Institute of Psychiatry, King's CollegeLondon, UK
*
*Address for correspondence: Dr W. El Hage, Psychological Medicine and Psychiatry, Institute of Psychiatry, King's CollegeLondon, London SE5 8AF, UK. (Email: Wissam.El-Hage@iop.kcl.ac.uk)
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Abstract

Vulnerability to depression has been linked to the interaction of genetic predisposition with stressful life events. This review considers the associations between serotonergic and hypothalamic–pituitary–adrenal (HPA) systems. We follow the standpoint of a previous Editorial Review (Bhagwagar & Cowen, Psychological Medicine 2008, 38, 307–313) and consider another possible mechanism of vulnerability to depressive disorder, that is we suggest that the gene×environment interaction involves complex participation of serotonergic genes modulating response to stress through the HPA system.

Type
Editorial
Copyright
Copyright © 2009 Cambridge University Press

Introduction

Major depressive disorder (MDD) has a heterogeneous aetiology and the contribution of environmental factors is at least equivalent to that of genetic factors. A genetic diathesis predisposes individuals to the disorder in the context of life stressors (Kendler et al. Reference Kendler, Thornton and Gardner2001). Environmental factors are now taken into account in studies of MDD, which is not a trivial task because their evaluation is usually retrospective. Moreover, it is not explicit which stressful events are the most relevant, ranging from acute to chronic or traumatic stress events. The evidence suggests that the acute and recent stress is more relevant, compared with chronic and distal events (for a review see Monroe & Reid, Reference Monroe and Reid2008).

In the following sections we consider some of the possible factors that play a role in the gene–environment interaction relevant to the concept of vulnerability to MDD.

The serotonergic system

Serotonergic vulnerability (Jans et al. Reference Jans, Riedel, Markus and Blokland2006) is an increased sensitivity to natural or experimental alterations of the serotonergic system, such as genetic factors, female gender, personality characteristics (neuroticism), environmental stress (prenatal stress, life experiences) or drug use. An insertion/deletion polymorphism in the serotonin transporter-linked promoter region 5-HTTLPR modulates serotonin transporter gene (SLC6A4) expression, where the short allele (S) is associated with lower expression levels compared to the long allele (L). Importantly, the risk for depression has been associated with an interaction of the S allele with stressful life events (Caspi et al. Reference Caspi, Sugden, Moffitt, Taylor, Craig, Harrington, McClay, Mill, Martin, Braithwaite and Poulton2003). What are the neural mechanisms of such an interaction? Neuroimaging studies show that, in response to aversive visual signals, S allele carriers demonstrate amygdala hyperactivity and also altered connectivity between the pregenual anterior cingulate cortex (ACC) and the amygdala (for a meta-analysis see Munafo et al. Reference Munafo, Brown and Hariri2008). In other words, people who genetically have low activity of 5-HTTLPR, and consequently are at risk for developing depression, demonstrate an overactivity of the amygdala to aversive signals. These experiments are regarded as modelling the brain's responsivity to potentially stressful environmental signals. A functional magnetic resonance imaging (fMRI) study (Canli et al. Reference Canli, Qiu, Omura, Congdon, Haas and Amin2006) has indeed found that the life stress measure correlated positively with resting activation in the amygdala and hippocampus in S allele carriers and negatively in L allele carriers.

The literature indicating a net inhibitory effect of serotonin on amygdala activity (Stutzmann & LeDoux, Reference Stutzmann and LeDoux1999) seems to support this model. However, the bigger picture of major depression is far from clear. Thus, a recent meta-analysis has not confirmed a direct link between 5-HTTLPR and MDD (Kato, Reference Kato2007). Levinson (Reference Levinson2006) suggested that there were small positive associations between 5-HTTLPR and depression-related personality traits but not with MDD itself. Kato (Reference Kato2007) argued that, in depression, the previously reported positive findings of a gene–environmental interaction between 5-HTTLPR and stress were not replicated consistently. One reason for these discrepancies is that 5-HTTLPR polymorphisms are now found to be more complex than previously thought, with at least 14 alleles of the 5-HTTLPR. There are views that the 5-HTTLPR polymorphisms may not be directly associated with MDD but modulate the serotonergic response to stress (for a methodological review see Uher & McGuffin, Reference Uher and McGuffin2007).

Stress and the hypothalamic–pituitary–adrenal (HPA) axis

Traditionally, studies of vulnerability to stress have focused on malfunctioning of the HPA system involving neuroendocrine metabolism. A large body of knowledge suggests that exposure to stress leads to hyperactivation of the HPA system, which, in people with a deficitary feedback mechanism, is followed by hypercortisolism. This hypercortisolism is present during depressive episodes, in remitted patients and in those at high risk, for example in children from affected families (Mannie et al. Reference Mannie, Harmer and Cowen2007). Importantly, the degree of hypercortisolism has been shown to predict the occurrence of depression in high-risk individuals (Harris et al. Reference Harris, Borsanyi, Messari, Stanford, Brown, Cleary, Shiers and Herbert2000; Halligan et al. Reference Halligan, Herbert, Goodyer and Murray2007).

Two receptor subtypes, glucocorticoid and mineralocorticoid receptors (GR and MR respectively), contribute to the regulation of HPA activity. One of the models of depression (Pariante, Reference Pariante2006) suggests that the main neuroendocrinological abnormality is glucocorticoid resistance resulting from decreased GR function or expression in the brain. The hypercortisolism would be a compensatory mechanism aiming to overcome the glucocorticoid resistance. Thus, in a proportion of MDD patients, GR dysfunction might be the primary source of the HPA axis abnormalities. An elevated waking cortisol level might be part of an endophenotype predisposing a subject to the development of depression in the context of stressful life events.

HPA-related genes

Growing evidence is suggesting that some polymorphisms in the MR and GR genes may underlie vulnerability to depression.

Glucocorticoid receptor

A significant association of MDD with polymorphisms in the gene coding for the GR was observed in a Belgian sample (in the promoter region NR3C1-1, rs10482605), a Swedish sample (R23K, rs6190) and a German population (R23K) (van West et al. Reference van West, Van Den Eede, Del-Favero, Souery, Norrback, Van Duijn, Sluijs, Adolfsson, Mendlewicz, Deboutte, Van Broeckhoven and Claes2005; van Rossum et al. Reference van Rossum, Binder, Majer, Koper, Ising, Modell, Salyakina, Lamberts and Holsboer2006). Kumsta et al. (Reference Kumsta, Entringer, Koper, van Rossum, Hellhammer and Wust2007) investigated 206 healthy subjects and associations between common GR gene (NR3C1) polymorphisms and HPA axis responses to psychosocial stress, using the Trier Social Stress Test (TSST). The study detected a significant association, but no clear aetiological relationship, between GR gene polymorphisms (ER22/23EK, N363S, BclI, 9β) and HPA axis regulation and on glucocorticoid sensitivity as well as a sex-specific impact (BclI GG, 9β AG) on responses to psychosocial stress. Recently, Bradley et al. (Reference Bradley, Binder, Epstein, Tang, Nair, Liu, Gillespie, Berg, Evces, Newport, Stowe, Heim, Nemeroff, Schwartz, Cubells and Ressler2008) showed that child abuse interacts with the corticotrophin-releasing factor type 1 receptor (CRF-R1) genotype to enhance risk for depression in adults, in two independent ethnically different populations. They suggested that alterations in CRF-R1 responsiveness during these early emotionally crucial periods could alter later risk for HPA axis overactivity and depression.

In sum, the GR- and CRF-coding genetic polymorphisms are likely to have a modulating (rather than a causal) effect in the development of MDD.

Mineralocorticoid receptor

In a cohort of healthy males (DeRijk et al. Reference DeRijk, Wust, Meijer, Zennaro, Federenko, Hellhammer, Giacchetti, Vreugdenhil, Zitman and de Kloet2006), carriers of the minor allele of the MR gene variant I180V showed significantly higher salivary and total cortisol and also heart rate responses to the TSST than non-carriers. Kuningas et al. (Reference Kuningas, de Rijk, Westendorp, Jolles, Slagboom and van Heemst2006) assessed the impact of cortisol levels and of variations in the MR and GR genes on depressive symptoms. They showed that the prevalence of depressive symptoms was dependent on a variation in the MR gene, where carriers of the MR-I180V single nucleotide polymorphism (SNP) had more depressive symptoms compared to the non-carriers.

Thus, several genes involved in modulation of HPA axis functioning may have a role in the mechanisms of vulnerability to MDD. The involvement of serotonergic genes in vulnerability has also been highlighted. The question arises: do these mechanisms of vulnerability operate independently? We believe there should be a common pathway where the serotonergic and HPA systems converge in developing vulnerability to depressive states. The functional links between these systems may provide some clues.

Links between 5-HT and HPA systems

Gotlib et al. (Reference Gotlib, Joormann, Minor and Hallmayer2008) has shown recently that cortisol response may be a crucial mechanism underlying the association between the 5-HTTLPR gene and exposure to stressful events in increasing risk for depression. We consider below possible neural processes involved in such an interaction (Fig. 1).

It is well established that the activity of the amygdala is associated with the HPA axis through serotonergic projections to the hypothalamus (Weidenfeld et al. Reference Weidenfeld, Newman, Itzik, Gur and Feldman2002), influencing the stress response (Herman et al. Reference Herman, Ostrander, Mueller and Figueiredo2005). It has also been suggested that the central amygdaloid nucleus takes part in overproduction of CRF in melancholic patients with hypercortisolaemia (Reul & Holsboer, Reference Reul and Holsboer2002).

However, the serotonergic system has been found to modulate HPA axis functioning: for example, studies with 5-HTT knockout mice have shown that one of the functions of the serotonin transporter is to restrain the HPA response to stress (Tjurmina et al. Reference Tjurmina, Armando, Saavedra, Li and Murphy2004; Murphy & Lesch, Reference Murphy and Lesch2008). Jabbi et al. (Reference Jabbi, Korf, Kema, Hartman, van der Pompe, Minderaa, Ormel and den Boer2007) explored the influence of 5-HTTLPR polymorphisms on HPA axis reactivity using combined dexamethasone and CRF challenge, which is known to induce neuroendocrine states similar to stress-related clinical phenotypes. The study showed higher endocrine response in females homozygous for S allele of 5-HTTLPR which might contribute to the sex-related differences in MDD prevalence. Indeed, the same 5-HTTLPR polymorphisms also interacted with baseline measures of cortisol in determining susceptibility to MDD.

Conclusions

Given the above-mentioned close relationship between the amygdala, serotonergic transmission and the HPA axis, their concerted participation in limbic response to stress might be expected. This response may develop into an exaggerated reaction in people with low activity of 5-HTTLPR/elevated activity in the amygdala, where the hyperactive amygdala enhances HPA axis functioning; sustained hypercortisolism will follow, contingent on MR and GR gene expression.

Fig. 1. Altered relationships between serotonergic, limbic and hypothalamic–pituitary–adrenal (HPA) systems underlie the vulnerability to depression. Reduced serotonergic inhibition (arrows A) is associated with overactivity in the amygdala and the HPA system. The overactive amygdala provides an additional boost to cortisol and corticotrophin-releasing factor production (arrow B). Genetic polymorphisms are associated with risk/vulnerability to depression. This diagram demonstrates the relationships between three systems underlying the vulnerability to depression. We acknowledge that there are several other systems involved (e.g. dopaminergic system, lateral, orbital frontal and cingulate circuits) but these are not the subject of this review.

Future studies of limbic brain modulation by genetic polymorphisms pertaining to serotonergic and HPA systems may tell us more about vulnerability to MDD.

Acknowledgements

W.E.H. is currently supported by Servier, the French Association of Biological Psychiatry (AFPB) and Janssen-Cilag. He received a research grant from Lundbeck that is unrelated to the content of this manuscript.

Declaration of Interest

None.

References

Bhagwagar, Z, Cowen, PJ (2008). ‘It's not over when it's over’: persistent neurobiological abnormalities in recovered depressed patients. Psychological Medicine 38, 307313.CrossRefGoogle Scholar
Bradley, RG, Binder, EB, Epstein, MP, Tang, Y, Nair, HP, Liu, W, Gillespie, CF, Berg, T, Evces, M, Newport, DJ, Stowe, ZN, Heim, CM, Nemeroff, CB, Schwartz, A, Cubells, JF, Ressler, KJ (2008). Influence of child abuse on adult depression: moderation by the corticotropin-releasing hormone receptor gene. Archives of General Psychiatry 65, 190200.CrossRefGoogle ScholarPubMed
Canli, T, Qiu, M, Omura, K, Congdon, E, Haas, BW, Amin, Z (2006). Neural correlates of epigenesis. Proceedings of the National Academy of Sciences of the United States of America 103, 1603316038.CrossRefGoogle ScholarPubMed
Caspi, A, Sugden, K, Moffitt, TE, Taylor, A, Craig, IW, Harrington, H, McClay, J, Mill, J, Martin, J, Braithwaite, A, Poulton, R (2003). Influence of life stress on depression: moderation by a polymorphism in the 5-HTT gene. Science 301, 386389.CrossRefGoogle ScholarPubMed
DeRijk, RH, Wust, S, Meijer, OC, Zennaro, MC, Federenko, IS, Hellhammer, DH, Giacchetti, G, Vreugdenhil, E, Zitman, FG, de Kloet, ER (2006). A common polymorphism in the mineralocorticoid receptor modulates stress responsiveness. Journal of Clinical Endocrinology and Metabolism 91, 50835089.CrossRefGoogle ScholarPubMed
Gotlib, IH, Joormann, J, Minor, KL, Hallmayer, J (2008). HPA axis reactivity: a mechanism underlying the associations among 5-HTTLPR, stress, and depression. Biological Psychiatry 63, 847851.CrossRefGoogle ScholarPubMed
Halligan, SL, Herbert, J, Goodyer, I, Murray, L (2007). Disturbances in morning cortisol secretion in association with maternal postnatal depression predict subsequent depressive symptomatology in adolescents. Biological Psychiatry 62, 4046.CrossRefGoogle ScholarPubMed
Harris, TO, Borsanyi, S, Messari, S, Stanford, K, Brown, GW, Cleary, SE, Shiers, HM, Herbert, J (2000). Morning cortisol as a risk factor for subsequent major depressive disorder in adult women. British Journal of Psychiatry 177, 505510.CrossRefGoogle ScholarPubMed
Herman, JP, Ostrander, MM, Mueller, NK, Figueiredo, H (2005). Limbic system mechanisms of stress regulation: Hypothalamo-pituitary-adrenocortical axis. Progress in Neuro-Psychopharmacology and Biological Psychiatry 29, 12011213.CrossRefGoogle ScholarPubMed
Jabbi, M, Korf, J, Kema, IP, Hartman, C, van der Pompe, G, Minderaa, RB, Ormel, J, den Boer, JA (2007). Convergent genetic modulation of the endocrine stress response involves polymorphic variations of 5-HTT, COMT and MAOA. Molecular Psychiatry 12, 483490.CrossRefGoogle ScholarPubMed
Jans, LAW, Riedel, WJ, Markus, CR, Blokland, A (2006). Serotonergic vulnerability and depression: assumptions, experimental evidence and implications. Molecular Psychiatry 12, 522543.CrossRefGoogle ScholarPubMed
Kato, TADA (2007). Molecular genetics of bipolar disorder and depression. Psychiatry and Clinical Neurosciences 61, 319.CrossRefGoogle ScholarPubMed
Kendler, KS, Thornton, LM, Gardner, CO (2001). Genetic risk, number of previous depressive episodes, and stressful life events in predicting onset of major depression. American Journal of Psychiatry 158, 582586.CrossRefGoogle ScholarPubMed
Kumsta, R, Entringer, S, Koper, JW, van Rossum, EFC, Hellhammer, DH, Wust, S (2007). Sex specific associations between common glucocorticoid receptor gene variants and hypothalamus-pituitary-adrenal axis responses to psychosocial stress. Biological Psychiatry 62, 863869.CrossRefGoogle ScholarPubMed
Kuningas, M, de Rijk, RH, Westendorp, RGJ, Jolles, J, Slagboom, PE, van Heemst, D (2006). Mental performance in old age dependent on cortisol and genetic variance in the mineralocorticoid and glucocorticoid receptors. Neuropsychopharmacology 32, 12951301.Google Scholar
Levinson, DF (2006). The genetics of depression: a review. Biological Psychiatry 60, 8492.CrossRefGoogle ScholarPubMed
Mannie, ZN, Harmer, CJ, Cowen, PJ (2007). Increased waking salivary cortisol levels in young people at familial risk of depression. American Journal of Psychiatry 164, 617621.CrossRefGoogle ScholarPubMed
Monroe, SM, Reid, MW (2008). Gene–environment interactions in depression research: genetic polymorphisms and life-stress polyprocedures. Psychological Science 19, 947956.CrossRefGoogle ScholarPubMed
Munafo, MR, Brown, SM, Hariri, AR (2008). Serotonin transporter (5-HTTLPR) genotype and amygdala activation: a meta-analysis. Biological Psychiatry 63, 852857.CrossRefGoogle ScholarPubMed
Murphy, DL, Lesch, KP (2008). Targeting the murine serotonin transporter: insights into human neurobiology. Nature Reviews Neuroscience 9, 8596.Google Scholar
Pariante, CM (2006). The glucocorticoid receptor: part of the solution or part of the problem? Journal of Psychopharmacology 20, 7984.CrossRefGoogle ScholarPubMed
Reul, JM, Holsboer, F (2002). Corticotropin-releasing factor receptors 1 and 2 in anxiety and depression. Current Opinion in Pharmacology 2, 2333.CrossRefGoogle ScholarPubMed
Stutzmann, GE, LeDoux, JE (1999). GABAergic antagonists block the inhibitory effects of serotonin in the lateral amygdala: a mechanism for modulation of sensory inputs related to fear conditioning. Journal of Neuroscience 19, RC8.CrossRefGoogle ScholarPubMed
Tjurmina, OA, Armando, I, Saavedra, JM, Li, Q, Murphy, DL (2004). Life-long serotonin reuptake deficiency results in complex alterations in adrenomedullary responses to stress. Annals of the New York Academy of Sciences 1018, 99104.CrossRefGoogle ScholarPubMed
Uher, R, McGuffin, P (2007). The moderation by the serotonin transporter gene of environmental adversity in the aetiology of mental illness: review and methodological analysis. Molecular Psychiatry 13, 131146.CrossRefGoogle ScholarPubMed
van Rossum, EFC, Binder, EB, Majer, M, Koper, JW, Ising, M, Modell, S, Salyakina, D, Lamberts, SWJ, Holsboer, F (2006). Polymorphisms of the glucocorticoid receptor gene and major depression. Biological Psychiatry 59, 681688.CrossRefGoogle ScholarPubMed
van West, D, Van Den Eede, F, Del-Favero, J, Souery, D, Norrback, KF, Van Duijn, C, Sluijs, S, Adolfsson, R, Mendlewicz, J, Deboutte, D, Van Broeckhoven, C, Claes, S (2005). Glucocorticoid receptor gene-based SNP analysis in patients with recurrent major depression. Neuropsychopharmacology 31, 620627.Google Scholar
Weidenfeld, J, Newman, ME, Itzik, A, Gur, E, Feldman, S (2002). The amygdala regulates the pituitary-adrenocortical response and release of hypothalamic serotonin following electrical stimulation of the dorsal raphe nucleus in the rat. Neuroendocrinology 76, 6369.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Altered relationships between serotonergic, limbic and hypothalamic–pituitary–adrenal (HPA) systems underlie the vulnerability to depression. Reduced serotonergic inhibition (arrows A) is associated with overactivity in the amygdala and the HPA system. The overactive amygdala provides an additional boost to cortisol and corticotrophin-releasing factor production (arrow B). Genetic polymorphisms are associated with risk/vulnerability to depression. This diagram demonstrates the relationships between three systems underlying the vulnerability to depression. We acknowledge that there are several other systems involved (e.g. dopaminergic system, lateral, orbital frontal and cingulate circuits) but these are not the subject of this review.