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From stress to psychosis: whom, how, when and why?

Published online by Cambridge University Press:  06 June 2014

V. Mondelli
V. Mondelli*
Affiliation:
Department of Psychological Medicine, King's College London, Institute of Psychiatry, London, UK
*
Address for correspondence: Dr V. Mondelli, Sections of Perinatal Psychiatry & Stress, Psychiatry and Immunology (SPI-Lab), Centre for the Cellular Basis of Behaviour, The James Black Centre, Institute of Psychiatry, King's College London, 125 Coldharbour Lane, London SE5 9NU, UK. (Email: valeria.mondelli@kcl.ac.uk)
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Abstract

The role of stress in precipitating the onset and relapse of psychosis has been now widely recognised. Over the past decade, the major challenge of research in this field has been to elucidate the biological mechanisms involved in the interaction between stress and psychosis onset. Obvious focus of this research has been the study of biological systems involved in the stress response. I will here briefly discuss the current evidence of abnormalities in stress biomarkers, such as cortisol and inflammatory markers, in patients with psychosis and their possible clinical implications. Stress biomarkers appear to hold strong potential as predictors of psychosis as well as of clinical outcome, and may represent optimal targets for the development of novel therapeutic agents for psychosis.

Keywords

Cortisolinflammationpsychosisstress
Type
Editorials
Information
Epidemiology and Psychiatric Sciences , Volume 23 , Issue 3 , September 2014 , pp. 215 - 218
Copyright
Copyright © Cambridge University Press 2014 

The first clinical observations on the association between stress and mental disorders date back to the 18th century, when the idea that social stress was one of the causes of mental illness was formulated in France by Philippe Pinel, and by his student Jean Esquirol. However, it was only later on that the first studies were conducted to specifically investigate the role of psychosocial stressful events in the onset of psychosis. The first major study investigating the potential relationship between the experience of stressful events and schizophrenia was conducted about 40 years ago (Brown & Birley, Reference Brown and Birley1968). This study reported that patients with schizophrenia experienced more stressful events in the 3 months preceding relapse of the illness than the control subjects. During the 3 weeks preceding the onset of the relapse, 46% of patients experienced at least one stressful event compared to 12% in an earlier 3 months period, suggesting a possible relationship between the life events and the onset of schizophrenia (Brown & Birley, Reference Brown and Birley1968). Some years later, Bebbington et al. (Reference Bebbington, Wilkins, Jones, Foerster, Murray, Toone and Lewis1993) replicated these findings, reporting an excess of stressful life events over the 6 months before the relapse of psychosis, both in patients with schizophrenia and in patients with affective psychoses when compared with a psychiatrically healthy sample from the local general population.

These observations provided a basis for the diathesis–stress model of schizophrenia, developed in the 1960–1970s. David Rosenthal played a central role in promulgating the view that the behavioural expression of the biological vulnerability for schizophrenia was influenced by exposure to stress. This view generated further research questions, mainly trying to clarify how exposure to stress could trigger the expression of constitutional vulnerability. Indeed, in the past decade, one of the major challenges in this research field has been to elucidate the biological mechanisms involved in the interaction between stress and onset of psychosis. Obvious focus of this research has been the study of biological systems involved in the stress response. I will discuss here some of the main findings on stress biomarkers in psychosis and their possible implications and translation in clinical settings.

Hypothalamic–pituitary–adrenal (HPA) axis and psychosis

The study of the HPA axis, the main biological system involved in the stress response, is central to reach a better understanding of the biological mechanisms behind the association between stress and psychosis and leading to the onset of psychosis. The HPA axis is activated by the release of corticotropin releasing hormone (CRH) and vasopressin (AVP), synthesised in the hypothalamus, which activate the secretion of adrenocorticotropic hormone (ACTH) from the pituitary, which finally stimulates the secretion of cortisol from the adrenal gland. Cortisol then interacts with its receptors in multiple target tissues also including the HPA axis, where it is responsible for the feedback inhibition of the secretion of ACTH from the pituitary and CRH from the hypothalamus (Pariante & Lightman, Reference Pariante and Lightman2008).

Studies conducted in the past decade have shown that patients with first-episode psychosis have increased activation in the HPA axis (elevated cortisol and ACTH levels, enlarged pituitary volume) (Walker et al. Reference Walker, Mittal and Tessner2008; Mondelli et al. Reference Mondelli, Dazzan, Hepgul, Di Forti, Aas, D'Albenzio, Di Nicola, Fisher, Handley, Marques, Morgan, Navari, Taylor, Papadopoulos, Aitchison, Murray and Pariante2010a), together with a blunted cortisol awakening response (Mondelli et al. Reference Mondelli, Dazzan, Hepgul, Di Forti, Aas, D'Albenzio, Di Nicola, Fisher, Handley, Marques, Morgan, Navari, Taylor, Papadopoulos, Aitchison, Murray and Pariante2010a). The cortisol awakening response is a measure of acute reactivity of the HPA axis, so a blunted awakening response suggests reduced HPA axis reactivity to stress. This is consistent with the evidence that psychotic patients also have a blunted cortisol response to psychological and psychosocial stressors (Breier et al. Reference Breier, Wolkowitz, Doran, Bellar and Pickar1988; Jansen et al. Reference Jansen, Gispen-de Wied, Gademan, De Jonge, Van Der Linden and Kahn1998). Within samples of patients with psychosis, reduced HPA axis reactivity to stress has been associated with more severe symptoms and worse cognitive function (Breier et al. Reference Breier, Wolkowitz, Doran, Bellar and Pickar1988; Aas et al. Reference Aas, Dazzan, Mondelli, Toulopoulou, Reichenberg, Di Forti, Fisher, Handley, Hepgul, Marques, Miorelli, Taylor, Russo, Wiffen, Papadopoulos, Aitchison, Morgan, Murray and Pariante2011).

Interestingly, a hyperactivity of the HPA axis appears to be part of the biological vulnerability to psychosis, which is present prior to the onset of psychosis (Aiello et al. Reference Aiello, Horowitz, Hepgul, Pariante and Mondelli2012). In particular, subjects who experience attenuated psychotic symptoms show increased cortisol levels as well as larger pituitary and smaller hippocampal volumes. Moreover, this HPA axis hyperactivity seems to be even greater among those individuals who subsequently develop frank psychosis. Similarly, relatives of patients with psychotic disorders present an increased sensitivity to stress, as shown by increased emotional reactivity to daily life stress, increased ACTH in response to stress, larger pituitary volume and smaller hippocampal volume (Aiello et al. Reference Aiello, Horowitz, Hepgul, Pariante and Mondelli2012).

These abnormalities could play a relevant role in the development of psychosis through their effect on the neurotransmitter systems as well as on neurogenesis. In particular, administration of glucocorticoids has been shown to increase dopaminergic activity in the mesolimbic system in animals, suggesting a possible link between increased cortisol levels and the onset of psychotic symptoms (Schatzberg et al. Reference Schatzberg, Rothschild, Langlais, Bird and Cole1985). Moreover, cortisol has been reported to blunt sympathetic nervous system responses activated by stress in humans (Raison & Miller, Reference Raison and Miller2003). Interestingly, although cortisol response to psychological stress is found to be blunted in first-episode psychosis, the sympathetic nervous system response to stress has been shown to be preserved in the same subjects (Van Venrooij et al. Reference Van Venrooij, Fluitman, Lijmer, Kavelaars, Heijnen, Westenberg, Kahn and Gispen-De Wied2012). Therefore, it is possible to suggest that, in the presence of a stressful condition, the lack of cortisol response cannot restrain the activation of the sympathetic nervous system, resulting in a persistent increased arousal and a consequent exacerbation of psychotic symptoms (Borges et al. Reference Borges, Gayer-Anderson and Mondelli2013).

The effect of HPA axis activation on neurogenesis and neuroplasticity is one of the other mechanisms suggested explaining the association between abnormalities in HPA axis and onset of psychosis. Indeed, glucocorticoids can also influence neuroplasticity (decreasing neurogenesis and remodelling neuronal dendrites), affecting neurotrophins levels, such as brain-derived neurotrophic factor, and through their interaction with pro-inflammatory cytokines, excitatory amino acid neurotransmitters and N-methyl-D-aspartate (NMDA) receptors (McEwen, Reference Mcewen2000). This is particularly important since a number of studies have shown brain volume changes at the onset of psychosis, or during the transition to psychosis, suggesting a critical role for neuroplasticity, especially in specific brain areas, in the development of psychosis (Cahn et al. Reference Cahn, Rais, Stigter, Van Haren, Caspers, Hulshoff Pol, Xu, Schnack and Kahn2009; Takahashi et al. Reference Takahashi, Wood, Yung, Soulsby, Mcgorry, Suzuki, Kawasaki, Phillips, Velakoulis and Pantelis2009). Indeed, we have shown that high cortisol levels are associated with smaller hippocampal volume in first-episode psychosis, further supporting this biological pathway to explain the link between HPA axis hyperactivity and the onset of psychosis (Mondelli et al. Reference Mondelli, Pariante, Navari, Aas, D'Albenzio, Di Forti, Handley, Hepgul, Marques, Taylor, Papadopoulos, Aitchison, Murray and Dazzan2010b, Reference Mondelli, Cattaneo, Belvederi Murri, Di Forti, Handley, Hepgul, Miorelli, Navari, Papadopoulos, Aitchison, Morgan, Murray, Dazzan and Pariante2011).

Interestingly, antipsychotic medications can affect cortisol levels, but have been reported to be able to only partly re-establish a ‘normal’ HPA axis activity; in particular antipsychotic treatment seem to reduce/normalise the high levels of cortisol during the day but does not seem to affect the abnormalities in the cortisol awakening response (Mondelli et al. Reference Mondelli, Dazzan, Hepgul, Di Forti, Aas, D'Albenzio, Di Nicola, Fisher, Handley, Marques, Morgan, Navari, Taylor, Papadopoulos, Aitchison, Murray and Pariante2010a). Furthermore, persistent non-suppression of cortisol levels following the dexamethasone test after 4 weeks of antipsychotic treatment is associated with a poor clinical outcome (Tandon et al. Reference Tandon, Mazzara, Dequardo, Craig, Meador-Woodruff, Goldman and Greden1991). Conversely, a reduction in cortisol levels after 12 weeks of antipsychotic treatment is associated with an improvement in psychotic symptoms (Zhang et al. Reference Zhang, Zhou, Cao, Wu and Shen2005; Garner et al. Reference Garner, Phassouliotis, Phillips, Markulev, Butselaar, Bendall, Yun and Mcgorry2011). Further studies would need to investigate if the regulation of the HPA axis is important for response to treatment, and if we can use the HPA axis as a possible biological target system for the development of novel drugs for treatment-resistant patients.

Inflammation and psychosis

The immune system has also been demonstrated to be one of the biological systems activated by psychosocial stress; and indeed recent studies suggest inflammation as one of the possible mediators between stress and the onset of psychiatric disorders. More specifically, when we mention inflammation in this context we refer to a phenomenon called systemic or chronic, low-grade inflammation which is different from responses to acute infectious stimuli because (1) it is systemic and not limited to a local site of injury or infection; (2) it is of lower magnitude than other types of inflammation; (3) it is typically a longer term phenomenon, as opposed to the transient nature of inflammatory responses to infection; and (4) does not have a clear origin or does not follow an apparent stimulus, such as infection or injury (Rohleder, Reference Rohleder2014).

Over the past few decades of research, there has been an incredibly increasing body of enquiry supporting the role of chronic, low-grade inflammation in the pathogenesis of different psychiatric disorders from both preclinical and clinical studies (Dantzer, Reference Dantzer2001; Dantzer et al. Reference Dantzer, O'Connor, Freund, Johnson and Kelley2008). The most consistent and established findings come from studies in depression. However, over the past few years, it has become more and more evident that an increased inflammatory status is present both at the onset of psychosis and in the later stages of the disorder. This has been suggested by findings of increased cytokine levels in peripheral blood and cerebrospinal fluid in patients with psychosis (Miller et al. Reference Miller, Buckley, Seabolt, Mellor and Kirkpatrick2011; Zajkowska & Mondelli, Reference Zajkowska and Mondelli2014). In particular, increased levels of the pro-inflammatory cytokines interleukin (IL)-6, tumour necrosis factor-α and IL-1β are the most consistent findings from the studies conducted in first-episode psychosis patients (Zajkowska & Mondelli, Reference Zajkowska and Mondelli2014). The mechanisms through which inflammatory cytokines have been suggested to mediate the onset of psychosis include interaction with multiple pathways such as monoamine metabolism, neuroendocrine function and synaptic plasticity. Interestingly, increased inflammation appears to contribute to the brain abnormalities evident at the onset of psychosis, as shown by our previous findings of an association between increased levels IL-6 and reduced hippocampal volume in first-episode psychosis patients (Mondelli et al. Reference Mondelli, Cattaneo, Belvederi Murri, Di Forti, Handley, Hepgul, Miorelli, Navari, Papadopoulos, Aitchison, Morgan, Murray, Dazzan and Pariante2011).

Studies on the effect of antipsychotic medication on inflammatory markers have given so far mixed findings, showing both anti-inflammatory and pro-inflammatory effects. Indeed, some of these discrepancies could be partly explained by what reported by a recent longitudinal study showing an initial anti-inflammatory effect of antipsychotic medication followed by a gradual rise again of cytokines levels along an increase in body weight (Song et al. Reference Song, Fan, Li, Zhang, Gao, Zhao, Harrington, Ziedonis and Luxian2014). These data suggest that the presence of both a direct anti-inflammatory activity of the antipsychotic treatment and an indirect pro-inflammatory activity, possibly mediated by their effect on weight-gain and increased adiposity. It remains, however, unclear whether the possible anti-inflammatory effect of these medications contributes to improve the clinical outcome of these patients. Interestingly, only three studies have investigated so far whether the increased inflammation is linked to clinical outcomes in psychosis, and all found that higher inflammation was associated with a poorer clinical outcome (McAllister et al. Reference Mcallister, Van Kammen, Rehn, Miller, Gurklis, Kelley, Yao and Peters1995; Lin et al. Reference Lin, Kenis, Bignotti, Tura, De Jong, Bosmans, Pioli, Altamura, Scharpe and Maes1998; Zhang et al. Reference Zhang, Zhou, Cao, Wu and Shen2005).

Clinical implications and conclusions

Our understanding of the biological mechanisms linking stress to psychosis onset has greatly increased over the past few years. Indeed, we have now a clearer picture of what are the biological abnormalities in the stress response present in patients with psychosis. But how can we use this new knowledge about stress biomarkers to improve clinical care of patients with psychosis? Can we use stress biomarkers to predict who is going to develop psychosis following exposure to high levels of stress? Can we use stress biomarkers to predict who is going to be resistant to antipsychotic treatment? Are biological systems involved in the stress response a new therapeutic target for patients with psychosis? The findings so far suggest that stress biomarkers hold strong potential as predictors of psychosis as well as of clinical outcome, and may represent optimal targets for the development of novel therapeutic agents. Future studies will be fundamental to reveal the clinical benefit of all the research work conducted in the last 40 years on the link between stress and psychosis.

Acknowledgements

This work has been supported by the South London and Maudsley NHS Foundation Trust & Institute of Psychiatry NIHR Biomedical Research Centre for Mental Health.

Financial Support

This work has been supported by the South London and Maudsley NHS Foundation Trust & Institute of Psychiatry NIHR Biomedical Research Centre for Mental Health.

Conflict of Interest

None.

Ethical Standard

Not applicable.

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