Psychosocial stress as a cause of obesity: physiology and behaviour

Overall, the literature underlines the importance of the bidirectional associations between mental health and adiposity⁽Reference Tomiyama^30, Reference Gatineau and Dent³¹⁾. In this review, the main focus will be on the direction from stress towards adiposity as diet plays an important role in this direction. In adults, a comprehensive meta-analysis indeed concluded that work and life stress significantly increase BMI and/or waist longitudinally⁽Reference Wardle, Chida and Gibson³²⁾. In children and adolescents, less research has been performed although this has been booming the last years⁽Reference Wilson and Sato³³⁾. There is evidence from a review that early-life stress is associated with multiple biological and behavioural pathways in children that may increase risk for later obesity⁽Reference Miller and Lumeng³⁴⁾. A systematic review including twelve longitudinal studies in children/adolescents⁽Reference Incledon, Wake and Hay³⁵⁾ on clinical depression, perceived stress, anger/anxiety and behaviour concluded that the evidence is low for this relationship in children/adolescents. Another review focused on the effect of both household and individual stressors on children’s overweight parameters⁽Reference Gundersen, Mahatmya and Garasky³⁶⁾.

Several mechanisms in the effect of stress on adiposity have been described in the literature⁽Reference Tomiyama³⁰⁾. Mainly mechanisms are divided in physiological/biochemistry and behavioural (lifestyle) pathways (Fig. 1), as will be explained in the next paragraphs. In addition, cognitive characteristics like executive function and self-regulation are important⁽Reference Aparicio, Canals and Arija³⁷⁾.

Fig. 1. The classic behavioural and physiological pathways in the stress–obesity relationship. Behavioural pathways consist of less physical activity, sleep problems and an unhealthier diet. The underlying physiology is mainly due to increased cortisol levels that stimulate fat storage and change dietary behaviour. Indeed, cortisol influences brain regions essential for dietary behaviour, i.e. the reward and appetite regions, thus many appetite biomarkers are relevant for stress research. VTA, ventral tegmental area; NPY, neuropeptide Y; AgRp, agouti-related protein; POMC, pro-opiomelanocortin; CART, cocaine- and amphetamine-regulated transcript; PYY, peptide tyrosine tyrosine; CCK, cholecystokinin; GLP, glucagon-like peptide.

The direct physiological pathway is dominated by cortisol. This cortisol interacts with lipid metabolism in two ways, as reviewed by Peckett et al. ⁽Reference Peckett, Wright and Riddell³⁸⁾. First, cortisol increases the amount of circulating NEFA by stimulating the lipoprotein lipase enzyme. These NEFA can then be used to accumulate fat in fat cells. Second, cortisol decreases this fat storage. Increased adiposity is caused by hyperplasy (adipogenesis) and in the presence of insulin also by hypertrophy (lipogenesis). In addition, cortisol may influence lipolysis (degradation of adipose tissue TAG to fatty acids): both prolipolytic and antilipolytic activity has been hypothesised, but the mechanisms are still unclear and may depend on duration, dose and location of cortisol exposure. Antilipolytic activity has mainly been observed in high cortisol concentrations and in the abdominal region. The fat storage chiefly occurs in the visceral fat cells since the cortisol receptors have a high density in this region, and thus mainly abdominal obesity is theorised⁽Reference Bjorntorp³⁹⁾.

Apart from that direct effect on fat storage, stress may indirectly facilitate adiposity through behavioural pathways such as maladaptive coping behaviours leading to an adiposity-stimulating lifestyle⁽Reference Tomiyama^30, Reference Miller and Lumeng³⁴⁾: emotional eating of ‘comfort’ food (rich in sugar and fat), a disordered sleep and a lack of exercise with an increase in screen time.

Psychosocial stress as a cause of uncontrolled eating: biological underpinnings

A meta-analysis concluded that children/adolescents with stress have higher intake of unhealthy food and in the oldest also lower intake of healthy food⁽Reference Hill, Moss and Sykes-Muskett⁴⁰⁾. The preferred foods are rich in sugar and fat and have been called ‘comfort food’ since eating functions as a way to cope with stress via distraction and reward feelings⁽Reference Macht¹⁶⁾. Even in paediatric literature, perceived stress and cortisol have been associated with more snacking, sweet food intake and less fruit/vegetable intake⁽Reference Jenkins, Rew and Sternglanz^41–Reference Michels, Sioen and Braet⁴⁵⁾. These stress-induced dietary changes are often reflected as maladaptive uncontrolled eating behaviour⁽Reference Macht¹⁶⁾. In several studies, children’s and adolescents’ emotions and stress have been associated mainly with emotional eating⁽Reference Goossens, Braet and Van Vlierberghe^46–Reference Nguyen-Rodriguez, McClain and Spruijt-Metz⁴⁸⁾ and sometimes with increased external eating⁽Reference Braet and Van Strien^47, Reference Hou, Xu and Zhao⁴⁹⁾. Although eating palatable food can increase positive mood and reduce stress feelings through sensory pleasure⁽Reference Gibson⁵⁰⁾, this increase in positive mood is only temporary and is mostly followed by negative feelings like shame and guilt⁽Reference Gibson⁵⁰⁾. Thus stress-induced or emotional eating creates a vicious circle. Herein, emotion regulation could be an important skill as a target for obesity prevention/intervention⁽Reference Aparicio, Canals and Arija³⁷⁾ as the use of adaptive emotion regulation towards negative emotions (like reappraisal, problem-solving and acceptance) is a protective factor⁽Reference Braet, Theuwis and Van Durme⁵¹⁾ minimising unhealthy dietary response⁽Reference Svaldi, Tuschen-Caffier and Trentowska⁵²⁾ and physiological cortisol response⁽Reference Perry, Donzella and Parenteau⁵³⁾ after stressor exposure.

A well-known underlying pathway in stress-induced eating is cortisol⁽Reference Adam and Epel^54–Reference Epel, Tomiyama, Dallman, Brownell and Gold⁵⁷⁾, mainly by hypothalamic actions. After all, hypothalamic nuclei have overlapping functions in appetite regulation, stress response and rewards, while exerting effects on other brain regions like the mesolimbic reward system, cortex and brainstem⁽Reference al’Absi⁵⁸⁾. A first hypothalamic nucleus is the paraventricular nucleus regulating cortisol secretion. A second one is the arcuate nucleus acting as the central appetite control centre in which the pro-opiomelanocortin/cocaine- and amphetamine-regulated transcript (POMC/CART) neurons suppress food intake, whereas the neuropeptide Y/agouti-related protein (NPY/AgRP) neurons stimulate appetite. This arcuate nucleus transduces signals further to the other hypothalamic nuclei such as the paraventricular, lateral, dorsomedial and ventromedial nuclei. Certain of these nuclei form the bridge towards the appetite-regulating hypocretinergic (orexins) and endocannabinoid system and even the autonomic nervous system⁽Reference Abdalla⁵⁹⁾.

The two main diet-related actions of cortisol are thus increased reward sensitivity (opioid and dopamine system, especially when dieting) and appetite (arcuate nucleus in the hypothalamus), as summarised in Fig. 1. Cortisol is known to up-regulate NPY (an appetite and reward inducer) and dysregulate insulin and leptin (appetite and reward diminishing)⁽Reference Adam and Epel⁵⁴⁾. To explain the latter: insulin and leptin decrease appetite and reward but the body becomes resistant due to the dysregulation, thus appetite and reward will be increased⁽Reference Adam and Epel⁵⁴⁾. Based on my own longitudinal research, the combination of high stress and hyperleptinaemia might make girls more vulnerable to stress-induced eating⁽Reference Michels, Sioen and Ruige⁶⁰⁾. A review indicates a stress-induced change in other hormones that act on the arcuate nucleus such as ghrelin⁽Reference Labarthe, Fiquet and Hassouna⁶¹⁾. In a stressful situation, ghrelin is hypothesised to rise as ghrelin can then lower anxiety feelings (it is anxiolytic). Ghrelin will then also increase hunger and food reward and might thus lead to more emotional eating and a higher obesity risk⁽Reference Labarthe, Fiquet and Hassouna⁶¹⁾. With less evidence on the causal role in emotional eating, also other gastrointestinal appetite-reducing hormones have been related to stress/depression⁽Reference Lach, Schellekens and Dinan⁶²⁾ and eating disorders⁽Reference Culbert, Racine and Klump⁶³⁾: peptide tyrosine tyrosine (peptide YY; PYY), cholecystokinin (CCK) and glucagon-like peptide (GLP). Therefore, the next paragraphs will elaborate on the gut–brain axis and its role in appetite.

Gut bacteria

Analysing microbiota in the stress–diet relationship is relevant as: (1) bacteria are related to stress; (2) bacteria are related to diet; and (3) bacteria can interfere in the diet–stress relationship. These three aspects are consecutively discussed in the next three sections.

Gut bacteria decide what is on the menu

Since our bacteria are completely dependent on our food for their own metabolism (some prefer fibre, some prefer proteins), it seems logical that they have developed mechanisms to (co-)control our nutritional intake. Indeed, there is more and more evidence that gut bacteria have a role in regulating our appetite, satiety and potentially our food preferences or taste perceptions, as will be described below. Because of its role in energy homeostasis, the gut microbiome has also been associated with the metabolic syndrome⁽Reference de Clercq, Frissen and Groen⁸³⁾ and childhood obesity⁽Reference Indiani, Rizzardi and Castelo⁸⁴⁾.

Our appetite is influenced by hormones and neurotransmitters which can be directly produced by the gut bacteria themselves or whose production is indirectly stimulated by bacteria. Fig. 2 summarises some main pathways. The final target are the two energy-regulating neuron groups POMC/CART and NPY/AgRP within the arcuate nucleus; these neurons are influenced by gut-produced molecules that affect appetite and satiety such as ghrelin, CCK, GLP-1, GLP-2 and PYY⁽Reference de Clercq, Frissen and Groen⁸³⁾. Indeed, eating disorders are typically linked to changes in these hormonal factors⁽Reference Culbert, Racine and Klump⁶³⁾. From gut bacteria towards appetite, a first potential indirect pathway is via SCFA. These SCFA are volatile fatty acids like butyrate, acetate, propionate and valerate produced by the gut microbiota as fermentation products from food components such as fibre. These SCFA normally reduce appetite by stimulating the release of appetite-reducing hormones PYY and GLP-1 from the entero-endocrine cells⁽Reference de Clercq, Frissen and Groen^83, Reference Tolhurst, Heffron and Lam^85, Reference Larraufie, Martin-Gallausiaux and Lapaque⁸⁶⁾. Stress-induced gut dysbiosis might cause imbalance in this protective mechanism that in turn can lead to uncontrolled eating. As a second indirect pathway, specific microbes might regulate intestinal endocannabinoid-like compounds such as 2-olyeol-glycerol and oleoyl-ethanolamide which again can stimulate GLP production by entero-endocrine cells⁽Reference Cani, Plovier and Van Hul⁸⁷⁾ while gut microbiota dysbiosis seems to decrease GLP-1 sensitivity⁽Reference Yamane and Inagaki⁸⁸⁾. Finally, direct effects of the microbiota on the arcuate nucleus have been suggested, for example, an Escherichia coli bacterial strain producing caseinolytic protease B seems to reduce appetite via the arcuate nucleus⁽Reference Breton, Legrand and Akkermann⁸⁹⁾. Next to these endocrine parameters, the two other main pathways in the microbiota–gut–brain axis (see ‘Gut bacteria communicate with the brain’ section) might be involved: the nervous system (for example, nervus vagus stimulation) and inflammatory regulation (for example, gut barrier integrity).

Fig. 2. Some pathways in the microbiota–gut–brain axis from microbiota towards appetite. The gut–brain axis links the gut microbiota with stress and appetite brain centres. The microbiota can directly act upon the appetite brain centres but also indirectly via SCFA and endocannabinoid analogues that regulate entero-endocrine cells’ release of appetite-influencing molecules. An additional indirect pathway towards appetite is that the gut microbiota induces epigenetic changes. It should be considered that most links also work in the other direction, for example, diet can influence epigenetics, gut microbiota composition and SCFA production. NPY, neuropeptide Y; AgRp, agouti-related protein; POMC, pro-opiomelanocortin; CART, cocaine- and amphetamine-regulated transcript; HPA, hypothalamus–pituitary–adrenal; PYY, peptide tyrosine tyrosine; GLP, glucagon-like peptide; CCK, cholecystokinin.

All the above pathways target appetite. For eating behaviour, not only appetite should be targeted but also impulse control and/or changed food preferences and taste perception. For example, food preference for proteins was dependent on intestinal bacteria in an experiment with fruit flies⁽Reference Leitao-Goncalves, Carvalho-Santos and Francisco⁹⁰⁾ and many of the mentioned appetite-regulating neuropeptides are summarised in a review on taste sensitivity⁽Reference Fabian, Beck and Fejerdy⁹¹⁾. Direct studies on uncontrolled eating behaviour associated with gut bacteria are missing but, indirectly, gut bacterial changes after bariatric surgery were found to be associated with an observed hedonic eating decline⁽Reference Sanmiguel, Jacobs and Gupta⁹²⁾.

The stress–bacteria–diet triangle: bidirectionality and implications

Taken together, stress, diet and bacteria form a triangle: gut bacteria are linked to both stress and diet (see the ‘Gut bacteria communicate with the brain’ and ‘Gut bacteria decide what is on the menu’ sections), while diet and stress are also interrelated (see ‘Psychosocial stress as a cause of uncontrolled eating: biological underpinnings’ section). Fig. 3 metaphorically translates this bidirectional link of gut bacteria with stress and diet. These bidirectional links highlight gut bacteria as an interesting target point for research, prevention and treatment as bacterial imbalance has multiple implications. To create a balanced gut bacterial composition/activity, a bacteria-friendly and thus fibre-rich diet should be combined with a relaxed mind. On the other hand, uncontrolled eating and a stressed brain can (at least partially) be prevented by balanced gut bacteria. Thus, gut microbiota can be an intermediate pathway in stress–diet and diet–stress. Nevertheless, no study has shown that the specific gut microbiome changes resulting from stress are in turn directly responsible for dietary and weight changes.

Fig. 3. The stress–bacteria–diet interaction triangle with a comparison with a forest ecosystem. This figure shows that stress, gut bacteria and diet are bidirectionally related to each other. To make the metaphor towards a forest ecosystem, the gut bacteria symbolise the trees in the forest as the ideal situation is a diversity of trees in the forest and a high diversity of bacteria in our gut. The diet is then representing the nutritious soil and stress represents the atmosphere. In the case of the forest, the trees will not survive without an appropriate atmosphere (air/sun/humidity) and nutritious soil while on the other hand, the trees themselves will influence the soil and atmosphere by the autumn leaves that enrich the soil and by the produced oxygen. Thus, bidirectional interactions exist. The same type of interaction can be translated towards the gut microbiota. Concerning food, we know that fibre-rich food can enrich our bacteria and apparently our bacteria might affect our food intake. Concerning our brains, I have summarised in this review the bidirectional gut–brain axis where certain bacteria can influence our stress reactivity while stress might act upon the bacteria. Freely interpreted, it seems these interactions teach us that we should create a relaxed atmosphere and optimal nutrition for our internal forest to obtain a balanced ecosystem of bacteria resulting in low stress and appropriate appetite.

Epigenetics: relevance for stress, eating behaviour, obesity and gut bacteria

Physiological and behavioural functions are particularly sensitive to the programming effects of environmental factors such as stress and nutrition during early life⁽Reference Patchev, Rodrigues and Sousa¹⁰⁰⁾. One way of programming is epigenetics. Epigenetics can be seen as a measure of metabolic ageing and concerns changes in gene expression that are not due to changes in DNA sequence but, for example, due to DNA methylation or histone modification which then alters transcription and thus expression and bodily functions. An epigenetic clock DNA methylation signature based on seven to 353 sites has outperformed other markers of ageing and is linked to a broad range of health aspects like obesity⁽Reference Declerck and Vanden Berghe¹⁰¹⁾.

There is increasing evidence that the response to early-life adversity is system/genome-wide and persists into adulthood for example, in relation to childhood abuse⁽Reference Labonte, Suderman and Maussion¹⁰²⁾ and even during pregnancy⁽Reference Provencal and Binder¹⁰³⁾. Based on a systematic review, stress seems to affect methylation on the cortisol axis itself, on serotonergic/dopaminergic/noradrenergic neurotransmission and neural growth⁽Reference Bakusic, Schaufeli and Claes¹⁰⁴⁾. These pathways are also important in obesity aetiology as they are related to food behaviour. Stress-induced changes in dietary intake (i.e. comfort food) can induce epigenetic effects as nutrition is one of the frequently researched lifestyle factors affecting epigenetics⁽Reference Park, Friso and Choi¹⁰⁵⁾. Even appetite and its related impulses like impulsivity and reward sensitivity are sensitive to epigenetic changes⁽Reference Archer, Oscar-Berman and Blum¹⁰⁶⁾. For example, a review summarised that DNA methylation dysregulation in eating disorder is accompanied by a disturbed dopaminergic and endocannabinoid system⁽Reference Yilmaz, Hardaway and Bulik¹⁰⁷⁾. In rats, it has been shown that a methyl-balanced diet during adolescence might prevent stress-induced binge eating⁽Reference Schroeder, Jakovcevski and Polacheck¹⁰⁸⁾ and can reverse changes in DNA methylation and negative behavioural consequences induced by early-life stress⁽Reference Weaver, Champagne and Brown¹⁰⁹⁾. Since almost no research has been done on stress-induced changes in obesity-related genes, a recent study tried to associate psychosocial factors with gene-level DNA methylation of eighty-seven overweight-associated genes in older adults, although with limited success⁽Reference Elboudwarej¹¹⁰⁾. Taken together, epigenetic changes by stress, diet and obesity can influence the stress response, eating behaviour and obesity.

Interestingly, gut bacteria are partially involved in this epigenetic programming. Mice lacking gut bacteria possess several transcriptional differences, some related to energy homeostasis and cortisol⁽Reference Diaz Heijtz, Wang and Anuar¹¹¹⁾. Indeed, SCFA and certain polyphenol metabolites produced by bacteria are inhibitors of histone deacetylases and can thus induce epigenetic changes⁽Reference Stilling, Dinan and Cryan¹¹²⁾, amongst others influencing appetite through PYY elevations⁽Reference Larraufie, Martin-Gallausiaux and Lapaque⁸⁶⁾ (see the left side of Fig. 2). Because of those complex interactions, the bidirectional stress–diet–obesity link can also work transgenerationally (from mother to child) via bacterial and epigenetic changes; for example, maternal lifestyle can make an impact on the neonatal microbiome leading to specific epigenetic signatures that may potentially predispose to the development of late-life obesity⁽Reference Li¹¹³⁾. Nevertheless, such studies on childhood stress should still be tested. As bidirectional links between epigenetic changes and the microbiota exist, integrative studies using both epigenomics and metagenomics are needed⁽Reference Carbonero¹¹⁴⁾.

The potential of metabolomics as a tool in biological underpinnings

As multiple biological pathways seem to be involved in stress–diet–obesity, a study of all metabolites, i.e. metabolomics, is believed to aid in unravelling the biological underpinnings. Metabolomics is the comprehensive study of the metabolome – the repertoire of small molecules present in cells, tissues and body fluids. The metabolome is regarded as the most revealing real-time quantifiable read-out of the human biochemical state at a system’s level, thus allowing insight in mechanisms and providing predictive, diagnostic or prognostic markers for diverse disease states⁽Reference Beger, Dunn and Schmidt¹¹⁵⁾. Sometimes interchangeably defined as ‘metabonomics’, the metabolic patterns are dynamic and arise as the product of our own gene-encoded proteins in combination with metabolic products of our microbes and our environment like the food that we eat. Consequently, metabolomics is relevant in the stress–diet–obesity axis as metabolic profiles have been related to gut microbiota⁽Reference Vernocchi, Del Chierico and Putignani¹¹⁶⁾, stress⁽Reference Li, Tang and Cheng¹¹⁷⁾, childhood obesity programming⁽Reference Rauschert, Kirchberg and Marchioro¹¹⁸⁾ and clinical eating disorders⁽Reference Focker, Timmesfeld and Scherag¹¹⁹⁾. Within stress-related metabolomics, stress profiles are distinguished by neurotransmitters and energy-related metabolites⁽Reference Li, Tang and Cheng¹¹⁷⁾, which again reflects the stress–obesity relationship. Within obesity-related metabolomics, branched-chain amino acids are often significant and related to gut bacteria⁽Reference Vernocchi, Del Chierico and Putignani¹¹⁶⁾, although data from adult and childhood obesity research gives sometimes opposite results⁽Reference Rauschert, Kirchberg and Marchioro¹¹⁸⁾. Another common pathway might be the inflammatory system, as adipose tissue, diet, stress and gut microbiota are associated with inflammation⁽Reference Grenham, Clarke and Cryan^67, Reference Hansel, Hong and Camara¹²⁰⁾. In addition, mitochondrial metabolites might be relevant to focus on as mitochondria are responsible for cellular energy/signalling and have been reciprocally linked to stress, energy homeostasis, microbiota and gene expression⁽Reference Picard and Turnbull^121–Reference Bajpai, Darra and Agrawal¹²³⁾. Up to now, the study of metabolomics never seems to have combined stress and obesity data or stress–diet data.