Much of the research on the role of serotonin in depression has focused on studying the SLC6A4 gene polymorphism located in the 5-HTTLPR. However, the results of the studies are not consistent.

An example of this can be seen in the results published by certain authors who analysed the polymorphic variations of the 5-HTTLPR. Gonda et al.13 found no relationship between this polymorphism and the risk of suffering depression in a European population sample, while in an American population sample, Contreras et al.17 found that this polymorphism generates a high risk of depression in people exposed to stressful events.

Of all the polymorphisms of this gene, rs25531 is characterised, grouped into “long” (L) or “short” (S) forms. The long allele consists of a 44-base-pair (bp) insertion and the short allele, a deletion of the same size. Humans can have three possible genotypes: a combination of short and long (SL); short and short (SS); or long and long (LL). The presence of these two alleles has been the subject of study as it has been found to affect development of symptoms of depression, dependent on the stressful events the person has experienced.18 However, Willeit et al.19 associated the presence of the S allele with atypical depression and the L allele with melancholic depression.

The 5-HTTLPR genotype is associated with negative information processing styles after exposure to stressful events, which triggers depressive symptoms and sensitivity to stress.20 Tests were conducted on adults to determine whether or not the type of polymorphism in the 5-HTTLPR, traumatic events experienced in childhood and recent negative experiences, all together, affected the possible cognitive endophenotypes of depression (such as attention and the ability to recognise emotions). Results suggested that low-expression 5-HTTLPR alleles (or S alleles) can confer a greater risk of depression as, in the tests carried out, the carriers of these alleles focused their attention on negative information.21 Some authors have reported that people who have the short allele have a greater risk of depression, poorer cognitive performance and increased vulnerability to suffer cognitive impairment in old age compared to people with the long allele.15,22 The frequency of the SS genotype is especially high in subjects with depression with onset before the age of 65 years.23

Kendler et al.24 genotyped a group of male and female twins, and found that homozygotes with a short allele (S) at the SLC6A4 locus were more sensitive to the depressing effects of all stressful events than those with long alleles (L). The influence of the SS genotype was found to be strongly linked to having two or more first-degree relatives with a history of depression.25

Importantly, different studies suggest that it is not necessary to have a short-form homozygous genotype (SS), but that an S allele, even if it is heterozygous (SL), is sufficient to generate a statistically greater risk of depression,14,17,26 in addition to influencing the severity of the disorder.27,28

Another of the variations reported in the effects of the 5-HTTLPR polymorphism on emotional state is patient gender. Rucci et al.,29 for example, found that women with a unipolar disorder and the SS genotype may have higher levels of depression. This is in line with Song et al.,30 who found a higher rate of women diagnosed with depression and the S allele.

Sumner et al.5 reported that people with homozygous S allele (SS) had a better performing autobiographical memory than carriers of L alleles (SL or LL). However, the authors also concluded that the rs25531 polymorphism does not modify the function of the genotype, suggesting that this variation has no effect on a possible diagnosis of depression. That contrasts with the results of the previously mentioned authors.

In relation to the anatomical appearance of the brain, the influence of the 5-HTTLPR polymorphism on the cortical thickness of regions involved in the processing of emotions and cognitive control, as well as on the volumes of different structures in individuals with depression, has been studied by structural magnetic resonance imaging, but no effect of the genotype of this polymorphism was found on the cortical thickness of the regions examined (region of the anterior and posterior cingulate gyrus, frontal-lateral region and parahippocampus). However, larger volumes were found in the thalamus and left putamen of individuals homozygous for the L allele.31

In research using high-resolution magnetic resonance imaging, it was found that patients with the long homozygous genotype (LL) had significantly smaller hippocampal grey matter and white matter than controls with the same genotype.32,33 The authors concluded that the decrease in hippocampus volumes in patients with major depression but not in healthy controls could be related to the development of the central nervous system, modulation by certain effects of the disease, different vulnerabilities to stress or different responses to antidepressant therapy. If the greater reuptake of serotonin in subjects with the LL genotype modulates the course of the disease, hippocampus volumes may be affected as a result of depression or neurotoxic processes related to stress. The LL genotype may cause a different vulnerability to the stress reaction. One hypothesis postulated by other authors is that stress and increased glucocorticoids may contribute to the loss of hippocampal volume through glutamatergic-toxic effects.34 In addition, stress decreases the expression of neurotrophic factor derived from the brain and this has trophic effects on serotonergic neurons in the hippocampus.35

Taylor et al.36 analysed differences in the morphological effects of suffering episodes of depression at different stages of life (early-onset and late-onset depression). The authors found a relationship between diagnosis of the condition and the homozygous LL genotype, specifically in the right hippocampus, which is smaller in subjects with late-onset depression than in those diagnosed at a younger age.

In addition to the studies carried out with magnetic resonance imaging, Cole et al.37 compared healthy people and patients with depression, and found that there were no significant differences in the volume of the hippocampus between S-allele carriers and LL homozygotes. However, in post-mortem brains it has been found that carriers of short alleles have significantly reduced perigenual anterior cingulate cortex (pACC) and amygdala volumes.38 These results are related to the functional connectivity between these two structures and could predict the variation in the measures of temperamental traits related to anxiety and depression.

Costafreda et al.39 analysed the effects of 5-HTTLPR on the connectivity between the different brain structures. They found that the genotype with a short allele in this polymorphism was associated with an increase in the activity of the amygdala and a frontal-limbic connectivity bias. It has been suggested that this polymorphism modulates resting state perfusion in key mood processing structures.40

Mann et al.41 reported that variations in SLC6A4 directly affect the ventral prefrontal cortex, which may be reflected in a generalised deterioration in the serotonergic function involved in the degree of serotonin uptake, significantly lower than that of patients with depression and healthy controls.42

Schneider et al.43 argue that the polymorphic SLC6A4 promoter region, especially its single-nucleotide polymorphism rs25531, is a risk factor for depression; in their study, carriers of risk alleles (SS genotype) had significantly greater activation of the bilateral amygdala when shown images with negative emotional content. The association of the S allele with depression was also described by other authors who found a greater prevalence of this allele in hospitalised patients with depressive episodes.44

In addition to magnetic resonance imaging methods, changes in connectivity have been studied using auditory evoked potentials. Cheng et al.,45 for example, analysed the response to the P200 wave generated in the primary auditory cortex, which is characterised by a high rate of serotonin synthesis, in people with the L allele compared to those homozygous for the S allele. They found that those in the second group had a shorter wave than the other participants, which they believe suggests a relationship between the P200 wave and the SS genotype. This is because depression can alter the response processes to different external stimuli, and the genotype described in the article is strongly related to the severity of the condition.

Other polymorphic regions that have been studied are variable number tandem repeats (VNTR) in intron 2 of the SLC6A4 gene. They are called STin 2. These variations contain a variable number of tandem repeats of 17 bp, which generates three VNTR alleles, STin2.9, STin2.10, and STin 2.12, which contain 9, 10 and 12 copies of the element, respectively. STin2.10 and STin 2.12 have been associated with neurological abnormalities such as affect disorders.6 However, Ogilvie et al.46 found a significant difference between the control group and the depression group, largely explained by the excess of the STin2.9 allele in the unipolar group.

Nevertheless, despite there being great support for the association between the 5-HTTLPR polymorphism and depression, there is a group of authors whose research found no relationship between these two factors, challenging the hypothesis that the variants in that region contribute significantly to the human emotional state.47 Among that group were Baghai et al.,48 who studied the possible effects of partial sleep deprivation in patients with depression and polymorphisms in SLC6A4. However, the effect was only transitory and most patients suffered an increase in depressive symptoms two days after the intervention. Other studies that analysed the genotype with the presence of the short allele in a group of families made up of parents, twins and their siblings found no direct association between 5-HTTLPR and depression,49,50 but it may be associated with specific clinical signs of the disease.51

In addition to the relationship between polymorphisms of the SLC6A4 gene and depression, other areas have been studied, such as the association between depression and cortisol and cholesterol concentrations; to cope with the stress caused by traumatic events, the body needs to generate effective adaptive responses. The most studied end result of this process is the variation in cortisol concentration, with increased values being associated with depression. Therefore, interactions between the cortisol response and the serotonergic system can affect hippocampal volume, specifically in patients with depression and homozygous LL genotype.33

Other studies have also examined the relationship between the allelic variation of SLC6A4 and other risk factors; for example, the concentration of high-density lipoprotein cholesterol (HDL-C). The results suggest that low levels of this type of cholesterol can be a risk factor for suffering depression in old age, but the genotype with the S allele is associated with a greater predisposition.10 The biological hypotheses that explain the relationship between cholesterol concentration and depression maintain that unhealthy lifestyle habits can lead to accumulation of white adipose tissue, which increases the production of cytokines and inflammatory substances. This inflammatory response can, in turn, cause hyperactivation of the hypothalamic-pituitary-adrenal (HPA) axis, which stimulates the release of lipids into the bloodstream, resulting in a reduction in HDL-C, and which is associated with the development of depression.52

The rs6295 polymorphism of the serotonin 1A receptor (HTR1A) has been studied in depth because it can have functional effects on gene expression. This polymorphism is a common variant at the 1019 site upstream of the basal promoter area; it is therefore also known as polymorphism C(-1019)G.53

The G variant of the C(-1019)G polymorphism has been associated with high expression of 5-HT1A receptors, which can generate a greater risk of depression and a deficient clinical response,9 especially when the individual has suffered stressful events in life.12 Results from the different studies are conflicting, but there are recent findings that support an association between rs6295 and mood disorders such as major depressive disorder and bipolar disorder.13

Another polymorphism studied in this family is G861C, found in the serotonin-1B receptor (HTR1B) gene. This has been associated with the inhibition of the serotonin release process generated in the basal ganglia, mainly because these receptors activate second messengers, which inhibit the activity of adenylate cyclase and manage the release of the neurotransmitter. Huang et al.54 found a strong correlation between this polymorphism and substance abuse (cocaine) in patients diagnosed with major depression. The authors state that they do not know how genetics may affect substance abuse.

Serotonergic neurons project to most parts of the brain and show active postsynaptic heteroreceptors in the cortex, the limbic regions, the hypothalamus and the spinal cord. An increase in the uptake of the neurotransmitter serotonin by the presynaptic transporters could therefore decrease its availability in the extracellular area, thereby affecting postsynaptic uptake and its subsequent distribution to different structures, which can contribute to depression.1

Of the polymorphisms associated with the serotonin-2A receptor (HTR2A), the two that have been studied the most are the synonymous nucleotide polymorphism c.102C>T (rs6313) and the non-synonymous polymorphism c.1354, p.His452Tyr (rs6313); according to Minov et al.,55 no differential relationship with depression was found in a study comparing adults with depression and healthy controls. The single-nucleotide polymorphism -1438A/G (rs6311), located in the promoter region of HTR2A and studied in a population in north-eastern Thailand, was not found to be associated with depression risk.56 However, we should stress the fundamental role that other variations in this gene, such as T102C(rs6313), can play in the aetiology of depression.

Cao et al.57 and Gonda et al.13 reported that the rs6311 polymorphism seems to be an important susceptibility factor in the aetiology of depression, as it can affect the activation of other genes involved in the disease.