Atopy and autoimmune thyroid diseases: melatonin can be useful?

It has been proposed that innate immunity has a role in allergic inflammation, and epithelial cells, dendritic cells, natural killer lymphocytes, and mast cells might play a regulatory role in allergy. It has also been suggested that there is some form of cooperation between Th2 mediated allergy, and Th1 mediated inflammation responses [28].

The adaptive cellular immune response has been characterized broadly as being polarized in two directions [29]. Type 1 responses, directed by Th1 CD4+ T cells and identified by the signature cytokine interferon (IFN)-g, are considered as protective against infections by intracellular pathogens [30], and have been incriminated in the pathogenesis of autoimmune diseases, such as thyroid disease. Many other autoimmune diseases such as rheumatoid arthritis, juvenile rheumatoid arthritis, insulin-dependent diabetes mellitus and multiple sclerosis are associated with a Th1 phenotype [31].

Autoimmune thyroid disease (ATD) is a multifactorial disease in which autoimmunity against thyroid antigens develops against a particular genetic background facilitated by exposure to environmental factors. Autoimmune thyroid diseases are characterized by infiltration of the thyroid by T and B cells which are reactive to thyroid antigens, by the production of thyroid autoantibodies and by abnormal thyroid function [32]. ATD presents a hereditary component, as reported in several studies that show a definite genetic propensity for thyroid autoimmunity to run in families [33]. The childhood prevalence of chronic autoimmune thyroiditis peaks in early to mid-puberty [34].

By contrast, type 2 responses, directed by Th2 CD4+ T cells and identified by the signature cytokines interleukin (IL) -4, IL-5 and IL-13, are considered to play a pathogenic role in allergic diseases [35]. Reciprocal counter-regulation of Th1 and Th2 cells [36] predicts that Th1-type autoimmune diseases and Th2-mediated allergic diseases would occur in mutually exclusive populations of patients. However, recent observations have challenged the validity of the long-standing Th1/Th2 paradigm [37], and a far more complex story explaining the immunological basis of cellular immune-mediated host defence and the pathogenesis of autoimmune and allergic diseases is emerging. The new paradigm identifies additional lymphocyte subsets, such as Th17 T cells, Treg and novel soluble factors. These provide a new prism through which to examine the intersection of autoimmune and allergic disease (Fig. 1) [37].

Mittermann et al. demonstrated that a considerable percentage of patients suffering from atopic dermatitis had enhanced IgE autoantibody levels against a broad variety of human proteins expressed in a variety of cell and tissue types. Furthermore, they showed that the levels of IgE autoantibodies were associated with severity of disease [38].

Several studies reported a higher incidence of ATD in subjects affected by allergic diseases. Pedullá et al. showed an increased prevalence of thyroid autoimmunity in children with AD, underlining a significant relationship between the expression of AD and thyroid autoimmunity in a pediatric population [39]. Furthermore, Pedullá et al. demonstrated that the frequency of thyroid autoimmunity was significantly higher among children with IgE-mediated AD than non-IgE-mediated AD, suggesting atopy and thyroid autoimmunity as potential outcomes of dysregulated immunity [39]. Hidaka et al. suggested that eosinophils and their activation play an important role in inflammatory processes in allergic diseases. Th2 cytokines stimulate eosinophils and it has recently been found that the peripheral eosinophil count was increased in thyrotoxic patients with Graves’ disease [40]. Moreover, the same authors demonstrated that an allergic condition is closely related to Graves’ disease and that a Th2-type immune response is crucial in the pathogenesis of Graves’ disease [41].

Whereas oxidative reactions occur in all tissues and organs, the thyroid gland is an organ in which oxidative processes are widely signalized and are indispensable for physiological functions of the organism [42]. Hydrogen peroxide acts as an electron acceptor at each step of thyroid hormone biosynthesis and is essential for thyroperoxidase (TPO) activity, the key enzyme in this process. In addition, antioxidative enzyme activity [superoxide dismutase (SOD), glutathione (GSH) peroxidase (GSH-Px) and catalase (CAT)] has been well documented in the thyroid [43].

The use of various exogenous antioxidants in thyroid tissues has been shown to be beneficial in experimental (in vitro or in vivo) studies [43, 44]. Unfortunately, the applicability of different antioxidants has not yet been clearly confirmed in clinical studies and still no effective antioxidative medication is available for widespread use [45].

Moreover, melatonin, an ubiquitous antioxidant molecule with pleiotropic action in many tissues, has protective effects against oxidative stress [46, 47], the thyroid included [48].

There are data in literature pointing to the relationship between melatonin and thyroid activity. Several studies have suggested a paracrine role for this molecule in the regulation of thyroid activity. The antioxidant role of melatonin in the thyroid gland was first reported by Kvetnoy [49]. It has been demonstrated that melatonin is, at rat thyroid level, synthesized by C cells -the minor neuroendocrine thyroid cell population- and, that melatonin receptors (MT)1 are present in follicular cells [50], suggesting a role for thyroid melatonin. Recently, another study has shown that thyroid C-cells synthesize melatonin under thyroid-stimulating hormone control, supporting the hypothesis of a paracrine role for C-cell-synthesised melatonin within the thyroid gland.

In particular, Garcia-Marin et al. [27] analyzed both the effect of melatonin on the expression of the thyroid tissue-specific genes PAX8 and TTF1 and examined TSH regulation of key enzymes for melatonin biosynthesis, such as aralkylamine N-acetyltransferase (AANAT) and acetyl serotonin methyltransferase (ASMT). They showed both the involvement of melatonin in thyroid function by directly-regulating thyroglobulin gene expression in follicular cells and that AANAT and ASMT are regulated by thyroid-stimulating hormone. Furthermore, it has been demonstrated that thyroid C-cells synthesized melatonin under thyroid-stimulating hormone control, supporting the possible paracrine role for C-cell-synthesised melatonin within the thyroid [27].

Additionally, Karbownik M. et al. commented the evidence that melatonin, acting as an antioxidant agent, influences thyroid growth, counteracting significant oxidative damage that occurs in the course of thyroid diseases, and the stimulatory effects of thyroid hormones [42].

The same research group [48], in an experimental study, estimated melatonin effects on basal and iron-induced lipid peroxidation related to Fenton reaction in homogenates of the porcine thyroid gland, showing that the degree of lipid peroxidation was decreased, in a concentration-dependent manner, by melatonin, and supporting the protective role of this indolamine in preventing pathological processes, such as thyroid cancer, related to oxidative injury.

Data in literature has shown melatonin action on the thyroid gland itself, such as the inhibitory effect of melatonin on cell proliferation and thyroid hormone synthesis [51, 52] or the protective effect of melatonin against oxidative damage in the thyroid gland [53, 54].

It has been well reported that the administration of chronic melatonin is efficient in protecting against the damaging effects of different prooxidants and that under basal conditions it does not change the level of oxidative damage to macromolecules [55]. In addition, it has been evaluated that the effects of Caffeic acid phenethyl ester (CAPE) on Fenton reaction-induced oxidative damage to membrane lipids (lipid peroxidation, LPO) in porcine thyroid and the liver are similar to those caused by melatonin. Whereas CAPE decreased basal LPO in a concentration-dependent manner in both tissues, melatonin did not change the basal LPO level. When antioxidants were used together with Fenton reaction substrates, they prevented – in a concentration-dependent manner and to a similar extent – experimentally- induced LPO in both tissue effects of melatonin [56].