T helper cell 2 immune skewing in pregnancy/early life: chemical exposure and the development of atopic disease and allergy.

During the last 50 years there has been a significant increase in Western societies of atopic disease and associated allergy. The balance between functional subpopulations of T helper cells (Th) determines the quality of the immune response provoked by antigen. One such subpopulation - Th2 cells - is associated with the production of IgE antibody and atopic allergy, whereas, Th1 cells antagonize IgE responses and the development of allergic disease. In seeking to provide a mechanistic basis for this increased prevalence of allergic disease, one proposal has been the 'hygiene hypothesis', which argues that in Westernized societies reduced exposure during early childhood to pathogenic microorganisms favours the development of atopic allergy. Pregnancy is normally associated with Th2 skewing, which persists for some months in the neonate before Th1/Th2 realignment occurs. In this review, we consider the immunophysiology of Th2 immune skewing during pregnancy. In particular, we explore the possibility that altered and increased patterns of exposure to certain chemicals have served to accentuate this normal Th2 skewing and therefore further promote the persistence of a Th2 bias in neonates. Furthermore, we propose that the more marked Th2 skewing observed in first pregnancy may, at least in part, explain the higher prevalence of atopic disease and allergy in the first born.

The hapten-atopy hypothesis III: the potential role of airborne chemicals.

One explanation for the large increase in the prevalence of atopic disease in developed countries during the last 50 years is the 'hygiene hypothesis'. This proposes that a reduced exposure to pathogenic microorganisms at a key period(s) during development results in the maintenance or acquisition of an atopic phenotype. Alternatively, or additionally, we have postulated that increased exposure to chemicals generally, and to irritant/haptenic chemicals in particular, during critical windows of maternal pregnancy/early life have also contributed to changes in the prevalence of atopic disease. Having previously reviewed the potential roles of oral and cutaneous exposure to chemicals on the subsequent diagnosis of atopic disease, we here consider possible evidence of a role for exposure to airborne chemicals as a contributory factor in acquired susceptibility to atopic allergy. After controlling for known confounders, five specific maternal occupations during pregnancy have been implicated as being associated with subsequent atopic disease in the offspring. Each of these occupations is characterized by high and persistent exposure to airborne chemicals. High-level exposure to volatile organic compounds in the domestic environment, either during pregnancy or in early life, is also associated with development of childhood atopic disease. Similarly, sustained exposure to airborne chlorinated chemicals from swimming pools during childhood has been associated with the development of atopic allergy. A possible immunological basis for these associations is that exposure to certain airborne chemicals, even at low levels, can result in the delivery of 'danger' signals that, in turn, bias the immune response towards the selective induction or maintenance of preferential T helper 2-type immune responses consistent with the acquisition of allergic sensitization.

Why does allergic contact dermatitis exist?

The skin immune system's propensity to produce allergic contact dermatitis (ACD) to harmless chemicals, while otherwise being an efficient defence system, represents a dermatological paradox. We postulate that a major role in signalling in ACD is played by Toll-like receptor (TLR)2 and TLR4, and arises from their activation by extracellular danger-associated molecular patterns (DAMPs). Ligand activation of TLR4/2 results in the expression of interleukins (ILs) IL-1ß, IL-6, IL-12, IL-18 and IL-23, tumour necrosis factor-α and interferon-α. These cytokines promote acquisition of sensitization, and facilitate elicitation of contact allergy via multiple mechanisms, including the recruitment of CD4+ Th1 and Th17 cells. As Th1 cells secrete large amounts of DAMPs, a DAMP immune circuit (positive-feedback loop) is created. This is an important driver of skin sensitization and skin inflammation. Pathogenic extracellular bacteria, but not commensal bacteria, produce pathogen-associated molecular pattern molecules, which stimulate the expression of Th1- and Th17-promoting cytokines via TLR2 and TLR4. This also induces an immune circuit. The ability of the skin immune system to activate host defence mechanisms and to distinguish between pathogenic bacteria and commensals provides an explanation for why skin sensitization and ACD develop, as they are processes that rely on the same biological pathways. These pathways may also shed light on the pathogenesis of chronic pustular inflammatory dermatoses (e.g. acne vulgaris). The existence of safety signals from commensal bacteria, which prevent initiation of these pathways, may provide opportunities for novel therapeutic approaches to the treatment of inflammatory skin diseases.