Abstract
Vitamin D is widely known for its role in bone metabolism, but this sterol hormone also has important immunomodulatory properties. Vitamin D is produced by the conversion of D3 in the skin following UVB exposure, or after ingestion of D2 or D3. At the extremes of latitude, there is insufficient UVB intensity in the autumn and winter months for adequate synthesis of vitamin D to occur. Growing evidence implicates vitamin D deficiency in early life in the pathogenesis of nonskeletal disorders (e. g., type 1 diabetes and multiple sclerosis) and, more recently, atopic disorders. Several studies have reported higher rates of food allergy/anaphylaxis or proxy measures at higher absolute latitudes. Although causality remains to be determined, these studies suggest a possible role for sunlight and/or vitamin D in the pathogenesis of food allergy/anaphylaxis.
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Introduction
Food allergy and anaphylaxis have become an increasing public and personal health burden in developed countries over the past decade, contributing to increased demand for specialty services [1], significant economic cost of care [2], and reduced quality of life for food-allergic children and their families [3]. Effective strategies for primary prevention are lacking, and secondary prevention is limited to strategies to reduce the risk of unintentional exposure. Although specific immunotherapy appears promising, it remains at the investigational stage [4]. While several factors have been proposed for the rise in food allergy (reviewed in [5]), the possibility that vitamin D status may play a pathogenic role has received recent attention. In this article, we review the evidence for and against a possible role of vitamin D status in allergic disease in general, and food allergy and anaphylaxis in particular. Because most food allergy begins in childhood, we have focused our review—when possible—on early-childhood.
Vitamin D Physiology
Vitamin D is widely known for its role in bone metabolism, but this sterol hormone also has important immunomodulatory properties. Vitamin D is produced by the conversion of D3 in the skin following UVB exposure, or after ingestion of D2 or D3. It is then converted in the liver to 25-hydroxyvitamin D (25[OH]D), which circulates bound to vitamin D–binding protein, and then is converted in the kidney to its active form, 1,25-dihydroxyvitamin D. This acts as a hormone (rather than vitamin) to increase calcium absorption in the intestine and regulate the differentiation and activation of osteoblasts and osteoclasts in the bone. Importantly, this conversion can also occur within cells of the immune system, such as activated T cells, dendritic cells, and possibly B cells, thus concentrating high levels of active vitamin D within the lymphoid microenvironment. Circulating levels of 25(OH)D are considered to be the best overall indicator of vitamin D status because levels reflect total vitamin D intake from sunlight exposure, dietary intake, and supplements. As little vitamin D is present naturally in most unfortified foods, levels of circulating 25(OH)D are largely determined by skin production that occurs in response to the variable amounts of UVB in sunlight [6].
Vitamin D Deficiency
Seasonal differences in UVB exposure result in lower 25(OH)D levels in autumn/winter months. At the extremes of latitude (eg, Europe, northern United States and Canada, southern Australia, and New Zealand), there is insufficient UVB intensity in the cooler months for adequate synthesis of 25(OH)D to occur, regardless of sun exposure [7]. Vitamin D insufficiency (defined as 25(OH)D <30 ng/mL [<75 nmol/L]) is thus common in these regions. Prevalence varies, but in many industrialized countries, up to 50% of the population has insufficient vitamin D, with perhaps 10% being deficient (defined as 25[OH]D <10 ng/mL [<50 nmol/L]) [8]. Almost 50% of US children were found to be vitamin D insufficient, and one in six were deficient in a recent US study [9], reflected in recent reports of rickets in the country [10]. Deficiency has also been shown to be common in pregnant women and neonates in many countries, including the United States [11], New Zealand [12], and Australia [13, 14].
Risk factors for vitamin D deficiency include dark-colored skin, skin coverage (due to religious, cultural, or health-related reasons), time spent indoors (e.g., immobility in older adults), malabsorption of dietary vitamin D precursors (e.g., celiac disease, inflammatory bowel disease), obesity (e.g., reduced mobility, sequestration of vitamin D in adipose tissue), sunscreen use, as well as the intensity of ambient UVB exposure (e.g., latitude and local weather conditions such as cloud cover or pollution, with lower ambient temperature potentially influencing time spent outside). Recent work suggests there likely is also a significant genetic contribution to variations in 25(OH)D levels secondary to polymorphisms in genes related to vitamin D metabolism that is equivalent in magnitude to that observed with seasonal differences between winter and summer [15••], which may in part explain why even those without obvious risk factors may be deficient [16••, 17••]. Trends to greater levels of vitamin D deficiency and insufficiency likely reflect several lifestyle changes in recent decades, particularly behavioral factors such as time spent indoors [8, 18]. Low neonatal 25(OH)D levels have recognized adverse effects on bone health during early-childhood [19]. In recent years, there has been an increasing appreciation that vitamin D deficiency in early life is implicated in the pathogenesis of many disorders (including type 1 diabetes and multiple sclerosis) and, more recently, atopic disorders, including food allergy [20–22].
Geographic Variations in Anaphylaxis
Estimates of anaphylaxis incidence vary widely, from 3.2 to 60 per 100,000 patient-years [23, 24], in part likely related to differences in the definition of anaphylaxis used; the research setting (hospital or community based); or whether calculations have been made based on actual episodes of anaphylaxis, estimates of the proportion of the population at risk (e.g., incidence of allergy to known triggers), or epinephrine autoinjector prescription rates [25, 26]. One potential influence rarely examined in a systematic way is whether geographic variation may also occur. Based on the hypothesis linking early-life vitamin D status with recurrent wheezing and possibly asthma [27], Camargo and colleagues [28] examined geographic variation in epinephrine autoinjector prescription rates in the United States, demonstrating fourfold higher prescription rates in (the less sunny) northern United States compared with sunnier southern regions that could not be accounted for by measured demographic factors (Fig. 1). This novel finding raised the possibility of an etiologic role for sunlight/vitamin D status in food allergy, a major driver of epinephrine autoinjector prescriptions. Similar geographic patterns were previously observed for some other disorders, such as multiple sclerosis and type 1 diabetes [29]. These US epinephrine autoinjector findings were reproduced and extended in an Australian study by the authors that demonstrated that hospital anaphylaxis admission rates and epinephrine autoinjector prescription rates were significantly higher in less sunny southern regions of the country (Fig. 2) [30], although most prominent in children 0 to 4 years of age. Importantly, these trends could not be accounted for by demographic factors (e.g., socioeconomic status, access to medical care) and were most prominent in children 0 to 4 and 5 to 14 years of age—the age groups in which food allergy most commonly first presents and is the most common trigger of anaphylaxis [31]. Similar findings were described by Sheehan and colleagues [32], who examined hospital admissions and emergency department attendances coded as anaphylaxis in 24 pediatric hospitals in the United States. Specifically excluding sting anaphylaxis due to coding issues, overall anaphylaxis rates were higher in the 11 northern compared with the 13 southern hospitals (0.88 vs 0.63 per 1,000 encounters, respectively; P < 0.001). When reanalyzed by cause, admissions triggered by food, immunization or serum, or “other” causes (but not medication) were all more common in the northern hospitals. Specifically, the incidence of food anaphylaxis was almost double in the North compared with that in the South (0.31 vs 0.17 per 1000 encounters; RR, 1.81; 95% CI, 1.66–1.98; P < 0.001), although a separate study by the same group demonstrated that higher rates of sting anaphylaxis were more common in southern regions [33]. By contrast, no latitudinal pattern in self-reports of food allergy was found by Hughes and colleagues [34] in Australia, although these conclusions were based on only 14 older individuals aged 18 to 61 years. Most recently, Mulla and colleagues [35] compared anaphylaxis admission rates in New York (northern United States) and Florida (southern United States) and found twice the rate of anaphylaxis admissions in New York residents in patients 0 to 19 years of age, with a reversal in older age groups. Taken as a whole, these studies suggest that latitudinal patterns may be influenced by age and cause of anaphylaxis, and that subanalysis of data is required for appropriate interpretation.
Childhood Food Allergy
Despite recent increases in anaphylaxis-related emergency department visits and hospital admissions in the United Kingdom [36], Australia [37], and United States [38]; more frequent anaphylaxis diagnoses in community-based studies [39, 40]; and specific evidence of increased peanut allergy prevalence in birth cohort and community-based studies [41–43], risk factors for food allergy and anaphylaxis remain poorly defined. Hypotheses for these increases include changes in exposure to microbial products, topical sensitization, Caesarean section births, antacid medication use by infants, food processing methods, timing of introduction of allergenic food, or factors related to socioeconomic status or location of residence, as recently reviewed [5, 44–47]. That vitamin D status might also play a role in food allergy pathogenesis is suggested by a consistent inverse relationship between increasing latitude and proxy markers of food allergy prevalence, specifically higher rates of epinephrine autoinjector prescriptions and food allergy–related hospital admissions in less sunny regions of the United States and Australia [28, 30, 32] and higher infant hypoallergenic formula prescription rates in less sunny southern regions of Australia (Fig. 3) [48]. This hypothesis is reinforced by recent evidence of higher rates of food sensitization and physician-diagnosed FA in infants born in fall/winter compared with sunnier months in Europe [49, 50], the United States [51], and Australia (Fig. 4a) [52]; higher rates of food sensitization in infants born to mothers with low vitamin D intake during pregnancy [53]; and higher rates of food sensitization in children and adolescents (but not adults) with vitamin D deficiency [54••].
Vitamin D Status and Other Atopic Disorders
Evidence that vitamin D status may be involved in the pathogenesis of atopic disorders is derived from epidemiologic and clinical studies and from in vitro studies examining the influence of vitamin D on immune function. Several studies have linked vitamin D deficiency with atopic dermatitis and recurrent wheezing in early life [27, 55, 56], two components of the “atopic March” of early-childhood. Observational studies also have linked low vitamin D status with impaired lung capacity, increased bronchial reactivity, relatively poor asthma control, steroid unresponsiveness, and higher rates of asthma-related hospitalization, as recently reviewed [57–59]. Low intakes of vitamin D during pregnancy also have been linked to the presence and severity of allergic rhinitis in offspring [60]. Low 25(OH)D levels at age 6 and 14 years have been associated with higher rates of atopic disease in unselected community birth cohorts [61••]. One small, prospective, randomized, double-blind trial of vitamin D supplementation demonstrated a halving of infection-related asthma exacerbation [62••] and risk of wintertime influenza A [63]. Vitamin D status has been associated inversely with eczema severity [64], and sun exposure or vitamin D supplementation has been associated with clinical improvement in atopic eczema in small studies [55, 65].
By contrast, ecological studies examining latitudinal variation in disease prevalence (as a proxy marker of vitamin D status) have yielded conflicting results. Whereas the relationship between latitude and proxy markers of food allergy/anaphylaxis prevalence is relatively consistent (as discussed above), conflicting evidence of a relationship between latitude and prevalence of atopic eczema [29, 66, 67] and allergic rhinitis [34, 67, 68] has been observed. These findings raise the possibility that if vitamin D status does play a role in the pathogenesis of atopic disease, its effect may not be uniform across all age groups or across all disorders classified as “atopic.”
Can Vitamin D Increase the Risk of Atopic Disease?
Although correction of vitamin D insufficiency may offer health benefits, it is important to consider that observational data may reflect reverse causation. For example, the relationship between asthma severity and low vitamin D status might conceivably be secondary to those with more severe disease undertaking less outdoor activity. More importantly, it is necessary to be aware of published evidence that vitamin D supplementation might directly increase the risk of allergic disease (reviewed in [69]). Maternal 25(OH)D levels greater than 30 ng/mL during pregnancy have been associated with a higher risk of offspring eczema at 9 months and asthma at 9 years compared with children born to women with levels less than 10 ng/mL [70]. The potential for harmful effects from excessive vitamin D supplementation has been supported by the results of follow-up studies demonstrating increased risk of sensitization to inhalant or food allergen, allergic rhinitis, or asthma with vitamin D–containing cod liver oil supplements during infancy [71–73], which is contrary to the findings of other studies described above. In interpreting the results of these studies, however, it is important to be aware that cod liver oil contains vitamins A and D, and that both vitamins bind the same nuclear retinoic X receptor. Thus, it is conceivable that the presence of both in the same preparation might antagonize the other’s effects [74]. Most recently, Rothers and colleagues [75] demonstrated that both lower (<10 ng/mL) and higher (≥20 ng/mL) levels of cord blood 25(OH)D were associated with higher frequency of IgE sensitization to inhalants through to age 5 years compared with a reference group (10–19.9 nmol/L), although no association with increased risk of allergic rhinitis or asthma was observed [75]. In sum, the precise connection among sunlight, vitamin D, and allergic diseases, while intriguing, remains unclear.
Vitamin D and Immune Function
The biological plausibility of the “vitamin D–allergy hypothesis” is informed by growing evidence of the pleiotropic effects of vitamin D on the developing immune system. Recent studies have demonstrated associations between vitamin D receptor polymorphism and asthma risk [76]; between genetic variants in the vitamin D activation enzyme, vitamin D levels, and total IgE [77]; and between low vitamin D intake during pregnancy and higher cord blood interleukin-10 levels [78], known to suppress IgE production (reviewed in [74]). Furthermore, vitamin D receptor agonists have been shown to suppress allergen-specific IgE synthesis in vitro and in vivo [79, 80], modulate dendritic cell maturation to induce tolerogenic dendritic cells, induce regulatory CD4+CD25+forkhead box P3 (FoxP3)+ T cells, but also FoxP3-Treg1 cells expressing interleukin-10 [81••], thus affecting both T-helper type 1 (Th1) and Th2 cell function, as recently reviewed [74].
Although the potential effect of vitamin D on Th1/Th2 adaptive immune response is of interest, actions on the innate immune system are also important. For example, several studies have demonstrated an inverse relationship between vitamin D status and increased risk of respiratory tract infections [82••] and increased risk of wheezing in early life [27], [82••, 83] without any apparent effect on incident asthma at age 5 years [82••]. Vitamin D stimulates production of antibacterial peptides such as cathelicidin, which in experimental models is considered to have a role in enhancing resistance to infection and maintaining mucosal integrity (reviewed in [21]). It is conceivable that disrupted mucosal integrity and impaired tolerization (and perhaps altered gut microbiota) resulting from vitamin D deficiency may act synergistically with allergen exposure to increase the risk of sensitization at critical periods of immune development.
Conclusions
If sunlight/vitamin D status is one of the many factors playing a role in the pathogenesis of one or more allergic diseases, the relationship between sunlight/vitamin D status and risk may not be linear. As with any hormone, supraphysiologic vitamin D levels might also be harmful, as recently reviewed [77]. Furthermore, any impact of vitamin D status on disease risk may not be uniform across all age groups or applicable to all disorders traditionally classified as “atopic.” If vitamin D is demonstrated to play a role in disease pathogenesis, it may force a reconsideration of data from published trials examining the relative benefits of breastfeeding (in which neonatal vitamin D status is dependent on that of the mother and thus variable) compared with infant formula feeding (in which vitamin D supplementation is routine). Further evidence of a possible role of sunlight/vitamin D status in pathogenesis, however, will require prospective cohort studies of neonatal 25(OH)D levels and subsequent risk of disease. If consistent associations are found, observational studies could be followed by randomized controlled trials to test causality more formally and monitor for adverse effects [84]. This would need to be undertaken in several age and ethnic groups and need to take account of the significant genetic variability of the response to dietary supplementation and metabolism of vitamin D, as recently described [15••]. Long term, the potential survival benefits of sun exposure on vitamin D status need to be balanced with the known deleterious long-term consequences of increased risk of skin cancer (which generally occurs beyond reproductive age), which may force consideration of the relative merits of modest sun exposure with oral supplementation [85••]. Regardless of the potential contribution by sunlight/vitamin D status to the pathogenesis of food allergy/anaphylaxis, the frequency of vitamin D deficiency in pregnant women without obvious risk factors [16••, 17••] and their neonates is a general health concern [11, 16••, 17••]. This high frequency provides a rationale, in our opinion, to screen all pregnant women (not just high-risk groups) and to supplement individuals found to have vitamin D deficiency. The exact threshold for treatment and optimal regimen will require further study.
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Disclosure
Dr. Mullins has received unrestricted investigator-initiated grants from Commonwealth Serum Laboratories Australia and Alphapharm Australia, Abbott Nutrition Australia, and the Ilhan Food Allergy Foundation.
Dr. Camargo has received investigator-initiated research grants from and served as a consultant for Dey Pharma and Sanofi-Aventis. Study sponsors had no input into the contents of this article.
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Mullins, R.J., Camargo, C.A. Latitude, Sunlight, Vitamin D, and Childhood Food Allergy/Anaphylaxis. Curr Allergy Asthma Rep 12, 64–71 (2012). https://doi.org/10.1007/s11882-011-0230-7
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DOI: https://doi.org/10.1007/s11882-011-0230-7