Thymic stromal lymphopoietin (TSLP)-mediated dermal inflammation aggravates experimental asthma.

Individuals with one atopic disease are far more likely to develop a second. Approximately half of all atopic dermatitis (AD) patients subsequently develop asthma, particularly those with severe AD. This association, suggesting a role for AD as an entry point for subsequent allergic disease, is a phenomenon known as the "atopic march." Although the underlying cause of the atopic march remains unknown, recent evidence suggests a role for the cytokine thymic stromal lymphopoietin (TSLP). We have established a mouse model to determine whether TSLP plays a role in this phenomenon, and in this study show that mice exposed to the antigen ovalbumin (OVA) in the skin in the presence of TSLP develop severe airway inflammation when later challenged with the same antigen in the lung. Interestingly, neither TSLP production in the lung nor circulating TSLP is required to aggravate the asthma that was induced upon subsequent antigen challenge. However, CD4 T cells are required in the challenge phase of the response, as was challenge with the sensitizing antigen, demonstrating that the response was antigen specific. This study, which provides a clean mouse model to study human atopic march, indicates that skin-derived TSLP may represent an important factor that triggers progression from AD to asthma.

Introduction

Atopic dermatitis (AD), one of the most common allergic skin inflammatory diseases, has a particularly high prevalence among infants and children. Onset is during the first 6 months of life in 45% of all cases [1]. Based on several longitudinal studies, approximately half of AD patients will develop asthma, especially with severe AD, and two thirds will develop allergic rhinitis. In general, the clinical signs of AD predate the development of asthma and allergic rhinitis, suggesting that AD is an entry point for subsequent allergic diseases [2, 3], but the molecular mechanisms underlying the “atopic march” remain unclear.

Recently, thymic stromal lymphopoietin (TSLP), an IL-7-related cytokine, has emerged as an important potential contributor to allergic inflammation. While TSLP was initially identified and characterized in thymic stromal cells [4, 5], it is expressed predominantly in epithelial cells (ECs) of the skin (keratinocytes), lung (small airway ECs), and intestine (intestinal ECs) [6-8]. Originally discovered due to its potent effects on B and T cell growth and differentiation [9-11], TSLP has also been shown to be associated with the pathogenesis of multiple inflammatory diseases including atopic dermatitis and asthma. The involvement of TSLP in allergic inflammation was first demonstrated in atopic dermatitis patients. TSLP protein, although undetectable in normal and nonlesional skin in these patients, is highly expressed in acute and chronic AD lesions [8]. In addition, human asthmatics have increased concentrations of TSLP in their airways correlating with Th2-attracting chemokine expression and disease severity [12]. Murine models have extended these findings, showing that inducible epidermal TSLP expression induces a spontaneous AD-like disease [13] characterized by all the hallmark features of human AD. In contrast, TSLPR-deficient mice exhibited a dramatically reduced Th2-type inflammatory response in a FITC contact hypersensitivity based model of AD [14]. Mice expressing surfactant protein C promoter-driven TSLP in the lung developed severe airway inflammation [15] while mice deficient in the TSLP receptor failed to develop asthma in response to inhaled antigen [15, 16].

TSLP is considered a likely candidate for perpetuating the atopic march for several reasons. First, TSLP expression has been found at elevated levels in the skin of AD patients and in the lungs of asthmatics [8, 12]. Second, TSLP is an epithelial cell-derived cytokine; and both AD and asthma develop at epithelial cell surfaces [17]. Third, as described previously, a role for TSLP in allergic inflammation has been demonstrated in both humans and mice. Finally, three models of induced expression of TSLP in mouse keratinocytes resulted in subsequent airway inflammation following challenge. These models include topical application of a vitamin D3 analogue and keratinocyte-specific deletion of the Notch signaling pathway [18, 19]. An important caveat in these studies is that the methods used to induce TSLP expression results in artificially high systemic levels of TSLP, which is not seen in AD patients.

To develop a model to test the role of TSLP in the atopic march we extended work showing that intradermal injection of TSLP in wild-type mice led to a marked increase of inflammatory infiltrate in the subcutis, in the absence of detectable circulating cytokine [20]. We administered TSLP, in the presence of antigen, via intradermal injection, to ask whether subsequent challenge with antigen in lung was capable of inducing airway inflammatory disease. We demonstrate that intradermal administration of TSLP and OVA leads to an allergic asthma-like phenotype upon intranasal challenge with OVA. Interestingly, in contrast to previous studies [18], neither TSLP production in the lung nor circulating TSLP is required to aggravate the disease induced upon OVA challenge. TSLP-induced responses are antigen-specific and T cell-dependent in this model. In addition, allergic disease development is blocked through oral exposure to OVA antigen prior to, but not after, skin sensitization. Our study demonstrates that skin-restricted TSLP triggers a progression from atopic dermatitis to asthma.

Results

Mice sensitized in the skin in the presence of TSLP develop aggravated asthma-like airway inflammation upon challenge

Epidemiological studies have shown that children with AD, especially those with severe disease, are likely to also develop asthma, demonstrating a link between these two conditions [2]. Given its purported role in these allergic diseases, TSLP was a likely candidate as the factor that links AD and asthma. Our laboratory has found that mice with a skin-specific inducible TSLP transgene develop an AD-like disease, as well as pulmonary inflammation ([13] and Fig. S1). However, we also observed inflammatory infiltrates in a wide variety of organs including liver, gastrointestinal tract, and spleen (Fig. S1) perhaps due to elevated systemic levels of TSLP. We therefore sought to develop a mouse model that recapitulates human atopic disease and determine whether TSLP plays a role in this phenomenon. To test this, we modified a protocol from Jessup et al. for TSLP-mediated skin inflammation [20]. Wild-type BALB/c mice were treated with TSLP and the antigen OVA intradermally (four times over two weeks) to induce an AD-like skin inflammatory disease. Following a nine-day rest period the mice were treated intranasally with OVA for four consecutive days (Fig. 1A). Consistent with the induction of Th2-type inflammation by TSLP treatment, total serum IgE and OVA-specific IgE were markedly elevated in TSLP+OVA treated mice (Fig. 1B and C). To assess lung infiltration of leukocytes, bronchoalveolar lavage (BAL) fluid was analyzed on day (D) 25. In PBS-exposed mice, regardless of sensitization status, the predominant cell type seen in BAL was the alveolar macrophage. TSLP skin sensitization without antigen failed to alter the cellular composition of the BAL upon subsequent OVA re-challenge, while mice where Mouse Serum Albumin (MSA) was substituted for TSLP during the sensitization phase showed only mildly increased cell infiltration. In contrast, following OVA re-challenge, exposure of mice to TSLP+OVA at sensitization caused an influx of eosinophils into the BALF and increased cellular infiltrate three-fold over the mice given MSA+OVA (Fig. 1D).

Figure 1

Intradermal administration of TSLP aggravates airway inflammation and mucus secretion in experimental asthma. (A) Experimental protocol. Mice received injections of TSLP and OVA (5 μg) four times for 12 days and rested for 9 days. To induce experimental asthma, mice were OVA challenged (50 μg in 30 μL saline) on 4 consecutive days (D21–D24) by intranasal instillation. Mice were killed on D25 for analysis. Total serum IgE (B) and OVA-specific IgE (C) on D25 (n = 5, two independent experiments). (D) Cell counts in the BAL fluid. The significance between two groups was determined by two-tailed Student’s t test. (n = 5, two independent experiments). (E) Representative lung tissue cross sections stained with PAS to visualize mucus-producing goblet cells and airway inflammation. Bar, 100 μm.

Consistent with increases in BAL cellularity, histopathological analysis of lung section showed that only mice sensitized in the skin with TSLP+OVA showed severe inflammatory infiltrates (data not shown). In addition, lungs from these mice also showed enhanced goblet cell metaplasia and mucus overproduction by PAS staining, while lungs from the other groups did not (Fig. 1E). This suggests that intradermal administration of TSLP during the antigen sensitization phase is necessary to aggravate allergic airway inflammation in this model.

IL-4, IL-5, IL-10, and IL-13 production from restimulated inguinal lymph node CD4 T cells were very low and showed no difference compared to control groups, indicating that skin inflammation was resolved at the time that lung inflammation developed (data not shown). Analysis of lung cytokine RNA levels showed that, compared with MSA+OVA treatment, TSLP+OVA treatment induced the production of the Th2 cytokines IL-4, IL-10, IL-13, and TNF, as well as of eosinophil chemoattractant chemokine (eotaxin-2) (Fig. 2A).

Figure 2

Airway inflammation does not require systemic TSLP. (A) No locally induced TSLP. Quantitative RT-PCR analyses of cytokines and chemokines in lungs on D25. n ≥ 4 mice per group. The significance of gene expression between two groups was determined by two-tailed Student’s t test. (B) and (C) No circulating TSLP. Serum TSLP levels not enhanced on D14 (B) and D25 (C). K5-TSLP mice were treated on 1mg/ml of doxycycline for 3 weeks and used as positive control. n ≥ 4 mice per group. N.D., < 7.8 pg/ml.

To ensure that the disease we observed in this model system was TSLP-dependent and not due to the influence of potential contaminating factors such as LPS in either the TSLP or OVA stocks, LPS-unresponsive TLR4mut mice were subjected to the same skin sensitization and lung challenge model. The TLR4mut mice developed disease indistinguishable from that seen in WT mice (Fig. S2). Thus, the aggravated airway inflammatory response seen in wild-type mice was due to the presence of TSLP during the sensitization step.

To determine whether increasing the time between skin exposure to TSLP plus antigen and lung challenge affected development of airway inflammation, the interval between skin sensitization and lung challenge was increased from 9 to 30 days. The airway inflammation that developed in mice sensitized in the skin with TSLP+OVA in this protocol was indistinguishable from that shown in Figure 1 for mice rested 9 days (Fig. S3).

To determine the specificity of the response to skin sensitization in the presence of TSLP we asked whether a second epithelial-derived cytokine, IL-25, could promote a similar set of responses. Rapidly emerging studies implicate IL-25 as a critical regulator of innate and adaptive immune responses associated with Th2 cytokine-mediated inflammation at mucosal sites [21]. In addition, IL-25 expression is elevated in the skin of atopic dermatitis patients, suggesting a role in disease [22]. However, mice sensitized in the skin with IL-25+OVA, followed by pulmonary challenge with OVA, showed no elevated levels of total serum IgE and OVA-specific IgE (Fig. S4 A and B) and mildly increased cell infiltration (Fig. S4C).

Airway inflammation does not require systemic TSLP

The data shown above clearly shows the requirement for TSLP during the skin sensitization phase in this model. To begin to determine if TSLP was also involved directly during the lung challenge, TSLP mRNA expression levels in the lungs of all treatment groups was measured on D25, as was circulating TSLP in the serum on days 14 and 25. Lung TSLP mRNA levels were equivalent in all groups (Fig. 2A), and TSLP protein in the serum was undetectable (<7.8 pg/ml), suggesting that circulating TSLP is not required for the development of allergic airway inflammation upon re-challenge in this model (Figs. 2B and C). To further assess the role of TSLP in this process we took 2 approaches. For the first approach TSLP-deficient mice were sensitized in the skin with TSLP+OVA as before, and then challenged intranasally with OVA. As shown in Figure 3A, the TSLP-deficient mice responded to the intranasal challenge as robustly as the TSLP-sufficient mice, showing that TSLP was not required for the airway challenge. To exclude a role for systemic TSLP during the skin sensitization phase, mice were treated intranasally with an antibody to murine TSLP (anti-TSLP) on D0 and D8. Airway inflammation in anti-TSLP-treated animals was indistinguishable from that seen in control antibody treated mice (Fig. S5). To ascertain whether TSLP was required during airway challenge, TSLP+OVA-sensitized mice were given anti-TSLP the days before intranasal OVA challenge. Again, anti-TSLP-treated mice developed robust airway inflammation following OVA challenge (Fig. 3B). Taken together, we conclude from these studies that increased skin-restricted TSLP levels during the antigen sensitization phase is sufficient to yield an aggravated response to antigen when subsequently encountered within the lung.

Figure 3

TSLP is dispensable once skin inflammation develops. (A) Total number and differential cell counts of cells isolated from BAL taken from TSLP–deficient (TSLP-KO) or WT BALB/c mice treated with MSA or TSLP plus OVA followed by OVA challenge. n ≥ 5 mice per group from two independent experiments. (B) Acute blockade of TSLP after skin sensitization does not inhibit allergic asthma. Cell counts in the BAL fluid. n ≥ 4 mice per group from two independent experiments. The significance between two groups was determined by two-tailed Student’s t test.

Airway disease development is dependent on CD4 T cells

Studies in mouse models of asthma have shown that allergic airway inflammation is dependent on CD4 T cells and more specifically, is seen when T-cell receptor-transgenic Th2, but not Th1, cells are adoptively transferred to mice [23-27]. TSLP, when injected intradermally together with OVA, induced IL-4-producing CD4+ T cells (Fig. S6), as described before [20]. The role of CD4 T cells in atopic airway inflammation was assessed in mice treated with the depleting anti-CD4 antibody GK1.5. Mice were treated with anti-CD4 nine days prior to intranasal OVA challenge, and again three days before. This led to a nearly complete loss of CD4+ T cells. Acute depletion of CD4 T cells also led to a dramatic reduction in airway disease development, as measured by BAL infiltrates, airway eosinophilia, and mucus production (Fig. 4A and data not shown). These data demonstrate that CD4+ T cells are required for the induction of pulmonary inflammation following skin sensitization.

Figure 4

CD4 T cells are required for TSLP-mediated airway inflammation. (A) Cell counts in BAL fluid from WT BALB/c mice treated i.p. with rIgG or anti-CD4 Ab (GK1.5), to acutely deplete CD4 T cells after skin sensitization. n ≥ 4 mice per group from two independent experiments. (B) DO11.10 CD4+ T cells were transferred to WT BALB/c mice and then sensitized with TSLP+OVA (solid squares) or MSA+OVA (open squares). On D14, CD4+ T cells were isolated and negatively selected prior to transfer of 2 ×107 cells/mouse. Recipient mice were intranasally challenged with OVA starting 24 hours after transfer, and airway symptom were monitored as above. Cell counts in BAL fluid. n = 5 mice per group. The significance between two groups was determined by two-tailed Student’s t test. (C) Skin-draining LN cells from TSLP+OVA treated mice transfer disease to naïve mice. Skin-draining LN cells from mice treated with TSLP+OVA (solid square) and MSA+OVA (open square) were isolated, and cells were cultured with OVA (100 μg/mL) for 72 hours prior to washing and intravenous transfer to naïve mice (2 × 107 cells/mouse). Cell counts in BAL fluid. n = 5 mice per group. The significance between two groups was determined by two-tailed Student’s t test.

To determine the nature of the CD4 T cells that were driving lung pathology, TSLP+OVA primed mice were depleted of CD4 T cells as described above, and naïve, OVA-specific DO11.10 CD4 T cells were adoptively transferred prior to intranasal OVA challenge. As shown in Figure S7, reconstituting mice with DO11.10 CD4 T cells failed to develop the airway inflammatory phenotype in response to i.n. OVA. These data are consistent with a critical role of memory CD4 T cells, primed during skin sensitization, becoming reactivated following intranasal challenge.

We hypothesized that the lack of OVA-specific CD4+ T cells in the airway was responsible for the lack of allergic symptoms. To test this, we first transferred DO11.10 CD4+ T cells to WT BALB/c mice prior to skin sensitization. CD4+ T cells from primed mice were then isolated and further transferred to naïve recipient mice. Upon intranasal challenge, only mice receiving CD4+ T cells from TSLP+OVA treated mice developed airway inflammation (Fig. 4B). Alternatively, we transferred skin-draining LN cells from sensitized mice with allergic skin inflammation into naïve mice. After OVA challenge of these mice, transfer of the primed cells from TSLP+OVA treated mice restored airway inflammation (Fig. 4C) in recipient mice. Taken together, these data demonstrate a critical role of CD4+ T cells in the inflammation seen in these mice.

Airway inflammation is antigen-specific

Early exposure to high levels of birch pollen in infancy increases the risk of skin sensitization and allergic asthma to the same allergen [28]. To test the antigen specificity of our atopic model, mice were sensitized in the skin with TSLP+OVA, and then challenged in the airways with a second antigen, BSA. Control experiments showed that mice sensitized and challenged with BSA responded in a manner similar to that seen with OVA (Fig. 5). However, mice that were OVA-sensitized and then exposed to intranasal BSA on day 21 displayed a lack of airway inflammation, as judged by total BAL cellularity, eosinophil counts and antigen-specific IgE (Fig. 5A, B and C). Similarly, BSA-sensitized and OVA-exposed mice were also free of airway inflammation (Fig. 5A and B). Similar results were obtained when house dust mice (HDM) antigen was used as a second antigen (Fig. S8). These data demonstrate that the effect seen in TSLP+antigen sensitized and challenged mice was antigen-specific.

Figure 5

Airway inflammation is antigen-specific. To test the antigen specificity of atopic model, low endotoxin BSA used to sensitize and challenge the mice. (A) Total cell counts in BAL fluid. (B) Differential cell counts in BAL. (C) Serum OVA and BSA-specific IgE on D25. n ≥ 4 mice per group from two independent experiments.

Tolerance to antigen can be achieved before skin sensitization, but not after

Previous studies have shown that mice can be tolerized to an aero-antigen through oral administration of the same antigen [29-32]. We sought to determine whether oral administration of OVA, either before or after skin sensitization, was capable of tolerizing the mice to subsequent airway exposure to antigen. Mice were given dietary OVA (in the drinking water) for 5 days, either days −7 through −2 prior to skin sensitization (referred to as Tol −7), or days +14 through +19 after the initiation of skin sensitization (referred to as Tol 14). Both untreated and Tol mice were sensitized and challenged as before, and the affect of oral OVA treatment on airway inflammation was determined. As expected from previous studies, the Tol −7 group displayed much-reduced airway inflammation (Fig. 6). BAL cellularity was reduced to levels seen in control animals, and both total and antigen-specific IgE were dramatically decreased (Fig. 6A and B). In addition, BAL eosinophil numbers were reduced by more than 15-fold, and goblet cell metaplasia, mucus overproduction, as well as overall lung inflammation, were markedly decreased (data not shown).

Figure 6

Antigen feeding before, but not after, skin sensitization suppresses asthma-like inflammatory response. Mice were administered a 1% OVA solution in drinking water for 5 consecutive days (days –7 to –2, Tol -7; or days 14 to 19, Tol 14). (A) Cell counts in BAL fluid. (B) Total and (C) OVA-specific serum IgE on D25. n = 4 mice per group from two independent experiments.

In contrast, the Tol 14 group, when challenged via the airways, displayed an inflammatory response largely equivalent to that seen in the control group (Fig. 6). The Tol 14 group showed increased BAL cellularity, lung inflammation, and elevated IgE levels (Fig. 6 and data not shown). These data show that, while naïve mice can be tolerized to antigen, once sensitized in the presence of TSLP the mice are no longer capable of developing tolerance to that antigen.

Transgenic mice co-overexpressing TSLP and antigen in the skin develop aggravated asthma-like airway inflammation upon challenge

To study immune responses induced to skin-associated self-Ags, we used mice that inducibly express a TSLP transgene specifically in keratinocytes in the presence of dietary doxycycline [13]. These mice were crossed to mice that contain a similar transgene that expresses a membrane-bound form of ovalbumin, using the same regulatory mechanisms as the K5-TSLP mice (see Methods for details of the mouse strains). We generated triple transgenic mice (referred to as K5-TSLP/TGO), allowing keratinocyte-specific expression of both transgenes in the presence of doxycycline. We first monitored proliferation of OVA-specific CD4 T cells following transfer into doxycycline -treated K5-TGO mice. Following transfer, robust proliferation was seen in skin draining lymph, with much less seen in more distal sites (Fig. 7A). No proliferation was observed when cells were transferred into control mice. K5-TSLP/TGO mice were then given dietary doxycycline (1 mg/ml for 3 weeks) to induce TSLP and OVA expression in keratinocytes. To exclude a role for circulating TSLP affecting responses during the skin sensitization phase, mice were treated intranasally with the anti-mTSLP antibody described above on D0 and D12. At the end of the doxycyline treatment period the skin of the K5-TSLP/TGO mice displayed features consistent with eczematous inflammation [13], which subsequent receded and ultimately disappeared during the rest period. These features were not present in doxycycline-treated K5-TGO skin. Following an 18-day rest period the mice were treated intranasally with OVA for four consecutive days. Only the K5-TSLP/TGO mice developed airway inflammation (Fig. 7B and C). Thus the induced expression of epidermal TSLP with OVA was sufficient to drive an aggravation of the asthma that was generated upon OVA challenge at a time when the skin AD had resolved.

Figure 7

Mice overexpressing TSLP and antigen in the skin develop aggravated asthma-like airway inflammation. (A) OVA-specific T cells are primed in K5-TGO mice. K5-TGO mice received 1 mg/ml of doxycycline for 3 weeks of treatment. Profile of DO11.10 CD4 T cells transferred into K5-TGO (left) and control (right) mice were determined in inguinal lymph node (upper) and spleen (lower). (B) Total cell counts and differential cell counts in the BAL (n = 4). (C) H&E staining of skin (upper) and PAS staining of lung (lower) from K5-TSLP/TGO mice (left) and K5-TGO mice (right). Bar, 100 μm.

Discussion

Allergic diseases tend to develop in a sequential manner in childhood, a phenomenon referred to as the “atopic march” [33]. A wide variety of epidemiological and birth-cohort studies have been performed to attempt to explain this. For example, this phenomenon commonly manifests as a child with atopic dermatitis going on to subsequently develop asthma, or allergic reactions to aeroallergens [34]. This may be due to fact that, of the atopic diseases, atopic dermatitis seems to develop earliest, with 85% of those individuals with the disease becoming symptomatic by age 5 [35]. This phenomenon has suggested that these diseases share a common underlying mechanism or factor, capable of promoting a Th2-type response to environmental antigens. One candidate for this factor is TSLP, which is overexpressed in the affected tissues in each of these diseases [8, 12, 36]. The work presented herein supports this model, and demonstrates that sensitization to antigen, in the presence of TSLP, in the skin leads to aggravated pulmonary responses when that antigen is inhaled.

Recently two studies have shown a link between elevated TSLP expression in the skin and airway inflammation following aero-antigen challenge [18, 19]. Similarly we have found that, in addition to skin inflammation, dox-treated K5-TSLP mice develop pulmonary inflammation similar to the SPC-TSLP mice after >5 weeks of treatment (Fig. S1). The major caveat with each of these systems is that, unlike human AD patients, these mice all displayed elevated circulating levels of TSLP (Figure 2 and [18, 19]). Thus, it is not possible to distinguish between an effect of circulating TSLP promoting responses directly in the lung, or an alteration of responses in the lung subsequent to TSLP effects locally in the skin. In addition to pulmonary inflammation, these 3 mouse models also develop a variety of inflammatory responses at other sites, further complicating the interpretation of the data [10, 19, 37]. To circumvent these caveats we have developed a mouse model that uses intradermal injection of TSLP, in the presence or absence of antigen, followed by intranasal challenge after a rest period (see Fig. 1 for schematic of model). As shown in Figure 1, these mice develop significant airway inflammation following intranasal challenge. Importantly, they do not have detectable circulating levels of TSLP. For these reasons we feel that this model more faithfully represents the events involved in the atopic march.

Epicutaneous sensitization with allergen followed by airway challenge induces airway inflammation and airway hyperresponsiveness [38, 39]. Our data provide strong evidence that cutaneous exposure to allergen, in the presence of TSLP, can trigger progression from atopic dermatitis to asthma. Using intradermal administration of TSLP, we found that mice sensitized to an antigen in this fashion develop allergic airway inflammation when subsequently challenged via the airways with the same antigen. This indicates that allergen sensitization in the skin can affect and sensitize the airways. Interestingly, our data indicates that TSLP is only involved in the sensitization phase of the response while the subsequent response to pulmonary challenge is TSLP independent. This suggests that TSLP is acting locally to drive the initial response to allergen challenge, and that the subsequent “march” of the allergic response to the lung is regulated by signals delivered during this cutaneous response. While the factors that mediate the lung pathology following intranasal challenge remain to be elucidated, our data demonstrates that CD4 memory T cells are required for airway inflammation. Administration of naïve, antigen-specific cells following skin sensitization and CD4 depletion failed to reconstitute the pulmonary response following antigen challenge.

TSLP is one of several epithelial-derived cytokines capable of promoting type-2 immune responses [21]. In particular, IL-25 expression, like TSLP, is elevated in lesional skin of atopic dermatitis patients [22, 40]. It has also been shown to promote Th2-type responses through the expansion of skin-homing Th2 memory cells [22]. It was of note, therefore, that cutaneous administration of antigen with IL-25 failed to promote airway inflammation upon subsequent pulmonary antigen challenge (Fig. S4). These data suggest that the response seen in mice sensitized with antigen and TSLP is specific for TSLP, and not simply a general promotion of a Th2 response.

Finally, the observation that once sensitized to antigen in the presence of TSLP mice cannot be tolerized to that antigen is of significance and has implications for the development of treatments for individuals that develop asthma subsequent to AD. Since, before skin immunization, naïve OVA-specific T cells that will become Tregs cannot be distinguished from those that will become Th2 cells, it remains to be determined whether generation of Tregs versus that of effector T cells is a stochastic process or some microenvironmental conditions promote the development of one cell type over the other. Therapies that modify the severity of AD in infants and young children might decrease the risk for the eventual development of asthma.

In conclusion, our present study not only provides a mouse model for studying possible mechanisms involved in the “atopic march” but also suggests that overproduction of TSLP in the skin of patients with AD could be a risk factor for the development of allergic airway inflammation. Together our study support the hypothesis that skin may be an important site for systemic sensitization to certain allergens, and that epidermal TSLP may promote sensitization, asthma and food allergies. Collectively, the results of our study elucidate a novel mechanism for the atopic march, and implicate TSLP as an initiating factor in this disease process.

Materials and Methods

An expanded Materials and Methods section is available in the Online Data Supplement.

Mice and injections

6 to 8-wk-old female BALB/c mice were obtained from Charles River Laboratories. K5-TSLP mice were generated as described previously [10, 13]. C3H/Hej-BALB/c (TLR4mut) and DO11.10 mice were purchased from The Jackson Laboratory and described previously [41]. All animals were housed in specific pathogen free conditions in the Benaroya Research Institute animal facility. Intradermal injections were performed, as previously described [20], with minimal modifications to the dose volume. Briefly, fur was stripped from the lower backs of mice, and 5 μg TSLP (generous gift of Amgen Inc.) or MSA (Sigma-Aldrich) with OVA (A7642; Sigma-Aldrich), low endotoxin BSA (Sigma-Aldrich) or HDM (Greer Laboratories) were injected intradermally in a 100 μl volume of sterile PBS by inserting the needle into the superficial dermis as close to the epithelium as possible. Experimental protocols were approved by the Institutional Animal Care and Use Committees of Benaroya Research Institute (Seattle, WA). Detailed information on the generation of TRE-TGO and TSLP deficient mice is in the Online Data Supplement.

TSLP antibody treatment

To block TSLP in the lung at time of skin sensitization, an antibody to murine TSLP (R&D Systems) was administered intranasally (50 μg i.n. on D0 and D8). Acute blocking of TSLP after skin sensitization was performed as previously described [14], with minimal modifications. In brief, mice were treated with TSLP blocking antibody on days 14 (200 μg i.p.) and 15 (100 μg i.v.). Mice received further treatments on days 19 (100 μg i.v.) and 20 (50 μg i.n.) followed by OVA challenge.

Statistics

All statistical analysis was performed using GraphPad Prism 5. Unless otherwise indicated, all statistical tests are one-way ANOVA with a Tukey post-hoc test with significance between groups represented as * for p≤ .05, ** for p≤ .01, and *** for p≤ .001.