Aimee Hoskins

Natural source d-α-tocopheryl acetate inhibits oxidant stress and modulates atopic asthma in humans in vivo

Asthma is associated with oxidant stress and diminished antioxidant defenses. Yet, the mechanistic role of oxidant stress and antioxidant supplementation in human asthmatics remains uncertain. We determined the effect of high doses of the antioxidant natural‐source d‐α‐tocopheryl acetate for 16 weeks on allergen‐induced airway oxidant stress, inflammation, and bronchial responsiveness to methacholine and allergen in atopic asthmatics in vivo.

Vitamin E prevents NRF2 suppression by allergens in asthmatic alveolar macrophages in vivo

Asthma is a chronic inflammatory airway disease associated with increased generation of reactive oxidant species and disturbed antioxidant defenses. NRF2 is the master transcription factor that regulates the expression of Phase II antioxidant and detoxifying enzymes. Disruption of NRF2 augments oxidative stress and inflammation in a mouse model of asthma, suggesting a protective role for NRF2 in the lungs in vivo. Yet, little is known about the regulation and function of NRF2 in human asthmatics. Using segmental allergen challenge, a well-established experimental model of IgE-mediated asthma exacerbation in human atopic asthmatics, we investigated the effects of a specific allergen and the modulatory role of vitamin E on NRF2 and a NRF2-target gene, superoxide dismutase, in alveolar macrophages recovered from the airways at 24h after allergen instillation in vivo. Allergen-provoked airway inflammation in sensitive asthmatics caused a profound inhibition of macrophage NRF2 activity and superoxide dismutase, rendering them incapable of responding to the NRF2 inducers. Prolonged treatment with high doses of the antioxidant vitamin E lessened this allergen-induced drop in alveolar macrophage NRF2. These results are the first to demonstrate that NRF2 expression in human asthmatics is compromised upon allergen challenge but can be rescued by vitamin E in vivo.

Asthmatic Airway Neutrophilia after Allergen Challenge Is Associated with the Glutathione S-Transferase M1 Genotype

RATIONALE Asthma is a heterogeneous lung disorder characterized by airway inflammation and airway dysfunction, manifesting as hyperresponsiveness and obstruction. Glutathione S-transferase M1 (GSTM1) is a multifunctional phase II enzyme and regulator of stress-activated cellular signaling relevant to asthma pathobiology. A common homozygous deletion polymorphism of the GSTM1 gene eliminates enzyme activity. OBJECTIVES To determine the effect of GSTM1 on airway inflammation and reactivity in adults with established atopic asthma in vivo. METHODS Nineteen GSTM1 wild-type and eighteen GSTM1-null individuals with mild atopic asthma underwent methacholine and inhaled allergen challenges, and endobronchial allergen provocations through a bronchoscope. MEASUREMENTS AND MAIN RESULTS The influx of inflammatory cells, panels of cytokines and chemokines linked to asthmatic inflammation, F(2)-isoprostanes (markers of oxidative stress), and IgE were measured in bronchoalveolar lavage fluid at baseline and 24 hours after allergen instillation. Individuals with asthma with the GSTM1 wild-type genotype had greater baseline and allergen-provoked airway neutrophilia and concentrations of myeloperoxidase than GSTM1-null patients. In contrast, the eosinophilic inflammation was unaffected by GSTM1. The allergen-stimulated generation of acute-stress and proneutrophilic mediators, tumor necrosis factor-α, CXCL-8, IL-1β, and IL-6, was also greater in the GSTM1 wild-type patients. Moreover, post-allergen airway concentrations of IgE and neutrophil-generated mediators, matrix metalloproteinase-9, B-cell activating factor, transforming growth factor-β1, and elastase were higher in GSTM1 wild-type individuals with asthma. Total airway IgE correlated with B-cell activating factor concentrations. In contrast, levels of F(2)-isoprostane were comparable in both groups. Finally, GSTM1 wild-type individuals with asthma required lower threshold concentrations of allergen to produce bronchoconstriction. CONCLUSIONS The functional GSTM1 genotype promotes neutrophilic airway inflammation in humans with atopic asthma in vivo.

Glutathione S-transferase P1 Ile105Val polymorphism modulates allergen-induced airway inflammation in human atopic asthmatics in vivo.

Glutathione S‐transferase P1 is a Phase II cytoprotective and detoxifying enzyme that is widely expressed in human airways. The glutathione S‐transferase P1 Ile105Val polymorphism has been linked with atopic disorders and asthma. Yet, little remains known about the regulation of allergic inflammation by glutathione S‐transferase P1 in human asthmatics.

Glutathione S-transferase M1 modulates allergen-induced NF-κB activation in asthmatic airway epithelium.

Glutathione S‐transferase M1 (GSTM1) is a phase II enzyme and regulator of inflammatory signaling in airway epithelial cells. We have found upregulation of neutrophilic airway inflammation in atopic asthmatics expressing GSTM1 gene (GSTM1+) compared to GSTM1null asthmatics. We hypothesized that GSTM1 modulates NF‐κB activation in bronchial epithelium in atopic asthmatics. We determined regulation of allergen‐induced NF‐κB activation in bronchial epithelium by GSTM1 in human atopic asthmatics in vivo.

Iloprost inhalation in mild asthma.

Objective. To determine the feasibility of administering iloprost by inhalation in patients with mild atopic asthma. Methods. Volunteers underwent supervised inhalation of iloprost in the clinic with measurement of spirometry and blood pressure for 2 hours. The volunteers then inhaled iloprost four times daily at a dose of 2.5 or 5 μg for 14 days. Spirometry, asthma questionnaires, peak flow diaries, measurement of methacholine responsiveness, and exhaled nitric oxide concentrations were obtained prior to and after the treatment period. Results. Chronic inhalation of iloprost (2.5–5 μg) did not alter spirometry or methacholine responsiveness. Conclusion. Inhaled iloprost in carefully selected volunteers with mild asthma appears to be a suitable intervention to explore the effects of prostacyclin in human asthma.

Exhaled Breath Condensate Formate after Inhaled Allergen Provocation in Atopic Asthmatics In Vivo

Objective. The dual actions of S-nitrosoglutathione reductase comprise reduction of S-nitrosoglutathione, a potent endogenous airway smooth muscle relaxant that is depleted in asthmatics, and detoxification of formaldehyde to formate. Airway formate production is increased in children with asthma, suggesting increased activity of S-nitrosoglutathione reductase. We determined formate in exhaled breath condensate from adult atopic asthmatics with asthma exacerbation produced by inhaled allergen in vivo, Methods. Twenty-two adult atopic asthmatics underwent inhaled allergen challenge using specific allergen. Exhaled breath condensate was collected at baseline, 1 h after inhalation of the provocative dose of allergen, and then every 2 h for 8 h during the challenge. Formate was analyzed by ion chromatography, Results. Eleven asthmatics developed an isolated early airway response, and another 11 volunteers early response followed by late airway response (dual response). Formate concentrations doubled 1 h post-challenge in asthmatics with dual-airway response but essentially unchanged in patients with an isolated early reaction, Conclusions. Dual-airway response to allergen in atopic asthmatics could be associated with increased activity of S-nitrosoglutathione reductase as suggested by greater concentrations of formate in exhaled breath condensate. Measurement of formate in exhaled breath condensate could serve as a noninvasive biomarker of S-nitrosoglutathione reductase activity in vivo. Our results need to be confirmed in a larger group of asthmatics.

Diagnostic utility of concentrated Mus m 1 allergen extract in humans

There is growing evidence that the mouse allergen is a major causative factor for allergic rhinitis, conjunctivitis, and asthma in children and adults of urban and rural populations.1 Furthermore, exposure to mice by laboratory animal workers is associated with a high risk of developing occupational allergies.2 Our Allergy practice at Vanderbilt University has recognized a number of patients with poorly controlled allergies to the mice that they work with. This clinical observation prompted an investigation for a better diagnostic and therapeutic option for our patients. The major mouse allergens belong to the lipocalin family of proteins that are synthesized in the mouse liver and secreted in the urine. The major mouse allergen is known as Mus m 1 in the allergen nomenclature. Although detectable in serum and pelt extracts, Mus m 1 concentration is 10 times greater in mouse urine than serum.3 Yet, currently the only commercially available mouse extracts are mouse epithelial extracts which contain varying low concentrations of the major mouse allergen Mus m 1 (0.5–8 µg/mL).4 We hypothesized that a highly concentrated major mouse allergen extract suitable for mouse allergy testing in humans could be isolated from mouse urine. The purpose of the study was to develop a new method for preparing mouse urine allergen extract and assess its diagnostic properties in humans. Volunteers underwent skin prick testing and intranasal challenge with the mouse urine extract to determine the diagnostic performance. To our knowledge, this is the first study to determine the diagnostic performance of mouse urine extract. We asked ALK-Abello Laboratory (Round Rock, TX) to prepare a new mouse urine extract to use in our investigation. Mouse urine collected from male laboratory mice was stored frozen until tested for Mus m 1 (Indoor Biotechnologies, Charlottesville, NC). Urine, containing 2,000 to 3,000 µg/mL of Mus m 1 was dialyzed using 0.4% phenol in normal saline, and then diluted to a concentration of 100 µg/ml. The final extract contained 100 µg/mL of Mus m 1 in 50% glycerin, 0.9% NaCl and 0.4% phenol. Qualitative analysis of protein content in the new mouse urine extract and the commercial mouse epithelial extract (ALK-Abello) were analyzed by reversed-phase liquid chromatography-tandem mass spectrometry.5 Thirty nine healthy individuals (32 women, 7 men, age 18–60 years) with a history of mouse exposure were recruited from Vanderbilt University by means of mass e-mail and advertisement. Volunteers consented verbally and in writing to the protocol that was approved by the Vanderbilt University Committee for the Protection of Human Subjects. An Investigational New Drug agreement with the U.S. Food and Drug Administration for the use of mouse urine extract for skin testing and nasal provocations in humans was in place prior to initiation of the study. Subjects discontinued any medications that could interfere with testing at least 5 days prior to the study. Patients completed a questionnaire to assess mouse-related allergic symptoms and exposure. Volunteers then underwent skin prick testing with common aeroallergens (cat and dog hair, mixed mites, German cockroach, alternaria, cladosporium, Bermuda grass, Johnson grass, pecan pollen, oak, cedar, ragweed, mixed lambs quarter) and the commercial mouse epithelial extract (ALK-Abello). Subsequently, volunteers underwent titrated skin prick testing to the new mouse urine extract. Normal saline was added to the mouse urine extract containing 100 µg/mL of Mus m 1 to produce concentrations of extract ranging from 0.33 µg/mL to 100 µg/mL. Skin prick testing to the new mouse urine extract started at 0.33 µg/mL if positive to the commercial mouse epithelial extract or 1 µg/mL if the subject was negative to the commercial mouse epithelial extract in prior testing. Regardless of the starting point, the dose was then increased by ½ log increments until the subject was considered positive or reached the maximum concentration of 100 µg/mL. Allergy testing was performed using standard guidelines and was considered positive if the wheal was ≥3 mm than negative control at 15 min post-exposure.6 Intradermal testing was not done. In addition, all volunteers, regardless of symptoms, underwent nasal challenge to the new mouse urine extract using the procedure described by Bousquet and colleagues.7 The starting point for the nasal challenge depended on the titrated skin test results and clinical symptoms to mice, as evaluated by the mouse symptom and exposure survey. Each challenge was 0.1mL of full strength mouse extract diluted with 0.9% NaCl beginning with glycerin control followed by increases in concentration of mouse allergen extract until a positive challenge or maximum dose (100 µg/mL) was reached. A positive challenge was determined by using a 13-point symptom score of sneezing, pruritis, rhinorrhea, nasal blockage and ocular symptoms.8 Each symptom was graded by the participant and accumulated to give a total score for each incremental challenge, including the glycerin control.9 The nasal challenge was considered positive if the subject had a non65 cumulative symptom score of ≥5. All participants tolerated the experiments well. The primary statistical objective was to compare the results of the titrated skin prick testing and nasal challenge of the new mouse urine extract. The sensitivity, specificity, positive predictive value and negative predictive value of the titrated skin prick test were calculated using 95% confidence intervals for each of these values by employing the Wilson score-test-based method for calculating confidence intervals for binomial probabilities and R (www.r-project.org) software. Qualitative reversed-phase liquid chromatography-tandem mass spectrometry analysis of the mouse urine extract revealed approximately 26 mouse urine proteins and a minute amount of albumin. In contrast, the commercial mouse epithelial extract contained more than 267 proteins including high amounts of albumin, diverse bioactive proteins including heat shock proteins and other poorly characterized proteins with only small quantities of mouse urine proteins. The mouse exposure and symptom survey was completed by 39 volunteers. These volunteers were exposed to mice on average 14 hours per week. Ninety two percent of participants (36/39) handled mice as laboratory workers. Self diagnosis of allergy to mouse and other aeroallergens based on nasal, ocular, respiratory and skin symptoms was reported by 23/39 (59%) and 29/39 individuals (74%), respectively. Thirty seven had interpretable skin prick testing (2 individuals had dermatographism). Among these 37 patients, 28 (76%) had a positive test with at least one aeroallergen, 13 (35%) with the mouse epithelial extract, and 9 (24%) with the mouse urine extract. Nasal challenge with the mouse urine extract was completed in 35 participants. Two volunteers were excluded from the study because they developed reaction to glycerin control either on skin testing or nasal challenge. Out of the 9 subjects with positive skin test to the mouse urine extract, 8 reported symptoms on the survey, and 7 were positive to nasal challenge using mouse urine extract. All subjects with negative mouse symptom questionnaires had negative nasal challenges. The sensitivity of the new mouse urine extract was 70% (7/10), specificity 92% (23/25), positive predictive value 78% (7/9), and negative predictive value 88% (23/26). The most important characteristics of allergen extracts used for diagnostic challenges and immunotherapy include chemical purity and predictable concentration of the specific antigen. We describe a new mouse urine extract that has a greater concentration of the major mouse allergen Mus m 1 and chemical purity than the commercially available mouse epithelial extract. The urine extract contains mostly mouse urine proteins, whereas the epithelial extract is a mixture of albumin, nonspecific proteins including heat shock proteins with a small amount of Mus m 1. However, despite the improved purity, the mouse urine extract did not demonstrate a clear improvement in diagnostic performance over the previously published data of the diagnostic performance of the mouse epithelial extract.4 Comparative performance is revealed in table 1. Table 1 Comparative Performance of Mouse Urine Extract to Mouse Epithelia Extract These results may suggest that Mus m 1 is not the only allergen causing clinical symptoms to mice. There are studies suggesting that serum albumin may also play an etiologic role in mouse allergy in humans.10 Serum albumin is abundantly present in the mouse epithelial extract. Perhaps, the optimal diagnostic method for mouse allergy should include testing with both Mus m 1 and albumin proteins. Importantly, it is also possible, that the reaction to the highly impure epithelial extract is mediated by both IgE and non-IgE mediated inflammatory pathways, thus only in part assessing a true allergic response to mouse. Thus, we describe a new mouse allergen extract containing pure and highly concentrated mouse urine protein that is suitable for diagnostic purposes in humans. Therefore, in our opinion, despite comparable diagnostic efficacy, the newly described urine extract could be superior to the epithelial extract as a diagnostic and research tool for mouse allergy in humans. Furthermore, if we assume that human allergy to mice is similar to cat and dog in which there is a dose dependent response to the major allergen in immunotherapy, then in the future this new extract could be used to develop desensitization methods based on dose of major allergen.11,12 This could give laboratory workers as well as children and adults with severe allergy and asthma to mice an option for relief that was previously never available.