A GWAS approach identifies Dapp1 as a determinant of air pollution-induced airway hyperreactivity
Authors:
Hadi Maazi aff001; Jaana A. Hartiala aff002; Yuzo Suzuki aff001; Amanda L. Crow aff002; Pedram Shafiei Jahani aff001; Jonathan Lam aff001; Nisheel Patel aff001; Diamanda Rigas aff001; Yi Han aff002; Pin Huang aff002; Eleazar Eskin aff004; Aldons. J. Lusis aff005; Frank D. Gilliland aff002; Omid Akbari aff001; Hooman Allayee aff002
Authors place of work:
Departments of Molecular Microbiology and Immunology, Keck School of Medicine, University of Southern California, Los Angeles, California, United States of America
aff001; Department of Preventive Medicine, Keck School of Medicine, University of Southern California, Los Angeles, California, United States of America
aff002; Department of Biochemistry & Molecular Medicine, Keck School of Medicine, University of Southern California, Los Angeles, California, United States of America
aff003; Department of Computer Science and Inter-Departmental Program in Bioinformatics, University of California, Los Angeles, Los Angeles, California, United States of America
aff004; Department of Human Genetics, David Geffen School of Medicine at UCLA, Los Angeles, California, United States of America
aff005; Department of Medicine, David Geffen School of Medicine at UCLA, Los Angeles, California, United States of America
aff006; Department of Microbiology, Immunology, and Molecular Genetics, David Geffen School of Medicine at UCLA, Los Angeles, California, United States of America
aff007
Published in the journal:
A GWAS approach identifies Dapp1 as a determinant of air pollution-induced airway hyperreactivity. PLoS Genet 15(12): e32767. doi:10.1371/journal.pgen.1008528
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1008528
Summary
Asthma is a chronic inflammatory disease of the airways with contributions from genes, environmental exposures, and their interactions. While genome-wide association studies (GWAS) in humans have identified ~200 susceptibility loci, the genetic factors that modulate risk of asthma through gene-environment (GxE) interactions remain poorly understood. Using the Hybrid Mouse Diversity Panel (HMDP), we sought to identify the genetic determinants of airway hyperreactivity (AHR) in response to diesel exhaust particles (DEP), a model traffic-related air pollutant. As measured by invasive plethysmography, AHR under control and DEP-exposed conditions varied 3-4-fold in over 100 inbred strains from the HMDP. A GWAS with linear mixed models mapped two loci significantly associated with lung resistance under control exposure to chromosomes 2 (p = 3.0x10-6) and 19 (p = 5.6x10-7). The chromosome 19 locus harbors Il33 and is syntenic to asthma association signals observed at the IL33 locus in humans. A GxE GWAS for post-DEP exposure lung resistance identified a significantly associated locus on chromosome 3 (p = 2.5x10-6). Among the genes at this locus is Dapp1, an adaptor molecule expressed in immune-related and mucosal tissues, including the lung. Dapp1-deficient mice exhibited significantly lower AHR than control mice but only after DEP exposure, thus functionally validating Dapp1 as one of the genes underlying the GxE association at this locus. In summary, our results indicate that some of the genetic determinants for asthma-related phenotypes may be shared between mice and humans, as well as the existence of GxE interactions in mice that modulate lung function in response to air pollution exposures relevant to humans.
Keywords:
Genetic loci – Genome-wide association studies – Human genetics – Inhalation – Air pollution – Inbred strains – Asthma – genetic predisposition
Introduction
Asthma is a complex disease characterized by chronic airway inflammation that affects over 300 million people worldwide [1]. It is generally accepted that susceptibility to asthma results from interactions between genetic risk factors and environmental exposures, such as allergens and air pollutants [2–4]. In this regard, particulate matter with diameter less than 2.5 μM (PM2.5) is a well-studied ambient air pollutant that has been linked to reduced lung development in children and risk of asthma [5]. Traffic emissions, including combustion products, are major sources of PM2.5 [6] that can penetrate deep into small lung airways where they trigger immune responses either alone or by acting as adjuvants for simultaneously inhaled aeroallergens [7–10]. However, not all individuals respond the same to such exposures and evidence suggests that genetic background can modulate differences in the response to PM2.5 and other ambient air pollutants [5, 6, 8, 11–13].
Estimates for the heritability of asthma have ranged between 35%-95% [14], suggesting a strong genetic component to risk of asthma. Genome-wide association studies (GWAS) in humans support this notion and have identified ~200 loci for asthma and related pulmonary phenotypes [15–35]. Interestingly, the genes located at these loci along with bioinformatic analyses provide compelling genetic evidence for a strong inflammatory component to asthma susceptibility [31, 35]. Despite the large numbers of loci identified to date, the risk alleles, most of which are common in the population, still only explain a small fraction (~7%) of asthma’s overall heritability [36, 37]. This observation implies either the existence of additional variants with smaller effect sizes, rare susceptibility alleles, and/or higher order interactions between genes and environmental factors. Furthermore, while identification of genes is one important step towards improving our understanding of asthma pathogenesis, it does not provide direct information about interactions between genetic risk factors and environmental triggers. This is compounded by the inherent difficulties of carrying out gene-environment (GxE) interaction studies in humans. For example, accurate exposure assessments, adequately powered sample sizes in which genetic, phenotypic, and exposure data are all available, and the heterogeneous nature of asthma itself pose significant practical and technical hurdles that have yet to be overcome. Thus, the complex GxE interactions that modulate risk of asthma remain unknown. However, a better understanding of these interactions may provide important novel insights into the biological mechanisms of asthma and potentially identify subgroups of individuals at higher risk [38].
To circumvent the challenges of genetic studies of asthma-related traits in humans, gene discovery efforts have leveraged naturally occurring variation in mice. A variety of strategies, including linkage mapping with crosses or association studies with small numbers of inbred strains, have identified several loci for airway hyperreactivity (AHR) under both unexposed conditions or after exposure to various allergens, such as ovalbumin or house dust mite (HDM) [39]. In this regard, we have developed a panel of inbred mouse strains, termed the Hybrid Mouse Diversity Panel (HMDP) [40], that has been used to identify loci for a number of complex traits relevant to human diseases [41–45]. Furthermore, the renewable nature of the HDMP, where multiple subjects of the same genotype can be studied, has been proven useful for GxE studies with a diverse array of exposures, including inflammatory responses to LPS [46, 47], dietary or pharmacological challenges [48–52], and noise insults [53, 54]. In the present study, we used the HMDP to further elucidate the genetic architecture of asthma-related phenotypes in mice and identify loci that modulate AHR in response to diesel exhaust particles (DEP), as a model traffic-related air pollutant.
Results
Lung function varies among HMDP strains
As an initial step towards identifying the genetic factors and GxE interactions underlying asthma-related traits in mice, we determined AHR in 101 strains from the HMDP (S1 Table) by measuring lung resistance with and without exposure to DEP. To increase lung function responses, mice were first sensitized on day 0 through an intraperitoneal injection of DEP (200μg), HDM (25μg), + 2.25mg Alum as an adjuvant, followed by daily inhalation exposure on days 7–10 to either aerosolized PBS (n = 2–4 mice/strain), as a control, or DEP (n = 2–4 mice/strain) for 20mins. Lung resistance in response to increasing doses of methacholine was then measured on day 11 using invasive plethysmography (Fig 1A).
In the control PBS inhalation exposure group, lung resistance among the 101 HMDP strains exhibited 3-4-fold variation at baseline and as a function of increasing doses of methacholine (Fig 1B). Similar variation was also observed among strains after inhalation exposure to aerosolized DEP (Fig 1C). A comparison of lung resistance in response to 10mg/ml methacholine for each strain after inhalation exposure to PBS or DEP further illustrates the variation observed among the HMDP (Fig 1D). Interestingly, strains that exhibited the highest lung resistance after PBS exposure were not necessarily the same as those with high lung resistance after DEP exposure. For example, at a 10mg/ml dose of methacholine, strain BXD42/TyJ has the third highest lung resistance (11.0 cmH2O.ml-1.S-1) after inhalation exposure to PBS, but exhibits a more subdued response (3.4 cmH2O.ml-1.S-1) after DEP inhalation exposure (Fig 1D). Given that the same exposure protocol was used to characterize all strains, these findings indicate that genetic background modulates variation in lung resistance with and without inhalation exposure to DEP.
Mapping of loci for lung resistance in the HMDP
We next used the phenotype data generated in the HMDP to identify the genetic determinants of AHR under control PBS conditions. conditions. A GWAS analysis for AHR at individual methacholine doses identified two loci on that were significantly associated with peak lung resistance in response to 2.5mg/ml of methacholine in PBS-exposed mice (Fig 2A). Several suggestively associated loci were also observed on chromosomes 6, 8, 13 and 17 (Fig 2A). The lead SNP on chromosome 2 (rs27250829) yielded a p-value of 3.0x10-6 and had a minor allele frequency (MAF) of 0.20, whereas the lead SNP on chromosome 19 (rs51547574) was slightly more frequent (MAF = 0.26) and one magnitude more strongly associated with lung resistance (p = 5.6x10-7). As shown in Fig 2B, the minor T allele of rs51547574, which is also the non-C57BL/6 allele, was associated with lower peak lung resistance in response to 2.5mg/ml methacholine in control PBS-exposed mice. While the most significant association with lung resistance was at a methacholine dose of 2.5mg/ml, a similar pattern of association was observed with varying levels of significance at other doses as well (Table 1). Interestingly, association with the chromosome 19 locus was observed at the baseline AHR measurement before administration of methacholine (Table 1), suggesting that the effect of this locus on lung resistance manifests even under basal conditions and in the absence of stimulating bronchial constriction. In addition, rs51547574 is located 24kb downstream of Il33, although other genes, such as Trpd52l3, Uhrf2, and Gldc, are also located within the interval encompassing other tightly linked SNPs (r2≥0.8) (Fig 2C). To prioritize among these positional candidates, we next leveraged gene expression data available in the HMDP from several tissues, including liver, adipose, heart, aorta, bone, and macrophages [55]. Of the genes within the high linkage disequilibrium (LD) block on chromosome 19, rs51547574 yielded a cis expression quantitative trait locus (eQTL) for Il33 in heart (p = 4.1x10-4) and adipose (p = 0.04). Although not conclusive due to these eQTLs being observed in tissues not directly relevant to asthma or lung function, these results suggest that Il33 could represent at least one of the candidate causal genes at the chromosome 19 locus.
GxE GWAS for lung resistance in response to DEP
We next applied the same strategy to identify the genetic determinants of lung resistance after inhalation exposure to DEP. For these analyses, we calculated the mean strain difference in peak lung resistance in DEP-induced and control PBS exposures (delta, Δ AHRDEP—AHRPBS) at each dose of methacholine, as well as Δ area under the curve (AUC) values across all methacholine doses. A GxE GWAS for AUC-based Δ AHRDEP—AHRPBS only identified two suggestively associated loci on chromosomes 4 and 15 (S1 Fig). By comparison, analysis of the Δ AHRDEP—AHRPBS data at individual methacholine doses revealed a significantly associated locus for lung resistance on chromosome 3 at a methacholine dose of 10mg/ml (lead SNP rs30880385; p = 2.5 x 10−6; Fig 3A). The minor C allele of rs30880385 is the non-C57BL/6 allele and has a frequency of 0.36 among the HMDP strains. Although there were no genome-wide significant differences in lung resistance under PBS or DEP exposures conditions as a function of rs30880385 genotype (S2A Fig), the C allele was associated with a significantly (p = 2.5 x 10−6) greater difference in Δ (DEP-PBS) lung resistance at a methacholine dose of 10mg/ml (Fig 3B and S2B Fig). Analysis of AHR across all methacholine doses using AUC values also revealed a modestly significant difference (p = 0.05) as a function of rs30880385 genotype (S2C Fig). Similarly, there was only nominal evidence (p<0.05) for association of this locus with AHR in response to PBS exposure at a methacholine dose of 10mg/ml (S2 Table). These observations suggest that association of the chromosome 3 locus with lung resistance is mediated through an interaction with DEP exposure. A regional plot of this locus shows that rs30880385 is located 19kb upstream of Dapp1 (Fig 3C), although other genes located within the region encompassed by tightly linked SNPs (r2≥0.8) include Gm5105, Mttp, and Lamtor3 (Fig 3C). Interrogation of the HDMP gene expression database however did not identify any cis eQTLs for Dapp1, Gm5105, Mttp, or Lamtor3 among the available tissues.
DAPP1 is expressed in the lungs and associated with inflammatory cytokines in humans
Although none of the candidate causal genes at the chromosome 3 locus are known to have a biological role in lung function or asthma, previous studies have shown that Dapp1 encodes a multi-functional adaptor protein involved in T cell activation that is also highly expressed in lymphocytes and lung pneumocytes in mice and humans [56–58]. Since gene expression data available in the HDMP may not have necessarily been in tissues most relevant to the immune system-related functions of Dapp1, we next leveraged publicly available mutli-tissue RNAseq data in humans from the GTEx Project [59]. DAPP1 expression in humans was highest in lymphocytes, spleen, whole blood, and several mucosal tissues, including the lung (Fig 4A). Moreover, DAPP1 expression in the lung was highly positively correlated with a panel of pro-inflammatory cytokines, including several that have been implicated in asthma, such as IL1A, IL7, IL12A, IL17A, IL23A, and IL33 (Fig 4B). In spleen, DAPP1 expression was similarly positively associated with expression of cytokines, but the pattern was characterized by fewer and less significant correlations than those in the lung (Fig 4B). A similar analysis in the HMDP with Dapp1 did not reveal significant correlations with expression of the same pro-inflammatory cytokine genes among the available tissues. Nonetheless, based on the multiple significant correlations observed in humans, we reasoned that Dapp1 could be at least one of the genes at the chromosome 3 locus that mediated the effects of DEP on lung resistance in mice.
Functional validation of Dapp1 as an exposure-responsive gene
We next sought to functionally validate the GxE association signal on chromosome 3 using an in vivo approach with Dapp1 deficient (Dapp1-/-) mice. We first used the same exposure protocol as for the HMDP strain survey (Fig 1A) to characterize female Dapp1-/- mice and female wildtype (WT) C57BL/6J controls purchased from JAX. As shown in S3 Fig, there was a non-significant trend for a difference between DEP-exposed Dapp1-/- mice and WT controls. Therefore, we repeated these experiments a second time using the same dual exposure sensitization step with DEP and HDM. However, mice underwent inhalation exposure to both DEP and HDM on days 7–10, followed by measurement of AHR on day 11. The rationale for this strategy was that the combination of dual exposures with DEP and HDM for both sensitization and inhalation would induce lung resistance sufficiently to reveal a phenotypic difference between Dapp1-/- mice and WT mice. In addition, we carried out two independent experiments using female WT C57BL/6J controls purchased from either JAX or male and female WT littermates generated through an intercross between Dapp1+/- mice. In both experiments, inhalation exposure to DEP and HDM robustly induced AHR in control mice and WT littermates (Fig 5A and 5D). However, the induction of lung resistance by DEP was significantly blunted in Dapp1-/- mice, particularly at methacholine doses of 20 and 40mg/ml (Fig 5A and 5D). These differences were observed in experiments using only female mice as well as in those where mice of both sexes were used. By comparison there were no differences between WT or Dapp1-/- mice under control PBS conditions (Fig 5A and 5D). To examine whether reduced lung resistance in response to DEP in Dapp1-/- was associated with modulation of airway inflammation, we characterized the cellular composition of bronchoalveolar lavages (BAL) from Dapp1-/- and WT mice. Inhalation exposure to DEP/HDM significantly increased eosinophil and neutrophil numbers in the BAL of both Dapp1-/- animals and control mice/WT littermates compared to the corresponding PBS-exposed control groups (Fig 5B, 5C, 5E and 5F). However, there were no significant differences in eosinophil and neutrophil counts in the BAL of Dapp1-/- mice and either set of WT controls littermates after inhalation exposure to DEP/HDM (Fig 5B, 5C, 5E and 5F). Taken together, these data corroborate the GxE GWAS results on chromosome 3 and provide functional evidence that Dapp1 modulates lung resistance in response to DEP through mechanisms that are independent of eosinophil and neutrophil recruitment to the lung.
Discussion
In the present study, we characterized asthma-related traits in over 100 inbred strains of mice from the HMDP to facilitate identification of genetic determinants for AHR, particularly after exposure to a model traffic-related air pollutant. These efforts demonstrated that lung function across the HMDP varied several fold under control exposures as well as in response to DEP and revealed several significantly and suggestively associated loci for AHR. At one locus in particular, we functionally demonstrated that Dapp1 modulates lung resistance in response to DEP exposure, thus providing evidence for a novel GxE interaction that influences asthma-related traits in mice. Taken together, these findings represent one experimental approach to understanding the genetic factors that determine susceptibility to asthma in response to environmental pollutants that are known to have large independent adverse effects on lung function/growth, especially in children [60–62].
Two important considerations in our studies are whether the identified loci corroborate results of previous mouse studies and whether the identified genetic pathways are relevant to humans. In this regard, we mapped lung resistance under control conditions to two loci on chromosome 2 and 19. Interestingly, our lead SNP (rs27250829) on chromosome 2 maps to position 137,425,632 (based on build NCBI37/mm9), which is within the ~36Mb interval (chr 2:122,652,343–163020182) spanning a QTL for AHR previously reported in mice [63]. By comparison, of the genes within the relatively small LD block on chromosome 19, a cis eQTL were only observed for Il33, providing functional evidence that this cytokine gene is at least one candidate causal gene at this locus. Although these results are not entirely conclusive since the eQTLs for were only modestly significant and observed in tissues not directly relevant to asthma, it is noteworthy that syntenic association signals for asthma have been identified with rare and common genetic variation at the IL33 locus in multiple human studies [15–34, 64]. These observations support the notion that some of the genetic determinants for asthma-related phenotypes may be shared between mice and humans.
The GxE locus we identified on chromosome 3 in response to DEP contained several genes without an obvious role in lung function or asthma-related traits. Of these, we prioritized Dapp1 because of its known role in mediating activation of and interactions between immune cells [65–69], its expression profile in tissues relevant to asthma, and the high correlation of its mRNA levels with those of several asthma-related inflammatory cytokines in humans. In two independent experiments with genetically targeted mice, we functionally validated Dapp1 as an exposure-responsive gene at the chromosome 3 locus. It should be noted that a phenotypic difference between Dapp1-/- and WT mice was observed after inhalation exposure to both DEP and HDM, which is slightly different from the protocol we used for the HMDP strain survey. Thus, when on the background of a relatively resistant strain (C57BL/6J), it is possible that both triggers are required in order for the protective effect of Dapp1 deficiency on induction of AHR to manifest. Regardless, a mechanism(s) for how Dapp1 would be involved in lung resistance, particularly in response to DEP/HDM, is still not directly evident. It is also not known whether Dapp1 mediates a response to other exposures as well. Interestingly, DAPP1 expression has been shown to change in human bronchial epithelial cells after exposure to cigarette smoke [70]. Taken together with our results, these observations suggest that Dapp1 potentially mediates exposure-induced lung resistance through immune system-related mechanisms. This notion would be consistent with the apparent strong immunological component that GWAS studies in humans have indicated for asthma based on the positional candidate genes located at the identified loci [31]. However, a large human GWAS did not reveal any main effect associations between the DAPP1 locus and asthma [35], including with SNPs that yielded strong multi-tissue cis eQTLs for DAPP1 and other genes in the syntenic region [59]. Additional studies will be needed in order to obtain a more definitive understanding of how Dapp1 function influences AHR and its relevance to the biological mechanisms and GxE interactions of asthma in humans.
Compared to humans, inbred strains provide certain advantages for GxE studies, including the ability to tightly control environmental exposures across strains and the ability to phenotype multiple individuals of the same genotype. While we used the HMDP to search for genetic determinants of AHR after DEP exposure, analogous strategies with various other mouse genetics platforms have also been used to explore GxE interactions underlying allergen-induced asthma traits [39]. For example, Kelada et al. used have used the Collaborative Cross [71, 72] to identify loci for allergic airway disease with and without exposure to HDM that were distinct from those identified herein. Collectively, these findings illustrate the utility of leveraging natural genetic variation with inbred mouse strains to identify both main genetic effects and GxE interactions for asthma-related phenotypes, as well as the existence of exposure-specific GxE loci.
While the present analyses have revealed novel genetic determinants of AHR in mice, our study should also be taken in the context of certain limitations. First, our exposure protocol was relatively short-term compared to the chronic nature of how humans are typically exposed to environmental pollutants. Second, we focused on DEP as a model traffic-related air pollutant and sensitized mice with HDM in conjunction with Alum as an adjuvant. We chose this strategy based on the notion that immune responses in humans are potentiated by natural occurring adjuvants and prior mouse studies where it has been shown that Alum promotes the development of lung resistance in combination with asthma triggers, such as DEP [73]. However, it is possible that other components of DEP could be causing subsequent immune responses by virtue of being in the immunization mix with Alum or that DEP could exacerbate already existing allergic airway disease. Alternatively, it is not known whether the GxE interactions we identified herein are specific to DEP or apply to other exposures as well. Addressing these possibilities will require appropriately designed studies. Lastly, the ~100 HMDP inbred strains, which originate from a small number of founders, provide limited genetic diversity and relatively lower power to detect loci compared to large outbred human populations. This may explain, at least in part, why we only mapped a small number of loci for lung resistance in the HMDP whereas human GWAS have identified ~200 genomic regions for asthma-related traits.
In conclusion, we identified several loci associated with AHR in mice, including Dapp1 as a determinant of lung resistance in response to DEP exposure. These results may have implications for genetic susceptibility to asthma in humans, which will need to be addressed using cohorts in which traffic-related air pollution exposure estimates are available along with genotype and phenotype information. Moreover, these results demonstrate the utility of the HMDP for dissecting the genetic architecture of complex traits, particularly for those phenotypes that are strongly influenced by environmental exposures.
Methods
Ethics statement
All animal studies were approved by the USC Keck School of Medicine Institutional Animal Care and Use Committee and conducted in accordance with the Department of Animal Resources’ guidelines. Human studies were conducted with publicly available de-identified gene expression data from the GTEx Project [59].
Mice and HMDP panel
Six to eight-week-old female mice of 101 strains (n = 4–8) were purchased from the Jackson Laboratories. A full list of strain names and stock numbers are provided in the S1 Table. Biological validation of Dapp1 was carried out using previously generated genetically modified mice bred onto a C57Bl/6J background that were kindly provided by Dr. Aaron Marshall [68]. Control animals for the first set of exposure experiments with female Dapp1-/- mice were female C57BL/6J mice purchased from the Jackson Laboratories. For the second set of exposure experiments, Dapp1-/- and WT littermates of both sexes were generated through an intercross between Dapp1+/- heterozygotes. All mice in the study, including the Dapp1-/- and 101 HMDP strains, were housed and bred in the same vivarium room. Mice were maintained on a 12-hour light/dark cycle in sterilized microisolator cages and received autoclaved food and water ad libitum.
Exposure protocol and measurement of AHR
DEP (engine combustion products) were collected from a light-duty, four-cylinder diesel engine (type 4JB1, Isuzu, Japan) under a 10-torque load in a cyclone impactor using standard diesel fuel, as described previously [74]. The collected DEP were then suspended in PBS as one batch with multiple aliquots that were used for intraperitoneal injections directly or aerosolized for inhalation exposures using Aeroneb ultrasonic nebulizers (Aerogen, Chicago, IL) with a pore size of 4–5μM. Based on prior mouse [75, 76] and human [77, 78] studies and our own pilot experiments with two relatively sensitive (Balb/cByJ) and resistant (C57BL/6J) mouse strains, we designed an exposure protocol that could be uniformly adapted across ~100 strains of different genetic backgrounds and varying susceptibilities to DEP (additional details are provided in the S1 Appendix). To sufficiently induce AHR, mice from the HMDP (n = 4–8 per strain) were first sensitized on day 0 through a 100μl intraperitoneal injection containing 200μg DEP and 25μg HDM (Stallergenes Greer, Lenoir, NC) + 2.25mg Alum as an adjuvant [73]. On days 7–10, mice were separated into two groups and placed in insulated chambers daily for 20mins supplied with ambient air and saturated with aerosolized PBS (control; n = 2-4/strain) or 200μg DEP (exposed; n = 2-4/strain). To avoid batch effects, the same collection of DEP and lot (# 145793) of HDM was used for all strains and all exposures were carried out at the same time in the mornings. Based on prior analyses [79], there was minimal (0.01%) contamination of the HDM extract we used with endotoxin (0.1μg LPS/mg HDM). On day 11, airway hyperreactivity was measured by invasive plethysmography. Lung resistance and dynamic compliance at baseline and in response to sequentially increasing doses of methacholine was measured using a Buxco FinePointe (Data Sciences International, St. Paul, MN) respiratory system in tracheostomized immobilized mice that were mechanically ventilated under general anesthesia, as described elsewhere [80].
Characterization of Dapp1-/- mice
For exposure experiments with Dapp1-/- mice and WT controls or littermates, mice were first sensitized on day 0 with 200μg DEP and 25μg HDM (Stallergenes Greer, Lenoir, NC) + 2.25mg Alum. This was followed by one set of inhalation experiments that mimicked the exposure paradigm used for the HMDP where mice were exposed daily to aerosolized PBS or 200μg DEP for 20mins on days 7–10, followed by measurement of AHR on day 11. To induce lung resistance further, a second set of inhalation experiments were also conducted where mice were first sensitized in the same manner with 200μg DEP and 25μg HDM but underwent daily inhalation exposure to aerosolized PBS or both 200μg DEP and 25μg HDM for 20mins on days 7–10, followed by measurement of AHR on day 11. For both exposure studies, BAL fluid was collected after completion of AHR measurements by cannulating the trachea and washing the airways three times with 1mL PBS. The fluid was recovered each time and centrifuged at 400g for 7mins to pellet the cells. Leukocytes in BAL fluid were quantified by flow cytometry after staining with phycoerythrin (PE)-anti-Siglec-F (BD Biosciences, San Jose, Calif), fluorescein isothiocyanate (FITC)-anti-CD19, peridinin-chlorophyll-protein complex (PerCP)/Cy5.5-anti-CD3ε, allophycocyanin (APC)-anti-Gr-1, PE/Cy7-anti-CD45, APC/Cy7-anti-CD11c (BioLegend, San Diego, Calif), and eFluor450-anti-CD11b (eBioscience, San Diego, Calif) in the presence of anti-mouse FC-block (BioXcell, West Lebanon, NH). CountBright absolute count beads (Thermo Fisher Scientific, Waltham, Mass) were used to calculate absolute cell number, according to the manufacturer’s instructions. At least 105 CD45++ cells were acquired on a BD FACSCanto II (BD Biosciences). Data were analyzed with FlowJo software (TreeStar, Ashland, OR).
GWAS analyses for main effects and GxE interactions
GWAS analyses in the HMDP were carried out for main SNP effects under control PBS conditions at the individual mouse level with lung resistance measurements obtained at each methacholine dose. For the GxE interaction analyses, we derived DEP-induced AHR traits by calculating the mean strain difference (delta, Δ) in lung resistance at each dose of methacholine between DEP-exposed mice and PBS-exposed controls. These calculated Δ values were then analyzed at each methacholine dose. In addition, we also tested for association with AHR data that incorporated lung resistance measurements at all methacholine doses. This was done by calculating mean strain differences in area under the curve (AUC) values between DEP-exposed and PBS-exposed mice (Δ AUCDEP—AUCPBS). Given this analytical approach, the statistical model used to test for GxE interactions did not include terms for the main effects of SNPs and DEP exposure. Genotypes for ~450,000 SNPs in the HMDP strains were obtained from the Mouse Diversity Array [81]. SNPs were required to have minor allele frequencies >5% and missing genotype frequencies <10%. Applying these filtering criteria resulted in a final set of ~200,000 SNPs that were used for analysis. Association testing was performed using python-based linear mixed models with log or normal inverse transformed traits as implemented in the program pylmm [82], which has the advantage of accounting for population structure among the inbred strains in the HMDP. Genome-wide significance threshold in the HMDP was determined by the family-wise error rate as the probability of observing one or more false positives across all SNPs per phenotype. We ran 100 different sets of permutation tests and parametric bootstrapping of size 1,000 and observed that the genome-wide significance threshold at a family-wise error rate of 0.05 corresponded to a p-value of 4.1x10-6, similar to what we have used in previous HMDP studies [41–45]. This is approximately one order of magnitude larger than the threshold obtained by Bonferroni correction (4.6x10-7), which would be an overly conservative estimate of significance since nearby SNPs among inbred mouse strains are highly correlated with each other.
Bioinformatics analyses with DAPP1 in humans
Gene expression data for DAPP1 in various tissues and asthma-related pro-inflammatory cytokine genes in lung and spleen were taken from the GTEx Project [59]. The relationship between DAPP1 and pro-inflammatory cytokines genes was tested by Spearman’s correlation analyses. Data were analyzed using R [83] and correlations were considered significant at a p-value<0.05.
Statistical analyses
Differences in lung resistance in between Dapp1-/- mice and WT controls were analyzed by two-way ANOVA and generalized linear models with log transformed data, followed by a Tukey post-hoc test. Cell counts in the bronchoalveolar lavage from PBS control and DEP-exposed WT and Dapp1-/- mice were compared using a Kruskal–Wallis test followed by Dunn's multiple comparisons non-parametric test. Data were analyzed using GraphPad Prism v6.04 and differences were considered significant at a p-value<0.05.
Supporting information
S1 Appendix [docx]
Additional details and considerations for the exposure protocol.
S1 Table [docx]
List of HMDP strains used in the study.
S2 Table [docx]
Association of lead SNP (rs30880385) at GxE locus on chromosome 3 with lung resistance under control PBS conditions.
S1 Fig [auc]
Results of a GWAS for AHR in the HMDP in response to DEP exposure.
S2 Fig [tiff]
Genotypic effect of lead SNP at chromosome 3 GxE Locus on lung resistance among HDMP strains.
S3 Fig [b]
Evaluation of as a DEP-responsive gene.
Zdroje
1. Network GA. Global Asthma Report (http://www.globalasthmareport.org/). 2018.
2. Romieu I, Moreno-Macias H, London SJ. Gene by environment interaction and ambient air pollution. Proc Am Thorac Soc. 2010;7(2):116–22. doi: 10.1513/pats.200909-097RM 20427582; PubMed Central PMCID: PMC3266017.
3. London SJ, Romieu I. Gene by environment interaction in asthma. Annu Rev Public Health. 2009;30:55–80. doi: 10.1146/annurev.publhealth.031308.100151 18980546.
4. McDonnell WF. Intersubject variability in human acute ozone responsiveness. Pharmacogenetics. 1991;1(2):110–3. doi: 10.1097/00008571-199111000-00010 1844868.
5. Khreis H, Kelly C, Tate J, Parslow R, Lucas K, Nieuwenhuijsen M. Exposure to traffic-related air pollution and risk of development of childhood asthma: A systematic review and meta-analysis. Environ Int. 2016. doi: 10.1016/j.envint.2016.11.012 27881237.
6. Jung CR, Young LH, Hsu HT, Lin MY, Chen YC, Hwang BF, et al. PM2.5 components and outpatient visits for asthma: A time-stratified case-crossover study in a suburban area. Environ Pollut. 2017;231(Pt 1):1085–92. doi: 10.1016/j.envpol.2017.08.102 28922715.
7. Liu H, Fan X, Wang N, Zhang Y, Yu J. Exacerbating effects of PM2.5 in OVA-sensitized and challenged mice and the expression of TRPA1 and TRPV1 proteins in lungs. J Asthma. 2017;54(8):807–17. doi: 10.1080/02770903.2016.1266495 28102732.
8. Pennington AF, Strickland MJ, Klein M, Zhai X, Bates JT, Drews-Botsch C, et al. Exposure to Mobile Source Air Pollution in Early-life and Childhood Asthma Incidence: The Kaiser Air Pollution and Pediatric Asthma Study. Epidemiology. 2018;29(1):22–30. doi: 10.1097/EDE.0000000000000754 28926373; PubMed Central PMCID: PMC5718963.
9. He M, Ichinose T, Yoshida Y, Arashidani K, Yoshida S, Takano H, et al. Urban PM2.5 exacerbates allergic inflammation in the murine lung via a TLR2/TLR4/MyD88-signaling pathway. Sci Rep. 2017;7(1):11027. doi: 10.1038/s41598-017-11471-y 28887522; PubMed Central PMCID: PMC5591243.
10. Falcon-Rodriguez CI, De Vizcaya-Ruiz A, Rosas-Perez IA, Osornio-Vargas AR, Segura-Medina P. Inhalation of concentrated PM2.5 from Mexico City acts as an adjuvant in a guinea pig model of allergic asthma. Environ Pollut. 2017;228:474–83. doi: 10.1016/j.envpol.2017.05.050 28570992.
11. Mazenq J, Dubus JC, Gaudart J, Charpin D, Nougairede A, Viudes G, et al. Air pollution and children's asthma-related emergency hospital visits in southeastern France. Eur J Pediatr. 2017;176(6):705–11. doi: 10.1007/s00431-017-2900-5 28382539.
12. Zhang Y, Salam MT, Berhane K, Eckel SP, Rappaport EB, Linn WS, et al. Genetic and epigenetic susceptibility of airway inflammation to PM2.5 in school children: new insights from quantile regression. Environ Health. 2017;16(1):88. doi: 10.1186/s12940-017-0285-6 28821285; PubMed Central PMCID: PMC5563051.
13. Weichenthal S, Bai L, Hatzopoulou M, Van Ryswyk K, Kwong JC, Jerrett M, et al. Long-term exposure to ambient ultrafine particles and respiratory disease incidence in in Toronto, Canada: a cohort study. Environ Health. 2017;16(1):64. doi: 10.1186/s12940-017-0276-7 28629362; PubMed Central PMCID: PMC5477122.
14. Ober C, Yao TC. The genetics of asthma and allergic disease: a 21st century perspective. Immunol Rev. 2011;242(1):10–30. doi: 10.1111/j.1600-065X.2011.01029.x 21682736; PubMed Central PMCID: PMC3151648.
15. Moffatt MF, Kabesch M, Liang L, Dixon AL, Strachan D, Heath S, et al. Genetic variants regulating ORMDL3 expression contribute to the risk of childhood asthma. Nature. 2007;448(7152):470–3. doi: 10.1038/nature06014 17611496.
16. Moffatt MF, Gut IG, Demenais F, Strachan DP, Bouzigon E, Heath S, et al. A large-scale, consortium-based genomewide association study of asthma. N Engl J Med. 2010;363(13):1211–21. doi: 10.1056/NEJMoa0906312 20860503.
17. Sleiman PM, Flory J, Imielinski M, Bradfield JP, Annaiah K, Willis-Owen SA, et al. Variants of DENND1B associated with asthma in children. N Engl J Med. 2010;362(1):36–44. doi: 10.1056/NEJMoa0901867 20032318.
18. Ferreira MA, Matheson MC, Duffy DL, Marks GB, Hui J, Le Souef P, et al. Identification of IL6R and chromosome 11q13.5 as risk loci for asthma. Lancet. 2011;378(9795):1006–14. doi: 10.1016/S0140-6736(11)60874-X 21907864; PubMed Central PMCID: PMC3517659.
19. Hirota T, Takahashi A, Kubo M, Tsunoda T, Tomita K, Doi S, et al. Genome-wide association study identifies three new susceptibility loci for adult asthma in the Japanese population. Nat Genet. 2011;43(9):893–6. doi: 10.1038/ng.887 21804548; PubMed Central PMCID: PMC4310726.
20. Noguchi E, Sakamoto H, Hirota T, Ochiai K, Imoto Y, Sakashita M, et al. Genome-wide association study identifies HLA-DP as a susceptibility gene for pediatric asthma in Asian populations. PLoS Genet. 2011;7(7):e1002170. doi: 10.1371/journal.pgen.1002170 21814517; PubMed Central PMCID: PMC3140987.
21. Torgerson DG, Ampleford EJ, Chiu GY, Gauderman WJ, Gignoux CR, Graves PE, et al. Meta-analysis of genome-wide association studies of asthma in ethnically diverse North American populations. Nat Genet. 2011;43(9):887–92. doi: 10.1038/ng.888 21804549.
22. Forno E, Lasky-Su J, Himes B, Howrylak J, Ramsey C, Brehm J, et al. Genome-wide association study of the age of onset of childhood asthma. J Allergy Clin Immunol. 2012;130(1):83–90 e4. doi: 10.1016/j.jaci.2012.03.020 22560479; PubMed Central PMCID: PMC3387331.
23. Lasky-Su J, Himes BE, Raby BA, Klanderman BJ, Sylvia JS, Lange C, et al. HLA-DQ strikes again: genome-wide association study further confirms HLA-DQ in the diagnosis of asthma among adults. Clin Exp Allergy. 2012;42(12):1724–33. doi: 10.1111/cea.12000 23181788; PubMed Central PMCID: PMC6343489.
24. Ding L, Abebe T, Beyene J, Wilke RA, Goldberg A, Woo JG, et al. Rank-based genome-wide analysis reveals the association of ryanodine receptor-2 gene variants with childhood asthma among human populations. Human genomics. 2013;7:16. doi: 10.1186/1479-7364-7-16 23829686; PubMed Central PMCID: PMC3708719.
25. Galanter JM, Gignoux CR, Torgerson DG, Roth LA, Eng C, Oh SS, et al. Genome-wide association study and admixture mapping identify different asthma-associated loci in Latinos: the Genes-environments & Admixture in Latino Americans study. J Allergy Clin Immunol. 2014;134(2):295–305. doi: 10.1016/j.jaci.2013.08.055 24406073; PubMed Central PMCID: PMC4085159.
26. Pickrell JK, Berisa T, Liu JZ, Segurel L, Tung JY, Hinds DA. Detection and interpretation of shared genetic influences on 42 human traits. Nat Genet. 2016;48(7):709–17. doi: 10.1038/ng.3570 27182965; PubMed Central PMCID: PMC5207801.
27. White MJ, Risse-Adams O, Goddard P, Contreras MG, Adams J, Hu D, et al. Novel genetic risk factors for asthma in African American children: Precision Medicine and the SAGE II Study. Immunogenetics. 2016;68(6–7):391–400. doi: 10.1007/s00251-016-0914-1 27142222; PubMed Central PMCID: PMC4927336.
28. Almoguera B, Vazquez L, Mentch F, Connolly J, Pacheco JA, Sundaresan AS, et al. Identification of Four Novel Loci in Asthma in European American and African American Populations. Am J Respir Crit Care Med. 2017;195(4):456–63. doi: 10.1164/rccm.201604-0861OC 27611488; PubMed Central PMCID: PMC5378422.
29. Yan Q, Brehm J, Pino-Yanes M, Forno E, Lin J, Oh SS, et al. A meta-analysis of genome-wide association studies of asthma in Puerto Ricans. Eur Respir J. 2017;49(5). doi: 10.1183/13993003.01505–2016 28461288; PubMed Central PMCID: PMC5527708.
30. Ferreira MA, Vonk JM, Baurecht H, Marenholz I, Tian C, Hoffman JD, et al. Shared genetic origin of asthma, hay fever and eczema elucidates allergic disease biology. Nat Genet. 2017;49(12):1752–7. doi: 10.1038/ng.3985 29083406; PubMed Central PMCID: PMC5989923.
31. Demenais F, Margaritte-Jeannin P, Barnes KC, Cookson WOC, Altmuller J, Ang W, et al. Multiancestry association study identifies new asthma risk loci that colocalize with immune-cell enhancer marks. Nat Genet. 2018;50(1):42–53. doi: 10.1038/s41588-017-0014-7 29273806; PubMed Central PMCID: PMC5901974.
32. Zhu Z, Lee PH, Chaffin MD, Chung W, Loh PR, Lu Q, et al. A genome-wide cross-trait analysis from UK Biobank highlights the shared genetic architecture of asthma and allergic diseases. Nat Genet. 2018;50(6):857–64. doi: 10.1038/s41588-018-0121-0 29785011; PubMed Central PMCID: PMC5980765.
33. Pividori M, Schoettler N, Nicolae DL, Ober C, Im HK. Shared and distinct genetic risk factors for childhood-onset and adult-onset asthma: genome-wide and transcriptome-wide studies. Lancet Respir Med. 2019. doi: 10.1016/S2213-2600(19)30055-4 31036433.
34. Shrine N, Portelli MA, John C, Soler Artigas M, Bennett N, Hall R, et al. Moderate-to-severe asthma in individuals of European ancestry: a genome-wide association study. Lancet Respir Med. 2019;7(1):20–34. doi: 10.1016/S2213-2600(18)30389-8 30552067; PubMed Central PMCID: PMC6314966.
35. Han Y, Jia Q, Jahani PS, Hurrell BP, Pan C, Huang P, et al. Large-scale genetic analysis identifies 66 novel loci for asthma. bioRxiv. 2019:749598. doi: 10.1101/749598
36. Vicente CT, Revez JA, Ferreira MAR. Lessons from ten years of genome-wide association studies of asthma. Clin Transl Immunology. 2017;6(12):e165. doi: 10.1038/cti.2017.54 29333270; PubMed Central PMCID: PMC5750453.
37. Kim KW, Ober C. Lessons Learned From GWAS of Asthma. Allergy Asthma Immunol Res. 2019;11(2):170–87. doi: 10.4168/aair.2019.11.2.170 30661310; PubMed Central PMCID: PMC6340805.
38. Khoury MJ. Editorial: Emergence of Gene-Environment Interaction Analysis in Epidemiologic Research. Am J Epidemiol. 2017;186(7):751–2. doi: 10.1093/aje/kwx226 28978194.
39. Leme AS, Berndt A, Williams LK, Tsaih SW, Szatkiewicz JP, Verdugo R, et al. A survey of airway responsiveness in 36 inbred mouse strains facilitates gene mapping studies and identification of quantitative trait loci. Mol Genet Genomics. 2010;283(4):317–26. doi: 10.1007/s00438-010-0515-x 20143096.
40. Bennett BJ, Farber CR, Orozco L, Kang HM, Ghazalpour A, Siemers N, et al. A high-resolution association mapping panel for the dissection of complex traits in mice. Genome Res. 2010;20(2):281–90. doi: 10.1101/gr.099234.109 20054062; PubMed Central PMCID: PMC2813484.
41. Farber CR, Bennett BJ, Orozco L, Zou W, Lira A, Kostem E, et al. Mouse genome-wide association and systems genetics identify Asxl2 as a regulator of bone mineral density and osteoclastogenesis. PLoS Genet. 2011;7(4):e1002038. doi: 10.1371/journal.pgen.1002038 21490954.
42. Davis RC, van Nas A, Bennett B, Orozco L, Pan C, Rau CD, et al. Genome-wide association mapping of blood cell traits in mice. Mamm Genome. 2013;24(3–4):105–18. doi: 10.1007/s00335-013-9448-0 23417284.
43. Hartiala J, Bennett BJ, Tang WH, Wang Z, Stewart AF, Roberts R, et al. Comparative genome-wide association studies in mice and humans for trimethylamine N-oxide, a proatherogenic metabolite of choline and L-carnitine. Arterioscler Thromb Vasc Biol. 2014;34(6):1307–13. Epub 2014/03/29. doi: 10.1161/ATVBAHA.114.303252 24675659; PubMed Central PMCID: PMC4035110.
44. Zhou X, Crow AL, Hartiala J, Spindler TJ, Ghazalpour A, Barsky LW, et al. The genetic landscape of hematopoietic stem cell frequency in mice. Stem Cell Reports. 2015;5(1):125–38. doi: 10.1016/j.stemcr.2015.05.008 26050929.
45. Lusis AJ, Seldin MM, Allayee H, Bennett BJ, Civelek M, Davis RC, et al. The Hybrid Mouse Diversity Panel: a resource for systems genetics analyses of metabolic and cardiovascular traits. J Lipid Res. 2016;57(6):925–42. doi: 10.1194/jlr.R066944 27099397; PubMed Central PMCID: PMC4878195.
46. Hiyari S, Green E, Pan C, Lari S, Davar M, Davis R, et al. Genome-Wide Association Study Identifies Cxcl Family Members as Partial Mediators of LPS-induced Periodontitis. J Bone Miner Res. 2018. Epub 2018/04/11. doi: 10.1002/jbmr.3440 29637625.
47. Orozco LD, Bennett BJ, Farber CR, Ghazalpour A, Pan C, Che N, et al. Unraveling inflammatory responses using systems genetics and gene-environment interactions in macrophages. Cell. 2012;151(3):658–70. doi: 10.1016/j.cell.2012.08.043 23101632.
48. Bennett BJ, Davis RC, Civelek M, Orozco L, Wu J, Qi H, et al. Genetic architecture of atherosclerosis in mice: A systems genetics analysis of common inbred strains. PLoS Genet. 2015;11(12):e1005711. doi: 10.1371/journal.pgen.1005711 26694027; PubMed Central PMCID: PMC4687930.
49. Parks BW, Sallam T, Mehrabian M, Psychogios N, Hui ST, Norheim F, et al. Genetic architecture of insulin resistance in the mouse. Cell Metab. 2015;21(2):334–47. Epub 2015/02/05. doi: 10.1016/j.cmet.2015.01.002 25651185; PubMed Central PMCID: PMC4349439.
50. Parks BW, Nam E, Org E, Kostem E, Norheim F, Hui ST, et al. Genetic control of obesity and gut microbiota composition in response to high-fat, high-sucrose diet in mice. Cell Metab. 2013;17(1):141–52. doi: 10.1016/j.cmet.2012.12.007 23312289.
51. Wang JJ, Rau C, Avetisyan R, Ren S, Romay MC, Stolin G, et al. Genetic Dissection of Cardiac Remodeling in an Isoproterenol-Induced Heart Failure Mouse Model. PLoS Genet. 2016;12(7):e1006038. Epub 2016/07/08. doi: 10.1371/journal.pgen.1006038 27385019; PubMed Central PMCID: PMC4934852.
52. Rau CD, Wang J, Avetisyan R, Romay MC, Martin L, Ren S, et al. Mapping genetic contributions to cardiac pathology induced by Beta-adrenergic stimulation in mice. Circ Cardiovasc Genet. 2015;8(1):40–9. Epub 2014/12/07. doi: 10.1161/CIRCGENETICS.113.000732 25480693; PubMed Central PMCID: PMC4334708.
53. Lavinsky J, Ge M, Crow AL, Pan C, Wang J, Salehi P, et al. The Genetic Architecture of Noise-Induced Hearing Loss: Evidence for a Gene-by-Environment Interaction. G3 (Bethesda). 2016;6(10):3219–28. Epub 2016/08/16. doi: 10.1534/g3.116.032516 27520957; PubMed Central PMCID: PMC5068943.
54. Lavinsky J, Crow AL, Pan C, Wang J, Aaron KA, Ho MK, et al. Genome-wide association study identifies nox3 as a critical gene for susceptibility to noise-induced hearing loss. PLoS Genet. 2015;11(4):e1005094. Epub 2015/04/17. doi: 10.1371/journal.pgen.1005094 25880434; PubMed Central PMCID: PMC4399881.
55. van Nas A, Pan C, Ingram-Drake LA, Ghazalpour A, Drake TA, Sobel EM, et al. The systems genetics resource: a web application to mine global data for complex disease traits. Front Genet. 2013;4:84. doi: 10.3389/fgene.2013.00084 23730305; PubMed Central PMCID: PMC3657633.
56. Awasthi S, Maity T, Oyler BL, Qi Y, Zhang X, Goodlett DR, et al. Quantitative targeted proteomic analysis of potential markers of tyrosine kinase inhibitor (TKI) sensitivity in EGFR mutated lung adenocarcinoma. J Proteomics. 2018. Epub 2018/04/17. doi: 10.1016/j.jprot.2018.04.005 29660496.
57. Zhang X, Maity T, Kashyap MK, Bansal M, Venugopalan A, Singh S, et al. Quantitative Tyrosine Phosphoproteomics of Epidermal Growth Factor Receptor (EGFR) Tyrosine Kinase Inhibitor-treated Lung Adenocarcinoma Cells Reveals Potential Novel Biomarkers of Therapeutic Response. Mol Cell Proteomics. 2017;16(5):891–910. Epub 2017/03/24. doi: 10.1074/mcp.M117.067439 28331001; PubMed Central PMCID: PMC5417828.
58. Allam A, Marshall AJ. Role of the adaptor proteins Bam32, TAPP1 and TAPP2 in lymphocyte activation. Immunol Lett. 2005;97(1):7–17. Epub 2005/01/01. doi: 10.1016/j.imlet.2004.09.019 15626471.
59. Consortium GTEx. The Genotype-Tissue Expression (GTEx) project. Nat Genet. 2013;45(6):580–5. doi: 10.1038/ng.2653 23715323; PubMed Central PMCID: PMC4010069.
60. Gauderman WJ, Urman R, Avol E, Berhane K, McConnell R, Rappaport E, et al. Association of improved air quality with lung development in children. N Engl J Med. 2015;372(10):905–13. Epub 2015/03/05. doi: 10.1056/NEJMoa1414123 25738666; PubMed Central PMCID: PMC4430551.
61. Gauderman WJ, Avol E, Gilliland F, Vora H, Thomas D, Berhane K, et al. The effect of air pollution on lung development from 10 to 18 years of age. N Engl J Med. 2004;351(11):1057–67. doi: 10.1056/NEJMoa040610 15356303.
62. Gauderman WJ, Vora H, McConnell R, Berhane K, Gilliland F, Thomas D, et al. Effect of exposure to traffic on lung development from 10 to 18 years of age: a cohort study. Lancet. 2007;369(9561):571–7. doi: 10.1016/S0140-6736(07)60037-3 17307103.
63. De Sanctis GT, Merchant M, Beier DR, Dredge RD, Grobholz JK, Martin TR, et al. Quantitative locus analysis of airway hyperresponsiveness in A/J and C57BL/6J mice. Nat Genet. 1995;11(2):150–4. doi: 10.1038/ng1095-150 7550342.
64. Smith D, Helgason H, Sulem P, Bjornsdottir US, Lim AC, Sveinbjornsson G, et al. A rare IL33 loss-of-function mutation reduces blood eosinophil counts and protects from asthma. PLoS Genet. 2017;13(3):e1006659. Epub 2017/03/09. doi: 10.1371/journal.pgen.1006659 28273074; PubMed Central PMCID: PMC5362243.
65. Marshall AJ, Niiro H, Lerner CG, Yun TJ, Thomas S, Disteche CM, et al. A novel B lymphocyte-associated adaptor protein, Bam32, regulates antigen receptor signaling downstream of phosphatidylinositol 3-kinase. J Exp Med. 2000;191(8):1319–32. doi: 10.1084/jem.191.8.1319 10770799; PubMed Central PMCID: PMC2193139.
66. Marshall AJ, Zhang T, Al-Alwan M. Regulation of B-lymphocyte activation by the PH domain adaptor protein Bam32/DAPP1. Biochem Soc Trans. 2007;35(Pt 2):181–2. doi: 10.1042/BST0350181 17371232.
67. Al-Alwan M, Hou S, Zhang TT, Makondo K, Marshall AJ. Bam32/DAPP1 promotes B cell adhesion and formation of polarized conjugates with T cells. J Immunol. 2010;184(12):6961–9. doi: 10.4049/jimmunol.0904176 20495066.
68. Hou S, Pauls SD, Liu P, Marshall AJ. The PH domain adaptor protein Bam32/DAPP1 functions in mast cells to restrain FcvarepsilonRI-induced calcium flux and granule release. Mol Immunol. 2010;48(1–3):89–97. doi: 10.1016/j.molimm.2010.09.007 20956018.
69. Ortner D, Grabher D, Hermann M, Kremmer E, Hofer S, Heufler C. The adaptor protein Bam32 in human dendritic cells participates in the regulation of MHC class I-induced CD8+ T cell activation. J Immunol. 2011;187(8):3972–8. doi: 10.4049/jimmunol.1003072 21930970.
70. Jorgensen ED, Dozmorov I, Frank MB, Centola M, Albino AP. Global gene expression analysis of human bronchial epithelial cells treated with tobacco condensates. Cell Cycle. 2004;3(9):1154–68. 15326394.
71. Kelada SN, Carpenter DE, Aylor DL, Chines P, Rutledge H, Chesler EJ, et al. Integrative genetic analysis of allergic inflammation in the murine lung. Am J Respir Cell Mol Biol. 2014;51(3):436–45. Epub 2014/04/04. doi: 10.1165/rcmb.2013-0501OC 24693920; PubMed Central PMCID: PMC4189492.
72. Kelada SNP. Plethysmography Phenotype QTL in Mice Before and After Allergen Sensitization and Challenge. G3-Genes Genom Genet. 2016;6(9):2857–65. doi: 10.1534/g3.116.032912 WOS:000384021400018. 27449512
73. Kool M, Soullie T, van Nimwegen M, Willart MA, Muskens F, Jung S, et al. Alum adjuvant boosts adaptive immunity by inducing uric acid and activating inflammatory dendritic cells. J Exp Med. 2008;205(4):869–82. doi: 10.1084/jem.20071087 18362170; PubMed Central PMCID: PMC2292225.
74. Diaz-Sanchez D, Dotson AR, Takenaka H, Saxon A. Diesel exhaust particles induce local IgE production in vivo and alter the pattern of IgE messenger RNA isoforms. J Clin Invest. 1994;94(4):1417–25. doi: 10.1172/JCI117478 7523450; PubMed Central PMCID: PMC295270.
75. Acciani TH, Brandt EB, Khurana Hershey GK, Le Cras TD. Diesel exhaust particle exposure increases severity of allergic asthma in young mice. Clin Exp Allergy. 2013;43(12):1406–18. doi: 10.1111/cea.12200 24112543.
76. Brandt EB, Biagini Myers JM, Acciani TH, Ryan PH, Sivaprasad U, Ruff B, et al. Exposure to allergen and diesel exhaust particles potentiates secondary allergen-specific memory responses, promoting asthma susceptibility. J Allergy Clin Immunol. 2015;136(2):295–303 e7. doi: 10.1016/j.jaci.2014.11.043 25748065; PubMed Central PMCID: PMC4530081.
77. Hirota JA, Knight DA. Human airway epithelial cell innate immunity: relevance to asthma. Curr Opin Immunol. 2012;24(6):740–6. doi: 10.1016/j.coi.2012.08.012 23089231.
78. Brusselle GG, Provoost S, Bracke KR, Kuchmiy A, Lamkanfi M. Inflammasomes in respiratory disease: from bench to bedside. Chest. 2014;145(5):1121–33. doi: 10.1378/chest.13-1885 24798836.
79. Bracken SJ, Adami AJ, Szczepanek SM, Ehsan M, Natarajan P, Guernsey LA, et al. Long-term exposure to house dust mite leads to the suppression of allergic airway disease despite persistent lung inflammation. Int Arch Allergy Immunol. 2015;166(4):243–58. doi: 10.1159/000381058 25924733; PubMed Central PMCID: PMC4485530.
80. Maazi H, Patel N, Sankaranarayanan I, Suzuki Y, Rigas D, Soroosh P, et al. ICOS:ICOS-ligand interaction is required for type 2 innate lymphoid cell function, homeostasis, and induction of airway hyperreactivity. Immunity. 2015;42(3):538–51. doi: 10.1016/j.immuni.2015.02.007 25769613; PubMed Central PMCID: PMC4366271.
81. Rau CD, Parks B, Wang Y, Eskin E, Simecek P, Churchill GA, et al. High-density genotypes of inbred mouse strains: improved power and precision of association mapping. G3 (Bethesda). 2015;5(10):2021–6. doi: 10.1534/g3.115.020784 26224782; PubMed Central PMCID: PMC4592984.
82. Furlotte NA, Eskin E. Efficient multiple-trait association and estimation of genetic correlation using the matrix-variate linear mixed model. Genetics. 2015;200(1):59–68. Epub 2015/03/01. doi: 10.1534/genetics.114.171447 25724382; PubMed Central PMCID: PMC4423381.
83. R Development Core Team (2014). R: A language and environment for statistical computing. R Foundation for Statistical Computing. Vienna, Austria. http://www.R-project.org/.
Štítky
Genetika Reprodukčná medicínaČlánok vyšiel v časopise
PLOS Genetics
2019 Číslo 12
- Je „freeze-all“ pro všechny? Odborníci na fertilitu diskutovali na virtuálním summitu
- Gynekologové a odborníci na reprodukční medicínu se sejdou na prvním virtuálním summitu
Najčítanejšie v tomto čísle
- Aspergillus fumigatus calcium-responsive transcription factors regulate cell wall architecture promoting stress tolerance, virulence and caspofungin resistance
- Architecture of the Escherichia coli nucleoid
- Common gardens in teosintes reveal the establishment of a syndrome of adaptation to altitude
- Restricted and non-essential redundancy of RNAi and piRNA pathways in mouse oocytes