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Adulthood asthma as a consequence of childhood adversity: a systematic review of epigenetically affected genes

Published online by Cambridge University Press:  08 March 2022

Yasemin Saygideger Open the ORCID record for Yasemin Saygideger [Opens in a new window] ,
Hakan Özkan ,
Oya Baydar  and
Ozge Yilmaz
Yasemin Saygideger*
Affiliation:
Department of Pulmonary, School of Medicine, Cukurova University, Adana, Turkey Department of Translational Medicine, Graduate School of Health Sciences, Cukurova University, Adana, Turkey
Hakan Özkan
Affiliation:
Department of Pediatrics, Division of Neonatal Intensive Care, Metro Hospital, Adana, Turkey
Oya Baydar
Affiliation:
Department of Pulmonary, School of Medicine, Cukurova University, Adana, Turkey
Ozge Yilmaz
Affiliation:
Department of Pediatric Allergy and Immunology, School of Medicine, Celal Bayar University, Manisa, Turkey
*
Address for correspondence: Yasemin Saygideger, Department of Pulmonary, School of Medicine, Cukurova University, Adana, Turkey. Email: ysaygideger@cu.edu.tr
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Abstract

There is an accumulating data that shows relation between childhood adversity and vulnerability to chronic diseases as well as epigenetic influences that in turn give rise to these diseases. Asthma is one of the chronic diseases that is influenced from genetic regulation of the inflammatory biomolecules and therefore the hypothesis in this research was childhood adversity might have caused epigenetic differentiation in the asthma-related genes in the population who had childhood trauma. To test this hypothesis, the literature was systematically reviewed to extract epigenetically modified gene data of the adults who had childhood adversity, and affected genes were further evaluated for their association with asthma. PRISMA guidelines were adopted and PubMed and Google Scholar were included in the searched databases, to evaluate epigenetic modifications in asthma-related genes of physically, emotionally or sexually abused children. After retrieving a total of 5245 articles, 36 of them were included in the study. Several genes and pathways that may contribute to pathogenesis of asthma development, increased inflammation, or response to asthma treatment were found epigenetically affected by childhood traumas. Childhood adversity, causing epigenetic changes in DNA, may lead to asthma development or influence the course of the disease and therefore should be taken into account for the prolonged health consequences.

Keywords

Asthmaepigeneticschild abusechildhood adversityasthma-related genesinflammation
Type
Original Article
Information
Journal of Developmental Origins of Health and Disease , Volume 13 , Issue 6 , December 2022 , pp. 674 - 682
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Copyright
© The Author(s), 2022. Published by Cambridge University Press in association with International Society for Developmental Origins of Health and Disease

Introduction and aim

Chronic respiratory diseases, particularly asthma, is known to be regulated by cellular and immunologic responses to environmental and biological factors to varying degrees in different individuals. Prenatal in utero stress, microbiota at birth or various postnatal factors such as nutrition, infections, and second-hand smoke contribute to the development of these responses. Reference Carraro, Scheltema, Bont and Baraldi1,Reference Zhang and Kutateladze2 Cumulative data also indicate a relation between early life adversities and chronic airway diseases. These studies not only focus on asthma, but also other chronic disorders including chronic obstructive pulmonary disease, cancer, and immune system disorders. Reference Shields, Hovdestad, Pelletier, Dykxhoorn, O’Donnell and Tonmyr3-Reference Bellis, Hughes, Leckenby, Hardcastle, Perkins and Lowey10 They have evaluated different types of adversities ranging from sexual and physical abuse to gun violence and emotional abuse in children, and the outcome revealed that there was a strong correlation between childhood adversities and presence of adulthood chronic respiratory diseases (Table S1).

Child adversities are known as risk factors for psychosocial or mental disorders in different levels and found associated with addiction to smoke, alcohol, or drugs. Reference Sinha11 In this context, search for the epigenetic changes in acute and chronic stress including childhood adversities revealed that the methylation status of various genes changes due to these childhood conditions. Reference Yang, Zhang and Ge12 The proposed pathways regarding epigenetic changes suggest that stress activates hypothalamic pituitary adrenal axis (HPA axis) and this induce cortisol increase leading to direct or indirect regulation of immune system.

The hypothesis of this research was, epigenetic changes might lead to asthma in abused children. Therefore, we systematically screened the studies that listed significantly affected genes from epigenetic changes associated with child abuse and then further evaluated for the role of these genes in asthma pathogenesis.

Methods

We followed PRISMA Statement Reference Moher, Liberati, Tetzlaff and Altman13 for review of the literature for childhood adversity and asthma in population-based researches. We used Cukurova University Library help to construct keywords as (“child abuse” OR “child adversity” OR “child sexual abuse” OR “child physical abuse” OR “child neglect” OR “child trauma") AND ("genetics” OR “epigenetics” OR (DNA Methylation)) in NCBI-PubMed and Google Scholar to bring together the informative data that shows relation between childhood adversity and epigenetic changes. Only original research articles were included; review articles, preprint articles, articles involving adversities that occurred after age of 18 and articles that did not have the results of epigenetic analysis as well as the ones involving only economical adversities and pregnancy adversities were excluded. Initially, 5245 articles were retrieved, and majority of those articles were excluded after reviewing the abstracts and titles. Among the 36 articles that were identified after this first review, 15 had whole genome methylation arrays and 21 had methylation data for single genes or pathways, given in the adopted PRISMA flowchart (Fig. 1). Finally, we extracted significantly methylated genes from each study and evaluated the functions of these genes on Gene Cards and NCBI Gene web sites in order to identify the relations with asthma. We also searched PubMed to assess in vivo, in vitro, and clinical studies in relation with these differentially methylated genes and asthma. We then run a gene ontology (GO) analysis using an online tool Reference Pomaznoy, Ha and Peters14 and visualized the pathways related with the evaluated genes.

Fig. 1. Adopted PRISMA flowchart as of date 18 Decemeber 2019.

Results

After reviewing 36 full text articles, differentially methylated genes were recorded and analyzed for their role in asthma. The study sample sizes, methods, studied tissues, countries, and significantly differently methylated genes and their possible contribution to asthma is listed in Table 1 for 15 whole genome analysis or microarray studies. Twenty-one single gene or pathway studies are excluded from the main list due to possible bias and listed in Table S2. All studies were performed in developed countries including USA, Canada, UK, Netherlands, and so forth, and they have extracted DNAs were from whole blood, saliva, T cells, and monocytes. There was at least one affected gene related to asthma in each study while some of the studies showed multiple pathways involved in asthma pathogenesis (Table 1). Single gene or pathway studies mostly had data for post-traumatic stress disorder genes and focused on HPA axis and immune system-related genes, therefore, the genes that regulate HPA axis, NR3C1 and FKBP5, were the most well-studied genes in the adults that had childhood adversities (Table S2). NR3C1 and FKBP5 are also involved in asthma pathogenesis by decreased suppression of inflammation and decrease response to corticosteroids, respectively. Other significantly deregulated genes that were affected by childhood adversities were interleukins, ADAM family, Wingless type-Integration family (WNT), STAT, and mitogene-activated protein kinase (MAPK) pathway and inflammatory-related genes (Table 1). Only one recent study had found no significant relation between childhood adversity and epigenetic regulation after applying multiple statistical corrections. Reference Marzi, Sugden and Arseneault25 The total number of affected genes were

Table 1. Properties of 15 studies of childhood adversity and possible effects of differentially methylated genes in asthma

NR3C1 and asthma

The NR3C1 gene encodes glucocorticoid receptor (GR), which has DNA binding, nuclear localization, ligand binding, and two activation function domains, and has the ability to inhibit the expression of asthma-related cytokines such as IL-5. Reference Panek, Jonakowski and ZioŁo29 IL-5 induces the activity of eosinophils in asthma, after being released from the active macrophages and T lymphocytes. IL-5-induced leukotrienes, therefore, causes asthmatic reactions and symptoms. In a recent bioinformatics study that evaluated ignored genes that might have a function in allergic asthma, NR3C1 was found to be downregulated. Reference Riba, Garcia Manteiga and Bošnjak30 It has also been shown that polymorphisms and mutations in specific sites of this gene has correlation with increase in transforming growth factor (TGF)-β expression in asthma patients, Reference Panek, Pietras and Fabijan31 which is a well-known mediator that leads smooth muscle proliferation and airway remodeling. Regarding the epigenetic regulation of NR3C1, maternal stress during pregnancy, caused increased methylation in the umbilical cord blood mononuclear cells that cause decreased GR expression in the child, which may affect cytokine production and treatment response in the childhood asthma. Reference Al‐Hussainy and Mohammed32

FKBP5 and asthma

FKBP5 or FK506-binding protein 51, is a member of immunophilin protein family that has peptidyl-prolyl isomerases to catalyze isomeric shape of proline amino acid and thus, act as co-chaperon to assist protein folding in various proteins. Increased levels of protein is found in central and peripheric airway brushings of severe asthma patients comparing to healthy subjects. Reference Singhania, Rupani and Jayasekera33 It also serves as a receptor for steroids and immune suppressive drugs and therefore, mostly studied for the effects of treatment response in asthma. FKBP5 express an inhibitory effect on GR function by binding to glucocorticoid-GR complex and delays nuclear translocation of the signal. Reference Zannas, Wiechmann, Gassen and Binder34 There are also other rules of this protein in different pathways related with asthma pathogenesis. Increased levels of FKBP5 induce T-cell proliferation and function by binding to calcineurin and activating nuclear factor of activated T-cells pathway. Reference Zannas, Wiechmann, Gassen and Binder34 Besides, stress induced decrease in FKBP5 methylation, upregulated the protein levels in blood and immune cells and this increase in FKBP5 promotes NF-kB (nuclear factor kappa-light-chain enhancer of activated B cells) mediated inflammation. Reference Zannas, Jia and Hafner35 Thus, reduced methylation of FKBP5 in the abused children, might play role in the asthma development.

FANK1 and asthma

The relationship of FANK1 (Fibronectin type 3 and ankyrin repeat domains protein 1) with asthma is not well studied. There are studies that suggest the role of FANK1 in inhibition or activation of apoptosis. It is known to be expressed mostly by testis cells, but recently shown to be present also in T cells, alveolar, and epithelial cells of bronchi. Reference Wu, Orozco and Boyer36 In a computational analysis of asthma-related genes, FANK1 has come forward as one of the 10 genes found to be associated with asthma. Reference Tremblay, Lemire and Potvin37 However, the functional relation currently remains unknown.

CHRNA5 and asthma

CHRNA5 (Neuronal acetylcholine receptor subunit alpha-5), is a cholinergic nicotinic receptor gene that acts in opening ion channels on the plasma membrane after acetylcholine binding. Expression of the gene is mostly found in airway myocytes and epithelial cells throughout the lungs. Reference Wilk, Shrine and Loehr38 In a meta-analysis that evaluate chromosome 15q25 region and airflow obstruction, Asp389Asn missense single nucleotide polymorphism in CHRNA5 was associated with airflow obstruction in never smokers. Reference Wilk, Shrine and Loehr38 Silencing this gene in three-dimensional cell culture model, increased thickness of the epithelium, suggesting the lead to airway remodeling. Reference Krais, Hautefeuille and Cros39 Studies show increased dependency to cigarette smoking in men Reference Xie, Kranzler and Zhang40,Reference Zhang, Chen, Mu and Wang41 but there is no data that shows relation with epigenetic regulation of CHRNA5 and asthma but since genetically modification of the gene contributes airflow obstruction, and in vitro knock-down of the gene causes increased thickness in the airway models, it is possible that the increased methylation might contribute to asthma phenotype in the abused child.

ADAMs 10 and 17 and asthma

ADAM (A disintegrin and metalloproteinase domain containing protein) family proteins act as sheddase, with its adhesion and protease function, and shed various membrane proteins at the outer cell membrane that cause the maturation of those proteins and/or releasing them from the membrane. A single ADAM protein can cleave more than one protein as well as different ADAM members may cleave the same substrate. ADAM10 and ADAM17 have the similar active sites that both of them can cleave membrane bound TNF-alpha to its mature dissolvable state. ADAM10 has ability to shed ephrin/eph complexes between the cells, helps releasing soluble forms of IL6 and IL11 by mediating cleavage of IL6R and IL11RA, and also other surface proteins including heparin binding epidermal growth factor. ADAM10 also serves as a receptor for S. aureus, increasing the virulence of the bacteria. ADAM17 also cleaves IL6R, IL1RII, TGF-alpha, growth hormone receptor. Reference Dreymueller, Uhlig and Ludwig42 Obviously, there are other many proteins and pathways effected by these two ADAMs that are not listed here. Thus, ADAM 10 and 17 playing role in endothelial permeability, smooth muscle transactivation, leukocyte recruitment, preventing resolution of inflammation and inducing inflammation, are important proteins in asthma pathogenesis and might be target for the treatment of the disease. Loss of function mutations of ADAM10 and ADAM17 are extremely rare and mice with double knockout of these genes do not survive. Reference Dreymueller, Uhlig and Ludwig42 Overall, epigenetic regulation of these genes might affect asthma development in children.

SLC6A4 (SERT) and asthma

SLC6A4 gene, encodes sodium-dependent serotonin transporter and solute carrier family 6-member 4 (also SERT or 5HT transporter) protein that involves in recycling of serotonin (5-hydroxy tryptamine, 5HT) molecules by transporting them from the synaptic area to the presynaptic membrane. 5HT, besides its functions in the central nervous system, has ability to induce cytokine and chemokine synthesis, cell proliferation and tissue regeneration, Reference Kang, Ha and Bahaie43 therefore, it is well studied in the pathogenesis of asthma. Increased levels of serotonin is found in symptomatic asthmatic patients and negatively correlated with FEV1 levels. Reference Kang, Ha and Bahaie43 5HT, stimulates PGE2 production by alveolar macrophages, activates eosinophils, and suppresses IL-12 expression. Reference Kang, Ha and Bahaie43 5HT also act as a platelet-stored vasoconstrictor. Termination of the serotonin signal depends on the levels of SLC6A4 and activation of the receptor helps relief of asthma symptoms to release. Reference Flanagan, Sebastian, Battaglia, Foster, Cormier and Nichols44 There are studies that evaluated the relationship between SLC6A4 gene polymorphisms and asthma but have not found any correlations up to now with the studied ones. Reference Farjadian, Moghtaderi, Fakhraei, Nasiri and Farjam45 SLC6A4 knockout mice show anxiety-like behavior and changes in the methylation of the gene may contribute the levels of 5HT and therefore influence asthma genotype in the maltreated and affected children.

OXTR and asthma

OXTR gene codes for oxytocin receptor, which is a G protein coupled receptor that needs to activate phosphatidylinositol-calcium second messenger molecules. Studies have shown that OXTR is expressed both in human and mice airway smooth muscle cells and its expression is affected by cytokines such as IL-13 and TNF-alpha. Reference Amrani, Syed and Huang46 Oxytocine levels in BAL fluids were also found increased in asthmatic patients comparing to healthy control subjects Reference Amrani, Syed and Huang46 suggesting that OXTR and its epigenetic regulation might have a role in the pathogenesis of asthma.

RPTOR, MTOR, and asthma

RPTOR or raptor (Regulatory-associated protein of mTOR), regulates mammalian target of rapamycin complex 1 (mTORC1) activity which involves in cell growth, survival, and autophagy. It also has role in maintaining the size of the cell. It is mostly expressed in muscle cells including lungs. In a study that evaluate airway smooth muscle tissue with RNA sequencing to compare asthmatic and normal people, RPTOR was found one of the four genes which were associated with airway hyper-responsiveness. Reference Yick, Zwinderman and Kunst47 mTOR (mechanistic target of rapamycin kinase), was also found to involve in airway remodeling models in mouse models as well as regulation of Th17/Treg and Th1/Th2 ratio. Reference Zhang, Jing and Qiao48 Therefore, epigenetic regulation of mTOR and related pathways significantly influence asthma development.

RGS3 and HCK and asthma

RGS3 involves in inflammation and Tcell migration, Reference Williams, Yau and Sethakorn49 and HCK takes plays in MAPK signaling pathway which in turn related with airway smooth muscle proliferation. Reference Sakai, Nishimura and Watanabe50 Labonte et al found these two genes were significantly hypermethylated in the brain tissue of the traumatic children, but currently there is no data that shows the epigenetic change in the blood or other tissues in these two genes.

CXCL10 and asthma

C-X-C motif chemokine ligand 10 (IFN-gamma-induced protein 10 (IP-10) or small inducible cytokine B10) is a small protein coded by CXCL10 gene. It is expressed in monocytes, endothelial cells, and fibroblasts and has a variety of role in the inflammation. Therefore, the effects on the asthma pathogenesis is well studied. mRNA levels of CXCL10 were found increased in bronchoalveolar fluid of asthmatic patients and data suggest that it has role in corticosteroid therapy-induced persistent type I inflammation. Reference Gauthier, Chakraborty and Oriss51 Kaufman et al., evaluated epigenetic influences on the obesity in adverse childhood experienced children and found decreased methylation of the promoter region of CXCL10. Therefore, inducing obesity or involving inflammation, epigenetic regulation of the gene may contribute to asthma development in the abused children.

STAT and asthma

STAT family of proteins (signal transducer and activator of transcription) act as transcription factors after extracellular cytokine or growth factor binding in the cell and lead to the expression of proliferation, differentiation, and apoptosis-related genes. STAT1 was reported one of the asthma-ignorome gene together with NR3C1 Reference Riba, Garcia Manteiga and Bošnjak30 and variants of STAT6 found related with risk for asthma in a meta-analysis study. Reference Qian, Gao, Ye and Lu52 Epigenetic regulation of Jak-STAT pathway in childhood asthma has been recently reported. Reference Zhang, Chen, Mu and Wang41

CREB and asthma

CREB (cAMP response element-binding protein) is another transcription factor that regulate expression or suppression of multiple genes after getting activated by upstream signaling pathways those use cAMP as secondary messenger. Therefore, it involves multiple pathways in Asthma signaling including therapy response. Reference Kim, Cho, Woo and Liggett53

NFKB, IKappaBR, and asthma

NF-KB (nuclear factor kappa-light-chain enhancer of activated B cells), consists of protein to regulate transcription, cytokine production, and survival when the cell is under stress. Together with MAPK pathway, epigenetic regulation of NF-KB signaling was found significantly affected in adult-onset asthma. Reference Jeong, Imboden and Ghantous54 Researchers have been interested in targeting NF-KB for asthma treatment for the last years. IKappaBR (IKBR) or TONSL gene codes for Tonsoku like DNA Repair protein that negatively regulate NFKB mediated transcription. Therefore, increased methylation of IKBR and demethylation of NFKB would worsen asthma phenotype in the maltreated children.

ALDH2 and asthma

ALDH2 (acetaldehyde dehydrogenase 2) is a member of ALDH family of proteins that acts as an antioxidant and its increased expression inhibits the harmful effects of oxidative stress. Polymorphisms of the gene may cause premature lung aging Reference Kuroda, Hegab and Jingtao55 and ALDH2-deficient mice had alcohol-induced asthma in an animal model study. Reference Shimoda, Obase, Matsuse, Asai and Iwanaga56 These and several other studies indicate that increased methylation of ALDH2 may have role in the asthma pathogenesis.

MAPK pathway, NPY − FOXP4, and asthma

MAPK pathway is a series of signaling cascade pathways that induce distinct pathways in the cell regarding differentiation, proliferation, and cell survival. Its role in asthma pathogenesis has been shown and reviewed in the literature. Reference Chung57

NPY (Neuropeptid Y) involves in multiple signaling pathways including MAPK pathway, and it also regulates intracellular calcium levels. The expression levels of NPY on antigen presenting cells in allergic asthma has been shown, and its role on cytokine expression is not yet clear. Reference Makinde, Steininger and Agrawal58 In a study, the loss of FOXP4 (Forkhead box protein 4) together with FOXP1, which are transcription factors located in airway cells, led to increased NYP expression resulting in airway hyperreactivity through activation of smooth muscle myosin light-chain phosphorylation. Reference Li, Koziol-White and Jude59

ATP2A3 and asthma

ATP2A3 (Sarcoplasmic/Endoplasmic Reticulum Calcium ATPase 3), involving intracellular calcium levels, influence a variety of signaling pathways. the expression was shown to vary among different childhood asthma phenotypes. Reference Boeck, Landgraf-Rauf and Vogelsang60

Other relevant genes and gene ontology and pathway analysis

The rest of the genes listed in Table 1 are usually found in the literature that assessed obesity asthma relationship or that took place in the gene expression pathways in immune system.

After reviewing these genes in the literature, we further ran a GO analysis using two different online tools Reference Pomaznoy, Ha and Peters14,Reference Fabregat, Sidiropoulos and Viteri61 and visualized the pathways related with the evaluated genes (Fig. 2 and Fig. S1 and Table S3).

Fig. 2. Gene enrichment and pathway analysis of the affected genes. Differentially methylated genes in the adults who had childhood adversity, that have relationship with asthma are shown in orange color and significantly related pathways are in green. Dark green shows strongest relation. The full list of the pathways and corresponding full image are given in supplementary material.

Conclusion and discussion

In this research, we demonstrated that childhood adversity, including sexual and physical abuse and neglect, effects the epigenetic regulation of the genes that are shown to play role in asthma pathogenesis, as a potential risk factor of the adulthood asthma. These epigenetic changes focused on altered methylation of DNA, which has become convenient to study comparing to chromatin purification. Reference DeVries and Vercelli62 The increased or decreased methylation of the genes found in the adults, who experienced adverse childhood events, were included well-studied asthma-related genes such as ADAM10 &17 and CXCL10 as well as the genes that seemed less common in asthma pathogenesis regarded studies such as ALDH2, FOXP4, and FANK1. We would like to remind that the list of “significantly changed” genes might have caused a bias in the generation of our table in this article, which the cutoff points of each study were different, especially in the whole genome array-based studies. This might have led the ignorance of many other affected genes that may play role in asthma pathogenesis.

Up-to-date scientific investigations of asthma pathogenesis indicate a multi-complex pathophysiologic process that might be responsible of the diverse phenotypes among asthma patients, and recent studies indicate a contribution of lifelong epigenetic influences to this pathophysiology. Reference Chogtu, Bhattacharjee and Magazine63 The complexity increases while the type of the adversity and its relationship with asthma may differ from population to population, related to cultures and traditions, and therefore, one of the limitations of this systematic review is that the origin of most studies included the countries with similar socioeconomic background, decreasing the value of generalizability. This study also did not include in utero period of the children, which may also contribute to epigenetic alterations. This systematic review included Pubmed and Google Academic search due to their common usage in the field and therefore, studies in other databases might have been excluded due to this limitation. Although the genes listed in this study have been associated with asthma and a few of them are well studied, the underlying pathway for these associations may need deeper research for future discoveries of personalized medicine and to understand the pathogenesis of the relationship of these epigenetic influences with asthma.

Supplementary materials

For supplementary material for this article, please visit https://doi.org/10.1017/S2040174422000083

Acknowledgements

We thank to Cukurova University Library for helping to build the key words for database search.

Author contributions

YS designed the study analyzed the results and wrote the manuscript; HO and OB involved in literature search and data collection; OY critically reviewed the manuscript.

Financial support

None.

Conflict of interest

All authors declare no support, financial or otherwise, from any organization for the submitted work.

Ethical standards

The article contains only publicly available data and ethical approval is not applicable.

Footnotes

Part of this work has been presented at Turkish Thoracic Society’s 22nd Annual Congress in April 2019.

References

Carraro, S, Scheltema, N, Bont, L, Baraldi, E. Early-life origins of chronic respiratory diseases: understanding and promoting healthy ageing. Eur Respir J. 2014; 44(6), 16821696. DOI 10.1183/09031936.00084114.CrossRefGoogle ScholarPubMed
Zhang, Y, Kutateladze, TG. Diet and the epigenome. Nat Commun. 2018; 9(1), 2376. DOI 10.1038/s41467-018-05778-1.Google ScholarPubMed
Shields, ME, Hovdestad, WE, Pelletier, C, Dykxhoorn, JL, O’Donnell, SC, Tonmyr, L. Childhood maltreatment as a risk factor for diabetes: findings from a population-based survey of Canadian adults. BMC Public Health. 2016; 16(1). DOI 10.1186/s12889-016-3491-1.Google ScholarPubMed
Bhan, N, Glymour, MM, Kawachi, I, Subramanian, SV. Childhood adversity and asthma prevalence: evidence from 10 US states (2009-2011. BMJ Open Respir Res. 2014; 1(1), e000016. DOI 10.1136/bmjresp-2013-000016.CrossRefGoogle ScholarPubMed
Ayaydin, H, Abali, O, Okumus Akdeniz, N, et al. Immune system changes after sexual abuse in adolescents. Pediatr Int. 2016; 58(2), 105112. DOI 10.111/ped.12767.CrossRefGoogle ScholarPubMed
Remigio-Baker, RA, Hayes, DK, Reyes-Salvail, F. Adverse childhood events are related to the prevalence of asthma and chronic obstructive pulmonary disorder among adult women in Hawaii. Lung. 2015; 193(6), 885891. DOI 10.1007/s00408-015-9777-8.Google Scholar
Clemens, V, Huber-Lang, M, Plener, PL, Brähler, E, Brown, RC, Fegert, JM. Association of child maltreatment subtypes and long-term physical health in a German representative sample. Eur J Psychotraumatol. 2018; 9(1), 1510278. DOI 10.1080/20008198.2018.1510278.CrossRefGoogle Scholar
Rosas-Salazar, C, Han, Y-Y, Brehm, JM, et al. Gun violence, African ancestry, and asthma. Chest. 2016; 149(6), 14361444. DOI 10.1016/j.chest.2016.02.639.CrossRefGoogle ScholarPubMed
Bonfim, CB, dos Santos, DN, Barreto, ML. The association of intrafamilial violence against children with symptoms of atopic and non-atopic asthma: a cross-sectional study in Salvador. Brazil Child Abuse Neglect. 2015; 50(2), 244253. DOI 10.1016/j.chiabu.2015.05.021.CrossRefGoogle ScholarPubMed
Bellis, MA, Hughes, K, Leckenby, N, Hardcastle, KA, Perkins, C, Lowey, H. Measuring mortality and the burden of adult disease associated with adverse childhood experiences in England: a national survey. J Public Health. 2014; 37(3), 445454. DOI 10.1093/pubmed/fdu065.CrossRefGoogle ScholarPubMed
Sinha, R. Chronic stress, drug use, and vulnerability to addiction. Ann NY Acad Sci. 2008; 1141(1), 105130. DOI 10.1196/annals.1441.030.CrossRefGoogle ScholarPubMed
Yang, B-Z, Zhang, H, Ge, W, et al. Child abuse and epigenetic mechanisms of disease risk. Am J Prev Med. 2013; 44(2), 101107. DOI 10.1016/j.amepre.2012.10.012.Google ScholarPubMed
Moher, D, Liberati, A, Tetzlaff, J, Altman, DG, PRISMA Group*. Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. Ann Intern Med. 2009; 151(4), 264269.CrossRefGoogle ScholarPubMed
Pomaznoy, M, Ha, B, Peters, B. GOnet: a tool for interactive gene ontology analysis. BMC Bioinform. 2018; 19(1), 470. DOI 10.1186/s12859-018-2533-3.CrossRefGoogle ScholarPubMed
Mehta, D, Klengel, T, Conneely, KN, et al. Childhood maltreatment is associated with distinct genomic and epigenetic profiles in posttraumatic stress disorder. Proc Natl Acad Sci USA. 2013; 110(20), 83028307. DOI 10.1073/pnas.1217750110.CrossRefGoogle ScholarPubMed
Provençal, N, Suderman, MJ, Caramaschi, D, et al. Differential DNA methylation regions in cytokine and transcription factor genomic loci associate with childhood physical aggression. PLoS ONE. 2013; 8(8), e71691. DOI 10.1371/journal.pone.0071691.CrossRefGoogle ScholarPubMed
Guillemin, C, Provençal, N, Suderman, M, et al. DNA methylation signature of childhood chronic physical aggression in T cells of both men and women. PLoS ONE. 2014; 9(1), e86822. DOI 10.1371/journal.pone.0086822.Google Scholar
Provençal, N, Suderman, MJ, Guillemin, C, et al. Association of childhood chronic physical aggression with a DNA methylation signature in adult human T cells. PLoS ONE. 2014; 9(4), e89839. DOI 10.1371/journal.pone.0089839.CrossRefGoogle ScholarPubMed
Suderman, M, Borghol, N, Pappas, JJ, et al. Childhood abuse is associated with methylation of multiple loci in adult DNA. BMC Med Genom. 2014; 7(1), 68. DOI 10.1186/1755-8794-7-13.CrossRefGoogle ScholarPubMed
Labonté, B, Turecki, G. Epigenetic effects of childhood adversity in the brain and suicide risk (Chapter 13). In The Neurobiological Basis of Suicide (ed. Dwivedi Y), 2012, CRC Press/Taylor & Francis, Boca Raton, FL.Google ScholarPubMed
Schwaiger, M, Grinberg, M, Moser, D, et al. Altered stress-induced regulation of genes in monocytes in adults with a history of childhood adversity. Neuropsychopharmacol. 2016; 41(10), 25302540. DOI 10.1038/npp.2016.57.CrossRefGoogle ScholarPubMed
Cicchetti, D, Hetzel, S, Rogosch, FA, Handley, ED, Toth, SL. An investigation of child maltreatment and epigenetic mechanisms of mental and physical health risk. Dev Psychopathol. 2016; 28(4pt2), 13051317. DOI 10.1017/s0954579416000869.Google ScholarPubMed
Cecil, CAM, Smith, RG, Walton, E, Mill, J, McCrory, EJ, Viding, E. Epigenetic signatures of childhood abuse and neglect: implications for psychiatric vulnerability. J Psychiatr Res. 2016; 83(7), 184194. DOI 10.1016/j.jpsychires.2016.09.010.CrossRefGoogle ScholarPubMed
Kaufman, J, Montalvo-Ortiz, JL, Holbrook, H, et al. Adverse childhood experiences, epigenetic measures, and obesity in youth. J Pediatr. 2018; 202, 150156.e3. DOI 10.1016/j.jpeds.2018.06.051.CrossRefGoogle ScholarPubMed
Marzi, SJ, Sugden, K, Arseneault, L, et al. Analysis of DNA methylation in young people: limited evidence for an association between victimization stress and epigenetic variation in blood. Am J Psychiatry. 2018; 175(6), 517529. DOI 10.1176/appi.ajp.2017.17060693.CrossRefGoogle ScholarPubMed
Houtepen, LC, Hardy, R, Maddock, J, et al. Childhood adversity and DNA methylation in two population-based cohorts. Transl Psychiatry. 2018; 8(1), 378. DOI 10.1038/s41398-018-0307-3.Google ScholarPubMed
Marinova, Z, Maercker, A, Küffer, A, et al. DNA methylation profiles of elderly individuals subjected to indentured childhood labor and trauma. BMC Med Genet. 2017; 18(1), 608. DOI 10.1186/s12881-017-0370-2.CrossRefGoogle ScholarPubMed
Khulan, B, Manning, JR, Dunbar, DR, et al. Epigenomic profiling of men exposed to early-life stress reveals DNA methylation differences in association with current mental state. Transl Psychiatry. 2014; 4(9), e448. DOI 10.1038/tp.2014.94.CrossRefGoogle ScholarPubMed
Panek, M, Jonakowski, M, ZioŁo, J, et al. A novel approach to understanding the role of polymorphic forms of the NR3C1 and TGF-β1 genes in the modulation of the expression of IL-5 and IL-15 mRNA in asthmatic inflammation. Mol Med Rep. 2016; 13(6), 48794887. DOI 10.3892/mmr.2016.5104.CrossRefGoogle ScholarPubMed
Riba, M, Garcia Manteiga, JM, Bošnjak, B, et al. Revealing the acute asthma ignorome: characterization and validation of uninvestigated gene networks. Sci Rep. 2016; 6(1), 2055. DOI 10.1038/srep24647.CrossRefGoogle ScholarPubMed
Panek, M, Pietras, T, Fabijan, A, et al. The NR3C1 glucocorticoid receptor gene polymorphisms may modulate the TGF-beta mRNA expression in asthma patients. Inflammation. 2015; 38(4), 14791492. DOI 10.1007/s10753-015-0123-3.Google ScholarPubMed
Al‐Hussainy, A, Mohammed, R. Consequences of maternal psychological stress during pregnancy for the risk of asthma in the offspring. Scand J Immunol. 2021; 93(1), e12919.CrossRefGoogle ScholarPubMed
Singhania, A, Rupani, H, Jayasekera, N, et al. Altered epithelial gene expression in peripheral airways of severe asthma. PLOS ONE. 2017; 12(1), e0168680. DOI 10.1371/journal.pone.0168680.Google ScholarPubMed
Zannas, AS, Wiechmann, T, Gassen, NC, Binder, EB. Gene-stress–epigenetic regulation of FKBP5: clinical and translational implications. Neuropsychopharmacolo. 2015; 41(1), 261274. DOI 10.1038/npp.2015.235.CrossRefGoogle ScholarPubMed
Zannas, AS, Jia, M, Hafner, K, et al. Epigenetic upregulation of FKBP5 by aging and stress contributes to NF-κB-driven inflammation and cardiovascular risk. Proc Natl Acad Sci USA. 2019; 116(23), 1137011379. DOI 10.1073/pnas.1816847116.CrossRefGoogle ScholarPubMed
Wu, C, Orozco, C, Boyer, J, et al. BioGPS: an extensible and customizable portal for querying and organizing gene annotation resources 2021, http://biogps.org/#goto=genereport&id=92565.Google Scholar
Tremblay, K, Lemire, M, Potvin, C, et al. Genes to diseases (G2D) computational method to identify asthma candidate genes. PLoS ONE. 2008; 3(8), e2907. DOI 10.1371/journal.pone.0002907.CrossRefGoogle ScholarPubMed
Wilk, JB, Shrine, NRG, Loehr, LR, et al. Genome-wide association studies identify chrna5/3andHTR4 in the development of airflow obstruction. Am J Respir Crit Care Med. 2012; 186(7), 622632. DOI 10.1164/rccm.201202-0366oc.CrossRefGoogle ScholarPubMed
Krais, AM, Hautefeuille, AH, Cros, M-P, et al. CHRNA5 as negative regulator of nicotine signaling in normal and cancer bronchial cells: effects on motility, migration and p63 expression. Carcinogenesis. 2011; 32(9), 13881395. DOI 10.1093/carcin/bgr090.CrossRefGoogle ScholarPubMed
Xie, P, Kranzler, HR, Zhang, H, et al. Childhood adversity increases risk for nicotine dependence and interacts with α5 nicotinic acetylcholine receptor genotype specifically in males. Neuropsychopharmacol. 2011; 37(3), 669676. DOI 10.1038/npp.2011.240.Google ScholarPubMed
Zhang, N-Z, Chen, X-J, Mu, Y-H, Wang, H. Identification of differentially expressed genes in childhood asthma. Medicine. 2018; 97(21), e10861. DOI 10.1097/md.0000000000010861.Google ScholarPubMed
Dreymueller, D, Uhlig, S, Ludwig, A. ADAM-family metalloproteinases in lung inflammation: potential therapeutic targets. Am J Physiol Lung Cell Mol Physiol. 2015; 308(4), L325L343. DOI 10.1152/ajplung.00294.2014.CrossRefGoogle ScholarPubMed
Kang, BN, Ha, SG, Bahaie, NS, et al. Regulation of serotonin-induced trafficking and migration of Eosinophils. PLoS ONE. 2013; 8(1), e54840. DOI 10.1371/journal.pone.0054840.CrossRefGoogle ScholarPubMed
Flanagan, TW, Sebastian, MN, Battaglia, DM, Foster, TP, Cormier, SA, Nichols, CD. 5-HT2 receptor activation alleviates airway inflammation and structural remodeling in a chronic mouse asthma model. Life Sci. 2019; 236(Suppl 2), 116790. DOI 10.1016/j.lfs.2019.116790.CrossRefGoogle Scholar
Farjadian, S, Moghtaderi, M, Fakhraei, B, Nasiri, M, Farjam, M. Association between serotonin transporter gene polymorphisms and childhood asthma. J Asthma. 2013; 50(10), 10311035. DOI 10.3109/02770903.2013.834503.CrossRefGoogle ScholarPubMed
Amrani, Y, Syed, F, Huang, C, et al. Expression and activation of the oxytocin receptor in airway smooth muscle cells: regulation by TNFα and IL-13. Respir Res. 2010; 11(1), 629. DOI 10.1186/1465-9921-11-104.CrossRefGoogle ScholarPubMed
Yick, CY, Zwinderman, AH, Kunst, PW, et al. Gene expression profiling of laser microdissected airway smooth muscle tissue in asthma and atopy. Allergy. 2014; 69(9), 12331240. DOI 10.1111/all.12452.Google ScholarPubMed
Zhang, Y, Jing, Y, Qiao, J, et al. Activation of the mTOR signaling pathway is required for asthma onset. Sci Rep. 2017; 7(1), 143. DOI 10.1038/s41598-017-04826-y.Google ScholarPubMed
Williams, JW, Yau, D, Sethakorn, N, et al. RGS3 controls T lymphocyte migration in a model of Th2-mediated airway inflammation. Am J Physiol Lung Cell Mol Physiol. 2013; 305(10), L693L701. DOI 10.1152/ajplung.00214.2013.CrossRefGoogle Scholar
Sakai, H, Nishimura, A, Watanabe, Y, et al. Involvement of Src family kinase activation in angiotensin II-induced hyperresponsiveness of rat bronchial smooth muscle. Peptides. 2010; 31(12), 22162221. DOI 10.1016/j.peptides.2010.09.012.CrossRefGoogle ScholarPubMed
Gauthier, M, Chakraborty, K, Oriss, TB, et al. Severe asthma in humans and mouse model suggests a CXCL10 signature underlies corticosteroid resistant Th1 bias. JCI Insight. 2017; 2(13), e94580. DOI 10.1172/jci.insight.94580.Google ScholarPubMed
Qian, X, Gao, Y, Ye, X, Lu, M. Association of STAT6 variants with asthma risk: a systematic review and meta-analysis. Hum Immunol. 2014; 75(8), 847853. DOI 10.1016/j.humimm.2014.06.007.CrossRefGoogle ScholarPubMed
Kim, D, Cho, S, Woo, JA, Liggett, SB. A CREB-mediated increase in miRNA let-7f during prolonged β-agonist exposure: a novel mechanism of β2-adrenergic receptor down-regulation in airway smooth muscle. The FASEB J. 2018; 32(7), 36803688. DOI 10.1096/fj.201701278r.Google ScholarPubMed
Jeong, A, Imboden, M, Ghantous, A, et al. DNA methylation in inflammatory pathways modifies the association between BMI and adult-onset non-atopic asthma. Int J Environ Res Public Health. 2019; 16(4), 600. DOI 10.3390/ijerph16040600.Google ScholarPubMed
Kuroda, A, Hegab, AE, Jingtao, G, et al. Effects of the common polymorphism in the human aldehyde dehydrogenase 2 (ALDH2) gene on the lung. Respir Res. 2017; 18(1), 583. DOI 10.1186/s12931-017-0554-5.CrossRefGoogle ScholarPubMed
Shimoda, T, Obase, Y, Matsuse, H, Asai, S, Iwanaga, T. The pathogenesis of alcohol-induced airflow limitation in acetaldehyde dehydrogenase 2-deficient mice. Intl Arch Allergy Immunol. 2016; 171(3-4), 276284. DOI 10.1159/000452709.Google ScholarPubMed
Chung, KF. p38 mitogen-activated protein kinase pathways in asthma and COPD. Chest. 2011; 139(6), 14701479. DOI 10.1378/chest.10-1914.CrossRefGoogle ScholarPubMed
Makinde, TO, Steininger, R, Agrawal, DK. NPY and NPY receptors in airway structural and inflammatory cells in allergic asthma. Exp Mol Pathol. 2013; 94(1), 4550. DOI 10.1016/j.yexmp.2012.05.009.Google ScholarPubMed
Li, S, Koziol-White, C, Jude, J, et al. Epithelium-generated neuropeptide Y induces smooth muscle contraction to promote airway hyperresponsiveness. J Clin Invest. 2016; 126(5), 19781982. DOI 10.1172/JCI81389.CrossRefGoogle ScholarPubMed
Boeck, A, Landgraf-Rauf, K, Vogelsang, V, et al. Ca2+ and innate immune pathways are activated and differentially expressed in childhood asthma phenotypes. Pediatr Allergy Immunol. 2018; 29(8), 823833. DOI 10.1111/pai.12971.CrossRefGoogle ScholarPubMed
Fabregat, A, Sidiropoulos, K, Viteri, G, et al. Reactome pathway analysis: a high-performance in-memory approach. BMC Bioinform. 2017; 18(1), 383. DOI 10.1186/s12859-017-1559-2.Google ScholarPubMed
DeVries, A, Vercelli, D. Epigenetic mechanisms in asthma. Ann Am Thorac Soc. 2016; 13(Suppl 1), S48S50. DOI 10.1513/AnnalsATS.201507-420MG.CrossRefGoogle ScholarPubMed
Chogtu, B, Bhattacharjee, D, Magazine, R. Epigenetics: the new frontier in the landscape of asthma. Scientifica. 2016; 2016(2), 4638949. DOI 10.1155/2016/4638949.Google ScholarPubMed
Figure 0

Fig. 1. Adopted PRISMA flowchart as of date 18 Decemeber 2019.

Figure 1

Table 1. Properties of 15 studies of childhood adversity and possible effects of differentially methylated genes in asthma

Figure 2

Fig. 2. Gene enrichment and pathway analysis of the affected genes. Differentially methylated genes in the adults who had childhood adversity, that have relationship with asthma are shown in orange color and significantly related pathways are in green. Dark green shows strongest relation. The full list of the pathways and corresponding full image are given in supplementary material.

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