Chromosomal Numerical Aberrations and Rare Copy Number Variation in Patients with Inflammatory Bowel Disease

Abstract Background and Aims Inflammatory bowel diseases [IBD] have a complex polygenic aetiology. Rare genetic variants can cause monogenic intestinal inflammation. The impact of chromosomal aberrations and large structural abnormalities on IBD susceptibility is not clear. We aimed to comprehensively characterise the phenotype and prevalence of patients with IBD who possess rare numerical and structural chromosomal abnormalities. Methods We performed a systematic literature search of databases PubMed and Embase; and analysed gnomAD, Clinvar, the 100 000 Genomes Project, and DECIPHER databases. Further, we analysed international paediatric IBD cohorts to investigate the role of IL2RA duplications in IBD susceptibility. Results A meta-analysis suggests that monosomy X [Turner syndrome] is associated with increased expressivity of IBD that exceeds the population baseline (1.86%, 95% confidence interval [CI] 1.48 to 2.34%) and causes a younger age of IBD onset. There is little evidence that Klinefelter syndrome, Trisomy 21, Trisomy 18, mosaic Trisomy 9 and 16, or partial trisomies contribute to IBD susceptibility. Copy number analysis studies suggest inconsistent results. Monoallelic loss of X-linked or haploinsufficient genes is associated with IBD by hemizygous or heterozygous deletions, respectively. However, haploinsufficient gene deletions are detected in healthy reference populations, suggesting that the expressivity of IBD might be overestimated. One duplication that has previously been identified as potentially contributing to IBD risk involves the IL2RA/IL15R loci. Here we provide additional evidence that a microduplication of this locus may predispose to very-early-onset IBD by identifying a second case in a distinct kindred. However, the penetrance of intestinal inflammation in this genetic aberration is low [<2.6%]. Conclusions Turner syndrome is associated with increased susceptibility to intestinal inflammation. Duplication of the IL2RA/IL15R loci may contribute to disease risk.


Introduction
Inflammatory bowel disease [IBD] comprises a group of inflammatory disorders arising from the dysregulated interplay between innate and adaptive immune responses and the gut environment, including intestinal microbiota and dietary factors. 1,2 IBD is categorised by endoscopic and histological features into Crohn's disease [CD], ulcerative colitis [UC], and IBD unclassified [IBDU]. Genome-wide association studies have uncovered hundreds of common polygenic risk loci that contribute towards the genetic heritability of classical polygenic IBD. 3 However, rare genetic variants may also contribute significantly to the risk of an individual developing classical polygenic IBD. 4 In contrast to the majority of patients with polygenic IBD, IBD may also emerge with a Mendelian pattern of inheritance, where a single gene defect leads to IBD. 5 In a recent position statement of the European Society for Paediatric Gastroenterology Hepatology and Nutrition [ESPGHAN], 75 genes causing monogenic IBD were highlighted as having clinical significance for diagnosis and treatment. 6 Overall, over 100 genes likely contribute to monogenic forms of IBD. 7 These genes encode a functionally diverse set of proteins, and defects may cause primary immunodeficiency, immune dysregulation, and intestinal epithelial dysfunction, among other phenotypes. Several monogenic IBD syndromes are associated with particularly severe and treatment-refractory disease that can be associated with significant morbidity. 6 There is limited knowledge regarding whether larger structural and numerical chromosomal abnormalities affect IBD susceptibility. The structural diversity of the human genome encompasses complete or partial loss or gain of entire chromosomes, such as monosomies and trisomies, and includes smaller deletions or duplications that contribute to copy number variation [CNV]. CNV contributes towards 4.8-9.7% of the diversity of the human genome, 8 suggesting a relevant contribution to disease, especially for dosagesensitive genes. 9 Despite this, the contribution of CNV in monogenic IBD genes has been scarcely investigated in genetic susceptibility studies.
Here, we perform a systematic search on the role of numerical chromosomal abnormalities and rare CNV. We review the literature and interrogate the DECIPHER and ClinVar databases to identify case reports of genetic structural aberrations linked to IBD. We identify candidate regions for rare CNV and perform a replication analysis in large IBD cohorts, based on exome sequencing.

Ethics approval
Experiments were carried out with Research Ethics Board [REB] approval from the Hospital for Sick Children, the Oxford IBD cohort study [rare disease subproject], the Department of Pediatrics, UT Southwestern Medical Center, and Genomics England Research Consortium. Informed written consent to participate in research was obtained from patient/families and controls. Parents of the patients that are reported as case report in this paper consented to their information being published as a detailed case report.

Definitions
Genomic chromosomal abnormalities were categorised into numerical chromosomal abnormalities and structural variants. Numerical abnormalities were defined as chromosomal aneuploidies where the entire chromosome was either gained or lost. These were further divided into sex chromosome aneuploidies [monosomy X, ie, Turner syndrome; and 47,XXY, ie, Klinefelter syndrome] and trisomies [Trisomy 21, Trisomy 18, Trisomy 16, and Trisomy 9]. Structural abnormalities were defined as unbalanced structural rearrangements that result in CNV larger than 1 kb in size. 10 These were further divided into partial monosomies and trisomies that were considered to be: >1 Mb [large deletions or duplications] or <1 Mb [microdeletions and microduplications]. Rare CNVs were defined as present at mean allele frequencies <0.001 based on the data from the gnomAD database. 11 More common CNVs <1 kb in size were excluded from the search, which was designed to focus on rare and putatively highly penetrant variants and to focus on gene dose effects.

Search strategy
We performed a systematic literature search on the role of numerical and structural chromosomal abnormalities in patients with IBD. PubMed and Embase databases were searched for each of the chromosomal defects and CNVs separately [last accessed August 31, 2021] [ Figure 1]. The search was done for terms 'inflammatory bowel disease' and 'Turner syndrome', 'Down syndrome', 'Klinefelter syndrome', 'trisomy 9', 'trisomy 18', 'trisomy 16', 'partial trisomy', 'partial monosomy', 'copy number variation'. These were mapped to Medical Subject Heading controlled vocabulary terms on PubMed or mapped to Emtree terms on Embase [Supplementary Figure 1]. The search was limited to publication years 1980-2021 for chromosomal aneuploidies and 1990-2021 for structural abnormalities, to acknowledge technical progress in detection of CNV using cytogenetics and hybridisation technologies.
Abstracts were screened to remove irrelevant results that did not include the search terms. Only full-text papers written in English were included. Additional studies were identified from conferences, correspondence with authors, and manual searching of included study references and citations.

DECIPHER database search
The literature search was complemented by analysis of genetic aberrations associated with colitis, enterocolitis, UC, and CD in the DECIPHER and ClinVar databases [ Figure  1]. The DECIPHER database [release DECIPHER v11.6 on August 18, 2021, https://www.deciphergenomics.org] 12 contains data from over 39 000 patients who provided consent for broad data sharing. Single nucleotide variants and insertions/deletions less than 1 kb in length were excluded from the search. For CNV analysis of specific regions, additional patient data were analysed from the ClinVar database, which contains reports on human genetic variation and its relationship to clinically relevant phenotypes [accessed on August 18, 2021, https://www.ncbi.nlm.nih.gov/clinvar/]. 13 To assess the frequency of genetic variants in a healthy population, we screened the GnomAD database [release v3.1.3 September 2021, https://gnomad.broadinstitute. org/]. GnomAD removes data from patients with severe paediatric disease and their first-degree relatives, so their frequency in the database is lower than in the general population. 11 2.5. Replication study to detect patients with IL2RA duplication A survey for patients with IL2RA duplication was performed across several IBD cohorts. Patients with IL2RA duplications were screened for in tertiary referral centre databases in Oxford, UK [n = 700 genotyped IBD patients], London UK [n = 1296], 14 Toronto, Canada [n = 3158], 15 and in the UK 100 000 Genomes Project database which contains wholegenome data from individuals with rare disease or cancer. 16  • Reviews that do not include a case report or screen study for the association between an abnormality and IBD Figure 1. Reports identified and excluded in systematic review of cytogenetic abnormalities and inflammatory bowel disease [IBD]. Six disorders or syndromes were included in the initial assessment. Reports of IBD or IBD-like disease were the initial selection criteria that yielded 190 publications and 16 DECIPHER entries. Reports were excluded based on exclusion criteria. Numbers in brackets represent the number of cases for each abnormality type that remained after exclusion. These numbers include duplicated publications or Decipher reports that include more than one abnormality. The total number of unique publications and Decipher reports was 50.
majority [80%] of the samples used in the CNV analysis come from a previously published cohort collected from the greater Toronto area. 15 The Genomics England 100 000 genomes dataset was also screened for duplications that included IL2RA. Copy number gains were called using Canvas. 18  Lymphocyte proliferation was quantified by flow cytometry of fluorescently dyed alkyne-modified nucleoside incorporation in peripheral blood mononuclear cells [PBMCs] that were stimulated with three different stimuli: agonistic anti-CD3 alone, agonistic anti-CD3 plus anti-CD28, and agonistic anti-CD3 plus exogenous IL2. Proliferation was measured as the amount of fluorescent signal.
A control sample from a healthy unrelated individual was included for all analyses.

Statistics
The 95% confidence intervals [CIs] for each proportion were calculated using the Wald method. The Mann-Whitney test was used for comparing age of onset data between the classical IBD and Turner syndrome cohorts. One-way analysis of variance [ANOVA] was used to compare age of onset date between different sub-genotypes of the Turner syndrome cohort. All statistical analyses were done using the GraphPad PRISM software [version 9.2.0].

Numerical chromosomal aberrations
The database search identified 41 unique relevant articles that were reviewed in full text and nine unique DECIPHER reports [ Figure 1]. Two unique articles reported on multiple conditions 19,20 as well as one Decipher entry [Patient 349797], so they were included as duplicates. In patients with Turner syndrome the reported penetrance exceeded the conservative upper border population baseline risk for IBD of 1%. 21 There was insufficient evidence to support the association between IBD and Down syndrome, Klinefelter syndrome, Trisomy 9, Trisomy 18, Trisomy 16, or large chromosomal deletions or duplications [ Figure 2A].

Turner syndrome is associated with a penetrance of IBD that exceeds the population baseline
In total 22 published studies were identified describing patients with Turner syndrome and IBD [ Figure 1]; 23 individuals with IBD and Turner syndrome were described in case reports [Supplementary  Figure 2B].
Data from the Turner syndrome case reports and Turner syndrome cohort studies did not show an enrichment of a particular IBD phenotype. CD was reported in 65% of case reports, and similarly the larger-scale studies did not suggest a strong bias towards either phenotype. [23][24][25] Based on the case reports, 26% of patients with Turner syndrome [6/23] were described to have a 'severe' phenotype of IBD. However, this may be a consequence of publication bias. Consistent criteria for assessing severity were lacking and an increased severity was not reported in the Turner syndrome cohort studies. We investigated whether sub-genotypes of patients with Turner syndrome carried a different risk profile. Among the case reports [n = 22], 27% of individuals were 45,X; 18% were 46,X,i[Xq]; 23% expressed 45,X/46,X,i[Xq] mosaicism; and 32% had other forms of mosaicism. We did not find a significant correlation between karyotype and IBD onset age [n = 20, p = 0.1859, ANOVA] [ Figure 2B]. Among the Turner syndrome cohort studies, 22

Klinefelter syndrome
One paper reported five patients with Klinefelter syndrome [47,XXY] and UC, out of a cohort of 2208 patients. 27 The relative risk [RR] was not significantly elevated for this con-

Down syndrome and IBD
In all, 21 patients with IBD and trisomy 21 [Down syndrome] were reported [Supplementary Table 1]. Two isolated reports suggest a combination of primary sclerosing cholangitis and Crohn's disease in patients with Down Syndrome. 28,29 In a large IBD cohort, the prevalence of Down syndrome was similar to that in the general population [of Spain 0.2% vs 0.1%, respectively, n = 1200]. 30 Based on all the published data of individuals with Down syndrome and IBD, we found no association with a particular IBD sub-phenotype [ Figure 2A]. Age of IBD onset was 25 years +/-5.4 for males and 12 years +/-2.3 for females [based on n = 4 and n = 8, respectively]. There was insufficient evidence for a younger age of onset or increased severity in patients with Trisomy 21. In summary, there was no evidence for increased IBD susceptibility in this population.

Trisomy 9, Trisomy 18, and Trisomy 16
Three patients with either full Trisomy 18, mosaic Trisomy 9, or Trisomy 16 were identified who presented with IBD [Supplementary Table 1]. We identified a 2-year-old child with Trisomy 18, characterised by discontinuous colitis with histopathological changes of chronic active inflammation with mild architectural distortion consistent with IBDU [ Supplementary  Information]. A child with Trisomy 9 was described to suffer from CD from the age of 2 years, and the patient with mosaic Trisomy 16 had UC onset at 10 years of age. 31,32 A strong association between IBD and these syndromes cannot be assumed, given the large number of patients reported with these genetic conditions without intestinal inflammation. 33   XIAP. 38 Another case report described three patients with IBD and homozygous loss of function of the IL10RB locus: two patients with homozygous deletions and a patient with a heterozygous deletion and a duplication causing a frameshift loss-of-function mutation. 39 Recently, a genome sequencing identified a 12.3 kb homozygous tandem duplication that disrupted the reading frame of the LRBA gene. 40 In DECIPHER, 20 patients had a CTLA4 deletion, 10 had a TNFAIP3 deletion, and 30 had X-linked XIAP deletions, including one 46,XY patient. Out of these patients, none presented with IBD-like disease and two patients with CTLA4 deletion and one patient with TNFAIP3 deletion had 'recurrent infections' listed as a phenotype. The 46,XY patient with the XIAP deletion had mild global developmental delay but no symptoms characteristic of X-linked lymphoproliferative syndrome 2 [XLP2] caused by XIAP deficiency. The lack of IBD or other immunodeficiency symptoms in patients with these deletions confirms the incomplete expressivity or the patients are listed on the database before immunodeficiency manifests.

CNV and IBD
Two studies investigated the association between rare genomewide CNV [population frequency <0.1% 41 and <1% 42] and IBD. None of the loci identified in the two studies overlapped or were replicated in other studies. Data are summarised in Table 1 and Figure 3A and B.
In addition to these systematic studies, there were published case reports and patients with intestinal inflammation reported in clinical databases such as DECIPHER or Clinvar [ Table 1, Figure 3A and B]. One published case report and seven DECIPHER database entries described patients with IBD and deletions and/or duplications of more than 1 Mb [Supplementary Table 3]. Five of these patients had very-early onset IBD.
Among genes previously implicated in Mendelian disorders associated with an increased penetrance of IBD, CNV were identified affecting TRNT1, CYBA, ARPC1B, and IL2RA genes. The deletion 3p26.3q25.3 present in one patient spanned the TRNT1 gene, which has been associated with intestinal inflammation with autosomal recessive defects. 44,45 The same patient had a duplication 16q22.1 that spanned the CYBA monogenic IBD gene and PLCG2. Gain-of-function variants in PLCG2 have been associated with IBD as part of a broader phenotype of PLCγ2-associated antibody deficiency and immune dysregulation [PLAID] or auto-inflammation and PLCγ2-associated antibody deficiency and immune dysregulation [APLAID] syndromes. 46,47 Another patient with a 7q21.3q22.2 duplication spanned the monogenic IBD gene ARPC1B; however intestinal inflammation was previously associated with an autosomal recessive loss-of-function of this gene. 48 The duplication of the IL2RA locus as a potential cause of very-early-onset IBD was described in a 2-year-old patient [ Figure 2C, Supplementary Table 3]. 43 Again, although this involves a different mode of inheritance [gene loss rather than gene dose increase], loss-of-function autosomal recessive variants in IL2RA have been associated with chronic intestinal inflammation. 49 Two DECIPHER entries reported patients with IBD and microdeletions/microduplications that spanned a single gene: duplication of the EYS gene and a deletion of the IMMP2L gene [involved in mitochondrial protein transport].
Pathogenic EYS variants are typically associated with retinitis pigmentosa and defective photoreceptor development and the gene also demonstrates enriched expression in intestinal enteroendocrine cells and granulocytes. 50 The majority of the CNVs identified in all sources were unique to single patients. There were two loci reported in both the literature and identified among the DECIPHER dataset patients. Deletion 16p13.3 was present in the genome of a 3-year-old DECIPHER patient [249933] with CD. A 36-yearold patient with colitis, described by Cox and Butler [2015], had partial trisomy 15q26 and partial monosomy 16p13.3. 20 These two 16p13.3 deletions had an overlap of 1.92 Mb. The DECIPHER Patient 308104, diagnosed with UC, had a complement duplication17q25.3, which was also overrepresented in the IBD patients investigated by Frenkel et al. [2019]. 41 Both duplications overlapped with the SLC25A10 gene that encodes a mitochondrial transmembrane transporter.

Replication study IL2RA
Only one of the recently described duplications, a variant spanning the IL2RA locus and presenting with infantile-onset IBD, was supported by functional evidence. 43 We have therefore chosen this variant for validation analysis. The previously described variant duplication of the 374kb locus included not only IL2RA, IL15RA, FBXO18, ANKRD16, and RBM17, but also two partially overlapping genes [GD12, PFKFB3]. Functional evidence suggested a gene dose effect of the IL2 receptor. 43 In the replication study and search, we investigated duplications that encompass the entire IL2RA gene, assuming that such CNVs likely result in a higher gene dosage.
We found no record of whole-gene IL2RA duplication in the gnomAD database, suggesting that this duplication cannot be observed in reference populations around the globe. As the functional validation of the IL2RA duplication and its potential role in IBD provided a relevant and testable hypothesis, we further investigated the impact of IL2RA duplication variants in the IBD patient population. We performed a survey among multiple paediatric IBD centres for patients where a clinical diagnosis of IL2RA duplication was made and searched genetically characterised IBD cohorts in the UK [Oxford and London], screened an IBD cohort using parental samples as controls [Toronto], and searched the DECIPHER database and the 100 000 Genomes Project for further patients.
Among tertiary referral centre cohorts, the survey identified one patient with an IL2RA duplication and infantile-onset IBD where a diagnosis was established by clinical genetics. Genetic panel screening revealed an IL2RA duplication that was confirmed by array comparative genomic hybridisation [aCGH]. The identified chr10:5918731-6182347 region of duplication involved IL15RA and IL2RA as well as FBXO18, ANKRD16, and RBM17. The 3-year-old female patient was diagnosed with IBD at 21 months of age [infantile-onset IBD] when she presented with diarrhoea, haematochezia, and poor appetite. Endoscopy revealed pancolitis with neutrophilic infiltration, crypt abscesses, crypt distortion, and basal lymphoplasmacytosis [ Figure 4A-D]. The patient was started on prednisone and sulphasalazine treatment. The patient was corticosteroid-dependent and needed frequent hospitalisations. Subsequent treatments included corticosteroids, antibiotics, and anti-TNF therapy [adalimumab and infliximab], as well as azathioprine, sirolimus, and tacrolimus. We performed immunophenotyping and functional studies to investigate the impact of the IL2RA duplication [ Figure 4E]. Immunophenotyping suggested normal CD3 + cells [proportion slightly raised 82% with absolute T cell numbers within normal range for patient's age], an increased proportion and absolute numbers of CD8 + T cells among T cells [35.1% and 1540 Gpt/l, respectively], normal proportion and absolute numbers of regulatory T cells [CD4 + CD25 + CD127 low and Foxp3 expressing Treg cells], and normal number of CD3-CD19 + B cells.
In line with the IL2RA duplication, the median fluorescence intensity [MdFI] of the CD25 signal among CD4 + T cells was about double in the patient compared with control [MdFI 3066 versus 1529; Figure 4E].
The proportion of activated HLA DR + effector T cells was high [22.2%]. The proliferation of CD3 + cells in response to stimulation with anti-CD3 antibody was augmented by addition of exogenous IL2 [50.4% vs 62.5%]. IL-2 induced phosphorylation of STAT5 [pSTAT5] in lymphocytes and CD4 T cells on flow cytometry were comparable.
The patient did not present with additional syndromic features or developmental delay but the disease onset, inflammation, and severity of the inflammatory response is comparable to the previously published patient with a similar duplication 43 [ Figure 4F].
To screen an IBD cohort systematically [ Figure 4G] a total of 3158 exomes were analysed, of which 1293 were probands with paediatric onset IBD. We were not able to identify additional IBD patients with a duplication of the IL2RA locus, but there was one unaffected mother who had an IL2RA duplication [DUP:10:5991252:6557098], which also involved five genes [IL15RA, IL2RA, PFKFB3, PRKCQ, and RBM17].
A CNV analysis of the DECIPHER database revealed 38 patients with duplications in the IL2RA locus, of whom 37 patients had both IL2RA and IL15R duplications [ Figure 4G]. Whereas developmental delay was a common finding in those patients, none of the patients were described as having intestinal inflammation. This suggests that the penetrance of intestinal inflammation due to IL2RA duplication is low [<2.6%, 90% confidence interval <0.0001 to 0.12]. The median age of patients from the DECIPHER data at their latest clinical visit was 2 years [mean 5.57 years, n = 33], potentially representing a bias if IBD has not developed by this age. In the 100 000 Genomes Project, eight participants were identified to have duplications that included IL2RA or part of the IL2RA gene [ Figure 4G]. None of these participants had colitis listed as a phenotype.
In summary, the duplication of the IL2RA/IL15RA locus has been identified in two infantile IBD patients with surprising genetic and phenotypic similarity. The duplication might be functionally relevant but the IBD penetrance is likely to be below 2%. There is currently no indication that the size of the duplication or a combination of genes in this locus has additive or protective effects.

Discussion
We investigated the association between IBD and a diverse range of rare chromosomal structural and numerical abnormalities. Among the numerical chromosomal abnormalities, Turner syndrome was associated with an increased risk of IBD [approximately 2% penetrance], whereas other numerical chromosomal abnormalities had limited evidence for increased susceptibility. Our analysis suggests that patients with Turner syndrome presented with IBD at a significantly younger age than the classical IBD cohort, but typically not at an extreme young age such as very-early-onset IBD. Turner syndrome is a condition in females that results from the complete or partial loss of one X chromosome, altering the gene dosage of up to 15% of genes on the X chromosome that escape inactivation. 51 Complete loss of one X chromosome or partial deletion has pervasive effects on the genome, epigenome, and transcriptome of female individuals, 52 all resulting in changed gene dosages. Individuals with Turner syndrome have a distinguishable RNA expression profile, as well as a distinct autosomal DNA and X-chromosomal methylation profiles compared with karyotypical 46,XY males and 46,XX females. 53 Theoretically, the increased occurrence of IBD in individuals with Turner syndrome could be attributed to the loss of function of monogenic IBD genes on the X chromosome. A possible candidate could be the CD40LG that was identified by Trolle et al. 53 as differentially expressed in Turner syndrome patients. However, the distinctly lower penetrance of IBD in Turner syndrome compared with X-linked monogenic IBD defects in genes like CYBB, FOXP3, and WAS suggests a more complex genetic interplay. 6,[54][55][56] As the loss of one X chromosome or its parts has broad effects on gene expression across the whole genome, development of IBD and other autoimmune disease in patients with Turner syndrome could be due to cumulative gene dosage effects on multiple loci. Alternatively, the findings of co-occurring Turner syndrome and IBD in women with mosaic karyotypes could be biased: a large scale Biobank study showed that patients with mosaic Turner karyotypes have reduced penetrance of comorbidities common in patients with Turner syndrome. 57 Women with mosaic 45,X/46,XX karyotype were only slightly shorter than average, had a normal birth rate and reproductive lifespan, and had no cardiovascular abnormalities. In our data, this karyotype was rare [n = 2 case reports] and other karyotypes were predominant, suggesting that IBD has increased penetrance in non-mosaic Turner syndrome karyotypes. A well-known contributor of chromosomal abnormalities is the hemizygotic, haploinsufficient or compound heterozygous deletion of established monogenic IBD genes such as CTLA4, ICOS, TNFAIP3, and XIAP. In these cases, loss of additional genes might contribute to additional functional defects. Tran et al. 36 discuss a patient with a deletion that encompasses CTLA4 as well as ICOS, presenting with very-early-onset [VEO]-IBD unresponsive to conventional therapy. 36 Biallelic mutations in the ICOS gene cause a deficiency that is characterised by nearly absent class-switched memory B cells; this leads to recurrent infections and autoimmune pathologies including IBD. 58 The development of VEO-IBD in this patient could be evidence of the causative CTLA4 deletion, with  additional effects of the compound ICOS deletion resulting in a more severe IBD phenotype. The only duplication with functional assessment of the gene dosage consequences was the duplication of the IL2RA locus found in a patient with infantile IBD. 43 We identified another patient with a nearly identical duplication. However, our systematic search for additional patients with IL2RA CNV suggests that the duplication of the IL2RA locus is associated with expressivity of infantile IBD that is <2%. Absent IL2RA signalling causes an immune dysregulation, polyendocrinopathy, enteropathy, and X-linked [IPEX]-like condition due to impaired persistence and function of regulatory T cells. 49 Joosse et al. 43 showed that the duplication increases IL2 responsiveness in activated CD4 + T cells, which they postulated could then overstimulate these cells in the antigen-rich environment of the colon and induce inflammation. Our functional data support an effect on effector T cells since those show stronger IL2RA expression. However, the DECIPHER data illustrate that duplication of the IL2RA locus is consistently associated with developmental problems, but not with IBD or other immunemediated disorders. Our screening of multiple cohorts makes a selection bias [patients with a syndromal phenotype might be underrepresented in IBD cohorts] or reporting bias [IBD might be underreported in databases such as DECIPHER] less likely. In light of the very variable duplication size flanking the IL2RA locus from both sides, it is unlikely that microduplications including the IL2RA and IL15RA locus are compensated by a dose effect of protective genes. We cannot exclude that additional genetic variants [such as somatic variants] contribute to the IBD risk in patients with IL2RA locus duplication.
In summary, we found evidence that some numerical chromosomal aberrations like the Turner syndrome might contribute to an IBD phenotype. The role of other numerical abnormalities and structural abnormalities is less clear. Copy number analysis is essential in patients where a monogenic IBD cause needs to be excluded. Our study highlights the complexities involved with analysing gene copy number data: a large systematic analysis of copy number variation in a large set of patients is required to gain better insight into how chromosomal aberrations contribute to IBD.