Genetic predisposition to ductal carcinoma in situ of the breast

Background

Ductal carcinoma in situ (DCIS) is a non-invasive form of breast cancer. It is often associated with invasive ductal carcinoma (IDC), and is considered to be a non-obligate precursor of IDC. It is not clear to what extent these two forms of cancer share low-risk susceptibility loci, or whether there are differences in the strength of association for shared loci.

Methods

To identify genetic polymorphisms that predispose to DCIS, we pooled data from 38 studies comprising 5,067 cases of DCIS, 24,584 cases of IDC and 37,467 controls, all genotyped using the iCOGS chip.

Results

Most (67 %) of the 76 known breast cancer predisposition loci showed an association with DCIS in the same direction as previously reported for invasive breast cancer. Case-only analysis showed no evidence for differences between associations for IDC and DCIS after considering multiple testing.

Analysis by estrogen receptor (ER) status confirmed that loci associated with ER positive IDC were also associated with ER positive DCIS. Analysis of DCIS by grade suggested that two independent SNPs at 11q13.3 near CCND1 were specific to low/intermediate grade DCIS (rs75915166, rs554219). These associations with grade remained after adjusting for ER status and were also found in IDC.

We found no novel DCIS-specific loci at a genome wide significance level of P < 5.0x10^-8.

Conclusion

In conclusion, this study provides the strongest evidence to date of a shared genetic susceptibility for IDC and DCIS. Studies with larger numbers of DCIS are needed to determine if IDC or DCIS specific loci exist.

Ductal carcinoma in situ (DCIS) is a non-obligate precursor of invasive breast cancer including invasive ductal/no special type carcinomas (IDC). Since the introduction of screening mammography there has been a 7-fold increase in reported DCIS incidence in the USA, primarily in postmenopausal women [1], with about 20 % of screen-detected tumors being DCIS [2]. Approximately 45–78 % of all invasive breast cancers are associated with DCIS [3, 4]. It is hypothesized in the majority of these cases that the invasive component has arisen from the DCIS as they generally share the same somatic genetic changes. The proportion of IDC associated with DCIS varies depending on subtype, with luminal and human epidermal growth factor receptor 2 (HER2)-positive IDC having more frequent DCIS (53 % and 63 %, respectively) than invasive basal breast cancers (33 %) [5].

As most DCIS is treated surgically, the natural progression of untreated DCIS is not known. However, in one small study of patients with predominantly low-grade DCIS misdiagnosed as benign breast disease and who received no surgical intervention, 6 out of 13 patients developed ipsilateral invasive carcinoma with mean time to the development of invasive carcinoma being 9.0 years [6]. In two specific DCIS trials in which DCIS was treated with breast-conserving surgery alone with no radiotherapy, long-term follow up shows that up to 30 % of women develop a recurrence (half of which will be DCIS and half invasive cancer) by 10 years [7].

Methods for accurately predicting the behavior of DCIS are poor [8]. Although grade has not been shown to be a good predictor of recurrence many clinicians use this classification to determine the use of radiotherapy following breast-conserving surgery. There is a strong correlation between the grade of the in situ and co-existing invasive components in IDC, suggesting that DCIS does not progress from low through to high grade before becoming invasive [9, 10].

Most non-genetic risk factors for breast cancer have similar associations with DCIS and IDC, supporting the notion that DCIS is a precursor of invasive cancer [11, 12]. There is also evidence from epidemiological studies that there is an inherited predisposition to DCIS. Women with DCIS have been shown to be 2.4 times (95 % CI 0.8, 7.2) more likely to have an affected mother and sister with breast cancer than controls [13]. Furthermore, there is evidence from a study of almost 40,000 women that the familial relative risk of DCIS is greater than that of invasive breast cancer. For women aged 30–49 years with a family history of breast cancer the odds ratio (OR) for developing DCIS was calculated as 2.4 (95 % CI 1.1, 4.9) compared to 1.7 (95 % CI 0.9, 3.4) for invasive cancer. For women aged 50 years and above the risks were slightly reduced, but still higher for DCIS (OR = 2.2, 95 % CI 1.0, 4.2) than invasive disease (OR = 1.5, 95 % CI 1.0, 2.2) [14]. However, this was not confirmed in the Million Women Study, in which the association with family history was similar for DCIS and IDC [12].

A small part of this inherited predisposition is explained by BRCA1/2 mutations, as mutations in these genes are found in a similar proportion of DCIS and invasive breast cancer cases [15]. For low-risk common breast cancer predisposition alleles most of the initial breast cancer association studies have not been powered to identify associations with DCIS, so it is not clear whether all the low-risk susceptibility loci that have been identified are associated with DCIS and what the strength of any associations are.

It is now evident that some low-risk susceptibility loci are associated with different pathological subtypes of breast cancer and support the hypothesis that breast tumor subtypes arise through distinct molecular pathways [16–18]. In order to identify further low-risk susceptibility loci, it will be necessary to look at specific morphological subtypes including DCIS and the cytonuclear grade and estrogen receptor (ER) status of the disease. In this study we analyzed 3,078 cases of pure DCIS collected through the ICICLE study (a study to Investigate the genetics of In situ Carcinoma of the ductaL subtype) and performed a meta-analysis with 2,352 in situ cases collected through the Breast Cancer Association Consortium (BCAC). Our aims were to assess whether any of the known low-risk breast susceptibility alleles have different associations for DCIS and IDC, and to identify if there are any DCIS-specific low-risk alleles.

Ethics statement

All studies were performed with ethical committee approval (listed in acknowledgements) and subjects participated in the studies after providing informed consent.

Study populations

Cases came from ICICLE (MREC 08/H0502/4), a UK study of DCIS, and from 37 studies forming part of the BCAC included in the Collaborative Oncological Gene-Environment Study (COGS) [19] (Additional file 1). The ICICLE study recruited patients from participating centers throughout the UK with the aim of identifying predisposition genes for DCIS. Patients aged 60 years or less at the time of diagnosis, with a current or past history of DCIS (without invasive disease of any histological subtype) were eligible. A total of 3,078 subjects were recruited following identification from local pathology reports in 97 UK hospitals. All cases were genotyped with the iCOGS chip and compared to 5,000 UK controls selected from four UK studies (BBCS 1,231 controls, SBCS 704 controls, UKBGS 370 controls, SEARCH 2,695 controls) participating in BCAC (Additional file 2) and already typed on the iCOGS chip. Controls were randomly selected prior to analysis, and were excluded from case–control comparisons with BCAC cases from the originating study. After excluding individuals based on genotyping quality (see subsection “Genotyping and analysis”) and non-European ancestry, data for the ICICLE study available for analysis included 2,715 subjects with DCIS (cases) and 4,813 controls.

Women with all types of breast cancer were recruited into the BCAC studies. Pathological information in BCAC was collected in the individual studies but was also combined and checked through standardized data control in a central database. A total of 2,352 subjects with DCIS were identified in the central BCAC pathology database (see Additional file 3 for number of cases by study). Controls came from the 37 BCAC studies (37,654 in total).

Genotyping and analysis

After DNA extraction from peripheral blood, ICICLE samples were genotyped on the iCOGS custom Illumina iSelect array (Illumina, San Diego, CA), which contains 211,155 single nucleotide polymorphisms (SNPs), at King’s College London. The remaining cases and controls were genotyped as part of the COGS project described in detail elsewhere [19]. The ICICLE cases were analyzed using the same quality control (QC) criteria as the COGS project. Briefly, genotypes were called using Illumina’s proprietary GenCall algorithm and 10,000 SNPs were manually inspected to verify the algorithm calls. Individuals were excluded if genotypically non-European or not female, or had an overall call rate <95 %. SNPs were excluded with a Gen-Train score <0.4, call rate <95 % (call rate <99 % if minor allele frequency (MAF) was <0.1) and Hardy Weinberg equilibrium (HWE) value of P <10^-7 or evidence of poor clustering on inspection of cluster plots. All SNPs with MAF <0.01 were excluded. A cryptic relatedness analysis of the whole dataset was performed using 46,789 uncorrelated SNPs and led to the exclusion of 28 cases and 18 controls due to relatedness between the ICICLE and BCAC samples (PIHAT >0.1875).

For ICICLE cases and controls, principal component analysis (PCA) was carried out on a subset of 46,789 uncorrelated SNPs and individuals or groups distinct from the main cluster (327 cases and 164 controls) were excluded using the first five principal components (PCs) (Additional file 4). Following removal of outliers, the PCA was repeated and the first five PCs were included as covariates in the analysis.

The adequacy of the case–control matching was evaluated using quantile-quantile plots of test statistics and the inflation factor (λ) calculated using 37,289 uncorrelated SNPs that were not selected by BCAC and were not within one of the four common fine-mapping regions, to minimize selection for SNPs associated with breast cancer (Additional file 5). As the majority of the SNPs on the iCOGS array are associated with breast, ovarian or prostate cancer, the SNPs selected for this analysis were taken from the set of prostate cancer SNPs, with the assumption that these SNPs were more likely to be representative of common SNPs in terms of population structure in our study.

For each SNP, we estimated a per-allele OR and reported corresponding 95 % CI using logistic regression analysis, including the five PCs as covariates, using PLINK v1.07 (http://pngu.mgh.harvard.edu/~purcell/plink/).

Genotyping and analysis of BCAC studies have been described in detail elsewhere [19]. In brief, data were analyzed using the Genotype Library and Utilities (GLU) package to estimate per-allele ORs for each SNP using unconditional logistic regression. All analyses were performed in subjects of European ancestry (determined by PC analyses) and adjusted for study and seven principal components.

Case–control ORs for DCIS cases vs controls from BCAC and ICICLE were combined using inverse variance-weighted fixed-effects meta-analysis, as implemented in METAL [20]. Case-only analyses were also carried out to compare genotype frequencies for (1) ER-positive (ER+) vs ER-negative (ER–) DCIS, (2) high grade DCIS vs low and intermediate grade DCIS, and (3) DCIS vs IDC (see Additional file 3 for number of cases by study), (4) DCIS diagnosis in patients <50 years of age vs DCIS diagnosis in patients ≥50 years, and were used as a test for heterogeneity of ORs by tumor subtype/age (see Additional file 6 for number of cases by group). Only studies with data on both subtypes contributed to case-only analysis comparing these subtypes. Similar case-only analyses were performed for the IDC cases in these studies to assess whether any heterogeneity evident in DCIS also occurred in IDC.

Novel SNPs showing the strongest evidence of association with DCIS (P <6 × 10^-6) in the meta-analysis (after excluding previously reported loci) were genotyped in a phase II analysis at LGC Genomics (LGC, Teddington, UK). The phase II samples consisted of 653 DCIS cases from the ICICLE and Breakthrough Generation Studies and 1,882 controls from the ICICLE study not previously genotyped on the iCOGS chip. All individuals included in the analysis were of European ancestry (self-reported).

For the known breast cancer predisposition loci P <0.00066 was considered statistically significant (with Bonferroni correction for multiple testing on 76 known loci). All of the known breast cancer susceptibility loci were included in the iCOGS chip with the exception of rs2284378 (20q11), which was identified as an ER– breast cancer predisposition SNP after the iCOGS chip was developed [21].

Assessment of grade and ER status

For the ICICLE study, information on cytonuclear grade of DCIS was available for 2,578 cases, mostly from the local histopathology reports. In 200 cases where the grade data were missing from the report but the tumor block was available, an H&E section was cut and the DCIS was graded by the study histopathologist (SEP) according to UK and College of American Pathologists guidelines [22]. Data on grade of DCIS were available from histopathology reports for 828 BCAC cases.

A subset of 81 ICICLE cases, graded in the pathology report and with a tumor block available, were examined to assess the reliability of the cytonuclear grade provided by the pathology reports. In the majority of cases (86.5 %) grade was concordant with the pathology report. Nine cases were re-graded as low/intermediate grade and two cases as high grade. As the study pathologist re-graded the samples on a single H&E section, rather than all the blocks from an individual case, and in some cases on re-excision specimens with residual disease rather than the original excision specimen, the grade reported in the pathology report, if available, was used for the purposes of this study.

ER status from local histopathology reports was available for 1,086 ICICLE cases. For the remaining 781 ICICLE cases where the tumor block was available, immunohistochemistry was performed on 3-μM sections, which were incubated at 60 °C for 1 h prior to automated staining using the VENTANA®. Estrogen receptor staining was carried out using CONFIRM™ anti-estrogen receptor (SP1) rabbit monoclonal primary antibody (Catalog number 790-4324) with no variation to the recommended protocol. ER staining was scored by three independent reviewers (CP, VS, DLe) using the Allred method, and any discrepancies were reviewed by the study histopathologist (SEP). DCIS with an Allred score ≥3 was considered ER+ and DCIS with scores of 0–2 (approximately equivalent to <1 % of nuclei) was regarded as ER–. ER status was available on 965 cases from BCAC (Additional file 6).

Assessment of known breast cancer susceptibility loci for association with DCIS

For the majority of known loci (n = 46) the risk allele for invasive breast cancer is the minor allele. For the ORs presented here the reference allele was set as the non-risk allele to make it clear whether the association with DCIS was in the same direction as previously published for invasive breast cancer. Thus, ORs for DCIS will be >1 if in the same direction as invasive disease and <1 if in the opposite direction.

Of the 76 known common breast cancer susceptibility loci genotyped on the iCOGS array, 51 were associated with DCIS (P <0.05), with the effect in the same direction as previously reported in IDC (Fig. 1 and Additional file 7). Sixteen SNPs were significantly associated with DCIS (P <0.00066) with three being genome-wide significant (P <5 × 10^-8, Table 1). The strongest associations were with for loci in FGFR2 (rs2981579: OR 1.29, 95 % CI 1.24, 1.35; P = 9.0 × 10^-30) and TOX3 (rs3803662: OR 1.15, 95 % CI 1.1, 1.21; P = 1.7 × 10^-8).

Known breast cancer predisposition loci for ductal carcinoma in situ plotted according to the risk allele for invasive disease. Odds ratios >1 indicate that the association is in the same direction as previously published for invasive breast cancer

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The case-only analysis (DCIS vs IDC) confirmed the shared genetic susceptibility between DCIS and IDC as none of the heterogeneity P values (P-Het) were significant after Bonferroni adjustment for 76 SNPs (Additional file 7). The case-only analysis (DCIS diagnosed at <50 years vs ≥50 years of age) revealed one SNP (rs527616, 18q11.2) that was significantly associated with DCIS in younger women (P-Het_<50/≥50 = 0.0003) even though the overall P value for DCIS was not statistically significant after Bonferroni correction (OR 1.05, 95 % CI 1.01, 1.11; P = 0.020) (Additional file 8).

Assessment of known breast cancer susceptibility loci for association with DCIS by ER status

Following immunohistochemistry for ER in the ICICLE study samples, 1,484 cases (54 %) were classified as ER+ and 383 (14 %) as ER–. The ER data on BCAC DCIS were less complete with 664 (28 %) ER+, 301 (13 %) ER– and 1,387 cases (59 %) of unknown ER status (Additional file 6). Analysis by ER status confirmed that loci associated with ER+ IDC were also associated with ER+ DCIS (Fig. 2 and Additional file 9). These similarities were less clear for ER– DCIS and ER– IDC but this may be due to small numbers of ER– DCIS cases. A case-only analysis of ER+ vs ER– DCIS was not performed due to the small numbers of ER– cases.

Known breast cancer predisposition loci for estrogen receptor-positive (ER+) (black lines) and ER– ductal carcinoma in situ (gray lines). Due to the large number of single nucleotide polymorphisms (SNPs), for better visual representation the plot is split into two different sections (a and b) with a descending order of effect size for the ER+ group. OR odds ratio

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Assessment of known breast cancer susceptibility loci for association with DCIS by grade

Grade data were available for 95 % of ICICLE DCIS cases; 1,635 (60 %) were of high cytonuclear grade and 943 (35 %) of low/intermediate grade. The grade data on the BCAC DCIS were less complete with data only available for 35 % of cases: 306 (13 %) high grade and 522 (22 %) low/intermediate grade cases (Additional file 6). Case–control analysis was performed separately on the low/intermediate and high grade subsets and a case-only analysis of low/intermediate grade vs high grade DCIS was performed to assess whether any of these loci were grade-specific.

Analysis of DCIS by grade revealed that although the majority of SNPs predispose to all grades of DCIS, some are grade-specific (Additional files 10 and 11). The two SNPs close to CCND1 were strongly associated with low/intermediate grade DCIS (rs75915166, OR 1.36, 95 % CI 1.17, 1.59; P = 7.2 × 10^-5; rs554219, OR 1.32, 95 % CI 1.18, 1.48; P = 8.2 × 10^-7) and there was no association with high grade DCIS (Table 2). Case-only analysis confirmed that these loci were low/intermediate grade-specific (rs75915166, P-Het_{low/highgrade} = 0.00014; rs554219, P-Het_{low/highgrade} = 0.00013) and this was independent of ER status (adjusted for ER status rs75915166, P = 0.0050; rs554219, P = 0.019).

A similar-case-only analysis of IDC by grade confirmed that the two SNPs on 11q13.3 close to CCND1 were also invasive grade 1/2-specific in IDC (rs75915166, OR 1.42, P = 1.7 × 10^-30, P-Het = 2.8 × 10^-10; rs554219, OR 1.39, P = 4.7 × 10^-49, P-Het = 1.3 × 10^-17) and again were independent of ER status (P = 1.3 × 10^-6, P = 1.6 × 10^-6, respectively) (Additional file 12). In addition, other grade-specific loci were identified including three (rs2363956, rs8170 and rs10069690) specific to grade 3 invasive disease (Additional file 13).

rs10941679, 5p12 were borderline associated with low/intermediate grade DCIS (OR 1.26, P = 2.1 × 10^-7, P-Het_{low/highgrade} = 0.0033). This locus has previously been shown to be associated with low grade progesterone receptor (PR) + IDC [23]. There was no evidence of any high grade DCIS specific loci (Additional file 11).

Search for new DCIS predisposition loci

All SNPs that were genome-wide significant (P <5 × 10^-8) in the meta-analysis were correlated with one of the known breast cancer predisposition loci. There were three SNPs that were not correlated with known loci at P <6 × 10^-6 (Table 3), all with very little evidence of an association with IDC.

Of these novel SNPs, rs12631593, 3p14.2, (an intronic variant in FHIT, chr3: 60726844) was the most strongly associated with DCIS (OR 1.21, 95 % CI 1.13, 1.29; P = 5.5 × 10^-8). This SNP showed little association with IDC (OR 1.01, 95 % CI 0.97, 1.05; P = 0.54) and this was supported by the case-only analysis (P-Het_DCIS/IDC = 0.0048).

The other loci were on 22q13.2, rs73179023 (DCIS only: OR 0.85, 95 % CI 0.79, 0.90; P = 1.1 × 10^-6; IDC only: OR 0.97, 95 % CI 0.93, 1.00; P = 0.060, P-Het_DCIS/IDC = 0.0099) and 7q21.3, rs13236351 (DCIS only: OR 1.30, 95 % CI 1.16, 1.46; P = 5.7 × 10^-6; IDC only: OR 1.05, 95 % CI 0.99, 1.13; P = 0.13, P-Het_DCIS/IDC = 0.17).

These SNPs were genotyped in a validation study including a further 653 DCIS cases and 1,882 controls, however, for all three loci there was no evidence of an association (for rs12631593, rs13236351, and rs73179023, P = 0.49, 0.61, and 0.57, respectively) and none were genome wide significant following a meta-analysis of all data (P = 7.8 × 10^-7, 2.9 × 10^-5, and 1.7 × 10^-6 respectively) (Table 3).

This study provides the strongest evidence to date for a shared genetic susceptibility between DCIS and IDC, based on 5,067 cases with pure DCIS (no invasive disease) and 24,670 cases with IDC. It differs from previous BCAC analyses of DCIS, as it has included an additional 3,078 DCIS cases, excluded all cases of pure LCIS and has also compared DCIS to IDC rather than all invasive disease.

An important finding of this study is the lack of DCIS/IDC-specific loci among the known breast cancer predisposition loci. Of the five breast cancer predisposition alleles originally reported by Easton et al. [24], three were shown to be associated with in situ (998 cases of DCIS and LCIS) disease (rs2981582-FGFR2, rs3803662-TOX3, rs889312-MAP3K1) with rs889312 showing a stronger association with DCIS (P-trend 0.007, per allele OR 1.30 for DCIS, per allele OR 1.13 for invasive disease). However, this finding of potential DCIS-specific loci was not confirmed in the Million women study which found no differential association with DCIS vs IDC for twelve breast cancer susceptibility loci, including rs889312, although their sample size was smaller (873 DCIS and 4,959 IDC) [12]. In the recent BCAC COGS analysis all 41 novel SNPs identified on the iCOGS chip had comparable ORs for invasive and in situ disease (based on data from 2,335 in situ, and 42,118 invasive cases), with the exceptions of rs12493607 (TGFBR2), and rs3903072 (11q13.1), for which associations seemed to be restricted to invasive disease [19]; however, we found no evidence of an IDC-specific association with these loci after correcting for multiple testing. A recent study investigating the association between 39 of the known breast cancer predisposition loci and breast cancer in situ (BCIS) suggested that rs1011970 (9p21.3, CDKN2BAS) had a stronger association with BCIS than invasive breast cancer (BC), P-Het_BCIS/BC = 0.0065. This trend remained in a DCIS vs BC analysis (P-Het_DCIS/BC = 0.021) [25]. Our data, however, do not support this finding (DCIS OR 1.08, 95 % CI 1.02, 1.14; P = 0.011; IDC OR 1.05, 95 % CI 1.0, 1.09; P = 0.0025, P-Het_DCIS/IDC = 0.33).

We have also shown for the first time that seven of the known invasive breast cancer predisposition loci not previously shown to be associated with DCIS have comparable ORs for IDC and DCIS: rs4973768 (SLC4A7), rs3821902 (ATXN7) [26], rs10995190 (ZNF365), rs554219 (CCND1), rs3757318 and rs2046210 (ESR1).

This lack of DCIS/IDC-specific loci is in contrast to our previous study of lobular cancer in which we showed that there are loci that are specific to invasive lobular cancer (ILC), showing no association with lobular carcinoma in situ (LCIS) and there was also a suggestion of LCIS-specific loci [16]. When we compare the DCIS data presented here to our previous LCIS analyses it reveals that there is some overlap between loci that are associated with ER+ DCIS and LCIS (Fig. 3 and Additional file 14). However, there are also some differences: rs6678914, LGR6 and rs865686, 9q31.2 are strongly associated with LCIS but there is little evidence of association with ER+ DCIS (P-Het_DCIS/LCIS = 7.4 × 10^-5 and 6.6 × 10^-4, respectively). We have also previously shown that rs11249433, 1p11.2 and rs11977670, 7q34 have a stronger association with invasive lobular cancer than IDC [16]. These loci were only weakly associated with LCIS and were not associated with ER+ DCIS in this analysis.

Known breast cancer predisposition loci for estrogen receptor-positive (ER+) (black) ductal carcinoma in situ and lobular carcinoma in situ (gray). Due to the large number of single nucleotide polymorphisms (SNPs), for better visual representation, the plot is split into two different sections (a and b) with a descending order of effect size for the ER+ group. OR odds ratio

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Most association studies of invasive breast cancer involve subgroup analyses based on ER status. In contrast to invasive breast cancer, ER status in DCIS is not routinely assessed in all centers despite evidence from the NSABP B-24 trial of benefit from endocrine therapy in ER+ DCIS [7]. A national audit of DCIS in the UK revealed that ER status was assessed in only 50 % of DCIS cases and ER positivity in low and intermediate grade DCIS was significantly more common than in high grade DCIS (P <0.001) (ER+ high grade 69 %, intermediate grade 94 %, low grade 99 %) [27]. In order to overcome this issue we performed ER immunohistochemistry on the samples from ICICLE for which ER status was unknown. However, there was still a large amount of missing data on ER status in the BCAC cases, resulting in only 684 ER– DCIS cases being available for analysis, making it difficult to draw definitive conclusions about ER– DCIS. In essence the findings are similar to invasive breast cancer, with ER– and ER+ DCIS having different genetic susceptibility profiles and ER+ DCIS having a very similar profile to ER+ IDC.

Cytonuclear grade of DCIS is used by many clinicians to select those cases most likely to benefit from radiotherapy despite the fact that grade has not been shown to be a good predictor of recurrence. In the UK audit of DCIS, grade data were available for 99 % of DCIS cases, with 59 % classified as high grade, 29 % as intermediate and 11 % as low grade [27]. Similarly, in our study data on grade were available for 95 % of cases in ICICLE. In invasive disease only a minority of predisposition loci have been shown to be grade specific; rs2981582 (FGFR2) and rs13281615 (8q24) [28, 29] and rs10941679 (5p12) [23]. We have shown that analysis of DCIS by grade reveals other known loci that are grade specific. The loci with the strongest association with grade were SNPs on 11q13, which had a stronger association with low/intermediate grade DCIS and IDC than high grade lesions. The finding of a strong association with low and intermediate grade ductal carcinomas that is independent of ER status in both DCIS and IDC for these loci is novel. rs614367 was the first locus on 11q13 shown to be associated with invasive breast cancer [30]. Fine mapping of the region subsequently identified two independent signals (rs554219 and rs78540526, r ² = 0.38), which are the loci reported in this analysis. Functional analyses demonstrated that the risk variants modify enhancer and silencer elements, with the likely target gene being CCND1 [31].

A study of 150 cases of subsequent breast cancer (invasive and in situ) after DCIS observed significant association for both grade and ER status between the index DCIS and the subsequent breast cancer (whether ipsilateral or contralateral), suggesting that women with DCIS are at risk of developing subsequent breast cancers of a similar phenotype [32]. This finding supports the genetic predisposition data presented here, with ER and grade-specific loci in DCIS having similar specificity in IDC.

Although we did not identify any novel loci that reached genome wide significance, we did identify three potential novel DCIS predisposition loci, two of which were DCIS-specific (rs12631593, rs73179023), and therefore need further investigation in other cohorts of DCIS. As at least 45 % of patients with IDC have associated DCIS present at diagnosis consistent with direct precursor behavior, it may seem biologically implausible that an SNP predisposes to DCIS but is not associated with IDC. However, it is possible that there is a subset of patients with DCIS with very low probability of progression. If the finding of DCIS-specific predisposition loci were confirmed in other studies, identifying such a subset of patients with low-risk DCIS would be clinically valuable.

In conclusion this is the largest study to assess genetic predisposition in DCIS and shows that the majority of invasive breast cancer predisposition loci also predispose to DCIS. It highlights that, as for invasive disease, different SNPs predispose to ER+ and ER– DCIS. In addition it shows the importance of grade in both DCIS and IDC.

ABCS:

Amsterdam Breast Cancer Study

BBBC:

Bavarian Breast Cancer Cases and Controls

BBCS:

British Breast Cancer Study

BC:

breast cancer

BCAC:

Breast Cancer Association Consortium

BCIS:

breast carcinoma in situ

CI:

confidence interval

COGS:

Collaborative Oncological Gene-Environment Study

DCIS:

ductal carcinoma in situ

ER:

Estrogen receptor

H&E:

hematoxylin and eosin

HWE:

Hardy Weinberg equilibrium

ICICLE:

study to investigate the genetics of in situ carcinoma of the ductal subtype

IDC:

invasive ductal carcinoma

LCIS:

lobular carcinoma in situ

MAF:

minor allele frequency

OR:

odds ratio

PCA:

principal component analysis

P-Het :

P value for heterogeneity

SNP:

single nucleotide polymorphism

We thank all the individuals who took part in these studies and all the researchers, clinicians, technicians and administrative staff who have enabled this work to be carried out. This study would not have been possible without the contributions of the following: Andrew Berchuck (OCAC), Rosalind A. Eeles, Ali Amin Al Olama, Zsofia Kote-Jarai, Sara Benlloch (PRACTICAL), Antonis Antoniou, Lesley McGuffog, Ken Offit (CIMBA), Andrew Lee, and Ed Dicks, Craig Luccarini and the staff of the Centre for Genetic Epidemiology Laboratory, the staff of the CNIO genotyping unit, Francois Bacot, Sylvie LaBoissière and Frederic Robidoux and the staff of the McGill University and Génome Québec Innovation Centre, Sune F. Nielsen, Borge G. Nordestgaard, and the staff of the Copenhagen DNA Laboratory, and Julie M. Cunningham, Sharon A. Windebank, Christopher A. Hilker, Jeffrey Meyer and the staff of Mayo Clinic Genotyping Core Facility. In particular, we thank: Maria Troy (ICICLE); the Swedish Medical Research Council (pKARMA); Siranoush Manoukian, Bernard Peissel, Daniela Zaffaroni and Jacopo Azzollini of the Fondazione IRCCS Istituto Nazionale dei Tumori (INT); Bernado Bonanni, Monica Barile and Irene Feroce of the Istituto Europeo di Oncologia (IEO), and the personnel of the Cogentech Cancer Genetic Test Laboratory (MBCSG); Emily Hallberg for contributions to sample and phenotype management (MCBCS); the SEARCH and EPIC teams, Kirsimari Aaltonen, Karl von Smitten, Sofia Khan, Tuomas Heikkinen, Irja Erkkilä (HEBCS); Petra Seibold, Dieter Flesch-Janys, Judith Heinz, Nadia Obi, Alina Vrieling, Sabine Behrens, Ursula Eilber, Muhabbet Celik, Til Olchers and Stefan Nickels (MARIE); Eileen Williams, Elaine Ryder-Mills, Kara Sargus (BBCS); Heather Thorne, Eveline Niedermayr, all the kConFab research nurses and staff, the heads and staff of the Family Cancer Clinics, and the Clinical Follow Up Study (which has received funding from the NHMRC, the National Breast Cancer Foundation, Cancer Australia, and the National Institute of Health (USA)) for their contributions to this resource, and the many families who contribute to kConFab; members of the Data Bank and Biorepository (DBBR) at Roswell Park Cancer Institute (RPCI) for providing biospecimens; staff and participants of the Copenhagen General Population Study and for the excellent technical assistance of Dorthe Uldall Andersen, Maria Birna Arnadottir, Anne Bank, Dorthe Kjeldgård Hansen (CGPS); Sten Cornelissen, Richard van Hien, Linde Braaf, Frans Hogervorst, Senno Verhoef, Laura van ‘t Veer, Emiel Rutgers, C Ellen van der Schoot, Femke Atsma (ABCS); Sue Higham, Helen Cramp, Ian Brock, Sabapathy Balasubramanian, Malcolm W.R. Reed and Dan Connley (SBCS); Breakthrough Breast Cancer and the Institute of Cancer Research for support and funding of the Breakthrough Generations Study, and the study participants, study staff, and the doctors, nurses and other health care providers and health information sources who have contributed to the study and acknowledge NHS funding to the Royal Marsden/ICR NIHR Biomedical Research Centre; Gilian Peuteman, Dominiek Smeets, Thomas Van Brussel and Kathleen Corthouts (LMBC); Niall McInerney, Gabrielle Colleran, Andrew Rowan, Angela Jones (BIGGS); Petra Bos, Jannet Blom, Ellen Crepin, Elisabeth Huijskens, Annette Heemskerk, the Erasmus MC Family Cancer Clinic (RBCS); Peter Bugert, Medical Faculty Mannheim (BSUCH); Eija Myöhänen, Helena Kemiläinen (KBCP); E. Krol-Warmerdam, and J. Blom for patient accrual, administering questionnaires, and managing clinical information, the LUMC survival data were retrieved from the Leiden hospital-based cancer registry system (ONCDOC) with the help of Dr. J. Molenaar (ORIGO); Guillermo Pita, Charo Alonso, Daniel Herrero, Nuria Álvarez, Pilar Zamora, Primitiva Menendez, the Human Genotyping-CEGEN Unit (CNIO); Teresa Selander, Nayana Weerasooriya (OFBCR); Arja Jukkola-Vuorinen, Mervi Grip, Saila Kauppila; Kari Mononen and Meeri Otsukka (OBCS); Hartwig Ziegler, Sonja Wolf, Christa Stegmaier, Katja Butterbach, Stefanie Engert, Heide Hellebrand, Sandra Kröber, Peter Hillemanns, Hans Christiansen and Johann H. Karstens (HMBCS); Maggie Angelakos, Judi Maskiell, Gillian Dite (ABCFS); The GENICA Network: Dr. Margarete Fischer-Bosch-Institute of Clinical Pharmacology, Stuttgart, and University of Tübingen, Germany [HB, Wing-Yee Lo, Christina Justenhoven], German Cancer Consortium (DKTK) and German Cancer Research Center (DKFZ) (HB), Department of Internal Medicine, Evangelische Kliniken Bonn gGmbH, Johanniter Krankenhaus, Bonn, Germany (Yon-Dschun Ko, Christian Baisch), Institute of Pathology, University of Bonn, Germany (Hans-Peter Fischer), Molecular Genetics of Breast Cancer, Deutsches Krebsforschungszentrum (DKFZ), Heidelberg, Germany (Ute Hamann), Institute for Prevention and Occupational Medicine of the German Social Accident Insurance, Institute of the Ruhr University Bochum (IPA), Bochum, Germany (TB, Beate Pesch, Sylvia Rabstein, Anne Lotz); and Institute of Occupational Medicine and Maritime Medicine, University Medical Center Hamburg-Eppendorf, Germany (Volker Harth); Martine Tranchant (CHU de Québec Research Center), Marie-France Valois, Annie Turgeon and Lea Heguy (McGill University Health Center, Royal Victoria Hospital; McGill University) for DNA extraction, sample management and skillful technical assistance. JS is Chairholder of the Canada Research Chair in Oncogenetics (MTLGEBCS); Dr. Kristine Kleivi, PhD (K.G. Jebsen Centre for Breast Cancer Research, Institute of Clinical Medicine, University of Oslo, Oslo, Norway and Department of Research, Vestre Viken, Drammen, Norway), Dr. Lars Ottestad, MD (Department of Genetics, Institute for Cancer Research, Oslo University Hospital Radiumhospitalet, Oslo, Norway), Prof. Em. Rolf Kåresen, MD (Department of Oncology, Oslo University Hospital and Faculty of Medicine, University of Oslo, Oslo, Norway), Dr. Anita Langerød, PhD (Department of Genetics, Institute for Cancer Research, Oslo University Hospital Radiumhospitalet, Oslo, Norway), Dr. Ellen Schlichting, MD (Department for Breast and Endocrine Surgery, Oslo University Hospital Ullevaal, Oslo, Norway), Dr. Marit Muri Holmen, MD (Department of Radiology and Nuclear Medicine, Oslo University Hospital, Oslo, Norway), Prof. Toril Sauer, MD (Department of Pathology at Akershus University hospital, Lørenskog, Norway), Dr. Vilde Haakensen, MD (Department of Genetics, Institute for Cancer Research, Oslo University Hospital Radiumhospitalet, Oslo, Norway), Dr. Olav Engebråten, MD (Institute for Clinical Medicine, Faculty of Medicine, University of Oslo and Department of Oncology, Oslo University Hospital, Oslo, Norway), Prof. Bjørn Naume, MD (Division of Cancer Medicine and Radiotherapy, Department of Oncology, Oslo University Hospital Radiumhospitalet, Oslo, Norway), Dr. Cecile E. Kiserud, MD (National Advisory Unit on Late Effects after Cancer Treatment, Department of Oncology, Oslo University Hospital, Oslo, Norway and Department of Oncology, Oslo University Hospital, Oslo, Norway), Dr. Kristin V. Reinertsen, MD (National Advisory Unit on Late Effects after Cancer Treatment, Department of Oncology, Oslo University Hospital, Oslo, Norway and Department of Oncology, Oslo University Hospital, Oslo, Norway), Assoc. Prof. Åslaug Helland, MD (Department of Genetics, Institute for Cancer Research and Department of Oncology, Oslo University Hospital Radiumhospitalet, Oslo, Norway), Dr. Margit Riis, MD (Dept of Breast- and Endocrine Surgery, Oslo University Hospital, Ullevål, Oslo, Norway), Dr. Ida Bukholm, MD (Department of Breast-Endocrine Surgery, Akershus University Hospital, Oslo, Norway and Department of Oncology, Division of Cancer Medicine, Surgery and Transplantation, Oslo University Hospital, Oslo, Norway), Prof. Per Eystein Lønning, MD (Section of Oncology, Institute of Medicine, University of Bergen and Department of Oncology, Haukeland University Hospital, Bergen, Norway), Dr Silje Nord, PhD (Department of Genetics, Institute for Cancer Research, Oslo University Hospital Radiumhospitalet, Oslo, Norway) and Grethe I. Grenaker Alnæs, M.Sc. (Department of Genetics, Institute for Cancer Research, Oslo University Hospital Radiumhospitalet, Oslo, Norway) (NBCS); Louise Brinton, Mark Sherman, Neonila Szeszenia-Dabrowska, Beata Peplonska, Witold Zatonski, Pei Chao, and Michael Stagner (PBCS). kConFab/AOCS Investigators (Georgia.Trench@qimrberghofer.edu.au) Peter MacCallum Cancer Center, The University of Melbourne, Melbourne, Australia.

Funding was as follows: ICICLE genotyping was funded by the Breast Cancer Now (http://breastcancernow.org/), and sample and data collection by Cancer Research UK. Core funding came from the National Institute for Health Research (NIHR) Biomedical Research Centre at Guy’s and St. Thomas’ NHS Foundation Trust and King’s College London and the Wellcome Trust Centre for Human Genetics (provided by the Wellcome Trust, 090532/Z/09/Z). The views expressed are those of the author(s) and not necessarily those of the NHS, NIHR or the Department of Health. BCAC is funded by Cancer Research UK (C1287/A10118, C1287/A12014) and by the European Community’s Seventh Framework Programme under grant agreement number 223175 (grant number HEALTH-F2-2009-223175) (COGS). Funding for the iCOGS infrastructure came from: the European Community’s Seventh Framework Programme under grant agreement number 223175 (HEALTH-F2-2009-223175) (COGS), Cancer Research UK (C1287/A10118, C1287/A 10710, C12292/A11174, C1281/A12014, C5047/A8384, C5047/A15007, C5047/A10692, C8197/A16565), the National Institutes of Health (CA128978) and Post-Cancer GWAS initiative (1U19 CA148537, 1U19 CA148065 and 1U19 CA148112 - the GAME-ON initiative), the Department of Defense (W81XWH-10-1-0341), the Canadian Institutes of Health Research (CIHR) for the CIHR Team in Familial Risks of Breast Cancer, Komen Foundation for the Cure, the Breast Cancer Research Foundation, and the Ovarian Cancer Research Fund. pKARMA was supported by Märit and Hans Rausings Initiative Against Breast Cancer. MCBCS was supported by the NIH grants CA128978, CA116167, CA176785 an NIH Specialized Program of Research Excellence (SPORE) in Breast Cancer (CA116201), and the Breast Cancer Research Foundation and a generous gift from the David F. and Margaret T. Grohne Family Foundation. SEARCH is funded by a programme grant from Cancer Research UK (C490/A10124) and supported by the UK National Institute for Health Research Biomedical Research Centre at the University of Cambridge. HEBCS was financially supported by the Helsinki University Central Hospital Research Fund, Academy of Finland (266528), the Finnish Cancer Society, The Nordic Cancer Union and the Sigrid Juselius Foundation. The MARIE study was supported by the Deutsche Krebshilfe e.V. (70-2892-BR I, 106332, 108253, 108419), the Hamburg Cancer Society, the German Cancer Research Centre (DKFZ) and the Federal Ministry of Education and Research (BMBF) Germany (01KH0402). The CECILE study was funded by Fondation de France, Institut National du Cancer (INCa), Ligue Nationale contre le Cancer, Ligue contre le Cancer Grand Ouest, Agence Nationale de Sécurité Sanitaire (ANSES), Agence Nationale de la Recherche (ANR). BBCS is funded by Cancer Research UK and Breakthrough Breast Cancer and acknowledges NHS funding to the NIHR Biomedical Research Centre, and the National Cancer Research Network (NCRN). kConFab is supported by a grant from the National Breast Cancer Foundation, and previously by the National Health and Medical Research Council (NHMRC), the Queensland Cancer Fund, the Cancer Councils of New South Wales, Victoria, Tasmania and South Australia, and the Cancer Foundation of Western Australia. Financial support for the AOCS was provided by the United States Army Medical Research and Materiel Command (DAMD17-01-1-0729), Cancer Council Victoria, Queensland Cancer Fund, Cancer Council New South Wales, Cancer Council South Australia, The Cancer Foundation of Western Australia, Cancer Council Tasmania and the National Health and Medical Research Council of Australia (NHMRC; 400413, 400281, 199600). GCT and PW are supported by the NHMRC. RB was a Cancer Institute NSW Clinical Research Fellow. TNBCC (RPCI) was supported by a Specialized Program of Research Excellence (SPORE) in Breast Cancer (CA116201), a grant from the Breast Cancer Research Foundation, a generous gift from the David F. and Margaret T. Grohne Family Foundation, and a Cancer Center Support Grant Shared Resource (P30 CA016056-32) for RPCI. The CGPS was supported by the Chief Physician Johan Boserup and Lise Boserup Fund, the Danish Medical Research Council and Herlev Hospital. The ABCS study was supported by the Dutch Cancer Society (grants NKI 2007-3839; 2009 4363); BBMRI-NL, which is a Research Infrastructure financed by the Dutch government (NWO 184.021.007); and the Dutch National Genomics Initiative. The SBCS was supported by Yorkshire Cancer Research S295, S299, S305PA and Sheffield Experimental Cancer Medicine Centre. The UKBGS is funded by Breast Cancer Now and the Institute of Cancer Research (ICR), London. ICR acknowledges NHS funding to the NIHR Biomedical Research Centre. LMBC is supported by the Stichting tegen Kanker (232-2008 and 196-2010). Diether Lambrechts is supported by the FWO and the KULPFV/10/016-SymBioSysII. RBCS was funded by the Dutch Cancer Society (DDHK 2004-3124, DDHK 2009-4318). The BSUCH study was supported by the Dietmar-Hopp Foundation, the Helmholtz Society and the German Cancer Research Center (DKFZ). MBCSG is supported by grants from the Italian Association for Cancer Research (AIRC) and by funds from the Italian citizens who allocated the 5/1000 share of their tax payment in support of the Fondazione IRCCS Istituto Nazionale Tumori, according to Italian laws (INT-Institutional strategic projects “5x1000”). KBCP was financially supported by the special Government Funding (EVO) of Kuopio University Hospital grants, Cancer Fund of North Savo, the Finnish Cancer Organizations, and by the strategic funding of the University of Eastern Finland. MEC was support by NIH grants CA63464, CA54281, CA098758 and CA132839. The ORIGO study was supported by the Dutch Cancer Society (RUL 1997-1505) and the Biobanking and Biomolecular Resources Research Infrastructure (BBMRI-NL CP16) The CNIO-BCS was supported by the Instituto de Salud Carlos III, the Red Temática de Investigación Cooperativa en Cáncer and grants from the Asociación Española Contra el Cáncer and the Fondo de Investigación Sanitario (PI11/00923 and PI12/00070). The Ontario Familial Breast Cancer Registry (OFBCR) was supported by grant UM1 CA164920 from the National Cancer Institute (USA). The content of this manuscript does not necessarily reflect the views or policies of the National Cancer Institute or any of the collaborating centers in the Breast Cancer Family Registry (BCFR), nor does mention of trade names, commercial products, or organizations imply endorsement by the USA Government or the BCFR. The SZBCS was supported by Grant PBZ_KBN_122/P05/2004 The work of the BBCC was partly funded by ELAN-Fond of the University Hospital of Erlangen. OBCS was supported by the Academy of Finland (grant number 250083, 122715 and Center of Excellence grant number 284605), the Finnish Cancer Foundation, the Sigrid Juselius Foundation, the University of Oulu, the University of Oulu Support Foundation and the special Governmental EVO funds for Oulu University Hospital-based research activities. The ESTHER study was supported by a grant from the Baden Württemberg Ministry of Science, Research and Arts. Additional cases were recruited in the context of the VERDI study, which was supported by a grant from the German Cancer Aid (Deutsche Krebshilfe). The GC-HBOC (German Consortium of Hereditary Breast and Ovarian Cancer) is supported by the German Cancer Aid (grant no 110837, coordinator: Rita K. Schmutzler). SKKDKFZS is supported by the DKFZ. HMBCS was supported by a grant from the Friends of Hannover Medical School and by the Rudolf Bartling Foundation. The Australian Breast Cancer Family Study (ABCFS) was supported by grant UM1 CA164920 from the National Cancer Institute (USA). The content of this manuscript does not necessarily reflect the views or policies of the National Cancer Institute or any of the collaborating centers in the Breast Cancer Family Registry (BCFR), nor does mention of trade names, commercial products, or organizations imply endorsement by the USA Government or the BCFR. The ABCFS is also supported by the National Health and Medical Research Council of Australia, the New South Wales Cancer Council, the Victorian Health Promotion Foundation (Australia) and the Victorian Breast Cancer Research Consortium. JLH is a National Health and Medical Research Council (NHMRC) Australia Fellow and a Victorian Breast Cancer Research Consortium Group Leader. MCS is a NHMRC Senior Research Fellow and a Victorian Breast Cancer Research Consortium Group Leader. GENICA was funded by the Federal Ministry of Education and Research (BMBF) Germany grants 01KW9975/5, 01KW9976/8, 01KW9977/0 and 01KW0114, the Robert Bosch Foundation, Stuttgart, Deutsches Krebsforschungszentrum (DKFZ), Heidelberg, the Institute for Prevention and Occupational Medicine of the German Social Accident Insurance, Institute of the Ruhr University Bochum (IPA), Bochum, and the Department of Internal Medicine, Evangelische Kliniken Bonn gGmbH, Johanniter Krankenhaus, Bonn, Germany. Financial support for KARBAC was provided through the regional agreement on medical training and clinical research (ALF) between Stockholm County Council and Karolinska Institutet, the Swedish Cancer Society, The Gustav V Jubilee foundation and and Bert von Kantzows foundation. MCCS cohort recruitment was funded by VicHealth and Cancer Council Victoria. The MCCS was further supported by Australian NHMRC grants 209057, 251553 and 504711 and by infrastructure provided by Cancer Council Victoria. Cases and their vital status were ascertained through the Victorian Cancer Registry (VCR). The work of MTLGEBCS was supported by the Quebec Breast Cancer Foundation, the Canadian Institutes of Health Research for the CIHR Team in Familial Risks of Breast Cancer programme - grant number CRN-87521 and the Ministry of Economic Development, Innovation and Export Trade - grant number PSR-SIIRI-701. The NBCS has received funding from the K.G. Jebsen Centre for Breast Cancer Research; the Research Council of Norway grant 193387/V50 (to A-L Børresen-Dale and V.N. Kristensen) and grant 193387/H10 (to A-L Børresen-Dale and V.N. Kristensen), South Eastern Norway Health Authority (grant 39346 to A-L Børresen-Dale) and the Norwegian Cancer Society (to A-L Børresen-Dale and V.N. Kristensen). PBCS was funded by Intramural Research Funds of the National Cancer Institute, Department of Health and Human Services, USA. The SASBAC study was supported by funding from the Agency for Science, Technology and Research of Singapore (A*STAR), the US National Institute of Health (NIH) and the Susan G. Komen Breast Cancer Foundation. Ethical approval bodies for BCAC studies are listed below.

Funding

ICICLE genotyping was funded by the Breast Cancer Now (http://breastcancernow.org/), and sample and data collection.

Authors and Affiliations

1. Research Oncology, Guy’s Hospital, King’s College London, London, UK

   Christos Petridis, Vandna Shah, Dina Levi, Sarah E. Pinder & Elinor J. Sawyer

2. Medical and Molecular Genetics, Guy’s Hospital, King’s College London, London, UK

   Christos Petridis

3. Division of Genetics and Epidemiology, The Institute of Cancer Research, London, UK

   Mark N. Brook, Anthony Swerdlow, Minouk J. Schoemaker & Montserrat García-Closas

4. Centre for Molecular Oncology, Barts Cancer Institute, Queen Mary University of London, London, UK

   Kelly Kohut, Patricia Gorman, Michele Caneppele & Rebecca Roylance

5. Biomedical Research Centre, King’s College London, Guy’s Hospital, London, UK

   Efterpi Papouli

6. The Breast Cancer Now Toby Robins Research Centre, The Institute of Cancer Research, London, UK

   Nick Orr

7. Sheffield Cancer Research, Department of Oncology, University of Sheffield, Sheffield, UK

   Angela Cox

8. Academic Unit of Pathology, Department of Neuroscience, University of Sheffield, Sheffield, UK

   Simon S. Cross

9. Department of Non-Communicable Disease Epidemiology, London School of Hygiene and Tropical Medicine, London, UK

   Isabel dos-Santos-Silva & Julian Peto

10. Division of Breast Cancer Research, The Institute of Cancer Research, London, UK

    Anthony Swerdlow

11. Centre for Cancer Genetic Epidemiology, Department of Public Health and Primary Care, University of Cambridge, Cambridge, UK

    Manjeet K. Bolla, Qin Wang, Joe Dennis, Kyriaki Michailidou, Douglas F. Easton & Paul D. P. Pharoah

12. Human Cancer Genetics Program, Spanish National Cancer Research Centre, Madrid, Spain

    Javier Benitez & Anna González-Neira

13. Centro de Investigación en Red de Enfermedades Raras, Valencia, Spain

    Javier Benitez

14. Centre d’innovation Génome Québec et Université McGill, Montréal, Canada

    Daniel C. Tessier & Daniel Vincent

15. Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, Stockholm, Sweden

    Jingmei Li, Kamila Czene, Judith S. Brand & Per Hall

16. Division of Cancer Epidemiology and Genetics, National Cancer Institute, Rockville, MD, USA

    Jonine Figueroa & Montserrat García-Closas

17. Department of Genetics, Institute for Cancer Research, Oslo University Hospital Radiumhospitalet, Oslo, Norway

    Vessela Kristensen & Anne-Lise Borresen-Dale

18. K.G. Jebsen Center for Breast Cancer Research, Institute of Clinical Medicine, Faculty of Medicine, University of Oslo, Oslo, Norway

    Vessela Kristensen & Anne-Lise Borresen-Dale

19. Department of Clinical Molecular Biology, Oslo University Hospital, University of Oslo, Oslo, Norway

    Vessela Kristensen

20. Genomics Center, Centre Hospitalier Universitaire de Québec Research Center, Laval University, Québec City, Canada

    Penny Soucy & Jacques Simard

21. Cancer Epidemiology Centre, Cancer Council Victoria, Melbourne, Australia

    Roger L. Milne & Graham G. Giles

22. Centre for Epidemiology and Biostatistics, Melbourne School of Population and Global health, The University of Melbourne, Melbourne, VIC, Australia

    Roger L. Milne, Graham G. Giles & John L. Hopper

23. Department of Oncology - Pathology, Karolinska Institutet, Stockholm, Sweden

    Sara Margolin

24. Department of Molecular Medicine and Surgery, Karolinska Institutet, Stockholm, Sweden

    Annika Lindblom

25. Institute for Prevention and Occupational Medicine of the German Social Accident Insurance, Institute of the Ruhr University Bochum, Bochum, Germany

    Thomas Brüning

26. Dr. Margarete Fischer-Bosch-Institute of Clinical Pharmacology, Stuttgart, Germany

    Hiltrud Brauch

27. University of Tübingen, Tübingen, Germany

    Hiltrud Brauch

28. German Cancer Consortium (DKTK), German Cancer Research Center (DKFZ), Heidelberg, Germany

    Hiltrud Brauch & Hermann Brenner

29. Department of Pathology, The University of Melbourne, Melbourne, Australia

    Melissa C. Southey

30. Gynaecology Research Unit, Hannover Medical School, Hannover, Germany

    Thilo Dörk

31. Department of Radiation Oncology, Hannover Medical School, Hannover, Germany

    Natalia V. Bogdanova

32. Molecular Genetics of Breast Cancer, German Cancer Research Center (DKFZ), Heidelberg, Germany

    Maria Kabisch & Ute Hamann

33. Center for Familial Breast and Ovarian Cancer, Medical Faculty, University of Cologne and University Hospital Cologne, Cologne, Germany

    Rita K. Schmutzler

34. Center for Integrated Oncology (CIO), Medical Faculty, University of Cologne and University Hospital Cologne, Cologne, Germany

    Rita K. Schmutzler

35. Center for Molecular Medicine Cologne (CMMC), Medical Faculty, University of Cologne and University Hospital Cologne, Cologne, Germany

    Rita K. Schmutzler

36. Division of Gynaecology and Obstetrics, Technische Universität München, Munich, Germany

    Alfons Meindl

37. Division of Clinical Epidemiology and Aging Research, German Cancer Research Center (DKFZ), Heidelberg, Germany

    Hermann Brenner & Volker Arndt

38. Division of Preventive Oncology, German Cancer Research Center (DKFZ), Heidelberg, Germany

    Hermann Brenner

39. Laboratory of Cancer Genetics and Tumor Biology, Cancer and Translational Medicine Research Unit, Biocenter Oulu, University of Oulu, Oulu, Finland

    Robert Winqvist & Katri Pylkäs

40. Laboratory of Cancer Genetics and Tumor Biology, Northern Finland Laboratory Centre NordLab, Oulu, Finland

    Robert Winqvist & Katri Pylkäs

41. Department of Gynaecology and Obstetrics, University Hospital Erlangen, Friedrich-Alexander University Erlangen-Nuremberg, Comprehensive Cancer Center Erlangen-EMN, Erlangen, Germany

    Peter A. Fasching & Matthias W. Beckmann

42. David Geffen School of Medicine, Department of Medicine Division of Hematology and Oncology, University of California at Los Angeles, Los Angeles, CA, USA

    Peter A. Fasching

43. Department of Genetics and Pathology, Pomeranian Medical University, Szczecin, Poland

    Jan Lubinski & Anna Jakubowska

44. Department of Laboratory Medicine and Pathobiology, University of Toronto, Toronto, Canada

    Anna Marie Mulligan

45. Laboratory Medicine Program, University Health Network, Toronto, Canada

    Anna Marie Mulligan

46. Lunenfeld-Tanenbaum Research Institute of Mount Sinai Hospital, Toronto, Canada

    Irene L. Andrulis

47. Department of Molecular Genetics, University of Toronto, Toronto, Canada

    Irene L. Andrulis

48. Department of Surgery, Leiden University Medical Center, Leiden, The Netherlands

    Rob A. E. M. Tollenaar

49. Department of Pathology, Leiden University Medical Center, Leiden, The Netherlands

    Peter Devilee

50. Department of Human Genetics, Leiden University Medical Center, Leiden, The Netherlands

    Peter Devilee

51. University of Hawaii Cancer Center, Honolulu, HI, USA

    Loic Le Marchand

52. Department of Preventive Medicine, Keck School of Medicine, University of Southern California, Los Angeles, CA, USA

    Christopher A. Haiman

53. Imaging Center, Department of Clinical Pathology, Kuopio University Hospital, Kuopio, Finland

    Arto Mannermaa & Veli-Matti Kosma

54. Institute of Clinical Medicine, Pathology and Forensic Medicine, University of Eastern Finland, Kuopio, Finland

    Arto Mannermaa & Veli-Matti Kosma

55. Cancer Center of Eastern Finland, University of Eastern Finland, Kuopio, Finland

    Arto Mannermaa & Veli-Matti Kosma

56. Unit of Molecular Bases of Genetic Risk and Genetic Testing, Department of Preventive and Predictive Medicine, Fondazione IRCCS (Istituto Di Ricovero e Cura a Carattere Scientifico) Istituto Nazionale dei Tumori (INT), Milan, Italy

    Paolo Radice

57. IFOM, Fondazione Istituto FIRC (Italian Foundation of Cancer Research) di Oncologia Molecolare, Milan, Italy

    Paolo Peterlongo

58. National Center for Tumor Diseases, University of Heidelberg, Heidelberg, Germany

    Frederik Marme

59. Department of Obstetrics and Gynecology, University of Heidelberg, Heidelberg, Germany

    Frederik Marme & Barbara Burwinkel

60. Molecular Epidemiology Group, German Cancer Research Center (DKFZ), Heidelberg, Germany

    Barbara Burwinkel

61. Department of Pathology, Erasmus University Medical Center, Rotterdam, The Netherlands

    Carolien H. M. van Deurzen

62. Department of Medical Oncology, Family Cancer Clinic, Erasmus MC Cancer Institute, Rotterdam, The Netherlands

    Antoinette Hollestelle

63. School of Medicine, National University of Ireland, Galway, Ireland

    Nicola Miller & Michael J. Kerin

64. Vesalius Research Center, VIB, Leuven, Belgium

    Diether Lambrechts

65. Laboratory for Translational Genetics, Department of Oncology, University of Leuven, Leuven, Belgium

    Diether Lambrechts

66. University Hospital Gashuisberg, Leuven, Belgium

    Giuseppe Floris

67. Netherlands Cancer Institute, Antoni van Leeuwenhoek hospital, Amsterdam, The Netherlands

    Jelle Wesseling & Marjanka K Schmidt

68. Department of Breast Surgery, Herlev Hospital, Copenhagen University Hospital, Herlev, Denmark

    Henrik Flyger

69. Copenhagen General Population Study, Herlev Hospital, Copenhagen University Hospital, Herlev, Denmark

    Stig E. Bojesen

70. Department of Clinical Biochemistry, Herlev Hospital, Copenhagen University Hospital, Herlev, Denmark

    Stig E. Bojesen

71. Faculty of Health and Medical Sciences, University of Copenhagen, Copenhagen, Denmark

    Stig E. Bojesen

72. Department of Cancer Prevention and Control, Roswell Park Cancer Institute, Buffalo, NY, USA

    Song Yao

73. Roswell Park Cancer Institute, Buffalo, NY, USA

    Christine B. Ambrosone

74. Department of Genetics, QIMR Berghofer Medical Research Institute, Brisbane, Australia

    Georgia Chenevix-Trench

75. Environmental Epidemiology of Cancer, Center for Research in Epidemiology and Population Health, INSERM, Villejuif, France

    Thérèse Truong & Pascal Guénel

76. University Paris-Sud, Villejuif, France

    Thérèse Truong & Pascal Guénel

77. Division of Cancer Epidemiology, German Cancer Research Center (DKFZ), Heidelberg, Germany

    Anja Rudolph & Jenny Chang-Claude

78. Department of Obstetrics and Gynecology, Helsinki University Hospital, University of Helsinki, Helsinki, Finland

    Heli Nevanlinna

79. Department of Oncology, Helsinki University Hospital, University of Helsinki, Helsinki, Finland

    Carl Blomqvist

80. Department of Health Sciences Research, Mayo Clinic, Rochester, MN, USA

    Janet E. Olson

81. Department of Laboratory Medicine and Pathology, Mayo Clinic, Rochester, MN, USA

    Fergus J. Couch

82. Centre for Cancer Genetic Epidemiology, Department of Oncology, University of Cambridge, Cambridge, UK

    Alison M. Dunning, Douglas F. Easton & Paul D. P. Pharoah

83. Wellcome Trust Centre for Human Genetics and Oxford NIHR Biomedical Research Centre, University of Oxford, Oxford, UK

    Ian Tomlinson

Corresponding author

Correspondence to Elinor J. Sawyer.

Competing interests

The authors declare that there are no conflicts of interest.

Authors’ contributions

The study was conceived by ES and RR. Analysis and genotyping in ICICLE was performed by ES. Meta-analyses were performed by MGC. The manuscript was prepared by ES. EJS, RR and IT conceived and designed the experiments. CP, VS, DLe, EP, AGN, DCT, DV, FB, JD, and AMD performed the experiments. CP, MNB, MKB, QW, KM, IT, MGC, and EJS analyzed the data. CP, MNB, VS, KK, PGo, MC, DLe, EP, NO, AC, SSC, IdSS, JP, AS, MJS, MKB, QW, JD, KM, JB, AGN, DCT, DV, JLi, JF, VK, ALBD, PS, JS, RLM, GGG, SM, AL, TB, HBra, MCS, JLH, TD, NVB, MK, UH, RKS, AMe, HBre, VA, RW, KP, PAF, MWB, JLu, AJ, AMM, ILA, RAEMT, PD, LLM, CAH, AMa, VMK, PR, PP, FM, BB, CHMvD, AH, NM, MJK, DLa, GF, JW, HF, SEB, SY, CBA, GCT, TT, PGu, AR, JCC, HN, CB, KC, JSB, JEO, FJC, AMD, PH, DFE, PDPP, SEP, MKS, IT, RR, MGC, and EJS contributed reagents/materials/analysis tools. CP, IT, MGC, and EJS wrote the paper. SEP performed the histopathology review. CP, VS, DLe, and SEP performed ER scoring. CP, MNB, VS, KK, PGo, MC, DLe, EP, NO, AC, SSC, IdSS, JP, AS, MJS, MKB, QW, JD, KM, JB, AGN, DCT, DV, JLi, JF, VK, ALBD, PS, JS, RLM, GGG, SM, AL, TB, HBra, MCS, JLH, TD, NVB, MK, UH, RKS, AMe, HBre, VA, RW, KP, PAF, MWB, JLu, AJ, AMM, ILA, RAEMT, PD, LLM, CAH, AMa, VMK, PR, PP, FM, BB, CHMvD, AH, NM, MJK, DLa, GF, JW, HF, SEB, SY, CBA, GCT, TT, PGu, AR, JCC, HN, CB, KC, JSB, JEO, FJC, AMD, PH, DFE, PDPP, SEP, MKS, IT, RR, MGC, and EJS provided critical review of the manuscript. CP, MNB, VS, KK, PGo, MC, DLe, EP, NO, AC, SSC, IdSS, JP, AS, MJS, MKB, QW, JD, KM, JB, AGN, DCT, DV, JLi, JF, VK, ALBD, PS, JS, RLM, GGG, SM, AL, TB, HBra, MCS, JLH, TD, NVB, MK, UH, RKS, AMe, HBre, VA, RW, KP, PAF, MWB, JLu, AJ, AMM, ILA, RAEMT, PD, LLM, CAH AMa VMK PR PP FM BB CHMvD AH NM MJK DLa GF JW HF SEB SY CBA GCT TT, PGu, AR, JCC, HN, CB, KC, JSB, JEO, FJC, AMD, PH, DFE, PDPP, SEP, MKS, IT, RR, MGC, and EJS approved the final version of the manuscript.

Authors’ information

Study was conceived by ES & RR, analysis & genotyping of ICICLE performed by ES, meta-analyses performed by MGC, manuscript prepared by ES.

Rebecca Roylance, Montserrat García-Closas and Elinor J. Sawyer are senior co-authors

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