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. Author manuscript; available in PMC: 2017 May 12.
Published in final edited form as: Genet Med. 2016 Oct 6;19(5):599–603. doi: 10.1038/gim.2016.147

Genetic modifiers of CHEK2*1100delC associated breast cancer risk

Taru A Muranen 1, Dario Greco 4, Carl Blomqvist 2, Kristiina Aittomäki 3, Sofia Khan 1, Frans Hogervorst 5, Senno Verhoef 5, Paul DP Pharoah 6,7, Alison M Dunning 6, Mitul Shah 6, Robert Luben 8, Stig E Bojesen 9,10,11, Børge G Nordestgaard 9,10,11, Minouk Schoemaker 12, Anthony Swerdlow 12,13, Montserrat García-Closas 12,14, Jonine Figueroa 14, Thilo Dörk 15, Natalia V Bogdanova 16, Per Hall 17, Jingmei Li 17, Elza Khusnutdinova 20,21, Marina Bermisheva 15,21, Vessela Kristensen 22,26,27, Anne-Lise Borresen-Dale 22,27; NBCS Investigators22,23,24,25,26,27,28,29,30,31,32,33,34,35,36, Julian Peto 37, Isabel dos Santos Silva 37, Fergus J Couch 38, Janet E Olson 39, Peter Hillemans 15, Tjoung-Won Park-Simon 15, Hiltrud Brauch 40,46,47, Ute Hamann 41, Barbara Burwinkel 42,48, Frederik Marme 48,49, Alfons Meindl 50, Rita K Schmutzler 51,52,53, Angela Cox 54, Simon S Cross 55, Elinor J Sawyer 56, Ian Tomlinson 57, Diether Lambrechts 58,59, Matthieu Moisse 58, Annika Lindblom 18, Sara Margolin 19, Antoinette Hollestelle 60, John WM Martens 60, Peter A Fasching 61,62, Matthias W Beckmann 61, Irene L Andrulis 63,65, Julia A Knight 64,66; kConFab/AOCS Investigators67, Hoda Anton-Culver 70, Argyrios Ziogas 70, Graham G Giles 68,71, Roger L Milne 68,71, Hermann Brenner 40,43,44, Volker Arndt 44, Arto Mannermaa 72,73,74, Veli-Matti Kosma 72,73,74, Jenny Chang-Claude 45, Anja Rudolph 45, Peter Devilee 75,76, Caroline Seynaeve 60, John L Hopper 68, Melissa C Southey 69, Esther M John 77,78,79, Alice S Whittemore 78,79, Manjeet K Bolla 7, Qin Wang 7, Kyriaki Michailidou 7,80, Joe Dennis 7, Douglas F Easton 6,7, Marjanka K Schmidt 5,*, Heli Nevanlinna 1,*
PMCID: PMC5382131  NIHMSID: NIHMS819618  PMID: 27711073

Abstract

Purpose

CHEK2*1100delC is a founder variant in European populations conferring a 2–3 fold increased risk of breast cancer (BC). Epidemiologic and family studies have suggested that the risk associated with CHEK2*1100delC is modified by other genetic factors in a multiplicative fashion. We have investigated this empirically using data from the Breast Cancer Association Consortium (BCAC).

Methods

With genotype data of 39,139 (624 1100delC carriers) BC patients and 40,063 (224) healthy controls from 32 BCAC studies, we analyzed the combined risk effects of CHEK2*1100delC and 77 common variants in terms of a polygenic risk score (PRS) and pairwise interaction.

Results

The PRS conferred an odds ratio (OR) of 1.59 [95% CI 1.21–2.09] per standard deviation for BC for CHEK2*1100delC carriers and 1.58 [1.55–1.62] for non-carriers. No evidence for deviation from the multiplicative model was found. The OR for the highest quintile of the PRS was 2.03 [0.86–4.78] for CHEK2*1100delC carriers placing them to the high risk category according to UK NICE guidelines. OR for the lowest quintile was 0.52 [0.16–1.74], indicating life-time risk close to population average.

Conclusion

Our results confirm the multiplicative nature of risk effects conferred by CHEK2*1100delC and the common susceptibility variants. Furthermore, the PRS could identify the carriers at a high life-time risk for clinical actions.

Keywords: Breast cancer, CHEK2*1100delC, Polygenic risk score (PRS), common variants, Breast Cancer Association Consortium (BCAC)

INTRODUCTION

The protein truncating mutation CHEK2*1100delC (checkpoint kinase 2) is a moderate penetrance breast cancer risk variant with relative risk estimate of 2–3 fold.1, 2 However, several studies have shown that the cumulative life-time risk of breast cancer in CHEK2*1100delC carriers is markedly higher in women with a family history than without,35 and that CHEK2*1100delC carriers have a higher probability of developing bilateral breast cancer.6 These observations are quantitatively consistent with a simple polygenic model suggesting that CHEK2*1100delC combines multiplicatively with other genetic loci. However, this has not yet been established empirically.

Genome wide association studies have identified common genetic variants that are associated with increased risk of breast cancer. A polygenic risk score (PRS), based on 77 low penetrance variants has been estimated to explain approximately 12–14% of the excess familial risk and shown to identify individuals at high risk at the population level.7, 8 Some of these variants predominantly predispose to either estrogen receptor positive (ER+) or estrogen receptor negative (ER−) disease, which represent the two main etiological subclasses of breast cancer.9 CHEK2*1100delC carriers are more strongly predisposed to ER+ disease: about 90% of carrier tumors are ER+ in comparison to 77–78% of non-carrier tumours.10

Here, we investigate the synergistic risk effects attributable to CHEK2*1100delC and the common breast cancer susceptibility variants both individually and summarized in terms of the PRS.7, 8

PATIENTS AND METHODS

Study participants

Female invasive breast cancer patients and healthy controls of European ancestry were included from studies participating in the Breast Cancer Association Consortium (BCAC)(Table S1). Data from a study were included if the study provided genotype data of the common variants from at least one breast cancer patient carrying the 1100delC variant. This selection yielded data from 32 studies and a total of 79,202 study subjects, including 848 CHEK2*1100delC carriers (Table S2) for pairwise interaction analyses. Complete quality controlled7, 10 genotype data for all common variants and CHEK2*1100delC were available from 33,624 study subjects (369 CHEK2*1100delC carriers, Table S2). This data were used in the analyses involving the PRS.

All participating studies were approved by their institutional review committees. Each study followed national guidelines for participant inclusion and informed consent procedures.

Genotyping

All variants except CHEK2*1100delC were genotyped centrally using a custom Illumina iSelect genotyping array (iCOGS, Illumina, Inc. San Diego, CA, USA) as part of the COGS consortium studies as described earlier.7, 8 CHEK2*1100delC was primarily genotyped using a custom made TaqMan assay (Applied Biosystems, Foster City, CA, USA), with a small minority being genotyped using iPLEX.10 In addition to the 38,549 study subjects genotyped using the iCOGS array, 40,653 BCAC study subjects were genotyped for up to 25 of the common risk variants and these data were used in the pairwise interaction analysis (Table S2, Table S3). These samples were genotyped by independent studies following BCAC genotyping standards as described previously.11, 12

Statistical analyses

Statistical analyses were performed using Stata SE 10 (StataCorp, College Station, Texas, USA) and R version 2.15.2.13 For the common variants a log-additive model was assumed; i.e. the risk was analyzed in terms of the number of disease-associated alleles [0,1,2] carried. CHEK2*1100delC was assumed to follow a dominant inheritance model as the number of rare homozygotes was small (n=19). All analyses were adjusted for study and seven principal components defined on the basis of the genome-wide data from the iCOGS project as described previously.7 All reported tests were two-sided.

Polygenic risk score

In order to investigate the combined effects of common variants and CHEK2*1100delC, a polygenic risk score (PRS) based on the main effects of the common variants was calculated using the formula:

i=1nailog2ORi

where n is the number of loci included in the model, a is the number of susceptibility alleles in locus i and OR is the per allele odds ratio for breast cancer, estimated separately for each variant in the whole data set (Table S4a, column “All”). Results using a PRS based on previously reported ORs7, 8 were essentially identical (data not shown). The PRS was approximately normally distributed in all study subgroups, and was standardized by mean and standard deviation of the PRS among the healthy individuals.8 For pairs of linked variants with r2>0.75, we included in the PRS only the lead variant (rs2981579, not rs2981582; rs12662670, not rs3757318; rs554219, not rs614367). We excluded two variants (rs78540526 and rs75915166) included in the PRS of Mavaddat et al.8, which were not genotyped on the iCOGS array, as well as rs17879961, the CHEK2 missense variant I157T, because the number of study subjects carrying both 1100delC and I157T was very low (n=5). Thus, the resulting PRS included 74 variants. The interaction between PRS and CHEK2*1100delC was assessed by comparing nested logistic regression models: a model including the PRS and 1100delC genotype and a model supplemented with an interaction term, coded as the product of the PRS and 1100delC. In analyses of the PRS and positive family history of breast cancer, positive family history was defined as at least one first degree relative with breast cancer.

The cumulative life-time breast cancer risk of CHEK2*1100delC carriers in different PRS-percentiles was derived assuming an average life-time risk of 22% for CHEK2*1100delC carriers14 and previously published relative risk estimates associated with the PRS.8

Pairwise interaction analyses

We tested for pairwise interaction between each common variant and CHEK2*1100delC as described above for the interaction between the PRS and 1100delC. P-values were corrected for 77 parallel tests using the Benjamini-Hochberg method.15 The OR for breast cancer was estimated separately for each of the common variants for the whole dataset and for the subgroup of 1100delC carriers. These analyses were also performed separately on a subgroup of breast cancer patients with ER+ disease, because 1100delC is associated with ER+ breast cancer.10 We tested for heterogeneity in the ORs among different BCAC studies by including an interaction term between variant and the study, separately for each variant. No significant heterogeneity was found for any variant (data not shown). Statistical power was estimated as previously suggested for risk interaction analyses.16

RESULTS

We analyzed the combined effects of CHEK2*1100delC and common low penetrance breast cancer risk variants using data from the international Breast Cancer Association Consortium (Table S2). The PRS summarizing the individual effects of 74 common variants was strongly associated with breast cancer risk among CHEK2*1100delC carriers (OR per unit standard deviation 1.59 [1.21–2.09], P=0.0008) and the OR was similar to that in non-carriers (1.58 [1.55–1.62], Pinteraction 0.93). ORs for the highest and lowest quintiles of the PRS distribution were 2.03 [0.86–4.78] and 0.52 [0.16–1.74] for CHEK2*1100delC carriers, respectively, when compared to the middle quintile (Table 1). Both estimates were similar to those among non-carriers.

Table 1.

Breast cancer risk associated with the polygenic risk score (PRS) for non-carriers and the carriers of CHEK2*1100delC.

Non-carriers CHEK2*1100delC carriers
OR [95% CI] P OR [95% CI] P
PRSa 1.58 [1.55 – 1.62] <1.0E-10 1.59 [1.21 – 2.09]b 0.0008
Percentile of PRS, %
< 20 0.52 [0.48 – 0.56] <1.0E-10 0.52 [0.16 – 1.74] 0.29
20–40 0.78 [0.72 – 0.84] 2E-11 0.72 [0.28 – 1.88] 0.51
40–60 referent referent
60–80 1.25 [1.16 – 1.34] 8E-10 0.93 [0.39 – 2.25] 0.88
> 80 1.92 [1.80 – 2.06] <1.0E-10 2.03 [0.86 – 4.78] 0.11
a

Odds ratio (OR) was estimated per unit standard deviation of the PRS.

b

P-value for pairwise interaction between CHEK2*1100delC and PRS: 0.93.

The OR associated with CHEK2*1100delC in the analysis data set 2.99 [2.32–3.85] was attenuated, when the model was adjusted for positive family history of breast cancer. The OR associated with the PRS was also slightly attenuated (Table 2). No significant interaction between risk effects associated with 1100delC, PRS and positive family history was found. However, in a case-only analysis there was a significant association between the PRS and family history of breast cancer, among both CHEK2*1100delC carriers (OR 1.29 [1.01–1.65], P=0.04) and non-carriers (OR 1.17 [1.12–1.21], P=4E-16) (Figure S1).

Table 2.

Relative breast cancer risk associated with CHEK2*1100delC, PRS and positive family history of breast cancer in the analysis data set.

Risk model Parameters OR [95% CI] P
BC ~ 1100delC + PRS 1100delC 2.99 [2.32 – 3.85] <1.0E-10
PRS 1.58 [1.55 – 1.62] <1.0E-10
BC ~ 1100delC + PRS + family history 1100delC 2.42 [1.71 – 3.47] 9.4E-7
PRS 1.55 [1.50 – 1.60] <1.0E-10
family historya 2.73 [2.48 – 3.47] <1.0E-10
a

No significant interaction between positive family history of breast cancer and either CHEK2*1100delC or PRS was found.

When altogether 77 common variants were considered individually, we found nominally significant interactions between five variants and CHEK2*1100delC for overall breast cancer (rs11249433, rs11780156, rs204247, rs2981582 and rs704010; Table S4a). Two of these represented synergistic (more than multiplicative) and three antagonistic interactions (the estimated effect in 1100delC carriers being in the opposite direction to that in non-carriers). However, none of the interactions were significant after correction for multiple testing. Nine variants showed a nominally significant interaction for ER-positive breast cancer (Table S4b).

DISCUSSION

Our analyses on the synergistic effects of CHEK2*1100delC and 77 common low penetrance variants on breast cancer risk give strong support to the predicted multiplicative polygenic model.8, 17, 18 While this has previously been shown for combinations of low penetrance variants,8 and for variants in combination with BRCA1 and BRCA2 mutations,19 this is the first direct demonstration for a “moderate” risk gene and has important implications for risk prediction. The PRS was a significant risk factor for CHEK2*1100delC carriers, and the estimated OR per unit standard deviation was very similar in CHEK2*1100delC carriers and in non-carriers, consistent with the hypothesis that the common susceptibility variants combine with the rare CHEK2*1100delC variant in an approximately multiplicative fashion. Similarly, the PRS risk estimates for the highest and lowest quintiles did not differ between the CHEK2*1100delC carriers and non-carriers. These two estimates in the CHEK2*1100delC carriers alone did not reach statistical significance (Table 1), possibly reflecting limited statistical power due to the relatively low number of healthy variant carriers (Table S2). However, this is the largest study genotyped for CHEK2*1100delC and these common variants, and even though some of the point estimates are not significant, they are consistent with the previous reports. Most importantly, we did not find evidence for deviation from the multiplicative model, suggesting that the PRS could be used in risk stratification of 1100delC carriers in a similar manner to non-carriers.

The unadjusted OR for the CHEK2*110delC variants (Table 2) was higher in our analysis data set than in previous reports.2, 14 Adjusting for positive family history markedly attenuated the CHEK2*1100delC associated OR, suggestive of some oversampling of familial cases. The PRS OR was also slightly attenuated after the adjustment. However, CHEK2*1100delC, PRS and family history remained significant risk factors in the combined model (Table 2) suggesting that the common variants together explain part of the excess familial risk as previously suggested,17 but that the PRS has predictive value also in breast cancer families segregating CHEK2*1100delC.

Recently, a large study estimating the risk associated with CHEK2*1100delC in relation to age, tumor subtype and family history reported the cumulative life-time risk for 1100delC carriers to be about 22%.14 Assuming that the relative effect of the PRS is the same in carriers and non-carriers (OR higher than 1.48 [1.39–1.57] or lower than 0.65 [0.60–0.70] for percentiles above 80% or lower than 20%, respectively),8 20% of the 1100delC carriers with highest PRS would have life-time risk higher than 32.6% [30.6%–34.5%] exceeding the threshold for the high-risk category (>30%) according to the UK NICE guidelines for familial breast cancer.20 Similarly, for the 20% of 1100delC carriers with lowest PRS, the life-time risk would be lower than 14.3% [13.2%–15.4%], i.e. close to the average population risk. These observations imply that, if CHEK2*1100delC is to be used in risk prediction, it can be made more effective by including the PRS, representing the risk modifying effects of common variants, in the prediction.

CHEK2*1100delC carrier cancers do not represent a phenotypically distinct subgroup of breast carcinomas. Instead, the phenotypic diversity of CHEK2*1100delC associated cancers resembles that of breast tumors in general.10 Thus, it was not surprising that the relative risks conferred by the common variants were similar for the CHEK2*1100delC carriers and for non-carriers, and no significant pairwise interaction was found. We estimated that we had sufficient statistical power (80%, at P<0.05) to detect a pairwise interaction between CHEK2*1100delC and any of the common variants, if the interaction OR was 2.5 or greater, but not enough power to detect interactions comparable in magnitude to the risk effects associated with the low penetrance variants (OR 1.1–1.5). Thus, it remains possible that more modest departures from a multiplicative model may exist. If so, however, much larger case-control studies, perhaps combined with pedigree analyses, will be required to detect them.

In conclusion, our analyses confirm the predicted multiplicative relationship between CHEK2*1100delC and the common low penetrance variants. Hence, the PRS could be similarly applied for risk prediction for the variant carriers as for the general population. Most importantly, the PRS could help identifying the high risk group of the CHEK2*1100delC carriers, who would best benefit from clinical intervention.

Supplementary Material

Supplementary _Appendix_ online only material_ etc.__1
Supplementary _Appendix_ online only material_ etc.__2. Figure S1.

Relationship between the polygenic risk score (PRS) and positive family history of breast cancer.

Supplementary _Appendix_ online only material_ etc.__3. Table S1.

Description of study design and genotype data availability of 32 studies participating in the Breast Cancer Association Consortium (BCAC).

Supplementary _Appendix_ online only material_ etc.__4. Table S2.

CHEK2*1100delC genotype data availability for breast cancer (BC) cases and controls.

Supplementary _Appendix_ online only material_ etc.__5. Table S3.

Description of genotype data coverage and genotyping methods for each low penetrance variant.

Supplementary _Appendix_ online only material_ etc.__6. Table S4.

Odds ratios (OR) and 95% confidence intervals (CI) estimated for the whole dataset and for the carriers of CHEK2*1100delC, as well as for pairwise interaction between each variant and CHEK2*1100delC for (a) breast cancer (b) estrogen receptor positive (ER+) breast cancer.

Acknowledgments

FUNDING

The Breast Cancer Association Consortium (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 n° 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 Defence (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.

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 was 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.

The Amsterdam Breast Cancer Study (ABCS) 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 work of the Bavarian Breast Cancer Cases and Controls (BBCC) was partly funded by ELAN-Fond of the University Hospital of Erlangen.

The British Breast Cancer Study (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).

EJS is supported by NIHR Comprehensive Biomedical Research Centre, Guy's & St. Thomas' NHS Foundation Trust in partnership with King's College London, United Kingdom. IT is supported by the Oxford Biomedical Research Centre and core funding to the Wellcome Trust Centre for Human Genetics from the Wellcome Trust (090532/Z/09/Z).

The Breast Cancer Study of the University of Heidelberg (BSUCH) was supported by the Dietmar-Hopp Foundation, the Helmholtz Society and the German Cancer Research Center (DKFZ).

The Copenhagen General Population Study (CGPS) was supported by the Chief Physician Johan Boserup and Lise Boserup Fund, the Danish Medical Research Council and Herlev Hospital.

The ESTHER Breast Cancer 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 German Consortium of Hereditary Breast and Ovarian Cancer (GC-HBOC) is supported by the German Cancer Aid (grant no 110837, coordinator: RKS).

The Gene Environment Interaction and Breast Cancer in Germany (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, as well as the Department of Internal Medicine, Evangelische Kliniken Bonn gGmbH, Johanniter Krankenhaus, Bonn, Germany.

The Genetic Epidemiology Study of Breast Cancer by Age 50 (GESBC) was supported by the Deutsche Krebshilfe e. V. [70492] and the German Cancer Research Center (DKFZ).

The Hannover Breast Cancer Study (HABCS) study was supported by the Rudolf Bartling Foundation.

The Helsinki Breast Cancer Study (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 work of TAM has been supported by Ida Montin Foundation, Cancer Society of Finland and Finnish Cultural Foundation.

The Hannover-Minsk Breast Cancer Study (HMBCS) was supported by a grant from the Friends of Hannover Medical School and by the Rudolf Bartling Foundation.

The Hannover-Ufa Breast Cancer Study (HUBCS) was supported by a grant from the German Federal Ministry of Research and Education (RUS08/017).

“Financial support for the Karolinska Breast Cancer Study (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.

The Kuopio Breast Cancer Project (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.

The Kathleen Cuningham Foundation Consortium for research into Familial Breast Cancer (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 Australian Ovarian Cancer Study (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).

The Leuven Multidisciplinary Breast Centre (LMBC) is supported by the 'Stichting tegen Kanker' (232-2008 and 196-2010). DL is supported by the FWO and the KULPFV/10/016-SymBioSysII.

The Mayo Clinic Breast Cancer Study (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 and the Ting Tsung and Wei Fong Chao Foundation.

The Melbourne Collaborative Cohort Study (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) and the Australian Institute of Health and Welfare (AIHW), including the National Death Index (NDI) and the Australian Cancer Database.

The Norwegian Breast Cancer Study (NBCS) has received funding from the K.G. Jebsen Centre for Breast Cancer Research; the Research Council of Norway grant 193387/V50 (to ALBD and VKr) and grant 193387/H10 (to ALBD and VKr), South Eastern Norway Health Authority (grant 39346 to to ALBD and VKr) and the Norwegian Cancer Society (to to ALBD and VKr).

The Northern California Breast Cancer Family Registry (NC-BCFR) 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 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 Leiden University Medical Centre Breast Cancer Study (ORIGO) was supported by the Dutch Cancer Society (RUL 1997-1505) and the Biobanking and Biomolecular Resources Research Infrastructure (BBMRI-NL CP16).

The NCI Polish Breast Cancer Study (PBCS) was funded by Intramural Research Funds of the National Cancer Institute, Department of Health and Human Services, USA.

The Rotterdam Breast Cancer Study (RBCS) was funded by the Dutch Cancer Society (DDHK 2004-3124, DDHK 2009-4318).

The Singapore and Sweden Breast Cancer Study (SASBAC) 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.

The Sheffield Breast Cancer Study (SBCS) was supported by Yorkshire Cancer Research S295, S299, S305PA and Sheffield Experimental Cancer Medicine Centre.

The Study of Epidemiology and Risk factors in Cancer Heredity (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.

The UCI Breast Cancer Study (UCIBCS) component of this research was supported by the NIH [CA58860, CA92044] and the Lon V Smith Foundation [LVS39420].

The UK Breakthrough Generations Study (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

We thank all the individuals who took part in these studies and all the researchers, clinicians, technicians and administrative staff who enabled this work to be carried out (details in online Supplementary data).

Footnotes

CONFLICT OF INTEREST: The authors declare no conflict of interest. The funders had no role in conception and design of the study, nor in interpretation of the final results.

Supplementary data. Detailed acknowledgements.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplementary _Appendix_ online only material_ etc.__1
Supplementary _Appendix_ online only material_ etc.__2. Figure S1.

Relationship between the polygenic risk score (PRS) and positive family history of breast cancer.

Supplementary _Appendix_ online only material_ etc.__3. Table S1.

Description of study design and genotype data availability of 32 studies participating in the Breast Cancer Association Consortium (BCAC).

Supplementary _Appendix_ online only material_ etc.__4. Table S2.

CHEK2*1100delC genotype data availability for breast cancer (BC) cases and controls.

Supplementary _Appendix_ online only material_ etc.__5. Table S3.

Description of genotype data coverage and genotyping methods for each low penetrance variant.

Supplementary _Appendix_ online only material_ etc.__6. Table S4.

Odds ratios (OR) and 95% confidence intervals (CI) estimated for the whole dataset and for the carriers of CHEK2*1100delC, as well as for pairwise interaction between each variant and CHEK2*1100delC for (a) breast cancer (b) estrogen receptor positive (ER+) breast cancer.

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