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Original research
Population-based targeted sequencing of 54 candidate genes identifies PALB2 as a susceptibility gene for high-grade serous ovarian cancer
  1. Honglin Song1,
  2. Ed M Dicks1,
  3. Jonathan Tyrer1,
  4. Maria Intermaggio2,
  5. Georgia Chenevix-Trench3,
  6. David D Bowtell4,
  7. Nadia Traficante5,
  8. AOCS Group6,7,
  9. James Brenton8,
  10. Teodora Goranova8,
  11. Karen Hosking1,
  12. Anna Piskorz8,
  13. Elke van Oudenhove9,
  14. Jen Doherty10,
  15. Holly R Harris11,12,
  16. Mary Anne Rossing11,12,
  17. Matthias Duerst13,
  18. Thilo Dork14,
  19. Natalia V Bogdanova15,16,
  20. Francesmary Modugno17,18,
  21. Kirsten Moysich19,
  22. Kunle Odunsi20,
  23. Roberta Ness21,
  24. Beth Y Karlan22,23,
  25. Jenny Lester22,23,
  26. Allan Jensen24,
  27. Susanne Krüger Kjaer25,
  28. Estrid Høgdall24,26,
  29. Ian G Campbell5,27,
  30. Conxi Lázaro28,
  31. Miguel Angel Pujara29,
  32. Julie Cunningham30,
  33. Robert Vierkant31,
  34. Stacey J Winham31,
  35. Michelle Hildebrandt32,
  36. Chad Huff32,
  37. Donghui Li32,
  38. Xifeng Wu32,
  39. Yao Yu32,
  40. Jennifer B Permuth33,
  41. Douglas A Levine34,35,
  42. Joellen M Schildkraut36,
  43. Marjorie J Riggan37,
  44. Andrew Berchuck37,
  45. Penelope M Webb38,
  46. OPAL Study Group38,
  47. Cezary Cybulski39,
  48. Jacek Gronwald39,
  49. Anna Jakubowska39,40,
  50. Jan Lubinski39,
  51. Jennifer Alsop1,
  52. Patricia Harrington1,
  53. Isaac Chan2,
  54. Usha Menon41,
  55. Celeste L Pearce42,
  56. Anna H Wu43,
  57. Anna de Fazio44,45,
  58. Catherine J Kennedy44,45,
  59. Ellen Goode46,
  60. Susan Ramus2,47,
  61. Simon Gayther48,
  62. Paul Pharoah49
  1. 1 Department of Oncology, University of Cambridge, Cambridge, Cambridgeshire, UK
  2. 2 School of Women's and Children's Health, Faculty of Medicine, University of New South Wales, Sydney, New South Wales, Australia
  3. 3 Cancer Genetics, Queensland Institute of Medical Research—QIMR, Herston, Queensland, Australia
  4. 4 Cancer Genomics and Genetics and Women’s Cancer Programs, Peter MacCallum Cancer Centre, Melbourne, Victoria, Australia
  5. 5 Sir Peter MacCallum Department of Oncology, The University of Melbourne, Melbourne, Victoria, Australia
  6. 6 QIMR Berghofer Department of Genetics and Computational Biology, Herston, Queensland, Australia
  7. 7 Department of Research, Peter MacCallum Cancer Centre, Melbourne, Victoria, Australia
  8. 8 Cancer Research UK Cambridge Institute, University of Cambridge, Cambridge, Cambridgeshire, UK
  9. 9 Laura and Isaac Perlmutter Cancer Center, New York University, New York, New York, USA
  10. 10 Huntsman Institute, University of Utah, Salt Lake City, Utah, USA
  11. 11 Division of Public Health Sciences, Fred Hutchinson Cancer Research Center, Seattle, Washington, USA
  12. 12 Department of Epidemiology, University of Washington, Seattle, Washington, USA
  13. 13 Department of Gynaecology, Jena University Hospital, Friedrich Schiller University Jena, Jena, Thüringen, Germany
  14. 14 Gynaecology Research Unit, Hannover Medical School, Hannover, Niedersachsen, Germany
  15. 15 Department of Radiation Oncology, Hannover Medical School, Hannover, Niedersachsen, Germany
  16. 16 Department of Gynaecology, NN Alexandrov National Cancer Centre, Minsk, Minsk, Belarus
  17. 17 Womens Cancer Research Center, Magee-Womens Research Institute, Pittsburgh, Pennsylvania, USA
  18. 18 Department of Obstetrics, Gynecology and Reproductive Sciences, University of Pittsburgh School of Medicine, Pittsburgh, Pennsylvania, USA
  19. 19 Division of Cancer Prevention and Control, Roswell Park Cancer Institute, Buffalo, New York, USA
  20. 20 Department of Gynecologic Oncology, Roswell Park Cancer Institute, Buffalo, New York, USA
  21. 21 School of Public Health, University of Texas Health Science Center at Houston, Houston, Texas, USA
  22. 22 Department of Obstetrics and Gynecology, David Geffen School of Medicine, University of California Los Angeles, Los Angeles, California, USA
  23. 23 Women's Cancer Program at the Samuel Oschin Comprehensive Cancer Institute, Cedars-Sinai Medical Center, Los Angeles, California, USA
  24. 24 Department of Virus, Lifestyle and Genes, Danish Cancer Society Research Center, Kobenhavn, Denmark
  25. 25 Department of Gynaecology, Rigshospitalet, University of Copenhagen, Kobenhavn, Denmark
  26. 26 Department of Pathology, Herlev Hospital, University of Copenhagen, Kobenhavn, Denmark
  27. 27 Department of Research, Cancer Genomics and Genetics, Peter MacCallum Cancer Centre, Melbourne, Victoria, Australia
  28. 28 Hereditary Cancer Program, Catalan Institute of Oncology, Barcelona, Catalunya, Spain
  29. 29 Translational Research Laboratory, Catalan Institute of Oncology, Barcelona, Catalunya, Spain
  30. 30 Department of Laboratory Medicine and Pathology, Mayo Clinic, Rochester, Minnesota, USA
  31. 31 Department of Health Science Research, Division of Biomedical Statistics and Informatics, Mayo Clinic, Rochester, Minnesota, USA
  32. 32 Department of Epidemiology, University of Texas MD Anderson Cancer Center, Houston, Texas, USA
  33. 33 Department of Cancer Epidemiology, Moffitt Cancer Center, Tampa, Florida, USA
  34. 34 Department of Surgery, Memorial Sloan Kettering Cancer Center, New York, New York, USA
  35. 35 Gynecologic Oncology, Laura and Isaac Pearlmutter Cancer Center, New York University, New York, New York, USA
  36. 36 Department of Public Health Sciences, University of Virginia, Charlottesville, Virginia, USA
  37. 37 Department of Gynecologic Oncology, Duke University Hospital, Durham, North Carolina, USA
  38. 38 Population Health Department, QIMR Berghofer Medical Research Institute, Herston, Queensland, Australia
  39. 39 Department of Genetics and Pathology, Pomeranian Medical University in Szczecin, Szczecin, Zachodniopomorskie, Poland
  40. 40 Independent Laboratory of Molecular Biology and Genetic Diagnostics, Pomeranian Medical University in Szczecin, Szczecin, Zachodniopomorskie, Poland
  41. 41 MRC Clinical Trials Unit, Institute of Clinical Trials & Methodology, University College London, London, London, UK
  42. 42 Department of Epidemiology, University of Michigan School of Public Health, Ann Arbor, Michigan, USA
  43. 43 Department of Preventive Medicine, Keck School of Medicine, University of Southern California, Los Angeles, California, USA
  44. 44 Centre for Cancer Research, The Westmead Institute for Medical Research, The University of Sydney, Sydney, New South Wales, Australia
  45. 45 Department of Gynaecological Oncology, Westmead Hospital, Westmead, New South Wales, Australia
  46. 46 Department of Health Science Research, Division of Epidemiology, Mayo Clinic, Rochester, Minnesota, USA
  47. 47 Kinghorn Cancer Centre, Garvan Institute of Medical Research, Darlinghurst, New South Wales, Australia
  48. 48 Center for Bioinformatics and Functional Genomics and the Cedars Sinai Genomics Core, Cedars-Sinai Medical Center, Los Angeles, California, USA
  49. 49 Department of Public Health and Primary Care, University of Cambridge, Cambridge, UK
  1. Correspondence to Dr Paul Pharoah, Department of Public Health and Primary Care, University of Cambridge, Cambridge CB2 1TN, UK; pp10001{at}medschl.cam.ac.uk

Abstract

Purpose The known epithelial ovarian cancer (EOC) susceptibility genes account for less than 50% of the heritable risk of ovarian cancer suggesting that other susceptibility genes exist. The aim of this study was to evaluate the contribution to ovarian cancer susceptibility of rare deleterious germline variants in a set of candidate genes.

Methods We sequenced the coding region of 54 candidate genes in 6385 invasive EOC cases and 6115 controls of broad European ancestry. Genes with an increased frequency of putative deleterious variants in cases versus controls were further examined in an independent set of 14 135 EOC cases and 28 655 controls from the Ovarian Cancer Association Consortium and the UK Biobank. For each gene, we estimated the EOC risks and evaluated associations between germline variant status and clinical characteristics.

Results The ORs associated for high-grade serous ovarian cancer were 3.01 for PALB2 (95% CI 1.59 to 5.68; p=0.00068), 1.99 for POLK (95% CI 1.15 to 3.43; p=0.014) and 4.07 for SLX4 (95% CI 1.34 to 12.4; p=0.013). Deleterious mutations in FBXO10 were associated with a reduced risk of disease (OR 0.27, 95% CI 0.07 to 1.00, p=0.049). However, based on the Bayes false discovery probability, only the association for PALB2 in high-grade serous ovarian cancer is likely to represent a true positive.

Conclusions We have found strong evidence that carriers of PALB2 deleterious mutations are at increased risk of high-grade serous ovarian cancer. Whether the magnitude of risk is sufficiently high to warrant the inclusion of PALB2 in cancer gene panels for ovarian cancer risk testing is unclear; much larger sample sizes will be needed to provide sufficiently precise estimates for clinical counselling.

  • cancer: endocrine
  • genetic epidemiology

Data availability statement

Data are available from the authors on request.

https://creativecommons.org/licenses/by/4.0/

This is an open access article distributed in accordance with the Creative Commons Attribution 4.0 Unported (CC BY 4.0) license, which permits others to copy, redistribute, remix, transform and build upon this work for any purpose, provided the original work is properly cited, a link to the licence is given, and indication of whether changes were made. See: https://creativecommons.org/licenses/by/4.0/.

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Introduction

Rare, predicted deleterious variants in multiple genes have been shown to be associated with a moderate to high risk of epithelial ovarian cancer (EOC). These include the DNA double stand break repair genes BRCA1,1 BRCA,2 BRIP1,3 RAD51C, and RAD51 4, and the mismatch repair genes MSH2 and MSH6.5 6 ANKRD11, FANCM, PALB2 and POLE have recently been reported as possible susceptibility genes.7–9 Multiple common variants conferring weaker risk effects have also been identified,10–17 some of which modify EOC risk in carriers of more highly penetrant gene mutations.18 19

EOC is heterogeneous with five main histotypes: high-grade serous (HGSOC), low-grade serous, endometrioid, clear cell and mucinous ovarian cancer. These have different clinical characteristics and outcomes and are characterised by different germline and somatic genetic changes that result in the perturbation of different molecular pathways. For example, germline mutations in DNA double break repair genes predispose to HGSOC while germline mutations in mismatch repair genes increase risk of the endometrioid and clear cell histotypes.6

The known susceptibility alleles account for less than 50% of the excess familial risk of ovarian cancer, suggesting that other susceptibility genes and alleles exist.15 The unexplained genetic component of risk is likely to be made up of a combination of common genetic variants conferring weak effects and uncommon alleles conferring weak to moderate relative risks (less than 10-fold).

The aim of this study was to identify additional ovarian cancer susceptibility genes using case-control sequencing of candidate genes identified through various approaches including their known function in pathways that are associated with ovarian cancer development and from whole exome sequencing studies (WES) of ovarian cancer cases that have identified putative deleterious mutations in genes not previously evaluated for EOC risk.

Material and methods

Selection of candidate genes

Genes based on known biological function

As several EOC susceptibility genes are involved in DNA double-strand break repair and Fanconi anaemia (FA),8 we selected genes involved in these pathways. FA is a rare genetic disease characterised by chromosomal instability, hypersensitivity to DNA crosslinking agents, defective DNA repair, severe bone marrow failure, cancer susceptibility and many congenital defects. To date, 22 FA genes have been identified, of which eight have previously been evaluated in ovarian cancer case-control studies:3 4 6 8 FANCD1, FNACJ (BRIP1), FANCL, FANCN (PALB2), FANCM, FANCO (RAD51C), FANCS (BRCA1) and FANCV (MAD2L2). We selected nine FA genes not previously studied in ovarian cancer: FANCA, FANCB, FANCC, FANCD2, FANCE, FANCG, FANCI, FANCP (SLX4), FANCW. We also included FANCN (PALB2), which has been studied previously in ovarian cancer3 9 20–22 but its association with EOC risk is equivocal. Eight candidate genes involved in other aspects of DNA repair were also included: ALKBH3, CHEK2, GTF2H4, POLE, POLK, RDM1 and XRCC1.

Genes from whole exome sequencing studies (WES)

Twelve genes (BUB1B, C5orf28, C6, DNAJB4, EXO1, LIG4, MKNK2, MMRN1, PARP1, RAD52, SMC1A and SNRNP200) were selected from WES analysis of EOC cases where putative deleterious (truncating) mutations were identified at a greater frequency in cases compared with publicly available WES data from controls reported by the NHLBI GO Exome Sequencing Project and The Exome Aggregation Consortium databases (http://exac.broadinstitute.org). Germline WES data for EOC cases were available for 412 HGSOC cases from the Cancer Genome Atlas ovarian cancer study; 513 ovarian cancer cases from an Australian case series 6; 97 familial non-BRCA1/BRCA2 ovarian cancer cases from Gilda Radner Familial Ovarian Cancer Registry and 54 ovarian cancer cases from the UK Familial Ovarian Cancer Registry.

Four genes from these WES studies (GANC, KNTC1, PSG6 and UPK2) were selected because more than one family member diagnosed with ovarian cancer from 10 familial cases carried the same truncating mutation in one of these genes.

Finally, 21 genes were selected from analyses of several other unpublished EOC WES studies (personal communications) where the frequency of truncating mutations was greater in cases compared with controls. These genes were ANAPC2, CNKSR1, DUOX1, FBXO10, NAT10, OSGIN1, PAK4, PHF20L1, PIK3C2G, PTGER3, PTX3, RAD54B, RECQL, RIPK3, RNASEL, SMG5, SPHK1, SULT1C2, UHRF2, WNT5A and ZFHX3.

Study subjects

We used case-control data from targeted sequencing, exome and array-based genotyping.

Targeted sequencing

We included 5914 EOC cases and 5479 controls of European ancestries from 19 studies—13 case-control studies, 1 familial ovarian cancer study from Poland, 2 clinical trials and 3 case-only studies (online supplementary table 1).14 HGSOC cases were preferentially plated out for sequencing where possible.

Exome sequencing

We extracted data on the 54 candidate genes from 829 case and 913 controls from two ovarian cancer case-control studies (MDA23–25 and NCO14) for which whole exome sequence data were available (online supplementary table 1).

Variants from genotyping array data

For genes that reached nominal significance in the combined analysis of the targeted sequencing and exome sequencing data, we extracted genotypes of any deleterious variants included on the OncoArray and UK Biobank Axiom Array. These two arrays were used to genotype up to 18 936 controls and 13 288 cases from the Ovarian Cancer Association Consortium (OCAC),15 9725 controls and 858 cases from UK Biobank GWAS (https://www.ukbiobank.ac.uk/), respectively. Samples overlapped with the sequencing studies were excluded from the analysis.

All studies had ethics committee approval, and all participants provided informed consent.

Sequencing methods

Target sequence enrichment followed by sequencing was performed on the coding sequence and splice-sites of ALKBH3, ANAPC2, BUB1B, C5ORF28, C6, CHEK2, CNKSR1, DNAJB4, DUOX1, EXO1, FANCA, FANCB, FANCC, FANCD2, FANCE, FANCG, FANCI, FBXO10, GANC, GTF2H4, KNTC1, LIG4, MKNK2, MMRN1, NAT10, OSGIN1, PAK4, PALB2, PARP1, PHF20L1, PIK3C2G, POLE, POLK, PSG6, PTGER3, PTX3, RAD52, RAD54B, RDM1, RECQL, REV3L, RIPK3, RNASEL, SLX4, SMC1A, SMG5, SNRNP200, SPHK1, SULT1C2, UHRF2, UPK2, WNT5A, XRCC1 and ZFHX3. The target sequence was identified from the NCBI Reference Sequence Database48.48 Fluidigm access arrays as previously described.6 A total of 1663 amplicons were designed to cover the 159 kb target region. Libraries were sequenced using 150 bp paired-end sequencing on the Illumina HiSeq4000 or HiSeq2500.

Sequencing reads were demultiplexed and then aligned against the human genome reference sequence (hg19) using the Burrows-Wheeler Aligner.26 The Genome Analysis Toolkit27 was used for base quality-score recalibration, local indel realignment and variant calling. Finally, ANNOVAR28 was used for variant annotation. Variants were called if (1) genotype information was available from a chip genotype for that sample or (2) the variants were presented in more than one amplicon or (3) read depth ≥15 and alternate allele frequency ≥40% or (4) read depth ≥100 and alternate allele frequency ≥25%. These thresholds were defined using the results from sequencing of positive controls with known variants and genotype information from chip array genotyping of overlapping samples.

We excluded 356 cases and 269 controls because <80% of the target sequence bases had a read depth of at least 15. The average percentage coverage of the genes at 15X read depth ranged from 64% to 99% (online supplementary table 2). The mean sequencing depth for these genes ranged from 130 (IQR 104–152) to 432 (IQR 364–492). Concordance for 111 duplicate pairs was 98% (7384 concordant variants out of total 7572 variants called).

For the exome sequencing, sonication fragmentation was used to fragment DNA samples. Fragments with an average size of 200 bp were selected to generate libraries for sequencing. Agilent SureSelect Clinical Research Exome (CRE) v1 was used for exome enrichment and sequencing was performed on an Illumina HiSeq 4000 using 2×150 bp paired-end reads. Cutadapt (https://doi.org/10.14806/ej.17.1.200) was used to locate and remove residual adapters in reads. FLASH (Fast Length Adjustment of SHort reads)29 was used to merge the overlapped paired-end reads into one read, using default parameters. Reference genome alignment and joint genotype calling according to a pipeline described in Yu et al.30 The coding sequences and splice sites of all 54 genes were extracted. Fifty-three genes with 100% average coverage at 10X were included in the analysis. GTF2H4 was excluded from the analysis, as the average coverage was only 43%.

Deleterious variants were defined as those predicted to result in protein truncation (frameshift indel, splice site, nonsense mutations and start loss) or predicted to be deleterious and/or likely deleterious by Clinvar.31 Any exonic single nucleotide variants within 3 bp of the exon-intron boundary and any intronic variants within 20 bp of the exon-intron boundary at the 5-prime end, and 6 bp at the 3-prime end, were evaluated using the software MaxEntScan to identify those most likely to disrupt splicing.32 Variants with a MaxEntScan score that decreased by more than 40% compared with the reference sequence and having a reference sequence score ≥3 were considered deleterious. Sequencing alignments were confirmed by visual inspection using the Integrative Genomic Viewer.33

Statistical methods

Risk estimation and genotype-phenotype analyses

We used a simple burden test for association between deleterious variants and ovarian cancer risk on a gene-by-gene basis. The burden test was based on unconditional logistic regression adjusted for country (Australia, Denmark, German, Poland, the UK and the USA) and sequencing method (targeted sequencing or exome sequencing). ORs and associated 95% CI were calculated.

Missense variant analyses

We also identified multiple rare (minor allele frequency <1%) missense variants that have an unknown functional effect on the protein. We used the rare admixture likelihood burden test34 to test these variants for association. We excluded any missense variants classified as deleterious and classified the remaining variants by whether or not they are predicted to have a damaging effect on protein function by two out of three prediction tools—SIFT (score <0.05),35 polyphen-236 (classified as probably damaging or damaging) and Provean37 (score≤−2.5). Subjects with a missense variant call rate less than 80% and variants with a call rate less than 80% or with genotype frequencies inconsistent with Hardy-Weinberg equilibrium (p<10–5) were excluded.

Results

Germline deleterious mutations in ovarian cancer cases and controls

Sequencing results were available for 6385 EOC cases and 6115 controls after quality control analysis. The characteristics of these individuals by study are summarised in online supplementary table 1. Most EOC cases were serous histotype (n=6304, 98.7%), of which 5951 were the HGSOC histotype (93.2%).

We identified 629 unique, putative-deleterious variants (online supplementary table 3) in 1051 ovarian cancer cases (967 high-grade serous histotype) and 964 controls. There was a nominally significant higher frequency of mutations in cases compared with controls for POLK, PALB2 and SLX4 and a lower frequency of mutations in cases compared with controls for FBXO10 (table 1). The associated ORs are shown in table 1—for POLK, PALB2 and SLX4 the effect size was slightly larger for HGSOC. The frequency of deleterious variants in the other genes was similar in cases compared with controls (online supplementary table 4). Given the evidence for association of multiple FA genes with EOC risk, we also carried out a burden test to compare the frequency of deleterious variants in any of the eight genes which were not significantly associated with ovarian cancer risks individually (FANCA, FANCB, FANCC, FANCD2, FANCE, FANCG, FANCI and FANCL). A combined analysis will have greater power if multiple genes were associated but the effect sizes too small to detect individually. There was no significant difference in the frequency of deleterious variants in cases (96/6184, 1.6%) and controls (85/6089, 1.4%) (p=0.50).

Table 1

Frequency of mutations and estimated risk of EOC in candidate genes (p<0.05) from targeted sequencing and exome sequencing

Validation analyses in ovarian cancer case-control studies

We also evaluated risk associations between deleterious variants in POLK, PALB2, and SLX4 with EOC risk based on germline genotyping data for 13 277 EOC cases and 18 930 controls from OCAC and for 858 EOC cases and 9725 controls and from UK Biobank. For OCAC samples, data were available for six deleterious non-monomorphic variants in PALB2; for UK Biobank samples, data were available for seven PALB2 and one POLK deleterious variants (table 2, list of variants in online supplementary table 5).

Table 2

Frequency of mutations and estimated risk of EOC in candidate genes for validation chip genotyping data

In OCAC case-control analyses, PALB2 variants showed a non-significant increased risk of EOC (OR 2.10, 95% CI 0.74 to 5.94, p=0.16). The strength of this association increased when the analysis was restricted to 6181 HGSOC cases (OR 3.48, 95% CI 1.10 to 11.1, p=0.035). In UK Biobank, we observed a weak association for PALB2 mutations with EOC risk (OR 3.12, 95% CI 0.87 to 11.2, p=0.081). There was no evidence of risk association for mutations in POLK (table 2).

We then performed a meta-analysis by combining the targeted sequencing, WES and chip genotyping data. Taken together, putative deleterious mutations were associated with increased risk for PALB2 (OR 2.60, 95% CI 1.45 to 4.64; p=0.0013), POLK (OR 1.77, 95% CI 1.07 to 2.93; p=0.026) and SLK4 (OR 3.37, 95% CI 1.17 to 9.70, p=0.024) and decreased risk for FBXO10 (95% CI 0.07 to 1.00; p=0.049). After stratifying cases by histological subtype, the estimated risks were higher for HGSOC for PALB2 (OR 3.01, 95% CI 1.59 to 5.68; p=0.00068), POLK (OR 1.99, 95% CI 1.15 to 3.43; p=0.014) and SLK4 (OR 3.92, 95% CI 1.33 to 11.5; p=0.013).

We used an approximate Bayes factor to calculate the Bayes false discovery probability (BFDP) described by Wakefield38 for PALB2, SLX4, POLK and FBXO10 based on several different priors and assuming that the associated risk is unlikely to be greater than an OR of 4 (table 3). The evidence for association of PALB2 was strong with a BFDP of less than 15% when the prior on the alternative hypothesis is 0.1. The nominally significant associations for the other three genes are likely to be false positives.

Table 3

Bayes false discovery probability for the associations reported for PALB2, SLX4, POLK and FBXO10 from the meta-analysis of all the available data

Predicting the functional impact of missense coding variants

Combining the whole exome and targeted sequencing data, we identified 5265 unique missense variants with minor allele frequency less than 1% in the 54 genes (online supplementary table 6). We used the in silico software programs SIFT, Polyphen-2 and Provean to evaluate the predicted impact of these variants on protein function for each gene. Of the 5265 variants, 2111 were classified as ‘deleterious’ based on at least 2 out of 3 of these classifiers. We found weak evidence for association with increased EOC risk for rare missense variants in DUOX1 and PAK4 using burden testing (p=0.015 and 0.025, respectively) (online supplementary table 7); for DUOX1, the strength of this association improved when the analyses were restricted to the HGSOC histotype (p=0.0061). When we performed the same analyses for 1493 very rare variants (MAF<0.001), we observed significant association for missense variants in DUOX1 and FANCE (p=0.015 and 0.034, respectively).

Discussion

We have evaluated the association between putative deleterious variants in 54 genes with the risk of HGSOC through a combination of whole exome and targeted sequencing analysis in 5951 cases and 6115 controls of broad European ancestries. We found evidence for four genes—PALB2, POLK, SLX4 and FBXO10—associated with HGSOC risk. Association analysis in an additional 14 135 ovarian cancer cases and 28 655 controls genotyped through OCAC and the UK Biobank provided further support for PALB2 as a HGSOC susceptibility gene.

The probability that a genetic association deemed statistically significant is a false positive depends on the prior of the null hypothesis and the power of the study to detect an effect size plausible under the alternative hypothesis. We calculated Wakefield’s BFDP38 based on several different priors to further evaluate the likelihood that PALB2, POLK, SLX4 and FBXO10 are EOC susceptibility genes. If we assume the prior on the alternative to be 1 in 10 or 1 in 20, the BFDPs for the association of deleterious variants in PALB2 with HGSOC are 0.14 and 0.26, respectively. These moderately strong priors are reasonable given the evidence for the association from previously published studies.20 Two studies have reported nominally significant associations for PALB2 with OR 4.4 (95% CI 2.1 to 9.1)20 and (2.87, 95% CI 1.61 to 4.74).21 Kotsopoulos and colleagues reported an increased risk that was not significant (OR, 4.55, 95% CI 0.76 to 27) and, in a subset of the samples included in this study, we also found a non-significant increase in risk (OR 3.2, 95% CI 0.86 to 12).3

It is possible that cryptic population structure could cause spurious association in these data. Principal component analysis is one approach to reducing the risk of such bias, but there are too few common variants in the regions covered by the targeted sequencing panel to do a principal component analysis and chip genotyping data that would be required for such an analysis is not available for all the samples. Adjusting for country of origin and restricting the analysis to samples from individuals of broad European ancestries should reduce any problem with population stratification.

We lacked the statistical power to identify susceptibility genes conferring relative risks of less than 2 (figure 1). Our use of targeted sequencing and a definition of deleterious variants as those that likely truncate the protein product will have probably underestimated the true prevalence of deleterious variants in these genes. Incomplete coverage of each gene will have missed some small indels and single nucleotide variants. Amplicon based sequencing will also miss large deletions and rearrangements, which are relatively common in some genes.39 40 Finally, any functional mutations in the non-coding region of these genes will have been missed.41

Figure 1

Power to detect association for 5951 cases and 6385 controls at a Type I error rate of 0.0001 by deleterious variant carrier frequency and effect size (OR).

Some commercial gene-panel tests for hereditary breast-ovarian cancer already include PALB2. However, whether there is clinical utility in testing unaffected women for deleterious mutations in PALB2 is not clear given the uncertainties in the risk estimates for this gene. There is no consensus over the risk threshold at which preventative surgery should be offered; many cancer genetics clinics in the UK will refer women if their predicted lifetime risk of EOC is greater than 10%. Others have suggested that the risk threshold should be lower given the low risk nature of the intervention; prophylactic surgery has been shown to be cost-effective for women at a lifetime risk of 5%. Recent updates to the US National Comprehensive Cancer Network Guidelines recommend considering risk reducing salpingo-oophorectomy in carriers of moderate risk genes if the lifetime risk of such mutation carriers exceeds 2.6%. Based on our data and population data for ovarian cancer incidence in England and Wales in 2016, the cumulative risk of ovarian cancer by age 80 for a carrier of a deleterious PALB2 mutation is 3.2% (figure 2). Thus, a woman carrying a PALB2 deleterious mutation would be eligible for prophylactic surgery. However, the CIs for this estimate range from 1.8% to 5.7%. Very large, well-designed case-control studies will be required to provide more precise, unbiased estimates of risk suitable for clinical counselling.

Figure 2

Estimated cumulative risk (%) of ovarian cancer in a PALB2 deleterious variant carrier compared with population risks for England and Wales, 2016.

In summary, we have found relatively strong evidence that deleterious germline mutations in PALB2 are associated with a moderate increase in the risk of HGSOC with weak evidence for POLK, SLX4 and FBXO10. Mutations in the other 50 genes we tested are unlikely to contribute meaningfully to genetic predisposition to HGSOC. This study highlights the importance of large sample sizes needed to obtain risk estimates with the precision necessary for clinical use.

Data availability statement

Data are available from the authors on request.

Acknowledgments

We thank all the study participants who contributed to this study and all the researchers, clinicians and technical and administrative staff who have made possible this work. In particular, we thank: the clinical and scientific collaborators listed at www.aocstudy.org/ (AOCS) and opalstudy.qimrberghofer.edu.au (OPL).

References

Footnotes

  • HS and EMD contributed equally.

  • SR, SG and PP contributed equally.

  • Contributors HS planned the study, co-ordinated the sequencing, collated the results and drafted the manuscript. EDM carried out the analysis of the sequencing data. JT carried out the biostatistical analyses. GC-T, DDB, NT, JB, TG, KH, AP, EVO, JD, HRH, MAR, MD, TD, NVB, FM, KM, KO, RN, BYK, JLe, AJe, SKK, EH, CL, Miquel Angel Pujana, JC, RV, SJW, MH, CH, DL, XW, YY, JBP, DAL, JMS, AB, PMW, CC, JG, AJa, JLu, JA, CJK, IC, UM, CLP, AHW and AdF were responsible for data and sample collection for the contributing studies. MJR co-ordinated the collection of the OCAC phenotype data. Maria Intermaggio and PH carried out the targeted sequencing. IGC, EG, SR, SG and PP planned the study.

  • Funding American Cancer Society: SIOP-06-258-01-COUN. Cancer Councils of New South Wales, Victoria, Queensland, South Australia and Tasmania and Cancer Foundation of Western Australia: Multi-State Applications 191, 211 and 182. Cancer Institute NSW: 12/RIG/1-17, 15/RIG/1-16. Cancer Research UK: C490/A10119, C490/A10124, C490/A16561, Cambridge Cancer Centre. Kræftens Bekæmpelse: 94 222 52. Medical Research Council: MR_UU_12023. U.S. Department of Health and Human Services, National Institutes of Health, National Cancer Institute: K07CA080668, K22 CA193860, MO1RR000056, P50CA159981, R01CA112523, R01CA122443, P30CA15083, P50CA136393, R01CA76016, R01CA126841, R01CA178535, R01CA188943, R01CA61107, R01CA87538, R01CA95023. U.S. Department of Health and Human Services, National Institutes of Health, National Center for Advancing Translational Sciences: UL1TR000124. National Health and Medical Research Council of Australia 199600, 310670, 400281, 400413, 628903, APP1025142. National Institutes of Health Research: Cambridge Biomedical Research Centre, University College London Hospitals Biomedical Research Centre. The Eve Appeal: UKOPS Study. U.S. Army Medical Research and Materiel Command: DAMD17-01-1-0729, DAMD17-02-1-0669, DAMD17-02-1-06. U.S Department of Defense Ovarian Cancer Research Program: W81XWH-07-0449. The University of Cambridge has received salary support in respect of PDPP from the NHS in the East of England through the Clinical Academic Reserve. SG is a recipient of the Barth Family Chair in Cancer Genetics.

  • Competing interests None declared.

  • Provenance and peer review Not commissioned; externally peer reviewed.