Prevalence of Germline BAP1, CDKN2A, and CDK4 Mutations in an Australian Population-Based Sample of Cutaneous Melanoma Cases

Lauren G. Aoude; Michael Gartside; Peter Johansson; Jane M. Palmer; Judith Symmons; Nicholas G. Martin; Grant W. Montgomery; Nicholas K. Hayward

doi:10.1017/thg.2015.12

Prevalence of Germline BAP1, CDKN2A, and CDK4 Mutations in an Australian Population-Based Sample of Cutaneous Melanoma Cases

Published online by Cambridge University Press: 19 March 2015

Grant W. Montgomery and

Nicholas K. Hayward

Show author details

Lauren G. Aoude*: Affiliation:
QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia University of Queensland, Brisbane, Queensland, Australia
Michael Gartside: Affiliation:
QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Peter Johansson: Affiliation:
QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Jane M. Palmer: Affiliation:
QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Judith Symmons: Affiliation:
QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Nicholas G. Martin: Affiliation:
QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Grant W. Montgomery: Affiliation:
QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia
Nicholas K. Hayward: Affiliation:
QIMR Berghofer Medical Research Institute, Brisbane, Queensland, Australia University of Queensland, Brisbane, Queensland, Australia
*: address for correspondence: Lauren G. Aoude, QIMR Berghofer Medical Research Institute, 300 Herston Road, Herston QLD 4006, Australia. E-mail: Lauren.Aoude@qimrberghofer.edu.au

Article contents

Abstract
Materials and Methods
Results
Discussion
Supplementary Material
References

Abstract

Mutations in Cyclin-Dependent Kinase Inhibitor 2A (CDKN2A) and Cyclin-Dependent Kinase 4 (CDK4) contribute to susceptibility in approximately 40% of high-density cutaneous melanoma (CMM) families and about 2% of unselected CMM cases. BRCA-1 associated protein-1 (BAP1) has been more recently shown to predispose to CMM and uveal melanoma (UMM) in some families; however, its contribution to CMM development in the general population is unreported. We sought to determine the contribution of these genes to CMM susceptibility in a population-based sample of cases from Australia. We genotyped 1,109 probands from Queensland families and found that approximately 1.31% harbored mutations in CDKN2A, including some with novel missense mutations (p.R22W, p.G35R and p.I49F). BAP1 missense variants occurred in 0.63% of cases but no CDK4 variants were observed in the sample. This is the first estimate of the contribution of BAP1 and CDK4 to a population-based sample of CMM and supports the previously reported estimate of CDKN2A germline mutation prevalence.

Keywords

BAP1 CDK4 CDKN2A cutaneous melanoma germline mutation

Type: Articles
Information: Twin Research and Human Genetics , Volume 18 , Issue 2 , April 2015 , pp. 126 - 133

DOI: https://doi.org/10.1017/thg.2015.12 [Opens in a new window]
Copyright: Copyright © The Author(s) 2015

Many environmental and genetic factors play a part in melanomagenesis. While exposure to ultraviolet radiation plays a significant role in melanoma development, an underlying genetic predisposition also contributes to an individual's risk. Studies have shown that ~10% of cutaneous malignant melanoma (CMM) cases occur in people that have a family history of melanoma (Gruis et al., Reference Gruis, van der Velden, Sandkuijl, Prins, Weaver-Feldhaus, Kamb and Frants1995; Hussussian et al., Reference Hussussian, Struewing, Goldstein, Higgins, Ally, Sheahan and Dracopoli1994; MacGeoch et al., Reference MacGeoch, Bishop, Bataille, Bishop, Frischauf, Meloni and Spurr1994; Soufir et al., Reference Soufir, Avril, Chompret, Demenais, Bombled, Spatz and Bressac-de Paillerets1998; Walker et al., Reference Walker, Hussussian, Flores, Glendening, Haluska, Dracopoli and Fountain1995; Zuo et al., Reference Zuo, Weger, Yang, Goldstein, Tucker, Walker and Dracopoli1996). Known high-risk genes account for susceptibility in a proportion of these families. The major CMM predisposition locus CDKN2A encodes two tumor suppressors, p16INK4A and p14ARF, that inhibit progression of cancer cells by inducing senescence or apoptosis, respectively (de Snoo & Hayward, Reference de Snoo and Hayward2005; Palmieri et al., Reference Palmieri, Capone, Ascierto, Gentilcore, Stroncek, Casula and Ascierto2009). CDKN2A is thus involved in two of the most important tumor suppressor pathways, the p53 and the retinoblastoma (RB) pathways.

The largest study of germline mutations in CDKN2A in families to date was conducted by the International Melanoma Genetics Consortium (GenoMEL), in which 466 families from North America, Europe, Asia, and Australia were genotyped for mutations in CDKN2A and CDK4 (Goldstein et al., Reference Goldstein, Chan, Harland, Gillanders, Hayward, Avril and Yakobson2006). They found 41% of high-density families (defined by case-load depending on the region of origin) carried germline mutations in either p16 (38%), p14 (1.5%) or CDK4 (1%). Overall, 57 unique mutations in p16 were attributed to increased CMM risk. In contrast, only two variants in CDK4 have been attributed to CMM risk; p.R24C and p.R24H (Soufir et al., Reference Soufir, Avril, Chompret, Demenais, Bombled, Spatz and Bressac-de Paillerets1998; Zuo et al., Reference Zuo, Weger, Yang, Goldstein, Tucker, Walker and Dracopoli1996). A study into the prevalence of CDKN2A and CDK4 mutations in CMM cases from a Greek hospital-based sample found that 5% of cases (16 of 320) harbored a mutation in one of these genes (Nikolaou et al., Reference Nikolaou, Kang, Stratigos, Gogas, Latorre, Gabree and Tsao2011). But, to date, there are only two published studies determining the prevalence of high-risk predisposition loci in population-based samples of CMM cases. The Genes Environment and Melanoma (GEM) study genotyped probands from nine different geographical regions in the USA, Canada, Italy, and Australia (Begg et al., Reference Begg, Orlow, Hummer, Armstrong, Kricker, Marrett and Berwick2005). They discovered 65 CDKN2A mutation carriers in a sample of 3,550 affected individuals, equating to a population frequency of ~2%. A second study looked at the contribution of CDKN2A to melanoma in a population-based sample of cases (N = 482) from Queensland (Aitken et al., Reference Aitken, Welch, Duffy, Milligan, Green, Martin and Hayward1999), from which it was estimated that CDKN2A mutations occur in 0.2% of population-based Queensland CMM cases (Aitken et al., Reference Aitken, Welch, Duffy, Milligan, Green, Martin and Hayward1999).

BAP1 is a tumor suppressor gene located on chromosome 3 that has also been associated with predisposition to CMM. In a seminal study, somatic BAP1 mutations were first observed in a panel of sporadic UMM cases; notably, a single UMM case also carried a germline BAP1 mutation (Harbour et al., Reference Harbour, Onken, Roberson, Duan, Cao, Worley and Bowcock2010). Since then, BAP1 has been linked to predisposition of a spectrum of cancer types extending beyond UMM to include CMM, mesothelioma, renal cell carcinoma, basal cell carcinoma, as well as a distinct type of benign melanocytic tumor (Abdel-Rahman et al., Reference Abdel-Rahman, Pilarski, Cebulla, Massengill, Christopher, Boru and Davidorf2011; Aoude et al., Reference Aoude, Vajdic, Kricker, Armstrong and Hayward2013; Carbone et al., Reference Carbone, Ferris, Baumann, Napolitano, Lum, Flores and Yang2012; Cheung et al., Reference Cheung, Talarchek, Schindeler, Saraiva, Penney, Ludman and Testa2013; de la Fouchardiere et al., Reference de la Fouchardiere, Cabaret, Savin, Combemale, Schvartz, Penet and Bressac-de Paillerets2014; Harbour et al., Reference Harbour, Onken, Roberson, Duan, Cao, Worley and Bowcock2010; Hoiom et al., Reference Hoiom, Edsgard, Helgadottir, Eriksson, All-Ericsson, Tuominen and Hansson2013; Njauw et al., Reference Njauw, Kim, Piris, Gabree, Taylor, Lane and Tsao2012; Popova et al., Reference Popova, Hebert, Jacquemin, Gad, Caux-Moncoutier, Dubois-d’Enghien and Stern2013; Testa et al., Reference Testa, Cheung, Pei, Below, Tan, Sementino and Carbone2011; Wadt et al., Reference Wadt, Aoude, Johansson, Solinas, Pritchard, Crainic and Hayward2014; Wiesner et al., Reference Wiesner, Obenauf, Murali, Fried, Griewank, Ulz and Speicher2011). Population-based and clinic-based prevalence studies show that BAP1 germline mutations contribute to only a small proportion of UMM cases overall (3–4%; Aoude et al., Reference Aoude, Vajdic, Kricker, Armstrong and Hayward2013; Njauw et al., Reference Njauw, Kim, Piris, Gabree, Taylor, Lane and Tsao2012) but the contribution of such mutations to a population based-sample of CMM cases has not been reported.

The primary aim of this study was to more fully quantify the contribution of constitutional CDKN2A and CDK4 mutations in an Australian population-based sample of CMM cases. A secondary aim was to determine the prevalence of germline BAP1 mutations in this sample.

Materials and Methods

Ethics

Written consent was obtained for each participant in this study. Ethics approval was obtained from the QIMR Berghofer Human Research Ethics Committee (HREC).

Study Cohort

Samples were ascertained as part of the Q-MEGA project, a population-based study from Queensland investigating the associations between genes and environment in CMM development (Baxter et al., Reference Baxter, Hughes, Kvaskoff, Siskind, Shekar, Aitken and Whiteman2008). Q-MEGA is made up of four distinct CMM case sample collections: childhood, adolescent, men over 50 years, and the Queensland Familial Melanoma Project (QFMP; Aitken et al., Reference Aitken, Green, MacLennan, Youl and Martin1996). Individuals who presented with histologically confirmed CMM and were reported to the Queensland Cancer Registry between the years 1982 and 1990 were approached to participate in the QFMP study (N = 12,006). This accounted for approximately 95% of CMM cases diagnosed in Queensland over this period (Aitken et al., Reference Aitken, Green, MacLennan, Youl and Martin1996). Cases were asked to fill out a questionnaire pertaining to family history, pigmentation, freckling, mole count, and likelihood of sunburn. In the instance where an individual had a family history of melanoma, the first degree relatives and affected cases were also ascertained. A follow-up study in 2002–2005 collected updated data and additional blood samples. A total of 1,897 individual families were sampled and stratified into three categories according to a standardized family risk index, previously described (Aitken et al., Reference Aitken, Duffy, Green, Youl, MacLennan and Martin1994). Generally, although there were a few exceptions, individuals with no family history of CMM were categorized as low-risk (N = 1,392), two-case families were categorized as intermediate-risk (N = 414) and families with three or more cases were categorized as high-risk (N = 91). Additionally, twins with CMM collected in Queensland and New South Wales were included (Shekar et al., Reference Shekar, Duffy, Youl, Baxter, Kvaskoff, Whiteman and Martin2009). For the current study a random selection of 1,109 cases from across the 2,599 probands in Q-MEGA was used (Table 1). Selection was based on the order in which DNA samples were replated into 384 well plates.

TABLE 1 Number of Samples Sequenced for CDKN2A and BAP1 Variants

~ Aitken et al., (Reference Aitken, Welch, Duffy, Milligan, Green, Martin and Hayward1999); *Whiteman et al. (Reference Whiteman, Milligan, Welch, Green and Hayward1997); ^BAP1 sequencing only.

Sample Preparation

Blood samples were obtained from 2,599 probands (Table 1) ascertained through the Q-MEGA studies (Baxter et al., Reference Baxter, Hughes, Kvaskoff, Siskind, Shekar, Aitken and Whiteman2008). Genomic DNA was extracted using a standard salting out method (Miller et al., Reference Miller, Dykes and Polesky1988).

Targeted Sequencing of CDKN2A and BAP1 using the Ion Torrent PGM

Melanoma cases were assessed for variants in BAP1 and CDKN2A in a targeted sequencing approach. Using Ion AmpliSeq library kits (Life Technologies, CA, USA), 10 ng of genomic DNA from each proband were amplified using custom-designed primer pools. The panel was designed to generate coverage of 40X across all regions with amplicon lengths of 150 bp to 250 bp. BAP1 and CDKN2A had coverage of 96% and 97%, respectively. Ion Xpress barcode adapters 1–64 were used to pool samples. Unamplified libraries were purified using Agencourt Ampure XP reagent (Beckman Coulter, CA, USA) in order to eliminate fragments < 100 bp and increase the proportion of on-target reads. Libraries were equalized to ~100 pM using Ion Library Equalizer kits then combined into a single sample. A portion of the library (4 μL) was then diluted in 21 μL nuclease-free water to create a working stock. Using OT2 200 Kits (Life Technologies, CA, USA), clonal amplification and template enrichment of the Ion Sphere particles was performed. The template quality was assessed using a Qubit 2.0 (Life Technologies, CA, USA). Finally, Ion 318v2 chips were run on a Personal Genome Machine (Life Technologies, CA, USA) with 500 run flows per chip.

Overall, 1,109 samples had mean sequence coverage of 30X and therefore the sequencing of these samples was considered to be of sufficient depth to give accurate reads. Sequence data were analyzed using Torrent Suite software (Life Technologies, CA, USA). In order to minimize the false positive rates, filtering criteria were applied to the output. First, variants were required to have minimum of four reads for the reference and four reads for the alternative alleles. The variant allele also had to comprise at least 20% of the total read count. Quality score had to be > 40. Synonymous variants were excluded. Variants occurring commonly in the NHLBI Exome Sequencing Project (ESP6500; minor allele frequency (MAF) > 0.01) were also excluded as they are unlikely to be high-risk predisposition variants, but rather, common population polymorphisms. This sculpted the final list of variants, which were verified using Sanger sequencing. As a previous study has reported the CDKN2A mutations in the QFMP high-risk cohort (Aitken et al., Reference Aitken, Welch, Duffy, Milligan, Green, Martin and Hayward1999), CDKN2A genotyping of these samples was not repeated here, but the published results were included in the overall prevalence statistics. Sanger sequencing was used to validate the CDKN2A and BAP1 variants identified through targeted sequencing. See Supplementary Table S1 for the list of primers used. Supplementary material is available on the Cambridge Journals Online website.

CDK4 Genotyping using the Sequenom MassArray

The two known familial melanoma variants in CDK4 (p.R24C and p.R24H) were genotyped in the QFMP probands using a Sequenom iPLEX gold assay (Sequenom Bioscience, CA, USA). The MassArray designer software was used to design the forward, reverse and extension primers for p.R24C (acgttggatgagtggctgaaattggtgtcg, acgttggatgtcacactcttgagggccac, and gcactgtggggatcac) and p.R24H (acgttggatgagtggctgaaattggtgtcg, acgttggatgtcacactcttgagggccac, and ttggccactgtggggatca). IPLEX Gold PCR amplification reactions were set up according to standard manufacturer protocols. Cluster plots were analyzed using Typer Analyzer software 4.0.

Results

Targeted sequencing of an unselected population of CMM cases from Queensland, Australia revealed 6 of 1,055 cases harbor a missense variant in CDKN2A (Table 2). We report a single incidence of each of the following variants occurring in p16 (NM_000077): p.L16P, p.R22W, p.G35R, and p.I49F. We also report two incidences of p.G101W (rs104894094), a common founder mutation in European melanoma populations (Goldstein et al., Reference Goldstein, Chan, Harland, Gillanders, Hayward, Avril and Yakobson2006). We found a recurrent mutation, p.A121T (rs199888003), in p14 (NM_058195) in two cases. As this residue is not overly conserved in primates (Rhesus, Figure 1), this is likely to be a non-deleterious mutation and is therefore not included in the overall prevalence statistics. Seventy-two cases carried the well-documented CDKN2A p.A148T polymorphism, giving it a MAF of 0.0353. The MAF reported for this variant in the European American cohort (N = 4,300) of the ESP6500 is 0.0225, which correlates well with the occurrence in our sample. CDKN2A p.A148T has also been omitted from the prevalence statistics. Of the variants seen here, three are novel and have not been previously reported to the Leiden Open Variation Database (p.R22W, p.G35R, and p.I49F). All occur at evolutionarily conserved amino acids (Figure 1), and although none of these variants have been reported as somatic mutations in CMM in the COSMIC (catalogue of somatic mutations in cancer) database, p.G35R has been seen in ovarian and pancreatic cancers (Table 3).

TABLE 2 Variants in BAP1 and CDKN2A Identified Through Targeted Sequencing

*European American population; NA = not available; GERP++ is an estimate of the constrained elements in the human genome.

TABLE 3 CDKN2A Mutations Reported in Publically Available Databases LOVD and COSMIC

LOVD = Leiden open variation database 3.0, which lists published germline CDKN2A variants in cancer; COSMIC = catalogue of somatic mutations in cancer v68; CMM = cutaneous malignant melanoma; CNS = central nervous system.

Note: Conservation of protein altering missense variants in BAP1 and CDKN2A.

FIGURE 1 Conservation across species.

The incidence of CDKN2A mutation in the QFMP high-risk probands has been reported previously (Supplementary Table S2; Aitken et al., Reference Aitken, Welch, Duffy, Milligan, Green, Martin and Hayward1999). We did not re-genotype CDKN2A in these samples here, as the results for over 95% of the cases are in the report by Aitken et al. (Reference Aitken, Welch, Duffy, Milligan, Green, Martin and Hayward1999). In that study, Sanger sequencing found that 9 of 87 probands had a CDKN2A mutation. When these results are combined with those of the current study, we find that 1.31% (15 of 1,142) of the Australian population-based CMM sample carries a CDKN2A mutation affecting p16. The childhood cohort has also been partly reported on previously, with the p.L16P mutation being found in a case presenting with multiple primary melanomas by the age of 12 (Whiteman et al., Reference Whiteman, Milligan, Welch, Green and Hayward1997), the results of which have been replicated here.

Genotyping of CDK4 p.R24C and p.R24H showed that no proband in this population-based sample is a carrier of a melanoma-associated CDK4 mutation.

Targeted sequencing of an unselected population of CMM cases from Queensland, Australia found 7 out of 1,109 cases harbor a missense variant in BAP1 (Table 2). Two novel variants occurred in the ubiquitin carboxy-terminal hydrolase domain (p.G121R and p.R150C), one novel variant occurred in the BARD1 interacting domain (p.P222T), two novel variants occurred outside of any known domain (p.N446I and p.P519A) and a recurrent variant (p.V604M) was seen in two probands in the BRCA1 interacting domain (Figure 2). In our study, the MAF for p.V604M is 0.0018, compared to the MAF reported in the ESP6500 of 0.000154. Overall, 0.63% of cases harbored a missense variant in BAP1.

Note: All germline variants found in the population-based sample of cutaneous melanoma cases are shown in relation to their position in the protein. The arrows show the position of germline variants. UCH is the ubiquitin carboxy-terminal hydrolase domain; HBM is the HCFC1 binding motif; ULD is the UCH37-like domain. Binding sites for genes BARD1, BRCA1 and YY1 are depicted by their gene symbols.

FIGURE 2 Germline variants in functional domains and protein interaction regions of BAP1.

Since some missense mutations in BAP1 have been shown to affect alternative splicing (Popova et al., Reference Popova, Hebert, Jacquemin, Gad, Caux-Moncoutier, Dubois-d’Enghien and Stern2013; Wadt et al., Reference Wadt, Choi, Chung, Kiilgaard, Heegaard, Drzewiecki and Brown2012), the Automated Splice Site and Exon Definition Analyses (ASSEDA) online tool (https://splice.uwo.ca), was used to assess whether BAP1 mutations in this study might create cryptic acceptor/donor sites (Rogan et al., Reference Rogan, Svojanovsky and Leeder2003). No splice site alterations were predicted. Mutations in BAP1 occurred in highly conserved residues across species (Figure 1) and the five novel mutations (p.G121R, p.R150C, p.P222T, p.N446I, and p.P519A) were predicted to be damaging by SIFT and/or Polyphen 2 (Table 2).

Discussion

We identified CDKN2A missense mutations in 0.57% of melanoma cases in the intermediate, low, twin, childhood, adolescent, and men over 50 cohorts. When this data is combined with that for the QFMP high-risk group published by Aitken et al. (Reference Aitken, Welch, Duffy, Milligan, Green, Martin and Hayward1999), 1.31% of the overall Queensland population-based sample of CMM cases carried a CDKN2A mutation. The estimate for CDKN2A we report here is in keeping with that reported (~2%) in the GEM study (Begg et al., Reference Begg, Orlow, Hummer, Armstrong, Kricker, Marrett and Berwick2005). As might be expected, since CDKN2A mutation has been associated with an increased risk of development of cancer in general (Mukherjee et al., Reference Mukherjee, Delancey, Raskin, Everett, Jeter, Begg and Investigators2012), CDKN2A mutation-positive families in this study are enriched for other cancers (Tables 3 and 4), although absolute numbers are too low to show statistically significant association with any particular cancer type other than melanoma. Furthermore, because the number of mutations we observe is low, there is no statistical difference between the individual Q-MEGA population groups.

TABLE 4 Summary of Cancers in Families With Germline BAP1 and CDKN2A Mutations

CMM = cutaneous malignant melanoma.

The CDKN2A p.G35R mutation has been reported to occur somatically in the COSMIC database, but here we report for the first time its occurrence in the germline of an individual presenting with melanoma and colorectal cancer. A study using both functional and computational prediction of p16 mutations has found that the pathogenicity of this mutation is uncertain (Scaini et al., Reference Scaini, Minervini, Elefanti, Ghiorzo, Pastorino, Tognazzo and Tosatto2014). The p.A148T variant was observed at a frequency of 6.8% in the Queensland melanoma cases. This substitution is generally not thought to be deleterious, but the functional effect of this variant has been debated in the literature (Debniak et al., Reference Debniak, Scott, Huzarski, Byrski, Rozmiarek, Debniak and Lubinski2005; Spica et al., Reference Spica, Portela, Gerard, Formicone, Descamps, Crickx and Melan2006). It has been shown to occur more frequently in Celtic populations and therefore its potential association with CMM risk may be due to its prevalence in a more melanoma-prone population (Aitken et al., Reference Aitken, Welch, Duffy, Milligan, Green, Martin and Hayward1999).

We found that 0.63% of CMM cases harbored germline missense mutations in BAP1. This mutation rate is similar to that reported by Njauw et al. (Reference Njauw, Kim, Piris, Gabree, Taylor, Lane and Tsao2012) when they screened a hospital-based sample of 193 CMM families for BAP1 mutation and reported one truncating mutation (0.5%). To date, all disease-associated variants in BAP1 have been shown to truncate the protein. The variants we report here are all missense mutations that occur at highly conserved residues in mammals (Figure 2). None were predicted to alter splicing; thus, at this stage it is not clear whether they are responsible for melanoma susceptibility in these individuals, or if they represent rare, benign polymorphisms.

We did not observe any mutations in CDK4. This result is in keeping with the low frequency of mutations of this gene reported in the literature. To date, only 17 families worldwide have been documented to carry CDK4 mutations (Puntervoll et al., Reference Puntervoll, Yang, Vetti, Bachmann, Avril, Benfodda and Molven2013; Soufir et al., Reference Soufir, Avril, Chompret, Demenais, Bombled, Spatz and Bressac-de Paillerets1998; Zuo et al., Reference Zuo, Weger, Yang, Goldstein, Tucker, Walker and Dracopoli1996). All reported pathogenic mutations in p14 have been splice mutations, whole gene deletions or insertions (Harland et al., Reference Harland, Taylor, Chambers, Kukalizch, Randerson-Moor, Gruis and Bishop2005; Mistry et al., Reference Mistry, Taylor, Randerson-Moor, Harland, Turner, Barrett and Bishop2005; Randerson-Moor et al., Reference Randerson-Moor, Harland, Williams, Cuthbert-Heavens, Sheridan, Aveyard and Bishop2001; Rizos et al., Reference Rizos, Puig, Badenas, Malvehy, Darmanian, Jimenez and Kefford2001). Currently, no pathogenic missense mutations are known to occur in p14.

In summary, we report three novel variants in CDKN2A and three previously reported mutations, along with seven novel missense variants in BAP1. Germline mutations that we observe for the two genes combined (~2%) thus account for only a small proportion of all CMM cases in this population. This suggests that genes other than the high-penetrance familial melanoma loci are responsible for the bulk of CMM susceptibility in the general population.

Acknowledgments

The authors would like to thank the participants of this study. This project was funded by the National Health and Medical Research Council of Australia (NHMRC). LGA received support from an Australia and New Zealand Banking Group Limited Trustees PhD scholarship. NKH and GWM are supported by fellowships from the NHMRC.

Supplementary Material

To view supplementary material for this article, please visit http://dx.doi.org/10.1017/thg.2015.12

References

Abdel-Rahman, M. H., Pilarski, R., Cebulla, C. M., Massengill, J. B., Christopher, B. N., Boru, G., . . . Davidorf, F. H. (2011). Germline BAP1 mutation predisposes to uveal melanoma, lung adenocarcinoma, meningioma, and other cancers. Journal of Medical Genetics, 48, 856–859.Google Scholar

Aitken, J. F., Duffy, D. L., Green, A., Youl, P., MacLennan, R., & Martin, N. G. (1994). Heterogeneity of melanoma risk in families of melanoma patients. American Journal of Epidemiology, 140, 961–973.Google Scholar

Aitken, J. F., Green, A. C., MacLennan, R., Youl, P., & Martin, N. G. (1996). The Queensland familial melanoma project: Study design and characteristics of participants. Melanoma Research, 6, 155–165.CrossRef Google Scholar PubMed

Aitken, J., Welch, J., Duffy, D., Milligan, A., Green, A., Martin, N., . . . Hayward, N. (1999). CDKN2A variants in a population-based sample of Queensland families with melanoma. Journal of the National Cancer Institute, 91, 446–452.Google Scholar

Aoude, L. G., Vajdic, C. M., Kricker, A., Armstrong, B., & Hayward, N. K. (2013). Prevalence of germline BAP1 mutation in a population-based sample of uveal melanoma cases. Pigment Cell & Melanoma Research, 26, 278–279.CrossRef Google Scholar

Baxter, A. J., Hughes, M. C., Kvaskoff, M., Siskind, V., Shekar, S., Aitken, J. F., . . . Whiteman, D. C. (2008). The Queensland study of melanoma: Environmental and genetic associations (Q-MEGA); study design, baseline characteristics, and repeatability of phenotype and sun exposure measures. Twin Research and Human Genetics, 11, 183–196.Google Scholar

Begg, C. B., Orlow, I., Hummer, A. J., Armstrong, B. K., Kricker, A., Marrett, L. D., . . . Berwick, M. (2005). Lifetime risk of melanoma in CDKN2A mutation carriers in a population-based sample. Journal of the National Cancer Institute, 97, 1507–1515.Google Scholar

Carbone, M., Korb Ferris, L., Baumann, F., Napolitano, A., Lum, C. A., Flores, E. G., . . . Yang, H. (2012). BAP1 cancer syndrome: Malignant mesothelioma, uveal and cutaneous melanoma, and MBAITs. Journal of Translational Medicine, 10, 179.Google Scholar

Cheung, M., Talarchek, J., Schindeler, K., Saraiva, E., Penney, L. S., Ludman, M., . . . Testa, J. R. (2013). Further evidence for germline BAP1 mutations predisposing to melanoma and malignant mesothelioma. Cancer Genetics, 206, 206–210.Google Scholar

Debniak, T., Scott, R. J., Huzarski, T., Byrski, T., Rozmiarek, A., Debniak, B., . . . Lubinski, J. (2005). CDKN2A common variants and their association with melanoma risk: A population-based study. Cancer Research, 65, 835–839.CrossRef Google Scholar PubMed

de la Fouchardiere, A., Cabaret, O., Savin, L., Combemale, P., Schvartz, H., Penet, C., . . . Bressac-de Paillerets, B. (2014). Germline BAP1 mutations predispose also to multiple basal cell carcinomas. Clinical Genetics. Advance online publication. doi: 10.1111/cge.12472 Google Scholar

de Snoo, F. A., & Hayward, N. K. (2005). Cutaneous melanoma susceptibility and progression genes. Cancer Letters, 230, 153–186.Google Scholar

Goldstein, A. M., Chan, M., Harland, M., Gillanders, E. M., Hayward, N. K., Avril, M. F., . . . Yakobson, E. (2006). High-risk melanoma susceptibility genes and pancreatic cancer, neural system tumors, and uveal melanoma across GenoMEL. Cancer Research, 66, 9818–9828.Google Scholar

Gruis, N. A., van der Velden, P. A., Sandkuijl, L. A., Prins, D. E., Weaver-Feldhaus, J., Kamb, A., . . . Frants, R. R. (1995). Homozygotes for CDKN2 (p16) germline mutation in Dutch familial melanoma kindreds. Nature Genetics, 10, 351–353.Google Scholar

Harbour, J. W., Onken, M. D., Roberson, E. D., Duan, S., Cao, L., Worley, L. A., . . . Bowcock, A. M. (2010). Frequent mutation of BAP1 in metastasizing uveal melanomas. Science, 330, 1410–1413.Google Scholar

Harland, M., Taylor, C. F., Chambers, P. A., Kukalizch, K., Randerson-Moor, J. A., Gruis, N. A., . . . Bishop, J. A. (2005). A mutation hotspot at the p14ARF splice site. Oncogene, 24, 4604–4608.Google Scholar

Hoiom, V., Edsgard, D., Helgadottir, H., Eriksson, H., All-Ericsson, C., Tuominen, R., . . . Hansson, J. (2013). Hereditary uveal melanoma: A report of a germline mutation in BAP1. Genes Chromosomes Cancer, 52, 378–384.CrossRef Google Scholar PubMed

Hussussian, C. J., Struewing, J. P., Goldstein, A. M., Higgins, P. A., Ally, D. S., Sheahan, M. D., . . . Dracopoli, N. C. (1994). Germline p16 mutations in familial melanoma. Nature Genetics, 8, 15–21.Google Scholar

MacGeoch, C., Bishop, J. A., Bataille, V., Bishop, D. T., Frischauf, A. M., Meloni, R., . . . Spurr, N. K. (1994). Genetic heterogeneity in familial malignant melanoma. Human Molecular Genetics, 3, 2195–2200.Google Scholar

Miller, S. A., Dykes, D. D., & Polesky, H. F. (1988). A simple salting out procedure for extracting DNA from human nucleated cells. Nucleic Acids Research, 16, 1215.Google Scholar

Mistry, S. H., Taylor, C., Randerson-Moor, J. A., Harland, M., Turner, F., Barrett, J. H., . . . Bishop, D. T. (2005). Prevalence of 9p21 deletions in UK melanoma families. Genes Chromosomes Cancer, 44, 292–300.Google Scholar

Mukherjee, B., Delancey, J. O., Raskin, L., Everett, J., Jeter, J., Begg, C. B., . . . Investigators, G. E. M. S. (2012). Risk of non-melanoma cancers in first-degree relatives of CDKN2A mutation carriers. Journal of the National Cancer Institute, 104, 953–956.Google Scholar

Nikolaou, V., Kang, X., Stratigos, A., Gogas, H., Latorre, M. C., Gabree, M., . . . Tsao, H. (2011). Comprehensive mutational analysis of CDKN2A and CDK4 in Greek patients with cutaneous melanoma. British Journal of Dermatology, 165, 1219–1222.Google Scholar

Njauw, C. N., Kim, I., Piris, A., Gabree, M., Taylor, M., Lane, A. M., . . . Tsao, H. (2012). Germline bap1 inactivation is preferentially associated with metastatic ocular melanoma and cutaneous-ocular melanoma families. PLoS One, 7, e35295.Google Scholar

Palmieri, G., Capone, M., Ascierto, M. L., Gentilcore, G., Stroncek, D. F., Casula, M., . . . Ascierto, P. A. (2009). Main roads to melanoma. Journal of Translational Medicine, 7, 86.Google Scholar

Popova, T., Hebert, L., Jacquemin, V., Gad, S., Caux-Moncoutier, V., Dubois-d’Enghien, C., . . . Stern, M. H. (2013). Germline BAP1 mutations predispose to renal cell carcinomas. American Journal of Human Genetics, 92, 974–980.Google Scholar

Puntervoll, H. E., Yang, X. R., Vetti, H. H., Bachmann, I. M., Avril, M. F., Benfodda, M., . . . Molven, A. (2013). Melanoma prone families with CDK4 germline mutation: Phenotypic profile and associations with MC1R variants. Journal of Medical Genetics, 50, 264–270.Google Scholar

Randerson-Moor, J. A., Harland, M., Williams, S., Cuthbert-Heavens, D., Sheridan, E., Aveyard, J., . . . Bishop, D. T. (2001). A germline deletion of p14(ARF) but not CDKN2A in a melanoma-neural system tumour syndrome family. Human Molecular Genetics, 10, 55–62.Google Scholar

Rizos, H., Puig, S., Badenas, C., Malvehy, J., Darmanian, A. P., Jimenez, L., . . . Kefford, R. F. (2001). A melanoma-associated germline mutation in exon 1beta inactivates p14ARF. Oncogene, 20, 5543–5547.Google Scholar

Rogan, P. K., Svojanovsky, S., & Leeder, J. S. (2003). Information theory-based analysis of CYP2C19, CYP2D6 and CYP3A5 splicing mutations. Pharmacogenetics, 13, 207–218.CrossRef Google Scholar PubMed

Scaini, M. C., Minervini, G., Elefanti, L., Ghiorzo, P., Pastorino, L., Tognazzo, S., . . . Tosatto, S. C. (2014). CDKN2A unclassified variants in familial malignant melanoma: Combining functional and computational approaches for their assessment. Human Mutation, 35, 828–840.Google Scholar

Shekar, S. N., Duffy, D. L., Youl, P., Baxter, A. J., Kvaskoff, M., Whiteman, D. C., . . . Martin, N. G. (2009). A population-based study of Australian twins with melanoma suggests a strong genetic contribution to liability. Journal of Investigative Dermatology, 129, 2211–2219.Google Scholar

Soufir, N., Avril, M. F., Chompret, A., Demenais, F., Bombled, J., Spatz, A., . . . Bressac-de Paillerets, B. (1998). Prevalence of p16 and CDK4 germline mutations in 48 melanoma-prone families in France. The French familial melanoma study group. Human Molecular Genetics, 7, 209–216.Google Scholar

Spica, T., Portela, M., Gerard, B., Formicone, F., Descamps, V., Crickx, B., . . . Melan, C. (2006). The A148T variant of the CDKN2A gene is not associated with melanoma risk in the French and Italian populations. Journal of Investigative Dermatology, 126, 1657–1660.Google Scholar

Testa, J. R., Cheung, M., Pei, J., Below, J. E., Tan, Y., Sementino, E., . . . Carbone, M. (2011). Germline BAP1 mutations predispose to malignant mesothelioma. Nature Genetics, 43, 1022–1025.Google Scholar

Wadt, K., Choi, J., Chung, J. Y., Kiilgaard, J., Heegaard, S., Drzewiecki, K. T., . . . Brown, K. M. (2012). A cryptic BAP1 splice mutation in a family with uveal and cutaneous melanoma, and paraganglioma. Pigment Cell Melanoma Research, 25, 815–818.Google Scholar

Wadt, K. A., Aoude, L. G., Johansson, P., Solinas, A., Pritchard, A., Crainic, O., . . . Hayward, N. K. (2014). A recurrent germline BAP1 mutation and extension of the BAP1 tumor predisposition spectrum to include basal cell carcinoma. Clinical Genetics. Advance online publication. doi: 10.1111/cge.12501 Google Scholar

Walker, G. J., Hussussian, C. J., Flores, J. F., Glendening, J. M., Haluska, F. G., Dracopoli, N. C., . . . Fountain, J. W. (1995). Mutations of the CDKN2/p16INK4 gene in Australian melanoma kindreds. Human Molecular Genetics, 4, 1845–1852.Google Scholar

Whiteman, D. C., Milligan, A., Welch, J., Green, A. C., & Hayward, N. K. (1997). Germline CDKN2A mutations in childhood melanoma. Journal of the National Cancer Institute, 89, 1460.Google Scholar

Wiesner, T., Obenauf, A. C., Murali, R., Fried, I., Griewank, K. G., Ulz, P., . . . Speicher, M. R. (2011). Germline mutations in BAP1 predispose to melanocytic tumors. Nature Genetics, 43, 1018–1021.CrossRef Google Scholar PubMed

Zuo, L., Weger, J., Yang, Q., Goldstein, A. M., Tucker, M. A., Walker, G. J., . . . Dracopoli, N. C. (1996). Germline mutations in the p16INK4a binding domain of CDK4 in familial melanoma. Nature Genetics, 12, 97–99.Google Scholar