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Acquired Melanocytic Nevi in Childhood and Familial Melanoma

Acquired Melanocytic Nevi in Childhood and Familial Melanoma Abstract Importance In the surveillance of familial melanoma, the identification of children at greater risk of developing melanoma later in life would serve as a helpful tool. Objective To determine whether acquired melanocytic nevi in childhood are an indicator of risk of melanoma in children from families with familial melanoma. Design, Setting, and Participants A 20-year follow-up study of a cohort of children from families with familial melanoma. Phenotypical data on melanocytic nevi were collected from a random sample of 133 members of families with familial melanoma 2 to 18 years of age with variable risks of being a mutation carrier. More than 20 years of follow-up data (gene-carrier status, diagnosis of melanoma, and excisions of nevi) were collected. In a subgroup of 40 people, childhood phenotypical data were compared with data on nevus numbers in adulthood. Survival analyses, correlation analyses, and t tests were calculated to examine associations. Main Outcomes and Measures Nevus count and distribution in childhood were correlated with the occurrence of melanoma and mutation carrier status. Results Significant risk factors for melanoma were found, specifically in the group with the highest risk of being a mutation carrier: total number of atypical nevi in childhood (hazard ratio [HR], 1.21; 95% CI, 1.02-1.44; P = .03), the nevus count of atypical nevi on the buttocks (HR, 14.00; 95% CI, 2.94-66.55; P = .001), and the number of excisions during follow-up (HR, 1.27; 95% CI, 1.23-1.31; P < .001). The analysis also found a correlation between the distribution of nevi in childhood and adulthood and the distribution of melanomas (correlation, 0.89; 95% CI, 0.67-0.96; and correlation, 0.99; 95% CI, 0.98-1.00; P < .001, respectively for both). Conclusions and Relevance Numbers and distribution of melanocytic nevi in childhood are major indicators of the risk of melanoma in patients from families with familial melanoma. Melanoma is hereditary in approximately 10% of cases.1,2 Familial melanoma is also known as familial atypical multiple mole melanoma (FAMMM) syndrome. The clinical diagnostic criteria are defined as the occurrence of invasive cutaneous melanoma in 2 or more first-degree relatives or 3 or more family members (irrespective of the degree of relationship) on the same side of the family.3 Many members of melanoma families exhibit atypical nevi; however, the occurrence of clinically atypical nevi is not required for the diagnosis.4 The presence of multiple atypical nevi in family members implies that they are 3 times more likely to be carriers of a mutation in a melanoma-predisposing gene than their relatives without atypical moles.4 Germline mutations in CDKN2A are found in about 40% of melanoma families. CDKN2A encodes 2 distinct proteins, p16INK4 and p14ARF, which function as tumor suppressors. In the Netherlands, the p16-Leiden (19–base pair deletion) is the most prevalent CDKN2A germline mutation.5-7 Besides hereditary factors, multiple studies2 have explored other risk factors for melanoma. The development of nevi begins in childhood. The number of acquired melanocytic nevi is an independent risk factor for cutaneous melanoma. Atypical nevi strongly correlate with melanoma risk.8 Some studies9-11 have investigated the site-specific relationship between nevi and melanoma. Melanomas occurred more frequently in individuals with a high number of melanocytic nevi at the same site where the melanoma originated. One study12 compared the site-specific risk of sporadic melanoma with the site-specific distribution of nevi in childhood. This study has found associations between the nevus distribution in children and the melanoma distribution in adults. However, this study compared a cohort of children with a different cohort of adults, and sporadic cases of melanoma, not the familial type we report, were involved. To our knowledge, no studies have been published so far that have compared the nevus distribution and nevus count in childhood with the melanoma distribution in adulthood in the same cohort. Methods From 1985 to 1990, a total of 133 children from 34 families who fulfilled the diagnostic requirements of familial melanoma were photographed at the Department of Dermatology at the Leiden University Medical Center, Leiden, the Netherlands. At that time, the CDKN2A gene had not yet been discovered. At the moment of photographing, the children were between 2 and 18 years old. The children were included by chance (they accompanied their parents) and were photographed with the oral consent of their parents. All people who were included in the study received a letter of invitation for a second visit approximately 20 years later. This follow-up study was approved by the ethics committee of the Leiden University Medical Center, and the patients consented by making the follow-up appointment. Before the participants (the children from 20 years ago) were invited for the second mole count, approval was provided by our institutional review board. Pictures were taken of the trunk, buttocks, and legs at a fixed distance. Slides of these pictures were projected to produce enlarged, real-size pictures. Two dermatologists simultaneously counted the melanocytic nevi from the projected pictures of the children, finding consensus on the final outcome. Nevi were defined as pigmented macules or papules with a minimal diameter of 2 mm, excluding freckles, café au lait macules, and warts. The number of atypical nevi was noted, defined as predominantly flat or macular, with 3 or more of the following 5 ABCDE features: asymmetry, indistinct borders, variation in color, diameter of 5 mm or larger, and erythema.13 The total number of melanocytic nevi 5 mm or larger in diameter, including typical and atypical nevi, was also documented. Nevi were counted per body part. Some parts of the bodies, such as the flanks, were not photographed separately and could not be counted. These body parts were equal for all children (Figure). Persons included in this study were all members of familial melanoma families under study at our department and were seen on several research occasions; however, they were not necessarily under regular surveillance. Review of patient medical records and pedigrees was used to confirm the diagnoses and to gather information about the chance of having a gene mutation. From 2004 onward, these families were invited to have their DNA tested. Information was collected about a proven p16-Leiden mutation, p14ARF mutation, or an unknown gene mutation (this means that a melanoma patient in the family was tested but no CDKN2A mutation was found). If no genetic testing was performed in that family, this was also noted. Therefore, 3 types of families were included: CDKN2A-positive families, CDKN2A-negative families, and families without DNA testing. Persons were categorized into 4 different groups. The first group consisted of people with a proven CDKN2A mutation. The second group included people at 50% risk for a CDKN2A mutation and people from non-CDKN2A families who had a first-degree relative with melanoma. The third group contained persons with a 25% risk of a CDKN2A mutation and people who had a second-degree relative with melanoma. The last group included people who were proven to have no gene mutation or whose parents or grandparents were proven to have no gene mutation. In CDKN2A-positive families, members with a proven absence of that gene mutation are strictly speaking no longer patients; however, their melanoma risk is reported to be still slightly higher than the population risk.14 The mechanism of this observation is not clear but could be due to shared minor melanoma risk factors within families, either genetic or environmental. Furthermore, the children were divided into 2 groups (ie, <13 years and ≥13 years old), and analyses were performed on these prepubertal and postpubertal subgroups. From all included patients, the numbers of lesions comprising suspicious nevi, atypical nevi, or melanoma removed in the past were extracted from the database and examined as a separate determinant. Patient records, the hospital oncology registry, and a research database (ie, the Dutch section of the familial melanoma research database by GenoMel, the international melanoma genetics consortium) were examined. Histopathologic outcomes of all lesions were recorded. Forty people were seen for a second visit (28% of the total people who were invited) during which a total skin examination and a total nevus count were performed by the same dermatologist who also counted the nevi from the childhood pictures. The definition of a nevus and atypical nevus were the same as for the first visit. The melanocytic nevi of the second count were arranged into several localizations (left or right where appropriate): face, scalp, hands, lower arms, upper arms, ventral thorax, dorsal thorax, buttocks, upper legs, lower legs, and feet. Analyses of the data were performed with SPSS statistical software, version 17 (SPSS Inc). Survival analyses, correlation analyses, and t tests were used. Logistic regression analyses were used to examine associations with gene mutations and removed lesions. The occurrence of melanoma was evaluated with survival analyses using the Kaplan-Meier method, log-rank tests, and the Cox proportional hazards regression tests. Proportions were compared using 2-sided z tests. Cox proportional hazards regression was used to estimate the risk of melanoma. We also evaluated random-effects models (frailty models in the case of the Cox proportional hazards model) to account for family effects. Only 34 families were present in the data set; therefore, only models with few covariates could be fitted reliably. Because the random effect in the considered models was never statistically significant, we only describe models without random effects. Tests were considered statistically significant at P ≤ .05. Results Of the 133 participants included in this study, 52 (39.1%) were female and 81 (60.9%) were male. The mean age was 13 years at childhood and 34 years at adulthood. The mean count of nevi in childhood was 36. Forty people were seen for a second nevus count; their mean count was 39 in childhood and 121 in adulthood (Table 1). Fifteen people (11.3%) had at least one melanoma or melanoma in situ (4 males and 11 females); 7 people had more than one melanoma. The mean age at which the participants developed their first melanoma was 26 years. One person died of melanoma at the age of 38 years. Eighty-eight of the 133 study participants (66.2%) were members of families with a proven p16-Leiden mutation; 8 people (6.0%) were family members with a proven mutation in the CDKN2A gene that affected purely p14ARF. Of all study participants, 12 (9.0%) were proven to have a gene mutation. On the basis of their position in the pedigree, 52 people (39.1%) had a gene mutation risk of 50%, 41 (30.8%) had a risk of gene mutation of 25% or less, and 28 (21.1%) were proven to have no gene mutation themselves or no gene mutation in their parents or grandparents. Two groups of gene mutation risk were formed: 50% or greater and 25% or less. The group with a 50% or greater risk of gene mutation consisted of 64 people (48.1%); those with a 25% or less risk consisted of 69 people (51.9%). Of the 15 people with at least one melanoma, 10 were carriers of the p16-Leiden mutation; 4 people were not formally tested. In the families of 2 of these 4 people, the p16-Leiden gene mutation was determined in other members, and in the families of the remaining 2 people, no genetic testing was performed. One person with a melanoma was proven to have no gene mutation, whereas in his family the p16-Leiden mutation was verified in a different family member (phenocopy phenomenon). In all 247 removed lesions, 22 melanomas and 5 melanomas in situ were found. The total number of nevi in childhood was a significant (hazard ratio [HR], 1.02; 95% CI, 1.00-1.03; P = .04) predictor of the development of melanoma later in life. The total nevus count on the legs in childhood was on its own significantly (HR, 1.04; 95% CI, 1.02-1.06; P < .001) associated with melanoma. Analyses were also performed in the 2 gene mutation risk groups (≥50% and ≤25%). The total number of nevi in childhood was a significant (HR, 1.02; 95% CI, 1.00-1.03; P = .03) predictor of the development of melanoma in the group with a 50% or greater risk of a gene mutation but not in the group with a risk of 25% or less (HR, 0.98; 95% CI, 0.87-1.11; P = .75). When the different body parts were examined, the same results were observed. The nevus count on the legs in childhood was a significant predictor (HR, 1.04; 95% CI, 1.03-1.05; P < .001) of melanoma in the 50% or greater risk group. The total count of childhood nevi with a diameter of 5 mm or larger was not a significant predictor of melanoma; however, childhood nevi 5 mm or larger on the buttocks gave a high risk of melanoma (HR, 1.47; 95% CI, 1.98-44.38; P = .005), specifically in the high-risk group (HR, 6.47; 95% CI, 1.36-30.75; P = .02). The total count of atypical nevi in childhood yielded a higher risk of melanoma (HR, 1.21; 95% CI, 1.02-1.44; P = .03). Atypical nevi on the ventral body side and atypical nevi on the buttocks in childhood accounted for a higher risk of melanoma (HR, 1.48; 95% CI, 1.02-2.14; P = .04; and HR, 14.00; 95% CI, 2.94-66.55; P = .001; respectively) (Table 2). The total count of nevi in adulthood did not indicate a significant risk of melanoma (n = 40). When the distribution of the nevi was taken into account, the nevus count on the lower half of the body (legs and buttocks) indicated a higher risk of melanoma. Analysis of the upper half of the body revealed a converse association with melanoma (HR, 0.97; 95% CI, 0.94-1.00; P = .04) (Table 3). In the 50% or greater risk group, the total nevus count in adulthood was a risk indicator for melanoma (HR, 1.01; 95% CI, 1.00-1.05; P = .03) as was the nevus count on the lower half of the body (HR, 1.02; 95% CI, 1.01-1.03; P = .01). No association between the risk of melanoma and nevus size of 5 mm or larger in adulthood or the atypical nevus count was found. The number of melanocytic lesions that were removed produced a higher risk of melanoma in the whole group (HR, 1.27; 95% CI, 1.23-1.31; P < .001) and especially in the 50% or greater risk group. An association was found between the numbers of nevi on a certain site (distribution) in childhood and the site of melanoma in adulthood (n = 133; correlation, 0.89; 95% CI, 0.67-0.96; P < .001). A high association between nevus distribution and melanoma distribution in adulthood (n = 40) was seen among all localizations (correlation, 0.99; 95% CI, 0.98-1.00; P < .001). Gene mutation status (ie, CDKN2A mutation carriers) obviously was a significant (HR, 118.10; 95% CI, 23.65-910.51) predictor of melanoma. No association was found between the count and distribution of nevi, numbers of nevi 5 mm or larger, numbers of atypical nevi, and the number of removed lesions as predictors for gene mutation status. Discussion This study examined the numbers and distribution of acquired melanocytic nevi in a cohort of children from familial melanoma families as a risk indicator for melanoma later in life. A group of 133 children with varying degrees of risk of being a mutation carrier on the basis of genetic testing in adulthood or their position in the pedigree were included, and 20 years later 15 people had developed 27 melanomas. A subgroup of adults who were seen for a second nevus count consisted of 40 people who were part of the cohort of 133 children. This small group might be biased at inclusion because it can be expected that these persons are under regular surveillance because of development of melanoma or their type and number of nevi. Nevertheless, this group had significant results that are important for clinical practice. Concerning the role of the total number of nevi as a risk indicator for melanoma later in life, we found that the total nevus count in childhood was a significant risk factor for melanoma. A childhood nevus count of 5 mm or larger on the buttocks also resulted in a higher risk of melanoma. Nevi 5 mm or larger have previously been described as a risk factor of melanoma in multiple studies.15 Buttock moles are a component of the so-called atypical mole syndrome phenotype, a complex risk phenotype for melanoma.16 There is no clue as to how or why these nevi preferentially appear on the buttocks. The total count of atypical nevi in childhood also yielded an increased risk of melanoma. This correlation was reported in multiple previous studies.8 The ages of the included children were between 2 and 18 years; this is the age range in which nevus counts in individuals vary significantly.9 The association between the number of nevi and melanoma will certainly differ between very young children and older children, which is why we divided the children into 2 groups (ie, <13 years and ≥13 years old) and performed the analyses on these prepubertal and postpubertal subgroups. The analyses revealed that nevi larger than 5 mm on the buttocks and the total number of atypical nevi in the age group younger than 13 years were still indicative of an increased risk of melanoma (P = .007 and P = .004, respectively). In the 13 years or older group, these associations were lost, which might be a result of the small group size or reflect the variability in nevus counts in this age group. It could also be that buttock nevi are a much more specific indicator of risk when present before puberty. Earlier population studies1,8,10,14 have found that high numbers of nevi in both childhood and adulthood increase the risk of melanoma. Surprisingly, adulthood nevus count was not significantly associated with melanoma in our data, which seems to be due to lack of power. Still, our finding is compatible with a positive association of nevus count with increased risk of death by 0.4% per nevus. During the years we have followed up our study population, they received sun exposure counseling that was especially aimed at children. It seems plausible that young individuals from melanoma families under surveillance for many years might have lower nevus counts. Previous studies1,8 have found that numbers of nevi 5 mm or larger and atypical nevi in adulthood were strongly correlated with melanoma. Our findings could not confirm this report, which might be because of the size of the research group. Furthermore, some of the 40 people who had a second nevus count presented themselves without any nevi 5 mm or larger (n = 7) and/or atypical nevi (n = 22), which reflects the variable phenotype in familial melanoma.4 Analyses of melanoma and number of lesions removed were performed in all 133 cases from the patient records, the hospital oncology registry, and the research database. Some data may be missing because our findings could be checked by personal history in only 40 people. All the families who were included in this study have been included in family studies for many years and usually report all cancer cases loyally, even those from second-degree relatives. However, we may have missed melanomas. People who were seen for a second nevus count were between the ages of 21 and 41 years. If the cohort had been followed up for a longer period, more melanomas would have developed. It is therefore suspected that the analyses would then have resulted in more significant outcomes; therefore, we consider our findings conservative. Our analysis, not surprisingly, confirmed the findings of other publications1,2 that the presence of a CDKN2A mutation yields a higher risk of melanoma compared with families without such a mutation, implicating a lower melanoma risk in families with unresolved genetic mechanisms. Regarding the distribution of childhood nevi, the analyses revealed a high association with melanoma distribution in adulthood. This correlation could also be found in the distribution of adulthood nevi and melanoma distribution. Melanoma in adulthood tends to develop more frequently on the sites with the highest nevus count in adulthood according to the literature.9-11 Several correlations could not be found in the 25% or less group, which can be viewed as a matched control group, supporting the positive correlations we found in the 50% or greater group. The 25% or less group consisted of children from the same families who shared the same genetic background and environmental exposure. They were included completely at random, years before the identification of the CDKN2A gene. Both risk groups are expected to contain a few people who belong to the other group, so-called misclassifications. These misclassifications dilute findings but have nevertheless led to significant outcomes. Children and young adults most often do not want to be genetically tested for financial reasons, which prevented us from definitively classifying all individuals. The association between the occurrence of nevi and the CDKN2A mutation is puzzling. The children included in our study have been selected solely on the basis of multiple melanoma patients in their family. Later, in 21 of the 34 families, a CDKN2A mutation was found. Linkage analysis performed in 1993 on the Leiden FAMMM families provided evidence of linkage of the atypical nevi phenotype to the melanoma locus on chromosome 9p21.17 Inclusion of family members with 10 or more atypical nevi and/or melanoma as affected individuals led to a slight decrease in the logarithm of the odds score compared with inclusion of melanoma patients alone. Broadening the inclusion criteria to persons with 5 or fewer atypical nevi as affected individuals resulted in a remarkably decreased logarithm of the odds score, suggesting that the presence of atypical nevi could not be ascribed entirely to a melanoma susceptibility gene in that locus. Several years later, a genome-wide scan that investigated the genetic component of atypical nevi in these large extended founder pedigrees with many family members with atypical nevi again did not reveal a nevus locus on chromosome 9p. The strongest evidence of an atypical nevus susceptibility gene was mapped to chromosome band 7q21.3, a region containing the candidate gene CDK6.18 Making use of advanced technological genome-wide association studies, Falchi et al19 reported a nevus-associated variant of MTAP adjacent to CDKN2A on chromosome 9p21. Other nevus-associated variants were identified on chromosome 22q13.19 In addition, protecting variants in the NID1 gene on chromosome 1q42 were recently identified.20 We do not know yet whether the currently identified nevus-related variants segregate with extensive moles in families. On the basis of the results of the current study, physicians should take additional care of children from families at high risk of melanoma. Children with a high number of melanocytic nevi and children with atypical nevi should be included in a surveillance program with their parents. Buttocks should be checked for moles. In addition, sun avoidance information should be provided, with emphasis on the prevention of sunburns. Despite the difficulty in performing long-term follow-up studies in children from families with melanoma, results of these studies provide us with additional information about risk factors and may help to detect melanoma as early as possible. Back to top Article Information Accepted for Publication: May 14, 2013. Corresponding Author: Wilma Bergman, MD, PhD, Leiden University Medical Center, Albinusdreef 2, 2300 RC Leiden, the Netherlands (w.bergman@lumc.nl). Published Online: November 6, 2013. doi:10.1001/jamadermatol.2013.5588. Author Contribution: Drs Vredenborg and Bergman had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis. Study concept and design: Vredenborg, Kukutsch, Bergman. Acquisition of data: Vredenborg, Boonk, Gruis, Out-Luijting. Analysis and interpretation of data: Vredenborg, Böhringer, Kukutsch, Bergman. Drafting of the manuscript: Vredenborg, Böhringer, Kukutsch, Bergman. Critical revision of the manuscript for important intellectual content: All authors. Statistical analysis: Vredenborg, Böhringer. Administrative, technical, or material support: Vredenborg, Boonk, Gruis, Out-Luijting, Kukutsch, Bergman. Study supervision: Vredenborg, Kukutsch, Bergman. Financial Disclosure: None reported. References 1. Ford D, Bliss JM, Swerdlow AJ, et al; the International Melanoma Analysis Group (IMAGE). Risk of cutaneous melanoma associated with a family history of the disease. Int J Cancer. 1995;62(4):377-381.PubMedGoogle ScholarCrossref 2. Goldstein AM, Tucker MA. Genetic epidemiology of familial melanoma. Dermatol Clin. 1995;13(3):605-612.PubMedGoogle Scholar 3. Eckerle MD, Bishop M, Resse E, et al. Familial atypical multiple mole melanoma syndrome. In: Riegert-Johnson DL, Boardman LA, Hefferon T, et al, eds. Cancer Syndromes. Bethesda, MD: National Center for Biotechnology Information; 2009. 4. Bishop JA, Wachsmuth RC, Harland M, et al. Genotype/phenotype and penetrance studies in melanoma families with germline CDKN2A mutations. J Invest Dermatol. 2000;114(1):28-33.PubMedGoogle ScholarCrossref 5. Gruis NA, van der Velden PA, Sandkuijl LA, et al. Homozygotes for CDKN2 (p16) germline mutation in Dutch familial melanoma kindreds. Nat Genet. 1995;10(3):351-353.PubMedGoogle ScholarCrossref 6. van der Rhee JI, Krijnen P, Gruis NA, et al. Clinical and histologic characteristics of malignant melanoma in families with a germline mutation in CDKN2A. J Am Acad Dermatol. 2011;65(2):281-288.PubMedGoogle ScholarCrossref 7. van der Rhee JI, de Snoo FA, Vasen HF, et al. Effectiveness and causes for failure of surveillance of CDKN2A-mutated melanoma families. J Am Acad Dermatol. 2011;65(2):289-296.PubMedGoogle ScholarCrossref 8. Psaty EL, Scope A, Halpern AC, Marghoob AA. Defining the patient at high risk for melanoma. Int J Dermatol. 2010;49(4):362-376.PubMedGoogle ScholarCrossref 9. Grulich AE, Bataille V, Swerdlow AJ, et al. Naevi and pigmentary characteristics as risk factors for melanoma in a high-risk population: a case-control study in New South Wales, Australia. Int J Cancer. 1996;67(4):485-491.PubMedGoogle ScholarCrossref 10. Krüger S, Garbe C, Büttner P, Stadler R, Guggenmoos-Holzmann I, Orfanos CE. Epidemiologic evidence for the role of melanocytic nevi as risk markers and direct precursors of cutaneous malignant melanoma: results of a case control study in melanoma patients and nonmelanoma control subjects. J Am Acad Dermatol. 1992;26(6):920-926.PubMedGoogle ScholarCrossref 11. Ródenas JM, Delgado-Rodríguez M, Farinas-Alvarez C, Herranz MT, Serrano S. Melanocytic nevi and risk of cutaneous malignant melanoma in southern Spain. Am J Epidemiol. 1997;145(11):1020-1029.PubMedGoogle ScholarCrossref 12. Juhl AL, Byers TE, Robinson WA, Morelli JG, Crane LA. The anatomic distribution of melanoma and relationships with childhood nevus distribution in Colorado. Melanoma Res. 2009;19(4):252-259.PubMedGoogle ScholarCrossref 13. Bergman W, Gruis NA. Management of melanoma families. Cancers. 2010;2(2):549-566.Google ScholarCrossref 14. Kefford R, Bishop JN, Tucker M, et al; Melanoma Genetics Consortium. Genetic testing for melanoma. Lancet Oncol. 2002;3(11):653-654.PubMedGoogle ScholarCrossref 15. Grob JJ, Gouvernet J, Aymar D, et al. Count of benign melanocytic nevi as a major indicator of risk for nonfamilial nodular and superficial spreading melanoma. Cancer. 1990;66(2):387-395.PubMedGoogle ScholarCrossref 16. Newton Bishop JA, Bataille V, Pinney E, Bishop DT. Family studies in melanoma: identification of the atypical mole syndrome (AMS) phenotype. Melanoma Res. 1994;4(4):199-206.PubMedGoogle ScholarCrossref 17. Gruis NA, Sandkuijl LA, Weber JL, et al. Linkage analysis in Dutch familial atypical multiple mole-melanoma (FAMMM) syndrome families: effect of naevus count. Melanoma Res. 1993;3(4):271-277.PubMedGoogle Scholar 18. de Snoo FA, Hottenga JJ, Gillanders EM, et al. Genome-wide linkage scan for atypical nevi in p16-Leiden melanoma families. Eur J Hum Genet. 2008;16(9):1135-1141.PubMedGoogle ScholarCrossref 19. Falchi M, Bataille V, Hayward NK, et al. Genome-wide association study identifies variants at 9p21 and 22q13 associated with development of cutaneous nevi. Nat Genet. 2009;41(8):915-919.PubMedGoogle ScholarCrossref 20. Nan H, Xu M, Zhang J, et al. Genome-wide association study identifies nidogen 1 (NID1) as a susceptibility locus to cutaneous nevi and melanoma risk. Hum Mol Genet. 2011;20(13):2673-2679.PubMedGoogle ScholarCrossref http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png JAMA Dermatology American Medical Association

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American Medical Association
Copyright
Copyright © 2014 American Medical Association. All Rights Reserved.
ISSN
2168-6068
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2168-6084
DOI
10.1001/jamadermatol.2013.5588
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24196164
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Abstract

Abstract Importance In the surveillance of familial melanoma, the identification of children at greater risk of developing melanoma later in life would serve as a helpful tool. Objective To determine whether acquired melanocytic nevi in childhood are an indicator of risk of melanoma in children from families with familial melanoma. Design, Setting, and Participants A 20-year follow-up study of a cohort of children from families with familial melanoma. Phenotypical data on melanocytic nevi were collected from a random sample of 133 members of families with familial melanoma 2 to 18 years of age with variable risks of being a mutation carrier. More than 20 years of follow-up data (gene-carrier status, diagnosis of melanoma, and excisions of nevi) were collected. In a subgroup of 40 people, childhood phenotypical data were compared with data on nevus numbers in adulthood. Survival analyses, correlation analyses, and t tests were calculated to examine associations. Main Outcomes and Measures Nevus count and distribution in childhood were correlated with the occurrence of melanoma and mutation carrier status. Results Significant risk factors for melanoma were found, specifically in the group with the highest risk of being a mutation carrier: total number of atypical nevi in childhood (hazard ratio [HR], 1.21; 95% CI, 1.02-1.44; P = .03), the nevus count of atypical nevi on the buttocks (HR, 14.00; 95% CI, 2.94-66.55; P = .001), and the number of excisions during follow-up (HR, 1.27; 95% CI, 1.23-1.31; P < .001). The analysis also found a correlation between the distribution of nevi in childhood and adulthood and the distribution of melanomas (correlation, 0.89; 95% CI, 0.67-0.96; and correlation, 0.99; 95% CI, 0.98-1.00; P < .001, respectively for both). Conclusions and Relevance Numbers and distribution of melanocytic nevi in childhood are major indicators of the risk of melanoma in patients from families with familial melanoma. Melanoma is hereditary in approximately 10% of cases.1,2 Familial melanoma is also known as familial atypical multiple mole melanoma (FAMMM) syndrome. The clinical diagnostic criteria are defined as the occurrence of invasive cutaneous melanoma in 2 or more first-degree relatives or 3 or more family members (irrespective of the degree of relationship) on the same side of the family.3 Many members of melanoma families exhibit atypical nevi; however, the occurrence of clinically atypical nevi is not required for the diagnosis.4 The presence of multiple atypical nevi in family members implies that they are 3 times more likely to be carriers of a mutation in a melanoma-predisposing gene than their relatives without atypical moles.4 Germline mutations in CDKN2A are found in about 40% of melanoma families. CDKN2A encodes 2 distinct proteins, p16INK4 and p14ARF, which function as tumor suppressors. In the Netherlands, the p16-Leiden (19–base pair deletion) is the most prevalent CDKN2A germline mutation.5-7 Besides hereditary factors, multiple studies2 have explored other risk factors for melanoma. The development of nevi begins in childhood. The number of acquired melanocytic nevi is an independent risk factor for cutaneous melanoma. Atypical nevi strongly correlate with melanoma risk.8 Some studies9-11 have investigated the site-specific relationship between nevi and melanoma. Melanomas occurred more frequently in individuals with a high number of melanocytic nevi at the same site where the melanoma originated. One study12 compared the site-specific risk of sporadic melanoma with the site-specific distribution of nevi in childhood. This study has found associations between the nevus distribution in children and the melanoma distribution in adults. However, this study compared a cohort of children with a different cohort of adults, and sporadic cases of melanoma, not the familial type we report, were involved. To our knowledge, no studies have been published so far that have compared the nevus distribution and nevus count in childhood with the melanoma distribution in adulthood in the same cohort. Methods From 1985 to 1990, a total of 133 children from 34 families who fulfilled the diagnostic requirements of familial melanoma were photographed at the Department of Dermatology at the Leiden University Medical Center, Leiden, the Netherlands. At that time, the CDKN2A gene had not yet been discovered. At the moment of photographing, the children were between 2 and 18 years old. The children were included by chance (they accompanied their parents) and were photographed with the oral consent of their parents. All people who were included in the study received a letter of invitation for a second visit approximately 20 years later. This follow-up study was approved by the ethics committee of the Leiden University Medical Center, and the patients consented by making the follow-up appointment. Before the participants (the children from 20 years ago) were invited for the second mole count, approval was provided by our institutional review board. Pictures were taken of the trunk, buttocks, and legs at a fixed distance. Slides of these pictures were projected to produce enlarged, real-size pictures. Two dermatologists simultaneously counted the melanocytic nevi from the projected pictures of the children, finding consensus on the final outcome. Nevi were defined as pigmented macules or papules with a minimal diameter of 2 mm, excluding freckles, café au lait macules, and warts. The number of atypical nevi was noted, defined as predominantly flat or macular, with 3 or more of the following 5 ABCDE features: asymmetry, indistinct borders, variation in color, diameter of 5 mm or larger, and erythema.13 The total number of melanocytic nevi 5 mm or larger in diameter, including typical and atypical nevi, was also documented. Nevi were counted per body part. Some parts of the bodies, such as the flanks, were not photographed separately and could not be counted. These body parts were equal for all children (Figure). Persons included in this study were all members of familial melanoma families under study at our department and were seen on several research occasions; however, they were not necessarily under regular surveillance. Review of patient medical records and pedigrees was used to confirm the diagnoses and to gather information about the chance of having a gene mutation. From 2004 onward, these families were invited to have their DNA tested. Information was collected about a proven p16-Leiden mutation, p14ARF mutation, or an unknown gene mutation (this means that a melanoma patient in the family was tested but no CDKN2A mutation was found). If no genetic testing was performed in that family, this was also noted. Therefore, 3 types of families were included: CDKN2A-positive families, CDKN2A-negative families, and families without DNA testing. Persons were categorized into 4 different groups. The first group consisted of people with a proven CDKN2A mutation. The second group included people at 50% risk for a CDKN2A mutation and people from non-CDKN2A families who had a first-degree relative with melanoma. The third group contained persons with a 25% risk of a CDKN2A mutation and people who had a second-degree relative with melanoma. The last group included people who were proven to have no gene mutation or whose parents or grandparents were proven to have no gene mutation. In CDKN2A-positive families, members with a proven absence of that gene mutation are strictly speaking no longer patients; however, their melanoma risk is reported to be still slightly higher than the population risk.14 The mechanism of this observation is not clear but could be due to shared minor melanoma risk factors within families, either genetic or environmental. Furthermore, the children were divided into 2 groups (ie, <13 years and ≥13 years old), and analyses were performed on these prepubertal and postpubertal subgroups. From all included patients, the numbers of lesions comprising suspicious nevi, atypical nevi, or melanoma removed in the past were extracted from the database and examined as a separate determinant. Patient records, the hospital oncology registry, and a research database (ie, the Dutch section of the familial melanoma research database by GenoMel, the international melanoma genetics consortium) were examined. Histopathologic outcomes of all lesions were recorded. Forty people were seen for a second visit (28% of the total people who were invited) during which a total skin examination and a total nevus count were performed by the same dermatologist who also counted the nevi from the childhood pictures. The definition of a nevus and atypical nevus were the same as for the first visit. The melanocytic nevi of the second count were arranged into several localizations (left or right where appropriate): face, scalp, hands, lower arms, upper arms, ventral thorax, dorsal thorax, buttocks, upper legs, lower legs, and feet. Analyses of the data were performed with SPSS statistical software, version 17 (SPSS Inc). Survival analyses, correlation analyses, and t tests were used. Logistic regression analyses were used to examine associations with gene mutations and removed lesions. The occurrence of melanoma was evaluated with survival analyses using the Kaplan-Meier method, log-rank tests, and the Cox proportional hazards regression tests. Proportions were compared using 2-sided z tests. Cox proportional hazards regression was used to estimate the risk of melanoma. We also evaluated random-effects models (frailty models in the case of the Cox proportional hazards model) to account for family effects. Only 34 families were present in the data set; therefore, only models with few covariates could be fitted reliably. Because the random effect in the considered models was never statistically significant, we only describe models without random effects. Tests were considered statistically significant at P ≤ .05. Results Of the 133 participants included in this study, 52 (39.1%) were female and 81 (60.9%) were male. The mean age was 13 years at childhood and 34 years at adulthood. The mean count of nevi in childhood was 36. Forty people were seen for a second nevus count; their mean count was 39 in childhood and 121 in adulthood (Table 1). Fifteen people (11.3%) had at least one melanoma or melanoma in situ (4 males and 11 females); 7 people had more than one melanoma. The mean age at which the participants developed their first melanoma was 26 years. One person died of melanoma at the age of 38 years. Eighty-eight of the 133 study participants (66.2%) were members of families with a proven p16-Leiden mutation; 8 people (6.0%) were family members with a proven mutation in the CDKN2A gene that affected purely p14ARF. Of all study participants, 12 (9.0%) were proven to have a gene mutation. On the basis of their position in the pedigree, 52 people (39.1%) had a gene mutation risk of 50%, 41 (30.8%) had a risk of gene mutation of 25% or less, and 28 (21.1%) were proven to have no gene mutation themselves or no gene mutation in their parents or grandparents. Two groups of gene mutation risk were formed: 50% or greater and 25% or less. The group with a 50% or greater risk of gene mutation consisted of 64 people (48.1%); those with a 25% or less risk consisted of 69 people (51.9%). Of the 15 people with at least one melanoma, 10 were carriers of the p16-Leiden mutation; 4 people were not formally tested. In the families of 2 of these 4 people, the p16-Leiden gene mutation was determined in other members, and in the families of the remaining 2 people, no genetic testing was performed. One person with a melanoma was proven to have no gene mutation, whereas in his family the p16-Leiden mutation was verified in a different family member (phenocopy phenomenon). In all 247 removed lesions, 22 melanomas and 5 melanomas in situ were found. The total number of nevi in childhood was a significant (hazard ratio [HR], 1.02; 95% CI, 1.00-1.03; P = .04) predictor of the development of melanoma later in life. The total nevus count on the legs in childhood was on its own significantly (HR, 1.04; 95% CI, 1.02-1.06; P < .001) associated with melanoma. Analyses were also performed in the 2 gene mutation risk groups (≥50% and ≤25%). The total number of nevi in childhood was a significant (HR, 1.02; 95% CI, 1.00-1.03; P = .03) predictor of the development of melanoma in the group with a 50% or greater risk of a gene mutation but not in the group with a risk of 25% or less (HR, 0.98; 95% CI, 0.87-1.11; P = .75). When the different body parts were examined, the same results were observed. The nevus count on the legs in childhood was a significant predictor (HR, 1.04; 95% CI, 1.03-1.05; P < .001) of melanoma in the 50% or greater risk group. The total count of childhood nevi with a diameter of 5 mm or larger was not a significant predictor of melanoma; however, childhood nevi 5 mm or larger on the buttocks gave a high risk of melanoma (HR, 1.47; 95% CI, 1.98-44.38; P = .005), specifically in the high-risk group (HR, 6.47; 95% CI, 1.36-30.75; P = .02). The total count of atypical nevi in childhood yielded a higher risk of melanoma (HR, 1.21; 95% CI, 1.02-1.44; P = .03). Atypical nevi on the ventral body side and atypical nevi on the buttocks in childhood accounted for a higher risk of melanoma (HR, 1.48; 95% CI, 1.02-2.14; P = .04; and HR, 14.00; 95% CI, 2.94-66.55; P = .001; respectively) (Table 2). The total count of nevi in adulthood did not indicate a significant risk of melanoma (n = 40). When the distribution of the nevi was taken into account, the nevus count on the lower half of the body (legs and buttocks) indicated a higher risk of melanoma. Analysis of the upper half of the body revealed a converse association with melanoma (HR, 0.97; 95% CI, 0.94-1.00; P = .04) (Table 3). In the 50% or greater risk group, the total nevus count in adulthood was a risk indicator for melanoma (HR, 1.01; 95% CI, 1.00-1.05; P = .03) as was the nevus count on the lower half of the body (HR, 1.02; 95% CI, 1.01-1.03; P = .01). No association between the risk of melanoma and nevus size of 5 mm or larger in adulthood or the atypical nevus count was found. The number of melanocytic lesions that were removed produced a higher risk of melanoma in the whole group (HR, 1.27; 95% CI, 1.23-1.31; P < .001) and especially in the 50% or greater risk group. An association was found between the numbers of nevi on a certain site (distribution) in childhood and the site of melanoma in adulthood (n = 133; correlation, 0.89; 95% CI, 0.67-0.96; P < .001). A high association between nevus distribution and melanoma distribution in adulthood (n = 40) was seen among all localizations (correlation, 0.99; 95% CI, 0.98-1.00; P < .001). Gene mutation status (ie, CDKN2A mutation carriers) obviously was a significant (HR, 118.10; 95% CI, 23.65-910.51) predictor of melanoma. No association was found between the count and distribution of nevi, numbers of nevi 5 mm or larger, numbers of atypical nevi, and the number of removed lesions as predictors for gene mutation status. Discussion This study examined the numbers and distribution of acquired melanocytic nevi in a cohort of children from familial melanoma families as a risk indicator for melanoma later in life. A group of 133 children with varying degrees of risk of being a mutation carrier on the basis of genetic testing in adulthood or their position in the pedigree were included, and 20 years later 15 people had developed 27 melanomas. A subgroup of adults who were seen for a second nevus count consisted of 40 people who were part of the cohort of 133 children. This small group might be biased at inclusion because it can be expected that these persons are under regular surveillance because of development of melanoma or their type and number of nevi. Nevertheless, this group had significant results that are important for clinical practice. Concerning the role of the total number of nevi as a risk indicator for melanoma later in life, we found that the total nevus count in childhood was a significant risk factor for melanoma. A childhood nevus count of 5 mm or larger on the buttocks also resulted in a higher risk of melanoma. Nevi 5 mm or larger have previously been described as a risk factor of melanoma in multiple studies.15 Buttock moles are a component of the so-called atypical mole syndrome phenotype, a complex risk phenotype for melanoma.16 There is no clue as to how or why these nevi preferentially appear on the buttocks. The total count of atypical nevi in childhood also yielded an increased risk of melanoma. This correlation was reported in multiple previous studies.8 The ages of the included children were between 2 and 18 years; this is the age range in which nevus counts in individuals vary significantly.9 The association between the number of nevi and melanoma will certainly differ between very young children and older children, which is why we divided the children into 2 groups (ie, <13 years and ≥13 years old) and performed the analyses on these prepubertal and postpubertal subgroups. The analyses revealed that nevi larger than 5 mm on the buttocks and the total number of atypical nevi in the age group younger than 13 years were still indicative of an increased risk of melanoma (P = .007 and P = .004, respectively). In the 13 years or older group, these associations were lost, which might be a result of the small group size or reflect the variability in nevus counts in this age group. It could also be that buttock nevi are a much more specific indicator of risk when present before puberty. Earlier population studies1,8,10,14 have found that high numbers of nevi in both childhood and adulthood increase the risk of melanoma. Surprisingly, adulthood nevus count was not significantly associated with melanoma in our data, which seems to be due to lack of power. Still, our finding is compatible with a positive association of nevus count with increased risk of death by 0.4% per nevus. During the years we have followed up our study population, they received sun exposure counseling that was especially aimed at children. It seems plausible that young individuals from melanoma families under surveillance for many years might have lower nevus counts. Previous studies1,8 have found that numbers of nevi 5 mm or larger and atypical nevi in adulthood were strongly correlated with melanoma. Our findings could not confirm this report, which might be because of the size of the research group. Furthermore, some of the 40 people who had a second nevus count presented themselves without any nevi 5 mm or larger (n = 7) and/or atypical nevi (n = 22), which reflects the variable phenotype in familial melanoma.4 Analyses of melanoma and number of lesions removed were performed in all 133 cases from the patient records, the hospital oncology registry, and the research database. Some data may be missing because our findings could be checked by personal history in only 40 people. All the families who were included in this study have been included in family studies for many years and usually report all cancer cases loyally, even those from second-degree relatives. However, we may have missed melanomas. People who were seen for a second nevus count were between the ages of 21 and 41 years. If the cohort had been followed up for a longer period, more melanomas would have developed. It is therefore suspected that the analyses would then have resulted in more significant outcomes; therefore, we consider our findings conservative. Our analysis, not surprisingly, confirmed the findings of other publications1,2 that the presence of a CDKN2A mutation yields a higher risk of melanoma compared with families without such a mutation, implicating a lower melanoma risk in families with unresolved genetic mechanisms. Regarding the distribution of childhood nevi, the analyses revealed a high association with melanoma distribution in adulthood. This correlation could also be found in the distribution of adulthood nevi and melanoma distribution. Melanoma in adulthood tends to develop more frequently on the sites with the highest nevus count in adulthood according to the literature.9-11 Several correlations could not be found in the 25% or less group, which can be viewed as a matched control group, supporting the positive correlations we found in the 50% or greater group. The 25% or less group consisted of children from the same families who shared the same genetic background and environmental exposure. They were included completely at random, years before the identification of the CDKN2A gene. Both risk groups are expected to contain a few people who belong to the other group, so-called misclassifications. These misclassifications dilute findings but have nevertheless led to significant outcomes. Children and young adults most often do not want to be genetically tested for financial reasons, which prevented us from definitively classifying all individuals. The association between the occurrence of nevi and the CDKN2A mutation is puzzling. The children included in our study have been selected solely on the basis of multiple melanoma patients in their family. Later, in 21 of the 34 families, a CDKN2A mutation was found. Linkage analysis performed in 1993 on the Leiden FAMMM families provided evidence of linkage of the atypical nevi phenotype to the melanoma locus on chromosome 9p21.17 Inclusion of family members with 10 or more atypical nevi and/or melanoma as affected individuals led to a slight decrease in the logarithm of the odds score compared with inclusion of melanoma patients alone. Broadening the inclusion criteria to persons with 5 or fewer atypical nevi as affected individuals resulted in a remarkably decreased logarithm of the odds score, suggesting that the presence of atypical nevi could not be ascribed entirely to a melanoma susceptibility gene in that locus. Several years later, a genome-wide scan that investigated the genetic component of atypical nevi in these large extended founder pedigrees with many family members with atypical nevi again did not reveal a nevus locus on chromosome 9p. The strongest evidence of an atypical nevus susceptibility gene was mapped to chromosome band 7q21.3, a region containing the candidate gene CDK6.18 Making use of advanced technological genome-wide association studies, Falchi et al19 reported a nevus-associated variant of MTAP adjacent to CDKN2A on chromosome 9p21. Other nevus-associated variants were identified on chromosome 22q13.19 In addition, protecting variants in the NID1 gene on chromosome 1q42 were recently identified.20 We do not know yet whether the currently identified nevus-related variants segregate with extensive moles in families. On the basis of the results of the current study, physicians should take additional care of children from families at high risk of melanoma. Children with a high number of melanocytic nevi and children with atypical nevi should be included in a surveillance program with their parents. Buttocks should be checked for moles. In addition, sun avoidance information should be provided, with emphasis on the prevention of sunburns. Despite the difficulty in performing long-term follow-up studies in children from families with melanoma, results of these studies provide us with additional information about risk factors and may help to detect melanoma as early as possible. Back to top Article Information Accepted for Publication: May 14, 2013. Corresponding Author: Wilma Bergman, MD, PhD, Leiden University Medical Center, Albinusdreef 2, 2300 RC Leiden, the Netherlands (w.bergman@lumc.nl). Published Online: November 6, 2013. doi:10.1001/jamadermatol.2013.5588. Author Contribution: Drs Vredenborg and Bergman had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis. Study concept and design: Vredenborg, Kukutsch, Bergman. Acquisition of data: Vredenborg, Boonk, Gruis, Out-Luijting. Analysis and interpretation of data: Vredenborg, Böhringer, Kukutsch, Bergman. Drafting of the manuscript: Vredenborg, Böhringer, Kukutsch, Bergman. Critical revision of the manuscript for important intellectual content: All authors. Statistical analysis: Vredenborg, Böhringer. Administrative, technical, or material support: Vredenborg, Boonk, Gruis, Out-Luijting, Kukutsch, Bergman. Study supervision: Vredenborg, Kukutsch, Bergman. Financial Disclosure: None reported. References 1. Ford D, Bliss JM, Swerdlow AJ, et al; the International Melanoma Analysis Group (IMAGE). Risk of cutaneous melanoma associated with a family history of the disease. Int J Cancer. 1995;62(4):377-381.PubMedGoogle ScholarCrossref 2. Goldstein AM, Tucker MA. Genetic epidemiology of familial melanoma. Dermatol Clin. 1995;13(3):605-612.PubMedGoogle Scholar 3. Eckerle MD, Bishop M, Resse E, et al. Familial atypical multiple mole melanoma syndrome. In: Riegert-Johnson DL, Boardman LA, Hefferon T, et al, eds. Cancer Syndromes. Bethesda, MD: National Center for Biotechnology Information; 2009. 4. Bishop JA, Wachsmuth RC, Harland M, et al. Genotype/phenotype and penetrance studies in melanoma families with germline CDKN2A mutations. J Invest Dermatol. 2000;114(1):28-33.PubMedGoogle ScholarCrossref 5. Gruis NA, van der Velden PA, Sandkuijl LA, et al. Homozygotes for CDKN2 (p16) germline mutation in Dutch familial melanoma kindreds. Nat Genet. 1995;10(3):351-353.PubMedGoogle ScholarCrossref 6. van der Rhee JI, Krijnen P, Gruis NA, et al. Clinical and histologic characteristics of malignant melanoma in families with a germline mutation in CDKN2A. J Am Acad Dermatol. 2011;65(2):281-288.PubMedGoogle ScholarCrossref 7. van der Rhee JI, de Snoo FA, Vasen HF, et al. Effectiveness and causes for failure of surveillance of CDKN2A-mutated melanoma families. J Am Acad Dermatol. 2011;65(2):289-296.PubMedGoogle ScholarCrossref 8. Psaty EL, Scope A, Halpern AC, Marghoob AA. Defining the patient at high risk for melanoma. Int J Dermatol. 2010;49(4):362-376.PubMedGoogle ScholarCrossref 9. Grulich AE, Bataille V, Swerdlow AJ, et al. Naevi and pigmentary characteristics as risk factors for melanoma in a high-risk population: a case-control study in New South Wales, Australia. Int J Cancer. 1996;67(4):485-491.PubMedGoogle ScholarCrossref 10. 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Genetic testing for melanoma. Lancet Oncol. 2002;3(11):653-654.PubMedGoogle ScholarCrossref 15. Grob JJ, Gouvernet J, Aymar D, et al. Count of benign melanocytic nevi as a major indicator of risk for nonfamilial nodular and superficial spreading melanoma. Cancer. 1990;66(2):387-395.PubMedGoogle ScholarCrossref 16. Newton Bishop JA, Bataille V, Pinney E, Bishop DT. Family studies in melanoma: identification of the atypical mole syndrome (AMS) phenotype. Melanoma Res. 1994;4(4):199-206.PubMedGoogle ScholarCrossref 17. Gruis NA, Sandkuijl LA, Weber JL, et al. Linkage analysis in Dutch familial atypical multiple mole-melanoma (FAMMM) syndrome families: effect of naevus count. Melanoma Res. 1993;3(4):271-277.PubMedGoogle Scholar 18. de Snoo FA, Hottenga JJ, Gillanders EM, et al. Genome-wide linkage scan for atypical nevi in p16-Leiden melanoma families. Eur J Hum Genet. 2008;16(9):1135-1141.PubMedGoogle ScholarCrossref 19. Falchi M, Bataille V, Hayward NK, et al. Genome-wide association study identifies variants at 9p21 and 22q13 associated with development of cutaneous nevi. Nat Genet. 2009;41(8):915-919.PubMedGoogle ScholarCrossref 20. Nan H, Xu M, Zhang J, et al. Genome-wide association study identifies nidogen 1 (NID1) as a susceptibility locus to cutaneous nevi and melanoma risk. Hum Mol Genet. 2011;20(13):2673-2679.PubMedGoogle ScholarCrossref

Journal

JAMA DermatologyAmerican Medical Association

Published: Jan 1, 2014

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