- Short Report
- Open Access
Mutation screening of CHD5 in melanoma-prone families linked to 1p36 revealed no deleterious coding or splice site changes
BMC Research Notes volume 1, Article number: 86 (2008)
A subset of cutaneous malignant melanoma and dysplastic nevi (CMM/DN) families is linked to 1p36. To date, no CMM/DN susceptibility gene has been identified at this locus. Data from mouse studies identified chromodomain helicase DNA binding protein 5 (CHD5) as a tumor suppressor affecting cellular proliferation and apoptosis via the CDKN2A/p53 pathway. Based on these findings, we felt it was important to screen CHD5 as a familial CMM/DN susceptibility gene.
Eight unrelated CMM/DN families showing prior evidence of linkage to the 1p36 locus were identified for CHD5 mutation screening. One CMM/DN affected and one unaffected individual from each family were selected for sequencing of the CHD5 coding exons and their respective intron-exon boundaries. CHD5 variants that were identified solely among affecteds in the screening panel were further assessed by sequencing additional affected and unaffected members of these families to determine if the variant co-segregated with the CMM/DN phenotype.
Single nucleotide polymorphisms in the CHD5 intronic and coding regions were identified among affecteds in the screening panel. None of these variants completely co-segregated with CMM/DN affection status among these eight families.
There is no evidence to support CHD5 as a major melanoma susceptibility gene among the eight CMM/DN families screened.
Familial cutaneous malignant melanoma results from a complex interplay of genetic and environmental components. The etiologic complexity is compounded by the presence of genetic heterogeneity . Two major susceptibility genes CDKN2A (MIM 600160), CDK4 (MIM 123829) and a modifier gene MC1R (MIM 155555) have been identified . Mutations in CDKN2A account for 20–40% of CMM kindreds , while CDK4 mutations have been identified in < 10 CMM families [3–6]. MC1R variants have been associated with melanoma risk among individuals of European descent [7, 8] and as a modifier of melanoma risk in CDKN2A mutation-positive CMM families [9–11]. Two putative chromosome 1p melanoma susceptibility loci (1p22, 1p36) [12–15] have been identified by linkage analysis in a subset of CMM families. In particular, families exhibiting CMM/DN phenotype showed simultaneous linkage to both 1p36 and 9p21 . To date, no candidate genes have been identified at either 1p22 or 1p36.
Deletion of chromosomal band 1p36 is frequently observed in many human cancers including melanoma [16, 17] and has been hypothesized to contain a tumor suppressor gene. In 2007, Bagchi et al.  engineered a mouse with a deletion or duplication of a genomic interval corresponding to human 1p36. Flow cytometry studies of mouse embryonic fibroblasts revealed that mice with a heterozygous deletion exhibited enhanced cellular proliferation whereas mice carrying a duplication showed enhanced senescence. Gene knockdown/rescue experiments identified chromodomain helicase DNA binding domain 5 (Chd5) as the putative dosage-sensitive gene responsible for the observed haploinsufficiency-associated cellular proliferation and duplication-associated apoptosis. Subsequent experiments showed that Chd5 mediated apoptosis involved p53 and that Chd5 haploinsufficiency led to decreased expression of CDKN2A (p16) and p19 (human p14ARF- alternate-spliced exon 1β transcript of CDKN2A, aka ARF) . These findings support CHD5 (MIM 610771) as a putative candidate gene for familial CMM kindreds mapping to 1p36.
To evaluate if CHD5 is a major melanoma susceptibility gene in CMM/DN kindreds showing linkage to 1p36, we selected a panel of 16 individuals from eight CMM/DN families for sequencing of all CHD5 coding exons and their respective intron-exon boundaries.
Eight familial CMM/DN kindreds with previous evidence of linkage to 1p36  were selected for CHD5 sequencing. The 1p36 linkage among the CMM/DN families were based on three genotyped markers D1S47 (RFLP), Zmax 2.82 at θ = 0.1, D1S160, Zmax 3.71 at θ = 0.1 and PND (RFLP located in the NPPA gene), Zmax 2.0 at θ = 0.1 . D1S47 is located adjacent to CHD5, D1S160 and PND are located 3 and 6 Mb (respectively) centromeric to CHD5. Five of these families showed linkage to both 1p36 and 9p21. Among these five families, four have CDKN2A mutations and one has an ARF mutation. Among the three remaining families, two have CDK4 mutations and one has no identified mutation in CDKN2A nor CDK4 (Table 1). The families averaged seven CMM patients (minimum, four). The median age at first CMM diagnosis was 31 years; half the CMM patients had multiple melanoma tumors. One affected and one unaffected family member was selected for CHD5 mutation screening except for family G in which two affecteds were selected because both the paternal and maternal lineages showed CMM/DN (Table 1). The affecteds were selected based on sharing the putative 1p36 haplotype and the unaffected were chosen who did not share the 1p36 haplotype. All study subjects are of Caucasian descent. This study was approved by the institutional review board of the US National Cancer Institute and adheres to the tenets of the Helsinki Declaration. Written, informed consent was obtained from all participants.
Genomic DNA from a panel of 16 individuals (Table 1) was analyzed for CHD5 mutations by bi-directional sequencing of all coding exons. Intron-exon boundaries were determined by aligning the reference CHD5 mRNA (NM_015557) sequence to the genomic sequence (AL031847, AL035406) with NCBI Spidey . We looked for potentially damaging changes that affect splice donor/acceptor sites or caused in- or out-of-frame deletions/duplications, non-conservative amino acid coding changes and nonsense substitutions. PCR primers were designed to amplify exons and flanking introns. Primer sequences and PCR conditions for each exon are detailed in Table 2. Taq Gold (Applied Biosystems, Foster City, CA) or Advantage GC-2 polymerase (Clontech, Mountain View, CA) were used to amplify the genomic DNA from each subject. Sequencing reactions were performed on PCR purified products using BigDye v3.1 chemistry and analyzed with an automated 3130XL Genetic Analyzer (Applied Biosystems).
Sequence-derived electropherograms from the 16 individuals were compared with the published CHD5 sequence using Sequencher v4.6 software (Gene Codes Corp., Ann Arbor, MI).
Computational analysis of single nucleotide polymorphisms
PMUT  online tool was used to assess the potential functional effects of missense changes found in CHD5. PMUT utilizes neural networks trained with a large database of neutral and disease-associated human mutations to predict the effects of single amino acid substitutions. The user inputs the reference amino acid sequence of the protein and designates the position of the amino acid substitution of interest. The output is a pathogenicity index ranging from 0 to 1 (indices > 0.5 predict a pathologic change and < 0.5 a neutral change) and a confidence index ranging from 0 (low) to 9 (high) .
ESEfinder 3.0  was used to scan the genomic region containing SNPs found only among affected individuals in the screening panel for the identification of splice enhancer binding sites in the wildtype sequence. A comparison was then made with the variant sequence to determine if the single nucleotide substitution created a new splice enhancer binding site or destroyed an existing binding site.
All coding exons and flanking intronic sequence were examined. Six single nucleotide polymorphisms (SNPs) located in introns and four in the coding region (cSNPs) were detected in one or more affected individuals in the screening panel (Table 3). Among the 10 SNPs detected, four were previously identified in the dbSNP database and have an assigned rs identification number  and six are newly discovered (Table 3). Of the four cSNPs, three are synonymous and one is a nonsynonymous nucleotide change leading to a substitution of isoleucine for methionine at position 1117 (I1117M, Table 3). I1117M variant was detected in family AH in affected individual (AH-3005) and was not present in the unaffected individual (AH-3006) (Fig. 1a) or among the remainder of individuals in the screening panel (Table 1). Isoleucine 1117 is located in the C-terminal DNA binding domain of CHD5. Amino acid sequence alignment of the reference CHD5 protein (NP_056372) with mammalian Chd5 orthologs and non-mammalian paralogs (i.e. Chd-3 C. elegans, Chd4 in Danio and Xenopus) revealed high conservation of isoleucine at position 1117 (Fig. 1b). Computational analysis of the potential deleterious effects of the I1117M variant using the online tool PMUT predicted that this is a neutral substitution (index 0.049) with a reliability index of 9 (high). Scanning the genomic region of the four cSNPs (Table 3) with ESEfinder 3.0  found a potential change in the c.531G>A (P177P) variant. The G to A nucleotide substitution at position 531 may potentially eliminate two SF2/ASF binding sites and create a new SC35 binding site in this region. There were no changes in exonic splice enhancer binding sites detected by ESEfinder 3.0 among the other three cSNPs.
Among the six intronic SNPs associated with affected individuals in the screening panel, two located in introns 8 and 11 have been previously identified (rs41279496, rs17489787) in dbSNP  and four are newly discovered in this study (Table 3). Computational search of the genomic region containing these six intronic SNPs for exonic splice enhancer sequence with the online tool ESEfinder 3.0  found no destruction of existing splice enhancer binding sites or creation of additional binding sites by these SNPs.
Sequencing of additional affected and unaffected members from family AH revealed that the I1117M variant is present in the unaffected mother of AH-3005, but not in his affected father nor in the four remaining CMM/DN affected individuals in this family. Sequence analysis of the remainder of the intronic SNPs and synonymous cSNPs detected in the screening panel (Table 3) among additional affected and unaffected family members from each respective family revealed that these polymorphisms did not co-segregate with the CMM/DN trait.
The search for additional major susceptibility genes for familial melanoma has remained elusive. Currently two genes (CDKN2A, CDK4) have been identified and together account for ≤ 40% of all CMM families. Thus, a majority of CMM families do not have a defined CMM susceptibility gene. Linkage analysis of CDKN2A, CDK4 mutation negative families identified a susceptibility locus at 1p22 , however, no candidate gene has been identified. Prior linkage studies identified a subset of CMM/DN families with simultaneous linkage to 9p21 and 1p36 . Loss of heterozygosity at 1p36 was originally found in neuroblastoma  and has subsequently been reported in many types of human tumors  suggesting the presence of a tumor suppressor gene(s) in this region. Somatic deletion of the 1p36 locus occurs in a wide range of solid and lymphoid tumors  and has been observed in nodular, metastatic and superficial spreading melanomas [16, 17]. Therefore the loss of a common tumor suppressor gene or a combination of several genes in this region may predispose to tumor development or contribute to tumor progression [24, 25].
Recently, CHD5 was identified as a candidate tumor suppressor gene [18, 24] by the use of Cre-loxP site-specific recombinant technology to generate a region of gain or loss of mouse chromosome 4 corresponding to the human 1p36 locus. Bagchi et al [18, 24] was able to demonstrate that mouse cells with an extra copy of chromosome 4 corresponding to human 1p36 exhibited enhance cellular senescence. The observed cellular senescence was rescued by RNAi-mediated knockdown of p53. Mouse cells deficient in Chd5 due to loss of one copy by Cre-loxP-mediated recombination expressed decreased levels of p53, p16 and p19. Subsequent experiments showed that cellular proliferation can be restored by depletion of p19 suggesting that Chd5 regulated p53 expression and that cell growth was directed through chromatin remodeling and control of gene expression at the CDKN2A (p16/p19) locus.
Among the eight CMM/DN families screened for CHD5 mutations in this study, only one family (AH) was found to have a missense coding change. However, upon in depth mutation analysis of family AH with additional affected and unaffected family members, the I1117M variant was found to be inherited from the unaffected mother. Family AH consists of six CMM/DN affected individuals. The CMM/DN phenotype is inherited through the paternal side of the family. Neither the affected father nor additional affected individuals carried the I1117M variant. This finding strongly suggests that the I1117M variant is not associated with the CMM/DN phenotype. Sequence analysis of the remaining intronic SNPs and synonymous cSNPs found in the screening panel (Table 3) among additional affected and unaffected individuals from their respective CMM/DN kindreds revealed that none of these variants showed complete co-segregation with the CMM/DN phenotype. Taken together, these results did not support CHD5 as a melanoma susceptibility gene in these eight families.
Limitations of this study include small sample size. Also we did not possess a source of mRNA to study CHD5 expression in tumor or compare melanocyte expression of CHD5 between affected individuals and controls. To our knowledge, the eight families screened represent all the known CMM families linked to 1p36. We limited our CHD5 mutation screen to the coding regions and flanking splice sites, thus changes to promoter, enhancer and micro-RNA binding sites may have been missed. We caution that our findings pertain only to the eight families screened in this study and should not be generalized to other CMM families.
In conclusion, we have not found evidence that CHD5 is a major melanoma susceptibility gene among the eight CMM/DN families screened. We are not aware of additional CMM families linked to the 1p36 locus. Thus, mutation screening of more 1p36-linked families may be challenging. Given the small number of families analyzed, a rare mutation in CHD5 may have been missed.
- CDKN2A :
cyclin-dependent kinase inhibitor 2A
- CDK4 :
cyclin-dependent kinase 4
- CHD4 :
chromodomain helicase DNA-binding protein 4
- CHD5 :
chromodomain helicase DNA-binding protein 5
cutaneous malignant melanoma and dysplastic nevi
single nucleotide polymorphism database
- MC1R :
melanocortin 1 receptor
alternate designation for CDKN2A
designation for alternate-spliced exon 1β transcript of CDKN2A: SNP, single nucleotide polymorphism.
Hayward NK: Genetics of melanoma predisposition. Oncogene. 2003, 22: 3053-3062. 10.1038/sj.onc.1206445.
Goldstein AM, Chan M, Harland M, Gillanders EM, Hayward NK, Avril MF, Azizi E, Bianchi-Scarra G, Bishop DT, Bressac-de Paillerets B, Bruno W, Calista D, Cannon Albright LA, Demenais F, Elder DE, Ghiorzo P, Gruis NA, Hansson J, Hogg D, Holland EA, Kanetsky PA, Kefford RF, Landi MT, Lang J, Leachman SA, Mackie RM, Magnusson V, Mann GJ, Niendorf K, Newton Bishop J, Palmer JM, Puig S, Puig-Butille JA, de Snoo FA, Stark M, Tsao H, Tucker MA, Whitaker L, Yakobson E, Melanoma Genetics Consortium (GenoMEL): High-risk melanoma susceptibility genes and pancreatic cancer, neural system tumors, and uveal melanoma across GenoMEL. Cancer Res. 2006, 66: 9818-9828. 10.1158/0008-5472.CAN-06-0494.
Zuo L, Weger J, Yang Q, Goldstein AM, Tucker MA, Walker GJ, Hayward N, Dracopoli NC: Germline mutations in the p16INK4a binding domain of CDK4 in familial melanoma. Nat Genet. 1996, 12: 97-99. 10.1038/ng0196-97.
Soufir N, Avril MF, Chompret A, Demenais F, Bombled J, Spatz A, Stoppa-Lyonnet D, Benard J, Bressac-de Paillerets B: Prevalence of p16 and CDK4 germline mutations in 48 melanoma-prone families in France. The French Familial Melanoma Study Group. Hum Mol Genet. 1998, 7: 209-216. 10.1093/hmg/7.2.209.
Molven A, Grimstvedt MB, Steine SJ, Harland M, Avril MF, Hayward NK, Akslen LA: A large Norwegian family with inherited malignant melanoma, multiple atypical nevi, and CDK4 mutation. Genes Chromosomes Cancer. 2005, 44: 10-18. 10.1002/gcc.20202.
Pjanova D, Engele L, Randerson-Moor JA, Harland M, Bishop DT, Newton Bishop JA, Taylor C, Debniak T, Lubinski J, Kleina R, Heisele O: CDKN2A and CDK4 variants in Latvian melanoma patients: analysis of a clinic-based population. Melanoma Res. 2007, 17: 185-191. 10.1097/CMR.0b013e328014a2cd.
Valverde P, Healy G, Sikkink S, Haldane F, Thody AJ, Carothers A, Jackson IJ, Rees JL: The Asp84Glu variant of the melanocortin 1 receptor (MC1R) is associated with melanoma. Hum Mol Genet. 1996, 5: 1663-1666. 10.1093/hmg/5.10.1663.
Palmer JS, Duffy DL, Box NF, Aitken JF, O'Gorman LE, Green AC, Hayward NK, Martin NG, Sturm RA: Melanocortin-1 receptor polymorphisms and risk of melanoma: is the association explained solely by pigmentation phenotype?. Am J Hum Genet. 2000, 66: 176-186. 10.1086/302711.
Box NF, Duffy DL, Chen W, Stark M, Martin NG, Sturm RA, Hayward NK: MC1R genotype modifies risk of melanoma in families segregating CDKN2A mutations. Am J Hum Genet. 2001, 69: 765-773. 10.1086/323412.
Velden van der PA, Sandkuijl LA, Bergman W, Pavel S, van Mourik L, Frants RR, Gruis NA: Melanocortin-1 receptor variant R151C modifies melanoma risk in Dutch families with melanoma. Am J Hum Genet. 2001, 69: 774-779. 10.1086/323411.
Goldstein AM, Landi MT, Tsang S, Fraser MC, Munroe DJ, Tucker MA: Association of MC1R variants and risk of melanoma-prone families with CDKN2A mutations. Cancer Epidemiol Biomarkers Prev. 2005, 14: 2208-2212.
Gillanders E, Juo SH, Holland EA, Jones M, Nancarrow D, Freas-Lutz D, Sood R, Park N, Faruque M, Markey C, Kefford RF, Palmer J, Bergman W, Bishop DT, Tucker MA, Bressac-de Paillerets B, Hansson J, Stark M, Gruis N, Bishop JN, Goldstein AM, Bailey-Wilson JE, Mann GJ, Hayward N, Trent J, Lund Melanoma Study Group; Melanoma Genetics Consortium: Localization of a novel melanoma susceptibility locus to 1p22. Am J Hum Genet. 2003, 73: 301-313. 10.1086/377140.
Bale SJ, Dracopoli NC, Tucker MA, Clark WH, Fraser MC, Stanger BZ, Green P, Donis-Keller H, Housman DE, Greene MH: Mapping the gene for hereditary cutaneous melanoma-dysplastic nevus syndrome to chromosome 1p. N Engl J Med. 1989, 320: 1367-1372.
Goldstein AM, Dracopoli NC, Ho EC, Fraser MC, Kearns KS, Bale SJ, McBride OW, Clark WH, Tucker MA: Further evidence for a locus for cutaneous malignant melanoma-dysplastic nevus (CMM/DN) on chromosome 1p, and evidence for genetic heterogeneity. Am J Hum Genet. 1993, 52: 537-550.
Goldstein AM, Goldin LR, Dracopoli NC, Clark WH, Tucker MA: Two-locus linkage analysis of cutaneous malignant melanoma/dysplastic nevi. Am J Hum Genet. 1996, 58: 1050-1056.
Hussein MR, Roggero E, Tuthill RJ, Wood GS, Sudilovsky O: Identification of novel deletion loci at 1p36 and 9p22-21 in melanocytic dysplastic nevi and cutaneous malignant melanoma. Arch Dermatol. 2003, 139: 816-817. 10.1001/archderm.139.6.816.
Poetsch M, Dittberner T, Woenckhaus C: Microsatellite analysis at 1p36.3 in malignant melanoma of the skin: fine mapping in search of a possible tumor suppressor gene region. Melanoma Res. 2003, 13: 29-33. 10.1097/00008390-200302000-00006.
Bagchi A, Papazoglu C, Wu Y, Capurso D, Brodt M, Francis D, Bredel M, Vogel H, Mills AA: CHD5 is a tumor suppressor at human 1p36. Cell. 2007, 128: 459-475. 10.1016/j.cell.2006.11.052.
National Center for Biotechnology Information (NCBI) Spidey. [http://0-www.ncbi.nlm.nih.gov.brum.beds.ac.uk/spidey/]
Ferrer-Costa C, Gelpi JL, Zamakola L, Parraga I, de la Cruz X, Orozco M: PMUT: a web-based tool for the annotation of pathological mutations on proteins. Bioinformatics. 2005, 21: 3176-3178. 10.1093/bioinformatics/bti486. [http://mmb2.pcb.ub.es:8080/PMut/]
Smith PJ, Zhang C, Wang J, Chew SL, Zhang MQ, Krainer AR: An increased specificity score matrix for the prediction of SF2/ASF-specific exonic splicing enhancers. Hum Mol Genet. 2006, 15: 2490-2508. 10.1093/hmg/ddl171. [http://rulai.cshl.edu/cgi-bin/tools/ESE3/esefinder.cgi?process=home]
Single nucleotide polymorphism database (dbSNP). [http://0-www.ncbi.nlm.nih.gov.brum.beds.ac.uk/projects/SNP/]
Brodeur GM, Sekhon G, Goldstein MN: Chromosomal aberrations in human neuroblastomas. Cancer. 1977, 40: 2256-2263. 10.1002/1097-0142(197711)40:5<2256::AID-CNCR2820400536>3.0.CO;2-1.
Bagchi A, Mills AA: The quest for the 1p36 tumor suppressor. Cancer Res. 2008, 68: 2551-2556. 10.1158/0008-5472.CAN-07-2095.
Okawa ER, Gotoh T, Manne J, Igarashi J, Fujita T, Silverman KA, Xhao H, Mosse YP, White PS, Brodeur GM: Expression and sequence analysis of candidates for the 1p36.31 tumor suppressor gene deleted in neuroblastomas. Oncogene. 2008, 28: 803-810. 10.1038/sj.onc.1210675.
This research was supported by the Intramural Research Program of the NIH, National Cancer Institute, Division of Cancer Epidemiology and Genetics.
The authors declare that they have no competing interests.
DN provided the bioinformatics support, designed and carried out the sequencing of CHD5. He collated, analyzed the sequencing data and drafted the manuscript. AG generated the hypothesis for this study, reviewed the sequence variants and affection status among the eight CMM/DN pedigrees and derived the segregation analysis of the CHD 5 variants. XY and AG identified the eight CMM/DN families showing linkage to 1p36. MT identified and evaluated the CMM/DN families. All authors read, contributed to and approved the final manuscript.
Authors’ original submitted files for images
Below are the links to the authors’ original submitted files for images.
About this article
Cite this article
Ng, D., Yang, X.R., Tucker, M.A. et al. Mutation screening of CHD5 in melanoma-prone families linked to 1p36 revealed no deleterious coding or splice site changes. BMC Res Notes 1, 86 (2008). https://0-doi-org.brum.beds.ac.uk/10.1186/1756-0500-1-86
- 1p36 Locus
- Exonic Splice Enhancer
- Screening Panel
- Unaffected Family Member