Molecular genetics of familial cutaneous melanoma

PURPOSE: A family history of melanoma is a significant risk factor for the disease, and recently several loci that determine susceptibility to the development of melanoma have been identified. The most important of these is p16/CDKN2A. We attempted to determine the degree to which the p16/CDKN2A gene has been implicated in the development of melanoma, and to identify other genetic factors that play a role as well. METHODS: We reviewed the literature published since the isolation of p16/CDKN2A and identified 13 studies that report the status of the gene in melanoma samples and 12 reports that examine p16/CDKN2A in melanoma kindreds. We also reviewed associated studies on CDK4 and RB1 involvement in melanoma, and examined the role of p16/CDKN2A in other inherited cancers. RESULTS: The evidence strongly implicates p16/CDKN2A in determining predisposition to malignant melanoma. Overall, approximately 20% of families that have been studied show mutations in the gene. However, because of clustering of sporadic cases in families, and potentially because of technical factors, this is likely an underestimate of the proportion of the genetic predisposition for melanoma that is due to p16/CDKN2A mutation. Rare families carry a mutated CDK4 gene that is also responsible for inherited melanoma. CONCLUSION: The gene p16/CDKN2A is an important determinant of melanoma risk. A commercial test is presently available to assess the status of this locus. However, because of uncertainties regarding the interpretation of the results of p16/CDKN2A genetic testing, we do not recommend routine clinical use of this test at this time.     

Screening of germline mutations in the CDKN2A and CDKN2B genes in Swedish families with hereditary cutaneous melanoma

BACKGROUND: Approximately 10% of human cutaneous melanomas occur in families in which several members are affected. The familial predisposition to this disease is often associated with dysplastic nevus syndrome, a condition in which afflicted family members have multiple dysplastic nevi (atypical moles). The chromosome region 9p21 and markers on chromosomes 1p and 6p have been linked to melanoma susceptibility. The tumor suppressor genes CDKN2A and CDKN2B have been mapped to the 9p21 region, and genetic analyses have revealed the presence of germline CDKN2A alterations in melanoma families. The reported frequencies of such alterations, however, vary among these families. PURPOSE: The present investigation was carried out to determine the frequencies of CDKN2A and CDKN2B germline gene mutations among members in a population-based cohort of Swedish melanoma families (i.e., melanoma kindreds). METHODS: DNA was prepared from blood samples obtained from 181 individuals belonging to 100 melanoma kindreds. The polymerase chain reaction (PCR) technique, followed by single-strand conformation polymorphism (SSCP) and nucleotide sequence analyses, were used to identify the types and frequencies of mutations in exons 1, 1beta, 2, and 3 of the CDKN2A gene and in exons 1 and 2 of the CDKN2B gene. RESULTS: CDKN2A gene aberrations were independently identified by both SSCP and nucleotide-sequence analyses. Nucleotide-sequence analysis identified a single point mutation leading to a substitution of leucine for proline in codon 48 of exon 1 in a family with a history of melanoma and several other cancers. A second abnormality, leading to an insertion of an extra arginine residue at codon number 113 of exon 2, was seen in four separate families. The CDKN2A exon-3 coding region had the wild-type sequence in all samples. No germline mutations were found in the alternative exon 1beta of the CDKN2A gene or in exons 1 and 2 of the CDKN2B gene. CONCLUSIONS: The present investigation demonstrates that CDKN2A germline gene mutations were observed in 7.8% of the 64 Swedish melanoma kindreds that each included at least two first-degree relatives with melanoma and dysplastic nevus syndrome. No CDKN2A exon 1beta or CDKN2B mutations were identified. The critical genes responsible for the inheritance of a susceptibility to develop melanoma among family members in this population have yet to be identified.     

Toxicity of cytostatic drugs to normal bone marrow cells in vitro

Metastatic melanomas are often resistant to chemotherapy. To study whether the p53 mutational status affects chemosensitivity, we compared the responses to chemotherapy of four melanoma cell lines containing the wild-type p53 and four cell lines carrying the mutant p53. Cisplatin, at 10 microM, virtually killed all the cells in the wild-type p53 cell lines, while 57-95% of the cells in the mutant p53 cell lines survived (P = 0.005). After treatment with 100 nM of vincristine, on average 18% of the wild-type p53 melanoma cells survived compared with 55% of the mutant p53 cells (P = 0.04). After treatment with 40 nM, 200 nM or 1 microM of camptothecin the survival rates were, on average, 16%, 8% and 4% for the wild-type p53 melanoma cells, compared with 89%, 67% and 38% for the mutant p53 cells, respectively (P = 0.00004, P = 0.003 and P = 0.04, respectively). The anticancer agents were not toxic to normal melanocytes at doses inducing cytotoxicity in wild-type p53 melanoma cells. The main mechanism of cytotoxicity appears to be drug-induced apoptosis. Cisplatin, camptothecin and vincristine all induced apoptosis in wild-type p53 melanoma cells, but not in mutant p53 cells. Our results suggest that chemotherapy-induced apoptosis in melanoma cells is p53 dependent, and mutation of the p53 gene is an indicator of drug resistance in melanoma.     

Study on the elimination of Angiostrongylus costaricensis first stage larvae in the experimental infection of Swiss mice

We report six of 16 U.K. melanoma families and two of 17 patients with multiple primary melanomas and a negative family history who have between them four different functionally damaging mutations of the CDKN2A (p16) gene: an Arg 24 Pro substitution in exon 1 in one family, a stop codon at codon 44 of exon 1 in one family, and a Met 53 Ile substitution in exon 2 in four families. One multiple primary melanoma patient also has the Met 53 Ile mutation and a second has a G-T substitution at the IVS2 + 1 splice donor site. Our data together with other recent publications from France and the U.S.A. indicate that screening melanoma kindreds with only two affected family members for CDKN2A mutations is justified.     

Growth arrest and suppression of tumorigenicity of bladder-carcinoma cell lines induced by the P16/CDKN2 (p16INK4A, MTS1) gene and other loci on human chromosome 9

Wild-type P16/CDKN2 (p16INK4A, MTS1) cDNA, directed by the cytomegalovirus (CMV) immediate early promoter, was transfected into RT4 and RT112 bladder-carcinoma cell lines bearing a mutated endogenous P16/CDKN2 gene and lacking endogenous P16/CDKN2 respectively. In both cases, only transfected clones with rearranged exogenous P16/CDKN2 cDNA could be grown and propagated in cell culture. This result is reminiscent of transfection of wild-type p53 into cells with a deleted or mutated endogenous gene and suggests that P16/CDKN2, over-expressed under control of the strong CMV promoter, induces growth arrest in RT4 and RT112 cells. Transfer of human chromosome 9 to RT4 cells produced RT4/H9 hybrid clones retaining the P16/CDKN2 gene, since in RT4/H9 cell clones P16/CDKN2-gene expression is modulated by the physiological control of chromosomal regulatory sequence. All the RT4/H9 clones lost the entire chromosome 9, except clone 4 and clone 5, which maintained a deleted and an intact chromosome 9 respectively. Loss of several loci in 9p21, including P16/CDKN2, in tumors induced in nude mice by clone 4 and clone 5 suggests that P16/CDKN2 or other genes in 9p21 suppress tumorigenicity in bladder-carcinoma cells. Tumors induced by clone 4 and clone 5 show loss of markers in 9q. The regions 9q22.3, 9q32-33 and 9q34.2, which were maintained in the 2 clones and lost in their derived tumors, may contain tumor-suppressor genes relevant in bladder carcinoma. The results of this study suggest that the P16/CDKN2 gene controls growth of bladder-carcinoma cells when it is over-expressed, and may be involved in the development of bladder carcinoma, but other genes in 9p21 and 9q may participate in bladder-cancer progression.     

Mutational analysis of CDKN2 (MTS1/p16ink4) in human breast carcinomas

The CDKN2 gene that encodes the cell cycle regulatory protein cyclin-dependent kinase-4 inhibitor (p16) has recently been mapped to chromosome 9p21. Frequent homozygous deletions of this gene have been documented in cell lines derived from different types of tumors, including breast tumors, suggesting that CDKN2 is a tumor suppressor gene involved in a wide variety of human cancers. To determine the frequency of CDKN2 mutations in breast carcinomas, we screened 37 primary tumors and 5 established breast tumor cell lines by single-strand conformation polymorphism analysis. In addition, Southern blot analysis was performed on a set of five primary breast carcinoma samples and five breast tumor cell lines. Two of the five tumor cell lines revealed a homozygous deletion of the CDKN2 gene, but no mutations were observed in any of the primary breast carcinomas. These results suggest that the mutation of the CDKN2 gene may not be a critical genetic change in the formation of primary breast carcinoma.     

Loss of heterozygosity and mutation analysis of the p16 (9p21) and p53 (17p13) genes in squamous cell carcinoma of the head and neck

We analyzed allelic loss at the p53 gene (17p13) and at chromosome region 9p21 in 35 primary head and neck squamous cell carcinomas. Loss of heterozygosity (LOH) at p53 and 9p21 was found in 50 and 75% of informative cases, respectively. LOH at the p53 gene did not increase significantly with tumor stage, but was more frequent in moderately and poorly differentiated tumors than in well-differentiated tumors. LOH plus mutation or homozygous deletion of p53 was limited to advanced stage and poorly differentiated tumors. Allelic loss at 9p21 is frequent in early stage head and neck squamous cell carcinoma and is not significantly associated with LOH at p53. The second exon of the p16/MTS1/CDKN2 gene was found to be homozygously deleted in 1 of 19 cases showing LOH at 9p21, but direct sequencing did not show mutations in the remaining 18 cases. This suggests that p16 plays a limited role in the development of head and neck squamous cell carcinoma.     

The 9p21 region in bladder cancer cell lines: large homozygous deletion inactivate the CDKN2, CDKN2B and MTAP genes

Homozygous and hemizygous deletions of 9p21 are the earliest and most common genetic alteration in bladder cancer. The identification of two cell cycle regulators, CDKN2 and CDKN2B, that map to the common region of deletion has prompted the hypothesis that they are critical tumor suppressor genes in this malignancy. However, controversy as to whether these genes are the only or even the most important target in bladder cancer oncogenesis remains. To more clearly determine the effect of these 9p21 alterations, we mapped the homozygous deletions and performed a detailed mutational and expression analysis for CDKN2, CDKN2B and a closely linked gene, methylthioadenoside phosphorylase (MTAP), in 16 established bladder cancer cell lines. Nine of the 16 lines exhibit large (30 to > 2000 kb) homozygous deletions on 9p21. All deletions include at least one exon of CDKN2, eight of nine include CDKN2B, and six of nine include MTAP. MTAP function correlates with the genomic deletions. SSCP and sequence analysis does not reveal any inactivating point mutations of CDKN2 or of CDKN2B in any of the cell lines without homozygous deletions, and all express the CDKN2 and the CDKN2B mRNA as well as the encoded p16 protein. The p16 protein levels vary widely and are correlated with absent pRb expression. We conclude that the 9p21 deletions in bladder cancer usually inactivate the CDKN2. CDKN2B, and MTAP genes but that CDKN2 is the most common target. Other mechanisms for inactivating this gene in bladder cancer appear to be uncommon.     

Analysis of p53 in human cutaneous melanoma cell lines

Mutations in the p53 tumour suppressor gene have been detected in a variety of human malignancies. Mutations have been found predominantly in conserved regions two to five. Our aim was to analyse p53 at the protein and DNA level in seven melanoma cell lines of cutaneous origin (HMB-2, DX3, LT5.1, MJM, SK23, A375P and A375M), including two parental/metastatic derivatives (A375P and A375M; DX3 and LT5.1). By immunohistochemical staining with three mouse monoclonal antibodies and a rabbit polyclonal serum, it was possible to observe differential nuclear expression of p53. The quantitation of p53 protein levels by ELISA correlated with the nuclear staining pattern. Western blotting showed an intact p53 protein in all cell lines; p53 was polymorphic in three cell lines (MJM, A375P and A375M). DNA sequencing studies showed that all cell lines had wild type p53. These results suggest that p53 is unlikely to play a significant role in the genesis of cutaneous melanoma.     

Growth inhibitory concentrations of EGF induce p21 (WAF1/Cip1) and alter cell cycle control in squamous carcinoma cells

Previous studies have reported inhibition of A431 squamous carcinoma cell growth by nanomolar concentrations of epidermal growth factor (EGF), a potent mitogen for cells of epithelial origin. In this study, we examined potential mechanisms through which inhibition of keratinocyte growth mediated by EGF might occur by analysing components of the cell cycle regulatory machinery in A431, HN6 and HN30 keratinocytes in the presence of growth inhibitory or growth stimulatory doses of EGF. Treatment of cells with 25 pM EGF produced an increase in [3H]thymidine incorporation in A431, HN6 and HN30 cells, with respect to control cultures. Exposure to 2.5 nM EGF reduced [3H]thymidine incorporation in A431 cells and HN6 cells to 11% and 70% of control levels, respectively, whereas HN30 cells continued to proliferate in the presence of EGF. [3H]thymidine incorporation assays carried out over 24 h revealed repression of DNA synthesis in A431 cells after 12 h exposure to 2.5 nM EGF compared to untreated cells. Flow cytometry studies demonstrated accumulation of cells in G0/G1 after addition of 2.5 nM, but not 25 pM EGF. Western blot analysis revealed elevation of p21 (WAF1/CIP1/SDI1) protein levels in A431 and HN6 cells under growth-inhibitory conditions. Stimulatory doses of EGF did not induce p21 in these cells. Northern blot hybridization demonstrated elevated levels of p21 mRNA within 4 h of exposure of A431 cells to 2.5 nM EGF, which remained elevated above basal levels at 24 h. In vitro kinase assays demonstrated temporal differences in CDK2 and CDK6 activities which were related to EGF concentration. Immunocomplex Western blotting demonstrated increased association of p21 with CDK2 and CDK6 in A431 cells treated with 2.5 nm EGF. Furthermore, temporal alterations in the association of PCNA with p21 and with CDK6 were observed. The data indicate that p21 is a likely mediator of EGF-induced growth-inhibition, probably through mechanisms involving sequestration of PCNA and inhibition of CDK activity.     

Genetic and epigenetic alterations of the cyclin-dependent kinase inhibitors p15INK4b and p16INK4a in human thyroid carcinoma cell lines and primary thyroid carcinomas

BACKGROUND: D-type cyclins, in association with the cyclin-dependent kinases CDK4 and CDK6, promote progression through the G1 phase of the cell cycle. CDK activity is modulated by inhibitors such as p15INK4b and p16INK4a. Loss of function of p15INK4b and p16INK4a (multiple tumor suppressor-I and CDK4 inhibitor) determines impairment in the control of the cell cycle and contributes to the transformation of several cell types. METHODS: The authors examined 20 thyroid neoplasms (12 papillary carcinomas and 8 follicular adenomas) and 4 human thyroid carcinoma cell lines for gene mutations and epigenetic modifications of the p15INK4b and p16INK4a genes by Southern blot analysis, single strand conformation polymorphism, and a polymerase chain reaction-based methylation assay. RESULTS: Abnormalities of p16 were found in the four cell lines studied. In follicular carcinoma (WRO) cells, both the p15 and p16 genes were homozygously deleted. Undifferentiated carcinoma (FRO) cells had a nonsense point mutation at codon 72 (CGA-TGA, Arg-Stop) of p16, whereas the poorly differentiated papillary carcinoma (NPA) line harbored a point mutation at the exon 1-intron 1 boundary that altered the donor splicing site and caused an aberrantly spliced form of p16INK4a. Furthermore, p16 allelic loss was evident in the DNA of both FRO and NPA cells. Finally, p16 expression was absent in the ARO cell line, likely due to a de novo methylation of exon 1 of p16INK4a. Regarding the primary thyroid tumors, a missense point mutation at codon 91 was found in 1 of 12 papillary thyroid carcinomas (GCC-GTC, Ala-Val). No mutations were found in follicular adenomas. However, in 6 of 20 primary tumors there was hypermethylation at exon 1 of p16. CONCLUSIONS: The high prevalence of p15 and p16 mutations in the cell lines described suggests involvement of these genes in immortalization in vitro. The p16 defects may have preexisted in a small subclone of the primary tumor that were selected for in vitro. Alternatively, p16 mutations may have arisen de novo during cell culture. Mutations of p15INK4b and p16INK4a do not appear to be critical events in the development of follicular adenomas or papillary carcinomas. However, de novo methylation of the 5' CpG island of p16 is common in primary tumors, indicating that the function of this gene may be lost as an epigenetic event during disease progression.     

Genomic organization and mutation analysis of Hel-N1 in lung cancers with chromosome 9p21 deletions

Allelic loss of chromosome 9p21 is common in small cell lung cancer (SCLC), but inactivation of the tumor suppressor gene CDKN2a is rare, implying the existence of another target gene at 9p21. A recent deletion mapping study of chromosome 9p has also identified a site of deletion in non-small cell lung cancer (NSCLC) centered around D9S126. The Hel-N1 (human elav-like neuronal protein 1) gene encodes a neural-specific RNA binding protein that is expressed in SCLC. We have mapped this potentially important gene in lung tumorigenesis to within 100 kb of the D9S126 marker at chromosome band 9p21 by using homozygously deleted tumor cell lines and fluorescence in situ hybridization to normal metaphase spreads. Hel-N1 is, therefore, a candidate target suppressor gene in both SCLC and NSCLC. We have determined the genomic organization and intron/exon boundaries of Hel-N1 and have screened the entire coding region for mutations by sequencing 14 primary SCLCs and cell lines and 21 primary NSCLCs preselected for localized 9p21 deletion or monosomy of chromosome 9. A homozygous deletion including Hel-N1 and CDKN2a was found in a SCLC cell line, and a single-base polymorphism in exon 2 of Hel-N1 was observed in eight tumors. No somatic mutations of Hel-N1 were found in this panel of lung tumors. Hel-N1 does not appear to be a primary inactivation target of 9p21 deletion in lung cancer.