Haplotype analysis of two recurrent CDKN2A mutations in 10 melanoma families: Evidence for common founders and independent mutations

Germ-line mutations in CDKN2A have been shown to predispose to cutaneous malignant melanoma. We have identified 2 new melanoma kindreds which carry a duplication of a 24bp repeat present in the 5′ region of CDKN2A previously identified in melanoma families from Australia and the United States. This mutation has now been reported in 5 melanoma families from 3 continents: Europe, North America, and Australasia. The M53I mutation in exon 2 of CDKN2A has also been documented in 5 melanoma families from Australia and North America. The aim of this study was to determine whether the occurrence of the mutations in these families from geographically diverse populations represented mutation hotspots within CDKN2A or were due to common ancestors. Haplotypes of 11 microsatellite markers flanking CDKN2A were constructed in 5 families carrying the M53I mutation and 5 families carrying the 24bp duplication. There were some differences in the segregating haplotypes due primarily to recombinations and mutations within the short tandem-repeat markers; however, the data provide evidence to indicate that there were at least 3 independent 24bp duplication events and possibly only 1 original M53I mutation. This is the first study to date which indicates common founders in melanoma families from different continents. Hum Mutat 11:424–431, 1998. © 1998 Wiley-Liss, Inc.     

CDKN2A mutations in Spanish cutaneous malignant melanoma families and patients with multiple melanomas and other neoplasia

The CDKN2A gene has been implicated in cutaneous malignant melanoma (CMM) in about 40% of families with linkage to chromosome 9p21, while a small proportion of families have mutations in the CDK4 gene. In order to estimate the importance of these genes in the predisposition to CMM in Spanish families and patients we have analysed, by SSCA, a total of 56 subjects belonging to 34 CMM families, and nine patients with multiple CMM and other neoplasia. We have detected germline CDKN2A mutations in six out of the 34 families (17%). A frameshift mutation (358delG) and four missense mutations (G59V, G101W (two cases), D84Y, and R87W) were identified. Five CMM patients from different families (14%) carried the A148T variant, which is known not to affect p16 activity. No mutations were detected in the patients with multiple CMM or other neoplasms. We have not found mutations either in exon 1 beta of the CDKN2A gene or in exon 2A of CDK4. Linkage analysis of the 9p21 region showed exclusion for one of the families for CMM and for four families for CMM/dysplastic naevi. This study indicates a small role for CDKN2A in Spanish CMM families and suggests that other genes are also responsible for CMM predisposition.     

Clinical and genetic analysis of 18 pancreatic carcinoma/melanoma‐prone families

Bartsch DK, Langer P, Habbe N, Matthäi E, Chaloupka B, Sina M, Hahn SA, Slater EP. Clinical and genetic analysis of 18 pancreatic carcinoma/melanoma‐prone families. Families with both melanoma and pancreatic cancer are extremely rare and some are affected with the autosomal dominant inherited familial atypical multiple mole melanoma‐pancreatic cancer (FAMMM‐PC) syndrome. The phenotypic and genotypic expressions of such pancreatic cancer–melanoma prone families are not well defined. The National Case Collection of Familial Pancreatic Cancer of the Deutsche Krebshilfe includes 110 pancreatic cancer families, 18 of which (16%) show an association of pancreatic cancer and melanoma. These 18 families were analysed regarding their phenotype and the prevalence of germline mutations in the candidate genes CDKN2A, BRCA2, CHEK2, NOD2, ARL11 and Palladin (PALLD). There were two types of families: five families with the FAMMM‐PC phenotype and 13 PC/melanoma families without the multiple mole phenotypes (PCMS). The prevalences of PC and melanoma in the two types of families were similar. The prevalence of other tumour types, especially breast carcinoma, was higher (11%) in PCMS‐ than in FAMMM‐PC families (2.4%, p = 0.02). CDKN2A mutations were identified in 2 of 18 (11%) PCMS families. A cosegregating BRCA2 mutation was detected in one PCMS family without breast cancer. None of the reported germline mutations in the NOD2, Palladin, ARL11 or CHEK2 genes were detected in either type of family. In conclusion, families with an accumulation of PC and melanoma show a large variety of phenotypic expression, which is not always consistent with the FAMMM‐PC phenotype. More PC/melanoma‐prone families need to be analysed to clarify whether such families represent variations of the FAMMM‐PC syndrome or two distinct hereditary cancer syndromes.     

High prevalence of the G101W germline mutation in the CDKN2A (P16ink4a) gene in 62 Italian malignant melanoma families

CDKN2A germline mutation frequency estimates are commonly based on families with several melanoma cases. When we started counseling in a research setting on gene susceptibility analysis in northern and central Italy, however, we mostly found small families with few cases. Here we briefly characterize those kindred, estimate CDKN2A/CDK4 mutation test yields, and provide indications on the possibility of implementing formal DNA testing for melanoma‐prone families in Italy. In September 1995 we started genetic counseling in a research setting at our Medical Genetics Center. Screening for CDKN2A/CDK4 mutations was performed on families with two melanoma patients, one of whom was younger than 50 years at onset, the other complying with one of the following: 1) being a first‐degree relative, 2) having an additional relative with pancreatic cancer, or 3) having multiple primary melanomas. Sixty‐two of 67 (80%) melanoma cases met our criteria. Four previously described CDKN2A mutations (G101W, R24P, V126D, and N71S) were found in 21 of the 62 families (34%) with a high prevalence of G101W (18/21). The percentage of families with two melanoma cases/family harboring a mutation was low (7%, 2/27), but rose to 45% (9/20) if one of the melanoma patients carried multiple melanomas or if pancreatic cancer was present in that family. In the 15 families with three melanoma cases the presence of a mutation was higher (67%, 10/15) and reached 100% in the 4 families with four or more melanoma cases. Our results suggest that CDKN2A/CDK4 counseling‐based mutational analysis may be reasonably efficient also for families with two melanoma cases, if one patient carries multiple melanomas or if pancreatic cancer is present in the family. © 2002 Wiley‐Liss, Inc.     

Functional,structural, and genetic evaluation of 20 CDKN2A germ line mutations identified in melanoma‐prone families or patients

Germline mutations of the CDKN2A gene are found in melanoma‐prone families and individuals with multiple sporadic melanomas. The encoded protein, p16^INK4A, comprises four ankyrin‐type repeats, and the mutations, most of which are missense and occur throughout the entire coding region, can disrupt the conformation of these structural motifs as well as the association of p16^INK4a with its physiological targets, the cyclin‐dependent kinases (CDKs) CDK4 and CDK6. Assessing pathogenicity of nonsynonymous mutations is critical to evaluate melanoma risk in carriers. In the current study, we investigate 20 CDKN2A germline mutations whose effects on p16^INK4A structure and function have not been previously documented (Thr18_Ala19dup, Gly23Asp, Arg24Gln, Gly35Ala, Gly35Val, Ala57Val, Ala60Val, Ala60Arg, Leu65dup, Gly67Arg, Gly67_Asn71del, Glu69Gly, Asp74Tyr, Thr77Pro, Arg80Pro, Pro81Thr, Arg87Trp, Leu97Arg, Arg99Pro, and [Leu113Leu;Pro114Ser]). By considering genetic information, the predicted impact of each variant on the protein structure, its ability to interact with CDK4 and impede cell proliferation in experimental settings, we conclude that 18 of the 20 CDKN2A variants can be classed as loss of function mutations, whereas the results for two remain ambiguous. Discriminating between mutant and neutral variants of p16^INK4A not only adds to our understanding of the functionally critical residues in the protein but provides information that can be used for melanoma risk prediction. Hum Mutat 0, 1–11, 2009. © 2009 Wiley‐Liss, Inc.     

Expression and localization of mutant p16 proteins in melanocytic lesions from familial melanoma patients

Little is known about the correlation between the loss of p16 expression and tumor progression in familial melanoma; no systematic study has been conducted on p16 expression in melanocytic tumors from patients carrying germline CDKN2A mutations. We analyzed 98 early primary lesions from familial patients, previously tested for germline CDKN2A status, by quantitative immunohistochemistry using 3 p16 antibodies. We found that p16 expression was inversely correlated with tumor progression and was significantly lower in melanomas, including in situ lesions, than in nevi. Of other features analyzed, tumor thickness showed the most significant correlation with p16 levels. Lesions from mutation-negative patients displayed combined nuclear and cytoplasmic staining. However, some mutation-positive lesions (ie, G101W, 113insR, M53I, R24P, and 33ins24), including benign nevi, showed nuclear mislocalization, confirming previous studies suggesting that subcellular distribution indicates functional impairment of p16.     

Predicting functional significance of cancer‐associated p16INK4a mutations in CDKN2A

Inherited mutations affecting the INK4a/ARF locus (CDKN2A) are associated with melanoma susceptibility in 40% of multiple case melanoma families. Over 60 different germline INK4a/ARF mutations have been detected in more than 190 families worldwide. The majority of these alterations are missense mutations affecting p16^INK4a, and only 25% of these have been functionally assessed. There is therefore a need for an accurate and rapid assay to determine the functional significance of p16^INK4a mutations. We reviewed the performance of several in vivo functional assays that measure critical aspects of p16^INK4a function, including subcellular location, CDK binding and cell cycle inhibition. In this report the function of 28 p16^INK4a variants, many associated with melanoma susceptibility were compared. We show that assessment of CDK4 binding and subcellular localization can accurately and rapidly determine the functional significance of melanoma‐associated p16^INK4a mutations. p16^INK4a‐CDK6 binding affinity was unhelpful, as no disease‐associated mutation showed reduced CDK6 affinity while maintaining the ability to bind CDK4. Likewise, in silico analyses did not contribute substantially, with only 12 of 25 melanoma‐associated missense variants consistently predicted as deleterious. The ability to determine variant functional activity accurately would identify disease‐associated mutations and facilitate effective genetic counselling of individuals at high risk of melanoma. Hum Mutat 31:1–10, 2010. © 2010 Wiley‐Liss, Inc.     

Human malignant melanoma: detection of BRAF- and c-kit-activating mutations by high-resolution amplicon melting analysis

Activating mutations in the BRAF kinase have been reported in a large number of cases of malignant melanoma. This suggests that therapy with specific RAF kinase inhibitors may find use in treating this disease. If the response to RAF kinase inhibition is dependent on the presence of an activated BRAF protein, it will be necessary to evaluate cases of malignant melanoma for the presence or absence of BRAF mutations. High-resolution amplicon melting analysis is able to detect single base-pair changes in DNA isolated from paraffin-embedded tissue sections and obviates the need for direct DNA sequencing. Results can be available within 48 hours. In this report, we used high-resolution amplicon melting analysis to evaluate 90 cases of malignant melanoma for BRAF mutations. Of these 90 cases, 74 were metastatic melanomas, 12 were primary cutaneous melanomas, and 4 were in situ melanomas. BRAF activation mutations were found in 43 cases (48%). Forty-one of these mutations were in exon 15. The mutations in exon 15 included V600E (34 cases), V600K (6 cases), and V600R (1 case). Two activating mutations were found in exon 11, G469V and G469R. The presence or absence of a BRAF mutation in the junctional component of an invasive melanoma was maintained in the invasive component. We also evaluated these 90 cases, as well as an additional 10 cases (total of 100) for the expression of c-kit. The majority of invasive and metastatic malignant melanomas did not express c-kit, although all in situ lesions and the junctional components of invasive lesions were strongly c-kit positive. Surprisingly, 2 cases of metastatic malignant melanoma (2%) showed strong and diffuse c-kit expression and contained a c-kit-activating mutation, L576P, as detected by high-resolution amplicon melting analysis and confirmed by direct DNA sequencing. These 2 c-kit mutation-positive cases did not contain BRAF mutations. The presence of a c-kit-activating mutation in metastatic malignant melanoma suggests that a small number of melanomas may progress by a somatic mutation of the c-kit gene. The presence of BRAF- and c-kit-activating mutations in malignant melanoma suggests new approaches to treating this disease involving specific tyrosine kinase inhibitors may prove worthwhile and that mutation analysis by high-resolution melting analysis might help guide therapy.     

Problems in using statistical analysis of replacement and silent mutations in antibody genes for determining antigen-driven affinity selection

The analysis of molecular signatures of antigen-driven affinity selection of B cells is of immense use in studies on normal and abnormal B cell development. Most of the published literature compares the expected and observed frequencies of replacement (R) and silent (S) mutations in the complementarity-determining regions (CDRs) and the framework regions (FRs) of antibody genes to identify the signature of antigenic selection. The basic assumption of this statistical method is that antigenic selection creates a bias for R mutations in the CDRs and for S mutations in the FRs. However, it has been argued that the differences in intrinsic mutability among different regions of an antibody gene can generate a statistically significant bias even in the absence of any antigenic selection. We have modified the existing statistical method to include the effects of intrinsic mutability of different regions of an antibody gene. We used this method to analyse sequences of several B cell-derived monoclonals against T-dependent antigens, T-independent antigens, clones derived from lymphoma and amyloidogenic clones. Our sequence analysis indicates that even after correcting for the intrinsic mutability of antibody genes, statistical parameters fail to reflect the role of antigen-driven affinity selection in maturation of many clones. We suggest that, contrary to the basic assumption of such statistical methods, selection can act both for and against R mutations in the CDR as well as in the FR regions. In addition we have identified different methodological difficulties in the current uses of such statistical analysis of antibody genes.     

Genotype and haplotype analysis of cell cycle genes in sporadic colorectal cancer in the Czech Republic

The Czech Republic has one of the highest incidences of colorectal cancer (CRC) in the world. To assess the role of genetic variants on the disease, we genotyped polymorphisms in the TP53 (rs17878362:A₁>A₂, rs1042522:G>C, rs12947788:C>T, and rs17884306:G>A), CDKN1A (rs1801270:C>A and rs1059234:C>T), and CDKN2A (rs3731249:G>A, rs11515:C>G, and rs3088440:C>T) genes in 614 hospital‐based CRC cases and 614 matched controls from the country. Despite the tendency toward differential distribution of variant allele frequencies for some polymorphisms, none was significantly associated with CRC risk. We observed differential distribution of major haplotypes arising from four polymorphisms in the TP53 gene between cases and controls (global P<0.0001). The two most common haplotypes, A₁GCG and A₂CCG, were present in 81% of the cases compared to 71% of the controls. In comparison to the most common haplotype (A₁GCG), the haplotype A₂CCG was associated with an increased risk (odds ratio [OR], 1.40; 95% confidence interval [CI], 1.07–1.82), while the four other haplotypes A₁CCG (OR, 0.60; 95% CI, 0.45–0.79), A₂GCG (OR, 0.53; 95% CI, 0.35–0.81), A₁GTG (OR, 0.31; 95% CI, 0.15–0.64), and A₁GCA (OR, 0.19; 95% CI, 0.07–0.51) were associated with a decreased risk. The effect of haplotypes in the TP53 gene was similar in colon (global P<0.0001) and rectal cancers (P=0.006). No association with the disease was observed with haplotypes of the CDKN1A and CDKN2A polymorphisms. The results from this study suggest that prevalent haplotypes within the TP53 gene may modulate CRC risks in the population. Hum Mutat 0, 1–9, 2009. © 2009 Wiley‐Liss, Inc.     

A summary of mutations in the UV‐sensitive disorders: Xeroderma pigmentosum,Cockayne syndrome,and trichothiodystrophy

The human diseases xeroderma pigmentosum, Cockayne syndrome, and trichothiodystrophy are caused by mutations in a set of interacting gene products, which carry out the process of nucleotide excision repair. The majority of the genes have now been cloned and many mutations in the genes identified. The relationships between the distribution of mutations in the genes and the clinical presentations can be used for diagnosis and for understanding the functions and the modes of interaction among the gene products. The summary presented here represents currently known mutations that can be used as the basis for future studies of the structure, function, and biochemical properties of the proteins involved in this set of complex disorders, and may allow determination of the critical sites for mutations leading to different clinical manifestations. The summary indicates where more data are needed for some complementation groups that have few reported mutations, and for the groups for which the gene(s) are not yet cloned. These include the Xeroderma pigmentosum (XP) variant, the trichothiodystrophy group A (TTDA), and ultraviolet sensitive syndrome (UV^s) groups. We also recommend that the XP‐group E should be defined explicitly through molecular terms, because assignment by complementation in culture has been difficult. XP‐E by this definition contains only those cell lines and patients that have mutations in the small subunit, DDB2, of a damage‐specific DNA binding protein. Hum Mutat 14:9–22, 1999. © 1999 Wiley‐Liss, Inc.     

TET2 mutations in B cells of patients affected by angioimmunoblastic T‐cell lymphoma

Angioimmunoblastic T‐cell lymphomas (AITLs) frequently carry mutations in the TET2 and IDH2 genes. TET2 mutations represent early genetic lesions as they had already been detected in haematopoietic precursor cells of AITL patients. We show by analysis of whole‐tissue sections and microdissected PD1⁺ cells that the frequency of TET2‐mutated AITL is presumably even higher than reported (12/13 cases in our collection; 92%). In two‐thirds of informative AITLs (6/9), a fraction of B cells was also TET2‐mutated. Investigation of four AITLs by TET2 and IGHV gene sequencing of single microdissected B cells showed that between 10% and 60% of polyclonal B cells in AITL lymph nodes harboured the identical TET2 mutations of the respective T‐cell lymphoma clone. Thus, TET2‐mutated haematopoietic precursor cells in AITL patients not only give rise to the T‐cell lymphoma but also generate a large population of mutated mature B cells. Future studies will show whether this is a reason why AITL patients frequently also develop B‐cell lymphomas. Copyright © 2017 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

BRAF V600E,TERT promoter mutations and CDKN2A/B homozygous deletions are frequent in epithelioid glioblastomas: a histological and molecular analysis focusing on intratumoral heterogeneity

Epithelioid glioblastoma (E‐GBM) is a rare aggressive variant of IDH‐wildtype glioblastoma newly recognized in the 2016 World Health Organization classification, composed predominantly of monotonous, patternless sheets of round cells with laterally positioned nuclei and plump eosinophilic cytoplasm. Approximately 50% of E‐GBM harbor BRAF V600E, which is much less frequently found in other types of glioblastomas. Most E‐GBM are recognized as primary/de novo lesions; however, several E‐GBM with co‐ or pre‐existing lower‐grade lesions have been reported. To better understand associations between E‐GBM and the lower‐grade lesions, we undertook a histological and molecular analysis of 14 E‐GBM, 10 of which exhibited lower‐grade glioma‐like components (8 E‐GBM with co‐existing diffuse glioma‐like components, 1 E‐GBM with a co‐existing PXA‐like component and 1 E‐GBM with a pre‐existing PXA). Molecular results demonstrated that the prevalence of BRAF V600E, TERT promoter mutations and CDKN2A/B homozygous deletions in E‐GBM were 13/14 (93%), 10/14 (71%) and 11/14 (79%), respectively, and concurrent BRAF V600E, TERT promoter mutations and CDKN2A/B homozygous deletions were observed in 7/14 (50%) of E‐GBM. These alterations were also frequently seen in the lower‐grade lesions irrespective of the histology. Genetic analysis including array comparative genomic hybridization performed for 5 E‐GBM with co‐ and pre‐existing lower‐grade components revealed that all molecular changes found in the lower‐grade components were also observed in the E‐GBM components, and additional changes were detected in the E‐GBM components. In conclusion, E‐GBM frequently exhibit BRAF V600E, TERT promoter mutations and CDKN2A/B homozygous deletions and these alterations tend to coexist in E‐GBM. Taken together with the facts that only one PXA preceded E‐GBM among these lower‐grade lesions, and that co‐occurrence of BRAF V600E, TERT promoter mutations and CDKN2A/B homozygous deletions have been reported to be rare in conventional lower‐grade diffuse gliomas, the diffuse glioma‐like components may be distinct infiltrative components of E‐GBM, reflecting intratumoral heterogeneity.     

Detection of novel germline mutations in six breast cancer predisposition genes by targeted next‐generation sequencing

In this study, a customized amplicon‐based target sequencing panel was designed to enrich the whole exon regions of six genes associated with the risk of breast cancer. Targeted next‐generation sequencing (NGS) was performed for 146 breast cancer patients (BC), 71 healthy women with a family history of breast cancer (high risk), and 55 healthy women without a family history of cancer (control). Sixteen possible disease‐causing mutations on four genes were identified in 20 samples. The percentages of possible disease‐causing mutation carriers in the BC group (8.9%) and in the high‐risk group (8.5%) were higher than that in the control group (1.8%). The BRCA1 possible disease‐causing mutation group had a higher prevalence in family history and triple‐negative breast cancer, while the BRCA2 possible disease‐causing mutation group was younger and more likely to develop axillary lymph node metastasis (P < 0.05). Among the 146 patients, 47 with a family history of breast cancer were also sequenced with another 14 moderate‐risk genes. Three additional possible disease‐causing mutations were found on PALB2, CHEK2, and PMS2 genes, respectively. The results demonstrate that the six‐gene targeted NGS panel may provide an approach to assess the genetic risk of breast cancer and predict the clinical prognosis of breast cancer patients.