Activating BRAF and N-Ras mutations in sporadic primary melanomas: an inverse association with allelic loss on chromosome 9

We searched and report mutations in the BRAF and N-ras genes in 22 out of 35 (63 percent) primary sporadic melanomas. In three melanomas, mutations were concomitantly present in both genes. In all, 10 out of 12 mutations in the BRAF gene involved the 'hot spot' codon 600 (In all communications on mutations in the BRAF gene, the nucleotide and codon numbers have been based on the NCBI gene bank nucleotide sequence NM_004333. However, according to NCBI gene bank sequence with accession number NT_007914, there is a discrepancy of one codon (three nucleotides) in exon 1 in the sequence with accession number NM_004333. The sequence analysis of exon 1 of the BRAF gene in our laboratory has shown that the sequence derived from NT_007914 is correct (Kumar et al., 2003). Due to the correctness of the latter, sequence numbering of codons and nucleotides after exon 1 are changed by +1 and +3, respectively.), one tandem CT1789-90TC base change represented a novel mutation and another mutation caused a G466R amino-acid change within the glycine-rich loop in the kinase domain. Mutations in the N-ras gene in 11 melanomas were at codon 61 whereas two melanomas carried mutations in codon 12 including a tandem mutation GG>AA. We observed an inverse association between BRAF/N-ras mutations and the frequency of loss of heterozygosity (LOH) on chromosome 9 at 10 different loci. Melanomas with BRAF/N-ras mutations showed a statistically significant decreased frequency of LOH on chromosome 9 compared with cases without mutations (mean fractional allelic loss (FAL)=0.29+/-0.23 vs 0.72+/-0.33; t-test, P=0.0001). Difference in the FAL value between tumours with and without BRAF/N-ras mutations on 33 loci on five other chromosomes was not statistically significant (mean FAL 0.17+/-0.19 vs 0.25+/-0.22; t-test, P=0.24). Melanoma cases with BRAF/N-ras mutations were also associated with lower age at diagnosis than cases without mutations (mean age 80.38+/-7.24 vs 65.77+/-19.79 years; t-test, P=0.02). Our data suggest that the occurrence of BRAF/N-ras mutations compensate the requirement for the allelic loss at chromosome 9, which is one of the key events in melanoma.     

Screening of N-ras codon 61 mutations in paired primary and metastatic cutaneous melanomas: mutations occur early and persist throughout tumor progression.

PURPOSE: Mutations in the ras genes often occur during tumorigenesis. In malignant melanoma, the most common ras alterations are N-ras codon 61 mutations. This study was aimed to measure the frequency of such mutations in a large series of paired primary and metastatic melanomas to determine their role in melanoma initiation and progression. EXPERIMENTAL DESIGN: Seventy-four primary melanomas and 88 metastases originating from 54 of the primary tumors were screened for N-ras codon 61 mutations using single-strand conformation polymorphism and nucleotide sequence analyses. RESULTS: Twenty-one of the 74 primary tumors (28%) had activating N-ras codon 61 mutations. From 20 of the mutated primary tumors, a total of 34 metastases were analyzed, and all but one showed the same mutation as the primary tumor from which they originated. The remaining 53 primary tumors and corresponding metastases (n = 54) were wild-type for N-ras codon 61. Analysis of the different growth phases of the mutated primary tumors showed that the mutations were already present in the radial growth phase. Mutations were also detected in tumor-associated nevi. N-ras codon 61 mutations were associated with a higher Clark level of invasion (P = 0.012) and a lower age at diagnosis (P = 0.042) but did not affect survival (P = 0.671). CONCLUSIONS: This study shows that N-ras codon 61 mutations occur early in primary melanomas rather than in the metastatic stage and that once the mutations have occurred, they persist throughout tumor progression. This suggests that activated N-ras may be an attractive target for therapy in the subset of melanoma patients carrying such mutations.     

A novel N-ras mutation in malignant melanoma is associated with excellent prognosis.

Mutations in the ras gene are key events in the process of carcinogenesis; in particular, point mutations in codon 61 of exon 2 of the N-ras gene occur frequently in malignant melanoma (MM). We searched for point mutations in the N-ras gene in a large series of primary and metastatic MM from 81 different retrospectively selected patients using the very sensitive denaturing gradient gel electrophoresis technique, followed by sequencing. The classical codon 12 and codon 61 mutations were found in 21 and 17% of the cases, respectively. No codon 13 mutation was found. A novel mutation at codon 18 of exon 1, consisting of a substitution of alanine (GCA) by threonine (ACA), was found in 15% of the primary MMs but in none of the metastatic MMs. All of the other cases were free of mutations. Using microdissected cells from distinctive MM growth phases as source of DNA for mutation analysis, this particular N-ras exon 1 mutation at codon 18 was already present in the radial growth phase and preserved throughout the successive growth phases; it was also found in a dysplastic nevi in continuity with a MM, indicating a clonal relationship between both lesions. Our findings also illustrate the clonal relationship between the distinctive growth phases in MM and suggest the codon 18 mutation to occur early in MM development. The MM in patients with this mutation were significantly thinner than those without a codon 18 mutation (P = 0.0257). Statistical analysis, comparing the group of codon 18 patients with the group of patients with the classical mutations and without mutations, revealed a highly significant difference in overall outcome. The cumulative probability of developing metastasis was significantly lower for the group patients with a codon 18 mutation (P = 0.0130). We can thus conclude that this codon 18 mutation identifies a group of patients with better prognosis than patients with melanoma that harbor wild-type sequence or classical activating point mutations in codon 12 or 61. Preliminary nucleotide binding measurements could not detect a difference between wild-type Ras protein and the mutant Ras(A18T) protein. However, for a precise elucidation of the role of the N-Ras(A18T) mutant in melanoma, additional studies aimed to measure the affinity to guanine nucleotide exchange factors and GTPase-activating proteins are needed.     

Mutation analysis of the N-ras proto-oncogene in active and remission phase of human acute leukemias

DNA isolated from blood or bone-marrow samples from 18 patients with acute non-lymphocytic leukemia (ANLL) and 14 patients with acute lymphocytic leukemia (ALL) was analyzed for the presence of mutations in the N-ras gene. Using synthetic oligonucleotide probes we detected mutations in 5 cases of ANLL; 4 GGT----GAT transitions in codon 12 and one CAA----AAA transversion in codon 61. One case exhibited homozygosity for the mutation. No mutations could be detected at these codons in the DNA of the 14 ALL patients. In a follow-up study with 3 of the above 5 patients, the mutation could no longer be detected in 2 cases following successful induction of clinical remission by chemotherapy. However, the mutated N-ras persisted in one patient who did not achieve remission. We show that oligonucleotide hybridization is a sensitive assay for the detection of N-ras point mutations, which in ANLL could be used to follow the fate of the leukemic clone during (and after) therapy.     

Frequency and nature of germline Rb-1 gene mutations in a series of patients with sporadic unilateral retinoblastoma

Constitutional Rb-1 gene mutations were studied in a series of 17 families with isolated unilateral retinoblastoma patients. Peripheral blood lymphocytes were analysed by karyotyping, Southern blot hybridisation, and 'exon by exon' sequencing. Mutations were detected in 4 (24%) of the investigated probands. All mutations were identified by sequencing. No alteration was detected by Southern blotting or karyotyping. In one of our cases with a R358 stop codon mutation, retinoblastoma was unilateral at the time of diagnosis, but a tumour of the second eye was diagnosed after 35 months of follow-up. After exclusion of this case, the frequency of constitutional mutations in our series was 19% (3 of 16 cases). Alterations in our cases without involvement of the second eye included G-->A substitution in the promoter region 198 bp upstream of the initiating methionine codon; G-->C transversion in the splice donor site at position +1 leading to exon 6 skipping and a 137 bp in-frame deletion, starting 3 bp from the 5' end of exon 15 to 27 bp from the 3' end of exon 16. All alterations were germline de novo abnormalities.     

Activation of ras oncogenes and expression of tumor-specific transplantation antigens in methylcholanthrene-induced murine fibrosarcomas

The DNA of 22 fibrosarcomas, newly induced in BALB/c mice by subcutaneous doses of 3-methylcholanthrene (3-MCA), was tested in NIH 3T3 transformation assay. Activation of K-ras and N-ras was found in 7 and 3 cases respectively. No H-ras activation was detected. Polymerase chain reaction and oligonucleotide hybridization performed on the DNA of the 22 sarcomas revealed 5 cases of K-ras mutation at codon 12, 3 at codon 13 and 1 at both codons. One case of K13 mutation was not detectable by transfection. Three cases of mutation at codon 61 of N-ras were also found, one of which was simultaneous with a K12 mutation. Tumor-specific transplantation antigens (TSTA) were assessed in the 22 original tumors. Altogether 16 sarcomas were immunogenic, with the highest frequency of TSTA+ tumors (10/11 and 5/6) in the groups given 1.0 and 0.1 mg of 3-MCA respectively, the lowest (1/5) in that with 0.01 mg of carcinogen; ras mutations occurred in the DNAs of 11 out of the 16 TSTA+ sarcomas, but none of the DNAs of the 6 TSTA- tumors showed ras mutation. The results suggest that 3-MCA-induced transformation of subcutaneous fibroblasts can involve mutations in codons 12, 13 or 61 of K- and N- but not H-ras gene and that such mutation is accompanied by the expression of TSTA.     

N-ras mutations in myeloid leukemias

The presence of mutations activating the N-ras gene was investigated by the polymerase chain reaction technique in twenty patients with acute myeloblastic leukemia (AML) at onset and in four patients with Ph1 positive chronic myelogeneous leukemia (CML) either in chronic phase or in blast crisis. Four remission samples and four relapses from the AML cases were also studied. Mutations were found in five out of twenty (25%) untreated AML cases at onset. No mutations were detected in the complete remission samples, two of them with N-ras mutations during the leukemic phase. Two out of the four leukemia relapses were positive for the same N-ras mutation shown at presentation, whereas no new mutations were found in the other two initially negative cases. An N-ras mutation appeared during the blast crisis of one of the four CML, which were all negative during the chronic phase. In conclusion, whereas some data appear to be consistent with a role of the N-ras mutations as initiating events in myeloid leukemias, in other cases N-ras activation seems to represent a factor involved in progression. These data suggest that a partial overlapping between initiation and progression factors could exist in naturally occurring tumors.     

Mutational analysis of ras gene family in lung cancer in Thai

H-, K- and N-ras gene mutations were analyzed in lung cancer from Thai patients. Thirteen out of 58 cases (22%) harbored the mutations. Ten cases showed K-ras gene mutations at codon 12, 1 case presented a mutation at codon 13 and another case exhibited a mutation at codon 63. Silent mutations of N-ras gene in codons 57 and 62 were seen in one patient, whilst no H-ras mutation was found in these patients. Bases change in K-ras gene were G right curved arrow T transversion (62%), G right curved arrow A transition (15%) and G right curved arrow C transition (15%), whereas T right curved arrow G transversion and A right curved arrow G transition were detected in N-ras mutant gene.     

Distinct spectrum of N-ras mutations in aml and mds patients in yugoslavia

Mutations that activate ras genes were demonstrated to be associated with certain types of malignancies. Multiple point mutations were predominantly found in the N-ras and occasionally in the K-ras genes. The analysis of 4 MDS, 23 AML and 11 CML patients from Yugoslavia revealed the prevalence of the N-ras mutation (83%) over K-ras mutations (17%). Although the frequencies of the N- and K-ras mutations in these patients were similar to the ones reported for patients from USA and Japan, the N-ras mutational spectra considerably differed. The prevailing type of mutation in patients from Yugoslavia was G-to-T transversion at the first position in the codon 12 of the N-ras gene. This study supports a hypothesis that different geographical and environmental factors may cause the accumulation of different type of point mutations in the same target gene.     

中国肺腺癌患者上皮生长因子受体基因突变的研究

目的:分析我国肺腺癌患者上皮生长因子受体(EGFR)基因突变的发生率和突变类型。方法:在上海、杭州和昆明等地收集61例肺腺癌及其正常肺组织,采用PCR扩增和基因测序方法对组织DNA中EGFR外显子19~21基因突变进行分析。结果:正常肺组织中EGFR基因均为野生型,肺腺癌组织中EGFR基因突变检测率为47.5%(29/61),其中外显子19和21突变分别占突变总数的55.2%(16/29)和44.8%(13/29),外显子20未检测到突变。外显子19突变发生在第746~752位密码子,均为碱基缺失突变,有6种不同类型。外显子21突变全部是第858位密码子碱基替换突变。EGFR基因突变与患者性别和年龄无显著相关性。但昆明和上海等地患者的基因突变存在明显差异。结论:EGFR基因突变是一种肿瘤特异性的体细胞遗传改变,突变发生率约占肺腺癌总数的一半,其中以外显子19和21突变为主。我国EGFR基因突变存在地域差异。     

BRAF mutations in metastatic melanoma: a possible association with clinical outcome.

PURPOSE: The RAS-RAF-mitogen-activated protein kinase pathways mediate the cellular response to growth signals. In melanocytes, BRAF is involved in cAMP-dependent growth signals. Recently, activating mutations in the BRAF gene, were reported in a large proportion of melanomas. We have studied mutations in the BRAF gene and their association with clinical parameters. EXPERIMENTAL DESIGN: We analyzed exons 1, 11, and 15 of the BRAF gene and exons 1 and 2 of the N-ras gene for mutations in 38 metastatic melanomas by PCR-single-strand conformation polymorphism and direct sequencing. Kaplan-Meier survival and multivariate analyses were used to correlate mutations with various clinical parameters. RESULTS: Mutations in exon 15 of the BRAF gene were detected in 26 (68%) melanomas. In 25 cases, mutation involved the "hot spot" codon 600(2)of the BRAF gene. Three melanomas without a BRAF mutation carried amino acid substituting base changes at codon 61 of the N-ras gene. In a multivariate proportional hazard (Cox) model, BRAF mutation, along with the stage of metastatic melanomas, showed a statistically significant hazard ratio of 2.16 (95% confidence interval 1.02-4.59; chi(2) for the model 6.94, degrees of freedom 2, P = 0.03) for diminished duration of response to the treatment. In a Kaplan-Meier survival model, cases with BRAF mutation showed longer disease-free survival (median of 12 months) than cases without mutation (median of 5 months), although this association was not statistically significant (Log-rank test P = 0.13). CONCLUSIONS: Our results, besides confirming the high frequency of BRAF mutations in metastatic melanomas, also underline the potential importance of these mutations in disease outcome.     

Low frequency of ras gene mutations in neuroblastomas, pheochromocytomas, and medullary thyroid cancers

Little is known about the prevalence and significance of ras gene activation in neural crest tumors such as neuroblastomas, pheochromocytomas, and medullary thyroid cancers (MTCs). Therefore, we analyzed DNA from 10 human neuroblastoma cell lines and 10 primary human pheochromocytomas for activating mutations in N-ras, H-ras, and K-ras. We also studied DNA from 24 primary neuroblastomas and 10 MTCs for N-ras mutations. ras genes were analyzed by direct sequencing of specific DNA fragments amplified by the polymerase chain reaction. With the exception of the SK-N-SH cell line, the examined ras gene sequences were normal in all the neuroblastomas, pheochromocytomas, and MTCs tested. A single point mutation was identified at codon 59 (GCT(ala)----ACT(thr)) in one N-ras allele in an SK-N-SH subline. Interestingly, this mutation is different from the activating codon 61 mutation which resulted in the initial identification of N-ras from SK-N-SH DNA. Therefore, we analyzed the sequences of earlier passages and sublines of the SK-N-SH cell line, but mutations at codon 59 or 61 were not detected, suggesting that neither mutation was present in the primary tumor. Our results indicate that N-ras mutations may occur spontaneously during in vitro passage of cell lines but rarely, if ever, occur in primary neuroblastomas, pheochromocytomas, and MTCs. In addition, we have not found H-ras or K-ras mutations in any neuroblastoma cell line or primary pheochromocytoma.     

ras mutations in endocrine tumors: mutation detection by polymerase chain reaction-single strand conformation polymorphism.

To elucidate the molecular basis for endocrine tumorigenesis, ras mutations in human endocrine tumors were analyzed using polymerase chain reaction-single strand conformation polymorphism (PCR-SSCP) analysis. Mutations of the H-, K-, N-ras genes were examined in genomic DNAs from 169 successfully amplified primary endocrine tumors out of 189 samples. Four out of 24 thyroid follicular adenomas analyzed contained mutated N-ras codon 61, and one contained the mutated H-ras codon 61. One of the 19 pheochromocytomas revealed mutation of the H-ras codon 13. No mutations of the ras gene were detected in pituitary adenomas, parathyroid tumors, thyroid cancers, endocrine pancreatic tumors, and adrenocortical tumors. Based on these findings we conclude that activation of the ras gene may play a role in the tumorigenesis of a limited number of thyroid follicular adenomas and pheochromocytomas, and that mutation of the ras gene is not frequent in other human endocrine tumors.     

Incidence of p53 and ras gene mutations in DMBA-induced rat leukemias

Leukemia, a form of haematological malignancy, is a multi-stage disease and a wide range of diverse genes has been speculated to correlate with its initiation and development. Ras has been speculated to be an initiating gene for haematological malignancy, but more investigation will be needed to determine the genes associated with the progression of the disease. 7,12-dimethylbenz(a)anthracene (DMBA)-induced rat leukemia provides a good tool for research into various stages of the disease. The entire coding regions of p53 and ras genes were examined for mutations in the present study. In this experiment, we used fluorescence-labeled polymerase chain reaction single-stranded conformation polymorphism analysis (PCR-SSCP) and direct sequencing to detect mutations of both genes on rat erythroleukemia. Fifteen out of 18 (83.3%) rat leukemias were found to have N-ras codon 61 mutation, consistent with previous results. The result of direct sequencing showed a single base substitution (CAA to CTA), resulting in an amino-acid change from Gln to Leu. No mutations were found in H-ras, K-ras or codon 12 of N-ras. The incidence of p53 gene mutation was 16.6% (3/18) in rat leukemia at late-stage. In the present study, mutation of the p53 gene was detected in three DMBA-induced leukemias as follows: a single-base substitution (CAT to CGT) at codon 177 (exon 5), resulting in an amino-acid change from Arg to Leu, a CGG to CTG/CGG changed at codon 211 (exon 6) resulting in an amino-acid change from His to Arg/His, and a GGG to TGG at codon 242 (exon 6) resulting in an amino-acid change from Gly to Trp, respectively. Thus, mutations of p53 gene do not seem to respond to the carcinogenesis of the DMBA-induced leukemia, in contrast to mutation of the N-ras oncogene, and may possibly be involved in the progress of multi-stage leukemogenesis.     

Low incidence of point mutation of c-Ki-ras and N-ras oncogenes in human hepatocellular carcinoma

We examined the incidence of point mutation in codons 12, 13 and 61 of c-Ki-ras and N-ras genes in human hepatocellular carcinoma (HCC) using the polymerase chain reaction and oligonucleotide hybridization techniques. Among 34 tissues specimens surgically resected from 30 patients and 5 cell lines of human HCC, only two had ras point mutations; in one case, codon 12 of c-Ki-ras was altered from GGT, coding glycine, to GTT, coding valine; in the other case, codon 61 of N-ras was altered from CAA, coding glutamine, to AAA, coding lysine. Thus, point-mutational activation of ras oncogenes is an uncommon event in human HCC.     

Lack of association between N-ras gene mutations and clinical prognosis in Brazilian children with acute lymphoblastic leukemia.

Point mutations in codons 12, 13 and 61 of the N-ras proto-oncogene have been detected in several human malignancies. We studied 170 patients with acute lymphoblastic leukemia (ALL), treated from 1988 to 1994 according to a protocol derived from BFM-83 studies, in order to evaluate the incidence and prognostic significance of mutations in this gene in childhood ALL. DNA was extracted from bone marrow smears at diagnosis and amplified by polymerase chain reaction (PCR). After screening with SSCP, PCR products were hybridized with allele specific probes and, in some cases, cloned in a pMOS Blue T vector and sequenced. Exon 2 was also studied in 101 children. Our results showed 4% of mutations in codons 12 and 13 and 2% in exon 2. Similar to a previous report, we identified 7% of mutations among children who were studied for both exons. A new mutation in codon 64 of the N-ras gene was detected in one patient. No significant clinical differences between patients with and without mutations were detected (sex, age, leukocyte counts at diagnosis, nutritional status, and risk factor according to the BFM protocol). Children with mutations in codons 12 and 13 showed significantly higher reactivity to PAS staining on blast cells than children with a wild type N-ras gene configuration. Comparison of overall- and recurrence-free survival did not show significant difference between groups with and without mutations. Our results suggest that mutations in the ras gene are infrequent in children with ALL at diagnosis and seem to be of low prognostic value.     

Activating mutations of ras family genes in prostatic-cancer

ras family genes (H-, K- and N-ras) encode for a 21 kD membrane protein which possesses GTPase activity and participates in a signal transduction pathway. Activating mutations of the ras family genes occur at codons 12, 13 and 61 and have been detected in a variety of human tumours, including colonic, bladder and pancreatic cancers. Prostatic cancer is among the most common malignancies throughout the world and a major cause of death from cancer in males. Data reported on the implication of the ras family genes in the development of the disease are conflicting. The aim of this study was to determine the incidence of mutations at codon 12 of H-ras, codon 12 of K-ras and codon 61 of N-ras proto-oncogenes, in a Greek population with prostatic cancer. Our analysis revealed that 4 out of 20 (20%) samples harboured a K-ras codon 12 point mutation, 1 out of 20 (5%) specimens contained mutations at codon 12 of the H-ras and 1 out of 20 (5%) at codon 61 of the N-ras, indicating a role for the ras genes in the development of the disease.     

N-ras gene mutations in acute myeloid leukemia: accurate detection by solid-phase minisequencing.

Mutations in the N-ras gene are found in one-third of patients with acute myeloid leukemia. The N-ras mutations could serve as markers for residual cells, if a highly sensitive method for detecting the mutations was available. We applied a new method, solid-phase minisequencing, to analyze bone-marrow cells from 16 patients with acute myeloid leukemia for mutations in codon 12, 13 and 61 of the N-ras gene. In the solid-phase minisequencing technique the mutations are identified by a primer extension reaction, in which a single labelled nucleoside triphosphate is incorporated into an immobilized DNA fragment previously amplified by the polymerase chain reaction. We identified N-ras mutations in 5 of the patients (30%). In one patient, we observed 2 mutations that were shown to be located in different alleles. With the solid-phase minisequencing method, we were able to determine the proportion of mutated cells in the samples. We found that in 4 of the samples only a fraction (7-64%) of the blasts carried an N-ras mutation, and in one sample practically all blast cells were mutated. The method was highly sensitive, allowing us to identify N-ras mutations even when the sample consisted of 99.7% normal cells and only 0.3% mutated blasts.     

Evidence for pluripotent stem cell origin of idiopathic myelofibrosis: clonal analysis of a case characterized by a N-ras gene mutation

Three cases of idiopathic myelofibrosis were screened for the presence of mutations at codon 12, 13, or 61 of the ras gene family by a rapid method based on polymerase chain reaction and hybridization to mutation-specific oligonucleotides. PB cells of one patient showed a point mutation at codon 12 of the N-ras oncogene. This molecular genetic hallmark was used to investigate the clonal relationship of different cell lineages by cell separation analysis. Presence of the N-ras 12 mutation in granulocytes, monocytes, B cells, and T lymphocytes, as well as erythroblasts, indicates that idiopathic myelofibrosis originates from a pluripotent stem cell, at least in this patient.     

ras gene mutations as a prognostic marker in adenocarcinoma of the human lung without lymph node metastasis.

Adenocarcinoma of the lung obtained at surgical resection was examined for mutation at codons 12, 13, and 61 of the oncogenes K-ras, H-ras, and N-ras, using polymerase chain reaction and oligonucleotide hybridization techniques. The mutation was detected in 18 of the 115 cases (15.7%), and 15 of 18 were at codon 12, 2 were at codon 13 of K-ras, and 1 was at codon 61 of N-ras. G to T transversions were most common. The ras gene mutations were more frequent in the male patients (P = 0.0048). No significant differences were found to be related to stage of the disease or tumor-nodes-metastases classification between positive and negative groups of the ras gene mutations. A history of tobacco use was not always a factor contributing to mutation. Of the completely resected group without lymph node metastasis, the 5-year survival rate in the ras-positive group was 53.3%, which was significantly poorer than the 83.6% survival rate in the ras-negative group (P less than 0.05). Our findings suggest that ras gene mutations may be prognostic, especially in the early stage adenocarcinoma of the lung.