Analysis of RAS oncogene mutations in human lymphoid malignancies.

We investigated the frequency of mutations activating RAS oncogenes in human lymphoid malignancies, including B- and T-cell-derived acute lymphoblastic leukemia, chronic lymphocytic leukemia, and non-Hodgkin lymphoma. By the polymerase chain reaction/oligonucleotide hybridization method, DNA from 178 cases was analyzed for activating mutations involving codons 12 and 61 of the HRAS, KRAS and NRAS genes and codon 13 of the NRAS gene. Mutations involving codons 12 or 13 of the NRAS gene were detected in 6 of 33 cases of acute lymphoblastic leukemia (6/33, 18%), whereas no mutations were found in non-Hodgkin lymphoma or chronic lymphocytic leukemia. Direct nucleotide sequence analysis of polymerase chain reaction products showed that the mutations involved a G----A transition in five of the six cases of acute lymphocytic leukemia. In four cases the mutations seemed to occur in only a fraction of the neoplastic cells, and one case displayed two distinct NRAS mutations, most likely present in two distinct cell populations. These results indicate the following: (i) RAS oncogenes are not found in all types of human malignancies, (ii) significant differences in the frequency of RAS mutations can be found among subtypes of neoplasms derived from the same tissue, (iii) in lymphoid neoplasms the NRAS mutation correlates with the most undifferentiated acute lymphocytic leukemia phenotype, and (iv) NRAS mutations present in only a fraction of malignant cells may result from either the selective loss or the acquisition of mutated alleles during tumor development.     

Frequency of RAS gene mutation and its cooperative genetic events in Southeast Asian adult acute myeloid leukemia

RAS gene as one of the most frequently mutated genes in acute myeloid leukemia (AML) has become an attractive target for molecular therapy. The role of oncogenic RAS and its associated genetic events in AML are not yet defined. We examined the frequency of RAS mutation in 239 Thai de novo adult AML patients using polymerase chain reaction-single-strand conformational polymorphism analysis. Thirty-five RAS mutations were found in 32 cases (13%) predominantly classified as M1/M2 (53%) followed by M4/M5 subtype (38%). Ten cases were positive for N-RAS codon 12, 11 cases for N-RAS codon 61, 13 cases for N-RAS codon 13, and one case for K-RAS codon 13. No mutation was found in K-RAS exon 2 or H-RAS. The most common base substitution was the G to A transition at codon 13. Most M1/M2 cases had mutations at codon 12 or 13, whereas M4/M5 cases preferentially affected codon 61. Half of the patients with RAS mutations had abnormal karyotypes with the majority involving chromosomes 21, 11 and 7. Four patients had core-binding factor leukemia and four additional patients had coexisting FLT3 or AML1 mutation. One patient had RAS, FLT3 and t(8;21) and the other had RAS, AML1 point mutation and del(9q). In conclusion, mutation of RAS gene was not as common in the Thais as in the western population. Several additional genetic abnormalities occurred in RAS-mutated patients. Future molecular-targeting approaches should take into account the multiple genetic events that coexist with RAS mutations in AML patients.     

RAS mutations are frequent in FAB type M4 and M5 of acute myeloid leukemia, and related to late relapse: a study of the Japanese Childhood AML Cooperative Study Group

Mutations in RAS are frequent in acute myeloid leukemia (AML), and are thought to contribute to leukemogenesis in a subset of patients; however, their prognostic significance has not been firmly established. One hundred and fifty-seven pediatric patients with AML were analyzed for NRAS and KRAS mutations around hot spots at codons 12, 13, and 61. Twenty-nine patients (18.5%) had an activating mutation of RAS. We found KRAS mutations to be more frequent than NRAS mutations (18/29, 62.1% of patients with RAS mutation), in contrast to previous reports (18-40%). The frequency of RAS mutation was higher in French-American-British types M4 and M5 than other types (P?=?0.02). There were no significant differences in other clinical manifestations or distribution in cytogenetic subgroups, or aberrations of other genes, including KIT mutation, FLT3-ITD, and MLL-PTD, between patients with and without RAS mutations. No significant differences were observed in the 3-year overall survival and disease-free survival; however, the presence of RAS mutation was related to late relapse. The occurrence of clinical events at relatively late period should be monitored for in AML patients with mutations in RAS.     

The pattern of mutational involvement of RAS genes in human hematologic malignancies determined by DNA amplification and direct sequencing

DNA from 161 patients with various forms of hematologic malignancies were investigated for mutations in exons 1 and 2 of the N-RAS, K-RAS and Ha-RAS gene by direct sequencing of DNA amplified in vitro by the polymerase chain reaction. Mutations involving either codons 11, 12, or 13 of the N-RAS gene were identified in 18 of the 161 patients. The relative frequencies of N-RAS gene mutations in these hematologic disorders was as follows: acute myelogenous leukemia (AML), 15%; acute lymphoblastic leukemia (ALL), 14%; myelodysplastic syndromes, 24%; and myeloid and lymphoid blast crisis of chronic myelogenous leukemia (CML), 3%. No correlation was observed between the presence of mutations and cytologic features or immunophenotype of these malignancies. Mutations involving codons 12 or 13 were equally prevalent, with a glycine to aspartic acid substitution being the most frequently encountered change. A single T-ALL case had a codon 11 mutation resulting in substitution of alanine with threonine. We failed to find mutations in exons 1 and 2 of the K-RAS or Ha-RAS genes in any case except a single AML with a mutation in codon 61 of the K-RAS gene. Also, no mutations were identified in chronic phase of CML, chronic lymphocytic leukemia. Ph1 positive ALL, non-Hodgkin's lymphoma, Hodgkin's disease, or multiple myeloma. These results indicate that RAS mutations, especially those involving exon 1 of the N-RAS gene, are frequent only in a subset of hematologic malignancies.     

Analysis of ras gene mutations in childhood myeloid leukaemia

Previous studies have shown that approximately 30% of adult acute myeloid leukaemias and 20% of adult acute lymphoid leukaemias contain point mutated ras oncogenes. In order to assess whether ras oncogenes are also involved in childhood leukaemias, we have used polymerase chain reaction (PCR) amplification and synthetic oligonucleotide probes to study the nature and frequency of ras gene mutations in childhood leukaemias, concentrating largely on the acute myeloid leukaemias (AML). Thirty-four childhood presentation AML DNAs were screened for mutations in and around codons 12, 61 and 117 of N-, K- and H-ras. Eight of these samples (24%) contained ras mutations. As in the adult disease, the gene predominantly involved was N-ras (6/8), with occasional activation of K-ras (2/6). The most common base change was a G----A transition at codon 12 or 13 (4/8). Of the patients with mutant ras, 4/8 were diagnosed as AML FAB subtype M5. Five of the 34 childhood AMLs analysed displayed abnormalities of chromosome 7. However, none of these cases contained a mutant ras gene. One AML patient was studied at relapse, 14 months after initial presentation. The presentation mutation (N61p3) was not detectable, although a new mutation (N13Cys) was readily identified. This observation extends our original finding with presentation and relapse samples of adult AML, in which it was uncommon for the relapse sample to contain the same ras mutation as the presentation DNA. In addition, two out of five patients diagnosed as juvenile CML, were found to harbour mutant ras.     

RAS gene mutations in acute and chronic myelocytic leukemias, chronic myeloproliferative disorders, and myelodysplastic syndromes.

We report on investigations aimed at detecting mutated RAS genes in a variety of preleukemic disorders and leukemias of myeloid origin. DNA transfection analyses (tumorigenicity assay) and hybridization to mutation-specific oligonucleotide probes established NRAS mutations in codon 12 or 61 of 4/9 acute myelocytic leukemias (AML) and three AML lines. Leukemic cells of another AML patient showed HRAS gene activation. By using a rapid and sensitive dot-blot screening procedure based on the combination of in vitro amplification of RAS-specific sequences and oligonucleotide hybridization we additionally screened 15 myelodysplastic syndromes, 26 Philadelphia chromosome-positive chronic myelocytic leukemias in chronic or acute phase, and 19 other chronic myeloproliferative disorders. A mutation within NRAS codon 12 could thus be demonstrated in a patient with idiopathic myelofibrosis and in another with chronic myelomonocytic leukemia. Moreover, mutated NRAS sequences were detected in lymphocytes, in granulocytes, as well as in monocytes/macrophages of the latter case.     

Analysis of N-ras gene mutations in acute myeloid leukemia by allele specific restriction analysis

N-ras gene activation occurs via single base substitutions in codons 12, 13, and 61. We have developed a rapid screening method, termed allele specific restriction analysis (ASRA), for detection of N-ras mutations at these three critical codons in acute myeloid leukemia (AML). Patient DNA samples are amplified by the polymerase chain reaction (PCR) by using primers that induce restriction sites in normal but not mutant N-ras alleles. We have used ASRA to identify 5 point mutations in four out of 19 patients at initial presentation of de novo AML. Three patients had one mutation at codon 12, 13, or 61 respectively, while a fourth patient had concurrent mutations at codons 12 and 13. N-ras mutations were more common in patients over 65 years of age (P less than 0.04), but did not correlate with FAB classification, attainment of complete remission, disease free survival, or overall survival. ASRA can also be used as the first step in a more sensitive approach to the detection of ras mutations. When ASRA was combined with allele specific oligonucleotide (ASO) hybridization the sensitivity and specificity of these assays were increased. This allowed identification of additional low level mutations in two patients. The data presented here constitute the first complete analysis of N-ras mutations in leukemia by ASRA and include the first identification of three concurrent N-ras mutations in a single leukemic patient. By facilitating sensitive sequential studies, ASRA should contribute to our understanding of the role of N-ras mutations in leukemogenesis.     

Implications of NRAS mutations in AML: a study of 2502 patients

We analyzed 2502 patients with acute myeloid leukemia at diagnosis for NRAS mutations around the hot spots at codons 12, 13, and 61 and correlated the results to cytomorphology, cytogenetics, other molecular markers, and prognostic relevance of these mutations. Two hundred fifty-seven (10.3%) of 2502 patients had NRAS mutations (NRAS(mut)). Most mutations (112 of 257; 43.6%) were found at codon 12, mostly resulting in changes from glycine to asparagine. The history of AML did not differ significantly in association with NRAS mutations. The subgroups with inv(16)/t(16;16) and inv(3)/t(3;3) showed a significantly higher frequency of NRAS(mut) (50 of 133, 37.6% [P < .001], and 11 of 41, 26.8% [P = .004], respectively) than the total cohort. In addition, in these 2 subgroups, mutations of codon 61 were significantly overrepresented (both P < .001). In contrast, NRAS mutations were significantly underrepresented in t(15;17) (2 of 102; 2%; P = .005) in the subgroup with MLL/11q23 rearrangements (3 of 77; 3.9%; P = .061) and in the complex aberrant karyotype (4 of 258; 1.6%; P < .001). Overall, we did not find a significant prognostic impact of NRAS(mut) for overall survival, event-free survival, and disease-free survival. However, there was a trend to better survival in most subgroups, especially when other molecular markers (FLT3-LM, MLL-PTD, and NPM) were taken into account.     

Activated protooncogenes in human lung tumors from smokers.

Fourteen primary human lung tumor DNAs from smokers were analyzed for transforming activity by two DNA transfection assays. Activated protooncogenes were detected in 3 of 11 tumor DNAs by the NIH 3T3 focus assay, whereas activated protooncogenes were detected in 11 of 13 tumor DNAs by the NIH 3T3 cotransfection-nude mouse tumorigenicity assay. K- or NRAS genes activated by point mutation at codons 12 or 61 were detected in a large cell carcinoma, a squamous cell carcinoma, and 5 adenocarcinomas. An HRAS oncogene activated by a different mechanism was detected in an epidermoid carcinoma. One adenocarcinoma was found to contain an activated RAF gene. Two unidentified transforming genes were detected in a squamous cell carcinoma DNA and two adenocarcinoma DNAs. Eight of 10 lung adenocarcinomas that had formed metastases at the time of surgery were found to contain RAS oncogenes. No significant increase in metastasis was observed in the lung adenocarcinomas that contained one or more 6-kilobase EcoRI alleles of the LMYC gene. Overall, 12 of 14 (86%) of the lung tumor DNAs from smokers were found to contain activated protooncogenes. RAS oncogenes appear to play a role in the development of metastases in lung adenocarcinomas.     

RAS mutation in acute myeloid leukemia is associated with distinct cytogenetic subgroups but does not influence outcome in patients younger than 60 years

The pathogenesis of acute myeloid leukemia (AML) involves the cooperation of mutations promoting proliferation/survival and those impairing differentiation. The RAS pathway has been implicated as a key component of the proliferative drive in AML. We have screened AML patients, predominantly younger than 60 years and treated within 2 clinical trials, for NRAS (n = 1106), KRAS (n = 739), and HRAS (n = 200) hot-spot mutations using denaturing high-performance liquid chromatography or restriction fragment length polymorphism (RFLP) analysis. NRAS mutations were confirmed in 11% of patients (126/1106) and KRAS mutations in 5% (39/739). No HRAS mutations were detected in 200 randomly selected samples. Codons most frequently mutated were N12 (43%), N13 (21%), and K12 (21%). KRAS mutations were relatively overrepresented in French-American-British (FAB) type M4 (P < .001). NRAS mutation was over-represented in the t(3;5)(q21 approximately 25;q31 approximately q35) subgroup (P < .001) and underrepresented in t(15;17)(q22;q21) (P < .001). KRAS mutation was overrepresented in inv(16)(p13q22) (P = .004). Twenty-three percent of KRAS mutations were within the inv(16) subgroup. RAS mutation and FLT3 ITD were rarely coexistent (14/768; P < .001). Median percentage of RAS mutant allele assayed by quantitative RFLP analysis was 28% (N12), 19% (N13), 25% (N61), and 21% (K12). RAS mutation did not influence clinical outcome (overall/disease-free survival, complete remission, relapse rate) either for the entire cohort or within cytogenetic risk groups.     

FLT3, RAS, and TP53 mutations in elderly patients with acute myeloid leukemia

The prevalence and significance of genetic abnormalities in older patients with acute myeloid leukemia (AML) are unknown. Polymerase chain reactions and single-stranded conformational polymorphism analyses were used to examine 140 elderly AML patients enrolled in the Southwest Oncology Group study 9031 for FLT3, RAS, and TP53 mutations, which were found in 34%, 19%, and 9% of patients, respectively. All but one of the FLT3 (46 of 47) mutations were internal tandem duplications (ITDs) within exons 11 and 12. In the remaining case, a novel internal tandem triplication was found in exon 11. FLT3 ITDs were associated with higher white blood cell counts, higher peripheral blast percentages, normal cytogenetics, and less disease resistance. All RAS mutations (28 of 28) were missense point mutations in codons 12, 13, or 61. RAS mutations were associated with lower peripheral blast and bone marrow blast percentages. Only 2 of 47 patients with FLT3 ITDs also had a RAS mutation, indicating a significant negative association between FLT3 and RAS mutations (P =.0013). Most TP53 mutations (11 of 12) were missense point mutations in exons 5 to 8 and were associated with abnormal cytogenetics, especially abnormalities in both chromosomes 5 and 7. FLT3 and RAS mutations were not associated with inferior clinical outcomes, but TP53 mutations were associated with a worse overall survival (median 1 versus 8 months, P =.0007). These results indicate that mutations in FLT3, RAS, or TP53 are common in older patients with AML and are associated with specific AML phenotypes as defined by laboratory values, cytogenetics, and clinical outcomes. (Blood. 2001;97:3589-3595)     

High-throughput mutation profiling of CTCL samples reveals KRAS and NRAS mutations sensitizing tumors toward inhibition of the RAS/RAF/MEK signaling cascade

Cutaneous T-cell lymphomas (CTCLs) are malignancies of skin-homing lymphoid cells, which have so far not been investigated thoroughly for common oncogenic mutations. We screened 90 biopsy specimens from CTCL patients (41 mycosis fungoides, 36 Sézary syndrome, and 13 non-mycosis fungoides/Sézary syndrome CTCL) for somatic mutations using OncoMap technology. We detected oncogenic mutations for the RAS pathway in 4 of 90 samples. One mycosis fungoides and one pleomorphic CTCL harbored a KRAS(G13D) mutation; one Sézary syndrome and one CD30(+) CTCL harbored a NRAS(Q61K) amino acid change. All mutations were found in stage IV patients (4 of 42) who showed significantly decreased overall survival compared with stage IV patients without mutations (P = .04). In addition, we detected a NRAS(Q61K) mutation in the CTCL cell line Hut78. Knockdown of NRAS by siRNA induced apoptosis in mutant Hut78 cells but not in CTCL cell lines lacking RAS mutations. The NRAS(Q61K) mutation sensitized Hut78 cells toward growth inhibition by the MEK inhibitors U0126, AZD6244, and PD0325901. Furthermore, we found that MEK inhibitors exclusively induce apoptosis in Hut78 cells. Taken together, we conclude that RAS mutations are rare events at a late stage of CTCL, and our preclinical results suggest that such late-stage patients profit from MEK inhibitors.     

A single, multiplex analysis for all relevant activating NRAS gene mutations using heteroduplex generators

We describe a multiplex polymerase chain reaction (PCR)-based test that detected all relevant NRAS activating mutations using a single PCR followed directly by electrophoresis. The test uses a Universal Heteroduplex Generator (UHG) to detect exon-2 (codon 61) NRAS mutations in multiplex with an UHG for exon-1 (codons 12 and 13). The method differentiated all 19 relevant mutations in these exons and showed a mutation independent sensitivity of approximately 6%. The sensitive, specific detection of all NRAS activating mutations using this single rapid test represents a minimum workload and could be applied readily for large-scale screening and for routine analysis.     

Somatic PTPN11 mutations in childhood acute myeloid leukaemia

Somatic mutations in PTPN11, the gene encoding the transducer SHP-2, have emerged as a novel class of lesions that upregulate RAS signalling and contribute to leukaemogenesis. In a recent study of 69 children and adolescents with de novo acute myeloid leukaemia (AML), we documented a non-random distribution of PTPN11 mutations among French-American-British (FAB) subtypes. Lesions were restricted to FAB-M5 cases, where they were relatively common (four of 12 cases). Here, we report on the results of a molecular screening performed on 181 additional unselected patients, enrolled in participating institutions of the Associazione Italiana Ematologia Oncologia Pediatrica-AML Study Group, to provide a more accurate picture of the prevalence, spectrum and distribution of PTPN11 mutations in childhood AML and to investigate their clinical relevance. We concluded that PTPN11 defects do not represent a frequent event in this heterogeneous group of malignancies (4.4%), although they recur in a considerable percentage of patients with FAB-M5 (18%). PTPN11 lesions rarely occur in other subtypes. Within the FAB-M5 group no clear association of PTPN11 mutations with any clinical variable was evident. Nearly two third of the patients with this subtype were found to harbour an activating mutation in PTPN11, NRAS, KRAS2 or FLT3.     

Infrequent point mutations in codons 12 and 61 of ras oncogenes in human hepatocellular carcinomas.

DNA from human hepatocellular carcinomas (HCC) were analysed for the presence of mutations in codons 12 and 61 of the K-ras, H-ras and N-ras genes. The relevant ras sequences were amplified in vitro using the polymerase chain reaction and point mutations detected by selective hybridisation using mutation-specific synthetic oligonucleotides. In one of the 19 HCCs a mutation in codon 61 of the K-ras gene was detected, whilst in 3/19 HCCs a mutation was found in codon 61 of the N-ras gene. The mutations were all heterozygous A-T transversions and were found in HCCs arising in patients with underlying cirrhosis. In two of these patients where the corresponding normal tissue was available only the wild-type ras gene was detected, indicating that oncogenic activation of the ras gene was a consequence of somatic mutation. In another patient the same mutation in codon 61 of the N-ras gene was found in cirrhotic liver tissue and in all four patients the same mutation was also detected in formalin-fixed, paraffin-embedded liver biopsy HCC tissue obtained at diagnosis. These results indicate that mutational activation of the ras genes at codon 61 is an infrequent but possibly early event in the development of HCC in Britain.     

Mutational activation of N- and K-ras oncogenes in plasma cell dyscrasias

The frequency of N- and K-ras oncogene mutations was investigated in plasma cell dyscrasias. Genomic DNAs from 128 patients were selected for this study: 30 monoclonal gammopathies of undetermined significance, 8 solitary plasmacytomas, 77 multiple myelomas (MM), and 13 plasma cell leukemias (PCL). A two-step experimental approach was devised. All samples were screened for mutations by single-strand conformation polymorphism analysis. DNA fragments displaying an altered electrophoretic mobility were further studied by direct sequencing to confirm and characterize the nature of the mutations. Ras mutations are not randomly distributed because they are detectable only in MM (9%) and PCL (30.7%). N-ras codons 12, 13, and 61 and K-ras codon 12 were found to be mutated, but N-ras codon 61 mutation was the most frequent finding (63.6%). In conclusion, ras mutations were found in PCL, and in a subset of MM characterized by advanced-stage disease and adverse prognostic parameters. Furthermore, based on our findings, it is possible to speculate that ras mutations represent a late molecular lesion in the process of multistep carcinogenesis.     

N-ras mutations in adult de novo acute myelogenous leukemia: prevalence and clinical significance

Point mutations of the N-ras proto-oncogenes have been previously detected in 20% to 60% of samples of acute myelogenous leukemia (AML), but the clinical significance of these mutations is presently unclear. We directly sequenced polymerase chain reaction (PCR) amplified N-ras fragments to determine the frequency of N-ras point mutations in 55 adult patients with de novo AML. Mutations were present in 8 of 55 (15%) patients. These mutations were usually in codon 12, 13, or 61, but one patient had mutations in both codons 13 and 61, and another had an unusual point mutation in N-ras codon 60. A comparison of patients with and without N-ras mutations showed no statistically significant differences in pretreatment clinical variables, response to induction therapy, or survival, except for a possibly higher percentage of FAB M4 subtypes in patients with the N-ras mutation. These data together with previous reports suggest that the presence of N-ras point mutations do not clearly define a unique clinical or biologic subset of AML patients.     

A high frequency of N-RAS oncogene mutations in multiple myeloma.

Mutation of the RAS oncogene was studied in ten patients with multiple myeloma, and the DNA from nude mouse tumors formed by cells obtained from tumorigenecity assays (in vivo selection assays) in these patients was analyzed by PCR and oligonucleotide hybridization. Mutations of the N-RAS oncogene were identified in two of three patients investigated by in vivo selection assay and in five of ten patients investigated by PCR analysis of DNA from myeloma cells. In the two former patients, mutation of the N-RAS oncogene was observed at the 61st codon. Of the five N-RAS mutant-positive patients investigated by the PCR analysis, one had a mutation at codon 12, two had mutations at codon 13, and two had mutations at codon 61. None of the patients had mutations of the K-RAS oncogene. These results suggest that the frequency of RAS gene mutation in multiple myeloma is higher than in other lymphoid malignancies such as acute lymphocytic leukemia, chronic lymphocytic leukemia, and malignant lymphoma. As the mutation was observed only at the N-RAS oncogene level, it is speculated that N-RAS oncogene activation might play an important role in the progression of multiple myeloma.     

Occurrence of point mutations in p53 gene is not increased in patients with acute myeloid leukaemia carrying an activating N-ras mutation

Summary. The frequency of simultaneously detecting N- ras and p53 gene mutations was studied in leukaemia cells of patients with acute myeloid leukaemia (AML) or with myelodysplastic syndrome (MDS). Using in vitro DNA amplification followed by oligonucleotide hybridization analysis, 45 AML and six MDS patients were screened for activating mutations in codons 12, 13 and 61 of N- ras. Ten of them (eight AML and two MDS) were found positive. These 10 patients and 10 others without activating N- ras mutation were further analysed by direct sequencing of the amplified exons for p53 mutations and for atypical N- ras mutations. Beside the activating mutations in the N- ras gene, no additional transforming or nontransforming mutations could be detected in the N- ras. However, exon 7 of p53 was mutated in two AML patients without activating N- ras mutation. These data show that p53 mutations occurred with half the frequency of N- ras mutations in AML and that no positive correlation could be found between the onset of mutations in N- ras and p53 genes.     

Oncogenic NRAS rapidly and efficiently induces CMML- and AML-like diseases in mice

Activating mutations in RAS, predominantly NRAS, are common in myeloid malignancies. Previous studies in animal models have shown that oncogenic NRAS is unable to induce myeloid malignancies effectively, and it was suggested that oncogenic NRAS might only act as a secondary mutation in leukemogenesis. In this study, we examined the leukemogenicity of NRAS using an improved mouse bone marrow transduction and transplantation model. We found that oncogenic NRAS rapidly and efficiently induced chronic myelomonocytic leukemia (CMML)- or acute myeloid leukemia (AML)- like disease in mice, indicating that mutated NRAS can function as an initiating oncogene in the induction of myeloid malignancies. In addition to CMML and AML, we found that NRAS induced mastocytosis in mice. This result indicates that activation of the RAS pathway also plays an important role in the pathogenesis of mastocytosis. The mouse model for NRAS leukemogenesis established here provides a system for further studying the molecular mechanisms in the pathogenesis of myeloid malignancies and for testing relevant therapies.