Variant | Gene | Type | COSMIC ID | DNA Change (Coding Nucleotide) | Exon |
---|---|---|---|---|---|
NPM1 copy number gain | NPM1 | CNV | |||
NPM1 copy number loss | NPM1 | CNV | |||
NPM1 any mutation | NPM1 | any | |||
NPM1 codon(s) 288 frameshift | NPM1 | frameshift | 11 | ||
NPM1 codon(s) 290 frameshift | NPM1 | frameshift | 11 |
This gene is a known cancer gene.
Mutations of NPM1 have been reported in approximately 25-35% of cases of acute myeloid leukemia (AML). The mutations of NPM1 are frameshift mutations in the C-terminus of the protein that alter the C-terminal amino acid sequence and are associated with aberrant cytoplasmic localization of the protein. NPM1 mutations in AML are typically associated with a normal karyotype and may co-exist with FLT3 mutations. The presence of NPM1 mutations has been associated with improved complete remission rates, but not necessarily overall survival, in multivariate analysis including assessment of the variety of more recently discovered mutations that may be present in AML. In addition, cytogenetically normal AML with mutated NPM1, without FLT3 ITD or mutated DNMT3A, has been considered to be a favorable genetic risk group according to some studies, although other studies suggest that coexistant mutations in IDH1 or IDH2 may be required for the favorable risk effect of NPM1.
This gene is a known cancer gene.
RAD21 belongs to the cohesin complex family of genes that encode protein subunits of the cohesion complex, which regulates chromosomal segregation. is a member of the cohesin complex that regulates chromosome segregation during meiosis and mitosis. Loss of function mutations of RAD21 have been described throughout the gene in approximately 1% of cases of myelodysplasia, 1-5% of acute myeloid leukemia (AML), 1% of chronic myeloid leukemia and tend to be mutually exclusive of other mutations in the other components of the cohesin complex (ie, STAG1, SMC3, STAG2, SMC1A). In AML, mutations in the cohesin complex genes tend to be associated with mutations in NPM1. Cohesin complex mutations do not have clear prognostic impact in AML. Cohesin complex mutations are associated with an unfavorable prognosis in myelodysplastic syndrome, and are more frequently found in patients with high IPSS scores and secondary acute myeloid leukemia.
SMC3 is a member of the cohesin complex and has been found to be mutated in approximately 1% of acute myeloid leukemia and 1% myelodysplastic syndromes. The mutations of SMC3 described tend to be missense mutations that occur throughout the gene. Mutations of the various members of the cohesin complex appear to occur in a mutually exclusive manner. Cases of AML with mutations of the cohesin complex may be associated with mutations of NPM1. Currently there does not appear to be any clear prognosistic impact of cohesin complex gene mutations in AML. Cohesin complex mutations are associated with an unfavorable prognosis in myelodysplastic syndrome, and are more frequently found in patients with high IPSS scores and secondary acute myeloid leukemia.
BCOR is a ubiquitously expressed nuclear protein that is a transcriptional corepressor important in several cellular processes. Somatic, nonsense and frameshift mutations throughout BCOR have been reported in approximately 7% of chronic myelomonocytic leukemia, 4% of patients with myelodysplastic syndrome(MDS), 4% of primary acute myeloid leukemia and appear to be associated with RUNX1 and DNMT3A mutations . Also, BCOR mutations may be enriched among cases of AML lacking NPM1, CEBPA, FLT3-ITD, IDH1 and MLL-PTD alterations. BCOR mutations tend to be subclonal in MDS, clonal in primary AML and are believed to have significance as loss of function mutations in a tumor suppressor gene that affect the functional allele in male and female patients. The presence of BCOR mutation in patients with MDS and AML has been associated with poorer overall survival according to some studies.
BCOR is a ubiquitously expressed nuclear protein that is a transcriptional corepressor important in several cellular processes. Somatic, nonsense and frameshift mutations throughout BCOR have been reported in approximately 7% of chronic myelomonocytic leukemia, 4% of patients with myelodysplastic syndrome(MDS), 4% of primary acute myeloid leukemia and appear to be associated with RUNX1 and DNMT3A mutations . Also, BCOR mutations may be enriched among cases of AML lacking NPM1, CEBPA, FLT3-ITD, IDH1 and MLL-PTD alterations. BCOR mutations tend to be subclonal in MDS, clonal in primary AML and are believed to have significance as loss of function mutations in a tumor suppressor gene that affect the functional allele in male and female patients. The presence of BCOR mutation in patients with MDS and AML has been associated with poorer overall survival according to some studies.
DNMT3A is a DNA methyltransferase. Recurrent, somatic, heterozygous mutations in DNMT3A have been reported in approximately 18-25% of cases of acute myeloid leukemia (up to 34% of normal karyotype AML), 12-18% of cases of myelodysplastic syndrome, up to 15% of myeloproliferative neoplasms, less than 5% of cases of chronic myelomonocytic leukemia and 15% of cases of adult, eary T cell precursor acute lymphoblastic leukemia. DNMT3A is also one of the most frequently mutated genes in CHIP and CCUS. Mutations in DNMT3A may occur together with mutations in other genes including JAK2, FLT3, IDH1/IDH2, ASXL1, TET2 and NPM1. DNMT3A mutations have been associated with reduced enzymatic activity or altered histone binding, as well as reduced DNA methylation in various genomic regions and altered gene expression in some models. Codon R882 is a hotspot for mutations in DNMT3A. DNMT3A mutations may be associated with adverse prognosis in specific subtypes of AML according to some, but not all studies; the prognostic significance of DNMT3A in AML may depend on patient age, type of DNMT3A mutation (R882 or non-R882 mutation) and the co-existence (or absence) of specific mutations in other genes. DNMT3A mutations may also be associated with adverse prognosis in MDS according to some studies.
ASXL1 regulates epigenetic functions including histone and chromatin modifications. ASXL1 mutations have been reported in 40-50% of chronic myelomonocytic leukemia(CMML), 20% of myelodsyplastic syndromes, 20-35% of primary myelofibrosis, 15% of systemic mastocytosis, 30% of patients with secondary acute myeloid leukemia and 5-10% of primary acute myeloid leukemia. ASXL1 mutations have also been described in CHIP and CCUS. In CMML, missense mutations of ASXL1 appear to be less common (less than 10% of cases). Nonsense and frameshift mutations (but apparently not missense mutations) of ASXL1 have been reported to carry an adverse prognostic impact in cases of chronic myelomonocytic leukemia. In addition, ASXL1 mutations have been associated with adverse outcome in myelodysplasia, primary myelofibrosis and systemic mastocytosis. Among cases of AML, ASXL1 mutations appear to be associated with adverse prognosis in some subtypes of AML according to some, but not all, studies. ASXL1 mutations may coexist with mutations of splicing factor components, TET2 and RUNX1; for example, co-existence of U2AF1 and ASXL1 mutations have been described in CMML and primary myelofibrosis; While in AML, ASXL1 mutations have been reported to be exclusive of NPM1 mutations according to some studies.
ASXL1 regulates epigenetic functions including histone and chromatin modifications. ASXL1 mutations have been reported in 40-50% of chronic myelomonocytic leukemia(CMML), 20% of myelodsyplastic syndromes, 20-35% of primary myelofibrosis, 15% of systemic mastocytosis, 30% of patients with secondary acute myeloid leukemia and 5-10% of primary acute myeloid leukemia. ASXL1 mutations have also been described in CHIP and CCUS. In CMML, missense mutations of ASXL1 appear to be less common (less than 10% of cases). Nonsense and frameshift mutations (but apparently not missense mutations) of ASXL1 have been reported to carry an adverse prognostic impact in cases of chronic myelomonocytic leukemia. In addition, ASXL1 mutations have been associated with adverse outcome in myelodysplasia, primary myelofibrosis and systemic mastocytosis. Among cases of AML, ASXL1 mutations appear to be associated with adverse prognosis in some subtypes of AML according to some, but not all, studies. ASXL1 mutations may coexist with mutations of splicing factor components, TET2 and RUNX1; for example, co-existence of U2AF1 and ASXL1 mutations have been described in CMML and primary myelofibrosis; While in AML, ASXL1 mutations have been reported to be exclusive of NPM1 mutations according to some studies.
IDH1 is an enzyme localized to the cytoplasm and peroxisomes and involved in citrate metabolism. Mutations at Arg132 of IDH1 are typically heterozygous mutations and considered gain of function mutations that lead to increased levels of 2-hydroxyglutarate which are believed to alter epigenetic regulation (ie, DNA methylation) in AML. Mutations of IDH1 appear to be mutually exclusive of mutations in TET2, another gene involved in regulation of DNA methylation, and also exclusive of mutations in IDH2. Mutations of IDH1 have been shown to lead to increased DNA methylation in AML. Recurrent missense mutation of Arg 132 in IDH1 has been reported in approximately 5-15% of cases of acute myeloid leukemia and is often associated with a normal karyotype, wild type CEBPA, wild type FLT3 and the presence of NPM1 mutations. In addition, this mutation has been reported in approximately 10-20% of cases with leukemic transformation of myeloproliferative neoplasms and has been reported in less than 5% of chronic phase primary myelofibrosis, less than 5% of myelodysplastic syndrome and rare cases of polycythemia vera, essential thrombocytosis and chronic myelomonocytic leukemia. The prognostic impact of IDH1 mutations in AML appears uncertain, however, in the settings of primary myelofibrosis and polycythemia vera, the presence of IDH1 mutation is independently associated with inferior survival. Mutant IDH1 represents a therapeutic target in some clinical settings.
WT1 encodes for a transcription factor containing an N-terminal transactivation domain and a C-terminal zinc-finger domain necessary for the development of the urogenital system. The precise roles of WT1 in normal and malignant hematopoiesis remain uncertain. New emerging supports a novel role of WT1 in the regulation of epigenetic programs through its interaction with TET proteins in the 5=hydroxymethylation of cytosines. WT1 mutations are found in 6% of acute myeloid leukemia overall, and about 8-13% in cytogenetically normal AML. Higher frequencies are present in biallelic CEBPA mutated acute myeloid leukemia (14%), followed by t(15;17)/PML-RARA (11.0%), and FLT3-ITD (8.5%,). WT1 mutations are associated with younger age in AML. WT1 mutations are typically putative loss of function mutations and most frequently occur in exon 7 or exon 9. About 75% of these mutations are frameshift, and the remaining are missense, nonsense, splice site or inframe indel mutations. In some cases two or more mutations in WT1 may occur. In addition, WT1 mutations may coexist with mutations in NPM1, FLT3, among others. WT1 is overexpressed in the majority of AML, giving rise to the concept that it may act as both a tumor suppressor and oncogene, depending on the context. Several studies showed that WT1 mutations are associated with a worse prognosis in cytogenetically normal acute myeloid leukemia, although one study including patients from three German-Austrian AML study protocols demonstrated no association with overall survival or relapse-free survival. Given its over-expression in AML, clinical trials employing peptide vaccination strategy against WT1 has been ongoing in AML patients.
PTPN11 encodes SHP2, a member of the non-receptor protein tyrosine phosphatase (PTP) family that regulates growth factor and cytokine signaling and plays a key role in the proliferation and survival of hematopoietic cells. PTPN11 mutation is directly associated with the pathogenesis of Noonan syndrome and childhood leukemias. Despite its direct function in protein dephosphorylation, SHP2 plays an overall positive role in transducing signals. Germline and somatic mutations that result in increased activity of PTPN11 have been described in Noonan's syndrome (approximately 50%), juvenile myelomonocytic leukemia (35-42%), pediatric and adult myelodysplasic syndromes (4-10%), B cell acute lymphoblastic leukemia (5-10%), as well as pediatric and adult acute myeloid leukemia (5-10%). These gain of function mutations most often occur as heterozygous missense mutations located in exon 3 (SH2 domain) or exon 13 (phosphatase domain) . Within cases of juvenile myelomonocytic leukemia, mutations of PTPN11 tend to be exclusive of mutations in RAS, CBL and NF-1. PTPN11 mutations in adult AML are associated with a normal karyotype and concurrent NPM1 mutation, but no alteration of the FLT3. In one study, myelodysplastic syndromes with PTPN11 mutations were shown to have a worse overall survival. Small molecule inhibitors of PTPN11 are currently being developed.
RUNX1(AML1, CBFA2) encodes the alpha subunit of core binding factor and is a transcription factor important in normal hematopoietic development. RUNX1 mutations have been reported in approximately 10% of myelodysplastic cases, 5-15% of acute myeloid leukemia, 8-37% of chronic myelomonocytic leukemia, 10% of T cell acute lymphoblastic leukemia, 3% of systemic mastocytosis, 2% of essential thrombocythemia and 2% of polycythemia vera. The mutations include frameshift, missense, nonsense, and splice site mutations. Typically, the Runt domain and the region just downstream of the Runt domain are affected and the mutations tend to be monoallelic. AML with RUNX1 mutation which does not fulfill the diagnostic criteria for other specific AML subtypes in the categories of AML with recurrent genetic abnormalities, therapy-related myeloid neoplasms, or AML with myelodysplasia-related changes is now classified the provisional entity of AML with mutated RUNX1. RUNX1 mutations may be associated with Trisomy 8 or MLL-PTD in AML according to some studies. They tend not to occur in AML cases with favorable cytogenetic findings and appear to be exclusive of NPM1 or CEBPA mutations in AML. Myeloid neoplasms, predominantly MDS/AML, developing in patients, usually at a young age, with a familial platelet disorder and germline monoallelic RUNX1 mutations are categorized as myeloid neoplasms with germline RUNX1 mutation. Of note, RUNX1 may also be involved in large intragenic deletions and translocations (e.g., t(8;21)(RUNX1-ETO), t(3;21)(RUNX1-EVI1), t(12;21)(TEL-RUNX1) which are not detected by this assay. Mutated RUNX1 is a poor-risk prognostic marker in AML unless it co-occurs with favorable-risk AML subtypes (NCCN Guidelines for AML). RUNX1 nonsense or frameshift mutations are associated with an unfavorable prognosis in myelodysplastic syndrome, independent of IPSS, IPSS-R, age, and other gene mutations (NCCN Guidelines for Myelodysplastic Syndromes). RUNX1 mutations are independently associated with unfavorable outcomes and shorter survival after hematopoietic stem cell transplantation in patients with myelodysplastic syndrome and myelodysplastic syndrome/acute myeloid leukemia. RUNX1 mutations are also associated with an unfavorable prognosis chronic myelomonocytic leukemia and systemic mastocytosis.