The significance of CUX1 and chromosome 7 in myeloid malignancies

Key Points Autosomal-dominant SAMD9L gain-of-function mutations predispose to myeloid malignancies involving chromosome 7 aberrations. Hematopoietic reversions frequently occur postnatally and are associated with milder disease manifestations.

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Cytogenetics in Hairy Cell Leukemia at Diagnosis and Relapse: The Rate of Therapy-Related Myeloid Malignancies Is Low

Blood ◽

10.1182/blood.v126.23.2644.2644 ◽

2015 ◽

Vol 126 (23) ◽

pp. 2644-2644

Author(s):

Bartlomiej Getta ◽

Omar Abdel-Wahab ◽

Jae H. Park ◽

Martin S Tallman

Keyword(s):

Hairy Cell Leukemia ◽

Disease Type ◽

Chromosome 7 ◽

Hairy Cell ◽

Disease Relapse ◽

Cell Leukemia ◽

Abnormal Karyotype ◽

Cytogenetic Abnormalities ◽

Myeloid Malignancies

Abstract Cytogenetic analysis of a large cohort of hairy cell leukemia (HCL) patients (pts) has never been reported. The influence on outcome of cytogenetic abnormalities is unknown. We retrospectively reviewed records of pts with HCL treated at Memorial Sloan Kettering Cancer Center between January 1973 and December 2013. 501 pts were identified and 331 were confirmed to have a diagnosis of HCL by histopathology or immunophenotyping. 170 patients were excluded, either because their final diagnosis was an alternate disease or there was inaccessible clinical data. Descriptive statistics were used to evaluate the cohort. 260/331 (79%) were men, overall median age at diagnosis was 53 years (range 20-84 years) and median follow-up was 61 months. 241 had classical HCL and 18 had variant disease based on absent expression of CD25 by immunophenotyping or immunohistochemistry with median diagnostic WBC of 3.2x10^9/L and 8.4x10^9/L respectively. BRAF mutation testing was performed infrequently (<10% pts). In 72 pts we were unable to review immunophenotyping data to confirm disease type. 64 pts never received treatment, 156 received one line and 111 received at least 2 lines of therapy during follow up. The most common initial treatment was cladribine (n=215, 80%). Assessment of bone marrow cytogenetics was available in 105 of 331 patients (32%) at diagnosis with 92 cases of classical HCL, 8 variant HCL and 5 with unconfirmed disease type. Karyotype was normal in 95 patients (90.5%) and abnormal in 10 (9.5%). Abnormal karyotype was more common in patients with variant than classical disease, seen in 3/8 versus 7/92 respectively (p=0.007). 9/10 with abnormal karyotype had multiple clones identified including at least one cytogenetically normal metaphase. Sex chromosome loss was present in 4/10 pts (3 with loss of Y and 1 female with loss of X) while loss of genetic material from chromosome 7 was the most common autosomal abnormality (3/10 patients). The presence of an abnormal karyotype at diagnosis did not worsen survival compared to patients with a normal karyotype with an estimated 5 year OS of 100% and 97%, respectively. 30/111 pts (24 classical and 6 variant HCL) who received two or more lines of therapy had cytogenetics evaluated at some point during disease relapse and 17/30 had cytogenetic abnormalities. 6 of these had cytogenetics at diagnosis and 4/6 were normal. Pts with an abnormal karyotype received more lines of therapy prior to identification of a cytogenetic abnormality than those with normal cytogenetics with a median of 3 and 1 lines respectively (p=0.008). Pts with variant HCL were more likely to have abnormal cytogenetics at relapse (6/6) than those with classical disease (11/24) (p=0.017). Cytogenetic abnormalities of all evaluable pts with relapsed HCL were reviewed. The most common abnormalities seen at relapse were monosomies or partial chromosome deletions seen in 14/17 cases. The most common abnormalities were loss of material from chromosome 7 (6/17 pts) and chromosomes 13 and 17 (4/17 pts each). Multiple abnormalities were present in 11/17 pts. No abnormality appeared to be specific for classical or variant disease. In particular loss of material from chromosome 7 was seen in both disease types. Only 2 of the 331 pts developed a therapy-related acute myeloid leukemia (t-AML) both had classical HCL. The first developed t-AML with a complex monosomal karyotype after prior treatment with cladribine, pentostatin, fludarabine and rituximab. The second had t-AML with monosomy 7 following 4 treatments with cladribine. There were no cases of myelodysplasia. In summary we identified cytogenetic abnormalities in 10% of newly diagnosed HCL pts and found that this did not adversely affect survival. Pts with variant HCL are more likely to have abnormal cytogenetics at diagnosis and at disease relapse compared to those with classical disease. Cytogenetic changes appear to be more common in those who received more lines of cytotoxic chemotherapy. Loss of material from chromosome 7 is the most common cytogenetic change seen at diagnosis and at disease progression. The rate of therapy-related myeloid malignancies is low and is not increased in HCL variant. Identification of new molecular mutations arising during disease relapse may be insightful. Disclosures Park: Actinium Pharmaceuticals, Inc.: Research Funding; Juno Therapeutics: Consultancy.

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Various Abnormalities at Chromosome 7 Carry Distinct Biologic and Prognostic Implications In Myelodysplastic/Myeloproliferative Syndromes and Related Marrow Failures

Blood ◽

10.1182/blood.v116.21.2744.2744 ◽

2010 ◽

Vol 116 (21) ◽

pp. 2744-2744

Author(s):

Aaron D Viny ◽

Bartlomiej Przychodzen ◽

Christine L. O'Keefe ◽

Hideki Makishima ◽

Yuka Sugimoto ◽

...

Keyword(s):

Poor Prognosis ◽

Conflicts Of Interest ◽

Bone Marrow Failure ◽

Uniparental Disomy ◽

Chromosome 7 ◽

Juvenile Myelomonocytic Leukemia ◽

Monosomy 7 ◽

Myeloid Malignancies ◽

Chromosome 5Q ◽

Myelomonocytic Leukemia

Abstract Abstract 2744 Deletions involving chromosome 7 are frequently encountered in myeloid malignancies, mostly imparting a poor prognosis. Single nucleotide polymorphism array (SNP-A)-based cytogenetics has allowed for an improvement in the mapping of disease-related chromosomal regions through identification of microdeletion that define minimally affected areas for the search for pathogenic mutations. In addition, SNP-A facilitated the detection of somatic uniparental disomy (sUPD), which is frequently found in myeloid malignancies. Regions of sUPD are often associated with homozygous mutations present in the affected area, as shown for example for UPD9p and JAK2 or UPD11q and C-CBL mutations. Based on the precise mapping of genomic lesions on chromosome 7, we compared the outcomes of patients characterized by specific chromosomal abnormalities. Among 1163 patients with various myeloid malignancies studied by SNP-A we identified patients with somatic LOH involving chromosome 7 for whom clinical outcome data was available to assess survival. Regions fulfilling the criteria of germ line-encoded copy number variants and regions of homozygosity present in a control cohort (N=1535) were excluded. The rest of newly observed regions were in/excluded based on their absence or presence in the paired non-clonal DNA. In total, we identified 45 patients with monosomy 7, 37 patients with del(7q), and 21 with UPD7q. The CDR for del(7q) and UPD(7q) spanned nt 115221516–126602492 and nt 127,484,450–158821424, respectively. Among patients with monosomy 7, 17 were primary MDS, 22 had various bone marrow failure disorders including juvenile myelomonocytic leukemia (JMML) and clonal disease in the context of aplastic anemia (AA) and Fanconi anemia (FA), whereas UPD7q was predominantly found in MDS/MPD and MPD (N=10), sAML (N=3), and primary MDS (N=7). Patients with del(7q) included primary MDS and sAML. The most common concomitant cytogenetic abnormalities were seen in chromosome 5q and 17p, including frequent UPD17p. Chromosome 5q and 17p lesions were more common in del(7q), identified in 10 and 7 patients respectively, and were represented equivalently among monosomy 7 (N=5 for each) and UPD7q patients (N=3 and 5 respectively). In addition to the large deletions of the long arm of chromosome 7 ([del(7q)] discussed above, using SNP-A-based karyotyping, 18 patients were identified with overlapping microdeletions involving two distinct loci at 7q22.1 (N=5 and 6, respectively), and one at 7q36.1 (N=2). The first 7q22.1 loci was found in 1 patient with MDS and 5 with MPN, while the second loci was identified in 3 patients with chronic myelomonocytic leukemia (CMML), 1 with MPN, and 1 with sAML. The 7q36.1 minimally affected region was found in 2 patients, 1 each with MDS and CMML. In 15 patients non-recurrent microdeletions were found with average size of 799 kb. Clinical parameters were compared for each abnormality and Kaplan-Meier plots were generated and evaluated by log-rank test. Comparison of monosomy 7 and del(7q) did not show statistically different impact on outcome (p=0.26), whereas each was found to carry a significantly poorer prognosis (OS) than UPD7 (p=0.05 and 0.02 respectively). Deletion of 7q36.1, whose common deleted region was consistent with our previous identification of mutation within EZH2, carried an overall poor prognosis while 7q22.1 did not affect survival compared to patients without chromosome 7 abnormalities. These data confirm the known poor outcomes of patients with chromosome 7 abnormalities shared among monosomy 7 as well as del(7q). A slightly better albeit poor prognosis was seen in UPD(7q), suggesting that pattern or inheritance of chromosome 7 abnormalities into the dysplastic clone may affect ultimate leukemogenicity. UPD7q may represent a distinct pathogenesis, likely with distinct gene mutations compared to del(7q) and monosomy 7. Somatic microdeletions in chromosome 7 analysis may be nonpathogenic while those with poor prognosis, such as 7q36.1, may harbor pathogeneic genes. Disclosures: No relevant conflicts of interest to declare.

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The prognostic impact of loss of chromosome 7 material detected by fluorescence in situ hybridization (FISH) in myeloid malignancies

Journal of the Egyptian National Cancer Institute ◽

10.1016/j.jnci.2018.11.001 ◽

2018 ◽

Vol 30 (4) ◽

pp. 133-138

Author(s):

Mohamed Amr M. El-Menoufy ◽

Zeinab I. Mourad ◽

Nahla M. Farahat

Keyword(s):

In Situ Hybridization ◽

Fluorescence In Situ Hybridization ◽

Chromosome 7 ◽

Prognostic Impact ◽

Myeloid Malignancies

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Next Generation Exome Sequencing for Identification of the Gene Mutations Associated with Loss of Heterozygozity on Chromosome 7 In Myeloid Malignancies

Blood ◽

10.1182/blood.v116.21.297.297 ◽

2010 ◽

Vol 116 (21) ◽

pp. 297-297

Author(s):

Yuka Sugimoto ◽

Hideki Makishima ◽

Hadrian Szpurka ◽

Anna Jankowska ◽

Kathryn Guinta ◽

...

Keyword(s):

Exome Sequencing ◽

Research Funding ◽

Sanger Sequencing ◽

False Positives ◽

Chromosome 7 ◽

Next Generation ◽

Monosomy 7 ◽

Myeloid Malignancies ◽

Homozygous Mutations ◽

Myelomonocytic Leukemia

Abstract Abstract 297 Loss of heterozygosity (LOH) involving chromosome-7 is one of the most common unbalanced chromosomal defects found in chronic and acute myeloid malignancies. Recent application of single nucleotide polymorphism arrays (SNP-A) led to realization that recurrent areas of LOH may be not only due to deletion of the whole chromosome-7, its long arm but due to copy-neutral LOH, most often involving 7q. We hypothesized that deletions and uniparental disomy (UPD) involving long arm of chromosome-7 may be associated with pathogenic hemizygous or homozygous mutations, respectively. Such mutations may affect tumor suppressor genes and likely contribute to/drive malignant evolution in myeloid disorders. We identified a large number of patients with lesions of chromosome-7 (monosomy-7, del(7q), and UPD(7q)), including 38 patients with microdeletions 7q. After unsuccessful targeted Sanger sequencing of large numbers of genes on chromosome-7 we set up to apply the next generation sequencing (NGS) of the exome libraries generated from patients with LOH7. Exome chromosome-7 libraries were enriched for the content of coding sequences using the SureSelect capture synthetic biotinylated RNA probes, tiling all the coding regions from chromosome-7. For NGS exome sequencing we selected 6 cases of monosomy-7 (2 sAML, 1 MDS, 1 chronic myelomonocytic leukemia (CMML), 1 juvenile myelomonocytic leukemia (JMML), and 1 aplastic anemia (AA)), 2 cases of del(7q) with MDS, 3 cases of UPD(7q) (2 MDS and 1 MDS/MPN) and also studied paired germline samples when possible. We treated monosomy-7 and del(7q) as one class and analyzed them together. Cases with UPD(7q) were analyzed separately. Averaged sequencing depth was 79. Each monosomy-7 sample had 3788, 3792, 5306, 4013, 5237, 4016 potential alterations (average; 4359/sample), and each del(7q) sample had 5431, 4521 observations (average; 4976/sample). After exclusion of observations outside of affected regions del(7q), we eliminated previously reported SNPs and non-coding lesions and selected 658 observations of which 422 were nonsynonymous. For further analysis, the alteration leading to stop codons were chosen as tier 1 candidates (N=16). After elimination of false positives due to the accumulation of reading errors at specific locations were discarded, 3 candidates were left and verified by Sanger sequencing. All of 3 were confirmed as new SNPs. After elimination of false positives, the alteration present in multiple samples were designated as tier 2 group (N=101). All of these sequence changes were shown to be new SNPs; 2 were not confirmed by traditional sequencing. Mutations for which the non-reference base occurred greater than 50% were designated tier 3 candidates (N=73), of which 25 candidates have been already checked by resequencing. To date, we have identified 2 somatic point mutations confirmed by Sanger sequencing, including NRCAM1Q1040K and LMTK2A1147T and each identified in different monosomy-7 samples. Screening of 30 monosomy-7 or del(7q) samples showed that observed mutations were not recurrent. The similar stepwise analytic approach was applied to 3 cases of UPD(7q) (average; 4312 observations per sample). After exclusion of reported SNPs and synonymous alterations, we selected a total of 147 alterations. The number was further reduced to 5 potential pathogenic changes after elimination of false positive NGS artifacts. By verification with Sanger sequencing, recurrent EZH2 homozygous mutations (both were R690H) were confirmed in 2 cases with UPD7q. Then we sequenced whole the exons in additional 12 cases of UPD(7q) were sequenced yielding 2 EZH2 mutations. In addition, EZH2 mutations were identified in 2 cases of microdeletion 7q36.1 and 4 cases without LOH7q occurring in heterozygous constellation. No mutations of EZH2 were found in monosomy-7 or del(7q) sequenced (N=28). In conclusion, to date, using NGS strategy, we have identified 3 new mutations including NRCAM1Q1040K, LMTK2A1147T, and recurrently occurring mutation of EZH2 (EZH2R690H). Several additional candidate mutations are currently screened. Disclosures: Maciejewski: Eisai: Research Funding; Celgene: Research Funding.

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