Alexander Pemov

Mitotic Recombination of Chromosome Arm 17q as a Cause of Loss of Heterozygosity of NF1 in Neurofibromatosis Type 1-Associated Glomus Tumors

Neurofibromatosis type 1 (NF1) is a common, autosomal dominant, tumor‐predisposition syndrome that arises secondary to mutations in NF1. Glomus tumors are painful benign tumors that originate from the glomus body in the fingers and toes due to biallelic inactivation of NF1. We karyotyped cultures from four previously reported and one new glomus tumor and hybridized tumor (and matching germline) DNA on Illumina HumanOmni1‐Quad SNP arrays (∼1 × 106 SNPs). Two tumors displayed evidence of copy‐neutral loss of heterozygosity of chromosome arm 17q not observed in the germline sample, consistent with a mitotic recombination event. One of these two tumors, NF1‐G12, featured extreme polyploidy (near‐tetraploidy, near‐hexaploidy, or near‐septaploidy) across all chromosomes. In the remaining four tumors, there were few cytogenetic abnormalities observed, and copy‐number analysis was consistent with diploidy in all chromosomes. This is the first study of glomus tumors cytogenetics, to our knowledge, and the first to report biallelic inactivation of NF1 secondary to mitotic recombination of chromosome arm 17q in multiple NF1‐associated glomus tumors. We have observed mitotic recombination in 22% of molecularly characterized NF1‐associated glomus tumors, suggesting that it is a not uncommon mechanism in the reduction to homozygosity of the NF1 germline mutation in these tumors. In tumor NF1‐G12, we hypothesize that mitotic recombination also “unmasked” (reduced to homozygosity) a hypomorphic germline allele in a gene on chromosome arm 17q associated with chromosomal instability, resulting in the extreme polyploidy.

Genetic modifiers of neurofibromatosis type 1-associated café-au-lait macule count identified using multi-platform analysis.

Neurofibromatosis type 1 (NF1) is an autosomal dominant, monogenic disorder of dysregulated neurocutaneous tissue growth. Pleiotropy, variable expressivity and few NF1 genotype-phenotype correlates limit clinical prognostication in NF1. Phenotype complexity in NF1 is hypothesized to derive in part from genetic modifiers unlinked to the NF1 locus. In this study, we hypothesized that normal variation in germline gene expression confers risk for certain phenotypes in NF1. In a set of 79 individuals with NF1, we examined the association between gene expression in lymphoblastoid cell lines with NF1-associated phenotypes and sequenced select genes with significant phenotype/expression correlations. In a discovery cohort of 89 self-reported European-Americans with NF1 we examined the association between germline sequence variants of these genes with café-au-lait macule (CALM) count, a tractable, tumor-like phenotype in NF1. Two correlated, common SNPs (rs4660761 and rs7161) between DPH2 and ATP6V0B were significantly associated with the CALM count. Analysis with tiled regression also identified SNP rs4660761 as significantly associated with CALM count. SNP rs1800934 and 12 rare variants in the mismatch repair gene MSH6 were also associated with CALM count. Both SNPs rs7161 and rs4660761 (DPH2 and ATP6V0B) were highly significant in a mega-analysis in a combined cohort of 180 self-reported European-Americans; SNP rs1800934 (MSH6) was near-significant in a meta-analysis assuming dominant effect of the minor allele. SNP rs4660761 is predicted to regulate ATP6V0B, a gene associated with melanosome biology. Individuals with homozygous mutations in MSH6 can develop an NF1-like phenotype, including multiple CALMs. Through a multi-platform approach, we identified variants that influence NF1 CALM count.

Whole-exome sequencing reveals a C-terminal germline variant in CEBPA-associated acute myeloid leukemia: 45-year follow-up of a large family

Familial acute myeloid leukemia is rare and linked to germline mutations in RUNX1, GATA2 or CCAAT/enhancer binding protein-α (CEBPA). We re-evaluated a large family with acute myeloid leukemia originally seen at NIH in 1969. We used whole exome sequencing to study this family, and conducted in silico bioinformatics analysis, protein structural modeling and laboratory experiments to assess the impact of the identified CEBPA Q311P mutation. Unlike most previously identified germline mutations in CEBPA, which were N-terminal frameshift mutations, we identified a novel Q311P variant that was located in the C-terminal bZip domain of C/EBPα. Protein structural modeling suggested that the Q311P mutation alters the ability of the CEBPA dimer to bind DNA. Electrophoretic mobility shift assays showed that the Q311P mu-tant had attenuated binding to DNA, as predicted by the protein modeling. Consistent with these findings, we found that the Q311P mutation has reduced transactivation, consistent with a loss-of-function mutation. From 45 years of follow up, we observed incomplete penetrance (46%) of CEBPA Q311P. This study of a large multi-generational pedigree reveals that a germline mutation in the C-terminal bZip domain can alter the ability of C/EBP-α to bind DNA and reduces transactivation, leading to acute myeloid leukemia.

The primacy of NF1 loss as the driver of tumorigenesis in neurofibromatosis type 1-associated plexiform neurofibromas

Neurofibromatosis type 1 (NF1) is a common tumor-predisposition disorder due to germline mutations in the tumor suppressor gene NF1. A virtually pathognomonic finding of NF1 is the plexiform neurofibroma (PN), a benign, likely congenital tumor that arises from bi-allelic inactivation of NF1. PN can undergo transformation to a malignant peripheral nerve sheath tumor, an aggressive soft-tissue sarcoma. To better understand the non-NF1 genetic contributions to PN pathogenesis, we performed whole-exome sequencing, RNASeq profiling and genome-wide copy-number determination for 23 low-passage Schwann cell cultures established from surgical PN material with matching germline DNA. All resected tumors were derived from routine debulking surgeries. None of the tumors were considered at risk for malignant transformation at the time; for example, there was no pain or rapid growth. Deep (~500X) NF1 exon sequencing was also conducted on tumor DNA. Non-NF1 somatic mutation verification was performed using the Ampliseq/IonTorrent platform. We identified 100% of the germline NF1 mutations and found somatic NF1 inactivation in 74% of the PN. One individual with three PNs had different NF1 somatic mutations in each tumor. The median number of somatic mutations per sample, including NF1, was one (range 0–8). NF1 was the only gene that was recurrently somatically inactivated in multiple tumors. Gene Set Enrichment Analysis of transcriptome-wide tumor RNA sequencing identified five significant (FDR<0.01) and seven trending (0.01⩽FDR<0.02) gene sets related to DNA replication, telomere maintenance and elongation, cell cycle progression, signal transduction and cell proliferation. We found no recurrent non-NF1 locus copy-number variation in PN. This is the first multi-sample whole-exome and whole-transcriptome sequencing study of NF1-associated PN. Taken together with concurrent copy-number data, our comprehensive genetic analysis reveals the primacy of NF1 loss as the driver of PN tumorigenesis.

First insight into the somatic mutation burden of neurofibromatosis type 2-associated grade I and grade II meningiomas: a case report comprehensive genomic study of two cranial meningiomas with vastly different clinical presentation

BackgroundNeurofibromatosis type 2 (NF2) is a rare autosomal dominant nervous system tumor predisposition disorder caused by constitutive inactivation of one of the two copies of NF2. Meningiomas affect about one half of NF2 patients, and are associated with a higher disease burden. Currently, the somatic mutation landscape in NF2-associated meningiomas remains largely unexamined.Case presentationHere, we present an in-depth genomic study of benign and atypical meningiomas, both from a single NF2 patient. While the grade I tumor was asymptomatic, the grade II tumor exhibited an unusually high growth rate: expanding to 335 times its initial volume within one year. The genomes of both tumors were examined by whole-exome sequencing (WES) complemented with spectral karyotyping (SKY) and SNP-array copy-number analyses. To better understand the clonal composition of the atypical meningioma, the tumor was divided in four sections and each section was investigated independently. Both tumors had second copy inactivation of NF2, confirming the central role of the gene in meningioma formation. The genome of the benign tumor closely resembled that of a normal diploid cell and had only one other deleterious mutation (EPHB3). In contrast, the chromosomal architecture of the grade II tumor was highly re-arranged, yet uniform among all analyzed fragments, implying that this large and fast growing tumor was composed of relatively few clones. Besides multiple gains and losses, the grade II meningioma harbored numerous chromosomal translocations. WES analysis of the atypical tumor identified deleterious mutations in two genes: ADAMTSL3 and CAPN5 in all fragments, indicating that the mutations were present in the cell undergoing fast clonal expansionConclusionsThis is the first WES study of NF2-associated meningiomas. Besides second NF2 copy inactivation, we found low somatic burden in both tumors and high level of genomic instability in the atypical meningioma. Genomic instability resulting in altered gene dosage and compromised structural integrity of multiple genes may be the primary reason of the high growth rate for the grade II tumor. Further study of ADAMTSL3 and CAPN5 may lead to elucidation of their molecular implications in meningioma pathogenesis.

Abstract 1456: Identifying early genetic steps in malignant transformation of neurofibromatosis type 1- associated plexiform neurofibromas

BACKGROUND: Neurofibromatosis type 1 (NF1) is a genetic tumor predisposition disorder caused by germline mutations in tumor suppressor NF1. Plexiform neurofibromas (PN) are benign tumors that arise prenatally or early in childhood and affect 30-50% of NF1 population. Somatic inactivation of second copy of NF1 is believed to be primary genetic event leading to PN initiation. NF1 patients have 8-12% lifetime risk of developing malignant peripheral nerve sheath tumor (MPNST), a highly aggressive soft tissue sarcoma, often arising from pre-existing PN and atypical NF (ANF). ANF are pre-malignant tumors that often arise within PN and can transform into MPNST. They are distinct from both PN and MPNST clinically and histologically, thus representing an intermediate step in malignant transformation. Several studies identified deletion of the CDKN2A/2B locus as the most frequent genetic event in ANF, however it is not clear whether other genes or pathways play role in PN transformation into ANF and further into MPNST. In this study, we performed genomic analysis of 16 ANF and 4 MPNST matched with normal DNA obtained from 14 and 4 patients, respectively. METHODS: We performed whole exome sequencing and whole transcriptome RNASeq analyses on Illumina Hi-Seq 2500 platform and copy-number variant (CNV) analysis on Illumina HumanOmniExpressExome-8 SNP-arrays. In addition, we performed deep sequencing of NF1 and validation of select mutations on IonTorrent platform. For select tumors we estimated growth rate and metabolic activity by using volumetric MRI and FDG-PET. RESULTS: We identified inactivation of NF1 in the majority of ANF and all MPNST. We also detected CDKN2A/B locus deletion in the majority of ANF and MPNST (heterozygous in ANF and mostly homozygous in MPNST). We determined that PRC2 genes (EED and SUZ12) were mutated in multiple MPNST but never in ANF. We identified a low number of point mutations and small indels in the genomes of ANF (median 1, range 0-4) and somewhat elevated mutation burden in MPNST (median 23, range 18-31), however none of these mutations were recurrent and none of the mutant genes (other than NF1 and CDKN2A) were present in multiple samples. We found 93 CNV per tumor (median) in ANF that constituted ~2% of their genomes. In comparison, we observed 2,249 CNV (median) in MPNST that comprised ~75% of their genomes. We didn’t detect significant correlation between growth rate or metabolic activity and the degree of genomic instability or mutation burden in the tumors, however the size of the sample set was modest. RNAseq data analysis is pending. CONCLUSIONS: It appears that PN-ANF transition is predominantly if not exclusively driven by heterozygous deletion of the CDKN2A/2B locus. Further progression to MPNST likely involves homozygous loss of CDKN2A/B and complete inactivation of the PRC2 complex. Widespread LOH in MPNST may accelerate inactivation of key gatekeepers. Citation Format: Alexander Pemov, Nancy F. Hansen, Rajesh Patidar, Christine Higham, Eva Dombi, Joseph F. Boland, Settara C. Chandrasekharappa, NIH Intramural Sequencing Center, James C. Mullikin, Margaret Wallace, Javed Khan, Eric Legius, Brigitte Widemann, Douglas R. Stewart. Identifying early genetic steps in malignant transformation of neurofibromatosis type 1- associated plexiform neurofibromas [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 1456. doi:10.1158/1538-7445.AM2017-1456

Abstract 2756: Whole-exome sequencing reveals a novel germline variant in CEBPA-associated familial acute myeloid leukemia: 45-year follow-up of a large family

Familial acute myeloid leukemia (AML) is rare and linked to germline mutations in RUNX1 or CCAAT/enhancer binding protein-α (CEBPA). We conducted whole-exome sequencing on a large family with AML originally evaluated at NIH in 1969 and uncovered a CEBPA Q311P mutation in all tested, affected members. The Q311P variant, located in the C-terminal bZip domain of CEBPA, was predicted to be highly deleterious by in silico algorithms; the Q311 position was highly conserved among CEBPA orthologs and paralogs. This variant has not been observed in the NHLBI9s Exome Sequencing Project or the Broad Institute9s Exome Aggregation Consortium. Protein structural modeling suggested that the Q311P mutation alters the ability of the CEBPA dimer to bind DNA. Electrophoretic mobility shift assays showed that the Q311P mutant had attenuated binding to DNA, as predicted by the protein modeling. Consistent with these findings, we found that the Q311P mutation has reduced transactivation of a promoter with a tetramer of CEBP sites, consistent with a loss-of-function mutation. In addition, there was decreased colony survival in fibroblasts with CEBPA Q311P, associated with the clinical radiosensitivity postulated in one carrier. From 45 years of follow-up, we observed incomplete penetrance (46%) of CEBPA Q311P; we did not observe other cancers or leukemias segregating with the mutation. Thus, we present a comprehensive clinical and molecular characterization of a novel AML-associated variant in CEBPA in a NCI family with nearly half a century of follow-up. This study reveals that a germline mutation in the C-terminal bZip domain can alter the ability of CEBPA to bind DNA and reduces transactivation, leading to AML, though with lower penetrance than the canonical N-terminal frameshift germline mutations. Citation Format: Anand Pathak, Katja Seipel, Alexander Pemov, Ramita Dewan, Christina Brown, Sarangan Ravichandran, Brian T. Luke, Meredith Yeager, Richard A. Gatti, Neil Caporaso, John J. Mulvihill, Lynn Goldin, Thomas Muller Pabst, Mary Lou McMaster, Douglas R. Stewart. Whole-exome sequencing reveals a novel germline variant in CEBPA-associated familial acute myeloid leukemia: 45-year follow-up of a large family. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2756. doi:10.1158/1538-7445.AM2015-2756