Burkitt lymphoma is characterized by deregulation of MYC, but the contribution of other genetic mutations to the disease is largely unknown. Here, we describe the first completely sequenced genome from a Burkitt lymphoma tumor and germline DNA from the same affected individual. We further sequenced the exomes of 59 Burkitt lymphoma tumors and compared them to sequenced exomes from 94 diffuse large B-cell lymphoma (DLBCL) tumors. We identified 70 genes that were recurrently mutated in Burkitt lymphomas, including ID3, GNA13, RET, PIK3R1 and the SWI/SNF genes ARID1A and SMARCA4. Our data implicate a number of genes in cancer for the first time, including CCT6B, SALL3, FTCD and PC. ID3 mutations occurred in 34% of Burkitt lymphomas and not in DLBCLs. We show experimentally that ID3 mutations promote cell cycle progression and proliferation. Our work thus elucidates commonly occurring gene-coding mutations in Burkitt lymphoma and implicates ID3 as a new tumor suppressor gene.
SUMMARY Using sequential gene expression profiling (GEP) samples, we defined a major functional group related to drug resistance that contains chromosomal instability (CIN) genes. One CIN gene in particular, NEK2, was highly correlated with drug resistance, rapid relapse, and poor outcome in multiple cancers. Over-expressing NEK2 in cancer cells resulted in enhanced CIN, cell proliferation and drug resistance, while targeting NEK2 by NEK2 shRNA overcame cancer cell drug resistance and induced apoptosis in vitro and in a xenograft myeloma mouse model. High expression of NEK2 induced drug resistance mainly through activation of the efflux pumps. Thus, NEK2 represents a strong predictor for drug resistance and poor prognosis in cancer and could be an important target for cancer therapy.
De-ubiquitinating enzymes (DUBs) can reverse the modifications catalyzed by ubiquitin ligases and as such are believed to be important regulators of a variety of cellular processes. Several members of this protein family have been associated with human cancers; however, there is little evidence for a direct link between deregulated de-ubiquitination and neoplastic transformation. Ubiquitin C-terminal hydrolase (UCH)-L1 is a DUB of unknown function that is overexpressed in several human cancers, but whether it has oncogenic properties has not been established. To address this issue, we generated mice that overexpress UCH-L1 under the control of a ubiquitous promoter. Here, we show that UCH-L1 transgenic mice are prone to malignancy, primarily lymphomas and lung tumors. Furthermore, UCH-L1 overexpression strongly accelerated lymphomagenesis in Eμ-myc transgenic mice. Aberrantly expressed UCH-L1 boosts signaling through the Akt pathway by downregulating the antagonistic phosphatase PHLPP1, an event that requires its de-ubiquitinase activity. These data provide the first in vivo evidence for DUB-driven oncogenesis and suggest that UCH-L1 hyperactivity deregulates normal Akt signaling.
Key Points We investigated all 3 subtypes of BL by WGS and transcriptome sequencing. Experimental validation through CRISPR screening and mouse models provides a better functional understanding of BL genetic drivers.
To detect targeted antileukemia agents we have designed a novel, high-content in vivo screen using genetically engineered, T-cell reporting zebrafish. We exploited the developmental similarities between normal and malignant T lymphoblasts to screen a small molecule library for activity against immature T cells with a simple visual readout in zebrafish larvae. After screening 26 400 molecules, we identified Lenaldekar (LDK), a compound that eliminates immature T cells in developing zebrafish without affecting the cell cycle in other cell types. LDK is well tolerated in vertebrates and induces longterm remission in adult zebrafish with cMYCinduced T-cell acute lymphoblastic leukemia (T-ALL). LDK causes dephosphorylation of members of the PI3 kinase/AKT/mTOR pathway and delays sensitive cells in late mitosis. Among human cancers, LDK selectively affects survival of hematopoietic malignancy lines and primary leukemias, including therapy-refractory B-ALL and chronic myelogenous leukemia samples, and inhibits growth of human T-ALL xenografts. This work demonstrates the utility of our method using zebrafish for antineoplastic candidate drug identification and suggests a new approach for targeted leukemia therapy. Although our efforts focused on leukemia therapy, this screening approach has broad implications as it can be translated to other cancer types involving malignant degeneration of developmentally arrested cells. (Blood. 2012;119(24):5621-5631) IntroductionThe yearly incidence in the US for all leukemia types, including acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), and chronic myelogenous leukemia (CML), was estimated at more than 40 000 men and women in 2010, with a yearly death rate of 50%. 1 More than 2000 cases of ALL are diagnosed in US children every year, making it the most common childhood cancer. 2 T-cell ALL (T-ALL) represents approximately 15% and 25% of pediatric and adult ALL cases, respectively. 3 Although leukemia treatment has become increasingly efficient over the past 50 years, mortality from ALL is still 20% for children and more than 40% for adults, and T-ALL has been more difficult to treat than B-cell ALL (B-ALL). 4 Currently, research efforts are devoted to molecularbased risk stratification of patients and the development of targeted therapies to limit side effects [5][6][7] and to increase treatment efficacy.Development of targeted cancer therapies typically requires knowledge of the molecular target. 8 In the absence thereof, an alternative approach may use a robust readout designed to screen large numbers of compounds for specific effects 9 against the malignant cell type in question. More than 50% of patients with T-ALL have deregulated NOTCH1, 10 and in a recent study 47% had mutations in the PI3 kinase/AKT/mTOR (P/A/mT) pathway. 11 NOTCH1 signaling requires proteolytic cleavage by ␥-secretase and other proteases 12 to release the intracytoplasmic domain, providing severalpotential targets for therapeutic intervention. Targeted treatment approaches for T-ALL using...
Background-Diffuse large B-cell lymphoma (DLBCL) makes up 10-20% of pediatric nonHodgkin lymphoma, and these patients have a significantly better prognosis than adults with DLBCL. The difference in prognosis may be related to clinical, phenotypic, and/or biological differences between adult and pediatric DLBCL. In adult DLBCL, the germinal center (GC) phenotype is associated with a better prognosis than the activated B-cell (ABC) phenotype. However, a high proliferative index and expression of Bcl2 and c-Myc protein have all been associated with worse outcomes. While multiple studies have addressed the phenotype and expression patterns of adult DLBCL, relatively little is known about these biological variables in pediatric DLBCL. The goal of this study was to investigate the proliferative index, the relative frequencies of the GC and non-GC subtypes, and the expression of Bcl2 and c-Myc protein in a cohort of children with DLBCL treated in a uniform manner.
The adult high-grade B-cell lymphomas sharing molecular features with Burkitt lymphoma (BL) are highly aggressive lymphomas with poor clinical outcome. High-resolution structural and functional genomic analysis of adult Burkitt lymphoma (BL) and high-grade B-cell lymphoma with BL gene signature (adult-molecularly defined BL [mBL]) revealed the MYC-ARF-p53 axis as the primary deregulated pathway. Adult-mBL had either unique or more frequent genomic aberrations (del13q14, del17p, gain8q24, and gain18q21) compared with pediatric-mBL, but shared commonly mutated genes. Mutations in genes promoting the tonic B-cell receptor (BCR)→PI3K pathway ( and ) did not differ by age, whereas effectors of chronic BCR→NF-κB signaling were associated with adult-mBL. A subset of adult-mBL had translocation and mutation and elevated mRNA and protein expression, but had a mutation profile similar to mBL. These double-hit lymphomas may have arisen from a tumor precursor that acquired both and translocations and/or () mutation. Gain/amplification of and its paralogue loci was observed in 50% of adult-mBL. In vitro studies suggested's role in constitutive activation of BCR signaling and sensitivity to ibrutinib. Overall integrative analysis identified an interrelated gene network affected by copy number and mutation, leading to disruption of the p53 pathway and the BCR→PI3K or NF-κB activation, which can be further exploited in vivo by small-molecule inhibitors for effective therapy in adult-mBL.
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