Abstract: Background: Acquired aplastic anemia (AA), the prototypical bone marrow failure syndrome, is inferred to result from immune-mediated destruction of hematopoietic progenitors, as most patients respond to immunosuppressive therapies. Clonal hematopoiesis in AA is evident in the presence of paroxysmal nocturnal hemoglobinuria (PNH) cells in as many as half of patients and by identification of uniparental disomies involving 6p (6pUPD) chromosome in 13% of cases. In addition, "clonal transformation", as defined by the development of myelodysplastic syndromes (MDS) or acute myelogenous leukemia (AML) is a serious long-term complication in 10-15% AA patients. Methods: We performed targeted deep sequencing and SNP array-based copy number (CN) analysis of peripheral blood- or granulocyte-derived DNA from 439 patients with AA (280 from US and 159 from Japanese cohorts) for a panel of 103 candidate genes, chosen because they are known to be frequently mutated in myeloid neoplasms. Germline DNA was available for 288 out of 439 patients and was used to confirm the somatic origin of mutations. Whole exome sequencing (WES) was performed in 52 cases. Where serial samples were available, the chronology of detected mutations was also investigated. Results: Targeted deep sequencing provided highly concordant results between the US and Japanese cohorts; approximately one third of AA patients had mutations in genes commonly affected in myeloid neoplasms, and about one third of patients in whom mutations were identified had multiple mutations. Multi-lineage involvement of mutations was confirmed in 6 cases using flow-sorted bone marrow samples. However, compared to myeloid neoplasms, mutations in AA were at much lower variant allele frequencies (VAFs) ( 〈 10% on average) and most frequently involved 5 genes: PIGA, BCOR/BCORL1, DNMT3A and ASXL1 (Fig.1). Although CN abnormalities were rare, about 13% of AA patients in both cohorts showed 6pUPD. Combined, clonal hematopoiesis was detected in as many as 46.5% and 47.8% of US and Japanese patients, respectively. We focused efforts on the large NIH cohort, due to accessible serial samples and well characterized clinical phenotypes at many time points. For 46 cases for which diagnostic samples were available, mutations were detected from at the time of diagnosis but at very low VAFs. The size of DNMT3A or ASXL1 mutated clones tended to increase over time, regardless of the emergence of chromosomal anomalies or blasts, whereas that of BCOR or PIGA mutated clones was more likely to decrease or remain stable. In both patient cohorts, presence of an acquired mutation was associated with older age, but did not correlate with response to immunosuppressive therapy (IST) or overall survival (OS). Mutations in PIGA and BCOR/BCORL1 were more common in AA than in MDS/AML and when combined, were associated with favorable OS (favorable mutations) (P = 0.044). Conversely, 17 high-risk mutations were extracted to predict poor OS (Fig. 2), which combined with favorable mutations, could be used to stratify AA patients with regard to OS (P = 0.0025). WES allowed capture of more mutations and better characterization of clonal hematopoiesis: more than 60% of AA patients had somatic mutations by combined targeted and whole exome sequencing. In 36 cases, WES was performed for all available serial samples, which enabled comprehensive monitoring of the dynamic chronological behavior of hematopoietic clones for as long as a decade after diagnosis. In many cases, clonal hematopoiesis developed gradually and was unrelated to the severity of cytopenias or to clinical evolution to abnormal cytogenetics, marrow dysplasia, and leukemia. Acquisition of new mutations within founder clones and subsequent selection shaped highly complex clonal structures in some cases (Fig. 3). The emergence of clonal hematopoiesis predated the development of MDS or leukemic transformation, with clones often detectable at time of diagnosis. Conclusions: Clonal hematopoiesis in AA was prevalent, associated in about half of cases with mutations in genes recurrently mutated in myeloid neoplasms. The highly biased set of mutated genes associated with clonal hematopoiesis in AA is evidence for Darwinian selection of particular cell clones under in the bone marrow failure environment. Mutations could be used to better predict prognosis of AA patients. Figure 1 Figure 1. Figure 2 Figure 2. Figure 3 Figure 3. Disclosures No relevant conflicts of interest to declare.

Abstract: MDS and related disorders, including MDS/MPN and sAML that evolved from these conditions constitute disease continuum characterized by a wide spectrum of molecular lesions which often overlap. Here, we defined general mutational spectrum and clonal architecture in a large cohort (n=718) of MDS studied by whole exome sequencing (WES) and target deep sequencing. Within this cohort 97 cases were studied at multiple time points to clarify the clinical impact of clonal dynamics on phenotype commitment or outcomes. All samples were obtained after informed consent, according to protocols approved by the respective ethics boards of the participating institutions. When mean and maximum variant allele frequency (VAF) for whole mutations were at one time-point evaluated in disease phenotypes, significantly higher averaged values suggested their larger clones in sAML and CMML compared to MDS. Clustering analysis of multiple mutational events by Pyclone software discriminated the cases with multiple mutational clones (positive heterogeneity) and those with a single expansion of MDS clone (no heterogeneity detected). Over 80% of low-risk MDS and all the sAML harbored multiple clusters of mutations. These results suggest that intra-tumor heterogeneity of MDS is most likely due to various sizes of clonal and subclonal mutations, likely impacting clinical behavior. To delineate clonal dynamics in MDS, we assessed mutational burden and their temporal changes in serially collected samples (n=97). Among these, Pyclone analysis was applied to exome sequencing at two time points (n=11 pairs). All cases showed various mutational clusters with individual expansions and declines, including initially present, newly acquired or disappearing during clinical course. Initial subclones were identified at disease presentation in 55% of cases, of which in 86% the subclones expanded to occupy whole MDS population with clonal sweep. New subclones acquired during clinical course were identified in 91%, in which 60% cases harbored clonal sweep. Disappearing clones were observed in 55% of cases. Next, we applied clustering analysis on clonal size of driver mutations evaluated at multiple time points (n=97 cases) to categorize the most frequently mutated genes into 3 subtypes. Mutational burden of PTPN11 most frequently increased and were associated with leukemic evolution (an example of type I gene). Similarly, CBL, NRAS, STAG2, RUNX1, and IDH1 were categorized into the type I genes, demonstrating increased clonal size resulting in the evolutions into high-risk phenotypes. Although JAK2 mutations were related to the stable clinical course when the mutational burden decreased, cases with highly expanded JAK2 mutations resulted in leukemic evolution (occasional evolution or expansions; type II gene). DNMT3A, SRSF2, TP53, U2AF1, and ASXL1 mutations were also categorized into such type II consequences with occasional progression. The last category (type III) included clonal/founder genes EZH2, TET2, SF3B1 and PRPF8, demonstrating random shifts of clonal size and lack of association with leukemic evolution. The proposed hierarchical categorization correlates with clinical parameters. Cases with the increasing burden of type I gene mutations showed most significant increases in myeloblasts. Overall survival measured from second sampling time points in the cases with increasing type I mutations was significantly shorter in the whole cohort (HR=2.05, 95%CI; 1.14-3.79, P=0.016) and in the cases solely with IPSS INT-1 (HR=2.37, 95%CI; 1.01-5.97, P=0.048). Subcohorts classified according to the presence or absence of increasing type I mutations did not differ with regard to the IPSS categories. In contrast, increased mutational burden of type II and III genes did not correlated with any of the clinical parameters examined, even though some gene mutations including TP53, EZH2, and U2AF1 represented poor prognostic factors at disease presentation. In conclusion, this work demonstrates that detailed understanding of clonal dynamics allows for new insights into clinical significance of somatic mutations, made possible only by serial sample sequencing at multiple time points. Increasing clonal burden of extracted genes associated with predictive prognostic impact should be prospectively validated in more uniform and larger cohort of MDS. Disclosures Sekeres: TetraLogic: Membership on an entity's Board of Directors or advisory committees; Celgene Corporation: Membership on an entity's Board of Directors or advisory committees; Amgen: Membership on an entity's Board of Directors or advisory committees. Shih:Novartis: Research Funding.

Abstract: Myelodysplastic syndromes (MDS) are a heterogeneous group of chronic myeloid neoplasms, in which disease progression is quite common, eventually terminating in secondary acute myeloid leukemia (sAML). To elucidate differential roles of mutations in MDS progression and sAML evolution, we investigated clonal dynamics of somatic mutations using targeted sequencing of 699 MDS patients, of which 122 were analyzed for longitudinally collected samples. Combining publicly available data, mutational data in a total of 2,250 MDS cases were assessed for their enrichment in specific disease subtypes. All samples were obtained after informed consent. Genotyping data from samples with low- (n=1,207) and high-risk (n=683) MDS as well as sAML (n=360) were available for most prevalently mutated 25 driver genes. In univariate comparison between low- and high-risk MDS, the majority of differentially mutated genes were enriched in high-risk MDS, except for SF3B1, which was more frequently mutated in low-risk MDS. Multivariate analysis was performed using a least absolute shrinkage and selection operator model. As a result, mutations in 7 genes (FLT3, PTPN11, WT1, IDH1, NPM1, IDH2,and NRAS) designated as 'Type-1' mutations, were significantly enriched in sAML compared to high-risk MDS. When comparison was made between high- and low-risk MDS, mutations in 10 genes, including GATA2, NRAS, KRAS, IDH2, TP53, RUNX1, STAG2, ASXL1, ZRSR2, and TET2, were enriched in high-risk MDS. The latter mutations are designated as 'Type-2' mutations, excluding NRAS and IDH2 mutations, which were already assigned to the Type-1 category. To characterize the chronological behavior of Type-1 and Type-2 mutations, we performed longitudinal analyses of 122 cases, of which 90 progressed to sAML. Overall, driver mutations tended to increase their clone sizes between two time points. In accordance with their significant enrichment in sAML, Type-1 mutations were more likely to be newly acquired at the second time points, compared to Type-2 and other mutations (P=0.0001). By contrast, in patients with high-risk MDS at the second time point, Type-2 mutations were more dominant than Type-1 mutations, and most of the Type-2 mutations (88%) increased their clone sizes at the second sampling. Similarly, Type-2 mutations found in high-risk MDS or sAML evolving from low-risk MDS increased their clone sizes more frequently (30 out of 38 mutations (79%)) than Type-2 mutations in stable low-risk MDS without disease progression over time (4 out of 11 (36%)) (P=0.02). These findings suggest that Type-1 and Type-2 mutations might be associated with progression from high-risk MDS to sAML and low- to high-risk MDS, respectively. To further clarify the effects of the different classes of mutations on progression to sAML, 429 patients with MDS were analyzed for progression free survival (or PFS). Patients with Type-1 mutations (Group-I) had a significantly shorter PFS, compared to those who had Type-2 mutations but lacked Type-1 mutations (Group-II) (HR=1.82, 95% CI:1.08−3.05; P=0.025). Nevertheless, PFS in Group-II cases was still significantly shorter than that in other cases (HR=2.46, 95% CI:1.43−4.23; P=0.001). Of note, some Group-II cases subsequently acquired Type-I mutations during progression to sAML. By contrast, SF3B1-mutated patients tended to show slower progression to sAML, unless they carried either of Type-1 or 2 mutations (Group-III). Finally, the effects of these mutations on overall survival (OS) were assessed in a larger cohort of patients with MDS (n=1,347). Group-I cases were shown to have a significantly shorter OS than Group-II cases (HR=1.50, 95% CI:1.20−1.86; P 〈 0.001). Other independent prognostic factors included the International Prognostic Scoring System (IPSS) score and the mutational category (i.e., Group-I, -II, and -III) for PFS, while the presence of complex karyotypes, together with IPSS score, Group-I, -7/del(7q), age, and del(20q) were among the negative predictors of OS. In conclusion, our study has elucidated clonal dynamics associated with MDS progression and sAML evolution. Close monitoring of these sets of distinct mutations in the prospective fashion may help in the prediction of the clinical outcome in MDS. Disclosures Makishima: The Yasuda Medical Foundation: Research Funding. Sekeres:Millenium/Takeda: Membership on an entity's Board of Directors or advisory committees; Celgene: Membership on an entity's Board of Directors or advisory committees. Meggendorfer:MLL Munich Leukemia Laboratory: Employment. Haferlach:MLL Munich Leukemia Laboratory: Employment, Equity Ownership. Kern:MLL Munich Leukemia Laboratory: Employment, Equity Ownership. Ogawa:Kan research institute: Consultancy, Research Funding; Takeda Pharmaceuticals: Consultancy, Research Funding; Sumitomo Dainippon Pharma: Research Funding.

Abstract: Background: Studies on germline variants responsible for cancer predisposition provide an important clue to the understanding of genetic basis of cancer and also help better prediction and management of relevant cancers. As for myeloid neoplasms, only a handful of genes, including RUNX1, CEBPA, GATA2, ETV6, and ANKRD26, have been implicated in early onset familial acute myeloid leukemia (AML) and myelodysplastic syndromes (MDS), although they are rarely seen in sporadic cases. Recently, using whole exome sequencing of familial AML/MDS, we have reported novel AML/MDS predisposing gene, DDX41, an encoding dead-box helicase gene. Conspicuously, the onset of AML/MDS was over 60 in most of the affected cases, raising a possibility that the genetic predisposition might be obscured and many cases could be diagnosed with sporadic AML/MDS. In this study, we investigated germline DDX41 mutations in sporadic cases with AML/MDS and the incidence and mutation types were compared between Asian and Western patients. Patients and Methods: We performed targeted sequencing of DDX41 in patients from Asian (N = 239) cohort of AML/MDS, where the origin of the detected variations was determined by using matched germline DNA. The result was compared to those obtained from the Western cohort (N = 1,034) in terms of frequency and type of mutation. The effect size of the mutations was estimated by calculating odds ratios of each variant for AML/MDS development using the data for DDX41 variants in Asian and Western population from the ExAC (Exome Aggregation Consortium) database (http://exac.broadinstitute.org) as controls. Results: Germline and somatic DDX41 mutations were found in 12 (5.0%) and 10 (4.7%) of sporadic cases with AML/MDS from the Asian cohort, as compared to 8 (0.8%) and 10 (1.0%) from the Western cohort. All the patients with germline variants were aged over 40 year-old with a median of 68.5, confirming the late onset of the disease also in the sporadic cases with germline variants. Eight of the 12 germline variants (67%) in the Asian cohort were accompanied by an additional somatic mutation, as compared to 2 of the 8 (25%) in the Western cohort. Biallelic involvement was demonstrated in selected cases (N = 2). In total, 8 and 3 germline variants were observed in the Asian and the Western cohorts, respectively, without no common variants between both cohorts, of which the predominant variants included p.A500fs (n=5; 42%) and p.E7X (n=2; 17%) in the Asian cohort and p.F140fs (n=6; 75%) in Western cohort. In contrast, a prominent hotspot mutation involving a highly conserved amino-acid within the helicase domain (p.R525H) was commonly observed in both cohorts, accounting for 55% of all the somatic mutations. These germline variants as a whole showed significant enrichment in AML/MDS cases compared to the respective control population (OR 〉 171, 95% confidence interval (CI): 51-730 for the Asian variants and more than 21.7, 95%CI: 8.4-50 for the Western variants), although the enrichment of individual variants showed substantial variations, suggesting different effect size among these variants: the odds ratio was 19.5 (p 〈 0.001) for p.F140fs, and 92.4 (p 〈 0.001) for p.A500fs. p.E7X was detected in 2 out of 239 cases with MDS/AML, whereas not in the control Asian population. Conclusion: We demonstrated frequent germline variants of DDX41 among sporadic cases with AML/MDS from different ethnic populations. Having common ancestral origins in different ethnic populations, these alleles are found in the general population at very low frequencies ( 〈 1 in 4000), accounting for the largest congenital risk for the development of sporadic AML/MDS therein (3-5% of all sporadic AML/MDS). The onset was typically over 40 years of age and frequently accompanied by an additional somatic mutation most likely in the unaffected allele, showing a prominent hotspot at p.R525. The germline variants seem to be dominant and caused premature truncation of the protein, leading to loss-of-function in most cases, whereas somatic mutations were typically missense variants not totally abrogating protein function, suggesting the importance of less than haploinsufficiency but more than null function for leukemogenesis. At the meeting, an extended result from more than 1000 Asian cases will be presented. Disclosures Kiyoi: Kyowa-Hakko Kirin Co., Ltd.: Consultancy, Research Funding; Pfizer Inc.: Research Funding; Novartis Pharma K.k.: Research Funding; Mochida Pharmaceutical Co., Ltd.: Research Funding; Taisho Toyama Pharmaceutical Co., Ltd.: Research Funding; Eisai Co., Ltd.: Research Funding; Zenyaku Kogyo Company, Ltd.: Research Funding; FUJIFILM RI Pharma Co.,Ltd.: Patents & Royalties, Research Funding; Chugai Pharmaceutical Co., LTD.: Research Funding; Fujifilm Corporation.: Patents & Royalties, Research Funding; Nippon Boehringer Ingelheim Co., Ltd.: Research Funding; Bristol-Myers Squibb.: Research Funding; Alexion Pharmaceuticals.: Research Funding; Sumitomo Dainippon Pharma Co., Ltd.: Research Funding; Takeda Pharmaceutical Co., Ltd.: Research Funding; Yakult Honsha Co., Ltd.: Research Funding; Astellas Pharma Inc.: Consultancy, Research Funding; Teijin Ltd.: Research Funding; Japan Blood Products Organization.: Research Funding; Nippon Shinyaku Co.,Ltd.: Research Funding; MSD K.K.: Research Funding. Miyazaki:Shin-bio: Honoraria; Sumitomo Dainippon: Honoraria; Chugai: Honoraria, Research Funding; Celgene Japan: Honoraria; Kyowa-Kirin: Honoraria, Research Funding. Naoe:Kyowa Hakko Kirin Co., Ltd.: Patents & Royalties, Research Funding; Celgene K.K.: Research Funding; FUJIFILM Corporation: Patents & Royalties, Research Funding; Astellas Pharma Inc.: Research Funding; Toyama Chemical CO., LTD.: Research Funding; Nippon Boehringer Ingelheim Co., Ltd.: Research Funding; Otsuka Pharmaceutical Co., Ltd.: Research Funding; Pfizer Inc.: Research Funding; Chugai Pharmaceutical Co., Ltd.: Patents & Royalties. Usuki:Boehringer Ingelheim: Other: personal fees, Research Funding; Shionogi: Other: personal fees; Fujimoto Pharmaceutical: Research Funding; Takeda Pharmaceutical: Research Funding; SymBio Pharmaceutical: Other: personal fees, Research Funding; Eisai: Research Funding; Otsuka Pharmaceutical: Research Funding; Kyowa Hakko Kirin: Other: personal fees, Research Funding; Shire: Research Funding; Nippon Shinyaku: Other: personal fees, Research Funding; Novartis: Other: personal fees, Research Funding; Sanofi: Other: personal fees, Research Funding; MSD: Other: personal fees, Research Funding; Celgene: Other: personal fees, Research Funding; Sumitomo Dainippon Pharma: Other: personal fees, Research Funding; Taiho Pharmaceutical: Other: personal fees, Research Funding; Fuji Film RI Pharma: Other: personal fees; Chugai Pharmaceutical: Other: personal fees; GlaxoSmithKline: Other: personal fees, Research Funding; Bristol-Myers Squibb: Other; Astellas: Research Funding. Miyawaki:Astellas Pharma Inc.: Consultancy, Other: personal fees; Ohtsuka Pharma Co, LTD.: Other: Safety Data Committee.

Abstract: Myelodysplastic syndromes (MDS) and related disorders are a heterogeneous group of chronic myeloid neoplasms with a high propensity to acute myeloid leukemia. A cardinal feature of MDS, as revealed by the recent genetic studies, is a high frequency of mutations and copy number variations (CNVs) affecting epigenetic regulators, such as TET2, IDH1/2, DNMT3A, ASXL1, EZH2, and other genes, underscoring a major role of deregulated epigenetic regulation in MDS pathogenesis. Meanwhile, these mutations/deletions have different impacts on the phenotype and the clinical outcome of MDS, suggesting that it should be important to understand the underlying mechanism for abnormal epigenetic regulation for better classification and management of MDS. SETD2 and ASH1L are structurally related proteins that belong to the histone methyltransferase family of proteins commonly engaged in methylation of histone H3K36. Both genes have been reported to undergo frequent somatic mutations and copy number alterations, and also show abnormal gene expression in a variety of non-hematological cancers. Moreover, germline mutation of SETD2 has been implicated in overgrowth syndromes susceptible to various cancers. However, the role of alterations in these genes has not been examined in hematological malignancies including myelodysplasia. In this study, we interrogated somatic mutations and copy number variations, among a total of 1116 cases with MDS and myelodysplastic/myeloproliferative neoplasms (MDS/MPN), who had been analyzed by target deep sequencing (n=944), and single nucleotide polymorphism-array karyotyping (SNP-A) (n=222). Gene expression was analyzed in MDS cases and healthy controls, using publically available gene expression datasets. SETD2 mutations were found in 6 cases, including 2 with nonsense and 4 with missense mutations, and an additional 10 cases had gene deletions spanning 1.8-176 Mb regions commonly affecting the SETD2 locus in chromosome 3p21.31, where SETD2 represented the most frequently deleted gene within the commonly deleted region. SETD2 deletion significantly correlated with reduced SETD2 expression. Moreover, MDS cases showed a significantly higher SETD2 expression than healthy controls. In total, 16 cases had either mutations or deletions of the SETD2 gene, of which 70% (7 out of 10 cases with detailed diagnostic information) were RAEB-1/2 cases. SETD2 -mutated/deleted cases had frequent mutations in TP53 (n=4), SRSF2 (n=3), and ASXL1 (n=3) and showed a significantly poor prognosis compared to those without mutations/deletions (HR=3.82, 95%CI; 1.42-10.32, P=0.004). ASH1L, on the other hand, was mutated and amplified in 7 and 13 cases, respectively, of which a single case carried both mutation and amplification with the mutated allele being selectively amplified. All the mutations were missense variants, of which 3 were clustered between S1201 and S1209. MDS cases showed significantly higher expression of ASH1L compared to healthy controls, suggesting the role of ASH1L overexpression in MDS development. Frequent mutations in TET2 (n=8) and SF3B1 (n=6) were noted among the 19 cases with ASH1L lesions. RAEB-1/2 cases were less frequent (n=11) compared to SETD2-mutated/deleted cases. ASH1L mutations did not significantly affect overall survival compared to ASH1L-intact cases. Gene Set Expression Analysis (Broad Institute) on suppressed SETD2 and accelerated ASH1L demonstrated 2 distinct expression signatures most likely due to the differentially methylated H3K36. We described recurrent mutations and CNVs affecting two histone methyltransferase genes, which are thought to represent novel driver genes in MDS involved in epigenetic regulations. Given that SETD2 overexpression and reduced ASH1L expression are found in as many as 89% of MDS cases, deregulation of both genes might play a more role than expected from the incidence of mutations and CNVs alone. Although commonly involved in histone H3K36 methylation, both methyltransferases have distinct impacts on the pathogenesis and clinical outcome of MDS in terms of the mode of genetic alterations and their functional consequences: SETD2 was frequently affected by truncating mutations and gene deletions, whereas ASH1L underwent gene amplification without no truncating mutations, suggesting different gene targets for both methyltransferases, which should be further clarified through functional studies. Disclosures Alpermann: MLL Munich Leukemia Laboratory: Employment. Nadarajah:MLL Munich Leukemia Laboratory: Employment. Haferlach:MLL Munich Leukemia Laboratory: Employment, Equity Ownership. Kern:MLL Munich Leukemia Laboratory: Employment, Equity Ownership. Shih:Novartis: Research Funding.

Abstract: Renal cell carcinoma (RCC) is the most common form of adult kidney cancer and accounts for 2-3% of all adult malignancies, in which clear cell carcinoma accounts for more than 80% of the cases. As for the pathogenesis of clear cell RCC, inactivation of the VHL gene has been reported in 80% of clear cell RCC and more recently, frequent mutations of epigenetic regulators, including PBRM1, SETD2, KDM5C and UTX, have been demonstrated through high-throughput mutation studies, including PBRM1 has been demonstrated in ∼40% of the cases. Nevertheless, probably, our knowledge of the full spectrum of gene mutations in RCC is still incomplete. In this study, to obtain a better understanding of molecular pathogenesis of clear cell RCC, we performed an integrated genetic study of clear cell RCC, where a total of 93 paired specimens were analyzed by massively parallel sequencing of SureSelect (Agilent)-enriched whole exomes, SNP array-based copy number analysis (Affymetrix), as well as gene expression profiling (Agilent). In whole exome sequencing, 42 somatic mutations per sample were identified on average, which involved not only previously reported genes, but also a number of novel gene targets. Among these, mutations of genes involved in chromatin regulation or histone modification were preferentially found in advanced cases. To understand whole picture of gene mutations of epigenetic mechanism in clear cell RCC, mutation analysis of 85 genes involved in chromatin regulation or histone modification were performed in 180 cases using multiplexed barcode sequencing. A total of 201 somatic mutations were validated and 74% cases had at least one somatic mutation. PBRM1 mutations were found in 43% cases and SETD2 were mutated in 10% of cases. When comparing clinical picture with mutation status, SETD2 mutation was associated with the risk of metastasis, while PBRM1 mutations had no impact on prognosis. Our results showed that in clear cell RCC, multiple component of complexes involved in epigenetic regulation undergo gene mutations, confirming that deregulated epigenetic apparatus play important roles in pathogenesis of clear cell RCC. In this meeting, we will present the result of our integrated genetic analysis of RCC and discuss the genetic basis of RCC in terms of copy number alterations, gene mutations, as well as gene expression profiles. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 2092. doi:1538-7445.AM2012-2092

Abstract: Pediatric acute myeloid leukemia (AML) comprises ∼20% of pediatric leukemia, representing one of the major therapeutic challenges in pediatric oncology. Nearly 40% of patients still relapse after present first-line therapies and once the relapse occurs, the long-term survival rates decrease, ranging from 21% to 34%. As for the pathogenesis of AML relapse, the recent development of massively parallel sequencing technologies has provided a new opportunity to investigate comprehensive genetic alterations that are involved in tumor recurrence of adult AML. However, little is known about the molecular details of relapsed pediatric AML. Methods In order to reveal the clonal origin and the major mutational events in relapsed pediatric AML, we performed whole exome sequencing of 4 trio samples from diagnostic, relapsed and complete remission phases using Illumina HiSeq 2000. Copy number abnormalities were also detected using whole exome sequencing. Subsequently, deep sequencing of identified mutations was performed to evaluate intra-tumor heterogeneity and the clonolocal history of relapsed clones. Results Whole-exome sequencing of 12 samples from 4 patients were analyzed with a mean coverage of more than x100, and 95 % of the targeted sequences were analyzed at more than x20 depth on average. A total of 98 somatic mutations were identified, where mean number of non-silent mutations was higher at relapsed phase than at the time of diagnosis (14.0/case vs 10.5/case) (p=0.270). Assessment of clonality using variant allele frequencies of individual mutations suggested that some mutations were subclonal mutations, consisting of intra-tumor heterogeneity both at the time of diagnosis and at relapse. In all 4 patients, relapsed AML evolved from one of the subclones at the initial phase, which was accompanied by many additional mutations including common driver mutations that were absent or existed only with lower allele frequency in the diagnostic samples, indicating a multistep process of leukemia recurrence. Forty-six out of the 98 mutations were specific either at the time of diagnosis (n = 16) or at relapse (n = 30). Relapse-specific mutations and copy number changes were found in several genes including known drivers such as NRAS and CREBBP. These mutations were further investigated in an extended cohort of relapsed pediatric AML samples using targeted sequencing to evaluate their prevalence. In some cases, AML relapse may accompany a dynamic clonal change. For example, some bona fide driver mutations, such as KRAS mutations, that were predominant at the time of diagnosis disappeared in relapsed samples. Discussion Whole exome sequencing unmasked clonal structure of primary and relapsed pediatric AML, which helped to understand the underlying mechanism of relapse in pediatric AML. Our results suggested that pediatric AML has intra-tumor heterogeneity and subclonal mutations such as NRAS and CREBBP occurring in one of the subclones could drive the AML relapse. Disclosures: No relevant conflicts of interest to declare.