Abstract: Isolated chronic idiopathic neutropenia (CIN) is a rare disease with multiple contributing etiologies that must be ruled out before establishing a diagnosis. We studied clinical and molecular data of 238 consecutive adult patients with CIN. Autoimmune neutropenia was present in 28% of our cohort. In contrast, T cell-mediated neutropenia was the main underlying pathological mechanism among patients with T cell expansions, such as T-cell large granular lymphocytic leukemia (T-LGL) and T cell clonopathy of undetermined significance, found in 37% and 8% of cases, respectively. Patients with neutropenia also had hypogammaglobulinemia (6%) and/or monoclonal gammopathy of undetermined significance (5%). NGS application has further broadened the spectrum of causes of CIN by including manifestations of clonal hematopoiesis, present in 12% of cases. TET2 (3%), TP53 (2%), and IDH1/IDH2 (2%) mutations were the most commonly found and were enriched in cases with T-LGL. We show that these clinico-molecular associations can be simultaneously present, complicating a proper diagnostic distinction within the broader entity of seemingly idiopathic neutropenia of autoimmune origin. Identification of etiologic culprits may also guide rational selection of therapies.

Abstract: Complete or partial deletions of chromosome 7 (-7/del7q) belong to the most frequent chromosomal abnormalities in myeloid neoplasm (MN) and are associated with a poor prognosis. The disease biology of -7/del7q and the genes responsible for the leukemogenic properties have not been completely elucidated. Chromosomal deletions may create clonal vulnerabilities due to haploinsufficient (HI) genes contained in the deleted regions. Therefore, HI genes are potential targets of synthetic lethal strategies. Through the most comprehensive multimodal analysis of more than 600 -7/del7q MN samples, we elucidated the disease biology and qualified a list of most consistently deleted and HI genes. Among them, 27 potentially synthetic lethal target genes were identified with the following properties: (i) unaffected genes by hemizygous/homozygous LOF mutations; (ii) prenatal lethality in knockout mice; and (iii) vulnerability of leukemia cells by CRISPR and shRNA knockout screens. In -7/del7q cells, we also identified 26 up or down-regulated genes mapping on other chromosomes as downstream pathways or compensation mechanisms. Our findings shed light on the pathogenesis of -7/del7q MNs, while 27 potential synthetic lethal target genes and 26 differential expressed genes allow for a therapeutic window of -7/del7q.

Abstract: Next-generation Sequencing (NGS) of cancer tissues is increasingly being carried out to identify somatic genomic alterations that may guide physicians to make therapeutic decisions. However, a single tissue biopsy may not reflect complete genomic architecture due to the heterogeneous nature of tumors. Circulating tumor DNA (ctDNA) analysis is a robust noninvasive method to detect and monitor genomic alterations in blood in real time. We analyzed 28 matched tissue NGS and ctDNA from gastrointestinal and lung cancers for concordance of somatic genomic alterations, driver, and actionable alterations. Six patients (21%) had at least one concordant mutation between tissue and ctDNA sequencing. At the gene level, among all the mutations (n = 104) detected by tissue and blood sequencing, 7.7% (n = 8) of mutations were concordant. Tissue and ctDNA sequencing identified driver mutations in 60% and 64% of the tested samples, respectively. We found high discordance between tissue and ctDNA testing, especially with respect to the driver and actionable alterations. Both tissue and ctDNA NGS detected actionable alterations in 25% of patients. When somatic alterations identified by each test were combined, the total number of patients with actionable mutations increased to 32%. Our data show significant discordance between tissue NGS and ctDNA analysis. These results suggest tissue NGS and ctDNA NGS are complementary approaches rather than exclusive of each other. When performed in isolation, tissue and ctDNA NGS can each potentially miss driver and targetable alterations, suggesting that both approaches should be incorporated to enhance mutation detection rates. Larger prospective studies are needed to better clarify this emerging precision oncology landscape. Mol Cancer Ther; 17(5); 1123–32. ©2018 AACR.

Abstract: Structural and functional variability of human leukocyte antigen (HLA) is the foundation for competent anti-tumor and infectious adaptive immune responses. HLA genomic heterogeneity enables the presentation of a broad immune-peptidome, sustaining an efficient diversification of T cell receptor repertoires (TCR). 1,2,3 Any perturbation impacting this diversity may be at the basis of pathological processes, hampering antigen presentation capabilities and T-cell reactivity. In allogeneic hematopoietic cell transplantation (allo-HCT) setting, the graft versus leukemia (GvL) effect should ensure disease control allowing the recognition of recipient neoantigen burden by donor T-cell effectors. However, the molecular dissection of graft versus host responses (GvH) remains elusive. Herein, by means of a broad immunogenetic study of a cohort of patients with myeloid malignancies who received a donor matched allo-HCT, we investigated how dysfunction of HLA variability could have an impact on alloreactive responses, ultimately hindering disease control. To that end, we combined NGS-based HLA genotyping and TCR-beta sequencing to molecularly characterize the HLA region in terms of locus-specific divergence and somatic mutational profile, and dissect features and clonotypic spectra of TCR repertoires. We first hypothesized that more diverse HLA genotypes could better present leukemic neoantigen burden than less diverse complexes, enhancing the GvL effect. Hence, we performed a matched-pair analysis between allo-HCT recipients relapsing after 3mo (median 6.2 mo. [IQR=4.6-12]), N=75) compared to patients without recurrence (N=193, matched for ethnicity, age, disease, graft source and conditioning regimens) and characterized the patterns of HLA evolutionary divergence (HED), 1 a metric recently conceived to quantitate the pair-wise distance (based on physiochemical composition) between the amino acids located within the peptide-binding groove of two homologous HLA alleles. Overall, the relapsed group was characterized by a lower global (class I/II) mean HED (p=.0029) compared to non-relapsed patients, with major differences seen for C (p=.0041), DQB1 (p=.0291), and DPB1 (p=.0396) loci. When studying the landscape of post-transplant TCR reconstitution (+3 months) in a subset of 25 patients, we observed an inverse correlation between TCR clonal expansion and global HED (AdjR 2=0.04, p= & lt;2e-16), contributing to decrease the diversity of TCR repertoires in patients with lower HED. Although not different in number, the expansion of clonotypes with known anti-cancer specificity was higher in non-relapsing group (p=6.3e-08), possibly underlying a better tumor-surveillance. Next, we sought to investigate the patterns of somatic HLA dysfunction in relapsing patients (intended as allelic loss or mutations). Indeed, through a recently implemented HLA mutational calling algorithm, we observed somatic events encompassing both class I and II alleles in 23% (N=8/34 profiled patients). Interestingly, when analyzing patients with relapse who received a donor lymphocyte infusion-based treatment (DLI), none of the cases harboring mutational events (N=4/4) responded to this salvage strategy. It is noteworthy that in this last group, one patient relapsed with an extramedullary localization along with the acquisition of HLA mutations. HLA mutated group had a higher (although not significant) leukemia mutational burden compared to non-mutated group (mean number of leukemia-associated mutations: 3.6 vs 1.9/patient), underscoring the need for further driver mutational events compensating the possible lower immunogenic potential of HLA mutant clones. Despite a mild increase in mutational burden, driver hits (such as IDH1/2, FLT3, TP53, NPM1) were never present in patients carrying HLA aberrations, who instead harbored in a few cases mainly lesions in epigenetic regulators and chromatin modifiers (TET2, EP300, DNMT3A, EZH2). Altogether these findings pinpoint the role of the dysfunction of the structural variability of HLA complexes within both germline (HED) and somatic (HLA loss/mutations) scenarios as mechanisms hampering a successful neoantigen presentation and TCR recovery processes, possibly conveying a higher risk of disease relapse or treatment-resistance. Disclosures Balasubramanian: Servier Pharmaceuticals: Research Funding. Carraway: Takeda: Other: Independent review committee; AbbVie: Other: Independent review committee; Stemline: Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; Novartis: Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; Jazz: Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; Agios: Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; Celgene, a Bristol Myers Squibb company: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding, Speakers Bureau; Bristol Myers Squibb: Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; Astex: Other: Independent review committee. Hamilton: Syndax: Membership on an entity's Board of Directors or advisory committees; Equilium: Membership on an entity's Board of Directors or advisory committees. Majhail: Anthem, Inc: Consultancy; Incyte Corporation: Consultancy. Maciejewski: Bristol Myers Squibb/Celgene: Consultancy; Regeneron: Consultancy; Alexion: Consultancy; Novartis: Consultancy.