Project description:Upregulated heme biosynthesis, an exploitable vulnerability in MYCN-driven leukemogenesis

Project description:Acute myeloid leukemia (AML) is a clonal hematopoietic malignancy, characterized by expansion of immature leukemic blasts in the bone marrow. In AML, specific tyrosine kinases have been implicated in leukemogenesis, and are associated with poor treatment outcome. However, targeted therapy using kinase inhibitors (KIs) has had limited success, and may be improved by proper patient selection. We performed phosphotyrosine (pY) based, label-free phosphoproteomics to identify hyperphosphorylated, active kinases in two FLT3+ AML Pt samples.

Project description:All cancer cells reprogram metabolism to support aberrant growth. Here, we report that cancer cells employ and depend on imbalanced and dynamic heme metabolic pathways, to accumulate heme intermediates, i.e., porphyrins. We coined this essential metabolic rewiring ‘porphyrin overdrive’ and determined that it is cancer-essential and cancer-specific. Among the major drivers are genes encoding mid-step enzymes governing the production of heme intermediates. CRISPR/Cas9 editing to engineer leukemia cell lines with impaired heme biosynthetic steps confirmed our whole genomic data analyses that porphyrin overdrive is linked to oncogenic states and cellular differentiation. While porphyrin overdrive is absent in differentiated cells or somatic stem cells, it is present in patient-derived tumor progenitor cells, demonstrated by single cell RNAseq, and in early embryogenesis. In conclusion, we identified a dependence of cancer cells on non-homeostatic heme metabolism, and we targeted this cancer metabolic vulnerability with a novel “bait-and-kill” strategy to eradicate malignant cells.

Project description:We addressed changes in gene expression profile in response to reduced oxygen tension in wild type or heme depletion caused by deletion of heme biosynthesis gene hem1 Keywords: Response to heme depletion and hypoxia

Project description:Acute myeloid leukemia (AML) is an aggressive blood cancer that stems from the rapid expansion of immature leukemic blasts in the bone marrow. Mutations in epigenetic factors represent the largest category of genetic drivers of AML. The chromatin assembly factor CHAF1B is a master epigenetic regulator of transcription associated with self-renewal and the undifferentiated state of AML blasts. Upregulation of CHAF1B, as observed in almost all AML samples, promotes leukemic progression by repressing transcription of differentiation factors and tumor suppressors. However, the specific factors regulated by CHAF1B and their contributions to leukemogenesis are unstudied. We analyzed RNAseq from mouse MLL-AF9 leukemic cells and bone marrow aspirates representing a diverse collection of pediatric AML samples and identified the E3 ubiquitin ligase TRIM13 as a target of CHAF1B-mediated transcriptional repression associated with leukemogenesis. We found that CHAF1B binds the promoter of TRIM13, resulting in its transcriptional repression. In turn, TRIM13 suppresses self-renewal of leukemic cells by promoting pernicious entry into the cell cycle through its nuclear localization and catalytic ubiquitination of cell cycle-promoting protein CCNA1. Overexpression of TRIM13 initially prompts a proliferative burst in AML cells that is followed by exhaustion, while loss of total TRIM13 or deletion of its catalytic domain enhanced leukemogenesis in AML cell lines and patient-derived xenografts. These data suggest that CHAF1B promotes leukemic development in part by repressing TRIM13 expression, and that this relationship is necessary for leukemic progression.

Project description:Acute myeloid leukemia (AML) is a clonal hematopoietic malignancy, characterized by expansion of immature leukemic blasts in the bone marrow. In AML, specific tyrosine kinases have been implicated in leukemogenesis, and are associated with poor treatment outcome. However, targeted therapy using kinase inhibitors (KIs) has had limited success, and may be improved by proper patient selection. We performed phosphotyrosine (pY) based, label-free phosphoproteomics to identify hyperphosphorylated, active kinases in two FLT3+ AML Pt samples and this data is deposited in PXD015639 . Here are the corresponding lysate samples

Project description:Haemophilus influenzae frequently causes human disease, and humans are it’s sole niche. This bacterium has an absolute requirement for both a porphyrin and an iron source for aerobic growth, and exogenous heme can satisfy both requirements. Heme and iron can be acquired by H. influenzae from free or human protein-bound sources. The ability to selectively regulate the acquisition of heme and iron from physiological sources is a major virulence determinant for this microorganism. We utilized whole genome arrays to identify the full set of H. influenzae Rd KW20 iron and heme regulated genes. Condition specific RNA was derived from cells starved for both heme and iron and cells from the same culture 20 mins after the addition of exogenous iron and heme. The results identified 162 genes with a change in transcription ≥ 1.5 fold. Eighty genes in 42 operons were preferentially expressed under iron/ heme starvation; 82 genes in 50 operons were preferentially expressed under iron/heme replete conditions. In each case, all genes contained within the operon were co-regulated. The former group included genes encoding proteins known to have a role in iron and heme uptake as well as several hypothetical ORFs. Enzymes involved in the gluconeogenesis pathway and glycogen biosynthesis were also upregulated. The genes showing increased transcription immediately after the addition of iron and heme primarily encode proteins involved with aerobic respiration and protein biosynthesis, consistent with a relaxation of starvation. Genomic transcriptional profiling provides a more complete understanding of the effects of iron and heme availability. Keywords: Transcription analyses

Project description:Mutation or epigenetic silencing of the transcription factor C/EBP? is observed in ~10% of patients with acute myeloid leukemia (AML). In both cases, a common global gene expression profile is observed, but down-stream targets relevant for leukemogenesis are not known. Here we identify Sox4 as a direct target of C/EBP? whereby its expression is inversely correlated with C/EBP? activity. Downregulation of Sox4 abrogated increased self-renewal of leukemic cells and restored their differentiation. Gene expression profiles of leukemia initiating cells (LICs) from both Sox4 overexpression and murine mutant C/EBP? AML models clustered together, but differed from other types of AML. Our data demonstrate that Sox4 overexpression resulting from C/EBP? inactivation contributes to the development of leukemias with a distinct LIC phenotype. K/L (bi-allelic Cebpa mutations) leukemic mice and Sox4 overexprssing leukemic mice were used for RNA extraction and hybridization on Affymetrix microarrays. We compared these microarray samples with the C57/BL6 wild type mice.

Project description:Leukemogenesis is a stepwise progression from mutated, pre-neoplastic hematopoietic stem cells (HSCs) to full-blown leukemia. Our ability to prevent or treat de novo and secondary acute myeloid leukemia (AML) is limited by our incomplete understanding of the epigenetic disruption that is central to this process, including improper histone methylation. We performed a comprehensive analysis of 16 histone H3 genes in 434 primary acute myeloid leukemia (AML) samples and identified mutations in adult and pediatric cases (1.6%), with a higher incidence in secondary AML (s-AML) (9%). These included four novel amino acid substitutions (Q69H, A26P, R2Q and R8H) as well as K27M and K27I in H3.1 and H3.3 genes. These mutations are important early events in leukemogenesis as they were observed in pre-leukemic HSCs in two cases and were in the major clones in every sample. Consistent with a role in pre-leukemic HSC clonal expansion, the mutant histones increased functional human HSC frequency and altered differentiation along the erythroid and myeloid lineages, with activity dependent on the specific mutation (K27M, K27I and Q69H). In established human leukemia, the K27M/I mutant histones amplified leukemic aggressiveness, with increased proliferation, expansion of leukemic progenitor and blast cells, and superior competitiveness in vivo. This was associated with increased expression in genes involved in erythrocyte and myeloid differentiation, correlated with a corresponding decrease in histone H3 K27 tri-methylation and increase in K27 acetylation. While histone mutations can co-occur with alterations in RUNX1, we observed that the functional impact of histone mutations is independent of RUNX1 mutations. Taken together, these data establish the involvement of H3 mutations as early drivers of pre-leukemic HSC expansion and leukemogenesis.

Project description:Acute myeloid leukemia (AML) with chromosomal rearrangements involving the H3K4 methyltransferase mixed-lineage leukemia (MLL) is an aggressive subtype with low overall survival. MLL rearrangements rapidly transform hematological stem and progenitor cell (HSPC) to leukemia stem cell (LSC). Bortezomib (Velcade) is used widely in hematological malignancies. However, it is still unknown whether bortezomib possesses anti-self-renewal and anti-leukemogenesis of LSC in AML with MLL rearrangements. Here, we found that bortezomib inhibited cell proliferation, induced apoptosis, and decreased colony formation in leukemic cell lines, primary AML blasts, and MLL-AF9-transformed murine leukemic blasts. Besides, bortezomib reduced the frequency and function of LSC, inhibited the progression, and prolonged