Cancer cells are hallmarked by high proliferation and imbalanced redox consumption and signaling. Various oncogenic pathways such as proliferation and evading cell death converge on redox-dependent signaling processes. Nrf2 is a key regulator in these redox-dependent events and operates in cytoprotection, drug metabolism and malignant progression in cancer cells. Here, we show that patients with primary malignant brain tumors (glioblastomas, WHO °IV gliomas, GBM) have a devastating outcome and overall reduced survival when Nrf2 levels are upregulated. Nrf2 overexpression or Keap1 knockdown in glioma cells accelerate proliferation and oncogenic transformation. Further, activation of the Nrf2-Keap1 signaling upregulates xCT (aka SLC7A11 or system Xc−) and amplifies glutamate secretion thereby impacting on the tumor microenvironment. Moreover, both fostered Nrf2 expression and conversely Keap1 inhibition promote resistance to ferroptosis. Altogether, the Nrf2-Keap1 pathway operates as a switch for malignancy in gliomas promoting cell proliferation and resistance to cell death processes such as ferroptosis. Our data demonstrate that the Nrf2-Keap1 pathway is critical for cancer cell growth and operates on xCT. Nrf2 presents the Achilles’ heel of cancer cells and thus provides a valid therapeutic target for sensitizing cancer for chemotherapeutics.
The development and regulation of malignant self-renewal remains an unresolved issue. Here, we provide biochemical, genetic, and functional evidence that dynamics in ribosomal RNA (rRNA) 2'-O-methylation regulate leukemia stem cell (LSC) activity in vivo. A comprehensive analysis of the rRNA 2'-O-methylation landscape of 94 acute myeloid leukemia (AML) patients revealed dynamic 2'-O-methylation specifically at exterior sites of ribosomes. rRNA 2'-O-methylation pattern is closely associated with AML development stage and LSC gene expression signature. Forced expression of 2'-O-methyltransferase FBL induced an AML stem cell phenotype and enabled engraftment of non-LSC leukemia cells in NSG mice. Enhanced 2’-O-methylation redirected the ribosome translation program towards amino acid transporter mRNAs enriched in optimal codons and subsequently increased intracellular amino acid levels. Methylation at the single site 18S-guanosine 1447 was instrumental for LSC activity. Collectively, our work demonstrates that dynamic 2'-O-Me at specific sites on ribosomal RNAs shifts translational preferences and controls AML-LSC self-renewal.
Inducible transgene expression in PDX models in vivo identifies KLF4 as a therapeutic target for B-ALL
Background Clinically relevant methods are not available that prioritize and validate potential therapeutic targets for individual tumors, from the vast amount of tumor descriptive expression data. Methods We established inducible transgene expression in clinically relevant patient-derived xenograft (PDX) models in vivo to fill this gap. Results With this technique at hand, we analyzed the role of the transcription factor Krüppel-like factor 4 (KLF4) in B-cell acute lymphoblastic leukemia (B-ALL) PDX models at different disease stages. In competitive preclinical in vivo trials, we found that re-expression of wild type KLF4 reduced the leukemia load in PDX models of B-ALL, with the strongest effects being observed after conventional chemotherapy in minimal residual disease (MRD). A nonfunctional KLF4 mutant had no effect on this model. The re-expression of KLF4 sensitized tumor cells in the PDX model towards systemic chemotherapy in vivo. It is of major translational relevance that azacitidine upregulated KLF4 levels in the PDX model and a KLF4 knockout reduced azacitidine-induced cell death, suggesting that azacitidine can regulate KLF4 re-expression. These results support the application of azacitidine in patients with B-ALL as a therapeutic option to regulate KLF4. Conclusion Genetic engineering of PDX models allows the examination of the function of dysregulated genes like KLF4 in a highly clinically relevant translational context, and it also enables the selection of therapeutic targets in individual tumors and links their functions to clinically available drugs, which will facilitate personalized treatment in the future.
Resistance towards cancer treatment represents a major clinical obstacle, preventing cure of cancer patients. To gain mechanistic insights, we developed a model for acquired resistance to chemotherapy by treating mice carrying patient derived xenografts (PDX) of acute lymphoblastic leukemia with widely-used cytotoxic drugs for 18 consecutive weeks. In two distinct PDX samples, tumors initially responded to treatment, until stable disease and eventually tumor re-growth evolved under therapy, at highly similar kinetics between replicate mice. Notably, replicate tumors developed different mutations in TP53 and individual sets of chromosomal alterations, suggesting independent parallel clonal evolution rather than selection, driven by a combination of stochastic and deterministic processes. Transcriptome and proteome showed shared dysregulations between replicate tumors providing putative targets to overcome resistance. In vivo CRISPR/Cas9 dropout screens in PDX revealed broad dependency on BCL2, BRIP1 and COPS2. Accordingly, venetoclax re-sensitized derivative tumors towards chemotherapy, despite genomic heterogeneity, demonstrating direct translatability of the approach. Hence, despite the presence of multiple resistance-associated genomic alterations, effective rescue treatment for polychemotherapy-resistant tumors can be identified using functional testing in preclinical models.
Background: Functional genomic screens elegantly increase our understanding of biology of leukemias. So far, CRISPR/Cas9 screens are widely performed in cell lines and in genetically engineered mouse models, in vitro and in vivo; here, we extended their use to patient-derived leukemia cells in vivo. Methods Serially transplantable patient-derived xenograft (PDX) models were generated from children and adults with acute lymphoblastic leukemia (ALL). Cas9 was stably expressed in PDX ALL cells using a split form of Cas9 assembled by inteins, facilitating lentiviral-mediated gene delivery. Customized sgRNA library was generated using golden gate cloning, at 5 sgRNAs per target gene. The sgRNA vector additionally expressed a fluorochrome marker and a tag, for sequential magnetic-activated cell sorting (MACS) and flow cytometry (FACS) enrichment of sgRNA transduced PDX cells. Highly enriched Cas9/sgRNA double transgenic cells were transplanted into NSG mice and animals sacrificed after different periods of time. Cells were re-isolated from bone marrow, purified and subjected to PCR-based amplification of sgRNA library followed by next generation sequencing. Differential sgRNA distributions were analysed using a MAGeCK pipeline. Results We aimed to establish a comprehensive CRISPR screen pipeline allowing functional genomic screens in patients' acute leukemia cells. We investigated surface molecules required for cell homing and growth in mice, using a distinct customized sgRNA library. Quality controls of the sgRNA plasmid pool as well as transgenic PDX input samples verified standard distribution of all sgRNAs. As knockout was required at the time point of transplantation, conditions for prolonged culture of PDX ALL cells in vitro were optimized. Before injection into NSG mice, transduced PDX ALL cells were successfully enriched to above 95% using MACS and FACS. Over time in vivo, deep sequencing of re-isolated PDX cells revealed unchanged distribution of control sgRNAs, but strong loss of sgRNAs targeting CXCR4 and ITGB1, suggesting that CXCR4 and ITGB1 might be required for PDX ALL cell homing and engraftment. To validate the findings of drop-out CRISPR screen, we analyzed single sgRNAs targeting CXCR4 and ITGB1 in PDX cells. Competitive in vivo assays monitored by recombinant fluorochrome markers showed that the cells with CXCR4 or ITGB1 knockout had a significant disadvantage in vivo with respect to homing and growth in mice, compared to the control population. Taken together, we established a comprehensive workflow for CRISPR screen in PDX model of ALL in vivo. Our data identify and validate that CXCR4 and ITGB1 are required for homing and growth of PDX ALL cells in mice. Conclusion We show that CRISPR/Cas9 functional genetic screens are feasible in PDX acute leukemia models in vivo and report the first such screen, as far as to our knowledge. Extending CRISPR/Cas9 screens to patients' cells will greatly facilitate our understanding of individual leukemia biology and therapeutic targets in the future. Disclosures Becker: AVA Lifescience GmbH: Consultancy.
<p>Supplementary Figure S1 shows enrichment of FBL in LSC, correlation of FBL with LSC signature and rRNA 2'-O-Me in healthy hematopoietic cells. Supplementary Figure S2 shows the association of rRNA 2’-O-Me with LSC and hematopoietic differentiation signatures. Supplementary Figure S3 shows strategy for LSC sorting and distribution of LSC methylation sites on ribosomes. Supplementary Figure S4 shows the effect of FBL knockdown on rRNA 2’-O-methylation and in vitro proliferation of leukemia cells. Supplementary Figure S5 show the effect of FBL overexpression on in vivo engraftment of primary AML cells. Supplementary Figure S6 shows the effect of FBL knockdown on nascent proteome and metabolism of AML cells. Supplementary Figure S7 shows the ribosome footprinting analysis after FBL knockdown. Supplementary Figure S8 shows the association of Gm1447 with LSC signature and the effect of Gm1447 supression on cellular amino acid levels. Supplementary Figure S9 shows regulatory effect of Gm1447 on in vivo leukemic self-renewal.</p>
<p>Supplementary table S1 shows all rRNA 2’-O-methylation sites identified in human AMLs. Supplementary table S2 shows dynamic rRNA 2’-O-methylation sites in each DyMeC cluster. Supplementary table S3 shows the location of rRNA 2’-O-methylation static sites in ribosome regions. Supplementary table S4 shows proteins with altered translation after FBL knockdown.</p>
<div>Abstract<p>The development and regulation of malignant self-renewal remain unresolved issues. Here, we provide biochemical, genetic, and functional evidence that dynamics in ribosomal RNA (rRNA) 2′-O-methylation regulate leukemia stem cell (LSC) activity <i>in vivo</i>. A comprehensive analysis of the rRNA 2′-O-methylation landscape of 94 patients with acute myeloid leukemia (AML) revealed dynamic 2′-O-methylation specifically at exterior sites of ribosomes. The rRNA 2′-O-methylation pattern is closely associated with AML development stage and LSC gene expression signature. Forced expression of the 2′-O-methyltransferase fibrillarin (FBL) induced an AML stem cell phenotype and enabled engraftment of non-LSC leukemia cells in NSG mice. Enhanced 2′-O-methylation redirected the ribosome translation program toward amino acid transporter mRNAs enriched in optimal codons and subsequently increased intracellular amino acid levels. Methylation at the single site 18S-guanosine 1447 was instrumental for LSC activity. Collectively, our work demonstrates that dynamic 2′-O-methylation at specific sites on rRNAs shifts translational preferences and controls AML LSC self-renewal.</p>Significance:<p>We establish the complete rRNA 2′-O-methylation landscape in human AML. Plasticity of rRNA 2′-O-methylation shifts protein translation toward an LSC phenotype. This dynamic process constitutes a novel concept of how cancers reprogram cell fate and function.</p><p><i><a href="https://aacrjournals.org/cancerdiscovery/article/doi/10.1158/2159-8290.CD-13-2-ITI" target="_blank">This article is highlighted in the In This Issue feature, p. 247</a></i></p></div>
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