Project description:The cyclin-dependent kinases (CDK) CDK6 and CDK4 have redundant functions in regulating cell-cycle progression. We describe a novel role for CDK6 in hematopoietic and leukemic stem cells (HSCs and LSCs) that exceeds its function as cell-cycle regulator. Although hematopoiesis appears regular under steady state conditions Cdk6-/- HSCs do not efficiently repopulate upon competitive transplantation and Cdk6-deficient mice are significantly more susceptible to 5-fluorouracil (5-FU) treatment. We find that activation of HSCs requires CDK6, which interferes with transcription of key regulators including Egr1. The central role of Egr1 is supported by transcriptional profiling of HSCs. The impaired repopulation capacity extends to BCR-ABLp210+ leukemic stem cells. Transplantation with BCR-ABLp210+-infected bone marrow (BM) from Cdk6-/- mice fails to induce disease although recipient mice do harbor LSCs. Egr1 knock-down in cdk6-/- BCR-ABLp210+ LSKs significantly enhances colony formation underlining the importance of the Cdk6-Egr1 axis. Our findings define CDK6 as an important regulator of stem cell activation and as essential component of a transcriptional complex that suppresses Egr1 in HSCs and LSCs.

Project description:This SuperSeries is composed of the following subset Series: GSE35110: Gene expression profiling in WT and Hif1a-/- HSCs GSE35111: Gene expression profiling in BCR/ABL expressing LSCs and BCR/ABL expressing Hif1a-/-LSCs Refer to individual Series

Project description:Using a mouse model of chronic myelogenous leukemia (CML), here we report that HIF1M-NM-1 plays a crucial role in survival maintenance of leukemia stem cells (LSCs). Deletion of HIF1M-NM-1 impairs the propagation of CML through impairing cell cycle progression and inducing apoptosis of LSCs. Deletion of HIF1M-NM-1 results in elevated expression of p16Ink4a and p19Arf in LSCs, and knockdown of p16Ink4a and p19Arf rescues the defective colony-forming ability of HIF1M-NM-1-/- LSCs. To further identify the pathways in which Hif1a regulates function of LSCs, we performed a comparative DNA microarray analysis using total RNA isolated from BCR-ABL-expressing wild type LSCs and BCR-ABL-expressing Hif1a-/- LSCs. The result was validated by quantitative real-time PCR analysis of non-BCR-ABL-expressing Lin-Sca-1+c-Kit+ cells, BCR-ABL-expressing wild type LSCs, and BCR-ABL-expressing Hif1a-/- LSCs. To identify genes that are regulated by BCR-ABL in LSCs and LSCs without the Hif1a gene, we compared the gene profile between wild type (WT) LSCs and Hif1a-/- LSCs.

Project description:We previously demonstrated that Alox5 deficiency impairs the function of LSCs and prevents the initiation of BCR-ABL-induced CML. To identify the pathways in which Alox5 gene regulates function of LSCs, we performed a comparative DNA microarray analysis using total RNA isolated from non-BCR-ABL-expressing Lin-Sca-1+c-Kit+, BCR-ABL-expressing wild type LSCs and BCR-ABL-expressing Alox5-/- LSCs. The result was validated by quantitative real-time PCR analysis of non-BCR-ABL-expressing Lin-Sca-1+c-Kit+, BCR-ABL-expressing wild type LSCs and BCR-ABL-expressing Alox5-/- LSCs. We have shown that Alox5 is a critical regulator of leukemia stem cells (LSCs) in a BCR-ABL-induced chronic myeloid leukemia (CML) mouse model, and we hypothesize that the Alox5 pathway represents a major molecular network that regulates LSC function. Therefore, we sought to further dissect this pathway by comparing the gene expression profiles of wild type and Alox5-/- LSCs derived from our mouse model for BCR-ABL-induced CML. DNA microarray analysis revealed a small group of candidate genes that exhibited changes in the levels of transcription in the absence of Alox5 expression. In particular, we noted that the expression of the Msr1 gene was up-regulated in Alox5-/- LSCs, suggesting that Msr1 might suppress the proliferation of LSCs.  Using our CML mouse model, we show that Msr1 is down-regulated by BCR-ABL and this down-regulation is partially restored by Alox5 deletion, and that Msr1 deletion causes acceleration of CML development. Moreover, Msr1 deletion markedly increases LSC function through its effects on cell cycle progression and apoptosis. We also show that Msr1 affects CML development by regulating the PI3K-AKT pathway and ?-Catenin. Together, these results demonstrate that Msr1 suppresses LSCs and CML development. The enhancement of Msr1 function may be of significance in the development of novel therapeutic strategies targeting CML. To identify genes that are regulated by BCR-ABL in LSCs and LSCs without Alox5 gene, we compared the gene profile between wild type(WT) LSCs or Alox5-/- LSCs.

Project description:To understand the underlying mechanism by which Alox15 gene is required by HSCs, we performed a comparative DNA microarray analysis using total RNA isolated from wild type Lin-Sca-1+c-Kit+, Alox5-/- Lin-Sca-1+c-Kit+. The result was validated by quantitative real-time PCR analysis of wild type Lin-Sca-1+c-Kit+ and Alox15-/- Lin-Sca-1+c-Kit+. Cancer stem cells are responsible for the initiation and maintenance of some types of cancer, and few effective target genes in these stem cells have been identified. Here we show that the arachidonate 15-lipoxygenase gene (Alox15) is essential for the survival of leukemia stem cells (LSCs) in BCR-ABL-induced chronic myeloid leukemia (CML). In the absence of Alox15, BCR-ABL failed to induce CML in mice. This Alox15 deficiency caused the impairment of LSC function through affecting cell division and apoptosis, leading to eventual deletion of LSCs. Inhibition of Alox15 function by a chemical compound also impaired the function of LSCs, and cured CML mice. In addition, we show that Alox15 is required for the survival of human CD34+ CML stem cells. The defective CML phenotype in the absence of Alox15 is rescued by depleting P-selectin. The underlying mechanisms are also related to pathways involving PTEN, PI3K/AKT, and ICSBP. These results identify Alox15 as a potential target gene for eradicating LSCs in CML, providing a novel strategy for treating CML patients for cure. we compared the gene profile of HSCs between WT mice and Alox15-/- mice.

Project description:Using BCR-ABL-induced chronic myeloid leukemia (CML) as a disease model for leukemia stem cells (LSCs), we showed that BCR-ABL down-regulates the B lymphoid kinase (Blk) gene in leukemia stem cells in CML mice and that Blk functions as a tumor suppressor in LSCs and suppresses LSC function. Inhibition of this Blk pathway accelerates CML development, whereas increased activity of the Blk pathway delays CML development. To identify the pathways in which Blk regulates function of LSCs, we performed a comparative DNA microarray analysis using total RNA isolated from non-BCR-ABL-expressing Lin-Sca-1+c-Kit+, BCR-ABL- and BCR-ABL-Blk expressing LSCs. This analysis revealed a large group of candidate genes that exhibited changes in the levels of transcription in the Blk expressing LSCs, and uncovered the molecular mechanisms by which Blk suppresses LSCs and CML development. Bone marrow cells were transduced with GFP, BCR-ABL-GFP or BCR-ABL-Blk-GFP, followed by transplantation into recipient mice. Fourteen days after transplantation, bone marrow cells were isolated and LSCs were sorted by FACS for isolation of total RNA for DNA microarray analysis.

Project description:Gene expression analysis of AML LSCs vs normal HSCs Total RNA obtained from FACS-sorted AML-LSCs (n=12) and normal HSCs (n=5) were subjected to the microarray analysis

Project description:Using a mouse model of chronic myelogenous leukemia (CML), here we report that HIF1α plays a crucial role in survival maintenance of leukemia stem cells (LSCs). Deletion of HIF1α impairs the propagation of CML through impairing cell cycle progression and inducing apoptosis of LSCs. Deletion of HIF1α results in elevated expression of p16Ink4a and p19Arf in LSCs, and knockdown of p16Ink4a and p19Arf rescues the defective colony-forming ability of HIF1α-/- LSCs. To further identify the pathways in which Hif1a regulates function of LSCs, we performed a comparative DNA microarray analysis using total RNA isolated from BCR-ABL-expressing wild type LSCs and BCR-ABL-expressing Hif1a-/- LSCs. The result was validated by quantitative real-time PCR analysis of non-BCR-ABL-expressing Lin-Sca-1+c-Kit+ cells, BCR-ABL-expressing wild type LSCs, and BCR-ABL-expressing Hif1a-/- LSCs.

Project description:The transcription factor c-JUN and its upstream kinase JNK1 have been implicated in BCR-ABL induced leukemogenesis. JNK1 has been shown to regulate BCL2 expression thereby altering leukemogenesis, but the impact of c-JUN remained unclear. In this study we show that JNK1 and c-JUN promote leukemogenesis via separate pathways, since lack of c-JUN impairs proliferation of p185BCR-ABL transformed cells without affecting viability. The decreased proliferation of c-JunD/D cells is associated with the loss of cyclin dependent kinase 6 (CDK6) expression. In c-JunD/D cells CDK6 expression becomes down-regulated upon BCR-ABL induced transformation which correlates with CpG island methylation within the 5´ region of Cdk6. We verified the impact of Cdk6 deficiency by using Cdk6-/- mice that developed BCR-ABL induced B-lymphoid leukemia with significantly increased latency and an attenuated disease phenotype. In addition we show that re-expression of CDK6 in BCR-ABL transformed c-JunD/D cells reconstitutes proliferation and tumor formation in Nu/Nu mice. In summary, our study reveals a novel function for the AP-1 transcription factor c-JUN in leukemogenesis by antagonizing promoter methylation. Moreover, we identify CDK6 as relevant and critical target of AP-1 regulated DNA methylation upon BCR-ABL induced transformation, thereby accelerating leukemogenesis. Overall, 8 samples consisting of 4 wild type and 4 c-jun knock out samples were hybridized to MoGene-1_0-st-v1 microarrays.

Project description:Dertermination of chromatin accessibility in murine BCR-ABL+ CDK6-wt and CDK6-KO cells