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Characterizing the role of PLAGL2 in human leukemia initiationXu, Joshua January 2024 (has links)
The identification and understanding of early drivers in malignancy is crucial to revert preleukemic events and prevent leukemic relapse. Del(20q) is one of the most common primary cytogenetic abnormalities found in preleukemic malignancies from myeloproliferative neoplasms to myelodysplastic syndrome (MDS). Previous studies have identified a “common retained region” within 20q11.21 that is often amplified in a subset of MDS patients. PLAGL2 is one of the 4 genes identified to be within the minimally conserved amplified region. Indeed, in previously published datasets of MDS hematopoietic stem and progenitor cells (HSPCs) transcriptome, PLAGL2 is significantly elevated in del(20q) patients compared to healthy controls. However, we have found that its level is also higher in HSPCs of cytogenetically normal MDS patients with low blasts. Given these findings, we sought to define the role of PLAGL2 as a potential early driver of myeloid malignancies.
Results
In healthy cord blood (CB) HSPCs, PLAGL2 overexpression enhanced proliferation ex vivo, better maintained stemness and decreased apoptosis. Colony formation assays also identified increased output of the erythroid lineage. Xenotransplanted CB CD34+ HSPCs overexpressing PLAGL2 exhibited increased engraftment competitiveness and led to splenomegaly with signs of hypercellularity after 20 weeks, features consistent with clinical observations of hematological malignancy. Grafts derived from PLAGL2 overexpressing cells reproducibly maintained a significantly larger CD34+ HSPC compartment. Intriguingly we also identified that ~50% of PLAGL2-overexpressing grafts exhibited a significant erythroid (CD71+/CD235a+) component where none was observed in the control group. This unique finding of aberrant erythropoiesis is reminiscent of clinical observations in patients with 20q11.21 amplification, where a high proportion of erythroblasts in the marrow and in some cases progression to erythroleukemia was noted. To evaluate the progression of PLAGL2-overexpressing grafts, further secondary transplantations were carried out and showed the persistence of only immature erythroid progenitors (CD71+/CD235a-) coupled with a near complete absence of lymphopoiesis in the same grafts. Together, our data strongly suggests ectopic levels of PLAGL2 can independently drive the expansion of human HSPCs and enforce features of myeloid malignancy.
To uncover the molecular mechanism underlying PLAGL2 function, we performed RNA-seq and CUT&RUN in human CB CD34+ HSPCs overexpressing PLAGL2. Gene set enrichment analysis of the transcriptome and over-representation analysis of bound genes both identified signatures consistent with LSCs. We compared these findings with identically-derived omics profiles of HSPCs overexpressing PLAG1, a closely related family member that our lab has identified as a potent expander of HSCs ex vivo but not capable of promoting malignant features. We found a strong common feature in the downregulation of ribosomal components and translation machinery, then functionally validated reduced protein synthesis in PLAGL2 overexpressing HSPCs through OP-Puro assays. We have shown dampened mRNA translation to be one of the mechanisms by which PLAG1 enhances stemness and survival of HSCs, one that potentially extends to PLAGL2 as well. However, we also identified discordant signatures, notably PLAGL2's unique capacity to reduce mitochondrial translation, a pathway associated with ineffective erythropoiesis and MDS and one potential pathway by which PLAGL2 can enforce malignant phenotypes.
Finally, to investigate the potential of PLAGL2 as a therapeutic target in MDS and AML, we performed shRNA knockdown in MDSL, a human MDS cell line, and primary human AML. In vitro competitive assays with MDSL showed steady dropout of PLAGL2 depleted cells. Similarly, depletion of PLAGL2 in primary AML was also able to attenuate colony formation and engraftment in vivo, highlighting the therapeutic potential of PLAGL2 inhibition throughout myeloid malignancies.
Conclusion
We have identified PLAGL2's potential as an early independent driver of myeloid malignancy and aberrant erythroid differentiation. An understanding of PLAGL2 and its downstream mechanisms will not only further our understanding on the development of early myeloid malignancies but also potentially provide another avenue to treat or prevent leukemia before it manifests. / Thesis / Doctor of Philosophy (PhD)
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A MOLECULAR ‘SWITCHBOARD’-LYSINE MODIFICATIONS AND THEIR IMPACT ON TRANSCRIPTIONZheng, Gang January 2006 (has links)
No description available.
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PLAGL2 Cooperates in Leukemia Development by Upregulating MPL Expression: A DissertationLandrette, Sean F. 22 June 2006 (has links)
Chromosomal alterations involving the RUNXI or CBFB genes are specifically and recurrently associated with human acute myeloid leukemia (AML). One such chromosomal alteration, a pericentric inversion of chromosome 16, is present in the majority of cases of the AML subtype M4Eo. This inversion joins CBFB with the smooth muscle myosin gene MYH11 creating the fusion CBFB-MYH11. Knock-in studies in the mouse have demonstrated that expression of the protein product of the Cbfb-MYH11fusion, Cbfβ-SMMHC, predisposes mice to AML and that chemical mutagenesis both accelerates and increases the penetrance of the disease (Castilla et al., 1999). However, the mechanism of transformation and the associated collaborating genetic events remain to be resolved.
As detailed in Chapter 2, we used retroviral insertional mutagenesis (RIM) to identify mutations in Cbfb-MYH11 chimeric mice that contribute to AML. The genetic screen identified 54 independent candidate cooperating genes including 6 common insertion sites: Plag1, Plagl2, Runx2, H2T23, Pstpip2, and Dok1. Focusing on the 2 members of the Plag family of transcription factors, Chapter 3 presents experiments demonstrating that Plag1 and Plagl2 independently cooperate with Cbfβ-SMMHC in vivo to efficiently trigger leukemia with short latency in the mouse. In addition, Plag1 and PLAGL2 increased proliferation and in vitro cell renewal in Cbfβ-SMMHC hematopoietic progenitors. Furthemore, PLAG1 and PLAGL2 expression was increased in 20% of human AML samples suggesting that PLAG1 and PLAGL2 may also contribute to human AML. Interestingly, PLAGL2was preferentially increased in samples with chromosome 16 inversion, t(8;21), and t(15;17).
To define the mechanism by which PLAGL2 contributes to leukemogenesis, Chapter 4 presents studies assessing the role of the Mp1 signaling cascade as a Plagl2 downstream pathway in leukemia development. Using microarray analysis we discovered that PLAGL2 induces the expression of Mp1 transcript in primary bone marrow cells that express Cbfβ-SMMHC and that this induction is maintained in leukemogenesis. We have also performed luciferase assays to confirm that the Mp1 proximal promoter can be directly bound and activated by PLAGL2. Furthermore, we demonstrate increased Mp1 expression leads to hypersensitivity to the Mp1 ligand thrombopoietin (TPO) in PLAGL2/Cbfβ-SMMHC leukemic cells. To test the functional relevance in leukemia formation, we performed a bone-marrow transplantation assay and demonstrate that overexpression of Mp1 is indeed sufficient to cooperate with Cbfβ-SMMHC in leukemia induction. This data reveals that PLAGL2 cooperates with Cbfβ-SMMHC at least in part by inducing the expression of the cytokine receptor Mp1. Thus, we have identified the Mp1 signal transduction pathway as a novel target for therapeutic intervention in AML.
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