Gina Kirsammer

Increased dosage of the chromosome 21 ortholog Dyrk1a promotes megakaryoblastic leukemia in a murine model of Down syndrome

Individuals with Down syndrome (DS; also known as trisomy 21) have a markedly increased risk of leukemia in childhood but a decreased risk of solid tumors in adulthood. Acquired mutations in the transcription factor-encoding GATA1 gene are observed in nearly all individuals with DS who are born with transient myeloproliferative disorder (TMD), a clonal preleukemia, and/or who develop acute megakaryoblastic leukemia (AMKL). Individuals who do not have DS but bear germline GATA1 mutations analogous to those detected in individuals with TMD and DS-AMKL are not predisposed to leukemia. To better understand the functional contribution of trisomy 21 to leukemogenesis, we used mouse and human cell models of DS to reproduce the multistep pathogenesis of DS-AMKL and to identify chromosome 21 genes that promote megakaryoblastic leukemia in children with DS. Our results revealed that trisomy for only 33 orthologs of human chromosome 21 (Hsa21) genes was sufficient to cooperate with GATA1 mutations to initiate megakaryoblastic leukemia in vivo. Furthermore, through a functional screening of the trisomic genes, we demonstrated that DYRK1A, which encodes dual-specificity tyrosine-(Y)-phosphorylation-regulated kinase 1A, was a potent megakaryoblastic tumor-promoting gene that contributed to leukemogenesis through dysregulation of nuclear factor of activated T cells (NFAT) activation. Given that calcineurin/NFAT pathway inhibition has been implicated in the decreased tumor incidence in adults with DS, our results show that the same pathway can be both proleukemic in children and antitumorigenic in adults.

Embryonic signaling in melanoma: Potential for diagnosis and therapy

As the frequency of melanoma diagnosis increases, current treatment strategies are still struggling to significantly impact patient survival. Some promise has been shown in treating certain melanomas by targeting activated signaling pathways resulting from specific mutations in proteins, such as BRAF and NRAS. Recently, the identification of embryonic signaling pathways in melanoma has helped us better understand certain biological characteristics, such as cellular heterogeneity and phenotypic plasticity, and has provided novel insight pertinent to diagnosis and therapy. For instance, our studies have shown that the TGF-β family member, Nodal, is expressed in melanoma and is responsible, at least in part, for tumor cell plasticity and aggressiveness. Since the majority of normal adult tissues do not express Nodal, we reason that this embryonic morphogen could be used to identify and target aggressive melanoma cells. We have also identified that molecular cross-talk between the Notch and Nodal pathways may represent a mechanism responsible for the overexpression of Nodal in melanoma. Further exploitation of the relationship between embryonic signaling pathways and cancer pathogenesis could lead to novel approaches for diagnosis and therapy in cancers, such as melanoma.

Nodal signaling promotes a tumorigenic phenotype in human breast cancer

The Ras-ERK pathway is deregulated in approximately a third of human cancers, particularly those of epithelial origin. In aggressive, triple-negative, basal-like breast cancers, most tumors display increased MEK and ERK phosphorylation and exhibit a gene expression profile characteristic of Kras or EGFR mutant tumors; however, Ras family genetic mutations are uncommon in triple-negative breast cancer and EGFR mutations account for only a subset of these tumors. Therefore, the upstream events that activate MAPK signaling and promote tumor aggression in triple-negative breast cancers remain poorly defined. We have previously shown that a secreted TGF-β family signaling ligand, Nodal, is expressed in breast cancer in correlation with disease progression. Here we highlight key findings demonstrating that Nodal is required in aggressive human breast cancer cells to activate ERK signaling and downstream tumorigenic phenotypes both in vitro and in vivo. Experimental knockdown of Nodal signaling downregulates ERK activity, resulting in loss of c-myc, upregulation of p27, G1 cell cycle arrest, increased apoptosis and decreased tumorigenicity. The data suggest that ERK activation by Nodal signaling regulates c-myc and p27 proteins post-translationally and that this cascade is essential for aggressive breast tumor behavior in vivo. As the MAPK pathway is an important target for treating triple-negative breast cancers, upstream Nodal signaling may represent a promising target for breast cancer diagnosis and combined therapies aimed at blocking ERK pathway activation.

Melanoma Tumor Cell Heterogeneity: A Molecular Approach to Study Subpopulations Expressing the Embryonic Morphogen Nodal

As the frequency of melanoma increases, current treatment strategies are struggling to significantly impact patient survival. One of the critical issues in designing efficient therapies is understanding the composition of heterogeneous melanoma tumors in order to target cancer stem cells (CSCs) and drug-resistant subpopulations. In this review, we summarize recent findings pertinent to the reemergence of the embryonic Nodal signaling pathway in melanoma and its significance as a prognostic biomarker and therapeutic target. In addition, we offer a novel molecular approach to studying the functional relevance of Nodal-expressing subpopulations and their CSC phenotype.

Aurora kinase A is required for hematopoiesis but is dispensable for murine megakaryocyte endomitosis and differentiation

Aurora kinase A (AURKA) is a therapeutic target in acute megakaryocytic leukemia. However, its requirement in normal hematopoiesis and megakaryocyte development has not been extensively characterized. Based on its role as a cell cycle regulator, we predicted that an Aurka deficiency would lead to severe abnormalities in all hematopoietic lineages. Here we reveal that loss of Aurka in hematopoietic cells causes profound cell autonomous defects in the peripheral blood and bone marrow. Surprisingly, in contrast to the survival defects of nearly all hematopoietic lineages, deletion of Aurka was associated with increased differentiation and polyploidization of megakaryocytes both in vivo and in vitro. Furthermore, in contrast to other cell types examined, megakaryocytes continued DNA synthesis after loss of Aurka. Thus, like other cell cycle regulators such as Aurkb and survivin, Aurka is required for hematopoiesis, but is dispensable for megakaryocyte endomitosis. Our work supports a growing body of evidence that the megakaryocyte endomitotic cell cycle differs significantly from the proliferative cell cycle.

Lessons from Embryogenesis

The plastic phenotype of aggressive melanoma has presented a significant challenge in the detection and targeting of tumor cells exhibiting stem cell-like characteristics. As the molecular signaling pathways underlying tumor cell plasticity become more transparent, our understanding of how to suppress this elusive phenotype will be enhanced. Indeed, we are making progress in identifying critical embryonic pathways, such as the Nodal signaling pathway, that reemerge in aggressive tumor cells – in the absence of regulatory check points. Because Nodal is not expressed by the majority of normal adult tissues, and is over-expressed by aggressive tumor cells, it represents a valuable new therapeutic target. Collectively, we have learned a great deal from studies that focus our attention on the convergence of embryonic and tumorigenic signaling pathways. At this interaction of normal development and tumor formation reside the clues to suppressing cancer progression.

USP22 deficiency leads to myeloid leukemia upon oncogenic Kras activation through a PU.1 dependent mechanism

Ras mutations are commonly observed in juvenile myelomonocytic leukemia (JMML) and chronic myelomonocytic leukemia (CMML). JMML and CMML transform into acute myeloid leukemia (AML) in about 10% and 50% of patients, respectively. However, how additional events cooperate with Ras to promote this transformation are largely unknown. We show that absence of the ubiquitin-specific peptidase 22 (USP22), a component of the Spt-Ada-GCN5-acetyltransferase chromatin-remodeling complex that is linked to cancer progression, unexpectedly promotes AML transformation in mice expressing oncogenic KrasG12D/+ USP22 deficiency in KrasG12D/+ mice resulted in shorter survival compared with control mice. This was due to a block in myeloid cell differentiation leading to the generation of AML. This effect was cell autonomous because mice transplanted with USP22-deficient KrasG12D/+ cells developed an aggressive disease and died rapidly. The transcriptome profile of USP22-deficient KrasG12D/+ progenitors resembled leukemic stem cells and was highly correlated with genes associated with poor prognosis in AML. We show that USP22 functions as a PU.1 deubiquitylase by positively regulating its protein stability and promoting the expression of PU.1 target genes. Reconstitution of PU.1 overexpression in USP22-deficient KrasG12D/+ progenitors rescued their differentiation. Our findings uncovered an unexpected role for USP22 in Ras-induced leukemogenesis and provide further insights into the function of USP22 in carcinogenesis.

Signaling a link between interferon and the traits of Down syndrome

Elevated interferon signaling is a hallmark of Down syndrome.

Reprogramming Breast Cancer Cells with Embryonic Microenvironments: Insights from Nodal Signaling

Normal developmental pathways that determine cell fate, migration, and proliferative potential become reactivated in cancer to promote the most devastating aspect of the disease, namely, metastasis to new sites. However, unlike their function in the delimited process of normal growth and differentiation, developmental pathways in the context of metastatic cancer support an aberrant and unlimited morphogenic program. Understanding how specific morphogenic pathways function in normal development and how they become deregulated in cancer may provide insight into new therapeutic opportunities to limit cancer spread. Adding complexity, however, such developmental pathways do not function solely through linear, cell autonomous programs but rather as dynamic, iterative processes between cells and their microenvironment. Therefore, comprehensive strategies to treat cancer and limit recurrence and metastasis must consider the ever-changing, reciprocal developmental relationship of cancer cells with their microenvironment. One important developmental pathway that shapes the interdependent evolution of breast cancer cells and their microenvironment is signaling by the embryonic morphogen Nodal, a member of the TGF-β family and a promising, new therapeutic target. Herein we review the significance of bidirectional signaling with the microenvironment in tumor progression and the distorted recapitulation of normal developmental programs that promote tumor aggression. Further, this chapter examines the reemergence of Nodal signaling during breast cancer growth and, finally, the therapeutic potential of targeting cancer cell–microenvironment interactions in general, and particularly Nodal signaling, to reprogram these relationships and promote a more benign developmental course in malignant breast cancer.

Abstract 3353: Nodal signaling mediates the aggressive, tumorigenic phenotype in breast cancer cells

The embryonic morphogen Nodal is a potent inducer of EMT and critical mediator of stem cell pluripotency in the developing embryo, but is not expressed in normal adult tissues. Intriguingly, our lab has recently shown that Nodal, a TGF-beta family member, is in fact secreted by melanoma and breast cancer cells and that Nodal expression positively correlates with tumor grade in human patient samples. Our current studies demonstrate a positive role for Nodal in regulating breast cancer cell renewal and aggressiveness. Specifically, short hairpin (shRNA) knockdown of Nodal expression in human breast cancer cell lines diminishes proliferation, invasion and clonogenicity of these cell lines in vitro and dramatically curtails tumor formation in a mouse xenograft model. Additionally, our data suggest that these effects may be caused, in part, by alterations in the expression of adhesion receptors known to function in tumor engraftment and metastasis. Taken together, our data suggest that Nodal signaling may facilitate the acquisition of self-renewal and migratory capabilities in breast cancer cells and represent a novel therapeutic target for disrupting these processes in breast cancer cells. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 3353. doi:1538-7445.AM2012-3353