Isolation of TPO-dependent subclones from the multipotent 32D cell line

Pathological interactions between hematopoietic stem cells and their niche revealed by mouse models of primary myelofibrosis

Primary myelofibrosis (PMF) belongs to the Philadelphia-negative myeloproliferative neoplasms and is a hematological disorder caused by abnormal function of the hematopoietic stem cells. The disease manifests itself with a plethora of alterations, including anemia, splenomegaly and extramedullary hematopoiesis. Its hallmarks are progressive marrow fibrosis and atypical megakaryocytic hyperplasia, two distinctive features used to clinically monitor disease progression. In an attempt to investigate the role of abnormal megakaryocytopoiesis in the pathogenesis of PMF, several transgenic mouse models have been generated. These models are based either on mutations that interfere with the extrinsic (thrombopoietin and its receptor, MPL) and intrinsic (the GATA1 transcription factor) control of normal megakaryocytopoiesis, or on known genetic lesions associated with the human disease. Here we provide an up-to-date review on the insights into the pathobiology of human PMF achieved by studying these animal models, with particular emphasis on results obtained with Gata1(low) mice.

Establishment of an ES cell-derived murine megakaryocytic cell line, MKD1, with features of primary megakaryocyte progenitors

Because of the scarcity of megakaryocytes in hematopoietic tissues, studying megakaryopoiesis heavily relies on the availability of appropriate cellular models. Here, we report the establishment of a new mouse embryonic stem (ES) cell-derived megakaryocytic cell line, MKD1. The cells are factor-dependent, their cell surface immunophenotype and gene expression profile closely resemble that of primary megakaryocyte progenitors (MkPs) and they further differentiate along the megakaryocyte lineage upon valproic acid treatment. At a functional level, we show that ablation of SCL expression, a transcription factor critical for MkP maturation, leads to gene expression alterations similar to that observed in primary, Scl-excised MkPs. Moreover, the cell line is amenable to biochemical and transcriptional analyses, as we report for GpVI, a direct target of SCL. Thus, the MKD1 cell line offers a pertinent experimental model to study the cellular and molecular mechanisms underlying MkP biology and more broadly megakaryopoiesis.

Interleukin-3 and erythropoietin cooperate in the regulation of the expression of erythroid-specific transcription factors during erythroid differentiation

OBJECTIVE

To characterize how interleukin-3 and erythropoietin regulate cell fate by modulating the expression of lineage-specific transcription factors.

METHODS

This study analyzed mRNA and protein levels, gene transcription rates, and mRNA and protein stabilities of erythroid-specific transcription factors in lineage-restricted cells derived from the 32D cell line cultured either in interleukin-3 or erythropoietin.

RESULTS

Erythroid 32D subclones expressed levels of Idl, Gata-2, and Scl comparable and levels of Eklf and Gata-1 higher than those expressed by myeloid subclones. While maintained in interleukin-3, erythroid cells remained immature despite their high expression of Gata-1, Gata-2, Scl, Eklf, and Idl. Switching the erythroid cells to erythropoietin induced cell maturation (within 48 hours) and reduced expression of Gata-2 and Idl (in 24 hours) but did not alter the expression of Gata-1. The effects of interleukin-3 were mostly mediated by increases in transcription rates (Scl and Gata-2), and that of erythropoietin was apparently due to increased mRNA and protein (Gata-1, Scl, and Eklf) stability. In particular, erythropoietin increased the stability of the processed and transcriptionally more active form of GATA-1 protein.

CONCLUSIONS

These results suggest that interleukin-3 and erythropoietin cooperate to establish the lineage-specific transcription factor milieu of erythroid cells: interleukin-3 regulates mainly gene transcription and erythropoietin consistently increases mRNA and protein stability.

Differentiation of murine committed megakaryocytic progenitors isolated by a novel strategy reveals the complexity of GATA and Ets factor involvement in megakaryocytopoiesis and an unexpected potential role for GATA-6

OBJECTIVE

The differentiation of megakaryocytes is characterized by polyploidization and cytoplasmic maturation leading to platelet production. Studying these processes is hindered by the paucity of bone marrow megakaryocytes and their precursors. We describe a method for the expansion and purification of committed megakaryocyte progenitors and demonstrate their usefulness by studying changes in the expression of Ets and GATA family transcription factors throughout megakaryocytopoiesis.

METHODS

A two-step serum-free method was developed. Cells isolated using this method were analyzed for surface marker expression by flow cytometry, and for their ability to differentiate using single-cell culture. Purified progenitors were induced to differentiate and analyzed with respect to their ploidy by flow cytometry and expression of specific genes by RT-PCR.

RESULTS

A population of Lin- c-kit+ CD45+ CD41+ CD31+ CD34low CD9low FcgammaRII/IIIlow Sca-1med/low committed megakaryocyte progenitors was purified. These cells could be differentiated efficiently, achieving ploidy of up to 128N. Analysis of RNA demonstrated the expected increases in expression of key megakaryocyte-associated genes. RT-PCR analysis also revealed that a range of Ets and GATA factors are expressed, their individual levels and patterns of expression varying widely. Surprisingly, we find that GATA-6 is specifically expressed in late differentiated megakaryocytes and has the potential to regulate megakaryocyte-expressed genes in cooperation with Ets factors.

CONCLUSION

Purified primary megakaryocytic progenitors are able to differentiate as a cohort into fully mature megakaryocytes. The number of cells obtainable, and the synchrony of the differentiation process, facilitates analysis of the dynamics of molecular processes involved in megakaryocytopoiesis. The expression pattern of Ets and GATA family transcription factors reveals the complexity of the involvement of these key megakaryocytic regulators. The finding of GATA-6 expression and demonstration of its functional activity suggests a novel mechanism for the regulation of certain genes late in megakaryocytopoiesis.