THE CONSEQUENCES OF DISRUPTING THE MDM2-P53 BALANCE IN HEMATOPOIESIS

The bone marrow accommodates hematopoietic stem cells and progenitors. These cells provide an indispensible resource for replenishing the blood constituents throughout an organism’s life. A tissue with such a high turn-over rate mandates intact cycling checkpoint and apoptotic pathways to avoid inappropriate cell proliferation and ultimately the development of leukemias. p53, a major tumor suppressor, is a transcription factor that regulates cell cycle, and induces apoptosis and senescence. Mice inheriting a hypomorphic p53 allele in the absence of Mdm2, a p53 inhibitor, have elevated p53 cell cycle activity and die by postnatal day 13 due to hematopoietic failure. Hematopoiesis progresses normally during embryogenesis until it moves to the bone marrow in late development. Increased oxidative stress in the bone marrow compartment postnatally is the impediment for normal hematopoiesis via activation of p53. p53 in turn stimulates the generation of more reactive oxygen species and depletes bone marrow cellularity. Also, p53 exerts various defects on the hematopoietic niche by increasing mesenchymal lineage populations and their differentiation. Hematopoietic defects are rescued with antioxidants or when cells are cultured at low oxygen levels. Deletion of p16 partially rescues bone marrow cellularity and progenitors via a p53-independent pathway. Thus, although p53 is required to inhibit tumorigenesis, Mdm2 is required to control ROS-induced p53 levels for sustainable hematopoiesis and survival during homeostasis.

Expression and regulation of a hematopoietic proteoglycan core protein gene during hematopoiesis

Factors involved in regulating tissue specific gene expression play a major role in cell differentiation. In order to further understand the differentiation events occurring during hematopoiesis, a myeloid specific gene was characterized, the expression pattern during hematopoiesis was analyzed, and the mechanisms governing its regulation were assessed. Previously, our laboratory isolated an anonymous cDNA clone, pD-D1, which displayed preferential expression in myeloid cells. From nucleotide sequencing of overlapping cDNA clones I determined that the D-D1 message encodes a hematopoietic proteoglycan core protein (HpPG). The expression pattern of the gene was assessed by in situ hybridization of bone marrow and peripheral blood samples. The gene was shown to be expressed, at variable levels, in all leukocytes analyzed, including cells from every stage of neutrophil development. In an attempt to ascertain the differentiation time point in which the HpPG gene is initially expressed, more immature populations of leukemic myeloblasts were assessed by northern blot analysis. Though the initial point of expression was not obtained, an up-regulatory event was discovered corresponding to a time point in which granule genesis occurs. This finding is consistent with prior observations of extensive packaging of proteoglycans into the secretory granules of granule producing hematopoietic cells. The HpPG gene was also found to be expressed at low levels in all stages of lymphocyte development analyzed, suggesting that the HpPG gene is initially expressed before the decision for myeloid-lymphoid differentiation. To assess the mechanism for the up-regulatory event, a K562 in vitro megakaryocytic differentiation system was used. Nuclear run-off analyses in this system demonstrated the up-regulation to be under transcriptional control. In addition, the HpPG gene was found to be down regulated during macrophage differentiation of HL60 cells and was also shown to be transcriptionally controlled. These results indicate that there are multiple points of transcriptional regulation of the HpPG gene during differentiation. Furthermore, the factors regulating the gene at these time points are likely to play an important role in the differentiation of granule producing cells and macrophages. ^

Molecular mechanisms of signal transducer and activator of transcription (STAT) protein function in hematopoiesis

Hematopoietic growth factors play important roles in regulating blood cell growth and development in vivo. In this work, we investigated the signaling mechanisms of two growth factors with clinical significance, erythropoietin (Epo) and granulocyte colony-stimulating factor (G-CSF). Epo is essential for the survival, proliferation and differentiation of red blood cell progenitors, while G-CSF plays an important role in controlling mature neutrophil production. To identify which amino acid(s) and/or motif in EpoR is responsible for cell survival, wild type or mutant EpoR isoforms were transfected into the growth factor-dependent 32D cell line. Proliferation and apoptosis assays demonstrated that an EpoR isoform that lacks intracellular tyrosine residues and is truncated after 321 amino acids in the cytoplasmic tail (EpoR 1-321) mediates Epo-dependent cell survival. Furthermore, in absence of fetal calf serum (FCS), Epo signaling through wild type or mutant receptors supported anti-apoptosis, but not proliferation during 72 hours in response to Epo. To investigate the signaling pathway by which EpoR regulates cell survival, a dominant negative Stat5b (dnStat5b) isoform was generated and coexpressed with EpoR in stable cell lines. Expression of dnStat5b causes a significant induction of apoptosis in the presence of Epo in cells expressing EpoR 1-321, indicating that Stat5 is essential for survival signaling through tyrosine independent sequences in the EpoR. In a second project to investigate G-CSF signaling, we studied mechanisms by which G-CSF regulates the expression of PU.1, an important transcription factor in myeloid and B cell development. We demonstrated, by immunoblot and real time RT-PCR, that PU.1 is induced by G-CSF ex vivo as well as in vivo. To test whether G-CSF signaling through Stat3 is required for PU.1 regulation, the upstream region of the PU.1 gene was analyzed for potential Stat3 binding motifs. Four potential sites were identified; chromatin immunoprecipitations demonstrated that G-CSF activated Stat3 binds to 3 of the 4 binding motifs. In addition, PU.1 induction by G-CSF was completely abrogated in bone marrow from hematopoietic conditional Stat3 knockout mice. These results indicate an important role for Stat3 in G-CSF-dependent PU.1 gene regulation. Collectively, our works demonstrate that Stat protein play important and diverse roles in hematopoietic growth factor signaling. ^