Mechanism of erythropoietin action on the erythroid progenitor cells induced from murine erythroleukemia cells (TSA8)

Erythropoietin is a well-known erythroid differentiation and growth factor, but the mechanism of its action is not well understood. In this work, we have examined its mechanism of action on the erythropoietin-responsive murine erythroleukemia cells (TSA8). TSA8 cells become responsive to erythropoietin after induction with DMSO. Stimulatory effects on erythropoietin response are observed with the addition of compounds affecting the cAMP level such as forskolin, phosphodiesterase inhibitor and cholera toxin only in the presence of erythropoietin. cAMP analogues themselves show no stimulatory effect on TSA8 cells, nor does erythropoietin increase cAMP level in the cells. Thus, it is suggested that cAMP does not act as a direct second messenger for signal transduction through erythropoietin receptors, but as a stimulator of the erythropoietin receptor pathway and/or as a second messenger in combination with the receptor pathway. The mechanism for acquisition of responsiveness to growth and differentiation factors of progenitor cells is discussed.     

Factors controlling induction of commitment of murine erythroleukemia (TSA8) cells to CFU-E (colony forming unit-erythroid)

On addition of DMSO, the MEL cell line TSA8 becomes committed into erythroid progenitor cells (CFU-E) which can form differentiated colonies in the presence of erythropoietin. To understand the mechanism of cellular commitment, the number and the affinity of the receptors for erythropoietin were estimated. The affinity of the receptors did not change before or after induction. The number of receptors changed depending on the growth phase, but was not dependent on the addition of the inducer. Thus, the presence of the receptors for erythropoietin may be required, but are not essential for responsiveness to erythropoietin. Further examination of the optimum conditions for commitment suggests that the concomitant actions of induced factor(s) with the receptors may control commitment of TSA8 cells to CFU-E.     

Transmembrane signaling during erythropoietin- and dimethylsulfoxide-induced erythroid cell differentiation

Erythropoietin is a glycoprotein factor which specifically regulates the proliferation and differentiation of erythroid progenitor cells. We have investigated here the biochemical mechanisms of erythroid differentiation on mouse erythroleukemia SKT6 cells which can be induced to differentiate either with erythropoietin or dimethyl sulfoxide (Me2SO). cAMP-elevating agents, such as forskolin and 3-isobutyl-1-methyl-xanthine, caused spontaneous erythroid differentiation, and these agents showed the stimulatory effects on erythropoietin- or Me2SO-induced differentiation. An adenylate cyclase inhibitor, 2',5'-dideoxyadenosine, blocked erythropoietin-induced differentiation. The intracellular cAMP level was rapidly increased by addition of erythropoietin but not by Me2SO. These observations suggest that erythroid differentiation induced by erythropoietin is mediated, at least in part, through the cAMP-dependent pathway. When the effect of erythropoietin and Me2SO on the intracellular Ca2+ level was examined using fura 2, no acute change was observed. Measurements of the levels of inositol 1,4,5-trisphosphate and diacylglycerol following stimulation with erythropoietin or Me2SO showed that phosphatidylinositol turnover did not change significantly after erythropoietin stimulation but decreased gradually after Me2SO induction. Taken together, these results indicate that a complex signaling network including the cAMP-dependent pathway is involved in the erythroid differentiation process.     

Stage-specific gene expression in erythroid progenitor cells (CFU-E)

In erythropoietic differentiation, mature red blood cells are generated from specific progenitor cells through the action of specific growth regulatory molecules. To know the mechanism of differentiation, it is important to examine the control of gene expression in these progenitor cells in combination with growth regulatory molecules. We have cloned two genes expressing at a maximal level in the CFU-E (colony forming unit-erythroid), one of the erythroid progenitor cells from novel murine erythroleukemia (MEL) cell line (TSA8) which can be induced to CFU-E in vitro. The expression of these genes is well correlated with the appearance of CFU-E during induction of TSA8 cells, and is higher in the CFU-E-cells enriched from mouse fetal livers than in the more differentiated erythroid cells. Combining these with our previous results, it is suggested that in the erythropoiesis the progenitor cells have distinct patterns of gene expression. This expression is replaced through each progenitor cell rather than by the continuous increase in the expression of a set of genes specific to the mature erythroid cell following the commitment process.     

Induction of commitment of murine erythroleukemia cells (TSA8) to CFU-E with DMSO

The commitment of novel mouse erythroleukemic (MEL) cells (TSA8) to colony-forming units of erythroid (CFU-E) by dimethylsulfoxide (DMSO) was investigated. After exposure to the inducer in liquid culture, the cells were transferred to a semi-solid culture to examine their ability to form erythroid colonies which were dependent on erythropoietin. Exposure to DMSO for 2 days is optimum for CFU-E type colony formation and colonies induced in this manner are equivalent to CFU-E. The induction occurred in a synchronous manner. Partly stained colonies appeared prior to CFU-E formation and are thought to be a result of asymmetric cell division. Appearance of these partly stained colonies suggested that the number of erythropoietin receptors is important in the complete responsiveness to erythropoietin. TSA8 cells constitute a suitable model system in which to analyse the mechanism of commitment in early erythropoiesis.     

Differentiation of erythroid progenitor (CFU-E) cells from mouse fetal liver cells and murine erythroleukemia (TSA8) cells without proliferation.

Erythropoietin (epo) appears to play a significant role in influencing the proliferation and differentiation of erythroid progenitor (CFU-E) cells. To determine the mechanism of action of epo, the effect of drugs on the in vitro colony formation of CFU-E cells induced from a novel murine erythroleukemia cell line, TSA8, was examined. While cytosine arabinoside inhibited colony formation and terminal differentiation of the CFU-E cells responding to epo, herbimycin, which is a drug that inhibits src-related phosphorylation, inhibited colony formation only. The same effect of herbimycin was observed with normal CFU-E cells from mouse fetal liver cells. These results suggest that epo induces two signals, one for proliferation and the other for differentiation, and that the two signals are not linked in erythroid progenitor cells.     

Src transduces erythropoietin-induced differentiation signals through phosphatidylinositol 3-kinase

In this study, we examined the molecular mechanism of erythropoietin-initiated signal transduction of erythroid differentiation through Src and phosphatidylinositol 3-kinase (PI3-kinase). Antisense oligonucleotides against src but not lyn inhibited the formation of erythropoietin-dependent colonies derived from human bone marrow cells and erythropoietin-induced differentiation of K562 human erythroleukaemia cells. Antisense p85alpha oligonucleotide or LY294002, a selective inhibitor of PI3-kinase, independently inhibited the formation of erythropoietin-dependent colonies. In K562 cells, Src associated with PI3-kinase in response to erythropoietin. Antisense src RNA expression in K562 cells inhibited the erythropoietin-induced activation of PI3-kinase and its association with erythropoietin receptor. PP1, a selective inhibitor of the Src family, reduced erythropoietin-induced tyrosine phosphorylation of erythropoietin receptor and its association with PI3-kinase in F-36P human erythroleukaemia cells. The coexpression experiments and in vitro kinase assay further demonstrated that Src directly tyrosine-phosphorylated erythropoietin receptor, and associated with PI3-kinase. In vitro binding experiments proved that glutathione S-transferase-p85alpha N- or C-terminal SH2 domains independently bound to erythropoietin receptor, which was tyrosine-phosphorylated by Src. Taken together, Src transduces the erythropoietin-induced erythroid differentiation signals by regulating PI3-kinase activity.     

Combined action of c-kit and erythropoietin on erythroid progenitor cells.

Mutations at the murine dominant-white spotting locus (W) (c-kit) affect various aspects of hematopoiesis. We have made antibodies against c-Kit with the synthetic peptides deduced from the murine c-kit gene and examined the role of c-Kit in erythropoiesis. The antibody inhibited the stromal cell-dependent large colony formation of the erythroid progenitors. In the culture of erythropoietin-responsive erythroid progenitors of the anemia-inducing Friend virus-infected mouse spleen, the antibody inhibited only proliferation, but not differentiation of the progenitor cells. The inhibition was effective only at the early phase (within 6 hours after erythropoietin addition) before the cells start to proliferate induced by erythropoietin. During the early phase, erythropoietin down-regulated c-kit gene expression. These results suggest a mechanism of combined action of c-Kit with erythropoietin on the lineage-restricted erythroid progenitor cells.     

Activation of erythropoietin signaling by receptor dimerization

The hormone erythropoietin (Epo) is essential for red blood cell development. Epo binds a high affinity receptor on the surface of erythroid progenitor cells, stimulating receptor dimerization and activation of the intracellular signal transduction pathways that support erythroid cell survival, proliferation and differentiation. Biochemical and structural analysis of the erythropoietin receptor (EpoR) is revealing the molecular mechanisms of EpoR function, leading the way to the development of small molecule Epo mimetics. This review focuses on the role EpoR dimerization plays in receptor function.     

The action of erythropoietin is mediated by lipoxygenase metabolites in murine fetal liver cells

Erythroid progenitor cells synthesize 12-hydroxyeicosatetraenoic acid (12-HETE) and 15-hydroxyeicosatetraenoic acid (15-HETE) when stimulated by erythropoietin (Ep). Maximal stimulation of 12-HETE production occurred at one hour, whereas 15-HETE activity remained constant in response to Ep for 24 hours. Lipoxygenase-selective inhibitors of arachidonic acid metabolism blocked HETE production and Ep-stimulated growth and differentiation of erythroid progenitor cell-derived colonies (CFU-E). On the other hand, specific inhibitors of cyclooxygenase (aspirin and meclofenamate) did not significantly inhibit Ep-induced erythroid colony formation. It is hypothesized that the stimulation of HETE production from arachidonic acid (AA) is an essential step in the mechanism of action of Ep.     

Microenvironment created by stromal cells is essential for a rapid expansion of erythroid cells in mouse fetal liver

Mouse stromal cell lines (FLS lines), established from the livers of 13-day gestation mouse fetus, supported the proliferation and differentiation of the erythroid progenitor cells from mouse fetal livers and bone marrow in a semisolid medium in the presence of erythropoietin. A large erythroid colony of over 1000 benzidine-positive erythroid cells was developed from a single erythroid progenitor cell on the FLS cell layer after 4 days of culture. When in close contact with the layer, the erythroid progenitor cells divided rapidly with an average generation time of 9.6 h and mature erythroid cells, including enucleated erythrocytes, were produced. The present studies demonstrate that the microenvironment created by the stromal cells can support the rapid expansion of erythropoietic cell population in the fetal liver of mice.     

HS1 interacts with Lyn and is critical for erythropoietin-induced differentiation of erythroid cells

Erythroid cells terminally differentiate in response to erythropoietin binding its cognate receptor. Previously we have shown that the tyrosine kinase Lyn associates with the erythropoietin receptor and is essential for hemoglobin synthesis in three erythroleukemic cell lines. To understand Lyn signaling events in erythroid cells, the yeast two-hybrid system was used to analyze interactions with other proteins. Here we show that the hemopoietic-specific protein HS1 interacted directly with the SH3 domain of Lyn, via its proline-rich region. A truncated HS1, bearing the Lyn-binding domain, was introduced into J2E erythroleukemic cells to determine the impact upon responsiveness to erythropoietin. Truncated HS1 had a striking effect on the phenotype of the J2E line-the cells were smaller, more basophilic than the parental proerythoblastoid cells and had fewer surface erythropoietin receptors. Moreover, basal and erythropoietin-induced proliferation and differentiation were markedly suppressed. The inability of cells containing the truncated HS1 to differentiate may be a consequence of markedly reduced levels of Lyn and GATA-1. In addition, erythropoietin stimulation of these cells resulted in rapid, endosome-mediated degradation of endogenous HS1. The truncated HS1 also suppressed the development of erythroid colonies from fetal liver cells. These data show that disrupting HS1 has profoundly influenced the ability of erythroid cells to terminally differentiate.     

Rapid activation by erythropoietin of protein kinase C in nuclei of erythroid progenitor cells

The glycoprotein hormone erythropoietin (Ep) regulates the proliferation and differentiation of erythroid progenitor cells by a signal transduction system which is not well understood. It has recently been reported that prolactin, a mitogen and trophic hormone for liver, will activate a nuclear protein kinase C in hepatocytes. As similarities exist in the actions of Ep and prolactin in their target cells, we tested the hypothesis that Ep could activate protein kinase C in nuclei isolated from erythroid progenitor cells. In a pure population of such nuclei, Ep induced a rapid, time- and dose-dependent increase in phosphorylation of endogenous nuclear substrate which could be blocked by inhibitors of protein kinase C or by antibody to Ep. Other known activators of protein kinase C were also effective in this system. These findings show that Ep may exert its effects by a novel signalling pathway, the activation of a nuclear protein kinase C.     

The expression and synthesis of the band 3 protein initiates the formation of a stable membrane skeleton in murine Rauscher-transformed erythroid cells.

While the temporal sequences of the synthesis and assembly of membrane skeletal proteins has been studied during erythroid maturation, relatively little is known about the events which initiate the assembly of membrane skeleton at the early stages of mammalian erythroid commitment. To investigate the early events that initiate the assembly of the membrane skeleton in mammalian erythroid cells, we have studied the synthesis and assembly of membrane skeletal proteins in murine Rauscher erythroleukemia virus-transformed cells. These cells are blocked in differentiation at around the early progenitor (burst forming unit-erythroid, BFUe) cell stage but can be induced to differentiate in vitro. Pulse-labeling studies reveal that Rauscher cells actively synthesize alpha spectrin, beta spectrin, ankyrin and band 4.1 proteins. However, the synthesis of the band 3 protein and its mRNA are barely detectable in these cells. The peripheral membrane skeletal components assemble only transiently in the membrane skeleton and turn over rapidly, resulting in about 20-fold lower steady state levels than are found in mature erythrocytes. Upon induction with erythropoietin and dimethyl sulfoxide, the mRNA level and synthesis of band 3 are increased about 50-fold. In contrast, the synthesis of spectrin, ankyrin and band 4.1 is increased only about 1.5 to 2.0-fold. However, after induction, the fraction of these proteins assembled on the membrane is increased, their half-lives on the membrane are nearly doubled with a concomitant 4 to 5-fold increase in their steady-state levels. These results suggest that the synthesis of peripheral membrane proteins is detected at the earliest stages of erythroid commitment and increases only slightly during further differentiation.(ABSTRACT TRUNCATED AT 250 WORDS)