Antagonism between C/EBPbeta and FOG in eosinophil lineage commitment of multipotent hematopoietic progenitors.

The commitment of multipotent cells to particular developmental pathways requires specific changes in their transcription factor complement to generate the patterns of gene expression characteristic of specialized cell types. We have studied the role of the GATA cofactor Friend of GATA (FOG) in the differentiation of avian multipotent hematopoietic progenitors. We found that multipotent cells express high levels of FOG mRNA, which were rapidly down-regulated upon their C/EBPbeta-mediated commitment to the eosinophil lineage. Expression of FOG in eosinophils led to a loss of eosinophil markers and the acquisition of a multipotent phenotype, and constitutive expression of FOG in multipotent progenitors blocked activation of eosinophil-specific gene expression by C/EBPbeta. Our results show that FOG is a repressor of the eosinophil lineage, and that C/EBP-mediated down-regulation of FOG is a critical step in eosinophil lineage commitment. Furthermore, our results indicate that maintenance of a multipotent state in hematopoiesis is achieved through cooperation between FOG and GATA-1. We present a model in which C/EBPbeta induces eosinophil differentiation by the coordinate direct activation of eosinophil-specific promoters and the removal of FOG, a promoter of multipotency as well as a repressor of eosinophil gene expression.

Distinct C/EBP functions are required for eosinophil lineage commitment and maturation.

Hematopoietic differentiation involves the commitment of multipotent progenitors to a given lineage, followed by the maturation of the committed cells. To study the transcriptional events controlling these processes, we have investigated the role of C/EBP proteins in lineage choice of multipotent hematopoietic progenitors (MEPs) transformed by the E26 virus. We found that forced expression of either the alpha or beta isoforms of C/EBP in MEPs induced eosinophil differentiation and that in addition, C/EBPbeta could induce myeloid differentiation. Conversely, dominant-negative versions of C/EBPbeta inhibited myeloid differentiation. C/EBP-induced eosinophil differentiation could be separated into two distinct events, lineage commitment and maturation. Thus, eosinophils induced by transactivation-deficient C/EBPbeta alleles were found to be blocked in their maturation, whereas those expressing wild-type C/EBP proteins were not. Likewise, a 1-day activation of a conditional C/EBPbeta allele in multipotent progenitors led to the formation of immature eosinophils, whereas sustained activation produced mature eosinophils. These results show that C/EBP can induce both myeloid and eosinophil lineage commitment and that transactivation independent and dependent C/EBP functions are required during eosinophil lineage commitment and maturation, respectively.

Regulation of eosinophil-specific gene expression by a C/EBP-Ets complex and GATA-1.

The EOS47 antigen is an early and specific marker of eosinophil differentiation in the chicken haematopoietic system. To elucidate the transciptional events controlling commitment to the eosinophil lineage, we studied the regulation of the eosinophil-specific EOS47 promoter. This promoter is TATA-less, and binds trancription factors of the Ets, C/EBP, GATA and Myb families. These sites are contained within a 309 bp promoter fragment which is sufficient for specific high level transcription in an eosinophil cell line. Co-transfection experiments in Q2bn fibroblasts showed cooperative activation of the EOS47 proximal promoter by c-Myb, Ets-1/Fli-1, GATA-1 and C/EBPalpha. The Ets-1/Fli-1 and C/EBPalpha proteins were the most potent activators, and acted with high synergy through juxtaposed binding sites located approximately 60 bp upstream of the transcription start site. The Ets-1 and C/EBPalpha proteins were found to associate physically via their DNA-binding domains and to bind their combined binding site cooperatively. GATA-1 showed biphasic regulation of the EOS47 promoter, activating at low and repressing at high protein concentrations. These results demonstrate combinatorial activation of an eosinophil-specific promoter by ubiquitous and lineage-restricted haematopoietic transcription factors. They also indicate that direct interactions between C/EBPs and specific Ets family members, together with GATA-1, are important for eosinophil lineage determination.

Influence of the v-Myb transactivation domain on the oncoprotein's transformation specificity.

The v-myb-containing viruses AMV and E26 induce the proliferation of myelomonocytic cells. The E26 Myb protein, by virtue of its fusion to Ets, is also able to transform multipotent haematopoietic cells (MEPs). We have examined the biological effects of substituting the v-Myb transactivation domain with the strong acidic activator domain from the C-terminus of the HSV-1 VP16 protein. In the absence of Ets, deletion of the transactivation domain destroyed the ability of v-Myb to stimulate transcription and to transform cells, whilst the substitution of the VP16 transactivation domain into v-Myb resulted in a greatly enhanced transactivation potential and altered TATA box binding protein (TBP) binding properties. In spite of these functional differences, the v-Myb VP16 protein regained the ability to transform myeloid cells with the same characteristics as wild type v-Myb. A construct encoding v-Myb VP16 fused to v-Ets was still capable of inducing leukaemia and of transforming both myeloid cells and MEPs in vitro, although the latter cells exhibited an altered phenotype. Our results demonstrate that the transformation of myeloid cells by v-Myb is largely independent of the type and potency of the transactivation domain it contains, whereas transformation of MEPs by the Myb-Ets fusion protein has more stringent transactivation requirements of Myb.

Proposed structure for the DNA-binding domain of the Myb oncoprotein based on model building and mutational analysis.

Myb-related proteins from plants to humans are characterized by a DNA-binding domain which contains two to three imperfect repeats of approximately 50 amino acids each. Based on the evolutionary conservation of specific residues, secondary structural predictions suggest an arrangement of alpha helices homologous to that seen in the homeodomains, members of the helix-turn-helix family of DNA-binding proteins. We have used molecular modelling in conjunction with site-directed mutagenesis to test the feasibility of this structure. We propose that each Myb repeat consists of three alpha helices packed over a hydrophobic core which is built around the three highly conserved tryptophan residues. The C-terminal helix forms part of the helix-turn-helix motif and can be positioned into the major groove of B-form DNA, allowing prediction of residues critical for specificity of interaction. Modelling also allowed positioning of adjacent repeats around the major groove over an 8 bp binding site.

Monoclonal antibodies to novel erythroid differentiation antigens reveal specific effects of oncogenes on the leukaemic cell phenotype.

A panel of new monoclonal antibodies to antigens on the surface of chick erythroid progenitor cells is described. These are characterised with respect to their binding to different classes of normal haemopoietic cells of both the erythroid and myeloid lineages. Using these antibodies, we have examined the phenotype of avian leukaemic cells transformed by retroviruses carrying defined oncogenes. Our data show that these cells, although similar to the normal haematopoietic precursor from which they are derived, aberrantly express certain markers in an oncogene specific manner.

Chicken hematopoietic cells transformed by seven strains of defective avian leukemia viruses display three distinct phenotypes of differentiation.

Chicken hematopoietic cells transformed in vitro and in vivo by seven strains of replication-defective avian leukemia viruses were assayed for the expression of six erythroid and five myeloid differentiation parameters, including differentiation-specific surface antigens as detected by newly developed antisera. The transformed cells were found to display three distinct phenotypes of differentiation. First, cells transformed by AEV resemble erythroblasts. They express heme, globin, carbonic anhydrase and erythrocyte cell surface antigen at low levels, and histone H5 and erythroblast cell surface antigen at high levels. Second, cells transformed by MC29, CMII, OK10 and MH2 viruses have macrophage-like properties. They strongly express Fc receptors, phagocytic capacity and macrophage cell surface antigen, but only weakly express myeloblast cell surface antigen and are negative for ATPase activity. Third, cells transformed by AMV and E26 viruses resemble myeloblasts in that they weakly express Fc receptors, phagocytic capacity and macrophage cell surface antigen but strongly express myeloblast cell surface antigen and ATPase activity. No difference was found between in vitro- and in vivo-transformed cells in the parameters tested. In light of recent genetic and biochemical evidence, we believe that these phenotypes reflect the action of three new types of viral-transforming genes, designated erb (erythroblast), mac (macrophage) and myb (myeloblast).

[Toxaemia of pregnancy and the optic fundus (author's transl)]. / EPH-Gestose und Augenhintergrunnd.

Toxaemia of pregnancy in its various forms is the most dangerous complication of pregnancy. It threatens the life of the mother in up to 30 percent of cases, and of the infant in up to 50 percent of cases. The task of systematic medical examination and advice during pregnancy is the earliest possible diagnosis and treatment of symptoms of toxaemia. Generalised vascular spasms are at least in part responsible for the precipitation of toxaemia. Measurement of the vascular diameter in the retina which shows narrow vessels and tendency to spasms is a large advance in the ophthalmological diagnosis of a developing toxaemia of pregnancy.