Instructive role of M-CSF on commitment of bipotent myeloid cells involves ERK-dependent positive and negative signaling

International audienceM-CSF and G-CSF are instructive cytokines that specifically induce differentiation of bipotent myeloid progenitors into macrophages and granulocytes, respectively. Through morphology and colony assay studies, flow cytometry analysis of specific markers, and expression of myeloid transcription factors, we show here that the Eger/Fms cell line is composed of cells whose differentiation fate is instructed by M-CSF and G-CSF, thus representing a good in vitro model of myeloid bipotent progenitors. Consistent with the essential role of ERK1/2 during macrophage differentiation and defects of macrophagic differentiation in native ERK1(-/-) progenitors, ERK signaling is strongly activated in Eger/Fms cells upon M-CSF-induced macrophagic differentiation but only to a very small extent during G-CSF-induced granulocytic differentiation. Previous in vivo studies indicated a key role of Fli-1 in myeloid differentiation and demonstrated its weak expression during macrophagic differentiation with a strong expression during granulocytic differentiation. Here, we demonstrated that this effect could be mediated by a differential regulation of protein kinase Cdelta (PKCd) on Fli-1 expression in response to M-CSF and G-CSF. With the use of knockdown of PKCd by small interfering RNA, we demonstrated that M-CSF activates PKCd, which in turn, inhibits Fli-1 expression and granulocytic differentiation. Finally, we studied the connection between ERK and PKCd and showed that in the presence of the MEK inhibitor U0126, PKCd expression is decreased, and Fli-1 expression is increased in response to M-CSF. Altogether, we demonstrated that in bipotent myeloid cells, M-CSF promotes macrophagic over granulocytic differentiation by inducing ERK activation but also PKCd expression, which in turn, down-regulates Fli-1 expression and prevents granulocytic differentiatio

Severe Poikilocytosis Associated With A Denovo Alpha-28 Arg-]cys Mutation In Spectrin

Severe poikilocytosis was observed in an Italian child. The mutation responsible was a de novo alpha28 Arg --> Cys substitution (CGT --> TGT) in spectrin, a mutation known to cause hereditary elliptocytosis or hereditary pyropoikilocytosis. In this particular case the severity of the manifestations were accounted for by the occurrence, in trans to the alpha28 mutation, of the alpha(V/41) polymorphism. The latter has been shown previously to be associated with structural abnormalities at the alphaIV-alphaV domain junction and with a low expression level. The pronounced alteration of the dimer self association process was also explained by the location of the alpha28 mutation. This mutation occurs in helix 3 of repeating segment alpha1, e.g. precisely in the head-to-head contact between the spectrin alpha and beta chains. The present phenotype was compared to that yielded by another alpha28 mutation (Arg --> His) also combined, in trans, with the alpha(V/41) polymorphism. The pictures were very much alike, stressing the functional importance of residue alpha28. The de novo character of the present mutation strengthens the view that codon alpha28 is a 'hot spot' for mutations

Activator-mediated recruitment of the MLL2 methyltransferase complex to the beta-globin locus.

International audienceMLL-containing complexes methylate histone H3 at lysine 4 (H3K4) and have been implicated in the regulation of transcription. However, it is unclear how MLL complexes are targeted to specific gene loci. Here, we show that the MLL2 complex associates with the hematopoietic activator NF-E2 in erythroid cells and is important for H3K4 trimethylation and maximal levels of transcription at the beta-globin locus. Furthermore, recruitment of the MLL2 complex to the beta-globin locus is dependent upon NF-E2 and coincides spatio-temporally with NF-E2 binding during erythroid differentiation. Thus, a DNA-bound activator is important initially for guiding MLL2 to a particular genomic location. Interestingly, while the MLL2-associated subunit ASH2L is restricted to the beta-globin locus control region 38 kb upstream of the beta(maj)-globin gene, the MLL2 protein spreads across the beta-globin locus, suggesting a previously undefined mechanism by which an activator influences transcription and H3K4 trimethylation at a distance