Transcription factors of the RUNX and GATA families play key roles in the control of cell fate choice and differentiation, notably in the hematopoietic system. During Drosophila hematopoiesis, the RUNX factor Lozenge and the GATA factor Serpent cooperate to induce crystal cell differentiation. We used Serpent/ Lozenge-activated transcription as a paradigm to identify modulators of GATA/RUNX activity by a genomewide RNA interference screen in cultured Drosophila blood cells. Among the 129 factors identified, several belong to the Mediator complex. Mediator is organized in three modules plus a regulatory "CDK8 module," composed of Med12, Med13, CycC, and Cdk8, which has long been thought to behave as a single functional entity. Interestingly, our data demonstrate that Med12 and Med13 but not CycC or Cdk8 are essential for Serpent/Lozenge-induced transactivation in cell culture. Furthermore, our in vivo analysis of crystal cell development show that, while the four CDK8 module subunits control the emergence and the proliferation of this lineage, only Med12 and Med13 regulate its differentiation. We thus propose that Med12/Med13 acts as a coactivator for Serpent/Lozenge during crystal cell differentiation independently of CycC/Cdk8. More generally, we suggest that the set of conserved factors identified herein may regulate GATA/RUNX activity in mammals.During hematopoiesis, multipotent progenitors or stem cells generate a large spectrum of specialized cell types through the progressive deployment of cell-specific gene expression programs (59). In that respect, it is of particular interest to understand how combinatorial inputs from general and lineage-specific transcription factors converge to modulate RNA polymerase II machinery and establish the gene expression programs intrinsic to cell diversification. Over the last decade, cross-species conservation has shown that Drosophila is a valuable model system to gain insights into the mechanisms controlling blood cell fate choice and differentiation at the transcriptional level (36). Indeed, several key transcription factors and cofactors regulating blood cell development in vertebrates also participate in hematopoiesis in Drosophila.Reminiscent of the situation in vertebrates, hematopoiesis in the fruit fly occurs in two temporally and spatially distinct waves: blood cell progenitors (prohemocytes) arise first from the head mesoderm in the early embryo and then from a specialized organ, the lymph gland, in the larva (36). These progenitors differentiate into two main cell types, most closely related to vertebrate myeloid lineages: plasmatocytes, which function as macrophages, and crystal cells, which participate in melanization and clotting (53). So far, we have a better understanding of the transcriptional network controlling blood cell development in the embryo. In particular, it appears that transcription factors of the GATA and RUNX families, which regulate several steps of hematopoiesis in vertebrates, act together to control Drosophila blood cell fate choice and...
