Differential activation of JAK-STAT signaling reveals functional compartmentalization in Drosophila blood progenitors

To combat infection, the fruit fly Drosophila melanogaster relies on multiple innate defense reactions, many of which are shared with higher organisms. These reactions include the use of physical barriers together with local and systemic immune responses. First, epithelia, such as those beneath the cuticle, in the alimentary tract, and in tracheae, act both as a physical barrier and local defense against pathogens by producing antimicrobial peptides and reactive oxygen species. Second, specialized hemocytes participate in phagocytosis and encapsulation of foreign intruders in the hemolymph. Finally, the fat body, a functional equivalent of the mammalian liver, produces humoral response molecules including antimicrobial peptides. Here we review our current knowledge of the molecular mechanisms underlying Drosophila defense reactions together with strategies evolved by pathogens to evade them.

The mammalian blood system, containing more than 10 distinct mature cell types, stands on one specific cell type, hematopoietic stem cell (HSC). Within the system, only HSCs possess the ability of both multipotency and self-renewal. Multipotency is the ability to differentiate into all functional blood cells. Self-renewal is the ability to give rise to HSC itself without differentiation. Since mature blood cells (MBCs) are predominantly short-lived, HSCs continuously provide more differentiated progenitors while properly maintaining the HSC pool size throughout life by precisely balancing self-renewal and differentiation. Thus, understanding the mechanisms of self-renewal and differentiation of HSC has been a central issue. In this review, we focus on the hierarchical structure of the hematopoietic system, the current understanding of microenvironment and molecular cues regulating self-renewal and differentiation of adult HSCs, and the currently emerging systems approaches to understand HSC biology. © 2010 John Wiley & Sons, Inc.

Reactive Oxygen Species (ROS), produced during various electron transfer reactions in vivo are generally considered to be deleterious to cells1. In the mammalian haematopoietic system, haematopoietic stem cells (HSCs) contain low ROS levels, but unexpectedly, the common myeloid progenitors (CMPs), produce significantly elevated levels of ROS2. The functional significance of this difference in ROS level in the two progenitor types remains unresolved2,3. Here, we show that Drosophila multipotent haematopoietic progenitors which are largely akin to the mammalian myeloid progenitors4 display elevated levels of ROS under in vivo physiological conditions, which is downregulated upon differentiation. Scavenging the ROS from these haematopoietic progenitors using in vivo genetic tools, retards their differentiation into mature blood cells. Conversely, increasing the haematopoietic progenitor ROS beyond their basal level triggers precocious differentiation into all three mature blood cell types found in Drosophila, through a signaling pathway that involves JNK and FoxO activation as well as Polycomb downregulation. We conclude that the developmentally regulated, moderately high ROS level in the progenitor population sensitizes them to differentiation, and establishes a signaling role for ROS in the regulation of haematopoietic cell fate. Our results lead to a model that could be extended to reveal a probable signaling role for ROS in the differentiation of CMPs in mammalian haematopoietic development and oxidative stress response.