ROLES OF THE JAK PATHWAY IN FOLLICULAR PATTERNING IN DROSOPHILA

The JAK-STAT pathway is an intracellular signaling pathway that is found to have crucial roles in hematopoiesis, immune response and the development of many other tissues in mammals. The pathway is conserved in Drosophila melanogaster, and is much simpler: there is only one Drosophila JAK (Hopscotch, Hop) and STAT (STAT92E) respectively, while there are at least 4 JAKs and 7 STATs in mammals. The pathway has been intensively studied in Drosophila, and has been implicated in many tissue development and cellular processes. In this work, I present several roles of JAK signaling in oogenesis.First, JAK signaling is required for cell differentiation within a specific lineage of follicle cells – stalk cells and polar cells. Unpaired (upd), which encodes the known ligand for the pathway, is expressed specifically in the polar cells in the developing egg. Reduced function of Upd or Hop results in fusions of egg chambers, which is primarily caused by improper formation of stalk cells, while general activation of the pathway in the egg chamber produces an extra number of stalk cells and sometimes eliminates polarfollicle cells. Based on the known function of the Notch pathway in oogenesis, we propose a model that Notch signaling determines a pool of precursors for the polar and stalk cells while JAK activity determines their specific fates within that pool.Second, JAK signaling is also involved in epithelial follicle cell differentiation. Consistent with the expression pattern of upd in the ovary, there is a gradient of JAK activity expanding from the poles, and this JAK activation gradient is both required and sufficient to suppress the main body follicle cell fate. Also, different levels of JAK activity are required and sufficient to determine both anterior and posterior terminal follicle cell fates. Consistent with these data is a model that a gradient of JAK activity triggered by Upd from the poles pre-patterns the epithelium into three domains and pre-determines sub-populations of terminal follicle cell fates prior to the EGFR activation, and cooperates with EGFR activity later to define posterior terminal follicle cell fates. This provides the first evidence for a morphogenic function of the JAK-STAT pathway in any organism

Two Drosophila suppressors of cytokine signaling (SOCS) differentially regulate JAK and EGFR pathway activities

BACKGROUND: The Janus kinase (JAK) cascade is an essential and well-conserved pathway required to transduce signals for a variety of ligands in both vertebrates and invertebrates. While activation of the pathway is essential to many processes, mutations from mammals and Drosophila demonstrate that regulation is also critical. The SOCS (Suppressor Of Cytokine Signaling) proteins in mammals are regulators of the JAK pathway that participate in a negative feedback loop, as they are transcriptionally activated by JAK signaling. Examination of one Drosophila SOCS homologue, Socs36E, demonstrated that its expression is responsive to JAK pathway activity and it is capable of downregulating JAK signaling, similar to the well characterized mammalian SOCS. RESULTS: Based on sequence analysis of the Drosophila genome, there are three identifiable SOCS homologues in flies. All three are most similar to mammalian SOCS that have not been extensively characterized: Socs36E is most similar to mammalian SOCS5, while Socs44A and Socs16D are most similar to mammalian SOCS6 and 7. Although Socs44A is capable of repressing JAK activity in some tissues, its expression is not regulated by the pathway. Furthermore, Socs44A can enhance the activity of the EGFR/MAPK signaling cascade, in contrast to Socs36E. CONCLUSIONS: Two Drosophila SOCS proteins have some overlapping and some distinct capabilities. While Socs36E behaves similarly to the canonical vertebrate SOCS, Socs44A is not part of a JAK pathway negative feedback loop. Nonetheless, both SOCS regulate JAK and EGFR signaling pathways, albeit differently. The non-canonical properties of Socs44A may be representative of the class of less characterized vertebrate SOCS with which it shares greatest similarity

Bmi1 maintains the self-renewal property of innate-like B lymphocytes

The self-renewal ability is a unique property of fetal-derived innate-like B-1a lymphocytes, which survive and function without being replenished by bone marrow (BM) progenitors. However, the mechanism by which IgM-secreting mature B-1a lymphocytes self-renew is poorly understood. In this study, we showed that Bmi1 was critically involved in this process. Although Bmi1 is considered essential for lymphopoiesis, the number of mature conventional B cells was not altered when Bmi1 was deleted in the B cell lineage. In contrast, the number of peritoneal B-1a cells was significantly reduced. Peritoneal cell transfer assays revealed diminished self-renewal ability of Bmi1-deleted B-1a cells, which was restored by additional deletion of Ink4-Arf, the well-known target of Bmi1 Fetal liver cells with B cell-specific Bmi1 deletion failed to repopulate peritoneal B-1a cells, but not other B-2 lymphocytes after transplantation assays, suggesting that Bmi1 may be involved in the developmental process of B-1 progenitors to mature B-1a cells. Although Bmi1 deletion has also been shown to alter the microenvironment for hematopoietic stem cells, fat-associated lymphoid clusters, the reported niche for B-1a cells, were not impaired in Bmi1 -/- mice. RNA expression profiling suggested lysine demethylase 5B (Kdm5b) as another possible target of Bmi1, which was elevated in Bmi1-/- B-1a cells in a stress setting and might repress B-1a cell proliferation. Our work has indicated that Bmi1 plays pivotal roles in self-renewal and maintenance of fetal-derived B-1a cells

A Phyllopod-Mediated Feedback Loop Promotes Intestinal Stem Cell Enteroendocrine Commitment in Drosophila

Summary: The intestinal epithelium in the Drosophila midgut is maintained by intestinal stem cells (ISCs), which are capable of generating both enterocytes and enteroendocrine cells (EEs) via alternative cell fate specification. Activation of Delta-Notch signaling directs ISCs for enterocyte generation, but how EEs are generated from ISCs remains poorly understood. Here, we identified Phyllopod (Phyl) as a key regulator that drives EE generation from ISCs. Phyl, which is normally suppressed by Notch, functions as an adaptor protein that bridges Tramtrack 69 (Ttk69) and E3 ubiquitin ligase Sina for degradation. Degradation of Ttk69 allows the activation of the Achaete-Scute Complex (AS-C)-Pros regulatory axis, which promotes EE specification. Interestingly, expression of AS-C genes in turn further induces Phyl expression, thereby establishing a positive feedback loop for continuous EE fate specification and commitment. This positive feedback circuit-driven regulatory mechanism could represent a common strategy for reliable and irreversible cell fate determination from progenitor cells

ORIGINAL ARTICLE

www.nature.com/cr npg EGFR and Notch signaling respectively regulate proliferative activity and multiple cell lineage differentiation of Drosophila gastric stem cell