Role of Pumilio proteins during neural crest development

The neural crest (NC) is a multipotent stem cell‐like population, unique to vertebrates, that is characterized by its migratory behavior and broad ability to differentiate into many diverse derivatives including elements of the cardiovascular system, bone and cartilage of the face, the peripheral nervous system, and melanocytes. After neurulation, neural crest cells (NCC) delaminate, undergo EMT from the neural tube, and migrate both individually and collectively as chains. Various developmental diseases, including craniofacial abnormalities and neural crest‐derived cancers such as melanoma arise due to improper development of NC. While there has been much focus on transcriptional mechanisms in regulation of neural crest specification, the process of cell migration involves rapid changes that likely require post‐transcriptional regulation. In order to uncover novel proteins that might influence NC development, we have performed transcriptional profiling of migrating neural crest cells and found >300 genes that are upregulated in the migrating crest including the sequence specific RNA binding protein Pumilio1 (PUM1). PUM proteins are evolutionarily conserved translational regulators that play essential roles during germline development in both invertebrates and vertebrates. Here, we showed that pum1 and pum2 mRNA is present in both premigratory and migratory NC. Pum loss of function resulted in depletion of NC cells migrating neural tube. Conversely, over expression led to an increase in numbers of migrating cells. This led us to think about the potential role of PUM proteins in modulating the specification of NC cells. To identify potential NC targets of PUM, we carried out a bioinformatics screen focusing on NC relevant genes across multiple species that possessed a Pumilio Response Element (PRE) in their 3'UTR region. The PRE element, 5’‐UGUANAUA‐3,’ is a highly conserved consensus that PUM proteins recognize in the 3’UTRs of their targets. Interestingly, several neural crest markers possess a PRE, thus representing potential targets regulated by Pumilio during NC development. Investigation of the specific mechanism whereby PUM proteins regulate NC development is currently in progress

Reconstituting regulation of the canonical Wnt pathway by engineering a minimal β-catenin destruction machine

Negatively regulating key signaling pathways is critical to development and altered in cancer. Wnt signaling is kept off by the destruction complex, which is assembled around the tumor suppressors APC and Axin and targets β-catenin for destruction. Axin and APC are large proteins with many domains and motifs that bind other partners. We hypothesized that if we identified the essential regions required for APC:Axin cooperative function and used these data to design a minimal β-catenin-destruction machine, we would gain new insights into the core mechanisms of destruction complex function. We identified five key domains/motifs in APC or Axin that are essential for their function in reconstituting Wnt regulation. Strikingly, however, certain APC and Axin mutants that are nonfunctional on their own can complement one another in reducing β-catenin, revealing that the APC:Axin complex is a highly robust machine. We used these insights to design a minimal β-catenin-destruction machine, revealing that a minimized chimeric protein covalently linking the five essential regions of APC and Axin reconstitutes destruction complex internal structure, size, and dynamics, restoring efficient β-catenin destruction in colorectal tumor cells. On the basis of our data, we propose a new model of the mechanistic function of the destruction complex as an integrated machine

The Conserved MAPK Site in E(spl)-M8, an Effector of Drosophila Notch Signaling, Controls Repressor Activity during Eye Development

The specification of patterned R8 photoreceptors at the onset of eye development depends on timely inhibition of Atonal (Ato) by the Enhancer of split (E(spl) repressors. Repression of Ato by E(spl)-M8 requires the kinase CK2 and is inhibited by the phosphatase PP2A. The region targeted by CK2 harbors additional conserved Ser residues, raising the prospect of regulation via multi-site phosphorylation. Here we investigate one such motif that meets the consensus for modification by MAPK, a well-known effector of Epidermal Growth Factor Receptor (EGFR) signaling. Our studies reveal an important role for the predicted MAPK site of M8 during R8 birth. Ala/Asp mutations reveal that the CK2 and MAPK sites ensure that M8 repression of Ato and the R8 fate occurs in a timely manner and at a specific stage (stage-2/3) of the morphogenetic furrow (MF). M8 repression of Ato is mitigated by halved EGFR dosage, and this effect requires an intact MAPK site. Accordingly, variants with a phosphomimetic Asp at the MAPK site exhibit earlier (inappropriate) activity against Ato even at stage-1 of the MF, where a positive feedback-loop is necessary to raise Ato levels to a threshold sufficient for the R8 fate. Analysis of deletion variants reveals that both kinase sites (CK2 and MAPK) contribute to 'cis'-inhibition of M8. This key regulation by CK2 and MAPK is bypassed by the E(spl)D mutation encoding the truncated protein M8*, which potently inhibits Ato at stage-1 of R8 birth. We also provide evidence that PP2A likely targets the MAPK site. Thus multi-site phosphorylation controls timely onset of M8 repressor activity in the eye, a regulation that appears to be dispensable in the bristle. The high conservation of the CK2 and MAPK sites in the insect E(spl) proteins M7, M5 and Mγ, and their mammalian homologue HES6, suggest that this mode of regulation may enable E(spl)/HES proteins to orchestrate repression by distinct tissue-specific mechanisms, and is likely to have broader applicability than has been previously recognized

The Ser/Thr Phosphatase PP2A Regulatory Subunit Widerborst Inhibits Notch Signaling

Drosophila Enhancer of split M8, an effector of Notch signaling, is regulated by protein kinase CK2. The phosphatase PP2A is thought to play an opposing (inhibitory) role, but the identity of the regulatory subunit was unknown. The studies described here reveal a role for the PP2A regulatory subunit widerborst (wdb) in three developmental contexts; the bristle, wing and the R8 photoreceptors of the eye. wdb overexpression elicits bristle and wing defects akin to reduced Notch signaling, whereas hypomorphic mutations in this PP2A subunit elicit opposite effects. We have also evaluated wdb functions using mutations in Notch and E(spl) that affect the eye. We find that the eye and R8 defects of the well-known Nspl mutation are enhanced by a hypomorphic allele of wdb, whereas they are strongly rescued by wdb overexpression. Similarly, ectopic wdb rescues the eye and R8 defects of the E(spl)D mutation, which affects the m8 gene. In addition, wdb overexpression also rescues the bristle defects of ectopically expressed M8, or the eye and R8 defects of its CK2 phosphomimetic variant M8-S159D. The latter finding suggests that PP2A may target M8 at highly conserved residues in the vicinity of the CK2 site, whose phosphorylation controls repression of Atonal and the R8 fate. Together, the studies identify PP2A-Wdb as a participant in Notch signaling, and suggest that M8 activity is controlled by phosphorylation and dephosphorylation. The conservation of the phosphorylation sites between Drosophila E(spl) and the HES/HER proteins from mammals, reptiles, amphibians, birds and fish raises the prospect that this mode of regulation is widespread

Using Drosophila models and tools to understand the mechanisms of novel human cancer driver gene function

The formation, overgrowth and metastasis of tumors comprise a complex series of cellular and molecular events resulting from the combined effects of a variety of aberrant signaling pathways, mutations, and epigenetic alterations. Modeling this complexity in vivo requires multiple genes to be manipulated simultaneously, which is technically challenging. Here, we analyze how Drosophila research can further contribute to identifying pathways and elucidating mechanisms underlying novel cancer driver (risk) genes associated with tumor growth and metastasis in humans.Work in the authors laboratory is supported by the Spanish Ministry of Economy and Competitiveness and co-financed by FEDER funds (BFU2015-64239-R, the Spanish State Research Agency, through the “Severo Ochoa” Program for Centers of Excellence in R&D (SEV-2013-0317), the Scientific Foundation of the Spanish Association Against Cancer (AECC) (CICPF16001DOMÍ), and the Valencian Regional Government’s Prometeo Programme for research groups of excellence (PROMETEO/2017/146) to M.D.Peer reviewe