Developmental Signals Research Articles

Genome-Wide Analysis and Expression Profiling of Watermelon VQ Motif-Containing Genes Under Abiotic and Biotic Stresses

Valine-glutamine (VQ) motif-containing proteins play important roles in diverse plant developmental processes and signal transduction in response to biotic and abiotic stresses. However, no systematic investigation has been conducted on VQ genes in watermelon. In this study, we identified 31 watermelon VQ genes, which were classified into six subfamilies (I–VI). All of the deduced proteins contained a conserved FxxxVQxL/F/VTG motif. Eleven ClVQs were involved in segment duplication, which was the main factor in the expansion of the VQ family in watermelon. Numerous stress- and hormone-responsive cis-elements were detected in the putative promoter region of the ClVQ genes. Green fluorescent protein fusion proteins for ten selected ClVQs were localized in the nucleus, but three ClVQs also showed signals in cell membranes and the cell wall, thus confirming their predicted divergent functionality. Quantitative real-time PCR (qRT-PCR) analysis indicated that the majority of ClVQ genes were specifically or preferentially expressed in certain tissues or organs, especially in the male flower. Analyses of RNA-sequencing data under osmotic, cold, and drought stresses and Cucumber green mottle mosaic virus (CGMMV) infection revealed that the majority of ClVQ genes, especially those from subfamily IV, were responsive to these stresses. The results provide useful information for the functional characterization of watermelon ClVQ genes to unravel their biological roles.

Maternal obesity alters histone modifications mediated by the interaction between Ezh2 and Ampk, impairing neural differentiation in the developing embryonic brain cortex.

Neurodevelopmental disorders have complex origins that manifest early during embryonic growth and are associated with intricate gene regulation dynamics. A perturbed metabolic environment such as hyperglycemia or dyslipidemia, particularly due to maternal obesity, poses a threat to the optimal development of the embryonic central nervous system. Accumulating evidence suggests that these metabolic irregularities during pregnancy may alter neurogenesis pathways, thereby predisposing the developing fetus to neurodevelopmental disorders. One primary mechanism through which such disruptions may occur involves changes in histone modifications resulting from fluctuations in the expression of histone-modifying enzymes or the availability of their substrates. Herein, we have used a rat model of maternal obesity induced by a high-fat diet (HFD) before and during gestation to investigate the cellular and molecular repercussions of maternal obesity on embryonic cortical neurogenesis. Maternal obesity impairs neurogenesis by reducing cell proliferation, increasing neuronal marker expression, and shifting development toward astrogliogenesis. Differentially expressed genes (DEGs) revealed disruptions in key developmental signaling pathways and reduced Akt phosphorylation, particularly at E14.5. These changes were associated with epigenetic alterations, mainly the differential expression and phosphorylation of Ezh2 and subsequent changes in global histone modifications. ChIP-seq revealed reduced H3K27me3 at genes upregulated due to maternal obesity, which could have resulted from reduced expression and increased phosphorylation of Ezh2 at Thr311. Interestingly, Ezh2 also showed increased O-GlcNAcylation in HFD embryos along with increased association with Ampk-Thr172 in accordance with previous studies showing that Ampk catalyzes Ezh2-Thr311p. These results suggest that an epigenetic gene regulatory mechanism mediated by Ampk and Ezh2 interactions resulted in reduced H3K27me3 and de-repression of key developmental genes, which could have led to cell fate changes observed in the developing embryo brain cortex due to maternal obesity.

A spatiotemporal and machine-learning platform facilitates the manufacturing of hPSC-derived esophageal mucosa.

Human pluripotent stem cell-derived tissue engineering offers great promise for designer cell-based personalized therapeutics, but harnessing such potential requires a deeper understanding of tissue-level interactions. We previously developed a cell replacement manufacturing method for ectoderm-derived skin epithelium. However, it remains challenging to manufacture the endoderm-derived esophageal epithelium despite possessing a similar stratified epithelial structure. Here, we employ single-cell and spatial technologies to generate a spatiotemporal multi-omics cell census for human esophageal development. We identify the cellular diversity, dynamics, and signal communications for the developing esophageal epithelium and stroma. Using Manatee, a machine-learning algorithm, we prioritize the combinations of candidate human developmental signals for invitro derivation of esophageal basal cells. Functional validation of Manatee predictions leads to a clinically compatible system for manufacturing human esophageal mucosa.

Non-cell-autonomous regulation of mTORC2 by Hedgehog signaling maintains lipid homeostasis.

Organisms allocate energetic resources between essential cellular processes to maintain homeostasis and, in turn, maximize fitness. The nutritional regulators of energy homeostasis have been studied in detail; however, how developmental signals might impinge on these pathways to govern metabolism is poorly understood. Here, we identify a non-canonical role for Hedgehog (Hh), a classic regulator of development, in maintaining intestinal lipid homeostasis in Caenorhabditis elegans. We demonstrate, using C.elegans and mouse hepatocytes, that Hh metabolic regulation does not occur through the canonical Hh transcription factor TRA-1/GLI, but rather via non-canonical signaling that engages mammalian target of rapamycin complex 2 (mTORC2). Hh mutants display impaired lipid homeostasis, decreased growth, and upregulation of autophagy factors, mimicking loss of mTORC2. Additionally, we find that Hh inhibits p38 MAPK signaling in parallel to mTORC2 activation to modulate lipid homeostasis. Our findings reveal a non-canonical role for Hh signaling in lipid metabolism via regulation of core homeostatic pathways.

Chloroplast Vesiculation and Induced Chloroplast Vesiculation and Senescence-Associated Gene 12 Expression During Tomato Flower Pedicel Abscission.

Abscission is a tightly regulated process in which plants shed unnecessary, infected, damaged, or aging organs, as well as ripe fruits, through predetermined abscission zones in response to developmental, hormonal, and environmental signals. Despite its importance, the underlying mechanisms remain incompletely understood. This study highlights the deleterious effects of abscission on chloroplast ultrastructure in the cells of the tomato flower pedicel abscission zone, revealing spatiotemporal differential gene expression and key transcriptional networks involved in chloroplast vesiculation during abscission. Significant changes in chloroplast structure and vesicle formation were observed 8 and 14 h after abscission induction, coinciding with the differential expression of vesiculation-related genes, particularly with upregulation of Senescence-Associated Gene 12 (SAG12) and Chloroplast Vesiculation (CV). This suggests a possible vesicle transport of chloroplast degrading material for recycling by autophagy-independent senescence-associated vacuoles (SAVs) and CV-containing vesicles (CCVs). Ethylene signaling appears to be involved in the regulation of these processes, as treatment with a competitive inhibitor of ethylene action, 1-methylcyclopropene, delayed vesiculation, reduced the expression of SAG12, and increased expression of Curvature Thylakoid 1A (CURT1A). In addition, chloroplast vesiculation during abscission was associated with differential expression of photosynthesis-related genes, particularly those involved in light reactions, underscoring the possible functional impact of the observed structural changes. This work provides new insights into the molecular and ultrastructural mechanisms underlying abscission and offers potential new targets for agricultural or biotechnological applications.

Protocol to fluorescently stain vacuoles in Arabidopsis root cells.

Plant vacuoles are essential organelles that respond to developmental and environmental signals. Here, we present a protocol for staining the vacuole lumen in Arabidopsis root cells, enabling precise visualization of vacuolar dynamics. We describe steps for preparing plant material and staining with commonly used fluorescent dyes. We then detail procedures for visualizing vacuoles in the blue, green, and red emission spectra, allowing for their combined use with a variety of compatible fluorescent-tagged protein markers. For complete details on the use and execution of this protocol, please refer to Dubrovsky etal.,1 Fricker,2 Bassil etal.,3 Grzam etal.,4 and Stefano etal.5.

Barcoding Notch signaling in the developing brain.

Developmental signaling inputs are fundamental for shaping cell fates and behavior. However, traditional fluorescent-based signaling reporters have limitations in scalability and molecular resolution of cell types. We present SABER-seq, a CRISPR-Cas molecular recorder that stores transient developmental signaling cues as permanent mutations in cellular genomes for deconstruction at later stages via single-cell transcriptomics. We applied SABER-seq to record Notch signaling in developing zebrafish brains. SABER-seq has two components: a signaling sensor and a barcode recorder. The sensor activates Cas9 in a Notch-dependent manner with inducible control, while the recorder obtains mutations in ancestral cells where Notch is active. We combine SABER-seq with an expanded juvenile brain atlas to identify cell types derived from Notch-active founders. Our data reveal rare examples where differential Notch activities in ancestral progenitors are detected in terminally differentiated neuronal subtypes. SABER-seq is a novel platform for rapid, scalable and high-resolution mapping of signaling activity during development.

The people behind the papers - Alejandro Berrio and David McClay.

Early sea urchin embryos contain cells called micromeres, which play an important role in the formation of three mesodermal cell types: skeletogenic, blastocoelar and pigment cells. When micromeres are removed, the embryo can replace the skeletogenic and blastocoelar cells via a process called 'transfating', whereby other cells in the embryo step in to take on new roles. However, the pigment cells do not reappear, and the reasons for this are unclear. A new paper in Development reveals how the timing of developmental signals can affect transfating outcomes. To learn more about the story behind the paper, we caught up with first author Alejandro Berrio and corresponding author David McClay, the Arthur S. Pearse Professor Emeritus of Biology at Duke University, USA.

Stem Cell-Associated Proteins and Extracellular Matrix Composition of the Human Atrioventricular Junction.

The human heart regenerates slowly through life, but how new cells are generated is mostly unknown. The atrioventricular junction (AVj) has been indicated as a potential stem cell niche region. Little is known about the protein composition of the human AVj. To map the extracellular matrix (ECM) and expression of stem cell-related biomarkers, this study compares protein and gene expression patterns in AVj and Left Ventricular (LV) tissues. Biopsies were collected from 15 human hearts. Global quantitative proteomics and mRNA sequencing were used to identify differentially expressed proteins and altered genes. Of the total 4904 identified proteins, 1138 were differently expressed between the AVj and LV. While the top proteins in LV were involved in cardiac motor function and energy regulation, the AVj displayed proteins associated with early cardiomyocyte development, differentiation, proliferation, migration, and hypoxia. Furthermore, several developmental signalling pathways, including TGF-β, TNF, WNT, Notch, and FGF, were represented. RNA-seq data verified that the expressed genes were involved with differentiation, cell growth, proliferation, or ECM organization. Immunohistochemistry confirmed the expression of the stem cell-related biomarkers NPPA and POSTN in the AVj, further strengthening the hypothesis of the AVj as a specialized microenvironment conducive to stem cell niche activity.

Fetal Tracheal Occlusion Corelates with Normalized YAP Expression and Alveolar Epithelial Differentiation in CDH.

Congenital diaphragmatic hernia (CDH) is characterized by incomplete closure of the diaphragm. While the ensuing compression to the fetal lung causes lung hypoplasia, specific cellular phenotypes and developmental signaling defects in the alveolar epithelium in CDH are not fully understood. Employing lung samples from human CDH, a surgical lamb model and a nitrogen rat model, we investigate whether lung compression impairs alveolar epithelial differentiation and Yes-associated protein (YAP)-mediated mechanosensing. We showed that CDH in humans and lambs caused defective alveolar epithelial differentiation manifested by more abundant ATII cells, fewer ATI cells, and the emergence of cells expressing both ATI and ATII markers. Associated with the alveolar epithelial defects, we found a decrease in the level and nuclear localization of YAP. Reduced nuclear YAP and abnormal distal lung development were evident as early as 21 weeks in gestation in human CDH. In addition, rat fetuses with CDH also showed diminished nuclear YAP and mor abundant ATII cells. In contrast, the littermates without the hernia had no such alveolar phenotypes. Furthermore, fetal tracheal occlusion (TO) in the surgical lamb model of CDH fully normalized nuclear YAP and rescued alveolar epithelial defects in a gestational age-dependent manner. Taken together, our findings across species indicate that lung compression in CDH is sufficient to disrupt alveolar epithelial differentiation and impair YAP signaling. TO can restore nuclear YAP and rescue the alveolar defects in CDH, depending on the timing and the duration of this prenatal surgical intervention. This article is open access and distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivatives License 4.0 (http://creativecommons.org/licenses/by-nc-nd/4.0/).

Annexins: central regulators of plant growth and stress signaling.

Annexins are a family of multifunctional calcium-dependent and phospholipid-binding proteins that are widely distributed in the plant kingdom. They have a highly conserved evolutionary history that dates back to single-celled protists. Plant annexins, as soluble proteins, can flexibly bind to endomembranes and plasma membranes, exhibiting unique calcium-dependent and calcium-independent characteristics. Members of the annexin family have diverse functions, including binding to F-actin, participating in ATP and GTP hydrolysis, and even serving as peroxidases or cation channels. Annexins play pivotal roles in plant growth and stress signaling. They can respond sensitively to environmental, metabolic, and developmental signals, thereby affecting cytoskeleton remodeling and exocytosis mechanisms. Plant annexin gene families have been successfully identified in multiple species, and their expression and intracellular localization are precisely regulated by developmental processes and environmental factors. Although research on plant annexins has aroused great interest, their depth and breadth still need further expansion compared with those of animal annexins. This article provides a comprehensive and in-depth review of the characteristics and functions of plant annexin families, revealing their core roles in plant growth and adaptation, and yielding valuable references and insights for future research.

Reading m6A marks in mRNA: A potent mechanism of gene regulation in plants.

Modifications to RNA have recently been recognized as a pivotal regulator of gene expression in living organisms. More than 170 chemical modifications have been identified in RNAs, with N6-methyladenosine (m6A) being the most abundant modification in eukaryotic mRNAs. The addition and removal of m6A marks are catalyzed by methyltransferases (referred to as "writers") and demethylases (referred to as "erasers"), respectively. In addition, the m6A marks in mRNAs are recognized and interpreted by m6A-binding proteins (referred to as "readers"), which regulate the fate of mRNAs, including stability, splicing, transport, and translation. Therefore, exploring the mechanism underlying the m6A reader-mediated modulation of RNA metabolism is essential for a much deeper understanding of the epigenetic role of RNA modification in plants. Recent discoveries have improved our understanding of the functions of m6A readers in plant growth and development, stress response, and disease resistance. This review highlights the latest developments in m6A reader research, emphasizing the diverse RNA-binding domains crucial for m6A reader function and the biological and cellular roles of m6A readers in the plant response to developmental and environmental signals. Moreover, we propose and discuss the potential future research directions and challenges in identifying novel m6A readers and elucidating the cellular and mechanistic role of m6A readers in plants.

Catalytically inactive subgroup VIII receptor-like cytoplasmic kinases regulate the immune-triggered oxidative burst in Arabidopsis thaliana.

Protein kinases are key components of multiple cell signaling pathways. Several receptor-like cytoplasmic kinases (RLCKs) have demonstrated roles in immune and developmental signaling across various plant species, making them of interest in the study of phosphorylation-based signal relay. Here, we present our investigation of a subgroup of RLCKs in Arabidopsis thaliana. Specifically, we focus on subgroup VIII RLCKs: MAZ and its paralog CARK6, as well as CARK7 and its paralog CARK9. We found that both MAZ and CARK7 associate with the calcium-dependent protein kinase CPK28 in planta, and furthermore that CPK28 phosphorylates both MAZ and CARK7 on multiple residues in areas that are known to be critical for protein kinase activation. Genetic analysis suggests redundant roles for MAZ and CARK6 as negative regulators of the immune-triggered oxidative burst. We find evidence that supports homo- and hetero-dimerization between CARK7 and MAZ, which may be a general feature of this subgroup. Multiple biochemical experiments suggest that neither MAZ nor CARK7 demonstrate catalytic protein kinase activity in vitro. Interestingly, we find that a mutant variant of MAZ incapable of protein kinase activity can complement maz-1 mutants, suggesting noncatalytic roles of MAZ in planta. Overall, our study identifies subgroup VIII RLCKs as new players in Arabidopsis immune signaling and highlights the importance of noncatalytic functions of protein kinases.

Temporal Ablation of the Ciliary Protein IFT88 Alters Normal Brainwave Patterns.

The primary cilium is a hair-like organelle that hosts molecular machinery for various developmental and homeostatic signaling pathways. Its alteration can cause rare ciliopathies such as the Bardet-Biedl and Joubert syndromes, but is also linked to Alzheimer's disease, clinical depression, and autism spectrum disorder. These afflictions are caused by disturbances in a wide variety of genes but a common phenotype amongst them is cognitive impairment. While cilia-mediated neural function has been widely examined in early neurodevelopment, their function in the adult brain is not well understood. To help elucidate the role of cilia in neural activity, we temporally induced the ablation of IFT88, a gene encoding the intraflagellar transport 88 protein which is neccessary for ciliogenesis, in adult mice before performing memory-related behavioral assays and electroencephalogram/electromyogram (EEG/EMG) recordings. Inducible IFT88 KO mice exhibited severe learning deficits in trace fear conditioning and Morris water maze tests. They had strongly affected brainwave activity both under isoflurane induced anesthesia and during normal activity. And additionally, inducible IFT88 KO mice had altered sleep architecture and attenuated phase-amplitude coupling, a process that underlies learning and memory formation. These results highlight the growing significance of primary cilia for healthy neural function in the adult brain.

A Chemically Defined Culture for Tooth Reconstitution.

It is known for decades that dental epithelium and mesenchyme can reconstitute and regenerate a functional tooth. However, the mechanism of tooth reconstitution remains largely unknown due to the lack of an efficient in vitro model. Here, a chemically defined culture system is established that supports tooth reconstitution, further development with normal anatomy, and prompt response to chemical interference in key developmental signaling pathways, termed as toothoids. By using such a system, it is discovered that, during reconstitution, instead of resetting the developmental clock, dental cells reorganized and restarted from the respective developmental stage where they are originally isolated. Moreover, co-stimulation of Activin A and Hedgehog/Smoothened agonist (SAG) sustained the initial induction of tooth fate from the first branchial arch, which would be otherwise quickly lost in culture. Furthermore, activation of Bone Morphogenetic Protein (BMP) signaling triggered efficient enamel formation in the late-stage toothoids, without affecting the normal development of ameloblasts. Together, these data highlight the toothoid culture as a powerful tool to dissect the molecular mechanisms of tooth reconstitution and regeneration.

Acetoin Promotes Plant Growth and Alleviates Saline Stress by Activating Metabolic Pathways in Lettuce Seedlings.

Acetoin is a volatile organic compound, which is a class of metabolites produced by plant growth-promoting rhizobacteria. The mechanisms underlying plant growth promotion by acetoin and its potential to induce saline stress tolerance in plants are poorly understood. Lettuce (Lactuca sativa L. var. ramosa Hort.) seedlings in hydronics and pots under non-saline or saline conditions were foliar-sprayed with 10 mL of 0 or 1 mg·mL-1 acetoin at 7 and 14 d after transplantation and harvested 7 d after the second spray. Shoots and roots of hydroponic lettuce seedlings were harvested at 6 and 24 h after treatment for RNA sequencing. Seedlings sprayed with acetoin showed more vigorous growth, with higher shoot and root biomass than those of the controls, in both hydronic and pot modes. The transcriptomic analysis revealed acetoin application resulted in 177 differentially expressed genes (39 upregulated and 138 downregulated) in shoots and 397 differentially expressed genes (112 upregulated and 285 downregulated) in roots. These DEGs, mainly involved in plant hormone signal transduction and the mitogen-activated protein kinase, have the potential to trigger plants' responses to various environmental stimuli, including stress and developmental signals. Under saline conditions, acetoin-treated plants showed increased net leaf photosynthesis and activities of several defense enzymes, indicating that acetoin enhances both fundamental growth and the plant's stress defenses, especially against salinity. In summary, acetoin appears to act through a complex interplay of genetic and biochemical mechanisms, influencing key signaling pathways and physiological processes that lead to improved growth and stress tolerance in lettuce seedlings.

CNSC-10. WHEN GOOD THINGS GO OFF TRK: THE INTERSECTION OF NEUROSCIENCE & ONCOLOGY

Abstract How and why do processes and molecular players that were once an integral part of normal neurodevelopment go awry in pathological conditions, such as cancer? Embryogenesis, and neurodevelopment in particular, comprise an elegant and well-orchestrated series of tightly regulated events, culminating in an organized and highly functioning organism. Cancer, on the other hand, can often be viewed as an uncontrolled, unrestrained, genetically chaotic disease, lacking the precise spatial and temporal rigidity associated with normal development. While appearing to be on opposite sides of the organizational spectrum, the similarities between early neurodevelopment and oncogenesis are numerous. The link between developmental signaling and cancer initiation, maintenance, and metastasis has long been known for several members of the Wnt, Hedgehog, and Notch pathways and years of gene-level analyses have provided a wealth of knowledge and mechanistic insight. As advances in next generation sequencing allow for deeper characterization of genetic programs, it is increasingly possible to explore various isoforms of cancer associated genes. It is widely known that neurotrophins and their receptors (TrkA, TrkB, TrkC) are instrumental for neurodevelopment and that they remain critical for proper neuronal functioning throughout life. Our work highlights a previously unidentified role for an alternatively spliced neurotrophin receptor in neurodevelopment, embryogenesis, transformation, and oncogenesis across multiple tumor types in humans and mice. This specific isoform, TrkB.T1, is the predominant NTRK2 isoform across embryonic organogenesis, and forced overexpression of this embryonic pattern causes multiple solid and nonsolid tumors in mice. TrkB.T1 also emerges as the predominant NTRK isoform expressed in a wide range of adult and pediatric tumors, including those harboring various NTRK fusions. This work hopes to address the fundamental question of how neurodevelopmental processes can go awry in cancer, while seeking to better characterize the role of TRKs, in normal developmental processes and oncogenesis.

Prenatal light exposure affects diurnal rhythms and visual development of the layer embryonic retina

It is believed that some wavelengths of light penetrate through eggshell and are perceived by avian embryo, and may consequently affect rhythm establishment and development. This research aimed to explore the influence of prenatal light exposure on the morphological alterations of retinal tissue, the expression of visual developmental signaling systems (TGF-β/Smad pathway), the expression of clock related genes (cClock, cBmal1, cBmal2, cAanat), and melatonin concentration in the chicken embryonic retina. Layer eggs (Jingfen No.6) were subjected to white light (5000K, WL) and green light (520 nm/515-525 nm, GL) with a 12L:12D photoperiod throughout the entire incubation period, in contrast to no light incubation (NL). The results showed that the thickness of retina and each retinal lamina of chicken embryo in WL at E20 was much thicker than that of chicken embryo in GL (P < 0.05). In contrary, the expression level of TGF-β1 mRNA and Smad2/3 protein in retina was dramatically downregulated in WL when compared to that in NL and GL (P < 0.01). Furthermore, the incubation light simultaneously significantly affected the diurnal rhythms of the chicken embryonic retina. The expression of three clock genes (cBmal1/2, cClock) and cAanat exhibited significant diurnal rhythms in GL (P < 0.05). Additionally, green light stimulation significantly enhanced melatonin secretion but did not show diurnal rhythm. However, cBmal1, cAanat, and melatonin expression exhibited diurnal rhythms (P < 0.01), while the others did not in WL. In NL, only cBmal1 exhibited diurnal rhythmicity (P < 0.01). In conclusion, providing light of different wavelengths during the incubation process of poultry can have varying effects on embryonic visual development and the establishment of diurnal rhythms. WL had an advantage to GL and NL on retina development and diurnal rhythm through significantly influencing the expression of genes related to visual developmental signaling pathways and clock genes. A well-developed retina in WL exposure chicken embryo may be beneficial for establishing a melatonin rhythm. Conversely, the established circadian rhythm could improve embryonic development.

Cephalic ganglia transcriptomics of the American cockroach Periplaneta americana (Blattodea: Blattidae).

The American cockroach Periplaneta americana (L.) (Blattodea, Blattidae) has been a model organism for biochemical and physiological study for almost a century, however, its use does not benefit from the genetic tools found in key model species such as Drosophila melanogaster. To facilitate the use of the cockroach as a model system in neuroscience and to serve as a foundation for functional and translational experimentation, a transcriptome of the cephalic ganglia was assembled and annotated, and differential expression profiles between these ganglia were assessed. The transcriptome assembly yielded >400 k transcripts, with >40 k putative coding sequences. Gene ontology and protein domain searches indicate the cerebral and gnathal ganglia (GNG) have distinct genetic expression profiles. The developmental Toll signaling pathway appears to be active in the adult central nervous system (CNS), which may suggest a separate role for this pathway besides innate immune activation or embryonic development. The catabolic glycolytic and citric acid cycle enzymes are well represented in both ganglia, but key enzymes are more highly expressed in the GNG. Both ganglia express gluconeogenic and trehaloneogenic enzymes, suggesting a larger role of the CNS in regulating hemolymph sugar homeostasis than previously appreciated. The annotation and quantification of the cephalic ganglia transcriptome reveal both canonical and novel pathways in signaling and metabolism in an adult insect and lay a foundation for future functional and genetic analysis.

Rabex-5 E3 and Rab5 GEF domains differ in their regulation of Ras, Notch, and PI3K signaling in Drosophila wing development.

Rabex-5 (also called RabGEF1), a protein originally characterized for its Rab5 GEF function, also has an A20-like E3 ubiquitin ligase domain. We and others reported that Rabex-5 E3 activity promotes Ras mono- and di-ubiquitination to inhibit Ras signaling in Drosophila and mammals. Subsequently, we reported that Rabex-5 inhibits Notch signaling in the Drosophila hematopoietic system. Here we report genetic interactions using Rabex-5 transgenes encoding domain-specific mutations that show that Rabex-5 requires an intact E3 domain to inhibit Notch signaling in the epithelial tissue of the developing wing. Surprisingly, we discovered that Rabex-5 with an impaired E3 domain but active Rab5 GEF domain suppresses Notch loss-of-function phenotypes and enhances both Notch duplication phenotypes and activated Ras phenotypes consistent with a model that the Rab5 GEF activity of Rabex-5 might positively regulate Ras and Notch. Positive and negative regulation of developmental signaling by its different catalytic domains could allow Rabex-5 to precisely coordinate developmental signaling to fine-tune patterning. Finally, we report that Rabex-5 also inhibits the overgrowth due to loss of PTEN or activation of PI3K but not activation of AKT. Inhibition of Ras, Notch, and PI3K signaling may explain why Rabex-5 is deleted in some cancers. Paradoxically, Rabex-5 is reported to be an oncogene in other cancers. We propose that Rabex-5 acts as a tumor suppressor via its E3 activity to inhibit Ras, Notch, and PI3K signaling and as an oncogene via its Rab5 GEF activity to enhance Ras and Notch signaling.