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1. The C. elegans SMOC-1 protein acts cell non-autonomously to promote bone morphogenetic protein signaling

   https://doi.org/416669  

   Melisa S. DeGroot, Herong Shi (February 2019, Genetics)

   Bone morphogenetic protein (BMP) signaling regulates many different developmental and homeostatic processes in metazoans. The BMP pathway is conserved in Caenorhabditis elegans, and is known to regulate body size and mesoderm development. We have identified the C. elegans smoc-1 (Secreted MOdular Calcium-binding protein-1) gene as a new player in the BMP pathway. smoc-1(0) mutants have a small body size, while overexpression of smoc-1 leads to a long body size and increased expression of the RAD-SMAD (reporter acting downstream of SMAD) BMP reporter, suggesting that SMOC-1 acts as a positive modulator of BMP signaling. Using double-mutant analysis, we showed that SMOC-1 antagonizes the function of the glypican LON-2 and acts through the BMP ligand DBL-1 to regulate BMP signaling. Moreover, SMOC-1 appears to specifically regulate BMP signaling without significant involvement in a TGFβ-like pathway that regulates dauer development. We found that smoc-1 is expressed in multiple tissues, including cells of the pharynx, intestine, and posterior hypodermis, and that the expression of smoc-1 in the intestine is positively regulated by BMP signaling. We further established that SMOC-1 functions cell nonautonomously to regulate body size. Human SMOC1 and SMOC2 can each partially rescue the smoc-1(0) mutant phenotype, suggesting that SMOC-1's function in modulating BMP signaling is evolutionarily conserved. Together, our findings highlight a conserved role of SMOC proteins in modulating BMP signaling in metazoans. 

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2. Endoplasmic Reticulum Calcium Mediates Drosophila Wing Development

   https://doi.org/10.1089/bioe.2022.0036  

   George, Laura Faith; Follmer, Mikaela Lynn; Fontenoy, Emily; Moran, Hannah Rose; Brown, Jeremy Ryan; Ozekin, Yunus H.; Bates, Emily Anne (December 2023, Bioelectricity)

   The temporal dynamics of morphogen presentation impacts transcriptional responses and tissue patterning (1). However, the mechanisms controlling morphogen release are far from clear. We found that inwardly rectifying potassium (Irk) channels regulate endogenous transient increases in intracellular calcium and Bone Morphogenetic Protein (BMP/Dpp) release for Drosophila wing development (2). Inhibition of Irk channels reduces BMP/Dpp signaling, and ultimately disrupts wing morphology (2, 3). Ion channels impact development of several tissues and organisms in which BMP signaling is essential (2-15). In neurons and pancreatic beta cells, Irk channels modulate membrane potential to affect intracellular Ca++ to control secretion of neurotransmitters and insulin (15-21). Based on Irk activity in neurons, we hypothesized that electrical activity controls endoplasmic reticulum Ca++ release into the cytoplasm to regulate the release of BMP. To test this hypothesis, we reduced expression of proteins that control endoplasmic reticulum calcium (Stim, Orai, SERCA, SK, and Best2) and documented wing phenotypes. We found that reduced Stim and SERCA function decreases amplitude and frequency of endogenous calcium transients in the wing disc and reduced Dpp/BMP release in the wing disc. Together, our results suggest control of endoplasmic reticulum is required for Dpp/BMP release. 

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3. Systematic analysis of the Frazzled receptor interactome establishes previously unreported regulators of axon guidance

   https://doi.org/10.1242/dev.201636  

   Zang, Yixin; Bashaw, Greg J (August 2023, Development)

   ABSTRACT The Netrin receptor Dcc and its Drosophila homolog Frazzled play crucial roles in diverse developmental process, including axon guidance. In Drosophila, Fra regulates midline axon guidance through a Netrin-dependent and a Netrin-independent pathway. However, what molecules regulate these distinct signaling pathways remain unclear. To identify Fra-interacting proteins, we performed affinity purification mass spectrometry to establish a neuronal-specific Fra interactome. In addition to known interactors of Fra and Dcc, including Netrin and Robo1, our screen identified 85 candidate proteins, the majority of which are conserved in humans. Many of these proteins are expressed in the ventral nerve cord, and gene ontology, pathway analysis and biochemical validation identified several previously unreported pathways, including the receptor tyrosine phosphatase Lar, subunits of the COP9 signalosome and Rho-5, a regulator of the metalloprotease Tace. Finally, genetic analysis demonstrates that these genes regulate axon guidance and may define as yet unknown signaling mechanisms for Fra and its vertebrate homolog Dcc. Thus, the Fra interactome represents a resource to guide future functional studies. 

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4. AlphaFold2-Guided Functional Screens Reveal a Conserved Antioxidant Protein at ER Membranes

   https://doi.org/10.1101/2024.06.19.599784  

   Ji, Zhijian; Pandey, Taruna; Belly, Henry de; Yao, Jingxuan; Wang, Bingying; Weiner, Orion D; Tang, Yao; Guang, Shouhong; Xu, Shiya; Lou, Zhiyong; et al (June 2024, bioRxiv)

   Abstract Oxidative protein folding in the endoplasmic reticulum (ER) is essential for all eukaryotic cells yet generates hydrogen peroxide (H₂O₂), a reactive oxygen species (ROS). The ER-transmembrane protein that provides reducing equivalents to ER and guards the cytosol for antioxidant defense remains unidentified. Here we combine AlphaFold2-based and functional reporter screens inC. elegansto discover a previously uncharacterized and evolutionarily conserved protein ERGU-1 that fulfills these roles. DeletingC. elegansERGU-1 causes excessive H₂O₂and transcriptional gene up-regulation through SKN-1, homolog of mammalian antioxidant master regulator NRF2. ERGU-1 deficiency also impairs organismal reproduction and behavioral responses to H₂O₂. BothC. elegansand human ERGU-1 proteins localize to ER membranes and form network reticulum structures. Human andDrosophilahomologs of ERGU-1 can rescueC. elegansmutant phenotypes, demonstrating evolutionarily ancient and conserved functions. In addition, purified ERGU-1 and human homolog TMEM161B exhibit redox-modulated oligomeric states. Together, our results reveal an ER-membrane-specific protein machinery for peroxide detoxification and suggest a previously unknown and conserved mechanisms for antioxidant defense in animal cells. 

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5. SEM-2/SoxC regulates multiple aspects of C. elegans postembryonic mesoderm development

   https://doi.org/10.1371/journal.pgen.1011361  

   Baccas, Marissa; Ganesan, Vanathi; Leung, Amy; Pineiro, Lucas R; McKillop, Alexandra N; Liu, Jun (January 2025, PLOS Genetics)

   Grant, Barth D (Ed.)

   Development of multicellular organisms requires well-orchestrated interplay between cell-intrinsic transcription factors and cell-cell signaling. One set of highly conserved transcription factors that plays diverse roles in development is the SoxC group.C.eleganscontains a sole SoxC protein, SEM-2. SEM-2 is essential for embryonic development, and for specifying the sex myoblast (SM) fate in the postembryonic mesoderm, the M lineage. We have identified a novel partial loss-of-functionsem-2allele that has a proline to serine change in the C-terminal tail of the highly conserved DNA-binding domain. Detailed analyses of mutant animals harboring this point mutation uncovered new functions of SEM-2 in the M lineage. First, SEM-2 functions antagonistically with LET-381, the soleC.elegansFoxF/C forkhead transcription factor, to regulate dorsoventral patterning of the M lineage. Second, in addition to specifying the SM fate, SEM-2 is essential for the proliferation and diversification of the SM lineage. Finally, SEM-2 appears to directly regulate the expression ofhlh-8, which encodes a basic helix-loop-helix Twist transcription factor and plays critical roles in proper patterning of the M lineage. Our data, along with previous studies, suggest an evolutionarily conserved relationship between SoxC and Twist proteins. Furthermore, our work identified new interactions in the gene regulatory network (GRN) underlyingC.eleganspostembryonic development and adds to the general understanding of the structure-function relationship of SoxC proteins. 

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