The BED finger domain protein MIG-39 halts migration of distal tip cells in Caenorhabditis elegans

AbstractOrgans are often formed by the extension and branching of epithelial tubes. An appropriate termination of epithelial tube extension is important for generating organs of the proper size and morphology. However, the mechanism by which epithelial tubes terminate their extension is mostly unknown. Here we show that the BED-finger domain protein MIG-39 acts to stop epithelial tube extension in Caenorhabditis elegans. The gonadal leader cells, called distal tip cells (DTCs), migrate in a U-shaped pattern during larval development and stop migrating at the young adult stage, generating a gonad with anterior and posterior U-shaped arms. In mig-39 mutants, however, DTCs overshot their normal stopping position. MIG-39 promoted the deceleration of DTCs, leading to the proper timing and positioning of the cessation of DTC migration. Among three Rac GTPase genes, mutations in ced-10 and rac-2 enhanced the overshoot of anterior DTCs, while they suppressed that of posterior DTCs of mig-39 mutants. On the other hand, the mutation in mig-2 suppressed both the anterior and posterior DTC defects of mig-39. Genetic analyses suggested that MIG-39 acts in parallel with Rac GTPases in stopping DTC migration. We propose a model in which the anterior and posterior DTCs respond in an opposite manner to the levels of Rac activities in the cessation of DTC migration

bHLH Transcription factors regulate organ morphogenesis via activation of an ADAMTS protease in C. elegans

AbstractThe ADAMTS (a disintegrin and metalloprotease with thrombospondin motifs) family of secreted metalloproteases plays important roles in animal development and pathogenesis. However, transcriptional regulation of ADAMTS proteins during development remains largely unexplored. Here we show that basic helix–loop–helix (bHLH) transcription factors regulate the expression of an ADAMTS protease that is required for gonad development in Caenorhabditis elegans. Mutations in the gene mig-24 cause shortened and swollen gonad arms due to a defect in gonadal leader cell migration, although leader cell specification appears to occur normally. The MIG-24 protein is a bHLH transcription factor of the Achaete–Scute family and is specifically expressed in gonadal leader cells. MIG-24 can physically interact with HLH-2, an E/Daughterless family bHLH transcription factor and bind the promoter region of gon-1, which encodes an ADAMTS protease required for gonadal leader cell migration. Mutations or RNA interference of mig-24 and hlh-2 severely impaired gon-1 expression and forced expression of GON-1 in leader cells in mig-24 mutants partially rescued the gonadal elongation defect. We propose that, unlike most previously characterized Achaete–Scute transcription factors that are involved in cell fate specification, MIG-24 acts with HLH-2 in specified cells to control cell migration by activating the expression of the GON-1 ADAMTS protease

Maintenance of cell fates and regulation of the histone variant H3.3 by TLK kinase in Caenorhabditis elegans

Cell-fate maintenance is important to preserve the variety of cell types that are essential for the formation and function of tissues. We previously showed that the acetylated histone-binding protein BET-1 maintains cell fate by recruiting the histone variant H2A.z. Here, we report that Caenorhabditis elegans TLK-1 and the histone H3 chaperone CAF1 prevent the accumulation of histone variant H3.3. In addition, TLK-1 and CAF1 maintain cell fate by repressing ectopic expression of transcription factors that induce cell-fate specification. Genetic analyses suggested that TLK-1 and BET-1 act in parallel pathways. In tlk-1 mutants, the loss of SIN-3, which promotes histone acetylation, suppressed a defect in cell-fate maintenance in a manner dependent on MYST family histone acetyltransferase MYS-2 and BET-1. sin-3 mutation also suppressed abnormal H3.3 incorporation. Thus, we propose a hypothesis that the regulation and interaction of histone variants play crucial roles in cell-fate maintenance through the regulation of selector genes

A Fibulin-1 Homolog Interacts with an ADAM Protease that Controls Cell Migration in C. elegans

AbstractADAM (a disintegrin and metalloprotease) family proteins play important roles in animal development and pathogenesis [1]. In C. elegans, a secreted ADAM protein, MIG-17, acts from outside the gonad to control the migration of gonadal distal tip cells (DTCs) that promote gonad morphogenesis [2]. Here, we report that dominant mutations in the fbl-1 gene encoding fibulin-1 spliced isoforms, which are calcium binding extracellular matrix proteins, bypass the requirement for MIG-17 activity in directing DTC migration. Specific amino acid substitutions in the third EGF-like motif of one of the two isoforms, FBL-1C, which corresponds to mammalian fibulin-1C, suppress mig-17 mutations. FBL-1C is synthesized in the gut cells and localizes strongly to the gonadal basement membrane in a MIG-17-dependent manner. Localization of mutant FBL-1C is weaker than that of the wild-type protein and is insensitive to MIG-17 activity, suggesting that it gains a novel function that compensates for its reduced molecular density. We propose that proteolysis by MIG-17 recruits FBL-1C to the gonadal basement membrane, where it is required for the guidance of DTCs, and that mutant FBL-1C acts in a manner that mimics the downstream events of MIG-17-mediated proteolysis

Multiple functions of PBRM-1/Polybromo- and LET-526/Osa-containing chromatin remodeling complexes in C. elegans development

AbstractThe SWI/SNF-like chromatin remodeling complexes consist of two evolutionarily conserved subclasses, which are characterized by specific accessory components, the OSA/BAF250 and Polybromo proteins. These complexes regulate the expressions of distinct sets of target genes, with some overlap, and the regulatory components are thought to determine the target specificity for each complex. Here we isolated C. elegans mutants of the genes for the OSA/BAF250 homolog, LET-526, and the Polybromo homolog, PBRM-1, in a screen for the abnormal asymmetric cell division phenotype. In the asymmetric division of the T cell, both LET-526 and PBRM-1 regulated the asymmetric expression of psa-3/Meis between the T cell daughters, suggesting that the two subclasses share the same target. In the gonad, PBRM-1 regulated gonad primordium formation during embryogenesis, whereas LET-526 was required post-embryonically for distal tip cell (DTC) production from the gonad primordium, suggesting that these proteins have distinct targets for DTC development. Thus, the same cellular process is regulated by LET-526 and PBRM-1 in the asymmetric division of the T cell, but they regulate distinct cellular processes in the gonad morphogenesis. Although disruption of the core component PSA-1 or PSA-4 caused similar defects in the gonad and T cell, it also caused early embryonic arrest, which was not observed in the let-526, pbrm-1, or let-526 pbrm-1 double mutants, suggesting that some targets of SWI/SNF-like complexes do not require LET-526 or PBRM-1 for their transcription. Our results show that the target selection by SWI/SNF-like complexes during C. elegans development is intricately regulated by accessory components