Cooperative regulation of AJM-1 controls junctional integrity in Caenorhabditis elegans epithelia.

The function of epithelial cell sheets depends on the integrity of specialized cell-cell junctions that connect neighbouring cells. We have characterized the novel coiled-coil protein AJM-1, which localizes to an apical junctional domain of Caenorhabditis elegans epithelia basal to the HMR-HMP (cadherin-catenin) complex. In the absence of AJM-1, the integrity of this domain is compromised. Proper AJM-1 localization requires LET-413 and DLG-1, homologues of the Drosophila tumour suppressors Scribble and Discs large, respectively. DLG-1 physically interacts with AJM-1 and is required for its normal apical distribution, and LET-413 mediates the rapid accumulation of both DLG-1 and AJM-1 in the apical domain. In the absence of both dlg-1 and let-413 function AJM-1 is almost completely lost from apical junctions in embryos, whereas HMP-1 (α α-catenin) localization is only mildly affected. We conclude that LET-413 and DLG-1 cooperatively control AJM-1 localization and that AJM-1 controls the integrity of a distinct apical junctional domain in C. elegans. D uring animal development, specialized junctional domains are crucial for the function of epithelial cell sheets. In both vertebrates and invertebrates, adherens junctions are thought to regulate cell-cell adhesion and dynamic changes in cell morphology Here we show that the novel coiled-coil protein AJM-1 (for 'apical junction molecule') is required for the integrity of epithelial junctions of C. elegans and that it localizes to an apical junctional domain. (AJM-1 was originally called JAM-1 (refs 13, 14) but has been renamed to avoid confusion with the vertebrate transmembrane tight junction protein, JAM-1.) This domain is basal to the HMR-HMP(cadherin-catenin) complex; on the basis of the localization of the Discs large homologue DLG-1 to the same domain, it might be required for maintaining a tight apical seal between epithelial cells at apical junctions. Furthermore, we show that AJM-1 directly binds DLG-1, which is required for the proper distribution of AJM-1 around the junctional belt but not for general cell polarity. In addition, we show that in embryos lacking LET-413 the patterns of both DLG-1 and AJM-1 are equally disrupted, including a delay in concentration of these proteins at a narrow apical domain. Almost complete loss of junctional AJM-1 is observed in the absence of both LET-413 and DLG-1, whereas HMP-1 (α-catenin) localization is reduced but junctional. We propose a model in which LET-413 and DLG-1 control the integrity of a distinct apical subdomain by cooperatively regulating the localization of AJM-1. Results AJM-1 encodes a novel coiled-coil protein localizing to C. elegans apical junctions. As an initial step in understanding the molecular composition of apical junctions in C. elegans, we characterized the antigen recognized by the MH27 antibody. The antibody had been previously shown to stain apical borders of C. elegans epitheli

Cooperative regulation of AJM-1 controls junctional integrity in Caenorhabditis elegans epithelia.

The function of epithelial cell sheets depends on the integrity of specialized cell-cell junctions that connect neighbouring cells. We have characterized the novel coiled-coil protein AJM-1, which localizes to an apical junctional domain of Caenorhabditis elegans epithelia basal to the HMR-HMP (cadherin-catenin) complex. In the absence of AJM-1, the integrity of this domain is compromised. Proper AJM-1 localization requires LET-413 and DLG-1, homologues of the Drosophila tumour suppressors Scribble and Discs large, respectively. DLG-1 physically interacts with AJM-1 and is required for its normal apical distribution, and LET-413 mediates the rapid accumulation of both DLG-1 and AJM-1 in the apical domain. In the absence of both dlg-1 and let-413 function AJM-1 is almost completely lost from apical junctions in embryos, whereas HMP-1 (α α-catenin) localization is only mildly affected. We conclude that LET-413 and DLG-1 cooperatively control AJM-1 localization and that AJM-1 controls the integrity of a distinct apical junctional domain in C. elegans. D uring animal development, specialized junctional domains are crucial for the function of epithelial cell sheets. In both vertebrates and invertebrates, adherens junctions are thought to regulate cell-cell adhesion and dynamic changes in cell morphology Here we show that the novel coiled-coil protein AJM-1 (for 'apical junction molecule') is required for the integrity of epithelial junctions of C. elegans and that it localizes to an apical junctional domain. (AJM-1 was originally called JAM-1 (refs 13, 14) but has been renamed to avoid confusion with the vertebrate transmembrane tight junction protein, JAM-1.) This domain is basal to the HMR-HMP(cadherin-catenin) complex; on the basis of the localization of the Discs large homologue DLG-1 to the same domain, it might be required for maintaining a tight apical seal between epithelial cells at apical junctions. Furthermore, we show that AJM-1 directly binds DLG-1, which is required for the proper distribution of AJM-1 around the junctional belt but not for general cell polarity. In addition, we show that in embryos lacking LET-413 the patterns of both DLG-1 and AJM-1 are equally disrupted, including a delay in concentration of these proteins at a narrow apical domain. Almost complete loss of junctional AJM-1 is observed in the absence of both LET-413 and DLG-1, whereas HMP-1 (α-catenin) localization is reduced but junctional. We propose a model in which LET-413 and DLG-1 control the integrity of a distinct apical subdomain by cooperatively regulating the localization of AJM-1. Results AJM-1 encodes a novel coiled-coil protein localizing to C. elegans apical junctions. As an initial step in understanding the molecular composition of apical junctions in C. elegans, we characterized the antigen recognized by the MH27 antibody. The antibody had been previously shown to stain apical borders of C. elegans epitheli

The Inositol 1,4,5-Trisphosphate Receptor Regulates Epidermal Cell Migration in Caenorhabditis elegans

AbstractPolarized migration and spreading of epithelial sheets is important during many processes in vivo, including embryogenesis and wound healing. However, the signaling pathways that regulate epithelial migrations are poorly understood. To identify molecular components that regulate the spreading of epithelial sheets, we performed a screen for mutations that perturb epidermal cell migration during embryogenesis in Caenorhabditis elegans. We identified one mutant (jc5) as a weak mutation in itr-1, which encodes the single inositol 1,4,5-trisphosphate receptor (ITR) in C. elegans. During the migration of the embryonic epidermis, jc5 embryos display defects including misdirected migration or premature cessation of migration. Cells that halt their migration have disorganized F-actin and display reduced filopodial protrusive activity at their leading edge. Furthermore, some filopodia formed by epidermal cells in itr-1(jc5) embryos exhibit abnormally long lifetimes. Pharmacological studies with the inositol 1,4,5-trisphosphate antagonist xestospongin C phenocopy these defects, confirming that ITR function is important for proper epidermal migration. Our results provide the first molecular evidence that movements of embryonic epithelial cell sheets can be controlled by ITRs and suggest that such regulation may be a widespread mechanism for coordinating epithelial cell movements during embryogenesis

Dynamics and ultrastructure of developmental cell fusions in the Caenorhabditis elegans hypodermis

AbstractCell fusions produce multinucleate syncytia that are crucial to the structure of essential tissues in many organisms [1–5]. In humans the entire musculature, much of the placenta, and key cells in bones and blood are derived from cell fusion. Yet the developmental fusion of cell membranes has never been directly observed and is poorly understood. Similarity between viral fusion proteins and recently discovered cellular proteins implies that both cell–cell and virus–cell fusion may occur by a similar mechanism [6–8]. Paradoxically, however, fusion of enveloped viruses with cells involves an opening originating as a single pore [9–11], whereas electron microscopy studies of cell–cell fusion describe simultaneous breakdown of large areas of membrane [12,13]. Here, we have shown that developmental cell fusion is indeed consistent with initiation by a virus-like, pore-forming mechanism. We examined live cell fusions in the epithelia of Caenorhabditis elegans embryos by a new method that integrates multiphoton, confocal, and electron microscopy. The fusion aperture always originated at a single point restricted to the apical adherens junction and widened slowly as a radial wavefront. The fusing membranes dispersed by vesiculation, rather than simple unfolding of the conjoined double bilayer. Thus, in these cells fusion appears to require two specialized sequential processes: formation of a unique primary pore and expansion of the opening by radial internalization of the interacting cell membranes

LET-23 Receptor Localization by the Cell Junction Protein LIN-7 during C. elegans Vulval Induction

AbstractIn C. elegans, the anchor cell signal induces Pn.p cells to form the vulva by activating a conserved receptor tyrosine kinase pathway. lin-2 and lin-7 mutants exhibit a vulvaless phenotype similar to the phenotype observed when this signaling pathway is defective. We have found that LIN-7 is a cell junction–associated protein that binds to the LET-23 receptor tyrosine kinase. LET-23 is also localized to the cell junctions, and both LIN-2 and LIN-7 are required for this localization. LET-23 overexpression rescues the lin-2 or lin-7 vulvaless phenotype, suggesting that increased receptor density can compensate for mislocalization. These results suggest that proper localization of LET-23 receptor to the Pn.p cell junctions is required for signaling activity