Sophie Cornillon

Phg1p Is a Nine-transmembrane Protein Superfamily Member Involved in Dictyostelium Adhesion and Phagocytosis

To identify the molecular mechanisms involved in phagocytosis, we generated random insertion mutants ofDictyostelium discoideum and selected two mutants defective for phagocytosis. Both represented insertions in the same gene, namedPHG1. This gene encodes a polytopic membrane protein with an N-terminal lumenal domain and nine potential transmembrane segments. Homologous genes can be identified in many species; however, their function is yet to be elucidated. Disruption of PHG1 caused a selective defect in phagocytosis of latex beads and Escherichia coli, but not Klebsiella aerogenes bacteria. This defect in phagocytosis was caused by a decrease in the adhesion of mutant cells to phagocytosed particles. These results indicate that the Phg1 protein is involved in the adhesion of Dictyosteliumto various substrates, a crucial event of phagocytosis and demonstrate the usefulness of a genetic approach to dissect the molecular events involved in the phagocytic process.

Membrane sorting in the endocytic and phagocytic pathway of Dictyostelium discoideum.

To study sorting in the endocytic pathway of a phagocytic and macropinocytic cell, monoclonal antibodies to membrane proteins of Dictyostelium discoideum were generated. Whereas the p25 protein was localized to the cell surface, p80 was mostly present in intracellular endocytic compartments as observed by immunofluorescence as well as immunoelectron microscopy analysis. The p80 gene was identified and encodes a membrane protein presumably involved in copper transport. Expression of chimeric proteins revealed that the cytoplasmic domain of p80 was sufficient to cause constitutive endocytosis and localization of the protein to endocytic compartments. Dileucine- and tyrosine-based endocytic signals described previously in mammalian systems were also capable of targeting chimera to endocytic compartments. In phagocytosing cells no membrane sorting was observed during formation of the phagosome. Both p25 and p80 were incorporated non-selectively in nascent phagosomes, and then retrieved shortly after phagosome closure. Our results emphasize the fact that very active membrane traffic takes place in phagocytic and macropinocytic cells. This is coupled with precise membrane sorting to maintain the specific composition of endocytic compartments.

An adhesion molecule in free-living Dictyostelium amoebae with integrin beta features

The study of free‐living amoebae has proven valuable to explain the molecular mechanisms controlling phagocytosis, cell adhesion and motility. In this study, we identified a new adhesion molecule in Dictyostelium amoebae. The SibA (Similar to Integrin Beta) protein is a type I transmembrane protein, and its cytosolic, transmembrane and extracellular domains contain features also found in integrin β chains. In addition, the conserved cytosolic domain of SibA interacts with talin, a well‐characterized partner of mammalian integrins. Finally, genetic inactivation of SIBA affects adhesion to phagocytic particles, as well as cell adhesion and spreading on its substrate. It does not visibly alter the organization of the actin cytoskeleton, cellular migration or multicellular development. Our results indicate that the SibA protein is a Dictyostelium cell adhesion molecule presenting structural and functional similarities to metazoan integrin β chains. This study sheds light on the molecular mechanisms controlling cell adhesion and their establishment during evolution.

Localization of the Rh50-like protein to the contractile vacuole in Dictyostelium.

Abstract. The human Rhesus (Rh) family consists of three polytopic membrane proteins present at the cell surface of red blood cells. Although Rh proteins are essential for the expression of the blood group system their biological function remains unclear. In this study, the gene encoding a protein homologous to Rh50 in Dictyostelium discoideum was sequenced. The Rh50-like protein was localized to the contractile vacuole, the organelle responsible for maintenance of osmotic equilibrium within the cell. However, Rh50-like-deficient mutants in which the Rh50-like gene was disrupted did not appear to exhibit a phenotype related to osmoregulation. Nevertheless, these mutants may provide a valuable tool for studying the function of the rhesus protein.

Involvement of Sib Proteins in the Regulation of Cellular Adhesion in Dictyostelium discoideum

ABSTRACT Molecular mechanisms ensuring cellular adhesion have been studied in detail in Dictyostelium amoebae, but little is known about the regulation of cellular adhesion in these cells. Here, we show that cellular adhesion is regulated in Dictyostelium, notably by the concentration of a cellular secreted factor accumulating in the medium. This constitutes a quorum-sensing mechanism allowing coordinated regulation of cellular adhesion in a Dictyostelium population. In order to understand the mechanism underlying this regulation, we analyzed the expression of recently identified Dictyostelium adhesion molecules (Sib proteins) that present features also found in mammalian integrins. sibA and sibC are both expressed in vegetative Dictyostelium cells, but the expression of sibC is repressed strongly in conditions where cellular adhesion decreases. Analysis of sibA and sibC mutant cells further suggests that variations in the expression levels of sibC account largely for changes in cellular adhesion in response to environmental cues.

An insertional mutagenesis approach to Dictyostelium cell death.

Programmed cell death (PCD) in Dictyostelium shows a pattern of ordered degeneration similar to that observed in higher eukaryotes but somewhat different from the most studied form of PCD, i.e. apoptosis. To contribute to a genetic definition of this process, Dictyostelium HMX44A cells have been subjected to insertional mutagenesis, followed by selection based on several rounds of differentiation/regrowth to recover only cells resistant to death. We describe here the approach used, a partial characterization of the first mutant thus obtained called C5 showing some dissociation of cell death signs, and, in this case where plasmid rescue was not possible, as a first step towards identification of the gene at play recovery of genomic flanking sequences via genomic recircularization and PCR. This work demonstrates the feasibility of an insertional mutagenesis approach to obtain death-resistant mutants in Dictyostelium.

Formation of multivesicular endosomes in Dictyostelium.

Multivesicular endosomes are present in virtually every eucaryotic cell, where they arise by intra-endosomal budding of the limiting endosomal membrane. Some genetic diseases such as Chediak-Higashi syndrome are characterized by enlarged membrane-filled endosomes. The same altered endosomal morphology can be observed in cells exposed to certain drugs, for example U18666A. The mechanisms involved are still poorly characterized, partially because this atypical budding event is particularly difficult to observe in mammalian cells. Taking advantage of the simplicity of the endosomal structure in Dictyostelium discoideum, we could visualize intraendosomal budding at the ultrastructural level. In this model organism, the drug U18666A was shown to stimulate intra-endosomal budding, while an inhibitor of PI 3-kinase activity was found to have no effect on this process. Inactivation of a Dictyostelium gene with similarity to the gene responsible for Chediak-Higashi syndrome did not alter the intra-endosomal budding or the accumulation of intra-endosomal membranes. Thus, although treatment with U18666A and inactivation of the Chediak-Higashi gene cause similar morphological defects in mammalian cells, observations in a different model reveal that their respective modes of action are different.

TM9/Phg1 and SadA proteins control surface expression and stability of SibA adhesion molecules in Dictyostelium

ETOC: TM9/Phg1 proteins are essential for cellular adhesion in many systems, from Dictyostelium to human cells, yet their exact role remains unknown. We demonstrate that TM9 proteins participate in adhesion in Dictyostelium cells by controlling the surface levels of SibA adhesion molecules, notably by influencing their sorting in the endocytic pathway.