gp150 is a membrane glycoprotein which has been implicated in cell-cell adhesion in the postaggregation stages of Dictyostelium development. An analysis of its tryptic peptides by mass spectrometry has identified gp150 as the product of the lagC gene, which was previously shown to play a role in morphogenesis and cell-type specification. Antibodies raised against the GST-LagC fusion protein specifically recognized gp150 in wild-type cells and showed that it is missing in lagC-null cells. Immunolocalization studies have confirmed its enrichment in cell-cell contact regions. In mutant cells that lack the aggregation stage-specific cell adhesion molecule gp80, gp150 is expressed precociously. Moreover, these cells acquire EDTA-resistant cell-cell binding during aggregation, suggesting a role for gp150 in this process. Cells in which the genes encoding gp80 and gp150 are both inactivated do not acquire EDTA-resistant cell adhesion during aggregation. Strains transformed with an actin 15::lagC construct express gp150 precociously, but do not show EDTA-resistant adhesion during early development. However, vegetative cells expressing gp150 can be recruited into aggregates of 16-h lagC-null cells. These results, together with those obtained with the cell-to-substratum binding assay, indicate that gp150 mediates cell-cell adhesion via heterophilic interactions with another component that accumulates during the aggregation stage.
The social amoeba Dictyostelium discoideum is a simple but powerful model organism for the study of cell-cell adhesion molecules and their role in morphogenesis during development. Three adhesive systems have been characterized and studied in detail. The spatiotemporal expression of these adhesion proteins is stringently regulated, often coinciding with major shifts in the morphological complexity of development. At the onset of development, amoeboid cells express the Ca
2+-dependent cell-cell adhesion molecule DdCAD-1, which initiates weak homophilic interactions between cells and assists in the recruitment of individuals into cell streams. DdCAD-1 is unique because it is synthesized as a soluble protein in the cytoplasm. It is targeted for presentation on the cell surface by an unconventional protein transport mechanism via the contractile vacuole. Concomitant with the aggregation stage is the expression of the contact sites A glycoprotein csA ⁄ gp80 and TgrC1, both of which mediate Ca 2+ ⁄ Mg
2+-independent cell-cell adhesion. Whereas csA ⁄ gp80 is a homophilic binding protein, TgrC1 binds to a heterophilic receptor on the cell. During cell aggregation, csA ⁄ gp80 associates preferentially with lipid rafts, which facilitate the rapid assembly of adhesion complexes. TgrC1 is synthesized at low levels during aggregation and rapid accumulation occurs initially in the peripheral cells of loose mounds. The extracellular portion of TgrC1 is shed and becomes part of the extracellular matrix. Additionally, analyses of knockout mutants have revealed important biological roles played by these adhesion proteins, including size regulation, cell sorting and cell-type proportioning.
In Dictyostelium, soluble cell adhesion molecule, DdCAD-1, regulates cell-cell interaction through an unknown anchoring protein on the plasma membrane. Far western blot analysis using different probes revealed that the potential DdCAD-1 interacting protein was between 64 and 98 kDa. To isolate and identify the anchoring protein, GST-DdCAD-1 and anchoring protein were cross-linked in vivo by chemical cross-linker and stable protein complex was isolated by co-immunoprecipitation assays. The protein cross-linked to DdCAD-1 was extracted from the gel slice and trypsinized. The peptides were subjected to analysis by mass spectrometry, which showed that the putative anchoring protein belongs to ATP-binding cassette transporter family.
ABSTRACT. The signaling molecules NH 3 (unprotonated volatile ammonia), as well as cyclic adenosine monophosphate and differentiationinducing factor, play important roles in the multicellular development of the slime mould Dictyostelium discoideum. One of the downstream metabolic products catalyzed by allantoicase (allC) is ammonia. We observed the role of allC by RNAi-mediated manipulation of its expression. The allC gene of D. discoideum was silenced by RNAi. We found significant downregulation of allC mRNA and protein expression levels. Recombinant allC RNAi mutant cell lines had a shortened cell cycle, a reduction in cell size relative to wild-type cells and interrupted development. We conclude that the normal functions of allC include retarding cell division until a specific cell size is reached and coordinating the progression of development.
ABSTRACT. Dictyostelium discoideum allC RNAi mutant cells are motile and aggregate together, but do not undergo further morphological development. The relatively quick growth rate of allC RNAi mutants compared to wild-type D. discoideum results in a shortened mutant cell cycle. However, at present, little is known about the mechanism underlying this phenomenon. Here, we used semi-quantitative reverse transcription-polymerase chain reaction (RT-PCR), realtime quantitative RT-PCR, two-dimensional gel electrophoresis, and mass spectrometry/mass spectrometry to elucidate the phenomenon. We found significant downregulation of myosin II heavy chain, D. discoideum calcium-dependent cell adhesion molecule-1 (DdCAD-1) mRNA, DdCAD-1 protein, D. discoideum mRNA for 14-3-3 and 14-3-3 protein, and type A von Willebrand factor domain-containing protein mRNA in allC RNAi mutants. The results suggest that downregulation of the myosin II heavy chain could be one of key factors causing the developmental interruption and that downregulation of the 14-3-3 protein and the type A von Willebrand factor domain-containing protein
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