Analysis of rapamycin induced autophagy in Dictyostelium discoideum.

Natural autophagy and autophagic cell death is being studied in the model system, D. discoideum, which has well known genetic and experimental advantages over the other known systems. There is no apoptotic machinery present in this organism which could interfere with the non-apoptotic cell death. The target of rapamycin (TOR) pathway is a major nutrient-sensing pathway which when inhibited by the drug rapamycin induces autophagy. Rapamycin was originally discovered as an anti-fungal agent but its use was abandoned when it was discovered to have potent immunosuppressive and anti-proliferative properties. It is a known drug used today for various cancer treatments and also for increasing longevity in many model organisms. It has a wide usage but its effects on other pathways or molecules are not known. This model system was used to study the action of rapamycin on autophagy induction. Using the GFP-Atg8, an autophagosome marker, it was shown that rapamycin treatment can induce autophagy by an accumulation of reactive oxygen species and intracellular free calcium. Rapamycin suppresses proliferation by induction of cell cycle arrest in the G1 phase. Taken together, the results suggest that the core machinery for autophagy is conserved in D. discoideum and it can serve as a good model system to delineate the action of rapamycin induced autophagy.

On the origin of differentiation.

Following the origin of multicellularity in many groups of primitive organisms there evolved more than one cell type. It has been assumed that this early differentiation is related to size the larger the organism the more cell types. Here two very different kinds of organisms are considered: the volvocine algae that become multicellular by growth, and the cellular slime moulds that become multicellular by aggregation. In both cases there are species that have only one cell type and others that have two. It has been possible to show that there is a perfect correlation with size: the forms with two cell types are significantly larger than those with one. Also in both groups there are forms of intermediate size that will vary from one to two cell types depending on the size of the individuals, suggesting a form of quorum sensing. These observations reinforce the view that size plays a critical role in influencing the degree of differentiation.

Developmentally-regulated cell surface N-linked oligosaccharides participate in intercellular cohesion in Dictyostelium discoideum.

The ability of purified plasma membrane glycoconjugates to inhibit the EDTA-resistant agglutination between aggregation-stage cells of Dictyostelium discoideum has suggested that receptor binding of these glycoconjugates provides a basis for cell-cell cohesion during aggregation. This has been tested by analysis of a series of mutants with different defects in the assembly of N-linked oligosaccharides. Mutant HL241 lacks outer branch components of N-linked oligosaccharides and fails to aggregate or express EDTA-resistant cohesion. HL244 makes unsulphated but otherwise normal N-linked oligosaccharides, generates multiple tips on aggregated cell mounds in some clones, and shows abnormally strong EDTA-resistant cohesion. Two mutants that are temperature-sensitive for complete processing of N-linked oligosaccharides are also temperature-sensitive for expression of both aggregation ability and EDTA-resistant cohesion. A revertant that recovered essentially normal N-linked oligosaccharide processing at the restrictive temperature has also recovered its ability to aggregate and to agglutinate in EDTA.