TY  - GEN
T1  - Worm corpses affect quantification of dauer recovery
AU  - Gabaldon, Carolaing
AU  - Calixto, Andrea
DO  - 10.17912/micropub.biology.000121
UR  - http://beta.micropublication.org/journals/biology/micropub-biology-000121/
AB  - Diapause entry and recovery are behavioral adaptations that ensure the survival to environmental changes of animals capable of this type of developmental arrest. Caenorhabditis elegans enters diapause by forming the dauer larvae and at recovery resume post dauer L3 fate (Karp and Ambros, 2012). The precise quantification of dauer exit is required to estimate: post-dauer life span (Klass and Hirsh, 1976); dauer recovery ability after food replenishment (Cassada and Russell, 1975); to investigate components of bacterial extracts that promote dauer exit (Mylenko et al., 2016); the effect of enzymes and proteins involved in dauer recovery (Reape and Burnell, 1990), metabolic analysis at dauer recovery (Houthoofd et al., 2002), inhibition of dauer recovery by pheromone (Golden and Riddle, 1984a, Golden and Riddle, 1984b); global analysis of dauer gene expression (Wang and Kim, 2003) or longevity of dauers (Caneo et al., 2019). Dauers can be discriminated from non-dauers because they are resistant to 1% SDS treatment (Cassada and Russell, 1975). This method is also used to place the resulting dauers in food plates to quantify dauer recovery. We serendipitously found that when dauers alongside with corpses resulting from 1% SDS treatment were seeded in E. coli OP50 plates, a significant number of animals remained in diapause after 24 hours of food exposure. Three factors could be affecting dauer recovery: population size, ratio between dauer and cadaver, and the spatial distribution of them. To investigate how corpses affect dauer recovery, we mixed specific numbers of dauers (200, 400, 450 or 1500) and cadavers (1500 or 6000) and quantified dauer recovery after 24 hours (Figure 1A). Dauers and cadavers were well mixed to minimize the influence of spatial distribution of the worms. Worm cadavers affected recovery from dauers in a quorum-dependent fashion as observed before for live animals (Golden and Riddle, 1984a). Cadavers totaling 6000 in a proportion of 4:1, 3:1 or 30:1 (cadaver:dauer) prevented between 20-50% dauer recovery in plates with plenty of food. Cadavers totaling 1500 in a proportion of 4:1, 3:1, or 1:1 did not have the same effect on dauer recovery. However, when dauers outnumbered 1500 corpses in a proportion 1:1.3 there was dauer retention (Figure 1B). Figure 1B (bottom) shows that total number of animals (corpses and dauers) is also an important factor in dauer recovery. The proportion 4:1 and 3:1 were not sufficient by themselves. In our experiments, the minimum total number of worms for dauer retention was 3500. Using a 4:1 proportion (6000:1500), we tested whether dauer recovery impairment was dependent on pheromone from cadavers by using daf-22mutants of pheromone synthesis (Golden and Riddle, 1985). daf-22 cadavers did not prevent dauer exit in the 4:1 proportion, suggesting that pheromones are retained in corpses and are not sensed by dauers (Figure 1C). Importantly, supernatant from cadavers was not sufficient to induce dauer retention, suggesting that cadavers themselves impair dauer recovery. As expected, 6000 live animals prevented dauer recovery in the presence of food (Figure 1C). Our experiments show that cadavers retain the ability to be sensed by dauers as live worms and constitute a confounding factor in dauer recovery quantification. Dauer recovery is best achieved when only dauer larvae are placed on plates.
PY  - 2019
JO  - microPublication Biology
ER  -