Abstract:The TGF-β superfamily is conserved throughout metazoan, and its members play essential roles in development and disease. TGF-β has also been implicated in adult neural plasticity. However, the underlying mechanisms are not well understood. Here we report that DBL-1, a Caenorhabditis elegans TGF-β homolog known to control body morphology and immunity, is essential for aversive olfactory learning of potentially harmful bacteria food. We show that DBL-1 generated by the AVA command interneurons, which are critica… Show more
“…4E,F). Expressing the SMA-6 receptor, using previously reported strains able to rescue sma-6 aversive olfactory learning defects (Zhang and Zhang, 2012), in hypodermis (using the col-12
Fig. 4. HEN-1 and the DBL-1/Sma pathway regulate food-avoidance behavior.…”
Changes in metabolic state alter foraging behavior and food preference in animals. Here, I show that normally attractive food becomes repulsive to Caenorhabditis elegans if animals are chronically undernourished as a result of alimentary tract defects. This behavioral plasticity is achieved in two ways: increased food leaving and induction of aversive behavior towards food. A particularly strong food avoider is defective in the chitin synthase that makes the pharyngeal lining. Food avoidance induced by underfeeding is mediated by cGMP signaling in the olfactory neurons AWC and AWB, and the gustatory neurons ASJ and ASK. Food avoidance is enhanced by increased population density and is reduced if the animals are unable to correctly interpret their nutritional state as a result of defects in the AMP kinase or TOR/S6kinase pathways. The TGF-β/DBL-1 pathway suppresses food avoidance and the cellular basis for this is distinct from its role in aversive olfactory learning of harmful food. This study suggests that nutritional state feedback via nutrient sensors, population size and olfactory neurons guides food preference in C. elegans.
“…4E,F). Expressing the SMA-6 receptor, using previously reported strains able to rescue sma-6 aversive olfactory learning defects (Zhang and Zhang, 2012), in hypodermis (using the col-12
Fig. 4. HEN-1 and the DBL-1/Sma pathway regulate food-avoidance behavior.…”
Changes in metabolic state alter foraging behavior and food preference in animals. Here, I show that normally attractive food becomes repulsive to Caenorhabditis elegans if animals are chronically undernourished as a result of alimentary tract defects. This behavioral plasticity is achieved in two ways: increased food leaving and induction of aversive behavior towards food. A particularly strong food avoider is defective in the chitin synthase that makes the pharyngeal lining. Food avoidance induced by underfeeding is mediated by cGMP signaling in the olfactory neurons AWC and AWB, and the gustatory neurons ASJ and ASK. Food avoidance is enhanced by increased population density and is reduced if the animals are unable to correctly interpret their nutritional state as a result of defects in the AMP kinase or TOR/S6kinase pathways. The TGF-β/DBL-1 pathway suppresses food avoidance and the cellular basis for this is distinct from its role in aversive olfactory learning of harmful food. This study suggests that nutritional state feedback via nutrient sensors, population size and olfactory neurons guides food preference in C. elegans.
“…INS-6 secreted from ASI antagonizes expression of another insulin-like peptide, INS-7, in a second set of neurons, and the authors hypothesize that secreted INS-7, in turn, negatively affects aversive learning by antagonizing the insulin receptor DAF-2 [25]. In a second study, the secreted TGF-b ligand DBL-1 was also shown to be necessary for the aversive learning response on P. aeruginosa [26]. Thus, at least three neuropeptides promote aversive learning on P. aeruginosa, two of which -INS-6 and INS-7 -act through the aforementioned ADF modulatory circuit.…”
Section: Microbial Cues and Chemosensationmentioning
“…DAF-7 functions in the neuroendocrine regulation of diverse aspects of organismal development and physiology, including the dauer developmental decision, foraging and aggregation behaviors, quiescence, metabolism, and longevity (de Bono et al, 2002; Gallagher et al, 2013; Greer et al, 2008; Milward et al, 2011; Shaw et al, 2007; Swanson and Riddle, 1981). In addition, another C. elegans TGF-β-family ligand, DBL-1, has been shown to regulate olfactory aversive learning and antifungal defenses (Zhang and Zhang, 2012; Zugasti and Ewbank, 2009). Expression of daf-7 is limited to the ASI pair of chemosensory neurons and has been shown to respond to the availability of bacterial food (Ren et al, 1996; Schackwitz et al, 1996).…”
Summary
Discrimination among pathogenic and beneficial microbes is essential for host organism immunity and homeostasis. Here, we show that chemosensory detection of two secondary metabolites produced by Pseudomonas aeruginosa modulates a neuroendocrine signaling pathway that promotes avoidance behavior in the simple animal host Caenorhabditis elegans. Secondary metabolites phenazine-1-carboxamide and pyochelin activate a G protein-signaling pathway in the ASJ chemosensory neuron pair that induces expression of the neuromodulator DAF-7/TGF-β. DAF-7, in turn, activates a canonical TGF-β signaling pathway in adjacent interneurons to modulate aerotaxis behavior and promote avoidance of pathogenic P. aeruginosa. Our data provide a chemical, genetic, and neuronal basis for how the behavior and physiology of a simple animal host can be modified by the microbial environment, and suggest that secondary metabolites produced by microbes may provide environmental cues that contribute to pathogen recognition and host survival.
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