Your search keyword '"Butcher, Rebecca"' showing total 5 results

1. A hub-and-spoke circuit drives pheromone attraction and social behaviour in C. elegans.

Author

Macosko, Evan Z, Pokala, Navin, Feinberg, Evan H, Chalasani, Sreekanth H, Butcher, Rebecca A, Clardy, Jon, and Bargmann, Cornelia I

Subjects

Neural Pathways, Neurons, Animals, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Receptors, Neuropeptide Y, Pheromones, Feeding Behavior, Social Behavior, Mutation, Models, Neurological, Male, Disorders of Sex Development, Models, Neurological, Receptors, Neuropeptide Y, General Science & Technology

Abstract

Innate social behaviours emerge from neuronal circuits that interpret sensory information on the basis of an individual's own genotype, sex and experience. The regulated aggregation behaviour of the nematode Caenorhabditis elegans, a simple animal with only 302 neurons, is an attractive system to analyse these circuits. Wild social strains of C. elegans aggregate in the presence of specific sensory cues, but solitary strains do not. Here we identify the RMG inter/motor neuron as the hub of a regulated circuit that controls aggregation and related behaviours. RMG is the central site of action of the neuropeptide receptor gene npr-1, which distinguishes solitary strains (high npr-1 activity) from wild social strains (low npr-1 activity); high RMG activity is essential for all aspects of social behaviour. Anatomical gap junctions connect RMG to several classes of sensory neurons known to promote aggregation, and to ASK sensory neurons, which are implicated in male attraction to hermaphrodite pheromones. We find that ASK neurons respond directly to pheromones, and that high RMG activity enhances ASK responses in social strains, causing hermaphrodite attraction to pheromones at concentrations that repel solitary hermaphrodites. The coordination of social behaviours by RMG suggests an anatomical hub-and-spoke model for sensory integration in aggregation, and points to functions for related circuit motifs in the C. elegans wiring diagram.

Published

2009

2. Pathogenic bacteria modulate pheromone response to promote mating

Author

Wu, Taihong, primary, Ge, Minghai, additional, Wu, Min, additional, Duan, Fengyun, additional, Liang, Jingting, additional, Chen, Maoting, additional, Gracida, Xicotencatl, additional, Liu, He, additional, Yang, Wenxing, additional, Dar, Abdul Rouf, additional, Li, Chengyin, additional, Butcher, Rebecca A., additional, Saltzman, Arneet L., additional, and Zhang, Yun, additional

Published

2023

3. IL-17 is a neuromodulator of Caenorhabditis elegans sensory responses

Author

Chen, Changchun, Itakura, Eisuke, Nelson, Geoffrey M., Sheng, Ming, Laurent, Patrick, Fenk, Lorenz A., Butcher, Rebecca A., Hegde, Ramanujan S., and de Bono, Mario

Published

2017

4. Parallel evolution of domesticated Caenorhabditis species targets pheromone receptor genes

Author

McGrath, Patrick T., Xu, Yifan, Ailion, Michael, Garrison, Jennifer L., Butcher, Rebecca A., and Bargmann, Cornelia I.

Subjects

Caenorhabditis elegans -- Natural history -- Genetic aspects, Pheromones -- Genetic aspects, Evolutionary biology -- Genetic aspects, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Evolution can follow predictable genetic trajectories (1), indicating that discrete environmental shifts can select for reproducible genetic changes (2-4). Conspecific individuals are an important feature of an animal's environment, and a potential source of selective pressures. Here we show that adaptation of two Caenorhabditis species to growth at high density, a feature common to domestic environments, occurs by reproducible genetic changes to pheromone receptor genes. Chemical communication through pheromones that accumulate during high-density growth causes young nematode larvae to enter the long-lived but non-reproductive dauer stage. Two strains of Caenorhabditis elegans grown at high density have independently acquired multigenic resistance to pheromone-induced dauer formation. In each strain, resistance to the pheromone ascaroside C3 results from a deletion that disrupts the adjacent chemoreceptor genes serpentine receptor class g (srg)-36 and -37. Through misexpression experiments, we show that these genes encode redundant G-protein-coupled receptors for ascaroside C3. Multigenic resistance to dauer formation has also arisen in high-density cultures of a different nematode species, Caenorhabditis briggsae, resulting in part from deletion of an srggene paralogous to srg-36 and srg-37. These results demonstrate rapid remodelling of the chemoreceptor repertoire as an adaptation to specific environments, and indicate that parallel changes to a common genetic substrate can affect life-history traits across species., Caenorhabditis elegans and many other nematode species evaluate environmental conditions to choose between two alternative developmental trajectories, one leading to rapid reproduction and one leading to arrest in the long-lived, [...]

Published

2011

5. Balancing selection shapes density-dependent foraging behaviour

Author

Greene, Joshua S., Brown, Maximillian, Dobosiewicz, May, Ishida, Itzel G., Macosko, Evan Z., Zhang, Xinxing, Butcher, Rebecca A., Cline, Devin J., McGrath, Patrick T., and Bargmann, Cornelia I.

Subjects

Foraging (Animal feeding behavior) -- Observations, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

The optimal foraging strategy in a given environment depends on the number of competing individuals and their behavioural strategies. Little is known about the genes and neural circuits that integrate social information into foraging decisions. Here we show that ascaroside pheromones, small glycolipids that signal population density, suppress exploratory foraging in Caenorhabditis elegans, and that heritable variation in this behaviour generates alternative foraging strategies. We find that natural C. elegans isolates differ in their sensitivity to the potent ascaroside icas#9 (IC-asc-C5). A quantitative trait locus (QTL) regulating icas#9 sensitivity includes srx-43, a G-protein-coupled icas#9 receptor that acts in the ASI class of sensory neurons to suppress exploration. Two ancient haplotypes associated with this QTL confer competitive growth advantages that depend on ascaroside secretion, its detection by srx-43 and the distribution of food. These results suggest that balancing selection at the srx-43 locus generates alternative density-dependent behaviours, fulfilling a prediction of foraging game theory., Author(s): Joshua S. Greene [1]; Maximillian Brown [1]; May Dobosiewicz [1]; Itzel G. Ishida [1]; Evan Z. Macosko [1]; Xinxing Zhang [2]; Rebecca A. Butcher [2]; Devin J. Cline [3]; [...]

Published

2016