Monitoring carbon dioxide levels has a twofold importance for many living organisms: CO2 can act as a sensory cue for food or other animals, while regulating internal CO2 levels is an important part of homeostasis. C. elegans relies on diffusion for gas exchange, and avoids CO2 levels as low as 1%. We are interested in the neural and molecular mechanisms underlying the C. elegans CO2 avoidance behaviour.
Mutants defective in the
tax-4 or
tax-2 genes, which encode the a and b subunits, respectively, of a cGMP-gated ion channel, showed reduced CO2 avoidance in behavioural assays1,2. By expressing
tax-2 cDNA from neuron-specific promoters in
tax-2 mutants to rescue the avoidance behaviour, and by imaging neurons using the genetically encoded calcium indicator YC3.60, we have shown that sensory neurons previously implicated in oxygen, temperature, and salt-sensing, including BAG, AFD and ASE, are CO2 sensors as well3.
We have observed both persistent and transient cell-intrinsic calcium-responses in several sensory neurons, suggesting that CO2 stimuli could modulate neural activity in C. elegans in a complex manner. We are therefore investigating how CO2 stimuli can affect neural processing in downstream neurons.
1 Andrew Jonathan Bretscher, Karl Emanuel Busch, and Mario de Bono, A carbon dioxide avoidance behavior is integrated with responses to ambient oxygen and food in Caenorhabditis elegans. PNAS 105(23):8044-8049
2 Elissa A. Hallem and Paul W. Sternberg, Acute carbon dioxide avoidance in Caenorhabditis elegans. PNAS 105(23):8038-8043
3 Andrew Jonathan Bretscher, Eiji Kodama-Namba, Karl Emanuel Busch, Robin Joseph Murphy, Zoltan Soltesz, Patrick Laurent and Mario de Bono, Temperature, Oxygen, and Salt-Sensing Neurons in C. elegans Are Carbon Dioxide Sensors that Control Avoidance Behavior. Neuron 69(6):1099-1113.