Figure 6. A model for temporally uncoupled regulation of channel mRNA and protein in episodically versus continually active neurons. A, In PD neurons (continually active), there is continuous activity- and modulator-dependent feedback that signals to maintain and tune both channel mRNA and protein relationships in a continually coregulated state, so that ongoing activity can continue throughout the lifetime of the animal without interruption. This ongoing regulation is revealed by artificially silencing PD neurons with tetrodotoxin (TTX): when PD neurons are experimentally turned OFF (silent), both mRNA and membrane current relationships that are correlated in the active state are no longer maintained (Temporal et al., 2012, 2014; Santin and Schulz, 2019). B, In LG neurons (episodically active), when the animal is (1) in the “No Feeding” state, the gastric mill is silent, and the LG neuron is in its OFF state with no activity. In this state, membrane currents are correlated and presumably balanced to generate appropriate cell type–specific output on demand. Concurrently, the mRNA relationships for these channels are not actively being maintained (hence not correlated). When (2) “Feeding” is initiated, the gastric mill—including LG—becomes active. This results in LG neurons receiving both activity- and modulator-dependent feedback. Our data indicate that these feedback pathways result in coregulated channel mRNAs, manifesting as correlated channel mRNA abundance (Viteri and Schulz, 2023). Meanwhile, measured membrane currents are no longer correlated. However, the variability of the magnitudes of these currents across individuals is significantly decreased during the active state of LG (Fig. 2C), suggesting that neuromodulation influences state-dependent relationships among these currents to ensure robust output (Marder and Bucher, 2007; Stein, 2009) In the (3) “Post Feeding” phase, we hypothesize that the correlated mRNAs are used as templates for coregulated translation and processing of ion channel proteins, which are then turned over in the membrane (solid blue arrow) to prepare the LG neurons for the next feeding cycle. These new channels ensure appropriate output is generated again on demand, tuned by the feedback received in the previous activity cycle.