Abstract
Transcription factor nucleocytoplasmic dynamics play a key role in developmental gene regulation. In Dictyostelium , the transcription factor GtaC exhibits nucleocytoplasmic shuttling, but its shuttling trajectory across multicellular aggregation has not been systematically quantified. Using a knock-in strain, we tracked GtaC dynamics from starvation through aggregation and quantified developmental changes in shuttling period, amplitude, and synchrony. Notably, brief-pulse optogenetic activation of cAMP at higher input frequencies reproduced the reported attenuation of GtaC shuttling amplitude with high temporal precision and minimal phototoxicity. Together, long-term quantification and brief-pulse optogenetic cAMP perturbation show that GtaC nucleocytoplasmic shuttling is developmentally tuned in a frequency-dependent manner.