Data from: Complexity of frequency receptive fields predicts tonotopic variability across species
Gaucher, Quentin et al. (2020), Data from: Complexity of frequency receptive fields predicts tonotopic variability across species, Dryad, Dataset, https://doi.org/10.5061/dryad.9ghx3ffd9
Primary cortical areas contain maps of sensory features, including sound frequency in primary auditory cortex (A1). Two-photon calcium imaging in mice has confirmed the presence of these global tonotopic maps, while uncovering an unexpected local variability in the stimulus preferences of individual neurons in A1 and other primary regions. Here we show that local heterogeneity of frequency preferences is not unique to rodents. Using two-photon calcium imaging in layers 2/3, we found that local variance in frequency preferences is equivalent in ferrets and mice. Neurons with multipeaked frequency tuning are less spatially organized than those tuned to a single frequency in both species. Furthermore, we show that microelectrode recordings may describe a smoother tonotopic arrangement due to a sampling bias towards neurons with simple frequency tuning. These results help explain previous inconsistencies in cortical topography across species and recording techniques.
Ferret and mouse auditory cortical responses to pure tones, measured using 2-photon calcium imaging of GCaMP6. Images pre-processed using Suite2p software, and calcium traces for individual neurons then deconvolved into spike probabilities (OASIS).
The matlab code can be used to reproduce all the main figures in our published paper.
Biotechnology and Biological Sciences Research Council, Award: BB/M010929/1
Wellcome Trust, Award: WT076508AIA
Wellcome Trust, Award: WT108369/Z/2015/Z