Descending autonomic signaling, traveling from central stations, contributes to regulating heart rate (HR) in response to environmental demands. However, whether and how cardiac rhythm influences central functions in a “bottom-up modality” remains poorly understood. Here, we tested whether persistently elevated HR in mice affects the brain-heart bidirectional communication, the electroencephalographic (EEG) patterns, and behavior. To this end, we used mice with cardiac-selective overexpression of adenylyl cyclase type 8 (TGAC8 mice) that harbor continually heightened HR and autonomic surveillance escape. We implanted them with a double Holter system to obtain ECGs, EEGs, and evaluate changes in the ECG/EEG relationship via the Granger Causality statistical approach. Actigraphy, elevated plus maze, open field, Y-maze, fear conditioning tests served to assess behavior. First, we confirmed that TGAC8s mice have continuously elevated HR, reduced HR variability (HRV), i.e., High (HF) /Low Frequency (LF) components of the ECG, and decreased alpha-DFA. Moreover, as expected, TGAC8 mice isolated atria showed a substantially blunted response to sympathomimetic agents. When EEG rhythms are concerned, TGAC8 mice manifested a marked decrease in theta-2 frequency (in the range of 6-7 Hz), theta-2 wave count, and amplitude. In terms of behavior, TGAC8 mice showed no basal difference in anxiety levels, mood, and memory compared to WT littermates. In contrast, their locomotor activity (i.e. time mobile, total distance traveled, average and maximum speed) was significantly increased, and these changes correlated with the blunting in theta-2 activity. Of relevance, analysis of the informational flow between tachogram and EEG traces in theta-2 range, via Granger analysis, revealed a substantial decrement in the extent of heart/brain bidirectional communication. For the first time, our study shows that persistently elevated cardiac chronotropic activity is penetrant enough to disrupt the brain/heart flow of information, influencing central physiological patterns that control complex activities, such as locomotion.
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