Hallie Lazaro scite author profile

Nambiar

et al. 2020

Neuronal representations of spatial location and movement speed in the medial entorhinal cortex during the ‘active’ theta state of the brain are important for memory-guided navigation and rely on visual inputs. However, little is known about how visual inputs change neural dynamics as a function of running speed and time. By manipulating visual inputs in mice, we demonstrate that changes in spatial stability of grid cell firing correlate with changes in a proposed speed signal by local field potential theta frequency. In contrast, visual inputs do not alter the running speed-dependent gain in neuronal firing rates. Moreover, we provide evidence that sensory inputs other than visual inputs can support grid cell firing, though less accurately, in complete darkness. Finally, changes in spatial accuracy of grid cell firing on a 10 s time scale suggest that grid cell firing is a function of velocity signals integrated over past time.

Effects of visual inputs on neural dynamics for coding of location and running speed in medial entorhinal cortex

Dannenberg

Nambiar

et al. 2020

Preprint

11Neuronal representations of spatial location and movement speed are important for a broad 12 range of cognitive functions, including spatial self-localization and memory-guided navigation. 13Two possible speed signals, by theta frequency or by firing rate, have been hypothesized to 14 provide the velocity signal needed for generating the spatially periodic grid cell firing pattern. 15However, which of these speed signals is utilized by the brain remains unknown. By 16 manipulating visual inputs and analyzing the time-courses of evoked changes, we demonstrate 17 that changes in spatial stability of grid cell firing correlate in time with changes in speed coding 18 by local field potential theta frequency. In contrast, visual inputs do not affect speed coding by 19 firing rate even if baseline firing rates are changed. Moreover, grid cells maintain a spatially 20 periodic firing pattern, though less stable, in complete darkness. These data suggest that mice 21 use an oscillatory speed signal to perform path integration. 22 23 ( Supplementary Fig. 1B & C). 126 127Local field potential activity in the MEC primarily reflects the summed activity of synaptic inputs 128 to the MEC, which is likely to be correlated with firing patterns of MEC neurons. Many neurons 129 in the MEC show a theta rhythmic firing pattern and-similarly to the LFP theta frequency-the 130 frequency of theta rhythmic firing increases with running speed (Hinman et al., 2016). In our 131 data set, we identified a total of n = 342 neurons from 14 mice as theta modulated based on 132 their autocorrelograms. We asked if and how theta rhythmic firing in these theta modulated 133 MEC neurons is affected by removing and reinstating all visual inputs. Towards that aim we 134 used an MLE approach (Climer et al., 2015) to fit a model of theta spiking rhythmicity to the 135 observed spike train autocorrelations and identify the frequency and magnitude of theta 136

Temporal dynamics of cholinergic activity in the septo-hippocampal system

Kopsick

Hartzell

et al. 2022

Front. Neural Circuits

Cholinergic projection neurons in the medial septum and diagonal band of Broca are the major source of cholinergic modulation of hippocampal circuit functions that support neural coding of location and running speed. Changes in cholinergic modulation are known to correlate with changes in brain states, cognitive functions, and behavior. However, whether cholinergic modulation can change fast enough to serve as a potential speed signal in hippocampal and parahippocampal cortices and whether the temporal dynamics in such a signal depend on the presence of visual cues remain unknown. In this study, we use a fiber-photometric approach to quantify the temporal dynamics of cholinergic activity in freely moving mice as a function of the animal’s movement speed and visual cues. We show that the population activity of cholinergic neurons in the medial septum and diagonal band of Broca changes fast enough to be aligned well with changes in the animal’s running speed and is strongly and linearly correlated to the logarithm of the animal’s running speed. Intriguingly, the cholinergic modulation remains strongly and linearly correlated to the speed of the animal’s neck movements during periods of stationary activity. Furthermore, we show that cholinergic modulation is unaltered during darkness. Lastly, we identify rearing, a stereotypic behavior where the mouse stands on its hindlimbs to scan the environment from an elevated perspective, is associated with higher cholinergic activity than expected from neck movements on the horizontal plane alone. Taken together, these data show that temporal dynamics in the cholinergic modulation of hippocampal circuits are fast enough to provide a potential running speed signal in real-time. Moreover, the data show that cholinergic modulation is primarily a function of the logarithm of the animal’s movement speed, both during locomotion and during stationary activity, with no significant interaction with visual inputs. These data advance our understanding of temporal dynamics in cholinergic modulation of hippocampal circuits and their functions in the context of neural coding of location and running speed.

Author response: Effects of visual inputs on neural dynamics for coding of location and running speed in medial entorhinal cortex

Dannenberg

Nambiar

et al. 2020

Temporal dynamics of cholinergic activity in the septo-hippocampal system

Kopsick

Hartzell

et al. 2022

Preprint

Cholinergic projection neurons in the medial septum and diagonal band of Broca are the major source of cholinergic modulation of hippocampal circuit functions that support neural coding of location and running speed. Changes in cholinergic modulation are known to correlate with changes in brain states, cognitive functions, and behavior. However, whether cholinergic modulation can change fast enough to serve as a potential speed signal in hippocampal and parahippocampal cortices and whether the temporal dynamics in such a signal depend on the presence of visual cues remain unknown. In this study, we use a fiber-photometric approach to quantify the temporal dynamics of cholinergic activity in freely moving mice as a function of the animal's running speed and visual cues. We show that the population activity of cholinergic neurons in the medial septum and diagonal band of Broca changes fast enough to be aligned well with changes in the animal's running speed and is strongly and linearly correlated to the logarithm of the animal's running speed. Intriguingly, the cholinergic modulation remains strongly and linearly correlated to the speed of the animal's neck movements during periods of stationary activity. Furthermore, we show that cholinergic modulation is unaltered during darkness. Lastly, we identify rearing, a discrete behavior where the mouse stands on its hindlimbs to scan the environment from an elevated perspective, is associated with higher cholinergic activity than expected from neck movements on the horizontal plane alone. Taken together, these data show that temporal dynamics in the cholinergic modulation of hippocampal circuits are fast enough to provide a potential running speed signal in real-time. Moreover, the data show that cholinergic modulation is primarily a function of the logarithm of the animal's movement speed, both during locomotion and during stationary activity, with no significant interaction with visual inputs. These data advance our understanding of temporal dynamics in cholinergic modulation of hippocampal circuits and their functions in the context of neural coding of location and running speed.