Transformation of a Spatial Map across the Hippocampal-Lateral Septal Circuit

Tingley, David; Buzsáki, György

doi:10.1016/j.neuron.2018.04.028

Cited by 92 publications

(137 citation statements)

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“…The preserved place cell activity after gabazine injections demonstrates that the neural computation of self‐localization information occurs independently of the strength of the hippocampal theta rhythm. However, the theta rhythmic organization of hippocampal output may be critical for its ability to communicate to downstream structures and influence ongoing behavior (Benchenane et al, ; Hyman, Zilli, Paley, & Hasselmo, ; Tabuchi et al, ; Tingley & Buzsaki, ). To directly assess navigation abilities following septal injections, we trained rats in a place accuracy task where the rats were required to pause in a specific goal area in the recording arena to trigger the release of a sugar pellet from an overhead pellet feeder.…”

Section: Resultsmentioning

confidence: 99%

“…Indeed, since overall grid cell activity is also affected by septal inactivation, septal gabazine injections could be used in future studies to more directly test the role of theta rhythm in producing grid cell spatial firing patterns. However, recent work has demonstrated that spatial information in hippocampal output structures explicitly depends on phase coding relative to hippocampal theta (Tingley & Buzsaki, ). Thus, the coherent theta rhythm, coordinating activity across hippocampus and associated downstream regions, may form a channel for the broadcast of spatial information that is critically necessary to convert spatial codes to adaptive behavior.…”

Section: Discussionmentioning

confidence: 99%

“…Models have demonstrated how theta oscillators could contribute directly to the formation and expression of place cell firing fields (Lengyel, Szatmary, & Erdi, ; Welday, Shlifer, Bloom, Zhang, & Blair, ). Alternatively, theta may have little direct role in producing spatially localized firing (Brandon et al, ; Brandon, Koenig, Leutgeb, & Leutgeb, ; Yartsev, Witter, & Ulanovsky, ), but may allow the hippocampus to encode spatial or temporal event sequences (Gupta, van der Meer, Touretzky, & Redish, ; Wang, Romani, Lustig, Leonardo, & Pastalkova, ) or to efficiently broadcast spatial information to downstream structures (Benchenane et al, ; Tabuchi, Mulder, & Wiener, ; Tingley & Buzsaki, ; van der Meer & Redish, ). Therefore, to assess the functional relevance of hippocampal theta, it is of great interest to attenuate or abolish the rhythm independent from effects on place cell activity.…”

Section: Introductionmentioning

confidence: 99%

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Place cell firing cannot support navigation without intact septal circuits

et al. 2019

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Though it has been known for over half a century that interference with the normal activity of septohippocampal neurons can abolish hippocampal theta rhythmicity, a definitive answer to the question of its function has remained elusive. To clarify the role of septal circuits and theta in location‐specific activity of place cells and spatial behavior, three drugs were delivered to the medial septum of rats: Tetracaine, a local anesthetic; muscimol, a GABA‐A agonist; and gabazine, a GABA‐A antagonist. All three drugs disrupted normal oscillatory activity in the hippocampus. However, tetracaine and muscimol both reduced spatial firing and interfered with the rat's ability to navigate to a hidden goal. After gabazine, location‐specific firing was preserved in the absence of theta, but rats were unable to accurately locate the hidden goal. These results indicate that theta is unnecessary for location‐specific firing of hippocampal cells, and that place cell activity cannot support accurate navigation when septal circuits are disrupted.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Place cell firing cannot support navigation without intact septal circuits

et al. 2019

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“…In such models, oscillatory modulation of spike trains occurs in such a way that position information is conveyed by between‐cell spike intervals (i.e., spike correlations), rather than within‐cell spike intervals (i.e., firing rates). Recent evidence suggests that neural populations in the lateral septum may utilize this type of oscillatory interference code for the rat's position (Tingley & Buzsaki, ). Simulations presented below show that when an oscillatory interference code is constructed from simulated theta cells, position information can be recovered from theta cell co‐firing rates using a sigma‐chi decoding process similar to that used above for recovering velocity information from HD cell or grid cell co‐firing rates, and velocity information can be recovered from theta cell firing rates using the same sigma decoding process that was used above to recover position information from HD cell or grid cell firing rates.…”

Section: Resultsmentioning

confidence: 99%

“…Position‐tuned neurons (such as place and grid cells) exhibit oscillatory modulation of their spike trains by theta rhythm. Information about the animal's position can be decoded not only from the firing rates of these neurons (Wilson & McNaughton, ), but also from the phases at which spikes occur relative to theta rhythm in the local field potential (Climer, Newman, & Hasselmo, ; Hafting, Fyhn, Bonnevie, Moser, & Moser, ; Jeewajee et al, ; Jensen & Lisman, ; O'Keefe & Recce, ; Skaggs, McNaughton, Wilson, & Barnes, ; Tingley & Buzsaki, ). Hence, spatially tuned neurons can encode the animal's position in two different ways: in their firing rates and firing phases.…”

Section: Introductionmentioning

confidence: 99%

An uncertainty principle for neural coding: Conjugate representations of position and velocity are mapped onto firing rates and co‐firing rates of neural spike trains

Grgurich¹,

Blair²

2020

Hippocampus

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The hippocampal system contains neural populations that encode an animal's position and velocity as it navigates through space. Here, we show that such populations can embed two codes within their spike trains: a firing rate code ( R) conveyed by within‐cell spike intervals, and a co‐firing rate code (trueR˙) conveyed by between‐cell spike intervals. These two codes behave as conjugates of one another, obeying an analog of the uncertainty principle from physics: information conveyed in R comes at the expense of information in trueR˙, and vice versa. An exception to this trade‐off occurs when spike trains encode a pair of conjugate variables, such as position and velocity, which do not compete for capacity across R and trueR˙. To illustrate this, we describe two biologically inspired methods for decoding R and trueR˙, referred to as sigma and sigma‐chi decoding, respectively. Simulations of head direction and grid cells show that if firing rates are tuned for position (but not velocity), then position is recovered by sigma decoding, whereas velocity is recovered by sigma‐chi decoding. Conversely, simulations of oscillatory interference among theta‐modulated “speed cells” show that if co‐firing rates are tuned for position (but not velocity), then position is recovered by sigma‐chi decoding, whereas velocity is recovered by sigma decoding. Between these two extremes, information about both variables can be distributed across both channels, and partially recovered by both decoders. These results suggest that populations with different spatial and temporal tuning properties—such as speed versus grid cells—might not encode different information, but rather, distribute similar information about position and velocity in different ways across R and trueR˙. Such conjugate coding of position and velocity may influence how hippocampal populations are interconnected to form functional circuits, and how biological neurons integrate their inputs to decode information from firing rates and spike correlations.

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Modulation of lateral septal and dorsomedial striatal neurons by hippocampal sharp‐wave ripples, theta rhythm, and running speed

Howe¹,

Blair²

2021

Hippocampus

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Single units were recorded in hippocampus, lateral septum (LS), and dorsomedial striatum (DMS) while freely behaving rats (n = 3) ran trials in a T-maze task and rested in a holding bucket between trials. In LS, 28% (64/226) of recorded neurons were excited and 14% (31/226) were inhibited during sharp wave ripples (SWRs). LS neurons that were excited during SWRs fired preferentially on the downslope of hippocampal theta rhythm and had firing rates that were positively correlated with running speed; LS neurons that were inhibited during SWRs fired preferentially on the upslope of hippocampal theta rhythm and had firing rates that were negatively correlated with running speed. In DMS, only 3.3% (12/366) of recorded neurons were excited and 5.7% (21/366) were inhibited during SWRs. As in LS, DMS neurons that were excited by SWRs tended to have firing rates that were positively modulated by running speed, whereas DMS neurons that were inhibited by SWRs tended to have firing rates that were negatively modulated by running speed. But in contrast with LS, these two DMS subpopulations did not clearly segregate their spikes to different phases of the theta cycle. Based on these results and a review of prior findings, we discuss how concurrent activation of spatial trajectories in hippocampus and motor representations in LS and DMS may contribute to neural computations that support reinforcement learning and value-based decision making.

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Transformation of a Spatial Map across the Hippocampal-Lateral Septal Circuit

Cited by 92 publications

References 65 publications

Place cell firing cannot support navigation without intact septal circuits

Place cell firing cannot support navigation without intact septal circuits

An uncertainty principle for neural coding: Conjugate representations of position and velocity are mapped onto firing rates and co‐firing rates of neural spike trains

Modulation of lateral septal and dorsomedial striatal neurons by hippocampal sharp‐wave ripples, theta rhythm, and running speed

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