Place recognition and heading retrieval are mediated by dissociable cognitive systems in mice

Julian, Joshua B.; Keinath, Alexander; Muzzio, Isabel A.; Epstein, Russell A.

doi:10.1073/pnas.1424194112

Cited by 50 publications

(60 citation statements)

References 51 publications

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“…This evidence suggest that, coherently with its interconnectivity with the hippocampus, the RCS may selectively engaged in translating the stored allocentric reference frame to an egocentric one thanks to a re-establishment of an "ego-oriented bearing" [18], resulting from the continuous synchronization between the inter-object direction in the environment in respect to egocentric current heading. A recent study carried out by Julian and colleagues gave support to our findings [33]. They examined the navigational behavior of mice in two tasks, in which animals had to recognize the chamber in which they were located (i.e., place recognition) and to retrieve their facing direction within that chamber (i.e., heading retrieval).…”

Section: Discussionsupporting

confidence: 70%

Do not get lost in translation: The role of egocentric heading in spatial orientation

Serino

Mestre

Mallet

et al. 2015

Neuroscience Letters

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Section: Discussionsupporting

confidence: 70%

Do not get lost in translation: The role of egocentric heading in spatial orientation

Serino

Mestre

Mallet

et al. 2015

Neuroscience Letters

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“…A visual cue that had been previously shown to be discriminable to both oriented and disoriented mice was present along one wall [6]. To disorient the mouse prior to the start of each trial, the mouse was removed from the chamber and placed in a small, lidded cylinder, which was subjected to four full clockwise and counterclockwise rotations.…”

Section: Resultsmentioning

confidence: 99%

“…Notably, nongeometric cues that could potentially distinguish the geometrically equivalent corners, such as a marking along one wall, are often ignored. This pattern of results—observed across numerous species including birds [5], rodents [4,6], and humans [7]—indicates that reorientation behavior is strongly informed by the spatial geometry of the environment.…”

Section: Introductionmentioning

confidence: 93%

Environmental Geometry Aligns the Hippocampal Map during Spatial Reorientation

et al. 2017

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Summary When a navigator's internal sense of direction is disrupted, she must rely on external cues to regain her bearings, a process termed spatial reorientation. Extensive research has demonstrated that the geometric shape of the environment exerts powerful control over reorientation behavior, but the neural and cognitive mechanisms underlying this phenomenon are not well understood. Whereas some theories claim that geometry controls behavior through an allocentric mechanism potentially tied to the hippocampus, others postulate that disoriented navigators reach their goals by using an egocentric view-matching strategy. To resolve this debate, we characterized hippocampal representations during reorientation. We first recorded from CA1 cells as disoriented mice foraged in chambers of various shapes. We found that the alignment of the recovered hippocampal map was determined by the geometry of the chamber, but not by nongeometric cues, even when these cues could be used to disambiguate geometric ambiguities. We then recorded hippocampal activity as disoriented mice performed a classical goal-directed spatial memory task in a rectangular chamber. Again, we found that the recovered hippocampal map aligned solely to the chamber geometry. Critically, we also found a strong correspondence between the hippocampal map alignment and the animal's behavior, making it possible to predict the search location of the animal from neural responses on a trial-by-trial basis. Together, these results demonstrate that spatial reorientation involves the alignment of the hippocampal map to local geometry. We hypothesize that geometry may be an especially salient cue for reorientation because it is an inherently stable aspect of the environment.

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“…For example, recent work in our lab demonstrated a behavioral dissociation between local coordinate and global identity representations when rodent navigators were required to reorient themselves to their surroundings before locating a goal (Julian, Keinath, Muzzio, & Epstein, 2015). Previous studies had established that after disorientation, rodents (Cheng, 1986), humans (Hermer & Spelke, 1994; Learmonth, Newcombe, & Huttenlocher, 2001; Lee & Spelke, 2011), and many other species (Lee, Ferrari, Vallortigara, & Sovrano, 2015; Vallortigara, 2009) exhibit “geometric errors” in their search patterns.…”

Section: Discussionmentioning

confidence: 99%

“…Notably, this search pattern is often unaffected by non-geometric cues such as colors or patterns on a wall that could potentially disambiguate these two geometrically equivalent corners. We demonstrated that mice will, however, use these non-geometric cues to determine which chamber they are in—even while simultaneously ignoring them as a guide to locations within the chamber (Julian et al, 2015). That is, the mice used visual features to establish their coarse location within the wider world (e.g.…”

Section: Discussionmentioning

confidence: 99%

Schematic representations of local environmental space guide goal-directed navigation

2017

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To successfully navigate to a target, it is useful to be able to define its location at multiple levels of specificity. For example, the location of a favorite coffee mug can be described in terms of which room it is in, or in terms of where it is within the room. An appealing hypothesis is that these levels of description are retrieved from memory by accessing the same representation at progressively finer levels of granularity—first remembering the general location of an object and then “zooming in.” Here we provide evidence for an alternative view, in which navigational behavior is guided by independent representations at multiple spatial scales. Subjects learned the locations of objects that were positioned within four visually distinct but geometrically similar buildings, which were in turn positioned within a broader virtual park. They were then tested on their knowledge of object location by asking them to navigate to the remembered location of each object. We examined errors during the test phase for confusions among geometrically analogous locations in different buildings—that is, navigating to the right location in the wrong building. We observed that subjects frequently made these confusions, which are analogous to remembering a passage’s location on the page of a book but not remembering the page that the passage is on. This suggests that subjects were recalling the object’s local location without recalling its global location. Further manipulations across seven experiments indicated that geometric confusions were observed even between buildings that were not metrically identical as long as geometrical equivalence could be defined. However, removing the walls so that the larger environment was no longer divided into subspaces abolished these errors. Taken together, our results suggest that human spatial memory contains two separable representations of “where” an object can be found: (i) a schematic map of where an object lies with respect to local landmarks and boundaries; (ii) a representation of the identity and location of each local environment.

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Place recognition and heading retrieval are mediated by dissociable cognitive systems in mice

Cited by 50 publications

References 51 publications

Do not get lost in translation: The role of egocentric heading in spatial orientation

Do not get lost in translation: The role of egocentric heading in spatial orientation

Environmental Geometry Aligns the Hippocampal Map during Spatial Reorientation

Schematic representations of local environmental space guide goal-directed navigation

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