Otoconia‐deficient mice show selective spatial deficits

Yoder, Ryan M.; Kirby, Seth

doi:10.1002/hipo.22300

Cited by 23 publications

(33 citation statements)

References 40 publications

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“…In fact, rats with complete vestibular lesions were able to perform relatively well on the homing task in light [18], despite the fact that vestibular lesions or inactivation completely abolishes the head direction signal [13, 14]. However, tilted mice were impaired at performing a radial arm maze discrimination task in light when only distal cues were available to guide navigation [23]. Thus, signals from the otolith organs have an important role in the directional aspect of navigation, and visual information can compensate for these deficits in some tasks.…”

Section: Discussionmentioning

confidence: 99%

“…The otolith organs also contribute to head direction cell function, but this contribution appears to be relatively less than that of the canals; otoconia-deficient mice have head direction cells that are directionally tuned, but this tuning degrades over time [22]. Nevertheless, the degraded head direction signal of otoconia-deficient mice is paralleled by deficits in the performance of directional navigation tasks such as the radial arm maze, food-carrying (homing) task, and Y-maze alternation [4, 23, 24] for review, see [25]. However, otoconia-deficient mice were able to accurately perceive the goal location during the probe trial on a Barnes maze, suggesting place recognition was intact [23].…”

Section: Introductionmentioning

confidence: 99%

“…Nevertheless, the degraded head direction signal of otoconia-deficient mice is paralleled by deficits in the performance of directional navigation tasks such as the radial arm maze, food-carrying (homing) task, and Y-maze alternation [4, 23, 24] for review, see [25]. However, otoconia-deficient mice were able to accurately perceive the goal location during the probe trial on a Barnes maze, suggesting place recognition was intact [23]. The available evidence thus suggests that otolith signals contribute heavily to the directional aspect of navigation in both visual and non-visual environments, but have a lesser role in the locational aspect.…”

Section: Introductionmentioning

confidence: 99%

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Otolith dysfunction alters exploratory movement in mice

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Cherep

Donaldson

et al. 2017

Behavioural Brain Research

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The organization of rodent exploratory behavior appears to depend on self-movement cue processing. As of yet, however, no studies have directly examined the vestibular system’s contribution to the organization of exploratory movement. The current study sequentially segmented open field behavior into progressions and stops in order to characterize differences in movement organization between control and otoconia-deficient tilted mice under conditions with and without access to visual cues. Under completely dark conditions, tilted mice exhibited similar distance traveled and stop times overall, but had significantly more circuitous progressions, larger changes in heading between progressions, and less stable clustering of home bases, relative to control mice. In light conditions, control and tilted mice were similar on all measures except for the change in heading between progressions. This pattern of results is consistent with otoconia-deficient tilted mice using visual cues to compensate for impaired self-movement cue processing. This work provides the first empirical evidence that signals from the otolithic organs mediate the organization of exploratory behavior, based on a novel assessment of spatial orientation.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Otolith dysfunction alters exploratory movement in mice

Blankenship

Cherep

Donaldson

et al. 2017

Behavioural Brain Research

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“…Because head direction cell activity and landmark navigation is known to be disrupted in tilted mice, [7,9] we assessed landmark control over place cell activity by rotating the cue card in session 2 and measuring the degree to which place cells were anchored to that cue.…”

Section: Resultsmentioning

confidence: 99%

“…Otoconia-deficient head tilt mice are known to have attenuated vestibulo-ocular reflex [23], and this deficit may be present in tilted mice. However, previous studies show that tilted mice are able to rely on their visual system to navigate to cues, and their performance suffers to a greater extent in non-visual environments or when visual cues are sparse [9,24,25]. …”

Section: Resultsmentioning

confidence: 99%

Linear Self-Motion Cues Support the Spatial Distribution and Stability of Hippocampal Place Cells

et al. 2018

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The vestibular system provides a crucial component of place-cell and head-direction cell activity [1-7]. Otolith signals are necessary for head-direction signal stability and associated behavior [8, 9], and the head-direction signal's contribution to parahippocampal spatial representations [10-14] suggests that place cells may also require otolithic information. Here, we demonstrate that self-movement information from the otolith organs is necessary for the development of stable place fields within and across sessions. Place cells in otoconia-deficient tilted mice showed reduced spatial coherence and formed place fields that were located closer to environmental boundaries, relative to those of control mice. These differences reveal an important otolithic contribution to place-cell functioning and provide insight into the cognitive deficits associated with otolith dysfunction.

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Otolithic information is required for homing in the mouse

et al. 2015

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Navigation and the underlying brain signals are influenced by various allothetic and idiothetic cues, depending on environmental conditions and task demands. Visual landmarks typically control navigation in familiar environments but, in the absence of landmarks, self-movement cues are able to guide navigation relatively accurately. These self-movement cues include signals from the vestibular system, and may originate in the semicircular canals or otolith organs. Here, we tested the otolithic contribution to navigation on a food-hoarding task in darkness and in light. The dark test prevented the use of visual cues and thus favored the use of self-movement information, whereas the light test allowed the use of both visual and non-visual cues. In darkness, tilted mice made shorter-duration stops during the outward journey, and made more circuitous homeward journeys than control mice; heading error, trip duration, and peak error were greater for tilted mice than for controls. In light, tilted mice also showed more circuitous homeward trips, but appeared to correct for errors during the journey; heading error, trip duration, and peak error were similar between groups. These results suggest that signals from the otolith organs are necessary for accurate homing performance in mice, with the greatest contribution in non-visual environments.

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Otoconia‐deficient mice show selective spatial deficits

Cited by 23 publications

References 40 publications

Otolith dysfunction alters exploratory movement in mice

Otolith dysfunction alters exploratory movement in mice

Linear Self-Motion Cues Support the Spatial Distribution and Stability of Hippocampal Place Cells

Otolithic information is required for homing in the mouse

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