Close

Subchronic alteration of vestibular hair cells in mice: implications for multisensory gaze stabilization

Louise Schenberg, Aïda Palou, François Simon, Tess Bonnard, Charles-Elliot Barton, Desdemona Fricker, Michele Tagliabue, Jordi Llorens, Mathieu Beraneck

Posted on: 13 July 2023 , updated on: 14 July 2023

Preprint posted on 19 April 2023

When mice receive unreliable information from their ears, how do they use their eyes? 🐭 Schenberg et al. show that visual reflexes are altered and can supplement info during vestibular stimulation

Selected by Samantha Davis

Background

Balance and gaze stabilization are directed by the vestibular system, which begins with organs in the inner ear. Injury to these structures can lead to vertigo, disorientation, and falls as well as poor quality of life. Remarkably, the central vestibular system maintains plasticity throughout life and is able to recuperate after trauma in a process known as vestibular compensation. Other sensory systems such as the visual and proprioceptive systems provide feedback to guide recalibration. While many labs have begun investigating vestibular compensation, our knowledge of the involved mechanisms remains limited, especially since previous studies utilize complete suppression of the vestibular periphery.

A large number of patients experience fluctuating or incomplete vestibular dysfunction, warranting further study of compensation to transient or partial loss. Previous work has established 3,3ʹ-iminodiproprionitrile (IDPN) delivered subchronically as a model for fluctuating inner ear function in rodents with a treatment period followed by a washout period. Exposure to IDPN in drinking water has adverse effects on posture and locomotion, but its influence on gaze stabilization is currently unknown. As vestibulo-ocular circuits are used as the primary readout for clinical diagnostic testing, these results will be informative for clinicians as well as basic scientists.

Using IDPN exposure, the authors tested its effects on the two subclasses of peripheral organs—the semicircular canals and otolith organs—in mice with both histological and behavioral measures. Due to the multisensory nature of vestibular function, the authors additionally studied the integration of visual and vestibular systems during incomplete injury to the periphery.

Research questions: Does subchronic ototoxic exposure induce functional changes of the vestibular periphery? And if so, does visual information relieve transient and partial vestibular injury?

Results

Short-term ototoxic treatment reduces vestibulo-ocular reflexes temporarily

Testing of the canal-dependent and otolith-dependent vestibulo-ocular reflex (VOR) revealed significant dysfunction at the end of IDPN treatment. Interestingly, responses due to canal stimulation partially recovered by the end of the washout period, while those derived from otolith activation completely recovered. Despite reaching different levels of restoration, results of both tests followed a similar time course. Individual variability was similar between canal and otolith tests, such that functional changes were proportional at the end of treatment and washout periods. Therefore, the IDPN treatment affects gaze stabilization similarly for canal and otolith organ circuits.

IDPN affects type I hair cells specifically, which are restored after washout

To better understand the changes in function observed, histology of vestibular epithelium was performed. Although type II hair cell markers were unaffected in all organs, type I hair cell labeling was significantly reduced at treatment completion and recovered to control levels at the end of washout. Markers for type I hair cells of each organ type correlated with gain for their respective test; type II markers were not related to behavioral performance. This implies that type I hair cells are altered by brief IDPN exposure, though they do not seem to be killed by this compound, and that changes to these cells impact gaze stabilization.

Visual reflex is recruited at vestibular-dominated frequencies of motion

The optokinetic reflex (OKR) was also affected after IDPN treatment, with higher gain that persisted throughout the washout period; differences were significant specifically at higher frequencies. Phase, however, was unchanged in both temporal and stimulation frequency variables. Examining vestibular weight across frequencies suggested visual substitution in high frequencies specifically, which are driven by vestibular stimulation rather than visual. This reweighting of signals is most effectively accomplished with reliable vestibular responses, such that noisy and low-reproducible responses have additional adverse effects on gaze stabilization.

Significance 

This preprint from the Beraneck lab expands our understanding of vestibular compensation by addressing transient and partial dysfunction, and provides insight into visual reflexes during recovery. Visuo-vestibular integration is not only informed by the experimental results, but also through computational modeling. The approach translates to various patient experiences, generating interest from vestibular clinicians and scientists as well as those studying multisensory integration. 

Questions for the Authors

  1. Do you imagine type I hair cell function is permanently affected, even after the return of markers?
  2. How do you think aVOR results would differ at low and high frequencies over time?

References

Schenberg, L., Palou, A., Simon, F., Bonnard, T., Barton, C.-E., Fricker, D., … Beraneck, M. (2023). Subchronic alteration of vestibular hair cells in mice: implications for multisensory gaze stabilization. BioRxiv, 2023.04.19.535725. https://doi.org/10.1101/2023.04.19.535725

Tags: balance, plasticity, translational

doi: https://doi.org/10.1242/prelights.35022

Read preprint (No Ratings Yet)

Author's response

The author team shared

1. Do you imagine type I hair cell function is permanently affected, even after the return of markers?

Certainly, some type I hair cells may suffer a permanent loss of function, but our hypothesis is that most of them will recover function in parallel with the recovery in marker expression. More precisely, a recovery in type I hair cell function is the simplest explanation for the observed recovery in reflex gains during the washout period.

The question of cell function recovery is a very interesting one. Our previous studies on the subchronic IDPN model (Sedó-Cabezón et al., Dis. Model. Mech. 2015; Greguske et al., Arch. Toxicol., 2019) provide robust evidence that enduring toxic stress can cause a loss of function that is still reversible. The loss of vestibular function during continuous ototoxic exposure and its recovery during a subsequent washout period clearly associated with histological alterations and their posterior repair. While the initial observations focused on the loss of markers in the contact between the type I hair cell and its postsynaptic afferent, data in the present article and other unpublished data reveal that many molecular changes occur in the hair cell under toxic stress. We are now working to understand the relationship between these alterations and their reversion with the function loss and recovery. Importantly, we have obtained evidence that these phenomena are also relevant to the ototoxicity caused by the clinically relevant aminoglycoside antibiotics (Maroto et al., Arch. Toxicol. 2023).
On the other hand, the ototoxicity literature provides plenty of evidence for the persistence of damaged hair cells in vestibular epithelia after ototoxic insults. For instance, many images show hair cells with abnormal stereocilia that probably cannot accomplish proper mechanotrasduction. What determines that a hair cell shows reversible or persistent damage? What are the physiological consequences of the presence of damaged hair cells in the sensory epithelium? Are there molecular targets that can be stimulated to accelerate or induce hair cell repair? These are questions whose answers have clear therapeutic implications.

2. How do you think aVOR results would differ at low and high frequencies over time?

aVOR gain loss during the IDPN sub-chronic exposition is significantly present in all frequencies we tested (0.2 to 2Hz). However, we observed a gain loss at higher frequencies earlier during the protocol than at lower frequencies, concurring with data indicating that type I hair cells are better suited to detecting high frequencies stimulations than type II hair cells. As a six-week long exposure to IDPN leads to a decrease of the aVOR gain for both low and high frequencies, a longer exposition time should amplify the loss for all frequencies as both type I and type II hair cells have been showed to be damaged during a longer (8 weeks) exposure (Greguske et al, 2019).

Conversely, we observed during the washout period an earlier aVOR recovery of the lowest frequency compared to the highest frequencies. While the aVOR gain at these highest tested frequencies remained significantly decreased after 6 weeks of washout, a longer period might allow for further recovery. Whether a complete reversal of IDPN toxicity could ultimately be observed  remains an open question.

Have your say

Your email address will not be published. Required fields are marked *

This site uses Akismet to reduce spam. Learn how your comment data is processed.

Sign up to customise the site to your preferences and to receive alerts

Register here

Also in the animal behavior and cognition category:

A depth map of visual space in the primary visual cortex

Yiran He, Antonio Colas Nieto, Antonin Blot, et al.

Selected by 18 November 2024

Wing Gee Shum, Phoebe Reynolds

Neuroscience

Neural Basis of Number Sense in Larval Zebrafish

Peter Luu, Anna Nadtochiy, Mirko Zanon, et al.

Selected by 08 November 2024

Muhammed Sinan Malik

Animal Behavior and Cognition

Pharyngeal neuronal mechanisms governing sour taste perception in Drosophila melanogaster

Bhanu Shrestha, Jiun Sang, Suman Rimal, et al.

Selected by 23 September 2024

Matthew Davies

Cell Biology

Also in the neuroscience category:

Hippocampal neuroinflammation causes sex-specific disruptions in action selection, food approach memories, and neuronal activation

Kiruthika Ganesan, Sahar Ghorbanpour, William Kendall, et al.

Selected by 22 November 2024

Nicole Bertola

Neuroscience

A depth map of visual space in the primary visual cortex

Yiran He, Antonio Colas Nieto, Antonin Blot, et al.

Selected by 18 November 2024

Wing Gee Shum, Phoebe Reynolds

Neuroscience

Neural Basis of Number Sense in Larval Zebrafish

Peter Luu, Anna Nadtochiy, Mirko Zanon, et al.

Selected by 08 November 2024

Muhammed Sinan Malik

Animal Behavior and Cognition

Also in the neuroscience category:

2024 Hypothalamus GRC

This 2024 Hypothalamus GRC (Gordon Research Conference) preList offers an overview of cutting-edge research focused on the hypothalamus, a critical brain region involved in regulating homeostasis, behavior, and neuroendocrine functions. The studies included cover a range of topics, including neural circuits, molecular mechanisms, and the role of the hypothalamus in health and disease. This collection highlights some of the latest advances in understanding hypothalamic function, with potential implications for treating disorders such as obesity, stress, and metabolic diseases.

 



List by Nathalie Krauth

‘In preprints’ from Development 2022-2023

A list of the preprints featured in Development's 'In preprints' articles between 2022-2023

 



List by Alex Eve, Katherine Brown

CSHL 87th Symposium: Stem Cells

Preprints mentioned by speakers at the #CSHLsymp23

 



List by Alex Eve

Journal of Cell Science meeting ‘Imaging Cell Dynamics’

This preList highlights the preprints discussed at the JCS meeting 'Imaging Cell Dynamics'. The meeting was held from 14 - 17 May 2023 in Lisbon, Portugal and was organised by Erika Holzbaur, Jennifer Lippincott-Schwartz, Rob Parton and Michael Way.

 



List by Helen Zenner

ASCB EMBO Annual Meeting 2019

A collection of preprints presented at the 2019 ASCB EMBO Meeting in Washington, DC (December 7-11)

 



List by Madhuja Samaddar et al.

SDB 78th Annual Meeting 2019

A curation of the preprints presented at the SDB meeting in Boston, July 26-30 2019. The preList will be updated throughout the duration of the meeting.

 



List by Alex Eve

Autophagy

Preprints on autophagy and lysosomal degradation and its role in neurodegeneration and disease. Includes molecular mechanisms, upstream signalling and regulation as well as studies on pharmaceutical interventions to upregulate the process.

 



List by Sandra Malmgren Hill

Young Embryologist Network Conference 2019

Preprints presented at the Young Embryologist Network 2019 conference, 13 May, The Francis Crick Institute, London

 



List by Alex Eve
Close