Optogenetic Fmri Interrogation of Brain-Wide Central Vestibular Pathways

Optogenetic Fmri Interrogation of Brain-Wide Central Vestibular Pathways

Optogenetic fMRI interrogation of brain-wide central vestibular pathways Alex T. L. Leonga,b, Yong Guc, Ying-Shing Chand, Hairong Zhenge, Celia M. Donga,b, Russell W. Chana,b, Xunda Wanga,b, Yilong Liua,b, Li Hai Tanf, and Ed X. Wua,b,d,g,1 aLaboratory of Biomedical Imaging and Signal Processing, The University of Hong Kong, Pokfulam, Hong Kong SAR, China; bDepartment of Electrical and Electronic Engineering, The University of Hong Kong, Pokfulam, Hong Kong SAR, China; cInstitute of Neuroscience, Key Laboratory of Primate Neurobiology, CAS Center for Excellence in Brain Science and Intelligence Technology, Chinese Academy of Sciences, Shanghai 200031, China; dSchool of Biomedical Sciences, Li Ka Shing Faculty of Medicine, The University of Hong Kong, Pokfulam, Hong Kong SAR, China; eShenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, Shenzhen 518055, China; fCenter for Language and Brain, Shenzhen Institute of Neuroscience, Shenzhen 518057, China; and gState Key Laboratory of Pharmaceutical Biotechnology, The University of Hong Kong, Pokfulam, Hong Kong SAR, China Edited by Marcus E. Raichle, Washington University in St. Louis, St. Louis, MO, and approved March 20, 2019 (received for review July 20, 2018) Blood oxygen level-dependent functional MRI (fMRI) constitutes a multisensory integration process in the vestibular system is op- powerful neuroimaging technology to map brain-wide functions tokinetic nystagmus, whereby visual cues are used to induce in response to specific sensory or cognitive tasks. However, fMRI compensatory reflexive eye movements to maintain a stable gaze mapping of the vestibular system, which is pivotal for our sense of while moving (11, 12). These eye movements involve inputs from balance, poses significant challenges. Physical constraints limit a the vestibular labyrinth, extraocular muscle tones through the subject’s ability to perform motion- and balance-related tasks in- oculomotor nerve, oculomotor nucleus (OMN) in the brainstem, side the scanner, and current stimulation techniques within the visual-associated thalamus and cortices, and cerebellum into the scanner are nonspecific to delineate complex vestibular nucleus vestibular nuclei, which integrate and mediate the fast and slow (VN) pathways. Using fMRI, we examined brain-wide neural activ- phases of the nystagmus response (13–15). In addition, recipro- ity patterns elicited by optogenetically stimulating excitatory neu- cal projections were found between the motor cortex (M1 & M2) rons of a major vestibular nucleus, the ipsilateral medial VN (MVN). and vestibular nuclei (6–10), which indicates that the vestibular We demonstrated robust optogenetically evoked fMRI activations nuclei integrate sensory and motor information to ensure accu- NEUROSCIENCE bilaterally at sensorimotor cortices and their associated thalamic rate motor execution and control for self-motion perception, nuclei (auditory, visual, somatosensory, and motor), high-order another key multisensory integration process in the vestibular cortices (cingulate, retrosplenial, temporal association, and parie- system (4). Using diffusion-based magnetic resonance imaging tal), and hippocampal formations (dentate gyrus, entorhinal cor- (MRI) tractography, studies also found the existence of these tex, and subiculum). We then examined the modulatory effects of projections in humans (16). Emerging evidence indicates that the the vestibular system on sensory processing using auditory and vestibular system also plays a vital role in cognition (3, 5, 17), as visual stimulation in combination with optogenetic excitation of spatial memory deficits occur following lesions to vestibular the MVN. We found enhanced responses to sound in the auditory nuclei or sense organs (18, 19). Taken together, these studies cortex, thalamus, and inferior colliculus ipsilateral to the stimulated highlight the multimodal nature of vestibular processing. We MVN. In the visual pathway, we observed enhanced responses to need comprehensive in vivo brain-wide investigations to reveal visual stimuli in the ipsilateral visual cortex, thalamus, and contralat- key regions vital in processing vestibular sensory information. eral superior colliculus. Taken together, our imaging findings reveal multiple brain-wide central vestibular pathways. We demonstrate large-scale modulatory effects of the vestibular system on sensory Significance processing. The vestibular system provides a critical role to coordinate fMRI | vestibular system | optogenetic | medial vestibular nucleus | balance and movement, yet it remains an underappreciated vestibular functions sense. Functional MRI (fMRI) reveals much information about brain-wide sensory and cognitive processes. However, fMRI mong our sensory systems, five senses (sight, hearing, touch, mapping of regions that actively process vestibular informa- Asmell, and taste) receive the most attention, leaving our tion remains technically challenging, as it can permit only lim- vestibular sense as the least understood. The vestibular system ited movement during scanning. Here, we deploy fMRI and senses angular and linear acceleration of the head in three dimen- optogenetic stimulation of vestibular excitatory neurons to sions via a labyrinth of sense organs in the inner ear and generates visualize numerous brain-wide central vestibular pathways and compensatory eye/body movements (i.e., vestibulo-ocular reflexes, interrogate their functional roles in multisensory processing. vestibulo-spinal reflexes) that stabilize visual images on the retina Our study highlights multiple routes to investigate vestibular functions and their integration with other sensory systems. We and adjust posture (1–4). These interactions allow us to maintain a reveal a method to gain critical knowledge into this critical clear vision of our external environment, while sensing the di- brain system. rection and speed of our body during our actual movement. These functions strongly suggest the integration of sensory and motor Author contributions: A.T.L.L. and E.X.W. designed research; A.T.L.L. and C.M.D. per- systems at different regions in the vestibular system (5). formed research; A.T.L.L., Y.G., Y.-S.C., H.Z., C.M.D., R.W.C., X.W., Y.L., L.H.T., and Early anatomical tracer studies in rodents (6–8), cats (9), and E.X.W. analyzed data; and A.T.L.L., Y.G., and E.X.W. wrote the paper. primates (10) showed an extensive number of axonal projections The authors declare no conflict of interest. coursing into and out of the vestibular nuclei, a brainstem region This article is a PNAS Direct Submission. that connects the inputs from vestibular sense organs in the inner This open access article is distributed under Creative Commons Attribution-NonCommercial- ear to other regions in the central nervous system. These studies NoDerivatives License 4.0 (CC BY-NC-ND). showed that the vestibular nuclei receive inputs from all sensory 1To whom correspondence should be addressed. Email: [email protected]. modalities from both their respective peripheral sense organs This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10. and thalamic regions, indicating the importance of the vestibular 1073/pnas.1812453116/-/DCSupplemental. system in multisensory integration. One excellent example of the www.pnas.org/cgi/doi/10.1073/pnas.1812453116 PNAS Latest Articles | 1of8 Downloaded by guest on September 25, 2021 Blood oxygen level-dependent (BOLD) functional MRI (fMRI) the brain via the combined use of optogenetics and fMRI (33, 34). maps localize brain functions by measuring neuronal activities We selectively drove expression of the optogenetic construct throughout the brain in response to specific sensory or cognitive channelrhodopsin-2 (ChR2) in the excitatory neurons of the MVN + tasks in basic and clinical research populations. This approach through a Ca2 /calmodulin-dependent protein kinase IIα (CaMKIIα) revealed the topographical organization of sensory and motor promoter. We then investigated the large-scale spatiotemporal regions (20–23). However, defining vestibular (i.e., balance- distribution of downstream excitatory signal propagation from the related, spatial orientation-related) regions and examining their MVN along central vestibular pathways and characterized the functions via traditional fMRI mapping approaches is technically modulatory effects of MVN stimulation on auditory and visual difficult. In general, subjects positioned inside a scanner during processing at the cortical, thalamic, and midbrain regions. fMRI experiments are unable to perform vestibular tasks, such as head and body rotation and/or translation movements. To cir- Results cumvent this limitation, current fMRI investigations in humans Brain-Wide fMRI Mapping of Downstream Signal Propagation from and animals utilize caloric (24), galvanic/electrical (25–27), and the MVN. We expressed CaMKIIα-dependent ChR2(H134R) auditory vestibular-evoked myogenic potential (VEMP) (28–30) fused with mCherry in MVN excitatory neurons in normal adult stimulation of the vestibular nerve. Sprague–Dawley rats (Fig. 1A and SI Appendix, Fig. S1A). We Such stimulation techniques have provided much needed in- confirmed specific expression in MVN excitatory neurons through sights into the brain-wide regions that actively participate in pro- colocalization of mCherry with CaMKIIα staining and verification cessing vestibular input. However, limitations to these approaches, of their monosynaptic projection targets to the contralateral

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