neural substrates
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Unchanging and changing: hardwired taste circuits and their top-down control
The taste system detects 5 major categories of ethologically relevant stimuli (sweet, bitter, umami, sour and salt) and accordingly elicits acceptance or avoidance responses. While these taste responses are innate, the taste system retains a remarkable flexibility in response to changing external and internal contexts. Taste chemicals are first recognized by dedicated taste receptor cells (TRCs) and then transmitted to the cortex via a multi-station relay. I reasoned that if I could identify taste neural substrates along this pathway, it would provide an entry to decipher how taste signals are encoded to drive innate response and modulated to facilitate adaptive response. Given the innate nature of taste responses, these neural substrates should be genetically identifiable. I therefore exploited single-cell RNA sequencing to isolate molecular markers defining taste qualities in the taste ganglion and the nucleus of the solitary tract (NST) in the brainstem, the two stations transmitting taste signals from TRCs to the brain. How taste information propagates from the ganglion to the brain is highly debated (i.e., does taste information travel in labeled-lines?). Leveraging these genetic handles, I demonstrated one-to-one correspondence between ganglion and NST neurons coding for the same taste. Importantly, inactivating one ‘line’ did not affect responses to any other taste stimuli. These results clearly showed that taste information is transmitted to the brain via labeled lines. But are these labeled lines aptly adapted to the internal state and external environment? I studied the modulation of taste signals by conflicting taste qualities in the concurrence of sweet and bitter to understand how adaptive taste responses emerge from hardwired taste circuits. Using functional imaging, anatomical tracing and circuit mapping, I found that bitter signals suppress sweet signals in the NST via top-down modulation by taste cortex and amygdala of NST taste signals. While the bitter cortical field provides direct feedback onto the NST to amplify incoming bitter signals, it exerts negative feedback via amygdala onto the incoming sweet signal in the NST. By manipulating this feedback circuit, I showed that this top-down control is functionally required for bitter evoked suppression of sweet taste. These results illustrate how the taste system uses dedicated feedback lines to finely regulate innate behavioral responses and may have implications for the context-dependent modulation of hardwired circuits in general.
Primary Motor Cortex Circuitry in a Mouse Model of Parkinson’s Disease
The primary motor cortex (M1) is a major output center for movement execution and motor learning, and its dysfunction contributes to the pathophysiology of Parkinson’s disease (PD). While human studies have indicated that a loss of midbrain dopamine neurons alters M1 activation, the mechanisms underlying this phenomenon remain unclear. Using a mouse model of PD, we uncovered several shifts within M1 circuitry following dopamine depletion, including impaired excitation by thalamocortical afferents and altered excitability. Our findings add to the growing body of literature highlighting M1 as a major contributor in PD, and provide targeted neural substrates for possible therapeutic interventions.
Consciousness and implicit learning
Can we learn without conscious awareness? Numerous evidences in the research of implicit learning have indicated that people can learn the statistical structure of the stimuli but seemingly without any awareness of its underlying rules. However, it remains unclear what types of knowledge can be learned in implicit learning, what is the relationship between conscious and unconscious knowledge, and what are the neural substrates for the acquisition of conscious and unconscious knowledge. In this talk, I will discuss with you about these ongoing questions.
NEURAL SUBSTRATES OF SOCIAL HIGHER-ORDER LEARNING
FENS Forum 2026
AGE DEPENDENT EFFECT OF SOCIAL ISOLATION ON ANXIETY, SOCIAL BEHAVIOR AND NEURAL SUBSTRATES IN ZEBRAFISH
FENS Forum 2026
EMOTIONAL VALUE OF THE INITIAL ENCODING CONTEXT MODULATES THE NEURAL SUBSTRATES OF MEMORY INTEGRATION IN SENSORY PRECONDITIONING
FENS Forum 2026
FROM WALKING TO REACHING: SHARED NEURAL SUBSTRATES IN FREELY MOVING PRIMATES
FENS Forum 2026
OPTOGENETIC DISSOCIATION OF CINGULATE AND PRELIMBIC CORTEX FUNCTION IN MORPHINE-INDUCED REWARD AND AVERSION: NEURAL SUBSTRATES UNDERLYING THE PARADOXICAL EFFECT HYPOTHESIS
FENS Forum 2026
CONVERGENT NEURAL SUBSTRATES UNDERLYING ANHEDONIA AND COMPULSIVE EATING IN FRONTOTEMPORAL DEMENTIA
FENS Forum 2026
Neural substrates of a symbolic action grammar in primate frontal cortex
COSYNE 2025
Neural substrates for visual orientation
FENS Forum 2024
Distinct neural substrates for flexible and automatic motor sequence execution
COSYNE 2022
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