Takumi Sugioka scite author profile

Graphical Abstract Highlights d dI6dmrt3a and V0d neurons are commissural inhibitory neurons in zebrafish d dI6dmrt3a and V0d neurons are cooperatively involved in leftright alternation d dI6dmrt3a and V0d neurons are recruited at different frequencies of swimming d Ablation of dI6dmrt3a neurons impairs regular left-right alternation SUMMARY Commissural inhibitory neurons in the spinal cord of aquatic vertebrates coordinate left-right body alternation during swimming.Their developmental origin, however, has been elusive. We investigate this by comparing the anatomy and function of two commissural inhibitory neuron types, dI6dmrt3a and V0d, derived from the pd6 and p0 progenitor domains, respectively. We find that both of these commissural neuron types have monosynaptic, inhibitory connections to neuronal populations active during fictive swimming, supporting their role in providing inhibition to the contralateral side. V0d neurons tend to fire during faster and stronger movements, while dI6dmrt3a neurons tend to fire more consistently during normal fictive swimming. Ablation of dI6dmrt3a neurons leads to an impairment of left-right alternating activity through abnormal co-activation of ventral root neurons on both sides of the spinal cord. Our results suggest that dI6dmrt3a and V0d commissural inhibitory neurons synergistically provide inhibition to the opposite side across different swimming behaviors.

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Biomechanics and neural circuits for vestibular-induced fine postural control in larval zebrafish

Sugioka

Tanimoto

Higashijima

2023

Nat Commun

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Land-walking vertebrates maintain a desirable posture by finely controlling muscles. It is unclear whether fish also finely control posture in the water. Here, we showed that larval zebrafish have fine posture control. When roll-tilted, fish recovered their upright posture using a reflex behavior, which was a slight body bend near the swim bladder. The vestibular-induced body bend produces a misalignment between gravity and buoyancy, generating a moment of force that recovers the upright posture. We identified the neural circuits for the reflex, including the vestibular nucleus (tangential nucleus) through reticulospinal neurons (neurons in the nucleus of the medial longitudinal fasciculus) to the spinal cord, and finally to the posterior hypaxial muscles, a special class of muscles near the swim bladder. These results suggest that fish maintain a dorsal-up posture by frequently performing the body bend reflex and demonstrate that the reticulospinal pathway plays a critical role in fine postural control.

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Takumi Sugioka

Functional Diversity of Glycinergic Commissural Inhibitory Neurons in Larval Zebrafish

Biomechanics and neural circuits for vestibular-induced fine postural control in larval zebrafish

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