In a groundbreaking study that advances our understanding of motor control, researchers have unraveled critical brain circuits responsible for the seamless coordination of forelimb and orofacial movements during complex, naturalistic behaviors. The intricate orchestration of reach-to-consume actions, which necessitate precise timing and interplay between hand and mouth movements, has long puzzled neuroscientists seeking to decode how the brain integrates sensorimotor signals across distributed neural networks. The study, recently published in Nature Neuroscience, offers compelling evidence elucidating the pivotal role of corticothalamic pathways within the secondary motor cortex in coordinating such skilled motor acts in mice.
Complex motor behaviors, such as reaching for objects and bringing them to the mouth, rely on the integration of multiple cortical and subcortical brain regions. The research team, led by Li, An, Mulcahey, and colleagues, employed an innovative combination of wide-field calcium imaging and targeted photoinhibition techniques to map activity patterns across the mouse cortex during a reach-and-withdraw-to-drink (RWD) task. This ethologically relevant behavior mimics a natural sequence where mice extend their forelimb toward a spout, grasp the liquid source, and withdraw it toward the mouth for drinking, thereby engaging both forelimb and orofacial motor systems.
Wide-field imaging revealed a distributed cortical network dynamically engaged throughout the RWD behavior, highlighting a central area within the secondary motor cortex (MOs-c) as a key node. This region emerges as a high-order motor control hub where signals related to action progression converge. Targeting the MOs-c with photoinhibition selectively impaired components of the reach-to-consume sequence, affirming its essential role in finely tuned motor coordination. Such manipulation underscored the concept that this cortical locus orchestrates the timing and sequencing critical for effective sensorimotor integration.
The study went further to dissect the contributions of distinct projection neuron types within the MOs-c. Electrophysiological recordings complemented with cell-specific photoinhibition revealed remarkable functional divergence between pyramidal tract neurons and corticothalamic neurons (abbreviated CT^MOs). While both contribute to motor output, CT^MOs exhibited sustained firing spanning the entire RWD action duration, suggesting a unique integrative role that transcends simple motor execution. This finding sheds light on how neural circuits achieve ongoing coordination rather than merely initiating movement.
One of the most striking discoveries of the research lies in the interplay between CT^MOs neurons and thalamic circuits. CT^MOs neurons project to higher-order motor thalamic nuclei, which in turn send reciprocal feedback to cortical regions involved in motor planning. The authors demonstrated that CT^MOs amplify behaviorally relevant neural activity in postsynaptic thalamic neurons during the RWD behavior. Photoinhibition within these thalamic nodes additionally disrupted hand-to-mouth coordination, indicating that corticothalamic circuits serve as a bidirectional information highway crucial for synchronizing complex motor actions.
Monosynaptic tracing experiments revealed that CT^MOs neurons receive converging inputs from diverse forelimb and orofacial sensorimotor cortices. This anatomical convergence positions CT^MOs as integrative hubs where multimodal sensorimotor information is combined before influencing thalamic circuits. The reciprocal thalamocortical loop thus forms a feedback system that progressively refines motor output throughout ongoing behavior. This mechanistic insight elevates our understanding of higher-order motor control beyond traditional cortico-spinal paradigms.
The implications of these findings are profound: they challenge the long-held notion that cortical outputs to the spinal cord solely drive movement execution. Instead, the corticothalamic pathway provides a sophisticated modulatory channel that enhances the fidelity of sensorimotor integration. By selectively amplifying thalamic activity related to relevant motor programs, CT^MOs neurons ensure smooth transitions between successive motor phases required for functionally coherent actions like drinking.
Technically, the research employs a state-of-the-art combination of wide-field calcium imaging, which captures large-scale neural activity with high temporal resolution, and optogenetic photoinhibition, which enables cell-type specific and temporally precise suppression of neural populations. This methodology allowed the authors to systematically probe causal roles of neuronal subtypes and cortical areas during a naturalistic behavior, preserving ecological validity often lacking in simplified motor tasks.
Furthermore, the use of multichannel electrophysiology concurrently in cortical and thalamic regions enabled fine-grained assessment of neural dynamics underlying the coordinated motor sequence. Data revealed that not only do CT^MOs neurons sustain firing during action sequences, but postsynaptic thalamic neurons also show enhanced, temporally locked responses to these spike trains. Such synchronized corticothalamic activity likely underpins the neural computations supporting action progression and sensorimotor integration.
Behaviorally, disrupting this corticothalamic circuitry impaired the fluid coordination of forelimb reaching and mouth movements, underscoring the functional necessity of this pathway. These results provide a neurophysiological substrate for understanding disorders of motor coordination and perhaps offer targeted avenues for therapeutic interventions in diseases affecting skilled motor control, such as stroke or neurodegenerative conditions.
Taken together, this study paints a compelling picture of a distributed cortical network unified by a key corticothalamic axis that amplifies sensorimotor signals to choreograph complex, ethologically meaningful actions. It accentuates the central role of the secondary motor cortex’s corticothalamic output and its reciprocal thalamic partners as essential contributors to motor skill execution, coordination, and sequencing.
Beyond motor neuroscience, these insights may extend broadly to how the brain integrates multisensory inputs with motor plans, potentially informing artificial intelligence models of sensorimotor control and brain-machine interfaces. Emulating the corticothalamic feedback loops may enable more adaptive and fluid robotic control systems that better mimic naturalistic movement patterns.
As the field moves forward, further probing these corticothalamic circuits in diverse behavioral contexts and mapping their neuromodulatory regulation will be critical. Unraveling how these loops interact with basal ganglia, cerebellar, and spinal circuits could lead to a unified model of hierarchical motor coordination. Ultimately, this line of inquiry closes key gaps in understanding the neural logic of skilled behavior essential to survival.
The researchers’ achievement in delineating the specific roles of cortical projection neuron subtypes and their thalamic targets during a naturalistic action represents a milestone in systems neuroscience. It demonstrates the power of marrying advanced neurotechnological tools with ethologically relevant tasks to dissect the architecture of behaviorally critical neural circuits.
Li, An, Mulcahey and their team’s work not only clarifies how the brain executes seamless reach-to-consume movements but also sets the stage for translational breakthroughs targeting motor dysfunction. Their findings spotlight corticothalamic communication as an indispensable axis for action coordination, providing a paradigm for future studies to explore motor control mechanisms underlying complex behaviors in health and disease.
Subject of Research: Neural circuits underlying coordinated forelimb and orofacial movements during skilled motor behavior.
Article Title: Corticothalamic communication for action coordination in a skilled motor behavior.
Article References:
Li, Y., An, X., Mulcahey, P.J. et al. Corticothalamic communication for action coordination in a skilled motor behavior. Nat Neurosci (2026). https://doi.org/10.1038/s41593-025-02195-8
Image Credits: AI Generated
DOI: https://doi.org/10.1038/s41593-025-02195-8
Tags: brain circuits and motor skillscalcium imaging techniques in motor researchcomplex naturalistic behaviorscortical and subcortical brain regionscorticothalamic pathways in motor controlforelimb and orofacial movement coordinationintegration of sensorimotor signalsmotor control research advancementsNature Neuroscience study on motor behaviorphotoinhibition methods in neurosciencereach-to-consume actions in neuroscienceskilled motor coordination in mice
