Brainstem circuits help zebrafish get into the swim of things.

In this issue of Neuron, Berg et al.1 investigate the functional contribution of two molecularly distinct subpopulations of spinal-projecting midbrain neurons in adult zebrafish, shedding light on mechanisms regulating properties of locomotion such as speed and bout duration.

Structural and functional map for forelimb movement phases between cortex and medulla.

The cortex influences movement by widespread top-down projections to many nervous system regions. Skilled forelimb movements require brainstem circuitry in the medulla; however, the logic of cortical interactions with these neurons remains unexplored. Here, we reveal a fine-grained anatomical and functional map between anterior cortex (AC) and medulla in mice. Distinct cortical regions generate three-dimensional synaptic columns tiling the lateral medulla, topographically matching the dorso-ventral positions of postsynaptic neurons tuned to distinct forelimb action phases. Although medial AC (MAC) terminates ventrally and connects to forelimb-reaching-tuned neurons and its silencing impairs reaching, lateral AC (LAC) influences dorsally positioned neurons tuned to food handling, and its silencing impairs handling. Cortico-medullary neurons also extend collaterals to other subcortical structures through a segregated channel interaction logic. Our findings reveal a precise alignment between cortical location, its function, and specific forelimb-action-tuned medulla neurons, thereby clarifying interaction principles between these two key structures and beyond.

Networking brainstem and basal ganglia circuits for movement.

The execution and learning of diverse movements involve neuronal networks distributed throughout the nervous system. The brainstem and basal ganglia are key for processing motor information. Both harbour functionally specialized populations stratified on the basis of axonal projections, synaptic inputs and gene expression, revealing a correspondence between circuit anatomy and function at a high level of granularity. Neuronal populations within both structures form multistep processing chains dedicated to the execution of specific movements; however, the connectivity and communication between these two structures is only just beginning to be revealed. The brainstem and basal ganglia are also embedded into wider networks and into systems-level loops. Important networking components include broadcasting neurons in the cortex, cerebellar output neurons and midbrain dopaminergic neurons. Action-specific circuits can be enhanced, vetoed, work in synergy or competition with others, or undergo plasticity to allow adaptive behaviour. We propose that this highly specific organization of circuits in the motor system is a core ingredient for supporting behavioural specificity, and at the same time for providing an adequate substrate for behavioural flexibility.

Absence of familiarity triggers hallmarks of autism in mouse model through aberrant tail-of-striatum and prelimbic cortex signaling.

Autism spectrum disorder (ASD) involves genetic and environmental components. The underlying circuit mechanisms are unclear, but behaviorally, aversion toward unfamiliarity, a hallmark of autism, might be involved. Here, we show that in Shank3ΔC/ΔC ASD model mice, exposure to novel environments lacking familiar features produces long-lasting failure to engage and repetitive behaviors upon re-exposure. Inclusion of familiar features at first context exposure prevented enhanced dopamine transients in tail of striatum (TS) and restored context-specific control of engagement to wild-type levels in Shank3ΔC/ΔC mice. Engagement upon context re-exposure depended on the activity in prelimbic cortex (PreL)-to-TS projection neurons in wild-type mice and was restored in Shank3ΔC/ΔC mice by the chemogenetic activation of PreL→TS projection neurons. Environmental enrichment prevented ASD-like phenotypes by obviating the dependence on PreL→TS activity. Therefore, novel context experience has a key role in triggering ASD-like phenotypes in genetically predisposed mice, and behavioral therapies involving familiarity and enrichment might prevent the emergence of ASD phenotypes.

Functional diversity for body actions in the mesencephalic locomotor region.

The mesencephalic locomotor region (MLR) is a key midbrain center with roles in locomotion. Despite extensive studies and clinical trials aimed at therapy-resistant Parkinson's disease (PD), debate on its function remains. Here, we reveal the existence of functionally diverse neuronal populations with distinct roles in control of body movements. We identify two spatially intermingled glutamatergic populations separable by axonal projections, mouse genetics, neuronal activity profiles, and motor functions. Most spinally projecting MLR neurons encoded the full-body behavior rearing. Loss- and gain-of-function optogenetic perturbation experiments establish a function for these neurons in controlling body extension. In contrast, Rbp4-transgene-positive MLR neurons project in an ascending direction to basal ganglia, preferentially encode the forelimb behaviors handling and grooming, and exhibit a role in modulating movement. Thus, the MLR contains glutamatergic neuronal subpopulations stratified by projection target exhibiting roles in action control not restricted to locomotion.

A functional map for diverse forelimb actions within brainstem circuitry.

The brainstem is a key centre in the control of body movements. Although the precise nature of brainstem cell types and circuits that are central to full-body locomotion are becoming known1-5, efforts to understand the neuronal underpinnings of skilled forelimb movements have focused predominantly on supra-brainstem centres and the spinal cord6-12. Here we define the logic of a functional map for skilled forelimb movements within the lateral rostral medulla (latRM) of the brainstem. Using in vivo electrophysiology in freely moving mice, we reveal a neuronal code with tuning of latRM populations to distinct forelimb actions. These include reaching and food handling, both of which are impaired by perturbation of excitatory latRM neurons. Through the combinatorial use of genetics and viral tracing, we demonstrate that excitatory latRM neurons segregate into distinct populations by axonal target, and act through the differential recruitment of intra-brainstem and spinal circuits. Investigating the behavioural potential of projection-stratified latRM populations, we find that the optogenetic stimulation of these populations can elicit diverse forelimb movements, with each behaviour stably expressed by individual mice. In summary, projection-stratified brainstem populations encode action phases and together serve as putative building blocks for regulating key features of complex forelimb movements, identifying substrates of the brainstem for skilled forelimb behaviours.

Postmitotic Hoxa5 Expression Specifies Pontine Neuron Positional Identity and Input Connectivity of Cortical Afferent Subsets.

The mammalian precerebellar pontine nucleus (PN) has a main role in relaying cortical information to the cerebellum. The molecular determinants establishing ordered connectivity patterns between cortical afferents and precerebellar neurons are largely unknown. We show that expression of Hox5 transcription factors is induced in specific subsets of postmitotic PN neurons at migration onset. Hox5 induction is achieved by response to retinoic acid signaling, resulting in Jmjd3-dependent derepression of Polycomb chromatin and 3D conformational changes. Hoxa5 drives neurons to settle posteriorly in the PN, where they are monosynaptically targeted by cortical neuron subsets mainly carrying limb somatosensation. Furthermore, Hoxa5 postmigratory ectopic expression in PN neurons is sufficient to attract cortical somatosensory inputs regardless of position and avoid visual afferents. Transcriptome analysis further suggests that Hoxa5 is involved in circuit formation. Thus, Hoxa5 coordinates postmitotic specification, migration, settling position, and sub-circuit assembly of PN neuron subsets in the cortico-cerebellar pathway.

Brainstem Circuits Controlling Action Diversification.

Neuronal circuits that regulate movement are distributed throughout the nervous system. The brainstem is an important interface between upper motor centers involved in action planning and circuits in the spinal cord ultimately leading to execution of body movements. Here we focus on recent work using genetic and viral entry points to reveal the identity of functionally dedicated and frequently spatially intermingled brainstem populations essential for action diversification, a general principle conserved throughout evolution. Brainstem circuits with distinct organization and function control skilled forelimb behavior, orofacial movements, and locomotion. They convey regulatory parameters to motor output structures and collaborate in the construction of complex natural motor behaviors. Functionally tuned brainstem neurons for different actions serve as important integrators of synaptic inputs from upstream centers, including the basal ganglia and cortex, to regulate and modulate behavioral function in different contexts.

Thomas M. Jessell (1951-2019).

Thomas M. Jessell died on April 28, 2019. Tom revolutionized our understanding of the mechanisms through which neuronal cell type identities are programmed during development to dictate their function in the adult nervous system. Here, we (two former postdocs from his lab) remember some of his most important scientific contributions and how these changed the way we now understand and think about neuronal circuits controlling movement.

Functional Local Proprioceptive Feedback Circuits Initiate and Maintain Locomotor Recovery after Spinal Cord Injury.

Somatosensory feedback from proprioceptive afferents (PAs) is essential for locomotor recovery after spinal cord injury. To determine where or when proprioception is required for locomotor recovery after injury, we established an intersectional genetic model for PA ablation with spatial and temporal confinement. We found that complete or spatially restricted PA ablation in intact mice differentially affects locomotor performance. Following incomplete spinal cord injury, PA ablation below but not above the lesion severely restricts locomotor recovery and descending circuit reorganization. Furthermore, ablation of PAs after behavioral recovery permanently reverts functional improvements, demonstrating their essential role for maintaining regained locomotor function despite the presence of reorganized descending circuits. In parallel to recovery, PAs undergo reorganization of activity-dependent synaptic connectivity to specific local spinal targets. Our study reveals that PAs interacting with local spinal circuits serve as a continued driving force to initiate and maintain locomotor output after injury.

Connecting Circuits for Supraspinal Control of Locomotion.

Locomotion is regulated by distributed circuits and achieved by the concerted activation of body musculature. While the basic properties of executive circuits in the spinal cord are fairly well understood, the precise mechanisms by which the brain impacts locomotion are much less clear. This Review discusses recent work unraveling the cellular identity, connectivity, and function of supraspinal circuits. We focus on their involvement in the regulation of the different phases of locomotion and their interaction with spinal circuits. Dedicated neuronal populations in the brainstem carry locomotor instructions, including initiation, speed, and termination. To align locomotion with behavioral needs, brainstem output structures are recruited by midbrain and forebrain circuits that compute and infer volitional, innate, and context-dependent locomotor properties. We conclude that the emerging logic of supraspinal circuit organization helps to understand how locomotor programs from exploration to hunting and escape are regulated by the brain.

Mouse Motor Cortex Coordinates the Behavioral Response to Unpredicted Sensory Feedback.

Motor cortex (M1) lesions result in motor impairments, yet how M1 contributes to the control of movement remains controversial. To investigate the role of M1 in sensory guided motor coordination, we trained mice to navigate a virtual corridor using a spherical treadmill. This task required directional adjustments through spontaneous turning, while unexpected visual offset perturbations prompted induced turning. We found that M1 is essential for execution and learning of this visually guided task. Turn-selective layer 2/3 and layer 5 pyramidal tract (PT) neuron activation was shaped differentially with learning but scaled linearly with turn acceleration during spontaneous turns. During induced turns, however, layer 2/3 neurons were activated independent of behavioral response, while PT neurons still encoded behavioral response magnitude. Our results are consistent with a role of M1 in the detection of sensory perturbations that result in deviations from intended motor state and the initiation of an appropriate corrective response.

Author Correction: Transneuronal propagation of mutant huntingtin contributes to non-cell autonomous pathology in neurons.

In the version of this article initially published, the catalog numbers for BoNT A and B were given in the Methods section as T0195 and T5644; the correct numbers are B8776 and B6403. The error has been corrected in the HTML and PDF versions of the article.

Locomotor speed control circuits in the caudal brainstem.

Locomotion is a universal behaviour that provides animals with the ability to move between places. Classical experiments have used electrical microstimulation to identify brain regions that promote locomotion, but the identity of neurons that act as key intermediaries between higher motor planning centres and executive circuits in the spinal cord has remained controversial. Here we show that the mouse caudal brainstem encompasses functionally heterogeneous neuronal subpopulations that have differential effects on locomotion. These subpopulations are distinguishable by location, neurotransmitter identity and connectivity. Notably, glutamatergic neurons within the lateral paragigantocellular nucleus (LPGi), a small subregion in the caudal brainstem, are essential to support high-speed locomotion, and can positively tune locomotor speed through inputs from glutamatergic neurons of the upstream midbrain locomotor region. By contrast, glycinergic inhibitory neurons can induce different forms of behavioural arrest mapping onto distinct caudal brainstem regions. Anatomically, descending pathways of glutamatergic and glycinergic LPGi subpopulations communicate with distinct effector circuits in the spinal cord. Our results reveal that behaviourally opposing locomotor functions in the caudal brainstem were historically masked by the unexposed diversity of intermingled neuronal subpopulations. We demonstrate how specific brainstem neuron populations represent essential substrates to implement key parameters in the execution of motor programs.

Columnar-Intrinsic Cues Shape Premotor Input Specificity in Locomotor Circuits.

Control of movement relies on the ability of circuits within the spinal cord to establish connections with specific subtypes of motor neuron (MN). Although the pattern of output from locomotor networks can be influenced by MN position and identity, whether MNs exert an instructive role in shaping synaptic specificity within the spinal cord is unclear. We show that Hox transcription-factor-dependent programs in MNs are essential in establishing the central pattern of connectivity within the ventral spinal cord. Transformation of axially projecting MNs to a limb-level lateral motor column (LMC) fate, through mutation of the Hoxc9 gene, causes the central afferents of limb proprioceptive sensory neurons to target MNs connected to functionally inappropriate muscles. MN columnar identity also determines the pattern and distribution of inputs from multiple classes of premotor interneurons, indicating that MNs broadly influence circuit connectivity. These findings indicate that MN-intrinsic programs contribute to the initial architecture of locomotor circuits.

A V0 core neuronal circuit for inspiration.

Breathing in mammals relies on permanent rhythmic and bilaterally synchronized contractions of inspiratory pump muscles. These motor drives emerge from interactions between critical sets of brainstem neurons whose origins and synaptic ordered organization remain obscure. Here, we show, using a virus-based transsynaptic tracing strategy from the diaphragm muscle in the mouse, that the principal inspiratory premotor neurons share V0 identity with, and are connected by, neurons of the preBötzinger complex that paces inspiration. Deleting the commissural projections of V0s results in left-right desynchronized inspiratory motor commands in reduced brain preparations and breathing at birth. This work reveals the existence of a core inspiratory circuit in which V0 to V0 synapses enabling function of the rhythm generator also direct its output to secure bilaterally coordinated contractions of inspiratory effector muscles required for efficient breathing.The developmental origin and functional organization of the brainstem breathing circuits are poorly understood. Here using virus-based circuit-mapping approaches in mice, the authors reveal the lineage, neurotransmitter phenotype, and connectivity patterns of phrenic premotor neurons, which are a crucial component of the inspiratory circuit.