Cerebellar fastigial nucleus electrostimulation attenuates inflammation in a Post-Infarction rat model by activating cholinergic anti-inflammatory pathway.

There are negative correlations between indices of heart rate variability (HRV) and markers of inflammation. The inflammation plays an important role in myocardial damages after myocardial infarction (MI). Our previous study found that fastigial nucleus electrostimulation (FNS) improved abnormal HRV in a rat model of MI. Whether it can reduce inflammation and improve cardiac function after MI and the underlying mechanisms remain unknown. 66 Sprague Dawley rats were randomly divided into 4 groups as follows: i) Sham group (sham operation); ii) MI group (left anterior descending coronary artery ligation); iii) FNS + MI group (left fastigial nucleus electrostimulation plus MI); iv) FNL + FNS + MI group (left fastigial nucleus lesion plus FNS plus MI). The serum expressions of acetylcholine (ACh), pro-inflammatory cytokines tumor necrosis factor-α (TNF-α) and interleukin-6 (IL-6), and anti-inflammatory cytokines IL-10 were measured by ELISA. Subsequently, the infarct size, the infiltration of inflammatory cells, the fibrotic area, and cardiac function were also evaluated. Additionally, the expressions of the cholinergic anti-inflammatory pathway (CAP)-related proteins in infarct tissue, such as nuclear factor kappa B (NF-κB) and singal transducers and activators of transcription 3 (STAT3), were determined by Western blot. We found that FNS significantly increased ACh and IL-10 levels in serum, and decreased TNF-α and IL-6 levels. FNS significantly attenuated inflammatory cell infiltration, reduced infarct size, decreased fibrosis, increased left ventricular ejection fraction, and reduced mortality. Besides, the ratios of phosphorylated-STAT3/STAT3 and phosphorylated-NF-κB/NF-κB in infarct tissue significantly elevated after MI. FNS reduced the ratios of p-STAT3/STAT3 and p-NF-κB/NF-κB in infarct tissue. The protective effects of FNS were partially reversed by the fastigial nucleus lesion. Our data suggested that FNS can alleviate the inflammation after MI, and its cardiac neuroprotective mechanism may be achieved by increasing vagal tone, releasing ACh, and further activating the CAP via α7 nicotinic acetylcholine receptor. The precise mechanism remains to be elucidated.

Ventromedial Thalamus-Projecting DCN Neurons Modulate Associative Sensorimotor Responses in Mice.

The deep cerebellar nuclei (DCN) integrate various inputs to the cerebellum and form the final cerebellar outputs critical for associative sensorimotor learning. However, the functional relevance of distinct neuronal subpopulations within the DCN remains poorly understood. Here, we examined a subpopulation of mouse DCN neurons whose axons specifically project to the ventromedial (Vm) thalamus (DCNVm neurons), and found that these neurons represent a specific subset of DCN units whose activity varies with trace eyeblink conditioning (tEBC), a classical associative sensorimotor learning task. Upon conditioning, the activity of DCNVm neurons signaled the performance of conditioned eyeblink responses (CRs). Optogenetic activation and inhibition of the DCNVm neurons in well-trained mice amplified and diminished the CRs, respectively. Chemogenetic manipulation of the DCNVm neurons had no effects on non-associative motor coordination. Furthermore, optogenetic activation of the DCNVm neurons caused rapid elevated firing activity in the cingulate cortex, a brain area critical for bridging the time gap between sensory stimuli and motor execution during tEBC. Together, our data highlights DCNVm neurons' function and delineates their kinematic parameters that modulate the strength of associative sensorimotor responses.

Ventromedial Thalamus-Projecting DCN Neurons Modulate Associative Sensorimotor Responses in Mice / 神经科学通报·英文版

The deep cerebellar nuclei (DCN) integrate various inputs to the cerebellum and form the final cerebellar outputs critical for associative sensorimotor learning. However, the functional relevance of distinct neuronal subpopulations within the DCN remains poorly understood. Here, we examined a subpopulation of mouse DCN neurons whose axons specifically project to the ventromedial (Vm) thalamus (DCNVm neurons), and found that these neurons represent a specific subset of DCN units whose activity varies with trace eyeblink conditioning (tEBC), a classical associative sensorimotor learning task. Upon conditioning, the activity of DCNVm neurons signaled the performance of conditioned eyeblink responses (CRs). Optogenetic activation and inhibition of the DCNVm neurons in well-trained mice amplified and diminished the CRs, respectively. Chemogenetic manipulation of the DCNVm neurons had no effects on non-associative motor coordination. Furthermore, optogenetic activation of the DCNVm neurons caused rapid elevated firing activity in the cingulate cortex, a brain area critical for bridging the time gap between sensory stimuli and motor execution during tEBC. Together, our data highlights DCNVm neurons' function and delineates their kinematic parameters that modulate the strength of associative sensorimotor responses.

Electrical stimulation of the lateral cerebellar nucleus promotes neurogenesis in rats after motor cortical ischemia.

Deep brain stimulation (DBS) has been tentatively explored to promote motor recovery after stroke. Stroke could transiently activate endogenous self-repair processes, including neurogenesis in the subventricular zone (SVZ). In this regard, it is of considerable clinical interest to study whether DBS of the lateral cerebellar nucleus (LCN) could promote neurogenesis in the SVZ for functional recovery after stroke. In the present study, rats were trained on the pasta matrix reaching task and the ladder rung walking task before surgery. And then an electrode was implanted in the LCN following cortical ischemia induced by endothelin-1 injection. After 1 week of recovery, LCN DBS coupled with motor training for two weeks promoted motor function recovery, and reduced the infarct volumes post-ischemia. LCN DBS augmented poststroke neurogenetic responses, characterized by proliferation of neural progenitor cells (NPCs) and neuroblasts in the SVZ and subsequent differentiation into neurons in the ischemic penumbra at 21 days poststroke. DBS with the same stimulus parameters at 1 month after ischemia could also increase nascent neuroblasts in the SVZ and newly matured neurons in the perilesional cortex at 42 days poststroke. These results suggest that LCN DBS promotes endogenous neurogenesis for neurorestoration after cortical ischemia.

Subthalamic Nucleus Deep Brain Stimulation Modulates 2 Distinct Neurocircuits.

OBJECTIVE: Current understanding of the neuromodulatory effects of deep brain stimulation (DBS) on large-scale brain networks remains elusive, largely due to the lack of techniques that can reveal DBS-induced activity at the whole-brain level. Using a novel 3T magnetic resonance imaging (MRI)-compatible stimulator, we investigated whole-brain effects of subthalamic nucleus (STN) stimulation in patients with Parkinson disease. METHODS: Fourteen patients received STN-DBS treatment and participated in a block-design functional MRI (fMRI) experiment, wherein stimulations were delivered during "ON" blocks interleaved with "OFF" blocks. fMRI responses to low-frequency (60Hz) and high-frequency(130Hz) STN-DBS were measured 1, 3, 6, and 12 months postsurgery. To ensure reliability, multiple runs (48 minutes) of fMRI data were acquired at each postsurgical visit. Presurgical resting-state fMRI (30 minutes) data were also acquired. RESULTS: Two neurocircuits showed highly replicable, but distinct responses to STN-DBS. A circuit involving the globus pallidus internus (GPi), thalamus, and deep cerebellar nuclei was significantly activated, whereas another circuit involving the primary motor cortex (M1), putamen, and cerebellum showed DBS-induced deactivation. These 2 circuits were dissociable in terms of their DBS-induced responses and resting-state functional connectivity. The GPi circuit was frequency-dependent, selectively responding to high-frequency stimulation, whereas the M1 circuit was responsive in a time-dependent manner, showing enhanced deactivation over time. Finally, activation of the GPi circuit was associated with overall motor improvement, whereas M1 circuit deactivation was related to reduced bradykinesia. INTERPRETATION: Concurrent DBS-fMRI using 3T revealed 2 distinct circuits that responded differentially to STN-DBS and were related to divergent symptoms, a finding that may provide novel insights into the neural mechanisms underlying DBS. ANN NEUROL 2020;88:1178-1193.

Cerebellar Contribution to Preparatory Activity in Motor Neocortex.

In motor neocortex, preparatory activity predictive of specific movements is maintained by a positive feedback loop with the thalamus. Motor thalamus receives excitatory input from the cerebellum, which learns to generate predictive signals for motor control. The contribution of this pathway to neocortical preparatory signals remains poorly understood. Here, we show that, in a virtual reality conditioning task, cerebellar output neurons in the dentate nucleus exhibit preparatory activity similar to that in anterolateral motor cortex prior to reward acquisition. Silencing activity in dentate nucleus by photoactivating inhibitory Purkinje cells in the cerebellar cortex caused robust, short-latency suppression of preparatory activity in anterolateral motor cortex. Our results suggest that preparatory activity is controlled by a learned decrease of Purkinje cell firing in advance of reward under supervision of climbing fiber inputs signaling reward delivery. Thus, cerebellar computations exert a powerful influence on preparatory activity in motor neocortex.

Fastigial nucleus electrostimulation promotes axonal regeneration after experimental stroke via cAMP/PKA pathway.

Axon regeneration after cerebral ischemia in mammals is inadequate to restore function, illustrating the need to design better strategies for improving outcomes. Improvement of axon regeneration has been achieved through fastigial nucleus electrostimulation (FNS) in animal researches. However, the mechanisms underlying this neuroprotection remain poorly understood. Increasing the levels of the second messenger cyclic AMP (cAMP) enhances axon regeneration, making it an excellent candidate molecule that has therapeutic potential. In the present study, we examined the expression of cAMP signaling in ischemic brain tissues following focal cerebral ischemia. Adult rats were subjected to ischemia induced by middle cerebral artery occlusion (MCAO). A dipolar electrode was placed into the cerebellum to stimulate the cerebellar fastigial nucleus for 1 h after ischemia. Neurological deficits and the expressions of cAMP, PKA (protein kinase A) and ROCK (Rho-kinase) were determined. Axonal regeneration was measured by upregulation of growth-associated protein 43 (GAP43). The data indicated that FNS significantly enhanced axonal regeneration and motor function recovery after cerebral ischemia. FNS also significantly increased cAMP and PKA levels after ischemic brain injury. All the beneficial effects of FNS were blocked by Rp-cAMP, an antagonist of PKA. Our research suggested that the axonal regeneration conferred by FNS was likely achieved via the regulation of cAMP/PKA pathway.

Structural and functional connectivity of the nondecussating dentato-rubro-thalamic tract.

The dentato-rubro-thalamic tract (DRTT) regulates motor control, connecting the cerebellum to the thalamus. This tract is modulated by deep-brain stimulation in the surgical treatment of medically refractory tremor, especially in essential tremor, where high-frequency stimulation of the thalamus can improve symptoms. The DRTT is classically described as a decussating pathway, ascending to the contralateral thalamus. However, the existence of a nondecussating (i.e. ipsilateral) DRTT in humans was recently demonstrated, and these tracts are arranged in distinct regions of the superior cerebellar peduncle. We hypothesized that the ipsilateral DRTT is connected to specific thalamic nuclei and therefore may have unique functional relevance. The goals of this study were to confirm the presence of the decussating and nondecussating DRTT pathways, identify thalamic termination zones of each tract, and compare whether structural connectivity findings agree with functional connectivity. Diffusion-weighted imaging was used to perform probabilistic tractography of the decussating and nondecussating DRTT in young healthy subjects from the Human Connectome Project (n = 91) scanned using multi-shell diffusion-weighted imaging (270 directions; TR/TE = 5500/89 ms; spatial resolution = 1.25 mm isotropic). To define thalamic anatomical landmarks, a segmentation procedure based on the Morel Atlas was employed, and DRTT targeting was quantified based on the proportion of streamlines arriving at each nucleus. In parallel, functional connectivity analysis was performed using resting-state functional MRI (TR/TE = 720/33 ms; spatial resolution = 2 mm isotropic). It was found that the decussating and nondecussating DRTTs have significantly different thalamic endpoints, with the former preferentially targeting relatively anterior and lateral thalamic nuclei, and the latter connected to more posterior and medial nuclei (p < 0.001). Functional and structural connectivity measures were found to be significantly correlated (r = 0.45, p = 0.031). These findings provide new insight into pathways through which unilateral cerebellum can exert bilateral influence on movement and raise questions about the functional implications of ipsilateral cerebellar efferents.

Convergence of primary sensory cortex and cerebellar nuclei pathways in the whisker system.

To safely maneuver through the environment the brain needs to compare active sensory information with ongoing motor programs. This process occurs at various levels in the brain: at the lower level, i.e., in the spinal cord, reflexes are generated for the most primitive motor responses; at the intermediate level, i.e., in the brainstem, various nuclei co-process sensory- and motor-related inputs; and, at the higher level cerebellum and thalamo-cortical networks individually compute suitable commands for fine-tuned motor output. For sensorimotor processes the integrative capacities of the cerebral cortex and the cerebellum have been the topic of detailed analysis. Here, we use higher order sensorimotor integration in the whisker system as a model to evaluate the convergence pattern of primary sensory cortex projections and the cerebellar output nuclei throughout several brain nuclei. This prospective review focuses not only on the thalamus, but also incorporates extra-thalamic structures that could function as comparators of cerebellar output and sensory cortex output. Based on the literature on anatomical and physiological studies in the rodent brain and our qualitative data on the convergence of cerebellar sensory cortical projections we identify the superior colliculus as well as the zona incerta and the anterior pretectal nucleus as suitable candidates for cerebello-cortical convergence. Including these putative comparators we discuss the potential routes for sensorimotor information flow between the cerebellum and cerebral sensory cortex with a focus on the modulation of thalamic activity by extra-thalamic structures.

[Progress on the Relationship Between the Regulation of Gastrointestinal System Function by Acupuncture and Central Nuclei].

Acupuncture has a good curative effect in the treatment of gastrointestinal system diseases, such as functional dyspepsia, ulcerative colitis, and constipation. The central nuclei which are involved in the mechanism of acupuncture in regulating the gastrointestinal system have become a research hotspot in recent years. In the present paper, the authors summarized the effect of acupuncture and the central nervous system on gastrointestinal function regulation. It was found that the regulation of gastrointestinal function by acupuncture involved many brain regions such as the amygdala, paraventricular nucleus, locus coeruleus, raphe nucleus, and dorsal nucleus of the vagus nerve. Of these, the limbic brain region had the closest relation. However, the included studies were animal experiments, which involved less research on nuclear group interactions. The role of central nuclei in the regulation of gastrointestinal function by acupuncture is unclear. Thus, the introduction of more advanced brain imaging techniques to observe brain dysfunction of central nuclei and the relativity of acupuncture in regulating gastrointestinal function will be the focus in the future study, which will contribute to determining the effective mechanism of acupuncture and moxibustion.

Effects of fastigial nucleus electrostimulation on airway inflammation and remodeling in an experimental rat model of asthma.

BACKGROUND: Asthma is a chronic disease involving an immune response, which is characterized by non-specific inflammation and airway remodeling. Glucocorticoids are clinically beneficial in controlling asthma, but further options are needed. In our study, fastigial nucleus electrostimulation (FNS) was applied in a rat asthma model for the first time to investigate the effects of pre-intervention. OBJECTIVE: To observe the effects of FNS on airway inflammation and remodeling in asthmatic rats. METHODS: Forty rats were assigned randomly to the normal control (CON), model (MDL), FNS, or budesonide (BUD) groups. Asthma was induced with chicken egg (OVA). The animals in the CON and MDL groups were treated with normal saline. The animals in the other two groups received FNS or budesonide, respectively. RESULTS: The results indicated that IgE in the serum and airway fiber areas were higher in the MDL group than in other groups. After treatment for 3 weeks, collagen fibers in the bronchial wall in the FNS group were significantly lower compared with the MDL group. CONCLUSION: FNS significantly reduced IL-4, IL-13, TNF-α, OVA-IgE and TGF-ß1 in serum and BALF, and increased IFN-γ. Our results suggest that FNS may ameliorate asthma symptoms and induce changes of cytokines in the serum and lung milieu.

[Effects of acupuncture at "Zusanli" (ST 36) on sensitive neurons of gastric distention in LHA-FN circuit in rats].

OBJECTIVE: To observe the regulation effects of acupuncture at "Zusanli" (ST 36) on sensitive neurons of gastric distention (GD) in lateral hypothalamus area (LHA) and fastigial nuclear (FN) circuit, and to explore the central mechanism of acupuncture for gastric function. METHODS: A total of 101 rats were randomly assigned into a LHA group (50 rats) and a FN group (51 rats). Gastric distension surgery was performed in all the rats. According to the stereotaxic atlas of rat brain, the LHA and FN were located, followed by craniotomy. The endocranium was removed to exposure brain tissue, and warm paraffin oil was used to prevent desiccation. The electrical activities of neurons were probed by glass microelectrode to perform extracellular recording. The electrical activities of GD sensitive neurons in LHA were observed in LHA group, while those in FN were observed in FN group. One min after the electrical signal of neurons was recorded, acupuncture was given at left "Zusanli" (ST 36) with mild reinforcing and attenuating technique, 120~180 times/min for 1 min. The effects of acupuncture at "Zusanli" (ST 36) on spontaneous discharge of GD sensitive neurons in LHA and FN were observed. RESULTS: (1) Totally 54 LHA neurons of spontaneous discharge in LHA group and 85 FN neurons in FN group were recorded. GD-excitatory (GD-E) neurons were mainly in the LHA group (46.3%) and GD-non-response (GD-N) neurons were mainly in the FN group (54.12%). The average discharge frequency of GD-N neurons was (39.03±14.91) spikes/s, that of GD-E neurons was (19.67±12.08) spikes/s, and that of GD-inhibitory (GD-I) neurons was (28.76±7.26) spikes/s, which were statistically different from those before GD (all P<0.01). (2) In LHA group, acupuncture excited the activity of GD-E neurons, and inhibited the activity of GD-I neurons (P<0.05); in FN group, acupuncture excited the activity of GD-I neurons, but showed no effect on GD-E neurons (P<0.01). CONCLUSIONS: The signal of GD and acupuncture could converge in LHA and FN; acupuncture presented different regulation effects on identical type of GD-sensitive neurons in different nuclear groups; LHA-FN circuit might participate in central integration mechanism of acupuncture on gastric function.

[Effect of acupuncture at different acupoints on electric activities of rat cerebellar fastigial nuclear].

OJECTIVE: To explore whether different acupuncture signals were afferent to the cerebellar fastigial nucleus (FN) neuron and to find out their corresponding effect features through observing the effect of spontaneous discharge of cerebellar FN neuron by needling at different acupoints. METHODS: Totally 120 male SD rats were anesthetized by 20% urethane and their right cerebellar FN were positioned (AP 11. 6 mm, RL 1. 0 mm, H 5. 6 mm). Extracelluar discharge was recorded by glass microelectrode (AP: -11. 6 mm, R: 1. 0 mm, H: 5.7 -7. 0 mm), using extracellular microelectrode recording method, recording the spontaneous discharge of cerebellar FN neurons as a baseline. Random order of needling at zusanli (ST36), quchi (Lil1), weishu (BL21), and zhongwan (CV12) were compared with the baseline before each acupuncture. Their effects on the discharge of cerebellar FN neurons were observed and compared with baselines. RESULTS: The frequency of FN neuronal discharge could be elevated by needling at zusanli (ST36), quchi (LiI), weishu (BL21), and zhongwan (CV12) (P <0. 01, P <0. 05). The response rate of needling at Zhongwan (CV12, 56. 00%) was higher than that of needling at Zusanli (ST36), Quchi (Ll1), and Weishu (BL21) (35. 00%, 34. 62%, 36. 63%, respectively) with statistical difference (P <0. 05). The response rate of needling at zhongwan (CV12) was obviously higher than that of needing at other points (F = 2. 101, P < 0. 05). CONCLUSIONS: Needling at zusanli (ST36 ), quchi (Lil), weishu (BL21), and zhongwan (CV12) could elevate the spontaneous discharge frequency of cerebellar FN neurons. Needling at Zhongwan (CV12) had advantageous roles in regulating cerebellar FN.

Fastigial nucleus stimulation regulates neuroprotection via induction of a novel microRNA, rno-miR-676-1, in middle cerebral artery occlusion rats.

Previous studies have shown that fastigial nucleus stimulation (FNS) reduces tissue damage resulting from focal cerebral ischemia. Although the mechanisms of neuroprotection induced by FNS are not entirely understood, important data have been presented in the past two decades. MicroRNAs (miRNAs) are a newly discovered group of non-coding small RNA molecules that negatively regulate target gene expression and are involved in the regulation of cell proliferation and cell apoptosis. To date, no studies have demonstrated whether miRNAs can serve as mediators of the brain's response to FNS, which leads to endogenous neuroprotection. Therefore, this study investigated the profiles of FNS-mediated miRNAs. Using a combination of deep sequencing and microarray with computational analysis, we identified a novel miRNA in the rat ischemic cortex after 1 h of FNS. This novel miRNA (PC-3p-3469_406), herein referred to as rno-miR-676-1, was upregulated in rats with cerebral ischemia after FNS. In vivo observations indicate that this novel miRNA may have antiapoptotic effects and contribute to neuroprotection induced by FNS. Our study provides a better understanding of neuroprotection induced by FNS. MicroRNA (miRNA) is defined as a small non-coding RNA that fulfills both the expression and biogenesis criteria. Here, we describe a novel miRNA in the rat ischemic cortex expressed after 1 h of fastigial nucleus stimulation (FNS). The miRNA was functionally characterized by secondary structure, quantitative expression, the conservation analysis, target gene analysis, and biological functions. We consider rno-miR-676-1 to be a true microRNA and present evidence for its neuroprotective effects exerted after induction by FNS.

Deep brain stimulation for essential tremor: targeting the dentato-rubro-thalamic tract?

OBJECTIVE: The aim of our study was to evaluate the influence of the stimulation site relative to the dentato-rubro-thalamic tract (DRTT) on the alleviation of tremor in deep brain stimulation. METHODS: Ten DRTTs in five patients were investigated using preoperative diffusion tensor imaging (DTI). Regions of interest for fiber tracking were located in the cerebellar dentate nucleus, the superior cerebellar peduncle and the contralateral red nucleus. The position and distance of all intraoperative stimulation sites to the DRTT were measured and correlated to the amount of tremor reduction. RESULTS: Nine of 10 DRTTs could be identified using DTI-based fiber tracking. Better tremor reduction was achieved in locations in or posterior and lateral to the DRTT than in medial and anterior positions (p = 0.001). Stimulation sites inferior to and in the DRTT achieved better results than locations superior to the DRTT (p < 0.05). The vicinity of the stimulation site to the DRTT did not correlate with tremor alleviation. DISCUSSION: In deep brain stimulation targeting for thalamic stimulation sites is limited to statistical, atlas-based coordinates. Diffusion tensor imaging and fiber tracking was used to visualize the dentato-rubro-thalamic tract as a potential, individualized target structure. However, we could not demonstrate that contacts closer to the DRTT provided better clinical effects than distant contacts, in any given direction. DTI sequences with a higher number of read-out directions, probabilistic fiber tracking and three Tesla MRI scanners may lead to different results in the depiction of the chosen fiber tract and may provide a better correlation with stimulation effects. CONCLUSIONS: The results do not provide sufficient evidence to define the DRTT as a new DBS-target for tremor. Further investigations on different fiber tracts, DTI sequences, and fiber tracking algorithms are mandatory.

Baseline theta activities in medial prefrontal cortex and deep cerebellar nuclei are associated with the extinction of trace conditioned eyeblink responses in guinea pigs.

It has been shown that both the medial prefrontal cortex (mPFC) and the cerebellum are involved in the extinction of trace conditioned eyeblink responses (CR). However, the neural mechanisms underlying the extinction are still relatively unclear. Theta oscillation in either the mPFC or the cerebellum has been revealed to correlate with the performance of trace CRs during the asymptotic acquisition. Therefore, we sought to further evaluate the impacts of pre-conditioned stimulus (CS) spontaneous theta (5.0-10.0Hz) oscillations in the mPFC and the deep cerebellar nuclei (DCN) on the extinction of trace CRs. Albino guinea pigs were given acquisition training for ten daily sessions followed by seven daily sessions of extinction. Local field potential (LFP) signals in the mPFC and the DCN were recorded when the animals received the CS-alone extinction training. It was found that higher mPFC relative theta ratios [theta/(delta+beta)] during the baseline period (850-ms prior to the CS onset) were predictive of fewer CR incidences rather than more adaptive CR performance (i.e., higher CR magnitude and later CR peak/onset latencies). Likewise, the pre-CS DCN theta activity was associated with the faster CR extinction. Furthermore, it was revealed that the power of pre-CS theta activities in the mPFC and the DCN were correlated until the extinction training day 2. Collectively, these results suggest that the mPFC and the DCN may interact with each other, and the brain oscillation state in which baseline theta activities in both areas are present contributes to the subsequent extinction of trace CRs.

A defined heteromeric KV1 channel stabilizes the intrinsic pacemaking and regulates the output of deep cerebellar nuclear neurons to thalamic targets.

The output of the cerebellum to the motor axis of the central nervous system is orchestrated mainly by synaptic inputs and intrinsic pacemaker activity of deep cerebellar nuclear (DCN) projection neurons. Herein, we demonstrate that the soma of these cells is enriched with K(V)1 channels produced by mandatory multi-merization of K(V)1.1, 1.2 α and KV ß2 subunits. Being constitutively active, the K(+) current (IK(V)1) mediated by these channels stabilizes the rate and regulates the temporal precision of self-sustained firing of these neurons. Placed strategically, IK(V)1 provides a powerful counter-balance to prolonged depolarizing inputs, attenuates the rebound excitation, and dampens the membrane potential bi-stability. Somatic location with low activation threshold render IK(V)1 instrumental in voltage-dependent de-coupling of the axon initial segment from the cell body of projection neurons, impeding invasion of back-propagating action potentials into the somato-dendritic compartment. The latter is also demonstrated to secure the dominance of clock-like somatic pacemaking in driving the regenerative firing activity of these neurons, to encode time variant inputs with high fidelity. Through the use of multi-compartmental modelling and retro-axonal labelling, the physiological significance of the described functions for processing and communication of information from the lateral DCN to thalamic relay nuclei is established.

Fastigial nucleus electrostimulation reduces the expression of repulsive guidance molecule, improves axonal growth following focal cerebral ischemia.

The role of repulsive guidance molecule A (RGMa) in cerebral ischemia remains unclear. In the study, we examined the expression of RGMa in ischemic brain tissues following focal cerebral ischemia/reperfusion (IR) in rats. An established middle cerebral artery suture occlusion model was employed. A dipolar electrode was placed into the cerebellum to stimulate the cerebellar fastigial nucleus for 1 h at 2 h after ischemia. Reverse transcription-polymerase chain reaction was used to measure the mRNA RGMa and its downstream mediator, Ras homolog A (RhoA). Immunohistochemistry was applied to detect RGMa and RhoA expressions and to evaluate axonal regeneration by optical density analysis of 200 kDa neurofilaments. We found that both mRNA and protein levels of RGMa and RhoA were increased in the ischemic cortex and hippocampus 48 h following cerebral IR and these elevated levels were maintained for 2 weeks. Electrostimulation of the fastigial nucleus reduced the expression of RGMa and RhoA at 24 h and 2 weeks following cerebral IR. In addition, axonal growth was enhanced in the fastigial nucleus electrostimulated group compared to non-stimulated ischemic animals (P < 0.05). RGMa/RhoA expression was negatively correlated with the growth of axons (P < 0.05). Therefore, we concluded that RGMa and RhoA could be another key molecule and might inhibit axonal regeneration during cerebral IR injury. Electrostimulation of the fastigial nucleus enhances axonal growth, possibly by reducing the expression of RGMa and RhoA after cerebral IR.

Cerebellar nuclei are activated by high-frequency stimulation of the subthalamic nucleus.

The cerebellum, primarily considered a pure motor structure, is increasingly considered to play a role in behaviour and cognition. In a similar manner, there is increasing evidence that the basal ganglia are involved in non-motor processes. Recently a direct connection between the cerebellum and the basal ganglia has been shown to exist. High-frequency stimulation (HFS) of the subthalamic nucleus (STN) has become an accepted treatment in advanced Parkinson's disease (PD). We performed HFS of the STN in rats to evaluate the neuronal activation in the deep cerebellar nuclei (DCbN) using c-Fos immunohistochemistry. We found an increased c-Fos expression in the DCbN. Previously, we have shown that STN HFS in rats leads to decreased impulsive behaviour and our findings now suggest a link with increased DCbN activity. This is in line with our previous work showing that decreased DCbN activity is accompanied by disruptive behaviour. We suggest that the DCbN play a role in the selection of relevant information on which a behavioural response is based. The connection between the cerebellum and the basal ganglia may imply a role for the cerebellum in behavioural aspects of disorders of the basal ganglia.

Associative plasticity in the medial auditory thalamus and cerebellar interpositus nucleus during eyeblink conditioning.

Eyeblink conditioning, a type of associative motor learning, requires the cerebellum. The medial auditory thalamus is a necessary source of stimulus input to the cerebellum during auditory eyeblink conditioning. Nothing is currently known about interactions between the thalamus and cerebellum during associative learning. In the current study, neuronal activity was recorded in the cerebellar interpositus nucleus and medial auditory thalamus simultaneously from multiple tetrodes during auditory eyeblink conditioning to examine the relative timing of learning-related plasticity within these interconnected areas. Learning-related changes in neuronal activity correlated with the eyeblink conditioned response were evident in the cerebellum before the medial auditory thalamus over the course of training and within conditioning trials, suggesting that thalamic plasticity may be driven by cerebellar feedback. Short-latency plasticity developed in the thalamus during the first conditioning session and may reflect attention to the conditioned stimulus. Extinction training resulted in a decrease in learning-related activity in both structures and an increase in inhibition within the cerebellum. A feedback projection from the cerebellar nuclei to the medial auditory thalamus was identified, which may play a role in learning by facilitating stimulus input to the cerebellum via the thalamo-pontine projection.