Abstract
Purkinje cells (PCs) primarily project to cerebellar nuclei but also directly innervate the brainstem. Some PC-brainstem projections have been described previously, but most have not been thoroughly characterized. Here we use a PC-specific cre line to anatomically and electrophysiologically characterize PC projections to the brainstem. PC synapses are surprisingly widespread, with the highest densities found in the vestibular and parabrachial nuclei. However, there are pronounced regional differences in synaptic densities within both the vestibular and parabrachial nuclei. Large optogenetically-evoked PC-IPSCs are preferentially observed in subregions with the highest densities of PC synapses, suggesting that PCs selectively influence these areas and the behaviors they regulate. Unexpectedly, the pontine central gray and nearby subnuclei also contained a low density of PC synapses, and large PC-IPSCs are observed in a small fraction of cells. We combined electrophysiological recordings with immunohistochemistry to assess the molecular identities of these PC targets. PC synapses onto mesencephalic trigeminal neurons were not observed even though these cells are in close proximity to PC boutons. PC synapses onto locus coeruleus neurons are exceedingly rare or absent, even though previous studies concluded that PCs are a major input to these neurons. The availability of a highly selective cre line for PCs allowed us to study functional synapses, while avoiding complications that can accompany the use of viral approaches. We conclude that PCs directly innervate numerous brainstem nuclei, but only inhibit a small fraction of cells in many nuclei. This suggests that PCs target cell types with specific behavioral roles in brainstem regions.
Introduction
Delineating the PC output pathways that mediate signals from the cerebellar cortex to the rest of the brain is a vital step in understanding cerebellar function. Although most studies of PC outputs have focused on the prominent connections to cerebellar nuclei 1,2, PCs also project directly to the brainstem. Extensive PC projections to vestibular nuclei 3–6 play vital roles in vestibular and ocular-related functions 7–9. PCs also project to the prepositus hypoglossal nucleus, and this pathway may play a role in gaze stabilization 10–13. In addition, PCs prominently project to the parabrachial nucleus, which is suited to regulate broad-ranging nonmotor and autonomic functions 14–18.
Several studies suggested that PCs also inhibit cells in other brainstem nuclei that could allow the cerebellum to control diverse behaviors. Rabies-based tracing approaches suggested that PCs are the primary inhibitory inputs to the locus coeruleus (LC) 19–21, but this is controversial. These studies have been highly influential and raised the possibility that PCs directly modulate LC-norepinephrine release, and regulate stress, attention, motivation, arousal, pain modulation, reward processing and other behaviors 22–27. Furthermore, it was also suggested that disruption of the PC-LC pathway contributes to ASD and ADHD 28, and impairs the ability of the cerebellum to control seizures 29. However, other studies do not see strong evidence for this PC-LC connection. Retrograde tracing studies of projections to the LC using conventional tracers observed minimal PC labelling 30–32, and PC axons largely avoid the LC 17. Thus, there is no consensus on whether PCs strongly inhibit LC neurons. There is also suggestive evidence that the cerebellum influences additional brainstem nuclei: the injection of trans- synaptic viruses into the posterior vermis labelled cells in pontine central grey (PCG) and nearby nuclei including the LC, Barrington’s nucleus, dorsal tegmentum, and others 17. These findings raise the possibility that direct PC projections could allow the cerebellum to regulate arousal, sleep-state transitions, micturition, and other behaviors 33–37. However, the viruses used in these studies can also retrogradely label cells 38,39, and it is therefore necessary to assess whether there are functional PC synapses in these nuclei.
In this study, we determine whether PC make synapses and inhibit cells within various brainstem nuclei by determining whether PC synaptic boutons are present, and if PCs make functional synapses. Using PCP2-cre/Ai34D (PC/synaptophysin-tdTomato) mice to label PC synapses and map their locations, we find that PCs project widely in the brainstem, and that synaptic densities are highly nonuniform within different nuclei and subnuclei. We identify and characterize PC synapses in brainstem nuclei using optogenetics and PCP2-cre/Ai32 (PC/ChR2-YFP) mice. There was good agreement between the density of PC synaptic boutons and the probability of evoking PC-IPSCs in neurons within different regions and subregions. In regions with a low density of PC boutons, PC-IPSCs were typically observed in a small fraction of cells, raising the possibility that PCs selectively target specific types of neurons in these regions. These findings provide an important resource that will allow future studies to clarify the PC targets in various brainstem nuclei and the behaviors controlled by these output pathways.
Results
Visualization of PC projections to the brainstem
We visualized PC synapses in the brainstem of PC/synaptophysin-tdTomato mice in which synaptic boutons are intensely labelled, and axons, dendrites and somata weakly labelled. We imaged synaptophysin-tdTomato in both sagittal (Fig. 1A) and coronal sections (Fig. 1B), and aligned the images to the Allen Common Coordinate Framework (CCF) 40 based on the contours of the tissue. We collapsed the vestibular subnuclei (MV, LAV etc.) into the VN, and labelled the territories encompassing the dorsomedial pons as simply the PCG (see Methods). Likewise, the rostral/cauda or medial/lateral divisions of other nuclei are not annotated specifically (PGRN, NTS, etc.).
In low magnification images (Fig. 1A, 1B, left images), labeling is observed in the cerebellar nuclei and brainstem. In sagittal views, brainstem labeling is sparser in the medial sections than in lateral sections. In coronal sections, the brainstem labeling is densest at bregma -5.85 mm, and sparser in anterior and posterior sections. Medium (Fig. 1A, 1B, 2nd column from left) and high magnification images (Fig. 1A, 1B i-iv) showed highly variable densities of PC boutons in different regions. In some regions, labelling was extremely faint for medium magnification images, but PC synapses were apparent at higher magnifications (for example, in the PCG in Fig. 1Aa i and Fig. 1Ba ii).
There were pronounced regional differences in the extent of labelling within the VN and the PBN. In sagittal sections, for the VN the densest PC labelling was observed ventral to the cerebellar nuclei and the fourth ventricle (Fig. 1Ac ii), and expression fanned out ventrally, anteriorly, and posteriorly. Dense labeling of the VN was also present in the anterior dorsal regions of the other sagittal slices (Fig. 1Aa ii, Fig. 1Ab ii+iii, Fig. 1Ac ii, Fig. 1Ad ii). Although PC boutons were present throughout the VN, in anterior regions the densities were low near the midline (Fig. 1Aa iii, Fig. 1Ab iv) and moderate densities in more lateral sections (Fig. 1Ac iv, Fig. 1Ad iv). The density gradient of PC synapses within the VN was more apparent in coronal sections. Synaptic densities were highest in dorsal VN (Fig. 1Bb i+ii, Fig. 1Bc i, Fig. 1Bd i, Fig. 1Be ii), and lower in ventral VN (Fig. 1Ba iii, Fig. 1Bb iii, Fig. 1Bc iii, Fig. 1Bd ii). A gradient of labelling was also apparent within the PBN. The highest densities were present in posterior PBN (Fig. 1Ac i, Fig. 1Ba i). The differences in the densities of PC synapses within subregions of the VN and the PBN suggest that PCs preferentially regulate specific subregions.
Low levels of labelling were apparent in many other brainstem regions. In the PCG, fluorescence is apparent in high magnification views (Fig. 1Aa i, Fig. 1Ba ii+iv). Sparse labelling is present in the PRP (Fig. 1Ba-d iv), which is consistent with previous studies 10–13. Very little labelling was found in the GRN (Fig. 1Aa iv), the PRNr (Fig. 1Ad iii), the LC (Fig. 1Ab i), and the NTS (Fig. 1Be iii).
These fluorescence images establish that there is considerable variation in the densities of PC synapses between and within various brainstem regions. The highest densities of PC synapses are present in the range bregma -5.85 mm to -5.95 mm, and 1.5 to 2 mm from the midline.
Quantification of PC synapses in the brainstem
To quantifying the densities of PC synapses in the brainstem, we detected individual PC boutons, and registered images to the Allen CCF. Experiments were performed in CGRP-GFP/PCP2- cre/synaptophysin-tdTomato mice. We used synaptophysin-tdTomato fluorescence to label PC synapses, vGAT immunohistochemistry to visualize all GABAergic synapses, and CGRP-GFP to label subnuclei to aid in atlas alignment. The resulting alignment is shown for a coronal slice (Fig. 2A, see Methods). To quantify synapses, confocal images were taken for a z-stack of 1.5 µm, and all GABAergic synapses were detected based on the vGAT immunofluorescence (Fig. 2B, lower right, grey dots). PC boutons were determined by detecting vGAT and synaptophysin-tdTomato fluorescence colocalization (Fig. 2B, lower right, red dots, see Methods).
This approach was used to detect PC boutons in a series of coronal slices from Bregma -5.45 to -6.95, where the majority of PC projections reside. Inhibitory synapses were present at high densities in all regions in all slices (Fig. 2C, left, grey), while PC synapses were spatially restricted (Fig. 2C, left, red). The total number of detected PC boutons, the density of PC synapses, and the fraction of inhibitory boutons that are made by PCs, were determined for each region (Fig. 2D-F, data points color-coded to indicate slice position, n = 3 mice, 2 hemispheres/mouse).
High densities of PC synapses are present in the superior, lateral, spinal and medial vestibular nuclei, but there are pronounced regional differences in bouton densities within the subnuclei and related nuclei (Fig. 2C-F). In the superior vestibular nucleus, PC synapses are present at high density and comprise up to 85% of all inhibitory inputs. In the lateral vestibular nucleus, the number, density, and fractional contribution of PC synapses, were largest in posterior sections. PC inputs contributed to ∼40% of all inhibitory inputs in posterior LAV. The medial vestibular nucleus spanned the longest anterior-posteriorly and has the most PC synapses in the middle sections, from bregma -6.05 mm to -6.35 mm. There was a pronounced dorsal-ventral gradient in the density of PC synapses. The spinal vestibular nucleus is the most posterior nucleus and had less variability across the anterior-posterior axis. It has a high average PC synapse number and density across sections and 26% of inhibition originates from PCs. The prepositus nucleus also receives PC inputs that are highest at bregma -6.05 mm and -6.35 mm and highest in dorsal regions. PCs contribute up to 9% of the total inhibitory inputs in the prepositus nucleus (Fig. 2D left, middle, right). In the more posterior sections (bregma -6.65 mm and -6.95 mm), PC synapses were restricted to the dorsal region in the vestibular nuclei, the external cuneate, and the cuneate. The external cuneate and the cuneate are small regions, and the densities were correspondingly higher though the absolute number of synapses are relatively low and variable. The external cuneate spanned from bregma -6.65mm to -6.95 but has more PC synapses in the posterior section. It is evident that the vestibular nuclei, the cuneate nucleus and prepositus nucleus are not uniformly targeted by PCs.
There is a posterior to anterior gradient of PC synapses in the PB. In anterior sections (Fig. 2C, bregma -5.45 mm to -5.65 mm) high densities of PC synapses were only apparent in a few localized regions of the PB. The medial-ventral region of the PBN (bregma -5.65 mm) have extensive PC inputs, comparable in density to some regions of the vestibular nuclei.
PC synapses are present but at low densities within the pontine central gray (PCG) and nearby subnuclei including the LC, Barrington’s nucleus, sublateraldorsal nucleus, lateraldorsal tegmenta nucleus, dorsal tegmental nucleus, and supragenual nucleus (Fig. 2C, bregma -5.45 mm to -5.65 mm). PC synapses make up a small fraction of inhibitory synapses in these areas (Fig. 2F). The Barrington’s nucleus and the laterodorsal tegmental nucleus had a higher PC density and fraction of inhibition, although it is important to note that these PCG subregions are relatively small in area. The LC, which is labelled in CGRP mice, had few PC synapses with a slightly elevated PC density count in a few posterior sections.
Characterization of functional properties of PC synapses in the brainstem
To confirm these PC connections in different brainstem regions and examine their strength, we optically stimulated PC fibers in PC/ChR2-YFP mice and measured IPSCs in coronal brain slices of the dorsal brainstem. We recorded optically-evoked IPSCs in 133 of 310 neurons in the dorsal brainstem (between bregma -5.45 mm to -6.35 mm) to generate a physiological map of PC inputs to the brainstem. The IPSC amplitudes of the recorded brainstem neurons (Fig 3A, greyscale color-coded) are shown along with the density maps of PC boutons from Fig 2. For the density map, PC bouton counts were binned into 144 x 144 x 4 μm volumes, and averaged across the multiple sections. The likelihood of optically-evoking a PC-IPSC varied with coronal section from anterior to posterior was 9%, 32%, 51%, and 45% (-5.45, -5.65, -6.05 and -6.35 mm to Bregma). We quantified the response amplitudes (Fig. 3B), probability of evoking a PC-IPSC (Fig. 3C), and the IPSC amplitudes (Fig. 3D).
In the most anterior slices (Bregma -5.45 mm and -5.65 mm), PC-IPSCs were not evoked at most locations (47/53 cells nonresponding), which is consistent with the very low density of PC synaptic boutons (Fig. 3A). For the PCG, no PC-IPSCs were evoked in the Bregma -5.45 mm section. In the Bregma -5.65 mm section PC-IPSCs were evoked in 23% of cells, with highly variable amplitudes (Fig. 3B), and the average PC-IPSC in responding cells was over 1 nA (Fig. 3D). For the PB, PC- IPSCs were evoked with a low response probability in Bregma -5.45 mm slices, but at Bregma -5.65 mm, 48% of cells responded (Fig. 3C). In the PB, the amplitudes of IPSCs onto different cells were highly variable (50 pA to over 10 nA) (Fig. 3B), and the average of responding cells was 2 nA.
In more posterior slices (Bregma -6.05 mm and -6.35), PC-IPSCs were evoked in a high percentage of cells in the SUV, LAV, MV, and PRP (45%, 59%, 58%, and 52% respectively, Fig. 3C). The SUV and LAV had predominantly large IPSCs in responding cells, with most evoked currents larger than 500 pA and the average PC-IPSC of responding cells was several nanoamps. In the SPIV, MV, and PRP, PC- IPSCs ranged from 50 pA to ∼2nA and average IPSC amplitudes of responding cells was less than 1 nA (Fig. 3B, D). Overall, PC-IPSCs were evoked in a larger percentage of cells in regions with a high density of PC boutons (Fig. 3E).
Assessing PC inputs to the LC and mesencephalic trigeminal neurons
There are many types of molecularly distinct neurons in the brainstem 41, which could be differentially targeted by PCs and contribute to the highly heterogeneous amplitudes of evoked PC-IPSCs we observed. We therefore took a targeted approach to record from neurons in the MEV and LC, which are distinct neuron populations with well-characterized markers that are in close proximity to PC boutons and to areas with large PC inputs (the PB and vestibular nuclei, Fig 4A). Previous trans-synaptic tracing efforts had also suggested potential PC inputs to these cells, but functional characterizations of these connections are lacking 17,19–21.
We began by studying the extremely large unipolar neurons of the MEV. These neurons are developmentally part of the periphery, gap junction coupled, exhibit a unique chloride gradient, and directly sense and control the muscles of the jaw 42–44. We used immunohistochemistry for parvalbumin (PV) to identify MEV neurons 43. We measured PC-IPSCs, filled cells with biocytin, and identified these neurons based on their shape and PV expression (Fig. 4B). Recordings were made in both coronal slices (bregma -5.45 mm and -5.65 mm) and horizontal slices, but PC-IPSCs were not evoked in any of the recorded cells (Fig. 4C, n=23). Thus, despite their close proximity to PC synapses, PCs do not provide a significant source of inhibition to MEV neurons.
We also used optogenetics and immunohistochemistry to examine PC-IPSCs in the LC to directly assess whether PCs provide a major source of inhibition to LC neurons, as has been proposed 19–21. The low density of PC synapses in the LC raised doubts about whether PCs provide a prominent source of inhibition in the LC (Fig. 4A), but it was possible that PCs might synapse onto LC dendrites that extend beyond the core of the LC. We therefore directly assessed PC-LC synaptic connectivity synaptically by measuring optically-evoked PC-IPSCs using a recording electrode containing biocytin, and used immunohistochemistry to identify TH-expressing neurons of the LC (Fig. 4B). We examined the LC at two coronal levels in the posterior LC and found that no PC-IPSCs were evoked in the anterior section (0/27), while small currents were evoked in 2/40 neurons in posterior sections (bregma -5.65 mm) (Fig. 4C, D). The average PC-IPSC of all cells was 1.4 ± 8.2 pA, Thus, PCs do not provide a prominent source of inhibition to the LC.
Discussion
Widespread but nonuniform PC inputs to the brainstem
Here we find that PCs make direct synapses within numerous brainstem nuclei. The densities of these synapses vary widely in different nuclei. There is also a pronounced gradient of PC synapses across the dorsal-ventral axis of the several brainstem nuclei, indicating that PCs do not uniformly regulate activity within these nuclei. The combination of synaptophysin-TdT expression restricted to PCs and vGAT immunohistochemistry allowed us to quantify the absolute number and density of PC synapses, and the fraction of inhibitory inputs that are from PCs for each region. PC synapses comprised up to 75% of the inhibitory synapses in some vestibular regions and 55% in the caudal PB. Thus, PCs make prominent contributions to inhibition in some brainstem regions that are comparable to levels observed in cerebellar nuclei (72%) 45. In contrast, in the PRP and PCG PCs provide a low total number of inputs (PRP, PCG, vs. VN; 0.002, 0.006, >0.01 synapses/µm2 respectively) and a small fraction of inhibitory inputs (4, 8%, 15-50%), where they inhibit only a modest fraction of cells (13%, 33%, 54%). In all of these regions, PCs likely function similarly to their inputs to the cerebellar nuclei, where a very brief pause in firing can lead to large and rapid elevations in target cell firing 46,47, but PCs regulate the firing of a very different fraction of cells in brainstem nuclei.
PC synapses in the PCG and nearby regions
We establish that there are PC boutons within the PCG and associated nuclei, and that there are strong PC synapses in this region. This suggests that PCs play a role in regulating activity in these regions and in the behaviors they control. However, the PCG is enigmatic in structure and function, with the most commonly used mouse atlases disagreeing on the borders and identity of subnuclei 40,48,49 (see Methods). Barrington’s nucleus, a region that controls micturition 36,37, stands out as being well defined anatomically and functionally, and is a promising candidate for regulation by PCs. Our previous study raised the possibility that PCs in the posterior vermis might directly target cells in Barrington’s nucleus 17, but this study relied on AAV1 injections in the cerebellum, that in addition to anterogradely labelling PC targets, could have retrogradely labeled cells in Barrington’s nucleus if they project to the cerebellar cortex. Our results highlight the challenges in studying PC synapses in the PCG and related nuclei. We observed PC synapses and synaptic connections for cells in the vicinity of Barrington’s nucleus (Fig. 2 and Fig. 3). As suggestive as these findings are, it remains an open question whether direct PC synapses to Barrington’s nucleus control micturition without additional experiments using molecular markers to identify Barrington’s nucleus. Similarly, further studies are needed to identify other PC targets in the PCG and determine what behaviors they control.
Gradients of PC synapses in the brainstem
In general, PCs inputs to brainstem nuclei are spatially heterogenous. The caudal-rostral gradient of PC synapses in the PB allows PCs to target specific subtypes of PB neurons 17. We find that PC synapses in the PCG and nearby subnuclei also exhibit a caudal-rostral gradient. Additional studies are needed to identify PC targets in these regions and to determine the significance of their spatial heterogeneity.
There is also a pronounced dorsal-ventral gradient in many vestibular subnuclei and related nuclei. Previous studies suggested that PCs do not project to all regions of the VN, but they were unable to quantify the regional densities of PC synapses. Labeling individual PCs or those within subregions of the cerebellar cortex helped to determine their specific projections in the VN 3,16,50–52, but did not label all PC synapses in the VN. Immunohistochemical methods targeting proteins selectively expressed in PCs offer the potential to label all PC synapses in the VN. Calbindin is a widely used PC marker, but its presence in vestibular afferents compromises its use in the VN 53. PKCγ is also expressed by PCs, but has the advantage that it is not present in vestibular afferents 4. The lack of PKCγ immunoreactivity established that PC synapses are absent in the ventral VN, which is qualitatively similar to what we observe. However, the possibility that PKCγ is expressed by other cell types projecting to the VN complicates the use of PKCγ labeling as a definitive marker for identifying PC synapses. Our studies establish that PC synapses are present at high densities throughout the SUV; in the dorsal LAV, MV, PRP, SPIV; in subregions of the ECU; and there are large subregions that are devoid of PC synapses. Multiple lines of evidence suggest that PC synapses in the VN play a role in cancelling self-motion related to eye movements and proprioception 10. The distribution of synapses suggests that processing within VN subnuclei is spatially segregated according to the locations of PC synapses, implying that PC feedback potentially cancels signals related to self-motion specifically within these regions.
Brainstem regulation by direct PC inputs or indirectly via the deep cerebellar nuclei
PCs can also disynaptically influence the brainstem by disinhibiting cells in the deep cerebellar nuclei that in turn project to the brainstem. It is likely that some brainstem regions receive both direct PC input and indirect from deep cerebellar nuclei 22,54,55, and that these two different pathways serve different roles. For example, direct and indirect inputs target different regions of the PB and are implicated in different behaviors 17,56. The deep cerebellar nuclei projections to the vestibular nuclei are not well understood, but they are likely a mix of excitatory and inhibitory inputs 54,55.This raises the possibility that the indirect pathway through the deep cerebellar nuclei has the added flexibility of providing both excitation and inhibition.
Lack of significant PC inputs to LC neurons
We find that PCs do not provide a significant direct input to the LC. This has been controversial because retrograde labelling studies using rabies viruses concluded that PCs constitute one of the largest groups of cells projecting to the LC 19(Fig 2h,i), even though PC synapses did not appear to innervate the core of the LC (17 and Fig. 1, Fig. 2). We directly assessed PC to LC connection strengths using a cre line that is highly selective for PCs, and we found that in PC/ChR2-YFP mice, tiny optically-evoked PC-IPSCs (∼50 pA) were observed in just 3% of LC neurons. The average IPSC size for all cells was less than 2 pA. This indicates that within the LC, inhibition originates from brain regions other than PCs 21. The cerebellum may still regulate firing in the LC, but it does so via connections through the deep cerebellar nuclei and the LC 24,30,31.
Together, these findings indicate that reliance on anatomical tracing experiments alone is insufficient to establish the presence and importance of a synaptic connection. Studies highlighting PC inputs to the LC were conducted using rabies-tracing methods 19–21, which have limitations. These viruses have unknown tropism, unclear synapse specificity, and critically depend on the degree to which the “starter” cell population is restricted to the intended cell type 57,58. We were fortunate to have a highly selective cre line to selectively target PCs that allowed us to examine PC synapses in the brainstem while avoiding complications that can occur when using viruses.
PC targets in the brainstem
The next step in clarifying the PC to brainstem outputs and the behaviors they regulate is to determine the molecular identity of target cells. This is challenging because there are many types of neurons present in the brainstem 41,59–61. We previously identified candidate PC targets by injecting AAV1 in the cerebellar cortex to anterogradely label PC targets, and then using RNA-seq to determine the molecular identity of labelled cells 17. An important caveat to this approach is that it while it very effectively labels anterograde PC targets, it can also retrogradely label cells that project to the cerebellar cortex. It is therefore crucial to determine if functional PC synapse are present, unless it is known that the region does not project to the cerebellar cortex.
Our primary focus in our previous study 17 was to identify PC targets in the PB. The fact that the PB does not project to the posterior vermis of the cerebellum 62,63, and the observation that labelled cells were restricted to PBN regions receiving PC inputs, suggest that the following cells are PC targets: Satb2, Penk, and Tacr1 populations, which have roles in taste 64,65, thermoregulation 66, and pain 67,68, respectively. We also found that CGRP neurons 63,69,70, which are located in a region of the PB devoid of PC synapses, were not labelled by this method. This supports the hypothesis that PCs selectively inhibit specific types of brainstem neurons.
We also labelled neurons in the vestibular nucleus, Barrington’s nucleus, mesencephalic trigeminal nucleus, and the locus coeruleus in that previous study. The lack of PC-evoked inputs to neurons in the mesencephalic trigeminal nucleus and locus coeruleus shown here established that these populations are not targeted by PCs. It further suggests that these neurons project to the cerebellum and were retrogradely labelled71,72. For the multiple candidate PC targets in the vestibular nucleus, it is necessary to specifically test for the presence of PC synapses, as was done for GlyT2 expressing neurons 5,6. In the PCG and nearby nuclei, the sparsity of PC synapses combined with the large PC synaptic inputs in a small fraction of cells suggests that PCs only inhibit specific cells in these regions. This was also reflected in our previous anatomical experiments17, where we identified Crh-expressing Barrington’s neurons and other glutamatergic/GABAergic neurons in the PCG. These cells are important for micturition 36 and valence 33 respectively, and further indicate a broad range of PC output functions.
Methods
Animals
For anatomical studies, B6.Cg-Tg(PCP2-cre)3555Jdhu/J x B6;129S-Gt(ROSA)26Sortm34.1(CAG- Syp/tdTomato)Hze/J (PC/synaptophysin-tdTomato, Jackson Labs) was used. Calca-GFP (CGRP-GFP) (MMRRC, Stock number: 011187-UCD, generously provided by David Ginty) mice were crossed with the PC/synaptophysin-tdTomato mice to further support anatomical studies. For physiology experiments, B6.Cg-Tg(PCP2-cre)3555Jdhu/J × B6;129S-Gt(ROSA)26Sortm32(CAG-COP4*H134R/EYFP)Hze/J (PC/ChR2-YFP, Jackson Laboratory) mice were used. All animals were used under supervision of Harvard Medical School’s Institutional Animal Care and Use Committee (IACUC) or the Pennsylvania State University College of Medicine’s IACUC.
Anatomy
In order to identify inhibitory synapses PCs made in the brainstem, PC/synaptophysin-tdTomato mice were crossed with CGRP-GFP mice. Thus, synaptophysin-tdTomato was expressed selectively in all PCs and GFP is expressed in the lateral parabrachial nuclei, the LC, the hypoglossal nuclei, the vestibular nerve, the spinal tract of the trigeminal nerve, and the solitary tracts. Mice were anesthetized at P56 and perfused with PBS and 4% PFA. After removal, brains were post-fixed for one day in 4% PFA, and sliced coronally in 50 μm sections. Slices were stained with a vGAT (vesicular GABA transporter) antibody (Synaptic Systems, #131 004, 1:500), and visualized using an AlexaFluor 647 secondary (Thermo Fisher, #A-21450, 1:1000). Every third section of the dorsal brainstem was imaged on a confocal microscope (Leica Stellaris 5). Acquisitions were made with an XY resolution of 361.1 nm for an area of about 10 mm2 total per section, and 300 nm z steps for 4 μm stacks. Stitched images were imported into ZEISS arivis Pro (arivis).
We isolated individual synaptic boutons using vGAT fluorescence and analyzed the synaptophysin- tdTomato fluorescence for colabeling to identify PC synapses 17,73. Using a background correction feature in arivis, a background representation was generated with a 50 μm diameter Gaussian filter and subtracted from the vGAT fluorescence. vGAT was then isolated by a watershed algorithm provided with a 1 μm bouton diameter and threshold intensity. Thresholds were adjusted for each individual image based on three 50-pixel squares that had various densities of vGAT expression. Optimal threshold values were approximately one standard deviation above median. The following analysis were conducted in MATLAB: segmented vGAT boutons were analyzed for tdTomato-synaptophysin colocalization by finding a regional maximum in the tdTomato fluorescence (maximum center-to-center distance is 0.7 μm). We plotted the synaptophysin intensity values within each voxel. This histogram showed a bimodal distribution corresponding to noise and signal, and the signal threshold corresponded to the minimum between the two peaks.
We identified brainstem nuclei by aligning the Allen Common Coordinate Framework. We used several features to register confocal images of the brainstem: 1) the edges of the tissue and position of the ventricles, 2) the fiber tracts and features notable from autofluorescence and brightfield imaging, and 3) GFP labelling present in numerous brainstem regions in CGRP-GFP mice (including VIIn, sptv, LC, XII, and their axons). CGRP-GFP labelling in the LC and VIIn was particularly useful in anterior sections.
Puncta within each brainstem region were quantified using this aligned atlas. We matched our samples to the indicated bregma levels (±100 μm) in Figure 2. To determine the variability in our alignment, we sampled 50-70 points 350 μm apart across the atlas image before and after aligning to each confocal image. The displacement distances of these reference points were calculated for each image and binned based on the confocal image location relative to bregma. Our images were displaced from the Allen Common Coordinate Framework by an average of 107 μm. The displacement distances were 90 ± 25 μm (standard deviation, n=6 hemispheres, bregma -5.45 mm), 126±26 μm (n=10, bregma -5.65 mm),102±35 μm (n=8, bregma -6.05 mm),103±51 μm (n=8, bregma -6.35 mm). 108±43 μm (n=8, bregma -6.65 mm), 96±31 μm (n=8, bregma -6.95 mm).
It is important to note that the accuracy of our mapping is dependent on the accuracy of the reference maps that we register to. The PCG is one region in particular that varies substantially between reference atlases 40,48,49. We labelled the regions in/around the dorsomedial pons as the PCG, based off of the borders noted in the Allen CCF, but other atlases constrain the borders of the PCG, leaving parts of the dorsomedial pons effectively unlabelled. The precise location of many other regions within the dorsomedial pons also differ dramatically. Precise identification of these areas (i.e. Barrington’s nucleus) will require a molecularly targetted approach (in situ hybridization, etc.).
Electrophysiology
Mice of both sexes ranging from p24 to p50 (n=30) were anesthetized with ketamine / xylazine and transcardially perfused with warm choline ACSF solution (34°C) containing in mM: 110 Choline Cl, 2.5 KCl, 1.25 NaH2PO4, 25 NaHCO3, 25 glucose, 0.5 CaCl2, 7 MgCl2, 3.1 Na Pyruvate, 11.6 Na ascorbate, 0.002 (R,S)-CPP, 0.005 NBQX, oxygenated with 95% O2 / 5% CO2. Coronal slices were made (200 μm) using a Leica 1200S or a Campden Instrument 7000smz-2 vibratome in warm choline ACSF (34°C). Slices were then transferred to a holding chamber with warm ACSF (34°C) containing in mM: 127 NaCl, 2.5 KCl, 1.25 NaH2PO4, 25 NaHCO3, 25 glucose, 1.5 CaCl2, 1 MgCl2 and were recovered at 34°C for 30 minutes before being moved to room temperature until recordings began.
Voltage-clamp recordings were made across the brainstem. Borosilicate glass electrodes (2-4 MΩ) were filled with a high chloride internal containing in mM: 35 CsF, 100 CsCl, 10 EGTA, 10 HEPES, 4 QX-314, pH 7.3 with CsOH. This internal solution was used to increase sensitivity to inhibitory inputs and improve clamp. The osmolarity of internal solution was adjusted to 290-300 mOsm. Whole-cell capacitance and series resistance was left uncompensated for all experiments. Neurons were held at -70 mV. All experiments were performed at room temperature in the presence of 5 μM NBQX to block AMPARs and 2.5 μM (R,S)-CPP to block NMDARs, with a flow rate of 2 ml/min. ChR2 expressing PC axons were stimulated with 473 nm light from a light-emitting diode (Thorlabs or Sutter) in the entire field of view (1 ms, ∼80 mW/mm2) for at least 10 trials. Data were collected using Igor (Wavemetrics) running mafPC (courtesy of M. A. Xu-Friedman) or SutterPatch (Sutter). Images with a 4X objective were used to determine the positions of recorded cells. Slices were fixed and stained with DAPI to confirm the anterior-posterior position of the coronal slice, and matched to the closest indicated bregma level indicated in Figure 3.
In experiments targeting the LC or mesencephalic trigeminal nucleus, biocytin (B1592, Thermofisher) was included in the intracellular solution. Cells were then stained with an anti-tyrosine hydroxylase antibody to identify the LC (1:1000, AB152, Sigma) or anti-parvalbumin antibody to identify the mesencephalic trigeminal (1:1000 P3088, Sigma), followed by an Alexa 647 secondary antibody (1:1000 A32733 or ab150079, Thermofisher or Abcam respectively) and streptavidin-Alexa 594 conjugate (1:1000, 1402-3900, Thermofisher). Sections were subsequently imaged using a confocal microscope (Leica Stellaris 5) to determine the identity of the recorded cell.
References
- 1Cerebellum Lecture: the Cerebellar Nuclei-Core of the CerebellumCerebellum 23:620–677https://doi.org/10.1007/s12311-022-01506-0
- 2The Cerebellar CortexAnnu Rev Neurosci 45:151–175https://doi.org/10.1146/annurev-neuro-091421-125115
- 3Central vestibular system: vestibular nuclei and posterior cerebellumBrain Res Bull 60:511–541https://doi.org/10.1016/s0361-9230(03)00055-8
- 4Regional and cellular distribution of protein kinase C in rat cerebellar Purkinje cellsJ Comp Neurol 427:235–254https://doi.org/10.1002/1096-9861(20001113)427:2<235::aid-cne6>3.0.co;2-6
- 5Multiple types of cerebellar target neurons and their circuitry in the vestibulo- ocular reflexJ Neurosci 31:10776–10786https://doi.org/10.1523/JNEUROSCI.0768-11.2011
- 6Purkinje cell synapses target physiologically unique brainstem neuronsJ Neurosci 23:6392–6398https://doi.org/10.1523/JNEUROSCI.23-15-06392.2003
- 7Brain stem neurons in modified pathways for motor learning in the primate vestibulo-ocular reflexScience 242:771–773https://doi.org/10.1126/science.3142040
- 8Responses during eye movements of brain stem neurons that receive monosynaptic inhibition from the flocculus and ventral paraflocculus in monkeysJ Neurophysiol 72:909–927https://doi.org/10.1152/jn.1994.72.2.909
- 9Neural basis for motor learning in the vestibuloocular reflex of primates. I. Changes in the responses of brain stem neuronsJ Neurophysiol 72:928–953https://doi.org/10.1152/jn.1994.72.2.928
- 10Internal models of self-motion: neural computations by the vestibular cerebellumTrends Neurosci 46:986–1002https://doi.org/10.1016/j.tins.2023.08.009
- 11Angular Head Velocity Cells within Brainstem Nuclei Projecting to the Head Direction CircuitJ Neurosci 43:8403–8424https://doi.org/10.1523/JNEUROSCI.0581-23.2023
- 12The interconnection between the vestibular nuclei and the nodulus: a study of reciprocityBrain Res 449:47–53https://doi.org/10.1016/0006-8993(88)91022-0
- 13Organization of the vestibulocerebellumAnn N Y Acad Sci 781:553–579https://doi.org/10.1111/j.1749-6632.1996.tb15728.x
- 14Projection of reconstructed single Purkinje cell axons in relation to the cortical and nuclear aldolase C compartments of the rat cerebellumJ Comp Neurol 512:282–304https://doi.org/10.1002/cne.21889
- 15Projections of individual Purkinje cells of identified zones in the flocculus to the vestibular and cerebellar nuclei in the rabbitJ Comp Neurol 349:428–447https://doi.org/10.1002/cne.903490308
- 16Projections of individual Purkinje cells of identified zones in the ventral nodulus to the vestibular and cerebellar nuclei in the rabbitJ Comp Neurol 349:448–463https://doi.org/10.1002/cne.903490309
- 17A Purkinje cell to parabrachial nucleus pathway enables broad cerebellar influence over the forebrainNat Neurosci 26:1929–1941https://doi.org/10.1038/s41593-023-01462-w
- 18Anatomical Evidence for a Direct Projection from Purkinje Cells in the Mouse Cerebellar Vermis to Medial Parabrachial NucleusFront Neural Circuits 12https://doi.org/10.3389/fncir.2018.00006
- 19Viral-genetic tracing of the input-output organization of a central noradrenaline circuitNature 524:88–92https://doi.org/10.1038/nature14600
- 20Sex-Related Differential Whole-Brain Input Atlas of Locus Coeruleus Noradrenaline NeuronsFront Neural Circuits 14https://doi.org/10.3389/fncir.2020.00053
- 21Active control of arousal by a locus coeruleus GABAergic circuitNat Neurosci 22:218–228https://doi.org/10.1038/s41593-018-0305-z
- 22A Systematic Review of Direct Outputs from the Cerebellum to the Brainstem and Diencephalon in MammalsCerebellum 23:210–239https://doi.org/10.1007/s12311-022-01499-w
- 23Recent Advances in the Understanding of Specific Efferent Pathways Emerging From the CerebellumFront Neuroanat 15https://doi.org/10.3389/fnana.2021.759948
- 24Catecholaminergic Innervation of the Lateral Nucleus of the Cerebellum Modulates Cognitive BehaviorsJ Neurosci 41:3512–3530https://doi.org/10.1523/JNEUROSCI.2406-20.2021
- 25HippoBellum: Acute Cerebellar Modulation Alters Hippocampal Dynamics and FunctionJ Neurosci 40:6910–6926https://doi.org/10.1523/JNEUROSCI.0763-20.2020
- 26The little brain and the seahorse: Cerebellar-hippocampal interactionsFront Syst Neurosci 17https://doi.org/10.3389/fnsys.2023.1158492
- 27The integrated brain network that controls respirationElife 12https://doi.org/10.7554/eLife.83654
- 28Catecholaminergic and cholinergic neuromodulation in autism spectrum disorder: A comparison to attention-deficit hyperactivity disorderFront Neurosci 16https://doi.org/10.3389/fnins.2022.1078586
- 29The cerebellum and epilepsyEpilepsy Behav 121https://doi.org/10.1016/j.yebeh.2020.106909
- 30Afferent projections to the rat locus coeruleus as determined by a retrograde tracing techniqueJ Comp Neurol 178:1–16https://doi.org/10.1002/cne.901780102
- 31The brain nucleus locus coeruleus: restricted afferent control of a broad efferent networkScience 234:734–737https://doi.org/10.1126/science.3775363
- 32Locus coeruleus: From global projection system to adaptive regulation of behaviorBrain Res 1645:75–78https://doi.org/10.1016/j.brainres.2016.03.001
- 33Glutamatergic and GABAergic neurons in pontine central gray mediate opposing valence-specific behaviors through a global networkNeuron 111:1486–1503https://doi.org/10.1016/j.neuron.2023.02.012
- 34Neural and Homeostatic Regulation of REM SleepFront Psychol 11https://doi.org/10.3389/fpsyg.2020.01662
- 35Voluntary urination control by brainstem neurons that relax the urethral sphincterNat Neurosci 21:1229–1238https://doi.org/10.1038/s41593-018-0204-3
- 36Central Control Circuit for Context-Dependent MicturitionCell 167:73–86https://doi.org/10.1016/j.cell.2016.08.073
- 37Barrington’s nucleus: Neuroanatomic landscape of the mouse “pontine micturition center”J Comp Neurol 525:2287–2309https://doi.org/10.1002/cne.24215
- 38AAV-Mediated Anterograde Transsynaptic Tagging: Mapping Corticocollicular Input-Defined Neural Pathways for Defense BehaviorsNeuron 93:33–47https://doi.org/10.1016/j.neuron.2016.11.045
- 39Synaptic Specificity and Application of Anterograde Transsynaptic AAV for Probing Neural CircuitryJ Neurosci 40:3250–3267https://doi.org/10.1523/JNEUROSCI.2158-19.2020
- 40The Allen Mouse Brain Common Coordinate Framework: A 3D Reference AtlasCell 181:936–953https://doi.org/10.1016/j.cell.2020.04.007
- 41A spatially-resolved transcriptional atlas of the murine dorsal pons at single- cell resolutionNat Commun 15https://doi.org/10.1038/s41467-024-45907-7
- 42Synergy between electrical coupling and membrane properties promotes strong synchronization of neurons of the mesencephalic trigeminal nucleusJ Neurosci 32:4341–4359https://doi.org/10.1523/JNEUROSCI.6216-11.2012
- 43A critical role for Piezo2 channels in the mechanotransduction of mouse proprioceptive neuronsSci Rep 6https://doi.org/10.1038/srep25923
- 44Excitatory GABAergic synaptic potentials in the mesencephalic trigeminal nucleus of adult rat in vitroNeurosci Res 51:463–474https://doi.org/10.1016/j.neures.2004.12.016
- 45Postsynaptic targets of Purkinje cell terminals in the cerebellar and vestibular nuclei of the ratEur J Neurosci 7:2322–2333https://doi.org/10.1111/j.1460-9568.1995.tb00653.x
- 46Climbing fiber synapses rapidly and transiently inhibit neighboring Purkinje cells via ephaptic couplingNat Neurosci 23:1399–1409https://doi.org/10.1038/s41593-020-0701-z
- 47Implications of variable synaptic weights for rate and temporal coding of cerebellar outputsElife 13https://doi.org/10.7554/eLife.89095
- 48Paxinos and Franklin’s the mouse brain in stereotaxic coordinatesAcademic press
- 49Developmental Mouse Brain Common Coordinate FrameworkbioRxiv https://doi.org/10.1101/2023.09.14.557789
- 50Topographical distribution of Purkinje cells in the uvula and the nodulus projecting to the vestibular nuclei in catsBrain Res 416:100–112https://doi.org/10.1016/0006-8993(87)91501-0
- 51Corticonuclear and corticovestibular projections from the uvula in the albino rat: differential projections from sublobuli of the uvulaBrain Res 492:176–186https://doi.org/10.1016/0006-8993(89)90900-1
- 52Purkinje cell microzones mediate distinct kinematics of a single movementNat Commun 14https://doi.org/10.1038/s41467-023-40111-5
- 53Pattern of selected calcium-binding proteins in the vestibular nuclear complex of two rodent speciesJ Comp Neurol 365:575–584https://doi.org/10.1002/(SICI)1096-9861(19960219)365:4<575::AID-CNE5>3.0.CO;2-1
- 54Modular output circuits of the fastigial nucleus for diverse motor and nonmotor functions of the cerebellar vermisElife 9https://doi.org/10.7554/eLife.58613
- 55Diverse inhibitory projections from the cerebellar interposed nucleusElife 10https://doi.org/10.7554/eLife.66231
- 56Cerebellar nuclei neurons projecting to the lateral parabrachial nucleus modulate classical fear conditioningCell Rep 42https://doi.org/10.1016/j.celrep.2023.112291
- 57The Serendipity of Viral Trans-Neuronal Specificity: More Than Meets the EyeFront Cell Neurosci 15https://doi.org/10.3389/fncel.2021.720807
- 58Can transsynaptic viral strategies be used to reveal functional aspects of neural circuitry?J Neurosci Methods 348https://doi.org/10.1016/j.jneumeth.2020.109005
- 59The molecular cytoarchitecture of the adult mouse brainNature 624:333–342https://doi.org/10.1038/s41586-023-06818-7
- 60Molecularly defined and spatially resolved cell atlas of the whole mouse brainNature 624:343–354https://doi.org/10.1038/s41586-023-06808-9
- 61Neuronal classification and marker gene identification via single-cell expression profiling of brainstem vestibular neurons subserving cerebellar learningJ Neurosci 32:7819–7831https://doi.org/10.1523/JNEUROSCI.0543-12.2012
- 62Efferent projections of Vglut2, Foxp2, and Pdyn parabrachial neurons in miceJ Comp Neurol 529:657–693https://doi.org/10.1002/cne.24975
- 63Efferent projections of CGRP/Calca-expressing parabrachial neurons in miceJ Comp Neurol 529:2911–2957https://doi.org/10.1002/cne.25136
- 64SatB2-Expressing Neurons in the Parabrachial Nucleus Encode Sweet TasteCell Rep 27:1650–1656https://doi.org/10.1016/j.celrep.2019.04.040
- 65Satb2 neurons in the parabrachial nucleus mediate taste perceptionNat Commun 12https://doi.org/10.1038/s41467-020-20100-8
- 66Parabrachial opioidergic projections to preoptic hypothalamus mediate behavioral and physiological thermal defensesElife 10https://doi.org/10.7554/eLife.60779
- 67A spinoparabrachial circuit defined by Tacr1 expression drives painElife 10https://doi.org/10.7554/eLife.61135
- 68The Parabrachial Nucleus Directly Channels Spinal Nociceptive Signals to the Intralaminar Thalamic Nuclei, but Not the AmygdalaNeuron 107:909–923https://doi.org/10.1016/j.neuron.2020.06.017
- 69Encoding of danger by parabrachial CGRP neuronsNature 555:617–622https://doi.org/10.1038/nature25511
- 70The Parabrachial Nucleus: CGRP Neurons Function as a General AlarmTrends Neurosci 41:280–293https://doi.org/10.1016/j.tins.2018.03.007
- 71Cerebellar afferences from the mesencephalic trigeminal nucleus in the ratNeuroreport 6:2293–2296https://doi.org/10.1097/00001756-199511270-00006
- 72Norepinephrine release in the cerebellum contributes to aversive learningNat Commun 14https://doi.org/10.1038/s41467-023-40548-8
- 73Purkinje cell outputs selectively inhibit a subset of unipolar brush cells in the input layer of the cerebellar cortexElife 10https://doi.org/10.7554/eLife.68802
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