Abstract
Many neuron types consist of populations with continuously varying molecular properties. Here, we show a continuum of postsynaptic molecular properties in three types of neurons and assess the functional correlates in cerebellar unipolar brush cells (UBCs). While UBCs are generally thought to form discrete functional subtypes, with mossy fiber (MF) activation increasing firing in ON-UBCs and suppressing firing in OFF-UBCs, recent work also points to a heterogeneity of response profiles. Indeed, we find a continuum of response profiles that reflect the graded and inversely correlated expression of excitatory mGluR1 and inhibitory mGluR2/3 pathways. MFs coactivate mGluR2/3 and mGluR1 in many UBCs, leading to sequential inhibition-excitation because mGluR2/3-currents are faster. Additionally, we show that DAG-kinase controls mGluR1 response duration, and that graded DAG kinase levels correlate with systematic variation of response duration over two orders of magnitude. These results demonstrate that continuous variations in metabotropic signaling can generate a stable cell-autonomous basis for temporal integration and learning over multiple time scales.
Similar content being viewed by others
Introduction
Throughout the brain, many cells types exhibit continuous molecular variations1,2,3. Recent studies are beginning to provide insight into some functional implications of such graded heterogeneity. Molecular diversity can reflect spatial variations4,5,6, and variation in physiological properties such as excitability and spiking properties of neurons6,7. Here we find that transcripts controlling expression of postsynaptic receptors and downstream signaling pathways are selectively and differentially regulated in many cell types (Fig. 1). To evaluate the functional consequences of this graded continuum of synaptic properties, we studied cerebellar unipolar brush cells (UBCs). UBCs were recently shown to exhibit continuous molecular variations, but how this relates to physiological responses to synaptic inputs was unclear6. Interestingly, UBCs typically receive a single MF input and can transform brief synaptic inputs into diverse, long-lasting changes in firing8,9,10,11,12,13,14,15. For these reasons, UBCs are uniquely suited to dissect the relationship between transcriptomic continua and their functional implications at central synapses.
Synaptic properties of UBCs are thought to contribute to temporal learning in the cerebellum. While UBCs are present throughout the cerebellum, they are most abundant in regions controlling eye movement and in vestibular processing. To facilitate adaptative control of sensorimotor and cognitive behaviors16,17,18,19,20, the cerebellum makes learned predictions on time scales ranging from hundreds of milliseconds to tens of seconds21. MF inputs are transformed into high-dimensional spatial-temporal patterns of granule cell (GrC) activities at the input layer, then GrCs are pooled by the output neurons, the Purkinje cells (PCs), to produce a desired response (Fig. 2a). The capacity of this network to learn complex input-output associations across time necessitates the existence of a diverse temporal basis set in the GrCs22,23,24. UBCs have emerged as important circuit elements within the cerebellum that can overcome the short integration time constant of GrCs. Each UBC receives a single MF input but projects onto several hundred GrCs8. Traditionally, UBCs are functionally divided into OFF and ON subtypes. A MF burst suppresses firing in OFF-UBCs for hundreds of milliseconds by activating inhibitory group II metabotropic glutamate receptors (mGluR2/3)25,26,27 which are coupled to GIRK2, whereas in ON-UBCs MF activation leads to a prolonged glutamate signal and long-lasting activation of AMPA receptors (AMPARs) to increase firing in ON UBCs for tens to hundreds of milliseconds11,12,14,25,28. In this way, the UBC population makes a crucial contribution to temporal representation within the input layer by preprocessing MF inputs.
There are many unresolved issues regarding the generation of temporal responses in UBCs. (1) It is not known whether the diverse temporal responses of ON UBCs reflect factors upstream of receptor activation, such as differences in glutamate release or glutamate uptake11,12,14,25,28, or differences in the UBCs themselves, such as their ligand-gated receptors or their voltage-gated conductances13. (2) ON-UBCs are known to contain mGluR1 coupled to TRPC3 that have the potential to excite cells for longer durations than can be achieved with AMPARs, yet it is widely accepted that synaptic responses in most UBCs are dominated by AMPARs rather than mGluR1 currents14,25,28. (3) Molecular markers for UBC subtypes lack strict adherence to the ON and OFF dichotomy, leading some to suggest that there may be three or four subtypes of UBCs29,30,31. Notably, many UBCs contain both mGluR1 and mGluR2/3, but the functional implications of this are not known. (4) Single-cell RNAseq (scRNAseq) analysis suggests that UBCs have continuously varying properties, and responses evoked by pressure-applied glutamate also exhibited continuous variation over the entire population6, but the functional consequences of molecular diversity on responses evoked by synaptic activation are not known.
Here we reexamine the molecular and functional properties of UBCs. We observe expression gradients in components of the mGluR1 and mGluR2/3 signaling pathways that are inversely correlated, and uniform AMPAR expression. Concordantly, we find that MF activation evoked continuously varying UBC responses that ranged from brief suppression, to suppression followed by low-level long-lasting excitation, to brief intense excitation. MF excitation was mediated primarily by mGluR1 rather than by AMPARs. The amplitudes and durations of mGluR1 responses were inversely correlated and varied over two orders of magnitude, which was consistent with the coregulation of the mGluR1-TRPC3 pathway that determines amplitude, and DAG kinases that decrease response duration. We find the MFs coactivated mGluR2/3 and mGluR1 in many UBCs, with the faster mGluR2/3 component initially suppressing firing, and the slower mGluR1 component subsequently elevating firing. Together, the graded molecular variations across many components of metabotropic signaling generate a diverse continuum of cell-intrinsic synaptic responses. This provides a stable cell-autonomous mode of temporal integration and a population response which may support temporal learning over multiple timescales. Our findings reveal a surprising functional consequence of graded heterogeneity in metabotropic signaling in UBCs and suggest a possible role of such a molecular continuum in other brain areas.
Results
Transcriptomic cell type classifications based on scRNAseq data frequently uncover discrete neuron types exhibiting continuous variations in their molecular properties1,2,3. We analyzed three such cell types to determine whether components of postsynaptic glutamatergic signaling also varied continuously in these cells. UMAP embedding of gene expression is shown for cortical layer 2/3 intratelencephalic (IT) neurons, Purkinje cells and cerebellar UBCs (Fig. 1a–c, top). Across each of these cell types, we observed a continuous axis of molecular variation. To highlight the genes contributing to this molecular gradient, we ordered cells by their latent factor loadings (from high to low) and ordered the top 400 genes by their correlation with the latent factor (Fig. 1a–c, bottom). We indicate the position of genes encoding glutamatergic receptors and components of downstream pathways with three different colors. Ionotropic glutamate receptors (AMPARs and NMDARs) are shown in black (Gria1-4, Grin1, Grin2a, Grin2b, Grid1-2 and Grid2ip). Inhibitory Group II and Group III metabotropic glutamate receptors and the inwardly rectifying potassium channels they activate in blue (Grm2, Grm3, Grm7, Grm8, Kcnj3, Kcnj6), and components of excitatory Group I metabotropic glutamate receptor signaling pathways in red (Grm1, Grm5, Plcb1, Plcb4, Dgkb, Dgkg, Dgkz and Trpc3). These three types of cells, layer 2/3 cortical cells (Fig. 1a, Grm1, Grm5, and Dgkb), Purkinje cells (Fig. 1b, Grm1, Plcb1, Plcb4, and Dgkg) and UBCs (Fig. 1c, Dgkb, Trpc3, Dgkg, Grm1, Plcb4), all share the property that multiple components of excitatory group I metabotropic receptor signaling exhibit graded, continuous variations in expression levels.
The general implications of gradients in metabotropic signaling can be better appreciated by carefully analyzing the correspondence between molecular and functional properties in UBCs (Fig. 2a). UMAP visualization of normalized gene expression for mGluR1 signaling showed similar gradients for Grm1, Plcb4, Dgkb, Dgkg, and Trpc3, but Gnaq expression was uniform (Fig. 2b). NMDARs and AMPARs are both present in UBCs. Yet while AMPA receptors were thought to contribute to diverse excitatory responses of UBCs11,12,14,25,28, genes encoding AMPARs (Gria2) and NMDARs (Grin1) were not differentially expressed (Fig. 2c). Genes encoding mGluR2/3 (Grm2/3) and the downstream effector GIRK2 (Kcnj6) also exhibited graded expression across the population (Fig. 2d). The transcriptomic level co-regulation of mGluR1 and mGluR2/3 signaling pathways could potentially alter the relative strength and kinetics of synaptically-evoked metabotropic currents across the UBC population.
We assessed the functional consequences of these molecular properties by examining MF-evoked responses in a large population of UBCs. Cell-attached recordings of UBCs were performed in acute slices of adult mouse cerebellum in the presence of inhibitory synaptic blockers (see Methods). Brief electrical stimulations (20 × 100 Hz) of a MF input elicited a unique spiking response in each cell. Across cells, there was a tremendous diversity in the duration, amplitude, and sign of MF-evoked responses (Fig. 2e). In the extremes, MF activation either evoked a large transient increase in firing (Fig. 2e, top cell), or transiently prevented firing (Fig. 2e, bottom cell), in line with binary ON and OFF functional classification. However, most UBCs exhibited graded responses that did not readily conform to these two categories. Excitatory responses had highly variable durations in firing that persisted from hundreds of milliseconds to tens of seconds–a difference of two orders of magnitude. This is illustrated by the spiking evoked in four different cells (Fig. 2e, top four cells), for which the half-decay times of the instantaneous firing frequencies were 410 ms, 1.8 s, 6.8 s and 8.8 s respectively (Fig. 2f, top four cells). There was considerable variability in the spontaneous activity of UBCs, but for cells that had fired spontaneously at high frequencies, MF stimulation tended to transiently suppress firing (Fig. 2f, bottom three cells). For many of these cells (Fig. 2e, cells four and five), MF stimulation evoked a biphasic response profile where a pause in firing was followed by a small but long-lasting increase in firing. Importantly, the temporal profiles of spiking responses were cell-specific and did not depend on either the intensity (Extended Data Fig. 1) or the number of stimuli (Extended Data Fig. 2a, b).
The large systematic variations in the amplitudes and durations of excitation are surprising. Previous studies suggested that MF-evoked excitatory stimulation generated diverse responses which were primarily the result of prolonged glutamate elevation and AMPAR activation, but these responses typically lasted for hundreds of milliseconds14,25,28. While others have observed slow mGluR1 responses in some UBCs, these cells were excluded from further characterization28. Yet the scRNAseq data suggest that the functional gradient is potentially related to cell-intrinsic variations in mGluR1 signaling instead of the uniform expression of AMPARs or NMDARs.
To examine the relative contributions of ionotropic and metabotropic glutamate receptors to synaptically-evoked responses, we determined the effects of receptor antagonists on MF-evoked spiking. The co-application of AMPAR and NMDAR antagonists had negligible effects on MF-evoked firing in either fast or slow spiking UBCs (Fig. 3a, b). In contrast, an mGluR1 antagonist strongly attenuated MF-evoked firing in every cell regardless of decay kinetics (Fig. 3c, d). Thus, mGluR1 activation underlies most synaptic excitation of UBCs, and their responses kinetics are diverse, lasting from hundreds of milliseconds to tens of seconds.
DGKβ/γ are thought to terminate DAG signaling, but their involvement in mGluR1-dependent synaptic responses in the nervous system is not clearly understood. The concomitant rise of DGKβ/γ expression in UBCs with higher mGluR1 levels (Fig. 2b), suggests a possible role of DGKβ/γ in regulating the decay kinetics of mGluR1-dependent spiking responses. We tested the effects of DGK inhibitor II on mGluR1-dependent responses with AMPAR antagonist in baseline condition. Bath application of DGK inhibitor II increased the half-decay time of the spiking response in UBCs (Fig. 3e, f, n = 6) without changing peak response amplitude (Fig. 3g). No change in spiking response kinetics was observed in control wash-in experiments (Extended Data Fig. 3). This suggests that the cell-intrinsic differences in DGK expression influences the variable duration of sustained spiking, with higher levels of DGK corresponding to shorter mGluR1-dependent synaptic currents and faster decays of UBC spiking responses.
The time courses of UBC firing could be controlled by the duration of mGluR1-mediated synaptic currents, but active amplification could prolong the influence of otherwise transient synaptic currents32. We tested for a contribution from active amplification in cells for which MF activation evoked long-lasting increases in firing. In current-clamp, transient depolarization of UBCs with current injections elevated firing without evoking persistent activity (Fig. 4a). We also found that for MF-evoked responses in the same cell, suppressing the initial spikes with a hyperpolarizing current did not prevent the subsequent persistent firing (Fig. 4b). Finally, we tested whether transient hyperpolarization triggered subsequent long-lasting increases in firing, but we found that the evoked rebound spiking was much smaller and shorter-lived than MF-evoked spiking (Fig. 4c). These experiments suggest that sustained MF-evoked spiking responses in UBCs do not require active amplification.
These diverse synaptic responses could reflect differences in either cell-intrinsic properties or extrinsic factors such as the presynaptic release properties or feedforward UBC connections. To quantify cell-intrinsic influence, we measured the kinetics of the spiking response to both electrical stimulation and optically uncaged glutamate (see Methods). We found optically uncaged glutamate recapitulated electrically evoked responses remarkably well (Fig. 4d–i), reproducing the entire spectrum of UBC responses. In a cell with a brief MF response, uncaged glutamate mimicked the rapid kinetics of the spiking response (Fig. 4e). Likewise, in a cell where firing persisted for many seconds after the electrical stimulation, uncaged glutamate resulted in similarly prolonged firing (Fig. 4f). Lastly, MF stimulation and uncaged glutamate both transiently suppressed firing (Fig. 4g). The half decay times (Fig. 4h), and the amplitudes of spiking (Fig. 4i) evoked by uncaging and MF stimulation were linearly correlated. Importantly, altering the glutamate release by varying the duration of the light-pulse had minimal effect on the decay kinetics (Extended Data Fig. 2d–f). This suggests that the heterogeneity in the responses of different UBCs primarily reflected differences in cell-intrinsic properties of metabotropic signaling.
To test whether the time courses of the instantaneous firing rate closely reflected the underlying synaptic currents, we recorded MF-evoked responses in each UBC in both cell-attached and whole-cell voltage-clamp configurations. UBCs that were briefly excited had rapidly decaying synaptic currents (Fig. 5a), and as the duration of spiking increased the synaptic currents became slower (Fig. 5b, C). MF stimulation briefly suppressed firing in many UBCs, even in those that had a subsequent increase in firing (Fig. 5d). For such cells, a brief outward current preceded a long-lasting but smaller inward current. In cells without spontaneous activity, the outward current produced a noticeable delay in spike initiation (Fig. 5c). In spontaneously active UBCs, MF stimulation evoked an approximately one-second pause in firing, and in whole-cell recordings, the same MF stimulation evoked an outward synaptic current lasting about a second (Fig. 5e). The half-decay times of the spiking increases and the synaptic currents were correlated (Fig. 5f, R2 = 0.91, slope = 0.88, intercept = −0.22), as were the peaks of the firing rates and magnitudes of the inward currents (Fig. 5g, R2 = 0.69, slope = 0.71, intercept = −0.65). We found that the current typically outlasted spiking by a factor of 2.0 ± 0.6 (n = 17). This was consistent with a supra-linear f-I curve which temporally sharpened the spiking response. Similarly, the amplitudes of the outward current correlated well with the duration of spike suppression (Fig. 5h). These observations suggest that the amplitudes and time courses of synaptic currents are the main determinants of the magnitude and kinetics of firing rate increases.
To examine the contribution of mGluR1 to synaptic currents in the MF-UBC synapse, we carried out whole-cell voltage-clamp recordings. We found that mGluR1 responses were prone to washout. We therefore always identified MF inputs before break-in and used a freshly prepared K-Methanesulfonate based regenerating solution to provide the stability required for pharmacology (Extended Data Fig. 4, see Methods). Sequential wash-ins of an mGluR1 antagonist followed by AMPAR/NMDAR antagonists revealed that most synaptic current was mediated by mGluR1 (Fig. 5k). mGluR1 antagonists eliminated 91 ± 5% (n = 6) of the total synaptic charge while subsequent wash-in of AMPA/NMDA receptor antagonists eliminated only a small, rapid component of the synaptic current (Fig. 5k, Extended Data Fig. 5a). The large cell-to-cell variations in the time course of synaptic currents before drug wash-in were eliminated after blocking mGluR1 (Extended Data Fig. 5b). These observations indicate that MFs evoke increases in UBC spiking primarily by activating mGluR1s, and that diversity in the kinetics of mGluR1 currents is the primary determinant of the diverse spiking time courses.
To understand how mGluR2/3 currents relate to mGluR1 currents in UBCs, we used an antagonist to isolate the mGluR2/3 component. mGluR2/3 currents always activated during the onset of mGluR1 current in biphasic responding UBCs (Fig. 5l, left) and mediated all the outward currents that suppressed spiking (Fig. 5l, middle and left). The amplitude and time course of mGluR2/3-mediated current was variable in different cells (Fig. 5l). The mGluR2/3 component was more rapid than the mGluR1 component and terminated before peak mGluR1 response (Fig. 5i, j). These experiments suggest that the outward mGluR2/3 current makes important contributions to the initial temporal dynamics by suppressing spiking for variable durations in different UBCs.
MF stimulation evoked remarkably complex and diverse responses in UBCs (n = 84). Given that molecularly, UBCs were well-described along a single axis of variation, could there be a simple organizing principle for the functional properties of UBCs at a population level? We used the half-decay time of the firing rate elevation to sort most UBCs, and we used pause duration to sort the remaining UBCs for which firing was primarily suppressed (Fig. 6a, b). For visualization, we normalized the first group of cells by the peak firing rate increases (n = 70), and the second group by baseline firing rate (n = 14). The sorted heatmap plotted on a linear time axis (Fig. 6a) and on a logarithmic time axis (Fig. 6b), along with summary plots (Fig. 6c–h) revealed the continuous nature of the population response and several intriguing distributional properties. For cells that responded with elevated firing, their peak times and half-widths varied continuously over two orders of magnitude (Fig. 6c peak time, Radj2 = 0.96, slope = 0.027, intercept = −1.50, Fig. 6d half-width, Radj2 = 0.99, slope = 0.026, intercept = −0.86). The half-width to peak-time ratio was constant across all cells (Fig. 6e, HW-PT ratio = 4.2 ± 0.2, n = 70) which resulted in constant width of temporal tuning curves across cells on a logarithmic time scale (Fig. 6f, h, Radj2 = −0.015, slope = 0.0, intercept = 14.5). The distributions of the logarithm of half-widths and peak-times were indistinguishable from a uniform distribution (KS-tests, p = 0.793 and 0.9473), which were reflected in the uniform progression of peak times on a logarithmic heatmap (Fig. 6b). Pause durations from all cells, including those in which suppression dominated, followed a linear trend on the logarithmic time scale (Fig. 6g, Radj2 = 0.78, slope = 0.027, intercept = −2.22). Lastly, the maximum firing rate amplitude saturated above 200 Hz and then decreased nearly linearly on the log plot (Fig. 6h, Radj2 = 0.95, see Methods). Small increases in firing were also observed in the predominantly suppressed UBCs and they followed the same trend (Fig. 6h, gray markers). The continuity of pause and amplitude distributions strongly suggests that UBCs comprise a single population with a continuum of functional properties. A remarkable property of UBC responses is the tight tradeoff between amplitude and half-width of decay, potentially reflecting the correlated expressions of mGluR1 and DGK (Fig. 2b). This is readily appreciated by overlaying the un-normalized responses from three representative UBCs (Fig. 6i). Additionally, we found that every UBC response was well-approximated by shifting a single base Log-Gaussian response curve (Fig. 6i, j, black traces). This means that on a log-log plot, UBC responses appeared as quadratic curves with shifted peak amplitudes and peak times, but constant widths (Fig. 6j). The amplitude and duration trade-off gave rise to an approximate conservation of the average spiking response in each UBC. This was reflected in the shifted power-law decay of the population response regardless of the number of stimuli (Fig. 6k, l, Radj2 = 0.99, see Methods). We found that UBCs were able to act as single-neuron signal integrators. While repeated MF stimulations resulted in a succession of bursts in a fast UBC (Fig. 6m), UBCs with slower kinetics summated the input over time (Fig. 6n, o). Responses to sinusoidally modulated MF inputs produced a range of phase delays from cell-to-cell, which could serve an important role in adaptive vestibular behaviors33 (Extended Data Fig. 6). Taken together, the continuum of response properties allows the UBC population to function both as a distributed array of neural integrators with high memory capacity34, and as an efficient basis set for learning at multiple time-scales (Fig. 7c,d).
Discussion
Our main finding is that the population of UBCs provides a continuum of cell-intrinsic temporal transformations over an exceptionally wide range of time scales (Fig. 6), and that these transformations arise from the continuous variations in the amplitudes and time courses of metabotropic signaling, that in turn control the extent and the duration of the suppression and excitation of firing (Figs. 3–5,7b). These features are consistent with the observed graded molecular heterogeneity in metabotropic signaling pathways (Figs. 2, 7a), and it is likely that similar gradients in mGluR1/5 expression have similar consequences in other cell types (Fig. 1).
New insights into excitatory responses in UBCs
Our findings are a significant departure from previous population-level descriptions and mechanistic accounts of temporal processing in UBCs. We have shown that the diverse temporal responses of UBCs reflect cell-intrinsic synaptic differences rather than differences in glutamate release or glutamate uptake. We have also shown that MF excitation of UBCs is mediated primarily by activation of mGluR1, in contrast to previous studies that emphasized the importance of AMPAR signaling and concluded that MF activation of mGluR1 was less prominent14,25,28. There are a number of possible explanations for these differences. First, some studies measured UBC responses in weakly electric fish15 and the auditory system25, where it is possible that AMPAR signaling allows more rapid excitation of UBCs tailored to the temporal demands of those regions. For example, in weakly electric fish excitatory UBC responses persist for about 10 ms to 100 ms, which is a time scale suited to canceling very brief signals associated with the electric organ discharge15. Another contributing factor may be that most previous studies used whole cell recordings to characterize UBC responses11,12,14,25,28, and as we have shown mGluR1 responses can wash out under such conditions. Finally, one study selected cells that had simple classic ON and OFF UBC responses, and elected to not include cells with prolonged responses that did not conform to these categories28.
The systematic variation over two orders of magnitude in the amplitudes and time courses of MF-evoked mGluR1 responses within a single cell type was unprecedented. Previous studies suggested that glutamate diffusion determines the time course of excitatory responses by influencing the magnitude and duration of AMPAR activation11,12,14. Our caged glutamate experiments and the close correspondence between the amplitudes and time courses of MF-evoked and caged-glutamate-evoked excitation indicate that the properties of metabotropic signaling in UBCs are the primary determinants of the time courses of excitatory responses (Fig. 4d–f). We also found that although UBCs have active conductances that can result in rebound firing, MF-evoked increases in firing are dominated by the mGluR1-mediated currents (Fig. 4a–c).
Another notable feature of excitatory responses was that short-lived responses were at higher frequencies, such that MFs evoked a similar total number of spikes in UBCs regardless of the amplitude or duration of the responses. This is a natural consequence of the correlated expression of elements of the mGluR1 pathway. mGluR1 activation engages G proteins which in turn activate PLCβ4, elevating DAG levels that ultimately activate TRPC3. The responses are larger when the expression levels of mGluR1, PLCβ4, and TRPC3 are higher. In addition, the larger responses are associated with cells that have high DGK levels, rapid degradation of DAG and short-lived TRPC3 activation (Fig. 7b). There is continuous variation in the amplitudes and time course of responses in UBCs that conform to the classic ON-UBC category, but mGluR1 responses become particularly small and long lasting in UBCs that also have a prominent mGluR2/3 component.
mGluR2/3-mediated pauses in firing
mGluR2/3 strongly influenced the firing of a surprisingly large fraction of UBCs. MFs simply suppress firing in 17 % (14 out of 84) of UBCs, and these cells would traditionally be categorized as OFF UBCs. Even in this population of cells, the duration of suppression is graded and exhibits continuous variation. Previous studies had observed UBCs with mGluR2/3 and mGluR1 components, but here we see the functional importance of the presence of both types of receptors in the same cells. We see an inhibitory mGluR2/3 component in an additional 50% (42 out of 84) of cells that also have long lasting excitatory responses. The mGluR2/3 inhibition is always faster than the mGluR1 excitation and therefore suppress firing transiently prior to excitation. The mGluR2/3 currents also systematically vary in time course, but interestingly, and in contrast to the mGluR1 excitation, these currents are longer lasting at the extreme in cells lacking mGluR1, and they become faster in cells where mGluR1 is present. Consequently, MF stimulation evoked pauses are briefer in UBCs that have subsequent shorter-lived increases in firing.
General implications for other cell types
It is likely that similar mechanisms are at play for generating continuous gradients in the amplitude and time course of Group I mGluR-dependent signaling in other brain regions, because we found similar correlated gradients of mGluR1/5, PLCβ, and DGKβ/γ in layer 2/3 cortical neurons and in Purkinje cells (Fig. 1a, c). TRPC3 has been shown to contribute to functional heterogeneity in Purkinje cells35. Although we have focused on the excitatory TRPC3 mediated currents in UBCs, mGluR1/5 signaling extends to other aspects of synaptic function, including retrograde signaling by endocannabinoids, and regulation of long-term synaptic plasticity36,37. This raises the intriguing possibility that these processes are regulated in a continuous manner in cell types with correlated gradients of expression of mGluR1/5 signaling38.
Cell-intrinsic neural integrators
Our results suggest that transcriptomic control of metabotropic signaling generates a family of smoothly varying temporal transformations. The correlated change across numerous response properties suggests a remarkable level of coordination between multiple post-synaptic molecular drivers. This cell-intrinsic synaptic mechanism for generating long-lasting responses is not prone to noise accumulation or catastrophic failure, as can occur with network-based mechanisms39,40,41. The transient firing suppression is reminiscent of the stimulus-onset quenching of neural variability observed in many cortical neurons42, and could mediate a ‘soft-reset’ function at stimulus onset, which is particularly useful for controlling noise accumulation in cells with long integration time constants41.
Optimal basis set for temporal learning
Certain features of the basis expansion by UBCs likely have important implications for cerebellar learning. On a logarithmic time axis, UBC responses were well-approximated by shifted Gaussians (Fig. 6b, j, schematized in Fig. 7d). By direct analogy to radial basis functions, the UBC basis set may allow the cerebellum to model arbitrary input-output functions between hundreds of millisecond to tens of seconds43,44. Crucially, the fact that early responding UBCs had narrow temporal tuning curves while late responding UBCs had wide tuning curves (Fig. 6i, j) suggests that the precision of output generated from this basis set should scale inversely with the time delay. This may provide a cellular substrate for Weber’s Law, a linear correlation between mean and variability of response, frequently observed in cerebellar dependent timing tasks45,46. The graded molecular heterogeneity of metabotropic signaling in cortical neuron (Fig. 1a) suggests similar synaptic mechanisms could potentially underly multi-scale temporal representation and Weber’s law behaviors in other brain areas47,48,49. Representation and learning below the hundred-millisecond range is likely supported conjunctively by several synaptic mechanisms50. Lastly, the UBC basis set provides a dense temporal representation as individual responses overlap significantly in time. This is in contrast to sparse temporal representations such as the sequential burst of HVC neurons in bird songs51. Unlike in the imitation learning of songs, the cerebellum undergoes life-long adaptations. Therefore, the utilization of dense versus sparse temporal representations may reflect the underlying tasks, and the degree of generalization versus memorization required by the behavioral task. By demonstrating that a molecularly diverse type of neuron generates a multi-scaled basis expansion that is robust and flexible, our results highlight the functional relevance of molecular heterogeneity in central circuits.
Methods
Ethics
All animal procedures were carried out in accordance with the NIH and Animal Care and Use Committee (IACUC) guidelines and protocols approved by the Harvard Medical Area Standing Committee on Animals (animal protocol #1493). Animals are housed on a normal light-dark cycle with an ambient temperature of 18–23 °C with 40–60% humidity.
scRNA-seq
scRNA-seq data for UBC and Purkinje cells was obtained in Kozareva et al.6. In brief, high-throughput single-nucleus RNA-seq (snRNA-seq) was used to analyze 780,553 nuclei isolated from 16 different lobules from 6 p60 mice. Of these, 1613 were categorized as UBCs and 16634 as Purkinje cells. Although UBCs were found in all lobules, their density was regionally dependent, and as is well-established the density was particularly high in regions involved in vestibular processing such as lobules IX and X. scRNA-seq data for L2/3 cortical neurons was obtained from Yao et al.52. Latent factors were discovered using non-negative matrix factorization (NNMF) independently on the log count of transcripts. Factor 1 of UBC was closely related to one of the top 3 factors found in PC and L2/3 cortical neurons.
Slice preparation
Cerebellar slices were prepared from adult (P30-40) C57BL/6 mice of either sex. Animals were anesthetized by a peritoneal injection of 100/10 mg/kg ketamine/xylazine mixture and then intracardially perfused with ice-cold cutting solution (in mM): 110 Choline Cl, 2.5 KCl, 1.2 NaH2PO4, 25 NaHCO3, 25 glucose, 0.5 CaCl2, 7 MgSO4 2, 2.4 Na-pyruvate, 11.6 Na-ascorbate and 25 glucose equilibrated with 95% O2 and 5% CO2. Cerebellum was subsequently extracted, submerged in the cutting solution and 250 µm sagittal slices from the vermis were obtained using a Leica VT1200S vibratome (Leica Biosystems Inc. Buffalo Grove, IL). Slices were transferred into an incubation chamber with artificial cerebral spinal fluid (ACSF) containing (in mM): 125 NaCl, 26 NaHCO3, 1.25 NaH2PO4, 2.5 KCl, 1 MgCl2, 1.5 CaCl2 and 25 glucose and equilibrated with 95% O2 and 5% CO2 (pH 7.4, osmolarity 315). Following 30 min of incubation at 32 °C, the slices are kept for up to 5 h at room temperature.
Electrophysiology
Recordings were performed under physiological temperature (34–36 °C) in ACSF containing inhibitory receptor blockers 20 µM picrotoxin and 1 µM CGP. Optically guided cell-attached or whole-cell recordings were made in lobule X under an Olympus BX51WI microscope equipped with differential interference contrast (DIC) components. Patch-pipette of (2–3 MΩ for cell-attached recording, 4~5 MΩ for whole-cell recording) were pulled from borosilicate capillary glass (World Precision Instruments) with a Stutter P-97 horizontal puller. Mossy fiber (MF) stimulations were delivered via a bipolar theta glass pipette filled with bath solution positioned at least 50 µm away to avoid stimulating the recorded neuron. Care was taken during the search of the sole MF input to elicit reliable response and avoid antidromic spikes. Cell-attached recordings were made using ACSF with a loose patch of 100 MΩ. It is important to avoid using high-potassium internal solution for cell-attached recording as we have noticed significant depolarization block in persistently firing cells. In the case where both cell-attached and whole-cell recordings were done on the same cell, extracellular electrodes were swapped out with a second electrode with an internal solution containing (in mM): 122 K-methanesulfonate, 9 NaCl, 9 HEPES, 0.036 CaCl2, 1.62 MgCl2, and 0.18 EGTA. A separately aliquoted regenerating solution containing: 4 Mg-ATP, 0.3 Tris-GTP, 14 Tris-creatine phosphate was kept in a −20 °C freezer and added to the internal alone with 10 µM Alexa 589 dye on the day of recording (pH 7.4 and osmolarity 315). A −8mV liquid junction potential was corrected between the internal and external solutions. Series compensation was not made for voltage-clamp recording. Data were collected with Multiclamp 700B amplifier (Molecular Devices, LLC., San Jose, CA), filtered at 4 kHz (4-pole Bessel filter) online, digitized at 50 kHz with ITC18 (Heka Instrument, Inc., Holliston, MA), and saved using custom software (courtesy of Matthew Xu-Friedman, SUNY Buffalo, Buffalo, NY) in Igor Pro (WaveMetrics Inc., Portland, OR) for offline analysis.
Pharmacology
Sequential drug wash-ins were performed using a computer-controlled solenoid manifold system (ValveLink 8.2, Automate Scientific, Inc., Berkeley, CA) with a flow rate of 1 to 2 mL/min, where indicated, with mGluR1 antagonist (100 µM LY357385, Tocris Bio-Techne, Minneapolis, MN), AMPA receptor blocker (5 µM NBQX), NMDA receptor blocker (2 µM R-CPP), mGluR2/3 antagonist (1 µM LY341495, Tocris Bio-Techne, Minneapolis, MN) and DGK inhibitor II (100 µM R59949, MilliporeSigma, St. Louis, MO)
One-photon glutamate uncaging
Slices were incubated in 200 µM RuBi-Glutamate ACSF solution in the presence of inhibitory blockers 20 µM picrotoxin and 1 µM CGP at physiological temperature (34-36 °C). The osmolarity of the solution was monitored and adjusted with deionized water. After measuring the response to MF stimulation, optical uncaging of glutamate was done by 20 × 100Hz pulse train with 2 ms to 4 ms pulse width illumination over a 20 µm diameter spot above the dendritic brush. The light stimuli were delivered by a blue laser (MBL-III-473-50mW, Optoengine, Midvale, UT) through a 60x objective at >160 mW/mm2.
Data analysis
Pharmacology experiments were reported as time series plots showing mean±sem of spiking or current response during drug wash-in. Spiking response properties such as pause time and baseline firing were analyzed on average instantaneous firing rates over three to five trials. Measurements of half-decay time, amplitude, and width are extracted from a smooth response based on log-Gaussian fitted to the instantaneous firing rate using the nonlinear curve fitting toolbox in MATLAB 2017a. The parameterization used for log-Gaussian fit is \(A{e}^{-{(\frac{\mathrm{ln}}t-{\rm{\mu }}{\sigma })}^{2}}\), where \(A\) is amplitude, \(\mu\) is the log peak location and \(\sigma\) is the width of temporal response on a logarithmic time scale. All linear and non-linear regressions are performed in MATLAB and reported with adjusted \({R}^{2}\) values, calculated as \({R}_{adj}^{2}=1-\frac{(1-{R}^{2})(n-1)}{n-p-1}\), where \(n\) is the sample size, p is the number of model parameters, and \({R}^{2}\) is calculated as 1 minus the ratio of residual sum of squares over the total sum of squares, to assess the quality of the fits. An inverted soft-plus function of the form \(a-\,{\mathrm{ln}}(1+{e}^{\frac{x}{b}})\)was used to fit the log-transformed amplitude values vs. cell ID in Fig. 6h. Kolmogorov-Smirnov test was used for testing whether the distribution of peak time followed a uniform distribution on a logarithmic timescale.
The population response amplitude was defined as the L2-norm of the population activity vector, which each dimension being the instantaneous firing rate of one UBC over time. For ease of interpretation and to control for the expected \(\sqrt{N}\) increase in population amplitude as a function of N, the number of measured neurons, the population amplitude was normalized by \(\frac{1}{\sqrt{N}}\) in Fig. 6. Population response were fitted with a shifted power law of the form \(Cn{(t+{t}_{min}{n}^{\beta })}^{\propto }\), where \(n\) is the number of stimuli, \(C\) is a scaling constant for amplitude, \({t}_{min}\) and \(\beta\) control when and how fast power-law behavior dominates for different numbers of stimuli and \(\propto\) is the critical exponent.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
The UBC physiology data are openly available at http://github.com/chongguo/UBC_NatComm2021. Molecular data for cerebellar PC and UBCs can be visualized through (https://singlecell.broadinstitute.org/single_cell/study/SCP795/). Raw and processed data that support the findings of this study have been deposited in GEO under accession number GSE165371 and in at the Neuroscience Multi-omics (NeMO) Archive (https://nemoarchive.org/). Molecular data for the L2/3 cortical neuron are part of BICCN MOp data (RRID:SCR_015820) which can be accessed via the NeMO archive (RRID:SCR_002001) at accession: https://assets.nemoarchive.org/dat-ch1nqb7. Visualization and analysis resources: NeMO analytics: https://nemoanalytics.org/, Genome browser: https://brainome.ucsd.edu/annoj/BICCN_MOp/, Epiviz browser: https://epiviz.nemoanalytics.org/biccn_mop.
Code availability
The custom code used in the analysis will be available from Chong Guo’s GitHub repository upon publication: https://github.com/chongguo/UBC_NatComm2021.
References
Tasic, B. et al. Adult mouse cortical cell taxonomy revealed by single cell transcriptomics. Nat. Neurosci. 19, 335–346 (2016).
Gokce, O. et al. Cellular taxonomy of the mouse striatum as revealed by single-cell RNA-seq. Cell Rep. 16, 1126–1137 (2016).
Harris, K. D. et al. Classes and continua of hippocampal CA1 inhibitory neurons revealed by single-cell transcriptomics. PLoS Biol. 16, e2006387 (2018).
Stanley, G., Gokce, O., Malenka, R. C., Südhof, T. C. & Quake, S. R. Continuous and discrete neuron types of the adult murine striatum. Neuron 105, 688–699 (2020).
Cembrowski, M. S. et al. Spatial gene-expression gradients underlie prominent heterogeneity of CA1 pyramidal neurons. Neuron 89, 351–368 (2016).
Kozareva, V. et al. A transcriptomic atlas of the mouse cerebellum reveals regional specializations and novel cell types. Preprint at https://www.biorxiv.org/content/10.1101/2020.03.04.976407v1 (2020).
Muñoz-Manchado, A. B. et al. Diversity of interneurons in the dorsal striatum revealed by single-cell RNA sequencing and PatchSeq. Cell reports 24, 2179–2190 (2018).
Dino, M. R., Schuerger, R. J., Liu, Y., Slater, N. T. & Mugnaini, E. Unipolar brush cell: a potential feedforward excitatory interneuron of the cerebellum. Neuroscience 98, 625–636 (2000).
Mugnaini, E., Sekerková, G. & Martina, M. The unipolar brush cell: a remarkable neuron finally receiving deserved attention. Brain Res. Rev. 66, 220–245 (2011).
Kreko-Pierce, T. et al. Cerebellar ataxia caused by type ii unipolar brush cell dysfunction in the Asic5 knockout mouse. Sci. Rep. 10, 1–14 (2020).
Rossi, D. J., Alford, S., Mugnaini, E. & Slater, N. T. Properties of transmission at a giant glutamatergic synapse in cerebellum: the mossy fiber-unipolar brush cell synapse. J. Neurophysiol. 74, 24–42 (1995).
Kinney, G. A., Overstreet, L. S. & Slater, N. T. Prolonged physiological entrapment of glutamate in the synaptic cleft of cerebellar unipolar brush cells. J. Neurophysiol. 78, 1320–1333 (1997).
Locatelli, F., Botta, L., Prestori, F., Masetto, S. & D’Angelo, E. Late‐onset bursts evoked by mossy fibre bundle stimulation in unipolar brush cells: evidence for the involvement of H‐and TRP‐currents. J. Physiol. 591, 899–918 (2013).
van Dorp, S. & De Zeeuw, C. I. Variable timing of synaptic transmission in cerebellar unipolar brush cells. Proc. Natl Acad. Sci. 111, 5403–5408 (2014).
Kennedy, A. et al. A temporal basis for predicting the sensory consequences of motor commands in an electric fish. Nat. Neurosci. 17, 416–422 (2014).
Evarts, E. & Thach, W. Motor mechanisms of the CNS: cerebrocerebellar interrelations. Annu. Rev. Physiol. 31, 451–498 (1969).
Buckner, R. L. The cerebellum and cognitive function: 25 years of insight from anatomy and neuroimaging. Neuron 80, 807–815 (2013).
Schmahmann, J. D. Disorders of the cerebellum: ataxia, dysmetria of thought, and the cerebellar cognitive affective syndrome. J. Neuropsychiatry Clin. Neurosci. 16, 367–378 (2004).
Stoodley, C. J. & Schmahmann, J. D. Evidence for topographic organization in the cerebellum of motor control versus cognitive and affective processing. Cortex 46, 831–844 (2010).
Strick, P. L., Dum, R. P. & Fiez, J. A. Cerebellum and nonmotor function. Annu. Rev. Neurosci. 32, 413–434 (2009).
Mauk, M. D. & Buonomano, D. V. The neural basis of temporal processing. Annu. Rev. Neurosci. 27, 307–340 (2004).
Fujita, M. Adaptive filter model of the cerebellum. Biol. Cybern. 45, 195–206 (1982).
Dean, P., Porrill, J., Ekerot, C.-F. & Jörntell, H. The cerebellar microcircuit as an adaptive filter: experimental and computational evidence. Nat. Rev. Neurosci. 11, 30–43 (2010).
Medina, J. F. & Mauk, M. D. Computer simulation of cerebellar information processing. Nat. Neurosci. 3, 1205–1211 (2000).
Borges-Merjane, C. & Trussell, L. O. ON and OFF unipolar brush cells transform multisensory inputs to the auditory system. Neuron 85, 1029–1042 (2015).
Russo, M. J., Yau, H.-J., Nunzi, M.-G., Mugnaini, E. & Martina, M. Dynamic metabotropic control of intrinsic firing in cerebellar unipolar brush cells. J. Neurophysiol. 100, 3351–3360 (2008).
Knoflach, F. & Kemp, J. A. Metabotropic glutamate group II receptors activate a G protein‐coupled inwardly rectifying K+ current in neurones of the rat cerebellum. J. Physiol. 509, 347–354 (1998).
Zampini, V. et al. Mechanisms and functional roles of glutamatergic synapse diversity in a cerebellar circuit. Elife 5, e15872 (2016).
Nunzi, M. G., Shigemoto, R. & Mugnaini, E. Differential expression of calretinin and metabotropic glutamate receptor mGluR1α defines subsets of unipolar brush cells in mouse cerebellum. J. Comp. Neurol. 451, 189–199 (2002).
Singec, I., Knoth, R., Ditter, M., Frotscher, M. & Volk, B. Neurogranin expression by cerebellar neurons in rodents and non‐human primates. J. Comp. Neurol. 459, 278–289 (2003).
Chung, S. H., Marzban, H., Watanabe, M. & Hawkes, R. Phospholipase Cbeta4 expression identifies a novel subset of unipolar brush cells in the adult mouse. Cerebellum. 8, 267–276 (2009).
Egorov, A. V., Hamam, B. N., Fransen, E., Hasselmo, M. E. & Alonso, A. A. Graded persistent activity in entorhinal cortex neurons. Nature 420, 173–178 (2002).
Laurens, J. & Angelaki, D. E. Simple spike dynamics of Purkinje cells in the macaque vestibulo-cerebellum during passive whole-body self-motion. Proc. Natl Acad. Sci. USA 117, 3232–3238 (2020).
Fusi, S., Drew, P. J. & Abbott, L. F. Cascade models of synaptically stored memories. Neuron 45, 599–611 (2005).
Wu, B. et al. TRPC3 is a major contributor to functional heterogeneity of cerebellar Purkinje cells. Elife 8, e45590 (2019).
Chevaleyre, V., Takahashi, K. A. & Castillo, P. E. Endocannabinoid-mediated synaptic plasticity in the CNS. Annu. Rev. Neurosci. 29, 37–76 (2006).
Lüscher, C. & Huber, K. M. Group 1 mGluR-dependent synaptic long-term depression: mechanisms and implications for circuitry and disease. Neuron 65, 445–459 (2010).
Suvrathan, A., Payne, H. L. & Raymond, J. L. Timing rules for synaptic plasticity matched to behavioral function. Neuron 92, 959–967 (2016).
Buldyrev, S. V., Parshani, R., Paul, G., Stanley, H. E. & Havlin, S. Catastrophic cascade of failures in interdependent networks. Nature 464, 1025–1028 (2010).
Ganguli, S., Huh, D. & Sompolinsky, H. Memory traces in dynamical systems. Proc. Natl Acad. Sci. USA 105, 18970–18975 (2008).
Lim, S. & Goldman, M. S. Noise tolerance of attractor and feedforward memory models. Neural Comput 24, 332–390 (2012).
Churchland, M. M. et al. Stimulus onset quenches neural variability: a widespread cortical phenomenon. Nat. Neurosci. 13, 369 (2010).
Park, J. & Sandberg, I. W. Universal approximation using radial-basis-function networks. Neural Comput. 3, 246–257 (1991).
Leshno, M., Lin, V. Y., Pinkus, A. & Schocken, S. Multilayer feedforward networks with a nonpolynomial activation function can approximate any function. Neural Netw. 6, 861–867 (1993).
Heiney, S. A., Wohl, M. P., Chettih, S. N., Ruffolo, L. I. & Medina, J. F. Cerebellar-dependent expression of motor learning during eyeblink conditioning in head-fixed mice. J. Neurosci. 34, 14845–14853 (2014).
White, N. E., Kehoe, E. J., Choi, J.-S. & Moore, J. W. Coefficients of variation in timing of the classically conditioned eyeblink in rabbits. Psychobiology 28, 520–524 (2000).
Bright, I. M. et al. A temporal record of the past with a spectrum of time constants in the monkey entorhinal cortex. Proc. Natl Acad. Sci. USA 117, 20274–20283 (2020).
Kraus, B. J., Robinson, R. J. II, White, J. A., Eichenbaum, H. & Hasselmo, M. E. Hippocampal “time cells”: time versus path integration. Neuron 78, 1090–1101 (2013).
Liu, Y., Tiganj, Z., Hasselmo, M. E. & Howard, M. W. A neural microcircuit model for a scalable scale‐invariant representation of time. Hippocampus 29, 260–274 (2019).
Chabrol, F. P., Arenz, A., Wiechert, M. T., Margrie, T. W. & DiGregorio, D. A. Synaptic diversity enables temporal coding of coincident multisensory inputs in single neurons. Nat. Neurosci. 18, 718–727 (2015).
Hahnloser, R. H., Kozhevnikov, A. A. & Fee, M. S. An ultra-sparse code underliesthe generation of neural sequences in a songbird. Nature 419, 65–70 (2002).
Yao, Z. et al. An integrated transcriptomic and epigenomic atlas of mouse primary motor cortex cell types. Preprint at https://www.biorxiv.org/content/10.1101/2020.02.29.970558v2 (2020).
Acknowledgements
This work was supported by a NIH grant R35NS097284 to W.R.
Author information
Authors and Affiliations
Contributions
C.G. and W. R. conceived the experiments. E.M. and C.G. analyzed the data in Fig. 1. C.G. and V.H. both did experiments for Fig. 3e-g and Supplementary Fig. 3. C.G. performed all other experiments, conducted all other analyses and made the figures. C.G. and W.G.R. wrote the original draft of the manuscript and all authors helped revise the manuscript. We thank the members of the Regehr lab for feedback on the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Peer review information Nature communications thanks the anonymous reviewers for their contribution to the peer review of this work.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Guo, C., Huson, V., Macosko, E.Z. et al. Graded heterogeneity of metabotropic signaling underlies a continuum of cell-intrinsic temporal responses in unipolar brush cells. Nat Commun 12, 5491 (2021). https://doi.org/10.1038/s41467-021-22893-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-021-22893-8
- Springer Nature Limited
This article is cited by
-
A time-causal and time-recursive scale-covariant scale-space representation of temporal signals and past time
Biological Cybernetics (2023)
-
Synaptic basis of a sub-second representation of time in a neural circuit model
Nature Communications (2022)