Sensory processing and corollary discharge effects in posterior caudal lobe Purkinje cells in a weakly electric mormyrid fish Karina Alviña and Nathaniel B. Sawtell

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J Neurophysiol 112: 328 –339, 2014. First published April 30, 2014; doi:10.1152/jn.00016.2014.

Sensory processing and corollary discharge effects in posterior caudal lobe Purkinje cells in a weakly electric mormyrid fish Karina Alviña and Nathaniel B. Sawtell Department of Neuroscience, Columbia University, New York, New York Submitted 6 January 2014; accepted in final form 25 April 2014

cerebellum; corollary discharge; synaptic plasticity; electric fish THE BRAINS OF MOST VERTEBRATES contain both a cerebellum and sensory processing structures similar to the cerebellum in terms of their evolution, development, patterns of gene expression, and circuitry (Bell 2002; Bell et al. 2008). Studies of cerebellum-like structures involved in processing electrosensory information in fish suggest functional similarities as well. These structures, which include the dorsal octavolateral nucleus of elasmobranch fish and the electrosensory lobe (ELL) of weakly electric mormyrid and gymnotid fish, appear to act as adaptive sensory processors in which diverse sensory and motor signals conveyed by a granule cell-parallel fiber system cancel out predictable patterns of sensory input via mechanisms of associative synaptic plasticity (Bell 2001; Bodznick et al. 1999; Bol et al. 2011). This mode of operation resembles Marr-Albus and adaptive filter models of the cerebellum (Albus 1971; Dean et al. 2010; Fujita 1982; Marr 1969). Moreover, studies of the mormyrid ELL have provided a detailed mechanistic account of how motor corollary discharge signals related to the fish’s electric organ discharge (EOD) are used to predict and cancel the electrosensory consequences of the EOD (Bell 1981; Bell et al. 1997b; Kennedy et al. 2014; Roberts and Bell 2000). Intriguingly, this role for ELL circuitry closely resembles

Address for reprint requests and other correspondence: N. B. Sawtell, Columbia Univ., Dept. of Neuroscience, HHSC RM 501, 701 W 168th St., New York, NY 10032 (e-mail: [email protected]). 328

predictive or forward model functions hypothesized for the mammalian cerebellum (Ebner and Pasalar 2008; Izawa et al. 2012; Miall et al. 1993; Wolpert et al. 1998). However, in addition to these similarities, there are also important differences between cerebellum-like structures and the cerebellum, most notably the presence of climbing fiber (CF) input from the inferior olive exclusively to the latter. Given that many aspects of mammalian cerebellar function remain unresolved, examining the similarities and differences between the cerebellum and cerebellum-like structures may provide a useful perspective on cerebellar function in general. The nervous system of mormyrid fish offers a remarkable opportunity for such a comparison. Anatomical studies have shown that the posterior caudal lobe (LCp) of the mormyrid cerebellum receives the same sources of mossy fiber input and projects to the same target structures as ELL (Bell et al. 1981; Campbell et al. 2007), i.e., there is a region of the mormyrid cerebellum proper that is closely associated and arranged in parallel with ELL. Granule cells that send parallel fibers to the molecular layer of ELL are located in the same external granule cell mass, known as the eminentia granularis posterior (EGp), as the granule cells that send parallel fibers to LCp (Fig. 1A). Given that mossy fibers terminate widely within EGp, it is likely that ELL and LCp receive similar patterns of mossy fiber input (Bell et al. 1981; Campbell et al. 2007). These include corollary discharge input associated with the EOD motor command, electrosensory information, and proprioceptive signals (Bell et al. 1992; Sawtell 2010). LCp and ELL also have similar projection patterns. Glutamatergic efferent cells of ELL project to higher stages of electrosensory processing in the midbrain—the preeminential nucleus and the lateral toral nucleus. Glutamatergic efferent cells of LCp, equivalent to the deep cerebellar nuclear cells of higher vertebrates, project to these same structures (Bell et al. 1981; Campbell et al. 2007). LCp, but not ELL, also projects to two small nuclei, the rostral and caudal paraventricular nuclei, about which little is known. Additional similarities between LCp and ELL include several classes of interneurons found in both structures. These are the Golgi cells and unipolar brush cells located in EGp and the inhibitory molecular layer interneurons located in both LCp and ELL molecular layers (Campbell et al. 2007; Kennedy et al. 2014). It has been suggested that the presence of a distinct CF input from the inferior olive is the key feature that distinguishes the cerebellum proper from cerebellum-like structures (Bell 2002; Bell et al. 2008). This is the case for LCp versus ELL. While LCp Purkinje cells integrate parallel fiber input from EGp with CF input from the inferior olive, ELL principal cells integrate parallel fiber input from EGp with somatotopically organized

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Alviña K, Sawtell NB. Sensory processing and corollary discharge effects in posterior caudal lobe Purkinje cells in a weakly electric mormyrid fish. J Neurophysiol 112: 328 –339, 2014. First published April 30, 2014; doi:10.1152/jn.00016.2014.—Although it has been suggested that the cerebellum functions to predict the sensory consequences of motor commands, how such predictions are implemented in cerebellar circuitry remains largely unknown. A detailed and relatively complete account of predictive mechanisms has emerged from studies of cerebellum-like sensory structures in fish, suggesting that comparisons of the cerebellum and cerebellum-like structures may be useful. Here we characterize electrophysiological response properties of Purkinje cells in a region of the cerebellum proper of weakly electric mormyrid fish, the posterior caudal lobe (LCp), which receives the same mossy fiber inputs and projects to the same target structures as the electrosensory lobe (ELL), a well-studied cerebellum-like structure. We describe patterns of simple spike and climbing fiber activation in LCp Purkinje cells in response to motor corollary discharge, electrosensory, and proprioceptive inputs and provide evidence for two functionally distinct Purkinje cell subtypes within LCp. Protocols that induce rapid associative plasticity in ELL fail to induce plasticity in LCp, suggesting differences in the adaptive functions of the two structures. Similarities and differences between LCp and ELL are discussed in light of these results.

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tipolar and exhibit more irregular dendritic branching patterns (Fig. 1C) (Campbell et al. 2007; Zhang and Han 2007). In contrast to the great deal of information available about in vivo response properties and plasticity in ELL and EGp, knowledge of LCp is based on a single previous in vivo study that reported briefly on electrosensory and corollary discharge responses in Purkinje cells (Bell et al. 1992). The present study provides the first detailed description of in vivo response properties of LCp Purkinje cells with attention to both simple spike and CF responses. Our findings include prominent and temporally diverse corollary discharge responses in Purkinje cells, evidence for two functionally distinct subregions within LCp, and apparent differences in the conditions required to induce associative plasticity in LCp versus ELL.

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input from peripheral electroreceptors. Given the distinctive properties of CFs and the critical role they play in most theoretical accounts of cerebellar function, this difference may be extremely important. In vitro studies have revealed several additional differences between Purkinje cells in LCp and Purkinje-like medium ganglion (MG) cells in ELL. These include a prominent NMDA receptor-mediated component of parallel fiber synaptic transmission in MG cells but not Purkinje cells and dendritic spikes that appear to be primarily sodium mediated in MG cells and calcium mediated in Purkinje cells (Grant et al. 1998; Zhang et al. 2010; Zhang and Han 2007). To date, knowledge of LCp comes mainly from in vitro electrophysiological and anatomical studies. In vitro studies have shown that basic intrinsic and synaptic properties of LCp Purkinje cells are similar in many respects to those of mammalian Purkinje cells (Zhang and Han 2007). Anatomical studies have provided evidence for distinct Purkinje cell subtypes within LCp (Campbell et al. 2007; Zhang and Han 2007). Unlike most cerebella, LCp lacks a Purkinje cell layer; rather, Purkinje cell bodies are scattered throughout the molecular region. Purkinje cells located in the most dorsal part of the molecular layer have fan-shaped dendrites that extend toward the dorsal surface of LCp (Fig. 1B), while those located in the medial and ventral portions of the molecular region are mul-

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Fig. 1. Inputs, outputs, and circuitry of posterior caudal lobe (LCp) vs. electrosensory lobe (ELL). A: a Nissl-stained transverse section showing LCp and ELL. Mossy fibers convey a variety of sensory and motor signals to eminentia granularis posterior (EGp). EGp granule cells (GCs, filled circles) in turn send parallel fibers to LCp and ELL molecular layers. Dorsal (dPC) and multipolar (mPC) Purkinje cells (gray) also receive a climbing fiber input from the inferior olive, while Purkinje-like medium ganglion (MG) cells of ELL (gray) receive input from peripheral electroreceptors. Glutamatergic efferent neurons of ELL (orange) and LCp (cyan) project in parallel to higher stages of electrosensory processing. Whether or not dorsal and multipolar Purkinje cells converge onto the same efferent cells, as depicted, is not known. rpv and cpv, rostral and caudal paraventricular nuclei. B: sagittal section showing a fanshaped Purkinje cell located in the dorsal region of LCp filled with biocytin during intracellular recording. C: sagittal section showing a multipolar Purkinje cell located in the medial region of LCp filled with biocytin during intracellular recording.

Experimental preparation. All experiments performed in this study were approved by the Columbia University Institutional Animal Care and Use Committee and adhere to the American Physiological Society’s “Guiding Principles in the Care and Use of Vertebrate Animals in Research and Training.” Mormyrid fish (7–12 cm in length) of the species Gnathonemus petersii were used in these experiments. Surgical procedures to expose EGp for recording were identical to those described previously (Sawtell 2010). Briefly, fish were anesthetized (MS-222, 1:25,000) and held against a foam pad. Skin on the dorsal surface of the head was removed, and a long-lasting local anesthetic (0.75% bupivacaine) was applied to the wound margins. A plastic rod was cemented to the anterior portion of the skull to hold the head rigid. The posterior portion of the skull was removed, and the underlying valvula cerebelli was reflected laterally to expose EGp and the molecular layer of LCp. At the end of the surgery, a paralytic, gallamine triethiodide (Flaxedil), was given (⬃20 ␮g/cm of body length), the anesthetic was removed, and aerated tank water was passed over the fish’s gills for respiration. Paralysis blocks the effect of electromotoneurons on the electric organ, preventing the EOD, but the motor command signal that would normally elicit an EOD continues to be emitted by the electromotoneurons at a variable rate of 2–5 Hz. The timing of the EOD motor command can be measured precisely (see below), and the central effects of electric organ corollary discharge (EOCD) inputs can be observed in isolation from the electrosensory input that would normally result from the EOD. Methods for electrosensory stimulation and for generating controlled movements of the tail were the same as those described previously (Bell 1982; Bell and Grant 1992; Sawtell 2010). Electrophysiology. The EOD motor command signal was recorded with an electrode placed over the electric organ in the tail. The command signal is the synchronized volley of electromotoneurons that would normally elicit an EOD in the absence of neuromuscular blockade. The command signal lasts ⬃3 ms and consists of a small negative wave followed by three larger biphasic waves. The latencies of central corollary discharge or command-evoked responses were measured with respect to the negative peak of the first large biphasic wave in the command signal. EGp and the LCp molecular layer can be directly visualized after reflecting the overlying cerebellar valvula. Extracellular recordings from LCp Purkinje cells were made with glass microelectrodes filled with 2 M NaCl. Methods for in vivo whole cell current-clamp recordings were the same as those described previously (Sawtell 2010). Briefly, electrodes (9 –15 M⍀) were filled with an internal solution containing (in mM) 122 K-gluconate, 7 KCl, 10 HEPES, 0.4 Na2GTP, 4 MgATP, and 0.5 EGTA, with 0.5% biocytin (pH 7.2, 280 –290 mosM). No correction was made for liquid junction potentials. Only cells with stable membrane potentials more hyperpolarized than ⫺45 mV and access resistance ⬍100 M⍀ were analyzed. Membrane potentials were filtered at 3–10 kHz and digi-

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tized at 20 kHz (CED power1401 hardware and Spike2 software; Cambridge Electronics Design, Cambridge, UK). Histology. After recording, fish were deeply anesthetized with a concentrated solution of MS-222 (1:10,000) and transcardially perfused with a teleost Ringer solution followed by a fixative consisting of 2% paraformaldehyde and 2% glutaraldehyde or 4% paraformaldehyde in 0.1 M phosphate buffer. The brains were postfixed, cryoprotected with 20% sucrose, and sectioned at 50 ␮m on a cryostat. Sections were reacted with avidin-biotin complex and diaminobenzidine or a streptavidin-conjugated fluorescent dye to reveal the biocytin-filled cells. Data analysis and statistics. Data were analyzed off-line with Spike2 and MATLAB (MathWorks, Natick, MA). Data are expressed as means ⫾ SD, unless otherwise noted. Paired and unpaired Student’s t-tests were used to test for statistical significance, as noted. Differences were judged to be significant at P ⬍ 0.05. Only recordings from Purkinje cells, as judged by the presence of two distinct spike waveforms one much more frequent than the other, were included in the analysis. Unless stated otherwise, analysis of EOCD responses used only data from EOD commands separated by 200 ms or greater. Simple spike modulations in response to the EOD command were calculated as the difference between maximum evoked firing rate and the minimum evoked firing rate divided by the mean rate.

Basic electrophysiological properties of LCp Purkinje cells. LCp Purkinje cell recordings were characterized by the presence of two distinct all-or-none events that differed both in their waveforms (Fig. 2, A and C) and frequency of occurrence [simple spikes: 25.9 ⫾ 12.8 Hz (n ⫽ 100 extracellular record-

A Fig. 2. Electrophysiological properties of LCp Purkinje cells. A: extracellular trace from a Purkinje cell illustrating simple spike (SS) and climbing fiber (CF, arrow) response. Histogram shows a pause in simple spike firing following a CF response. B: overlaid intracellular traces showing CF responses evoked by microstimulation (left) and those occurring spontaneously (right) in the same Purkinje cell. C: intracellular traces from 3 different Purkinje cells showing the varied appearance of simple and CF responses. Top: a putative somatic recording. Middle and bottom: putative dendritic recordings. Scatterplot in inset shows amplitudes of simple and CF responses for a population of intracellularly recorded Purkinje cells (n ⫽ 61). D: in addition to spontaneous simple and CF responses (filled arrow), some Purkinje cells exhibited a third broad all-or-none event (open arrow), presumably a dendritic spike, that could be evoked by strong depolarizing current injection. E: overlaid intracellular traces and smoothed simple spike firing rates (25-ms Gaussian kernel; dotted lines are SE) triggered on the occurrence of a putative dendritic spike (top, open arrow) or a CF response (bottom, filled arrow) in the same Purkinje cell. Putative dendritic spikes were invariably preceded by a gradual depolarization and acceleration of simple spike firing and followed by a pause in firing (top, upper trace). This distinctive pattern was not associated with CF responses (bottom, upper trace).

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RESULTS

ings) and 18.9 ⫾ 13.2 (n ⫽ 55 whole cell recordings); CF responses: 0.47 ⫾ 0.34 (n ⫽ 55 whole cell recordings)]. The occurrence of a CF response was typically accompanied by a pause in simple spike firing (Fig. 2, A and E, bottom). The appearance of CF responses in our in vivo recordings is somewhat different from those observed in mammalian Purkinje cells but similar to those reported previously for mormyrid Purkinje cells in vitro (de Ruiter et al. 2006; Han and Bell 2003; Zhang and Han 2007). These studies have shown that CF activation evokes all-or-none excitatory postsynaptic potentials (EPSPs) in mormyrid Purkinje cells without obvious spikelike components (de Ruiter et al. 2006). All-or-none responses similar or identical to spontaneous CF responses could be evoked by microstimulation near the brain surface just anterior to LCp where the tract in which the axons of inferior olive neurons travel (Campbell et al. 2007), but not of surrounding regions (Fig. 2B). This observation is consistent with CF responses indeed being due to CF activation. Simple spike, but not CF response, amplitude varied widely in our whole cell recordings, without any obvious relation to recording quality (Fig. 2C). Most likely, this variation in simple spike amplitude is due to differences in recording location (somatic vs. dendritic) and to the failure of simple spikes to propagate into LCp Purkinje cell dendrites, as shown previously for Purkinje cells in other species (e.g., Llinas and Sugimori 1980a). In addition to simple spikes and CF responses, we also observed a third distinct type of spike that could be evoked by strong membrane potential depolarization. These spikes were much broader than simple spikes, and unlike CF responses they

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were always preceded by a strong membrane potential depolarization and high rates of simple spike firing (Fig. 2, D and E). Presumably these are dendritic spikes, as described in mormyrid Purkinje cells in vitro (Han and Bell 2003; Zhang and Han 2007). Consistent with a possible dendritic origin, we

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observed that these spikes were most easily evoked via current injections in putative dendritic recordings in which simple spikes were small (Fig. 2D). Finally, we occasionally observed distinctive firing patterns that resembled the trimodal pattern that has been described in Purkinje cells in other systems (Llinas and Sugimori 1980b; Womack and Khodakhah 2004; Zhang and Han 2007). These consisted of a gradual acceleration of simple spike firing terminated by a dendritic spike and a subsequent pause in simple spike firing (Fig. 2E, top). Electric organ corollary discharge responses in LCp Purkinje cells. EOCD responses have been well-studied in ELL, where they have been shown to play a variety of functions, including the generation of negative images of self-generated electrosensory input (Bell 2001). Although EOCD responses in LCp Purkinje cells were described briefly in a previous study (Bell et al. 1992), they have not been thoroughly characterized. As in previous studies, we take advantage of an awake preparation in which fish continue to emit the motor command to discharge their electric organ but the EOD itself is blocked by neuromuscular paralysis, allowing EOCD responses, i.e., neural activity in sensory areas that is time-locked to the EOD motor command, to be studied in isolation from electrosensory effects. Patterns of simple spike and CF responses to the EOD motor command were analyzed for 55 Purkinje cells recorded intracellularly. Nearly all cells exhibited some EOCD response, though the strength of such responses varied widely across cells. Figure 3A shows eight Purkinje cells selected for their prominent simple spike modulations. Two features of these responses are notable. First, a wide variety of relationships were observed between temporal patterns of simple spike firing and CF responses. In some cases simple spikes and CF responses were roughly antiphasic (Fig. 3A, top left), in others they were roughly in phase (Fig. 3A, top right), while some cells exhibited strong simple spike modulations without any modulation of CF responses (Fig. 3A, bottom). Second, whereas the EOD motor command itself is brief and highly stereotyped, effects of the command on Purkinje cells were substantially more delayed and temporally diverse. EOCD responses in LCp Purkinje cells are also considerably more delayed and diverse than EOCD responses observed previously in most granule cells in EGp (Fig. 3B) (Kennedy et al. 2014) and in MG cells in mormyromast zones of ELL (Fig. 3C) (Bell

Fig. 3. Electric organ corollary discharge (EOCD) responses in LCp Purkinje cells. A: electric organ discharge (EOD) command-evoked simple spike and CF response rates smoothed with a 25-ms Gaussian filter for 8 different Purkinje cells recorded intracellularly. Dotted lines are SE. Rasters correspond to the uppermost example in each row. Small black circles are simple spikes, and large gray circles are CFs. B, top: smoothed firing rate (25-ms Gaussian filter) of a typical EGp granule cell in response to the EOD motor command. Bottom: overlaid membrane potential (Vm) traces showing command-evoked depolarization and spiking in the same example granule cell. By comparison, responses of Purkinje cells are far more delayed and temporally diverse. C: EOD command-evoked narrow spike rates (25-ms Gaussian filter) overlaid for 10 different MG cells recorded in the mormyromast zones of ELL. Cells were selected at random from a large number of MG cell recordings from previous studies. Despite receiving similar parallel fiber input as LCp Purkinje cells, EOCD responses are less diverse and delayed in MG cells. D: individual trace from an intracellularly recorded Purkinje cell, illustrating subthreshold membrane potential modulation in relation to the EOD command. Filled arrow indicates CF response. Bottom trace is the electromotoneuron volley (EMN) measured near the tail. E–G: average command-evoked subthreshold responses for 3 Purkinje cells; E shows same cell as in D. Gray outlines are SE. J Neurophysiol • doi:10.1152/jn.00016.2014 • www.jn.org

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et al. 1997a; Mohr et al. 2003a; Sawtell et al. 2007). Diverse, delayed, and long-lasting subthreshold responses to the EOD command were also observed in intracellular recordings from Purkinje cells (Fig. 3, D–G). In some Purkinje cells subthreshold responses resembled a continuous oscillation locked to the EOD command (Fig. 3, D and E), while in others commandevoked EPSPs and inhibitory postsynaptic potentials (IPSPs) with sharp onsets were evident (Fig. 3, F and G). Variation in the strength of EOCD responses was strongly associated with recording depth. Purkinje cells encountered near the surface of LCp, which is directly visible after reflection of the overlying valvula cerebelli, tended to have weaker EOCD responses than those encountered deeper in LCp (Fig. 4, A and B). Figure 4C shows the strength of simple spike modulation for 100 extracellularly recorded Purkinje cells in three fish plotted versus recording depth. Given their superficial locations, weakly responding cells probably correspond to the dorsal Purkinje cells described in previous anatomical and in vitro studies of LCp (Campbell et al. 2007; Zhang and Han 2007). Consistent with this, morphologically identified dorsal Purkinje cells had smaller simple spike modulations in response to EOCD inputs than morphologically identified multipolar Purkinje cells [0.96 ⫾ 0.36 (n ⫽ 11) for dorsal cells vs. 2.58 ⫾ 0.86 (n ⫽ 9) for multipolar cells; P ⬍ 0.0001, Student’s t-test]. These results suggest that dorsal and multipolar Purkinje cells are functionally distinct. Finally, we noted that in some Purkinje cells accelerations in the rate of EOD motor commands emitted by the fish were associated with strong modulations of simple spike firing. Such accelerations can be evoked by sensory stimuli, the so-called novelty response (Post and von der Emde 1999), but also occurred spontaneously (Fig. 5A, top). These modulations did

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Fig. 5. Effects of EOD command rate on LCp Purkinje cell responses. A: spontaneous EOD command rate accelerations. Top: times of occurrence of individual EOD commands. Bottom: instantaneous command rate. B: EOD command-evoked simple spike firing rates (25-ms Gaussian filter) for 2 different Purkinje cells (black vs. gray trace) recorded in the same fish as the command intervals shown in A. Averages were constructed with commands separated by ⬎150 ms. C: opposite effects of command rate increases on simple spike firing for the same 2 Purkinje cells. D, top: intracellular traces from a different Purkinje cell illustrating that depolarization and increases in simple spike firing often precede increases in EOD command rate (arrows). Middle: times of occurrence of individual EOD commands. Bottom: instantaneous command rate.

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Fig. 4. Strength of LCp Purkinje cell EOCD responses varies with recording depth. A: command-evoked simple spike firing rate (25-ms Gaussian filter; dotted lines are SE) from a Purkinje cell recorded extracellularly near the surface of LCp (⬃80 ␮m deep); “mod” indicates the modulation of simple spike firing by the EOD motor command (see METHODS). B: command-evoked simple spike firing rate from a Purkinje cell recorded extracellularly deeper within LCp (⬃380 ␮m deep). C: command-evoked simple spike modulations plotted vs. recording depth for n ⫽ 100 extracellularly recorded Purkinje cells in 3 fish. D: average simple spike firing rate plotted vs. recording depth for the cells shown in C.

not appear to be the result of simple temporal summation of EOCD responses at high command rates, as cells with similar EOCD responses measured for normal EOD command intervals (⬎150 ms) (Fig. 5B) could have opposite responses to accelerations (Fig. 5C). Also, it was evident from intracellular recordings that in some cells depolarization consistently preceded the accelerations in EOD command rate (Fig. 5D) and hence could not result from simple temporal summation. Such responses were observed in roughly half of the Purkinje cells we recorded. Electrosensory responses in LCp Purkinje cells. Two main classes of electroreceptors project to ELL: ampullary receptors subserving passive electrolocation and mormyromast receptors subserving active electrolocation (Bell 1986b). While ampullary receptors are sensitive to low-frequency external fields, e.g., those emitted by other animals, and project to the ventrolateral zone of ELL, mormyromast receptors are sensitive to small changes in amplitude and waveform of the fish’s own EOD and project to the medial and dorsolateral zones of ELL. All three zones of ELL project to the midbrain preeminential nucleus, which, in turn, provides mossy fiber input to EGp (Bell and Szabo 1986). We first tested responses of Purkinje cells to low-frequency electrosensory stimuli designed to selectively engage ampul-

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cells and to those recorded in superficially located Purkinje cells (Fig. 4). Finally, all five Purkinje cells with responses to low-frequency electrosensory stimuli that were morphologically identified were dorsal Purkinje cells. We next tested responses of Purkinje cells to stimuli designed to engage mormyromast receptors involved in active electrolocation. These consisted of brief pulses delivered shortly after the EOD command, mimicking the fish’s own EOD. EOD mimics could be delivered either locally to restricted regions of the body surface to map receptive fields or globally to activate the entire receptor surface. In contrast to ELL (Bell and Grant 1992; Metzen et al. 2008; Sawtell and Williams 2008) or preeminential nucleus neurons (Sawtell et al. 2005; von der Emde and Bell 1996), LCp Purkinje cells did not respond strongly to local stimuli and appeared to lack well-delineated electrosensory receptive fields. As shown in Fig. 7, we did observe changes in simple spike firing and CF response patterns when we turned on a global EOD mimic locked to the EOD motor command. Although the EOD mimic activates both mormyromast and ampullary receptors (Bell and Russell 1978), we think it is likely that at least some of the responses we observed are related to activation of mormyromast receptors. If responses to EOD mimics were due exclusively to ampullary receptor activation, they should be strongest in superficial, putative dorsal Purkinje cells with weak EOCD responses. This did not appear to be the case. As can be seen in Fig. 7 and Fig. 9A, some Purkinje cells with responses to EOD mimics also exhibited strong EOCD responses.

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Fig. 6. Effects of low-frequency electrosensory stimuli (ES) on LCp Purkinje cell responses. A, top: intracellular trace showing subthreshold, simple spike, and CF response modulations evoked by a global sinusoidal ES (middle). Bottom: times of occurrence of individual EOD commands. B: simple spike and CF response rates (25-ms Gaussian filter) in relation to the phase of a 0.5-Hz global sinusoidal ES presented at 3 different stimulus intensities to the same cell. The phase of the ES is shown at bottom of B–D. Note that CF responses are modulated at lower stimulus intensities than simple spikes. C: simple spike and CF response rates (25-ms Gaussian filter) in relation to the phase of a sinusoidal ES presented at 5 different frequencies to the same cell (different from that shown in B). D: simple spike and CF response rates (25-ms Gaussian filter) in relation to the phase of a sinusoidal ES delivered via a local dipole positioned at 4 different locations on the body indicated by numbers in the schematic at top (different cell from those shown in B and C). Different locations of the local ES resulted in different phase relationships to the stimulus, though in each case simple spikes and CF responses were antiphasic.

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lary receptors. Such stimuli clearly modulated simple spikes and CF responses in putative dorsal Purkinje cells (Fig. 6A). Such stimuli modulated simple spikes and CF responses at intensities far below those required to activate mormyromast receptors and within the range shown to be effective for activating ampullary receptors (Bell 1982) (Fig. 6B). Several features of these responses were notable. Simple spike modulations and CF responses were strongest at low frequencies, typically peaking at ⬃1 Hz and declining sharply at higher frequencies (Fig. 6C). With local stimulation it was often possible to evoke different responses at different skin positions, with some positions yielding no response (Fig. 6D). Finally, modulations of simple spikes and CF responses were typically antiphasic (Fig. 6). Several observations suggest that responses to low-frequency electrosensory stimuli are specific to dorsal Purkinje cells. First, such responses were found almost exclusively at superficial depths. This observation was confirmed in a subset of experiments in which recording depth and responsiveness to low-frequency electrosensory stimulation were tracked for all recorded Purkinje cells. Fifteen of thirty-four extracellularly recorded Purkinje cells exhibited simple and/or CF response modulations in response to low-frequency electrosensory stimuli. Responsive cells were recorded at more superficial locations than nonresponsive cells (253 ⫾ 121.2 ␮m vs. 450.7 ⫾ 133.3 ␮m; P ⬍ 0.0001, Student’s t-test). Low-frequency responsive cells also exhibited weak EOCD responses (modulation index: 0.66 ⫾ 0.32, n ⫽ 13 whole cell recordings), similar to those observed in morphologically identified dorsal Purkinje

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Fig. 7. Effects of an EOD mimic on LCp Purkinje cell responses. A, left: EOD command-evoked simple spike and CF response rates (25-ms Gaussian filter; dotted lines are SE) for an example Purkinje cell recorded intracellularly. Right: effects of a global EOD mimic delivered 4.5 ms after the command (arrow). B: same display for a second example Purkinje cell. Rasters correspond to the cell shown in A.

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Proprioceptive responses in LCp Purkinje cells. Mossy fibers originating from the spinal cord and brain stem convey proprioceptive information about the posture and movements of the fish to EGp (Bell et al. 1981, 1992). Previous studies have suggested that such information is used by ELL neurons to cancel out self-generated changes in electrosensory input due to movements of the electric organ, located in the tail, relative to electroreceptors on the body surface (Bell et al. 1981; Sawtell 2010; Sawtell and Williams 2008). Purkinje cells commonly exhibited membrane potential, simple spike, and CF response modulations in response to passive sinusoidal displacements of the tail (0.1–1 Hz) (Fig. 8). A variety of response patterns were observed (Fig. 8, A and B), consistent with the variety of responses to tail position, velocity, and speed observed previously in mossy fibers (Sawtell 2010). Modulations of simple spike firing and CF responses were often, though not exclusively, antiphasic (Fig. 8). Modulations of simple spike and CF responses by tail movements were sometimes observed in the same Purkinje cells that exhibited simple spike and CF response modulations in response to low-frequency electrosensory stimuli (Fig. 8D; n ⫽ 8), suggestive of multimodal integration at the level of both Purkinje cells and the inferior olive. We also observed that Purkinje cells exhibiting clear modulation of simple spike and/or CF responses to tail displacements exhibited weaker EOCD responses than those that did not respond to tail movements [modulation index: 0.99 ⫾ 0.57 vs. 2.89 ⫾ 0.91 (n ⫽ 30 and 12 whole cell recordings, respectively); P ⬍ 0.00001, Student’s t-test]. Of 30 cells that responded to tail movements, 9 were morphologically identified as dorsal and 3 as multipolar Purkinje cells. Of 12 Purkinje cells that showed no response to tail movements, 6 were morphologically identified as multipolar Purkinje cells. LCp Purkinje cells do not exhibit rapid associative plasticity in vivo. Motivated by similarities between negative images described previously in ELL and mammalian cerebellar plasticity and learning (see DISCUSSION), we attempted to induce associative plasticity of EOCD and proprioceptive inputs in LCp Purkinje cells by pairing the EOD motor command or a proprioceptive stimulus with activation of CFs. First, we compared EOCD responses before, during, and after pairing with a

global EOD mimic locked to the EOD motor command (Fig. 9A). For the example Purkinje cell shown in Fig. 9A, the global EOD mimic caused a clear shift in the latency of commandevoked CF responses during pairing (Fig. 9A, bottom). In contrast to results obtained previously in ELL neurons (Bell 1981; Bell et al. 1997a; Bell and Grant 1992), no temporally specific change was apparent after 45 min of pairing (Fig. 9A, top). Similar experiments were performed for 13 cells, with pairing durations ranging from 5 to 45 min. Although we sometimes observed overall shifts in membrane potential, no temporally specific changes in EOD command-evoked subthreshold or simple spike responses were observed after pairing in these experiments. A second series of experiments were performed in which a single dendritic spike evoked by intracellular current injection was paired at a fixed delay after the EOD command for between 2 and 10 min (Fig. 9B, bottom). These pairings also failed to reveal temporally specific changes in EOCD responses (Fig. 9B, top; n ⫽ 11 cells). In a third series of experiments we compared subthreshold and simple spike responses to the EOD command before, during, and after

Fig. 8. Effects of passive tail movements on LCp Purkinje cell responses. A and B: 2 example Purkinje cells showing simple spike and CF response rates (25-ms Gaussian filter) in relation to the phase of a sinusoidal tail displacement (⫾20°) presented at 3 different frequencies to each cell. Note that simple spike and CF responses are roughly antiphasic. C: intracellular recording showing the average subthreshold response (Vm, middle) and CF responses (raster, top) in response to a sinusoidal tail displacement (bottom). D: example cell with simple spike and CF responses to both sinusoidal tail displacement (⫾20°) (top) and a low-frequency ES (bottom).

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Purkinje cells, independent of changes in synaptic transmission (Cerminara and Rawson 2004; Colin et al. 1980; Demer et al. 1985; Mathews et al. 2012; McKay et al. 2007; Montarolo et al. 1982; Savio and Tempia 1985). Finally, two additional sets of pairing experiments were conducted to test the possibility that proprioceptive inputs to LCp Purkinje cells exhibit plasticity. Simple spike responses to sinusoidal tail displacements were compared before, during, and after 5–20 min of pairing with either an electrosensory stimulus (200-ms square pulse; Fig. 10A, n ⫽ 9 cells) or electrical microstimulation evoking CF responses (Fig. 10B, n ⫽ 3 cells) at a fixed phase of the tail displacement. Electrosensory stimuli effectively drove CF responses in dorsal Pur-

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Fig. 9. LCp Purkinje cells do not exhibit rapid associative plasticity of EOCD responses. A, top: average subthreshold EOCD responses before (black) and after (gray) pairing the EOD command with a global EOD mimic (bottom) for 45 min. Although this cell exhibited an apparent increase in CF response rate after pairing, such changes were not consistently observed. B: same display as in A, but pairing was conducted by injecting current to evoke a dendritic spike at a fixed delay after the command (bottom). Pairing duration for the cell shown was 7 min. C: EOD command-evoked simple spike and CF response rates (25-ms Gaussian filter) for an extracellularly recorded Purkinje cell before (pre), during (pairing w CF stim), and at 2 times after (post) pairing the EOD command with a CF response evoked by microstimulation for 45 min. Inset: the evoked CF waveform. Although the overall rate of simple spike discharge was reduced, there was little change in the temporal pattern of simple spike firing.

pairing with microstimulation-evoked CF responses (Fig. 9C, inset). Compared with pairings using the global EOD mimic described above, microstimulation provided a much greater degree of control over the rate and timing of CF responses relative to the command. Pairings lasted between 3 and 40 min and were conducted in 12 cells. Despite the stronger engagement of CF responses in these experiments, temporally specific changes in command-evoked subthreshold or simple spike responses were not consistently observed after pairing (Fig. 9C). We did, however, observe overall reductions in simple spike firing after pairing in some experiments (Fig. 9C, compare pre vs. post). Such reductions could also be induced simply by increasing the rate of CF stimulation independent of the EOD command (data not shown) and hence are unlikely to reflect associative plasticity. These observations are consistent with results in mammalian Purkinje cells showing that changes in the rate of CF activation alter intrinsic excitability of

Fig. 10. LCp Purkinje cells do not exhibit rapid associative plasticity of proprioceptive responses. A: simple spike and CF response rates (25-ms Gaussian filter) in relation to the phase of a sinusoidal tail displacement (⫾20°) before (top), during (middle), and after (bottom) pairing with an ES (200-ms square pulse, inset) delivered at a fixed phase of the displacement for 10 min. The ES reliably evoked CF responses during pairing but did not cause a change in simple spike firing after pairing. B: simple spike and CF response rates (25-ms Gaussian filter) in relation to the phase of a sinusoidal tail displacement before (top), during (middle), and after (bottom) pairing with CF responses evoked by microstimulation (arrows, inset) at a fixed phase of the displacement for 10 min. Scale bar for inset, 20 ms.

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kinje cells, presumably via activation on low-frequency electroreceptors. Despite large changes in the pattern of CF responses during pairing, patterns of simple spike firing in relation to tail displacements were largely unchanged after pairing. DISCUSSION

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This study provides an initial characterization of the response properties of Purkinje cells in a region of the mormyrid cerebellum that is closely associated with the electrosensory system and has afferent and efferent connections similar to an extremely well-studied cerebellum-like structure—the ELL. One firm conclusion of our study is that functional differences exist between previously described dorsal and multipolar Purkinje cells located in different subregions of LCp (Campbell et al. 2007; Zhang and Han 2007). Strong responses to lowfrequency electrosensory and proprioceptive stimuli were common in putative dorsal Purkinje cells (located superficially in LCp) but rare or absent in putative multipolar Purkinje cells (located deeper in LCp). EOCD responses, on the other hand, were stronger in putative multipolar Purkinje cells. In some cases, putative multipolar Purkinje cells with prominent EOCD responses could be shown to respond to a global EOD mimic with changes in both simple spike firing and CF responses (Fig. 7). A similar pattern is observed in regions of ELL involved in passive versus active electrosensory processing, i.e., EOCD responses are much stronger in the latter (Bell 1982; Bell et al. 1992; Bell and Grant 1992). Hence, as in ELL, distinct LCp subregions may be dedicated to passive versus active electrosensory processing. Differences in EOCD responses we observed between dorsal and multipolar Purkinje cells are also consistent with a previous report that EOCD field potentials recorded in medial portions of EGp are much smaller than those recorded more laterally in EGp (Bell et al. 1992). EGp granule cells located medially are expected to send parallel fibers to the dorsal region of LCp, while granule cells located laterally are expected to project to the deeper portion of LCp as well as to ELL (Fig. 1A). Hence a possible explanation for the functional differences we observed is that information from ampullary and mormyromast regions of ELL remains segregated at the level of the preeminential nucleus and is returned to different subregions of EGp. This hypothesis could be tested with tracer injections into different zones of ELL and LCp. Responses of putative dorsal Purkinje cells to low-frequency electrosensory stimuli were more prominent than those of putative multipolar Purkinje cells to EOD mimics. This is surprising given that most of ELL and most of the preeminential nucleus are dedicated to active electrolocation. More complex or naturalistic electrosensory stimuli may be required to strongly engage multipolar Purkinje cells. Consistent with this possibility, a study in weakly electric gymnotid fish found that moving electrosensory stimuli were more effective than stationary ones in modulating activity in cerebellar neurons (Bastian 1975). The specific role(s) of LCp in electrosensory processing is unknown. One possibility is that LCp plays a relatively direct role in some form of electrosensory-guided behavior. One such behavior is the electromotor response, in which fish use electrosensory information to stabilize their position relative to a moving refuge (Cowan and Fortune 2007; Rose and Canfield

1993). This behavior is similar to well-studied optomotor responses. Adaptive modification of the gain of the optomotor response in larval zebrafish appears to be cerebellum dependent (Ahrens et al. 2012). Alternatively, LCp may play a more general role in electrosensory processing. The fact that LCp projects (in parallel with ELL) mainly to electrosensory processing regions rather than motor centers seems to suggest the latter. Behavioral studies coupled with lesions of LCp could begin to address this issue. Although the histological structure and connections of various regions of the cerebellum and the in vitro electrophysiological properties of various cerebellar cell types have been well-studied in mormyrid fish (Campbell et al. 2007; Han et al. 2007; Han and Bell 2003; Meek et al. 2008; Nieuwenhuys and Nicholson 1969; Zhang and Han 2007), very little is known about signals conveyed by CFs (Bell et al. 1992; Russell and Bell 1978). Our study provides some initial insights into this important issue. CF responses in LCp Purkinje cells were observed at specific delays relative to the EOD command and brief EOD mimic pulses and at specific phases in relation to low-frequency electrosensory stimuli and passive tail movements. CF responses in some Purkinje cells were modulated in relation to both low-frequency electrosensory and proprioceptive signals or to both EOCD and electrosensory signals, suggesting multimodal convergence of sensory and motor signals onto individual inferior olive neurons. Our results clearly indicate that signals conveyed by CFs to LCp are more diverse and complex than those conveyed by electroreceptors to ELL. Studies aimed at determining how CFs are engaged by more natural patterns of electrosensory input or in the context of electrosensory-guided behavior are needed in order to generate more specific hypotheses regarding LCp function. Comparisons with ELL. Intracellular and extracellular recordings from LCp Purkinje cells presented here, together with past in vitro studies of mormyrid Purkinje cells (de Ruiter et al. 2006; Han and Bell 2003; Zhang et al. 2012; Zhang and Han 2007), suggest that the basic electrophysiological properties of LCp Purkinje cells are quite similar to those described for Purkinje cells in other species. Similar to LCp Purkinje cells, the Purkinje-like MG cells of ELL also exhibit multiple types of all-or-none events. Narrow spikes are frequent and of axonal origin and convey the main output of MG cells, while broad spikes are infrequent and of dendritic origin and are key triggers for associative plasticity at parallel fiber synapses (Bell et al. 1997b; Engelmann et al. 2008; Grant et al. 1998). However, unlike CF responses in LCp Purkinje cells, MG cell broad spikes are not related to a CF input and can be readily evoked by somatic current injections at thresholds only modestly greater than those evoking axonal spikes. MG cell broad spikes also appear to differ from dendritic spikes in LCp Purkinje cells in that they are not associated with a trimodal firing pattern and are sodium spikes rather than calcium spikes (Grant et al. 1998; Zhang et al. 2010; Zhang and Han 2007). LCp Purkinje cells exhibited subthreshold and simple spike responses to the EOD motor command, electrosensory stimuli, and proprioceptive stimuli. Presumably such responses are mediated by mossy fiber-granule cell inputs. EOCD and proprioceptive responses have also been well-documented for ELL neurons, highlighting the fact that the same mossy fiber inputs are processed in parallel by a cerebellum-like circuit and a region of the cerebellum proper. EOCD responses provide an

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proaches that have revealed plastic changes in the responses of mammalian Purkinje cells in vivo (e.g., Jirenhed et al. 2007; Jirenhed and Hesslow 2011). These experiments took advantage of the fact that the fish’s own EOD command provides strong and natural activation of EOCD mossy fibers and evokes strong depolarizations in many LCp Purkinje cells, presumably mediated, at least in part, by parallel fiber synapses (Fig. 3, B–E). Similarly, passive tail displacements were used to provide strong and reasonably naturalistic engagement of proprioceptive mossy fibers. Activation of CFs at particular delays after the EOD command or particular phases of tail displacements was achieved via electrical microstimulation or with electrosensory stimuli. Such pairings failed to induce consistent changes in membrane potential and/or simple spike firing that were specific to the timing or phase of the CF responses during pairing. Although we sometimes observed overall changes in membrane potential and simple spike firing rates after pairing, such changes were nonspecific and were most prominent in experiments in which electrical microstimulation was used to evoke CF responses at rates substantially higher than those normally observed. These effects are likely due to changes in excitability rather than associative synaptic plasticity. Such excitability changes are a known consequence of changing the rate of CF input (Cerminara and Rawson 2004; Colin et al. 1980; Demer et al. 1985; Mathews et al. 2012; McKay et al. 2007; Montarolo et al. 1982; Savio and Tempia 1985). Although our failure to induce plasticity is not surprising on its own, it does contrast with ELL, where rapid associative plasticity is readily induced in vivo in a preparation identical to that used in the present study. Several explanations can be offered for why we failed to induce associative plasticity of EOCD or proprioceptive inputs. First, such plasticity may not exist in LCp. We believe this is unlikely in light of previous in vitro studies of Purkinje cells in the central lobes of the mormyrid cerebellum demonstrating plasticity of parallel fiber synapses induced by pairing with CF stimulation (Han et al. 2007). In addition, preliminary observations suggest that similar plasticity can be induced in vitro in LCp Purkinje cells (V. Han, unpublished observations). A second possibility is that plasticity driven by coactivation of parallel fiber and climbing input exists in LCp but our experimental protocols were simply insufficient to induce such plasticity. Negative images in ELL neurons can be induced very rapidly, over a timescale of just a few minutes of pairing (Bell 1982; Bell et al. 1997a; Bell and Grant 1992; Sawtell and Williams 2008). Although a variety of different protocols have been used to induce plasticity in Purkinje cell in vivo, some studies, including eyelid conditioning paradigms discussed above (Jirenhed et al. 2007; Jirenhed and Hesslow 2011), suggest that the induction of in vivo plasticity in the cerebellum may require longer-duration pairing periods. Different requirements for plasticity induction in LCp versus ELL may be related to previously described differences in parallel fiber synaptic transmission, i.e., the presence of a prominent NMDA receptor-mediated component of parallel fiber-evoked responses in MG but not LCp Purkinje cells (Grant et al. 1998; Zhang and Han 2007). The possibility of different timescales of plasticity in LCp versus ELL suggests an interpretation of the observation that EOCD responses in LCp Purkinje cells are more delayed and diverse than in MG cells, despite the fact that both cell types

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interesting point of comparison because they have been wellstudied both in ELL and in EGp. The EOD motor command, like the EOD itself, is brief and extremely stereotyped. In contrast, EOCD responses in putative multipolar Purkinje cells were often delayed and long-lasting and showed considerable diversity in their temporal patterns. Recent recordings and modeling of EOCD responses in EGp granule cells suggest that Purkinje cell responses we observed would not be expected based on simple summation of granule cell EOCD input. The large majority of granule cells are active at short delays after the EOD command (Fig. 3B), with only a small fraction of cells active at longer delays (Kennedy et al. 2014). Experimental and theoretical studies of negative image formation and sensory cancellation in ELL have shown that anti-Hebbian spike timing-dependent plasticity at parallel fiber-MG cell synapses, together with an array of granule cells active at a range of different delays after the EOD motor command, provides a mechanism for generating diverse and delayed EOCD responses (Bell 1981; Bell et al. 1997b; Kennedy et al. 2014; Roberts and Bell 2000). The possibility that similar mechanisms are involved in generating diverse and delayed EOCD responses observed in multipolar Purkinje cells is discussed below. Other mechanisms, besides plasticity, could also be responsible for shaping EOCD responses in LCp. LCp Purkinje cells receive inhibitory inputs from molecular layer interneurons and also inhibit each other, as shown by in vitro paired recordings (Zhang et al. 2012). To the extent to which they are understood, adaptive processes in the cerebellum appear similar in many respects to negative images and sensory cancellation described in ELL (Bell et al. 2008). In ELL, the pairing of parallel fiber signals, e.g., EOCD or proprioceptive input, with peripheral sensory input results in such signals eliciting a predictive reduction in principal cell activity, as described above for EOCD signals. In the cerebellum, pairing of parallel fiber signals with CF input leads to such signals eliciting a reduction in the firing of Purkinje cells. If the CFs convey some type of sensory signal, gated through the inferior olive, then the parallel fiber signals that are paired with the CFs and that predict their occurrence will reduce Purkinje cell activity. For example, adaptively timed pauses in Purkinje cell firing observed in the context of eyelid conditioning are similar in numerous respects to temporally specific negative images in ELL neurons (Jirenhed et al. 2007; Jirenhed and Hesslow 2011). A leading hypothesis regarding the mechanisms underlying such changes in Purkinje cell responses is similar to that described above for temporally specific negative images in ELL. Temporal patterns of simple spike firing in Purkinje cells are sculpted via CF-induced plasticity at parallel fiber-Purkinje cell synapses acting on an array of granule cell inputs with a variety of temporal activity patterns in relation to the conditioned stimulus (Medina et al. 2000; Medina and Mauk 2000). Extending these ideas to LCp, it could be hypothesized that temporal patterns of EOCD response in Purkinje cells are sculpted via CF-induced plasticity acting on an array of differently timed EOCD input conveyed by parallel fibers. We addressed this hypothesis by experimentally manipulating the relationship between mossy fiber and CF inputs. Our approach was similar to that used previously to reveal negative images in ELL neurons (Bell 1981; Bell et al. 1993; Sawtell 2010; Sawtell and Williams 2008) and similar also to ap-

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ACKNOWLEDGMENTS Present address of K. Alviña: Albert Einstein College of Medicine, Dept. of Neuroscience, 1410 Pelham Pkwy S., Rm. 703, Bronx, NY 10461. GRANTS This work was supported by grants from the National Science Foundation (1025849), the National Institute of Neurological Disorders and Stroke (NS075023), the Alfred P. Sloan Foundation, and the McKnight Endowment Fund for Neuroscience to N. B. Sawtell. DISCLOSURES No conflicts of interest, financial or otherwise, are declared by the author(s). AUTHOR CONTRIBUTIONS Author contributions: K.A. and N.B.S. performed experiments; K.A. and N.B.S. analyzed data; K.A. and N.B.S. edited and revised manuscript; K.A. and N.B.S. approved final version of manuscript; N.B.S. conception and design of research; N.B.S. interpreted results of experiments; N.B.S. prepared figures; N.B.S. drafted manuscript.

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presumably receive similar EOCD input via parallel fibers (compare Fig. 3, A and C). Diversity in Purkinje cell EOCD responses observed in our experimental preparation may reflect the maintenance of temporally specific plastic changes of EOCD inputs induced during the fish’s life. A lack of such diversity in MG cells may reflect the rapid adjustment of the strength of EOCD inputs to the artificial conditions imposed by our preparation, in which the EOD motor command has no sensory consequence because of blockade of the EOD by the paralytic (Bell 1986a). The stereotyped short-latency excitation observed in MG cells (Fig. 3C) is believed to be due to a nonplastic EOCD input from the juxtalobar nucleus to the basilar dendrites of MG cells (Mohr et al. 2003b). Finally, it is possible that some additional factor— besides coactivation of parallel fibers and CFs—is required for plasticity induction in Purkinje cells. Such a requirement would distinguish Purkinje cell plasticity from that observed in ELL, where coactivation of parallel fiber inputs with postsynaptic spikes appears to be the only requirement for plasticity induction and negative image formation. Consistent with such a possibility, neuromodulatory systems have been shown to affect induction of CF-induced plasticity of parallel fiber synapses onto Purkinje cells in vitro (Carey and Regehr 2009). Moreover, a recent study has provided evidence that CF error signals may be gated, such that they play a role in inducing Purkinje cell plasticity in the context of some forms of motor learning but not others (Kimpo et al. 2013). In summary, our results provide basic information about in vivo response properties of LCp Purkinje cells that will help guide future studies of this interesting region of the cerebellum. Given the key role for motor corollary discharge signals in hypothesized predictive functions of the cerebellum (Miall and Wolpert 1996; Wolpert et al. 1998), the prominence and accessibility of EOCD signals in LCp may provide unique opportunities for understanding how corollary discharge signals are processed and transformed in cerebellar circuitry. Moreover, given the striking anatomical parallelism between ELL and LCp, further studies may also contribute to a general understanding of how similarities and differences in circuit architecture relate to function.

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Sensory processing and corollary discharge effects in posterior caudal lobe Purkinje cells in a weakly electric mormyrid fish.

Although it has been suggested that the cerebellum functions to predict the sensory consequences of motor commands, how such predictions are implement...
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