State-, Timing-, and Pattern-Dependent Neuromodulation of Synaptic Strength by a Serotonergic Interneuron

Sakurai, Akira; Katz, Paul S.

doi:10.1523/jneurosci.4456-08.2009

Cited by 26 publications

(19 citation statements)

References 57 publications

(71 reference statements)

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“…In modulatory networks, more than sufficient scope for very complex nonlinearities, and so complex computations, appears to exist, for example, in the interactions between multiple modulators at the synapses where they modulate each other's release (Vizi & Lábos 1991;Stjärne & Stjärne 1995;Lundberg 1996;Salio et al 2006)-sometimes even differentially the release of just a specific subset of the total modulator complement (DeLong et al 2009)-and in their modulation, through intracellular signal-transduction pathways, of each other's receptors and so actions (Sebastião & Ribeiro 2000). Rooted in such interactions are then higher-order functional phenomena such as metamodulation (Katz & Edwards 1999;Stein 2009), the gating of the actions of one modulator by another (Dickinson et al 1997;Svensson et al 2001), complex dependence of the expression of the modulator actions on the state and activity of the underlying neuronal network (Ito & Schuman 2008;Sakurai & Katz 2009), and ultimately, it has been proposed, even such top-level functionalities of the vertebrate nervous system as the representations of memory, salience, reward, expectation and uncertainty (Hasselmo 1995;Yu & Dayan 2005;Cragg 2006). Very complex computations are inherent also in the processing of the released modulators-in particular, the purines and the neuropeptides-by the extracellular processing enzymes that transform the cocktail of active modulators into another cocktail with different activities, with dynamics that themselves can be modulated (Dale & Gilday 1996;Konkoy & Davis 1996;Dale 2002;Nusbaum 2002;Huxtable et al 2009).…”

Section: Computation Performed By the Neuromodulatory Networkmentioning

confidence: 99%

Beyond the wiring diagram: signalling through complex neuromodulator networks

Březina

2010

Phil. Trans. R. Soc. B

110

108

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During the computations performed by the nervous system, its 'wiring diagram'-the map of its neurons and synaptic connections-is dynamically modified and supplemented by multiple actions of neuromodulators that can be so complex that they can be thought of as constituting a biochemical network that combines with the neuronal network to perform the computation. Thus, the neuronal wiring diagram alone is not sufficient to specify, and permit us to understand, the computation that underlies behaviour. Here I review how such modulatory networks operate, the problems that their existence poses for the experimental study and conceptual understanding of the computations performed by the nervous system, and how these problems may perhaps be solved and the computations understood by considering the structural and functional 'logic' of the modulatory networks.

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Section: Computation Performed By the Neuromodulatory Networkmentioning

confidence: 99%

Beyond the wiring diagram: signalling through complex neuromodulator networks

Březina

2010

Phil. Trans. R. Soc. B

110

108

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“…Localization of neuromodulators to specific neurons made it possible to change the focus of research from studying overall actions of modulators on CPG networks to more specific studies of how neuromodulators may account for the actions of individual neurons that contain them (e.g., Harris-Warrick and Marder 1991;Jing and Weiss 2001;Jing et al 2007Jing et al -2009Koh et al 2003;Nusbaum and Beenhakker 2002;Sakurai and Katz 2009). Such studies are well illustrated by the actions of two modulatory pathways in Aplysia: one of which originates in the higher-order interneuron, CBI-3 Morgan et al 2002) and the other in the EN.…”

Section: Roles Of Modulatory Peptides In Input Neurons: Comparisons Wmentioning

confidence: 99%

Composite Modulatory Feedforward Loop Contributes to the Establishment of a Network State

Vilim

Hatcher

et al. 2010

Journal of Neurophysiology

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Wu JS, Vilim FS, Hatcher NG, Due MR, Sweedler JV, Weiss KR, Jing J. Composite modulatory feedforward loop contributes to the establishment of a network state. J Neurophysiol 103: 2174-2184, 2010. First published February 24, 2010 doi:10.1152/jn.01054.2009 are one of many network motifs identified in a variety of complex networks, but their functional role in neural networks is not well understood. We provide evidence that combinatorial actions of multiple modulators may be organized as FFLs to promote a specific network state in the Aplysia feeding motor network. The Aplysia feeding central pattern generator (CPG) receives two distinct inputs-a higher-order interneuron cerebral-buccal interneuron-2 (CBI-2) and the esophageal nerve (EN)-that promote ingestive and egestive motor programs, respectively. EN stimulation elicits a persistent egestive network state, which enables the network to temporarily express egestive programs following a switch of input from the EN to CBI-2. Previous work showed that a modulatory CPG element, B65, is specifically activated by the EN and participates in establishing the egestive state by enhancing activity of egestion-promoting B20 interneurons while suppressing activity and synaptic outputs of ingestion-promoting B40 interneurons. Here a peptidergic contribution is mediated by small cardioactive peptide (SCP). Immunostaining and mass spectrometry show that SCP is present in the EN and is released on EN stimulation. Importantly, SCP directly enhances activity and synaptic outputs of B20 and suppresses activity and synaptic outputs of B40. Moreover, SCP promotes B65 activity. Thus the direct and indirect (through B65) pathways to B20 and B40 from SCPergic neurons constitute two FFLs with one functioning to promote egestive output and the other to suppress ingestive output. This composite FFL consisting of the two combined FFLs appears to be an effective means to co-regulate activity of two competing elements that do not inhibit each other, thereby contributing to establish specific network states.

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“…stomatogastric nervous system; central pattern generator; sensorimotor; descending control; neuromodulation ONE OF THE BIGGEST CHALLENGES today is to determine how the neuromodulatory system contributes to the neuronal plasticity that allows the nervous system to respond adequately to different behavioral tasks (Gu 2002;Calabrese 2003;Krichmar 2008;Brezina 2010). In particular, motor pattern generating circuits show a high degree of flexibility due to neuromodulatory substances that trigger new patterns or modify ongoing activity (Morgan et al 2002;Nusbaum and Beenhakker 2002;Marder et al 2005;Dickinson 2006;Sakurai and Katz 2009). Recent studies (Chen et al 2009) have addressed the complexity and variety of paracrine neuromodulator release in vivo, but much less is known about the in vivo activity of neuromodulatory neurons that control behavior.…”

mentioning

confidence: 99%

“…In particular, motor pattern generating circuits show a high degree of flexibility due to neuromodulatory substances that trigger new patterns or modify ongoing activity (Morgan et al 2002;Nusbaum and Beenhakker 2002;Marder et al 2005;Dickinson 2006;Sakurai and Katz 2009). Recent studies (Chen et al 2009) have addressed the complexity and variety of paracrine neuromodulator release in vivo, but much less is known about the in vivo activity of neuromodulatory neurons that control behavior.…”

mentioning

confidence: 99%

Gastric and pyloric motor pattern control by a modulatory projection neuron in the intact crabCancer pagurus

Hedrich

Diehl

Stein

2011

Journal of Neurophysiology

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Hedrich UB, Diehl F, Stein W. Gastric and pyloric motor pattern control by a modulatory projection neuron in the intact crab Cancer pagurus. J Neurophysiol 105: 1671-1680, 2011. First published February 16, 2011 doi:10.1152/jn.01105.2010.-Neuronal release of modulatory substances provides motor pattern generating circuits with a high degree of flexibility. In vitro studies have characterized the actions of modulatory projection neurons in great detail in the stomatogastric nervous system, a model system for neuromodulatory influences on central pattern generators. Less is known about the activities and actions of modulatory neurons in fully functional and richly modulated network settings, i.e., in intact animals. It is also unknown whether their activities contribute to the motor patterns in different behavioral conditions. Here, we show for the first time the activity and effects of the well-characterized modulatory projection neuron 1 (MCN1) in vivo and compare them to in vitro conditions. MCN1 was always spontaneously active, typically in a rhythmic fashion with its firing being interrupted by ascending inhibitions from the pyloric motor circuit. Its activity contributed to pyloric motor activity, because 1) the cycle period of the motor pattern correlated with MCN1 firing frequency and 2) stimulating MCN1 shortened the cycle period while 3) lesioning of the MCN1 axon reduced motor activity. In addition, gastric mill motor activity was elicited for the duration of the stimulation. Chemosensory stimulation of the antennae moved MCN1 away from baseline activity by increasing its firing frequency. Following this increase, a gastric mill rhythm was elicited and the pyloric cycle period decreased. Lesioning the MCN1 axon prevented these effects. Thus modulatory projection neurons such as MCN1 can control the motor output in vivo, and they participate in the processing of exteroceptive sensory information in behaviorally relevant conditions. stomatogastric nervous system; central pattern generator; sensorimotor; descending control; neuromodulation ONE OF THE BIGGEST CHALLENGES today is to determine how the neuromodulatory system contributes to the neuronal plasticity that allows the nervous system to respond adequately to different behavioral tasks (Gu 2002;Calabrese 2003;Krichmar 2008;Brezina 2010). In particular, motor pattern generating circuits show a high degree of flexibility due to neuromodulatory substances that trigger new patterns or modify ongoing activity (Morgan et al. 2002;Nusbaum and Beenhakker 2002;Marder et al. 2005;Dickinson 2006;Sakurai and Katz 2009). Recent studies (Chen et al. 2009) have addressed the complexity and variety of paracrine neuromodulator release in vivo, but much less is known about the in vivo activity of neuromodulatory neurons that control behavior. In general, motor networks are governed by descending neurons from higher order circuits that are involved in decision making or relay the appropriate decisive information. In lamprey, fish, and tadpole, reticulospinal neurons in...

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State-, Timing-, and Pattern-Dependent Neuromodulation of Synaptic Strength by a Serotonergic Interneuron

Cited by 26 publications

References 57 publications

Beyond the wiring diagram: signalling through complex neuromodulator networks

Beyond the wiring diagram: signalling through complex neuromodulator networks

Composite Modulatory Feedforward Loop Contributes to the Establishment of a Network State

Gastric and pyloric motor pattern control by a modulatory projection neuron in the intact crabCancer pagurus

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