Hormonal Modulation of Sensorimotor Integration

DeLong, Nicholas D.; Nusbaum, Michael P.

doi:10.1523/jneurosci.5533-09.2010

Cited by 14 publications

(30 citation statements)

References 59 publications

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“…Such regulation provides added flexibility (and uncertainty, for the experimentalist) to the microcircuit response to a co-transmitting neuronal input. Examples of this selective regulation include the impact of hormonal modulation and proprioceptor feedback to the MCN1-driven gastric mill rhythm 59,138,141,142 (FIG. 6).…”

Section: Co-transmission: Stomatogastric Systemmentioning

confidence: 99%

Functional consequences of neuropeptide and small-molecule co-transmission

2017

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Colocalization of small-molecule and neuropeptide transmitters is common throughout the nervous system of all animals. The resulting co-transmission, which provides conjoint ionotropic (‘classical’) and metabotropic (‘modulatory’) actions, includes neuropeptide-specific aspects that are qualitatively different from those that result from metabotropic actions of small-molecule transmitter release. Here, we focus on the flexibility afforded to microcircuits by such co-transmission, using examples from various nervous systems. Insights from such studies indicate that co-transmission mediated even by a single neuron can configure microcircuit activity via an array of contributing mechanisms, operating on multiple timescales, to enhance both behavioural flexibility and robustness.

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Section: Co-transmission: Stomatogastric Systemmentioning

confidence: 99%

Functional consequences of neuropeptide and small-molecule co-transmission

2017

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“…This presents an interesting challenge for understanding how excitability and responses to modulators are controlled in neurons that may only be episodically activated, sometimes with days or weeks between epochs of activity. It is generally thought that the episodic gastric rhythm is specifically activated by descending neuromodulatory neurons, triggered by specific sets of sensory inputs (Beenhakker et al 2005(Beenhakker et al , 2007Blitz et al 1999Blitz et al , 2004Combes et al 1999;Dando and Selverston 1972;DeLong and Nusbaum 2010;Nusbaum and Marder 1989a). Because the period of time between feedings may vary considerably in the wild, it is also possible that the mechanisms governing the activation of the gastric rhythm must be robust to a very intermittent activation schedule.…”

Section: Discussionmentioning

confidence: 99%

Consequences of acute and long-term removal of neuromodulatory input on the episodic gastric rhythm of the crabCancer borealis

Hamood

Marder

2015

Journal of Neurophysiology

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Hamood AW, Marder E. Consequences of acute and long-term removal of neuromodulatory input on the episodic gastric rhythm of the crab Cancer borealis. J Neurophysiol 114: 1677-1692. First published July 8, 2015 doi:10.1152/jn.00536.2015.-For decades, the episodic gastric rhythm of the crustacean stomatogastric nervous system (STNS) has served as an important model system for understanding the generation of rhythmic motor behaviors. Here we quantitatively describe many features of the gastric rhythm of the crab Cancer borealis under several conditions. First, we analyzed spontaneous gastric rhythms produced by freshly dissected preparations of the STNS, including the cycle frequency and phase relationships among gastric units. We find that phase is relatively conserved across frequency, similar to the pyloric rhythm. We also describe relationships between these two rhythms, including a significant gastric/ pyloric frequency correlation. We then performed continuous, dayslong extracellular recordings of gastric activity from preparations of the STNS in which neuromodulatory inputs to the stomatogastric ganglion were left intact and also from preparations in which these modulatory inputs were cut (decentralization). This allowed us to provide quantitative descriptions of variability and phase conservation within preparations across time. For intact preparations, gastric activity was more variable than pyloric activity but remained relatively stable across 4 -6 days, and many significant correlations were found between phase and frequency within animals. Decentralized preparations displayed fewer episodes of gastric activity, with altered phase relationships, lower frequencies, and reduced coordination both among gastric units and between the gastric and pyloric rhythms. Together, these results provide insight into the role of neuromodulation in episodic pattern generation and the extent of animal-to-animal variability in features of spontaneously occurring gastric rhythms.

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“…The single firing rate (10 Hz=100 ms inter-spike interval) and burst duration (4.8 s) used were also within the physiological range of LG activity (inter-spike interval: 50-250 ms; burst duration: 2-9 s) (Beenhakker et al, 2004(Beenhakker et al, , 2005(Beenhakker et al, , 2007Blitz et al, 2004bBlitz et al, , 2008Colton and Nusbaum, 2014;DeLong and Nusbaum, 2010;Diehl et al, 2013;Hedrich et al, 2011;Kirby and Nusbaum, 2007;White and Nusbaum, 2011). Thus, our data indicate that during gastric mill rhythms triggered by multiple inputs, augmentation and facilitation/ depression would regulate responses of the three target muscles of LG.…”

Section: Physiological Activity Rangementioning

confidence: 99%

“…For instance, at the short end of the spectrum of physiological inter-burst intervals (3-4 s) (Beenhakker et al, 2004;Colton and Nusbaum, 2014;Diehl et al, 2013;Saideman et al, 2007), gm5b reached a peak depolarization with the first EJP, while gm6ab and gm8a depolarization increased over several EJPs even at 2 s. This could result in a faster rising phase of a gm5b contraction relative to the other LG innervated muscles. However, at long inter-burst intervals, such as those in response to proprioceptive feedback (∼15-25 s) (DeLong and Nusbaum, 2010), gm5b EJPs undergo facilitation instead of depression. Thus, at these longer intervals, the gm5b muscle would likely also require multiple LG action potentials to reach a peak response, and result in similar contraction onset between the three LG innervated muscles.…”

Section: Physiological Activity Rangementioning

confidence: 99%

“…Diehl et al (2013) focused on distinctions in the pattern of spiking within LG bursts, but a number of other aspects of LG activity differ depending on modulatory state and the complement of inputs acting on LG. In response to a number of different modulatory inputs, LG activity consists of firing rates of 4-20 Hz (50-250 ms inter-spike intervals), burst durations of 2-8 s and interburst intervals of 2-24 s in vitro and in vivo (Beenhakker et al, 2004(Beenhakker et al, , 2005(Beenhakker et al, , 2007Blitz et al, 2004bBlitz et al, , 2008Colton and Nusbaum, 2014;DeLong and Nusbaum, 2010;Diehl et al, 2013;Hedrich et al, 2011;Kirby and Nusbaum, 2007;White and Nusbaum, 2011). Similar to central and peripheral synapses in other systems, electrical responses at neuromuscular junctions in the STNS are shaped by multiple forms of activity-dependent synaptic plasticity including depression, facilitation and augmentation (Daur et al, 2012b;Jorge-Rivera et al, 1998;Katz et al, 1993;Sen et al, 1996;Stein et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

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Muscles innervated by a single motor neuron exhibit divergent synaptic properties on multiple time scales

Blitz

Pritchard

Latimer

et al. 2017

Journal of Experimental Biology

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Adaptive changes in the output of neural circuits underlying rhythmic behaviors are relayed to muscles via motor neuron activity. Presynaptic and postsynaptic properties of neuromuscular junctions can impact the transformation from motor neuron activity to muscle response. Further, synaptic plasticity occurring on the time scale of inter-spike intervals can differ between multiple muscles innervated by the same motor neuron. In rhythmic behaviors, motor neuron bursts can elicit additional synaptic plasticity. However, it is unknown whether plasticity regulated by the longer time scale of inter-burst intervals also differs between synapses from the same neuron, and whether any such distinctions occur across a physiological activity range. To address these issues, we measured electrical responses in muscles innervated by a chewing circuit neuron, the lateral gastric (LG) motor neuron, in a well-characterized small motor system, the stomatogastric nervous system (STNS) of the Jonah crab, Cancer borealis. In vitro and in vivo, sensory, hormonal and modulatory inputs elicit LG bursting consisting of inter-spike intervals of 50-250 ms and inter-burst intervals of 2-24 s. Muscles expressed similar facilitation measured with paired stimuli except at the shortest interspike interval. However, distinct decay time constants resulted in differences in temporal summation. In response to bursting activity, augmentation occurred to different extents and saturated at different inter-burst intervals. Further, augmentation interacted with facilitation, resulting in distinct intra-burst facilitation between muscles. Thus, responses of multiple target muscles diverge across a physiological activity range as a result of distinct synaptic properties sensitive to multiple time scales.

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Hormonal Modulation of Sensorimotor Integration

Cited by 14 publications

References 59 publications

Functional consequences of neuropeptide and small-molecule co-transmission

Functional consequences of neuropeptide and small-molecule co-transmission

Consequences of acute and long-term removal of neuromodulatory input on the episodic gastric rhythm of the crabCancer borealis

Muscles innervated by a single motor neuron exhibit divergent synaptic properties on multiple time scales

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