Recovery of rhythmic activity in a central pattern generator: analysis of the role of neuromodulator and activity-dependent mechanisms

The pyloric network of decapods crustaceans can undergo dramatic rhythmic activity changes. Under normal conditions the network generates low frequency rhythmic activity that depends obligatorily on the presence of neuromodulatory input from the central nervous system. When this input is removed (decentralization) the rhythmic activity ceases. In the continued absence of this input, periodic activity resumes after a few hours in the form of episodic bursting across the entire network that later turns into stable rhythmic activity that is nearly indistinguishable from control (recovery). It has been proposed that an activity-dependent modification of ionic conductance levels in the pyloric pacemaker neuron drives the process of recovery of activity. Previous modeling attempts have captured some aspects of the temporal changes observed experimentally, but key features could not be reproduced. Here we examined a model in which slow activity-dependent regulation of ionic conductances and slower neuromodulator-dependent regulation of intracellular Ca2+ concentration reproduce all the temporal features of this recovery. Key aspects of these two regulatory mechanisms are their independence and their different kinetics. We also examined the role of variability (noise) in the activity-dependent regulation pathway and observe that it can help to reduce unrealistic constraints that were otherwise required on the neuromodulator-dependent pathway. We conclude that small variations in intracellular Ca2+ concentration, a Ca2+ uptake regulation mechanism that is directly targeted by neuromodulator-activated signaling pathways, and variability in the Ca2+ concentration sensing signaling pathway can account for the observed changes in neuronal activity. Our conclusions are all amenable to experimental analysis.

[1]  HighWire Press Philosophical Transactions of the Royal Society of London , 1781, The London Medical Journal.

[2]  Michael J. O'Donovan,et al.  Mechanisms of spontaneous activity in developing spinal networks. , 1998, Journal of neurobiology.

[3]  M. Savignac,et al.  Ca2+-operated transcriptional networks: molecular mechanisms and in vivo models. , 2008, Physiological reviews.

[4]  J. Simmers,et al.  Transition to endogenous bursting after long-term decentralization requires De novo transcription in a critical time window. , 2000, Journal of neurophysiology.

[5]  N. Spitzer,et al.  Action potentials, calcium transients and the control of differentiation of excitable cells , 1994, Current Opinion in Neurobiology.

[6]  S. Hong,et al.  Activity-dependent reduction in voltage-dependent calcium current in a crayfish motoneuron , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[7]  A. Firth,et al.  Activated expression of cardiac adenylyl cyclase 6 reduces dilation and dysfunction of the pressure-overloaded heart. , 2011, Biochemical and biophysical research communications.

[8]  M. Brunelli,et al.  Cyclic AMP mediates inhibition of the Na(+)‐K+ electrogenic pump by serotonin in tactile sensory neurones of the leech. , 1993, The Journal of physiology.

[9]  G. Inesi,et al.  Silencing calcineurin A subunit reduces SERCA2 expression in cardiac myocytes. , 2011, American journal of physiology. Heart and circulatory physiology.

[10]  V. Shahrezaei,et al.  The stochastic nature of biochemical networks. , 2008, Current opinion in biotechnology.

[11]  E Marder,et al.  Proctolin activates an inward current whose voltage dependence is modified by extracellular Ca2+ , 1992, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[12]  Eve Marder,et al.  Network Stability from Activity-Dependent Regulation of Neuronal Conductances , 1999, Neural Computation.

[13]  E. Marder,et al.  Episodic bouts of activity accompany recovery of rhythmic output by a neuromodulator- and activity-deprived adult neural network. , 2003, Journal of neurophysiology.

[14]  K. Campbell,et al.  Ca‐ATPase isozyme expression in sarcoplasmic reticulum is altered by chronic stimulation of skeletal muscle , 1990, FEBS letters.

[15]  A. Wechsler,et al.  Transcriptional regulation of phospholamban gene and translational regulation of SERCA2 gene produces coordinate expression of these two sarcoplasmic reticulum proteins during skeletal muscle phenotype switching , 1995, The Journal of Biological Chemistry.

[16]  P. Meyrand,et al.  Functional differentiation of adult neural circuits from a single embryonic network , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[17]  A. Selverston,et al.  The Crustacean stomatogastric system : a model for the study of central nervous systems , 1987 .

[18]  R. Pilz,et al.  This Review Is Part of a Thematic Series on Cyclic Gmp–generating Enzymes and Cyclic Gmp–dependent Signaling, Which Includes the following Articles: Regulation of Nitric Oxide–sensitive Guanylyl Cyclase Cyclic Gmp Phosphodiesterases and Regulation of Smooth Muscle Function Structure, Regulation, and , 2022 .

[19]  D. McCrea,et al.  Organization of mammalian locomotor rhythm and pattern generation , 2008, Brain Research Reviews.

[20]  Bard Ermentrout,et al.  Simulating, analyzing, and animating dynamical systems - a guide to XPPAUT for researchers and students , 2002, Software, environments, tools.

[21]  R. Yuste,et al.  Neuronal domains in developing neocortex: Mechanisms of coactivation , 1995, Neuron.

[22]  Hans Forssberg,et al.  Anatomical and physiological evidence for D1 and D2 dopamine receptor colocalization in neostriatal neurons , 2000, Nature Neuroscience.

[23]  A. Selverston,et al.  Invertebrate central pattern generator circuits , 2010, Philosophical Transactions of the Royal Society B: Biological Sciences.

[24]  G. Lnenicka,et al.  Activity-Dependent Development of Calcium Regulation in Growing Motor Axons , 1998, The Journal of Neuroscience.

[25]  D. F. Russell CNS control of pattern generators in the lobster stomatogastric ganglion , 1979, Brain Research.

[26]  T. Hwa,et al.  Stochastic fluctuations in metabolic pathways , 2007, Proceedings of the National Academy of Sciences.

[27]  Jorge Golowasch,et al.  Modeling recovery of rhythmic activity: Hypothesis for the role of a calcium pump , 2007, Neurocomputing.

[28]  E. Marder Motor pattern generation , 2000, Current Opinion in Neurobiology.

[29]  N. Alpert,et al.  Regulation of myocardial Ca2+-ATPase and phospholamban mRNA expression in response to pressure overload and thyroid hormone. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[30]  Eve Marder,et al.  Animal-to-Animal Variability in Motor Pattern Production in Adults and during Growth , 2005, The Journal of Neuroscience.

[31]  Michael J. O'Donovan The origin of spontaneous activity in developing networks of the vertebrate nervous system , 1999, Current Opinion in Neurobiology.

[32]  O. Garaschuk,et al.  Developmental profile and synaptic origin of early network oscillations in the CA1 region of rat neonatal hippocampus , 1998, The Journal of physiology.

[33]  Jan-Marino Ramirez,et al.  Stabilization of Bursting in Respiratory Pacemaker Neurons , 2003, The Journal of Neuroscience.

[34]  J. Simmers,et al.  Neuromodulatory Inputs Maintain Expression of a Lobster Motor Pattern-Generating Network in a Modulation-Dependent State: Evidence from Long-Term Decentralization In Vitro , 1998, The Journal of Neuroscience.

[35]  M. Brunelli,et al.  Serotonin depresses the after-hyperpolarization through the inhibition of the Na+/K+ electrogenic pump in T sensory neurones of the leech. , 1991, The Journal of experimental biology.

[36]  Jie Liang,et al.  An optimal algorithm for enumerating state space of stochastic molecular networks with small copy numbers of molecules , 2007, 2007 29th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[37]  J. Golowasch,et al.  Activity and neuromodulatory input contribute to the recovery of rhythmic output after decentralization in a central pattern generator. , 2009, Journal of neurophysiology.

[38]  Molecular Commonalities of Cellular Rhythms in Cardiac and Nervous Systems , 2004 .

[39]  E. Marder,et al.  Principles of rhythmic motor pattern generation. , 1996, Physiological reviews.

[40]  Michael J. O'Donovan,et al.  Episodic activity in a heterogeneous excitatory network, from spiking neurons to mean field , 2008, Journal of Computational Neuroscience.

[41]  C. Brandl,et al.  Slow/cardiac sarcoplasmic reticulum Ca2+-ATPase and phospholamban mRNAs are expressed in chronically stimulated rabbit fast-twitch muscle. , 1989, European journal of biochemistry.

[42]  E Marder,et al.  Multiple Peptides Converge to Activate the Same Voltage-Dependent Current in a Central Pattern-Generating Circuit , 2000, The Journal of Neuroscience.

[43]  Jorge Golowasch,et al.  Ionic mechanism underlying recovery of rhythmic activity in adult isolated neurons. , 2006, Journal of neurophysiology.

[44]  M. MacKay-Lyons Central pattern generation of locomotion: a review of the evidence. , 2002, Physical therapy.

[45]  E. Marder,et al.  Central pattern generators and the control of rhythmic movements , 2001, Current Biology.

[46]  A. Therien,et al.  Mechanisms of sodium pump regulation. , 2000, American journal of physiology. Cell physiology.

[47]  John Simmers,et al.  Long-term neuromodulatory regulation of a motor pattern-generating network: maintenance of synaptic efficacy and oscillatory properties. , 2002, Journal of neurophysiology.

[48]  G. Schafe,et al.  Synaptic plasticity and NO-cGMP-PKG signaling coordinately regulate ERK-driven gene expression in the lateral amygdala and in the auditory thalamus following Pavlovian fear conditioning. , 2010, Learning & memory.

[49]  Ronald L Calabrese,et al.  Myomodulin increases Ih and inhibits the NA/K pump to modulate bursting in leech heart interneurons. , 2005, Journal of neurophysiology.

[50]  T. Murphy,et al.  Spontaneous synchronous synaptic calcium transients in cultured cortical neurons , 1992, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[51]  G. Boss,et al.  cGMP-dependent Protein Kinase Inhibits Serum-response Element-dependent Transcription by Inhibiting Rho Activation and Functions* , 2002, The Journal of Biological Chemistry.

[52]  P. Hamet,et al.  GREBP, a cGMP-response Element-binding Protein Repressing the Transcription of Natriuretic Peptide Receptor 1 (NPR1/GCA)* , 2010, The Journal of Biological Chemistry.

[53]  N. Spitzer,et al.  Spontaneous neuronal calcium spikes and waves during early differentiation , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[54]  D. Baylor,et al.  Synchronous bursts of action potentials in ganglion cells of the developing mammalian retina. , 1991, Science.

[55]  L. Jones,et al.  Phospholamban: protein structure, mechanism of action, and role in cardiac function. , 1998, Physiological reviews.

[56]  Jorge Golowasch,et al.  Neuromodulators, Not Activity, Control Coordinated Expression of Ionic Currents , 2007, The Journal of Neuroscience.

[57]  C. Shatz,et al.  Early functional neural networks in the developing retina , 1995, Nature.