Ontogeny of Modulatory Inputs to Motor Networks: Early Established Projection and Progressive Neurotransmitter Acquisition

Modulatory information plays a key role in the expression and the ontogeny of motor networks. Many developmental studies suggest that the acquisition of adult properties by immature networks involves their progressive innervation by modulatory input neurons. Using the stomatogastric nervous system of the European lobsterHomarus gammarus, we show that contrary to this assumption, the known population of projection neurons to motor networks, as revealed by retrograde dye migration, is established early in embryonic development. Moreover, these neurons display a large heterogeneity in the chronology of acquisition of their full adult neurotransmitter phenotype. We performed retrograde dye migration to compare the neuronal population projecting to motor networks located in the stomatogastric ganglion in the embryo and adult. We show that this neuronal population is quantitatively established at developmental stage 65%, and each identified projection neuron displays the same axon projection pattern in the adult and the embryo. We then combined retrograde dye migration with FLRFamide-like, histamine, and GABA immunocytochemistry to characterize the chronology of neurotransmitter expression in individual identified projection neurons. We show that this early established population of projection neurons gradually acquires its neurotransmitter phenotype complement. This study indicates that (1) the basic architecture of the known population of projection inputs to a target network is established early in development and (2) ontogenetic plasticity may depend on changes in neurotransmitter phenotype expression within preexisting neurons rather than in the addition of new projection neurons or fibers.

[1]  H. Joosten,et al.  The development of serotonergic raphespinal projections in Xenopus laevis , 1986, International Journal of Developmental Neuroscience.

[2]  E. Kravitz,et al.  Purification and characterization of FMRFamidelike immunoreactive substances from the lobster nervous system: Isolation and sequence analysis of two closely related peptides , 1987, The Journal of comparative neurology.

[3]  E. Marder,et al.  1 – Modulatory control of multiple task processing in the stomatogastric nervous system , 1992 .

[4]  R. Harris-Warrick,et al.  Serotonergic/cholinergic muscle receptor cells in the crab stomatogastric nervous system. II. Rapid nicotinic and prolonged modulatory effects on neurons in the stomatogastric ganglion. , 1989, Journal of neurophysiology.

[5]  M. Moulins,et al.  Nonlinear interneuronal properties underlie integrative flexibility in a lobster disynaptic sensorimotor pathway. , 1988, Journal of neurophysiology.

[6]  R. Harris-Warrick,et al.  Serotonergic/cholinergic muscle receptor cells in the crab stomatogastric nervous system. I. Identification and characterization of the gastropyloric receptor cells. , 1989, Journal of neurophysiology.

[7]  M. Moulins,et al.  Construction of a pattern-generating circuit with neurons of different networks , 1991, Nature.

[8]  J. Commissiong Development of catecholaminergic nerves in the spinal cord of the rat , 1983, Brain Research.

[9]  M. Moulins,et al.  Phylogenetic Plasticity of Crustacean Stomatogastric Circuits: I. Pyloric Patterns and Pyloric Circuit of the Shrimp Palaemon Serratus , 1988 .

[10]  R. Oppenheim,et al.  The onset and development of descending pathways to the spinal cord in the chick embryo , 1985, The Journal of comparative neurology.

[11]  G. Martin,et al.  Development of catecholaminergic projections to the spinal cord in the North American opossum, Didelphis virginiana , 1990, The Journal of comparative neurology.

[12]  E Marder,et al.  The actions of crustacean cardioactive peptide on adult and developing stomatogastric ganglion motor patterns. , 2000, Journal of neurobiology.

[13]  P. Skiebe Allatostatin‐like immunoreactivity in the stomatogastric nervous system and the pericardial organs of the crab Cancer pagurus, the lobster Homarus americanus, and the crayfish Cherax destructor and Procambarus clarkii , 1999, The Journal of comparative neurology.

[14]  N. Kudo,et al.  Development of descending fibers to the rat embryonic spinal cord , 1993, Neuroscience Research.

[15]  M. P. Nusbaum,et al.  Pyloric motor pattern modification by a newly identified projection neuron in the crab stomatogastric nervous system. , 1996, Journal of neurophysiology.

[16]  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.

[17]  M. Moulins,et al.  Identification of all GABA-immunoreactive neurons projecting to the lobster stomatogastric ganglion , 1990, Journal of neurocytology.

[18]  E Marder,et al.  Different Proctolin Neurons Elicit Distinct Motor Patterns from a Multifunctional Neuronal Network , 1999, The Journal of Neuroscience.

[19]  J. Ramirez,et al.  Reconfiguration of the neural network controlling multiple breathing patterns: eupnea, sighs and gasps , 2000, Nature Neuroscience.

[20]  N. Kudo,et al.  Reorganization of Locomotor Activity during Development in the Prenatal Rata , 1998, Annals of the New York Academy of Sciences.

[21]  S. Rossignol,et al.  Pharmacological Activation and Modulation of the Central Pattern Generator for Locomotion in the Cat a , 1998, Annals of the New York Academy of Sciences.

[22]  E Marder,et al.  Sequential developmental acquisition of neuromodulatory inputs to a central pattern‐generating network , 1999, The Journal of comparative neurology.

[23]  R. Harris-Warrick,et al.  Serotonergic innervation and modulation of the stomatogastric ganglion of three decapod crustaceans (Panulirus interruptus, Homarus americanus and Cancer irroratus). , 1984, The Journal of experimental biology.

[24]  P. Branchereau,et al.  Development of lumbar rhythmic networks: from embryonic to neonate locomotor-like patterns in the mouse , 2000, Brain Research Bulletin.

[25]  M. Moulins,et al.  PHYLOGENETIC PLASTICITY OF CRUSTACEAN STOMATOGASTRIC CIRCUITS II. EXTRINSIC INPUTS TO THE PYLORIC CIRCUIT OF THE SHRIMP PALAEMON SERRATUS , 1988 .

[26]  E. Marder,et al.  Distribution and effects of tachykinin‐like peptides in the stomatogastric nervous system of the crab, Cancer borealis , 1995, The Journal of comparative neurology.

[27]  K. Tazaki,et al.  Multiple motor patterns in the stomatogastric ganglion of the shrimp Penaeus japonicus , 2000, Journal of Comparative Physiology A.

[28]  M. Moulins,et al.  Suppressive control of the crustacean pyloric network by a pair of identified interneurons. I. Modulation of the motor pattern , 1990, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[29]  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.

[30]  R. Harris-Warrick,et al.  The evolution of neuronal circuits underlying species-specific behavior , 1999, Current Opinion in Neurobiology.

[31]  N. Okado,et al.  Immunohistochemical study on the development of serotoninergic neurons in the chick: II. Distribution of cell bodies and fibers in the spinal cord , 1986, The Journal of comparative neurology.

[32]  H. Donkelaar,et al.  Early development of descending pathways from the brain stem to the spinal cord in Xenopus laevis , 2004, Anatomy and Embryology.

[33]  G. Turrigiano,et al.  Distribution of cholecystokinin‐like immunoreactivity within the stomatogastric nervous systems of four species of decapod crustacea , 1991, The Journal of comparative neurology.

[34]  D Combes,et al.  Motor Pattern Specification by Dual Descending Pathways to a Lobster Rhythm-Generating Network , 1999, The Journal of Neuroscience.

[35]  Marco Capogna,et al.  Miniature synaptic events maintain dendritic spines via AMPA receptor activation , 1999, Nature Neuroscience.

[36]  E Marder,et al.  Encoding of muscle movement on two time scales by a sensory neuron that switches between spiking and bursting modes. , 1999, Journal of neurophysiology.

[37]  G. Martin,et al.  Developmental sequence in the origin of descending spinal pathways. Studies using retrograde transport techniques in the North American opossum (Didelphis virginiana). , 1984, Brain research.

[38]  M. Moulins,et al.  Dynamic construction of a neural network from multiple pattern generators in the lobster stomatogastric nervous system , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[39]  R. Harris-Warrick In: Dynamic Biological Networks: The Stomatogastric Nervous System , 1992 .

[40]  H. J. Donkelaar Development and Regenerative Capacity of Descending Supraspinal Pathways in Tetrapods: A Comparative Approach , 2000, Advances in Anatomy Embryology and Cell Biology.

[41]  E Marder,et al.  Sequential developmental acquisition of cotransmitters in identified sensory neurons of the stomatogastric nervous system of the lobsters, Homarus americanus and Homarus gammarus , 1999, The Journal of comparative neurology.

[42]  Pierre Meyrand,et al.  Central inputs mask multiple adult neural networks within a single embryonic network , 1999, Nature.

[43]  S. Faumont,et al.  Ontogenetic alteration in peptidergic expression within a stable neuronal population in lobster stomatogastric nervous system , 1998, The Journal of comparative neurology.

[44]  M. Geffard,et al.  Pre‐ and post‐natal ontogeny of serotonergic projections to the rat spinal cord , 1989, Journal of neuroscience research.

[45]  Z. Henderson Early development of the nucleus basalis-cortical projection but late expression of its cholinergic function , 1991, Neuroscience.

[46]  P. Meyrand,et al.  Development of rhythmic pattern generators , 1998, Current Opinion in Neurobiology.

[47]  K. Sillar,et al.  Descending serotonergic spinal projections and modulation of locomotor rhythmicity in Rana temporaria embryos , 1994, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[48]  E. Marder,et al.  Development of the peptidergic modulation of a rhythmic pattern generating network , 1999, Brain Research.

[49]  I. Cournil,et al.  Dopamine in the lobster Homarus gammarus: II. Dopamine‐immunoreactive neurons and development of the nervous system , 1995, The Journal of comparative neurology.

[50]  M J Coleman,et al.  Functional consequences of compartmentalization of synaptic input , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[51]  S. Inagaki,et al.  Ontogeny of the peptidergic system in the rat spinal cord: Immunohistochemical analysis , 1982, The Journal of comparative neurology.

[52]  K. Sillar,et al.  Development and Aminergic Neuromodulation of a Spinal Locomotor Network Controlling Swimming in Xenopus Larvae a , 1998, Annals of the New York Academy of Sciences.

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

[54]  B. Beltz,et al.  Embryonic Development of the American Lobster (Homarus americanus): Quantitative Staging and Characterization of an Embryonic Molt Cycle. , 1991, The Biological bulletin.

[55]  I. Cournil,et al.  A rhythmic modulatory gating system in the stomatogastric nervous system of Homarus gammarus. I. Pyloric-related neurons in the commissural ganglia. , 1994, Journal of neurophysiology.

[56]  M. P. Nusbaum,et al.  Distribution of modulatory inputs to the stomatogastric ganglion of the crab, Cancer borealis , 1992, The Journal of comparative neurology.

[57]  A method for the determination of projection areas of GABA immunoreactive neurons in the invertebrate nervous system , 1991, Journal of Neuroscience Methods.

[58]  S. Faumont,et al.  Species‐specific modulation of pattern‐generating circuits , 2000, The European journal of neuroscience.