Pyramidal cell axons show a local specialization for GABA and 5‐HT inputs in monkey and human cerebral cortex

Various mechanisms are thought to control excitation of pyramidal cells of the cerebral cortex. With immunocytochemical methods, we found that the proximal portions of numerous pyramidal cell axons (Pyr‐axons) in the human and monkey neocortex are immunoreactive for the serotonin (5‐HT) receptor 5‐HT‐1A. With double‐labeling experiments and confocal laser microscopy, we found that most (93.4%) of the 5‐HT1A–immunoreactive Pyr‐axons present in layers II and III were innervated by parvalbumin‐immunoreactive chandelier cell axon terminals. In addition, Pyr‐axons were compartmentalized: 5‐HT‐1A receptors were found proximal to inputs from chandelier cells. Although we found close appositions between GABAergic chandelier cell axon terminals and Pyr‐axons, suggesting synaptic connections, we did not observe 5‐HT–immunoreactive fibers in close proximity to the Pyr‐axons. These results suggested that Pyr‐axons are under the influence of 5‐HT in a paracrine manner (via 5‐HT‐1A receptors) and, more distally, are under the influence of γ‐aminobutyric acid (GABA) in a synaptic manner (through the axons of chandelier cells). The local axonal specialization might represent a powerful inhibitory mechanism by which the responses of large populations of pyramidal cells can be globally controlled by subcortical serotonin afferents, in addition to local inputs from GABAergic interneurons. J. Comp. Neurol. 433:148–155, 2001. © 2001 Wiley‐Liss, Inc.

[1]  P. Goldman-Rakic,et al.  Segregation of serotonin 5‐HT2A and 5‐HT3 receptors in inhibitory circuits of the primate cerebral cortex , 2000, The Journal of comparative neurology.

[2]  J. DeFelipe Chandelier cells and epilepsy. , 1999, Brain : a journal of neurology.

[3]  G. Elston,et al.  Distribution and patterns of connectivity of interneurons containing calbindin, calretinin, and parvalbumin in visual areas of the occipital and temporal lobes of the macaque monkey , 1999, The Journal of comparative neurology.

[4]  R. Wightman,et al.  Paracrine neurotransmission in the CNS: involvement of 5-HT , 1999, Trends in Neurosciences.

[5]  J. Raymond,et al.  The recombinant 5‐HT1A receptor: G protein coupling and signalling pathways , 1999, British journal of pharmacology.

[6]  N. Newberry,et al.  Actions of 5-HT on human neocortical neurones in vitro , 1999, Brain Research.

[7]  D. Contreras,et al.  Spatiotemporal Analysis of Local Field Potentials and Unit Discharges in Cat Cerebral Cortex during Natural Wake and Sleep States , 1999, The Journal of Neuroscience.

[8]  D. Lewis,et al.  Parvalbumin‐immunoreactive axon terminals in macaque monkey and human prefrontal cortex: Laminar, regional, and target specificity of type I and type II synapses , 1999, The Journal of comparative neurology.

[9]  P. Pauwels,et al.  Autoradiographic studies of 5‐HT1A‐receptor‐stimulated [35S]GTPγS‐binding responses in the human and monkey brain , 1999, The European journal of neuroscience.

[10]  P S Goldman-Rakic,et al.  5-Hydroxytryptamine2A serotonin receptors in the primate cerebral cortex: possible site of action of hallucinogenic and antipsychotic drugs in pyramidal cell apical dendrites. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[11]  A. Wenzel,et al.  Synapse‐specific localization of NMDA and GABAA receptor subunits revealed by antigen‐retrieval immunohistochemistry , 1998, The Journal of comparative neurology.

[12]  L. JakabR,et al.  霊長類大脳皮質の5‐ヒドロキシトリプタミン2Aセロトニン受容体 錐体細胞先端樹状突起での幻覚剤及び抗精神病剤の作用部位 , 1998 .

[13]  H. Haas,et al.  5-HT inhibits lateral entorhinal cortical neurons of the rat in vitro by activation of potassium channel-coupled 5-HT1A receptors , 1997, Brain Research.

[14]  E. Azmitia,et al.  Molecular characterization of antipeptide antibodies against the 5-HT1A receptor: evidence for state-dependent antibody binding. , 1997, Brain research. Molecular brain research.

[15]  A. Deutch,et al.  Serotonin 5‐HT2A receptors are expressed on pyramidal cells and interneurons in the rat cortex , 1997, Synapse.

[16]  M. Buhot Serotonin receptors in cognitive behaviors , 1997, Current Opinion in Neurobiology.

[17]  D. Johnston,et al.  Axonal Action-Potential Initiation and Na+ Channel Densities in the Soma and Axon Initial Segment of Subicular Pyramidal Neurons , 1996, The Journal of Neuroscience.

[18]  R G Sola,et al.  Inhibitory neurons in the human epileptogenic temporal neocortex. An immunocytochemical study. , 1996, Brain : a journal of neurology.

[19]  D Contreras,et al.  Mechanisms of long‐lasting hyperpolarizations underlying slow sleep oscillations in cat corticothalamic networks. , 1996, The Journal of physiology.

[20]  P. Goldman-Rakic,et al.  Serotonergic axons in monkey prefrontal cerebral cortex synapse predominantly on interneurons as demonstrated by serial section electron microscopy , 1996, The Journal of comparative neurology.

[21]  E. Azmitia,et al.  Cellular Localization of the 5-HT1A Receptor in Primate Brain Neurons and Glial Cells , 1996, Neuropsychopharmacology.

[22]  E. Azmitia,et al.  5‐HT1A receptor localization on the axon hillock of cervical spinal motoneurons in primates , 1995, The Journal of comparative neurology.

[23]  J. de Vry 5-HT1A receptor agonists: recent developments and controversial issues. , 1995, Psychopharmacology.

[24]  P P Humphrey,et al.  International Union of Pharmacology classification of receptors for 5-hydroxytryptamine (Serotonin). , 1994, Pharmacological reviews.

[25]  J DeFelipe,et al.  A study of SMI 32‐stained pyramidal cells, parvalbumin‐immunoreactive chandelier cells, and presumptive thalamocortical axons in the human temproal neocortex , 1994, The Journal of comparative neurology.

[26]  P. Somogyi,et al.  Physiological properties of anatomically identified axo-axonic cells in the rat hippocampus. , 1994, Journal of neurophysiology.

[27]  B. Sakmann,et al.  Active propagation of somatic action potentials into neocortical pyramidal cell dendrites , 1994, Nature.

[28]  E. Azmitia,et al.  Antipeptide antibodies against the 5-HT1A receptor , 1992, Journal of Chemical Neuroanatomy.

[29]  P. Goldman-Rakic,et al.  The synaptology of parvalbumin‐immunoreactive neurons in the primate prefrontal cortex , 1992, The Journal of comparative neurology.

[30]  J. DeFelipe,et al.  Synaptic relationships of serotonin-immunoreactive terminal baskets on GABA neurons in the cat auditory cortex. , 1991, Cerebral cortex.

[31]  I Fariñas,et al.  Patterns of synaptic input on corticocortical and corticothalamic cells in the cat visual cortex. II. The axon initial segment , 1991, The Journal of comparative neurology.

[32]  S. Peroutka Serotonin receptor subtypes : basic and clinical aspects , 1991 .

[33]  I. Divac Cortical circuits: Synaptic organization of the cerebral cortex. Structure, function and theory by Edward L. White, Birkäuser, 1989. Sw. fr. 88.00 (xvi + 223 pages) ISBN 3 7643 3402 9 , 1990, Trends in Neurosciences.

[34]  T. Segawa,et al.  [5-Hydroxytryptamine receptors]. , 1989, Nihon yakurigaku zasshi. Folia pharmacologica Japonica.

[35]  E G Jones,et al.  Visualization of chandelier cell axons by parvalbumin immunoreactivity in monkey cerebral cortex. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[36]  J. Palacios,et al.  Serotonin receptors in the human brain—III. Autoradiographic mapping of serotonin-1 receptors , 1987, Neuroscience.

[37]  E. Azmitia,et al.  The primate serotonergic system: a review of human and animal studies and a report on Macaca fascicularis. , 1986, Advances in neurology.

[38]  P. Somogyi,et al.  Identified axo-axonic cells are immunoreactive for GABA in the hippocampus visual cortex of the cat , 1985, Brain Research.

[39]  D. Schmechel,et al.  Variability in the terminations of GABAergic chandelier cell axons on initial segments of pyramidal cell axons in the monkey sensory‐motor cortex , 1985, The Journal of comparative neurology.

[40]  P. Somogyi,et al.  Glutamate decarboxylase‐immunoreactive terminals of Golgi‐impregnated axoaxonic cells and of presumed basket cells in synaptic contact with pyramidal neurons of the cat's visual cortex , 1983, The Journal of comparative neurology.

[41]  P. Somogyi,et al.  Synaptic connections of morphologically identified and physiologically characterized large basket cells in the striate cortex of cat , 1983, Neuroscience.

[42]  P. Somogyi,et al.  Glutamate decarboxylase immunoreactivity in the hippocampus of the cat: distribution of immunoreactive synaptic terminals with special reference to the axon initial segment of pyramidal neurons , 1983, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[43]  A. Cowey,et al.  The axo-axonic interneuron in the cerebral cortex of the rat, cat and monkey , 1982, Neuroscience.

[44]  A. Peters,et al.  Chandelier cells in rat visual cortex , 1982, The Journal of comparative neurology.

[45]  F. Valverde,et al.  A specialized type of neuron in the visual cortex of cat: A Golgi and electron microscope study of chandelier cells , 1980, The Journal of comparative neurology.

[46]  T. Powell,et al.  A study of the axon initial segment and proximal axon of neurons in the primate motor and somatic sensory cortices. , 1979, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[47]  Ronald M. Harper,et al.  Dorsal raphe neurons: depression of firing during sleep in cats , 1976, Brain Research.

[48]  M. Arbib,et al.  Conceptual models of neural organization. , 1974, Neurosciences Research Program bulletin.

[49]  S Garattini,et al.  Electrical stimulation of midbrain raphe: biochemical, behavioral and bioelectrical effects. , 1969, European journal of pharmacology.

[50]  J. Fallon,et al.  Monoamine Innervation of Cerebral Cortex and a Theory of the Role of Monoamines in Cerebral Cortex and Basal Ganglia , 1932 .