Ontogenesis of the pyramidal cell of the mammalian neocortex and developmental cytoarchitectonics: A unifying theory

The prenatal development of the mammalian neocortex has been analyzed, with the rapid Golgi method, in a variety of experimental animals (hamster, mouse, rat, and cat) and in humans. A new developmental conception of the structural organization of the mammalian neocortex is discussed. Neocortical development begins with the establishment of the primordial plexiform layer (PPL) which precedes and is a prerequisite for the subsequent formation of the cortical plate (CP). The formation of the CP occurs, in its entirety, within the PPL. During its development, three fundamental neuronal events occur: migration, early differentiation, and late maturation. All migrating neurons, travelling on radial glial fibers, reach layer I, develop an apical dendrite, and establish contacts with its elements. These newly differentiated neurons assume similar morphology resembling embryonic pyramidal cells. As such, an early differentiation stage common to all neurons of the CP is established. During the late maturation stage, all CP neurons acquire their specific phenotypic structural and functional features. Only pyramidal neurons retain and expand their original connections with layer I while other neuronal types lose these connections. The pyramidal cell is redefined in developmental terms: the neocortex's pyramidal cell is both structurally and functionally locked into position between layer I and the cortical depth of its soma. During mammalian evolution pyramidal cells are forced to structurally and functionally elongate their apical dendrite outwardly to accommodate an increasing amount of information without losing either their original anchorage to layer I or their cortical depth. This unique property of pyramidal neurons is considered to be a mammalian innovation. Based on these observations, a unifying developmental cytoarchitectonic theory applicable to all mammals is proposed. The theory considers the CP to be a mammalian innovation and to represent a single, stratified, and expanding telencephalic nucleus. The theory envisions the mammalian neocortex as an open biological system capable of progressive expansion by the recruitment and transformation of primitive neurons from upper layer II into pyramidal cells. Hence, the number of pyramidal cell strata increases over the course of mammalian phylogeny. The developmental roles of layer I in the migration of neurons, formation of the CP, unique morphology of pyramidal cells, and overall structural organization of the mammalian neocortex are emphasized. © 1992 Wiley‐Liss, Inc.

[1]  P. Morgane,et al.  Comparative and Evolutionary Anatomy of the Visual Cortex of the Dolphin , 1990 .

[2]  G. Shoukimas,et al.  The development of the cerebral cortex in the embryonic mouse: An electron microscopic serial section analysis , 1978, The Journal of comparative neurology.

[3]  A. Kriegstein,et al.  Initial expression and endogenous activation of NMDA channels in early neocortical development , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[4]  M. Miller,et al.  Development of Projection and Local Circuit Neurons in Neocortex , 1988 .

[5]  M. Marín‐padilla Embryonic Vascularization of the Mammalian Cerebral Cortex , 1988 .

[6]  I N FILIMONOFF,et al.  A rational subdivision of the cerebral cortex. , 1947, Archives of neurology and psychiatry.

[7]  T. Neary The Pallium of Anuran Amphibians , 1990 .

[8]  C. Shatz,et al.  Subplate neurons pioneer the first axon pathway from the cerebral cortex. , 1989, Science.

[9]  J. Altman,et al.  Development of layer I and the subplate in the rat neocortex , 1990, Experimental Neurology.

[10]  T. P. S. Powell,et al.  Similarity in number of neurons through the depth of the cortex in the binocular and monocular parts of area 17 of the monkey , 1981, Brain Research.

[11]  J. Altman,et al.  Cell migration in the rat embryonic neocortex , 1991, The Journal of comparative neurology.

[12]  Aström Ke On the Early Development of the Isocortex in Fetal Sheep , 1967 .

[13]  Garey Lj,et al.  The development of dendritic spines in the human visual cortex. , 1984 .

[14]  S. Easter,et al.  The development of the Xenopus retinofugal pathway: optic fibers join a pre-existing tract. , 1989, Development.

[15]  M. Norman,et al.  The Growth and Development of Microvasculature in Human Cerebral Cortex , 1986, Journal of neuropathology and experimental neurology.

[16]  M Marín-Padilla The pyramidal cell and its local-circuit interneurons: a hypothetical unit of the Mammalian cerebral cortex. , 1990, Journal of cognitive neuroscience.

[17]  R L Sidman,et al.  Histogenesis of cortical layers in human cerebellum, particularly the lamina dissecans , 1970, The Journal of comparative neurology.

[18]  C. Shatz,et al.  Studies of the earliest generated cells of the cat's visual cortex: cogeneration of subplate and marginal zones , 1985, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[19]  T. Powell,et al.  The basic uniformity in structure of the neocortex. , 1980, Brain : a journal of neurology.

[20]  Pasko Rakic,et al.  Cytology and time of origin of interstitial neurons in the white matter in infant and adult human and monkey telencephalon , 1980, Journal of neurocytology.

[21]  G. Stibitz,et al.  Spine distribution of the layer V pyramidal cell in man: a cortical model. , 1969, Brain research.

[22]  H. Uylings,et al.  GROWTH AND PLASTICITY OF CORTICAL DENDRITES , 1981 .

[23]  H. Uylings,et al.  Neuronal development in human prefrontal cortex in prenatal and postnatal stages. , 1990, Progress in brain research.

[24]  M. Marín‐padilla Central Nervous System: Structure versus Injury and Regeneration versus Recovery , 1992 .

[25]  M. Marín‐padilla Early vascularization of the embryonic cerebral cortex: Golgi and electron microscopic studies , 1985, The Journal of comparative neurology.

[26]  G. Hutchins,et al.  Computer ranking of the sequence of appearance of 73 features of the brain and related structures in staged human embryos during the sixth week of development. , 1987, The American journal of anatomy.

[27]  G Meyer,et al.  Forms and spatial arrangement of neurons in the primary motor cortex of man , 1987, The Journal of comparative neurology.

[28]  E. G. Jones,et al.  Modulatory Events in the Development and Evolution of Primate Neocortex , 1990 .

[29]  M Marin-Padilla,et al.  Number and distribution of the apical dendritic spines of the layer V pyramidal cells in man , 1967, The Journal of comparative neurology.

[30]  A. Fairén,et al.  Times of generation of glutamic acid decarboxylase immunoreactive neurons in mouse somatosensory cortex , 1986, The Journal of comparative neurology.

[31]  Stephen W. Wilson,et al.  The development of a simple scaffold of axon tracts in the brain of the embryonic zebrafish, Brachydanio rerio. , 1990, Development.

[32]  L. Becker,et al.  Morphology of the Developing Visual Cortex of the Human Infant: A Quantitative and Qualitative Golgi Study , 1980, Journal of neuropathology and experimental neurology.

[33]  A. Peters,et al.  Organization of pyramidal neurons in area 17 of monkey visual cortex , 1991, The Journal of comparative neurology.

[34]  J. Price,et al.  Clustering of dendrites in the cerebral cortex begins in the embryonic cortical plate , 1991, Journal of neurocytology.

[35]  G. I. Poliakov Some results of research into the development of the neuronal structure of the cortical ends of the analyzers in man , 1961, The Journal of comparative neurology.

[36]  M. Marín‐Padilla,et al.  Early Ontogenesis of the Human Cerebral Cortex , 1988 .

[37]  F. Ebner A COMPARISON OF PRIMITIVE FOREBRAIN ORGANIZATION IN METATHERIAN AND EUTHERIAN MAMMALS * , 1969 .

[38]  G R Stibitz,et al.  Distribution of the apical dendritic spines of the layer V pyramidal cells of the hamster neocortex. , 1968, Brain research.

[39]  R. Porter,et al.  Morphology of neurons in area 4γ of the cat's cortex studied with intracellular injection of HRP , 1988 .

[40]  S. Fujita The matrix cell and cytogenesis in the developing central nervous system , 1963, The Journal of comparative neurology.

[41]  Carla J. Shatz,et al.  The Role of the Subplate in the Development of the Mammalian Telencephalon , 1988 .

[42]  M. Marín‐Padilla,et al.  Prenatal and early postnatal ontogenesis of the human motor cortex: a golgi study. I. The sequential development of the cortical layers. , 1970, Brain research.

[43]  M Marín-Padilla,et al.  Three‐dimensional structural organization of layer I of the human cerebral cortex: A golgi study , 1990, The Journal of comparative neurology.

[44]  M. Marín‐padilla Neurogenesis of the climbing fibers in the human cerebellum: A Golgi study , 1985, The Journal of comparative neurology.

[45]  P. Rakić Mode of cell migration to the superficial layers of fetal monkey neocortex , 1972, The Journal of comparative neurology.

[46]  O. Steward,et al.  Differential subcellular localization of tubulin and the microtubule- associated protein MAP2 in brain tissue as revealed by immunocytochemistry with monoclonal hybridoma antibodies , 1984, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[47]  N. König,et al.  The time of origin of Cajal-Retzius cells in the rat temporal cortex. An autoradiographic study , 1977, Neuroscience Letters.

[48]  F. Valverde,et al.  Intrinsic neocortical organization: Some comparative aspects , 1986, Neuroscience.

[49]  I. Kostović,et al.  Prenatal development of neurons in the human prefrontal cortex: I. A qualitative Golgi study , 1988, The Journal of comparative neurology.

[50]  M. Marín‐padilla Prenatal and early postnatal ontogenesis of the human motor cortex: a golgi study. II. The basket-pyramidal system. , 1970, Brain research.

[51]  P. Rakić,et al.  Developmental history of the transient subplate zone in the visual and somatosensory cortex of the macaque monkey and human brain , 1990, The Journal of comparative neurology.

[52]  V S Caviness,et al.  Dynamic structure of the radial glial fiber system of the developing murine cerebral wall. An immunocytochemical analysis. , 1989, Brain research. Developmental brain research.