Anatomical Gradients in Proliferation and Differentiation of Embryonic Rat CNS Accessed by Buoyant Density Fractionation: α3, β3 and γ2 GABAA Receptor Subunit Co‐expression by Post‐mitotic Neocortical Neurons Correlates Directly with Cell Buoyancy

Development of the CNS occurs as complex cascade of pre‐programmed events involving distinct phases of cell proliferation and differentiation. Here we show these phases correlate with cells of specific buoyant densities which can be readily accessed by density gradient fractionation. Sprague‐Dawley dams were pulse‐labelled with bromodeoxyuridine (BrdU) and selected regions of embryonic (E) CNS tissues at El1–22 dissociated with papain into single‐cell suspensions. Proliferative cell populations were assessed by anti‐BrdU and propidium iodide staining using flow cytometry. Cell differentiation was evaluated using molecular and immunocytochemical probes against mRNAs and antigens differentiating the neuroepithelial, neuronal and glial cell lineages. The results show the emergence of distinctive spatiotemporal changes in BrdU+ populations throughout the CNS during embryonic development, which were followed by corresponding changes in the cellular distributions of antigens distinguishing specific cell types. Fractionation of neocortical cells using discontinuous Percoll gradients revealed that an increasing number of cells increase their buoyancy during corticogenesis. Immunocytochemical and molecular characterization showed that the proliferative and progenitor cell populations are for the most part associated with lower buoyancy or higher specific buoyant densities (> 1.056 g/ml) whereas the post‐mitotic, differentiated neurons generally separated into fractions of higher buoyancy or lower specific buoyant densities (<1.043 g/ml). Immunostaining with antibodies against several GABAA receptor subunits (α3, β3, γ2) revealed that the highest percent (70–90%) of immunopositive cells could be identified in the most buoyant, differentiating neurons found in the cortical plate/subplate regions, with the lowest percent of the immunopositive cells found in the least buoyant, proliferative and progenitor cell populations originating from the ventricular/subventricular zones. Taken together, these results indicate that buoyant density is distinguishing characteristic of embryonic CNS cells transforming from primarily proliferative to mainly differentiating, and that fractionation of these cells according to their buoyant densities provides rapid access to the properties of specific cell lineages during the prenatal period of CNS development.

[1]  J. Barker,et al.  GABA stimulates chemotaxis and chemokinesis of embryonic cortical neurons via calcium-dependent mechanisms , 1996, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[2]  W. Sieghart,et al.  Colocalization of GABA, glycine, and their receptors at synapses in the rat spinal cord , 1996, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[3]  A. Kriegstein,et al.  GABA and glutamate depolarize cortical progenitor cells and inhibit DNA synthesis , 1995, Neuron.

[4]  J. Fritschy,et al.  GABAA‐receptor heterogeneity in the adult rat brain: Differential regional and cellular distribution of seven major subunits , 1995, The Journal of comparative neurology.

[5]  J. Barker,et al.  Developmental kinetics of GAD family mRNAs parallel neurogenesis in the rat spinal cord , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[6]  J. Barker,et al.  Complementary expressions of transcripts encoding GAD67 and GABAA receptor alpha 4, beta 1, and gamma 1 subunits in the proliferative zone of the embryonic rat central nervous system , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[7]  Immunoaffinity purification of gamma-aminobutyric acidA (GABAA) receptors containing gamma 1-subunits. Evidence for the presence of a single type of gamma-subunit in GABAA receptors. , 1994, The Journal of biological chemistry.

[8]  M. Luskin Neuronal cell lineage in the vertebrate central nervous system , 1994, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[9]  J. Barker,et al.  Ontogeny of GABAA receptor subunit mRNAs in rat spinal cord and dorsal root ganglia , 1993, The Journal of comparative neurology.

[10]  J. Barker,et al.  Sodium channels, GABAA receptors, and glutamate receptors develop sequentially on embryonic rat spinal cord cells , 1993, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[11]  H. Mohler,et al.  GABAA receptor populations with novel subunit combinations and drug binding profiles identified in brain by alpha 5- and delta-subunit-specific immunopurification. , 1993, The Journal of biological chemistry.

[12]  M. Hatten,et al.  The role of migration in central nervous system neuronal development , 1993, Current Opinion in Neurobiology.

[13]  A. Trzeciak,et al.  GABAA-receptors: drug binding profile and distribution of receptors containing the alpha 2-subunit in situ. , 1993, Journal of receptor research.

[14]  J. Altman,et al.  Timetables of neurogenesis in the human brain based on experimentally determined patterns in the rat. , 1993, Neurotoxicology.

[15]  P. Malherbe,et al.  Comparative molecular neuroanatomy of cloned GABAA receptor subunits in the rat CNS , 1992, The Journal of comparative neurology.

[16]  J. Barker,et al.  Neuroepithelial cells in the rat spinal cord express glutamate decarboxylase immunoreactivity in vivo and in vitro , 1992, The Journal of comparative neurology.

[17]  W Wisden,et al.  The distribution of thirteen GABAA receptor subunit mRNAs in the rat brain. III. Embryonic and postnatal development , 1992, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[18]  J. Barker,et al.  Differential and transient expression of GABAA receptor alpha-subunit mRNAs in the developing rat CNS , 1992, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[19]  Z. Darżynkiewicz,et al.  Changes in nuclear chromatin related to apoptosis or necrosis induced by the DNA topoisomerase II inhibitor fostriecin in MOLT-4 and HL-60 cells are revealed by altered DNA sensitivity to denaturation. , 1992, Experimental cell research.

[20]  T Takahashi,et al.  BUdR as an S-phase marker for quantitative studies of cytokinetic behaviour in the murine cerebral ventricular zone , 1992, Journal of neurocytology.

[21]  W Wisden,et al.  The distribution of 13 GABAA receptor subunit mRNAs in the rat brain. I. Telencephalon, diencephalon, mesencephalon , 1992, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[22]  Z. Darżynkiewicz,et al.  Features of apoptotic cells measured by flow cytometry. , 1992, Cytometry.

[23]  S. Mcconnell,et al.  Cell cycle dependence of laminar determination in developing neocortex. , 1992, Science.

[24]  K. Fuchs,et al.  N‐Deglycosylation and immunological identification indicates the existence of β‐subunit isoforms of the rat GABAA receptor , 1991, FEBS letters.

[25]  M. Hearn,et al.  Rapid Isolation of Rat Brain Nuclei on Percoll Gradients , 1991, Journal of neurochemistry.

[26]  H. Lassmann,et al.  Immunohistochemical localization of the α 1, α 2 and α 3 subunit of the GABAA receptor in the rat brain , 1991, Neuroscience Letters.

[27]  H. Mohler,et al.  Immunochemical identification of the alpha 1- and alpha 3-subunits of the GABAA-receptor in rat brain. , 1991, Journal of receptor research.

[28]  H. Lassmann,et al.  Immunohistochemical localization of the alpha 1, alpha 2 and alpha 3 subunit of the GABAA receptor in the rat brain. , 1991, Neuroscience letters.

[29]  R. Oppenheim Cell death during development of the nervous system. , 1991, Annual review of neuroscience.

[30]  J. Barker,et al.  Embryonic and early postnatal hippocampal cells respond to nanomolar concentrations of muscimol. , 1990, Brain research. Developmental brain research.

[31]  P. Nurse Universal control mechanism regulating onset of M-phase , 1990, Nature.

[32]  Y. Ben-Ari,et al.  Giant synaptic potentials in immature rat CA3 hippocampal neurones. , 1989, The Journal of physiology.

[33]  J. Barker,et al.  Growth and differentiation properties of O‐2A Progenitors purified from rat cerebral hemispheres , 1988, Journal of neuroscience research.

[34]  Michael W. Miller,et al.  Use of bromodeoxyuridine-immunohistochemistry to examine the proliferation, migration and time of origin of cells in the central nervous system , 1988, Brain Research.

[35]  K. Frederiksen,et al.  Proliferation and differentiation of rat neuroepithelial precursor cells in vivo , 1988, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[36]  J. Barker,et al.  Flow cytometric analysis of membrane potential in embryonic rat spinal cord cells , 1988, Journal of Neuroscience Methods.

[37]  R. Baughman,et al.  Primary culture of identified neurons from the visual cortex of postnatal rats , 1986, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[38]  J. Rostas,et al.  A rapid method for isolation of synaptosomes on Percoll gradients , 1986, Brain Research.

[39]  M. Stromberg,et al.  Anatomy and embryology of the laboratory rat , 1986 .

[40]  J W Gray,et al.  Cell cycle analysis using flow cytometry. , 1986, International journal of radiation biology and related studies in physics, chemistry, and medicine.

[41]  E. M. Levin,et al.  Cell kinetic studies of in situ human brain tumors with bromodeoxyuridine. , 1985, Cytometry.

[42]  Y. Berwald‐Netter,et al.  Neuronal acquisition of tetanus toxin binding sites: relationship with the last mitotic cycle. , 1983, Developmental biology.

[43]  T. Johnson,et al.  G2 cell cycle arrest induced by glycopeptides isolated from the bovine cerebral cortex , 1983, The Journal of cell biology.

[44]  V. Argiro,et al.  [20] Techniques in the tissue culture of rat sympathetic neurons , 1983 .

[45]  V. Argiro,et al.  Techniques in the tissue culture of rat sympathetic neurons. , 1983, Methods in enzymology.

[46]  T. Johnson,et al.  Isolation of cell-surface glycopeptides from bovine cerebral cortex that inhibit cell growth and protein synthesis in normal but not in transformed cells. , 1982, The Biochemical journal.

[47]  M. Daniels,et al.  Conditioned medium from cultures of embryonic neurons contains a high molecular weight factor which induces acetylcholine receptor aggregation on cultured myotubes , 1982, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[48]  D. Silberberg,et al.  Long term culture of bovine oligodendroglia isolated with a percoll gradient , 1981, Brain Research.

[49]  M. Brysk,et al.  Separation of newborn rat epidermal cells on discontinuous isokinetic gradients of PERCOLL. , 1981, The Journal of investigative dermatology.

[50]  L. Enerbäck,et al.  Isolation of rat peritoneal mast cells by centrifugation on density gradients of Percoll. , 1980, Journal of immunological methods.

[51]  J. Brunstedt Rapid isolation of functionally intact pancreatic islets from mice and rats by percollTM gradient centrifucation. , 1980, Diabete & metabolisme.

[52]  K. Paigen,et al.  A simple, rapid, and sensitive DNA assay procedure. , 1980, Analytical biochemistry.

[53]  J. Kurnick,et al.  A Rapid Method for the Separation of Functional Lymphoid Cell Populations of Human and Animal Origin on PVP‐Silica (Percoll) Density Gradients , 1979, Scandinavian journal of immunology.

[54]  Y. Nagata,et al.  Bulk separation of neuronal cell bodies and glial cells from mammalian brain and some of their biochemical properties , 1978 .

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

[56]  Richard H. Hinton,et al.  Density gradient centrifugation , 1976 .

[57]  P. Seglen,et al.  The use of metrizamide as a gradient medium for isopycnic separation of rat liver cells , 1974, FEBS letters.

[58]  U. Murakami,et al.  Charasteristics of the cell cycle of matrix cells in the mouse embryo during histogenesis of telencephalon. , 1973, Experimental cell research.

[59]  J. Sykes,et al.  Separation of tumor cells from fibroblasts with use of discontinuous density gradients. , 1970, Journal of the National Cancer Institute.

[60]  S. Kauffman Lengthening of the generation cycle during embryonic differentiation of the mouse neural tube. , 1968, Experimental cell research.

[61]  J. Till,et al.  Density gradient centrifugation of hemopoietic colony‐forming cells , 1967 .

[62]  H. Pertoft Gradient centrifugation in colloidal silica-polysaccharide media. , 1966, Biochimica et biophysica acta.

[63]  A. W. Rogers,et al.  The migration of neuroblasts in the developing cerebral cortex. , 1965, Journal of anatomy.

[64]  J. Langman,et al.  The development of the spinal cord examined by autoradiography. , 1965, Journal of embryology and experimental morphology.