Postnatal Rat Spinal Cord Research Articles

MicroRNA-21 promotes neurite outgrowth by regulating PDCD4 in a rat model of spinal cord injury

Altered expression levels of microRNA-21 (miRNA-21) have been observed in a series of pathological processes, including cancer and central nervous system injury; however, the involvement of miRNA-21 in the molecular pathophysiology of spinal cord injury (SCI) has not been well documented. The present study examined the expression levels of miRNA-21 and its predicted target genes, programmed cell death 4 (PDCD4) and phosphatase and tensin homolog (PTEN), in rats using quantitative polymerase chain reaction and western blotting to further understand the role of miRNA-21 and the mechanisms underlying repair following SCI. The present study demonstrated that compared with uninjured spinal cords, miRNA-21 expression levels were significantly downregulated in injured spinal cords 4 and 8 h, and 1 day post-SCI, and were significantly upregulated after 3 and 7 days. Conversely, expression levels of PDCD4 and PTEN were significantly decreased at days 3 and 7 post-SCI compared with the control group. miRNA-21 overexpression in monolayer-cultured postnatal rat spinal cord neurons promoted neurite outgrowth and downregulated protein expression levels of PDCD4; however, PTEN protein expression levels were unaltered. To confirm that miRNA-21 directly targets PDCD4, a pRL-CMV luciferase reporter construct was used to detect miRNA-21 interactions with the PDCD4 3′-untranslated region. The results demonstrated that miRNA-21 decreased luciferase activity compared with a rat PDCD4 control reporter. The results of the present study suggested that increased miRNA-21 expression levels following SCI may promote the repair of injured spinal cords by inhibiting the expression of its target gene PDCD4.

Protective effect of rosemary on acrylamide motor neurotoxicity in spinal cord of rat offspring: postnatal follow-up study.

The direct interactive effects of rosemary and acrylamide on the development of motor neurons in the spinal cord remains unknown. Our goal is to confirm the protective effects of rosemary against motor neuronal degeneration induced by acrylamide in the developing postnatal rat spinal cord using a postnatal rat model. We assigned the offspring of treated female rats into control, rosemary; acrylamide group; and recovery groups. This work depended on clinical, histopathological, morphometrically, immunohistochemical and genetic methods. In the acrylamide group, we observed oxidation, motor neuron degeneration, apoptosis, myelin degeneration, neurofilament reduction, reactive gliosis. Whoever, concomitant rosemary intake and withdrawal of acrylamide modulate these effects. These findings proof that dietary rosemary can directly protect motor neuron against acrylamide toxicity in the mammalian developing spinal cord.

Intrinsic and extrinsic determinants of central nervous system axon outgrowth into alginate-based anisotropic hydrogels

Appropriate target reinnervation and functional recovery after spinal cord injury depend on longitudinally directed regrowth of injured axons. Anisotropic alginate-based capillary hydrogels (ACH) support peripheral nervous system derived axon growth, which is accompanied by glial supporting cell migration into the ACH. The aim of the present study was to analyze central nervous system (CNS) derived (entorhinal cortex, spinal cord slice cultures) axon regrowth into ACH containing linearly aligned capillaries of defined capillary sizes without and with gelatin constituent. Anisotropic ACH were prepared by ionotropic gel formation using Ba2+, Cu2+, Sr2+, or Zn2+ ions resulting in gels with average capillary diameters of 11, 13, 29, and 89μm, respectively. Postnatal rat entorhinal cortex or spinal cord slice cultures were placed on top of 500μm thick ACH. Seven days later axon growth and astroglial migration into the ACH were determined. Axon density within capillaries correlated positively with increasing capillary diameters, whereas longitudinally oriented axon outgrowth diminished with increasing capillary diameter. Axons growing into the hydrogels were always accompanied by astrocytes strongly suggesting that respective cells are required to mediate CNS axon elongation into ACH. Overall, midsize capillary diameter ACH appeared to be the best compromise between axon density and orientation. Taken together, ACH promote CNS axon ingrowth, which is determined by the capillary diameter and migration of slice culture derived astroglia into the hydrogel. Statement of SignificanceBiomaterials are investigated as therapeutic tools to bridge irreversible lesions following traumatic spinal cord injury. The goal is to develop biomaterials, which promote longitudinally oriented regeneration of as many injured axons as possible as prerequisite for substantial functional recovery. Optimal parameters of the biomaterial have yet to be defined. In the present study we show that increasing capillary diameters within such hydrogels enhanced central nervous system axon regeneration at the expense of longitudinal orientation. Axon ingrowth into the hydrogels was only observed in the presence of glial supporting cells, namely astrocytes. This suggests that alginate-based hydrogels need to be colonized with respective cells in order to facilitate axon ingrowth.

Time course of spinal doublecortin expression in developing rat and porcine spinal cord: implication in in vivo neural precursor grafting studies.

Expression of doublecortin (DCX), a 43-53 kDa microtubule binding protein, is frequently used as (i) an early neuronal marker to identify the stage of neuronal maturation of in vivo grafted neuronal precursors (NSCs), and (ii) a neuronal fate marker transiently expressed by immature neurons during development. Reliable identification of the origin of DCX-immunoreactive cells (i.e., host vs. graft) requires detailed spatial and temporal mapping of endogenous DCX expression at graft-targeted brain or spinal cord regions. Accordingly, in the present study, we analyzed (i) the time course of DCX expression in pre- and postnatal rat and porcine spinal cord, and (ii) the DCX expression in spinally grafted porcine-induced pluripotent stem cells (iPS)-derived NSCs and human embryonic stem cell (ES)-derived NSCs. In addition, complementary temporospatial GFAP expression study in porcine spinal cord was also performed. In 21-day-old rat fetuses, an intense DCX immunoreactivity distributed between the dorsal horn (DH) and ventral horn was seen and was still present in the DH neurons on postnatal day 20. In animals older than 8 weeks, no DCX immunoreactivity was seen at any spinal cord laminae. In contrast to rat, in porcine spinal cord (gestational period 113-114 days), DCX was only expressed during the pre-natal period (up to 100 days) but was no longer present in newborn piglets or in adult animals. Immunohistochemical analysis was confirmed with a comparable expression profile by western blot analysis. Contrary, the expression of porcine GFAP started within 70-80 days of the pre-natal period. Spinally grafted porcine iPS-NSCs and human ES-NSCs showed clear DCX expression at 3-4 weeks postgrafting. These data indicate that in spinal grafting studies which employ postnatal or adult porcine models, the expression of DCX can be used as a reliable marker of grafted neurons. In contrast, if grafted neurons are to be analyzed during the first 4 postnatal weeks in the rat spinal cord, additional markers or grafted cell-specific labeling techniques need to be employed to reliably identify grafted early postmitotic neurons and to differentiate the DCX expression from the neurons of the host.

Neurotensin inhibits background K+ channels and facilitates glutamatergic transmission in rat spinal cord dorsal horn

Neurotensin (NT) is a neuropeptide involved in the modulation of nociception. We have investigated the actions of NT on cultured postnatal rat spinal cord dorsal horn (DH) neurons. NT induced an inward current associated with a decrease in membrane conductance in 46% of the neurons and increased the frequency of glutamatergic miniature excitatory synaptic currents in 37% of the neurons. Similar effects were observed in acute slices. Both effects of NT were reproduced by the selective NTS1 agonist JMV449 and blocked by the NTS1 antagonist SR48692 and the NTS1/NTS2 antagonist SR142948A. The NTS2 agonist levocabastine had no effect. The actions of NT persisted after inactivation of G(i/o) proteins by pertussis toxin but were absent after inactivation of protein kinase C (PKC) by chelerythrine or inhibition of the MAPK (ERK1/2) pathway by PD98059. Pre- and postsynaptic effects of NT were insensitive to classical voltage- and Ca(2+) -dependent K(+) channel blockers. The K(+) conductance inhibited by NT was blocked by Ba(2+) and displayed no or little inward rectification, despite the presence of strongly rectifying Ba(2+) -sensitive K(+) conductance in these neurons. This suggested that NT blocked two-pore domain (K2P) background K(+) -channels rather than inwardly rectifying K(+) channels. Zn(2+) ions, which inhibit TRESK and TASK-3 K2P channels, decreased NT-induced current. Our results indicate that in DH neurons NT activates NTS1 receptors which, via the PKC-dependent activation of the MAPK (ERK1/2) pathway, depolarize the postsynaptic neuron and increase the synaptic release of glutamate. These actions of NT might modulate the transfer and the integration of somatosensory information in the DH.

Presynaptic functional trkB receptors mediate the release of excitatory neurotransmitters from primary afferent terminals in lamina II (substantia gelatinosa) of postnatal rat spinal cord

A subset of primary sensory neurons produces BDNF, which is implicated in control of nociceptive neurotransmission. We previously localized full-length trkB receptors on their terminals within lamina II. To functionally study these receptors, we here employed patch-clamp recordings, calcium imaging and immunocytochemistry on slices from 8-12 days post-natal rats. In this preparation, BDNF (100-500 ng/mL) enhances the release of sensory neurotransmitters (glutamate, substance P, CGRP) in lamina II by acting on trkB receptors expressed by primary afferent fibers of the peptidergic nociceptive type (PN-PAFs). Effect was blocked by trk antagonist K252a or anti-trkB antibody clone 47. A pre-synaptic mechanism was demonstrated after (i) patch-clamp recordings where the neurotrophin induced a significant increase in frequency, but not amplitude, of AMPA-mediated mEPSCs, (ii) real time calcium imaging, where sustained application of BDNF evoked an intense response in up to 57% lamina II neurons with a significant frequency rise. Antagonists of ionotropic glutamate receptors and NK(1) receptors completely inhibited the calcium response to BDNF. Reduction of CGRP (a specific marker of PN-PAFs) and substance P content in dorsal horn following BDNF preincubation, and analysis of the calcium response after depletion with capsaicin, confirmed that the neurotrophin presynaptically enhanced neurotransmitter release from PN-PAFs. This is the first demonstration that trkB receptors expressed by PN-PAF terminals in lamina II are functional during postnatal development. Implications of this finding are discussed considering that BDNF can be released by these same terminals and microglia, a fraction of which (as shown here) contains BDNF also in unactivated state.

Characterisation of transverse slice culture preparations of postnatal rat spinal cord: preservation of defined neuronal populations

Spinal cord injury induces degenerative and regenerative processes and complex interactions of neurons with non-neuronal cells. In order to develop an in vitro tool for the investigation of such processes, we prepared and characterised spinal cord slice cultures (SCSC) from Wistar rats (p0-12). SCSC were sustained in vitro up to 12 days and characterised by immunohistochemistry. Calbindin+ neurons, distributed across the entire gray matter, were visible also after longer culture periods. NeuN+ neurons were best preserved in the dorsal horn whereas large NeuN+ and choline acetyltransferase+ motoneurons in the ventral horn vanished after 3 days in vitro. Nestin immunoreactivity was found in animals of all age groups, either in cells interspersed in the ependymal lining around the central canal or in cells resembling protoplasmic astrocytes. Glial fibrillary acidic protein+ astrocytes, initially restricted to the white matter, invaded the gray matter of SCSC early during the culture period. Microglial cells, stained by Griffonia simplicifolia isolectin B4, were rapidly activated in the dorsal tract and in the gray matter but declined in number with time. SCSC derived from p0 or p3 animals showed a better preservation of the cytoarchitecture than cultures derived from older animals. In summary, SCSC undergo degenerative changes, but they contain defined neuronal populations, the cytoarchitecture is partially preserved and the glial reaction is limited.

Transient upregulation of Nkx2.2 expression in oligodendrocyte lineage cells during remyelination.

While numerous oligodendrocyte progenitor cells (OPCs) exist in the adult central nervous system (CNS), the molecular signals that promote or inhibit their differentiation into mature oligodendrocytes (OLs) are not known. To investigate whether remyelination in the adult CNS is regulated by the same mechanisms that promote developmental myelination, we used an acute demyelinating/remyelinating lesion in the adult rat spinal cord to examine the expression of the homeodomain transcription factor Nkx2.2, which has previously been implicated in oligodendrocyte differentiation during embryonic development. After a demyelinating insult, Nkx2.2 expression was upregulated first in NG2-expressing OPCs surrounding the lesion and subsequently in both precursors and OLs that appeared inside the lesion prior to the onset of remyelination. The temporal and spatial pattern of Nkx2.2 upregulation coincided with that of oligodendrocyte differentiation characterized in our previous study. A similar increase in the level of Nkx2.2 expression was observed in the postnatal developing optic nerve in a wave from the proximal to the distal retinal end. In vitro Nkx2.2 was expressed in OPCs and immature OLs isolated from postnatal rat spinal cord but was absent from mature OLs. These observations indicate that the process of generating new OLs in a remyelinating lesion recapitulates the developmental program involving activation of the Nkx2.2 gene, which may trigger the existing NG2-expressing precursors in the adult CNS to undergo terminal differentiation into remyelinating OLs.

Quantitative measurement of glutamate receptor subunit protein expression in the postnatal rat spinal cord

Glutamate is the major excitatory neurotransmitter in the CNS and its effects on neurons are dependent on the type and composition of glutamate receptors with which it interacts. In this study, the protein expression levels of several ionotropic glutamate receptor subunits ( N-methyl- d-aspartate (NMDA) subunits NR1, NR2A, NR2B, and α-amino-3-hydroxy-5-methyl-4-isoxazoleproprionic acid (AMPA) receptor subunits GluR1, GluR2, GluR4) were quantified in particulate preparations from rat spinal cord at various ages after birth. We found that all six subunits showed high expression in the early postnatal period, followed by a subsequent decline as the rats matured to adults. The levels of two subunits (NR2A and GluR4) were found to initially increase during the first postnatal week prior to the decline to adult levels. The high levels of expression observed of these subunits in the early postnatal period may have implications for mechanisms of neural injury and cell death in the immature nervous system that involve cation influx through ionotropic glutamate receptors.

Identification of cells expressing Cx43, Cx30, Cx26, Cx32 and Cx36 in gap junctions of rat brain and spinal cord.

We have identified cells expressing Cx26, Cx30, Cx32, Cx36 and Cx43 in gap junctions of rat central nervous system (CNS) using confocal light microscopic immunocytochemistry and freeze-fracture replica immunogold labeling (FRIL). Confocal microscopy was used to assess general distributions of connexins, whereas the 100-fold higher resolution of FRIL allowed co-localization of several different connexins within individual ultrastructurally-defined gap junction plaques in ultrastructurally and immunologically identified cell types. In >4000 labeled gap junctions found in >370 FRIL replicas of gray matter in adult rats, Cx26, Cx30 and Cx43 were found only in astrocyte gap junctions; Cx32 was only in oligodendrocytes, and Cx36 was only in neurons. Moreover, Cx26, Cx30 and Cx43 were co-localized in most astrocyte gap junctions. Oligodendrocytes shared intercellular gap junctions only with astrocytes, and these heterologous junctions had Cx32 on the oligodendrocyte side and Cx26, Cx30 and Cx43 on the astrocyte side. In 4 and 18 day postnatal rat spinal cord, neuronal gap junctions contained Cx36, whereas Cx26 was present in leptomenigeal gap junctions. Thus, in adult rat CNS, neurons and glia express different connexins, with "permissive" connexin pairing combinations apparently defining separate pathways for neuronal vs. glial gap junctional communication.

Developmental and adult expression of rat calcium-sensing receptor transcripts in neurons and oligodendrocytes.

The calcium-sensing receptor (CaSR) is a member of a growing family of heptahelical receptors with an unusually large extracellular domain. To further delineate its functions in neurons and glia, we have investigated the expression pattern of CaSR transcripts in the postnatal and adult rat brain, spinal cord and dorsal root ganglia by in situ hybridization. CaSR-expressing cells were spatially and temporally regulated in myelinated structures with a caudo-rostral pattern that paralleled that of myelin basic protein, a marker of myelination, with a downregulation observed in the adult. Double-labelling studies demonstrated that CaSR mRNA colocalizes with myelin basic protein-expressing cells within fibre tracts, suggesting that CaSR is expressed by mature oligodendrocytes. In cultured rat oligodendrocytes, Ca2+ induced stimulation of phosphatidylinositol hydrolysis with an EC50 of 1.4 mM and increased intracellular calcium. NPS R-568 (1 microM), a calcimimetic, significantly stimulates the inositol phosphate response, whereas a less potent stereoisomer, NPS S-568 (1 microM), was without effect. These data suggest that a functional CaSR is expressed in mature oligodendrocytes with a potential role in myelination. CaSR expression was also developmentally regulated in neurons of the orbital cortex and in the CA2 region of the hippocampus, and present in olfactory nuclei, hypothalamic areas and in the area postrema through postnatal days to adulthood. This expression is consistent with a role of CaSR in olfactory or gustatory signal integration, and with the regulation of fluid and mineral homeostasis. CaSR expression in a subpopulation of small cells in dorsal root ganglia suggests additional roles for extracellular Ca2+ in sensory nerves.

Spinal cord oligodendrocytes develop from a limited number of migratory, highly proliferative precursors

Oligodendrocytes are responsible for myelin formation in spinal cord white matter. In the mature spinal cord, the majority of white matter is localized peripherally. During early development, however, the first oligodendrocyte precursors arise in the ventral ventricular zone of the developing cord. Thus, prior to myelination, both migration and proliferation of oligodendrocyte precursors must occur. When and where these events occur is currently unclear. In the chick spinal cord, oligodendrocyte precursors express antigens recognized by the monoclonal antibody O4. Here we show that all chick spinal cord oligodendrocytes are derived from O4+ cells and all O4+ cells appear to give rise to oligodendrocytes. Analysis of the number and distribution of oligodendrocyte precursors in chick spinal cord at different stages of development suggests that relatively few cells migrate from the ventricular source which then proliferate extensively in white matter. This migration is guided by general dispersive cues. Clonal analysis of oligodendrocyte development in cultures derived from different regions of the rodent spinal cord indicated that the cells that initially populate dorsal and peripheral spinal cord retained similar clonal properties to those in ventral spinal cord, suggesting the migrating cells were immature, highly proliferative precursors. Consistent with these results, BrdU incorporation studies indicate that glial proliferation is extensive and persistent in postnatal rat spinal cord white matter. Together, these studies suggest that spinal cord white matter is initially populated by very immature precursors that then undergo extensive local proliferation prior to myelination. J. Neurosci. Res. 50:157–168, 1997. © 1997 Wiley-Liss, Inc.

Spinal cord oligodendrocytes develop from a limited number of migratory, highly proliferative precursors

Oligodendrocytes are responsible for myelin formation in spinal cord white matter. In the mature spinal cord, the majority of white matter is localized peripherally. During early development, however, the first oligodendrocyte precursors arise in the ventral ventricular zone of the developing cord. Thus, prior to myelination, both migration and proliferation of oligodendrocyte precursors must occur. When and where these events occur is currently unclear. In the chick spinal cord, oligodendrocyte precursors express antigens recognized by the monoclonal antibody O4. Here we show that all chick spinal cord oligodendrocytes are derived from O4+ cells and all O4+ cells appear to give rise to oligodendrocytes. Analysis of the number and distribution of oligodendrocyte precursors in chick spinal cord at different stages of development suggests that relatively few cells migrate from the ventricular source which then proliferate extensively in white matter. This migration is guided by general dispersive cues. Clonal analysis of oligodendrocyte development in cultures derived from different regions of the rodent spinal cord indicated that the cells that initially populate dorsal and peripheral spinal cord retained similar clonal properties to those in ventral spinal cord, suggesting the migrating cells were immature, highly proliferative precursors. Consistent with these results, BrdU incorporation studies indicate that glial proliferation is extensive and persistent in postnatal rat spinal cord white matter. Together, these studies suggest that spinal cord white matter is initially populated by very immature precursors that then undergo extensive local proliferation prior to myelination.

Pharmacological characterization of oxytocin-binding sites in rat spinal cord membranes: comparison with embryonic cultured spinal cord neurones and astrocytes.

Detection and pharmacological characterization of OT-binding sites were performed on 12-day-old rat spinal cord membranes and on embryonic cultured spinal neurones and astrocytes after 12 days in culture. In neurone-enriched cultures, OT-binding sites were detected by autoradiography on cells morphologically comparable to neurone-specific enolase immunoreactive cells. In astrocyte cultures, as shown by combination of autoradiography and immunocytochemistry, OT-binding sites were detected on cells expressing the glial fibrillary acidic protein (a specific astrocytic marker). The pharmacological characterization was assessed by binding studies performed with a highly specific radioiodinated OT antagonist on postnatal rat spinal cord membranes and on embryonic cultured spinal cord neurones and astrocytes. The saturation studies suggested the presence of a single class of binding sites of high affinity for the OT antagonist on spinal membranes and cultured cells, as already described in the rat for central and peripheric OT receptors. The competition studies indicated that on spinal membranes, OT and AVP had the same high affinity, as classically described, whereas on cultured cells, AVP had a lower affinity, suggesting that culture conditions may influence the pharmacology of the spinal OT-binding sites. Involvement of NEM- and Gpp[NH]p-insensitive G-proteins in the coupling of the spinal OT-binding sites with the effector system was evidenced on 12-day-old rat spinal membrane preparations and on neurone and astrocyte cultures.

Neurogenesis in postnatal rat spinal cord: a study in primary culture.

Spinal cord injuries result in paralysis, because when damaged neurons die they are not replaced. Neurogenesis of electrophysiologically functional neurons occurred in spinal cord cultured from postnatal rats. In these cultures, the numbers of immunocytochemically identified neurons increased over time. Additionally, neurons identified immunocytochemically or electrophysiologically incorporated bromodeoxyuridine, confirming they had differentiated from mitotic cells in vitro. These findings suggest that postnatal spinal cord retains the capacity to generate functional neurons. The presence of neuronal precursor cells in postnatal spinal cord may offer new therapeutic approaches for restoration of function to individuals with spinal cord injuries.

Developmental expression of alpha-, beta- and gamma-subspecies of protein kinase C in the dorsal corticospinal tract in the rat spinal cord.

Developmental expression of alpha-, beta- and gamma-subspecies of protein kinase C in the dorsal corticospinal tract was immunohistochemically investigated at the cervical level of the postnatal rat spinal cord. On postnatal day 0, immunoreactivity for these subspecies was uniformly distributed throughout the posterior funiculus. On postnatal day 7, immunoreactivity for this enzyme in the posterior funiculus began to decline. On postnatal days 14 and 21, the immunoreactivity in the posterior funiculus became weak, while the dorsal corticospinal tract forming in the most ventral portion of the posterior funiculus exhibited strong immunoreactivity for these three subspecies of protein kinase C. Thereafter, immunoreactivity in the corticospinal tract rapidly declined, and on postnatal days 28 and 35, weak immunoreaction was demonstrated as very fine granular deposits in the tract. Expression of this enzyme in the dorsal corticospinal tract at these stages resembled that in the adult rat. Electron microscopically, growth cones and nascent axonal shafts were first noted on postnatal day 2 in the most ventral portion of the posterior funiculus, and thereafter, the axonal shaft gradually thickened and on postnatal day 14 some axons began to be myelinated. The growth cones and thin axonal shafts randomly exhibited weak immunoreactivity in the axoplasm. The thicker unmyelinated axonal shafts showed distinct immunoreactivity uniformly throughout the axoplasm and along the axolemma as granular deposits. In these developing axons, intensity and distribution of immunoreactivity for all three subspecies were principally similar. In the mature myelinated axons, the intensity and distribution of immunoreactivity for each subspecies of protein kinase C were quite different, i.e. immunoreactivity for alpha-subspecies was randomly distributed on some cytoskeletal elements, and that for beta-subspecies was uniformly detected on most of the cytoskeletal elements. In contrast, immunoreactivity for gamma-subspecies was distributed mainly on the endoplasmic reticulum. These findings suggest that in growing corticospinal axons protein kinase C might be involved in several important aspects of axonal development, and that in mature axons this enzyme might participate in different aspects of axonal function.

Expression of α-, β- and γ-subspecies of protein kinase C in the motor neurons in the embryonic and postnatal rat spinal cord

Using polyclonal antibodies against alpha-, beta- and gamma-subspecies of protein kinase C, developmental changes in expression of these subspecies in the motor neurons in the rat cervical spinal cord were immunohistochemically investigated. On embryonic day-12, the motor neurons began to differentiate from undifferentiated neuroepithelial cells. On embryonic day-13, they began to express weak immunoreactivity for alpha- and beta-protein kinase C and slightly more evident immunoreactivity for gamma-protein kinase C. Immunoreactivity for protein kinase C in these neurons gradually became stronger, as the development progressed. Between embryonic day-18 and postnatal day-7, the motor neurons showed distinct immunoreactivity in the nucleus, perikaryal cytoplasm, axon and dendrites. At these stages, distribution and intensity of immunoreactivity for alpha-, beta- and gamma-protein kinase C were very similar. Thereafter, the expression of this enzyme in the nucleus gradually declined, while in the other structures, expression of each subspecies changed independently. On postnatal day-28 and 35, expression of beta-protein kinase C in the axons was stronger than that of alpha- and gamma-protein kinase C, and immunoreactivity for gamma-protein kinase C in the perikaryal cytoplasm and dendrites was slightly weaker than that for alpha- and beta-protein kinase C. Expression of this enzyme in the motor neurons at these stages was almost the same as in the adult animal. Electron microscopically, immunoreactivity for protein kinase C was randomly distributed in the nucleus, and in the perikaryal cytoplasm, often near the cisterns of the endoplasmic reticulum. Expression of protein kinase C in the growing axons was quite different from that in the mature axons. In the dendrites, immunoreactivity for protein kinase C was distributed randomly in the cytoplasm and at the postsynaptic densities. These findings suggest that protein kinase C might regulate not only the neural functions, but also several aspects of the differentiation process in the motor neurons.

Chondroitin sulfate proteoglycans in the developing central nervous system. I. cellular sites of synthesis of neurocan and phosphacan.

We have used in situ hybridization histochemistry to examine the cellular sites of synthesis of two major nervous tissue proteoglycans, neurocan and phosphacan, in embryonic and postnatal rat brain and spinal cord. Both proteoglycans were detected only in nervous tissue. Neurocan mRNA was evident in neurons, including cerebellar granule cells and Purkinje cells, and in neurons of the hippocampal formation and cerebellar nuclei. In contrast, phosphacan message was detected only in astroglia, such as the Golgi epithelial cells of the cerebellum. At embryonic day 13-16, phosphacan mRNA is largely confined to areas of active cell proliferation (e.g., the ventricular zone of the ganglionic eminence and septal area of the brain and the ependymal layer surrounding the central canal of the spinal cord) as well as being present in the roof plate. The distribution of neurocan message is more widespread, extending to the cortex, hippocampal formation, caudate putamen, and basal telencephalic neuroepithelium, and neurocan mRNA is present in both the ependymal and mantle layers of the spinal cord but not in the roof plate. The presence of neurocan mRNA in areas where the proteoglycan is not expressed suggests that the short open reading frame in the 5'-leader of neurocan may function as a cis-acting regulatory signal for the modulation of neurocan expression in the developing central nervous system.

Developmental changes in the expression of α-, β- and γ-subspecies of protein kinase C at synapses in the ventral horn of the embryonic and postnatal rat spinal cord

Developmental changes in expression of α-, β- and γ-subspecies of protein kinase C (PKC) at synapses in the ventral horn of the rat spinal cord were immunocytochemically investigated. On embryonic day 15, a few synapses were found in the ventral horn, and they gradually ncreased in number until postnatal day 21 or 28. During the embryonic period, immunoreactivity (IR) for all three subspecies was demonstrated in both the pre- and postsynaptic regions. In the former, IR was detected mainly along the outer surface of the synaptic vesicles, and in the latter, along the postsynaptic membranes. At these stages, synapses were morphologically immature, having a faint postsynaptic density and a few round synaptic vesicles. After birth, IR for PKCs at the postsynaptic densities became stronger, but gradually disappeared in most of the presynaptic regions. In adult, IR for PKCs was detected only at the postsynaptic densities. At the later postnatal stages, the synapses were fully mature, having a thick postsynaptic density, a great number of synaptic vesicles and a distinct synaptic cleft as those in adult animals. In addition, the developmental changes in expression of these subspecies of PKC in the presynaptic regions were quite different. These findings suggest that the increase in expression of PKC at postsynaptic densities might be closely related with the development of synaptic functions, and also that each subspecies of PKC may take part in different aspects of synaptogenesis.

Neuropeptide receptors in developing and adult rat spinal cord: An in vitro quantitative autoradiography study of calcitonin gene‐related peptide, neurokinins, μ‐opioid, galanin, somatostatin, neurotensin and vasoactive intestinal polypeptide receptors

A number of neuroactive peptides including calcitonin gene-related peptide (CGRP), substance P, neurokinin B, opioids, somatostatin (SRIF), galanin, neurotensin and vasoactive intestinal polypeptide (VIP) have been localized in adult rat spinal cord and are considered to participate either directly and/or indirectly in the processing of sensory, motor and autonomic functions. Most of these peptides appear early during development, leading to the suggestion that peptides, in addition to their neurotransmitter/neuromodulator roles, may possibly be involved in the normal growth and maturation of the spinal cord. To provide an anatomical substrate for a better understanding of the possible roles of peptides in the ontogenic development of the cord, we investigated the topographical profile as well as variation in densities of [125I]hCGRP alpha, [125I]substance P/neurokinin-1 (NK-1), [125I]eledoisin/neurokinin-3 (NK-3), [125I]FK 33-824 ([D-Ala2, Me-Phe4, Met(O)ol5]enkephalin)/mu-opioid, [125I]galanin, [125I]T0D8-SRIF14 (an analog of somatostatin); [125I]neurotensin and [125I]VIP binding sites in postnatal and adult rat spinal cord using in vitro quantitative receptor autoradiography. Receptor binding sites recognized by each radioligand are found to be distributed widely during early stages of postnatal development and then to undergo selective modification to attain their adult profile of distribution during the third week of postnatal development. The apparent density of various receptor sites, however, are differently regulated depending on the lamina and the stage of development studied. For example, the density of mu-opioid binding sites, following a peak at postnatal day 4 (P4), declines gradually in almost all regions of the spinal cord with the increasing age of the animal. [125I]substance P/NK-1 binding sites, on the other hand, show very little variation until P14 and then subsequently decrease as the development proceeds. In the adult rat, most of these peptide receptor binding sites are localized in relatively high amounts in the superficial laminae of the dorsal horn. To varying extents, moderate to low density of various peptide receptor binding sites are also found to be present in the ventral horn, intermediolateral cell column and around the central canal. Taken together, these results suggest that each receptor-ligand system is regulated differently during development and may each uniquely be involved in cellular growth, differentiation and in maturation of the normal neural circuits of the spinal cord. Furthermore, the selective localization of various receptor binding sites in adult rat spinal cord over a wide variety of functionally distinct regions reinforces the neurotransmitter/modulator roles of these peptides in sensory, motor and autonomic functions associated with the spinal cord.