Maturation of the hypothalamo-pituitary-gonadal axis of male Syrian hamsters.

Light-microscope immunocytochemistry (ICC) was used to investigate postnatal changes in the morphology of LHRH neurons in the brains of male Syrian hamsters and to relate these changes to more overt maturational developments within the hypothalamo-pituitary-gonadal axis. The animals were maintained under long-day photoperiods (14L:10D), and groups of 6-7 were killed at 10-day intervals from Day 15 to Day 65. Their brains were fixed with 4% paraformaldehyde, sectioned sagittally with a vibratome (75 microns), and processed for ICC using monoclonal LHRH antibody HU4H. Throughout the study period, the hamsters showed a progressive increase in plasma gonadotropin levels, closely followed by an increase in testicular weight and plasma testosterone levels. Histology of the testes revealed that spermatogenesis was already qualitatively completed by Day 35 and quantitative aspects were established by Day 45. Within the brain, LHRH neuronal perikarya were distributed primarily in the medial septal-preoptic area and the diagonal band of Broca; morphologically, these immunopositive neurons were either monopolar or bipolar. The total number of LHRH neurons detected in the areas examined was approximately 440 throughout the developmental period, and the relative proportions of monopolar and bipolar subtypes (86% and 14%, respectively) remained unchanged. In contrast, the area of the perikarya, as determined by autoimage analysis, showed a highly significant age-related increase, both for the monopolar and bipolar neurons. It is suggested that these developmental changes in the LHRH neurons reflect an increase in LHRH synthesis and may, therefore, provide a neuroendocrine trigger for the onset of puberty.     

Effect of Reversible Inhibition of Deoxyribonucleic Acid Synthesis on the Yeast Cell Cycle

Hydroxyurea (HU) preferentially inhibited deoxyribonucleic acid (DNA) replication and division in Saccharomyces cerevisiae. Growth, ribonucleic acid synthesis, and protein synthesis were less sensitive to this drug. Upon addition of HU, cells underwent one cycle of budding and the nuclei migrated into the necks between the mother cells and buds. Neither the nucleus nor the cells divided. Removal of HU allowed immediate resumption of DNA synthesis. Nuclear division, budding, and cell division occurred 1.5, 2, and 4 hr, respectively, after HU was removed. If protein synthesis was blocked at the time HU was removed, budding and cell division did not occur. These results were interpreted to indicate that HU prevents accumulation of the potential to initiate a new cell cycle.     

Effects of Hydroxyurea on Crithidia fasciculata

SYNOPSIS Hydroxyurea (HU) inhibits increase in cell number in cultures of Crithidia fasciculata. Complete inhibition is produced by 8 mM and higher concentrations. If HU is not removed, population growth resumes in 45–50 h: if HU is removed, partially synchronous growth occurs through 2 cycles. During HU inhibition, the rate of DNA synthesis is reduced to 1% of that in exponentially growing cultures; protein and RNA syntheses continue at slightly reduced rates. Mean cell size and protein and RNA contents per cell increase; rate of oxygen consumption per mg cell protein remains constant. The behavior of a culture upon addition of HU and upon its removal agrees with predictions based on the hypothesis that the only direct effect of HU is to block DNA synthesis. The synchrony produced by HU is judged satisfactory for investigations of kinetoplast and nuclear replication but not for biochemical characterization of other aspects of the cell cycle.     

Effects of hydroxyurea on Crithidia fasciculata.

Hydroxyurea (HU) inhibits increase in cell number in cultures of Crithidia fasciculata. Complete inhibition is produced by 8 mM and higher concentrations. If HU is not removed, population growth resumes in 45-50 h; if HU is removed, partially synchronous growth occurs through 2 cycles. During HU inhibition, the rate of DNA synthesis is reduced to 1% of that in exponentially growing cultures; protein and RNA syntheses continue at slightly reduced rates. Mean cell size and protein and RNA contents per cell increase; rate of oxygen consumption per mg cell protein remains constant. The behavior of a culture upon addition of HU and upon its removal agrees with predictions based on the hypothesis that the only direct effect of HU is to block DNA synthesis. The synchrony produced by HU is judged satisfactory for investigations of kinetoplast and nuclear replication but not for biochemical characterization of other aspects of the cell cycle.     

Neuronal survival in intact ciliary ganglia in vivo and in vitro: Ciliary neuronotrophic factor as a target surrogate

Ciliary neuronotrophic factor (CNTF) requirements for neuronal survival in the intact ciliary ganglion (CG) have been investigated in organ culture. Exogenous CNTF was not essential for neuronal survival until embryonic Day 8. Three-day cultures from 5-day ganglia were similar with or without CNTF, showing numerous neurons and extensive neuritic development. In 3-day cultures from 8-day-old ganglia, however, no neurons survived without CNTF, and the ganglia contained only nonneuronal cells and cell debris. Similar ganglia cultured with CNTF contained many neurons, surrounded by nonneuronal cells, and abundant neuritic processes. Morphologic maturation of the neurons was less advanced in CNTF-supported ganglia than in their in vivo counterparts.     

Early commitment of precursor cells from the rat superior cervical ganglion to neuronal or nonneuronal fates

To determine whether postmigratory neural crest cells retain the capacity to give rise to multiple cell types, the clonal progeny of embryonic rat superior cervical ganglion (SCG) cells were examined in culture. Double labeling with BrdU and neurofilament antibodies demonstrated that neuron precursors from the E14.5 SCG continued to proliferate for several days in culture. Using the BAG retrovirus to examine the progeny of single cells, we obtained several kinds of distinct clones from SCG cultures after 3 days. At E14.5, during peak neurogenesis in vivo, neuron-containing clones composed of one to seven cells were common. At E17.5, after neurons have been born in vivo, most clones in vitro contained flat cells, primarily reflecting glial cell division. Even in cultures from E13.5 ganglia, mixed clones containing neurons and flat cells were rarely observed. These observations suggest that neuronal and nonneuronal cell precursors are specified during or before early gangliogenesis.     

Control of peripheral glial cell proliferation: enteric neurons exert an inhibitory influence on Schwann cell and enteric glial cell DNA synthesis in culture

Neuronal membranes from rat dorsal root ganglia provide a mitogenic signal to cultured Schwann cells and it has been suggested this is an important factor in regulating Schwann cell numbers during development. In this study, the influence of enteric neurons on the DNA synthesis of both Schwann cells and enteric glia has been investigated as well as the effect of axonal membrane fractions (axolemma) on enteric glia. The proliferation rate of rat Schwann cells and enteric glia was assessed in culture using [3H]thymidine uptake and autoradiography in combination with immunolabelling to identify cell types. When purified rat Schwann cells were co-cultured with guinea pig enteric neurons, their DNA synthesis rate was reduced compared with control cultures of pure Schwann cells or Schwann cells not close to neurites or neuronal cell bodies. Nevertheless, in accordance with previous findings that sensory neurons stimulate Schwann cell division, these Schwann cells increased their DNA synthesis rate when in contact with neurites from purified guinea pig or adult rat dorsal root ganglion neurons and on exposure to bovine axolemmal fractions. The enteric neurons also suppressed the DNA synthesis of enteric glia in co-cultures of purified enteric neurons and enteric glia, while bovine axolemma stimulated their DNA synthesis. These results indicate that a mitotic inhibitory signal is associated with enteric neurons and can exert its effect on both Schwann cells and enteric glia, and that enteric glia, like Schwann cells, are stimulated to divide by axolemmal fractions. It thus seems possible that during development glial cell numbers in the peripheral nervous system may be controlled by both positive and negative regulators of cell growth.     

Formation and specification of neurons during the development of the leech central nervous system

In the leech embryo, neurogenesis takes place within the context of a stereotyped cell lineage. The prospective germ layers are formed during the early cleavage divisions by the reorganization and segregation of circumscribed domains within the cytoplasm of the fertilized egg. The majority of central neurons arise from the ectoderm, and central neuroblasts are distributed throughout both the length and width of each ectodermal hemisegment. Much of the segmental ganglion arises from medial neuroblasts, but there are also lateral ectodermal neuroblasts and mesodermal neuroblasts that migrate into the nascent ganglion from peripheral sites of origin. Some of these migratory cells are committed to neurogenesis prior to reaching their central destination. In addition, the leech embryo exhibits a secondary phase of neurogenesis that is restricted to the two sex segment ganglia. Secondary neurogenesis requires that a mitogenic or trophic signal be conveyed from the peripherally located male sex organ to a particular set of centrally located neuroblasts, apparently via already differentiated central neurons that innervate the sex organ. The differential specification of neuronal phenotypes within the leech central nervous system occurs in multiple steps. Some aspects of a neuron's identity are already specified at the time of its terminal cell division and would seem to involve the lineal inheritance of developmental commitments made by one of the neuron's progenitors. This lineage-based identity can then be modified by interactions between the postmitotic neuron and other neurons or non-neuronal target cells encountered during its terminal differentiation. © 1995 John Wiley & Sons, Inc.     

Yeast-phase cell cycle of the polymorphic fungus Wangiella dermatitidis.

The yeast-phase cell cycle of Wangiella dermatitidis was studied using flow microfluorimetry and the deoxyribonucleic acid (DNA) synthesis inhibitor hydroxyurea (HU). Exposure of exponential-phase yeastlike cells to 0.1 M HU for 3 to 6 h resulted in the arrest of the cells in DNA synthesis and produced a nearly homogeneous population of unbudded cells. Treatment of the yeast-phase cells with HU for 9 h or longer resulted in the accumulation of the cells predominantly as budded forms having either a single nucleus in the mother cell or a single nucleus arrested in the isthmus between the mother cell and the daughter bud. Exposure of unbudded stationary-phase cells to 0.1 M HU resulted in the accumulation of the cells in the same phenotypes. Analysis by flow microfluorimetry and cell counts of HU-inhibited mithramycin-stained cells indicated that the eventual progress of HU-inhibited cells from unbudded to the two budded forms was due to the limited continuation of the growth sequence of the cell cycle even in the absence of DNA synthesis, nuclear division, and in some cases nuclear migration. On the basis of these observations and the results of flow microfluorimetric analysis of exponential-phase cells, a map of the yeast-phase cell cycle was constructed. The cycle appears to consist of two independent sequences of events, a budding growth sequence and a DNA division sequence. The nuclear division cycle of yeast-phase cells growing exponentially with a 4.5-h generation time is composed of a G1 interval of 148 min, as S phase of 16 min, and a G2 plus M interval of 107 min.     

E-cadherin expression in a particular subset of sensory neurons.

We found that the dorsal root ganglia (DRG) and trigeminal ganglia of mouse embryos express the E-cadherin cell-cell adhesion molecule and analyzed its expression profile. E-cadherin expression began around Embryonic Day 12 (E12) in these ganglia, thereafter increased, and persisted to the adult stage. This cadherin was expressed by 10 and 30% of DRG neurons in E17 and postnatal animals, respectively, as well as by satellite cells and some Schwann cells. E-cadherin-positive primary sensory fibers terminated only in a narrow region of the dorsal horn of the spinal cord, which was identified as part of lamina II by double-staining for E-cadherin and substance P or somatostatin. This E-cadherin expressing area of the spinal cord extended to part of the trigeminal nucleus in the medulla. These results showed that E-cadherin is expressed in a particular subset of primary sensory neurons which may have specific functional properties. We suggest that this adhesion molecule may play a role in the selective adhesion of sensory neuronal fibers.     

Prevalence of Varicella-Zoster Virus DNA in Dissociated Human Trigeminal Ganglion Neurons and Nonneuronal Cells

Previous analyses using in situ hybridization alone or together with PCR have yielded conflicting results regarding the cell type in which latent varicella-zoster virus (VZV) resides. We separated human trigeminal ganglia (TG) into neuronal and nonneuronal fractions, followed by primary and nested PCR to quantitate VZV DNA at the single cell level. Both TG from each of eight cadavers were dissociated and separated into neuronal and nonneuronal cell suspensions by differential filtration. Analysis of the neuron fraction (5,000 neurons per sample) revealed VZV DNA in 9 of 16 samples, with copy numbers ranging from 1 to 12, whereas only 2 of 16 nonneuronal cell samples were positive for VZV DNA, with 1 copy each. Further analysis of 10 samples of 100 neurons and the corresponding nonneuronal cell fractions from each TG of a single subject revealed VZV DNA in 3 of 10 samples of the left TG (range, 2 to 5 copies) and in 1 of 10 samples of the right TG (2 copies) but in none of the 20 nonneuronal cell fractions. These data indicate that latent VZV DNA is present primarily, if not exclusively, in neurons, at a frequency of two to five copies per latently infected neuron.     

Development and regulation of substance P in sensory neurons in vitro

Substance P (SP), the putative neuropeptide mediator of pain sensation, is contained in small dorsomedial sensory neurons of the dorsal root ganglion. Using different culture techniques and a sensitive radioimmunoassay for SP, we studied the ontogeny and regulation of this functionally important neurotransmitter in these neurons, obtained from neonatal rats. In ganglion explants grown by two different techniques, SP increased two- to threefold during the first week in culture. This rise was predominantly due to mechanisms intrinsic to the ganglion since it occurred in a fully defined medium, in the absence of added nerve growth factor (NGF). Blockade of protein synthesis with cycloheximide prevented the increase in SP suggesting that ongoing protein synthesis was necessary. Furthermore, depolarization with veratridine blocked the increase in SP, an effect which was reversed by tetrodotoxin, suggesting that transmitter characteristics in sensory neurons may be regulated by depolarization and/or transmembrane sodium flux. After a week in culture on a collagen substratum, supplementary NGF was necessary for the continued rise in SP. However, raising the dose of the trophic factor had no incremental effect on SP content, suggesting that NGF was acting primarily on neuronal survival. To approach such questions at the cellular level, ganglia were dissociated and grown in cell culture. In all cultures, SP increased 1.5-fold during the first day. In the absence of NGF, however, SP and cell numbers fell progressively after the second day. NGF elicited parallel increases in cell survival and SP content, supporting the suggestion that NGF acts primarily through neuronal survival to increase SP. Veratridine blocked the increase in SP in a tetrodotoxin-reversible manner, without affecting neuronal survival, indicating that the effects of these agents do not depend on normal ganglionic cellular architecture. Consequently, depolarization probably affects ganglionic sensory neurons directly. Our studies suggest that the development of transmitter characteristics in primary sensory neurons may be regulated by multiple factors, including neuronal activity as well as trophic agents such as NGF.     

Coordination of division events in theChlamydomonas cell cycle

Summary At concentrations that did not affect growth, hydroxyurea and 2¹-deoxyadenosine inhibited DNA synthesis inChlamydomonas. Evidence that initiation of mitosis is dependent upon completion of DNA replication was provided by the arrest of inhibited cells with undivided nuclei containing undispersed nucleoli. Initiation of cytokinesis is not dependent upon progress of nuclear division since, in arrested cells, cleavage microtubules became deployed in a phycoplast and a cleavage furrow developed fully, until obstructed by the undivided nucleus. Chloroplast constriction and division also continued independently of nuclear division. It is concluded that nuclear division, cytoplasmic cleavage and chloroplast division are in separate sequences of dependent events. This is supported by flexibility of their relative timing in successive divisions, since after the first commitment to divide nuclear division is followed by initiation of cleavage and then chloroplast division, whereas following subsequent commitments these events occur in reverse time order. This flexibility of order indicates changing rates of progress through separate sequences of events.Deposition of wall material was dependent upon the completion of cytokinesis, but this inhibition of wall deposition by incomplete cytokinesis did not extend to other daughters within the same mother cell.These observations are correlated with our earlier data concerning the rate-limiting control points for division and a model for the coordination of division events is presented. The relationships between different plant cell cycles is discussed in view of the findings presented.     

Naturally occurring and induced neuronal death in the chick embryo in vivo requires protein and RNA synthesis: evidence for the role of cell death genes.

Treatment of chick embryos in ovo for 10-12 hr with inhibitors of protein and RNA synthesis during the peak time of normal cell death (Embryonic Day 8) for motoneurons and dorsal root ganglion cells markedly reduces the number of degenerating neurons in these populations. The massive neuronal death induced by the early absence of the limbs was also blocked almost completely by these agents. Further, the death of neurons following peripheral axotomy at the end of the normal cell death period (Embryonic Day 10) was reduced significantly by treatment with inhibitors of biosynthetic reactions. These results indicate that, in vivo, naturally occurring neuronal death, neuronal death induced by the absence of peripheral targets, and axotomy-induced neuronal death later in development all require active gene expression and protein and RNA synthesis. Therefore, neuronal death in a variety of situations may reflect the expression of a developmental fate that can normally only be overridden or suppressed by specific environmental signals (e.g., neurotrophic molecules).     

神经营养因子诱导分化的神经元样PC12细胞分裂的研究

神经营养因子（nerve growth factor,NGF）诱导PC12细胞分化产生的神经元样细胞一直被认为属于分裂后的细胞,没有分裂能力。然而在本研究中,我们观察了一些已经发生分化的PC12细胞,这些细胞长有很长的神经突起,在形态上属于神经元样细胞。在这些细胞中,我们不仅检测到DNA合成,而且观察到这些细胞的分裂现象。更令人感兴趣的是,除了胞体发生分裂外,位于胞体分裂位置的突起也一分为二,分别分配给两个子细胞。这些结果说明,形态发生分化的神经元样PC12细胞仍有分裂能力。本研究首次报道神经元样PC12细胞及其突起能发生分裂。     

Opposite Effect of Protein Synthesis Inhibitors on Potassium Deficiency-Induced Apoptotic Cell Death in Immature and Mature Neuronal Cultures

Abstract: Typically, primary cultures of rat cerebellar granule neurons are grown in the presence of 25 m M KCl and are considered to mature by ∼7 days in vitro. Potassium deficiency was created by growing the neurons from days 1 to 4 in the presence of 12.5 m M KCl (immature cultures) or by switching the mature neurons grown with 25 m M KCl to 12.5 m M KCl. In both conditions we observed neuronal death that bears the signs of apoptosis, i.e., DNA fragmentation determined qualitatively by agarose gel electrophoresis of DNA and quantitatively by in situ terminal deoxynucleotidyl transferase assay. The protein synthesis inhibitors cycloheximide and anisomycin provided neuroprotection in the mature cultures but potentiated the toxic effect of KCl deprivation in the immature neurons. The results suggest that a prudent use of protein synthesis inhibitors is critical in experiments with primary neuronal cultures.     

NUCLEOCYTOPLASMIC RATIO REQUIREMENTS FOR THE INITIATION OF DNA REPLICATION AND FISSION IN TETRAHYMENA

Hydroxyurea (10 mM) arrests the exponential growth of Tetrahymena by blocking DNA replication during S-phase. After removal of the hydroxyurea (HU), they have a long recovery period during which they are active in DNA synthesis. ³H-TdR uptake showed that on completion of the recovery period, the cells divide (recovery division) and enter a cell cycle which lacks G₁. The frequency, size and DNA content of the extranuclear chromatin bodies (ECB) formed at this division are all markedly increased (2–4) over the corresponding values obtained from exponential growth phase controls. Microspectrophotometric analysis of macronuclear DNA content (N) coupled with the cytoplasmic dry mass (C) values suggest that specific N to C ratios (N/C) are required for the initiation of DNA replication and fission: during a normal (exponential growth) cell cycle, both N and C double, but asynchronously, so that the N/C of both post-fission-daughter cells and pre-fission cells is identical (standardized to N/C = 1) but late G₁ cells have a low N/C. During a 10 hr exposure to HU, the N remains essentially the same whereas the C increases. When the HU is removed, the N increases by 4× and the C continues to increase until just prior to recovery division when it also reaches a value 4× that of the original daughter cells. Thus, the N/C = 1 is re-established. The enlarged ECB formed during recovery division may function to lower the N/C in the daughter cells, which in turn may in some way stimulate immediate DNA replication, thus eliminating G₁. The elimination of G₁ (and shortening in a few subsequent cell cycles) allows less time for cytoplasmic growth and results in the return of the cells to the generation time and the N and C values observed prior to the HU treatment.     

Cellular reactions to axotomy in rat superior cervical ganglia includes apoptotic cell death

The cellular response to axonal injury in the superior cervical ganglion was examined by immunofluoresence at intervals from 6 h to 14 days after transection of the internal and external carotid nerves. GAP-43-immunoreactivity (IR) appeared in some neurons in the ganglia 1 day after axotomy, while neurons in control ganglia were GAP-43 negative. In 3 days axotomized ganglia GAP-43-IR structures were increased in number and intensity in nerve fiber bundles, while GAP-43-positive perikarya were restricted to the middle and caudal parts of the ganglia and showed an intensity that was stronger than at 1 day after axotomy. These GAP-43-positive neurons were also galanin positive. In the cranial part of the ganglia, S100-IR in satellite cells was weak at 18 h after axotomy. Peripheral to this area, S100-IR was stronger and co-localized with HSP-72-IR, preferentially located in satellite cells. HSP-72-IR was, however, occasionally observed also in principal neurons at 1 and 3 days after axotomy. In eosin-stained sections, neurons and satellite cells in the cranial part of 1 day axotomized ganglia were reduced in number, and a further loss was noted at 3 days. At 12 h some satellite cells in the cranial part of the ganglia were labelled by the in situ DNA 3'-end labelling method, indicating apoptosis, and at 18 h many cells were labelled. Some neuronal perikarya were also labelled in this region. Labelling was not observed at 1 day or later after axotomy, nor in control ganglia. The results may imply that not only neurons but also satellite cells react to neuronal axonal injury with apoptosis. Neurons in the middle and caudal part of the ganglia survived and showed increased content of GAP-43 and galanin, possibly a sign of regeneration/neuronal plasticity.