Your search keyword '"Neurons growth & development"' showing total 6 results

1. Freeze-fracturing of nerve growth cones and young fibers. A study of developing plasma membrane.

Author

Pfenninger KH and Bunge RP

Subjects

Animals, Axons ultrastructure, Culture Techniques, Microscopy, Electron, Microscopy, Phase-Contrast, Neuroglia ultrastructure, Neurons ultrastructure, Olfactory Bulb, Pseudopodia ultrastructure, Rats, Spinal Cord, Cell Membrane ultrastructure, Freeze Etching methods, Neurons growth & development

Abstract

Neural and non-neural cellular processes have been studied in organotypic cultures of spinal cord and olfactory bulb by means of the freeze-fracturing technique. Identification of specific cellular elements in replicas has been achieved by comparison with thin-sectioned material in which differences in shape and contents are evident. Freeze-fracturing reveals that neural growth cones may be distinguished from glial pseudopodia by the low number of intramembranous particles within their plasma membrane; the counts of particles within the growth cone membrane average 85/microm(2) (for the inner leaflet) as opposed to hundreds per square micrometer in glial pseudopodia. Whereas the intramembranous particle number in glial pseudopodia is only slightly lower than in their perikaryal plasmalemma, the number of particles in outgrowing axons increases about eightfold from the periphery towards the perikaryon. Furthermore, with prolonged time of growth in culture, the particle density in the young nerve fibers increases by about the same factor. The same phenomenon, i.e. a low intramembranous particle level at earlier stages and an increase in numbers as the nerve fiber matures, is observed in fetal nerve tissue in vivo. These findings suggest that the plasmalemma of the outgrowing nerve, and especially of the growth cone, is immature and that maturation is accompanied by the insertion of intramembranous particles. Furthermore, these data indicate that the chemistry of the growth cone membrane is distinct from that of the neuron soma which may be significant for the mechanisms of guidance and recognition in the growing nerve tip.

Published

1974

2. Ultrastructure and function of growth cones and axons of cultured nerve cells.

Author

Yamada KM, Spooner BS, and Wessells NK

Subjects

Animals, Axons drug effects, Cell Membrane, Chick Embryo, Colchicine pharmacology, Cycloheximide pharmacology, Endoplasmic Reticulum, Ganglia, Spinal cytology, Inclusion Bodies, Leucine metabolism, Microscopy, Electron, Microscopy, Phase-Contrast, Microtubules, Mycotoxins pharmacology, Nerve Fibers, Myelinated, Nerve Growth Factors pharmacology, Neurofibrils, Neurons drug effects, Neurons embryology, Protein Biosynthesis, Proteins antagonists & inhibitors, Tritium, Axons cytology, Axons growth & development, Culture Techniques, Neurons cytology, Neurons growth & development

Abstract

Dorsal root ganglion nerve cells undergoing axon elongation in vitro have been analyzed ultrastructurally. The growth cone at the axonal tip contains smooth endoplasmic reticulum, vesicles, neurofilaments, occasional microtubules, and a network of 50-A in diameter microfilaments. The filamentous network fills the periphery of the growth cone and is the only structure found in microspikes. Elements of the network are oriented parallel to the axis of microspikes, but exhibit little orientation in the growth cone. Cytochalasin B causes rounding up of growth cones, retraction of microspikes, and cessation of axon elongation. The latter biological effect correlates with an ultrastructural alteration in the filamentous network of growth cones and microspikes. No other organelle appears to be affected by the drug. Removal of cytochalasin allows reinitiation of growth cone-microspike activity, and elongation begins anew. Such recovery will occur in the presence of the protein synthesis inhibitor cycloheximide, and in the absence of exogenous nerve growth factor. The neurofilaments and microtubules of axons are regularly spaced. Fine filaments indistinguishable from those in the growth cone interconnect neurofilaments, vesicles, microtubules, and plasma membrane. This filamentous network could provide the structural basis for the initiation of lateral microspikes and perhaps of collateral axons, besides playing a role in axonal transport.

Published

1971

3. Fine structure of nerve fibers and growth cones of isolated sympathetic neurons in culture.

Author

Bunge MB

Subjects

Animals, Axons cytology, Axons growth & development, Cell Membrane, Cells, Cultured, Dendrites cytology, Dendrites growth & development, Endoplasmic Reticulum, Inclusion Bodies, Microtubules, Mitochondria, Neurons growth & development, Polyribosomes, Rats, Sympathetic Nervous System, Neurons cytology

Abstract

The leading tips of elongating nerve fibers are enlarged into "growth cones" which are seen in tissue culture to continually undergo changes in conformation and to foster numerous transitory slender extensions (filopodia) and/or a veillike ruffling sheet. After explantation of 1-day-old rat superior cervical ganglia (as pieces or as individual neurons), nerve fibers and tips were photographed during growth and through the initial stages of aldehyde fixation and then relocated after embedding in plastic. Electron microscopy of serially sectioned tips revealed the following. The moving parts of the cone, the peripheral flange and filopodia, contained a distinctive apparently filamentous feltwork from which all organelles except membranous structures were excluded; microtubules were notably absent from these areas. The cone interior contained varied forms of agranular endoplasmic reticulum, vacuoles, vesicles, coated vesicles, mitochondria, microtubules, and occasional neurofilaments and polysomes. Dense-cored vesicles and lysosomal structures were also present and appeared to be formed locally, at least in part from reticulum. The possible roles of the various forms of agranular membranous components are discussed and it is suggested that structures involved in both the assembly and degradation of membrane are present in the cone. The content of these growing tips resembles that in sensory neuron growth cones studied by others.

Published

1973

4. Colchicine inhibition of nerve fiber formation in vitro.

Author

Daniels MP

Subjects

Animals, Autoradiography, Carbon Isotopes, Cell Count, Cell Survival, Chick Embryo, Colchicine administration & dosage, Culture Techniques, Leucine metabolism, Lumbosacral Region, Methylamines pharmacology, Microscopy, Phase-Contrast, Microtubules, Nerve Degeneration, Nerve Tissue Proteins biosynthesis, Neurons drug effects, Neurons metabolism, Protein Binding, Time Factors, Alkaloids pharmacology, Colchicine pharmacology, Ganglia, Spinal growth & development, Neurons growth & development

Abstract

Inhibition of nerve fiber (neurite) formation by colchicine and Colcemid was studied in monolayer cultures of dissociated spinal ganglia of the chick. Replica cultures were fixed after appropriate incubation and alkaloid treatment. Quantitative estimates of the mean total neurite length per neuron (MNL) were made by use of camera lucida tracing. MNL values plotted against time of incubation gave control curves with an initial lag period, a phase of rapid increase, and a final phase in which MNL increase was retarded. Colchicine at 0.01-0.05 microg/ml (2.4 x 10(-8)-1.2 x 10(-7)M) caused reversible, concentration dependent, inhibition of the increase in MNL when applied during the lag period or phase of rapid increase. At the highest concentration there was a net decrease in MNL. The effect of Colcemid at 0.05 microg/ml was similar to that of colchicine, but more rapidly reversible. In most experiments there was no loss of neurons during the period of inhibition of MNL increase by colchicine or Colcemid. Therefore selective destruction of neurons was not involved in the inhibition of neurite growth. Prolonged incubation after treatment with the highest concentration used resulted in a 50% loss of neurons, in part through detachment of viable cells. Quantitative radioautography of the alkaloid-treated neurons with leucine-(14)C indicated little or no inhibition of incorporation into protein during inhibition of MNL increase. The results strongly suggest that inhibition of neurite growth involves a specific effect of colchicine, presumably the disruption of microtubules. They are thus consistent with the hypothesis that the polymerization of microtubules is essential to the formation of nerve fibers.

Published

1972

5. Branching patterns of individual sympathetic neurons in culture.

Author

Bray D

Subjects

Animals, Axons cytology, Axons growth & development, Cell Movement, Cells, Cultured, Dendrites cytology, Dendrites growth & development, Motion Pictures, Neurons growth & development, Rats, Sympathetic Nervous System, Time Factors, Neurons cytology

Abstract

The growth of single sympathetic neurons in tissue culture was examined with particular regard to the way in which the patterns of axonal or dendritic processes (here called nerve fibers), were formed. The tips of the fibers were seen to advance in straight lines and to grow at rates that did not vary appreciably with time, with their position in the cell outgrowth, or with the fiber diameter. Most of the branch points were formed by the bifurcation of a fiber tip (growth cone), apparently at random, and thereafter remained at about the same distance from the cell body. It seemed that the final shape of a neuron was the result of the reiterated and largely autonomous activities of the growth cones. The other parts of the cell played a supportive role but, apart from this, had no obvious influence on the final pattern of branches formed.

Published

1973

6. The effects of varying concentrations of colchicine on the progression of grasshopper neuroblasts into metaphase.

Author

Mueller GA, Gaulden ME, and Drane W

Subjects

Animals, Culture Media, Insecta embryology, Neurons embryology, Neurons growth & development, Temperature, Time Factors, Colchicine pharmacology, Insecta drug effects, Mitosis drug effects, Neurons drug effects

Abstract

The effects of four concentrations of colchicine (2.5 x 10(-7), x 10(-5), x 10(-3), and x 10(-2)M) on the cell cycle of grasshopper neuroblasts have been determined by direct observations on living cells. The lowest concentration, 2.5 x 10(-7)M, does not completely disorganize the spindle but does retard its action. The three higher concentrations disorganize the spindle, so that all cells reaching metaphase are blocked in a c-mitotic condition throughout the period of observations (308 min at 38 degrees C, the minimum duration of the cell cycle in untreated neuroblasts). Continuous treatment with all concentrations reduces the rate at which neuroblasts enter metaphase, the extent of the reduction being a function of increasing concentration and time of exposure. After a short exposure to 2.5 x 10(-5)M colchicine, the neuroblasts recover from the inhibiting effects on progression through the cycle to metaphase, but they show no recovery from the inhibiting effects on spindle formation for more than 3 hr. Apparent stimulation of progression rate occurs early in exposure to all concentrations and during recovery from a short exposure to 2.5 x 10(-5)M. Morphological alterations in the chromatin of telophase, interphase, and prophase cells are induced by the higher concentrations of colchicine. The data indicate that caution should be exercised in the use of colchicine for determining cell cycle duration and/or the effects of physical and chemical agents on the cycle.

Published

1971