Iodination of plasma membrane proteins of BHK cells in different growth states

The surfaces of BHK cells in confluent monolayers, immediately after mechanical dispersal and in logarithmically growing suspension cultures have been iodinated with ¹²⁵I using the lactoperoxidase technique. Electrophoretic resolution of the labeled proteins revealed that the representation of plasma membrane proteins varies with the growth state. Trypsinization of the cells produced a drastic revision of the surfaces leaving behind root fragments of membrane components and exposing additional proteins for iodination. The rapid turnover of membrane proteins in growing BHK cells restored the plasma membrane to a state characteristic of the replicating cell within 10 h.     

Effects of semiconductor substrate and glia-free culture on the development of voltage-dependent currents in rat striatal neurones

An essential requirement for successful long-term coupling between neuronal assemblies and semiconductor devices is that the neurones must be able to fully develop their electrogenic repertoire when growing on semiconductor (silicon) substrates. While it has for some time been known that neurones may be cultured on silicon wafers insulated with SiO2 and Si3N4, an electrophysiological characterisation of their development under such conditions is lacking. The development of voltage-dependent membrane currents, especially of the rapid sodium inward current underlying the action potential, is of particular importance because the conductance change during the action potential determines the quality of cell-semiconductor coupling. We have cultured rat striatal neurones on either glass coverslips or silicon wafers insulated with SiO2 and Si3N4 using both serum-containing and serum-free media. We here report evidence that not only serum-free culture media but also growth on semiconductor surfaces may negatively affect the development of voltage-dependent currents in neurones. Furthermore, using surface-charge measurements with the atomic force microscope, we demonstrate a reduced negativity of the semiconductor surface compared to glass. The reduced surface charge may affect cellular development through an effect on the binding and/or orientation of extracellular matrix proteins, such as laminin. Our findings therefore suggest that semiconductor substrates are not entirely equivalent to glass in terms of their effects on neuronal cell growth and differentiation.     

Function of Catecholamine-containing Neurones in Mammalian Central Nervous System

SEVERAL chemical substances are involved in synaptic transmission in the mammalian central nervous system^1–3. The Falck-Hillarp technique⁴ has demonstrated noradrenaline, dopamine and 5-hydroxytryptamine within nerve cell bodies and terminals^5,6 and the belief that these amines act as neurohumours is strengthened by observations that nerve fibre activation leads to their release from the terminals^7,8. Histo-chemical evidence suggests that discrete systems of neurones can be identified by their content of particular amines and it seems possible that such neurohumorally homogeneous systems have a functional as well as a chemical identity. Before the anatomical distribution of amine-containing neurones had been described, Brodie and Shore⁹ proposed that noradrenaline functions as the central neurohumour of the sympathetic and 5-hydroxytryptamine of the parasympathetic system. This suggestion has not been supported by anatomical evidence; the amine-containing neurones form systems of small diameter fibres of very diffuse terminal distribution, which do not correspond to recognized ascending or descending pathways^5,6, although amine-containing neurones in invertebrates have been identified as sensory systems¹⁰.     

Excitable properties of insect neurones in culture: A developmental study

The passive and excitable electrical properties of cockroach neurones growing in vitro have been investigated using intracellular recording techniques. The resting membrane potentials of the neurones are similar to those of their in vivo counterparts but the input resistances and membrane capacitive properties are more typical of embryonic insect neurones. During the first 12 days of growth in vitro the neurones exhibit delayed rectification in response to the injection of depolarising current steps. After this period “all or none” action potentials can be evoked by depolarising pulses in approximately half of the neurones tested. These spikes are abolised by 1 μM tetrodotoxin but are unaffected by 5 mM Co²⁺. Spontaneous excitatory activity develops in approx 25% of the neurones after 3 weeks in culture.     

K252a Modulates the Expression of Nerve Growth Factor-Dependent Capsaicin Sensitivity and Substance P Levels in Cultured Adult Rat Dorsal Root Ganglion Neurones

Abstract: K252a, an inhibitor of trk phosphorylation and nerve growth factor signal transduction in PC12 cells, blocked nerve growth factor-induced responses in cultured adult rat dorsal root ganglion sensory neurones. The nerve growth factor-dependent appearance of capsaicin sensitivity and accumulation of the neuropeptide substance P were inhibited when dorsal root ganglion neurones were grown in the presence of low concentrations (100 n M ) of K252a. At higher concentrations (3 µ M ), however, K252a stimulated the development of capsaicin sensitivity and the accumulation of substance P even in the absence of nerve growth factor. By using a wide dose range, therefore, we showed that K252a could either inhibit or mimic nerve growth factor's actions on sensory neurones. These results may explain the apparent paradox in the literature that some groups show a blocking effect of K252a on nerve growth factor-dependent survival of dorsal root ganglion sensory neurones, whereas others report that K252a can substitute for nerve growth factor or other trophic factors and promote neuronal survival.     

Pacemaker Properties of Completely Isolated Neurones in <Emphasis Type="Italic">Aplysia californica</Emphasis>

SINGLE-CELL pacemaker activity is interesting because of its function in temporal organization and information processing in the nervous system. Many invertebrate neurones are regularly and autonomously active^1,2. Although the pacemaker rhythm probably originates within the recorded neurone, it is not clear whether it originates in the axonal tree or in the cell soma. Alving³ approached this question by studying pacemaker activity in the soma of Aplysia nerve cells, after ligaturing the axonal stem with fine sutures. The study described here presents evidence that nerve cell somata which are completely dissociated from all surrounding tissue and with or without axons, are able to maintain regular autorhythmic activity for periods of more than 24 h. The method of complete isolation of cells represents some progress over Alving's method because it is easier to accomplish, has a larger yield of viable neurones and allows longer recording periods.     

ELECTROPHORETIC CHARACTERIZATION OF LEUCINE-, GLUCOSAMINE- AND FUCOSE-LABELLED PROTEINS RAPIDLY TRANSPORTED IN FROG SCIATIC NERVE

—[³H]Leucine, [³H]glucosamine and [³H]fucose were incorporated in vitro into proteins in frog sciatic ganglia and subsequently transported at a rapid rate along the sciatic nerve towards a ligature, in front of which they accumulated. The synthesis of transported fucose-labelled proteins is closely linked to protein synthesis but is not dependent on RNA synthesis, as judged by effects after incubation for 17 h in the presence of cycloheximide and actinomycin D. Labelled ganglionic as well as transported material were solubilized in sodium dodecyl sulphate and characterized by polyacrylamide gel electrophoresis. The bulk of ganglionic proteins, labelled with any of the precursors used, had molecular weights exceeding 40,000. The radioactivity patterns of leucine- and glucosamine-labelled ganglionic proteins showed similarities with dominant peaks corresponding to molecular weights of about 75,000 and 50,000. The last peak was almost lacking in fucose-labelled ganglionic components. Leucine- and glucosamine labelled-transported proteins exhibited characteristic and similar electrophoretic distributions in contrast to the pattern of fucose-labelled nerve proteins, which was more polydisperse. The most conspicious nerve proteins corresponded to molecular weights of about 75,000 and 18,000. There was a remarkable agreement in the profile of leucine-labelled transported nerve proteins and fucose-labelled ganglionic proteins. In the light of these observations the possibility that glycoproteins constitute a large part of rapidly transported proteins will be discussed.     

A Role of Cyclic AMP in a Neurotrophic Process

TROPHIC effects of neurones can be defined as long-term interactions between nerve cells and the tissues they innervate, which initiate or control molecular modifications in the target cells¹. An example of trophic activity is the maintenance of the motor end plate of skeletal muscle by the nerve fibre. The motor nerve appears to exert a morphogenetic effect on its formation, because both the structural specializations and Cholinesterase activity of the end plate develop only in relation to the nerve fibre^2–5. Conversely, denervation is followed usually by degeneration of the junction and loss of end plate Cholinesterase activity^6–8.     

γ-Aminobutyric Acid Uptake by Sympathetic Ganglia

EXOGENOUS γ-aminobutyric acid (GABA) accumulates against a concentration gradient in isolated mammalian nervous tissue^1–3 and mixes with GABA stored in the tissue⁴. Thus, neurones which use GABA as an inhibitory transmitter might be identified by locating sites of accumulation of radioactively-labelled GABA using autoradiography^5–7, assuming that exogenous GABA is only taken up into neurones already containing GABA. A correlation between GABA uptake and endogenous content has been noted in slices from different parts of the brain³ and in different nerve-ending fractions^8–10. These experiments, however, do not show whether GABA can be accumulated in nerve tissue totally devoid of “gabanergic” neurones. To test this, we have measured the uptake of GABA by isolated sympathetic ganglia. The principal transmitter in the ganglion is acetylcholine while the postganglionic neurones are mainly adrenergic. By analogy with the brain, the ganglion contains negligible amounts of GABA, glutamic decarboxylase or GABA-transaminase^11,12.     

Cell wall and cell growth characteristics of giant‐celled algae

Because of their large sizes and simple shapes, giant‐celled algae have been used to study how the structural and mechanical properties of cell walls influence cell growth. Here we review known relationships between cell wall and cell growth properties that are characteristic of three representative taxa of giant‐celled algae, namely, Valonia ventricosa, internodal cells of characean algae, and Vaucheria frigida. Tip‐growing cells of the genus Vaucheria differ from cells undergoing diffuse growth in V. ventricosa and characean algae in terms of their basic architectures (non‐lamellate vs. multilamellate) and their dependence upon pH and Ca²⁺ for cell wall extensibility. To further understand the mechanisms controlling cell growth by cell walls, comparative analyses of cell wall structures and/or associated growth modes will be useful. The giant‐celled algae potentially serve as good models for such investigations because of their wide variety of developmental processes and cell shapes exhibited.     

NEWLY SYNTHESIZED RNA IN NUCLEI ISOLATED FROM NERVE AND GLIAL CELLS

—Nuclear RNA from neurones, astrocytes and other glial cells was pulse-labelled in vivo with [³H]uridine and analysed by sucrose density-gradient centrifugation after various periods of incorporation. Thirty min after the injection of the isotope, rapidly-labelled RNA appeared in all three cell types, a heterogeneous fraction sedimenting above 30S, the others at 25 and 12S. The transformation rate of the two latter components was equally rapid in all three types of nuclei studied. These components are assumed to be of messenger nature. The heavy fractions underwent transformations which in other cells have been described to lead to rRNA formation. The temporal pattern as well as the sequence of changes were similar in nuclei from neurones and astrocytes, the only difference being that a 35S intermediate was found in the former and a 32S in the latter. In non-astrocytic glial nuclei, synthesis and transformation of the 45S component were delayed as compared to the other cell types and the processing of this component may involve both a 32S and a 35S intermediate. Moreover, the radioactivity incorporated in all the nuclear RNA species was always lower in these cells.     

Simultaneous Recording of Input and Output of Lateral Geniculate Neurones

TO understand the way in which the cat dorsal lateral geniculate nucleus (LGN) processes visual information it would be useful to know the number and type of retinal inputs to individual LGN neurones. Using electrical stimulation of the optic nerve Bishop et al.¹concluded that an impulse in a single optic nerve fibre is sufficient to excite a single LGN neurone. From the appearance of excitatory postsynaptic potentials (EPSPs) recorded essentially intracellularly, Creutzfeldt suggested that LGN neurones are driven by perhaps one² or a few³ retinal ganglion cells. Hubel and Wiesel⁴ proposed models of convergence of several retinal inputs on single LGN neurones based on analyses of receptive fields. Guillery⁵ produced anatomical evidence that some types of LGN neurones receive inputs from several different retinal fibres. Now we report direct observations which were made by recording simultaneously from single LGN neurones and from individual retinal ganglion cells which provided excitatory input to them. We shall not consider inhibitory influences, which are currently under study.     

Synthesis and phosphorylation of cytoskeleton components in foetal,regenerating and adult normal rat hepatocytes during culture

Summary Detergent insoluble material (DIM) was prepared by gentle treatment with detergent from foetal, regenerating and adult normal rat hepatocytes cultured for various times. It retained to some degree the morphology of the cells. After incubation of intact cells with ³⁵S-methionine, most of the labelled DIM proteins were found to be components of the cytoskeleton. They included several cytokeratins, vimentin and actin. The synthesis rate varied with the age of animals and culture conditions. The high synthetic rate of vimentin in foetal and regenerating hepatocytes could be associated with cell proliferation. No correlation was found between cytokeratin synthesis and hepatocyte growth. Most of the cytoskeleton proteins could be phosphorylated in intact cells and in DIM from cultured hepatocytes. However the degree of phosphorylation of these proteins was not related to their synthetic rate. The decreased phosphorylation level in cultured adult rat hepatocytes could be related to the rapid loss of specific functions.     

Increased Activity of Choline Acetyl-transferase in Sympathetic Ganglia after Prolonged Administration of Nerve Growth Factor

A prolonged increase in the activity of preganglionic sympathetic nerves produces characteristic changes in the enzyme pattern of the postganglionic adrenergic neurones in adult rats^1–4. In newborn mice the normal development of adrenergic neurones depends materially on the intactness of the preganglionic cholinergic nerves⁵. These two findings contribute to the definition of the so far vague term “trophic response to neuronal activity” and the question arises whether these trophic actions are unidirectional only, or whether there is also a retrograde effect, that is, a dependence of the preganglionic cholinergic nerves on the function of the postjunctional adrenergic neurones. Transection experiments in the brain have shown that after lesioning of particular areas, for example, optic nerve tract, cingulate or visual cortex, there occurs not only orthograde but also retrograde trans-synaptic degeneration⁶. It seemed of interest to study this possible retrograde trophic effect in a less complex system and to investigate whether there are not only negative (degeneration) but also positive effects. The administration of nerve growth factor (NGF) to newborn rats produces a marked growth and enhanced differentiation of the adrenergic neurones⁷. The biochemical correlate to these morphological changes is a selective induction of tyrosine hydroxylase and dopamine β-hydroxylase⁸. We have investigated whether these effects are also reflected by changes in the preganglionic nerves.     

The development of a long,coiled, optic nerve in the stalk-eyed fly <Emphasis Type="Italic">Cyrtodiopsis whitei</Emphasis>

In the stalk-eyed fly Cyrtodiopsis whitei (Diopsidae; Diptera), the relatively long optic nerve develops within the tight lumen of a very short eyestalk. Axonal growth is generally considered in terms of path finding, selective fasciculation, and towing. Physical forces that are necessary for axon lengthening are generated either by the growth cone or by the growth of surrounding tissues. Therefore, it is surprising to encounter a loosely coiled nerve apparently lacking any attachments that could allow for pull, or towing, of the nerve. In this study, we used histological sections and whole-mount preparations to confirm that the optic nerve of the stalk-eyed fly indeed elongates without the external application of tension to the nerve. Secondly, we examined the distribution of cytoskeletal elements and selected proteins that may be involved in axon extension. Staining against the vesicle fusion proteins SNAP-24 and SNAP-25 consistently results in stronger staining in the rapidly extending optic nerve than in a control nerve, suggesting a possible role of these proteins in the extension process. On a gross morphological level, SNAP-24/25 as well as the cytoskeletal elements actin and tubulin are uniformly distributed throughout the lengths of the growing nerve, suggesting that nerve elongation is distributed rather than localized. Finally, we identified glia as a possible source for tension within the nerve bundle. Glia proliferate rapidly in the optic nerve but not in the control nerve. Much work continues to focus on the growth of axons in culture, but this study is one of the few that considers the dynamics of nerve bundle extension as a whole.This research is supported by the National Science Foundation (IBN-9974512 and IBN-211770).     

Enhancement of BDNF production by co-cultivation of human neuroblastoma and fibroblast cells

It has been proved that co-cultivation of human neuroblastoma cells and human fibrolast cells can enhance nerve cell growth and the production of BDNF in perfusion cultivation. In batch co-cultivation, maximum cell density was increased up to 1.76×10⁶ viable cells/mL from 9×10⁵ viable cells/mL of only neuroblastoma cell culture. The growth of neuroblastoma cells was greatly improved by culturing both nerve and fibroblast cells in a perfusion process, maintaining 1.5×10⁶ viable cells/mL, which was much higher than that from fed-batch cultivation. The nerve cell growth was greatly enhanced in both fed-batch and perfusion cultivations while the growth of fibroblast cells was not. It strongly implies that the factors secreted from, human fibroblast cells and/or the environments of co-culture system can enhance both cell growth and BDNF secretion. Specific BDNF production rate was not enhanced in co-cultures; however, the production period was increased as the cell growth was lengthened in the co-culture case. Competitive growth between nerve cells and fibroblast cells was not observed in all cases, showing no changes of fibroblast cell growth and only enhancement of the neuroblastoma cell growth and overall BDNF production. It was also found that the perfusion cultivation was the most appropriate process for cultivating two cell lines simultaneously in a bioreactor.     

Depression of presynaptic excitation by the activation of vanilloid receptor 1 in the rat spinal dorsal horn revealed by optical imaging

Hypoxia alters neuronal function and can lead to neuronal injury or death especially in the central nervous system. But little is known about the effects of hypoxia in neurones of the peripheral nervous system (PNS), which survive longer hypoxic periods. Additionally, people have experienced unpleasant sensations during ischemia which are dedicated to changes in conduction properties or changes in excitability in the PNS. However, the underlying ionic conductances in dorsal root ganglion (DRG) neurones have not been investigated in detail. Therefore we investigated the influence of moderate hypoxia (27.0 ± 1.5 mmHg) on action potentials, excitability and ionic conductances of small neurones in a slice preparation of DRGs of young rats. The neurones responded within a few minutes non-uniformly to moderate hypoxia: changes of excitability could be assigned to decreased outward currents in most of the neurones (77%) whereas a smaller group (23%) displayed increased outward currents in Ringer solution. We were able to attribute most of the reduction in outward-current to a voltage-gated K⁺ current which activated at potentials positive to -50 mV and was sensitive to 50 nM α-dendrotoxin (DTX). Other toxins that inhibit subtypes of voltage gated K⁺ channels, such as margatoxin (MgTX), dendrotoxin-K (DTX-K), r-tityustoxin Kα (TsTX-K) and r-agitoxin (AgTX-2) failed to prevent the hypoxia induced reduction. Therefore we could not assign the hypoxia sensitive K⁺ current to one homomeric K_V channel type in sensory neurones. Functionally this K⁺ current blockade might underlie the increased action potential (AP) duration in these neurones. Altogether these results, might explain the functional impairment of peripheral neurones under moderate hypoxia.     

Morphological changes and expression of protein kinase CK2 β subunit in the microglia after hypoglossal nerve transection

Following hypoglossal nerve transection, the microglia of the rat hypoglossal nucleus expressed protein kinase CK2 β subunit immunoreactivity. CK2 β immunostaining occurred on the operated side from postoperative day 3; on day 5 we observed strong immunoreactivity and the immunopositive microglial cell processes surrounded the injured neurones. Thereafter, the immunoreactivity decreased gradually and on day 10 the immunopositive cells surrounded only a few injured neurones. Electron microscopic observations on the hypoglossal nucleus revealed microglia-neuronal contact within 3 hours of nerve injury, and by day 3 all the injured neurones were in contact with microglial cells. These observations indicated that microglia-neuronal contact occurred earlier than the CK2 β subunit immunoreactivity. CK2 may not be implicated during the initial migration of the microglia to the injured neurones; however, it may enhance the growth and elongation of the microglial cell processes around the injured neurones.     

Using plusTipTracker Software to Measure Microtubule Dynamics in Xenopus laevis Growth Cones

Microtubule (MT) plus-end-tracking proteins (+TIPs) localize to the growing plus-ends of MTs and regulate MT dynamics^1,2. One of the most well-known and widely-utilized +TIPs for analyzing MT dynamics is the End-Binding protein, EB1, which binds all growing MT plus-ends, and thus, is a marker for MT polymerization¹. Many studies of EB1 behavior within growth cones have used time-consuming and biased computer-assisted, hand-tracking methods to analyze individual MTs^1-3. Our approach is to quantify global parameters of MT dynamics using the software package, plusTipTracker⁴, following the acquisition of high-resolution, live images of tagged EB1 in cultured embryonic growth cones⁵. This software is a MATLAB-based, open-source, user-friendly package that combines automated detection, tracking, visualization, and analysis for movies of fluorescently-labeled +TIPs. Here, we present the protocol for using plusTipTracker for the analysis of fluorescently-labeled +TIP comets in cultured Xenopus laevis growth cones. However, this software can also be used to characterize MT dynamics in various cell types^6-8.