Influence of the extracellular potassium environment on neurite growth in sensory neurons, spinal cord neurons and sympathetic neurons

Competition for neurotrophic factors: mathematical analysis

Neurotrophic factors, particularly the neurotrophin gene family of neurotrophic factors, are implicated in activity-dependent anatomical plasticity in the visual cortex and at the neuromuscular junction. Accumulating evidence implicates neurotrophic factors as possible mediators of activity-dependent competition between afferents, leading to the segregation of afferents' arbors on the target space. We present a biologically plausible mathematical model of competition for neurotrophic factors. We show that the model leads to anatomical segregation, provided that the levels of neurotrophic factors released in an activity-independent manner, or the levels available by exogenous infusion, are below a critical value, which we derive. Above this critical value, afferent segregation breaks down. We also show that the model segregates afferents even in the presence of very highly correlated patterns of afferent activity. The model is therefore ideally suited for application to the development of ocular dominance columns in the kitten visual cortex.

Competition for neurotrophic factors: ocular dominance columns

Activity-dependent competition between afferents in the primary visual cortex of many mammals is a quintessential feature of neuronal development. From both experimental and theoretical perspectives, understanding the mechanisms underlying competition is a significant challenge. Recent experimental work suggests that geniculocortical afferents might compete for retrograde neurotrophic factors. We show that a mathematically well-characterized model of retrograde neurotrophic interactions, in which the afferent uptake of neurotrophic factors is activity-dependent and in which the average level of uptake determines the complexity of the axonal arbors of afferents, permits the anatomical segregation of geniculocortical afferents into ocular dominance columns. The model induces segregation provided that the levels of neurotrophic factors available either by activity-independent release from cortical cells or by exogenous cortical infusion are not too high; otherwise segregation breaks down. We show that the model exhibits changes in ocular dominance column periodicity in response to changes in interocular image correlations and that the model predicts that changes in intraocular image correlations should also affect columnar periodicity.

Cholinergic differentiation of rat sympathetic neurons in culture: Effects of factors applied to distal neurites

Cholinergic properties are induced in sympathetic neurons by several factors applied to entire neurons in culture. Evidence from work with the rat sweat gland model indicates that factors located in target tissues can induce cholinergic differentiation in vivo. We now report that when leukemia inhibitory factor (LIF), heart cell-conditioned medium (HCCM), or dermal fibroblast-conditioned medium (DFCM) is applied to only distal neurites in compartmented cultures of rat sympathetic neurons, the neurons exhibit an increase in specific choline acetyltransferase activity and a concomitant decrease in levels of tyrosine hydroxylase. LIF, HCCM, and DFCM also induce neurite fasciculation, thus suggesting an additional role of cholinergic switching factors in regulating axon-axon and/or axon-substrate adhesion. These results demonstrate that rat sympathetic neurons have the cellular machinery to respond to cholinergic differentiation cues located in peripheral targets, analogous to the response to nerve growth factor.

Peptidergic neurons of the crab, Cardisoma carnifex, in defined culture maintain characteristic morphologies under a variety of conditions

Peptidergic neurons dissociated from the neurosecretory cell group, the X-organ, of adult crabs (Cardisoma carnifex) show immediate outgrowth on unconditioned plastic dishes in defined medium. Most of the neurons can be categorized as small cells, branchers or veilers. A fourth type, "superlarge," found occasionally, has a soma diameter greater than 40 microns and multipolar outgrowth. We report here the effects on morphology that follow alterations of the standard defined culturing conditions. The three common types of neurons are present when cells are grown in crab saline or saline with L-glutamine and glucose (saline medium). Changes of pH between 7.0 to 7.9 have no effect. Osmolarity changes cause transient varicosities in small cells. In some veilers, pits rapidly appear in the veil and then disappear within 35 min. In cultures at 26 degrees C instead of 22 degrees C, veilers extend processes from the initial veil in a pattern similar to branchers, and the processes of adjacent veilers sometimes form appositions. Culturing in higher [K+]o medium ([K+]o = 15-110 mM; standard = 11 mM) has no long-term effect, but growth is arrested by [K+]o greater than 30 mM. Cultures were also grown in media in which [Ca2+]o ranged from 0.1 microM to 26 mM (standard = 13 mM). Outgrowth occurred from all neuronal types in all [Ca2+]o tested. Thus, the expression of different outgrowth morphologies occurs under a wide variety of culturing conditions.

Depolarization-induced changes in neurite elongation and intracellular Ca2+ in isolated Helisoma neurons

This study focuses on the effects of K+ depolarization on neurite elongation of identified Helisoma neurons isolated into culture. Application of K+ to the external medium caused a dose-dependent suppression of neurite elongation. Lower concentrations of K+ were associated with a slowing in the rate of neurite elongation, whereas higher concentrations produced neurite retraction. Surprisingly, the effects of K+ depolarization were transient, and neurite elongation rates recovered towards control levels within 90 min even though the neurons remained in high-K+ solution. Identified neurons differed in the magnitude of their response to K+ depolarization; neurite elongation of buccal neuron B4 was inhibited at 5 mM K+, but elongation in B5 and B19 was not affected until concentrations of 25 mM. Electrophysiologically, K+ application evoked a brief period (5-10 s) of action potential activity that was followed by a steady-state membrane depolarization lasting 2 h or more. The changes in neurite elongation induced by K+ depolarization occurred in isolated growth cones severed from their neurites and were blocked by application of calcium antagonists. Intracellular free Ca2+ levels in growth cones of B4 and B19 increased and then decreased during the 90-min depolarization, corresponding to the changes in elongation. B4 and B19 showed differences in the magnitude, time course, and spatial distribution of the Ca2+ change during depolarization, reflecting their different sensitivities to depolarization.

Establishment of pure neuronal cultures from fetal rat spinal cord and proliferation of the neuronal precursor cells in the presence of fibroblast growth factor

A primary culture system of nearly pure neuronal cells from 14-day-old fetal rat spinal cord has been developed by combining a preplating step, the use of a chemically defined serum-free medium, and borated polylysine-coated dishes that prevented the formation of cell aggregates. About 98% of the cells were found to be immunostained with neuron-specific enolase antibodies, confirming their neuronal nature. The cultures are composed essentially of a population of non-motoneurons and contain few motoneurons, characterized by their large size and multipolar aspect, the presence of acetylcholinesterase (AChE), and the intense immunoreaction for growth-associated protein GAP-43. Neuronal precursor cells are also present in these cultures and proliferate during the first 3 days. The addition of bovine brain basic fibroblast growth factor (bFGF) stimulates their proliferation over a period of 2 days, as determined by measurement of [125I]iododeoxyuridine incorporation and by immunocytochemical reaction after bromodeoxyuridine incorporation into nuclei. The proliferating cells were characterized as neurons by immunostaining against neuron-specific enolase. Recombinant human bFGF and bovine brain acidic FGF (aFGF) exerted similar effects. Other growth factors, including epidermal growth factor (EGF), transforming growth factor beta 1 (TGF-beta 1), and thrombin, were without effect on the proliferative activity of these neuronal cells. bFGF has no effect on the survival of motoneurons and on the fiber outgrowth of the whole neuronal population. However, bFGF affects the development of bipolar AChE-positive neurons, probably belonging to the non-motoneuron population. The data indicate that bFGF and aFGF are mitogens for neuroblasts from rat spinal cord in culture and that bFGF influences the development of a subpopulation of spinal neurons that are AChE-positive.

Promotion of neuronal survival in vitro by thermal proteins and poly(dicarboxylic)amino acids

Evaluating molecules for their ability to promote survival and growth of neurons, we tested thermal proteins on cultures of dissociated fetal rat forebrain neurons. (Thermal proteins are polyamino acids formed when mixtures of amino acids with minimal proportions of glutamic or aspartic acid are heated.) Thermal proteins, added to low-density cultures in serum-free medium, stimulated neurite outgrowth and induced the formation of neuronal networks which survived for 6-10 days. Neurons in control cultures failed to grow and degenerated completely within 2-4 days. Effective concentrations (EC50) of thermal proteins ranged from 3 to 100 micrograms/ml. They were equally effective when present in the medium during the culture time or after precoating of the culture dishes. A single preparation which contained only aspartic and glutamic acid was effective, and similar survival promoting actions were then found for polyglutamic acid and mixed polyamino acids containing glutamic or aspartic acid. Thermal proteins and polyglutamic acid acted in a specific manner since, under the same experimental conditions, many control peptides, proteins and growth hormones failed to promote survival of neurons. Furthermore, their effects were antagonized by heparin, but not heparan sulfate nor chondroitin sulfate. These findings suggest that sequences of successive dicarboxylic amino acid residues are able to promote survival and neurite elongation of cultured neurons and that such sequences are responsible for the survival promoting action of thermal proteins. They invite the speculation that sequences of successive dicarboxylic amino acids, while occur in many proteins and show a high degree of evolutionary conservation, may have functional role in molecular recognition processes during neuronal development.

Elevated potassium shortens action potential duration by altering outward currents in chick dorsal root ganglia neurons

Dissociated embryonic chick dorsal root ganglion (DRG) neurons maintained in culture exhibit a mixed Na+/Ca2+ action potential. The characteristic "shoulder" on the repolarizing phase is due to the relatively prolonged inward Ca2+ current. DRG neurons grown in an elevated K+ medium (25 versus. 5 mM) lack the plateau phase of the action potential. Voltage-clamp analysis showed that this plastic change in action potential duration is not due to the loss of the inward Ca2+ current but is partly due to the appearance of a Ca2(+)-dependent, 4-aminopyridine-(4-AP)-sensitive transient outward current. Faster activation of the purely voltage-dependent delayed rectifier outward current also contributes to the rapid repolarization observed in neurons cultured in elevated K+ medium.

Effects of calcium ion on neurite outgrowth of rat spinal cord neurons in vitro: the role of non-neuronal cells in regulating neurite sprouting

The interactions of nerve cells with their environment and other cells are specific to different stages of cellular differentiation. Neurite outgrowth was measured from cultured spinal cord neurons under the influence of different Ca2+ concentrations. We used fluorodeoxyuridine (FuDr), an antimitotic agent which reduces significantly the proportion of non-neuronal cells in spinal cord cell cultures, to examine the effects of non-neuronal cells on neurite outgrowth. Spinal cord neurons responded to changes in their environment by means of two types of neurite outgrowth: sprouting and elongation. The concurrent presence of non-neuronal cells led to increased sprouting of neurites in certain ionic environments, thus lending support to the idea that non-neuronal cells release diffusible factors which influence sprouting and guide neurite outgrowth.

High K+-mediated survival of spinal sensory neurons depends on developmental stage

Elevated concentrations of K+ (35 mM) have previously been shown to support the survival of most embryonic chick sympathetic neurons in vitro (Wakade et al., Exp cell res 144 (1983) 377, [23]) and to be interchangeable with nerve growth factor (NGF) as a survival-promoting agent for these cells (Wakade & Thoenen, Neurosci lett 45 (1984) 71 [21]). In the present study, we show that dorsal root ganglion (DRG) neurons from embryonic day 6 do not survive in the presence of high K+, although both NGF and brain-derived neurotrophic factor (BDNF) each support the survival of more than 50% of the cells at this developmental stage. At E6, high K+ appears to have a cytotoxic effect on BDNF-dependent neurons, and there is also considerable inhibition of neurite outgrowth. At a later developmental stage (E12), high K+ supports the survival of about 40% of DRG cells. This subpopulation of neurons is distinct from that supported by NGF (as evidenced by the additivity of these two agents), but partially overlaps with that supported by BDNF (i.e., the two agents are less than additive). At E12, only approx. 20% of the cells can be supported by either NGF or BDNF, with the rest depending exclusively on one or the other of these factors. This is in contrast to the situation at E6, where there is considerable overlap between NGF- and BDNF-dependent populations.

Retraction and degeneration of sympathetic neurites in response to locally elevated potassium

Sympathetic neurons from superior cervical ganglia of newborn rats were plated into center compartments of 3-compartment culture dishes, allowing exposure of distal neurites to media of different composition than provided to cell bodies and proximal neurites. Cultures were maintained initially with an external potassium concentration ([K+]o) of either 5 mM in all compartments or 50 mM in all compartments. After neurites had elongated into distal compartments, the culture medium was changed such that: the cell bodies and proximal neurites were exposed to 5 mM [K+]o; the distal neurites in one side compartment of each culture were also exposed to 5 mM [K+]o; but the distal neurites in the opposite side compartment were exposed to 50 mM [K+]o. During the next 7-10 days, the distal neurites locally exposed to 50 mM [K+]o degenerated. Many neurites developed a stretched appearance before degenerating, and detailed observations suggest that the neurites retracted to the point where mechanical tension exceeded their strength and then abruptly disintegrated. Neurites in opposite side compartments exposed to 5 mM [K+]o were normal in appearance and did not degenerate. These results suggest that a proximo-distal increase in [K+]o causes an extreme retraction of neurites distal to the increase. These results raise the possibility that K+ released by active nerve endings might cause the retraction of inactive nerve endings, thus providing a possible mechanism for the influence of activity on competition for synaptic sites, a pervasive phenomenon in the developing nervous system.