Age-dependent requirements of sympathetic neurons in serum-free culture

Cyclic phosphatidic acid elicits neurotrophin-like actions in embryonic hippocampal neurons

Cyclic phosphatidic acid (cPA; 1-acyl-sn-glycerol-2,3-cyclic phosphate) is an analog of the growth factor-like phospholipid mediator lysophosphatidic acid (LPA). As brain tissue is the richest source of cPA we tested its effects on hippocampal neurons from day 16/17 embryonic rat cultured in a serum-free medium. Nanomolar concentrations of cPA elicited a neurotrophic effect and promoted neurite outgrowth that exceeded that of 50 ng/mL nerve growth factor (NGF). Pertussis toxin, the LPA1/LPA3 receptor-selective antagonist dioctylglycerol pyrophosphate, the myristoylated inhibitory pseudosubstrate peptide of protein kinase A (PKI), Wortmannin and PD98059 abolished the neurite-promoting effect. cPA elicited a sustained activation of extracellular signal-related kinases (ERK) 1/2 and Akt. Clostridium difficile toxin B, an inhibitor of the Rho family of GTPases, reduced cPA-induced enhancement of neurite outgrowth. In B5P cells, a clonal cell line of PC12 cells overexpressing tyrosine kinase NGF receptor (TrkA), cPA elicited transphosphorylation of TrkA. cPA-elicited ERK activation was blocked by K252a and PKI. These results suggest that cPA mimics the effects of, and activates signaling pathways similar to, the neurotrophin NGF in cultured embryonic hippocampal neurons and B5P cells.

Preferential activation of midbrain dopamine neurons by appetitive rather than aversive stimuli

Midbrain dopamine systems are crucially involved in motivational processes underlying the learning and execution of goal-directed behaviour. Dopamine neurons in monkeys are uniformly activated by unpredicted appetitive stimuli such as food and liquid rewards and conditioned, reward-predicting stimuli. By contrast, fully predicted stimuli are ineffective, and the omission of predicted reward depresses their activity. These characteristics follow associative-learning rules, suggesting that dopamine responses report an error in reward prediction. Accordingly, neural network models are efficiently trained using a dopamine-like reinforcement signal. However, it is unknown whether the responses to environmental stimuli concern specific motivational attributes or reflect more general stimulus salience. To resolve this, we have compared dopamine impulse responses to motivationally opposing appetitive and aversive stimuli. In contrast to appetitive events, primary and conditioned non-noxious aversive stimuli either failed to activate dopamine neurons or, in cases of close resemblance with appetitive stimuli, induced weaker responses than appetitive stimuli. Thus, dopamine neurons preferentially report environmental stimuli with appetitive rather than aversive motivational value.

Neuronal cell cultures: a tool for investigations in developmental neurobiology

The aim of this review is to describe environmental requirements for survival of neuronal cells in culture, and secondly to survey the complex interplay between hormones, neurotrophic factors, transport- and extracellular matrix- proteins, which characterize the developmental program of differentiating neurons. An overall reconsideration of the literature in this vast field is above the limits of the present paper; since progress and refinement in the techniques of neuronal cell cultures have paralleled the advancement in Developmental Neurobiology, we will run instead through the main steps which form the conceptual framework of neuronal cell cultures.

Co-activation of insulin-like growth factor-I receptors and protein kinase C results in parasympathetic neuronal survival

We have studied the interaction between several growth factors to promote parasympathetic neuronal survival. Neither insulin nor insulin-like growth factor-I (IGF-I) had any effect on the survival of embryonic day 8 chick ciliary neurons in culture. Similarly, the protein kinase C activator phorbol dibutyrate (PdBu) had only a minor survival-promoting activity. In combination with PdBu, however, IGF-I or insulin, at concentrations sufficient to act through the IGF-I receptor, were highly synergistic. In a similar fashion, acidic fibroblast growth factor (aFGF)-induced neuronal survival was greatly enhanced by PdBu, as well as by insulin or IGF-I. When added alone, aFGF-induced cell survival required the presence of 1% serum. However, addition of aFGF, IGF-I, or insulin with PdBu under serum-free conditions replaced the serum requirement. That is, these agonist combinations could apparently induce the second messenger requirement for ciliary neuronal survival. Therefore, IGF-I must now be included in the list of candidate molecules responsible for directing parasympathetic nerve formation. The synergy between agonists observed in these experiments highlights the possibility that combinations of growth factors, rather than sole molecules, may dictate parasympathetic nervous system development in vivo.

Nonidentical distribution of transferrin and ferric iron in human brain

Using the avidin-biotin immunoperoxidase technique and a diaminobenzidine intensification of the Prussian Blue method, we have compared the distribution of transferrin to that of ferric iron in five normal autopsy brains from adult human males. The observed distribution of transferrin was considerably more widespread than: (1) that of histochemically demonstrable ferric iron; (2) that reported for transferrin in the fetal and neonatal human brain; and (3) that reported for transferrin in other species. Transferrin immunoreactivity was present in neurons, oligodendrocytes, astrocytes, ependymal cells, and choroid plexus epithelial cells, although not in all cells of any type. Ferric iron, on the other hand, was demonstrable only in oligodendrocytes, in myelin sheaths, and possibly in axons. While staining for both transferrin and iron was relatively high in the basal ganglia and substantia nigra, the pattern of staining differed, with striatal efferent fibers staining more heavily than the neuropil for iron and less heavily than the neuropil for transferrin. The choroid plexus, which in the rat has been shown to synthesize transferrin, stained heavily for transferrin and not at all for iron. The findings of low iron and high transferrin in the choroid plexus suggest that the plexus may secrete transferrin into the cerebrospinal fluid, thereby facilitating the translocation of iron within the neuraxis. Furthermore, the nonidentical distribution of ferric iron and transferrin suggests that, in the human brain, transferrin may serve other functions besides the transport of iron from extracellular fluid to cytoplasm.

Morphological differentiation of embryonic rat sympathetic neurons in tissue culture. II. Serum promotes dendritic growth

In the preceding paper, we reported that embryonic rat sympathetic neurons formed axons, but not dendrites, when they were maintained in the absence of serum and nonneuronal cells. To assess the effects of serum-derived factors on cellular morphology, cultures were initially maintained in serum-free medium while nonneuronal cells were eliminated. Subsequently some cultures were chronically exposed either to fetal calf serum (10%) or to a high-molecular-weight ammonium sulfate fraction of serum (P40 material, 500 micrograms/ml). Phase-contrast microscopy revealed that serum and P40 material did not alter neuronal survival, but did cause flattening of the somata and fasciculation of processes. When neurons exposed to serum or P40 material were injected with Lucifer Yellow, it was found that the majority (greater than or equal to 90%) had local, tapered processes that could be identified as dendrites by light microscopic criteria. These local processes also exhibited other dendritic characteristics in that (1) they reacted with monoclonal antibodies to nonphosphorylated forms of the M and H neurofilament subunits and to microtubule-associated protein 2; and (2) they had substantial amounts of RNA as determined by [3H]uridine autoradiography. Quantitative measurements of the effects of serum and P40 material on dendritic morphology revealed that (1) an 8-day exposure caused most neurons (greater than 80%) to form dendrites; (2) neurons typically had more than one dendrite (mean of 4.1 +/- 0.2 dendrites/cell after a 28-day exposure); and (3) the dendrites were relatively short with the maximum extent of the dendritic arbor being 110 +/- 13 micron after 4 weeks. Serum and P40 material did not routinely cause the formation of supernumerary axons, did not alter radial axonal outgrowth from ganglion explants, and did not significantly increase [3H]leucine incorporation. Thus, serum contains a factor (or factors) which selectively stimulates the extension of dendrites, but not axons. If such a factor were operative in situ, it could play an important role in determining the morphology of sympathetic neurons. In examining the mechanism of serum-induced dendritic growth, we found that even high concentrations (5 micrograms/ml) of nerve growth factor failed to promote dendritic growth in the absence of serum; thus, nerve growth factor by itself is not a sufficient condition for the extension of dendrites.(ABSTRACT TRUNCATED AT 400 WORDS)

Transferrin and iron in cultured chick embryonic neurons: a comparison between human and chick transferrins

Transferrin was not required for the short-term survival of cultured chick retinal neurons. Both human and chick transferrin failed to enhance the in vitro survival of 8- or 11-day embryonic chick retinal neurons when cultured in a defined medium. Furthermore, maintenance of neurons in the presence of chick transferrin antibody did not alter in vitro survival. Retinal neurons, however, could bind and internalize human or chick transferrin when assayed for by fluorescence immunohistochemical techniques. Binding and internalization of chick transferrin appeared to be greater than human transferrin. Iron uptake was measured in cultures maintained in the absence of transferrin. After incubation with 59FeCl3, iron uptake was 3.5 +/- 1.1 fmoles/cell. The presence of chick transferrin antibody did not significantly alter the amount of iron uptake occurring in this assay. In a comparison of human and chick transferrin mediated iron uptake, chick transferrin was 50% more effective than human transferrin in transporting iron. This study demonstrates that cultured embryonic retinal neurons are not dependent on transferrin for survival or iron uptake, although they actively bind and internalize transferrin. Results also demonstrate that whereas cultured chick retinal neurons can bind and utilize human transferrin, they do so with less efficiency than chick transferrin.

Survival, morphology, and catecholamine storage of chromaffin cells in serum-free culture: evidence for a survival and differentiation promoting activity in medium conditioned by purified chromaffin cells

Adult bovine and young rat chromaffin cells cultured in serum-free medium were examined for their survival and differentiation following exposure to various additives, trophic agents and conditioned media. Adrenal chromaffin cells dissociated from 8 day old rats were maintained by dexamethasone, NGF and CNTF or without any additives in an N1-supplemented medium in similar numbers as in serum-containing medium for up to 6 days. Neuritic growth elicited by NGF or CNTF was enhanced in the absence of serum. Medium conditioned by purified bovine chromaffin cells improved cell survival and caused neurite outgrowth in a dose-dependent manner. The activiti(es) was sensitive to heat and trypsin and not blocked by the addition of anti-NGF antibodies. Bovine chromaffin cell survival was reduced by 30% when cells were maintained for one week in the absence as compared to the presence of serum. Addition of insulin, the N1 supplement, dexamethasone or dbcAMP single or in combinations improved the survival to different extents. A combination of insulin (5 micrograms/ml) and dexamethasone (5 X 10(-6) M) proved to be optimal in this respect. However, these supplements failed to restore the cellular catecholamine, noradrenaline and adrenaline contents to levels seen in the presence of serum. This was also true for a chromaffin cell-conditioned medium, which improved survival without elevating the catecholamine contents. Conditioned medium, however, partly restored a more physiological adrenaline-noradrenaline-ratio.

Effect of iron and transferrin on pure oligodendrocytes in culture; characterization of a high-affinity transferrin receptor at different ages

Oligodendrocytes in pure culture can grow on relatively low iron concentrations (0.1-0.3 microM), in the absence of transferrin; with micromolar concentrations of iron, toxic effects can be seen after one week in culture. When transferrin is added, the toxic effect of iron is increased. These properties account for the mode of selection of oligodendrocytes for pure cultures. Each oligodendrocyte presents between 1100 and 3600 receptor molecules, with a dissociation constant of 0.2-0.6 nM corresponding to a high affinity transferrin-binding site; these constants vary little with age in culture. These receptors may function as autoreceptors regulating transferrin synthesis by oligodendrocytes.

Sympathetic neuronotrophic activity in the pulp of the cat canine tooth

Extracts of these dental pulps from adult cats contained a non-dialysable agent or agents which could support neurone survival and neurite development for at least three days in neurone-enriched cultures of sympathetic ganglion cells from 11-day chick embryos. The neurone survival-promoting activity differed from nerve growth factor (NGF) in that: (1) anti-mouse NGF serum did not inhibit it; (2) nearly all ganglionic neurones survived in optimum concentrations of pulp extract, whereas only about 35 per cent were supported by NGF; and (3) cell bodies of NGF-supported neurones were markedly larger than in neurones supported by pulp extracts. The neuronotrophic activity in individual dental pulps was highly variable among different cats, but similar between mandibular canines from the same animal. Smaller pulps had higher concentrations of trophic activity than larger ones. Gingival tissue and the anterior belly of the disgastric muscle contained little neuronotrophic activity.

Age-dependent control of dorsal root ganglion neuron survival by macromolecular and low-molecular-weight trophic agents and substratum-bound laminins

Chick embryo dorsal root ganglion (DRG) neurons can be supported in vitro by nerve growth factor (NGF) and ciliary neuronotrophic factor (CNTF). Pyruvate is also required for survival of neurons from embryonic day 8 (E8) chick ciliary ganglia and from several chick and rat embryonic central nervous system sources. Here we have examined the survival requirements of chick DRG neurons between E6.5 and E15. These DRG neurons, initially dependent only on NGF, become dependent also on CNTF and later on increasingly independent from both factors. Pyruvate nearly doubles neuronal survival at all ages under all conditions. The pyruvate concentration permitting this additional survival was reduced two-fold with serine present. In the presence of polyornithine-bound laminins, nearly all seeded neurons were rescued by pyruvate plus NGF (E8 on), or pyruvate plus CNTF (E10 on), or pyruvate without trophic factors (E15). The same maximal survival was achieved without pyruvate by supplying E10 or older neurons with both NGF and CNTF. Unmodified polyornithine substrata yielded about one-half this number of surviving neurons.

Developmental changes in the responses of rat chromaffin cells to neuronotrophic and neurite-promoting factors

This study describes the survival and neurite outgrowth behaviors of cultured adrenal medullary (chromaffin) cells obtained from postnatal rats 1 day (D1) to 100 days (D100) old in response to nerve growth factor (NGF), chick eye ciliary neuronotrophic factor (CNTF), and laminin. In the absence of trophic factors the 4-day survival of cultured chromaffin cells (relative to the number of cells attached at 2 hr) increased from one-third of the cells at D1 to 40% at D8 and 90-100% at D16 and older stages. At saturating concentrations NGF increased cell survival at D8 by 90%, but failed to support all chromaffin cells present at 2 hr. In contrast, CNTF supported the survival of all cells at D8. At D1 NGF and CNTF had only a very small effect on survival during the 4-day culture period, although both factors clearly enhanced the numbers of surviving cells after 8 days. Either NGF or CNTF also elicited neurite outgrowth from rat chromaffin cells, which amounted to approximately 15-20% at D1 and D8 and subsequently decreased to about 5-8% at D30 and virtually zero at D100. At this last age both factors applied together clearly elicited neurites. Such a potentiating effect of NGF and CNTF was also seen at earlier postnatal ages. Laminin did not affect neurite growth at D30 in the absence of trophic factors, as already described for D8 rat chromaffin cells. In the presence of NGF, however, it increased neurite length and branching during a 4-day culture period and even enhanced neurite recruitment at later culture times. These data suggest that rat chromaffin cells undergo age-related changes in their responses to NGF and CNTF and that laminin modulates their neurite outgrowth behaviors in the presence of trophic factors.

NGF-dependent and -independent growth of neurites from sympathetic ganglion cells of the aged human in a serum-free culture

Small pieces of tissue isolated from abdominal sympathetic ganglia in aged male patients were cultured in a chemically defined, serum-free medium. The growth of neurites from pieces of ganglia in cultures with and without 50 ng/ml mouse 2.5S nerve growth factor (NGF) was compared. The NGF stimulated significantly greater regeneration of neurites, causing the growth of long fibers from the ganglion pieces. Many short neurites grew, even in the absence of the NGF, but these were generally short, except for long neurites generated in several nerve cells. A method was devised for the evaluation of NGF-dependent growth of neurites in the culture. The rate of the NGF-dependent growth of neurites, which was calculated by the difference in the total lengths of the NGF-dependent neurites between 2- and 4-day-old cultures, was approximately 160 micron/day. The results indicate that although the growth of neurites from some sympathetic nerve cells of the aged human become independent of the NGF, most of the nerve cells remain dependent on the NGF, even in the stage of senescence.

Towards an improved serum-free, chemically defined medium for long-term culturing of cerebral cortex tissue

The present study describes a series of experiments which have led to a substantially improved serum-free, chemically defined medium (CDM) for long-term culturing of reaggregated fetal rat cerebral cortex tissue. A reduction of the original medium concentrations of the hormones insuline, T3 and corticosterone, on the one hand, and an enrichment of the medium with the vitamins A, C and E, the unsaturated fatty acids linoleic and linolenic acid, and biotin, L-carnitine, D(+)-galactose, glutathione (reduced) and ethanolamine, on the other hand, formed the most important chemical adjustments of the medium. With the aid of this CDM (encoded R12), the light- and electron microscopic architecture of the tissue could be kept in a good condition (superior to that seen earlier in serum-supplemented medium) up to 23 days in vitro. From that time on, the neuronal network lying between the reaggregates degenerated for the largest part, while a portion of the large neurons (probably pyramidal cells) plus some of the neuronal network within the reaggregates degenerated too. This degeneration process continued during the following weeks, but the reaggregates nevertheless retained most of their mass, so that both small and large neuronal cell bodies (visible in transparent regions at the edge of the reaggregates) remained in good condition up to at least 103 DIV. Stout, thick nerve bundles interconnecting the reaggregates, also survived up to this point. Electron microscopic evaluation of such 'aged' reaggregates revealed degenerating as well as healthy regions. The latter had indeed retained healthy-looking pyramidal and non-pyramidal neurons, embedded within a dense neuropil which was often traversed by myelinated axons. The numerical synapse density in such selected, healthy tissue regions reached its maximum during the sixth week in vitro, followed by a rapid decrease and a stabilization at about half the peak values. The present culture system has opened the possibility for performing controlled quantitative studies on the relationship between structure and function of cerebral cortex tissues during development and aging, on its dependence on nutrients, hormones and drugs, and on special factors synthesized by the tissue and released into the nutrient medium.

Cerebellar macroneurons in serum-free cultures: evidence for intrinsic neuronotrophic and neuronotoxic activities

Cerebellar macroneurones survive and differentiate for at least 10 days in Eagle's minimum essential medium with insulin as the only supplement when cultured either as microexplants or in high-density dissociated cultures, while they do not survive if cultured in low density. The survival is related to the extracellular release of neuronotrophic factor(s). Using a quantitative bioassay of the neuronotrophic effect, it is possible to demonstrate that the effect is concentration dependent. The analysis of the dose-response curves suggests that the neuronotrophic activity is associated with a neuronotoxic activity. The two activities can be segregated using a simple physical method, allowing direct demonstration of the neuronotoxic activity.

Chemically defined requirements for the survival of cultured 8-day chick embryo ciliary ganglion neurons

We have previously demonstrated that both peripheral and central neurons from embryonic chick and newborn mouse can be maintained in a serum-free defined culture medium containing the appropriate neuronotrophic agent and the N1 supplement consisting of insulin, transferrin, putrescine, progesterone and selenite. In the present studies we have examined the short-term survival requirements of 8-day embryonic chick ciliary ganglion (CG) neurons. By comparing CG neuronal survival in our standard culture medium, Eagle's Basal Medium (EBM), with several other commercially available basal media, we have established that CG neurons also have specific requirements for pyruvate, serine and iron (Fe3+), in addition to their trophic factor (Ciliary Neuronotrophic Factor, CNTF) and the N1 supplement. The data suggest the existence of 3 subsets of CG neurons differing in their essential needs, namely: (1) those supported by glucose in the absence of pyruvate, (2) those requiring exogenous pyruvate but not serine or Fe3+, and (3) those which need pyruvate, serine and Fe3+. The minimal effective concentration of pyruvate could be decreased by a factor of 50 in the concurrent presence of serine and Fe3+. Serine was also a limiting element in the survival of some of these CG neurons. The Fe3+ concentration required by the same neurons was considerably diminished with the availability of transferrin, perhaps reflecting an increased Fe3+ transmembrane transport efficiency. Insulin was found to be the only N1 ingredient required for the survival of CG neurons. Insulin was a constant requirement for all 3 subsets of CG neurons, even when cultured in the total absence of glucose (but presence of pyruvate).

Serum vulnerability and time-dependent stabilization of neurites induced by nerve growth factor in PC12 pheochromocytoma cells

Cultures of PC12 pheochromocytoma cells were established on a polyornithine substratum in medium supplemented with the chemically defined N1 mixture in the presence or absence of Nerve Growth Factor (NGF). Normal cell proliferation in the absence of NGF was equally competent when fetal calf serum (FCS) was replaced with N1-supplemented medium. The differentiation of PC12 cells, which occurs upon NGF treatment, ultimately results in cell death without the addition of 0.1% FCS to the N1-supplemented medium. The combination of N1, 0.1% FCS, and NGF permits the PC12 cells to develop a neuritic outgrowth much earlier than when higher (1-10%) FCS levels are used. Neurite retraction is caused in a dose-dependent manner by a delayed presentation of FCS. Within 2 days of serum presentation, however, neurites regrow to achieve that percentage of neurite-bearing cells which is seen without a serum challenge. Moreover, the retraction response becomes less pronounced with time over the 8-day culture period for any given serum concentration. Among the N1 ingredients, only insulin and transferrin are needed by PC12 cells for survival whether in the dividing state or not. Neurite growth was not dependent on any of the N1 components.