Septal deafferentation enhances the neurotrophic effects of rat hippocampus on cultured neural cells from the central nervous system

Increased NGF-like activity in young but not aged rat hippocampus after septal lesions

Sympathetic sprouting in the hippocampus following septal denervation is thought to involve nerve growth factor (NGF). This sprouting response is dramatically reduced in aged rats, but immunological assays reveal no age-related decline in hippocampal NGF levels. In the present study, both a bioassay and an immunoassay were used to examine the effect of a medial septal lesion on hippocampal NGF levels in young adult (2-5 months) and aged (24 months) Fischer 344 rats. No significant differences were detected between normal young and aged rats, in agreement with earlier results. Following medial septal lesions, however, only young rats demonstrated significant increases in hippocampal NGF-like activity. These results support the hypothesis that the age-related deficit in sympathetic sprouting results from an attenuated neurotrophic response to hippocampal denervation.

Cytokine regulation of nerve growth factor-mediated cholinergic neurotrophic activity synthesized by astrocytes and fibroblasts

The neurotrophic activity of astrocytes and fibroblasts and its regulation by various cytokines were investigated. Astrocyte conditioned medium (ACM) enhanced the survival of neurons and the proliferation of astrocytes in embryonic cortical cultures grown in serum-free defined medium. However, these results were not affected by acidic fibroblast growth factor, interleukin-1 beta (IL-1 beta), tumor necrosis factor-alpha (TNF alpha), and transforming growth factor-beta 1. In contrast, ACM induced choline acetyltransferase expression in septal cholinergic neurons via nerve growth factor (NGF)-dependent and -independent mechanisms. However, neither acidic nor basic fibroblast growth factor is involved in this biological activity in ACM. The cytokines listed above mainly stimulate NGF-mediated cholinergic neurotrophic activity in ACM. A combination of IL-1 beta and TNF alpha significantly enhanced choline acetyltransferase activity in septal neurons co-cultured with astrocytes, and this effect was found to be mediated by NGF produced by activated astrocytes. Effects of astrocytes on GABAergic neurons were also examined. ACM was found to increase glutamate decarboxylase activity in neuronal cultures from septum in the presence of Ara-C. However, the cytokines did not enhance this activity in ACM. Moreover, a combination of IL-1 beta and TNF alpha had no effect on glutamate decarboxylase activity in septal neurons co-cultured with astrocytes. In a final set of experiments, cholinergic neurotrophic activity in skin-derived fibroblast conditioned medium (FCM) was examined. FCM was found to possess biological activity similar to that of ACM on septal neurons grown in serum-free defined medium with Ara-C. The cytokines also enhanced NGF-mediated cholinergic neurotrophic activity in FCM. Astrocytes and fibroblasts were found to possess NGF-type and non-NGF-type cholinergic neurotrophic activity, and various cytokines were found to regulate the NGF-type cholinergic neurotrophic activity in both types of cells. NGF produced by astrocytes and fibroblasts that are activated by cytokines is likely to be important for development and regeneration of NGF-sensitive neurons in the central and peripheral nervous systems.

Neuronal survival factor from bovine brain is identical to neuron-specific enolase

Neuronal survival factors in the central nervous system were investigated by using a primary culture of embryonic rat neocortical neurons. Bovine hippocampus was homogenized, and the supernatant from high-speed centrifugation was used as the starting material. At the step of DE-52 ion-exchange chromatography, neuronal survival activity was recovered in two fractions, fraction 14 (F14) and fraction 23 (F23). Antisera to the crude F14 and F23 fractions were raised in rabbits. These two antisera completely inhibited the neurotrophic activity of both fractions. Western blotting analysis revealed that anti-F14 antiserum recognized mainly a 30-kDa protein in F14 and anti-F23 antiserum recognized mainly a 44-kDa protein in F23. After sodium dodecyl sulfate-polyacrylamide gel electrophoresis of F23, the 44-kDa protein was cut out from the gel and partial amino acid sequences of the protein fragments were determined. A GenBank data bank indicated that the amino acid sequence of the fragment was identical to that of neuron-specific enolase (NSE). In our assay system, commercially available NSE itself possessed neuronal survival activity for the cultured neocortical neurons. The effects of NSE and F23 were inhibited completely by anti-NSE polyclonal antibody. Furthermore, highly purified NSE supported the survival of cultured neurons in a dose-dependent manner, and the neurotrophic effect was inhibited by monoclonal antibody to the NSE. These results strongly suggest that NSE is one of the neuronal survival factors in the central nervous system.

Hippocampal neurotrophic factors influence the perikaryal size of septal acetylcholinesterase-containing neurons in culture

The septal neurons were cultured under the following conditions: (1) treated with 7S nerve growth factor (NGF) (50 ng/ml); (2) grown with hippocampal cell-conditioned medium supernatant; (3) cocultivated with hippocampal cells; (4) cocultivated with cerebellar cells; (5) no treatment. Acetylcholinesterase histochemistry was used to identify cholinergic cells after pretreatment with diisopropylfluorophosphate. The mean values of the perikaryal major axis and minor axis at day 14 of culture were significantly larger in septal cells cocultivated with hippocampal cells than in septal cells grown under other conditions. NGF-treated septal cells showed a smaller, but significant, increase in the mean value of the major axis of these neurons.

Nerve-growth-factor-dependent and cell-density-independent survival of septal cholinergic neurons in culture from postnatal rats

We have established a primary neuronal cell culture technique from the postnatal (P11 to P15) rat CNS to study the nerve growth factor (NGF) response to basal forebrain cholinergic neurons. The survival of septal cholinergic neurons in culture was monitored both by the determination of choline acetyltransferase activity and by counting acetylcholinesterase-positive cells. Cells obtained from postnatal septal regions were found to require a plentiful oxygen supply during the dissociation of the cells. NGF-mediated survival of the septal cholinergic neurons was similarly observed in the cultures by using different plating cell densities up to 12.5 X 10(5) cells/cm2. These results suggest that the promotion by NGF of cell survival in culture is independent of plating cell density.

Nerve growth factor and phorbol esters increase the number of choline acetyltransferase-positive cells in two morphologically distinct classes of basal forebrain neurons in primary cultures

Nerve growth factor (NGF) has been shown to be active in the CNS as a neurotrophic agent. Cholinergic neurons of the basal forebrain are one cell type in the CNS which have been identified as a target for NGF. When dissociated cell cultures from the basal forebrain were treated for 7 days with NGF (20 ng/100 microliters), the number of choline acetyltransferase (ChAT)-immunopositive cells was increased from 30 +/- 6 to 58 +/- 3. Cholinergic cells taken from the basal forebrain exhibit 3 different morphologies: stellate, pyramidal, and bipolar. The NGF treatment was found to increase the number of stellate cells from 7 +/- 2 to 23 +/- 2 and the number of pyramidal cells from 14 +/- 2 to 26 +/- 2, but had no effect on the number of bipolar cells. The activation of protein kinase C by phorbol 12-myristate, 13-acetate (TPA) also increased the number of ChAT-positive cells in a dose-dependent manner. A maximal increase was observed with 10 ng/ml of TPA which increased the number of positive cells from a basal level of 21 +/- 4 to 42 +/- 4. As was the case with NGF, only the stellate and pyramidal cells were affected by the phorbol ester treatment. In co-addition experiments, the cultures were treated with 10 ng/100 of NGF and 10 ng/ml of TPA, with the result that there was no further increase in the number of immunopositive cells over the NGF controls. These results suggest that the mechanisms by which NGF and TPA increase the number of ChAT-positive cells are interactive at some point. The effect of TPA at the higher doses of NGF was distinctly different. When cells were treated with 20 ng/100 microliters of NGF and 0.05-50 ng/ml of TPA, the NGF response was down-regulated to the level of the vehicle-treated controls.

Astrocytes are important for sprouting in the septohippocampal circuit

Damage to the fimbria-fornix, and separately to the perforant path, leads to distinct and dramatic time-dependent increases in glial fibrillary acidic protein immunoreactivity (GFAP-IR) in specific areas of the hippocampal formation. Specifically, fimbria-fornix lesions resulted in an increase in the GFAP-IR in the pyramidal and oriens area of the CA3 as well as the inner molecular layer of the dentate gyrus. In addition, in the septum ipsilateral to the lesion, there was a rapid and robust increase in GFAP-IR in the dorsal lateral quadrant of the septum, but not in the medial region. Only after 30 days did the GFAP-IR reach the medial septum. Following perforant path lesions, there was a selective increase in GFAP-IR in the outer molecular layer of the dentate gyrus. Most of these changes were transient and had disappeared by 30 days postlesion. We speculate that the increase in GFAP-IR in these target areas is a necessary requirement for the sprouting responses that are observed. This hypothesis is supported by the fact that astrocytes secrete NGF in vitro and that NGF activity increases in these target areas following these same lesions. A mechanism for the selective activation of the astrocytes through the initial activation of microglia and secretion of interleukin-1 is postulated.

Developmental change in the nerve growth factor action from induction of choline acetyltransferase to promotion of cell survival in cultured basal forebrain cholinergic neurons from postnatal rats

Nerve growth factor (NGF), a well-characterized target-derived growth factor, has been postulated to promote neuronal differentiation and survival of the basal forebrain cholinergic neurons. In the present paper, we demonstrate that a developmental change in NGF action occurs in postnatal rat basal forebrain cholinergic neurons in culture. Firstly, NGF acts as maturation factor by increasing choline acetyltransferase (ChAT) activity and acts later as a survival factor. In dissociated cell cultures of septal neurons from early postnatal (P1-4) rats, ChAT activities were increased by the addition of NGF. That is, ChAT activities in P1 septal cells cultured for 7 days was increased 4-fold in the presence of NGF at a concentration of 100 ng/ml. However, the number of the acetylcholinesterase (AChE)-positive neurons was not significantly different between these groups. In contrast, septal neurons from P8 to P14 rats showed different responses to NGF. Although the P14 septal neurons in culture for 7 days without NGF lost about half of the ChAT activity during a 7-day cultivation, cells cultured with NGF retained the activity at the initial level. The number of AChE-positive neurons counted in cultures with NGF was much greater than the number without NGF. These results suggest that, during the early postnatal days, the action of NGF on the septal cholinergic neurons in culture changes from induction of ChAT activity to the promotion of cholinergic neuronal cell survival. During this developmental period in vivo, septal neurons are terminating their projections to the hippocampal formation. Similar NGF-regulated changes in cholinergic neurons were observed in cultured postnatal neurons from vertical limb of diagonal band. An analogy has been pointed out between the neuronal death of the basal forebrain cholinergic neurons and a similar neuronal death in senile dementia, especially Alzheimer's type. The work reported here might present a possibility that NGF could play a role in preventing the loss of the basal forebrain cholinergic neurons in this disease.

Alzheimer's disease brain extract stimulates the survival of cerebral cortical neurons from neonatal rats

Cell cultures of neonatal rat cerebral cortex in a serum-free medium were used to investigate a lack of neuronotrophic factors in Alzheimer's disease (AD) brain. A few neurons survived in the absence of brain extract. The addition of normal brain extract resulted in a 2.5-fold increase in neuronal survival. AD brain extract contained 4-fold neuronotrophic activity of normal brain extract. These findings are in contrary to the previous hypothesis of a lacking neuronotrophic factors in AD brain. These new results may change the concept of mechanism of neuronal death in AD.

Identification of trophic factors and transplanted cellular environments that promote CNS axonal regeneration

As indicated in this review, we have begun to elucidate cellular environments and trophic factors that promote the regeneration of adult mammalian CNS neurons. In the present paradigm, bilateral aspiration lesions of the fornix-fimbria are used to axotomize septal neurons and transect the septal cholinergic projection to the dorsal hippocampus in order to evaluate the influence of trophic factors, such as NGF, on neuronal survival and the ability of cellular transplants of PNS tissue to promote axonal regeneration in vivo. Initial results demonstrate that NGF is a potent trophic molecule that prevents retrograde degeneration of septal cholinergic neurons. Observations from transplantation studies demonstrate that viable Schwann cells obtained from PNS nerve grafts or Schwann cell-ECM cultures provide a favorable cellular milieu for CNS regeneration. These cellular transplants induce a remarkable sprouting response from septal cholinergic neurons and promote the rapid elongation of septal axons that reinnervate the denervated hippocampus. In stark contrast to the Schwann cell-laden transplants, transplants including only ECM channels synthesized by cultured Schwann cells do not promote axonal regeneration within the time periods that we have examined. Therefore, we hypothesize that viable Schwann cells are crucial for the process of regeneration because they contribute both trophic and tropic factors to the injured CNS neurons. The significant early sprouting phenomenon associated with transplants containing Schwann cells strongly suggests that soluble Schwann cell-synthesized factors induce axon elongation and possibly enhance the survival of injured septal neurons. The trophic factors probably function in a manner similar, if not identical, to the action of NGF on axotomized septal neurons. Moreover, Schwann cells appear to provide tropic signals, such as LAM or a LAM-NGF complex, that can act, when in the proper stereoconfiguration, to promote the elongation and orientation of regenerating axons. Thus, our current data indicate that in order to promote optimal axonal regeneration from injured CNS neurons, both trophic and tropic factors must be supplied from exogenous sources.

Sympathetic sprouting in the central nervous system: a model for studies of axonal growth in the mature mammalian brain

Sympathetic fibers innervate many peripheral tissues but are normally confined to extracerebral structures within the cranial cavity, e.g. blood vessels. The invasion of the central nervous system by vascular sympathetic axons is a unique example of neuronal plasticity which provides new information concerning the regulation and mechanisms of neuronal sprouting in both the peripheral and central nervous systems. In this paper, the principal findings concerning the conditions under which such sprouting occurs, the mechanisms which may be involved, and the question of its possible function are reviewed. Of special interest is the fact that a nerve growth factor-like brain factor may be involved in this growth response. The principles gleaned from studies of this sprouting phenomenon may be applicable to other models of neuronal plasticity and may have clinical relevance.

Subcultured astrocytes suppress the proliferation of neuroblasts in vitro

The effects of subcultured astrocytes on the proliferation of neuronal precursor cells (neuroblasts) from rat embryonic cerebral hemispheres were examined. The survivability of neurons and the neurite outgrowth were significantly enhanced by the subcultured astrocytes compared to those of neurons plated on poly-L-lysine-coated coverslips. The incorporation of [3H]thymidine into neuroblasts was remarkably suppressed by the subcultured astrocytes indicating that the astrocytes inhibit the proliferation of neuroblasts. These results suggest that astrocytes enhance the maturation of neuroblasts possibly via either cell-cell contact or trophic substances.