Parasympathetic neurotrophic activity in the rat iris: determination after different denervations

Beneficial effects of antioxidant-enriched diet for tyrosine hydroxylase-positive neurons in ventral mesencephalic tissue in oculo grafts

Supplementation of antioxidants to the diet has been proved to be beneficial in aging and after brain injury. Furthermore, it has been postulated that the locus coeruleus promotes survival of dopamine neurons. Thus, this study was performed to elucidate the effects of a blueberry-enriched diet on fetal ventral mesencephalic tissue in the presence or absence of locus coeruleus utilizing the in oculo grafting method. Sprague-Dawley rats were given control diet or diet supplemented with 2% blueberries, and solid tissue pieces of fetal locus coeruleus and ventral mesencephalon were implanted as single and co-grafts. The results revealed that the presence of locus coeruleus tissue or the addition of blueberries enhanced the survival of ventral mesencephalic tyrosine hydroxylase (TH)-positive neurons, whereas no additive effects were observed for the two treatments. The density of TH-positive nerve fibers in ventral mesencephalic tissue was significantly elevated when it was attached to the locus coeruleus or by blueberry treatment, whereas the innervation of dopamine-beta-hydroxylase-positive nerve fibers was not altered. The presence of locus coeruleus tissue or bluberry supplementation reduced the number of Iba-1-positive microglia in the ventral mesencephalic portion of single and co-grafts, respectively, whereas almost no OX6 immunoreactivity was found. Furthermore, neither the attachment of ventral mesencephalic tissue nor the addition of blueberries improved the survival of TH-positive neurons in the locus coerulean grafts. To conclude, locus coeruleus and blueberries are beneficial for the survival of fetal ventral mesencephalic tissue, findings that could be useful when grafting tissue in Parkinson's disease.

Proof of the mysterious efficacy of ginseng: basic and clinical trials: suppression of adrenal medullary function in vitro by ginseng

The root of Panax ginseng C.A. MEYER has been reported to have an anti-stress action. Therefore, the effects of ginseng components on functions of adrenal medulla, which is one of the most important organs responsive to stress, were investigated in vitro. First, the components of ginseng were mainly divided into two fractions, that is, the saponin-rich and non-saponin fractions. The saponin-rich fraction greatly reduced the secretion of catecholamines from bovine adrenal chromaffin cells stimulated by acetylcholine (ACh), whereas the non-saponin fraction did not affect it at all. The protopanaxatriol-type saponins inhibited the ACh-evoked secretion much more strongly than the protopanaxadiol-type. On the other hand, the oleanane-type saponin, ginsenoside-Ro, had no such effect. Recent reports have demonstrated that the saponins in ginseng are metabolized and absorbed in digestive tracts following oral administration of ginseng. All of the saponin metabolites greatly reduced the ACh-evoked secretion. M4 was the most effective inhibitor among the metabolites. M4 blocked ACh-induced Na(+) influx and ion inward current into the chromaffin cells and into the Xenopus oocytes expressing human alpha3beta4 nicotinic ACh receptors, respectively, suggesting that the saponin metabolites modulate nicotinic ACh receptors followed by the reduction of catecholamine secretion. It is highly possible that these effects of ginsenosides and their metabolites are associated with the anti-stress action of ginseng.

Tirilazad mesylate increases dopaminergic neuronal survival in the in Oculo grafting model

Grafting of fetal ventral mesencephalon in Parkinson's disease has been extensively studied. A crucial draw back of this technique is the low survival rate of the dopaminergic neurons. It has been documented that only 5-20% of the grafted neurons survive, and to enhance graft efficacy to a satisfying level, increased cell survival is of utmost desire. In this study we have used the antioxidant tiriliazad mesylate (U-74006F) to study the effect on the survival of dopaminergic neurons after grafting. The in oculo grafting model was used and ventral mesencephalon was dissected from E14-E15 rat fetuses in Hanks' balanced salt solution (HBSS), in Dulbecco's modified Eagle medium (DMEM), or in 0.3, 3.0, or 30 microM U-74006F diluted in DMEM. The tissue was then inserted into the anterior chamber of the eye. Some of the transplants were further treated with intraocular injections of 3 or 30 microM U-74006F (5 microliters) weekly for 2 weeks. Quantification of tyrosine hydroxylase (TH)-immunoreactive profiles revealed that in transplants treated with U-74006F at dissection only, no change in the number of TH-positive neurons was found. Pretreatment of 0.3 microM U-74006F during dissection combined with intraocular injections of U-74006F after grafting, on the other hand, resulted in a dose-dependent enhancement of survival of TH-positive neurons. Dissection in, and intraocular treatment with, 3 microM U-74006F resulted in a significantly enhanced survival of TH-positive neurons whereas using U-74006F at a concentration of 30 microM did not change the cell survival compared to solely DMEM-treated grafts. Thus, 30 microM was interpreted to be an overdose. Comparing cell survival when dissected in DMEM with that dissected in HBSS showed that DMEM was clearly superior. Nerve fiber formation was most pronounced in grafts treated with 3 microM U-74006F. In conclusion, survival of TH-positive neurons is enhanced by U-74006F, which is readily available for clinical use and thus could be employed to enhance graft survival when transplanting patients suffering from Parkinson's disease.

Glial cell line-derived neurotrophic factor stimulates fiber formation and survival in cultured neurons from peripheral autonomic ganglia

Human recombinant glial cell line-derived neurotrophic factor (GDNF) was tested for its ability to stimulate fiber formation and neuron survival in primary cultures of peripheral ganglia dissected from the chicken embryo. GDNF, first characterized by its actions on central nervous system (CNS) neurons, had a marked stimulatory effect on fiber outgrowth in sympathetic and ciliary ganglia. Weaker responses were evoked in sensory spinal and nodose ganglia and in the ganglion of Remak. In addition, survival of neurons from the sympathetic and ciliary ganglia was stimulated by GDNF at 50 ng/ml. The effects were not mimicked by the distant but related protein transforming growth factor beta 1 (TGF beta 1). The profile of neurons stimulated by GDNF is also distinct from the patterns of stimulation shown by nerve growth factor (NGF), stimulating strongly sympathetic but not ciliary ganglia, and ciliary neurotrophic factor (CNTF), stimulating mainly the ciliary ganglion. Moreover, using in situ hybridization histochemistry, GDNF was demonstrated to be present in the pineal gland in the newborn rat, a target organ for sympathetic innervation. The present results suggest that GDNF is likely to act upon receptors present in several autonomic and sensory neuronal populations. GDNF may serve to support fiber outgrowth and cell survival in peripheral ganglia, adding yet one more trophic factor to the list of specific proteins controlling development and maintenance of the peripheral nervous system.

Choroid coat extract and ciliary neurotrophic factor strongly promote neurite outgrowth in the embryonic chick retina

Previous studies have shown that extracts from the target optic tectum stimulate neurite outgrowth from retinal explants. The present study indicates that the choroid coat is an even richer source of retinotrophic activity. We thus studied the effects of recombinant rat ciliary neurotrophic factor (CNTF) on primary cultures of dissociated chick ciliary ganglion neurons and retinal explants for a comparison with choroid coat extract from the E18 chick. For our assays, E9 ciliary neurons were incubated in collagen gels and retinal explants were cultured on collagen gels with the addition of the trophic factors and maintained for two or four days. Survival of ciliary neurons per area as well as maximal neurite length in retinal cultures were determined. Growth responses occurred in a dose-dependent manner both to CNTF and choroid extract. Immunofluorescence examination of cells and developing processes showed 200 kdal neurofilament positivity demonstrating that the cells studied were neurons with neurites. It is concluded that a trophic activity of the choroid as well as the recombinant CNTF stimulate retinal neuron survival and neurite extension. The results suggest that CNTF may have developmental functions in the establishment of the visual pathways.

Re-initiated growth from mature ventral mesencephalon: an in oculo transplant study of nigrostriatal co-grafts

The ability of mature dopaminergic neurons derived from ventral mesencephalon to re-initiate growth after making contact with a non-innervated target was studied using the intra-ocular grafting model. Foetal ventral mesencephalic tissue or brain stem including the locus coeruleus area was grafted to the anterior chamber of the eye. Two weeks, 6 weeks or 1 year after the first implantation, foetal striatal tissue was placed in contact with the nigral graft or grafted alone. The size of the transplants was measured through the cornea. The final size of the striatal grafts was significantly larger when placed alone than when co-grafted with 1-year-old or 6-week-old dopaminergic grafts. Striatum grafted together with 2-week-old nigra was larger than when grafted adjacent to mature substantia nigra, but not significantly so. Nerve fibre outgrowth into the iris from the nigral transplants did not increase after maturation, but the re-innervated area of the host iris progressively increased around the locus coeruleus grafts. Ingrowth of tyrosine hydroxylase (TH) immunoreactive nerve fibres into the striatal grafts was studied 6 weeks after the second implantation. TH immunohistochemistry revealed innervation of the striatal piece in all cases, except for the group where striatum alone was grafted. With the short survival time for co-grafts of 6 weeks, TH-positive nerve fibres innervated a larger volume, had a patchy appearance and the density was higher in striatum grafted to 2 week-old nigral transplants than that seen in striatal transplants grafted to mature nigral grafts. The patchy pattern of TH-immunoreactive nerve terminals was also seen in striatum co-grafted with 6-week-old or 1-year-old nigral transplants. No difference in striatal innervation volume was detected between those latter two groups. When striatum was implanted adjacent to mature ventral mesencephalon and grown together for 6 months--the longer survival time--the same dense TH-positive innervation as seen in striatum co-grafted with immature nigral tissue at the shorter survival time was found. Additionally, the nigral part of the co-grafts showed increased TH-immunoreactive nerve fibre density. In conclusion, dopaminergic neurites from mature ventral mesencephalic transplants can re-initiate growth if placed in contact with non-innervated striatal tissue. The nigral grafts do not progressively re-innervate the host iris, while locus coeruleus grafts do. The intra-ocular grafting model can be used to study the in vivo effects of trophic factors on mature dopaminergic neurons.

A ciliary neuronotrophic factor from peripheral nerve and smooth muscle which is not retrogradely transported

We have found that a CNTF-like molecule which supports ciliary and sympathetic neurons is not retrogradely transported in either sympathetic or parasympathetic nerves. The factor has an apparent Mr of 21 kDa, a pI of 4.9, and is present in peripheral nerves and smooth muscle of the chick. Our experiments indicate that CNTF-like activity does not accumulate on the distal side of ligated chick expansor nerves. In contrast, there is a clear accumulation of NGF. The activity further differs from NGF in that it is not removed from a smooth muscle of the chick wing by innervating sympathetic fibers. Transection of these fibers does not lead to an accumulation of ciliary activity in the expansor secundariorum muscle, suggesting that neurons do not actively deplete the muscle of factor by retrograde transport. Finally, recombinant CNTF or semi-purified preparations of CNTF-like activity labelled with 125I were not transported to the ciliary ganglion of chicks following injection of biologically active material into the eye. Our results suggest either that endogenous CNTF does not act as a survival factor in vivo, or that retrograde transport is not a property inherent to all neuronotrophic molecules.

Screening for neurotrophic disturbances in amyotrophic lateral sclerosis

Neurotrophic activities in human serum and post-mortem muscle and spinal cord of possible relevance to pathophysiological mechanisms in amyotrophic lateral sclerosis (ALS) were studied. Tests included in vitro assays for nerve fibre outgrowth from sympathetic ganglia and for survival promotion of dissociated ciliary neurons, both types of neurons, of chicken embryo origin. Extracts of postmortem biceps muscle promoted survival of ciliary neurons in a dose-dependent manner. Half-maximum effect was found at a protein concentration of about 450 micrograms/ml for both ALS and control muscle. Ventral horn extracts were about 5 times as efficient as muscle in promoting neuron survival, again with no differences seen between control and ALS samples. Sera from patients suffering from ALS as well as normal sera did not enhance survival of ciliary neurons to any considerable extent, nor did they induce fibre outgrowth from sympathetic ganglia. Both groups of sera, if present above 5% in the medium, suppressed fibre outgrowth induced by added nerve growth factor (NGF). Sera from some of the ALS patients impaired survival in dissociated ciliary neurons supported by a trophic activity in choroid extract. The results do not indicate major neurotrophic deficits as the cause of ALS disease but suggest that a neurotoxic mechanism may be involved.

Chronic application of curare does not increase the level of motoneuron survival-promoting activity in limb muscle extracts during the naturally occurring motoneuron cell death period

Naturally occurring motoneuron cell death during development is a well-described phenomenon and the existence of a survival factor provided by target muscles has been postulated. Blockade of activity by chronic application of a neuromuscular junction blocker rescues almost all motoneurons from cell death. The present study was conducted in order to examine the possibility that the motoneuron survival-promoting activity in muscles increases following activity blockade. Cell culture was used to assess the degree of motoneuron survival-promoting activity present in muscle extracts. Embryonic chick motoneurons were labeled by injecting the water-insoluble fluorescent dye, DiI (Molecular Probes, Inc.) into the spinal nerves both before and during the cell death period. The labeled cells extending long neurites were counted after 2 days of culture as viable motoneurons in low-density heterogeneous cell cultures. The culture medium, Ham F12/DMEM (1:1 mixture) supplemented with 10% horse serum, 5% chick serum, and 5% fetal calf serum, was employed as a basic culture medium for assessing motoneuron survival factor, since it supported the survival of a significantly higher number of motoneurons derived from embryos before cell death than those during the cell death period, thus representing the motoneuron's requirement for survival factor in vivo. The number of surviving motoneurons clearly increased in proportion to the amount of muscle extract added to the culture medium. In comparison with control chick embryos, the dose-response relation between the number of surviving motoneurons and the amount of muscle extract added did not change when embryos were used after chronic application of curare. These results therefore indicate that survival factor derived from target muscle is crucial to the in vitro motoneurons during the cell death period, but do not support the idea that inactive muscle contains a higher amount of the survival factor.

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.

Comparative screening for ciliary neurotrophic activity in organs of the rat and chicken

A neuron-survival assay with dissociated ciliary ganglion neurons was used to examine the level of neurotrophic activity in organs of the rat and chicken. All tissue homogenates enhanced neuron survival at increasing protein concentrations, although 50% survival activity (1 trophic unit, TU, per ml) occurred at distinctly different levels in the different organs. Liver, spleen, T-cells, and submandibular gland from the rat were very low in survival-promoting activity (0.1-1.1 TU per mg of protein). Serum and lung were slightly richer (2.4-2.8 mg). Heart, brain, and skeletal muscle stimulated survival well (6.2-13 TU/mg). Unexpectedly, the highest activities were found in the rat kidney (44 TU/mg). The activity in adult chicken organs was less varied (1.6-9.1 TU/mg). Higher trophic activities were found in the chicken embryo, particularly at day 18 of development (20-30 TU/mg). The up to 100-fold difference in trophic level between organs should make it feasible to use subtractive hybridization, differential screening, and transient expression in eukaryotic cells for molecular cloning of the ciliary neurotrophic factor(s).

Chick embryo nerve growth factor. Fractionation and biological activity

A nerve growth factor (NGF)-like factor initiating nerve fibre outgrowth from sympathetic ganglia in culture was partially purified from chick embryo extract by cation-exchange chromatography followed by hydrophobic interaction chromatography on octylsulfide agarose. The NGF-like factor was markedly activated upon gel filtration in the presence of 6 M urea. Further analysis of the activated chick NGF by immunoblotting following SDS-PAGE, and by inhibition of bioassay response using antibodies to mouse beta NGF demonstrated a distinct antigenic cross-reactivity. The size of the chick embryo NGF was also indistinguishable from that of the mouse beta NGF with a molecular weight (MW) of about 14,000. The findings demonstrate directly the presence of biologically active NGF protein in the developing 18-day chick embryo.