Transplantation of fetal and early postnatal rat septal cholinergic neurons cultured in serum-free and serum-containing medium with nerve growth factor

Fetal rat (E17-E19) septal neurons were cultured in a defined, serum-free medium for 6-8 days with or without nerve growth factor (NGF) and transplanted into the hippocampus or the surrounding ventricle of 28 adult rats denervated of its septal input by a fimbria-fornix transection. The cholinergic septal neurons, which were visualized by acetylcholinesterase (AChE) histochemistry, always survived in transplantation to the adult brains from nearly pure neuronal cultures. Although choline acetyltransferase (ChAT) activity of septal neurons in culture was greatly increased (5.59-fold) by the addition of NGF to the defined medium, this ChAT induction appeared to have little effect on the subsequent survival or growth of the septal neurons after transplantation. These results demonstrate that survival of cultured fetal septal cholinergic neurons following transplantation is not dependent upon the presence of NGF or serum- or glia-derived factors during the preliminary culture. Postnatal rat (P4) septal neurons cultured for 5 days in serum-containing medium with NGF were also successfully transplanted in one of 3 cases.     

Basic FGF in adult rat brain: cellular distribution and response to entorhinal lesion and fimbria-fornix transection.

Basic fibroblast growth factor (bFGF) is a potent trophic factor for neurons and astrocytes and recently has been implicated in the pathology of Alzheimer's disease. In order to better understand the role of bFGF in normal brain function and during pathology, we have analyzed its anatomical distribution and its response to injury in the CNS. Double-staining immunohistochemistry showed that bFGF immunoreactivity was localized in astrocytes, in select neuronal populations, and occasionally in microglial cells throughout the normal rat brain. Neuronal populations that showed bFGF immunoreactivity included septohippocampal nucleus, cingulate cortex, subfield CA2 of the hippocampus, cerebellar Purkinje cells, cerebellar deep nuclei, facial nerve nucleus, and the motor and spinal subdivisions of the trigeminal nucleus and facial nerve nucleus. The pattern of bFGF immunoreactivity in the hippocampus was examined following entorhinal cortex lesion, or fimbria-fornix transection. After entorhinal cortex lesion, bFGF immunoreactivity increased in the outer molecular layer of the dentate gyrus ipsilateral to the lesion. The lesion effect on bFGF immunoreactivity was expressed as an increase in the number of bFGF astrocytes, as an increase in the intensity of bFGF immunoreactivity within astrocytes, and as an increase of bFGF immunoreactivity in the surrounding extracellular matrix, relative to the contralateral side. The time course and pattern of reorganization paralleled the sprouting of septal cholinergic terminals in response to the same type of lesion, suggesting that bFGF may play an important role in lesion-induced plasticity. After transection of the fimbria-fornix, chronic infusion of bFGF appeared to preserve NGF receptors on neurons within the medial septal complex and, as previously reported, prevent the death of medial septal neurons. Therefore, it appears that bFGF infusion, which has been shown to increase the synthesis of NGF by astrocytes (Yoshida and Gage, 1991), also helps enable neurons to respond to NGF. This suggests that after injury bFGF may participate in a cascade of neurotrophic events, directly and indirectly facilitating neuronal repair and/or promoting neuronal survival.     

Effects of sciatic nerve transplants after fimbria-fornix lesion: examination of the role of nerve growth factor

At two weeks post-transplantation, sciatic nerves inserted into the lesioned septo-hippocampal pathway contain NGF levels more than twice that of normal nerves. These transplanted nerves also contain regenerating cholinergic axons. Moreover, transplanted animals exhibit septal NGF levels that are significantly greater than in animals with lesions only. These results suggest a role for NGF in the ingrowth of axons into the transplants and in the increase in ChAT(+) septal neurons previously observed at this post-transplant time.     

Cholinergic expression by a neural stem cell line grafted to the adult medial septum/diagonal band complex

The potential of a neural stem cell line to acquire cholinergic characteristics was studied in transplants injected into the septum/diagonal band nuclei of young adult rats and mice. The stem cells integrated within the nuclei and survived for up to 9 months. Three methods were used to identify the grafted cells and to show differentiation into astrocytes and neurons. Enhanced survival of the stem cells occurred in the host brain with a previous lesion of the fimbria-fornix pathway. Differentiated cells acquired neuronal-like features including the expression of neurofilament subunits. In lesioned hosts, subpopulations of the grafted cells acquired a cholinergic neuronal phenotype and expressed choline acetyltransferase and the p75 neurotrophin receptor. Cells that developed into astrocytes were often associated with blood vessels and expressed glial fibrillary acidic protein. The results further exemplify the potential of stem cell lines and the property of site-specific differentiation when this line is transplanted to the cholinergic system of the adult brain.     

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.     

Coexistence of cholinergic, catecholaminergic, serotonergic, and glutamatergic neurotransmitter markers in mouse clonal hybrid neurons derived from the septal region.

Two clonal immortalized neurons designated SN6.1b and SN6.2a were isolated by limiting dilution from a mouse embryonic septal cholinergic neuronal hybrid cell line SN6 (Hammond et al., 1986). In the serum-containing medium without extra differentiating agents, one-third of SN6.1b cells stably exhibited a morphology of differentiated neurons with extensive elaborate neurites, while a majority of SN6.2a cells, along with the parent cell line SN6, were round in shape with poorly branched short processes. Neurochemical studies showed that both clones synthesized choline acetyltransferase (ChAT), dopamine, norepinephrine, serotonin, and glutamate. Immunocytochemically, they expressed a number of neuronal antigens, such as 200-kDa neurofilament protein, neuron-specific enolase, microtubule-associated protein 2, tau protein, tubulin, neural cell adhesion molecule, Thy-1.2, saxitoxin-binding sodium channel protein, ChAT, tyrosine hydroxylase, serotonin, and glutamate. The coexistence of cholinergic, catecholaminergic, serotonergic, and glutamatergic neurotransmitter markers in the clonal hybrid septal neurons that express a variety of immunocytochemical properties of differentiated neurons suggests that embryonic septal cholinergic neurons are potentially multiphenotypic with respect to neurotransmitter synthesis.     

Development of septal cholinergic neurons in culture: plating density and glial cells modulate effects of NGF on survival, fiber growth, and expression of transmitter-specific enzymes

To characterize the role of NGF in the development of forebrain cholinergic neurons, we established primary cell culture systems to grow these cells under controlled in vitro conditions. Cultures of dissociated cells were prepared from the septal area of fetal (E17) rats, which contained part of the group of basal forebrain cholinergic neurons. Cultures were treated either with NGF (100 ng/ml) or with an antiserum against NGF (1:500 dilution). To assess the influence of non-neuronal cells, 2 types of high-density cultures were prepared: mixed neuronal-glial cultures and pure neuronal cultures. Cholinergic neurons were identified using choline acetyltransferase (ChAT) immunocytochemistry and AChE cytochemistry. Receptors for NGF (NGF-R) were located immunocytochemically using monoclonal antibodies against rat NGF-R. We report that, first, NGF-R are exclusively localized on cholinergic neurons in septal cultures. All neurons labeled with antibodies against NGF-R also contained AChE. Twenty-one percent of all AChE-positive neurons were not stained in NGF-R immunocytochemistry (AChE has earlier been shown to be colocalized with ChAT in septal cultures). Second, NGF treatment increases and anti-NGF treatment reduces the number of AChE-positive neurons in cultures of low plating density, suggesting that NGF promotes survival of septal cholinergic neurons in these cultures. In cultures of high plating density, NGF increased the number of NGF-R and ChAT-positive neurons without affecting the number of AChE-positive neurons in these cultures. These results suggest that exogenous NGF is not required for survival of cholinergic neurons in high-density cultures but stimulates the expression of ChAT and NGF-R. Third, NGF stimulates fiber growth of septal cholinergic neurons, as assessed by computerized image analysis of AChE-positive neurons. Fourth, NGF specifically increases ChAT and AChE activities in septal cultures. These NGF-mediated increases in enzyme activities are more pronounced when neurons are grown together with glial cells. In pure neuronal cultures, NGF increased ChAT and AChE activities by 101 and 16%, and in mixed neuronal-glial cultures by 318 and 87%, respectively. Anti-NGF blocked the effects of NGF but failed to reduce ChAT and AChE activities below control levels in cultures of high plating density. Fifth, astrocytes attenuate the expression of ChAT and AChE by septal neurons in the absence of NGF.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ontogeny and cellular expression of MHC and leucocyte antigens in human retina

We have investigated the ontogeny of MHC class I, class II, CD45, and macrophage antigens in wholemounts of normal human fetal retina at 10–25 weeks gestation (WG) using monoclonal antibodies and immunogold histochemistry. MHC class I antigens were expressed on retinal vascular endothelial cells and provided a useful marker of vessel organization from 14–25 WG. Microglial cells expressed immunoreactivity to MHC class I, class II, and CD45 antigens from 10 WG (pre-vascularization) and macrophage S22 (Mac S22) antigen from 14 WG (post-vascularization), although none of the antigens tested were detected on neuronal or macroglial elements. Microglia expressing MHC, CD45, and macrophage antigens occurred in both ramified and rounded forms with no close correlation being observed between morphology and antigenicity. The numbers of immunoreactive cells labeled with each of the four markers increased steadily throughout gestation in all specimens studied. Equivalent numbers of microglia expressed MHC class I, class II, and CD45 antigens in retinae at similar gestational ages; however, our data indicate that microglia expressing Mac S22 antigen comprise approximately 40% or less of the population of MHC and CD45-immunoreactive cells during development. Topographical analyses suggest that MHC class I, class II, and CD45-positive microglia enter the retina from both the peripheral retinal margin and the optic disc from at least 10 WG; Mac S22-positive cells appear in association with the development of the retinal vasculature and enter the retina via the optic disc after 14 WG. © 1995 Wiley-Liss, Inc.     

Rescue of lesioned septal cholinergic neurons by nerve growth factor: specificity and requirement for chronic treatment

We earlier reported that chronic intraventricular injections of NGF into adult rats with partial transection of the fimbria prevent the lesion-induced disappearance of cholinergic neurons in the medial septal nucleus and the diagonal band of Broca (Hefti, 1986). The present study assessed the specificity and treatment requirements of this effect of NGF. Immunohistochemical visualization of NGF receptors (NGF-R) revealed that these molecules are selectively located in forebrain cholinergic neurons of unlesioned brains. Fimbrial transection resulted in transient accumulation of NGF-R in proximal stumps of lesioned axons but failed to induce the expression of NGF-R by other cells in the septal area or near the lesion. Two to three weeks after lesioning, the number of septal neurons expressing NGF-R was reduced by approximately 50% in parallel with the reduction of the number of neurons expressing cholinergic marker enzymes. Repeated intraventricular NGF injections during 4 weeks prevented the disappearance of these cells. Fimbrial transections also reduced the number of septal GABAergic neurons visualized by glutamate decarboxylase immunohistochemistry. The loss of GABAergic neurons was not prevented by NGF. These findings suggest that NGF prevents the lesion-induced degeneration of cholinergic neurons by directly acting on NGF-R expressed by cholinergic cells and that NGF does not affect any neuron with an axonal lesion. Delayed start of the NGF treatment failed to prevent the disappearance of lesioned cholinergic neurons, providing evidence that NGF treatment indeed promotes the survival of these cells rather than simply upregulating the expression of transmitter-specific enzymes. A single injection of NGF at the time of the lesion was not sufficient to prevent the lesion-induced degeneration of cholinergic neurons. Furthermore, termination of chronic NGF treatment after 4 weeks was followed by loss of septal cholinergic neurons after an additional 4 weeks. These findings suggest that the continuous presence of NGF during more than 4 weeks is required to prevent the degeneration of cholinergic cells. The data are discussed in the context of a possible physiological role of NGF in the function of adult forebrain cholinergic neurons.     

Acetylcholine-rich neuronal grafts in the forebrain of rats: Effects of environmental enrichment, neonatal noradrenaline depletion, host transplantation site and regional source of embryonic donor cells on graft size and acetylcholinesterase-positive fibre outgrowth

The importance of several factors influencing the survival of cholinergic-rich embryonic tissue transplanted to the adult rat forebrain and the extent of acetylcholinesterase-positive fibre innervation of the host brain was investigated in 3 experiments. In the first two experiments, embryonic ventral forebrain tissue was grafted to the neocortex of rats in which the intrinsic cortical cholinergic innervation had been removed by nucleus basalis lesions. Housing the host rats in an enriched environment produced a temporary enhancement of fibre outgrowth 4 weeks after transplantation, but this was not maintained after 10 weeks. Fibre outgrowth was greater when the grafts were transplanted to the noradrenaline-depleted neocortex than to the intact neocortex. Neither environmental enrichment nor noradrenaline depletion influenced graft survival or size. In the third experiment, the embryonic donor tissue was dissected to separate regions containing precursors of the nucleus basalis cholinergic cells from regions containing precursors of the septal cholinergic cells, and transplanted to either the neocortex following nucleus basalis lesions or to the hippocampus following fimbria-fornix lesions. Nucleus basalis grafts showed greater growth in size than septal grafts, and grafts placed into the hippocampus showed greater growth in size than grafts placed into the neocortex. More interestingly, the extent of fibre outgrowth depended on the appropriateness of the donor tissue to the host transplantation site: nucleus basalis tissue showed greater acetylcholinesterase-positive outgrowth than septal tissue in the neocortex, whereas septal tissue showed greater outgrowth than nucleus basalis tissue in the hippocampus.     

An in vivo and in vitro analysis of systemic immune function in mice with histologic evidence of neural transplant rejection

Histologic and immunocytochemical analyses of fetal neocortical tissue transplanted to the lateral ventricle of inbred adult mice indicate that this tissue survives transplantation well if the donor and host are isogeneic. The major histocompatibility complex (MHC) of the mouse is known as the H-2 locus. H-2-incompatible neural transplants (allografts), unlike their H-2-identical counterpart (isografts), are characterized by the presence of T cells comprising both major T-cell subsets and macrophages, and by a marked increase in the expression of both class I and class II (Ia) MHC antigens. These findings suggest a recognition of H-2 alloantigens by the host's immune system followed by an appropriate effector response. We report here our attempts to demonstrate systemic host sensitization to alloantigens in mice bearing H-2-incompatible intraventricular neural transplants. We measured the time to rejection of orthotopic skin grafts subsequent to neural transplantation, splenocyte proliferative responses to alloantigens in mixed lymphocyte cultures (MLC), and class I-restricted antigen-specific cytolytic T lymphocyte (CTL) activity. No significant differences were found in any of these tests of host systemic sensitization between mice with allogeneic neural transplants and those with isogeneic transplants or control animals. We conclude that intraventricular neural transplants, while recognized and affected by cells of the host's immune system, do not elicit a detectable systemic sensitization to class I H-2 alloantigens. Rejection of neural transplants may depend on sensitization to class II H-2 alloantigens, to so-called minor histocompatibility antigens, or some combination thereof.     

The Role of NGF and Afferent Denervation in the Process of Sympathetic Fiber Ingrowth into the Hippocampal Formation

Nerve growth factor (NGF) has been postulated to play an important role in the process of sympathetic sprouting into the septally deafferented hippocampal formation. In the current investigation we have used transplants of NGF-dependent neonatal superior cervical ganglion (SCG) neurons to investigate the influence of NGF and septal denervation (either alone or in combination with one another) upon neuronal survival and intrahippocampal sprouting. In the current model, SCG transplants were placed onto the dorsal surface of the CA1 hippocampal subfield and a continuous infusion device was used to deliver either NGF or vehicle into the hippocampal parenchyma. Following 15 days of vehicle infusion, little or no sympathetic neuronal survival was observed and no hippocampal fiber outgrowth was detected. NGF infusions, however, promoted both neuronal survival and intrahippocampal fiber outgrowth directed mainly toward the location of the infusion cannula. Septal denervation, achieved by either a septal ablation or fimbria–fornix transection, had no discernible impact upon SCG neuronal survival or fiber outgrowth, with or without NGF infusions. Similar results were also obtained when SCG were transplanted directly within the cortex, with or without an intracortical infusion. It appears, therefore, that NGF may be a sufficient, as well as necessary, component for eliciting and guiding the invasion of a tissue by NGF-sensitive fibers.     

Characterization of microglial reaction after middle cerebral artery occlusion in rat brain

We have studied the microglial reaction that accompanies cortical infarction induced by middle cerebral artery occlusion (MCAO). Lectin histochemistry with the B₄-isolectin from Griffonia simplicifoliaas well as immunocytochemistry with a panel of monoclonal antibodies directed against major histocompatibility complex (MHC) and lymphocytic antigens were performed. Principal attention was focused on neocortical and thalamic regions, representative of primary and secondary ischemic damage, respectively. With the lectin procedure, activated microglial cells were abundant in the neocortex 24 hours after MCAO. In contrast, microglial activation in the thalamus was not apparent until day 2 after MCAO. On day 5, MHC class II antigen was expressed by reactive microglia in fiber tracts traversing the striatum, but was absent from activated microglia in the primary cortical infarction area. MHC class I and lymphocytic antigens were expressed differentially on microglia with class I antigens appearing early and lymphocytic antigens appearing late in the time course after focal ischemia. The findings are compatible with previous studies during global ischemia and confirm the early activation and the progressive nature of immunomolecule expression on activated microglia after an ischemic insult. In addition to neocortical and thalamic sites, our results showed an early microglial activation to be present also in forebrain regions outside of the middle cerebral artery (MCA) territory, such as the contralateral cortex and hippocampus. A unilateral microglial reaction was also detectable after long-term survival (≥4 weeks) in the pyramidal tracts, as well as in the corticospinal tracts at cervical but not lumbar spinal cord levels. Ischemia-induced neuronal damage, as evaluated by Nissl staining, was found only in cortical and thalamic regions. We conclude that the demonstration of reactive microglia indicates not only imminent ischemic neuronal damage within MCA territory but can also delineate extra-focal disturbances, possibly reflecting subtle and transitory changes in neuronal activity. © 1993 Wiley-Liss, Inc.     

Nerve growth factor promotes survival of septal cholinergic neurons after fimbrial transections

Several findings obtained in recent years suggest that NGF, aside from its well-established function as a neurotrophic factor for peripheral sympathetic and sensory neurons, also has trophic influence on the cholinergic neurons of the basal forebrain. The present study assessed whether NGF was able to affect survival of central cholinergic neurons after axonal transections in adult rats. The septo-hippocampal pathway was transected unilaterally by cutting the fimbria, and animals were implanted with a cannula through which NGF or control solutions were injected intraventricularly over 4 weeks. The lesions reduced the number of large cell bodies, as visualized by Nissl staining in the medial septal nucleus and in the vertical limb of the diagonal band of Broca. Furthermore, in the same nuclei, they reduced the number of cell bodies positively stained for AChE after pretreatment with diisopropylfluorophosphate (a method known to result in reliable identification of cholinergic neurons in the septal area). On lesioned sides, the number of cholinergic cells in medial septal nucleus and the vertical limb of the diagonal band was reduced by 50 +/- 4%, as compared to the number on contralateral sides. On lesioned sides of animals chronically treated with NGF, the number of AChE-positive cells in these areas was reduced only by 12 +/- 6%, as compared to control levels. These findings suggest that fimbrial transections resulted in retrograde degeneration of cholinergic septo-hippocampal neurons and that NGF treatment strongly attenuated this lesion-induced degeneration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neuronal properties and trophic activities of immortalized hippocampal cells from embryonic and young adult mice

The hippocampal formation elaborates trophic factors such as nerve growth factor (NGF) to support the cholinergic innervation it receives from the septal region. To further study the trophic interactions of this pathway, hippocampal cells from embryonic day 18 and postnatal day 21 mice were immortalized via somatic cell fusion to N18TG2 neuroblastoma cells. The hippocampal cell lines exhibit morphological and cytoskeletal features which are typical of their neuronal parents but which are not expressed by the neuroblastoma parent. When differentiated with retinoic acid, the hippocampal cell lines exhibit electrophysiological features similar to cultured hippocampal neurons. Many of the lines constitutively express high levels of NGF, and at least one cell line exerts a non-NGF trophic effect on the expression of choline acetyltransferase by septal neurons in vitro. These cell lines are potentially useful for investigating the neurochemical and excitable properties of hippocampal neurons and identifying novel trophic activities that promote the development and maintenance of the septohippocampal pathway.     

Morphological response of axotomized septal neurons to nerve growth factor

Septal efferent fibers from the neurons in the medial septal nucleus are destroyed by fimbria-fornix aspirative lesion. In the present study we used quantitative morphometric techniques to evaluate the response of these axotomized septal neurons to a constant infusion of nerve growth factor (NGF). By 2 weeks following the lesion, approximately 75% of the cholinergic neurons had degenerated in the untreated rats. The remaining cholinergic neurons showed few signs of the effect of the lesion when stained for a polyclonal antibody to ChAT and examined in 40-micron-thick sections. In 1-micron-thick sections the remaining ChAT-immunoreactive (IR) neurons also appeared no different from the intact ChAT neurons. However, non-ChAT-IR neurons had a shrunken nucleus, while all other morphometric parameters appeared normal. NGF infusion protected most of the ChAT-IR neurons from degenerating. The saved neurons had the same parameters as the undamaged ChAT-IR neurons when examined in either 40-micron- or 1-micron-thick sections. In addition, the shrunken appearance of the non-ChAT-IR neurons' nuclei was avoided by the NGF infusions. Enlarged ChAT-IR processes were evident in the dorsolateral quadrant of the septum following damage to the fimbria-fornix. NGF-infusions prevented the formation of these processes. Instead, in the treated animals the dorsal lateral quadrant contained a dense plexus of fine ChAT-IR varicosities. Taken together these results demonstrate that NGF not only can protect the cholinergic neurons from axotomy-induced degeneration but can also cause the saved neurons to maintain the same morphometric appearance as intact ChAT-IR neurons.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ultrastructural characterization of identified cholinergic neurons transplanted to the hippocampal formation of the rat

The ultrastructural features of cholinergic neurons transplanted to the rat hippocampal formation were studied by using a monoclonal antibody to choline acetyltransferase (ChAT). Septal cell suspensions were prepared from E-18 rat embryos and injected into the hippocampus of host rats that had been previously subjected to a bilateral transection of the fimbria-fornix. Rats with fimbria-fornix lesions alone and unoperated rats served as controls and were examined to characterize the native hippocampal cholinergic system. Both unoperated controls and rats with fimbria-fornix lesions showed a sparse population of intrinsic ChAT-immunoreactive neurons that were most numerous in the subgranular zone, the hilus fascia dentata, and near the hippocampal fissure. ChAT-positive terminals from controls formed synapses on dendritic structures that were primarily symmetrical. ChAT-positive dendrites in controls received synaptic input from nonimmunoreactive axon terminals. In rats with septal transplants, ChAT-immunoreactive transplant neurons were found that were either bipolar or multipolar. Axons of transplanted neurons were unmyelinated and arose either from the cell body or a primary dendritic process where they gave off numerous collaterals. Terminals from transplant neurons formed synapses with many nonimmunoreactive neurons. In transplant animals, two main targets of ChAT-immunoreactive terminals were identified: The great majority of synapses were symmetrical junctions with dendritic spines and shafts. A number of terminals were found that appeared to be juxtaposed to nonimmunoreactive axon terminals, possibly forming symmetrical axo-axonic connections. In contrast, such axo-axonic contacts were not observed in the controls. It is concluded that transplanted cholinergic neurons may reinnervate the host hippocampus; however, this reinnervation is different from what is seen in the intact hippocampal formation.     

Acetylcholine-rich transplants in the hippocampus: influence of intrinsic growth factors and application of nerve growth factor on choline acetyltransferase activity

Three groups of rats received either unilateral fimbria-fornix lesions by aspiration through the overlying cingulate cortex (group I), a fimbria-fornix lesion followed by an intrahippocampal transplant of acetylcholine (ACh)-rich embryonic septal tissue (group II), or a similar septal transplant placed into the intact hippocampus, in the absence of the denervating lesion (group III). The 3 groups were subdivided into equal subgroups receiving 6 intrahippocampal injections of nerve growth factor (NGF) at 4-day intervals, control injections of cytochrome c, or no injections. On the 28th day all animals were sacrificed and the majority taken for biochemical analysis of hippocampal choline acetyltransferase (ChAT). The animals with intact hippocampi (group III) were given a denervating fimbria-fornix lesion 3 days prior to sacrifice in order to reveal graft-derived ChAT activity from intrinsic ChAT activity. The fimbria-fornix lesions (group I) depleted hippocampal ChAT activity to 15-20% of normal, which was not influenced by NGF injections. The ACh-rich grafts placed in the denervated hippocampus (group II) restored hippocampal ChAT activity to approximately 60% of the normal level, and this was promoted to approximately 84% of NGF, but not cytochrome c, injections into the hippocampus. Grafts placed into the intact hippocampus (group III) did not raise ChAT activity above the lesion-alone level, and this was not influenced by NGF injections. Acetylcholinesterase (AChE) histochemistry showed no difference in outgrowth from the grafts in the denervated hippocampus with or without NGF injections. The results are interpreted, in agreement with observations in tissue culture, as indicating that NGF enhances ChAT activity in grafted neurons, rather than promoting survival and growth per se.     

Mouse nerve growth factor prevents degeneration of axotomized basal forebrain cholinergic neurons in the monkey

NGF, a trophic polypeptide, is necessary for the normal development and survival of certain populations of neurons in the CNS and PNS. In the CNS, cholinergic neurons of the basal forebrain magnocellular complex (BFMC) are prominent targets of NGF. During rat development, NGF increases the activity of ChAT in these neurons. In adult rats with experimental injury of axons in the fimbria-fornix, NGF prevents degenerative changes in axotomized cholinergic BFMC neurons in the medial septal nucleus (MSN). Because the amino acid sequences of NGF and its receptor (NGF-R) are highly conserved across species, we hypothesized that mouse NGF would also prevent degeneration of cholinergic BFMC neurons in nonhuman primates. Therefore, the present study was designed to test whether fimbria-fornix lesions result in retrograde degenerative changes in basal forebrain cholinergic neurons in macaques, whether these changes are prevented by mouse NGF, and whether the protective effect of NGF is selective for cholinergic neurons of the basal forebrain. Following unilateral complete transection of the fornix, animals were allowed to survive for 2 weeks, during which time half of the subjects received intraventricular NGF in vehicle and the other half received vehicle alone. In animals receiving vehicle alone, there was a 55% reduction in the number of ChAT-immunoreactive cell bodies within the MSN ipsilateral to the lesion; loss of immunoreactive somata was more severe in caudal planes of the MSN. Remaining immunoreactive neurons appeared smaller than those in control, unoperated animals. In Nissl stains, there was no apparent loss of basophilic profiles in the MSN, but cells showed reduced size and intensity of basophilia. Treatment with NGF almost completely prevented reductions in the number and size of cholinergic neurons and had a significant general effect in preventing atrophy in basophilic magnocellular neurons of the MSN, though some basophilic neurons in the MSN did not appear to respond to NGF. Adjacent 7-microns-thick sections stained with ChAT and NGF-R immunocytochemistry revealed that these markers are strictly colocalized in individual neurons in the MSN in controls and in both groups of experimental animals. Thus, mouse NGF profoundly influences the process of axotomy-induced retrograde degeneration in cholinergic BFMC neurons in primates. The in vivo effectiveness of mouse NGF on primate BFMC neurons suggests that mouse or human recombinant NGF may be useful in ameliorating the ACh-dependent, age-associated memory impairments that occur in nonhuman primates.(ABSTRACT TRUNCATED AT 400 WORDS)     

BN rats do not reject F344 brain allografts even after systemic sensitization

Embryonic brain tissue allografts under many circumstances survive transplantation into the brain. It is generally believed that such grafts will not survive if the host animal is systemically sensitized, by skin grafting or other means, to major histocompatibility complex (MHC) antigens of the donor animal. We have found that F344 brain grafts survive in BN hosts even when the host is systemically sensitized to F344 tissue. Embryonic cerebral neocortex from F344 donors was transplanted into BN host rats (n = 95). Subsequently, the host rats were systemically sensitized with donor skin (n = 25), brain tissue (n = 41), or spleen cells (n = 6) and compared with a control group of rats consisting of allografts with no sensitization or sham procedures (n = 23). Rejection of the transplants in BN rat hosts was not provoked by any of the sensitization methods tested. Minor immunological responses that did not result in rejection were, however, present in many host animals. We did not observe infiltration of W3/13+ T cells and OX8+ cytotoxic lymphocytes in any of the groups. Nevertheless, substantial infiltrations of OX6+ antigen-presenting cells and W3/25+ helper T cells were present. There was also an extensive enhancement of MHC class I immunoreactivity in parts of the grafted tissue developing within the third ventricle, but not for the same type of graft in the lateral ventricle. This increase of MHC class I expression was not accompanied by infiltration of cytotoxic T cells. Our findings thus suggest that neural graft rejection depends on general genetic susceptibility to immune reactions, particularly experimental allergic encephalomyelitis and not only on disparity between donor and host antigens encoded by the MHC. Moreover, enhancement of MHC class I and class II expression within transplanted tissue does not predict graft rejection.