Reversible changes in the accumulation and activities of tyrosine hydroxylase and dopamine-beta-hydroxylase in neurons of nucleus locus coeruleus during the retrograde reaction

Interactions Between MPTP-Induced and Age-Related Neuronal Death in a Murine Model of Parkinson’s Disease

Abiotrophy is hypothesized to explain the onset and time course of deficits in Parkinson’s disease (PD) Abiotrophy includes: 1) exposure to agent(s) causing the death of dopaminergic nigrostriatal neurons (DNSns), 2) gradual death of DNSns with age, 3) summation of 1) and 2) until DNSn numbers fall below a threshold for detectable neurological deficits. Murine DNSn death following methyl-phenyl-tetrahydropyridine (MPTP) exposure occurs according to an exponential relationship while age-related death of DNSns occurs according to a second exponential relationship. Summing the two exponential losses overestimates experimental DNSn death showing a simple abiotrophic model is not sufficient. Aged murine DNSns greatly increase their dopamine synthesis and the density of their striatal axon terminals which may explain the above threshold. Murine DNSns die gradually after MPTP exposure and L-deprenyl treatment rescues MPTP-damaged DNSns by a previously undiscovered action, altering the abiotrophic interactions and possibly explaining the slowed progression of PD found with deprenyl treatment.

Pathological dynamics of activated microglia following medial forebrain bundle transection

To elucidate the role and pathological dynamics of activated microglia, this study assessed the phagocytic, immunophenotypic, morphological, and migratory properties of activated microglia in the medial forebrain bundle (MFB) axotomized rat brain. Activated microglia were identified using two different monoclonal antibodies: ED1 for phagocytic activity and OX6 for major histocompatibility complex (MHC) class II. Phagocytic microglia, characterized by ED1-immunoreactivity or ED1- and OX6-immunoreactivity, appeared in the MFB and substantia nigra (SN) as early as 1-3 days post-lesion (dpl), when there was no apparent loss of SN dopamine (DA) neurons. Thereafter, a great number of activated microglia selectively adhered to degenerating axons, dendrites and DA neuronal somas of the SN. This was followed by significant loss of these fibers and nigral DA neurons. Activation of microglia into phagocytic stage was most pronounced between 14 approximately 28 dpl and gradually subsided, but phagocytic microglia persisted until 70 dpl, the last time point examined. ED1 expression preceded MHC II expression in phagocytic microglia. All phagocytic microglia sticking to DA neurons showed activated but ramified form with enlarged somas and thickened processes. They were recruited to the SNc from cranial, dorsal and ventral aspects along various structures and finally stuck to DA neurons of the SNc. Characteristic rod-shaped microglia in the white matter were thought to migrate a long distance. The present study strongly suggests that neurons undergoing delayed neurodegeneration may be phagocytosed by numerous phagocytic, ramified microglia at various sites where specific surface signals are exposed or diffusible molecules are released.

Microglial phagocytosis of dopamine neurons at early phases of apoptosis

Transection of the medial forebrain bundle caused apoptosis of dopamine neurons in the rat substantia nigra. Immunohistochemical localization of activated microglia and tyrosine hydroxylase in the axotomized substantia nigra showed that activation of microglia was rapid and OX-6 (MHC-II marker)-positive and ED1 (lysosomal phagocytic marker)-positive microglia were apposed to structurally intact tyrosine hydroxylase-positive dopamine neurons, indicating microglial phagocytosis of degenerating dopamine neurons. The occurrence of microglial phagocytosis at early stages of apoptosis may indicate the evolution of apoptosis into an irreversible state. Alternatively, interventions that suppress early activation of microglia might lead to novel mechanisms for neuron protection.

In situ examination of tyrosine hydroxylase activity in the rat locus coeruleus using (3',5')-[(3)H(2)]-alpha-fluoromethyl-tyrosine as substrate of the enzyme

Tyrosine hydroxylase (TH) activity can be modified by changes in the specific activity of the enzyme (SA(TH)) or in the levels of active enzyme. We developed a methodology making it possible to measure with excellent anatomical resolution TH enzymatic activity and TH protein quantity by quantitative autoradiography and immunoautoradiography, respectively, from adjacent sections taken at serial intervals along the longitudinal extent of a same brain. SA(TH) was estimated by the slope of linear regressions established between TH activity and TH quantity measured at each anatomical plane. To evaluate TH activity, we used (3',5')-[(3)H(2)]-(D, L)-alpha-fluoromethyl-tyrosine [(3)H(2)]-MFMT, which is transformed by TH to [(3)H]-MFM-dopa, a potent and irreversible substrate for aromatic amino acid decarboxylase. We found that the SA(TH) in the cell body area of the LC (PKA) was 48% lower than that evaluated in the surrounding pericoerulean neuropil (PCN). In the PCN, 22% only of TH level exhibited a level of enzymatic activity above threshold. We also examined how SA(TH) was distributed in the LC 15 min and 3 days after RU 24722 treatment, a potent phasic and tonic activator of TH enzyme in noradrenergic neurons. Two distinct mechanisms have been observed: the short-term effect was due to an increase in the SA(TH) in the PKA only, while the long-term effect was mainly caused by an increase in the number of active TH proteins in the PCN. These results suggest that the fine regulation of TH activity which occurs in the different compartments of LC neurons may be critical in the functions involving the LC.

Mesencephalic THmRNA-reduced expression by blocking axonal transport with colchicine

Colchicine, an axonal transport blocking agent, was unilaterally injected in the medial forebrain bundle of rats. As early as 18 h after the injection a rapid decrease in TH-mRNA level was observed in the substantia nigra and the ventral tegmental area (SN/VTA) on the injected side. In contrast, TH protein levels remained stable for 48 h, and decreased later in both cells bodies and terminals (caudate/putamen). The number of TH-immunopositive cells in SN/VTA increased after colchicine equally in both sides, excluding a neurotoxic effect. These results suggest that TH gene expression is controlled by a retrogradely transported activating factor rather than by feedback inhibition by the end product, i.e. TH protein.

Olfactory bulbectomy increases prepro-galanin mRNA levels in the rat locus coeruleus

The effects of olfactory bulbectomy (OBX) on galanin (GAL) gene expression in the locus coeruleus (LC) were examined with quantitative in situ hybridization histochemistry. OBX increased prepro-GAL levels 3 and 14 days after surgery, as compared to sham-operated controls. Levels of mRNA encoding prepro-neuropeptide Y (NPY) were unchanged, and levels of mRNA encoding tyrosine hydroxylase (TH) were elevated in the LC only on day 3. The results indicate that GAL gene expression in the LC increases after lesioning a terminal field.

Differential effects of the intraventricular administration of 6-hydroxydopamine on the induction of type II beta-tubulin and tyrosine hydroxylase mRNA in the locus coeruleus of the aging Fischer 344 rat

Noradrenergic neurons of the locus coeruleus have been shown to respond to injury by increasing the synthesis of neurotransmitter (via the activation and induction of tyrosine hydroxylase, the rate-limiting catalyst in the production of catecholamines) and initiating compensatory axonal sprouting. However, this laboratory has recently described a significant deficit in the activation of tyrosine hydroxylase in the aged Fischer 344 rat, in contrast to the young and mature rat, following partial damage to cortical and hippocampal noradrenergic terminals induced by the neurotoxin 6-hydroxydopamine. To extend these observations, we measured changes in the relative levels of neuron-specific type II beta-tubulin and tyrosine hydroxylase mRNA in locus coeruleus neurons of 2, 12, and 24-month-old Fischer 344 rats following intraventricular infusions of 6-hydroxydopamine by using in situ hybridization histochemistry. These measures were used as markers of the responsiveness of these neurons to injury. 6-Hydroxydopamine treatment induced a persistent increase (at least 10 days) in the expression of type II beta-tubulin mRNA only in 2-month-old animals; this marker decreased in the 12 and 24-month-old animals. Relative levels of tyrosine hydroxylase mRNA increased in 2 and 12-month-old lesioned animals both 3 and 10 days post-treatment. In contrast, the induction of tyrosine hydroxylase mRNA in 24-month-old animals, seen three days post-treatment, was attenuated by 10 days. These data indicate that the capacity of locus coeruleus neurons to compensate for injury by either initiating a potential sprouting response or increasing their capacity to synthesize neurotransmitter is reduced in older animals.

Connection matrix of the hippocampal formation: I. The dentate gyrus

The hippocampal formation presents a special opportunity for realistic neural modeling since its structure, connectivity, and physiology are better understood than that of other cortical components. A review of the quantitative neuroanatomy of the rodent dentate gyrus (DG) is presented in the context of the development of a computational model of its connectivity. The DG is a three-layered folded sheet of neural tissue. This sheet is represented as a rectangle, having a surface area of 37 mm2 and a septotemporal length of 12 mm. Points, representing cell somata, are distributed in the model rectangle in a roughly uniform fashion. Synaptic connectivity is generated by assigning each presynaptic cell a spatial zone representing its axonal arbor. For each postsynaptic cell, a list of potential presynaptic cells is compiled, based on which arbor zones the given postsynaptic cell falls within. An appropriate number of presynaptic inputs are then selected at random. The principal cells of the DG, the granule cells, are represented in the model, as are non-principal cells, including basket cells, chandelier cells, mossy cells, and GABAergic peptidergic polymorphic (GPP) cells. The neurons of layer II of the entorhinal cortex are included also. The DG receives its main extrinsic input from these cells via the perforant path. The basket cells, chandelier cells, and GPP cells receive perforant path and granule cell input and exert both feedforward and feedback inhibition onto the granule cells. Mossy cells receive converging input from granule cells and send their output back primarily to distant septotemporal levels, where they contact both granule cells and non-principal cells. To permit numerical simulations, the model must be scaled down while preserving its anatomical structure. A variety of methods for doing this exist. Hippocampal allometry provides valuable clues in this regard.

Spontaneous and amphetamine-evoked release of cerebellar noradrenaline after sensorimotor cortex contusion: an in vivo microdialysis study in the awake rat

Microdialysis sampling combined with HPLC was used to assess spontaneous and d-amphetamine (AMPH)-evoked release of noradrenaline (NA) in the cerebellum 1 day after probe implantation and 1 day after contusion of the right sensorimotor cortex (SMCX) in rats. In normal controls the mean +/- SEM basal NA release was 10.08 +/- 0.97 pg in the left cerebellar hemisphere and 8.21 +/- 1.17 pg in the right hemisphere 22-24 h after probe implantation. The average +/- SEM NA release in a 3-h period after administration of AMPH (2 mg/kg, i.p.) increased to 453 +/- 47.35 pg in the left and to 402 +/- 49.95 pg in the right cerebellar hemisphere. NA release (range of 413-951% increase over baseline) was maximal 20-40 min postdrug, returned to basal levels within 5 h, and remained unchanged for the 22-24-h postdrug measurement period. Animals with a focal SMCX contusion had a marked depression of both spontaneous and AMPH-evoked NA release. Mean +/- SEM basal NA release was 4.84 +/- 1.09 pg in the left and 4.95 +/- 0.43 pg in the right cerebellar hemisphere from 22 to 24 h postinjury, with NA levels increasing to 259 +/- 75.44 and 219 +/- 23.45 pg in the respective hemispheres over a 3-h period after AMPH. The maximal AMPH-induced increase in NA release ranged from 522 to 1,088% of basal levels in contused rats, with NA release returning to predrug levels within 5 h and remaining depressed for at least 48 h postinjury.(ABSTRACT TRUNCATED AT 250 WORDS)

Axotomy-induced differential gene induction in neurons of the locus ceruleus and substantia nigra

The biochemical and molecular events correlated with neuronal injury and survival are not well understood. Previous studies have reported that following axotomy, neurons in the substantia nigra pars compacta (SNc) and the locus ceruleus (LC) exhibit a significant increase in tyrosine hydroxylase (TH) enzyme activity within 24-72 h (Brain Res., 144 (1978) 325-342; Brain Res., 92 (1975) 57-72). To investigate the potential contribution of TH gene induction to this increase a semi-quantitative immunocytochemical and in situ hybridization time course analysis was undertaken. Following axotomy, TH immunoreactivity increased in neurons of both the SNc and LC. In contrast, an increase in TH mRNA was only evident in neurons of the LC. As a possible mechanism for the observed alterations in TH gene expression, the levels of an immediate early gene, c-fos, were examined. C-fos mRNA and Fos protein were not expressed in either normal or axotomized neurons of the SNc. However, the constitutive expression in control LC neurons increased significantly following axotomy. These data demonstrate the differential response of two central catecholaminergic populations to axotomy and suggests a potential role for the immediate early gene, c-fos, in the post-injury reaction.

Unilateral locus coeruleus lesions facilitate motor recovery from cortical injury through supersensitivity mechanisms

Previous research has indicated that noradrenergic infusions into the cerebellum contralateral to a sensorimotor cortex injury facilitate recovery of motor function. In the present study, the locus coeruleus was lesioned at 2 weeks prior to, 1 week prior to, or simultaneous with a right sensorimotor cortex injury, and functional recovery in response to noradrenergic cerebellar infusions was measured using the beam-walk task. When the locus coeruleus lesion was separated from the sensorimotor cortex lesion by 1 week or more, noradrenergic-induced facilitation of functional recovery occurred with the greater effects observed at the 2-week interval. Simultaneous locus coeruleus and sensorimotor cortex injury with cerebellar noradrenergic infusions revealed no difference in functional recovery. The results suggest that denervation supersensitivity and/or sprouting developed in the cerebellum following the locus coeruleus lesions if a sufficient amount of time elapsed before the sensorimotor cortex injury. The heightened sensitivity to noradrenergic infusions in the contralateral cerebellum suggests that noradrenergic changes in this structure underlie the acceleration of functional recovery from the cortical injury.

Selegiline can mediate neuronal rescue rather than neuronal protection

Selegiline [(-)-deprenyl] has been reported to slow the progression of disabling deficits in Parkinson's disease (PD) and cognitive decline in Alzheimer disease (AD). The apparent slowing has been proposed to be based on either symptomatic improvement due to increased dopaminergic neurotransmission or alternately on protection of neurons from damage caused by toxic oxidative radicals. Both mechanisms are hypothesized to result from the inhibition of monoamine oxidase type B (MAO-B) activity. Our experiments in two animal models have shown that selegiline has a second, previously unsuspected action. That is, selegiline can rescue neurons after they have sustained lethal damage and the rescue is independent of MAO-B inhibition. It was previously shown that the coadministration of selegiline with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) could protect dopaminergic substantia nigra neurons (dSNns) from damage by blocking conversion of MPTP to its active radical N-methyl-4-phenylpyridinium (MPP+) by inhibiting MAO-B. In the first model, we treated C57BL mice with MPTP but delayed selegiline treatment for 72 h after the MPTP treatment to allow for complete conversion of MPTP to MPP+ and for maximal dSNn damage by MPP+. The delayed selegiline treatment rescued approximately 69% of the dSNns that had not died by the time the treatment began but were found to die with saline treatment. Selegiline doses that were too small to cause inhibition of MAO-B substrate oxidation rescued the MPTP-damaged dSNns. The second model was based on previous work showing that immature (14-day-old) rat facial motoneurons die after axotomy because of a loss of trophic support from the muscle they innervate. Selegiline treatment increased the number of motoneurons surviving axotomy from 24 to 52%, showing that selegiline can rescue neurons by partially compensating for the loss of target-derived trophic support. This "trophic-like" action of selegiline might account for the reported slowing of the progression of PD and AD and suggests that selegiline therapy may be of value with acute nervous system damage, particularly damage caused by trauma.

Cerebellar norepinephrine infusions facilitate recovery after sensorimotor cortex injury

This study reports the effects of norepinephrine infusions into cerebellum after unilateral sensorimotor cortex injury. The results demonstrate an immediate and permanent acceleration in motor recovery in awake rats infused with 150 micrograms norepinephrine into the cerebellum contralateral to a right sensorimotor cortex ablation. A vehicle infusion or infusion of norepinephrine into the ipsilateral cerebellum produced no beneficial effects on functional recovery.

Species-specific distribution of aromatic L-amino acid decarboxylase in the rodent adrenal gland, cerebellum, and olfactory bulb

Aromatic L-amino acid decarboxylase (AADC), the enzyme that converts L-dopa to dopamine, displayed species-specific differences in both activity and immunoreactivity in the cerebellum, olfactory bulb, and adrenal glands of three rodent species, the hamster, rat, and mouse. Specifically, in the hamster but not the rat or mouse, AADC immunoreactive cells were observed in the cerebellum and adrenal cortex. The unusual distribution of the enzyme was confirmed biochemically. AADC activity was greater in the adrenal gland and the cerebellum in the hamster than in the mouse or rat. In addition, by Western blot analysis, one band of appropriate molecular weight was observed both in the hamster adrenal gland and cerebellum. The rat adrenal gland displayed a similar immunoreactive protein on the Western blot; however, the protein could not be detected in the rat cerebellum by the technique utilized. Tyrosine hydroxylase (TH) immunoreactivity in these same tissues did not differ among the species. In the main olfactory bulb of the mouse, juxtaglomerular cells exhibited very limited immunoreactivity for AADC, but TH-immunoreactivity in these cells was robust. In contrast, juxtaglomerular cells in the rat displayed a similar intensity of immunostaining for both AADC and TH. AADC activity in the mouse, consistent with the reduced immunostaining for the enzyme, was 50% of that in the rat and the hamster. These data demonstrate that AADC protein, which is contained in cells of diverse function, also displays qualitative and quantitative species specific variations in both distribution and amount.

Fetal neocortical transplants into the medial forebrain bundle attract ingrowth of catecholaminergic fibers in adult rat brain

The hypothesis that fetal tissue grafts may exert a trophic influence on damaged catecholaminergic fibers was examined. Ascending dopamine and norepinephrine axons normally innervate frontal cortex targets in the intact rat brain. These and other ascending catecholaminergic fibers were disrupted with stereotaxic injections of 6-hydroxydopamine into the medial forebrain bundle (mfb), followed after 1 or 14 days by grafts of fetal neocortical tissue placed into the injection site, or by sham grafts. Glyoxylic acid histofluorescence techniques were then used to examine catecholaminergic fiber distribution. When such lesions were made without subsequent grafting, virtually no growth of catecholaminergic fibers occurred beyond the injection site and frontal cortex norepinephrine levels were depleted to 15% of control levels. However, when grafts of fetal neocortical tissue were made into the lesion site and animals examined 3 months later, catecholaminergic fibers grew through the lesion site to ramify within the graft tissue. Catecholaminergic fibers were seen in all portions of most grafts, though they were most dense on the caudal and ventral edges of the graft, close to the path of the mfb. Similar densities of graft innervation were seen 3 months after animals received grafts placed into the same site without prior lesioning of catecholaminergic fibers. Fetal neocortical grafts thus induce collateral sprouting from intact host catecholaminergic axons and may also promote regenerative sprouting when such fibers are otherwise irreparably damaged.

Cortical microstimulation thresholds adjacent to sensorimotor cortex injury

The initial severe contralateral impairment of motor function after unilateral damage to a portion of sensorimotor (SM) cortex lessens within a few weeks after injury. In this study, two hypotheses proposed to explain recovery of behavioral function after cortical injury were tested: (1) Intact cortex adjacent to the injury reorganizes to take over the function of the destroyed area. (2) Intact SM cortex adjacent or connected to the injured area undergoes a transient shock (diaschisis), and as this dissipates, some behavioral recovery occurs. Using microstimulation of the cortex of the adult rat, movements evoked from areas near cortical injuries were studied at various times after undercut laceration, contusion, or suction ablation of an area of SM cortex. Stimulation areas were compared to those obtained from uninjured control animals and to the contralateral uninjured hemisphere. No evidence was obtained for any reorganization of stimulated motor responses in the injured hemisphere even in animals followed for as long as 475 days postinjury, suggesting other mechanisms underlying functional recovery. In intact cortex at some distance from contusion and laceration injuries, there was a marked elevation of thresholds to evoke movements that returned to normal by 9-15 days postinjury. Some intact hindlimb responses were observed after contusion injury that were absent in animals after 15 days postinjury, indicating a slow-growing lesion after this type of trauma. Surprisingly, no elevation in thresholds was noted for ablation injuries up to the edge of the cavity at any time postinjury, indicating that threshold changes near the boundary may be uncorrelated with functional recovery.

Experimentally-induced neuron loss in the locus coeruleus of adult rats

Systemic administration of the noradrenergic neurotoxin N-(2-chloroethyl)-N-ethyl-2-bromobenzylamine (DSP-4) to adult rats causes widespread degeneration of locus coeruleus (LC) axon terminals. The present study was conducted to determine the effects of DSP-4-induced LC axon lesions on LC cell bodies. Six months after DSP-4 treatment, quantitative analysis of Nissl-stained sections revealed a profound loss of LC perikarya, ranging from 20 to 73% of control. The remaining LC neurons appeared shrunken, but stained strongly with dopamine beta-hydroxylase immunohistochemistry. These findings support the conclusion that DSP-4-induced LC axon lesions cause retrograde degeneration of LC neurons. DSP-4 may serve as a useful tool in studies of the mechanisms of LC neuron degeneration.

Evidence for decreased transport of PNMT protein in advanced Alzheimer's disease

Phenylethanolamine N-methyltransferase (PNMT) is the rate-limiting enzyme in the synthesis of epinephrine and a specific marker for adrenergic neurons. PNMT protein is decreased in axon terminals in brains from patients with Alzheimer's disease due to retrograde degeneration of epinephrine neurons. To determine the subcellular mechanism underlying retrograde degeneration, the distribution of PNMT between axon terminal and cell body was calculated in early and advanced Alzheimer cases compared with age-matched controls. In early Alzheimer's disease there is a decrease in PNMT in axon terminals and in total PNMT in epinephrine cell bodies and terminals compared with control values. There is no difference in the ratio of PNMT in cell body/axon terminal compared with controls. In contrast, in advanced Alzheimer's disease, PNMT activity increases by 124% in epinephrine neuronal cell bodies compared with controls. Immunochemical titration shows that this increased enzyme activity is due to an increase in PNMT protein. The cell body/axon terminal ratio of PNMT is increased 2.5-fold in advanced Alzheimer's disease compared with controls. These findings are consistent with the hypothesis that in early Alzheimer's disease there is a decreased synthesis or increased degradation of PNMT. However, in advanced Alzheimer's disease we propose that the accumulation of this enzyme in the perikarya results from a diminished transport of PNMT to axon terminals. We further postulate that epinephrine, the product of PNMT, and its further metabolites are endogenous neurotoxins. Therefore, the accumulation of PNMT in epinephrine cell bodies may contribute to the degeneration of these neurons in Alzheimer's disease.

Dose-dependent destruction of the coeruleus-cortical and nigral-striatal projections by MPTP

In order to determine whether 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) produces neuronal death or the loss of tyrosine hydroxylase (TH) immunoreactivity, 4 catecholaminergic nuclei in the mouse: substantia nigra compacta (SNc), locus coeruleus (LC), ventral tegmental area (VTA) and the A13 nucleus in the hypothalamus were quantitatively examined. Serial sections were taken through the rostrocaudal extent of each nucleus: alternate sections were incubated with TH antiserum and reacted with an immunoperoxidase technique while the alternate set was Nissl stained. Counts and 3 dimensional reconstructions of TH reactive somata were made for each nucleus for saline-treated controls and mice treated with different doses of MPTP (37.5, 75, 150 and 300 mg/kg). TH-positive neurons were counted along with their counterparts on the Nissl-stained alternative sections to both identify the catecholaminergic neurons and to measure their destruction. Concentrations of striatal dopamine and cortical norepinephrine were measured for all dosages of MPTP in order to determine the relationship between dosage, target tissue neurotransmitter concentration and neuronal destruction. By 20 days after MPTP injection there was a dose-dependent random loss of TH-immunoreactive neurons that was almost identical in all 4 nuclei examined. Analysis of the Nissl versus TH cell counts revealed that MPTP resulted in neuronal destruction in the SNc and the LC rather than just a loss of TH immunoreactivity. There was no difference in sensitivity to MPTP between the SNc and the LC. Decreases in cortical norepinephrine concentrations were about one third of the decreases of LC neuronal counts for all MPTP doses; while decreases in striatal dopamine and SNc cell loss was similar to the LC for the two lower doses of MPTP but for the higher doses, the relationship approached or exceeded a one to one ratio. Hence estimates of neuronal death based upon target tissue transmitter concentrations could not be made using the same relationship for SNc and the LC catecholaminergic neurons and use of the same relationship for higher MPTP dosages results in an underestimate of LC neuronal destruction relative to that in the SNc.

Transneuronal regulation of neuronal specific gene expression in the mouse olfactory bulb

Peripheral afferent denervation (deafferentation) of the rodent main olfactory bulb produces a marked decrease in tyrosine hydroxylase (TH) activity and immunoreactivity in a population of juxtaglomerular dopaminergic neurons. Preservation of activity and immunostaining for aromatic L-amino acid decarboxylase implies that these cells do not die, but change phenotype. We now report that the steady-state level of TH mRNA markedly decreases in the adult mouse olfactory bulb in response to deafferentation. This reduction is permanent following intranasal irrigation with 0.17 M zinc sulphate (ZnSO4) but reversible following deafferentation produced by intranasal irrigation with 0.7% Triton X-100. The initial declines in TH activity, protein and mRNA of dopaminergic juxtaglomerular neurons observed after Triton X-100 treatment are all reversible as the steady-state level of TH mRNA gradually returns to control levels. Steady-state levels of mRNA for olfactory marker protein (OMP), a protein found in high concentrations in olfactory receptor neurons and their processes which innervate the olfactory bulb, were also monitored following deafferentation. Following treatment with either ZnSO4 or Triton X-100, the pattern of changes in steady-state levels of OMP mRNA was similar to that observed for TH. The steady-state level of PEP19 mRNA, a peptide previously localized to granule cells in the olfactory bulb, was not altered by deafferentation. These data indicate selective and parallel regulation of TH and OMP message and protein levels following deafferentation.

Unilateral, neonatal olfactory deprivation alters tyrosine hydroxylase expression but not aromatic amino acid decarboxylase or GABA immunoreactivity

Recent publications have demonstrated an important role for olfactory afferent innervation in maintenance of the dopamine phenotype of olfactory bulb target neurons. The mechanisms underlying the control of phenotypic expression in this system are not known. These studies employed the model of unilateral neonatal olfactory deprivation to investigate the effects of lack of odorant stimulation on dopamine expression in the rat. Immunoreactivity of tyrosine hydroxylase, the first and rate-limiting enzyme in dopamine biosynthesis, used as a marker of the dopamine system, exhibited a large decrease both 40 and 70 days following olfactory deprivation. The losses were region specific suggesting that the deprivation was not complete. The number of immunoreactive GABAergic neurons was not reduced. The number of neurons containing aromatic L-amino acid decarboxylase (the second enzyme in the dopamine biosynthetic pathway) was also not decreased. Olfactory marker protein immunoreactivity in the glomeruli, a marker for afferent innervation, was not significantly altered indicating that the olfactory bulb was not denervated. These data demonstrate that neonatal deprivation, and the resulting lack of odorant stimulation, produces a transneuronal alteration in dopamine expression without neuronal loss. The studies also suggest that neuronal activity or the activity-dependent release of a trophic factor is necessary for the expression of the dopamine phenotype.

Evidence for retrograde degeneration of epinephrine neurons in Alzheimer's disease

Alzheimer's disease (AD) is associated with a progressive loss of locus ceruleus neurons. These noradrenergic neurons receive a major afferent projection from epinephrine neurons in epinephrine cell groups in the brainstem. The epinephrine neurons have a specific enzymatic marker, phenylethanolamine N-methyltransferase (PNMT), which allows them to be identified chemically and immunohistochemically. We have previously reported a decrease in PNMT in brains of patients with AD. We now report that the decrease in PNMT activity in projections to the locus ceruleus is not due to the loss of epinephrine neurons, although up to 33% of these neurons are atrophic. The decrease in presynaptic PNMT does, however, correlate with the loss of postsynaptic locus ceruleus neurons in brains from AD patients. The percentage of degenerating neurons in the epinephrine nuclei also correlates significantly with the amount of loss of locus ceruleus neurons in AD. In addition, there is a 55% decrease in mitogen activity, a nonspecific measure of growth or maintenance factors, in dialysed locus ceruleus extracts from the AD patients compared to those from control subjects. The mitogen activity in the locus ceruleus was significantly correlated with PNMT activity and with the density of locus ceruleus neurons in all cases examined. These findings provide evidence for the hypothesis that retrograde degeneration is a mechanism of neuronal degeneration in AD and suggest that trophic factors may play a role in this process.

Lateralized effect of cerebral infarction on spinal fluid monoamine metabolite concentrations in rats

Using a rat model of stroke, we studied the effect of unilateral middle cerebral artery ligation on cerebrospinal fluid monoamine metabolites at different intervals over a 40-day postoperative period. Male Sprague-Dawley rats were divided into four groups: an unoperated control group (n = 9), a sham-operated group (n = 9), a right middle cerebral artery ligation group (n = 10), and a left middle cerebral artery ligation group (n = 10). One hundred microliters of cerebrospinal fluid were collected percutaneously from the cerebellomedullary cistern just before and 5, 20, and 40 days after the surgical procedure. Monoamine metabolites--3-methoxy-4-hydroxyphenylglycol (MHPG), 5-hydroxy-indoleacetic acid (5-HIAA), and homovanillic acid (HVA)--were measured using high-performance liquid chromatography. MHPG concentration in the right lesion group was significantly depleted from control levels 5, 20, and 40 days after surgery. No such depletion was observed in the left lesion rats. Concentration of 5-HIAA was relatively lower at Days 5 and 20 in the right lesion group than in the left lesion group. HVA concentration did not differ among the groups at any time. Our study has demonstrated a differential effect of unilateral ischemia on cerebrospinal fluid neurochemistry in rats dependent on the cerebral hemisphere involved.

Destruction of cells in the midportion of the locus coeruleus by a dorsal bundle lesion in neonatal rats

Although insult of the developing noradrenergic neuronal system in the brain has been associated with redistribution of noradrenergic fiber input to various target brain regions, few studies have investigated the effects of such insults on locus coeruleus cell survival. In the present study the dorsal noradrenergic bundle was transected by means of a midbrain knife cut in rats 3 days after birth, and the effects of this lesion were determined approximately 8-10 weeks later. By means of an immunofluorescent histochemical procedure, it was shown that tyrosine hydroxylase-containing fibers and dopamine beta-hydroxylase-containing fibers were markedly reduced in number in the neocortex and hippocampus--regions anterograde to the site of axonal transection. It was further demonstrated that the number of fluorescent fibers coursing through the dorsal bundle was similarly reduced. Sprouting of noradrenergic fibers in the brainstem and cerebellum accompanied the above alterations. When locus coeruleus cell number was determined by counting Cresyl violet-stained nucleoli in serial sections it was found that dorsal bundle transection produced a loss of 17% of the cells of the coeruleus. By dividing the counts for each nucleus into fifths, it was additionally found that approximately 20-25% of those cells comprising the midportion of the nucleus, along a rostrocaudal axis, were the ones destroyed by axonal transection. These findings indicate that a neonatal lesion of the dorsal bundle produces a loss of cells in the midportion of the nucleus locus coeruleus, and that this effect is associated with noradrenergic neuronal hyperinnervation of the brainstem and cerebellum.

Developmental discord among markers for cholinergic differentiation: in vitro time courses for early expression and responses to skeletal muscle extract

The effects of skeletal muscle extract on the development of CAT, ACh synthesis, high affinity choline uptake, and AChE activities were studied in dissociated ventral spinal cord cultures prepared from 14-day gestational rat embryos. In the absence of muscle extract, the development of CAT and AChE follow biphasic time courses in which they show initial declines followed by periods of steadily increasing activity. In contrast, ACh synthesis and high affinity choline uptake both gradually increase throughout the entire culture period. The presence of muscle extract both prevents the initial decline of CAT and AChE as well as stimulates the rates of development of all four cholinergic markers; however, the degrees and time courses of stimulation differ markedly. The effects of muscle extract on the kinetic and pharmacological properties of ACh synthesis and choline uptake in rat ventral cord cultures were also investigated. Cells treated with muscle extract for 2 days express both high affinity (Km = 1.6 microM) and low affinity (Km = 22 microM) choline uptake mechanisms. Control cells, on the other hand, express only low affinity uptake at this stage but develop a high affinity uptake mechanism by Day 7. During this time both ACh synthesis and high affinity choline uptake become increasingly sensitive to inhibition by hemicholinium-3. These results demonstrate that skeletal muscle factors enhance the development of cholinergic properties in embryonic spinal cord cultures. However, differences in sensitivity to muscle extract concentration, time courses of development, and degrees of stimulation suggest that these changes may involve distinct cellular mechanisms which are differentially affected by skeletal muscle factors.

Neural activity in the regenerating optic nerve of the goldfish

1. Retinal ganglion cells of one eye were axotomized in goldfish either by sectioning the contralateral optic tract or by ablating the contralateral lobe of the optic tectum. Between 2 and 40 days later, multiunit activity in response to diffuse light flashes was recorded from the axotomized and normal optic nerves, and from the optic tectum. 2. Two days after tract section, the amplitude of the integrated multiunit response of the axotomized nerve was normal. By 16 days it had fallen to 15% of control values, at which time visual responses carried by the regenerating tract were first recorded in tectum. Activity in the axotomized nerve then recovered gradually. 3. After ablation of one tectal lobe, multiunit responses in the axotomized nerve had not recovered by 40 days. 4. Integrated spontaneous activity in the axotomized nerve was depressed with a similar time course to the depression of light-evoked activity, both after tract section and tectal ablation. 5. Retinal ganglion cell nuclear size, a morphological indicator of the cell body reaction, varied inversely with evoked activity, whether axotomy was by tract section or by tectal ablation. 6. Electrically evoked compound action potentials of normal amplitude could be recorded from an axotomized nerve despite depressed responses to light flashes. 7. It is concluded that optic nerve axotomy in goldfish reduces the number of optic fibres carrying impulses and/or the frequency of their discharge. The effect is closely linked to morphological changes occurring in the retinal ganglion cell bodies. Recovery of impulse activity and morphology depends upon the regenerating optic fibres innervating an appropriate target.

Localization of the main noradrenergic neuron groups in the pons and medulla of the rabbit and the importance of cathodal lesions for prolonged survival

Methods for stereotaxically localizing the major noradrenergic (NA) cell groups (i.e. A1, A2, A5 and A6 + A7) in the rabbit are described. Using a modified Kopf head holder we used surface landmarks including the obex for making lesions of the A1 and A2 cells in the medulla. Localization of the pontine cell groups was done by mapping intracerebral structures including the facial nerve for A5 and the motor nucleus of the trigeminal nerve for A6 + A7. In the initial experiments we made A1 lesions by passing anodal currents through stainless steel electrodes, which was associated with pulmonary oedema, neurological complications and a high mortality. This syndrome was probably related to toxic effects of ferric ion deposition, and disappeared when cathodal currents were employed. We have now made 106 bilateral cathodal lesions in the different groups, with a 20% intraoperative mortality. But virtually all survivors remained indefinitely in clinically good condition for the 2-4 weeks duration of our experiments. In 65 of these rabbits we achieved greater than 75% of NA cell destruction (average 84%). From the cardiovascular viewpoint 'non-specific' damage by the lesions was relatively small, except after A2 lesions where there was some impairment in the baroreceptor-heart rate reflex, though a considerable amount of residual function remained.

Biochemical evidence for an interaction between adrenaline and noradrenaline neurons in the rat brainstem

In this study, we sought to determine if there was an interaction between the C2 adrenaline-containing (A) neurons of the rat medulla oblongata and the noradrenaline-containing (NA) cell bodies of the locus coeruleus (LC). For this purpose, the biochemical response of the NA cell bodies of the LC after a lesion of the C2 region was studied by using as markers the in vitro activities of the catecholamine synthesizing enzymes: tyrosine hydroxylase (TH), dopamine-beta-hydroxylase (DBH) and phenylethanolamine-N-methyltransferase (PNMT). An increase in TH activity, not associated with any change in DBH or PNMT activity, was found in the LC (+104%, P less than 0.001) 4 days after a bilateral electrolytic lesion (3 mA for 5 s) of the C2 region. Conversely, the electrolytic lesioning of the neighboring A2 region of NA neurons did not modify the TH activity of the LC. These results suggest the existence of an ascending adrenergic inhibitory control of the NA cell bodies of the LC.

Carbonic anhydrase activity in the normal and injured peripheral nervous system of the rat

The carbonic anhydrase reactivity of primary neurons and axons of the L4 and L5 lumbar levels was studied in rats before and after various surgical procedures including transection of the spinal cord, removal of dorsal root ganglia, and transection of ventral or dorsal roots or spinal nerves. In normal animals, carbonic anhydrase reactivity was confined to large and medium size neurons of the dorsal root ganglia, and was also present in a sizeable percentage of cells scattered throughout the thoracolumbar sympathetic chain and in the celiac ganglion. At root level, enzymatic staining could be detected in 48.7% of the dorsal root myelinated axons of most sizes, whereas in ventral roots, it was restricted to small myelinated axons, in a proportion much higher at the L4 than in the L5 level. Spinal motoneurons remained unlabeled, despite procedures aimed at increasing the somal concentration of carbonic anhydrase, such as ventral root ligation and blocking of the fast or slow axoplasmic transport using colchicine or iminodiproprionitrile. However, it is likely that reactive ventral root axons originate from neurons situated segmentally in the spinal cord, and do not constitute aberrant sensory fibers, as carbonic anhydrase activity remained unchanged in the L4 and L5 ventral roots after removal of the corresponding spinal ganglia, whereas it disappeared after damage to the spinal cord at the lumbar level, or at a site distal to a ventral root section. Enzymatic staining of neurons of the dorsal root ganglia was not modified by a dorsal rhizotomy, but showed a marked decrease after transection of the spinal nerve.(ABSTRACT TRUNCATED AT 250 WORDS)

Injury of nigral neurons exposed to 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine: a tyrosine hydroxylase immunocytochemical study in monkey

Six monkeys treated with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine developed a Parkinsonian syndrome (rigidity, akinesia, flexed posture and tremor). In both high and low dose groups, neurons in the substantia nigra were selectively damaged. At high dose levels, nigral neurons were severely damaged, but because the monkeys died, the evolution of the pathology could not be studied. At low dose levels, some nigral neurons survived, and a significant number of these nerve cells showed reductions in the immunoreactivity of tyrosine hydroxylase. Axonal pathology was conspicuous in the nigrostriatal pathway. Loss of the immunoreactivity of tyrosine hydroxylase in perikarya may represent a retrograde axonal reaction, a potentially reversible response. The 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine model should prove useful for investigating abnormalities occurring as a consequence of dysfunction of the nigrostriatal system, for examining processes associated with repair of damaged neuronal systems, and for developing and testing therapeutic approaches designed to prevent or ameliorate the Parkinsonian syndrome.

Alterations in noradrenergic innervation of the brain following dorsal bundle lesions in neonatal rats

Several seemingly conflicting sets of data have been reported on the regenerative capacity of central noradrenergic neurons, following transection of the ascending noradrenergic fiber tract in neonatal rats (Iacovitti et al., Dev Brain Res 1: 21-33, 1981; Jonsson and Sachs, Brain Res Bull 9: 641-650, 1982). In order to more fully investigate changes in noradrenergic neurons in the brain after such a transection, rats were lesioned at various times after birth, sometimes in conjunction with administration of the neurotoxin, 6-hydroxydopa (6-OHDOPA). Animals were sacrificed at 7, 10, 14, 28, 42 or 56 days after birth, in order to assess the pattern of noradrenergic neuronal damage, as well as the recovery rate. Dorsal bundle lesions were associated with neocortical and hippocampal hypoinnervation by noradrenergic fibers, and sprouting of a collateral fiber group, with production of noradrenergic hyperinnervation of the cerebellum and pons-medulla. Recovery of the norepinephrine (NE) content to control levels occurred in the neocortex at 8 weeks, when the dorsal bundle was lesioned at birth. When the lesion was produced at a later time (3 days or 5 days after birth), less recovery in the neocortex and hippocampus was found. Histofluorescent fiber number, as observed with a glyoxylic acid method, correlated with NE changes. It appears that 6-OHDOPA (20 micrograms/g IP) does not modify long-term recovery from a dorsal bundle lesion, when rats are co-treated at 3 days after birth. However, the length of the proximal noradrenergic fiber stump may be an important factor affecting the capacity for recovery from injury.(ABSTRACT TRUNCATED AT 250 WORDS)

Axonal transport of beta-receptors during the response to axonal injury and repair in locus coeruleus neurons

Injections of the catecholamine neurotoxin, 6-hydroxydopamine, were placed in the ascending locus coeruleus (LC) pathway in the right cerebral cortex of rats partially destroying the noradrenergic projection to the somatosensory cortex. Norepinephrine (NE) levels fell to a nadir of 49% of control over the first 14 days, associated with a 40% increase in the number of beta-adrenoreceptor binding sites (labeled with [3H]dihydroalprenolol; [3H]DHA) in the denervated cortex. Both NE levels and cortical beta-receptor binding returned to control levels by 28 days. Similar changes, of lesser magnitude, also occurred in the unlesioned, left somatosensory cortex. Catecholamine histofluorescence studies supported these findings of denervation and reinnervation of the right cortex over a 3-month period. Anterograde axonal transport of beta-receptors was assessed by measuring the accumulation of beta-receptor binding sites ([3H]DHA) behind a second lesion placed in the more proximal portion of the ipsilateral LC pathway. Anterograde transport was completely blocked at 4 days, during the initial fall of NE levels, then was increased to 200% of control at 14-21 days, when recovery of cortical NE levels was beginning, and then returned towards control levels by 2-3 months when normal NE levels had been restored.(ABSTRACT TRUNCATED AT 250 WORDS)

Peripheral nerve grafts to the frog optic tectum: a morphological study of the axon reaction in trigeminal motor and sensory neurons

The mandibular branch of the trigeminal nerve was severed and the proximal stump was grafted onto the optic tectum in adult Rana pipiens. The resultant changes occurring in the cell bodies of origin in the ipsilateral trigeminal motor and mesencephalic nuclei were studied qualitatively and quantitatively. Nucleolar, nuclear, and somal cross-sectional areas increased in size significantly approximately 3 days after surgery and peaked at 6 weeks postsurgery. This swelling, in which the nucleolus was most severely affected, gradually reversed itself and disappeared by 24 weeks after surgery. Despite the cell enlargement, cytoplasmic basophilia was maintained or even slightly increased. These morphologic changes suggest a strong anabolic reaction. Two differences were found between the motoneurons and the sensory neurons. First, the morphometric cell changes occurred at a faster rate in neurons of the trigeminal motor nucleus than in those of the mesencephalic nucleus. The time course of the motoneuron response correlated well with that of axonal regeneration from the nerve graft. Second, there was a delayed loss of mesencephalic nucleus cells between 12 and 24 weeks after surgery, whereas cells of the trigeminal motor nucleus were maintained at all survival times studied. Taken together with sensory cell loss in the trigeminal ganglion, this suggests a greater viability of regenerating motoneurons.

Sequential changes of sensory neuron (fluoride-resistant) acid phosphatase in dorsal root ganglion neurons following neurectomy and rhizotomy

Five to seven days after sciatic nerve section in rats, fluoride-resistant acid phosphatase (FRAP) expression in dorsal root ganglion (drg) neurons was markedly decreased. The decrease was in contrast to increased acid phosphatase which has been reported to occur in other neurons after nerve section. FRAP expression in ganglion neurons subsequently increased 14-21 days after nerve section; this preceded the restitution of enzyme expression in the spinal cord substantia gelatinosa. FRAP expression in drg neurons was not decreased after dorsal root section.

Tryptophan hydroxylase in hippocampus and midbrain following unilateral injection of 5,7-dihydroxytryptamine

We have previously shown using anatomical methods that partial denervation of the rat hippocampus by removal of serotonergic (5-HT) fibers in the cingulum bundle induces sprouting of intact 5-HT fibers reaching the hippocampus in the fornix-fimbria. The biochemical properties of collateral sprouting fibers have remained largely uncharacterized. Thus, the rate-limiting enzyme in 5-HT synthesis, tryptophan hydroxylase (TPOH), was studied to determine whether new sprouts possess the ability to synthesize 5-HT. Unilateral stereotaxic injections of 5 micrograms 5,7-dihydroxytryptamine were made into the cingulum bundle of adult rats in order to produce partial and selective deafferentation of the hippocampus. Following injection, enzyme activity in the hippocampus declined gradually and bilaterally, reaching minimal levels by 7 days post-lesion. This decrease in enzyme activity was paralleled by a decrease in the Vmax and an increase in the Km of TPOH for tryptophan. Enzyme activity began to increase after 14 days post-lesion, reaching maximal levels by 60 days, but never returning to pre-lesion levels in the ipsilateral side. In midbrain, site of neuronal cell bodies of hippocampal 5-HT projections, enzyme activity gradually increased, reaching a maximum by 28 days after the lesion. These results indicate that 5-HT fibers remaining in the hippocampus following partial denervation are able to compensate biochemically for those removed by cingulum bundle lesions. Biochemical compensation may depend on increased synthesis of TPOH molecules in midbrain cell bodies with subsequent transport into sprouts of intact fibers in the hippocampus.

Axon reaction in hypoglossal and dorsal motor vagal neurons of adult rat: incorporation of [3H]leucine

Pairs of adult rats received [3H]leucine (i.p., 5 microCi/g body weight) 0.25, 1, and 16 h before killing and zero (unoperated control animals) and 1 to 164 days after unilateral cervical vagotomy and hypoglossal neurotomy. Grain counts and morphometric measurements were made on axotomized and uninjured neurons in histoautoradiographs of the medullary nuclei. Axotomized hypoglossal neurons, which largely survive the injury, both enlarged and incorporated increased amounts of tritiated leucine at each labeling interval, 3 through 28 days postoperatively. In the vagal dorsal motor nucleus (DMN), axotomized cells, which frequently die after neurotomy, enlarged slightly through 28 days postoperatively, then atrophied; DMN neurons increased amino acid uptake for a shorter period (days 7 through 14) than hypoglossal neurons. This increase achieved statistical significance only when the labeling intervals were 0.25 or 1.0 h. Neurons of the DMN contralateral to vagotomy also enlarged. Axotomized DMN neurons did not sustain increased protein synthesis as long as their hypoglossal counterparts and seemed to fail to increase synthesis of structural proteins with long half-lives (16-h labeling interval). The frequently necrobiotic response of axotomized DMN neurons may relate to these phenomena. From these and earlier results, we conclude that axon reaction appears to differ fundamentally in peripheral and central neurons. This difference may have significance for research on regeneration in the central nervous system.

Adaptive reaction of nigral neurons following lesion of their ventromedial-thalamic projection field

The response of reticulata-nigral neurons to injury of their ventromedial-thalamic (VM) projection was studied in the rat, by the autoradiographic [14C]deoxyglucose method. Electrolytic lesion of the VM induced reversible: reticulata hypoexcitability; and hyporesponsiveness of areas receiving reticulata efferents, to nigral electrical stimulus. The results suggest that distal axonal injury (in the VM) induces reversible rearrangement of functional properties in the nigral parent cells and their uninjured collaterals, as a retrograde reaction.

Effect of anterior-posterior lesion location on the asymmetrical behavioral and biochemical response to cortical suction ablations in the rat

Small cortical suction ablations were produced at one of several stereotaxically located sites along the anterior-posterior axis of the right or left hemisphere in the rat. Analysis of variance showed a highly significant effect of lesion location in the right hemisphere on locomotor activity. The most anterior lesions produced both the most hyperactivity and also the greatest reductions in the concentrations of norepinephrine in the ipsilateral and contralateral cortex and locus coeruleus. These results suggest that the effect of cortical lesions on spontaneous activity may be graded across the right hemisphere and that the anatomy of certain neurotransmitter pathways in the cortex may help to explain both the biochemical and behavioral findings.

Alterations of norepinephrine metabolism in rat locus coeruleus neurons in response to axonal injury

Adult male Sprague-Dawley rats were injected in the right cerebral hemisphere with the neurotoxin 6-hydroxydopamine (6-OHDA) at a site which interrupted the noradrenergic axons ascending from the locus coeruleus (LC). Distal to the injection site ('posterior cortex'), levels of norepinephrine (NE), dopamine-beta-hydroxylase (D beta H) and tyrosine hydroxylase (TH) fell to 39-42% of control levels ipsilateral to the lesion over the first 25 days, while contralateral levels fell to 32-73% of control during this time. These changes were paralleled by a 63% decrease in the high affinity uptake of [3H]NE in the ipsilateral posterior cortex at 12 days after the lesion. Both ipsilateral and contralateral levels of NE and D beta H fell in the LC during this time, while LC TH showed variable increases and decreases in activity. At 3 months after right cortical 6-OHDA injections, posterior cortical levels of NE, D beta H and TH, as well as the high affinity uptake of [3H]NE, had returned to control levels suggesting that some type of regeneration or axonal sprouting had occurred. Axonal transport of D beta H and TH was assessed by measuring the accumulation of enzyme activity proximal to a 6-OHDA lesion made in the more caudal portion of these same LC axons. Transport of D beta H fell to 7-40% of control from 2 to 24 days and rose to 160% of control by 3 months after the lesion. TH transport was decreased to only 61% of control only at 24 days and returned to control levels by 3 months. These studies document that there is independent regulation of the metabolism of the NE synthetic enzymes, D beta H and TH, during the degeneration and subsequent regeneration or collateral sprouting of injured distal axons of LC noradrenergic neurons.

Biochemical and morphological characterization of sympathetic neurons grown in a chemically-defined medium

Previous studies have demonstrated that individual neurons from neonatal rat superior cervical ganglion express a mixed adrenergic-cholinergic phenotype when grown under certain tissue culture conditions. The expression of this phenotype is critically influenced by a number of undefined components present in the culture medium. In the present study, we have examined whether superior cervical ganglion neurons grown on a chemically defined serum-free medium similarly develop dual transmitter expression, or if under these conditions, neurons express only those properties characteristic of their adrenergic heritage. To address this issue, we established that superior cervical ganglion neurons could be maintained in culture for extended periods on the defined medium described by Bottenstein & Sato in the absence of supporting cells. We then studied the biochemical, immunocytochemical and ultrastructural characteristics of these neurons. We found that in defined medium, superior cervical ganglion neurons continued to express, in a modified form, certain of their expected adrenergic properties, including the development of tyrosine hydroxylase and dopamine-beta-hydroxylase activities, stores of endogenous norepinephrine, synaptic vesicles with dense cores and tyrosine hydroxylase-immunoreactive staining properties. Superior cervical ganglion neurons grown on a defined medium did not, however, acquire cholinergic traits in culture. In this paper we show that choline acetyltransferase activity did not reach detectable levels; the comparison paper documents that cholinergic synapses were not formed. We concluded that superior cervical ganglion neurons, grown under serum-free culture conditions, develop certain properties characteristic of adrenergic neurons and do not express a mixed adrenergic-cholinergic phenotype. A comparison paper describes the electrophysiological properties of these neurons and demonstrates the frequent occurrence of electrotonic synapses in these cultures.

Effect of hydrocortisone on catecholamines and the enzymes synthesizing them in the developing sympathetic ganglion

Newborn rats were daily injected with 0.2 mg hydrocortisone acetate for seven days. They were killed 1, 7 or 21 days after the last injection, together with untreated controls. Hydrocortisone caused a great increase in the number of the small, intensely fluorescent (SIF) cells and the appearance of similar small cells with intense immunohistochemical reactions for tyrosine hydroxylase (TH), dopamine-beta-hydroxylase (DBH) and phenylethanolamine (noradrenaline) N-methyltransferase (PNMT) in the superior cervical ganglion. At the same time, the adrenaline content and the PNMT activity of the ganglion greatly increased, while no significant changes were observed in the dopamine or noradrenaline content or TH or DBH activity. All these changes essentially disappeared after a recovery period of seven or 21 days. It is concluded that hydrocortisone caused a temporary increase in the number of SIF cells by causing a synthesis of TH, DBH and PNMT in previously existing small, non-fluorescent cells, which start to synthesize and store adrenaline, thus becoming intensely fluorescent SIF cells. These SIF cells are different from the normal SIF cells of the same ganglion, most of which appear at a later stage of postnatal development when response to hydrocortisone is lost, which contain TH but neither DBH nor PNMT, and which permanently remain in the ganglion.

Acetylcholinesterase distribution in axotomized frog motoneurons

The distribution of acetylcholinesterase (AChE; EC 3.1.1.7) activity was examined in the perikarya and proximal axonal stumps of frog motoneurons injured by ventral root transection. Based upon measurements of net AChE accumulation in the proximal stumps of transected ventral roots, and upon orthograde clearances of AChE reported by others, it was determined that an amount of AChE equivalent to at least 0.7-2 times the perikaryal content of this enzyme enters the motor axon each day. A progressive decrease in the rate of AChE accumulation in transected axons during the first 3 days after ventral rhizotomy raised the possibility that excess enzyme might accumulate elsewhere within the axotomized motoneurons. However, AChE accumulation was detected only near the cut ends of the ventral roots and was not appreciably increased within injured motoneuronal cell bodies and proximal dendrites, which were isolated by a new method combining bulk and single-cell isolation techniques. These data suggest that AChE turnover is altered rapidly in response to axonal injury, thereby avoiding large perikaryal accumulations of this enzyme.