Human immunodeficiency virus type 1 gp120 and ethanol coexposure in rat organotypic brain slice cultures: Curtailment of gp120-induced neurotoxicity and neurotoxic mediators by moderate but not high ethanol concentrations

Human immunodeficiency virus type 1 (HIV-1) envelope protein gp120, implicated with other retroviral proteins in acquired immunodeficiency syndrome (AIDS)-related dementia, causes neuronal degeneration by inciting cascades of neurotoxic mediators from glia. It also may facilitate neuronal glutamate (N-methyl-D-aspartate, NMDA) receptor-mediated excitotoxicity by interacting at the glycine coagonist site. The authors reported that preconditioning rat organotypic hippocampal-cortical slice cultures subchronically with ethanol at concentrations occurring during moderate drinking (20 to 30 mM) prevented gp120's induction of neurotoxic mediators and intracellular calcium, as well as neuronal death. The authors now find that the acute copresence of ethanol in moderate as opposed to high concentrations similarly blocks the retroviral protein's neurotoxic effects in brain slice cultures, assessed with lactate dehydrogenase (LDH) release and propidium iodide (PI) labeling. As with ethanol preconditioning, neuroprotection against gp120 by moderate ethanol coexposure appears secondary to abrogation of the retroviral protein's early induction of arachidonic acid (AA), glutamate, and superoxide (but not nitric oxide) elevations/release. Additionally, experiments indicate that 30 mM ethanol is sufficient to inhibit the NMDA receptor, particularly in the presence of added glycine, thus hindering potential direct neuronal stimulation by gp120. However, in contrast to moderate ethanol, 100 mM ethanol, a concentration tolerated only in chronic alcoholics, potentiates gp120-dependent neurotoxicity (PI labeling) in the hippocampal CA1 region, augments LDH release, and fails to curtail gp120's actions on AA, glutamate, and superoxide-but does suppress nitric oxide induction. The results indicate dominant roles for AA, superoxide, and glutamate-mediated oxidative stress in gp120's neurotoxic mechanism, but perhaps a less important role for NMDA receptor stimulation, which would be constrained at both ethanol concentrations employed. We suggest that ethanol's concentration-dependent, two-edged sword behavior could alter the development of dementia in HIV-1-infected individuals during social consumption or abuse. Further studies are needed to elucidate the differing apparently glial effects of the two concentrations of ethanol.

Ethanol pre-exposure suppresses HIV-1 glycoprotein 120-induced neuronal degeneration by abrogating endogenous glutamate/Ca2+-mediated neurotoxicity

The neurotoxic mechanism of HIV-1 envelope glycoprotein 120 (gp120) involves glutamatergic (NMDA) receptor/Ca2+-dependent excitotoxicity, mediated in part via glia. Pro-inflammatory cytokines also may have roles. We have reported that pre-exposure of brain cultures to 'physiological' ethanol concentrations (20-30 mM) protects against neuronal damage from HIV-1 gp120, but not from the direct receptor agonist, NMDA. Using lactate dehydrogenase assays and propidium iodide staining of rat organotypic hippocampal-entorhinal cortical slice cultures we determined that ethanol's suppression of gp120 neurotoxicity required at least 4 days of pretreatment. The gp120-induced neurotoxicity was accompanied by interleukin-6 elevations that were not affected by the pretreatment. However, gp120 induced substantial, early increases in extracellular glutamate levels that were blocked by ethanol pretreatment, conceivably abrogating excitotoxicity. Consistent with abrogation of excitotoxic pathways, fura-2 imaging showed selective deficits in gp120-dependent intracellular Ca2+ responses in ethanol-pretreated slices. Gp120 is believed to increase glutamate levels by both stimulating release and inhibiting (re)uptake. Results with a labeled glutamate analog, D-[3H]aspartate, revealed that gp120's inhibition of glutamate uptake, rather than its stimulation of release, was abolished after ethanol. Further studies indicated that two converging effects of ethanol pretreatment may underlie the abolishment of gp120-mediated glutamate uptake inhibition: (a) blockade of gp120-induced release (ostensibly from glia) of arachidonic acid, an inhibitor of astroglial glutamate reuptake, and (b) modest proliferation and activation of astroglia upon gp120 stimulation--which are likely to augment glutamate transporters. Thus, as with gp120 itself, glia and glutamate/arachidonic acid regulation appear to be important targets for ethanol. Since moderate ethanol consumption is as common among HIV-infected individuals as in the general population, this newly recognized neuroprotective (and apparently anti-excitotoxic) effect of ethanol withdrawal in vitro could be important, but it requires further study before its significance, if any, is understood.

Increased beta-carboline 9N-methyltransferase activity in the frontal cortex in Parkinson's disease

Enzymatic beta-carboline N-methyltransferase activities generate N-methylated beta-carbolinium cations that are analogs of the parkinsonian-producing neurotoxin MPP+. We measured beta-carboline-2N-methyltransferase and beta-carboline-9N-methyltransferase activities in the supernatant and particulate fractions from postmortem human brains. These N-methyltransferase activities were assessed in the substantia nigra, putamen, and frontal cortex from control and Parkinson's disease cases. No significant differences were measured in any brain region in particulate and supernatant fraction beta-carboline 2N-methyltransferase activity or particulate fraction beta-carboline 9N-methyltransferase activity. Likewise, supernatant fraction beta-carboline 9N-methyltransferase activity was similar in the putamen and substantia nigra from Parkinson's disease and control cases. Unexpectedly, supernatant fraction beta-carboline 9N-methyltransferase activity was increased fourfold in Parkinson's disease frontal cortex (P < 0.05), suggesting that beta-carboline N-methylation may play a role in Parkinson's disease.

HIV-I gpI20 neurotoxicity in brain cultures is prevented by moderate ethanol pretreatment

The HIV-1 coat protein gp 20, a potent neurotoxin that may underlie AIDS dementia, activates glia to cause neurotoxicity via the NMDA receptor and perhaps other routes. We find that pretreating cultures of rat organotypic cortical/hippocampal slices or cerebellar granule cells subchronically with ethanol in physiological concentrations (20-30 mM; 6 days) largely or even completely inhibits neurodegeneration due to gp120. However, NMDA-induced neurotoxicity appears unaffected by moderate ethanol pretreatment, indicating that ethanol's neuroprotection against gp120 is upstream of the NMDA receptor, possibly at a glial activation stage. The results could lead to a better understanding of relationships between ethanol, glia and neurodegeneration, particularly in AIDS.

Brain neuronal degeneration caused by episodic alcohol intoxication in rats: effects of nimodipine, 6,7-dinitro-quinoxaline-2,3-dione, and MK-801

Rats repeatedly intoxicated with alcohol (ethanol, three times daily) over a 4-day period display neuronal degeneration in the dentate gyrus; entorhinal, piriform, insular, orbital, and perirhinal cortices; and in the olfactory nerve fibers and terminals in the olfactory bulb. Postulating a role for excitotoxicity, we have attempted to prevent the degeneration using antagonists that are neuroprotective in this type of brain damage. In an initial study, continuous subcutaneous infusion of a high dose of the glutamate/NMDA receptor antagonist MK-801 (2 mg/kg/day) by itself caused extensive neuronal degeneration in several brain regions and severe behavioral intoxication that precluded survival if combined with high blood alcohol levels (approximately 300 mg/dl). Moreover, the lower, nonneurotoxic blood alcohol levels (approximately 150 mg/dl) that were compatible with survival worsened the MK-801-induced brain damage. In a subsequent experiment, daily intraperitoneal injections of a lower dose of MK-801 (1 mg/kg/day) resulted in no MK-801 toxicity and, when combined with neurotoxic levels of alcohol, no reduction in alcohol-induced neurotoxicity. Nimodipine, a voltage-gated Ca2+ channel blocker, reduced the neuronal damage in the dentate gyrus, but greatly increased it in the piriform cortex when administered intragastrically at 600 mg/kg/day; it provided no protection from alcohol-dependent degeneration when given intragastrically at 100 mg/kg/day. Continuous intracerebroventricular delivery of 0.24 to 0.29 mg/day of 6,7-dinitro-quinoxaline-2,3-dione, a glutamate/alpha-amino-3-hydroxy-5-methyl-4-isoxazole receptor antagonist, failed to diminish alcohol-dependent neuronal damage in any brain region. We conclude that brain damage from episodic "binge" alcohol intoxication is not primarily mediated by excitotoxic mechanisms, implying that other, nonexcitotoxic pathophysiological mechanisms, are involved. Furthermore, MK-801, far from protecting from the alcohol-induced damage, at high doses causes widespread neuropathology that is significantly potentiated by alcohol.

Brain damage due to episodic alcohol exposure in vivo and in vitro: furosemide neuroprotection implicates edema-based mechanism

Adult rats intubated with a single dose of ethanol (alcohol; approximately 5 g/kg) for 5 to 10 successive days incur neurodegeneration in the entorhinal cortex, dentate gyrus, and olfactory bulbs accompanied by cerebrocortical edema and electrolyte (Na+, K+) accumulation. The brain damage is not lessened by cotreatment with the NMDA receptor antagonist MK-801; also, as reported elsewhere, MK-801 as well as non-NMDA receptor and Ca2+ channel antagonists are not neuroprotective in a similar, but more compressed, intoxication protocol. However, cotreatment with the electrolyte transport inhibitor/diuretic furosemide reduces alcohol-dependent cerebrocortical damage by 75-85% while preventing brain hydration and electrolyte elevations; olfactory bulb neurodegeneration is not attenuated. In parallel in vitro studies, rat organotypic entorhinal/hippocampal slice cultures exposed to alcohol (50-200 mM) 15 h/day for 6 days, mirroring episodic intoxication in vivo, demonstrate concentration-related release of the cytotoxic indicator, lactate dehydrogenase. Analogous to the in vivo findings, furosemide blocks this alcohol-induced in vitro cytotoxicity. Our results showing neuroprotection by furosemide indicate that brain edema and swelling are essential events in the brain damage induced by episodic alcohol exposure. Furosemide and related agents might be useful as neuroprotective agents in alcohol abuse. We suggest that the neurodegeneration is elicited in part by edema-dependent oxidative stress, but the regional selectivity of the damage may be best explained by physical (mechanical) compression of the limbic cortex against the adjacent tympanic bulla and subsequent neuronal cytoskeletal collapse. A scheme for these apparently nonexcitotoxic metabolic and mechanical pathways initiated by repeated alcohol exposure is proposed.

Characterization of brain beta-carboline-2-N-methyltransferase, an enzyme that may play a role in idiopathic Parkinson's disease

The activity of beta-carboline-2-N-methyltransferase results in the formation of neurotoxic N-methylated beta-carbolinium compounds. We have hypothesized that these N-methylated beta-carbolinium cations may contribute to the development of idiopathic Parkinson's disease. This report describes experiments undertaken to optimize assay conditions for bovine brain beta-carboline-2-N-methyltransferase activity. The activity of beta-carboline-2-N-methyltransferase is primarily localized in the cytosol, has a pH optimum of 8.5-9, and obeys Michaelis-Menten kinetics with respect to its substrates, 9-methylnorharman (9-MeNH) and S-adenosyl-L-methionine (SAM). Kinetic constants, KM and Vmax, with respect to 9-MeNH, are 75 microM and 48 pmol/h/mg protein, respectively. The KM for SAM is 81 microM and the Vmax is 53 pmol/h/mg protein. In addition, enzyme activity is inhibited by S-adenosyl-L-homocysteine (SAH) or zinc, and is increased 2-fold in the presence of iron or manganese. Enzyme characterization is a prerequisite to the purification of this N-methyltransferase from bovine brain as well as comparison of its activity in human brain from control and Parkinson's disease individuals.

Binge ethanol-induced brain damage in rats: effect of inhibitors of nitric oxide synthase

Testing the possible role of endogenous nitric oxide (NO) in the neurotoxicity of ethanol, we examined how two different NO synthase (NOS) inhibitors affected the extent cerebrocortical and olfactory neuronal damage in a modified "binge intoxication" rat model (Collins et al., Alcohol Clin. Exp. Res. 20:284-292, 1996). Male rats intragastrically fed ethanol (6.5 to 12 g/kg/day) in nutrient solution three times daily for 4 days also received NG-nitro-L-arginine methyl ester by chronic intracerebroventricular infusion or 7-nitro-indazole by daily intraperitoneal injection; control rats were given nutrient solution only and/or vehicles. Blood ethanol levels did not differ among the ethanol-treated groups. The amount of ethanol-dependent neuronal degeneration in the entorihinal cortex, dentate gyrus, and olfactory bulb glomeruli--visualized with the de Olmos cupric silver stain and quantitatively assessed in the binge-intoxicated rats--was either unchanged or significantly increased by the NOS inhibitors. Although the efficacies of the inhibitors cannot be directly compared because of various NOS forms were probably inhibited to differing extents, the results do not support the idea that endogenous NO is a neurotoxic mediator of ethanol's effects. Rather NO may have a modest neuroprotectant role in this model of early brain damage induced by ethanol. In addition, the NOS that is localized histochemically as NADPH diaphorase was present primarily in regions and/or cells not damaged by binge ethanol treatment. Assuming that NADPH diaphorase represents most of the NO forming enzyme(s) this suggests a transcellular mechanism for NO. A further observation was that hippocampal CA pyramidal neuron degeneration was extensive in rats infused centrally with NG-nitro-L-arginine methyl ester.

Neuronal degeneration in rat cerebrocortical and olfactory regions during subchronic "binge" intoxication with ethanol: possible explanation for olfactory deficits in alcoholics

Severe, repetitive ("binge") ethanol intoxication in adult rats (intragastric delivery 3 times daily for 4 days in a modification of the Majchrowicz method) precipitates neuronal degeneration in selected cerebral cortical regions involved in memory and olfaction, confirming the results of Switzer and colleagues (Anat. Rec. 202: 186a, 1982). Neuronal damage was visualized with the de Olmos cupric silver technique for degenerating neurons and processes (argyrophilia), and was quantitated by total counts and densities of argyrophilic cells/fields. The specificity of the degeneration provides a neuropathological basis for the olfactory memory deficits in chronic alcoholics. In highly intoxicated rats, argyrophilia was most extensive among hippocampal dentate gyrus granule cells, pyramidal neurons in layer 3 of the entorhinal cortex, and olfactory nerve terminals in the olfactory bulb. Degenerating pyramidal neurons were also consistently seen in the insular cortex and olfactory cortical regions, such as the piriform and perirhinal cortices. There were few argyrophilic neurons in the CA regions of the hippocampus and none in the cerebellum--regions generally shown to have cell loss in long-term ethanol feeding models--but degenerating mossy fibers in the CA2 region were observed. Degeneration was maximal before the peak period of abstinence symptoms in this model, because argyrophilic densities were no greater 36 hr, compared with 8 hr after the last ethanol dose. High blood ethanol levels were required, because argyrophilia, absent from isocaloric controls, also was only evident in ethanol-intoxicated rats with mean blood ethanol levels for days 2 to 4 above 300 mg/dl; however, it increased substantially between 350 and 550 mg/dl. The resemblance of the argyrophilic distribution to the regional neuropathology that occurs in experimental seizures indicates that the ethanol-induced degeneration may have an excitotoxic basis. Progressive reductions in the seizure threshold (e.g., kindling phenomena that have been documented during binge ethanol intoxication) might be associated with excitotoxic hyperactivity during the repetitive nadirs between high blood and brain ethanol peaks. However, direct toxic actions of ethanol or its metabolites could also be involved. Overall, the model should be useful for studying mechanisms of ethanol-induced selective cortical and olfactory brain damage.

Methyl-beta-carbolinium analogs of MPP+ cause nigrostriatal toxicity after substantia nigra injections in rats

Eleven beta-carbolinium compounds (beta C+s) and MPP+ were stereotaxically injected (40-200 nmol in 5 microliter of vehicle) unilaterally into the substantia nigra of anesthetized adult male Sprague-Dawley rats. The rats were sacrificed after three weeks. The ipsilateral striatum was analyzed for dopamine and DOPAC levels with HPLC. The brainstem injection site was fixed and cut coronally. The largest lesion area in each animal was measured using NIH IMAGE. Three beta C+s produced lesions whose mean areas were nearly as large as that produced by MPP+ (defined as 100%): 2,9-Me2-harman (94%), 2-Me-harmol (74%), and 2,9-Me2-norharman (57%). Three other compounds produced somewhat smaller lesions: 2-Me-harmaline (34%), 6-MeO-2-Me-harman (29%), and 2-Me-harmine (25%). The remaining compounds were ineffective (< or = 12%): norharman, 2-Me-norharman, 2-Me-harman, harmine, and 2-Me-6-MeO-harmalan. A 40 nmol dose of MPP+ reduced ipsilateral striatal dopamine to 0.6% of control. None of the beta C+s approached this, although several did significantly reduce striatal dopamine at doses of either 40 nmol (2,9-Me2-harman (37%), 2,9-Me2-norharman (42%), and 2-Me-harman (63%)) or 200 nmol (2-Me-harmaline (23%), norharman (63%), and 2-Me-norharman (64%)). There was a moderate negative correlation between lesion size and dopamine level (r = -0.65). There were also moderately strong correlation between lesion size and dopamine level (r = -0.65). There were also moderately strong correlations (r = 0.39-0.78) between the beta C+ nigral lesion area or striatal dopamine level potencies and their previously described IC50 values for inhibiting mitochondrial respiration or their toxicity to PC12 cells in culture. Interestingly, our correlation analysis revealed a remarkably strong correlation between beta C+ Ki MAO-A values and their toxicity to PC12 LDH release (r = -0.84) or PC12 protein loss (r = 0.79). Although beta C+s appear to be less specific toxins than MPP+, their levels in human substantia nigra are 8-20-fold higher than in cortex, making their role as relatively selective nigral toxins in Parkinson's disease plausible.

The effect of medial frontal cortex lesions on cardiovascular conditioned emotional responses in the rat

The effect of ventral medial frontal cortex (MFC) lesions on heart rate and blood pressure during conditioned emotional responses (CER) was investigated. Male Sprague-Dawley rats were divided into two groups: MFC-lesioned rats (n = 11) sustained bilateral lesions of the infralimbic and ventral prelimbic regions of the MFC via microinjection of the neurotoxin N-methyl-D-aspartate; Controls (n = 13) received sterile saline. Following a 2-week recovery period, all animals were trained; one of two tones served as the conditioned stimulus (CS) and a 2 mA footshock served as the unconditioned stimulus (US). The CS+ tone was consistently paired with the US, while the CS- tone was randomly paired with the US. Heart rate and blood pressure were recorded during CS+ and CS- presentations before and after administration of the following pharmacological agents: atropine, atenolol, and atropine + atenolol. All animals responded to the CS+ with increased BP compared to baseline; the increase was not significantly different between groups. Controls responded to the CS+ with increased HR, while MFC-lesioned animals displayed a bimodal HR response which was not significantly different from baseline, but was significantly different from Controls. Pharmacological blockade of the HR response revealed coactivation of the sympathetic and parasympathetic nervous systems during the CS+, with a significant decrease (52%) in the sympathetic tachycardia component of the CS+ HR response in MFC-lesioned rats as compared to Controls; the parasympathetic bradycardia component was not altered by MFC lesions. In all cases, CS- responses were smaller than the CS+ responses. Pharmacological analysis revealed that the CS- HR response was mediated by the sympathetic component only, which was also significantly reduced in MFC-lesioned animals as compared to Controls. This significant reduction in the sympathetically mediated HR component of both the reinforced CER (CS+) and the unreinforced CER (CS-) following ventral MFC lesions implies that the MFC is necessary for complete sympathetic activation of cardiovascular responses to both severely and mildly stressful stimuli. The role of the MFC in emotion is also discussed.

Differential cytotoxicities of N-methyl-beta-carbolinium analogues of MPP+ in PC12 cells: insights into potential neurotoxicants in Parkinson's disease

N-Methylated beta-carbolinium cations that can form in vivo from environmental or endogenous beta-carbolines are putative neurotoxic factors in Parkinson's disease. The cytotoxicities of 11 N-methylated beta-carbolinium cations and N-methyl-4-phenylpyridinium cation (MPP+), the experimental parkinsonian neurotoxicant which the carbolinium cations structurally resemble, were examined using rat pheochromocytoma (PC12) cells cultured in "low energy" N-5 medium; cell death was estimated by released lactate dehydrogenase activity and viable cell protein. Of the eight N2-monomethylated beta-carbolinium cations utilized, only 2-methyl-harmalinium (harmaline-2-methiodide) was as cytotoxic as MPP+. Also, three N2(beta), N9(indole)-dimethylated beta-carbolinium cations displayed cytotoxic effects, with the simplest, 2,9-dimethylnorharmanium, approaching the effectiveness of MPP+ in PC12 cells cultured in N-5 medium. However, when PC12 cells grown in higher energy Dulbecco's modified Eagle's medium were utilized with selected effective cations, it was observed that the cultures were relatively resistant to MPP+ and 2,9-dimethylnorharmanium, but remained vulnerable to 2-methylharmalinium. The results are interpreted to mean that different cytotoxic mechanisms exist for the two most potent beta-carbolinium cations--namely, a mechanism for the 2,9-dimethyl-beta-carbolinium species that, as with MPP+, is conditional on mitochondrial ATP depletion, but a different (or additional) mechanism for 2-methylharmalinium that is independent of mitochondrial inhibition. The possible accumulation of these cytotoxic cations in Parkinson's disease is discussed in the context of these findings.

Potential bioactivated neurotoxicants, N-methylated beta-carbolinium ions, are present in human brain

Potential bioactivated neurotoxicants, 2-N-methyl-beta-carbolinium and 2,9-N,N'-dimethyl-beta-carbolinium ions, as well as N-methylation activities which form these charged species, were analyzed for the first time in the parietal association cortex and the substantia nigra of human brain using GC/MS and HPLC. The brains were taken during forensic autopsies from corpses without obvious degeneration of substantia nigra. In the cortex, 2-methyl-norharmanium ion (2-MeNH) and 2,9-dimethyl-norharmanium ion (2,9-Me2NH) were detected in almost all samples. 2-Methyl-harmanium ions (2-MeHA) and 2,9-dimethyl-harmanium ions (2,9-Me2HA) were detectable in only two samples. In substantia nigra samples pooled from 3 or 4 brains for analysis, 2-MeNH and 2,9-Me2NH levels were higher than those in the cortex, whereas 2-MeHA and 2,9-Me2HA were below detection limits. Their precursors, norharman (NH) and harman (HA), were also measured using HPLC/fluorescence detection. In both regions, NH and HA were present in almost all samples; levels of NH and HA were also significantly higher in the nigra than in the cortex. Using 9-methyl-NH and 2-MeNH as substrates, in vitro N-methylation of the 2[beta] and 9[indole] nitrogens toward beta-carbolines was measured both in the cortex and in the nigra. 2[beta]-N-Methylation activity was significantly higher than 9[indole]-N-methylation activity in both regions. Recent studies show that beta-carbolinium ions resemble the synthetic parkinsonian toxicant, MPP+, with respect to structure and neurotoxic activity. Such 'bioactivated' carbolinium ions could be endogenous causative factors in Parkinson's disease.

Novel S-adenosylmethionine-dependent indole-N-methylation of beta-carbolines in brain particulate fractions

Guinea pig brain S-adenosylmethionine (SAM)-dependent N-methyltransferase activity toward physiologically relevant beta-carboline (BC) substrates was examined with reverse-phase HPLC and radiochemical detection. Representative BCs, norharman and harmine, were enzymatically methylated on the 2[beta]-nitrogen by [3H]CH3-SAM in undialyzed homogenates to yield 2[beta]-methylated BCs and subsequently on the 9[indole]-nitrogen to generate 2,9-dimethylated BC products. This may be the first account of mammalian indole N-methyl transfer. There was no HPLC evidence for 9-methyl BC or (from carbon methylation) 2,6-dimethyl BC products. Capillary gas chromatography-mass spectrometry analysis confirmed the structures of the 2,9-dimethyl and 2-methyl products of norharman. The 2[beta]- and 9[indole]-N-methylation activities were mainly in the nuclear fractions and were negligible in undialyzed cytosol. This differs from the cytosolic SAM-dependent N-methylations reported with other azaheterocyclics, including 1,2,3,4-tetrahydro-BCs. The involvement of a single enzyme was suggested because the two N-methyl transfers with BC substrate had similar subcellular activity patterns, regional brain distributions, and Km and Vmax values. Sequential N-methylation of various BCs that have been observed in vivo may be a unique route to centrally retained N2,N9-dimethylated beta-carbolinium ions. Because they resemble the synthetic parkinsonian toxicant, N-methyl-4-phenylpyridinium, with respect to structure and neurotoxic activity, such "bioactivated" carbolinium ions could be endogenous causative factors in Parkinson's disease.

Mono-N-methylation of 1,2,3,4-tetrahydro-beta-carbolines in brain cytosol: absence of indole methylation

In an accompanying report we demonstrated enzyme activity in guinea pig brain cell nuclei that catalyzes S-adenosylmethionine (SAM)-dependent N-methylations of heteroaromatic beta-carbolines (BCs) on the 2[beta]-nitrogen and subsequently on the 9[indole]-nitrogen, ultimately yielding N2,N9-dimethylated BCs. Presented here are the results of a parallel study of the N-methylation of 1,2,3,4-tetrahydro-BCs (THBCs), which form endogenously via condensations of tryptophan and its derived indoles with carbonyl compounds or, like their BC oxidation products, are environmental constituents and plant alkaloids. THBCs were enzymatically methylated on the 2[beta]-nitrogen by [3H]-SAM in undialyzed homogenates of rat or guinea pig brain, but [3H]methyl transfer to the 9[indole]-nitrogen was not observed. The structure of the 2[beta]-methyl THBC product was verified with capillary gas chromatography-mass spectrometry. Furthermore, whereas BC N-methylation was largely particulate and displayed micromolar Km values for BC substrate, THBC 2[beta]-N-methylation activity was cytosolic and displayed a relatively high (millimolar) Km for THBC substrate. The N-methylation of THBCs may be due to cytosolic N-methyltransferases that others have studied using different azaheterocyclics. Our overall studies indicate that N2,N9-dimethylated BCs could be unique neurotoxic factors that are bioactivated within brain by sequential N-methylations of BCs. These results suggest the possibility of an additional route to the putative 2,9-dimethylated toxins involving, as a first step, 2[beta]-N-methylation of environmental or endogenously derived THBCs in the brain and perhaps other organs.

Inhibition of mitochondrial succinate oxidation--similarities and differences between N-methylated beta-carbolines and MPP+

N-Methylated beta-carbolinium compounds (N-Me-BCs), including 2-N-methyl and 2,9-N,N-dimethyl analogs, structural analogs of 1-methyl-4-phenylpyridinium (MPP+), may be endogenously bioactivated, MPP(+)-like toxins, capable of inducing parkinsonism. Both MPP+ and selected N-Me-BCs inhibit NADH-linked mitochondrial respiration (Complex I). We now show that both also inhibit succinate-supported (Complex II) respiration, the greatest inhibition (80%) being seen for 2,9-dimethylharmanium. Complex I inhibition occurs at MPP+ concentrations (IC50 = 0.17 mM) about one order of magnitude lower than Complex II inhibition (greater than 1.2 mM). In contrast, Complex I and Complex II inhibition by the N-Me-BCs tested occurred at similar concentrations (I, 0.1 mM; II, 0.25 mM) and concentrations similar to Complex I inhibition by MPP+. 2,9-N,N-Dimethyl-BCs, which are the permanently charged BC analogs of MPP+, show inhibitory characteristics similar to MPP+: slow onset of inhibition, potentiation by TPB, and reversal by DNP. The fact that succinate oxidation cannot bypass the Complex II inhibition by N-Me-BCs could enhance any chronic neurotoxicity of N-Me-BCs.

Indole-N-methylated beta-carbolinium ions as potential brain-bioactivated neurotoxins

N-Methyl-4-phenylpyridinium ion (MPP+), a highly toxic metabolite produced in the brain from a street drug contaminant, is selectively taken up by nigrostriatal dopaminergic neurons and accumulated intraneuronally in mitochondria. There it inhibits respiration, causes neuronal death and, in primates, provokes a parkinsonian condition. It has been suggested that endogenously generated or activated agents resembling MPP+ may contribute to the development of Parkinson's disease. We report here that simple beta-carbolines derived from tryptophan or related open chain indoles, when specifically methyl-substituted on both (2[beta] and 9[indole]) available nitrogens, display mitochondrial inhibitory potencies and neurotoxic effects in vitro (PC12 cultures) and in vivo (striatal microdialysis) which approach or even surpass MPP+. These results take on physiological significance with our finding that brain enzyme activity catalyzes S-adenosylmethionine-dependent methylations of the beta- and indole-nitrogens in beta-carbolines that have been detected in vivo. The unusual 9[indole]-N-methyl transfer, previously unrecognized in animals, apparently requires prior methylation of the 2[beta]-nitrogen. Sequential di-N-methylation of endogenous or xenobiotic beta-carbolines to form unique, neurotoxic 2,9-N,N'-dimethyl-beta-carbolinium ions may serve as a brain bioactivation route in chronic neurodegenerative conditions such as Parkinson's disease.

The effect of medial frontal cortex lesions on respiration, "freezing," and ultrasonic vocalizations during conditioned emotional responses in rats

The effect of ventral medial frontal cortex (MFC) lesions on respiratory rate (RESP), immobility ("freezing"), and ultrasonic vocalizations (USVs) during conditioned emotional responses (CERs) was investigated. Male Sprague-Dawley rats were divided into two groups: MFC-lesioned rats (N = 11) sustained bilateral lesions of the infralimbic region of the MFC via microinjection of the neurotoxin NMDA; controls received sterile saline. Following a 2 week recovery period, all animals were differentially conditioned to two tones; a 2 mA footshock served as the unconditioned stimulus (US). The CS+tone was consistently paired with the US, while the CSr tone was randomly paired with the US. On the following day, RESP, freezing, and USVs were recorded during CER testing (no US were presented). All animals responded during the CS+ with increased RESP compared to baseline; the increase in MFC rats was significantly larger than in controls. All animals also froze at the onset of the CS+. Following the CS+, controls displayed a prolonged period of freezing (265 +/- 37 sec) and decreased RESP compared to baseline, and 92% emitted USVs. In contrast, MFC rats displayed a significantly shorter period of freezing (86 +/- 25 sec) and little or no USV; RESP remained significantly elevated throughout the remainder of the trial. These behaviors indicate a significantly altered stress response following ventral MFC lesions, implying that the MFC may be necessary for complete expression of various behavioral responses to "stressful" stimuli. The role of the MFC in emotion is also discussed.

Heterotopic neocortical transplants. An anatomical and electrophysiological analysis of host projections to occipital cortical grafts placed into sensorimotor cortical lesions made in newborn rats

Plates of presumptive occipital neocortex obtained from fetal rats at 14-16 days gestation were grafted into the cerebral hemisphere of newborn rats. The transplants were placed heterotopically into sensorimotor cortical lesion cavities made immediately prior to grafting. At maturity, some of the transplants were injected with the retrograde fluorescent tracers Fast Blue and Diamidino yellow. In other animals, single-unit activity in the transplants or in normal cortex was recorded using standard electrophysiological techniques. Histologically, host projections to the transplants were demonstrated by the presence of retrogradely labeled neurons in the host primary and secondary somatosensory cortices as well as several thalamic areas including the anteroventral, anteromedial, ventrobasal, mediodorsal and central medial nuclei. Additional labeling was found in the claustrum, lateral hypothalamus, zona incerta and basal forebrain. Electrophysiologically, transplant single-unit activity was evoked in 43/69 (62%) neurons by thalamic stimulation, but only 1/69 transplant neurons responded to electrical stimulation of the contralateral forepaw. In further work, volumetric measurements showed that the transplants did not ameliorate the thalamic atrophy found after neocortical lesions. These results are compared to previous studies involving the homotopic placement of sensorimotor cortical grafts.

Mitochondrial respiratory inhibition by N-methylated beta-carboline derivatives structurally resembling N-methyl-4-phenylpyridine

Mitochondrial accumulation and respiratory inhibition are critical steps in the actions of N-methyl-4-phenylpyridinium ion (MPP+), the toxic metabolite of the parkinsonism-inducing agent, N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine. We examined the respiratory characteristics of 2-methylated beta-carbolines (2-Me beta Cs) and 2-methylated 3,4-dihydro-beta-carbolines (2-MeDH beta Cs), which encompass the MPP+ structure. As indoleamine derivatives, they could have endogenous roles in idiopathic parkinsonism. With rat liver mitochondria, the order for inhibition of NAD(+)-linked O2 consumption (6-min preincubations) was as follows: MPP+ = 2-methylharmine greater than 2-methylharmol = 2-methylharmaline much greater than 2-methylharmalol greater than 2-methylnorharman greater than 6-OH-2-methylharmalan much greater than 2-methylharman. Similar to MPP+, 2-MeDH beta C/2-Me beta C inhibition was potentiated by tetraphenylboron and reversed by dinitrophenol, consistent with the involvement of cationic forms. However, the participation of neutral forms was indicated by the 2-MeDH beta C/2-Me beta C inhibitory time courses, which were unlike MPP+. The neutral forms probably arise via indolic nitrogen deprotonation because the characteristics of a cationic beta-carboline that cannot N-deprotonate, 2,9-dimethylnorharman, mirrored MPP+ rather than 2-Me beta Cs. Succinate-supported respiration was also significantly blocked by 2-MeDH beta Cs/2-Me beta Cs, but results with tetraphenylboron and 2,9-dimethylnorharman indicated that cationic forms were less important than in the inhibition of NAD(+)-linked respiration. We suggest that the relatively potent inhibition by certain 2-MeDH beta Cs/2-Me beta Cs involves neutral forms for passive mitochondrial entry and cationic as well as neutral forms that act at several respiratory sites. Respiratory inhibition could reasonably underlie the reported neurotoxicity of 2-Me beta Cs.

Hippocampal input to a "visceral motor" corticobulbar pathway: an anatomical and electrophysiological study in the rat

The hippocampus has previously been shown to influence cardiovascular function, and this effect appears to be mediated by the connection the hippocampus has with the infralimbic area of the medial frontal cortex (MFC), a region which projects directly to the nucleus of the solitary tract (NTS) in the dorsal medulla. In the present study, anatomical and electrophysiological techniques were utilized to determine the degree of convergence of hippocampal input to the MFC on neurons in the MFC which project to the NTS. Injections of the anterograde and retrograde neuroanatomical tracer wheat-germ agglutinin-horseradish peroxidase (WGA-HRP) into the NTS retrogradely labelled cells in the infralimbic and prelimbic regions of the MFC. Injections of WGA-HRP into the ventral hippocampus anterogradely labelled terminals in the MFC which, at the light microscopic level, closely overlapped the origin of the descending projection from the MFC to the brainstem. Electron microscopic analysis revealed that anterogradely labelled terminals make synaptic contact primarily on dendritic processes in the neuropil adjacent to retrogradely labelled cells. In addition, anterogradely labelled terminals did, in some cases, make synaptic contact on the somas of retrogradely labelled cells. Electrical stimulation of the NTS antidromically activated cells in the infralimbic and prelimbic areas of the MFC. The average latency of antidromic activation was 30 msec, corresponding to a conduction velocity of approximately 0.7 m/s. Electrical stimulation of the ventral hippocampus orthodromically activated cells in the MFC. With an appropriate delay between the hippocampal and NTS stimuli, the orthodromic and antidromic potentials could be made to collide. The results of this study establish a structural as well as functional link between the hippocampus and NTS-projection neurons in the MFC.

Dopamine uptake inhibitory capacities of beta-carboline and 3,4-dihydro-beta-carboline analogs of N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) oxidation products

Potentially endogenous beta-carboline and 3,4-dihydro-beta-carboline alkaloidal compounds were compared, generally as 2-methylated (quaternary) and normethylated pairs, to the neurotoxin, 1-methyl-4-phenyl-dihydropyridinium ion (MPP+), with respect to inhibition of [3H]dopamine uptake into rat striatal synaptosomal preparations. Although less potent than MPP+, several compounds displayed IC50 values for inhibition in the moderate range (12-24 microM). Notably, quaternization generally did not improve inhibitory potency, and the 3,4-dihydro-compounds often were more effective inhibitors than their heteroaromatic analogs. The partially competitive nature of inhibition by one of the more effective pairs, 2-methyl-harmine and harmine, was consistent with uptake of the beta-carbolines by the synaptosomal dopamine uptake system, as was the fact that the accumulation of 2-[14C]methyl-harmine was significantly reduced by low Na+ media and by nomifensine, a potent inhibitor of the dopamine transporter. When viewed with reports that certain 2-methyl-beta-carbolines show MPP+-like toxicity in vitro and in vivo, these studies support the proposal that a mammalian beta-carbolinium compound may be taken up by nigrostriatal neurons and provoke the neuronal degeneration underlying Parkinson's disease.

Striatal dopaminergic toxicity following intranigral injection in rats of 2-methyl-norharman, a beta-carbolinium analog of N-methyl-4-phenylpyridinium ion (MPP+)

Methylated beta-carboline compounds are mammalian indole metabolites that we have proposed to be endogenous neurotoxins due to their structural similarity to MPP+, the active oxidized product of the dopaminergic toxin, N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). Several laboratories have demonstrated that MPP+ administration into the substantia nigra or median forebrain bundle of rats results in extensive depletion of striatal dopamine and its metabolites. We now report that three weeks after intranigral injection of the beta-carboline, 2-methyl-norharman, striatal dopamine, DOPAC, and homovanillic acid (HVA) concentrations ipsilateral to the injection are reduced 41-64% compared to vehicle-injected controls; in individual animals dopamine depletions of 96% were achieved. In addition, at the 2-methyl-norharman injection site in the substantia nigra, large lesions and gliosis were apparent under light microscopic examination. This is the first direct demonstration that a 2-methyl-beta-carbolinium ion is neurotoxic. It lends further validity to the hypothesis that MPP+-like beta-carbolines may be endogenous causative agents in Parkinson's disease.

Organization of cerebral cortico-olivary projections in the rat

Injection of wheatgerm agglutinin-conjugated horseradish peroxidase into electrophysiologically identified portions of the rodent sensorimotor and medial frontal cortex revealed anterograde-labeled projections to the inferior olivary complex. Forelimb motor cortical and supplementary motor cortical regions were found to project predominantly to the principal olive while forelimb sensory cortex fibers distributed mainly within the dorsal accessory olive. Forelimb cortical fibers (both sensory and motor) terminated more rostrally and medially in the medial and dorsal accessory olives than did hindlimb projections. Medial frontal cortex projected to the beta subnucleus, the rostral medial accessory olive (especially the ventral aspect), and to the ventrolateral outgrowth of the dorsal cap. These findings indicate a more extensive origin for cortico-olivary projections than previously described for rats or cats and they demonstrate a rather precise topography for olivary projections from various cortical regions.

Fetal cortical transplants into neonatal rats respond to thalamic and peripheral stimulation in the adult. An electrophysiological study of single-unit activity

Plates of presumptive sensorimotor neocortex obtained from fetal rats at 14-16 days gestation were grafted into the cerebral hemisphere of 0- to 1-day-old newborn rats. The transplants were placed into small lesion cavities in the sensorimotor cortical area made immediately prior to grafting. At 4-5 months of age, single-unit activity in the transplants (TP) or normal cortex (NCX) was recorded under ketamine HCl anesthesia using standard electrophysiological techniques. Over 90% of cells in both the transplants (n = 63) and normal cortex (n = 39) responded to ventral thalamic stimulation. Their average response latencies were similar (11.48 +/- 0.56 ms in TP. 12.77 +/- 1.20 ms in NCX, mean +/- S.E.M., no significant difference), as were their average responses of slightly more than 1 spike per thalamic stimulus (1.24 +/- 0.08 in TP, 1.07 +/- 0.01 in NCX, no significant difference). In addition, 64% (30/47) of transplant cells and 44% (14/32) of normal cells also responded to electrical stimulation of the contralateral forepaw, and here also the latencies were similar (16.11 +/- 0.67 ms in TP, 14.30 +/- 0.78 ms in NCX). The spontaneous neuronal activity observed within the transplants was also comparable to that seen in normal cortex, as measured by comparison of spontaneous interspike interval (ISI) histograms (median ISI of 84.5 for TP and 80.5 for NCX) and comparison of the burst index (% of intervals less than 5 ms, 14.7% for TP and 10.5% for NCX). These results are compared to those found in several recent studies where fetal cortex is grafted into adult hosts.

Cardiovascular and respiratory responses to electrical and chemical stimulation of the hippocampus in anesthetized and awake rats

Electrical (30-60-s trains of 0.25-ms pulses at 25 Hz, currents 10-150 microA) and chemical (microinjections of 0.1-0.5 microliters of a 1.0 M glutamate solution) stimulation of the hippocampal formation in the anesthetized and the awake rat evokes marked decreases in heart rate, blood pressure and slower, deeper, more regular respirations. Artificial ventilation (2 ml/breath; 100 breaths/min) has no effect on the cardiovascular responses, indicating that these effects are not secondary to respiratory changes. Administration of methyl atropine (0.4 mg/kg) eliminates the bradycardia response and attenuates or obliterates the blood pressure response but does not alter the respiratory response. This suggests that the cardiovascular responses are mediated partially by the vagus nerve and partially by sympathetic influences. Ablation of the medial frontal cortex, a visceral motor region which projects directly to the nucleus of the solitary tract and which receives a heavy direct projection from the CA1 and subicular cell fields of the ventral hippocampus, markedly attenuates or eliminates the cardiovascular and respiratory responses to stimulation of the ventral but not the dorsal hippocampus. The possibility that the medial frontal cortex may be a relay by which the hippocampus influences cardiovascular responses, including those observed during stress, is discussed.

The rat medial frontal cortex projects directly to autonomic regions of the brainstem

Pressure injections of the anterograde tracer wheat germ agglutinin conjugated with horseradish peroxidase (WGA-HRP) into the infralimbic (IL) and prelimbic (PL) regions of the medial frontal cortex of the rat produced anterograde, terminal-like labeling in the lateral dorsal tegmental nucleus (LDTg) of the dorsal pons and the ventral, ventrolateral, intermediate, medial and commissural subnuclei of the nucleus of the solitary nucleus (NTS) in the dorsomedial medulla. Injections involving IL resulted in heavier labeling than the labeling seen after PL injections only. The LDTg has been described as the pontine micturition center, involved in the micturition reflex. The possible role that the projections to the LDTg may play in fluid homeostasis is discussed. The labeled NTS subnuclei receive visceral afferent inputs from the heart, baroreceptors, lungs and gut. The direct cortical projections to these areas may be involved in mediating the bradycardia, depressor responses, and changes in respiratory and gastric activity which are seen after electrical stimulation of the rat medial frontal cortex. The present data support the concept that the infralimbic and prelimbic cortices function as a "visceral motor" cortex, involved in control of a variety of autonomic functions.

Remodeling of dorsal column nuclear efferents to the basilar pontine gray after cortical ablations in newborn rats

In view of previous reports documenting corticopontine remodeling in response to neonatal cerebral cortical lesions, we examined possible alterations of ascending pontine afferents from the dorsal column nuclei after the same types of neonatal lesion. Two anterograde tracing techniques, autoradiography and the Fink-Heimer silver degeneration method, were combined to facilitate a topographic analysis. The distribution patterns of cuneo- and gracilopontine terminations appeared expanded in response to neonatal sensorimotor cortical lesions, as compared to non-lesioned animals.

A study of forelimb movements evoked by intracortical microstimulation after hemicerebellectomy in newborn, young and adult rats

Microstimulation of the cerebral motor cortex in normal adult rats evokes low-threshold contralateral and high-threshold ipsilateral forelimb movements. The present study examined the effects of hemicerebellar ablation at different postnatal ages on the current threshold values needed to evoke forelimb movements by intracortical stimulation. Animals that received hemicerebellar lesions at various ages were electrophysiologically tested 4-6 months postoperatively. In all groups, including non-lesion control animals, forelimb movements contralateral to the stimulating electrode were evoked at threshold values of 7-11 microA. Ipsilateral forelimb movements for control animals as well as those receiving cerebellar lesions at 45 or 120 days of age showed significantly higher mean threshold current values, ranging from 38 to 45 microA. In contrast, the mean threshold current values for ipsilateral forelimb movements in adult animals sustaining hemicerebellar lesions at 2, 10 or 21 days of age were significantly lowered, ranging from 16 to 22 microA. Secondary lesions of spared cerebellar tissue or callosal fibers in adult animals that had sustained hemicerebellectomy at two days of age had no effect on the current intensities needed to evoke forelimb responses. In comparison, lesions of the cerebral cortex contralateral to the stimulated cortex increased the threshold for ipsilateral movements and medullary pyramidal lesions ipsilateral to the stimulated cortex both reduced the number of responses and increased the threshold current intensities needed to evoke them. These data indicate that hemicerebellectomy within 3 weeks of age can induce electrophysiological alterations in the responses mediated by the corticospinal tract. These results support previous suggestions of the cerebral cortical involvement in compensation for neonatal cerebellar lesions.

A chronic unit study of the sensory properties of neurons in the forelimb areas of rat sensorimotor cortex

The sensory properties of neurons in the several forelimb areas of rat sensorimotor cortex were examined using the technique of extracellular single-unit recording in the awake, head-restrained rat. Cells with peripheral receptive fields were tested for the amount and modality of sensory input during joint manipulation and brushing and tapping of limbs, face and trunk. Input-output correlations were made on the basis of the results of receptive field mapping and intracortical microstimulation in the same electrode penetration. It was found that neurons (n = 117) in the rostral forelimb area receive virtually no sensory input while 30% of neurons (n = 114) in the caudal forelimb primary motor area do receive such input. The inputs to caudal forelimb motor area neurons were primarily (83%) from single joints; along perpendicular electrode penetrations the same joint that activated a cortical cell also moved when microstimulation was delivered along the same electrode penetration. In the granular and dysgranular zones of somatic sensory forelimb cortex, 70% of neurons (n = 82) were responsive to peripheral sensory inputs, with most of the cells in the granular cortex responsive to cutaneous inputs while cells in the dysgranular cortex were more responsive to deep inputs. The lack of sensory inputs to the rostral forelimb motor area is consistent with the proposal that this region may be a part of the supplementary motor area of the rat.

Topography of corticopontine remodelling after cortical lesions in newborn rats

Autoradiographic and axonal degeneration staining techniques were combined in individual animals to study the distribution of corticopontine fibers. In normal animals, forelimb and hindlimb motor cortical projections terminated somatotopically within the ipsilateral pontine nuclei. Sparse crossed projections also displayed a somatotopic pattern. After unilateral sensorimotor cortical lesions in newborn rats, an increase in the crossed corticopontine fibers arising from the opposite unablated motor cortex was observed at maturity. These fibers distributed in a topographic pattern similar to the normal ipsilateral corticopontine pattern; forelimb motor cortical projections terminated rostral to hindlimb motor cortical fibers. The specific distribution of the anomalous fibers suggests that they constitute a functional pathway.

The topographical organization of neurons in the rat medial frontal, insular and olfactory cortex projecting to the solitary nucleus, olfactory bulb, periaqueductal gray and superior colliculus

In 19 rats two different retrograde tracers (Fast Blue, Diamidino Yellow, Rhodamine-labeled latex microspheres, or wheat germ agglutinin conjugated with HRP) were injected into the solitary nucleus (NTS) and either the olfactory bulb (OB), periaqueductal gray (PAG) or superior colliculus (SC). The pattern of retrogradely labeled neurons in the medial frontal, insular and olfactory cortices was examined to determine the topographical organization of the cell populations projecting to these subcortical targets and the extent to which they overlapped. In the medial frontal cortex (MFC) SC projections originated most dorsally, while NTS and OB projections originated most ventrally and exhibited slight overlap. PAG projections originated from virtually the entire MFC and overlapped with cells projecting to the OB, NTS and SC. These results are consistent with the role of dorsal MFC as the rat's frontal eye field and the ventral MFC as a visceral motor area. Laterally, in the insular cortex there was virtually complete overlap between cells projecting to the NTS and PAG. The extensive overlap of PAG projections with NTS projections medially and laterally and with SC projections medially suggests the PAG is involved in a variety of brain visceral and somatic functions. In the piriform cortex there was overlap between cells projecting to the OB and cells projecting to the SC; the cells projecting to the SC were located in the endopiriform nucleus, and may provide a substrate for orienting responses to odors.

The organization of the rat motor cortex: a microstimulation mapping study

In conclusion, the rat primary motor cortex appears to be organized into irregularly shaped patches of cortex devoted to particular movements. The location of major subdivisions such as the forelimb or hindlimb areas is somatotopic and is consistent from animal to animal, but the internal organization of the pattern of movements represented within major subdivisions varies significantly between animals. The motor cortex includes both agranular primary motor cortex (AgL) and, in addition, a significant amount of the bordering granular somatic sensory cortex (Gr(SI)), as well as the rostral portion of the taste sensory insular or claustrocortex (Cl). The rat frontal cortex also contains a second, rostral motor representation of the forelimb, trunk and hindlimb, which is somatotopically organized and may be the rat's supplementary motor area. Both of these motor representations give rise to direct corticospinal projections, some of which may make monosynaptic connections with cervical enlargement motoneurons. Medial to the primary motor cortex, in cytoarchitectonic field AgM, is what appears to be part of the rat's frontal eye fields, a region which also includes the vibrissae motor representation. The somatic motor cortical output organization pattern in the rat is remarkably similar to that seen in the primate, whose primary, supplementary and frontal eye field cortical motor regions have been extensively studied.

The medial frontal cortex and gastric motility: microstimulation results and their possible significance for the overall pattern of organization of rat frontal and parietal cortex

Bilateral intracortical microstimulation (60-90 strains of 0.5 ms pulses at 10 Hz, currents below 50 microA) of medial frontal infralimbic and prelimbic cortical areas in ketamine-anesthetized rats produces clear and consistent decreases in ongoing gastric motility. The majority of responses consists of reductions in gastric tone, reductions in the amplitude of gastric contractions, or combined reductions in tone and amplitude. Bilateral section of the vagus nerves eliminates most of the responses, suggesting that the responses are mediated by this nerve. The effective cortical stimulation zone (the 'visceral motor' cortex) largely overlaps the source of the recently described direct projection from medial frontal cortex to the nucleus of the solitary tract; this pathway may be involved in producing the effect. Connections of this cortex with the limbic system suggest it may be involved in producing physiological responses to stress. The topographical, medial to lateral sequence of cortical functional areas revealed by these and other experiments (visceral motor, frontal eye fields, somatic motor, somatic sensory, visceral sensory) is discussed, as well as the possible implications of this pattern to the question of cortical evolutionary development.

A comparative topographical analysis of dorsal column nuclear and cerebral cortical projections to the basilar pontine gray in rats

The somatotopic distribution of dorsal column nuclear projections within the basilar pontine gray was examined in relation to the massive corticopontine projection system that emanates most heavily from motor and somatosensory cortex. The distribution patterns of these two systems were compared by combining autoradiographic and degeneration axonal tracing methods within individual animals. Stereotaxic injections of tritiated leucine (50 microCi/microliter) and lesions by aspiration were made in animals under ketamine hydrochloride anesthesia. The forelimb cortical injections (0.1-0.3 microliter) were centered in either sensory or motor cortical regions as determined by intracortical microstimulation and multiunit recording techniques. Because sensory and motor hindlimb cortical areas overlap extensively in the rat, hindlimb cortical injections (0.1-0.3 microliter) were limited to a single hindlimb sensorimotor cortical region. The corresponding contralateral dorsal column nucleus, cuneatus or gracilis, was then aspirated. A somatotopic distribution of fore- and hindlimb corticopontine fibers were found in discrete regions of the ipsilateral pontine gray. Hindlimb sensorimotor corticopontine fibers distributed caudal to forelimb projections. Similarly, pontine afferents from the dorsal column nuclei terminated somatotopically in the caudal half of the contralateral pontine gray in that gracilopontine fibers distributed caudal to cuneopontine fibers. Within individual animals, partially overlapping terminations were seen from nucleus cuneatus and the forelimb sensory cortical area as well as from nucleus gracilis and the hindlimb sensorimotor cortical area. No overlap existed in the pontine terminations from nucleus cuneatus and the forelimb motor cortical area.

Electrophysiological analysis of motor cortical plasticity after cortical lesions in newborn rats

Intracortical microstimulation of the motor cortex in normal adult rats evoked low threshold contralateral forelimb movements and high threshold ipsilateral movements. Ablation of the opposite sensorimotor cortex in adult animals did not alter these thresholds. However, stimulation of the unablated hemisphere in adult rats that sustained unilateral sensorimotor cortical lesions as neonates elicited low threshold ipsilateral forelimb movements that were similar to contralateral movements. These low threshold ipsilateral movements may be mediated via aberrant corticofugal pathways which are known to develop following neonatal cortical lesions.

Beta-carboline analogues of N-methyl-4-phenyl-1,2,5,6-tetrahydropyridine (MPTP): endogenous factors underlying idiopathic parkinsonism?

A remarkable structural similarity exists between the parkinsonian neurotoxin, N-methyl-4-phenyl-1,2,5,6-tetrahydropyridine (MPTP), and 2-[N]-methyl-tetrahydro-beta-carboline (2M-THBC), a tryptamine-derived alkaloid which can be biosynthesized in brain. To explore whether the beta-carboline also has neurotoxic effects, owl monkeys were treated daily with MPTP or 2M-THBC. Acute behavioral similarities were seen, but 2M-THBC did not induce persistent parkinsonism, nor did it cause apparent loss of nigral cells. However, 2M-THBC resembled MPTP in reducing 3,4-dihydroxyphenylacetic acid levels in caudate and in altering levels of serotonin and 5-hydroxyindoleacetic acid in substantia nigra. These limited similarities should be considered in the light of relationships between neurotoxicity, MPTP versus 2M-THBC oxidation, and the chronicity of human Parkinson's disease. We suggest that N-methylated beta-carboline species, possibly accumulating during stress and aging, could well be causative factors in parkinsonism.

Cytoarchitecture of the dorsal thalamus of the rat

Although several neuroanatomical studies have previously described various subdivisions of the rat thalamus, no comprehensive description of the entire thalamus accompanied by photomicrographs has been available. To provide such a description, the cytoarchitecture of the normal rat thalamus was studied in the coronal plane using a series of celloidin embedded, Nissl-stained 33 micrometers sections spaced 400 micrometers apart. Using the criteria of cell packing density, relative cell size, and the presence or absence of fibers, the thalamus can be subdivided into a ventral nuclear complex which includes the ventrolateral, ventromedial, and ventrobasal nuclei; the intralaminar nuclei which include central medial, central lateral, paracentral and parafascicular nuclei; the midline nuclei which include the medioventral, paratenial, rhomboid, paraventricular, and submedial nuclei; the anterior nuclear group which include the anterodorsal, anteroventral, and anteromedial nuclei; the mediodorsal nucleus; the lateral nuclear complex including both lateral posterior and lateral dorsal; the posterior nuclear complex; the reticular nucleus; and the diencephalic-mesencephalic junction. The terminology used is based on previous studies.

Rat medial frontal cortex: a visceral motor region with a direct projection to the solitary nucleus

Pressure injections of the neuroanatomical tracer wheat germ agglutinin conjugated with HRP (WGA-HRP) were made into either the dorsal medulla or the medial frontal cortex of the rat. Following the brainstem injections, retrogradely labeled neurons were found in the paraventricular nucleus of the hypothalamus, central nucleus of the amygdala, insular cortex and in the infralimbic, prelimbic and anterior cingulate regions of the medial frontal cortex. The infralimbic labeling consisted of a dense band of neurons and was bilateral. Cells in the prelimbic and anterior cingulate regions were less densely packed. Following injections of WGA-HRP into the medial frontal cortex anterograde labeling in the dorsal medulla was confined to the solitary nucleus (NTS). Label was found throughout the rostro-caudal extent of the NTS and was bilateral although heavier contralaterally. The projection from the medial frontal cortex to the solitary nucleus suggests that this area of cortex may function primarily as a visceral 'motor' cortical region that may play a role in regulating autonomic activities.

Substantia nigra single unit activity during penicillin-induced focal cortical epileptiform discharge in the rat

In urethane anesthetized rats single unit activity was recorded in the substantia nigra (SN) during focal cortical epileptiform discharges induced by topical application of penicillin to the cortical surface. Eighty percent of SN units responded during the cortical interictal spike discharge, 50% with an initial burst or increase in firing rate and 30% with an initial inhibition or decrease in firing rate. In view of the SN's widespread projections to thalamus and brainstem, these results suggest the SN may be a prominent element of the pathway involved in the spread and generalization of cortical epileptiform activity.

Propagation of focal cortical epileptiform discharge to the entopeduncular nucleus: effect of caudate lesions

Single-unit recordings were made in the entopeduncular nucleus of cats which had previously undergone ipsilateral caudate lesions. During penicillin-induced epileptiform discharge from the pericruciate cortex, the percentage of responsive entopeduncular neurons in animals with a lesion was less than 20%. In a previous study in intact cats and in control experiments in the present study the percentage of responsive entopeduncular cells was more than 75%. These results indicate that propagation of epileptic discharge through the basal ganglia depends on intact pathways from the cortex to the caudate and from the caudate to the entopeduncular nucleus.

A second forelimb motor area exists in rat frontal cortex

Intracortical microstimulation of 40--50 points in the frontal cortex of ketamine-anesthetized rats using perpendicular penetrations has demonstrated a second forelimb area located rostrally near the frontal pole as well as confirming the existence of a more caudally located forelimb area just anterior to bregma. Cortex where neck and/or vibrissae movements were evoked separated the two forelimb areas. The rostral and caudal forelimb areas defined by microstimulation correspond with patches of corticospinal neurons labeled with HRP following injections of this tracer into the cervical enlargement. Digit movements were commonly evoked from the rostral forelimb area but were rarely elicited from the caudal forelimb area. The question of whether the rostral forelimb region is part of primary or supplementary motor cortex is not yet able to be answered.

A simple method for glass insulating tungsten microelectrodes

A method for insulating tungsten wires with glass by collapsing a glass capillary tube around the wire is described. A common laboratory electrode puller can be used. A new method for removing the glass from the tip using hydrofluoric acid is also described.

Neuronal activity in chronic ferric chloride epileptic foci in cats and monkey

The firing patterns of neurons surrounding sites of ferric chloride (FeCl3) injection were studied in 6 cats and 1 Macaca mulatta monkey. Although a few neurons fired in poorly structured bursts similar to what has been described for some neurons in alumina foci in monkeys, no well-formed bursts were recorded. In addition, EEG spikes were not recorded chronically in two cats, nor were EEG spikes recorded during corticography. We could not confirm the reliability of this preparation in cats as a model of chronic epilepsy.

Operant control of precentral neurons: control of modal interspike intervals

The objects of these experiments were: (a) to determine modal interspike intervals (ISIs) of precentral cells involved in repetitious, gross motor movements; (b) to compare those modal ISIs to the modal ISIs of similar neurons under operant control; and (c) to determine if monkeys could change the modal ISIs of operantly controlled precentral neurons. Data were obtained from 4 monkeys conditioned to produce tonic firing of precentral neurons and one monkey trained to produce repetitious movements of the neck and contralateral limbs. Results are: (a) the modal ISIs from operantly controlled precentral units do not differ significantly from precentral neurons involved in repetitive gross motor movements; and (b) while under operant control, the monkeys cannot modify significantly the modal ISI of the majority of precentral neurons.