Fetal Ammon's Horn Transplants Improve Acquisition of a Radial Arm Maze and a Low-Rate Operant Schedule in Trimethyltin-Treated Rats

Freeman, James N., Baisden, Ronald H., Woodruff, Michael L.

01 January 1995

The results of previous studies indicated that block grafts of fetal hippocampal tissue made into cavities produced by aspiration lesions of the hippocampus in rats given the neurotoxin trimethyltin (TMT) significantly worsened the TMT-induced deficit in water maze acquisition. The purpose of the present study was to test the hypothesis that a procedure for transplantation that produced less destruction to the host brain and resulted in transplants with less mass might produce recovery in a spatial learning task in TMT-exposed rats. Acquisition of an externally cued (spatial) version of the radial arm maze (RAM), an internally cued version of the RAM, and of a differential reinforcement of low rate (DRL) operant schedule was assessed in normal rats, rats given TMT, and rats given TMT and stereotaxic implants of either fetal Ammon's horn or entorhinal cortex. The rats receiving Ammon's horn transplants made significantly fewer reentries into the baited arms in both maze configurations and fewer reentries into the nonbaited arms in the spatial RAM than rats in the TMT-only and TMT/entorhinal cortex transplant groups. The rats receiving transplants of Ammon's horn made significantly fewer responses and received more reinforcements during training on the DRL-20 schedule than rats receiving just TMT or rats receiving TMT and transplants of fetal entorhinal cortex. These results support the proposal that transplantation procedures that cause less damage to the host brain and result in transplants that do not occupy a large extent of the ventricular space increase the probability of behavioral recovery.

behavior

fetal transplant

hippocampus

trimethyltin

Biomedical Sciences

Effects of Trimethyltin on Acquisition and Reversal of a Light-Dark Discrimination by Rats

Woodruff, Michael L., Baisden, Ronald H., Cannon, Richard L., Kalbfleisch, John, Freeman, James N.

01 January 1994

The behavioral deficits produced by trimethyltin (TMT) are usually attributed to the hippocampal damage caused by this toxicant. The purpose of this experiment was to determine the effects of TMT administration on acquisition and reversal of a discrete trial light-dark discrimination. Acquisition of this task is impaired by hippocampal lesions but the effects of TMT on it are not known. Forty-five days after some of the rats were given one of three doses of TMT, adult, male Long-Evans rats were given 100 trials per day for 20 days to acquire a discrete trial lever press discrimination with lit cue lights located above the correct lever. At the end of this time the contingencies were reversed and the rats were given 30 more days of training. No significant group differences occurred during the first 20 days. A significant group effect was found for the 30 days of reversal training. The rats given the highest dose of TMT (6 mg/kg) obtained significantly more reinforcements during reversal training than the other groups. Because surgical hippocampal lesions generally impair both acquisition and reversal of visual discriminations, these data were unexpected and suggest that other factors than hippocampal damage enter into the behavioral effects of TMT.

hippocampus

rat

trimethyltin

visual discrimination learning

Biomedical Sciences

Trimethyltin Increases Choline Acetyltransferase in Rat Hippocampus

Cannon, Richard L., Hoover, Donald B., Woodruff, Michael L.

01 January 1991

The environmental neurotoxin trimethyltin (TMT) destroys parts of the hippocampal formation as well as the entorhinal cortex but leaves the septal cholinergic projection to the hippocampus and dentate gyrus intact. In this study we measured choline acetyltransferase (ChAT) activity in micropunch samples of the dentate gyrus, the CA1 region of Ammon's horn, and the caudate-putamen as a measure of density of cholinergic innervation in control rats and rats exposed to 7 mg/kg TMT by means of gastric intubation. Three months after the rats were exposed to a single dose of TMT both the dentate gyrus and CA1 demonstrated significantly higher ChAT activity in TMT-exposed rats than in control rats. No differences were found between groups for the caudate-putamen samples. These results support the hypothesis that exposure to TMT causes reactive synaptogenesis in the cholinergic septohippocampal system.

choline acetyltransferase

hippocampus

rat

reactive synaptogenesis

trimethyltin

Biomedical Sciences

The Time-Course of Trimethyltin-Induced Fiber and Terminal Degeneration in Hippocampus

Whittington, Dennis L., Woodruff, Michael L., Baisden, Ronald H.

01 January 1989

Trimethyltin (TMT) produces prominent neuron death in the hippocampus. The time-course of TMT-induced damage was studied using reduced-silver procedures for impregnation of degenerating axons and their terminals, and a modified Timm's stain procedure for visualization of hippocampal transitional metals. Standard cell body stains were also used. Fifty-four, adult, Long-Evans rats were gavaged with 6.0 mg TMT/kg b.wt. and 10 rats were gavaged with distilled water as controls. Five TMT-gavaged rats and one saline-gavaged rat were sacrificed on either postgavage day 1, 3, 6, 9, 14, 19, 30, 45, 70 or 99. Histological examination revealed a band of degenerating terminals in the stratum lucidum, below the hippocampal subfields CA3a,b pyramidal cells, by postgavage day 3. This preceded dentate gyrus granule cell loss supplying the mossy fiber input to the stratum lucidum by several days. Hippocampal pyramidal cell necrosis continued through the examination period while dentate granule cell loss subsided between postgavage days 9 and 14. Fiber and terminal degeneration was more extensive in the dorsal hippocampus than in the ventral hippocampus, although Timm's-stained sections revealed "bleaching" of stainable metal in the mossy fiber pathway of the ventral hippocampus. These data suggest that loss of ventral dentate granule cells might reduce TMT-induced necrosis of pyramidal cells in the ventral (temporal) part of the Ammon's horn, possibly by preventing the spread of seizure activity in this region of the hippocampus. Additionally, although previous studies have reported the toxic effects of TMT to last approximately 60 days, the results of the present study indicate that TMT-induced degeneration continues for more than 3 months. Reduced-silver stains, such as the Fink-Heimer procedure, appear to be more sensitive indicators of enduring neuropathology than more traditional cell stains.

fink-heimer technique

hippocampus

rat

time-course

trimethyltin

Biomedical Sciences

The Effect of Time Following Exposure to Trimethyltin (TMT) on Cholinergic Muscarinic Receptor Binding in Rat Hippocampus

Cannon, Richard L., Hoover, Donald B., Baisden, Ronald H., Woodruff, Michael L.

01 September 1994

Adult male Long-Evans rats were given 6 mg/kg trimethyltin (TMT). Rats were killed 1, 3, 7, 14, 21, 35 or 60 d later. An untreated control group was included. Brain sections were processed using film autoradiography to visualize in the hippocampus either total muscarinic receptor binding ([3H]quinuclidiny] benzilate: [3H]QNB), or M1 receptors ([3H]pirenzepine; [3H]PZ), or M2 receptors ([3H]oxotremorine-M; [3H]OXO-M). A reduction in [3H]QNB binding was found in CA1 and CA3c 7 d after TMT, but not in CA3a,b, or the dentate gyrus. [3H]PZ binding was decreased throughout Ammon's horn by 14 d after treatment. [3H]OXO-M binding decreased 1 d after exposure in CA1 and in all subfields of Ammon's horn by d 3. Neither [3H]PZ or [3H]OXO-M binding decreased in the dentate gyrus of TMT-treated rat at any time point. The temporal patterns of receptor loss may be explicable by reference to timing of fiber and cell body degeneration reported in previous studies and the regional differences may account for discrepancies between reports of either substantial decreases or no loss in hippocampal muscarinic receptors after TMT exposure.

autoradiography

cholinergic

hippocampus

muscarinic receptors

trimethyltin

Biomedical Sciences

Anatomical and Behavioral Sequelae of Fetal Brain Transplants in Rats With Trimethyltin-Induced Neurodegeneration

Woodruff, M. L., Baisden, R. H., Nonneman, A. J.

17 October 1991

The effect of transplants of either fetal hippocampal or dorsal ventricular ridge (DVR) tissue into the brains of adult male rats exposed to TMT was determined for two behavioral tasks. Administration of TMT produced deficits in acquisition and performance of an operant differential reinforcement of low response rates (DRL) schedule and learning in the Morris water maze. The fetal transplants developed well within the TMT damaged brains of the adult rats and numerous axons could be shown to cross the host transplant interface. The transplants significantly recuced the DRL deficit produced by exposure to TMT. However, the TMT-induced deficit in water maze acquisition was made significantly worse by the hippocampal transplants. The improvement in DRL performance is attributed to the effect on the host brain of an unidentified trophic substance produced by the transplants. However, this positive effect may not protect the brain sufficiently to produce recovery in tasks demanding more complex neural computations than are required to withhold lever-press responses. The transplant-induced deficit observed in some aspects of water maze acquisition and performance may be attributable to either a tumor-like deleterious effect of the mass of the transplant or to abnormal neuronal activity transmitted from the transplant to the host brain. The results of the present study, and those from other similar studies, suggest that transplants of fetal tissue may be useful in producing changes in the brain of an animal exposed to an environmental neurotoxin, but that research should be focused upon development of transplant methodology that will minimize adverse effects of the grafts.

hippocampus

neural transplantation

rat

recovery of function

trimethyltin

Biomedical Sciences

Exposure to Trimethyltin Significantly Enhances Acetylcholinesterase Staining in the Rat Dentate Gyrus

Woodruff, Michael L., Baisden, Ronald H.

01 January 1990

Trimethyltin (TMT) is known to produce substantial damage to the hippocampal formation. It also destroys neurons within the entorhinal cortex, thereby causing degeneration of perforant path afferents that terminate in the outer molecular layer (OML) of the dentate gyrus. Surgical destruction of the entorhinal cortex also causes the perforant path to degenerate. This leads to reactive synpatogenesis (axonal sprouting) of septal afferents to the dentate gyrus. The purpose of the present study was to determine whether administration of 6 mg/kg of TMT by gavage to rats would cause axonal sprouting within the septodentate projection. A histochemical stain for acetycholinesterase (AChE) was used. Compared to control subjects rats given TMT exhibited significantly denser AChE staining in the dentate OML. This is putative indication of reactive synaptogenesis within the cholinergic projection to this layer of the dentate and is somewhat surprising because other neurotoxins, such as lead and ethanol, that affect neurons within the hippocampal formation reduce the capacity for reactive synaptogenesis in response to lesions of the entorhinal cortex.

acetylcholinesterase

axonal sprouting

cholinergic

dentate gyrus

entorhinal cortex

hippocampus

neurotoxin

rat

reactive synaptogenesis

trimethyltin

Biomedical Sciences

Effects of Trimethyltin (TMT) on Choline Acetyltransferase Activity in the Rat Hippocampus - Influence of Dose and Time Following Exposure

Cannon, Richard L., Hoover, Donald B., Baisden, Ronald H., Woodruff, Michael L.

01 September 1994

Trimethyltin (TMT) destroys specific subfields of the hippocampus in the rat. TMT also increases choline acetyltransferase (ChAT) activity in CA1 of Ammon's horn and the outer molecular layer of the dentate gyrus. This observation suggests that axonal sprouting occurs in the cholinergic septohippocampal system in response to TMT. However, neither does-response nor time course data are available for the effects of TMT on this enzyme. The effects of three dose levels of TMT on ChAT activity in CA1 and the dentate gyrus were determined in Experiment 1 and ChAT activity in these two areas was measured at six time points following exposure to TMT in Experiment 2. Only the highest dose of TMT (6 mg/kg) significantly increased ChAT activity. ChAT activity in the dentate gyrus increased significantly by 3 d after administration and continued to increase until 21 d after exposure. A significant increase was not observed in CA1 until 7 d after exposure to TMT. Asymptotic levels were still reached at d 21. These results indicate a steep dose-response curve for TMT-induced changes in ChAT activity in the hippocampal formation and that this marker of cholinergic activity is more sensitive to perturbation by TMT in the dentate gyrus than Ammon's horn.

acetylcholine

axonal sprouting

choline acetyltransferase

cholinergic

Hippocampus

rat

trimethyltin

Biomedical Sciences