Abnormal turning behaviour, GABAergic inhibition and the degeneration of astrocytes in ovine Tribulus terrestris motor neuron disease

Objective To observe the clinical signs of sheep affected by Tribulus terrestris motor neuron disease, to ascertain their response to striatal dopamine reducing drugs, and to examine their brains and spinal cords for microscopic changes. Procedures Twenty‐eight sheep displaying well developed clinical signs of the disorder were observed. Twenty‐two of these and 22 normal sheep were then randomly allocated to three groups and treated with diazepam, chlorpromazine, or xylazine. The time that it took an animal to return to a standing position following drug administration was recorded. The brain and complete spinal cord were removed from each of the other six affected sheep and fixed in formalin. Brains were sectioned throughout at 5 mm intervals and spinal cords at 10 mm intervals. All tissues were paraffin embedded and examined by light microscopy. A few samples were examined by electron microscopy. Results Clinical signs included postural asymmetry with a right:left body‐side dominance within the group of 50:50, unequal flaccid paresis in the pelvic limbs, extensor muscle atrophy and adduction of the weaker pelvic limb, and concurrent abduction of the stronger. Forward motion followed either a fixed left or right hand curved trajectory, the sheep no longer being able to choose which. Twelve animals intermittently displayed rotational behaviour that involved loss of postural balance without locomotor activation. The administration of diazepam, chlorpromazine, or xylazine caused limb paresis and sedation, with affected sheep being slower than normal sheep by factors of 8, 3 and 2 respectively, to return to a standing position. There were scattered areas of mild Wallerian degeneration throughout the spinal cord, and in both the brain and the cord there were small numbers of degenerate astrocytes containing novel cytoplasmic pigment granules. Conclusions Affected sheep had a dysfunction in the control of directional change and this provides a new insight into the normal mechanism for ‘turning’ in quadrupeds. Directional change requires a functional asymmetry or lateralisation within the upper motor neuron to accommodate a difference in the rate of forward progression of each body side and, simultaneously, a lateral shift of the centre of gravity. The sensitivity of affected sheep to diazepam is consistent with a pre‐existing elevation in GABAergic neuronal inhibition, probably as a result of a reduction in glutamatergic neuronal excitation. The cytoplasmic pigment found in degenerate astrocytes was novel and its presence in the brain nuclei known to contribute to turning behaviour could have aetiological significance. The motor output of the basal ganglia in Tribulus neurotoxicity appeared to be excessively inhibitory to the pelvic limb extensor muscles and was asymmetric, causing fixation of the turning posture but not locomotor activation. An intoxication of specific purine sensitive, glutamate releasing astrocytes, located in nuclei controlling turning, was suspected.