The role of pattern vision in the increase of visual cortex acetylcholinesterase after first exposure of dark reared rats to light

Influence of visual deprivation on the visual and oculomotor system: acetylcholinesterase activity in oculomotor neurons

The effects of visual deprivation (dark-rearing) on neurons in both the visual and oculomotor systems of black mice were studied using morphologic and histochemical techniques. In the neurons of the dorsal nucleus of the lateral geniculate body, the cytoplasm of dark-reared mice was less developed and the cytoplasm/nucleus ratio was significantly smaller in the dark-reared mice than in the controls. In contrast, large motoneurons in the oculomotor nucleus did not show any ultrastructural changes and the cytoplasm/nucleus ratio was normal. However, in large motoneurons of dark-reared mice, acetylcholinesterase (AChE)-positive areas were scattered in the cytoplasm, and the ratio of the AChE-positive areas to the cytoplasm area was significantly smaller than that in the controls.

Synaptic competition in developmental binocular plasticity

A mathematical model of the possible physiological and biochemical mechanisms responsible for the changes occurring during binocular development is proposed. The model is based on the mechanisms postulated for the occurrence of well known plastic processes, such as post-tetanic potentiation, sensitization and heterosynaptic inhibition. Because all these processes are of presynaptic nature, we have postulated that the plastic processes occurring during development are of the same nature. The factors we have considered in our model are: the transmitter pool size, the mobilization or synthesis of the transmitter, the transmitter release by the physiological stimulus, the neuroendocrine and genetic activity. With this model we have simulated the following phenomena during ocular development: (1) normal binocular development; (2) monocular deprivation, including the effects of reversing the occluded eye; (3) binocular deprivation and recovery; and (4) effects of alternating deprivation on mature binocularity. The model also allows us to explain in a natural way the possible changes occurring during denervation or disuse.

Effects of early monocular deprivation on choline acetyltransferase and glutamic acid decarboxylase in pigeon visual Wulst

Choline acetyltransferase (ChAT) and glutamic acid decarboxylase (GAD) activities were measured in various visual structures of the pigeon brain after long-term monocular deprivation followed by short-term binocular presence or absence of light stimulation. The short-term phase (45 min) was coupled with a 2-deoxyglucose experiment in order to select the adequate brain samples. After mononuclear deprivation during the first 6-11 months, ChAT activity was higher by 40-60% in the dorsolateral visual Wulst contralateral to the deprived eye, as compared to the other side. In the same structure, animals, either monocularly deprived or undeprived and exposed binocularly to environmental light for 45 min, had higher ChAT activities on both sides than those maintained in the dark. Mononuclear deprivation performed in adult animals did not affect the ChAT activity in visual Wulst. GAD activity was bilaterally decreased in the visual Wulst after early monocular deprivation. These results suggest that early monocular deprivation has an effect on biochemical systems involved in synaptic transmission at selected relays of the visual pathways.