Neurotransmitter involvement in development and maintenance of the auditory space map in the guinea pig superior colliculus.

Neurotransmitter involvement in development and maintenance of the auditory space map in the guinea pig superior colliculus. J. Neurophysiol. 80: 2941-2953, 1998. The mammalian superior colliculus (SC) is a complex area of the midbrain in terms of anatomy, physiology, and neurochemistry. The SC bears representations of the major sensory modalites integrated with a motor output system. It is implicated with saccade generation, in behavioral responses to novel sensory stimuli and receives innervation from diverse regions of the brain using many neurotransmitter classes. Ethylene-vinyl acetate copolymer (Elvax-40W polymer) was used here to deliver chronically neurotransmitter receptor antagonists to the SC of the guinea pig to investigate the potential role played by the major neurotransmitter systems in the collicular representation of auditory space. Slices of polymer containing different drugs were implanted onto the SC of guinea pigs before the development of the SC azimuthal auditory space map, at approximately 20 days after birth (DAB). A further group of animals was exposed to aminophosphonopentanoic acid (AP5) at approximately 250 DAB. Azimuthal spatial tuning properties of deep layer multiunits of anesthetized guinea pigs were examined approximately 20 days after implantation of the Elvax polymer. Broadband noise bursts were presented to the animals under anechoic, free-field conditions. Neuronal responses were used to construct polar plots representative of the auditory spatial multiunit receptive fields (MURFs). Animals exposed to control polymer could develop a map of auditory space in the SC comparable with that seen in unimplanted normal animals. Exposure of the SC of young animals to AP5, 6-cyano-7-nitroquinoxaline-2,3-dione, or atropine, resulted in a reduction in the proportion of spatially tuned responses with an increase in the proportion of broadly tuned responses and a degradation in topographic order. Thus N-methyl--aspartate (NMDA) and non-NMDA glutamate receptors and muscarinic acetylcholine receptors appear to play vital roles in the development of the SC auditory space map. A group of animals exposed to AP5 beginning at approximately 250 DAB produced results very similar to those obtained in the young group exposed to AP5. Thus NMDA glutamate receptors also seem to be involved in the maintenance of the SC representation of auditory space in the adult guinea pig. Exposure of the SC of young guinea pigs to gamma-aminobutyric acid (GABA) receptor blocking agents produced some but not total disruption of the spatial tuning of auditory MURFs. Receptive fields were large compared with controls, but a significant degree of topographical organization was maintained. GABA receptors may play a role in the development of fine tuning and sharpening of auditory spatial responses in the SC but not necessarily in the generation of topographical order of the these responses.

The contribution of protein kinases to plastic events in the superior colliculus.

1. The superior colliculus (SC)/optic tectum is a multi-layered midbrain area that harbours representations of visual and auditory space and somatic body surface. The development and maintenance of these sensory maps has been shown to involve activity and experience-dependent mechanisms. 2. The implantation of an extra eye primordium into the developing forebrain of Rana pipens results in the formation of dually innervated tecta that would have normally be solely innervated by the contralateral retina. The retinal projections are arranged in an interdigitating pattern of alternate stripes of terminations from each retina. The establishment of this striped pattern requires retinal activity and depends on N-methyl-D-aspartate (NMDA) receptors. Manipulation of protein kinase activity leads to the formation of an abnormal stripe pattern. 3. Regeneration of the goldfish retinotectal projection, following crush of the optic nerve, occurs in an activity dependent manner involving NMDA receptors. Furthermore, a critical period exists, during which retinal activity is vital for reformation of the visual map. Protein kinase manipulations during this period disrupt normal reformation. The same manoeuvres at other time points have little effect on map reformation. 4. An unusual form of long-term potentiation (SC-LTP) has been demonstrated in the in vitro preparation of the guinea-pig SC. By stimulating the optic layer of the SC, a postsynaptic potentiation can be recorded in the superficial grey layer. The expression of SC-LTP is masked but not prevented by blockade of NMDA receptors. The role of protein kinases in this form of synaptic modification has also been studied using various manipulations and inhibitors with varying substrate specificity. Whereas H7, an inhibitor reputed to be protein kinase C specific, only masks the expression of SC-LTP, K252a which has a broad substrate specificity blocks the induction of SC-LTP. 5. Experience-dependent formation of the auditory space map in the deeper layers of the SC is believed to be under the instruction of the visual representation in the superficial layers. Furthermore, a crucial period exists during which normal auditory and visual experience are required for successful establishment of the auditory map. Chronic exposure to 5-aminophosphonopentanoic acid (AP5) during this time prevents the formation of the map. Chronic exposure to K252a, a broad kinase inhibitor, over the same time period, also disrupts the formation of the auditory space map. 6. Taken together, these models emphasise the role of protein kinases in synaptic plasticity observed in the SC. Furthermore, interference with protein kinase activity at crucial stages of regeneration or development appears to disrupt the sequence of events that lead to the consolidation of SC receptive fields.

Severing the intercollicular commissure prevents bilateral disruption of the map of auditory space in the superior colliculi following monocular enucleation.

A previous study demonstrated that developmental monocular enucleation resulted in bilateral disruption of the formation of the auditory space map in both superior collculi, even though only one colliculus had been deprived of visual input. The present study found similar map disruption, when monocular enucleation was carried out following the initial emergence of the map at 32 days after birth. The study also investigated the effect of monocular enucleation plus simultaneous transection of the intercollicular commissure (a recognised pathway for communication between the colliculi). Multi-unit responses to free-field auditory stimuli were recorded from both colliculi of the two experimental groups. In the group which had later monocular enucleation alone, the auditory responses were disrupted in a manner very similar to those recorded from animals which had undergone early monocular enucleation. Similarly, in the group in which the collicular commissure had been severed at the time of monocular enucleation, the auditory responses were also disrupted in the colliculus contralateral to the enucleation. In contrast, the colliculus ipsilateral to the enucleation exhibited normal, topographically organised, auditory responses. Thus, severing the intercollicular commissure at the time of monocular enucleation protected the map of auditory space in the ipsilateral colliculus.

The effect of dark-rearing, strobe-rearing and acute visual cortex removal on the visual responses in the superficial superior colliculus of the guinea-pig.

Extracellular multi-unit responses to visual stimuli were recorded in the cells of the superficial layers of the superior colliculus (SC) in four groups of adult guinea-pigs: a control group, a strobe-reared group, a dark-reared group and a group with the ipsilateral visual cortex removed acutely. Single unit visual responses were also recorded in a control and a dark-reared group. When guinea-pigs were either strobe or dark-reared from birth, the number of directionally selective responses in the superficial SC decreased significantly. Acute removal of the visual cortex had no affect on the number of directionally selective cells recorded in the SC. The correlation between azimuthal visual receptive field and rostrocaudal position of the recording electrode in the SC was not significantly different from the control group following strobe, dark-rearing or acute visual cortex removal. These data imply that, during early development, visual information is necessary for directional selectivity of the visual responses in the superficial SC. However, the map of visual azimuthal space is essentially unperturbed by visual restriction (in the form of dark or strobe-rearing) or acute visual cortex removal.