Reduced soma size of the M-neurons in the lateral geniculate nucleus following foetal alcohol exposure in non-human primates.

Visual impairment is commonly reported as a consequence of heavy prenatal ethanol exposure in humans. Children generally display characteristic cranio-facial dysmorphology and represent typical severe cases of foetal alcohol syndrome. Binge-like rodent model systems have concluded that third trimester equivalent ethanol exposure results in widespread apoptosis in the visual system from the retina to the visual cortex. Neither clinical nor animal studies address the consequences of more moderate prenatal ethanol exposure on the visual system. The current study uses a naturalistic and voluntary consumption approach in non-human primates (Chlorocebus sabeus) in order to more closely model prenatal ethanol consumption patterns in humans. Pregnant vervet monkeys voluntarily drank on average 2.418 +/- 0.296 g etoh/kg/day four times a week during the third trimester. Using unbiased stereology, we estimated the neuronal and glial population of the parvocellular (P) and magnocellular (M) layers of the lateral geniculate nucleus (LGN) following foetal alcohol exposure (FAE) in infant subjects. Layer volume and total number of neurons and glia in the LGN of the FAE subjects were not significantly different from age-matched control subjects. The M neuronal soma size of FAE subjects, however, was significantly reduced to resemble the size of the P-neurons. These results suggest that alterations at the level of morphology and anatomy of the M-neurons may lead to behavioural deficits associated with the integrity of the dorsal visual pathway.

Neural activity profiles of the neocortex and superior colliculus after bimodal sensory stimulation.

Current efforts at functional mapping of multisensory neurons are hampered by the need for both cellular-level resolution and the separate visualization of activity by different sensory cues. We have used a recently developed technique that exploits the differential time course of zif268 mRNA versus protein induction in neurons after sensory stimulation. Adult male rats were visually and acoustically deprived and then exposed to one of the following stimulation sequences: (i) no sensory stimulation; (ii) 2 h visual stimulation followed by 30 min auditory stimulation; (iii) 2 h auditory stimulation followed 30 min of visual stimulation; and (iv) 2 h compound visual and auditory stimulation. The neocortex and superior colliculus (SC) were then processed for fluorescent immunocytochemistry and in situ hybridization for staining of Zif268 protein and mRNA products. We have found that activity patterns in primary visual and auditory cortices were in accord with the sequence of the compound stimulus. We also show that SC superficial layers contained a pool of exclusively unimodal neurons, similar to that of visual cortex. Activity patterns of deep SC layers contained multimodal neurons with varying degrees of visual and auditory convergence. The deep SC layers also showed that auditory processing was largely carried out by a small, bimodal group of neurons whereas visual processing was coordinated by both a large unimodal and a small bimodal pool of neurons.

Molecular maps of neural activity and quiescence.

The rapid accumulation of inducible transcription factors (ITFs), such as c-Fos and Zif268, in activated neurons combined with histological methods that offer detection at the cellular level are key features that have led to their wide use in visualizing activated neurons. There are two major drawbacks of ITFs that limit their use in the CNS--cell-type expression specificity and stimulus-transcription coupling uncertainty. Recent technical advances in the field of molecular activity mapping now permit dual-labeling approaches that help resolve some of these ambiguities and identify neurons that are activated by different sensory stimuli. Furthermore, the recent identification of the robl/LC7-like gene, which shows immediate-early repression after stimulation, may have utility in functional mapping where it can be used to delineate quiescent neurons and serve as a complement to molecular activity markers.

Light-induced down-regulation of the rat class 1 dynein-associated protein robl/LC7-like gene in visual cortex.

Dynein and kinesin are the main microtubule-dependent motors that mediate intracellular movement in eukaryotic organisms. We have cloned a full-length cDNA encoding rat dynein light chain protein, robl/LC7-like (class 1), from visual cortex. We found that rat robl/LC7-like gene is highly expressed in neocortex and displays the unusual feature of being rapidly down-regulated by sensory stimulation. This effect was seen at both mRNA and protein levels in visual cortex, being detectable in as little as 45 min after the onset of visual stimulation. Down-regulation by sensory stimulation was also found within ocular dominance columns of area V1 in monocularly deprived monkeys. Our results suggest a high turnover rate of the robl/LC7-like protein and the presence of a repressor mechanism in neurons that is tightly coupled to synaptic stimulation.

Developmental profiles of SMI-32 immunoreactivity in monkey striate cortex.

A monoclonal antibody that recognizes a nonphosphorylated epitope on the medium and high molecular weight subunits of neurofilament (NF) proteins was used to investigate laminar and cell morphology changes in monkey striate cortex during post-natal development. Six cortices were obtained from monkeys of a variety of ages: five from developing animals with ages spanning the critical period and one adult. At post-natal day (PD) 0, immunohistochemistry with the SMI-32 antibody revealed immunoreactive (IR) cells in layer IVB and in infragranular layer VI. Early in the critical period (PD 7), these layers become more defined with an increase in the density of immunopositive cells. At the height of the critical period (PD 30 and 42), a drastic increase in the density of SMI-32 labelled pyramidal neurons in layers V and VI was observed. Similarly, layer IVC showed an abundance of dendritic fragments and dendrites that appeared to originate from the infragranular layers. At the end of the critical period (PD 103), a trend toward morphological maturation for individual neurons found within each layer was observed. During any developmental time point, neurons at first appearance tended to show an immature morphology with staining largely restricted to the cell bodies. As such, the characteristic arborizations common to mature pyramidal and multipolar cells was not evident. We propose that the staining pattern seen in this study is consistent with the idea that layers anatomically associated with the magnocellular (M) pathway develop earlier than their parvocellular (P) counterparts.

Rapid phosphorylation of Elk-1 transcription factor and activation of MAP kinase signal transduction pathways in response to visual stimulation.

The AP-1 transcription factor, which is composed of various combinations of Fos and Jun proteins, is believed to be a key participant in molecular processes that guide activity-dependent changes in gene expression. In this study, we investigated the activity of different MAP kinases that have been implicated in AP-1 activation. We examined the activities of ERK, JNK/SAPK, and p38 MAPK along with their nuclear targets (Elk-1 and c-Jun) in rat visual cortex after light stimulation. The transcription factor Elk-1 (a possible regulator of c-fos expression) was found to be transiently modified by phosphorylation when visual stimulation was applied after a period of dark rearing. In vitro kinase assay with Elk-1 as substrate showed that light stimulation activated MAPK/ERK in visual cortex but not frontal cortex. Furthermore, ERK activation was temporally matched to onset of Elk-1 phosphorylation. The activity of JNK1 (c-Jun N-terminal kinase 1) was elevated at 2-6 h after visual exposure and was also temporally correlated to increase of endogenous P-c-Jun levels and its appearance within the AP-1 DNA-binding complex. The activities of p38 MAP kinases did not change significantly. These results demonstrate the differential engagement of MAPK signaling pathways following sensory stimulation and their relative effects upon AP-1 expression in the intact brain.

Sensory regulation of immediate-early genes c-fos and zif268 in monkey visual cortex at birth and throughout the critical period.

The postnatal development of ocular dominance columns (ODCs) in monkey visual cortex provides an exquisite model for studying mechanisms of experience-guided neuronal plasticity. While the presence of columns at birth in Old World monkeys is now well established, it remains unclear whether cortical neurons at this early stage are capable of modulating gene expression in response to changing sensory conditions. Using a set of monocular deprivation and stimulation protocols, we examined activity-driven expression of the immediate-early genes (IEGs) c-fos and zif268 during the critical period of development. We observed well-delineated patterns of ODCs produced by sensory regulation of both IEGs throughout the critical period, starting as early as the first postnatal day. The expression levels are similar in layers II/II, IVC and VI throughout development, with no selective decline in the thalamorecepient layer (layer IVC) of adult monkeys. A narrow strip of non-columnar c-Fos expression was observed at the border of layers IVC and V. Our results show that neurons in monkey visual cortex are equipped at birth with the molecular machinery for coupling sensory inputs to active genomic responses and that this responsivity extends throughout the critical period. The findings are discussed within the context of a possible role for IEGs in sensory-driven cortical plasticity during development.

Differential expression of neurofilament protein in the visual system of the vervet monkey.

It has been previously reported that the monoclonal antibody SMI-32 reveals a characteristic pattern of immunostaining which may be used to delineate various cortical modules in the monkey visual system. We wished to examine staining patterns with this antibody at both the lateral geniculate nucleus (LGN) and cortical levels with regard to magno- and parvocellular processing schemes in the vervet monkey. Using standard immunohistochemical procedures, we have found that the M-layers of the LGN were intensely stained in comparison to P-layers and that there were regional variations in staining within the visual cortex that reflected this input. The transition between areas V1 and V2 was especially prominent due to differences in the laminar staining profiles. Another striking result was found within the superior temporal sulcus where heavy SMI-32 immunostaining confined to the floor of the sulcus coincided with a similar zone of intense myelin staining. We have also found a number of other areas within the intraparietal and lateral sulci that show foci of heavy SMI-32 staining. As with Cat-301 immunostaining, the regional variabilities that are observed with SMI-32 in the visual cortex reflect molecular distinctions that may provide further criteria for functional segmentation.