Expression of doublecortin correlates with neuronal migration and pattern formation in diverse regions of the developing chick brain.

The development of functional layers in the brain involves spatially and temporally regulated gene expression. Through cDNA library screening, we have identified genes that are expressed in a neural-specific manner during brain development. Sequencing and expression data indicate that one of the clones, 18C15, is the chick homologue of doublecortin, a human X-linked gene found to be mutated in subcortical laminar heterotopia (double cortex syndrome) and lissencephaly. The 18C15 mRNA contains multiple motifs that are known to regulate mRNA stability in response to inductive signals, and these motifs are conserved between the chick and human sequences. Doublecortin is found to be expressed at peak levels during early development of the cerebellum and forebrain, and is expressed in other regions including the tectum, spinal cord, and dorsal root ganglia. This study demonstrates both spatial and temporal regulation of doublecortin expression in the chick, which is associated with early events in brain development, including neuronal migration.

Thy-1 and AvGp50 signal transduction complex in the avian nervous system: c-Fyn and G alpha i protein association and activation of signalling pathways.

We have previously reported the isolation of two distinct populations of detergent resistant membrane complexes (DRMC's) from day-old chick brain (Henke et al.: J Neurosci Res 45:617-630, 1996). We now show that the glycosylphosphatidylinositol-anchored proteins Thy-1 and AvGp50 are associated in a signalling complex with c-Fyn, the heterotrimeric G alpha i subfamily members G alpha i-3, G alpha z, and G alpha o, alpha and beta tubulin, and a number of other phosphoproteins in immunocomplexes isolated from both populations of DRMC's. Activation of this signalling complex via Thy-1 monoclonal antibody incubation with chick forebrain cells, elicited a decrease in total phosphoprotein profile and tyrosine kinase activity present in DRMC fractions isolated from these cells, while AvGp50 and control antibodies had no effect. Down-regulation of the DRMC phosphoprotein profile was accompanied by an increase in the Thy-1-associated signalling complex, suggesting that activation of this complex initiates the decreases seen in overall DRMC kinase activity. This signalling complex provides the basis for GPI-anchored protein-mediated signal transduction within the unique plasma membrane domains represented by DRMC's.

Characterization of two distinct populations of detergent resistant membrane complexes isolated from chick brain tissues.

We report the isolation of two distinct populations of detergent resistant membrane complexes (DRMCs) from 1-day-old chick brain, utilizing a procedure involving Triton X-100 insolubility and sucrose density gradient centrifugation. The first population is abundant (1.8% of the total homogenate protein), highly enriched for two glycosylphosphatidylinositol (GPI)-anchored proteins (Thy-1 and AvGp50), and not enriched for caveolin. The second population is of relatively low abundance (0.2% of the total homogenate), contains relatively low levels of Thy-1 and AvGp50 enrichment, and is highly enriched in caveolin. Both populations of DRMCs are enriched for cholesterol, ganglioside GM1, total kinase and tyrosine kinase activities, and c-Src and c-Fyn. However, there are differences in the Coomassie-stained protein profiles, phosphoprotein components, tyrosine kinase activity, and electron microscopic morphology when the Thy-1 and AvGp50-enriched DRMCs are compared to the caveolin-rich DRMCs. In addition, the GPI-enriched DRMCs contain CaM kinase type II immunoreactivity, whereas this molecule was undectable in the caveolin-rich DRMCs. The isolation of two distinct DRMC fractions may be representative of unique plasma membrane signaling domains involved in GPI-anchored protein or other receptor-mediated signal transduction within the avian nervous system. Further, we have demonstrated for the first time that nervous system tissue, in particular the hatch chick cerebellum, contains caveolin immunoreactivity.

Differential induction and intracellular localization of SCG10 messenger RNA is associated with neuronal differentiation.

The differentiation of neurons involves the establishment of distinct molecular compartments which regulate neuronal shape and function. This requires targeting of specific gene products to growth-associated regions of the neuron. We have investigated the temporal and spatial regulation of SCG10 gene expression during neuronal differentiation. There are two SCG10 messenger RNAs, 1 and 2 kg in length, which encode the same growth-associated protein. These messenger RNAs were found to be differentially regulated during the onset of neurite outgrowth in early rat cerebellum development. In PC12 cells, the two SCG10 messenger RNAs were shown to be differentially induced by nerve growth factor. Regulation of the 2 kb messenger RNA, but not the 1 kb messenger RNA, is dependent on the differentiation of PC12 cells, indicating that post-transcriptional regulation of SCG10 expression during neurite outgrowth. Spatial regulation of the 2 kb SCG10 messenger RNA distribution during brain development was examined by in situ hybridization. The 2 kb messenger RNA was found to be localized to the neuronal pole where outgrowth was occurring, within differentiating neurons in vivo. Intracellular localization of SCG10 messenger RNA was also observed in differentiating primary cultured neurons, with the 2 kb messenger RNA transported into growing neurites during the development of neuronal polarity. In neurons which had developed polarity, the 2 kb SCG10 messenger RNA was consistently found in the cell body and axon. This study demonstrates both temporal and spatial post-transcriptional regulation of SCG10 expression which is associated with neurite outgrowth. The directed transport and positional translation of SCG10 messenger RNA provide a potential mechanism for protein targeting and the creation of molecular compartments during neuronal differentiation.

Induction of neuron-specific tropomyosin mRNAs by nerve growth factor is dependent on morphological differentiation.

We have examined the expression of brain-specific tropomyosins during neuronal differentiation. Both TmBr-1 and TmBr-3 were shown to be neuron specific. TmBr-1 and TmBr-3 mRNA levels increased during the most active phase of neurite outgrowth in the developing rat cerebellum. In PC12 cells stimulated by nerve growth factor (NGF) to differentiate to the neuronal phenotype, TmBr-1 and TmBr-3 levels increased with an increasing degree of morphological differentiation. Induction of TmBr-1 and TmBr-3 expression only occurred under conditions where PC12 cells were permitted to extend neurites. NGF was unable to maintain levels of TmBr-1 and TmBr-3 with the loss of neuronal phenotype by resuspension of differentiated PC12 cells. The unique cellular expression and regulation in vivo and in vitro of TmBr-1 and TmBr-3 strongly suggests a critical role of these tropomyosins in neuronal microfilament function. The findings reveal that the induction and maintenance of the neuronal tropomyosins is dependent on morphological differentiation and the maintenance of the neuronal phenotype.

Expression of actin and myosin genes during PC12 cell differentiation.

We have measured the accumulation of transcripts for myosin and actin during NGF induced differentiation of PC12 cells. Beta (beta) and gamma (gamma) actin and myosin light chains (MLC) 2 and 3 show different patterns of expression, with transient elevations in gene expression one day after NGF addition. This elevation occurs earlier than that of neurite outgrowth, neurofilament protein (NF68) (16) and Thy-1 glycoprotein gene expression. These results suggest differing mechanisms of control of actin and myosin expression, together with a varying function and relationship between them during NGF-induced neurite differentiation.