The role of gap junction proteins in the development of neural network functional topology.

Gap junctions (GJs) provide a common form of intercellular communication in most animal cells and tissues, from Hydra to human, including electrical synaptic signalling. Cell coupling via GJs has an important role in development in general, and in neural network development in particular. However, quantitative studies monitoring GJ proteins throughout nervous system development are few. Direct investigations demonstrating a role for GJ proteins by way of experimental manipulation of their expression are also rare. In the current work we focused on the role of invertebrate GJ proteins (innexins) in the in vitro development of neural network functional topology, using two-dimensional neural culture preparations derived from the frontal ganglion of the desert locust, Schistocerca gregaria. Immunocytochemistry and quantitative real-time PCR revealed a dynamic expression pattern of the innexins during development of the cultured networks. Changes were observed both in the levels and in the localization of expression. Down-regulating the expression of innexins, by using double-strand RNA for the first time in locust neural cultures, induced clear changes in network morphology, as well as inhibition of synaptogenesis, thus suggesting a role for GJs during the development of the functional topology of neuronal networks.

Neuronal soma migration is determined by neurite tension.

Neuronal migration is an intricate process involving a wide range of cellular mechanisms, some of which are still largely unknown. Using specially prepared culturing substrates, we were able to explore this and other developmental processes in networks composed of cultured locust neurons, and to analyze the role of neurite tension in these processes. Time lapse investigation shows that the shape and position of the cell soma are both linked to the extent and direction of the combined tension in its neurites. In particular, for migrating neurons (over 1-2 days) with three main neurites, a force-balance between neurite tension forces was demonstrated (ΣF=0). The results presented here suggest that neuronal migration is strongly affected by tension in neurites rather than being entirely determined by the interaction between soma and substrate. The validity of these results to other in-vitro and in-vivo data is discussed.

Transcriptional regulation of arylalkylamine-N-acetyltransferase-2 gene in the pineal gland of the gilthead seabream.

Pineal serotonin-N-acetyltransferase (arylalkylamine-N-acetyltransferase; AANAT) is considered the key enzyme in the generation of circulating melatonin rhythms; the rate of melatonin production is determined by AANAT activity. In all the examined species, AANAT activity is regulated at the post-translational level and, to a variable degree, also at the transcriptional level. Here, the transcriptional regulation of pineal aanat (aanat2) of the gilthead seabream (Sparus aurata) was investigated. Real-time polymerase chain reaction quantification of aanat2 mRNA levels in the pineal gland collected throughout the 24-h cycle revealed a rhythmic expression pattern. In cultured pineal glands, the amplitude was reduced, but the daily rhythmic expression pattern was maintained under constant illumination, indicating a circadian clock-controlled regulation of seabream aanat2. DNA constructs were prepared in which green fluorescent protein was driven by the aanat2 promoters of seabream and Northern pike. In vivo transient expression analyses in zebrafish embryos indicated that these promoters contain the necessary elements to drive enhanced expression in the pineal gland. In the light-entrainable clock-containing PAC-2 zebrafish cell line, a stably transfected seabream aanat2 promoter-luciferase DNA construct exhibited a clock-controlled circadian rhythm of luciferase activity, characteristic for an E-box-driven expression. In NIH-3T3 cells, the seabream aanat2 promoter was activated by a synergistic action of BMAL/CLOCK and orthodenticle homeobox 5 (OTX5). Promoter sequence analyses revealed the presence of the photoreceptor conserved element and an extended E-box (i.e. the binding sites for BMAL/CLOCK and OTX5 that have been previously associated with pineal-specific and rhythmic gene expression). These results suggest that seabream aanat2 is a clock-controlled gene that is regulated by conserved mechanisms.