Contactin-5 expression during development and wiring of the thalamocortical system.

The gene encoding the neural cell adhesion molecule Cntn5 (a.k.a. NB-2) has been put forward as a candidate in neurodevelopmental disorders, like autism spectrum disorder (ASD), by recent genetic findings. Little is known about the expression pattern and function of the gene, and its functional involvement in brain development has remained elusive. So far, most research has focused on its early postnatal expression in the auditory system, where the absence of Cntn5 causes abnormal responses to acoustic stimuli and a decrease in fiber density. The current study shows that the Cntn5 gene is expressed in forebrain structures during embryonic development, starting at E15.5, and that it continues to be expressed into adulthood. Sites of strong expression included the thalamus, the caudate putamen (CPu) and to a lesser extent layer Va of the cerebral cortex. Cntn5-positive thalamic nuclei include the laterodorsal (LD), ventrolateral (VL) and posterior group (Po), which contain glutamatergic neurons. Visualization of the expression pattern through the Tau-LacZ fusion protein coded by an insert in the Cntn5 gene, demonstrated that Cntn5-positive nuclei of the thalamus project to the cortex, based on co-localization with thalamocortical markers L1 and Calretinin. These results indicate that the cell adhesion functions of Cntn5 are exploited for circuit formation and connectivity in early development and for synaptic maintenance during adulthood. Subtle alterations in the formation of the thalamocortical circuit may contribute to neurodevelopmental disorders, such as ASD.

Neurohypophysial dysmorphogenesis in mice lacking the homeobox gene Uncx4.1.

A number of transcription factors have been implicated in the development of the hypothalamo-neurohypophysial system (HNS). Null mutations for these factors caused severe defects in proliferation, migration and survival during early embryogenesis. While they have informed about early events of HNS developments no insights in mechanisms of late development and maturation of this major peptidergic system have been obtained as yet. In a screen for adult-expressed homeobox genes we identified Uncx4.1 as a gene expressed in adult and embryonic magnocellular neurons of the (HNS). Null mutation of Uncx4.1 left these neurons viable and able to express neuropeptides. However, the connectivity of magnocellular neurons with posterior pituitary elements was compromised. As a consequence neuronal fibres traversed to the adenohypophysis. The penetrance of this phenotype was about 50%. The data show a selective role of Uncx4.1 in controlling the development of connections of hypothalamic neurons to pituitary elements, allowing central neurons to reach the peripheral blood circulation and to deliver hormones for control of peripheral functions.

Survey for paired-like homeodomain gene expression in the hypothalamus: restricted expression patterns of Rx, Alx4 and goosecoid.

Homeobox genes are important regulators of cellular identity. Several homeobox genes are known to be specifically expressed in subsets of neurons in the forebrain, exclusively, or in distinct combinations. In this study, we explored the expression of homeobox genes in the forebrain of the adult rat by a degenerate polymerase chain reaction cloning strategy. We identified the expression of 12 homeobox genes, several of which display a remarkable restricted expression pattern in the adult brain. We demonstrated the expression of goosecoid in a very small set of neurons in the hypothalamus. By using Otp as a marker, these goosecoid-positive cells were found to constitute a small area just beside the paraventricular nucleus. Furthermore, we found expression of Rx in the pineal gland, along with Alx4. Rx was additionally found in the posterior pituitary and in cells aligning the bottom of the third ventricle. These findings form a starting point to reveal functions of the described homeobox genes in the forebrain.