Bid Expression Network Controls Neuronal Cell Fate During Avian Ciliary Ganglion Development.

Avian ciliary ganglion (CG) development involves a transient execution phase of apoptosis controlling the final number of neurons, but the time-dependent molecular mechanisms for neuronal cell fate are largely unknown. To elucidate the molecular networks regulating important aspects of parasympathetic neuronal development, a genome-wide expression analysis was performed during multiple stages of avian CG development between embryonic days E6 and E14. The transcriptome data showed a well-defined sequence of events, starting from neuronal migration via neuronal fate cell determination, synaptic transmission, and regulation of synaptic plasticity to growth factor associated signaling.

RARβ regulates neuronal cell death and differentiation in the avian ciliary ganglion.

Programmed cell death during chicken ciliary ganglion (CG) development is mostly discussed as an extrinsically regulated process, guided either by the establishment of a functional balance between preganglionic and postganglionic activity or the availability of target-derived neurotrophic factors. We found that the expression of the gene coding for the nuclear retinoic acid receptor β (RARB) is transiently upregulated prior to and during the execution phase of cell death in the CG. Using retroviral vectors, the expression of RARB was knocked down during embryonic development in ovo.

The combination of limb-bud removal and in ovo electroporation techniques: a new powerful method to study gene function in motoneurons undergoing lesion-induced cell death.

Background: The chicken embryo is an important model organism for developmental biology studies. At present, many techniques on this model have been set up, from surgical procedures to molecular biology methods, to answer capital questions of cell biology. The study of the genes involved in motoneurons (MNs) survival and cell death is critical for a better understanding of the molecular mechanisms leading to MNs degenerative diseases, such as amyothophic lateral sclerosis (ALS) and motor peripheral neuropathies.

Differential contribution of hypothalamic MAPK activity to anxiety-like behaviour in virgin and lactating rats.

The c-Raf - MEK1/2 - ERK1/2 mitogen-activated protein kinase (MAPK) intracellular signalling cascade in neurons plays important roles in the control of a variety of behaviours, including social behaviours and anxiety. These roles partially overlap with those described for oxytocin (OXT), and it has been shown that OXT activates the MAPK pathway in the hypothalamus (of male), and hippocampus (of female) rats. Here, by combining behavioural (light/dark box) and biochemical analyses (western blotting), we tested two hypotheses: (i) that OXT is anxiolytic within the hypothalamus of females, and (ii) that this effect, as well as that of lactation-associated anxiolysis, depends on the recruitment of the MAPK pathway.