Effects of Salt Loading on the Morphology of Astrocytes in the Ventral Glia Limitans of the Rat Supraoptic Nucleus.

In the ventral glial limitans (VGL) of the supraoptic nucleus (SON) of the rat, a unique astrocyte type is found with an ability to undergo striking morphological plasticity in response to a wide range of physiological stimulations such as chronic hypernatraemia. This includes a thinning of the VGL, which contains the somata and proximal processes of these astrocytes, as well as an almost complete withdrawal of their vertically-oriented distal processes. Currently, there is little information available on the types of astrocytes that reside in the SON-VGL and which of these exhibit state-dependent structural plasticity. To address this, we enabled the visualisation of single SON-VGL glia using two novel cell labelling techniques with fluorescence microscopy. First, we used an inducible genetic reporter mouse line that allowed the specific labelling of a low density of astrocytes expressing glutamate and aspartate transporter (GLAST)/excitatory amino acid transporter 1. This approach revealed a high degree of variability in the morphology of mouse SON-VGL astrocytes, in contrast to what has been reported for cortical astrocytes. Next, we used the DiOlistlic labelling approach to label single glial cells with DiI in the SON-VGL of rats. Astrocytes observed using this approach shared the morphological features of GLAST-expressing astrocytes in the mouse SON-VGL. Specific structural aspects of these cells were modified by chronic hypernatraemia achieved by 7-day salt loading. Notably, the average area of cells exhibiting protoplasmic features was significantly reduced in the horizontal plane, and the size of varicosities present on fibrous projections was significantly enlarged. These observations indicate that novel cell labelling methods can significantly advance our understanding of SON-VGL cells and reveal specific forms of morphological plasticity that can be driven by chronic hypernatraemia.

Mechanical basis of osmosensory transduction in magnocellular neurosecretory neurones of the rat supraoptic nucleus.

Rat magnocellular neurosecretory cells (MNCs) release vasopressin and oxytocin to promote antidiuresis and natriuresis at the kidney. The osmotic control of oxytocin and vasopressin release at the neurohypophysis is required for osmoregulation in these animals, and this release is mediated by a modulation of the action potential firing rate by the MNCs. Under basal (isotonic) conditions, MNCs fire action potentials at a slow rate, and this activity is inhibited by hypo-osmotic conditions and enhanced by hypertonicity. The effects of changes in osmolality on MNCs are mediated by a number of different factors, including the involvement of synaptic inputs, the release of taurine by local glial cells and regulation of ion channels expressed within the neurosecretory neurones themselves. We review recent findings that have clarified our understanding of how osmotic stimuli modulate the activity of nonselective cation channels in MNCs. Previous studies have shown that osmotically-evoked changes in membrane potential and action potential firing rate in acutely isolated MNCs are provoked mainly by a modulation of nonselective cation channels. Notably, the excitation of isolated MNCs during hypertonicity is mediated by the activation of a capsaicin-insensitive cation channel that MNCs express as an N-terminal variant of the transient receptor potential vanilloid 1 (Trpv1) channel. The activation of this channel during hypertonicity is a mechanical process associated with cell shrinking. The effectiveness of this mechanical process depends on the presence of a thin layer of actin filaments (F-actin) beneath the plasma membrane, as well as a densely interweaved network of microtubules (MTs) occupying the bulk of the cytoplasm of MNCs. Although the mechanism by which F-actin contributes to Trpv1 activation remains unknown, recent data have shown that MTs interact with Trpv1 channels via binding sites on the C-terminus, and that the force mediated through this complex is required for channel gating during osmosensory transduction. Indeed, displacement of this interaction prevents channel activation during shrinking, whereas increasing the density of these interaction sites potentiates shrinking-induced activation of Trpv1. Therefore, the gain of the osmosensory transduction process can be regulated bi-directionally through changes in the organisation of F-actin and MTs.