Ectopic mineralization of connective tissue in Abcc6-/- mice: effects of dietary modifications and a phosphate binder--a preliminary study.

Pseudoxanthoma elasticum (PXE), a heritable multisystem disorder, is caused by mutations in the ABCC6 gene. We have developed a murine model for PXE by targeted inactivation of the corresponding mouse gene. A feature of this mouse model is ectopic mineralization of connective tissue capsule surrounding the bulb of vibrissae. This study was designed to investigate the effect of dietary sevelamer hydrochloride (Renagel), a phosphate binder, and specific mineral modifications on ectopic mineralization of connective tissue in Abcc6-/- mice. Three groups were fed a specific diet: (i) a standard rodent diet, (ii) a standard rodent diet supplemented with sevelamer hydrochloride, and (iii) a custom experimental diet with specific mineral modifications (high phosphorus, low calcium and low magnesium). The degree of mineralization was determined in hematoxylin-eosin-stained sections using computerized morphometric analysis and by chemical assays to measure the calcium and phosphorus content of the vibrissae. The results indicated increased mineralization in the Abcc6-/- mice fed a standard diet or a diet with mineral modifications as compared with control mice fed a standard diet. However, feeding Abcc6-/- mice with diet supplemented with sevelamer hydrochloride did not improve mineralization, in comparison to mice fed with normal diet. Collectively, these results suggest that the mineralization process in PXE may be exacerbated by changes in mineral intake. The role of dietary minerals, and phosphorus in particular, as well as that of phosphate binders, in ectopic mineralization of PXE, merits further investigation.

A new thalamic pathway of vibrissal information modulated by the motor cortex.

Three ascending pathways of information processing have been identified so far in the vibrissal system of rodents. In the ventral posterior medial nucleus of the thalamus, two of these pathways convey information through the core and tail of barrel-associated structures, called barreloids. The other pathway transits through the posterior group nucleus. The present study provides anatomical and electrophysiological evidence for the existence of an additional pathway that passes through the head of the barreloids. This pathway arises from multiwhisker-responsive cells in the principal trigeminal nucleus and differs from the classic lemniscal pathway, in that constituent thalamic cells have multiwhisker receptive field and receive corticothalamic input from lamina 6 of the vibrissa motor cortex. It is suggested that this pathway might be involved in relaying signals encoding phase of whisker motion during free whisking.