Distribution and morphology of transgenic mouse oligodendroglial-lineage cells following transplantation into normal and myelin-deficient rat CNS.

Glial cells from neonatal MbetaP5 transgenic mice, which express bacterial beta-galactosidase (lacZ) under control of the myelin basic protein (MBP) promoter (Gow et al, 1992), were transplanted into the spinal cord or cerebral hemisphere of immunosuppressed normal and myelin-deficient (md) rats in order to assess the ability of the donor cells to survive, migrate, and differentiate within normal compared with myelin-deficient central nervous system (CNS). LacZ+ cells were detected as early as 6-7 days after transplantation into the low thoracic cord and by 10 days had spread rostrally to the brainstem and caudally to the sacral spinal cord. Initially, compact lacZ+ cells, lacking processes, were found associated with small blood vessels and with the glia limitans. Cells of this type persisted throughout the experiment. Later, lacZ+ cells with processes were seen along fiber tracts in the dorsal columns and, after intracerebral injection, subjacent to ventricular ependyma, as well as scattered in cerebral white and gray parenchyma. The extent of spread was comparable in md and normal rats, but in the md group, the success rate was higher, and more cells differentiated into process-bearing oligodendrocytes. Acceptance of xenografts in immunosuppressed recipients equaled that of allografts. The overall spread of grafted cells exceeded that of injected charcoal, indicating active migration. In contrast to earlier studies that identified oligodendrocytes based on morphology alone, this study has allowed us to identify and track oligodendrocytes based on myelin gene expression. We show some oligodendrocytes whose morphology is consistent with classical morphological descriptions, some that resemble astrocytes, and a class of compact perivascular oligodendrocyte-lineage cells that we suggest are migratory.

Hyperparathyroidism is augmented by ovariectomy in Nagase analbuminemic rats.

The role of albumin in bone metabolism was studied in Nagase analbuminemic (NA) rats. Serum calcium (Ca), inorganic phosphate (Pi) and magnesium (Mg) concentrations did not differ between female NA and control Sprague-Dawley (SD) rats at the time of ovariectomy (ovx), although serum ionized Ca was significantly lower in NA rats than in SD rats. Serum parathyroid hormone (PTH) and osteocalcin (OC) concentrations and urinary Ca excretion were significantly greater in NA rats than in SD rats, suggesting hyperparathyroidism and the resultant enhanced bone turnover in NA rats. Paradoxically, ovx increased serum PTH and OC in NA rats but not in SD rats. Ovx-induced exacerbation of hyperparathyroidism was confirmed by significantly greater conversion of 25-hydroxyvitamin D to 1, 25-dihydroxyvitamin D in ovx NA rats even after normalization to vitamin D-binding protein. Bone mineral density (BMD) in proximal tibia increased similarly in a time-dependent manner in sham-operated NA and SD rats. However, ovx ablated the time-dependent increase of BMD in SD rats and significantly decreased BMD in NA rats by 2 wk after ovx, resulting in a significantly lower BMD in ovx NA rats than in ovx SD rats. In summary, NA rats, which are analbuminemic with compensatory increases in lipid and protein synthesis, developed hyperparathyroidism, possibly due to an increase in serum Pi and a reduction of ionized Ca, and ovx induced a greater BMD reduction in NA rats than in SD rats, probably by exacerbating hyperparathyroidism.