Developmental expression of a unique carbohydrate antigen, Tn antigen, in mouse central nervous tissues.

Using an anti-Tn monoclonal antibody, the Tn antigen was detected immunohistochemically in prenatal and early postnatal central nervous tissues. On embryonic day 9 (E9), the antigen was distributed throughout the single neuroepithelial layer in the neocortex and then became more prominent in the preplate than in the ventricular zone along with formation of the preplate. Following division of the preplate and concomitant formation of the cortical plate, distinct labeling of the neocortex occurred in the marginal, subplate and intermediate zones, whereas in the cortical plate and ventricular zone were virtually not immunostained. It is notable that thalamocortical afferent fibers were also immunostained specifically on E14. After birth, the localization of the antigen became less noticeable and by 3 weeks after birth, the antigen had substantially disappeared. In the developing cerebellum, prominent labeling was also observed in the molecular layer and outskirts of the cerebellar nuclei on early postnatal days. To characterize the glycoprotein bearing the Tn antigen biochemically, immunoblot analysis was performed. The glycoprotein, most of which was extracted with a salt solution, migrated as a broad smeared band corresponding to a molecular weight of about 250 kDa on SDS-PAGE. Among the various tissues examined, this glycoprotein was only detected in the brain and its amount increased until an early postnatal stage with a peak on postnatal day 3 (P3), and then decreased gradually with age. This spatially and developmentally regulated expression of the Tn antigen suggests that this antigen plays a significant role in brain development.

Activation of macrophages by crude polysaccharide fractions obtained from shoots of Glycyrrhiza glabra and hairy roots of Glycyrrhiza uralensis in vitro.

Many plant polysaccharide fractions have been reported as immunomodulatory agents. However, sometimes the possibility of contamination with bacterial lipopolysaccharide (LPS), a potent B cell mitogen and immune modulator, is discussed. In the present paper, we investigated the effects of crude polysaccharide fractions obtained from the shoot and hairy root of Glycyrrhizae sp. on murine peritoneal macrophage function, in order to clarify whether plants grown under aseptic conditions produce immunomodulatory polysaccharides. All crude polysaccharide fractions induced nitric oxide production by murine peritoneal macrophages in vitro. Chemical analysis revealed that LPS-like molecules were not present in all preparations. These results suggested that shoot and hairy root biosynthesized polysaccharides that could stimulate macrophages de novo.

Significant induction of a 54-kDa protein in rat liver with homologous alignment to mouse selenium binding protein by a coplanar polychlorinated biphenyl, 3,4,5,3',4'-pentachlorobiphenyl and 3-methylcholanthrene.

A 54-kDa protein in rat liver cytosol was significantly induced by treatment with 3,4,5,3',4'-pentachlorobiphenyl (25 mg/kg, single i.p.) and 3-methylcholanthrene (20 mg/kg, once a day for 3 days, i.p.). The protein exhibited pI of 6.8 on two-dimensional gel electrophoresis. The amino acid sequences of peptide fragments from the protein digested in situ were highly similar to a selenium binding protein in mice and to the isoform acetaminophen binding protein in mice. The present result clearly demonstrates that a coplanar polychlorinated biphenyl and 3-methylcholanthrene are responsible for induction of selenium binding protein homologues. The physiological role of the mouse proteins, however, is not yet elucidated.

Sulphotransferase-dependent dehydration of atropine and scopolamine in guinea pig.

1. Enzymatic dehydration of atropine and scopolamine was studied in guinea pig. 2. The incubation of these alkaloids with guinea pig liver cytosol in the absence of cofactors gave no dehydrated metabolite. However, when atropine and scopolamine were incubated with cytosol supplemented with ATP and sodium sulphate, dehydrated metabolites, apoatropine and aposcopolamine were formed. The formation of these metabolites was confirmed by gas chromatography-mass spectrometry. 3. The reaction required ATP as well as cytosol as the obligatory factors. Deletion of sodium sulphate from the reaction mixture also resulted in a decrease of the activities, although this treatment showed limited effect when the low concentration of atropine was used. Furthermore, dehydroepiandrosterone, an excellent substrate for hydroxysteroid-sulphotransferase, effectively inhibited the in vitro activity of atropine dehydration. 4. Administration of dehydroepiandrosterone to guinea pig followed by atropine treatment caused decreased urinary excretion of apoatropine. 5. These results strongly suggested that the dehydration of atropine and scopolamine takes place via the sulphate conjugate intermediates produced from the sulphotransferase-catalysed reaction. The present finding is the first example of the sulphotransferase-dependent dehydration of a drug, and its generality in drug metabolism is discussed.