Cholecalciferol and placental calcium transport

Transplacental movement of calcium from mother to fetus is essential for normal fetal development. In most species, fetal plasma calcium levels are higher than maternal levels at term. The role of cholecalciferol metabolites, with specific emphasis on 1,25-dihydroxycholecalciferol (1,25(OH)2D), in placental calcium transport and maintenance of the fetomaternal gradient has been extensively investigated. In rats, there is not an absolute demand for 1,25(OH)2D for maintenance of fetal calcium homeostasis in utero, even though it is essential for maintenance of maternal plasma calcium levels. However, in sheep, the absence of 1,25(OH)2D results in disruption of both maternal and fetal calcium homeostasis. It is known that rat and human placentas contain specific cytosolic binding proteins for 1,25(OH)2D that are similar to the well-characterized intestinal receptor. Two calcium-binding proteins (CaBP) have been detected in rat and human placentas: a protein immunologically identical to the vitamin D-dependent CaBP and a calcium-dependent ATPase. The levels of CaBP in rat placenta have been shown to increase in response to exogenously administered 1,25(OH)2D but cannot be obliterated with maternal vitamin D deficiency. No relationship has been shown between 1,25(OH)2D and placental Ca-ATPase in any species. Thus, the mechanism of action of 1,25(OH)2D in maintenance of the transplacental calcium gradient in sheep is unknown. In the pregnant rat (and perhaps human), 1,25(OH)2D is a critical factor in the maintenance of sufficient maternal calcium for transport to the fetus and may play a role in normal skeletal development of the neonate.     

Butyrylcholinesterase in pericytes associated with canine brain capillaries

Summary The distribution of the enzyme butyrylcholinesterase (BChE) in dog brain cortex and cerebellum was studied by light and electron microscopy using a Hatchett's brown technique. Staining was found in neuron cell bodies and processes, the white matter of the cerebellum, and in capillaries and arterioles. Electron microscopy indicated that the enzyme activity associated with vessels was present in pericytes. Reaction product was found at the cell membrane, the intermembranous space of the nuclear envelope, and the Golgi complex of these cells. The finding of BChE in canine brain pericytes and its absence in endothelium does not support the idea that this enzyme is important in blood-brain barrier function. The pericyte in dog brain may be a site of synthesis of this enzyme and is, in this respect, similar to the endothelial cell of rat brain.     

Comparison of Proanthocyanidins and Related Compounds in Leaves and Leaf-Derived Cell Cultures of Ginkgo bioloba L., Pseudotsuga menziesii Franco, and Ribes sanguineum Pursh

Proanthocyanidins, flavan-3-ols, and their flavanoid precursors in leaves and leaf-derived callus and cell suspension cultures have been isolated and analyzed by high performance liquid chromatography with C₁₈ columns, paper chromatography, and by chemical and spectrophotometric methods. Cultures of Ginkgo biloba and Pseudotsuga menziesii (Douglas-fir) produced much greater amounts of proanthocyanidins than leaves per milligram dry weight. In cultures, however, the prodelphinidin component relative to that of procyanidins decreased; this was most pronounced in Pseudotsuga. In contrast, callus cultures of Ribes sanguineum accumulated proanthocyanidins in amounts about equal to those in intact leaves per milligram dry weight and the prodelphinidin content remained high. Although Ginkgo and Ribes leaves contained major amounts of flavan-3-ols and dimers with the 2,3-cis-stereochemistry, their cultures tended to synthesize 2,3-trans-isomers instead. Glycosides of flavanone and 3-hydroxyflavanone precursors accumulated in medium to high amounts on a dry weight basis in leaves and cultures of Ribes and Pseudotsuga, and the 3′-glycosidic linkage predominated when the latter species was cultured with 2,4-dichlorophenoxyacetic acid rather than naphthaleneacetic acid.     

Carbon-13 NMR Studies of Salt Shock-Induced Carbohydrate Turnover in the Marine Cyanobacterium Agmenellum quadruplicatum

Carbon turnover in response to abrupt changes in salinity, including the mobilization of glycogen for use in osmoregulation was studied with pulse-chase strategies utilizing nuclear magnetic resonance (NMR)-silent and NMR-detectable ¹²C and ¹³C isotopes, respectively. Growth of Agmenellum quadruplicatum in 30%-enriched¹³C bicarbonate provided sufficient NMR-detectability of intracellular organic osmoregulants for these studies. A comparison of NMR spectra of intact cells and their ethanol extracts showed that the intact cell data were suitable for quantitative work, and, when combined with ESR measurements of cell volumes, yielded intracellular glucosylglycerol concentrations without disrupting the cells. NMR pulse-chase experiments were used to show that ¹³C-enriched glycogen, which had previously been accumulated by the cells under nitrogen-limited growth at low salinities, could be utilized for the synthesis of glucosylglycerol when the cells were abruptly transferred to hypersaline media, but only in the light. It was also shown that the accumulation of glucosylglycerol in the light occurred on a time scale similar to that of cell doubling. Depletion of glucosylglycerol when cells abruptly transferred to lower salinities appeared to be rapid—the intracellular pool of this osmoregulant was decreased 2-fold within 2 hours of hypotonic shock.     

Insulin-stimulated translocation of glucose transporters in the isolated rat adipose cells: Characterization of subcellular fractions

Insulin stimulates glucose transport in rat adipose cells through the translocation of glucose transporters from an intracellular pool to the plasma membrane. A detailed characterization of the morphology, protein composition and marker enzyme content of subcellular fractions of these cells, prepared by differential ultracentrifugation, and of the distribution of glucose transporters among these fractions is now described. Glucose transporters were measured using specific d-glucose-inhibitable [³H]cytochalasin B binding. In the basal state, roughly 90% of the cells' glucose transporters are associated with a low-density microsomal, Golgi marker enzyme-enriched membrane fraction. However, the distributions of glucose transporters and Golgi marker enzyme activities over all fractions are clearly distinct. Incubation of intact cells with insulin increases the number of glucose transporters in the plasma membrane fraction 4–5-fold and correspondingly decreases the intracellular pool, without influencing any other characteristics of the subcellular fractions examined or the estimated total number of glucose transporters (3.7·10⁶/cell). Insulin does not influence the K_d of the glucose transporters in the plasma membrane fraction for cytochalasin B binding (98 nM), but lowers that in the intracellular pool (from 141 to 93 nM). The calculated turnover numbers of the glucose transporters in the plasma membrane vesicles from basal and insulin-stimulated cells are similar (15·10³ mol of glucose/min per mol of transporters at 37°C), whereas insulin appears to increase the turnover number in the plasma membrane of intact cells roughly 4-fold. These results suggest that (1) the intracellular pool of glucose transporters may comprise a specialized membrane species, (2) intracellular glucose transporters may undergo conformational changes during their cycling to the plasma membrane in response to insulin, and (3) the translocation of glucose transporters may represent only one component in the mechanism through which insulin regulates glucose transport in the intact cell.     

Regulation of Tryptophan Biosynthetic Enzymes in Neurospora crassa

The formation of enzymatic activities involved in the biosynthesis of tryptophan in Neurospora crassa was examined under various conditions in several strains. With growth-limiting tryptophan, the formation of four enzymatic activities, anthranilic acid synthetase (AAS), anthranilate-5-phosphoribosylpyrophosphate phosphoribosyl transferase (PRAT), indoleglycerol phosphate synthetase (InGPS), and tryptophan synthetase (TS) did not occur coordinately. AAS and TS activities began to increase immediately, whereas PRAT and InGPS activities began to increase only after 6 to 12 hr of incubation. In the presence of amitrole (3-amino-1,2,4-triazole), the formation of TS activity in a wild-type strain was more greatly enhanced than were AAS and InGPS activities. With a tr-3 mutant, which ordinarily exhibits an elevated TS activity, amitrole did not produce an increase in TS activity greater than that observed on limiting tryptophan. With tr-3 mutants, the increased levels of TS activity could be correlated with the accumulation of indoleglycerol in the medium; prior genetic blocks which prevented or reduced the synthesis of indoleglycerol also reduced the formation of TS activity. The addition of indoleglycerol to cultures of a double mutant (tr-1, tr-3) which could not synthesize indoleglycerol markedly stimulated the production of TS activity but not PRAT activity; the production of TS activity reached the same level with limiting or with excess tryptophan. A model explaining these and other related observations on enzyme formation in N. crassa is proposed.     

Light-induced Changes in the Conformation and Configuration of the Thylakoid Membrane of Ulva and Porphyra Chloroplasts in Vivo

The ultrastructural basis of light-induced transmission and light scattering changes of thalli of Ulva and Porphyra were investigated by high resolution electron microscopy and microdensitometry. The results show that upon illumination of dark thalli (a) a reduction in thickness of thylakoid membranes (conformational change), (b) a more regular ordering, and (c) flattening of the thylakoids (configurational changes) have occurred. An explanation for the observed conformational and configurational changes was proposed in terms of correlated changes in ionic environment and osmotic properties of chloroplasts in vivo which are initiated by photosynthetic reactions.     

Localization and characterization of chromatin within the interphase nucleus of Amoeba proteus by means of in situ centrifugation and radioautography

Centrifugation of living Amoeba proteus labeled with ³H-thymidine permits the identification by electron microscopic radioautography of chromatin in the interphase nucleus by segregating (through centrifugation-induced stratification) the relatively dilute chromatin from the remainder of the nuclear contents. This procedure reveals that the bulk of the chromatin is in the form of a network of 800 to 900 Å fibrils that are moved by centrifugation to a region just centripetal to the rapidly sedimenting nucleoli. — There is a surprising absence of ³H-thymidine labeling associated with the numerous A. proteus nucleoli, raising the possibility that in this organism the genes specifying ribosomal RNA are non-nucleolar. ³H-thymidine label also is absent from nuclear helixes, membranes, and all other recognizable nuclear regions.