Effects of Anoectochilus formosanus Hayata extract and glucocorticoid on lung maturation in preterm rats.

We investigated the effects of maternal administration of Anoectochilus formosanus extract and dexamethasone on lung maturation in preterm rats. A. formosanus group mothers were tube-fed A. formosanus extract (300 mg/kg body wt./day) for 7 days from days 12-18 of gestation. Dexamethasone group mothers were injected intraperitoneally with dexamethasone (0.2 mg/kg body wt.) in saline on day 18 of gestation. Control group mothers were similarly injected with saline alone. On day 19 of gestation, fetuses were delivered by cesarean section. A. formosanus treatment significantly increased the fetal lung/body weight ratio, as compared to dexamethasone treatment. Saturated phosphatidylcholine levels in fetal lung tissue and growth hormone levels in maternal serum were significantly increased in the A. formosanus- and dexamethasone-treated groups as compared to controls. The histological appearance of preterm rat lungs revealed extensive branching of intermediate airways, denser mesenchyme, and more epithelial tubules in the dexamethasone and A. formosanus groups as compared with the control group. These results suggest that antenatal A. formosanus treatment may play a role in accelerating fetal rat lung maturation.

Effects of lectins on calcification by vesicles isolated from aortas of cholesterol-fed rabbits.

Advanced vascular calcification in atherosclerosis weakens arterial walls, thereby imposing a serious rupturing effect. However, the mechanism of dystrophic calcification remains unknown. Although accumulating morphological and biochemical evidence reveals a role for calcifiable vesicles in plaque calcification, the mechanism of vesicle-mediated calcification has not been fully explored. To study whether vesicles' membrane components, such as carbohydrates, may have a role in vesicle-mediated calcification, the effect of sugar-binding lectins on calcification was investigated. Atherosclerosis was developed by feeding rabbits with a diet supplemented with 0.5% cholesterol and 2% peanut oil for 4 months. Calcifiable vesicles were then isolated from thoracic aortas by collagenase digestion. The histological examination of aortas with hematoxylin counter-staining indicated abnormal formation of large plaques enriched with macrophage-derived foam cells. Fourier transform spectroscopy revealed mild calcification in aortas indicating that advanced stages of heavy calcification have yet to be reached. However, vesicles isolated from the aortas were capable of calcification in the presence of physiological levels of Ca(2+), Pi, and ATP. Thus, at this stage of atherosclerosis, aortas may start to produce calcifiable vesicles, but at a level insufficient for substantial formation of mineral in aortas. The assessments by FT-IR analysis and Alizarin red staining indicated that concanavalin A (Con A) substantially increased mineral formation by isolated vesicles. Con A also exerted a marked stimulatory effect on (45)Ca and (32)Pi deposition in a dose-dependent fashion with a half-maximal effect at 6-10 microg/ml. Either alpha-methylmannoside or alpha-methylglucoside, but not mannitol, at 10 mM abolished the stimulation. Con A stimulation was abolished after Con A was removed from calcifying media, suggesting that covalent binding may not be involved in the effect. Galactosides appear to also be implicated in (45)Ca and (32)Pi deposition since Abrus precartorius agglutinin, which specifically binds galactosides, enhanced the deposition. Neither wheat-germ agglutinin that binds N-acetylglucoside nor N-acetylgalactoside-specific Helix pomatia agglutinin was effective, suggesting that the acetylated forms of carbohydrate moieties are either absent in vesicles or may not be involved in calcification. None of these lectins exerted an effect on ATPase. Thus, the effects of lectins appeared to be mediated through interactions with carbohydrate moieties of calcifiable vesicles. Whether stimulation of vesicle-calcification by lectins is of pathological significance in atherosclerotic calcification requires further investigation.

Isolation of calcifiable vesicles from aortas of rabbits fed with high cholesterol diets.

Advanced arterial wall calcification in atherosclerosis imposes a serious rupturing effect on the aorta. However, the mechanism of dystrophic calcification linked to hyperlipidemia, that causes atherosclerosis remains unknown. Emerging morphological and biochemical evidence reveals that calcifiable vesicles may have a role in plaque calcification. To determine whether a high cholesterol diet can induce arterial calcification and produce or activate calcifiable vesicles in aortas, a rabbit model was used. After 2 months of daily high lipid feeding (supplemented with 2% cholesterol and 6% peanut oil), typical atherosclerotic lesions developed. However, the mineral, if present in aortas, was insufficient to be detected by Fourier transform-infrared spectroscopy (FT-IR) or alizarin red staining, indicative of a non-calcifying stage of atherosclerosis. Small segments of thoracic aortas were digested in a crude collagenase solution to release calcifiable vesicles. Vesicles were also isolated from normal aortas as control to consider the possibility that membrane vesicles may be produced by crude collagenase digestion, which could cause the degradation of some cells. Calcifiable vesicles were precipitated at 300,000 x g after subcellular particles were removed by centrifugation at 30,000 x g. Calcifiability of isolated vesicles was then tested using calcifying media containing physiological levels of Ca2+ and Pi and 1 mM ATP. Electron microscopic observations showed that the isolated vesicles were heterogeneous in size and shape and capable of depositing electron dense particles. Fourier transform infrared spectroscopic analysis of the deposited particles revealed the presence of an amorphous mineral phase. The spectroscopic mineral to matrix ratios, related to the amount of mineralization, indicated that vesicles from cholesterol-fed rabbits produced more minerals than control vesicles obtained from the normal aortas. Alizarin red staining for mineral further demonstrated substantially higher calcifiability of the experimental vesicles. A 3-5 h exposure of the vesicles to calcifying media caused significant deposition of 45Ca and 32Pi in a vesicle protein-concentration dependent manner. Similar to previously reported observations with human atherosclerotic aorta vesicles, rabbit vesicles were enriched in ATP-hydrolyzing enzymes including Mg2+- or Ca2+-ATPase and NTP pyrophosphohydrolase that are implicated in normal and pathological calcification. Altogether, these observations suggest that accumulation of the released calcifiable vesicles, as a result of high cholesterol diets, may have a role in dystrophic calcification in hyperlipidemia-related atherosclerosis.

Calcification of isolated matrix vesicles and reconstituted vesicles from fetal bovine cartilage.

Ca deposition by isolated matrix vesicles from fetal calf growth plate cartilage and by a deoxycholate extract from matrix vesicles that included their phosphatase was studied under defined in vitro conditions. Electron microscopy showed that after removal of deoxycholate and lyophilization of the vesicle extract, new vesicles were reconstituted, often with multiple membrane layers. Both intact calf vesicles and reconstituted vesicles initiated Ca deposition maximally when supplied with ATP, GTP, CTP, or UTP. Only nucleoside triphosphates supported Ca deposition well; mono- and diphosphoesters, although hydrolyzed, were ineffective as substrates. Nucleoside triphosphates supported Ca deposition even if the final [Ca] X [P] reached in the reaction mixture was below a metastable level (3.5 mM2), suggesting that matrix vesicles or reconstituted vesicles promote calcification by localizing Ca or PO4 or both. ATP or GTP supported Ca deposition readily at concentrations ranging from 0.25 to 1.0 mM but, at 2.5 and 5.0 mM, Ca deposition was inhibited. The ATPase of intact matrix vesicles and reconstituted vesicles was stimulated by addition of Ca2+ and Mg2+. Ca deposition did not require additional Mg2+. These results lend support to the hypothesis that matrix vesicles and their phosphatases play an important role in mineralization.