Protein associated with human lens 'native' membrane during aging and cataract formation

Plasma membrane contains extrinsic as well as intrinsic proteins. Changes in the extrinsic proteins of lens membrane during human aging and cataract formation have not been investigated in detail. Unlike previous studies which examined lens membrane after being stripped of extrinsic proteins by treatment with chaotropic agents, we have isolated whole or 'native' lens membrane on a sucrose gradient by ultracentrifugation of the total water-insoluble protein. Essentially all of the water-insoluble protein from young to aged to cataractous human lens appeared membrane associated. In young lens (20-37 years old), most of the membrane banded at the 25/45% sucrose interface fraction. This fraction contained relatively little urea-soluble protein and likely represents fiber-cell plasma membrane with its physiologically associated extrinsic and intrinsic proteins. With aging (62-80 years old), about one-third of the membrane, as judged by the distribution of cholesterol, banded at a much higher density (50/58% sucrose fraction). The higher density was due to a great increase in the membrane's relative protein content (protein/cholesterol). Although this extra protein was composed of both urea-insoluble and -soluble fractions, the urea-soluble protein predominated in all lenses. Cataractous lens differed from aged-clear lens in that much more of the total membrane (70-75%) had shifted to the high density and participated in this massive binding of cytosolic proteins. Although alpha-crystallin was the principal extrinsic-membrane protein in young lens, high molecular weight aggregate of modified (acidic) crystallins accounted for the increased extrinsic protein in aging. The extrinsic proteins bound to both clear-aged and cataractous lens membrane were aggregated. In conclusion, examination of human lens native membrane fractions revealed that the association of crystallins with membrane in both aging and cataracts was much greater than previously recognized and most of this increased protein was non-covalently bound to the membrane. Much more of the lens total membrane from cataractous than clear-aged lens was involved in this massive protein association and the protein bound to cataract membrane appeared more highly aggregated.     

Association of a protease (plasminogen activator) with a specific membrane fraction isolated from transformed cells

The intracellular distribution of specific protease, plasminogen activator (PA), has been examined in Rous sarcoma virus-transformed chick embryo fibroblasts (RSV-CEF). Cellular homogenates were fractionated by differential centrifugation followed by sucrose gradient centrifugation. The activities and the percent distribution of a series of marker enzymes, specific for different subcellular organelles, were compared to those of PA. Normal CEF have been similarly fractionated and the relatively low amount of PA activity present in these cells has been analyzed in terms of its subcellular distribution. A membrane fraction was isolated from the RSV-CEF that contained the bulk of the PA activity and less than 8% of the total cellular protein. The specific activity of the PA in this fraction is 40-fold higher than that of a comparable fraction isolated from companion cultures of normal cells. This fraction contains little or no nuclear and cytoplasmic material and is contaminated only to a relatively small degree with mitochondria, lysosomes, endoplasmic reticulum. Significant amounts of a putative Golgi membrane marker are present in this fraction. The relatively high specific activities of Na+,K+-ATPase, 5'-nucleotidase, and [3H]fucose indicate that the fraction is enriched in surface membrane. Further purification of the fraction by equilibrium centrifugation on shallow sucrose gradients reduces further the contaminating activities and results in a PA distribution that closely parallels the distribution of the membrane enzyme, 5'-nucleotidase. PA was not released from its membrane association by hypotonic and hypertonic extraction and ultrasonication, while granule-bound enzymes were released by these treatments. The PA activity from hamster SV40 cells fractionated the same way as that of RSV-CEF. These results suggest that a protease that is dramatically enhanced upon malignant transformation is associated with "plasma membrane-like" elements of the cell and may serve as an intrinsic modifier of cell surface proteins after malignant transformation.     

Purification of gamma-crystallin from human lenses by acetone precipitation method

PURPOSE: The aim of this study was to develop a new purification method for human lens gamma-crystallin by utilizing its unique property of remaining soluble during acetone precipitation of water soluble (WS) proteins. METHODS: The WS protein fractions from lenses of donors of different ages were precipitated with 50% acetone (v/v) and the supernatant and precipitated protein fractions were collected following centrifugation. Among lens crystallins, gamma-crystallin remained soluble (recovered in the supernatant following centrifugation) while other crystallins were precipitated. To determine the recovery of maximal levels of gamma-crystallin as soluble protein during acetone precipitation, the WS proteins were precipitated under different conditions, and both supernatant and precipitated fractions were quantified for proteins and analyzed by size-exclusion chromatographic and Western blot methods. Based on these results, a three-step purification procedure for gamma-crystallin was developed which consisted of acetone precipitation followed by preparative isoelectric focusing (IEF) and size-exclusion HPLC of the soluble fraction. RESULTS: During precipitation of WS proteins by 50% (v/v) acetone, only gamma-crystallin remained soluble. The identity of gamma-crystallin was based on its Mr of 20 kDa on SDS-PAGE, co-elution with lens homogenate gamma-crystallin during a size-exclusion Agarose chromatography, immunoreactivity with anti-gamma-crystallin antibody on a Western blot and an overlap of its partial N-terminal sequence with gammaC-crystallin. A three-step procedure, as described above, provided a highly purified preparation of gammaC-crystallin from the WS protein fraction. The three-step procedure was also utilized to recover a highly purified human lens recombinant gammaD-crystallin preparation from E. coli lysate. CONCLUSIONS: The unique property of human lens gamma-crystallin of remaining soluble during acetone precipitation can be utilized to purify this crystallin by a three-step procedure. This procedure is also applicable in the purification of recombinant gammaD-crystallin from E. coli lysate.     

The alkane oxidation system of Pseudomonas oleovorans: induction of the alk genes in Escherichia coli W3110 (pGEc47) affects membrane biogenesis and results in overexpression of alkane hydroxylase in a distinct cytoplasmic membrane subfraction

The alkane hydroxylase system of Pseudomonas oleovorans, which catalyses the initial oxidation of aliphatic substrates, is encoded by three genes. One of the gene products, the alkane hydroxylase AlkB, is an integral cytoplasmic membrane protein. Induction leads to the synthesis of 1.5-2% AlkB relative to the total cell protein, both in P. oleovorans and in recombinant Escherichia coli DH1. We present a study on the induction and localization of the alkane hydroxylase in E. coli W3110, which appears to be an interesting host strain because it permits expression levels of AlkB of up to 10-15% of the total cell protein. This expression level had negative effects on cell growth. The phospholipid content of such cells was about threefold higher than that of wild-type W3110. Freeze-fracture electron microscopy showed that induction of the alk genes led to the appearance of membrane vesicles in the cytoplasm; these occurred much more frequently in cells expressing alkB than in the negative control, which contained all of the alk genes except for alkB. Isolation and separation of the membranes of cells expressing alkB by density gradient centrifugation showed the customary cytoplasmic and outer membranes, as well as a low-density membrane fraction. This additional fraction was highly enriched in AlkB, as shown both by SDS-PAGE and enzyme activity measurements. A typical cytoplasmic membrane protein, NADH oxidase, was absent from the low-density membrane fraction. alkB expression in W3110 changed the composition of the phospholipid headgroup in the membrane, as well as the fatty acid composition of the membrane. The major changes occurred in the unsaturated fatty acids: C16:1 and C18:1 increased at the expense of C17:0cyc and C19:0cyc.     

Hybrid bilayer membranes in air and water: infrared spectroscopy and neutron reflectivity studies

In this report we describe the fabrication and characterization of a phospholipid/alkanethiol hybrid bilayer membrane in air. The bilayer is formed by the interaction of phospholipid with the hydrophobic surface of a self-assembled alkanethiol monolayer on gold. We have characterized the resulting hybrid bilayer membrane in air using atomic force microscopy, spectroscopic ellipsometry, and reflection-absorption infrared spectroscopy. These analyses indicate that the phospholipid added is one monolayer thick, is continuous, and exhibits molecular order which is similar to that observed for phospholipid/phospholipid model membranes. The hybrid bilayer prepared in air has also been re-introduced to water and characterized using neutron reflectivity and impedance spectroscopy. Impedance data indicate that when moved from air to water, hybrid bilayers exhibit a dielectric constant and thickness that is essentially equivalent to hybrid bilayers prepared in situ by adding phospholipid vesicles to alkanethiol monolayers in water. Neutron scattering from these samples was collected out to a wave vector transfer of 0.25 A(-1), and provided a sensitivity to changes in total layer thickness on the order of 1-2 A. The data confirm that the acyl chain region of the phospholipid layer is consistent with that observed for phospholipid-phospholipid bilayers, but suggest greater hydration of the phospholipid headgroups of HBMs than has been reported in studies of lipid multilayers.     

Shelf-life of prepeeled potato cultivated, stored, and processed by various methods

The present study was aimed to investigate the effects of indigestible dextrin and polydextrose, soluble dietary fibers with low molecular weight, on lipid metabolism and disaccharidase activities of intestinal mucosa in rats fed a high sucrose diet. Their effects were compared with those of well-known soluble fibers, pectin, and guar gum, and also with an insoluble fiber, cellulose. Dietary fibers added to diets at the 5% (w/w) level were alpha-cellulose, pectin, guar gum, indigestible dextrin, and polydextrose. Male Sprague-Dawley rats were given free access to test diets for 6 weeks. Body weight gain was the lowest in rats fed guar gum, the highest in rats fed cellulose, and in-between in rats fed other diets. Although guar gum, pectin, and indigestible feeding dextrin had lower plasma lipid values than cellulose feeding did, the differences were statistically insignificant. Liver triglyceride of the guar gum-fed group was about a third that of the cellulose-fed group, but although those of rats fed polydextrose, indigestible dextrin, and pectin were lower than that of cellulose, the differences were insignificant. Liver cholesterol and phospholipid concentrations were similar among groups. Daily fecal excretion of total lipid, cholesterol, and bile acids were highest in rats fed guar gum, followed by pectin-fed and cellulose-fed rats, and the lowest in rats fed indigestible dextrin and polydextrose. Jejunal sucrase activity was low in the order of guar-gum, polydextrose, indigestible dextrin, pectin, and cellulose. The results indicate that the hypolipidemic effect of soluble dietary fibers would be lessened with reduction in molecular weight, but that the lower sucrase activity by soluble fibers with low molecular weight might be beneficial for hypoglycemic effect.     

Effect of methylene chain length in phospholipid moiety on blood compatibility of phospholipid polymers

To investigate the effects of the methylene chain length between the phospholipid polar group and the backbone on blood compatibility of a phospholipid polymer, copolymers of omega-methacryloyloxyalkyl phosphorylcholine (MAPC) with n-butyl methacrylate (BMA) were synthesized. The methylene chains were ethylene (n = 2), tetramethylene (n = 4), and hexamethylene (n = 6). Every MAPC copolymer with an MAPC mole fraction in the range of 0.1-0.3 was soluble in ethanol but only swelled in water, and the equilibrium water fraction of the water-swollen MAPC copolymer membrane decreased with the length of the methylene chain. When a rabbit platelet-rich plasma was applied on the MAPC copolymer surface with an 0.1 MAPC mol fraction for 180 min, the number of adhered platelets depended on the length of the methylene chain in the MAPC moiety of the copolymer. The amount of phospholipid adsorbed on the MAPC copolymer from human plasma was larger than that on hydrophobic poly(BMA) and increased with the length of the methylene chain in the MAPC moiety. That is, the reduction of platelet adhesion corresponded to the increase in the amount of phospholipid adsorbed on the MAPC copolymer.     

Pharmacological properties of nicotinic acetylcholine receptors on adrenal chromaffin cells and their modification by hypoxic exposure

To characterize the properties of nicotinic acetylcholine receptors (nAChRs) in autonomic ganglia, we examined specific L-[3H]nicotine binding to membrane fraction prepared from cultured bovine adrenal chromaffin cells, using a modified filtration method. Binding of L-[3H]nicotine to non-treated glass fiber filters interfered with detection of specific binding to the membrane fraction. Presoaking the glass fiber filters in 3% or greater concentrations of polyethyleneimine solution (sixty times higher than the reported concentration) for more than 5 h could reduce the binding of L-[3H]nicotine to the filters to background level. Furthermore, specific L-[3H]nicotine binding to the membrane fraction was detected only when the membrane fraction was prepared in buffer containing no divalent cations such as Ca2+ and Mg2+ (EDTA and EGTA were added) and protease inhibitors. Specific binding of L-[3H]nicotine was saturable and reversible. Scatchard analysis revealed a single class of high affinity binding sites with an average Kd of 8.7 nM and a Bmax of 43.2 fmol/mg protein. Specific binding was sensitive to cholinergic agonists (carbamylcholine and L-nicotine) and ganglionic stimulating agents (lobeline and DMPP), but was resistant to neuromuscular blocking agents (alpha-bungarotoxin, d-tubocurarine) and hexamethonium. These results suggest that high-affinity nicotine binding sites on adrenal chromaffin cells are nAChRs of ganglion-type, which have properties different from nAChRs on the neuromuscular junction but similar to nAChRs in the brain.     

Direct bacterial identification from positive BacT/Alert blood cultures using MicroScan overnight and rapid panels

To resolve the apparent conflict between a lubricating glycoprotein, 'lubricin', as the active ingredient in synovial fluid (SF) and surface-active phospholipid (SAPL) present in SF (and adsorbed to articular cartilage) as the boundary lubricant reducing friction to such low physiological levels, lubricin was isolated from bovine SF following the original procedure of Swann et al. (Arthritis Rheum 1981;24:22-30). Analysis of the lipid extract by thin-layer chromatography and phosphorus determination demonstrated a phospholipid component of 11.1 +/- 1.7% (N = 5) which corresponds very closely to the 9.2-13.0% of lubricin which had hitherto remained unidentified and which has previously been shown to be transferable to the articular surface to impart lubrication. These results would appear to resolve any theoretical conflict in that lubricin is, indeed, an active ingredient within SF. Yet, as a large water-soluble molecule, it really functions as a carrier for the highly insoluble SAPL which it deposits on the articular surface as the oligolamellar layer visualized in previous studies. However, it is this deposited SAPL, rather than lubricin, which actually lubricates.     

Nonclinical model for assessing gastric effects of bisphosphonates

Mechanisms by which ketones potentiate manganese-bilirubin (Mn-BR)-induced cholestasis are unknown. The purpose of the present study was to investigate the effect of methyl isobutyl ketone (MiBK), a widely used ketonic solvent, at the level of the bile canalicular membrane (BCM) and to verify if altered membrane lipid dynamics could be involved in MiBK-potentiated Mn-BR cholestasis. Male Sprague-Dawley rats were exposed 4 hr/day for 3 days to MiBK vapors (200 or 600 ppm). Eighteen hours after the last exposure, manganese (Mn, 4.5 mg/kg) was given i.v. followed 15 min later by bilirubin (BR, 25 mg/kg). Rats were killed 30 min after BR; liver cell plasma membranes (bile canalicular and sinusoidal), microsomes, mitochondria, and cytosol were isolated by differential centrifugation. Lipids were extracted and cholesterol was measured in each fraction. After Mn-BR and MiBK exposure (600 ppm), results indicated a marked increase in BCM cholesterol content compared to rats exposed to air only. This increase was greater than that due to Mn-BR or MiBK given alone. Also, results indicated that cholesterol increased in a dose-related fashion in BCM after MiBK exposure, whereas PM cholesterol remained unaltered. To identify the source of the increased BCM cholesterol and to permit distinction between de novo cholesterol synthesis and subcellular shifts, the hepatic lipid pool was labeled in vivo with [3H]-cholesterol and [2-14C]-mevalonic acid, a cholesterol synthesis precursor. Results showed that after 600 ppm MiBK exposure, 14C-labeled cholesterol was greater than 3H-labeled cholesterol, indicating that the contribution of de novo cholesterol synthesis to the total cholesterol content of the various isolated hepatocellular fractions was more important than the contribution of intracellular pools. Therefore, increased BCM cholesterol content and enhanced accumulation of newly synthesized cholesterol appear to be involved in MiBK potentiation of Mn-BR-induced cholestasis.     

Long-term effect of soluble-fiber foods on postprandial fat metabolism in dyslipidemic subjects with apo E3 and apo E4 genotypes

To determine the long-term effect of soluble fiber on postprandial fat metabolism, we studied 33 dyslipidemic subjects, 16 with apolipoprotein (apo) E3/3 (E3) and 17 with E3/4 or E4/4 (E4) genotypes. They ate preweighed low-fat (20% of energy), high-fiber (> 5.7 g/MJ) diets for two 4-mo periods separated by a 2-mo washout period according to a randomized, crossover design. One diet contained foods rich in insoluble fiber and the other foods rich in soluble fiber. On 1 d during the last 2 wk of each diet, subjects ingested a standard, fiber-free, fatty liquid meal containing retinyl palmitate as a marker of intestinally derived lipoproteins. Plasma samples were obtained at hourly intervals for 10 h. Compared with the insoluble-fiber diet, soluble fiber reduced fasting plasma total cholesterol in both E3 (6.6 +/- 2.1%, P = 0.007)and E4 subjects (5.6 +/- 2.1%, P = 0.017). Soluble fiber increased fecal total bile acid output in both E3 (76 +/- 18%, P < 0.001) and E4 subjects (85 +/- 19%, P < 0.001). The incremental area under the chylomicron triacylglycerol response curve was significantly greater after soluble fiber than after insoluble fiber in E3 (3.56 +/- 0.56 compared with 2.87 +/- 0.38 mmol x h/L, respectively, P = 0.046) but not in E4 subjects (5.19 +/- 0.78 compared with 4.92 +/- 0.81 mmol x h/L). Kinetic analysis suggested an increase in retinyl palmitate absorption in E3 subjects after soluble fiber, but no difference in E4 subjects. These results suggest that a long-term increase in dietary soluble fiber has no effect on postprandial fat metabolism in subjects with an apo E3/4 or E4/4 genotype. However, soluble fiber enhances apparent fat absorption in E3 subjects, which could be due to an increased bile acid pool and increased micelle formation.     

Reconstitution of ciliary membranes containing tubulin

Membranes from the gill cilia of the mollusc Aequipecten irradians may be solubilized readily with Nonidet P-40. When the detergent is removed from the solution by adsorption to polystyrene beads, the proteins of the extract remain soluble. However, when the solution is frozen and thawed, nearly all of the proteins reassociate to form membrane vesicles, recruiting lipids from the medium. The membranes equilibrate as a narrow band (d = 1.167 g/cm3) upon sucrose density gradient centrifugation. The lipid composition of reconstituted membranes (1:2 cholesterol:phospholipids) closely resembles that of the original extract, as does the protein content (45%). Ciliary calmodulin is the major extract protein that does not associate with the reconstituted membrane, even in the presence of 1 mM calcium ions, suggesting that it is a soluble matrix component. The major protein of reconstituted vesicles is membrane tubulin, shown previously to differ hydrophobically from axonemal tubulin. The tubulin is tightly associated with the membrane since extraction with 1 mM iodide or thiocyanate leaves a vesicle fraction whose protein composition and bouyant density are unchanged. Subjecting the detergent-free membrane extract to a freeze-thaw cycle in the presence of elasmobranch brain tubulin or forming membranes by warming the extract in the presence of polymerization-competent tubulin yields a membrane fraction with little incorporated brain tubulin. This suggests that ciliary membrane tubulin specifically associates with lipids, whereas brain tubulin preferentially forms microtubules.     

Lp82 calpain during rat lens maturation and cataract formation

PURPOSE: To measure changes in levels of Lp82 during maturation and selenite cataract formation in rat lens. Lp82 is a lens-specific, calcium-activated isozyme from the calpain family of cysteine proteases (EC 34.22.17). METHODS: Competitive RT-PCR was used to assess Lp82 and m-calpain mRNA concentrations. Immunoblotting and ELISA after DEAE chromatography measured Lp82 and m-calpain protein levels. Casein zymography assessed proteolytic activities in regions and whole lenses from maturing rats. RESULTS: Levels of Lp82 mRNA, protein, and caseinolytic activity decreased more rapidly during maturation of rat lens than for m-calpain. Unexpectedly, the water-insoluble fraction of rat lens contained enzymatically active Lp82. Selenite injection also caused major loss of Lp82 protein during cataract formation. CONCLUSIONS: Lp82 is a proteolytic enzyme likely functioning in early lens development and maturation. The rapid loss of Lp82 activity during lens maturation is probably caused by three factors: autodegradation associated with the proteolysis of soluble and insoluble proteins occurring in the rat lens nucleus, association of Lp82 with the lens insoluble fraction, and loss of Lp82 mRNA. Lp82 may function early in lens maturation along with m-calpain, which then is predominant in the latter stages of maturation. Proteolysis in selenite cataract is partially caused by over-activation of Lp82.     

Soluble and insoluble fiber contents of some Cameroonian foodstuffs

As a result of the lack of reliable data on the fiber content of African foodstuffs, a study to determine the dietary fiber contents (soluble, insoluble and total) on a dry weight basis of a selected variety of major Cameroonian foods was conducted. The influence of processing and preparation methods on the fiber content was also assessed. Vegetables were found to be the richest source of total dietary fiber (57%), followed by legumes and seeds (30%) and fruits (16.5%). Okro (Hibiscus esculenta), plantain (Musa paradisiaca) and beans (Phaseolus spp) showed varietal differences in their soluble and insoluble fiber content, while methods of processing and preparation significantly influenced the fiber content of cassava (Manihot esculenta), corn (Zea mays) and beans.     

A nuclear membrane-associated DNA complex in cultured mammalian cells capable of synthesizing DNA in vitro

A DNA-nuclear membrane complex has been isolated by two different methods from the nuclei of cultured mouse fibroblast (3T3) cells. One method, utilizing the detergent sarkosyl (sodium lauroyl sarkosinate), yields a DNA-nuclear membrane complex (the M band), which contains virtually all of the DNA in the nuclei. However, treatment of the M band by sonication, vortexing, or freeze-thaw reduces the amount of DNA in the complex by approximately 50-80%, depending upon the phase of the cell cycle from which the complex was extracted. The remaining DNA is tightly bound to the nuclear membrane and resists further shearing procedures. Over 90% of the choline-labeled phospholipid present in nuclei is also found in these sheared M bands. The percentage of DNA associated with the nuclear membrane varies during the cell cycle and correlates well with the onset, continuation, and cessation of DNA synthesis. Thus, although DNA-membrane complexes can be detected throughout the cell cycle, the percentage of DNA bound to membrane increases during late G1 and S and decreases during G2. In addition, there are distinct qualitative differences in the type of DNA present in the membrane fraction, with a more highly d(A-T) rich DNA being present in confluent (G0) cells than in cells during the S phase. This d(A-T) rich DNA may be related to the mouse satellite DNA identified by others. The M band can be separated into two DNA-nuclear membrane subfractions by centrifugation through a continuous sucrose gradient. The relative proportions of these two subfractions depend upon the percentage of sarkosyl present in the M band prior to centrifugation, with complete removal of sarkosyl resulting in a very large increase in the sedimentation velocity of the complex and in the formation of only one fraction. Evidence that this is a complex of DNA with membrane is given by the finding that DNA is dissociated from the complex with Pronase, deoxycholate, or high levels of sarkosyl. Removal of virtually all of the DNA with DNase from this rapidly sedimenting complex does not dissociate any of the phospholipid which still sediments rapidly as a single band. A second method, which yields a DNA-membrane fraction from nuclei, utilizes sedimentation of lysed nuclei to equilibrium in CsCl density gradients. This low-density CsCl fraction contains only 10-15% of the total DNA, but contains most of the nascent DNA, which may be chased into a membrane-free fraction. The DNA-membrane fraction from CsCl gradients possesses properties in common with the M-band fraction and can be converted into an M band. DNA membrane complexes from sucrose gradients, as well as the crude M-band preparation and a non-membrane-associated DNA fraction from nuclei can synthesize DNA in vitro without the addition of an external DNA template or DNA polymerase. In contrast to the activity in the non-membrane-associated DNA fraction, the membrane-associated polymerase activity is strongly stimulated by adenosine triphosphate and is unaffected by ethidium bromide...     

Curare: a preventive of traumatic complications in convulsive shock therapy (including a preliminary report on a synthetic curare-like drug). 1940

Yellow fluorescent lipofuscin deposited in rat kidney was extracted in an aqueous solution and characterized after separation. Centrifugal fractionation of the extract revealed that most of the yellow fluorescence was detected in the 105,000 x g-supernatant, and little in nuclei, cell debris, mitochondria, lysosomes, microsomes and plasma membrane. The yellow fluorescence in the supernatant was fractionated by gel filtration through Sephadex columns into 5 yellow fluorescent fractions A, B (B1, B2 and B3) and C showing the same fluorescence spectra with excitation maximum/emission maximum at 400/620 nm. The components in fraction A were converted into the smaller molecular-weight components in fraction B on treatment with 4 M urea or protease, suggesting that they were proteinaceous. The smallest molecular-weight fluorescent components in fraction C were adherent to solid cellulose materials. The fluorescent components in all the fractions were soluble in water and insoluble in chloroform-methanol, indicating that they were not lipidic materials. The fluorophores in these fractions were kept stable on borohydride treatment, but readily converted into non-fluorescent components on heavy-metal ion treatment. The characteristics of the yellow fluorescence in these fractions were quite different from those of bluish lipofuscin-like fluorophores that may be generated in tissues during lipid peroxidation.     

A proteinase K inhibitor using alpha,beta-unsaturated (dehydro) residues: a presumptive model

PURPOSE: To quantify age-related changes in products of lipid oxidation in human lenses and to relate these changes to membrane hydrocarbon chain structure. Deviation from a well-defined membrane-lipid composition and structure could result in alterations in membrane function and disruption of the homeostasis of the cell. METHODS: Infrared spectroscopy was used to detect lipid compositional and structural changes in human lens membranes associated with age and cataracts. RESULTS: Lipid oxidation increased linearly threefold relative to total phospholipids in subjects ranging in age between 1 and 85 years, as was evident by increases in trans double bonds, lipid carbonyls, and secondary products. There was no statistical difference between the levels of lipid oxidation in the cortex or nucleus. Lipid hydrocarbon chain order (rigidity) increased from approximately 40% at birth to 70% at 80 years of age. Changes in lipid order correlated with changes in the relative content of membrane phosphatidylcholine and sphingomyelin, and with the level of lipid oxidation. CONCLUSIONS: Lipid oxidation increased linearly and uniformly throughout the human lens with age. The change in lipid oxidation with age correlated to a change in lipid order.     

Placental proteins and steroid hormones in the soluble fraction of human syncytiotrophoblast plasma membrane

Placental protein 5 (PP5), pregnancy-specific glycoprotein (SP1), pregnancy-associated alpha 2-glycoprotein (SP3) and chorionic gonadotrophin could not be demonstrated in appreciable molar quantities in the soluble fraction from microvillous plasma membrane preparations isolated from the syncytiotrophoblast of full-term human placentae. However, progesterone, total oestriol and placental lactogen may have some association with this membrane.     

Metalloproteinases and their inhibitors in squamous cell carcinoma of the hypopharynx: indicators of individual tumor aggressiveness

The physicochemical properties of recombinant hepatitis B surface antigen (r-HBsAg), which was expressed in C127 mammalian cell were studied. Using roller bottle culture in DMEM supplemented with fetal bovine serum, 10-15 mg/L of r-HBsAg was produced with about 31% of purification yield. The purity of r-HBsAg by HPLC was 99.8% and electron microscopic examination showed homogeneous spherical particle with 22 nm in diameter, a morphological characteristic of HBsAg. The density of r-HBsAg by CsCl density gradient method was 1.19 g/ml and the isoelectric point by Mono P HR 5/20 column was 4.6. The analysis of subunit protein pattern using SDS-PAGE followed by scanning densitometry gave 81.3% of S protein and 18.7% of pre-S protein. Fluorophore-assisted-carbohydrate-electrophoresis analysis showed the relative amount of carbohydrate to protein was 1.7% and its major component was N-acetyl glucosamine, which was about 39% of total carbohydrate. The relative amount of lipid to protein determined by vanillin phosphoric acid method was 32.5% and its major component was phospholipid, which was about 70% of total lipid. The physicochemical properties of C127 mammalian cell-derived r-HBsAg are similar to those of p-HBsAg, suggesting that the r-HBsAg can be used in developing a new preventive vaccine against hepatitis B.     

Novel configurations of the hammerhead ribozyme: increased activity and reduced magnesium ion requirement

Generally, stool weight is significantly increased by adding sources of insoluble fiber to the diet. Comparable amounts of fiber provided by wheat and oat brans have the same effect on daily stool output, even though > 90% of wheat bran fiber but only 50-60% of oat bran fiber is insoluble. To determine the bases for these increases in stool weight, stool samples collected from 5 men in 2 constant diet studies that determined the effects of wheat and oat brans on large-bowel physiology were fractionated by using a physicochemical procedure into plant, bacterial, and soluble fractions, which were weighed and analyzed for sugar content and composition. Nitrogen, crude fat, and ash outputs were also determined. Wheat bran increased the fecal concentration of sugars and mass of plant material more than did oat bran, whereas oat bran increased fecal bacterial mass more. Each fiber source increased nitrogen, ash, and fat excretion, but excretion of fat was greater with oat bran. The apparent digestibility of plant-derived neutral sugars decreased significantly when wheat but not oat bran was consumed. The apparent digestibility of neutral sugars provided by wheat bran was 56%; the apparent digestibility of those provided by oat bran was 96%. We conclude that bacteria and lipids are major contributors to the increase in stool weight with oat bran consumption, whereas undigested plant fiber is responsible for much of the increase in stool weight with wheat bran consumption. Results are consistent with the hypothesis that oat bran increases stool weight by providing rapidly fermented soluble fiber in the proximal colon for bacterial growth, which is sustained until excretion by fermentation of the insoluble fiber.