A reliable lacZ expression reporter cassette for multipurpose, knockout-first alleles

Alteration of the mouse genome through homologous recombination in embryonic stem (ES) cells is the most accurate and versatile way to dissect gene function in a vertebrate model. Most often, a selectable marker is used to create a knockout allele by replacing an essential part of the gene. However, knockout strategies are limited because the mutation is present constitutively. Conditional approaches based on the Cre-loxP site-specific recombination (SSR) system address this limitation; however, it requires that all parts of the targeted gene remain in ES cells. Here we report success with a "knockout-first" strategy that ablates gene function by insertion of RNA processing signals without deletion of any of the target gene. Incorporation of site-specific recombination target sites creates a multipurpose allele for both knockout and conditional applications.     

Evidence for vesicles that mediate long-chain fatty acid uptake by human microvascular endothelial cells

This study analyzes the mechanisms of long-chain fatty acid (LCFA) uptake by human microvascular endothelial cells (HMEC). The time course revealed the presence of an early, carrier-mediated uptake component and a later component mediated by clathrin-coated vesicles (CCV) and caveolae, as evidenced by three different experimental approaches: 1) significant reduction of [3H]oleate uptake over 5 min by either inhibition of CCV formation by potassium depletion or hypertonic medium, or disruption of caveolae by filipin III or cyclodextrin. 2) Co-localization of intracellular 12-(N-methyl)-N-[(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino]octadecanoic acid with CCV and caveolae using confocal laser scanning microscopy. 3) Enrichment of [3H]oleate in a subcellular fraction containing CCV and caveolae. Within 10 min, more than 75% of intracellular [3H]oleate remained unmetabolized, suggesting that HMEC preferentially shuttle LCFA through the cell using CCV and caveolae as carriers. The uptake of albumin paralleled that of oleate within the first 10 min, suggesting internalization of at least some LCFA bound to albumin. Compared to oleate and albumin, the uptake of sucrose and dextran was low, indicating a potential minor contribution of fluid-phase endocytosis to the total vesicular LCFA uptake. The data indicate a previously unrecognized role of both CCV and caveolae for the uptake of LCFA by HMEC.     

Sorting nexin 17 prevents lysosomal degradation of β1 integrins by binding to the β1-integrin tail

Integrin functions are controlled by regulating their affinity for ligand, and by the efficient recycling of intact integrins through endosomes. Here we demonstrate that the Kindlin-binding site in the β1-integrin cytoplasmic domain serves as a molecular switch enabling the sequential binding of two FERM-domain-containing proteins in different cellular compartments. When β1 integrins are at the plasma membrane, Kindlins control ligand-binding affinity. However, when they are internalized, Kindlins dissociate from integrins and sorting nexin 17 (SNX17) is recruited to free β1-integrin tails in early endosomes to prevent β1-integrin degradation, leading to their recycling back to the cell surface. Our results identify SNX17 as a β1-integrin-tail-binding protein that interacts with the free Kindlin-binding site in endosomes to stabilize β1 integrins, resulting in their recycling to the cell surface where they can be reused.     

Significantly greater antioxidant anticancer activities of 2,3-dehydrosilybin than silybin

Silybin or silymarin extract has been used to treat liver diseases, and has now been entered into clinical trials for cancer treatment. Here, we compared antioxidant and anticancer activities between silybin and its oxidized form 2,3-dehydrosilybin (DHS). With IC50 at three-fold lower concentrations than silybin, DHS inhibited reactive oxygen species generation in glucose-glucose oxidase system and HepG2 cells. Compared with silybin, DHS elicited greater protection against H2O2-induced HepG2 cell death and galactosamine-induced liver injury in vivo. It is known that oxidants induce releases of metalloproteinases (MMP)-2,-9 which are responsible for invasive and metastasis potentials of transformed cells. DHS at 10 microM markedly inhibited MMP-2,-9 releases as well as invasiveness, while silybin at 90 microM had marginal effects. DHS but not silybin at 30 microM induced apoptosis and loss of mitochondrial membrane potentials. LD50 of DHS was five-fold lower than that of silybin. Our data suggest that DHS may be more useful therapeutically than silybin.     

Uptake of long chain fatty acids is regulated by dynamic interaction of FAT/CD36 with cholesterol/sphingolipid enriched microdomains (lipid rafts)

Background  

Mechanisms of long chain fatty acid uptake across the plasma membrane are important targets in treatment of many human diseases like obesity or hepatic steatosis. Long chain fatty acid translocation is achieved by a concert of co-existing mechanisms. These lipids can passively diffuse, but certain membrane proteins can also accelerate the transport. However, we now can provide further evidence that not only proteins but also lipid microdomains play an important part in the regulation of the facilitated uptake process.     

Antiarrhythmic drugs impair hepatic uptake and secretory function by different mechanisms in the isolated perfused rat liver

In the present study the effect of various antiarrhythmic drugs on hepatic perfusion parameters, uptake capacity of organic anions and biliary secretion using the isolated perfused rat liver was examined. Infusion of verapamil (VP), diltiazem, N-propyl-ajmaline (NPAB), and quinidine at pharmacological doses induced consistently a 1.4-1.6-fold increase in portal pressure accompanied by a approximately 60% decrease in bile flow and a approximately 65% inhibition of biliary taurocholate (TC) excretion. Furthermore, hepatic uptake of oxygen, bromosulphthalein (BSP), and TC was significantly reduced. All these effects were dose-dependent and reversible upon withdrawal of the drugs. Studies of the hepatic circulation using a Trypan blue staining technique demonstrated a patchy perfusion pattern during infusion of the antiarrhythmic drugs as compared to the homogenously stained control organ. The hemodynamic alterations and the impairment of the hepatic initial uptake function could be entirely prevented by concomitant administration of the vasodilator papaverine. Bile flow and biliary TC excretion, however, were still inhibited under these conditions. The present results indicate that antiarrhythmic drugs produce cholestasis in the isolated perfused rat liver independently of their adverse effect on hepatic hemodynamics.     

Transmembrane transport of fatty acids in the heart

Summary Although fatty acid uptake by the myocardium is rapid and efficient, the mechanism of their transmembrane transport has been unclear. Fatty acids are presented to the plasma membrane of cardiomyocytes as albumin complexes within the plasma. Since albumin is not taken up by the cells, it was postulated that specific high affinity binding sites at the sarcolemma may mediate the dissociation of fatty acids from the albumin molecules, before they are transported into the cells. In studies with a representative long-chain fatty acid, oleate, it was in fact shown that fatty acids bind with high affinity to isolated plasma membranes of rat heart myocytes revealing a K_D of 42 nM. Moreover, a specific membrane fatty acid-binding protein (MFABP) was isolated from these membranes. It had a molecular weight of 40 kD, an isoelectric point of 9.0, and lacked carbohydrate or lipid components. Binding to a specific membrane protein might represent the first step of a carrier mediated uptake process. Therefore, the uptake kinetics of oleate by isolated rat heart myocytes was determined under conditions where only cellular influx and not metabolism occurred. Uptake revealed saturation kinetics and was temperature dependent which were considered as specific criteria for a facilitated transport mechanism. For evaluation whether uptake is mediated by MFABP, the effect of a monospecific antibody to this protein on cellular influx of oleate was examined. Inhibition of uptake of fatty acids but not of glucose by the antibody to MFABP indicated the physiologic significance of this protein as transmembrane carrier in the cellular uptake process of fatty acids. Such a transporter might represent an important site for the metabolic regulation of fatty acid influx into the myocardium.     

The metabolic capacity of lipid droplet localized acyl-CoA synthetase 3 is not sufficient to support local triglyceride synthesis independent of the endoplasmic reticulum in A431 cells

ACSL3 is the only long chain fatty acyl-CoA synthetase consistently found on growing and mature lipid droplets (LDs), suggesting that this specific localization has biological relevance. Current models for LD growth propose that triglycerides are synthesized by enzymes at the LD surface, with activated fatty acids provided by LD localized ACSL3, thus allowing growth independent of the ER. Here, we tested this hypothesis by quantifying ACSL3 on LDs from human A431 cells.RNAi of ACSL3 reduced the oleoyl-CoA synthetase activity by 83%, suggesting that ACSL3 is by far the dominant enzyme of A431 cells. Molar quantification revealed that there are 1.4 million ACSL3 molecules within a single cell. Metabolic labeling indicated that each ACSL3 molecule contributed a net gain of 3.1 oleoyl-CoA/s. 3D reconstruction of confocal images demonstrated that 530 individual lipid droplets were present in an average oleate fed A431 cell. A representative single lipid droplet with a diameter of 0.66?μm contained 680 ACSL3 molecules on the surface. Subcellular fractionation showed that at least 68% of ACSL3 remain at the ER even during extensive fatty acid supplementation. High resolution single molecule microscopy confirmed the abundance of cytoplasmic ACSL3 outside of LDs. Model calculations for triglyceride synthesis using only LD localized ACSL3 gave significant slower growth of LDs as observed experimentally.In conclusion, although ACSL3 is an abundant enzyme on A431 LDs, the metabolic capacity is not sufficient to account for LD growth solely by the local synthesis of triglycerides.     

Cellular influx of sulfobromophthalein by the biliary epithelium carcinoma cell line Sk-Cha-1 reveals kinetic criteria of a carrier-mediated uptake mechanism

Cellular uptake of the cholephilic organic anion sulphobromophthalein (BSP) by the human biliary epithelium carcinoma cell line Sk-Cha-1 was examined at 37 degrees C. In confluent monolayer cultures the cellular influx rate of increasing concentrations of [35S]BSP followed saturation kinetics with a Km value of 18 microM and a Vmax value of 243 pmol.min-1.mg protein-1. Uptake of [35S]BSP was competitively inhibited by the presence of bilirubin diglucuronide, but not by taurocholate or cholate. Furthermore, uptake was temperature dependent with maximal cellular influx rates at 37 degrees C.