Albumin endocytosis via megalin in astrocytes is caveola- and Dab-1 dependent and is required for the synthesis of the neurotrophic factor oleic acid

The synthesis and release of the neurotrophic factor oleic acid requires internalization of albumin into the astrocyte, which is mediated by megalin. In this study, we show that the binding and internalization of albumin involve its interaction with megalin, caveolin-1, caveolin-2 and cavin, but not with clathrin in astrocytes from primary culture. Electron microscopy analyses revealed albumin-gold complexes localized in caveolae, but not in clathrin-coated vesicles. Neither chlorpromazine nor silencing clathrin expression modified albumin uptake. Silencing caveolin-1 strongly reduced the binding and internalization of albumin and the distribution of megalin in the plasma membrane. However, silencing caveolin-2 only decreased albumin internalization, suggesting that caveolin-1 is responsible for megalin recruitment to the caveolae and that caveolin-2 participates in caveolae internalization. In most tissues, the cytosolic adaptor protein disabled (Dab)-2 connects megalin to clathrin, astrocytes lack Dab-2; instead, they express Dab-1, which interacts with caveolin-1 and megalin and is required for albumin internalization. The transcytosis of albumin in astrocytes, including the passage through the endoplasmic reticulum, which is a compulsory step for oleic acid synthesis, was confirmed by electron microscopy analyses. Thus, whereas silencing clathrin did not modify the synthesis and release of oleic acid, the knock-down of caveolin-1, caveolin-2 and Dab-1 strongly reduced the synthesis and release of this neurotrophic factor. In conclusion, caveola-mediated endocytosis of albumin requires megalin and the adaptor protein Dab-1 in cultured astrocytes. Albumin endocytosis may be a key step in brain development because it stimulates the synthesis of oleic acid, which in turn promotes neuronal differentiation.     

Effect of high-fat diet during gestation, lactation, or postweaning on physiological and behavioral indexes in borderline hypertensive rats

Maternal obesity is becoming more prevalent. We used borderline hypertensive rats (BHR) to investigate whether a high-fat diet at different stages of development has adverse programming consequences on metabolic parameters and blood pressure. Wistar dams were fed a high- or low-fat diet for 6 wk before mating with spontaneously hypertensive males and during the ensuing pregnancy. At birth, litters were fostered to a dam from the same diet group as during gestation or to the alternate diet condition. Female offspring were weaned on either control or "junk food" diets until about 6 mo of age. Rats fed the high-fat junk food diet were hyperphagic relative to their chow-fed controls. The junk food-fed rats were significantly heavier and had greater fat pad mass than those rats maintained on chow alone. Importantly, those rats suckled by high-fat dams had heavier fat pads than those suckled by control diet dams. Fasting serum leptin and insulin levels differed as a function of the gestational, lactational, and postweaning diet histories. Rats gestated in, or suckled by high-fat dams, or maintained on the junk food diet were hyperleptinemic compared with their respective controls. Indirect blood pressure did not differ as a function of postweaning diet, but rats gestated in the high-fat dams had lower mean arterial blood pressures than those gestated in the control diet dams. The postweaning dietary history affected food-motivated behavior; junk food-fed rats earned less food pellets on fixed (FR) and progressive (PR) ratio cost schedules than chow-fed controls. In conclusion, the effects of maternal high-fat diet during gestation or lactation were mostly small and transient. The postweaning effects of junk food diet were evident on the majority of the parameters measured, including body weight, fat pad mass, serum leptin and insulin levels, and operant performance.     

Glycosyltransferase Function in Core 2-Type Protein O Glycosylation

Three glycosyltransferases have been identified in mammals that can initiate core 2 protein O glycosylation. Core 2 O-glycans are abundant among glycoproteins but, to date, few functions for these structures have been identified. To investigate the biological roles of core 2 O-glycans, we produced and characterized mice deficient in one or more of the three known glycosyltransferases that generate core 2 O-glycans (C2GnT1, C2GnT2, and C2GnT3). A role for C2GnT1 in selectin ligand formation has been described. We now report that C2GnT2 deficiency impaired the mucosal barrier and increased susceptibility to colitis. C2GnT2 deficiency also reduced immunoglobulin abundance and resulted in the loss of all core 4 O-glycan biosynthetic activity. In contrast, the absence of C2GnT3 altered behavior linked to reduced thyroxine levels in circulation. Remarkably, elimination of all three C2GnTs was permissive of viability and fertility. Core 2 O-glycan structures were reduced among tissues from individual C2GnT deficiencies and completely absent from triply deficient mice. C2GnT deficiency also induced alterations in I-branching, core 1 O-glycan formation, and O mannosylation. Although the absence of C2GnT and C4GnT activities is tolerable in vivo, core 2 O glycosylation exerts a significant influence on O-glycan biosynthesis and is important in multiple physiological processes.Protein O glycosylation is a posttranslational modification implicated in a wide range of physiological processes, including cell adhesion and trafficking, T-cell apoptosis, cell signaling, endocytosis and pathogen-host interaction (1, 6, 27, 30, 54, 61, 71). Core-type protein O glycosylation is initiated in the secretory pathway by the covalent addition of a N-acetylgalactosamine (GalNAc) to the hydroxyl group of serine or threonine residues by one of multiple polypeptide GalNAc transferases (ppGalNAcTs) (20, 44, 57, 58). After linkage of the GalNAc monosaccharide to serine or threonine, other glycosyltransferases sequentially and sometimes competitively elaborate the repertoire of O-glycan structures to include different core subtypes (31, 42, 48, 49).The core 2 β1,6-N-acetylglucosaminyltransferases (C2GnTs) and the Core 2 O-glycans they generate are widely expressed among cells of mammalian species. The C2GnTs act after the core 1 β-1,3-galactosyltransferase adds a galactose in a β1,3-linkage to the GalNAc-Ser/Thr generating the initial core 1 O-glycan disaccharide structure (26). Then, one of the three C2GnTs (C2GnT1, C2GnT2, and C2GnT3) can add an N-acetylglucosamine (GlcNAc) in a β1,6-linkage to the GalNAc to initiate what is known as the core 2 O-glycan branch (Fig. ​(Fig.1a)1a) (7, 50, 51, 69). In a distinct pathway, core 3 β-1,3-N-acetylglucosaminyltransferase (C3GnT) can add a GlcNAc to the unmodified GalNAc to generate a core 3 O-glycan (24). In this case, C2GnT2 can add a GlcNAc in β1,6-linkage to the GalNAc of the core 3 O-glycan disaccharide to initiate the formation of a core 4 O-glycan (Fig. ​(Fig.1b)1b) (50, 69). In addition, both C2GnT2 and the I β-1,6-N-acetylglucosaminyltransferase (IGnT) are independently capable of forming branched polylactosamine structures (I-branches) from otherwise linear polylactosamine glycan chains (Fig. ​(Fig.1c)1c) (69).Open in a separate windowFIG. 1.Activity and expression of C2GnTs. (a to c) Monosaccharides are depicted as geometric shapes, with GalNAc as a yellow square, galactose as a yellow circle, and GlcNAc as a blue square. In addition, the vertical arrows indicate that each branch can be further elaborated by additional saccharide linkages. (a) Biantennary core 2 O-glycans are generated when any of the three C2GnTs acts on the core 1 O-glycan disaccharide. (b) C2GnT2 can generate core 4 O-glycans from core 3 O-glycans by adding a GlcNAc to the initiating GalNAc. (c) C2GnT2, in addition to IGnT, also has the ability to generate branched polylactosamine repeats from linear polylactosamine repeats. The figure depicts distal I-branching as the GlcNAc is transferred to the predistal galactose, the preferential I-branching activity of C2GnT2. However, IGnT preferentially has central I-branching activity that adds GlcNAc on the internal galactose in Galβ1→4GlcNAcβ1→3Gal-R (69). (d) RNA expression of murine Gcnt3 (left panel) and Gcnt4 (right panel), which code for C2GnT2 and C2GnT3, respectively, as determined by qPCR. The data on single animals are graphed relative to testes expression. All values are means ± the standard errors of the mean (SEM).C2GnT1-deficient mice have been shown to have an unexpected phenotype first observed as leukocytosis reflecting neutrophilia (14). This appears to be due to a severe but selective defect in selectin ligand biosynthesis among myeloid cells, leading to decreased recruitment of neutrophils that attenuates inflammation and vascular disease pathogenesis (14, 64). C2GnT1-deficient mice also exhibit a partial reduction in L-selectin ligand biosynthesis on high endothelial venules, resulting in reduced B-cell homing and colonization of peripheral lymph nodes (18, 21). Furthermore, thymic progenitors from C2GnT1-deficient mice have a reduced ability to home to the thymus due to the loss of P-selectin ligands on these cells (46). However, as of yet, C2GnT2 and C2GnT3 have not been similarly investigated, and their biological functions remain to be elucidated. To further investigate why multiple glycosyltransferases capable of core 2 O-glycan formation have been conserved, we have generated mice singly and multiply deficient in the three known C2GnTs and characterized the resulting physiology and alterations to the glycome.     

Aldosterone up‐regulates 12‐ and 15‐lipoxygenase expression and LDL oxidation in human vascular smooth muscle cells

Several lines of evidence suggest that aldosterone excess may have detrimental effects in the cardiovascular system, independent of its interaction with the renal epithelial cells. Here we examined the possibility that aldosterone modulates 12‐ and/or 15‐lipoxygenase (LO) expression/activity in human vascular smooth muscle cells (VSMC), in vitro, thereby potentially contributing to both vascular reactivity and atherogenesis. Following 24 h treatment of VSMC with aldosterone (1 nmol/L), there was a ～2‐fold increase in the generation rate of 12 hydroxyeicosatetraenoic acid (12‐HETE), 70% increase in platelet type 12‐LO mRNA expression (P < 0.001) along with a ～3‐fold increase in 12‐LO protein expression, which were blocked by the mineralocorticoid receptor (MR) antagonists spironolactone (100 nmol/L) and eplerelone (100 nmol/ml). Additionally, aldosterone (1 nmol/L; 24 h) increased the production of 15‐HETE (50%; P < 0.001) and the expression of 15‐LO type 2 mRNA (50%; P < 0.05) (in VSMC). Aldosterone also increased the 12‐ and 15‐LO type 2 mRNA expression in a line of human aortic smooth muscle cells (T/G HA‐VSMC) (60% and 50%, respectively). Aldosterone‐induced 12‐ and 15‐LO type 2 mRNA expressions were blocked by the EGF‐receptor antagonist AG 1478 and by the MAPK‐kinase inhibitor UO126. Aldosterone‐treated VSMC also showed increased LDL oxidation, (～2‐fold; P < 0.001), which was blocked by spironolactone. In conclusion, aldosterone increased 12‐ and 15‐LO expression in human VSMC, in association with increased 12‐ and 15‐HETE generation and enhanced LDL oxidation and may directly augment VSMC contractility, hypertrophy, and migration through 12‐HETE and promote LDL oxidation via the pro‐oxidative properties of these enzymes. J. Cell. Biochem. 108: 1203–1210, 2009. © 2009 Wiley‐Liss, Inc.     

Hip extensor EMG and forelimb/hind limb weight support asymmetry in primate quadrupeds

Higher weight support on the hind limb than forelimb is among the distinctive characteristics of primate quadrupeds. Although often assumed to be due to a more posteriorly positioned whole body center of mass, there are little data to support such a difference. Reynolds (1985. Am J Phys Anthropol 67:335-349) notes that the distribution of forces on the limbs can also be influenced by average limb posture, but suggests that this effect is too small to account for the asymmetry in weight support observed in primates. Instead, he proposes that high hind limb forces are brought about by an active process of shifting weight off the forelimbs and onto the hind limbs through use of hind limb retractors. In this study, we use video records of walking animals to explore the degree to which average limb posture in primates and other quadrupedal mammals deviates from vertical, and use electromyography to test Reynolds' model of hind limb retractor activity and posterior weight shift. The limb posture results indicate that primate forelimbs oscillate about a vertical or slightly retracted axis, and though the hind limbs are slightly protracted, the magnitude of deviation from vertical is too small to have a major effect on weight support distribution. The electromyographic results reveal higher levels of hip extensor activity in antipronograde primates that bear a higher proportion of weight on their hind limbs. This lends support to Reynolds' suggestion that some primates use muscles to actively shift weight onto hind limbs to relieve stresses on forelimbs less well structured for weight support.