Calpain system regulates muscle mass and glucose transporter GLUT4 turnover

The experiments in this study were undertaken to determine whether inhibition of calpain activity in skeletal muscle is associated with alterations in muscle metabolism. Transgenic mice that overexpress human calpastatin, an endogenous calpain inhibitor, in skeletal muscle were produced. Compared with wild type controls, muscle calpastatin mice demonstrated normal glucose tolerance. Levels of the glucose transporter GLUT4 were increased more than 3-fold in the transgenic mice by Western blotting while mRNA levels for GLUT4 and myocyte enhancer factors, MEF 2A and MEF 2D, protein levels were decreased. We found that GLUT4 can be degraded by calpain-2, suggesting that diminished degradation is responsible for the increase in muscle GLUT4 in the calpastatin transgenic mice. Despite the increase in GLUT4, glucose transport into isolated muscles from transgenic mice was not increased in response to insulin. The expression of protein kinase B was decreased by approximately 60% in calpastatin transgenic muscle. This decrease could play a role in accounting for the insulin resistance relative to GLUT4 content of calpastatin transgenic muscle. The muscle weights of transgenic animals were substantially increased compared with controls. These results are consistent with the conclusion that calpain-mediated pathways play an important role in the regulation of GLUT4 degradation in muscle and in the regulation of muscle mass. Inhibition of calpain activity in muscle by overexpression of calpastatin is associated with an increase in GLUT4 protein without a proportional increase in insulin-stimulated glucose transport. These findings provide evidence for a physiological role for calpains in the regulation of muscle glucose metabolism and muscle mass.     

In Vivo Labeling by CD73 Marks Multipotent Stromal Cells and Highlights Endothelial Heterogeneity in the Bone Marrow Niche

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Ions released from a S-PRG filler induces oxidative stress in <Emphasis Type="Italic">Candida albicans</Emphasis> inhibiting its growth and pathogenicity

Candida albicans causes opportunistic fungal infections usually hidden among more dominant bacteria and does not exhibit high pathogenicity in vivo. Among the elderly, due to reduced host resistance to pathogens attributable to immunoscenesence, oral candidiasis is more likely to develop often leading to systemic candidiasis. Surface pre-reacted glass ionomer filler (S-PRG filler) is an ion-releasing functional bioactive glass that can release and recharge six ions which in turn strengthens tooth structure, inhibits demineralization arising from dental caries, and suppresses dental plaque accumulation. However, its effects on C. albicans have never been elucidated. Here, we evaluated the effects of ion released from S-PRG filler on C. albicans. Results show that extraction liquids containing released ions (ELIS) decreased the amount of hydrogen peroxide and catalase activity in C. albicans. Moreover, ELIS presence was found to affect C. albicans: (1) suppression of fungal growth and biofilm formation, (2) prevent adherence to denture base resin, (3) inhibit dimorphism conversion, and (4) hinder the capability to produce secreted aspartyl proteinase. Taken together, our findings suggest that ELIS induces oxidative stress in C. albicans and suppresses its growth and pathogenicity. In this regard, we propose that ELIS has the potential to be clinically used to help prevent the onset and inhibition of oral candidiasis among the elderly population.     

Biosynthesis of C-labeled branched polysaccharides by pestalotiopsis from C-labeled glucoses and the mechanism of formation

Biosynthesis of branched glucan by Pestalotiopsis from media containing D-(1-¹³C)glucose, D-(2-¹³C)glucose, D-(4-¹³C)glucose, D-(6-¹³C)glucose or a mixture of D-(1-¹³C)glucose and D-(2-¹³C)glucose was carried out to elucidate biosynthetic mechanism of branched polysaccharides. ¹³C NMR spectra of the labeled polysaccharides were determined and assigned. Analysis of ¹³C NMR spectra of glucitol acetates obtained from hydrolysates of the labeled branched polysaccharides indicated that transfer of labeling from C-1 to C-3 and C-6 carbons, from C-2 to C-1, C-3 and C-5 carbons, and from C-6 to C-1 carbon. From the results the percentages of routes via which the polysaccharide is biosynthesized are estimated. They show that the biosynthesis of the polysaccharide via the Embden-Meyerhof pathway and that from lipids and proteins are more active, and the pentose cycle is less active, than in the biosynthesis of cellulose and curdlan. As for the results, labeling at C-6 carbon in the branched polysaccharide cultured from D-(6-¹³C)glucose was low, compared to that of cellulose and curdlan.     

Proteomic analysis of rice leaf, stem and root tissues during growth course

Rice proteins were isolated from leaf, stem and root tissues, harvesting at 1, 2, 4, 8 and 10 weeks after budding. Each tissue of each age was separately pulverized in liquid nitrogen, and the resulted tissue powders were suspended in 10% TCA-acetone and followed by acetone suspension to precipitate at low temperature, which resulted in the tissue-specific and age-specific protein mixture. The protein mixtures were separated by 2-DE using polyacrylamide gels (26 x 20 cm). The protein spots were identified by N-terminal sequence analysis and by MALDI and LC-MS/MS analyses after in-gel tryptic digestion. From a total of 4532 spots, 676 unique proteins were identified, of which 80 proteins (12%) were observed in all three tissues: leaf, stem and root. In addition, 45 (7%) were common in leaf and stem, 57 (8%) in stem and root, and 10 (2%) proteins in root and leaf. Also 141 unique proteins (21%) were observed only for leaf, 96 (14%) for stem, and 247 (36%) for root tissue. Proteins playing a role for photosynthesis and energy production were most abundant in leaf and stem, and those for cell defense were rich in roots.     

Thyroid-hormone-dependent and fibroblast-specific expression of BMP-4 correlates with adult epithelial development during amphibian intestinal remodeling

We have identified one of the genes that are up-regulated by thyroid hormone (TH) in Xenopus laevis small intestine as the Xenopus homolog of bone morphogenetic protein-4 (BMP-4). To clarify possible roles of BMP-4 in intestinal remodeling during metamorphosis, we have examined its expression in X. laevis intestine by using in situ hybridization and organ culture techniques. At the beginning of metamorphic climax, BMP-4 mRNA first becomes detectable in the connective tissue, concurrently with the appearance of adult epithelial primordia. Subsequently, when the adult epithelial primordia are actively proliferating, BMP-4 mRNA becomes more abundant only in the connective tissue with a gradient toward the epithelium. Thereafter, as the adult primordia differentiate, the level of BMP-4 mRNA gradually decreases. Thus, BMP-4 expression correlates well with cell proliferation and/or initial differentiation of the adult epithelium, but not with apoptosis of the larval epithelium. Furthermore, the present culture study indicates that (1) TH-induced expression of BMP-4 mRNA is higher in the anterior part of the intestine than in the posterior part, which agrees with the better development of the adult epithelium in the more anterior part, and that (2) the expression of BMP-4 mRNA is up-regulated by TH in the presence of epithelium, but not in its absence. Therefore, BMP-4, which is indirectly induced by TH through some epithelial factor(s), probably plays important roles in adult epithelial development during amphibian intestinal remodeling.     

Luxol Fast Blue Mbs and Phloxine; a Stain for Mitochondria

The applicability of Luxol fast blue MBS as a 0.1% solution in 0.05% acetic acid to the staining of mitochondria, first recognized in rat kidney by Shanklin and Nassar (Stain Techn., 34: 257-60. 1959), was confirmed in various organs (formalin-Zenker and Regaud's fixations; paraffin embedding) of the mouse and bullfrog. In liver cells and in the epithelium of renal tubules, mitochondria were stained green, selectively and clearly. The dark cells of the renal tubules and the middle piece of sperms in both animals were conspicuously demonstrated by their dense assemblages of green granules. The periodic acid-Schiff procedure proposed by Shanklin and Nassar as a counterstain was replaced by staining in 0.5% aqueous phloxine, 2-3 min; differentiation in 5% phosphotungstic acid, 2 min; and washing in water, 5 min. This simplified and accelerated the techique, and gave a better color contrast. Advantages of Luxol fast blue MBS and phloxine staining over traditional methods for mitochondria in paraffin sections are: durability of the stain, high specificity, simplicity of procedure, and constant result.     

Transplanted neural progenitor cells expressing mutant NT3 promote myelination and partial hindlimb recovery in the chronic phase after spinal cord injury

Neutrotrophin-3 (NT3) plays a protective role in injured central nervous system tissues through interaction with trk receptors. To enhance the regeneration of damaged tissue, a combination therapy with cell transplantation and neurotrophins has been under development. We examined whether the transplantation of neural progenitor cells (NPCs) secreting NT3/D15A, a multi-neurotrophin with the capacity to bind both trkB and trkC, would enhance the repair of damaged tissues and the functional recovery in a chronic phase of spinal cord injury. The cultured NPCs with lentiviral vector containing either GFP or NT3/D15A were transplanted into the contused spinal cord at 6 weeks after the initial thoracic injury. Eight weeks after the transplantation, the NT3/D15A transplants displayed better survival than the GFP transplants, and they exhibited enhanced myelin formation and partial improvement of hindlimb function. Our study revealed that NT3/D15A produced positive effects in injured spinal cords even in the chronic phase. These effects suggest an enhanced neurotrophin-trk signaling by NT3/D15A.