Bile acid pool changes and regulation of cholate synthesis in experimental diabetes

The effect of alloxan-diabetes and insulin treatment in bile acid pool size and composition, bile acid secretion and cholic acid synthesis was investigated in the rat. The size of the cholate pool was significantly increased 4 days after diabetes induction. It reached a constant size three times that of control animals after 2 weeks of diabetes. Changes in bile acid pool size and secretion were directly dependent of the insulin deficiency state since they were reversed by insulin treatment and were not influenced by the caloric intake of the animal nor the pharmacologic effect of alloxan. Biliary cholate secretion was also 3-fold increased in diabetic rats and it accounted for more than 80% of the total bile acids compared to 60% in the control group. The calculated daily rate of cholate synthesis was increased in diabetic rats and the circadian rhythm of cholate synthesis was abolished in this condition. Therefore, it was shown that the negative feedback mechanism that regulates bile acid snythesis was deleted in diabetes. This mechanism was partially restored after 2 weeks of insulin treatment. These studies demonstrated that bile acid metabolism was profoundly changed in alloxan-diabetic rats and suggested that insulin may play an important role in the regulation of bile acid snythesis and intestinal absorption.     

Female sperm storage in reptiles.

Internal fertilization and oviparity most likely are symplesiomorphies for modern reptiles, and viviparity has evolved independently numerous times in Sauria and Serpentes. Oviducal sperm storage is known in females of all taxa except Amphisbaenia. However, in Rhynchocephalia and Crocodilia, sperm storage is poorly studied, and specialized sperm storage tubules (Ssts) are unknown. We use the molecular phylogenetic hypothesis [(Chelonia+Archosauria) (Squamata)] to trace evolution of sperm storage characters. Ssts arose independently in Chelonia and Squamata. Turtles possess albumen-secreting glands in the anterior half of the oviduct (the tuba or isthmus), and the most distal of these glands also serve as Ssts; in addition, some turtles possess Ssts in the adjacent segment of the oviduct, the uterus. Squamates lack albumen-secreting glands, and the ancestral state is possession of Ssts in the posterior infundibulum (uterine tube). Secondarily, iguanids have evolved vaginal Ssts. In this paper, we present the first ultrastructural observations on vaginal Ssts in lizards, using Anolis sagrei (Polychrotidae). Proximally, the neck of these simple tubular glands continues the alternation of ciliated and secretory cells lining the lumen of the vagina. However, the epithelial cells of the distal sperm storage area are neither secretory nor ciliated. The Ssts of Anolis are more similar to those of birds more than to infundibular receptacles in snakes and lizards.     

Reduction of Proteinuria through Podocyte Alkalinization

Podocytes are highly differentiated cells and critical elements for the filtration barrier of the kidney. Loss of their foot process (FP) architecture (FP effacement) results in urinary protein loss. Here we show a novel role for the neutral amino acid glutamine in structural and functional regulation of the kidney filtration barrier. Metabolic flux analysis of cultured podocytes using genetic, toxic, and immunologic injury models identified increased glutamine utilization pathways. We show that glutamine uptake is increased in diseased podocytes to couple nutrient support to increased demand during the disease state of FP effacement. This feature can be utilized to transport increased amounts of glutamine into damaged podocytes. The availability of glutamine determines the regulation of podocyte intracellular pH (pH_i). Podocyte alkalinization reduces cytosolic cathepsin L protease activity and protects the podocyte cytoskeleton. Podocyte glutamine supplementation reduces proteinuria in LPS-treated mice, whereas acidification increases glomerular injury. In summary, our data provide a metabolic opportunity to combat urinary protein loss through modulation of podocyte amino acid utilization and pH_i.     

Regulation of Dynamin Oligomerization in Cells: The Role of Dynamin–Actin Interactions and Its GTPase Activity

Dynamin is a 96‐kDa protein that has multiple oligomerization states that influence its GTPase activity. A number of different dynamin effectors, including lipids, actin filaments, and SH3‐domain‐containing proteins, have been implicated in the regulation of dynamin oligomerization, though their roles in influencing dynamin oligomerization have been studied predominantly in vitro using recombinant proteins. Here, we identify higher order dynamin oligomers such as rings and helices in vitro and in live cells using fluorescence lifetime imaging microscopy (FLIM). FLIM detected GTP‐ and actin‐dependent dynamin oligomerization at distinct cellular sites, including the cell membrane and transition zones where cortical actin transitions into stress fibers. Our study identifies a major role for direct dynamin–actin interactions and dynamin's GTPase activity in the regulation of dynamin oligomerization in cells.      

Establishment of Protein Delivery Systems Targeting Podocytes

Background

Podocytes are uniquely structured cells that are critical to the kidney filtration barrier. Their anatomic location on the outer side of the glomerular capillaries expose podocytes to large quantities of both plasma and urinary components and thus are reachable for drug delivery. Recent years have made clear that interference with podocyte-specific disease pathways can modulate glomerular function and influence severity and progression of glomerular disease.

Methodology/Principal Findings

Here, we describe studies that show efficient transport of proteins into the mammalian cells mouse 3T3 fibroblasts and podocytes, utilizing an approach termed profection. We are using synthetic lipid structures that allow the safe packing of proteins or antibodies resulting in the subsequent delivery of protein into the cell. The uptake of lipid coated protein is facilitated by the intrinsic characteristic of cells such as podocytes to engulf particles that are physiologically retained in the extracellular matrix. Profection of the restriction enzyme MunI in 3T3 mouse fibroblasts caused an increase in DNA degradation. Moreover, purified proteins such as β-galactosidase and the large GTPase dynamin could be profected into podocytes using two different profection reagents with the success rate of 95–100%. The delivered β-galactosidase enzyme was properly folded and able to cleave its substrate X-gal in podocytes. Diseased podocytes are also potential recipients of protein cargo as we also delivered fluorophore labeled IgG into puromycin treated podocytes. We are currently optimizing our protocol for in vivo profection.

Conclusions

Protein transfer is developing as an exciting tool to study and target highly differentiated cells such as podocytes.     

Auxilin-dynamin interactions link the uncoating ATPase chaperone machinery with vesicle formation

The large GTPase dynamin is required for budding of clathrin-coated vesicles from the plasma membrane, after which the clathrin coat is removed by the chaperone Hsc70 and its cochaperone auxilin. Recent evidence suggests that the GTP-bound form of dynamin may recruit factors that execute the fission reaction. Here, we show that dynamin:GTP binds to Hsc70 and auxilin. We mapped two domains within auxilin that interact with dynamin, and these domains inhibit endocytosis when overexpressed in HeLa cells or when added in a permeable cell assay. The inhibition is not due to impairment of clathrin uncoating or to altered clathrin distribution in cells. Thus, in addition to its requirement for clathrin uncoating, our results show that auxilin also acts during the early steps of clathrin-coated vesicle formation. The data suggest that dynamin regulates the action of molecular chaperones in vesicle budding during endocytosis.     

Dual regulation of hepatitis C viral RNA by cellular RNAi requires partitioning of Ago2 to lipid droplets and P-bodies

The antiviral role of RNA interference (RNAi) in humans remains to be better understood. In RNAi, Ago2 proteins and microRNAs (miRNAs) or small interfering RNAs (siRNAs) form endonucleolytically active complexes which down-regulate expression of target mRNAs. P-bodies, cytoplasmic centers of mRNA decay, are involved in these pathways. Evidence exists that hepatitis C virus (HCV) utilizes host cellular RNAi machinery, including miRNA-122, Ago1-4, and Dicer proteins for replication and viral genome translation in Huh7 cells by, so far, nebulous mechanisms. Conversely, synthetic siRNAs have been used to suppress HCV replication. Here, using a combination of biochemical, transfection, confocal imaging, and digital image analysis approaches, we reveal that replication of HCV RNA depends on recruitment of Ago2 and miRNA-122 to lipid droplets, while suppression of HCV RNA by siRNA and Ago2 involves interaction with P-bodies. Such partitioning of Ago2 proteins into different complexes and separate subcellular domains likely results in modulation of their activity by different reaction partners. We propose a model in which partitioning of host RNAi and viral factors into physically and functionally distinct subcellular compartments emerges as a mechanism regulating the dual interaction of cellular RNAi with HCV RNA.