The role of P2Y1 purinergic receptors and cytosolic Ca2+ in hypotonically activated osmolyte efflux from a rat hepatoma cell line

Exposure of HTC rat hepatoma cells to a 33% decrease in extracellular osmolality caused the cytosolic Ca(2+) concentration ([Ca(2+)](i)) to increase transiently by approximately 90 nm. This rise in [Ca(2+)](i) was inhibited strongly by apyrase, grade VII (which has a low ATP/ADPase ratio) but not by apyrase grade VI (which has a high ATP/ADPase ratio) or hexokinase, indicating that extracellular ADP and/or ATP play a role in the [Ca(2+)](i) increase. The hypotonically induced rise in [Ca(2+)](i) was prevented by the prior discharge of the intracellular Ca(2+) store of the cells by thapsigargin. Removal of extracellular Ca(2+) or inhibition of Ca(2+) influx by 1-10 microm Gd(3+) depleted the thapsigargin-sensitive Ca(2+) stores and thereby diminished the rise in [Ca(2+)](i). The hypotonically induced rise in [Ca(2+)](i) was prevented by adenosine 2'-phosphate-5'-phosphate (A2P5P) and pyridoxyl-5'-phosphate-6-azophenyl-2',4'-disulfonate, inhibitors of purinergic P2Y(1) receptors for which ADP is a major agonist. Both inhibitors also blocked the rise in [Ca(2+)](i) elicited by addition of ADP to cells in isotonic medium, whereas A2P5P had no effect on the rise in [Ca(2+)](i) elicited by the addition of the P2Y(2) and P2Y(4) receptor agonist, UTP. HTC cells were shown to express mRNA encoding for rat P2Y(1), P2Y(2), and P2Y(6) receptors. Inhibition of the hypotonically induced rise in [Ca(2+)](i) blocked hypotonically induced K(+) ((86)Rb(+)) efflux, modulated the hypotonically induced efflux of taurine, but had no significant effect on Cl(-) ((125)I-) efflux. The interaction of extracellular ATP and/or ADP with P2Y(1) purinergic receptors therefore plays a role in the response of HTC cells to osmotic swelling but does not account for activation of all the efflux pathways involved in the volume-regulatory response.     

B cell positive selection by soluble self-antigen

It is well established that autoreactive B cells undergo negative selection. This stands in paradox with the high frequency of so-called natural autoreactive B cells producing low affinity polyreactive autoantibodies with recurrent specificities, suggesting that these B cells are selected on the basis of their autoreactivity. We previously described two transgenic mouse lines (with and without IgD) producing a human natural autoantibody (nAAb) that binds ssDNA and human Fcgamma. In the absence of human IgG, nAAb-transgenic B cells develop normally. By crossing these mice with animals expressing knockin chimeric IgG with the human Fcgamma, we now show that the constitutive expression of chimeric IgG promotes the increase of nAAb-expressing B cells. This positive selection is critically dependent on the presence of IgD, occurs in the spleen, and concerns all mature B cell subsets, with a relative preferential enrichment of marginal zone B cells. These data support the view that soluble self-Ags can result in positive clonal selection.     

Altering the expression kinetics of VP5 results in altered virulence and pathogenesis of herpes simplex virus type 1 in mice

While many herpes simplex virus (HSV) structural proteins are expressed with strict-late kinetics, the HSV virion protein 5 (VP5) is expressed as a "leaky-late" protein, such that appreciable amounts of VP5 are made prior to DNA replication. Our goal has been to determine if leaky-late expression of VP5 is a requirement for a normal HSV infection. It had been shown previously that recombinant viruses in which the VP5 promoter was replaced with promoters of other kinetic classes (including a strict late promoter) exhibited no alterations in replication kinetics or virus yields in vitro. In contrast, here we report that alterations in pathogenesis were observed when these recombinants were analyzed by experimental infection of mice. Following intracranial inoculation, a recombinant expressing VP5 from a strict-late promoter (U(L)38) exhibited an increased 50% lethal dose and a 10-fold decrease in virus yields in the central nervous system, while a recombinant expressing VP5 from an early (dUTPase) or another leaky-late (VP16) promoter exhibited wild-type neurovirulence. Moreover, following infection of the footpad, changing the expression kinetics of VP5 from leaky-late to strict-late resulted in 100-fold-less virus in the spinal ganglia during the acute infection than produced by either the parent virus or the rescued virus. These data indicate that the precise timing of appearance of the major capsid protein plays a role in the pathogenesis of HSV infections and that changing the expression kinetics has different effects in different cell types and tissues.     

TNF-alpha increases the carbohydrate sulfation of CD44: induction of 6-sulfo N-acetyl lactosamine on N- and O-linked glycans

CD44 and sulfation have both been implicated in leukocyte adhesion. In monocytes, the inflammatory cytokine tumor necrosis factor alpha (TNF-alpha) stimulates CD44 sulfation, and this correlates with the induction of CD44-mediated adhesion events. However, little is known about the sulfation of CD44 or its induction by inflammatory cytokines. We determined that TNF-alpha induces the carbohydrate sulfation of CD44. CD44 was established as a major sulfated cell surface protein on myeloid cells. In the SR91 myeloid cell line, the majority of CD44 sulfation was attributed to the glycosaminoglycan chondroitin sulfate. However, TNF-alpha stimulation increased CD44 sulfation two- to threefold, largely attributed to the increased sulfation of N- and O-linked glycans on CD44. Therefore, TNF-alpha induced a decrease in the percentage of CD44 sulfation due to chondroitin sulfate and an increase due to N- and O-linked sulfation. Furthermore, TNF-alpha induced the expression of 6-sulfo N-acetyl lactosamine (LacNAc)/Lewis x on these cells, which was detected by a monoclonal antibody after neuraminidase treatment. This 6-sulfo LacNAc/Lewis x epitope was induced on N-linked and (to a lesser extent) on O-linked glycans present on CD44. This demonstrates that CD44 is modified by sulfated carbohydrates in myeloid cells and that TNF-alpha modifies both the type and amount of carbohydrate sulfation occurring on CD44. In addition, it demonstrates that TNF-alpha can induce the expression of 6-sulfo N-acetyl glucosamine on both N- and O-linked glycans of CD44 in myeloid cells.     

Susceptibility and adaptive response to bile salts in Propionibacterium freudenreichii: physiological and proteomic analysis

Tolerance to digestive stresses is one of the main factors limiting the use of microorganisms as live probiotic agents. Susceptibility to bile salts and tolerance acquisition in the probiotic strain Propionibacterium freudenreichii SI41 were characterized. We showed that pretreatment with a moderate concentration of bile salts (0.2 g/liter) greatly increased its survival during a subsequent lethal challenge (1.0 g/liter, 60 s). Bile salts challenge led to drastic morphological changes, consistent with intracellular material leakage, for nonadapted cells but not for preexposed ones. Moreover, the physiological state of the cells during lethal treatment played an important role in the response to bile salts, as stationary-phase bacteria appeared much less sensitive than exponentially growing cells. Either thermal or detergent pretreatment conferred significantly increased protection toward bile salts challenge. In contrast, some other heterologous pretreatments (hypothermic and hyperosmotic) had no effect on tolerance to bile salts, while acid pretreatment even might have sensitized the cells. Two-dimensional electrophoresis experiments revealed that at least 24 proteins were induced during bile salts adaptation. Identification of these polypeptides suggested that the bile salts stress response involves signal sensing and transduction, a general stress response (also triggered by thermal denaturation, oxidative toxicity, and DNA damage), and an alternative sigma factor. Taken together, our results provide new insights into the tolerance of P. freudenreichii to bile salts, which must be taken into consideration for the use of probiotic strains and the improvement of technological processes.     

The contrasting effects of short‐ and long‐term habitat drainage on the population dynamics of freshwater turtles in a human‐dominated landscape

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Identification of GBF1 as a Cellular Factor Required for Hepatitis C Virus RNA Replication

In infected cells, hepatitis C virus (HCV) induces the formation of membrane alterations referred to as membranous webs, which are sites of RNA replication. In addition, HCV RNA replication also occurs in smaller membrane structures that are associated with the endoplasmic reticulum. However, cellular mechanisms involved in the formation of HCV replication complexes remain largely unknown. Here, we used brefeldin A (BFA) to investigate cellular mechanisms involved in HCV infection. BFA acts on cell membranes by interfering with the activation of several members of the family of ADP-ribosylation factors (ARF), which can lead to a wide range of inhibitory actions on membrane-associated mechanisms of the secretory and endocytic pathways. Our data show that HCV RNA replication is highly sensitive to BFA. Individual knockdown of the cellular targets of BFA using RNA interference and the use of a specific pharmacological inhibitor identified GBF1, a guanine nucleotide exchange factor for small GTPases of the ARF family, as a host factor critically involved in HCV replication. Furthermore, overexpression of a BFA-resistant GBF1 mutant rescued HCV replication in BFA-treated cells, indicating that GBF1 is the BFA-sensitive factor required for HCV replication. Finally, immunofluorescence and electron microscopy analyses indicated that BFA does not block the formation of membranous web-like structures induced by expression of HCV proteins in a nonreplicative context, suggesting that GBF1 is probably involved not in the formation of HCV replication complexes but, rather, in their activity. Altogether, our results highlight a functional connection between the early secretory pathway and HCV RNA replication.Hepatitis C virus (HCV) is an important human pathogen. It mainly infects human hepatocytes, and this often leads to chronic hepatitis, cirrhosis, or hepatocarcinoma. HCV studies have been hampered for many years by the difficulty in propagating this virus in vitro. Things have recently changed with the development of a cell culture model referred to as HCVcc (34, 60, 65), which allows the study of the HCV life cycle in cell culture and facilitates studies of the interactions between HCV and the host cell.HCV is an enveloped positive-strand RNA virus belonging to the family Flaviviridae (35). The viral genome contains a single open reading frame, which is flanked by two noncoding regions that are required for translation and replication. All viral proteins that are produced after proteolytic processing of the initially synthesized polyprotein are membrane associated (15, 43). This reflects the fact that virtually all steps of the viral life cycle occur in close association with cellular membranes.Interactions of HCV with cell membranes begin during entry. Several receptors, coreceptors, and other entry factors have been discovered over the years, which link HCV entry to specialized domains of the plasma membrane, such as tetraspanin-enriched microdomains and tight junctions (8, 16, 59). The internalization of the viral particle occurs by clathrin-mediated endocytosis (5, 40). The fusion of the viral envelope with the membrane of an acidic endosome likely mediates the transfer of the viral genome to the cytosol of the cell (5, 40, 57). However, little is known regarding the pre- and postfusion intracellular transport steps of entering viruses in the endocytic pathway.HCV RNA replication is also associated with cellular membranes. Replication begins with the translation of the genomic RNA of an incoming virus. This leads to the production of viral proteins, which in turn initiate the actual replication of the viral RNA. Mechanisms regulating the transition from the translation of the genomic RNA to its replication are not yet known. All viral proteins are not involved in RNA replication. Studies performed with subgenomic replicons demonstrated that proteins NS3-4A, NS4B, NS5A, and NS5B are necessary and sufficient for replication (6, 27, 37). RNA replication proceeds through the synthesis of a cRNA strand (negative strand), catalyzed by the RNA-dependent RNA polymerase activity of NS5B, which is then used as a template for the synthesis of new positive strands.Electron microscopy studies using a subgenomic replicon model suggested that replication takes place in membrane structures made of small vesicles, referred to as “membranous webs,” which are induced by the virus (26). Membranous webs are detectable not only in cells carrying subgenomic replicons but also in infected cells (50). They appear to be associated with the endoplasmic reticulum (ER) (26). In addition to the membranous webs, a second type of ER-associated replicase that is smaller and more mobile has recently been described (63). Cellular mechanisms leading to these membrane alterations are still poorly understood. In cells replicating and secreting infectious viruses effectively, the situation appears to be even more complex, since replicase components appear to be, at least in part, associated with cytoplasmic lipid droplets (41, 50, 56). This association depends on the capsid protein (41) and may reflect a coupling between replication and assembly. Indeed, HCV assembly and secretion show some similarities with very-low-density lipoprotein (VLDL) maturation and secretion (24, 64).Our knowledge of the cellular membrane mechanisms involved in the HCV life cycle is still limited. The expression of NS4B alone induces membrane alterations that are reminiscent of membranous webs (19). However, cellular factors that participate in this process are still unknown. On the other hand, several cellular proteins potentially involved in the HCV life cycle have been identified through their interactions with viral proteins. For some of these proteins, a functional role in infection was recently confirmed using RNA interference (48). It is very likely that other cellular factors critical to HCV infection have yet to be identified.To gain more insight into cellular mechanisms underlying HCV infection, we made use of brefeldin A (BFA), a macrocyclic lactone of fungal origin that exhibits a wide range of inhibitory actions on membrane-associated mechanisms of the secretory and endocytic pathways (30). BFA acts on cell membranes by interfering with the activation of several members of the family of ADP-ribosylation factors (ARFs). ARFs are small GTP-binding proteins of the Ras superfamily. They function as regulators of vesicular traffic, actin remodeling, and phospholipid metabolism by recruiting effectors to membranes. BFA does not actually interfere directly with ARF GTPases but rather interferes with their activation by regulators known as guanine nucleotide exchange factors (GEFs) (14, 25). We now report the identification of an ARF GEF as a cellular BFA-sensitive factor that is required for HCV replication.