Prolonged gene expression in mouse lung endothelial cells following transfection with Epstein-Barr virus-based episomal plasmid

The development of a strategy to deliver a gene to pulmonary endothelium will be useful for gene function study and for pulmonary gene therapy. Cationic lipidic vectors are efficient in gene transfer to pulmonary endothelium via the vascular route; however, gene expression is transient and lasts for only a few days. In this study, we show that pulmonary gene transfer via cationic lipidic vectors can be significantly improved using an Epstein-Barr virus (EBV)-based expression plasmid. Systemic administration of cationic liposomes followed by the EBV-based plasmid led to gene expression in the lung that lasted for more than 3 weeks. Prolonged and high levels of gene expression can also be obtained in primary mouse lung endothelial cells (MLEC) following lipofection with an EBV-based plasmid. These results suggest the utility of this gene transfer protocol in studying the expression of cloned genes in lung endothelial cells and in pulmonary gene therapy.     

Radiation-induced red cell damage: role of reactive oxygen species

BACKGROUND: Cellular blood components are irradiated to prevent graft- versus-host disease in transfusion recipients at risk for this syndrome. Because gamma radiation can result in the production of reactive oxygen species, the role of reactive oxygen species was investigated in radiation-induced red cell damage. STUDY DESIGN AND METHODS: Whole blood from normal donors was exposed to various doses of t-butyl hydroperoxide (0-1 mM) and/or to gamma-radiation (0-50 Gy). Oxidative damage was assessed by the extent of lipid peroxidation (measured by thiobarbituric acid-reactive substances [TBARS]) and hemoglobin oxidation. Fresh blood was divided into three parts-one initially irradiated and stored, another stored with portions irradiated weekly, and a third stored without irradiation. TBARS and hemoglobin oxidation were measured weekly. RESULTS: As expected, t- butyl hydroperoxide induced TBARS formation and hemoglobin oxidation in a dose-dependent fashion. The gamma-radiation not only increased hemoglobin oxidation and TBARS formation, but also enhanced the t-butyl hydroperoxide effect on red cells. Red cell storage increased TBARS generation and hemoglobin oxidation in a time-dependent fashion. When radiation was administered either initially or after weekly storage, TBARS production and hemoglobin oxidation were increased over that measured in unirradiated paired controls. CONCLUSION: Gamma radiation at clinically used doses increases lipid peroxidation and hemoglobin oxidation in human red cells. The effect of gamma-radiation is accentuated by blood storage and induces damage independent of time of storage.     

Pre-B cells and other possible precursor lymphoid cell lines derived from patients with X-linked agammaglobulinemia

A group of unique Epstein-Barr virus-containing cell lines was derived from the bone marrow of three patients with X-linked agammaglobulinemia. Efforts to obtain cell lines from the peripheral blood of these patients were uniformly unsuccessful. Immunofluorescence analyses as well as biosynthetic studies with [(35)S]methionine indicated unusual patterns of Ig synthesis in many of these bone marrow derived lines. Seven of the lines were of particular interest in that two produced no Ig of any type; two others showed no Ig by fluorescence but small amounts by [(35)S]methionine labeling; one expressed only cytoplasmic μ chains without any evidence of light chain synthesis, and two produced primarily μ chains with only slight amounts of light chains. One of the lines without membrane or cytoplasmic Ig studied in detail grew like a typical lymphoid line and was carried in intermittent culture over a period of 2 yr without Ig expression. One line grew quite differently and resembled the round cell type described previously, which has been obtained from a variety of sources. The cell line with cytoplasmic μ chains and no light-chain expression had the characteristic properties of pre-B cells. Three normal type Ig-producing cell lines also were obtained from the patients. The accumulated evidence obtained in the present study indicates that these unusual cell lines represent normal precursor cells of the B-cell lineage; these grew out in these cases because of the virtual absence of mature B cells that ordinarily overgrow the culture system. However, the possibility that in certain instances they reflect abnormal Ig synthesis characteristic of the disease has not been ruled out.     

Xenophagy in Helicobacter pylori‐ and Epstein–Barr virus‐induced gastric cancer

Helicobacter pylori and Epstein–Barr virus (EBV) account for roughly 80% and 10%, respectively, of gastric carcinomas worldwide. Autophagy is an evolutionarily conserved and intricately regulated cellular process that involves the sequestration of cytoplasmic proteins and organelles into double‐membrane autophagosomes that eventually fuse with lysosomes for degradation of the engulfed content. Emerging evidence indicates that xenophagy, a form of selective autophagy, plays a crucial role in the pathogenesis of H. pylori‐ and EBV‐induced gastric cancer. Xenophagy specifically recognizes intracellular H. pylori and EBV and physically targets these pathogens to the autophagosomal–lysosomal pathway for degradation. In this connection, H. pylori or EBV‐induced dysregulation of autophagy may be causally linked to gastric tumourigenesis and therefore can be exploited as therapeutic targets. This review will discuss how H. pylori and EBV infection activate autophagy and how these pathogens evade recognition and degradation by the autophagic pathway. Elucidating the molecular aspects of H. pylori‐ and EBV‐induced autophagy will help us better understand the pathogenesis of gastric cancer and promote the development of autophagy modulators as antimicrobial agents. Published by John Wiley & Sons, Ltd     

IL-4/IL-13-Dependent Alternative Activation of Macrophages but Not Microglial Cells Is Associated with Uncontrolled Cerebral Cryptococcosis

Both interleukin (IL)-4- and IL-13-dependent Th2-mediated immune mechanisms exacerbate murine Cryptococcus neoformans-induced bronchopulmonary disease. To study the roles of IL-4 and IL-13 in cerebral cryptococcosis, IL-4 receptor α-deficient (IL-4Rα^−/−), IL-4-deficient (IL-4^−/−), IL-13-deficient (IL-13^−/−), IL-13 transgenic (IL-13^T/+), and wild-type mice were infected intranasally. IL-13^T/+ mice displayed a higher fungal brain burden than wild-type mice, whereas the brain burdens of IL-4Rα^−/−, IL-4^−/−, and IL-13^−/− mice were significantly lower as compared with wild-type mice. On infection, 68% of wild-type mice and 88% of IL-13-overexpressing IL-13^T/+ mice developed significant cerebral lesions. In contrast, only a few IL-4Rα^−/−, IL-4^−/−, and IL-13^−/− mice had small lesions in their brains. Furthermore, IL-13^T/+ mice harbored large pseudocystic lesions in the central nervous system parenchyma, bordered by voluminous foamy alternatively activated macrophages (aaMphs) that contained intracellular cryptococci, without significant microglial activation. In wild-type mice, aaMphs tightly bordered pseudocystic lesions as well, and these mice, in addition, showed microglial cell activation. Interestingly, in resistant IL-4^−/−, IL-13^−/−, and IL-4Rα^−/− mice, no aaMphs were discernible. Microglial cells of all mouse genotypes neither internalized cryptococci nor expressed markers of alternative activation, although they displayed similar IL-4Rα expression levels as macrophages. These data provide the first evidence of the development of aaMphs in a central nervous system infectious disease model, pointing to distinct roles of macrophages versus microglial cells in the central nervous system immune response against C. neoformans.The opportunistic pathogenic yeast Cryptococcus neoformans causes life-threatening fungal infections of most internal organs including the central nervous system (CNS), primarily in patients affected by immunodeficiency syndromes such as AIDS.¹ The pathogenesis of cryptococcosis is not fully understood, however, especially in cases of different levels of immunocompetence. It is generally accepted that the fungus first invades the respiratory system, where it leads to relatively mild or asymptomatic bronchopneumonia in the immunocompetent.^2,3,4,5 Fungemia with generalization of the infection may result from reduced immunological control mechanisms.^6,7,8,9 Invasion of the CNS with subsequent development of meningoencephalitis is the major cause of death during cryptococcosis.^10,11The precise reaction pattern of recruited inflammatory cells, especially monocytes/macrophages, due to fungal invasion of the CNS parenchyma has been addressed mainly via analysis of helper T cell (Th)1 responses.¹² In this context, in addition to protective Th1-driven immune responses, the role of Th2 cytokines has gained interest recently.¹³ The major Th2 cytokines interleukin (IL)-4 and IL-13 act via the IL-4Rα chain together with the γ_c chain or the IL-13Rα1/2 chains, and regulate macrophage functional status.¹⁴ IL-4 has been shown to be detrimental in murine models of systemic and pulmonary cryptococcosis,^{6,15,16,17,18} and we have recently illustrated the role of IL-13 in inducing the formation of alternatively activated macrophages (aaMphs) in murine pulmonary cryptococcosis.¹⁹The activation phenotype of macrophages may critically influence the regulatory mechanisms by which inflammation and infection in the CNS are controlled. According to the current paradigm, classically activated macrophages are primed by interferon-γ and produce tumor necrosis factor, IL-1, oxygen and nitrogen radicals,²⁰ thereby producing proinflammatory cytokines that regulate the Th1 immune response. In contrast, aaMph²¹ develop in response to Th2 cytokine stimulation such as IL-4 and IL-13 and are characterized by expression of genes associated with endocytosis and tissue repair such as arginase-1, mannose receptor (CD206), found-in-inflammatory-zone (FIZZ), and chitinase 3-like 3 (YM1) and largely fail to produce nitric oxide (NO) due to their induction of arginase.²² As such, they are thought to be involved in tissue repair and remodeling,^22,23 in protection against diet-induced obesity,^24,25 and schistosomiasis,²⁶ but they may also elicit adverse tissue processes such as pulmonary or liver fibrosis.^{27,28,29,30,31} In particular, their development renders the host vulnerable to infection with pathogens where macrophage activation and killing functions are required.³²In murine models of pulmonary C. neoformans infection, aaMph have been shown to be associated with uncontrolled lung infection.^18,19 The role of aaMph versus classically activated macrophage in the CNS due to pulmonary infection with the neurotropic pathogen C. neoformans has not been defined yet. In this study, we aimed to characterize the morphology and functional status of CNS macrophages in cerebral cryptococcosis following intranasal infection of susceptible wild-type and IL-13-transgenic BALB/c mice. Moreover, using mice unable to produce IL-4 or IL-13 or respond to both (IL-4Rα^−/− mice), we show that abrogation of CNS aaMph development is associated with controlled infection.