Paloma B. Liton

Clinical Isolates of Measles Virus Use CD46 as a Cellular Receptor

ABSTRACT Laboratory strains of measles viruses (MV), such as Edmonston and Halle, use the complement regulatory protein CD46 as a cell surface receptor. The receptor usage of clinical isolates of MV, however, remains unclear. Receptor usage by primary patient isolates of MV was compared to isolates that had been passaged on a variety of tissue culture cell lines. All of the isolates could infect cells in a CD46-dependent manner, but their tropism was restricted according to cell type (e.g., lymphocytes versus fibroblasts). The results indicate that patient isolates that have not been adapted to tissue culture cell lines use CD46 as a receptor. In addition, passaging primary MV patient isolates in B95-8 cells selected variants that had alternate receptor usage compared to the original isolate. Thus, changes in receptor usage by MV are dependent upon the cell type used for isolation. Furthermore, our results confirm the relevance of the CD46 receptor to natural measles infection.

Cellular senescence in the glaucomatous outflow pathway.

The mechanisms responsible for the progressive malfunction of the trabecular meshwork (TM)-Schlemms canal (SC) conventional outflow pathway tissue in primary open angle glaucoma (POAG) are still not fully understood. To determine whether POAG is characterized by an accumulation of senescent cells, similar to what has been described in other diseases, we have compared the levels of the senescence marker senescence-associated-beta-galactosidase (SA-beta-gal) in the outflow pathway cells of POAG and age-matched control donors. POAG donors demonstrated a statistically significant fourfold increase in the percentage of SA-beta-gal positive cells. These results suggest a potential role for cellular senescence in the pathophysiology of the outflow pathway.

Proteasome inhibition by chronic oxidative stress in human trabecular meshwork cells

The pathophysiologic mechanisms leading to the malfunction of the trabecular meshwork (TM)-Schlemms canal (SC) outflow pathway in glaucoma are still unclear. We hypothesize that chronic oxidative stress may contribute to the malfunction of the outflow pathway by impairing the intracellular proteasome system of the cells, decreasing the ability of the tissue to modulate outflow resistance. To study the effects of chronic oxidative stress on proteasome function, primary cultures of human TM cells were incubated under 40% oxygen and proteasome activity was analyzed by measuring the accumulation of enhanced green fluorescent protein fused to a PEST motif. Changes in proteasome content, cellular senescence, and cell viability were also monitored. After 10 days of exposure to chronic oxidative stress, TM cells showed a marked decline in proteasome activity that was associated with premature senescence and decreased cell viability. These results suggest that proteasome failure may be involved in glaucoma pathophysiology.

Resveratrol prevents the expression of glaucoma markers induced by chronic oxidative stress in trabecular meshwork cells

Elevated intraocular pressure (IOP) constitutes the best characterized risk for primary open-angle glaucoma (POAG). Elevated IOP is believed to result from an increase in aqueous humor outflow resistance at the level of the trabecular meshwork (TM)/Schlemms canal. Malfunction of the TM in POAG is associated with the expression of markers for inflammation, cellular senescence, oxidative damage, and decreased cellularity. Current POAG treatments rely on lowering IOP, but there is no therapeutic approach available to delay the loss of function of the TM in POAG patients. We evaluated the effects of chronic administration of the dietary supplement resveratrol on the expression of markers for inflammation, oxidative damage, and cellular senescence in primary TM cells subjected to chronic oxidative stress (40% O2). Resveratrol treatment effectively prevented increased production of intracellular reactive oxygen species (iROS) and inflammatory markers (IL1alpha, IL6, IL8, and ELAM-1), and reduced expression of the senescence markers sa-beta-gal, lipofuscin, and accumulation of carbonylated proteins. Furthermore, resveratrol exerted antiapoptotic effects that were not associated with a decrease in cell proliferation. These results suggest that resveratrol could potentially have a role in preventing the TM tissue abnormalities observed in POAG.

Lysosomal basification and decreased autophagic flux in oxidatively stressed trabecular meshwork cells: Implications for glaucoma pathogenesis

Increasing evidence suggests oxidative damage as a key factor contributing to the failure of the conventional outflow pathway tissue to maintain appropriate levels of intraocular pressure, and thus increase the risk for developing glaucoma, a late-onset disease which is the second leading cause of permanent blindness worldwide. Autophagy is emerging as an essential cellular survival mechanism against a variety of stressors, including oxidative stress. Here, we have monitored, by using different methodologies (LC3-I to LC3-II turnover, tfLC3, and Cyto ID), the induction of autophagy and autophagy flux in TM cells subjected to a normobaric hyperoxic model of mild chronic oxidative stress. Our data indicate the MTOR-mediated activation of autophagy and nuclear translocation of TFEB in oxidatively stressed TM cells, as well as the role of autophagy in the occurrence of SA-GLB1/SA-β-gal. Concomitant with the activation of the autophagic pathway, TM cells grown under oxidative stress conditions displayed, however, reduced cathepsin (CTS) activities, reduced lysosomal acidification and impaired CTSB proteolytic maturation, resulting in decreased autophagic flux. We propose that diminished autophagic flux induced by oxidative stress might represent one of the factors leading to progressive failure of cellular TM function with age and contribute to the pathogenesis of primary open angle glaucoma.

Induction of TGF-β1 in the trabecular meshwork under cyclic mechanical stress

The pathophysiological mechanisms involved in the failure of the trabecular meshwork (TM) to maintain normal levels of aqueous outflow in glaucoma are not yet understood. Aberrant activation of the transforming growth factor beta‐1 (TGF‐β1) pathway has been implicated in several degenerative diseases. We investigated the possibility that chronic cyclic mechanical stress that affects the TM might result in increased production of TGF‐β1. Primary cultures of TM cells subjected to cyclic mechanical stress (5% stretching, 1 cycle/sec) demonstrate a significant increase in total and biologically active secreted TGF‐β1 that was associated with activation of the TGF‐β1 promoter, measured using a recombinant adenovirus expressing the secreted reporter gene secreted alkaline phosphatase protein (SEAP) under the TGF‐β1 gene promoter (AdTGFβ1‐SEAP). Associated changes in the transcription of MMP‐2, TIMP‐2, and CTGF were assessed by semiquantitative PCR. Immunohistochemical analysis of TGF‐β1 in organ culture of human eyes revealed a generalized accumulation of this protein in the extracellular matrix (ECM) of the TM, while expression of the TGF‐β1 promoter, analyzed using the LacZ reporter gene, was localized in some specific cells within the outflow pathway. Induction of the TGF‐β1 promoter in organ culture was demonstrated using a novel model for cyclic mechanical stress in human perfused anterior segments infected with AdTGFβ1‐SEAP. Given the relevant physiological and pathophysiological roles of TGF‐β1, its induction after cyclic mechanical stress in the TM supports the hypothesis that this cytokine might play a significant role in the physiology of the TM, and contribute to the pathological changes of this tissue in certain forms of glaucoma.

Intralysosomal Iron Induces Lysosomal Membrane Permeabilization and Cathepsin D-Mediated Cell Death in Trabecular Meshwork Cells Exposed to Oxidative Stress

PURPOSE To investigate the role of intralysosomal redox-active iron in oxidative stress-induced damage in trabecular meshwork (TM) cells. METHODS Chronic oxidative stress was applied using the hyperoxic model; acute oxidative stress was applied with H(2)O(2). Microarray analysis was performed using microarrays. mRNA and protein levels were quantified by real-time PCR and Western blot analysis, respectively. Redox-active iron was monitored using calcein-AM. Apoptosis was quantified using double staining. DNA damage was evaluated by single-cell gel electrophoresis assay. Lysosomal permeabilization was monitored using uptake and acridine orange relocation techniques. Intracellular ROS production was quantified using H(2)DCFDA. Cytosolic translocation of cathepsins was visualized with pepstatin-A-BODIPY-FL. Chemical inhibition of cathepsins was achieved with leupeptin and pepstatin A. Silencing of cathepsin expression was accomplished with miRNA sequences. Lysosomal iron chelation was achieved with desferrioxamine. RESULTS Chronically stressed TM cells showed elevated levels of redox-active iron and altered expression of genes involved in intracellular iron homeostasis. Although iron increased ROS production and lipofuscin levels and sensitized TM cells to H(2)O(2), intralysosomal iron chelation completely protected the cells against H(2)O(2)-induced cell death and apoptosis. The protective effect of desferrioxamine was mediated by the prevention of lysosomal ROS generation and the rupture of lysosomal membrane, with the subsequent release of cathepsin D into the cytosol. CONCLUSIONS These results indicate that the generation of intralysosomal ROS induces lysosomal membrane permeabilization and the release of cathepsin D into the cytosol, leading to TM cell death. Here, the authors propose a mechanism by which oxidative stress might contribute to the decrease in cellularity reported in the TM tissue with both aging and disease.

Cultured Porcine Trabecular Meshwork Cells Display Altered Lysosomal Function When Subjected to Chronic Oxidative Stress

PURPOSE To investigate the effects of chronic oxidative stress on lysosomal function in trabecular meshwork (TM) cells. METHODS Confluent cultures of porcine TM cells were grown for 2 weeks in physiological (5% O(2)) or hyperoxic conditions (40% O(2)) in the presence or absence of the protease inhibitor leupeptin (10 microM). The following parameters were quantified using the fluorogenic probes indicated within parentheses: autofluorescence, intracellular reactive oxygen species (ROS; H(2)DCFDA), mitochondrial membrane potential (JC-1), mitochondrial content (Mitotracker Red; Invitrogen-Molecular Probes, Eugene, OR), lysosomal content (acridine orange and Lysotracker Red [Invitrogen-Molecular Probes]), autophagic vacuole content (MDC), SA-beta-galactosidase (FDG), and cathepsin activities (z-FR-AMC). Cathepsin levels were quantified by qPCR and Western blot analysis. Ultrastructural analysis was performed by transmission electron microscopy. RESULTS Prolonged exposure of porcine TM cells to a hyperoxic environment led to an increase in ROS production and oxidized material. Electron micrographs revealed the cytoplasmic accumulation of lipofuscin-loaded lysosomes. Augmented lysosomal and autophagic vacuole content was confirmed with specific fluorophores. The mRNA and protein levels of several cathepsins were upregulated with oxidative stress. This upregulated expression did not correlate with increased lysosomal activity. CONCLUSIONS The results indicate that chronic exposure of TM cells to oxidative stress causes the accumulation of nondegradable material within the lysosomal compartment, leading to diminished lysosomal activity. Since the lysosomal system is responsible for the continuous turnover of cellular organelles, impaired lysosomal activity may lead to progressive failure of cellular TM function with age.

The role of proteolytic cellular systems in trabecular meshwork homeostasis

The molecular mechanisms contributing to the progressive malfunction of the trabecular meshwork (TM)/Schlemms canal (SC) conventional outflow pathway during aging and in Primary Open Angle Glaucoma (POAG) are still poorly understood. Progressive accumulation of damaged and cross-linked proteins is a hallmark of aging tissues and has been proposed to play a major role in the tissue abnormalities associated with organismal aging and many age-related diseases. Such progressive accumulation of damaged proteins with age is believed to result from both, increased oxidative stress that results in faster rates of protein damage, as well as from a functional decline in the cellular proteolytic machinery that eliminates misfolded and damaged proteins. Here, we review the reported data that supports the occurrence of oxidative damage and the alterations in the intracellular proteolytic systems in the TM in aging and POAG. Finally, we discuss how the functional decline of the cellular proteolytic machinery in the TM might lead to the observed physiologic alterations of the outflow pathway in glaucoma.

Stress Response of the Trabecular Meshwork

The trabecular meshwork (TM) is known to be subjected to different types of stress such as mechanical, oxidative, and phagocytic stress. Although short-term exposure to these stresses is expected to elicit adaptive responses, long-term exposure may lead to permanent alterations in the tissue physiology and contribute to the pathologic increase in aqueous humor outflow resistance frequently associated with glaucoma. A fuller understanding of the cell-specific and tissue-specific responses to stress in the TM, including changes in gene and protein expression, signal transduction, and potential pathogenic effects, could lead to novel prevention and therapeutic strategies for glaucoma. This review summarizes the current information available about how the TM responds to mechanical, oxidative, and phagocytic stress, as well as the evidence supporting the role that such responses may have in the alterations of the TM in aging and glaucoma.