LncRNA‐H19 gene plays a significant role in regulating glioma cell function

Abstract INTRODUCTION Glioblastoma multiforme (GBM) is the most common primary central nervous system malignancy associated with a 12-15 month survival after surgery and radio-chemotherapy. Utilizing adoptive cellular immunotherapy using natural killer (NK) cells has developed over the past two decades for a variety of hematologic malignancies. This approach in solid malignancies is limited by questions of cell dose versus tumor burden, insufficient tumor infiltration, and a tumor microenvironment that suppresses NK cell function. METHODS We isolated NK cells from healthy volunteers and activated them using IL-2, -15, -12, -18, then perform cytotoxic assays in the presence of glioma stem cells. We also tested the efficacy of the NK cells with intracranial delivery in a pre-clinical murine model of glioma. We tested various concentrations of IL-2 and IL-15 on the cytokine culture platform. RESULTS In this study, we demonstrate human NK cells, activated using a cytokine cocktail of interleukins-2, -15, -12, and -18, exert strong cytotoxic events against glioma cell lines. To further examine the efficacy of activated NK cells in vitro, we utilized intracranially xenografted glioma lines and demonstrated a survival benefit with tumor bed injections of these cytokine-activated NK cells (p=0.0089). We were able to confirm that NK cells cultured with low doses (200u IL2; 50ng/ml IL15) of both cytokines are just as effective as higher doses. This is important, as in vivoexhaustion of NK cells stimulated with high doses of either cytokine has been well validated. We also found that low-dose irradiation (4Gy) of glioma cells prior to co-culture with cytokine-activated NK cells promoted increased targeted glioma cell killing within 4 hours(32% cell killing). CONCLUSIONS These findings suggest that in a clinical study, injection of cytokine-activated NK cells into the glioblastoma tumor bed could be used as adjuvant treatment following either stereotactic radiation or surgical resection.

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Effect of Gap Junctional Communication on Glioma Cell Function

Neuroscience Intelligence Unit - Gap Junctions in the Nervous System ◽

10.1007/978-3-662-21935-5_11 ◽

1996 ◽

pp. 193-202 ◽

Cited By ~ 3

Author(s):

Christian C. G. Naus ◽

John F. Becherger ◽

Shari L. Bond

Keyword(s):

Glioma Cell ◽

Cell Function ◽

Gap Junctional Communication ◽

Junctional Communication ◽

Gap Junctional

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Freeze-substitution of rye grass and ragweed pollen grains

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100160984 ◽

1990 ◽

Vol 48 (3) ◽

pp. 686-687

Author(s):

Liza B. Martinez ◽

Susan M. Wick

Keyword(s):

Cell Function ◽

Pollen Grains ◽

Freeze Substitution ◽

Cell Types ◽

Rapid Freezing ◽

Rye Grass ◽

Acrylic Resins ◽

Allergenic Proteins ◽

Cold Embedding ◽

Structural Preservation

Rapid freezing and freeze-substitution have been employed as alternatives to chemical fixation because of the improved structural preservation obtained in various cell types. This has been attributed to biomolecular immobilization derived from the extremely rapid arrest of cell function. These methods allow the elimination of conventionally used fixatives, which may have denaturing or “masking” effects on proteins. Thus, this makes them ideal techniques for immunocytochemistry, in which preservation of both ultrastructure and antigenicity are important. These procedures are also compatible with cold embedding acrylic resins which are known to increase sensitivity in immunolabelling.This study reveals how rapid freezing and freeze-substitution may prove to be useful in the study of the mobile allergenic proteins of rye grass and ragweed. Most studies have relied on the use of osmium tetroxide to achieve the necessary ultrastructural detail in pollen whereas those that omitted it have had to contend with poor overall preservation.

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Confocal imaging of calcium in intact ventricular muscle provides a new view of excitation-contraction coupling

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100166154 ◽

1996 ◽

Vol 54 ◽

pp. 738-739

Author(s):

W.G. Wier

Keyword(s):

Local Control ◽

Cardiac Tissue ◽

Cell Function ◽

Isolated Heart ◽

Cardiac Cells ◽

Confocal Imaging ◽

Ion Concentration ◽

Heart Cell ◽

Free Calcium ◽

Heart Cells

A fundamentally new understanding of cardiac excitation-contraction (E-C) coupling is being developed from recent experimental work using confocal microscopy of single isolated heart cells. In particular, the transient change in intracellular free calcium ion concentration ([Ca2+]i transient) that activates muscle contraction is now viewed as resulting from the spatial and temporal summation of small (∼ 8 μm3), subcellular, stereotyped ‘local [Ca2+]i-transients' or, as they have been called, ‘calcium sparks'. This new understanding may be called ‘local control of E-C coupling'. The relevance to normal heart cell function of ‘local control, theory and the recent confocal data on spontaneous Ca2+ ‘sparks', and on electrically evoked local [Ca2+]i-transients has been unknown however, because the previous studies were all conducted on slack, internally perfused, single, enzymatically dissociated cardiac cells, at room temperature, usually with Cs+ replacing K+, and often in the presence of Ca2-channel blockers. The present work was undertaken to establish whether or not the concepts derived from these studies are in fact relevant to normal cardiac tissue under physiological conditions, by attempting to record local [Ca2+]i-transients, sparks (and Ca2+ waves) in intact, multi-cellular cardiac tissue.

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Adipokines as key players in β cell function and failure

Clinical Science ◽

10.1042/cs20190523 ◽

2019 ◽

Vol 133 (22) ◽

pp. 2317-2327 ◽

Cited By ~ 3

Author(s):

Nicolás Gómez-Banoy ◽

James C. Lo

Keyword(s):

Metabolic Diseases ◽

Cell Function ◽

Whole Body ◽

Pancreatic Β Cell ◽

Β Cell ◽

Cell Axis ◽

Β Cell Function ◽

Prevalence Of Obesity ◽

Specific Factors ◽

Whole Body Metabolism

Abstract The growing prevalence of obesity and its related metabolic diseases, mainly Type 2 diabetes (T2D), has increased the interest in adipose tissue (AT) and its role as a principal metabolic orchestrator. Two decades of research have now shown that ATs act as an endocrine organ, secreting soluble factors termed adipocytokines or adipokines. These adipokines play crucial roles in whole-body metabolism with different mechanisms of action largely dependent on the tissue or cell type they are acting on. The pancreatic β cell, a key regulator of glucose metabolism due to its ability to produce and secrete insulin, has been identified as a target for several adipokines. This review will focus on how adipokines affect pancreatic β cell function and their impact on pancreatic β cell survival in disease contexts such as diabetes. Initially, the “classic” adipokines will be discussed, followed by novel secreted adipocyte-specific factors that show therapeutic promise in regulating the adipose–pancreatic β cell axis.

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