Generación de linfocítica micropartículas y detección de su efecto proapoptótico sobre las células epiteliales de la vía aérea
Summary
Micropartículas membrana arrojar celulares (MPs) son vesículas biológicas activas que pueden ser aislados y sus efectos fisiopatológicos investigados en varios modelos. Aquí se describe un método para generar MPs derivadas de los linfocitos T (LMP) y para demostrar su efecto proapoptótico en células epiteliales de las vías respiratorias.
Abstract
El interés en las funciones biológicas de las vesículas de membrana derivadas de células en la comunicación celular se ha incrementado en los últimos años. Las micropartículas (MP) son un tal tipo de vesículas, que varían en diámetro desde 0,1 m a 1 m, y normalmente se desprenden de la membrana plasmática de las células eucariotas se someten a la activación o la apoptosis. Aquí se describe la generación de linfocitos T derivados de micropartículas (LMP) a partir de células CEM T apoptóticas estimulados con actinomicina D. LMP están aisladas a través de un proceso de centrifugación diferencial de varios pasos y que se caracteriza por citometría de flujo. Este protocolo también presenta un método de detección in situ la muerte celular para demostrar el efecto proapoptótico de LMP en las células epiteliales bronquiales derivados de ratón explantes de tejidos bronquiales respiratorias primarias. Los métodos descritos en este documento proporcionan un procedimiento reproducible para el aislamiento de cantidades abundantes de LMP a partir de linfocitos apoptóticos in vitro. LMP derivade esta manera se puede utilizar para evaluar las características de varios modelos de enfermedad, y para la farmacología y pruebas de toxicología. Dado que el epitelio de la vía aérea ofrece una barrera física y funcional de protección entre el ambiente externo y el tejido subyacente, el uso de explantes de tejidos bronquiales en lugar de líneas de células epiteliales inmortalizadas ofrece un modelo eficaz para investigaciones que requieran tejido del tracto de las vías respiratorias.
Introduction
Microparticles (MPs) are biologically active submicron membrane vesicles released following cell activation or apoptosis. MPs are derived from both healthy and damaged cells and are implicated in many physiological and pathological processes.1 MPs have been detected not only in human plasma, but also in inflammatory and apoptotic tissue. The biological utility of cell membrane–derived MPs has been demonstrated in various settings, including cell signalling models and as pharmacological tools.2,3 We previously demonstrated that LMPs derived from T lymphocytes following actinomycin D stimulation (to induce apoptosis) suppress angiogenesis and inhibit endothelial cell survival and proliferation.4,5 The antiangiogenic effects of LMPs may vary significantly depending on the stimuli used to activate T lymphocytes in vitro.6
The airway epithelium functions as a protective physical and functional barrier. Increased numbers of T lymphocytes in the airway can contribute to cell damage and airway inflammation.7 We have shown that LMPs induce apoptosis of human bronchial epithelial cells,8 which indicated LMPs may change barrier function of bronchial epithelium in vivo. Apoptotic cells can be identified using the TUNEL method, which detects in situ DNA fragmentation.
The overall goal of this protocol is to illustrate the in vitro production of LMPs from a T lymphocyte cell line, and to demonstrate their proapoptotic effect on airway epithelial cells. In situ cell death detection demonstrated that LMPs strongly induce airway bronchial epithelial cell death, suggesting that LMPs-mediated injury to the airway epithelium may impact barrier function of the damaged epithelium.
Protocol
Representative Results
Discussion
Los diputados son mediadores activos de diafonía intercelular y su estudio es la promesa en muchas áreas de la ciencia. 11 Este estudio presenta un protocolo detallado para la generación a gran escala in vitro de LMP derivado de una línea de células T apoptóticas. Estas MPs expresan un gran repertorio de moléculas de linfocitos y están biológicamente implicados en la regulación de la homeostasis celular y tisular. Sin embargo, LMPs procedente de diferentes fuentes puede ser biológicamente …
Declarações
The authors have nothing to disclose.
Acknowledgements
Este trabajo es apoyado por becas de los Institutos Canadienses de Investigación en Salud (178,918), Fonds de recherche en santé du Québec – Visión Red de Investigación de la Salud.
Materials
| LMPs production and characterization | |||
| CEM T cells | ATCC | CCL-119 | |
| X-VIVO 15 medium | Cambrex, Walkersville | 04-744Q | |
| Flask T75 | Sarstedt | 83.1813.502 | |
| Flask T175 | Sarstedt | 83.1812.502 | |
| Actinomycin D | Sigma Chemical Co. | A9415-2mg | |
| PBS | Lifetechnologies | 14190-144 | |
| 0.22µm filter | Sarstedt | 83.1826.001 | |
| Annexin-VCy5 | BD Pharmagen | 559933 | |
| FACS flow solution | BD Bio-sciences | 342003 | |
| Fluorescent microbeads (1 um) | Molecular Probes | T8880 | |
| Polysterene counting beads (7 um) | Bangs laboratories | PS06N/6994 | |
| Polypropylene FACS tubes | Falcon | 352058 | |
| 1 ml pipet | Fisher | 13-678-11B | |
| 5 ml pipet | Falcon | 357543 | |
| 25 ml pipet | Ultident | DL-357551 | |
| 1,5 ml conical polypropylene micro tube | Sarstedt | 72.690 | |
| 15 ml conical polypropylene tube | Sarstedt | 62.554.205 | |
| 50 ml conical polypropylene tube | Sarstedt | 62.547.205 | |
| 50 ml high speed polypropylene copolymer tube | Nalgene | 3119-0050 | |
| 250 ml high speed polypropylene bottle | Beckman | 356011 | |
| Protein assay (Bradford assay) | Bio-Rad Laboratories | 500-0006 | |
| Protein assay standard II | Bio-Rad Laboratories | 500-0007 | |
| Test tube 16×100 | VWR | 47729-576 | |
| Test tube 12×75 | Ultident | 170-14100005B | |
| Cell incubator | Mandel | Heracell 150 | |
| Low speed centrifuge | IEC | Centra8R | |
| High speed centrifuge | Beckman | Avanti J8 | |
| High speed rotor for 250ml bottle | Beckman | JLA16.250 | |
| High speed rotor for 50ml tube | Beckman | JA30.50 | |
| Fow cytometry | BD Bio-sciences | FACS Calibur | |
| Spectrophotometer | Beckman | Series 600 | |
| Bronchial tissue explants and sections | |||
| C57BL/6 mice (5-7 weeks old) | Charles River Laboratories, Inc. | ||
| Mouse Airway PrimaCell™ System: | CHI Scientific, Inc. | 2-82001 | |
| Rib-Back Carbon Steel Scalpel Blades | Becton Dickinson AcuteCare | 371310 | #10 |
| Scalpel Handle | Fine Science Tools Inc. | 10003-12 | #7 |
| phase-contrast inverted microscope | Olympus Optical CO., LTD. | CK2 | |
| high O2 gas mixture | VitalAire Canada Inc. | ||
| modular incubator chamber | Billups-Rothenberg Inc. | MIC-101 | |
| MaxQ 4000 incubated orbital shaker | Barnstead Lab-Line, | SHKA4000-7 | |
| 12-well tissue culture plate | Becton Dickinson and Company | 353043 | |
| Plastic tissue culture dishes (100 mm) | Sarstedt, Inc. | 83.1802 | |
| Surgical scissors | Fine Science Tools Inc. | 14060-09 | Straight, sharp, 9cm longth |
| Half-curved Graefe forceps | Fine Science Tools Inc. | 11052-10 | |
| humidified CO2 incubator | Mandel Scientific Company Inc. | SVH-51023421 | |
| Histopathological examination | |||
| formalin formaldehyde | Sigma-Aldrich, Inc. | HT5011 | |
| paraffin | Fisher scientific International, Inc. | T555 | |
| ethyl alcohol | Merck KGaA, Darmstadt | EX0278-1 | |
| glutaraldehyde | Sigma-Aldrich, Inc. | G6403 | |
| Cacodylate | Sigma-Aldrich, Inc. | 31533 | |
| microscope slides | VWR Scientific Inc. | 48300-025 | 25x75mm |
| Xylene | Fisher scientific International, Inc. | X5-4 | |
| Mayer's hematoxylin | Sigma-Aldrich, Inc. | MHS16 | Funnel with filter paper |
| HCl | Fisher scientific International, Inc. | A144s-500 | |
| eosin | Sigma-Aldrich, Inc. | HT110116 | Funnel with filter paper |
| Permount™ Mounting Medium | Thermo Fisher Scientific Inc. | SP15-100 | |
| glass coverslip | surgipath medical industries, Inc. | 84503 | 24×24 #1 |
| TUNEL detection kit | In Situ Cell Death Detection, POD | 11 684 817 910 | |
| oven | Despatch Industries Inc. | LEB-1-20 | |
| rotary Microtome | Leica Microsystems Inc. | RM2145 | |
| filter paper | Whatman International Ltd. | 1003150 | #3 |
| Microscope | Nikon Imaging Japan Inc. | E800 | |
| staining dish complete | Wheaton Industries, Inc. | 900200 | including dish, rack, cover |
| 1.5 ml eppendorf tube | Sarstedt Inc. | 72.69 | 39x10mm |
| Orbital and Reciprocating Water Bath | ExpotechUSA | ORS200 | |
| phosphate buffered saline | GIBCO | 14190-144 | |
| fume hood | Nicram RD Service | 3707E |
Referências
- Tushuizen, M. E., Diamant, M., Sturk, A., Nieuwland, R. Cell-derived microparticles in the pathogenesis of cardiovascular disease: friend or foe. Arterioscler Thromb Vasc Biol. 31 (1), 4-9 (2011).
- Martinez, M. C., Tual-Chalot, S., Leonetti, D., Andriantsitohaina, R. Microparticles: targets and tools in cardiovascular disease. Trends Pharmacol Sci. 32 (11), 659-665 (2011).
- Benameur, T., Andriantsitohaina, R., Martinez, M. C. Therapeutic potential of plasma membrane-derived microparticles. Pharmacol Rep. 61 (1), 49-57 (2009).
- Yang, C., et al. Lymphocytic microparticles inhibit angiogenesis by stimulating oxidative stress and negatively regulating VEGF-induced pathways. Am J Physiol Regul Integr Comp Physiol. 294 (2), 467-476 (2008).
- Yang, C., Gagnon, C., Hou, X., Hardy, P. Low density lipoprotein receptor mediates anti-VEGF effect of lymphocyte T-derived microparticles in Lewis lung carcinoma cells. Cancer Biol Ther. 10 (5), 448-456 (2010).
- Angelillo-Scherrer, A. Leukocyte-derived microparticles in vascular homeostasis. Circ Res. 110 (2), 356-369 (2012).
- Maeno, T., et al. CD8+ T Cells are required for inflammation and destruction in cigarette smoke-induced emphysema in mice. J Immunol. 178 (12), 8090-8096 (2007).
- Qiu, Q., Xiong, W., Yang, C., Gagnon, C., Hardy, P. Lymphocyte-derived microparticles induce bronchial epithelial cells’ pro-inflammatory cytokine production and apoptosis. Mol Immunol. 55 (3-4), 220-230 (2013).
- Martin, S., et al. Shed membrane particles from T lymphocytes impair endothelial function and regulate endothelial protein expression. Circulation. 109 (13), 1653-1659 (2004).
- Shet, A. S., et al. Sickle blood contains tissue factor-positive microparticles derived from endothelial cells and monocytes. Blood. 102 (7), 2678-2683 (2003).
- Mause, S. F., Weber, C. Microparticles: protagonists of a novel communication network for intercellular information exchange. Circ Res. 107 (9), 1047-1057 (2010).
- Yang, C., et al. Anti-proliferative and anti-tumour effects of lymphocyte-derived microparticles are neither species- nor tumour-type specific. J Extracell Vesicles. 3, (2014).
- Soleti, R., et al. Microparticles harboring Sonic Hedgehog promote angiogenesis through the upregulation of adhesion proteins and proangiogenic factors. Carcinogenesis. 30 (4), 580-588 (2009).
