Entwicklung eines<em> In Vitro</em> Assay Kontraktionsfunktion von mesenchymalen Zellen, die Unterzog Epithelial-mesenchymale Transition zur Bewertung
Summary
Here, we describe the development and application of a gel contraction assay for evaluating contractile function in mesenchymal cells that underwent epithelial-mesenchymal transition.
Abstract
Fibrosis is often involved in the pathogenesis of various chronic progressive diseases such as interstitial pulmonary disease. Pathological hallmark is the formation of fibroblastic foci, which is associated with the disease severity. Mesenchymal cells consisting of the fibroblastic foci are proposed to be derived from several cell sources, including originally resident intrapulmonary fibroblasts and circulating fibrocytes from bone marrow. Recently, mesenchymal cells that underwent epithelial-mesenchymal transition (EMT) have been also supposed to contribute to the pathogenesis of fibrosis. In addition, EMT can be induced by transforming growth factor β, and EMT can be enhanced by pro-inflammatory cytokines like tumor necrosis factor α. The gel contraction assay is an ideal in vitro model for the evaluation of contractility, which is one of the characteristic functions of fibroblasts and contributes to wound repair and fibrosis. Here, the development of a gel contraction assay is demonstrated for evaluating contractile ability of mesenchymal cells that underwent EMT.
Introduction
Fibrose ist in der Pathogenese verschiedener chronisch progressive Erkrankungen, wie interstitielle Lungenerkrankung, Herzfibrose, Leberzirrhose, terminalem Nierenversagen, systemischer Sklerose, Autoimmunerkrankung und 1 beteiligt. Unter interstitiellen Lungenerkrankungen, ist idiopathischer pulmonaler Fibrose (IPF) ist eine chronische progressive Krankheit und zeigt eine schlechte Prognose. Pathologisches Merkmal der IPF ist die Entwicklung von fibroblastischen Foci von aktivierten Fibroblasten und Myofibroblasten besteht, die mit der Prognose assoziiert sind. Die Ursprünge solcher Lungenfibroblasten vorgeschlagen von mehreren mesenchymalen Zellen abgeleitet werden, einschließlich ursprünglich resident Lungen Fibroblasten und Fibrozyten aus Knochenmark zirkuliert. Vor kurzem epithelial-mesenchymalen Übergang (EMT) wurde mit der Bildung von mesenchymalen Zellen 2, in Verbindung gebracht werden vorgeschlagen und zur Pathogenese von fibrotischen Erkrankungen beizutragen.
Es wird vermutet, dass EMT spielt eine wichtige Rolle im Prozess der fötalen Entwicklung, Wundheilung, und das Fortschreiten von Krebs, einschließlich der Tumorinvasion und Metastasierung 3. Nach dem Prozess des EMT, erhalten Epithelzellen die Fähigkeit der mesenchymalen Zellen , die durch Verlust von epithelialen Marker, wie E-Cadherin, und durch Expression von mesenchymalen Marker, wie Vimentin und α-smooth muscle actin (SMA) 4,5. Frühere Studien zeigten die Hinweise , dass EMT Verfahren hat sich mit der Entwicklung von Gewebefibrose in der Niere und der Lunge 6 7 verbunden. Darüber hinaus fördert die chronische Entzündung fibrotischen Erkrankung 8; Ferner, wie inflammatorische Zytokine wie Tumor – Nekrose – Faktor -Superfamilienmitglied 14 (TNFSF14; LIGHT), Tumor – Nekrose – Faktor (TNF) -α, und Interleukin-1β wurden EMT 9-12 gezeigt , zu verbessern.
Collagen-Gel Kontraktion Assay, ein Kollagen-basierte Zellkontraktion Test, bei dem Fibroblasten in Typ I eingebettet sindKollagengel dreidimensional, ist ein ideales in vitro – Modell für die Bewertung der Kontraktilität. Kontraktionsfähigkeit ist eines der charakteristischen Funktionen von Fibroblasten und trägt zu einer normalen Wundheilung und Fibrose 13. In diesem Test wird angenommen, dass die Bindung von Fibroblasten Integrin-abhängige Mechanismen Kollagen durch sollen Typ I mechanische Spannung unter bestimmten Bedingungen zu erzeugen, und damit zur Gewebekontraktion führen.
Hierbei wird die Entwicklung der Gelkontraktion Assays berichtet angepasst werden, um die Übernahme der kontraktilen Funktion in den Zellen zu bewerten, die EMT unterzog. Dieser Bericht zeigt, dass sich diese modifizierte Test zur Bewertung der Kontraktilität in mesenchymalen Zellen geeignet ist, die EMT unterzog.
Protocol
Representative Results
Discussion
Das Protokoll in dieser Studie entwickelt umfasst zwei Schritte. Der erste Schritt wird durchgeführt, EMT zu induzieren, während der zweite Schritt ist die Gelkontraktion Assays. Da es wichtig ist, um zu bestätigen, dass die Zellen EMT unterzog, Stufe 2 bietet eine hervorragende Ergänzung zu den morphologischen und Veränderungen der Genexpression. Frühere Studien zeigten , dass EMT von A549 – Zellen durch TGF-β1 induzierten wurde nur 24; aber, wie wir vorher 10, TNF-α – Behandlung berichtet…
Disclosures
The authors have nothing to disclose.
Acknowledgements
We thank Dr. Tadashi Koyama for technical help. This work was supported in part by JSPS KAKENHI Grant Numbers 23249045, 15K09211, 15K19172; a grant to the Respiratory Failure Research Group from the Ministry of Health, Labour and Welfare, Japan; a grant for research on allergic disease and immunology, Japan.
Materials
| DMEM | sigma aldrich | 11965-092 | For A549 medium |
| FBS | GIBCO | 10437 | |
| Transforming Growth Factor-β1, Human, recombinant | Wako Laboratory chemicals | 209-16544 | |
| Recombinant Human TNF-α | R&D systems | 210-TA/CF | |
| E-Cadherin (24E10) Rabbit mAb | Cell Signaling Technology | #3195 | 1:3000 dilution |
| Vimentin (D21H3) Rabbit mAb | Cell Signaling Technology | #5741 | 1:3000 dilution |
| Anti-α-Tubulin antibody | sigma aldrich | T9026 | 1:10000 dilution |
| Monoclonal Anti-Actin, α-Smooth Muscle antibody | sigma aldrich | A5228 | 1:10000 dilution |
| Anti-N-cadherin antibody | BD Transduction Laboratories | #610920 | 1:1000 dilution |
| Anti-Mouse IgG, HRP-Linked Whole Ab Sheep (secondary antibody) | GE Healthcare | NA931-100UL | 1:20000 dilution |
| Anti-Rabbit IgG, HRP-Linked Whole Ab Donkey (secondary antibody) | GE Healthcare | NA934-100UL | 1:20000 dilution |
| blocking reagent | GE Healthcare | RPN418 | 2% in TBS-T |
| 6 Well Clear Flat Bottom TC-Treated Multiwell Cell Culture Plate, with Lid | corning | #353046 | |
| 100 mm cell culture dish | TPP | #93100 | |
| DMEM, powder | life technologies | 12100-046 | For 4×DMEM |
| type 1 collagen gel | Nitta gelatin | Cellmatrix type I-A | |
| 24 well cell culture plate | AGC TECHNO GLASS | 1820-024 | |
| Gel Documentation System | ATTO | AE-6911FXN | Gel imager |
| gel analyzing software | ATTO | Densitograph, ver. 3.00 | analysing software bundled with AE-6911FXN |
| Trypsin-EDTA (0.05%), phenol red | life technologies | 25300054 | |
| 24 Well Plates, Non-Treated | IWAKI | 1820-024 | |
| Trypan Blue Solution, 0.4% | life technologies | 15250-061 | |
| RNA extraction kit | Qiagen | 74106 | |
| reverse transcriptase | life technologies | 18080044 | |
| real time PCR system | Stratagene | Mx-3000P | |
| SYBR green PCR kit | Qiagen | 204145 | |
| Protease Inhibitor Cocktail (100X) | life technologies | 78429 | |
| PVDF membrane | ATTO | 2392390 | |
| protein assay kit | bio-rad | 5000006JA | |
| polyacrylamide gel | ATTO | 2331810 | |
| western blotting detection reagent | GE Healthcare | RPN2232 | |
| cold CCD camera | ATTO | Ez-Capture MG/ST | |
| Trypsin inhibitor | sigma aldrich | T9003-100MG | |
| Polyoxyethylene (20)Sorbitan Monolaurate | Wako Laboratory chemicals | 163-11512 | |
| polyoxyethylene (9) octyiphenyl ether | Wako Laboratory chemicals | 141-08321 |
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