Fare İskelet Kası Algılama ve DNA Hasar Analizi<em> In Situ</em> TÜNEL Yöntemiyle
Summary
This video describes dissection, tissue processing, sectioning, and fluorescence-based TUNEL labeling of mouse skeletal muscle. It also describes a method for semi-automated analysis of TUNEL labeling.
Abstract
Terminal deoxynucleotidyl transferase (TdT) deoxyuridine triphosphate (dUTP) nick end labeling (TUNEL) is the method of using the TdT enzyme to covalently attach a tagged form of dUTP to 3’ ends of double- and single-stranded DNA breaks in cells. It is a reliable and useful method to detect DNA damage and cell death in situ. This video describes dissection, tissue processing, sectioning, and fluorescence-based TUNEL labeling of mouse skeletal muscle. It also describes a method of semi-automated TUNEL signal quantitation. Inherent normal tissue features and tissue processing conditions affect the ability of the TdT enzyme to efficiently label DNA. Tissue processing may also add undesirable autofluorescence that will interfere with TUNEL signal detection. Therefore, it is important to empirically determine tissue processing and TUNEL labeling methods that will yield the optimal signal-to-noise ratio for subsequent quantitation. The fluorescence-based assay described here provides a way to exclude autofluorescent signal by digital channel subtraction. The TUNEL assay, used with appropriate tissue processing techniques and controls, is a relatively fast, reproducible, quantitative method for detecting apoptosis in tissue. It can be used to confirm DNA damage and apoptosis as pathological mechanisms, to identify affected cell types, and to assess the efficacy of therapeutic treatments in vivo.
Introduction
Terminal deoksinükleotidil transferaz (TdT) dUTP çentik uç etiketleme (TÜNEL) dUTP 3 bağlamak için TdT enzim kullanılarak işlemidir 'çift ve tek bükümlü DNA 12,23 sonları arasında sona erer. Apoptoz ve DNA hasarının tespiti için TÜNEL metodu ilk Gavrieli ve ark. 1,12,24 tarafından, 20 yıl kadar önce bildirildi. O zamandan beri değerlendirilir ve farklı doku hazırlıkları 7,23,27,40 optimize edilmiştir. TÜNEL nöronlar 6,14,29 ve 43,44 kardiyomiyositlerde ve iskemiye bağlı hücre ölümü, eksitotoksik nöronal hücre ölümünü 30,31 incelemek için kullanılan ve artrit tedavisinde 39 bir biyolojik olarak edilmiştir. Aynı zamanda, çeşitli insan kanserlerinde 2,3,15,32,37,38,42 bir prognostik faktör ve tümör hücre markeri olarak kullanılmıştır.
Alternatif yöntemler DNA hasarı ve hücre ölümü tespiti için var, ama onlar, teknik zorlukları ve uyarılar var. Southern lekeleme quantif için kullanılabilmektedirY bir DNA tam doku lysate'lerin 7,9-11 hasar, ancak bu yöntem hücre düzeyinde çözümlemesi sağlamak ve ölçmek için zor değildir. kuyrukluyıldız tahlil hücrelerinden 4,20,28,36 korunmuş çekirdekleri ayıklanan gerektiren bir alternatif hücre tabanlı bir yöntemdir. Kuyrukluyıldız tahlil kültüre izole hücreler üzerinde iyi çalışır rağmen, iskelet kas dokusunda 8,21 den sağlam çekirdekleri hazırlamak için çok daha zordur. Güney blot gibi, kuyrukluyıldız tahlil bütün kas dokusu homojenattan hücre türüne özgü bilgi vermemektedir. TÜNEL yöntemiyle için başka bir alternatif, tek kordonlu DNA 25,33,41 karşı veya DNA hasarına ve hücre ölümü yolları (örneğin, p53, H2AX ve Kaspaz) 13,17,22,40 katılmak proteinlerine karşı antikorlar kullanılarak immunohistokimyasal olup. Bu gibi antikor bazlı yöntemler, yüksek bir sinyal-arka oranını elde etmek için antikorların tam karakterizasyon ve mükemmel antikor özelliklerini gerektirir. Hatta zaman spectüpte antikorlar antijen alma prosedürleri 34,35 ile hedef proteinin denatürasyon gerektirebilir, mevcuttur. Burada tartışmak gibi, kabul edilemeyecek kadar yüksek otofloresans kas dokusu sonuçlarında antijen alma. Alternatif yöntemlerin aksine, TUNEL basit pozitif ve negatif kontroller, iyi doku penetrasyonu antijeni alma gerektirmez ve hücresel düzey çözünürlük ile test edilebilir bir yüksek sinyal ve düşük arka plan, mükemmel özgüllük ile DNA hasarı algılama ulaşır. Alternatif yöntemler, tipik olarak gece boyunca inkubasyon gerek duyması karşısında ek olarak, TÜNEL metodu, işlemin tamamlanması için yaklaşık 4 saat sürer.
Biz Hsieh-Li ve arkadaşları 16 tarafından oluşturulan spinal müsküler atrofi (SMA) 10 bir fare modelinde iskelet kas hücresi ölümünü incelemek. Kas hücreleri apoptotik ölçmek için, farklı Skele genelinde sağlam çalışır doku hazırlanması, boyama ve kantitatif bir yöntem geliştirdikFarelerde farklı gelişimsel zaman noktalarında tal kas grupları. Biz piyasada mevcut TÜNEL-etiketleme kiti ve ticari olarak satılan görüntü analiz yazılımı kullanmak. Biz de başarıyla omurilik 10 immunofluorescent boyama birlikte TÜNEL tahlili kullandık.
Burada tarif edilen yöntemler, iskelet kası, doku patolojisi, hastalığın mekanizmaları, yaşlanmanın mekanizmasını ve gelişim (uygulama öncesi ve sonrası), hücre ölümünü değerlendirmek isteyen araştırmacılar için yararlıdır. TÜNEL tekniği hücrelerinin sadece bir alt grubu, etkilenen ve hücresel düzeyde çözünürlüğü gereklidir modeli sistemlerinde DNA hasarı tamir ve hücre ölümünün çalışmalar için özellikle yararlıdır.
Bu video diseksiyon, doku işleme, kesit ve fare iskelet kası flüoresan bazlı TÜNEL etiketleme tarif etmektedir. Aynı zamanda, yarı otomatik TÜNEL sinyal sayımı için bir yöntem tarif etmektedir.
Protocol
Representative Results
Discussion
Bir yöntem algılamak ve nicel olarak açıklanan fare iskelet kasında DNA hasarı ile ilişkili apoptozu analiz etmek. Prosedür doku hasadı, TUNEL boyama, dijital görüntü alımını ve görüntü analizi içerir. Ortak histolojik malzemeler ve aletler gereklidir, ve özel ticari TÜNEL kiti gereklidir. gerekli temel büyük ekipman öğeleri Kriyostaz, dijital görüntü özelliğine sahip epifluorescent mikroskop ve görüntü analizi için bir bilgisayar sistemi vardır.
deneyci po…
Divulgazioni
The authors have nothing to disclose.
Acknowledgements
This work was supported by NIH-NINDS grant RO1-NS065895 and NIH-NINDS grant 5-F31-NS076250-02.
We thank JHU SOM Microscope Facility for the use of the cryostat.
Materials
| Name of Reagent/ Equipment | Company | Catalog Number | Comments/Description |
| 4% Paraformaldehyde in phosphate buffered saline | Electron Microscopy Sciences | 19202 | For procedures described here, 4% solution was prepared fresh from powder. Paraformaldehyde from any supplier may be used. Prepared formaldehyde solution should be stored at 4 °C and should not be used after its expiration date (up to several months). Paraformaldehyde is a carcinogen and a toxin by inhalation and skin contact. Please follow precautions specified in the MSDS when handling paraformaldehyde. |
| Sucrose | Sigma | S0389 | Used for cryoprotecting tissue before freezing. Sucrose from any supplier may be used. |
| O.C.T. compound | Tissue-Tek | 4583 | Embedding medium for cryosectioning. |
| Cryostat | Leica | CM 3050S | A Leica CM3050S cryostat was used for the preparations described here. Any cryostat capable of cutting 10 μm sections may be used. |
| Glass slides, 25 x 75 x 1 mm | Fisher | 12-552-3 | Slides from any supplier may be used. |
| Gelatin | Sigma | G-9391 | Gelatin is used to promote tissue section adhesion to glass slides. To coat glass slides with gelatin, dissolve 2.75 g gelatin and 0.275 g chrome alum in 500 mL distilled water, warm to 60 °C, dip slides for several seconds, and let dry. Gelatin from any supplier may be used. Alternatively, gelatin-precoated slides may be purchased. |
| Chromium(III) potassium sulfate dodecahydrate (chrome alum) | Sigma | 243361 | Chrome alum is added to gelatin solution to promote tissue adhesion on glass slides. It is a possible carcinogen and a toxin by inhalation and skin contact. Please follow precautions specified in the MSDS when handling chrome alum. |
| Vectabond tissue adhesion reagent | Vector Labs | SP-1800 | Optional substrate for better tissue adhesion to glass slides; gellatin-coated slides may be used instead. |
| Tween20 | Sigma | P9416 | A detergent used to permeabilize tissue. Tween20 from any supplier may be used. |
| Triton X100 | Sigma | T8787 | A detergent used to permeabilize tissue. Triton X100 from any supplier may be used. |
| TACS 2 TdT fluorescein in situ apoptosis detection kit | Trevigen | 4812-30-K | Commercial kit for fluorescence-based TUNEL labeling. |
| DNase/nuclease | Trevigen | 4812-30-K | (included with kit) |
| DNase/nuclease buffer | Trevigen | 4812-30-K | (included with kit) |
| 10x phosphate buffered saline (PBS), pH 7.4 | Amresco | 780 | Make 1x PBS for washes and dilutions. PBS from any supplier may be used. |
| DNase-free water | Quality Biologicals | 351-029-131 | Water from any supplier may be used. |
| Hoechst 33258 | Sigma | 94403 | Nuclear dye. Any blue fluorescent nuclear dye may be used. As a DNA-binding dye, Hoechst is a suspected carcinogen and should be handled with protective equipment to minimize skin contact. |
| Parafilm M | multiple | 807 | Any other hydrophobic film or cover slip may be used. Available from multiple suppliers. |
| Fluorescent microscope with digital camera | – | – | Any fluorescent microscope capable of digitally capturing red, green, and blue fluorescence in separate channels may be used. |
| Vectashield antifade media | Vector Labs | H-1000 | Antifade media from any supplier may be used. |
| glass coverslips, No.1 thickness | Brain Research Labs | 2222-1 | Cover slips from any supplier may be used. The smallest size of 22×22 mm is sufficient for neonatal mouse leg sections. |
| Nail polish | Ted Pella | 114-8 | Used to seal coverslips. Nail polish from any supplier (including regular retailers) may be used. Avoid using nail polish with color or additives that may reflect light during fluorescent imaging. |
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