Summary

여러 형광에 의한 간 염색체 안정 수차의 검출<em> 현장에서</em> 하이브리드 (mFISH) 및 방사선 조사 마우스의 스펙트럼 핵형 분석 (SKY)

Published: January 11, 2017
doi:

Summary

The present protocol describes the usefulness of multiple fluorescence in situ hybridization (mFISH) and spectral karyotyping (SKY) in identifying inter-chromosomal stable aberrations in the bone marrow cells of mice after exposure to total body irradiation.

Abstract

Ionizing radiation (IR) induces numerous stable and unstable chromosomal aberrations. Unstable aberrations, where chromosome morphology is substantially compromised, can easily be identified by conventional chromosome staining techniques. However, detection of stable aberrations, which involve exchange or translocation of genetic materials without considerable modification in the chromosome morphology, requires sophisticated chromosome painting techniques that rely on in situ hybridization of fluorescently labeled DNA probes, a chromosome painting technique popularly known as fluorescence in situ hybridization (FISH). FISH probes can be specific for whole chromosome/s or precise sub-region on chromosome/s. The method not only allows visualization of stable aberrations, but it can also allow detection of the chromosome/s or specific DNA sequence/s involved in a particular aberration formation. A variety of chromosome painting techniques are available in cytogenetics; here two highly sensitive methods, multiple fluorescence in situ hybridization (mFISH) and spectral karyotyping (SKY), are discussed to identify inter-chromosomal stable aberrations that form in the bone marrow cells of mice after exposure to total body irradiation. Although both techniques rely on fluorescent labeled DNA probes, the method of detection and the process of image acquisition of the fluorescent signals are different. These two techniques have been used in various research areas, such as radiation biology, cancer cytogenetics, retrospective radiation biodosimetry, clinical cytogenetics, evolutionary cytogenetics, and comparative cytogenetics.

Introduction

The two most reliable methods of identifying radiation-induced inter-chromosomal stable aberrations are multiple fluorescence in situ hybridization (mFISH), which allows the painting of two or more chromosomes simultaneously, and spectral karyotyping (SKY), which imparts a distinct color to each homologous chromosome pair in the genome. Unlike unstable aberrations, stable aberrations are persistent in nature and may be propagated for several generations in irradiated populations1, and are regarded as critical molecular “signatures” of radiation-induced cytogenetic lesions2. Studies by various groups have shown that stable aberrations are associated with the pathogenesis and development of a number of diseases, including cancer3. Before the era of chromosome painting (also referred as molecular cytogenetics), the conventional G-banding technique was the only method for detecting stable chromosomal aberrations. However, chromosome banding is a challenge to cytogeneticists because the resolution is limited, reproducibility is uncertain, it is a labor-intensive procedure, and it requires highly skilled and experienced cytogeneticists for reliable data interpretation4. Moreover, the classic banding technique does not allow detection of complex chromosomal rearrangements, which involve the interaction of three or more breaks distributed among two or more chromosomes, a common outcome of radiation damage. Complex aberrations may persist in individuals many years after radiation exposure, making them useful for retrospective biodosimetry5. Therefore, an alternate approach was required to overcome the limitations of conventional banding techniques to detect stable chromosomal rearrangements.

In the late 1960s, the pioneering work of Gall and Pardue (1969) on molecular hybridization using nucleic acid probes labeled with radioactive material commenced a new era in the field of cytogenetics, which allowed detection of a specific DNA sequence on chromosomes6. However, the use of radioactive probes for molecular hybridization had several drawbacks: radioactive probes are relatively unstable, probe activity depends on radioactive decay of the isotope used, hybridization takes a longer time, the resolution is limited, the probes are relatively costly, and the radioactive materials are a health hazardous. Thus, it became necessary to develop and design non-radioactive probes. The introduction of fluorescent tagged nucleic acid probes in the 1980s and 1990s overcame the limitations of radioactive probes and greatly enhanced the safety, sensitivity, and specificity of the hybridization technique7-10. Fluorescent probes give rise to extremely bright signals when observed under fluorescence microscopes equipped with the appropriate excitation and emission filters. Any loss, gain, or rearrangement of fluorescent labeled chromosome/s or a part of the chromosome is easily identifiable with this FISH technique.

Analysis of chromosomal aberrations by FISH painting has led to marked progress in cytogenetic research over the years. Designing fluorescent labeled probes for specific applications ranging from locus-specific probes to whole-chromosome painting probes has advanced the field significantly; this has also facilitated the detection of submicroscopic (“cryptic”) rearrangement, which was not possible by conventional chromosome banding. Chromosome painting by mFISH and SKY have proven to be valuable tools for the identification of simple and complex inter-chromosomal rearrangements. The basic principles for both techniques are similar, but the method of detection and discrimination of fluorescent signal after in situ hybridization and the process of image acquisition are different. In mFISH, separate images of each of the four fluorochromes are captured by using narrow bandpass microscope filters; dedicated software is then used to combine the images. While in SKY, image acquirement is based on a combination of epifluorescence microscopy, charge-coupled device imaging, and Fourier spectroscopy, which allows the measurement of the entire emission spectrum with a single exposure at all image points. In both mFISH and SKY, monochrome images are captured independently, then merged, and finally, unique pseudo-colors are assigned to the chromosomes in monochromatic images based on the specific dye attached to each fluorochrome probe.

The contribution of mFISH and SKY analysis in the radiation biology field is remarkable, particularly for retrospective dose estimation of human exposure to IR (radiation biodosimetry)11-14, radiation carcinogenesis risk assessment15, as well as detection and risk estimation of radiotherapy-related secondary cancer16. A recent study on mice has shown that a FISH-based chromosome painting technique is also an important tool for evaluating the efficacy of radiation countermeasure17. In the present study, the effect of total body radiation exposure on the induction of stable chromosomal aberrations in the bone marrow cells of mice has been demonstrated using mFISH and SKY techniques.

Protocol

모든 동물 연구는 국립 보건원 (National Institutes of Health)의 실험 동물의 관리 및 사용에 대한 가이드의 권장 사항을 엄격히 준수하여 수행 하였다. 동물 프로토콜은 의료 과학에 대한 아칸소 대학의 기관 동물 관리 및 사용위원회에 의해 승인되었다. 신선한 공기와 표준 설치류 음식과 물을 무료로 이용할 수의 15 시간당 사이클 – 모든 동물은 10 20 ± 2 ℃에서 표준 에어컨 동물 시설에서 보관 하였다….

Representative Results

전신 방사선 조사 된 마우스의 골수 세포에서 다수의 염색체 수차를 유도한다. 현재 프로토콜은 방사선 조사 후 골수 세포의 생체 유사 분열 정지를 위해 최적화되고, 밀도 구배 원심 분리, 중기 세포 퍼짐의 제조 및 후속 의해 조사 생쥐 골수 단핵 세포의 분리의 뒷다리 골수 세포의 수확 mFISH과 SKY 기술에 의해 방사선 유발 안정적인 염색체 이상 검출. 염색체 이들 …

Discussion

몇 가지 중요한 단계는 mFISH과 SKY의 성공을 결정합니다. 첫번째 가장 중요한 단계는 골수 단핵 세포의 생체 유사 분열 정지를위한 콜히친 처리를 최적화한다. 콜히친 농도와 처리 시간을 개별적으로 또는 콘서트에 효과적인 염색체 그림의 유사 분열 지수뿐만 아니라 염색체 응축 – 두 가지 중요한 전제 조건을 결정한다. 높은 콜히친 농도 이상 처리 시간은 적절한 변성과 하이브리드에 대한…

Divulgations

The authors have nothing to disclose.

Acknowledgements

본 연구는 국립 항공 우주국 통해 아칸소 공간 그랜트 협회와 국립 우주 바이오 메디컬 연구소에 의해 지원되었다, 부여 NNX15AK32A (RP) 및 RE03701 (MH-J), 및 P20의 GM109005 (MH-J), 미국 재향 군인의 관리 ( MH-J). 우리는 원고의 준비 편집 지원 크리스토퍼 Fettes, 의료 과학 아칸소 대학의 환경 및 산업 보건학과에 대한 프로그램 코디네이터, 감사합니다.

Materials

Formamide Sigma-Aldrich 221198-100ML
SSC Buffer 20× Concentrate Sigma-Aldrich S6639-1L
SKY Laboratory Reagent for Mouse Applied Spectral Imaging FPRPR0030/M40
CAD – Concentrated Antibody Detection Kit Applied Spectral Imaging FPRPR0033
Single Paints Customized – 3 Colors; Mouse chromosome 1: Red, Mouse chromosome 2: Green, Mouse chromosome 3: Aqua Applied Spectral Imaging FPRPR0182/10
Glass coverslips Fisher Scientific 12-545B
Tween 20 Fisher Scientific BP337-100
Hydrochloric acid, 37%, Acros Organics Fisher Scientific AC45055-0025 
Fisherbrand Glass Staining Dishes  with Screw Cap Fisher Scientific 08-816
KaryoMAX Potassium Chloride Solution  Life Technologies 10575-090
Fisherbrand Superfrost Plus Microscope Slides Fisher Scientific 12-550-15
Colcemid powder Fisher Scientific 50-464-757 
Histopaque-1083  Sigma-Aldrich 10831
Shepherd Mark I, model 25 137Cs irradiator J. L. Shepherd & Associates Model 484B
Syringe 1 ml BD Biosciences 647911
Ethyl Alcohol, 200 Proof Fisher Scientific MEX02761
PBS, (1X PBS Liq.), w/o Calcium and Magnesium Fisher Scientific ICN1860454
Fetal Bovine Serum Fisher Scientific 10-437-010
Methanol Fisher Scientific A454SK-4
Glacial acetic acid Fisher Scientific AC295320010
Zeiss Microscope Zeiss AXIO Imager.Z2

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Pathak, R., Koturbash, I., Hauer-Jensen, M. Detection of Inter-chromosomal Stable Aberrations by Multiple Fluorescence In Situ Hybridization (mFISH) and Spectral Karyotyping (SKY) in Irradiated Mice. J. Vis. Exp. (119), e55162, doi:10.3791/55162 (2017).

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