Journal of Histochemistry and Cytochemistry, Vol. 50, 1697-1698, December 2002, Copyright © 2002, The Histochemical Society, Inc.
Suspension (S)-FISH, a New Technique for Interphase Nuclei
Ulf Steinhaeusera,
Heike Starkea,
Angela Nietzela,
Joerg Lindenaub,
Peter Ullmannb,
Uwe Claussena, and
Thomas Liehra
a Institute of Human Genetics, Jena, Germany
b Carl Zeiss Jena GmbH, Jena, Germany
Correspondence to:
Thomas Liehr, Institut für Humangenetik, Postfach, D-07740 Jena, Germany. E-mail: i8lith@mti-n.mti.uni-jena.de
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Summary |
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We describe a versatile method for performing fluorescence in situ hybridization (FISH) in suspension instead of on a slide as usually done. This so-called suspension-FISH (S-FISH) opens new possibilities for the analysis of shape and functions of the human interphase nucleus. The procedure is described and the first results using this approach are presented. (J Histochem Cytochem 50:16971698, 2002)
Key Words:
FISH, suspension FISH (S-FISH), interphase, nuclear architecture
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Introduction |
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FLUORESCENCE in situ hybridization (FISH) on human chromosomes in meta- and interphase is a technique well established in clinical and tumor cytogenetics as well as for studies of evolutional and interphase architecture (for review see Liehr and Claussen 2002a
, Liehr and Claussen 2002b
; and internet http://mti-n.mti.uni-jena.de/~huwww/MOL_ZYTO/mFISHlit.htm). However, all published FISH approaches are based on the air-drying procedure of chromosome preparation (Verma and Babu 1989
). After hypotonic treatment and fixing the cells in methanol/acetic acid, they are spread on the slide surface and air-dried. This procedure leads to well spread metaphases on the slide surface if adequate humidity in the air is present, and to flattening of the originally spherical interphase nuclei. This air-drying procedure is well-suited for nearly all FISH approaches. However, when interphase architecture is to be studied (for review see Chevret et al. 2000
; Cremer and Cremer 2001
), the flattening of the nuclei may lead to questionable results (Fig 1A).

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Figure 1.
Two normal interphase nuclei from peripheral blood, added to a slide using the usual air-drying method after hybridization with a centromeric probe for chromosome 17 (cen 17, labeled in green) are depicted. Whereas the upper nucleus shows the usual hybridization pattern, the lower has one normal and one abnormal (arrowhead) green signal. The latter is not spot-like but is stretched artificially over the entire nucleus due to the flattening process. Images for 1-3 were captured with the ISIS digital FISH imaging system (MetaSystems; Altlussheim, Germany) using a XC77 CCD camera with on-chip integration (Sony).
Figure 2. Result of S-FISH using the same centromere-specific probe for chromosome 17 (cen 17) as in Fig 1. Two interphase nuclei plus one partial metaphase showing two signals each are visible. By chance, all six signals were within the focus.
Figure 3. S-FISH result using two differently labeled probes. The interphase nucleus shows two red signals for the entire chromosome stained specific for chromosome 17 (wcp 17), but only one specific green signal of centromere-specific probe for chromosome 17 (cen 17) is depicted. The other was present but is out of focus.
Figure 4. S-FISH results taken with the Zeiss Laser Scanning Microscope LSM 510 META. These are 5-µm optical sectionings of two interphase nuclei hybridized with a centromere-specific probe for chromosome 17 (cen 17) (am). (n) A schematic of the two nuclei (black) and the signals within them (white). All green signals are about 15 µm in size. Whereas in nucleus II there are only two specific signals, in nucleus I three of them are visible. However, the analyzed blood cells were taken from a healthy person and two of the three signals are co-localized. Therefore, it is highly probable that those co-localized signals are due to premature chromatid distribution of one chromosome.
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Here we present for the first time a technique in which the entire FISH procedure is performed on a cell suspension and the cells are placed on a polished concave slide as the final step of the procedure, just before the evaluation. We call this procedure suspension-FISH (S-FISH) and show that it is possible to do 3D analyses on totally spherical interphase nuclei or even on 3D metaphases (Fig 2).
The S-FISH method is performed as follows:
- The cell suspension is centrifuged for 10 min at 700 rpm, the supernatant is discarded, and the pellet is re-suspended in 500 µl of methanol.
- Centrifuge between each step mentioned below, always using the same conditions for centrifugation as previously mentioned: 10 min, 700 rpm. Work at room temperature unless otherwise stated.
- Discard 450 µl of the supernatant, add
450 µl 0.9% NaCl, and incubate for 3 min.
- Replace the supernatant by 450 µl pepsin solution [i.e., 475 µl H2O, 25 µl 0.2 N HCl, 0.005% pepsin (Fluka 77163; Buchs, Switzerland)] and incubate for 5 min at 37C.
- Replace the supernatant by
450 µl 1 x PBS and incubate for 90 sec to remove the pepsin.
- Replace the PBS by 70% formamide/2 x SSC and incubate for 1 min.
- Add 25 µl 50% formamide/2 x SSC containing the probe and 20 µg of the blocking DNA (i.e., COT1). Three times the usually applied amount of the corresponding probe is used, i.e., for centromeres 60 ng and for whole chromosome paints 3 µg. Only directly labeled probes have been used thus far. Do not centrifuge but go on with the next step.
- Denature for 57 min at 80C and hybridize for 1216 hr at 37C in a thermocycler. Finish the hybridization by adding 600 µl of 0.4 SSC (68C). Incubate for 2 min and centrifuge.
- Replace the supernatant by 600 µl 1 x PBS at RT for 2 min.
- Replace the supernatant by 600 µl 4 x SSC/0.2% Tween at RT for 2 min.
- Re-suspend the pellet in 50 µl of antifade (e.g., Vectashield; Vector, Burlingame, CA); add 0.4 µg DAPI and place the solution on a slide [special slides, e.g., epoxy-covered ones (Roth L195.1) are best suited], cover with a coverslip, and evaluate with a fluorescence microscope. Before evaluation pre-cool the slide at 20C to make the antifade solution more viscous so that the nuclei do not move during image assessment.
The artificial flattening of interphase nuclei using the air-drying method can lead to very peculiar results when interphase diagnostics are performed. Even though the single nucleus shown in Fig 1 (arrowhead) is a very extreme example, such or similar nuclei are well known to any molecular cytogeneticist. It is therefore clear that interphase analyses with the goal of learning about interphase architecture performed on such nuclei may not reflect the in vivo situation. Therefore, we developed the S-FISH approach, which makes it possible to analyze totally spherical interphase nuclei.
The S-FISH approach has been tested successfully on 10 different chromosomal suspensions using one- to five-color FISH experiments. The evaluation was done with a Zeiss Axioplan 2 microscope (Fig 2 and Fig 3) or with a Zeiss Laser Scanning Microscope LSM 510 META (Fig 4). By these experiments it could be demonstrated (a) that is in principle possible to perform the complete FISH procedure in suspension, (b) that it is not necessary for evaluation of the interphase nuclei that they be fixed (and flattened) on the slide surface, and (c) that even metaphases can be analyzed three-dimensionally in principle by S-FISH (Fig 2). At present there is still the disadvantage that a three-fold probe volume has to be used compared to the normal FISH procedure. However, new horizons for analyses of the "real" interphase architecture are now open.
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Acknowledgments |
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Supported by the Herbert Quandt Stiftung der VARTA AG, the Wilhelm Sander-Stiftung (99.105.1), and the EU (ICA2-CT-2000-10012 and QLRT-1999-31590). The continuing support of the Carl Zeiss GmbH (Jena, Germany) is gratefully acknowledged.
Received for publication June 6, 2002; accepted July 24, 2002.
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Literature Cited |
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Chevret E, Volpi EV, Sheer D (2000) Mini review: form and function in the human interphase chromosome. Cytogenet Cell Genet 90:13-21[Medline]
Cremer T, Cremer C (2001) Chromosome territories, nuclear architecture and gene regulation in mammalian cells. Nature Rev Genet 2:292-301[Medline]
Liehr T, Claussen U (2002a) Review: multicolor-FISH approaches for the characterization of human chromosomes in clinical genetics and tumor cytogenetics. Curr Genomics 3:213-235
Liehr T, Claussen U (2002b) Review: recent developments in human molecular cytogenetics. Curr Mol Med 2:283-297[Medline]
Verma RS, Babu A (1989) Human chromosomesManual of Basic Techniques. New York, Oxford, Beijing, Frankfurt, Sao Paulo, Sydney, Tokyo, Toronto, Pergamon Press