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doi:10.1369/jhc.5B6902.2006
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Volume 54 (7): 843-847, 2006
Copyright ©The Histochemical Society, Inc.
BRIEF REPORT |
Fluorescent Immunohistochemistry and In Situ Hybridization Analysis of Mouse Pancreas Using Low-power Antigen-retrieval Technique
Division of Research Immunology/Bone Marrow Transplantation, Childrens Hospital, Los Angeles, California (SG,GMC,XW), and Division of Cancer Immunotherapeutics and Tumor Immunology, City of Hope National Medical Center, Duarte, California (GM)
Correspondence to: Gay M. Crooks, MD, Division of Research Immunology/BMT, Childrens Hospital Los Angeles, 4650 Sunset Blvd. MS #62, Los Angeles, CA 90027. E-mail: gcrooks{at}chla.usc.edu
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Summary |
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To facilitate the immunological reaction of antibodies with antigens in fixed tissues, it is necessary to unmask or retrieve the antigens through pretreatment of the specimens. However, adjustment of heating-induced antigen retrieval is always required for different tissues and antigens. In this study, by using a low-power antigen-retrieval technique with appropriate dilution of antibodies, we successfully immunostained key antigens in pancreas such as insulin, PDX-1, glucagon, cytokeratin, and CD31, which have previously presented a particular challenge for investigators because of the rapid autodigestion and high nonspecific antibody binding in this tissue. Satisfactory results were obtained when immunohistochemistry and fluorescence in situ hybridization analysis were combined in the same slides. (J Histochem Cytochem 54:843–847, 2006)
Key Words: heating-induced antigen retrieval • low-power antigen-retrieval technique • fluorescence immunohistochemistry
FLUORESCENCE IMMUNOHISTOCHEMISTRY (IHC) has been proven to be a reliable and sensitive tool for morphological and functional analysis of cells in different organs, especially when it is successfully applied in paraffin-embedded tissues. Recovery of antigen in formalin-fixed, paraffin-embedded tissue sections is required prior to antibody binding and visualization. Antigen retrieval (AR) includes a variety of methods including enzymatic digestion or heat-induced epitope retrieval through microwave irradiation or pressure cooking or a combination of both. Enzyme-digestion-related AR fails to give consistent and satisfactory immunostaining for many antigens. However, the heat-induced antigen-retrieval (HIAR) technique, a method created by Shi et al. (1991)
of boiling paraffin tissue sections in water or microwaving slides at 90–100C has been widely used as a simple, effective method for unmasking the antigen in formalin-fixed tissue sections. However, there is not one specific HIAR protocol that can be universally applied to various antigens (Shi et al. 1997). Widespread application of IHC has raised critical issues concerning time-consuming modifications of protocols for different tissue types and different antigens. It would therefore be desirable to develop a technique that works well with the widest possible variety of tissue types and antigens. In the present study, we developed a low-power AR (LAR) technique and obtained satisfactory staining for all of the antigens tested in murine pancreas and in other organs. In addition, this technique was also applied to simultaneous analysis of IHC and fluorescence in situ hybridization (FISH) chromosome detection.
Following sacrifice, pancreas from adult immunodeficient (Nod/Scid/ß2-microglobulin-null) (Nod/Scid/ß2Mnull) mice (The Jackson Laboratory; Bar Harbor, ME) were dissected and fixed in 10% neutral-buffered formalin (pH 6.8–7.2) (Richard-Allan Scientific; Kalamazoo, MI) for 6 to 24 hr and then embedded in paraffin (Leica; Nussloch, Germany) and sectioned using a microtome (Leica). Five-µm-thick slides were dewaxed with 100% toluene (Sigma-Aldrich; St Louis, MO) and rehydrated. LAR was performed as follows: a maximum of eight slides were placed into a plastic jar (EMS; Hatfield, PA) filled with 275 ml, 1:100 Vector unmasking buffer (pH 6.0) according to manufacturer's instructions (Vector Laboratories; Burlingame, CA). The jar was located in the center of the microwave with lid off and was heated on a turnable plate in a microwave oven with multiple power settings (NN-S763WF, Genius Sensor 1350 W; Panasonic, Secaucus, NJ) at power level 4 (40%) for three cycles, 5 min for each cycle with 1-min break. One slide jar was processed each time. Although the temperature reached 100C in the jar, there was no bubbling or overflow and, thus, the buffer level in the jar remained unchanged in the whole process, allowing even treatment of all the slides in the jar. In contrast, when some slides were treated with conventional power level 10 (100%), buffer had to be replenished in each cycle due to the loss of fluid by overflow. The slides treated with low power and conventional power were cooled at room temperature on the bench for 30 min and then unmasking buffer was replaced with Tris-buffered saline containing 0.1% Tween-20 (TBST). Nonspecific binding was blocked with 250–300 µl, 100 mM, pH 7.5, TBST with 1% BSA and 5% normal donkey serum (IgG free, protease free; Jackson ImmunoResearch Laboratories, West Grove, PA) for at least 30 min until primary antibody was added. The proper working dilutions for each antibody were optimized for the system as shown in Table 1 to give the strongest specific antigen staining with the lowest nonspecific background.
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Images were viewed with a Leica DMRXA microscope (Bannockburn, IL) using a Plan Apo x20/1.0 or 1.25 numerical aperture, phase 3 differential interference contrast. Filter sets used were DAPI, chroma 31000, fluorescein 41001, Cy3, 41007a (Chroma Technology; Rockingham, VT). The microscope was equipped with a LS300W ozone-free xenon arc lamp (Sutter Instrument; Novato, CA) coupled to the microscope with a liquid light guide. Images were acquired with an Applied Spectral Imaging Ltd. SkyVision–2/VDS-1300 12-bit digital camera from EasyFISH software (Migdal Ha'Emek, Israel). To compare the sensitivity and specificity of the signals after low- and conventional-power treatment, identical exposure time and intensity parameters were used.
Figure 1A
demonstrates fluorescent signals of insulin for ß cells of pancreatic islets and pancytokeratin (CK) for pancreatic duct epithelial cells on the same slides with no background. Interestingly, the successful costaining of insulin and CK enabled us to detect insulin-expressing cells (insulin+) within the ductal epithelial layer, considered by some investigators to be islet stem cells (Gu et al. 1994; Bonner-Weir 2000; Lechner and Habener 2003). Another component of the islets, the 
cells that produce glucagons, could be identified in the peripheral areas of the islet surrounding the insulin+ cells after dual staining (Figure 1B). PDX-1 plays a key transcriptional role during the development of pancreas, and it is exclusively localized to ß cells in the adult (Peers et al. 1994). Figure 1C shows the coexpression of insulin in cytoplasm and PDX-1 in nuclei of ß cells of the pancreas, providing two markers for detecting ß cells.
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Blood vessel and pancreatic ducts both appear as hollow structures in the pancreas. When IHC staining with Abs against the epithelial marker CK and the endothelial marker PECAM (CD31) was applied to the pancreatic tissue, CK+ duct and CD31+ vessels were readily distinguished. There were no structures expressing both CK and CD31, demonstrating the specificity of the staining (Figure 1D). All staining showed high specificity and extremely low autofluorescence (Figures 1A2–1D2).
When dual staining of insulin and PDX-1 was performed in two consecutive sections with low- (power 4) and conventional-power (power 10) HIAR, respectively, PDX-1 signals were greatly improved with low-power technique under identical imaging control (Figure 2 ). The same results were found when dual staining of insulin and glucagon was performed (data not shown), indicating that high energy delivered by power 10 may kill antigens to some extent. In some cases, conventional power AR even caused failure of IHC staining (personal communication).
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In the setting of transplantation where green fluorescent protein (GFP+) bone marrow cells from adult (10- to 12-week old) male mice transgenic for enhanced GFP gene (C57BL/6-TgN, ACEbEGFP 1Osb/J; The Jackson Laboratory) were used as donor, GFP detection was used to locate donor-derived cells in different tissues. Using LAR, we successfully identified donor GFP+ cells in the pancreas (Figure 3 ) and other tissues from different mouse strains (as shown in Table 2 ). The application of LAR was extended to multiple antigen detection in different organs (Jodele et al. 2005
; Kobayashi et al. 2005) (Table 2).
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It is often desirable to perform FISH and IHC on the same slide to see coexpression of specific chromosomes and protein, for example, to detect donor cells in sex-mismatched transplant settings. One of the primary technical concerns in these cases is that different procedures are required for FISH and IHC. We have found that unsatisfactory results of FISH staining can occur when IHC is performed prior to FISH staining. Vice versa, protein expression can be lost when FISH is processed first. In our studies, male pancreas was analyzed with IHC and FISH with the LAR technique. Slides were processed with LAR as described above, followed by digestion with 0.16% trypsin in diluent (Zymed; South San Francisco, CA) for 10 min at 37C and washing with TBST. After blocking, sections were incubated with primary Ab against the protein of interest, followed by incubation with biotinylated anti-mouse Ab, and then incubated with fluorescein (DTAF)-conjugated streptavidin (Jackson ImmunoResearch Laboratories). Post-fixation in 4% paraformaldehyde for 2 min, slides were sequentially dehydrated for 1 min in 70, 90, and 100% alcohol. One-µl Y-paint probe (Cy3) in 9-µl hybridization buffer (Cambio Ltd; Cambridge, UK) was applied on a 22 x 22-mm coverslip. Slides were sealed with rubber cement and denatured at 60C for 10 min and hybridized overnight at 37C in a humidified container. Slides were mounted with Vectashield (Vector Laboratories) medium containing DAPI after washing. Fluorescein and Cy3 filters were used to reveal protein and Y chromosomes, respectively.
It is well known that not all the Y chromosomes can be detected in male tissues due to incomplete sampling of entire nuclei during sectioning. At best, the efficiency of Y-chromosome detection in pancreas ranges from 60 to 80% with enzyme-mediated AR (Lechner et al. 2004) and in frozen section (Kodama et al. 2003). The LAR technique preserved protein expression well, e.g., insulin or CK with efficient detection of Y chromosomes. We observed 80–90% Y chromosomes of 2529 nuclei in the 5-µm sections of male pancreas with a background of 0.002% staining in negative (female pancreas) controls based on 2815 nuclei (Figure 4
). LAR used here provided efficient antigen retrieval for successful immunostaining of a variety of antigens under a standardized condition with low background.
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Acknowledgments |
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This work was generously supported by grants from the Seaver Institute and NIH Grant (R01-DK-68719).
Fluorescence microscopy was performed in the Congressman Julian Dixon Cellular Imaging Core of the Saban Research Institute, Childrens Hospital Los Angeles.
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Footnotes |
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Received for publication December 14, 2005; accepted March 2, 2006
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Literature Cited |
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TopSummaryLiterature Cited |
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Jodele S, Chantrain CF, Blavier L, Lutzko C, Crooks GM, Shimada H, Coussens LM, et al. (2005) The contribution of bone marrow-derived cells to the tumor vasculature in neuroblastoma is matrix metalloproteinase-9 dependent. Cancer Res 65:3200–3208
Kobayashi H, Carbonaro D, Pepper K, Petersen D, Ge S, Jackson H, Shimada H, et al. (2005) Neonatal gene therapy of MPS I mice by intravenous injection of a lentiviral vector. Mol Ther 11:776–789[Medline]
Kodama S, Kuhtreiber W, Fujimura S, Dale EA, Faustman DL (2003) Islet regeneration during the reversal of autoimmune diabetes in NOD mice. Science 302:1223–1227
Lechner A, Habener JF (2003) Stem/progenitor cells derived from adult tissues: potential for the treatment of diabetes mellitus. Am J Physiol Endocrinol Metab 284:E259–266
Lechner A, Yang YG, Blacken RA, Wang L, Nolan AL, Habener JF (2004) No evidence for significant transdifferentiation of bone marrow into pancreatic ß-cells in vivo. Diabetes 53:616–623
Peers B, Leonard J, Sharma S, Teitelman G, Montminy MR (1994) Insulin expression in pancreatic islet cells relies on cooperative interactions between the helix loop helix factor E47 and the homeobox factor STF-1. Mol Endocrinol 8:1798–1806[Abstract]
Shi SR, Cote RJ, Taylor CR (1997) Antigen retrieval immunohistochemistry: past, present, and future. J Histochem Cytochem 45:327–343
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Wang X, Ge S, Gonzalez I, McNamara G, Rountree BC, Xi KK, Huang G, et al. (2006) Formation of pancreatic duct epithelium from bone marrow during neonatal development. Stem Cells 24:307–314
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