Journal of Histochemistry and Cytochemistry, Vol. 46, 863-864, July 1998, Copyright © 1998, The Histochemical Society, Inc.


BRIEF REPORT

Intranuclear Distribution of HMGI/Y Proteins: An Immunocytochemical Study

Alberto M. Martellia, Massimo Ricciob, Renato Bareggia, Guidalberto Manfiolettic, Giovanna Tabellinia, Giovanna Baldinia, Paola Narduccia, and Vincenzo Giancottic
a Dipartimento di Morfologia Umana, Università di Trieste, Trieste, Italy
b Istituto di Citomorfologia Normale e Patologica del CNR, Bologna, Italy
c Dipartimento di Biochimica, Biofisica e Chimica delle Macromolecole, Università di Trieste, Trieste, Italy

Correspondence to: Alberto M. Martelli, Dipartimento di Morfologia Umana, Università di Trieste, via Manzoni 16, I-34138 Trieste, Italy.


  Summary
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The intranuclear distribution of HMGI/Y proteins was analyzed by immunofluorescent staining in several cell lines using a polyclonal antibody that stained a fibrogranular network. In actively growing 3T3 fibroblasts, HMGI/Y proteins were mainly localized to heterochromatin masses, whereas in quiescent cells they were more diffusely distributed. Double labeling experiments showed a co-localization of HMGI/Y with DNA topoisomerase II{alpha}. These results are in agreement with previously published biochemical data and indicate a possible involvement of HMGI/Y proteins in several nuclear functions, including chromatin organization and gene expression. (J Histochem Cytochem 46: 863–864, 1998)

Key Words: HMGI/Y proteins, 3T3 fibroblasts, immunofluorescent staining, heterochromatin


  Introduction
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Summary
Introduction
Literature Cited

High-mobility group (HMG) PROTEINS I/Y are part of a subset of nonhistone proteins that also includes HMGI-C, and these three polypeptides are referred to as HMGI (Bustin and Reeves 1996 ). HMGI and HMGY derive from alternative splicing of the same gene, whereas HMGI-C is the product of a different gene (Manfioletti et al. 1995 ). Enhanced expression of HMGI proteins has been correlated with neoplastic transformation because normal adult tissues contain very low or undetectable quantities of these polypeptides (e.g., Giancotti et al. 1985 ).

Moreover, it has been shown that transforming viruses are no longer able to transform rat thyroid cells if the cells also transcribe an anti-sense message for HMGI-C (Berlingieri et al. 1995 ). HMGI/Y proteins bind to scaffold-associated regions (SARs), i.e., to highly A-T-rich DNA sequences that are involved in attaching chromatin loops to a nucleoskeletal structure and are also associated with active genes (Zhao et al. 1993 ). Because no information is available concerning the distribution of HMGI/Y during interphase, we have performed an immunocytochemical analysis of the spatial distribution in the nucleus of HMGI/Y by means of a specific polyclonal antibody (Giancotti et al. 1996 ). To this end, cells growing on coverslips were fixed with 4% paraformaldehyde, permeabilized with 0.5% Triton X-100, and processed as reported by Neri et al. 1997 . In rat thyroid PC E1A+v-raf cells (which produce high levels of these polypeptides), the antibody stained several large dots with a finer, punctate immunoreactivity dispersed in between (Figure 1a). In contrast, in rat PC Cl 3 cells (which do not express these proteins; Berlingieri et al. 1995 ) no immunoreactivity was detected (Figure 1b). These results showed specificity of the antibody for immunocytochemical analysis. Using confocal laser scanning microscope (CLSM), it was possible to distinguish in HeLa cells a nuclear fibrogranular network stained by the antibody, with some faintly positive granules in the nucleoli (Figure 1c), consistent with the results of Yang-Yen and Rothblum 1988 showing involvement of HMGI/Y in rDNA synthesis. Because HMGI/Y proteins are preferentially localized to G/Q- and C-bands of chromosomes (Disney et al. 1989 ), we analyzed the distribution of HMGI/Y relative to DNA in interphase nuclei. As shown in Figure 1d, in quiescent Swiss 3T3 cells the antibody to HMGI/Y gave a fine punctate pattern. In contrast, in actively growing cells the immunofluorescent pattern was characterized by large dots and and interspersed punctate staining (Figure 1f). We stress that DAPI staining for DNA revealed no differences between the two types of cells, because the large heterochromatic regions were detected both in quiescent and in serum-stimulated cultures (compare Figure 1e with Figure 1g). In these regions, centromeric heterochromatin is replicated during the late S-phase (Nakayasu and Berezney 1989 ). Because Saitoh and Laemmli 1994 showed that HMGI/Y and topoisomerase II{alpha} co-localize along the scaffold of mitotic chromosomes, we analyzed by double immunostaining and CLSM whether this type of association was present in the interphase nucleus of HeLa cells. As shown in Figure 1j, almost all of the immunofluorescent signal due to HMGI/Y (Figure 1h, red) co-localized with that due to topoisomerase II{alpha} (Figure 1i, green). Topoisomerase II{alpha} was immunostained by monoclonal antibody Ki-S1 (Boehringer–Mannheim; Mannheim, Germany).



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Figure 1. See text for details. Bars: a,b,d–g = 5 µm; c = 1 µm; h–j = 1 µm.

In conclusion, we believe that our data are in agreement with previous findings (obtained by biochemical and molecular biology techniques) indicating an involvement of HMGI/Y in several key nuclear functions (Bustin and Reeves 1996 ). They also show that some of the architectural features found in mitotic chromosomes are maintained in the interphase nucleus. Future investigations with the antibody used for the present study may provide additional information on the roles played by HMGI/Y proteins.


  Acknowledgments

Supported by Associazione Italiana per la Ricerca sul Cancro (A.I.R.C.) 1996 grants to AMM and VG, and from Italian MURST 40% and 60% grants to Università di Trieste.

Received for publication October 14, 1997; accepted March 3, 1998.


  Literature Cited
Top
Summary
Introduction
Literature Cited

Berlingieri MT, Manfioletti G, Santoro M, Bandiera A, Visconti R, Giancotti V, Fusco A (1995) Inhibition of HMGI-C synthesis suppresses retrovirally induced neoplastic transformation of rat thyroid cells. Mol Cell Biol 15:1545-1553[Abstract]

Bustin M, Reeves R (1996) High-mobility-group chromosomal proteins: architectural components that facilitate chromatin function. Prog Nucleic Acid Res 54:35-100[Medline]

Disney JE, Johnson KR, Magnuson NS, Sylvester SR, Reeves R (1989) High-mobility group protein HMG-I localizes to G/Q- and C-bands of human and mouse chromosomes. J Cell Biol 109:1975-1982[Abstract]

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Giancotti V, Berlingieri MT, DiFiore PP, Fusco A, Vecchio G, Crane–Robinson C (1985) Changes in nuclear proteins on transformation of rat epithelial thyroid cells by a murine sarcoma retrovirus. Cancer Res 45:6051-6057[Abstract]

Manfioletti G, Rustighi A, Mantovani F, Goodwin GH, Giancotti V (1995) Isolation and characterization of the gene coding for murine high-mobility-group protein HMGI-C. Gene 167:249-253[Medline]

Nakayasu H, Berezney R (1989) Mapping replicational sites in the eucaryotic cell nucleus. J Cell Biol 108:1-11[Abstract]

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Saitoh Y, Laemmli UK (1994) Metaphase chromosome structure: bands arise from a differential folding path of the highly AT-rich scaffold. Cell 76:609-622[Medline]

Yang-Yen HF, Rothblum LI (1988) Purification and characterization of a high-mobility group-like DNA-binding protein that stimulates rRNA synthesis in vitro. Mol Cell Biol 8:3406-3414[Medline]

Zhao K, Kas E, Gonzalez E, Laemmli UK (1993) SAR-dependent mobilization of histone H1 by HMG-I/Y in vitro: HMG-I/Y is enriched in H1-depleted chromatin. EMBO J 12:3237-3247[Abstract]