Abstract
Whatever its field of application, animal transgenesis aims at a high level of reproducible and stable transgene expression. In the case of xenotransplantation, prevention of hyperacute rejection of grafts of animal origin requires the use of organs expressing human inhibitors of complement activation such as CD55 (DAF) and CD59. Pigs transgenic for these molecules have been produced, but with low and variable levels of expression. In order to improve cDNA expression, a vector containing the 5′HS4 region from the LCR of the chicken β‐globin locus and the promoter and the first intron from the human EF1α gene, was used to co‐express human CD55 and CD59 cDNAs in transgenic rabbits. The transgenic lines with the 5′HS4 region displayed dramatically enhanced CD55 and CD59 mRNA concentrations in brain, heart, kidney, liver, lung, muscle, spleen and aortic endothelial cells in comparison with the transgenic lines without the 5′HS4 region. In the absence of the 5′HS4 region, only some of the transgenic lines displayed specific mRNAs and at low levels. Human CD55 and CD59 proteins were detectable in mononuclear cells from transgenic rabbits although at a lower level than in human mononuclear cells. On the other hand, primary aortic endothelial cells from a bi‐transgenic line were very efficiently protected in vitro against human complement‐dependent lysis. Transgenic rabbits harbouring the two human inhibitors of complement activation, CD55 and CD59, can therefore be used as new models in xenotransplantation. Moreover, the vector containing the 5′HS4 region from the LCR of the chicken β‐globin locus seems appropriate not only for xenotransplantation but also for any other studies involving transgenic animals in which cDNAs have to be expressed at a high level in all cell types.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Attal J, Cajuero-Juarez M and Houdebine LM (1995) A simple method of DNA extraction from whole tissues and blood using glass powder for detection of transgenic animals by PCR. Transgenic Res 4:149–150.
Attal J, Théron MC, Taboit F, Cajuero-Juarez M, Kann G, Bolifraud P and Houdebine LM (1996) The RU5 ('R') region from human leukaemia viruses (HTLV-1) contains an internal ribosome entry site (IRES)-like sequence. FEBS Lett 392:220–224.
Avni D, Biberman Y and Meyubas O (1997) The 50 terminal oligopyrimidine tract confers translational control on TOP mRNAs in a cell type-and sequence context-dependent manner. Nucl Acids Res 25:995–1001.
Chomczynsky P and Sacchi N (1987) Single-step method of RNA isolation by acid guanidium thiocyanate-phenol-chloroform extraction. Anal Biochemi 162:156–159.
Chung JH, Whiteley M and Felsenfeld G (1993) A 50 element of the chicken beta-globin domain serves as an insulator in human erythroid cells and protects against position effect in drosophila. Cell 74:505–514.
Chung JH, Bell AC and Felsenfeld G (1997) Characterization of the chicken _-globin insulator. Proc Natl Acad Sci USA 94: 575–580.
Cozzi E and White DJG (1995) The generation of transgenic pigs as potential organ donors for humans. Nature Med 1:964–966.
Cozzi E, Tucker AW, Langford GA, Pino-Chavez G, Wright L, O'Connell MJ, Young VJ, Lancaster R, McLaughlin M, Hunt K, Bordin MC and White DJG (1997) Characterization of pigs transgenic for human Decay-Accelerating Factor. Transplantation 64:1383–1392.
Diamond LE, McCurry KR, Martin MJ, McClellan SB, Oldham ER, Platt JL and Logan JS (1996) Characterization of transgenic pigs expressing functionally active human CD59 on cardiac endothelium. Transplantation 61:1241–1249.
Festenstein R, Tolaini M, Corbella P, Mamalaki C, Prington J, Fox M, Miliou A, Jones M and Kioussis D (1996) Locus Control Region function and heterochromatin-induced position effect variegation. Science 271:1123–1125.
Fraser P and Grosveld F (1998) Locus control regions, chromatin activation and transcription. Curr Opin Cell Biol 10:361–365.
Grosveld F, van Assendelft GB, Greaves DR and Kollias G (1987) Position-independant, high-level expression of the human betaglobin gene in transgenic mice. Cell 51:975–985.
Hanaoka K, Hayasaka M, Uetsuki T, Fujisawa-Sehara A and Nabeshima YI (1991) A stable cellular marker for the analysis of mouse chimeras: the bacterial chloramphenicol acetyltransferase gene driven by the human elongation factor 1_ promoter. Differentiation 48:183–189.
Hogan B, Costantini F and Lacy E (1986) In: Manipulating the Mouse Embryo: A Laboratory Manual, Cold Spring Laboratory Press, Cold Spring Harbor, New York, USA. pp.174–175.
Kim DW, Uetsuki T, Kasiro Y, Yamaguchi N and Sugano S (1990) Use of the human elongation factor 1_ promoter as a versatile and efficient expression system. Gene 91:217–223.
Kim DW, Harada T, Saito I and Miyamura T (1993) An efficient expression vector for stable expression in human liver cells. Gene 134:307–308.
Kroshus TJ, Bolman RM, Dalmasso AP, Rollins SA, Guilmette ER, Williams BL, Squinto SP and Fodor WL (1996) Expression of human CD59 in transgenic pig organs enhances organ survival in an ex vivo xenogeneic perfusion model. Transplantation 61: 1513–1521.
Lathe R, Vilotte JL and Clark AJ (1987) Plasmid and bacteriophage vectors for excision of intact inserts. Gene 57:193–201.
Lublin DM and Atkinson JP (1989) Decay-accelerating factor: Biochemistry, molecular biology, and function. Ann Rev Immunol 7: 35–58.
Malassagne B, Taboit F, Conti F, Batteux F, Atia N, Chéreau C, Conjeaud H, Théron MC, Attal J, Graet F, Houdebine LM, Calmus Y, Houssin D and Weill B (1998) A newly established porcine aortic endothelial cell line: Characterization and application to the study of human-to-swine graft rejection. Exp Cell Res 238: 90–100.
McBurney MW, Staines WA, Boekelheide K, Parry D, Jardine K and Pickavance L (1994) Murine Pgk-1 promoter drives widespread but not uniform expression in transgenic mice. Dev Dynamics 200:278–293.
Medof ME, Kinoshita T and Nussenzweig V (1984) Inhibition of complement activation on the surface of cells after incorporation of Decay Accelerating Factor (DAF) into their membranes. J Exp Med 160:1558–1578.
Ortiz BD, Cado D, Chen V, Diaz PWandWinoto A (1997) Adjacent DNA elements dominantly restrict the ubiquitous activity of a novel chromatin-opening region to specific tissues. TIEMBO J 16: 5037–5045.
Palmiter RD, Sandgren EP, Avarbock MR, Allen DD and Brinster RL (1991) Heterologous introns can enhance expression of transgenes in mice. Proc Natl Acad Sci USA 88:478–482.
Petitclerc D, Attal J, Théron MC, Bearzotti M, Stinnakre MG, Pointu H, Puissant C and Houdebine LM (1995) The effect of various introns and transcription terminators on the efficiency of expression vectors in various cultured cell lines and in the mammary gland of transgenic mice. J Biotec 40:169–178.
Pikaart MJ, Targa-Recillas F and Felsenfeld G (1998) Loss of transcriptional activity of a transgene is accompanied by DNA methylation and histone deacetylation and is prevented by insulators. Genes Dev 12:2852–2862.
Platt JL, Lindman BJ, Chen H, Spitalnic SL and Bach FH (1990) Endothelial cell antigens recognized by human xenoreactive human natural antibodies. Transplantation 50:817–822.
Platt JL and Bach FH (1991) The barrier to xenotransplantation. Transplantation 52:937–947.
Platt J, Fischel RJ, Matas AJ, Reif SA, Bolman RM and Bach FH (1991) Immunopathology of hyperacute xenograft rejection in a swine-to-primate model. Transplantation 52:214–220.
Puissant C and Houdebine LM (1990) An improvement of the single-step method of RNA isolation by acid guanidium thiocyanate-phenol-chloroform extraction. Biotechniques 8:148–149.
Puissant C, Bayat-Sarmadi M, Devinoy E and Houdebine LM (1994) Variation of transferrin mRNA concentration in the rabbit mammary gland during the pregnancy-lactation-weaning cycle and in cultured mammary cells. A comparison with the other major milk protein mRNAs. Eur J Endocrinol 130:522–529.
Rollins SA and Sims PJ (1990) The complement-inhibitory activity of CD59 resides in its capacity to block incorporation of C9 into membrane C5b_9. J Immunol 144:3478–3483.
Sambrook J, Fritsch EF and Maniatis T (1989) Molecular cloning: A Laboratory Manual. Cold Spring Laboratory Press, Cold Spring Harbor, New York, USA.
Schönermark S, Rauterberg EW, Shin ML, Loke S, Roelcke D and Hänsch GM (1986) Homologous species restriction in lysis of human erythrocytes: a membrane-derived protein with C8-binding capacity functions as an inhibitor. J Immunol 136: 1772–1776.
Uetsuki T, Naito A, Nagata S and Kasiro Y (1989) Isolation and characterization of the human chromosomal gene for polypeptide chain elongation factor 1_. J Biol Chem 264:5791–5798.
van Denderen BJW, Pearse MJ, Katerelos M, Nottle MB, Du ZT, Aminian A, Adam WR, Shenoy-Scaria A, Lublin DM, Shinkel TA and d'Apice AJF (1996) Expression of functional decayaccelerating factor (CD55) in transgenic mice protects against human complement-mediated attack. Transplantation 61: 582–588.
Viglietta C, Massoud M and Houdebine LM (1997) The generation of transgenic rabbits. In: L.M. Houdebine (ed) Transgenic Animals: Generation and Use. Harwood Academic Publishers, Amsterdam, pp.11–13.
Wang Y, DeMayo FJ, Tsai SY and O'Malley BW (1996) Ligandinducible and liver-specific target gene expression in transgenic mice. Nature Biotech 15:239–243.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Taboit‐Dameron, F., Malassagne, B., Viglietta, C. et al. Association of the 5′ HS4 sequence of the chicken β‐globin locus control region with human EF1α gene promoter induces ubiquitous and high expression of human CD55 and CD59 cDNAs in transgenic rabbits. Transgenic Res 8, 223–235 (1999). https://doi.org/10.1023/A:1008919925303
Issue Date:
DOI: https://doi.org/10.1023/A:1008919925303