We investigated the effect of the 52 MAR (matrix attachment region) sequence of chicken lysozyme gene as a possible insulator for the expression of our transgenes in somatic cells to be used for nuclear transfer. With the preliminary purpose to demonstrate a possible positive effect (position or copy number) on the long-term combined expression during in vitro culture, we have created a bicistronic ubiquitous expression vector with (MAR+) or without (MAR–) MAR. The main structure of our constructs is composed of the pCAGGS promoter driving the expression of a reporter gene (enhanced green fluorescent protein, EGFP) followed by a loxable selection cassette (loxP-PGKneo). The MAR region was inserted before the selection cassette. After KpnI digestion, the resulting linearized vectors were purified and subsequently used to transfect adult porcine fibroblast cell lines using the Nucleofector system (Amaxa, Cologne, Germany). Fibroblasts were cultured in DMEM/M199 medium (1:1) + 10% FCS supplemented with 5 ng mL–1 of basic fibroblast growth factor (bFGF). In every experiment, 1 × 106 cells were transfected with 2.5 µg of linearized plasmid and selected for 3 weeks with medium supplemented with 400 µg mL–1 of Geneticin (G418 sulfate, Calbiochem, La Jolla, CA). On Day 8 of G418 selection, we analyzed 150 colonies for each treatment, using fluorescence microscopy with fluorescein isothiocyanate filters. Colonies were classified according to size (large) and cell morphology (small cells without signs of aging). In addition, colonies were classified for uniform GFP expression (uniform), patchy GFP expression (variegated), and no GFP expression (negative). Resistant colonies derived from MAR+ and MAR– vectors, respectively, had 36 (24%), 42 (28%), and 56 (37%) v. 79 (53%), 58 (39%), and 29 (19%) uniform, variegated, and negative GFP. Differences were significant for variegated and negative in MAR+ v. MAR– (chi square, P < 0.05). Thirty-six MAR+ and 42 MAR– colonies uniformly expressing GFP were transferred to 24-well plates and subjected to G418 selection until Day 22, when 7 MAR+ and 15 MAR– clones were still growing in culture. Four of seven MAR+ (57%) and 7/15 MAR– (47%) uniformly expressed high levels of GFP. In conclusion, we found that significantly fewer colonies expressed GFP with the MAR+ vector; however, within the GFP-expressing clones, expression was more uniform. Therefore, we did not find a beneficial effect of MAR sequences on expression in somatic cells during in vitro culture; however, further work is needed to investigate their effect after nuclear transfer and/or on the next generation of cloned transgenic animals
Influence of matrix attachment region on the expression of bicistronic vectors transfected in mammalian cells cultured in vitro / A. Perota, D. Brunetti, M. Lizier, F. Lucchini, C. Galli. - In: REPRODUCTION FERTILITY AND DEVELOPMENT. - ISSN 1031-3613. - 20:1(2008 Jan), pp. 234-234. ((Intervento presentato al convegno Annual Conference of the International Embryo Transfer Society tenutosi a Denver, Colorado nel 2008 [10.1071/RDv20n1Ab308].
Influence of matrix attachment region on the expression of bicistronic vectors transfected in mammalian cells cultured in vitro
A. Perota;D. Brunetti;C. Galli
2008
Abstract
We investigated the effect of the 52 MAR (matrix attachment region) sequence of chicken lysozyme gene as a possible insulator for the expression of our transgenes in somatic cells to be used for nuclear transfer. With the preliminary purpose to demonstrate a possible positive effect (position or copy number) on the long-term combined expression during in vitro culture, we have created a bicistronic ubiquitous expression vector with (MAR+) or without (MAR–) MAR. The main structure of our constructs is composed of the pCAGGS promoter driving the expression of a reporter gene (enhanced green fluorescent protein, EGFP) followed by a loxable selection cassette (loxP-PGKneo). The MAR region was inserted before the selection cassette. After KpnI digestion, the resulting linearized vectors were purified and subsequently used to transfect adult porcine fibroblast cell lines using the Nucleofector system (Amaxa, Cologne, Germany). Fibroblasts were cultured in DMEM/M199 medium (1:1) + 10% FCS supplemented with 5 ng mL–1 of basic fibroblast growth factor (bFGF). In every experiment, 1 × 106 cells were transfected with 2.5 µg of linearized plasmid and selected for 3 weeks with medium supplemented with 400 µg mL–1 of Geneticin (G418 sulfate, Calbiochem, La Jolla, CA). On Day 8 of G418 selection, we analyzed 150 colonies for each treatment, using fluorescence microscopy with fluorescein isothiocyanate filters. Colonies were classified according to size (large) and cell morphology (small cells without signs of aging). In addition, colonies were classified for uniform GFP expression (uniform), patchy GFP expression (variegated), and no GFP expression (negative). Resistant colonies derived from MAR+ and MAR– vectors, respectively, had 36 (24%), 42 (28%), and 56 (37%) v. 79 (53%), 58 (39%), and 29 (19%) uniform, variegated, and negative GFP. Differences were significant for variegated and negative in MAR+ v. MAR– (chi square, P < 0.05). Thirty-six MAR+ and 42 MAR– colonies uniformly expressing GFP were transferred to 24-well plates and subjected to G418 selection until Day 22, when 7 MAR+ and 15 MAR– clones were still growing in culture. Four of seven MAR+ (57%) and 7/15 MAR– (47%) uniformly expressed high levels of GFP. In conclusion, we found that significantly fewer colonies expressed GFP with the MAR+ vector; however, within the GFP-expressing clones, expression was more uniform. Therefore, we did not find a beneficial effect of MAR sequences on expression in somatic cells during in vitro culture; however, further work is needed to investigate their effect after nuclear transfer and/or on the next generation of cloned transgenic animals
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