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Segregation of transgenes in maize

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Abstract

Progeny recovered from backcrossed transgenic maize tissue culture regenerants (R0) were analyzed to determine the segregation, expression, and stability of the introduced genes. Transgenic A188×B73 R0 plants (regenerated from embryogenic suspension culture cells transformed by microprojectile bombardment; see [9]) were pollinated with nontransformed B73 pollen. Inheritance of a selectable marker gene, bar, and a nonselectable marker gene, uidA, was analyzed in progeny (R1) representing four independent transformation events. Activity of the bar gene product, phosphinothricin acetyltransferase (PAT), was assessed in plants comprising the four R1 populations. The number of R1 plants containing PAT activity per total number of R1 plants recovered for each population was 2/7, 19/34, 3/14 and 73/73. Molecular analysis confirmed the segregation of bar in three R1 populations and the lack of segregation in one R1 population. Cosegregation analysis indicated genetic linkage of bar and uidA in all four R1 populations. Analysis of numerous R2 plants derived from crossing transformed R1 plants with nontransformed inbreds revealed 1:1 segregation of PAT activity in three of four lines, including the line that failed to segregate in the R1 generation. Integrated copies of bar in one line appeared to be unstable or poorly transmitted.

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Author notes

  1. Peggy G. Lemaux

    Present address: Department of Plant Biology, University of California, 94720, Berkeley, CA, USA

Authors and Affiliations

  1. Discovery Research, DEKALB Plant Genetics, Eastern Point Road, 06340, Groton, CT, USA

    T. Michael Spencer, James V. O'Brien, William G. Start, Thomas R. Adams, William J. Gordon-Kamm & Peggy G. Lemaux

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  1. T. Michael Spencer
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  2. James V. O'Brien
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  3. William G. Start
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  4. Thomas R. Adams
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  5. William J. Gordon-Kamm
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  6. Peggy G. Lemaux
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Spencer, T.M., O'Brien, J.V., Start, W.G. et al. Segregation of transgenes in maize. Plant Mol Biol 18, 201–210 (1992). https://doi.org/10.1007/BF00034949

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  • DOI: https://doi.org/10.1007/BF00034949

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