Abstract
T-DNA insertion mutagenesis in Arabidopsis is an efficient and expedient method for isolating genes that may have agronomic importance in crop plants. More than 14,000 transformants, with an average of 1.5 inserts per transformant, have been generated in the laboratory at the University of Arizona, Tucson, United States of America. Assuming that the genome of Arabidopsis is 100 Mb and that insertion is random, there is a greater than 50% probability that any particular gene has been tagged in this population. These transformed lines have been screened for any visible alteration in phenotype. In addition, they have been screened under numerous selective regimes such as cold tolerance, auxin and ethylene resistance or sensitivity, and nitrate utilization, among many others. Twenty per cent of these transformants segregate for some type of mutation. Approximately 40% of these are due to T-DNA insertion. Genes have already been cloned from various developmental and biochemical pathways, including flower, root and trichome morphology, light and ethylene regulated growth, fatty acid desaturation and epicuticular wax (EW) production. Some of the isolated genes are being introduced into agronomic species in an attempt to improve specific traits. For example, two genes important in EW production have been introduced into
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Feldmann, K A
[1]
- Arizona Univ., Tucson, AZ (United States). Dept. of Plant Sciences
Citation Formats
Feldmann, K A.
Utility of T-DNA insertion mutagenesis in arabidopsis for crop improvement.
IAEA: N. p.,
1995.
Web.
Feldmann, K A.
Utility of T-DNA insertion mutagenesis in arabidopsis for crop improvement.
IAEA.
Feldmann, K A.
1995.
"Utility of T-DNA insertion mutagenesis in arabidopsis for crop improvement."
IAEA.
@misc{etde_208484,
title = {Utility of T-DNA insertion mutagenesis in arabidopsis for crop improvement}
author = {Feldmann, K A}
abstractNote = {T-DNA insertion mutagenesis in Arabidopsis is an efficient and expedient method for isolating genes that may have agronomic importance in crop plants. More than 14,000 transformants, with an average of 1.5 inserts per transformant, have been generated in the laboratory at the University of Arizona, Tucson, United States of America. Assuming that the genome of Arabidopsis is 100 Mb and that insertion is random, there is a greater than 50% probability that any particular gene has been tagged in this population. These transformed lines have been screened for any visible alteration in phenotype. In addition, they have been screened under numerous selective regimes such as cold tolerance, auxin and ethylene resistance or sensitivity, and nitrate utilization, among many others. Twenty per cent of these transformants segregate for some type of mutation. Approximately 40% of these are due to T-DNA insertion. Genes have already been cloned from various developmental and biochemical pathways, including flower, root and trichome morphology, light and ethylene regulated growth, fatty acid desaturation and epicuticular wax (EW) production. Some of the isolated genes are being introduced into agronomic species in an attempt to improve specific traits. For example, two genes important in EW production have been introduced into Brassica oleracea (broccoli) to modify the nature of the EW such that engineered plants will show greater resistance to herbivorous insects. Similarly, genes involved in fatty acid desaturation, male sterility, height or nitrogen metabolism, to mention only a few, could also be utilized to improve certain crop traits via genetic engineering. Several of these examples are described. (author). 57 refs, 1 fig., 2 tabs.}
place = {IAEA}
year = {1995}
month = {Nov}
}
title = {Utility of T-DNA insertion mutagenesis in arabidopsis for crop improvement}
author = {Feldmann, K A}
abstractNote = {T-DNA insertion mutagenesis in Arabidopsis is an efficient and expedient method for isolating genes that may have agronomic importance in crop plants. More than 14,000 transformants, with an average of 1.5 inserts per transformant, have been generated in the laboratory at the University of Arizona, Tucson, United States of America. Assuming that the genome of Arabidopsis is 100 Mb and that insertion is random, there is a greater than 50% probability that any particular gene has been tagged in this population. These transformed lines have been screened for any visible alteration in phenotype. In addition, they have been screened under numerous selective regimes such as cold tolerance, auxin and ethylene resistance or sensitivity, and nitrate utilization, among many others. Twenty per cent of these transformants segregate for some type of mutation. Approximately 40% of these are due to T-DNA insertion. Genes have already been cloned from various developmental and biochemical pathways, including flower, root and trichome morphology, light and ethylene regulated growth, fatty acid desaturation and epicuticular wax (EW) production. Some of the isolated genes are being introduced into agronomic species in an attempt to improve specific traits. For example, two genes important in EW production have been introduced into Brassica oleracea (broccoli) to modify the nature of the EW such that engineered plants will show greater resistance to herbivorous insects. Similarly, genes involved in fatty acid desaturation, male sterility, height or nitrogen metabolism, to mention only a few, could also be utilized to improve certain crop traits via genetic engineering. Several of these examples are described. (author). 57 refs, 1 fig., 2 tabs.}
place = {IAEA}
year = {1995}
month = {Nov}
}