G. L. Reed scite author profile

Russet Burbank potato plants have been genetically improved to resist insect attack and damage by Colorado potato beetles (Leptinotarsa decemlineata (Say)) by the insertion of a cryIIIA gene encoding the insect control protein of Bacillus thuringiensis var. tenebrionis. A modified gene that dramatically improved plant expression of this protein was utilized. Its expression in Russet Burbank potato plants resulted in protection from damage by all insect stages in the laboratory and in dramatic levels of protection at multiple field locations. Analysis of these genetically modified potatoes indicated that they conform to the standards for Russet Burbank potatoes in terms of agronomic and quality characteristics including taste.

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Flight and Sexual Activity of the European Corn Borer 1 , 2 , 3

Showers

Reed²,

Robinson³

et al. 1976

103

113

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Quantification of transgenic plant marker gene persistence in the field

Widmer

Seidler

Donegan³

et al. 1997

Molecular Ecology

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Methods were developed to monitor persistence of genomic DNA in decaying plants in the field. As a model, we used recombinant neomycin phosphotransferase II (rNPT‐II) marker genes present in genetically engineered plants. Polymerase chain reaction (PCR) primers were designed, complementary to 20‐bp sequences of the nopaline synthase promoter in a transgenic tobacco and the cauliflower mosaic virus 35S promoter in a transgenic potato. The PCR reverse primer was complementary to a 20‐bp sequence of the N‐terminal NPT‐II coding region. The PCR protocol allowed for quantification of as few as 10 rNPT‐II genes per reaction. We analysed rNPT‐II marker gene amounts in samples obtained from two field experiments performed at different locations in Oregon. In transgenic tobacco leaves, buried at 10 cm depth in a field plot in Corvallis, marker DNA amount dropped to 0.36% during the first 14 days and was detectable for 77 days at a final level of 0.06% of the initial amount. Monitoring of residual potato plant litter, from the soil surface of a test field in Hermiston, was performed for 137 days. After 84 days marker gene amounts dropped to 2.74% (leaf and stem) and 0.50% (tuber) of the initially detected amount. At the final sample date 1.98% (leaf and stem) and 0.19% (tuber) were detectable. These results represent the first quantitative analysis of plant DNA stability under field conditions and indicate that a proportion of the plant genomic DNA may persist in the field for several months.

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Transgenic Bt potato and conventional insecticides for Colorado potato beetle management: comparative efficacy and non‐target impacts

Reed¹,

Jensen²,

Riebe³

et al. 2001

Entomologia Exp Applicata

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Field studies were conducted in 1992 and 1993 in Hermiston, Oregon, to evaluate the efficacy of transgenic Bt potato (Newleaf®, which expresses the insecticidal protein Cry3Aa) and conventional insecticide spray programs against the important potato pest, Leptinotarsa decemlineata (Say), Colorado potato beetle (CPB), and their relative impact on non‐target arthropods in potato ecosystems. Results from the two years of field trials demonstrated that Newleaf potato plants were highly effective in suppressing populations of CPB, and provided better CPB control than weekly sprays of a microbial Bt‐based formulation containing Cry3Aa, bi‐weekly applications of permethrin, or early‐ and mid‐season applications of systemic insecticides (phorate and disulfoton). When compared with conventional potato plants not treated with any insecticides, the effective control of CPB by Newleaf potato plants or weekly sprays of a Bt‐based formulation did not significantly impact the abundance of beneficial predators or secondary potato pests. In contrast to Newleaf potato plants or microbial Bt formulations, however, bi‐weekly applications of permethrin significantly reduced the abundance of several major generalist predators such as spiders (Araneae), big‐eyed bugs (Geocorus sp.), damsel bugs (Nabid sp.), and minute pirate bugs (Orius sp.), and resulted in significant increases in the abundance of green peach aphid (GPA), Myzus persicae (Sulzer) – vector of viral diseases, on the treated potato plots. While systemic insecticides appeared to have reduced the abundance of some plant sap‐feeding insects such as GPA, lygus bugs, and leafhoppers, early and mid‐season applications of these insecticides had no significant impact on populations of the major beneficial predators. Thus, transgenic Bt potato, Bt‐based microbial formulations and systemic insecticides appeared to be compatible with the development of integrated pest management (IPM) against other potato pests such as GPA because these CPB control measures have little impact on major natural enemies. In contrast, the broad‐spectrum pyrethroid insecticide (permethrin) is less compatible with IPM programs against GPA and the potato leafroll viral disease.

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Microbial populations, fungal species diversity and plant pathogen levels in field plots of potato plants expressing theBacillus thuringiensis var.tenebrionis endotoxin

Donegan¹,

Schaller²,

Stone

et al. 1996

Transgenic Research

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The environmental release of genetically engineered (transgenic) plants may be accompanied by ecological effects including changes in the plant-associated microflora. A field release of transgenic potato plants that produce the insecticidal endotoxin of Bacillus thuringiensis var. tenebrionis (Btt) was monitored for changes in total bacterial and fungal populations, fungal species diversity and abundance, and plant pathogen levels. The microflora on three phenological stages of leaves (green, yellow and brown) were compared over the growing season (sample days 0, 21, 42, 63 and 98) for transgenic potato plants, commercial Russet Burbank potato plants treated with systemic insecticide (Di-Syston)and commercial Russet Burbank potato plants treated with microbial Btt (M-Trak). In addition, plant and soil assays were performed to assess disease incidence of Fusarium spp., Pythium spp., Verticillium dahliae, potato leaf roll virus (PLRV) and potato virus Y (PVY). Few significant differences in phylloplane microflora among the plant types were observed and none of the differences were persistent. Total bacterial populations on brown leaves on sample day 21 and on green leaves on sample day 42 were significantly higher on the transgenic potato plants. Total fungal populations on green leaves on sample day 63 were significantly different among the three plant types; lowest levels were on the commercial potato plants treated with systemic insecticide and highest levels were on the commercial potato plants treated with microbial Btt.Differences in fungal species assemblages and diversity were correlated with sampling dates, but relatively consistent among treatments. Alternaria alternata, a common saprophyte on leaves and in soil and leaf litter, was the most commonly isolated fungus species for all the plant treatments. Rhizosphere populations of the soilborne pathogens Pythium spp., Fusarium spp. and V. dahliae did not differ between the transgenic potato plants and the commercial potato plants treated with systemic insecticide. The incidence of tuber infection at the end of the growing season by the plant pathogen g dahliae was highest for the transgenic potato plants but this difference was related to longer viability of the transgenic potato plants. This difference in longevity between the transgenic potato plants and the commercial + systemic insecticide potato plants also made comparison of the incidence of PVY and PLRV problematic. Our results indicate that under field conditions the microflora of transgenic Btt-producing potato plants differed minimally from that of chemically and microbially treated commercial potato plants.

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G. L. Reed

Genetically improved potatoes: protection from damage by Colorado potato beetles

Flight and Sexual Activity of the European Corn Borer 1 , 2 , 3

Quantification of transgenic plant marker gene persistence in the field

Transgenic Bt potato and conventional insecticides for Colorado potato beetle management: comparative efficacy and non‐target impacts

Microbial populations, fungal species diversity and plant pathogen levels in field plots of potato plants expressing theBacillus thuringiensis var.tenebrionis endotoxin

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