Components of soybean resistance to the soybean aphid, Aphis glycines Matsumura

Diaz-Montano, John

January 1900

Master of Science / Department of Entomology / John C. Reese / The soybean aphid, Aphis glycines Matsumura, is a pest of soybean, Glycine max (L.) Merr. Studies to find control methods were initiated in 2000 when it was first detected in the United States. Aphis glycines can reduce yields by as much as 50%, and vectors several viral diseases. Plant resistance to A. glycines is one important component of integrated control. In the first study, reproduction of A. glycines was compared on 240 soybean entries. Eleven had fewer nymphs produced compared with two susceptible checks (KS4202 and Pioneer® 95B15). Antibiosis and antixenosis were assessed in no-choice and choice tests, respectively. Nine entries showed moderate antibiosis and the other two (K1639 and Pioneer® 95B97) showed strong antibiosis and antixenosis as categories of resistance to A. glycines. In the second study, chlorophyll loss was estimated in no-choice tests on infested and uninfested leaves of KS4202. The minimum combined number to detect significant chlorophyll loss was 30 aphids confined for 10 days. Using this number, seven resistant entries found in the first study were evaluated. There was no significant chlorophyll reduction between infested and uninfested leaves of five of the resistant entries (K1621, K1639, 95B97, Dowling and Jackson). Jackson and Dowling had a significantly lower percentage loss than the susceptible checks. In the third study, assessment of feeding behavior of A. glycines was compared and recorded for 9 h on four resistant entries and KS4202. The average time needed to reach the first sieve element phase by A. glycines was 3.5 h in KS4202 while in the resistant entries it was 7.5 h, and the total duration in this phase was longer than an hour in KS4202, and only two to seven minutes in the resistant entries. These data suggest that phloem tissues in the resistant plants change feeding behavior. However, aphids first reached the xylem phase and then the sieve element phase, and the time that aphids spent ingesting xylem sap was not different among all entries; therefore, it is possible that xylem sap in the resistant entries may contain toxic substances that alter aphid behavior and restrain further activities on the sieve element phase.

Soybean aphid

Soybean

Antibiosis

Antixenosis

Chlorophyll losses

Feeding Behavior

Host Plant Resistance

Agriculture, Agronomy (0285)

Biology, Entomology (0353)

Biology, Plant Physiology (0817)

Public health aspects of the house fly, Musca domestica L. (Diptera: muscidae) - Enterococcus spp. association

Akhtar, Mastura

January 1900

Doctor of Philosophy / Department of Entomology / Ludek Zurek / House fly (Musca domestica L.) larvae develop in decaying organic substrates such as animal manure and adult flies likely play an important role in the ecology of fecal bacteria, including potentially virulent strains. House fly larval development strictly depends on an active bacterial community in the habitat. Although the principle of this symbiosis is not well understood, this association plays a fundamental role in transmission of microbes by this insect. In this study, enterococci were chosen as a model organism to assess the role of house flies in dissemination of multi-drug resistant bacteria in the agricultural environment. House flies (FF) and cattle manure (FM) from a cattle feedlot (frequent use of antibiotics) and house flies (BF) and manure of the American bison (BM) from the Konza Prairie Nature Preserve (no antibiotic use) were collected and analyzed. Results showed a significantly higher prevalence of enterococci resistant to tetracycline and erythromycin in FM and FF compared to that of BF and BM. Enterococcal diversity did not indicate the house fly development in manure in the corresponding habitats but the antibiotic resistance data showed very similar profiles among isolates from flies and corresponding locations. Resistance genes (tetM, tetS, tetO, ermB) and the conjugative transposon Tn916 were the most commonly detected determinants from resistant isolates from both environments. The house fly digestive tract was evaluated for the potential for horizontal transfer of antibiotic resistance genes among Enterococcus faecalis. Horizontal transfer of the pCF10 plasmid with the tetracycline resistance gene (tetM) occurred in the fly digestive tract with a transfer rate up to 101 T/D. In addition, eight enterococcal species were selected to evaluate their role and survival during house fly development. Overall, the survival rate (egg to adult) was significantly higher with E. hirae, E. durans and E. avium compared to other strains. These results indicate: a) house flies play an important role in the ecology of antibiotic resistant enterococci; b) the house fly digestive tract provides conditions for horizontal gene transfer among enterococci, and c) enterococci support the house fly development and can colonize the gut of newly emerging adult flies.

House fly

Enterococcus

Multidrug resistant enterococci

Antibiotic use in food animals

Horizontal transfer of resistance genes

Biology, Entomology (0353)

Biology, Microbiology (0410)

Health Sciences, Public Health (0573)