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ARS Home » Midwest Area » West Lafayette, Indiana » Crop Production and Pest Control Research » Research » Publications at this Location » Publication #170894

Title: REGULATION OF WHEAT GENES IN RESPONSE TO HESSIAN FLY ATTACK

Author
item GIOVANINI, MARCELO - PURDUE UNIVERSITY
item Puthoff, David
item OHM, HERBERT - PURDUE UNIVERSITY
item Williams, Christie

Submitted to: Plant and Animal Genome Conference
Publication Type: Abstract Only
Publication Acceptance Date: 11/1/2004
Publication Date: 11/1/2004
Citation: Giovanini, M.P., Puthoff, D.P., Ohm, H.W., Williams, C.E. 2004. Regulation of wheat genes in response to Hessian fly attack. Plant and Animal Genome Conference. http://www.intl-pag.org/13/abstracts/PAG13_P687.html

Interpretive Summary:

Technical Abstract: Successful establishment of feeding sites by virulent Hessian fly larvae results in stunting of the susceptible seedlings of the wheat host. However, when avirulent larvae attempt to feed at the base of wheat seedlings, resistance responses lead to death of the first instar larvae, and nutritive tissue that forms the feeding site does not develop. The interactions of Hessian fly and wheat are dictated by a gene-for-gene relationship. However, classical PR (Pathogenesis related) protein-encoding genes show only minor involvement in the molecular response, whereas a typical oxidative burst and associated HR (Hypersensitive response) are not elicited upon avirulent fly attacks on resistance wheat plants. Mechanisms of resistance and susceptibility at the molecular level have not been elucidated. In order to characterize these interactions, we have cloned several wheat genes that are responsive to virulent and avirulent Hessian fly larvae. During compatible interactions, genes encoding several proteins that may function in formation of nutritive tissue (Hfr-2, a pore forming protein; GST, a putative auxin binding glutathione S-transferase; sorbitol transporter and connective tissue growth factors) were all significantly up-regulated in susceptible plants compared with the uninfested control. A gene encoding a lipid transfer protein was down-regulated during the compatible interactions. During incompatible interactions, resistance was accompanied by accumulation of transcripts from two genes with defense functions (wheat germ agglutinin and a flavanone-3 hydroxylase gene) which were then up-regulated at a later time during susceptibility. Studies that address the involvement of these genes in interactions with Hessian fly larvae will be presented.