Functional Variation for DIMBOA Content in Maize Butrón A 1, Chen Y-C 2, Rottinghaus GE 2, Guill K 3, McMullen MD 3, 1 Misión Biológica de Galicia (CSIC), Apdo. 28, Pontevedra, Spain; 2 Veterinary Medical Diagnostic Laboratory, University of Missouri; 3 USDA-ARS and the University of Missouri, Curtis Hall 302, Columbia MO, USA The main hydroxamic acid in maize (Zea mays L.) is 2-4- dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA). DIMBOA confers resistance to leaf-feeding by several corn borers including the European corn borer. Most genes involved in the DIMBOA metabolic pathway (Bx1, Bx2, Bx3, Bx4, Bx5, Bx6, Bx7 and Bx8) are located on the short arm of chromosome 4, and QTLs involved in maize resistance to leaf-feeding by European corn borer have been localized to that region. However, the low resolution of QTL linkage mapping does not allow convincing proof that genetic variation at bx loci was responsible for the variability for resistance. Therefore, a sub- sample of the Nested Association Mapping (NAM) population (Yu et al. 2008, Genetics 178: ) was used to finely map QTLs for DIMBOA content. A model including eight markers (on chromosomes 1, 2, 4, 5, 6, and 8) explained approximately 34% of phenotypic variability within eight RIL families. The closest marker to the major QTL detected in chromosome 4.01 at 7.2 cM explained 15.8% of phenotypic variation across the eight families (Table 1). The position of the largest QTL co-localizes with the majority of structural genes of the DIMBOA pathway. Therefore association analysis was used to determine if genetic variation at bx1 affects variation of DIMBOA content. General (GLM) and Mixed Linear Models (MLM) revealed associations between variability for DIMBOA content and sequence polymorphisms at bx1 locus. After adjusting for population structure, a model including two polymorphisms in Bx1 (X _620 and Bx1_1.9_143) explained 12% of phenotypic variation in a population of 282 diverse lines. This is close to the 15% effect predicted by the GLMSELECT analysis for the chromosome 4 QTL across 8 families of RILs. These results suggest that genetic variation for bx1 is likely behind the QTL detected in the region 4.01, but the specific causal polymorphisms responsible for that variation were not identified. Table 1. Effects of the marker identified as significant in the region 4.01 for DIMBOA (ppm) content among eight RIL families (from crosses of B73 to CML322, CML52, IL14H, M37W, MS71, NC350, Oh43 and Tx303) with their corresponding probability levels. Negative effects mean that the allele for higher amount came from B73 MarkerContigParameterCML322CML52IL14HM37WMS71NC350Oh43Tx303 PHM Effect p < < < < Fig. 1 Association of DNA polymorphisms with DIMBOA content across genomic portions of genes Bx1 ( bp) and Bx2 ( bp). The positions correspond to BAC sequence AC Blue diamonds indicate association with DIMBOA content. Level of statistical association for each SNP and INDEL is expressed as –Log P. Pink squares indicate r 2 LD scores for all marker pairs involving X _620 and yellow triangles r 2 LD scores for all marker pairs involving Bx1_1.9_143. Damage made by borers at mid-Whorl stage when DIMBOA is still present Indole-3-glycerole phosphate BX1 Indole BX2, BX3, BX4, BX5 DIBOA BX8/BX9 DIBOA-glucoside BX6 TRIBOA-glucoside BX7 DIMBOA-glucoside Fig 1. Enzymes and intermediates of DIMBOA-glc biosynthesis in maize as described by Jonczyk et al. (2008, Plant Physiology 146: )