Gene Conversion Between Direct Noncoding Repeats Promotes Genetic and Phenotypic Diversity at a Regulatory Locus of Zea mays (L.)

Feng Zhang¹ and Thomas Peterson²

Department of Genetics, Development and Cell Biology and Department of Agronomy, Iowa State University, Ames, Iowa 50011

^² Corresponding author: 2208 Molecular Biology Bldg., Iowa State University, Ames, IA 50011.
E-mail: thomasp{at}iastate.edu

While evolution of coding sequences has been intensively studied,diversification of noncoding regulatory regions remains poorlyunderstood. In this study, we investigated the molecular evolutionof an enhancer region located 5 kb upstream of the transcriptionstart site of the maize pericarp color1 (p1) gene. The p1 geneencodes an R2R3 Myb-like transcription factor that regulatesthe flavonoid biosynthetic pathway in maize floral organs. Distinctp1 alleles exhibit organ-specific expression patterns on kernelpericarp and cob glumes. A cob glume-specific regulatory regionhas been identified in the distal enhancer. Further characterizationof 6 single-copy p1 alleles, including P1-rr (red pericarp/redcob) and P1-rw (red pericarp and white cob), reveals 3 distinctenhancer types. Sequence variations in the enhancer are correlatedwith the p1 gene expression patterns in cob glume. Structuralcomparisons and phylogenetic analyses suggest that evolutionof the enhancer region is likely driven by gene conversion betweenlong direct noncoding repeats ( $~$ 6 kb in length). Given that tandemand segmental duplications are common in both animal and plantgenomes, our studies suggest that recombination between noncodingduplicated sequences could play an important role in creatinggenetic and phenotypic variations.