The ATP-binding cassette transporter genes include the pleiotropic drug resistance (PDR) family found only in fungi and plants. These transporters transport toxic compounds across biological membranes. Here, we investigated the evolution of the PDR1 gene in Brachypodium distachyon, a widely distributed temperate grass species that belongs to the Poaceae (Gramineae) family, which also contains the domesticated cereal crops. Because this species has multiple ploidy levels, investigating PDR1 evolution in B. distachyon will offer insights into the formation and evolution of polyploidy. From 23 B. distachyon ecotypes, 39 PDR1 homologs were identified. All ecotypes had either one or two PDR1 copies. Based on restriction site analysis, the PDR1 homologs were classified as E or H type. All but one diploid and tetraploid ecotypes had only a single H type PDR1. All but one hexaploid ecotypes had both an E and a H type PDR1. Phylogenetic analysis revealed that each type formed a well-supported cluster. The two PDR1 types appeared to evolve differently. These different evolutionary patterns could indicate a difference in age between the two types or might indicate different mutation rates or selection pressures on the two types. The phylogenetic analysis also revealed that the hexaploid ecotypes shared a genomic origin for their E type PDR1, but there were multiple origins for hexaploid H type PDR1 homologs. Overall, the results suggest that tetraploid and hexaploid might be misnomers in B. distachyon and suggest a complex polyploidization history during B. distachyon evolution.