The immunophilin-like FKBP42 TWISTED DWARF1 (TWD1) has been shown to control plant development via the positive modulation of ABCB/P-glycoprotein (PGP)-mediated transport of the plant hormone auxin. TWD1 functionally interacts with two closely related proteins, ABCB1/PGP1 and ABCB19/PGP19/MDR1, both of which exhibit the ability to bind to and be inhibited by the synthetic auxin transport inhibitor N-1-naphylphtalamic acid (NPA). They are also inhibited by flavonoid compounds, which are suspected modulators of auxin transport. The mechanisms by which flavonoids and NPA interfere with auxin efflux components are unclear. We report here the specific disruption of PGP1-TWD1 interaction by NPA and flavonoids using bioluminescence resonance energy transfer with flavonoids functioning as a classical established inhibitor of mammalian and plant PGPs. Accordingly, TWD1 was shown to mediate modulation of PGP1 efflux activity by these auxin transport inhibitors. NPA bound to both PGP1 and TWD1 but was excluded from the PGP1-TWD1 complex expressed in yeast, suggesting a transient mode of action in planta. As a consequence, auxin fluxes and gravitropism in twd1 roots are less affected by NPA treatment, whereas TWD1 gain-of-function promotes root bending. Our data support a novel model for the mode of drug-mediated P-glycoprotein regulation mediated via protein-protein interaction with immunophilin-like TWD1.Bioactive flavonoids derived from plant secondary metabolism serve as important nutraceuticals (1). They have healthpromoting effects, including antioxidant, anticarcinogenic, antiviral, and anti-inflammatory activities; however, the cellular targets of the in vivo protein remain largely unknown (1, 2). In plants, among other functions, flavonoids such as quercetin, kaempferol, and other aglycone molecules have been shown to inhibit cell-to-cell/polar auxin transport (PAT) 3 and consequently to enhance localized auxin accumulation (1, 3-6). During PAT, the plant hormone auxin, which determines many aspects of plant physiology and development, is moved directionally in a cell-to-cell mode (7-9).The regulatory impact of flavonoids on PAT initially was based on their ability to compete with N-1-naphtylphtalamic acid (NPA), a synthetic auxin transport inhibitor (ATI) (4, 10 -12) and herbicide (naptalam, alanap), for transporter binding sites. This concept is further supported by auxin-related phenotypes of Arabidopsis mutants with altered flavonoid levels (1, 3, 13), although fundamental physiological processes occur in the absence of flavonoids. Currently the flavonoids are seen as transport regulators or modulators (14); nevertheless, the mechanisms by which flavonoids interfere with auxin efflux components are not yet clear (1).The auxin efflux complex is thought to regulate PAT on the molecular level and consists of at least two proteins: a membrane integral transporter and an NPA-binding protein (NBP) regulatory subunit (11,(15)(16)(17). Recently, ABCB/P-glycoprotein (PGP)/multidrug resistance (MDR) proteins, members o...
