Intrinsic disorder and conformational coexistence in auxin coreceptors.

AUXIN/INDOLE 3-ACETIC ACID (Aux/IAA) transcriptional repressor proteins and the TRANSPORT INHIBITOR RESISTANT 1/AUXIN SIGNALING F-BOX (TIR1/AFB) proteins to which they bind act as auxin coreceptors. While the structure of TIR1 has been solved, structural characterization of the regions of the Aux/IAA protein responsible for auxin perception has been complicated by their predicted disorder. Here, we use NMR, CD and molecular dynamics simulation to investigate the N-terminal domains of the Aux/IAA protein IAA17/AXR3. We show that despite the conformational flexibility of the region, a critical W-P bond in the core of the Aux/IAA degron motif occurs at a strikingly high (1:1) ratio of cis to trans isomers, consistent with the requirement of the cis conformer for the formation of the fully-docked receptor complex. We show that the N-terminal half of AXR3 is a mixture of multiple transiently structured conformations with a propensity for two predominant and distinct conformational subpopulations within the overall ensemble. These two states were modeled together with the C-terminal PB1 domain to provide the first complete simulation of an Aux/IAA. Using MD to recreate the assembly of each complex in the presence of auxin, both structural arrangements were shown to engage with the TIR1 receptor, and contact maps from the simulations match closely observations of NMR signal-decreases. Together, our results and approach provide a platform for exploring the functional significance of variation in the Aux/IAA coreceptor family and for understanding the role of intrinsic disorder in auxin signal transduction and other signaling systems.

Identification and characterization of the Ipomoea nil RelA/SpoT Homologs (InRSHs) and potential directions of their transcriptional regulation.

Although the stringent response has been known for more than half a century and has been well studied in bacteria, only the research of the past 19 years revealed that the homologous mechanism is conserved in plants. The plant RelA/SpoT Homolog (RSH) genes have been identified and characterized in a limited number of plant species, whereas products of their catalytic activities, (p)ppGpp (alarmones), have been shown to accumulate mainly in chloroplasts. Here, we identified full-length sequences of the Ipomoea nil RSH genes (InRSH1, InRSH2 and InCRSH), determined their copy number in the I. nil genome as well as the structural conservancy between InRSHs and their Arabidopsis and rice orthologs. We showed that InRSHs are differentially expressed in I. nil organ tissues and that only InRSH2 is upregulated in response to salt, osmotic and drought stress. Our results of the E. coli relA/spoT mutant complementation test suggest that InRSH1 is likely a (p)ppGpp hydrolase, InCRSH - synthetase and InRSH2 shows both activities. Finally, we referred our results to the recently published I. nil genomic and proteomic data and uncovered the complexity of the I. nil RSH family as well as potential ways of the InRSH transcriptional regulation.

Assaying Auxin Receptor Activity Using SPR Assays with F-Box Proteins and Aux/IAA Degrons.

The identification of TIR1 as an auxin receptor combined with advanced biophysical instrumentation has led to the development of real-time activity assays for auxins. Traditionally, molecules have been assessed for auxinic activity using bioassays, and agrochemical compound discovery continues to be based on "spray and pray" technologies. Here, we describe the methodology behind an SPR-based assay that uses TIR1 and related F-box proteins with surface plasmon resonance spectrometry for rapid compound screening. In addition, methods for collecting kinetic binding data and data processing are given so that they may support programs for rational design of novel auxin ligands.