Key Residues and Phosphate Release Routes in the Saccharomyces cerevisiae Pho84 Transceptor: THE ROLE OF TYR179 IN FUNCTIONAL REGULATION.

Pho84, a major facilitator superfamily (MFS) protein, is the main high-affinity Pi transceptor in Saccharomyces cerevisiae Although transport mechanisms have been suggested for other MFS members, the key residues and molecular events driving transport by Pi:H+ symporters are unclear. The current Pho84 transport model is based on the inward-facing occluded crystal structure of the Pho84 homologue PiPT in the fungus Piriformospora indica However, this model is limited by the lack of experimental data on the regulatory residues for each stage of the transport cycle. In this study, an open, inward-facing conformation of Pho84 was used to study the release of Pi A comparison of this conformation with the model for Pi release in PiPT revealed that Tyr179 in Pho84 (Tyr150 in PiPT) is not part of the Pi binding site. This difference may be due to a lack of detailed information on the Pi release step in PiPT. Molecular dynamics simulations of Pho84 in which a residue adjacent to Tyr179, Asp178, is protonated revealed a conformational change in Pho84 from an open, inward-facing state to an occluded state. Tyr179 then became part of the binding site as was observed in the PiPT crystal structure. The importance of Tyr179 in regulating Pi release was supported by site-directed mutagenesis and transport assays. Using trehalase activity measurements, we demonstrated that the release of Pi is a critical step for transceptor signaling. Our results add to previous studies on PiPT, creating a more complete picture of the proton-coupled Pi transport cycle of a transceptor.

Industrial chicory genome gives insights into the molecular timetable of anther development and male sterility.

Industrial chicory (Cichorium intybus var. sativum) is a biannual crop mostly cultivated for extraction of inulin, a fructose polymer used as a dietary fiber. F1 hybrid breeding is a promising breeding strategy in chicory but relies on stable male sterile lines to prevent self-pollination. Here, we report the assembly and annotation of a new industrial chicory reference genome. Additionally, we performed RNA-Seq on subsequent stages of flower bud development of a fertile line and two cytoplasmic male sterile (CMS) clones. Comparison of fertile and CMS flower bud transcriptomes combined with morphological microscopic analysis of anthers, provided a molecular understanding of anther development and identified key genes in a range of underlying processes, including tapetum development, sink establishment, pollen wall development and anther dehiscence. We also described the role of phytohormones in the regulation of these processes under normal fertile flower bud development. In parallel, we evaluated which processes are disturbed in CMS clones and could contribute to the male sterile phenotype. Taken together, this study provides a state-of-the-art industrial chicory reference genome, an annotated and curated candidate gene set related to anther development and male sterility as well as a detailed molecular timetable of flower bud development in fertile and CMS lines.