Phytophthora infestans RXLR effector SFI5 requires association with calmodulin for PTI/MTI suppressing activity.

Pathogens secrete effector proteins to interfere with plant innate immunity, in which Ca2+ /calmodulin (CaM) signalling plays key roles. Thus far, few effectors have been identified that directly interact with CaM for defence suppression. Here, we report that SFI5, an RXLR effector from Phytophthora infestans, suppresses microbe-associated molecular pattern (MAMP)-triggered immunity (MTI) by interacting with host CaMs. We predicted the CaM-binding site in SFI5 using in silico analysis. The interaction between SFI5 and CaM was tested by both in vitro and in vivo assays. MTI suppression by SFI5 and truncated variants were performed in a tomato protoplast system. We found that both the predicted CaM-binding site and the full-length SFI5 protein interact with CaM in the presence of Ca2+ . MTI responses, such as FRK1 upregulation, reactive oxygen species accumulation, and mitogen-activated protein kinase activation were suppressed by truncated SFI5 proteins containing the C-terminal CaM-binding site but not by those without it. The plasma membrane localization of SFI5 and its ability to enhance infection were also perturbed by loss of the CaM-binding site. We conclude that CaM-binding is required for localization and activity of SFI5. We propose that SFI5 suppresses plant immunity by interfering with immune signalling components after activation by CaMs.

The Mo-Se active site of nicotinate dehydrogenase.

Nicotinate dehydrogenase (NDH) from Eubacterium barkeri is a molybdoenzyme catalyzing the hydroxylation of nicotinate to 6-hydroxynicotinate. Reactivity of NDH critically depends on the presence of labile (nonselenocysteine) selenium with an as-yet-unidentified form and function. We have determined the crystal structure of NDH and analyzed its active site by multiple wavelengths anomalous dispersion methods. We show that selenium is bound as a terminal Mo=Se ligand to molybdenum and that it occupies the position of the terminal sulfido ligand in other molybdenum hydroxylases. The role of selenium in catalysis has been assessed by model calculations, which indicate an acceleration of the critical hydride transfer from the substrate to the selenido ligand in the course of substrate hydroxylation when compared with an active site containing a sulfido ligand. The MoO(OH)Se active site of NDH shows a novel type of utilization and reactivity of selenium in nature.

HTHP: a novel class of hexameric, tyrosine-coordinated heme proteins.

We have cloned, expressed, isolated and characterized a hexameric tyrosine-coordinated heme protein (HTHP) from the marine bacterium Silicibacter pomeroyi. HTHP shows peroxidase and catalase activity and has a high thermal stability. As-isolated HTHP has absorption maxima at 407, 495, 504, 532 and 622 nm wavelength. Upon reduction maxima at 430, 564 and 596 nm wavelength are discernible. The crystal structure of HTHP reveals a hexameric, ring-like arrangement of six monomers. Each monomer binds a solvent accessible heme group, which is stabilized by the interaction of three neighboring monomers. The pocket around the heme distal side is positively charged due to three conserved arginine residues in direct vicinity. The heme iron is penta-coordinated with a tyrosine residue as proximal ligand. The coordinating hydroxyl-group of the tyrosine ligand interacts with the guanidinium group of a nearby arginine residue, an arrangement closely resembling the catalytic dyad found in monofunctional heme-containing catalases and coral allene oxide synthases, which are b-type cytochromes with tyrosine coordination trans to an empty coordination site. Despite the similarity in heme coordination HTHP is functionally and structurally unrelated to catalases and other heme-containing proteins. Its hexameric arrangement, solvent accessible heme binding pocket and heme coordination by tyrosine render HTHP a unique protein with unusual properties. A database search against complete and incomplete genomes shows that the 76 amino acid residues sequence of HTHP is unrelated to characterized proteins, but is homologous to orfs found in a phylogenetically diverse set of bacteria with sequence identities of 30-76%. We therefore propose that HTHP is the prototype of a new class of heme proteins.

Molecular and functional analysis of nicotinate catabolism in Eubacterium barkeri.

The anaerobic soil bacterium Eubacterium barkeri catabolizes nicotinate to pyruvate and propionate via a unique fermentation. A full molecular characterization of nicotinate fermentation in this organism was accomplished by the following results: (i) A 23.2-kb DNA segment with a gene cluster encoding all nine enzymes was cloned and sequenced, (ii) two chiral intermediates were discovered, and (iii) three enzymes were found, completing the hitherto unknown part of the pathway. Nicotinate dehydrogenase, a (nonselenocysteine) selenium-containing four-subunit enzyme, is encoded by ndhF (FAD subunit), ndhS (2 x [2Fe-2S] subunit), and by the ndhL/ndhM genes. In contrast to all enzymes of the xanthine dehydrogenase family, the latter two encode a two-subunit molybdopterin protein. The 6-hydroxynicotinate reductase, catalyzing reduction of 6-hydroxynicotinate to 1,4,5,6-tetrahydro-6-oxonicotinate, was purified and shown to contain a covalently bound flavin cofactor, one [2Fe-2S](2+/1+) and two [4Fe-4S](2+/1+) clusters. Enamidase, a bifunctional Fe-Zn enzyme belonging to the amidohydrolase family, mediates hydrolysis of 1,4,5,6-tetrahydro-6-oxonicotinate to ammonia and (S)-2-formylglutarate. NADH-dependent reduction of the latter to (S)-2-(hydroxymethyl)glutarate is catalyzed by a member of the 3-hydroxyisobutyrate/phosphogluconate dehydrogenase family. A [4Fe-4S]-containing serine dehydratase-like enzyme is predicted to form 2-methyleneglutarate. After the action of the coenzyme B(12)-dependent 2-methyleneglutarate mutase and 3-methylitaconate isomerase, an aconitase and isocitrate lyase family pair of enzymes, (2R,3S)-dimethylmalate dehydratase and lyase, completes the pathway. Genes corresponding to the first three enzymes of the E. barkeri nicotinate catabolism were identified in nine Proteobacteria.