Thioredoxins (Trxs) are ubiquitous small proteins with a redoxactive disulfide bridge. In their reduced form, they constitute very efficient protein disulfide oxidoreductases. In chloroplasts, two types of Trxs ( f and m) coexist and play central roles in the regulation of the Calvin cycle and other processes. Here, we identified a class of Trx targets in the inner plastid envelope membrane of chloroplasts that share a CxxC motif Ϸ73 aa from their carboxyl-terminal end. Members of this group belong to a superfamily of Rieske iron-sulfur proteins involved in protein translocation and chlorophyll metabolism. These proteins include the protein translocon protein TIC55, the precursor NADPH:protochlorophyllide oxidoreductase translocon protein PTC52, which operates as protochlorophyllide a-oxygenase, and the lethal leaf spot protein LLS1, which is identical with pheophorbide a oxygenase. The role of these proteins in dark/light regulation and oxidative control by the Trx system is discussed.protein translocation ͉ tetrapyrrole biosynthesis ͉ Tigrina d12 ͉ FLU mutant ͉ photooxidative stress
The Arabidopsis CAO gene encodes a 52-kDa protein with predicted localization in the plastid compartment. Here, we report that CAO is an intrinsic Rieske iron-sulfur protein of the plastidenvelope inner and thylakoid membranes. Activity measurements revealed that CAO catalyzes chlorophyllide a to chlorophyllide b conversion in vitro and that the enzyme was only slightly active with protochlorophyllide a, the nonreduced precursor of chlorophyllide a. Protein import and organelle fractionation studies identified CAO to be distinct from Ptc52 in the substrate-dependent transport pathway of NADPH:protochlorophyllide oxidoreductase A but instead to be part of a separate translocon complex. This complex was involved in the regulated import and stabilization of the chlorophyllide b-binding light-harvesting proteins Lhcb1 (LHCII) and Lhcb4 (CP29) in chloroplasts. Together, our results provide insights into the plastid subcompartmentalization and evolution of chlorophyll precursor biosynthesis in relation to protein import in higher plants.chlorophyll biosynthesis ͉ light-harvesting proteins ͉ protein import
NADPH:protochlorophyllide oxidoreductase (POR) B is a key enzyme for the light-induced greening of etiolated angiosperm plants. It is nucleus-encoded, imported into the plastids posttranslationally, and assembled into larger light-harvesting POR:protochlorophyllide complexes termed LHPP (Reinbothe et al., Nature 397:80-84, 1999). An in vitro-mutagenesis approach was taken to study the role of the evolutionarily conserved Cys residues in pigment binding. Four Cys residues are present in the PORB of which two, Cys276 and Cys303, established distinct pigment binding sites, as shown by biochemical tests, protein import studies, and in vitro-reconstitution experiments. While Cys276 constituted the Pchlide binding site in the active site of the enzyme, Cys303 established a second, low affinity pigment binding site that was involved in the assembly and stabilization of imported PORB enzyme inside etioplasts.
Higher plants contain a small, 5-member family of Rieske non-heme oxygenases that comprise the inner plastid envelope protein TIC55, phaeophorbide
a
oxygenasee (PAO), chlorophyllide
a
oxygenase (CAO), choline monooxygenase, and a 52 kDa protein (PTC52) associated with the precursor NADPH:protochlorophyllide (Pchlide) oxidoreductase A (pPORA) A translocon (PTC). Some of these chloroplast proteins have documented roles in chlorophyll biosynthesis (CAO) and degradation (PAO and TIC55), whereas the function of PTC52 remains unresolved. Biochemical evidence provided here identifies PTC52 as Pchlide
a
oxygenase of the inner plastid envelope linking Pchlide
b
synthesis to pPORA import. Protochlorophyllide
b
is the preferred substrate of PORA and its lack no longer allows pPORA import. The Pchlide
b
-dependent import pathway of pPORA thus operates in etiolated seedlings and is switched off during greening. Using dexamethasone-induced RNA interference (RNAi) we tested if PTC52 is involved in controlling both, pPORA import and Pchlide homeostasis
in planta
. As shown here,
RNAi
plants deprived of
PTC52
transcript and PTC52 protein were unable to import pPORA and died as a result of excess Pchlide
a
accumulation causing singlet oxygen formation during greening. In genetic studies, no homozygous
ptc52
knock-out mutants could be obtained presumably as a result of embryo lethality, suggesting a role for PTC52 in the initial greening of plant embryos. Phylogenetic studies identified PTC52-like genes amongst unicellular photosynthetic bacteria and higher plants, suggesting that the biochemical function associated with PTC52 may have an ancient evolutionary origin. PTC52 also harbors conserved motifs with bacterial oxygenases such as the terminal oxygenase component of 3-ketosteroid 9-alpha-hydroxylase (KshA) from
Rhodococcus rhodochrous
. 3D-modeling of PTC52 structure permitted the prediction of amino acid residues that contribute to the substrate specificity of this enzyme.
In vitro
-mutagenesis was used to test the predicted PTC52 model and provide insights into the reaction mechanism of this Rieske non-heme oxygenase.
Genetic analysis of all Mucor-like fungi is severely impaired by the low efficiency of transformation systems and the genetic instability of the introduced plasmid constructs. The transformation efficiency of one of the model systems among mucoralean fungi, Absidia glauca, was improved considerably by microprojectile bombardment. For this purpose, a plasmid was constructed conferring (i) neomycin resistance as a selective marker and (ii) fluorescence due to expression of the gfp gene from the jellyfish Aequorea victoria. Compared with previous techniques, this method offers increased efficiency, with considerably easier handling than procedures based on protoplasts and, therefore, improved reliability. The uninucleate sporangiospores of A. glauca can be transformed early during the germination process. At this stage the number of nuclei ranges between 1 and 2. Thus, the abundance of transgenic nuclei in the coenocytic mycelia is high, and fewer problems are encountered with detecting low expression levels of the genes used for selection and monitoring of transformants.
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