Claude Didierjean

The Canonical Helix of Urea Oligomers at Atomic Resolution: Insights Into Folding‐Induced Axial Organization

Foldamers are discrete artificial oligomers with defined and predictable folding patterns akin to naturally occurring helices, turns, and linear strands. Because of their diversity in size, shape, and side chain appendages, and also their resistance to enzymatic degradation, peptidomimetic helical foldamers are unique scaffolds for use in a range of biological and biomedical applications. Characterizing such helical folds at atomic resolution is of prime importance if molecules are to be designed that can target biological surfaces and for reliable structure–function analysis. To date, extensive crystallographic data sets have been gathered on aliphatic (band a/b-peptides) and aromatic oligoamides, thus providing a detailed picture of the structural diversity within these foldamer families. Few other helical peptidomimetic backbones have been characterized by crystallographic analysis. Crystal structures are also central to gain precise insight into axial and lateral 13] self-assembling properties of helical foldamers, en route to new tertiary and quaternary structural motifs and more sophisticated self-assembled nanostructures. Notable achievements include the atomic structure determination of large (> 8 kDa) aromatic oligoamide foldamers and helix-bundle quaternary structures formed by designed band a/b-peptides. 13] Oligomers consisting of N,N’-linked urea bridging units are receiving increasing attention as folding backbones. Peptidomimetic oligoureas belonging to the g-peptide lineage, (-NH-CH(R)-CH2N’H-CO)n-, have a remarkable propensity to fold into helical secondary structures in solution and show promise for interaction with biologi-

Structure-function relationship of the chloroplastic glutaredoxin S12 with an atypical WCSYS active site.

Glutaredoxins (Grxs) are efficient catalysts for the reduction of mixed disulfides in glutathionylated proteins, using glutathione or thioredoxin reductases for their regeneration. Using GFP fusion, we have shown that poplar GrxS12, which possesses a monothiol 28WCSYS32 active site, is localized in chloroplasts. In the presence of reduced glutathione, the recombinant protein is able to reduce in vitro substrates, such as hydroxyethyldisulfide and dehydroascorbate, and to regenerate the glutathionylated glyceraldehyde-3-phosphate dehydrogenase. Although the protein possesses two conserved cysteines, it is functioning through a monothiol mechanism, the conserved C terminus cysteine (Cys87) being dispensable, since the C87S variant is fully active in all activity assays. Biochemical and crystallographic studies revealed that Cys87 exhibits a certain reactivity, since its pKa is around 5.6. Coupled with thiol titration, fluorescence, and mass spectrometry analyses, the resolution of poplar GrxS12 x-ray crystal structure shows that the only oxidation state is a glutathionylated derivative of the active site cysteine (Cys29) and that the enzyme does not form inter- or intramolecular disulfides. Contrary to some plant Grxs, GrxS12 does not incorporate an iron-sulfur cluster in its wild-type form, but when the active site is mutated into YCSYS, it binds a [2Fe-2S] cluster, indicating that the single Trp residue prevents this incorporation.

Thioredoxins and related proteins in photosynthetic organisms: molecular basis for thiol dependent regulation

Thioredoxins are small molecular weight disulfide oxidoreductases specialized in the reduction of disulfide bonds on other proteins. Generally, the enzymes which are selectively and reversibly reduced by these proteins oscillate between an oxidized and inactive conformation and a reduced and active conformation. Thioredoxin constitutes the archetype of a family of protein disulfide oxidoreductases which comprises glutaredoxin and protein disulfide isomerase. Thioredoxin and glutaredoxin serve many roles in the cell, including the redox regulation of target enzymes and transcription factors. They can also serve as hydrogen donors to peroxiredoxins, recently discovered heme free peroxidases, the function of which is to get rid of hydroperoxides in the cell. This review describes the molecular basis for the functioning and interaction between these enzymes in photosynthetic organisms.

Arabidopsis Chloroplastic Glutaredoxin C5 as a Model to Explore Molecular Determinants for Iron-Sulfur Cluster Binding into Glutaredoxins

Unlike thioredoxins, glutaredoxins are involved in iron-sulfur cluster assembly and in reduction of specific disulfides (i.e. protein-glutathione adducts), and thus they are also important redox regulators of chloroplast metabolism. Using GFP fusion, AtGrxC5 isoform, present exclusively in Brassicaceae, was shown to be localized in chloroplasts. A comparison of the biochemical, structural, and spectroscopic properties of Arabidopsis GrxC5 (WCSYC active site) with poplar GrxS12 (WCSYS active site), a chloroplastic paralog, indicated that, contrary to the solely apomonomeric GrxS12 isoform, AtGrxC5 exists as two forms when expressed in Escherichia coli. The monomeric apoprotein possesses deglutathionylation activity mediating the recycling of plastidial methionine sulfoxide reductase B1 and peroxiredoxin IIE, whereas the dimeric holoprotein incorporates a [2Fe-2S] cluster. Site-directed mutagenesis experiments and resolution of the x-ray crystal structure of AtGrxC5 in its holoform revealed that, although not involved in its ligation, the presence of the second active site cysteine (Cys32) is required for cluster formation. In addition, thiol titrations, fluorescence measurements, and mass spectrometry analyses showed that, despite the presence of a dithiol active site, AtGrxC5 does not form any inter- or intramolecular disulfide bond and that its activity exclusively relies on a monothiol mechanism.

The roles of glutaredoxins ligating Fe-S clusters: Sensing, transfer or repair functions?

Glutaredoxins (Grxs) are major oxidoreductases involved in the reduction of glutathionylated proteins. Owing to the capacity of several class I Grxs and likely all class II Grxs to incorporate iron-sulfur (Fe-S) clusters, they are also linked to iron metabolism. Most Grxs bind [2Fe-2S] clusters which are oxidatively- and reductively-labile and have identical ligation, involving notably external glutathione. However, subtle differences in the structural organization explain that class II Fe-S Grxs, having more labile and solvent-exposed clusters, can accept Fe-S clusters and transfer them to client proteins, whereas class I Fe-S Grxs usually do not. From the observed glutathione disulfide-mediated Fe-S cluster degradation, the current view is that the more stable Fe-S clusters found in class I Fe-S Grxs might constitute a sensor of oxidative stress conditions by modulating their activity. Indeed, in response to an oxidative signal, inactive holoforms i.e., without disulfide reductase activity, should be converted to active apoforms. Among class II Fe-S Grxs, monodomain Grxs likely serve as carrier proteins for the delivery of preassembled Fe-S clusters to acceptor proteins in organelles. Another proposed function is the repair of Fe-S clusters. From their cytoplasmic and/or nuclear localization, multidomain Grxs function in signalling pathways. In particular, they regulate iron homeostasis in yeast species by modulating the activity of transcription factors and eventually forming heterocomplexes with BolA-like proteins in response to the cellular iron status. We provide an overview of the biochemical and structural properties of Fe-S cluster-loaded Grxs in relation to their hypothetical or confirmed associated functions. This article is part of a Special Issue entitled: Fe/S proteins: Analysis, structure, function, biogenesis and diseases.

The tert-butyl side chain: a powerful means to lock peptoid amide bonds in the cis conformation.

The very simple sterically hindered tert-butyl side chain exerts complete control over the peptoid amide geometry which only exists in the cis conformation. It is exemplified in NtBu glycine homo-oligomers and in linear oligopeptoids designed with an alternating cis-trans backbone amide pattern.

An Atypical Catalytic Mechanism Involving Three Cysteines of Thioredoxin.

Unlike other thioredoxins h characterized so far, a poplar thioredoxin of the h type, PtTrxh4, is reduced by glutathione and glutaredoxin (Grx) but not NADPH:thioredoxin reductase (NTR). PtTrxh4 contains three cysteines: one localized in an N-terminal extension (Cys4) and two (Cys58 and Cys61) in the classical thioredoxin active site (57WCGPC61). The property of a mutant in which Cys58 was replaced by serine demonstrates that it is responsible for the initial nucleophilic attack during the catalytic cycle. The observation that the C4S mutant is inactive in the presence of Grx but fully active when dithiothreitol is used as a reductant indicates that Cys4 is required for the regeneration of PtTrxh4 by Grx. Biochemical and x-ray crystallographic studies indicate that two intramolecular disulfide bonds involving Cys58 can be formed, linking it to either Cys61 or Cys4. We propose thus a four-step disulfide cascade mechanism involving the transient glutathionylation of Cys4 to convert this atypical thioredoxin h back to its active reduced form.

Control of Duplex Formation and Columnar Self‐Assembly with Heterogeneous Amide/Urea Macrocycles

The perfect blend: A new class of self-assembling cyclooligomers with mixed urea/amide backbone is described (see figure). A high level of hierarchical and directional control is achieved: depending on the level of backbone preorganization, columnar or tubular arrangements with either parallel or antiparallel growing modes can be selected.

Redox based anti-oxidant systems in plants: Biochemical and structural analyses

We provide in this paper a comparative biochemical and structural analysis of the major thiol oxidoreductases (thioredoxin and glutaredoxin) of photosynthetic organisms in relation with their reductases and with target proteins, especially those involved either in the detoxication of peroxides such as hydrogen peroxide (thiol-peroxidases) or in the repair of oxidized methionines in proteins (methionine sulfoxide reductases). Particular emphasis will be given to the catalytic and regeneration mechanisms used by these enzymes. In addition, the protein-protein interactions of these systems will be discussed, leading to an integrated view of the functioning of these systems in various plant sub-cellular compartments.

Helical Oligomers of Thiazole‐Based γ‐Amino Acids: Synthesis and Structural Studies

9-Helix: 4-Amino(methyl)-1,3-thiazole-5-carboxylic acids (ATCs) were synthesized as new γ-amino acid building blocks. The structures of various ATC oligomers were analyzed in solution by CD and NMR spectroscopy and in the solid state by X-ray crystallography. The ATC sequences adopted a well-defined 9-helix structure in the solid state and in aprotic and protic organic solvents as well as in aqueous solution.