Jean‐Michel Wieruszeski scite author profile

We report here a biochemical and structural characterization of domain 2 of the nonstructural 5A protein (NS5A) from the JFH1 Hepatitis C virus strain and its interactions with cyclophilins A and B (CypA and CypB). Gel filtration chromatography, circular dichroism spectroscopy, and finally NMR spectroscopy all indicate the natively unfolded nature of this NS5A-D2 domain. Because mutations in this domain have been linked to cyclosporin A resistance, we used NMR spectroscopy to investigate potential interactions between NS5A-D2 and cellular CypA and CypB. We observed a direct molecular interaction between NS5A-D2 and both cyclophilins. The interaction surface on the cyclophilins corresponds to their active site, whereas on NS5A-D2, it proved to be distributed over the many proline residues of the domain. NMR heteronuclear exchange spectroscopy yielded direct evidence that many proline residues in NS5A-D2 form a valid substrate for the enzymatic peptidyl-prolyl cis/trans isomerase (PPIase) activity of CypA and CypB.

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Waxy Chlamydomonas reinhardtii: monocellular algal mutants defective in amylose biosynthesis and granule-bound starch synthase activity accumulate a structurally modified amylopectin

Delrue

et al. 1992

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Amylose-defective mutants were selected after UV mutagenesis of Chlamydomonas reinhardtii cells. Two recessive nuclear alleles of the ST-2 gene led to the disappearance not only of amylose but also of a fraction of the amylopectin. Granule-bound starch synthase activities were markedly reduced in strains carrying either st-2-1 or st-2-2, as is the case for amylose-deficient (waxy) endosperm mutants of higher plants. The main 76-kDa protein associated with the starch granule was either missing or greatly diminished in both mutants, while st-2-1-carrying strains displayed a novel 56-kDa major protein. Methylation and nuclear magnetic resonance analysis of wild-type algal storage polysaccharide revealed a structure identical to that of higher-plant starch, while amylose-defective mutants retained a modified amylopectin fraction. We thus propose that the waxy gene product conditions not only the synthesis of amylose from endosperm storage tissue in higher-plant amyloplasts but also that of amylose and a fraction of amylopectin in all starch-accumulating plastids. The nature of the ST-2 (waxy) gene product with respect to the granule-bound starch synthase activities is discussed.Our knowledge of starch synthesis and degradation, while having developed mostly from observations made in higherplant storage tissues, has benefited from investigations performed on a number of model microbial systems. Chlorella pyrenoidosa, for instance, has been the subject of several of the pioneer studies dealing with the enzymology of starch anabolism (16,20). Prokaryotic organisms such as Escherichia coli have yielded a number of relevant genetic and biochemical studies, mostly because of the parallel that can be drawn between the regulation of plant and bacterial ADP-pyrophosphorylases (reviewed in reference 18). However, the very nature of the storage polysaccharide (glycogen) has prevented the use of model bacterial systems to investigate the biogenesis of the starch granule itself. Thus, our knowledge of the intricate pathways of amylose and amylopectin biosyntheses stems solely from those elegant genetic investigations performed on pea or cereal mutations which express themselves only in the endosperm (reviewed in references 15 and 22). Even in that case, we do not yet know precisely which of the starch synthases and starch branching enzymes are responsible for amylose or amylopectin biosynthesis, let alone how they act coordinately to produce a complex structure such as the starch granule. One of the best and most studied endosperm mutants, waxy maize, seemed until very recently to shed at least some light on the biosynthesis of amylose. Waxy mutations have been identified in most cereals (22, 32) and more recently in storage tissues of dicots such as potato (9) or in the perisperm of the amaranth (11). They all lead to the decrease or absence of both amylose and granule-bound starch synthase. While there is no doubt that one of the main proteins associated with the starch granule is the product of the waxy * Corresponding author...

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Structural Impact of Heparin Binding to Full-Length Tau As Studied by NMR Spectroscopy

et al. 2006

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The neuronal Tau protein is involved in stabilizing microtubules but is also the major component of the paired helical filaments (PHFs), the intracellular aggregates that characterize Alzheimer's disease (AD) in neurons. In vitro, Tau can be induced to form AD-like aggregates by adding polyanions such as heparin. While previous studies have identified the microtubule binding repeats (MTBRs) as the major player in Tau aggregation, the fact that the full-length protein does not aggregate by itself indicates the presence of inhibitory factors. Charge and conformational changes are of uttermost importance near the second (R2) and third (R3) MTBR that are thought to be involved directly in the nucleation of the aggregation. Recently, the positively charged regions flanking the MTBR were proposed to inhibit PHF assembly, where hyperphosphorylation neutralizes these basic inhibitory domains, enabling Tau-Tau interactions. Here we present results of an NMR study on the interaction between intact full-length Tau and small heparin fragments of well-defined size, under conditions where no aggregation occurs. Our findings reveal (i) micromolar affinity of heparin to residues in R2 and R3, (ii) two zones of strong interaction within the positively charged inhibitory regions flanking the MTBR, and (iii) another interaction site upstream of the two inserts encoded by exons 2 and 3. Three-dimensional heteronuclear NMR experiments demonstrate that the interaction with heparin induces beta-strand structure in several regions of Tau that might act as nucleation sites for its aggregation but indicate as well alpha-helical structure in regions outside the core of PHF. In the PHF, the residues outside of the core maintain sufficient mobility for NMR detection and recover their unbound chemical shift values after an overnight incubation at 37 degrees C with heparin. Heparin thus becomes integrated into the rigid core region of the PHF, probably providing the charge compensation for the lysine-rich stretches that form upon the in-register, parallel stacking of the repeat regions.

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