Thymine Photodimers. Two-dimensional NMR and photo-CIDNP studies

De erfelijke eigenschappen van levende organismen zijn vastgelegd in DNA molekulen in de vorm van een specifieke volgorde van de basen adenine, cytosine, guanine en thymine. Het essentieel voor de ontwikkeling van levende organisemen, dat de DNA molekulen zeer vaak gedupliceerd kunnen worden zoder dat de vastgelegde code noemenswaardig veranderd. Dit vereist een extreem hoge stabiliteit van het DNA molekuul. In schijnbare tegenspraak hiermee is het feit, dat het DNA wordt blootgesteld aan een groot aantal externe factoren, die de genetische code kunnen verminken. Een van die factoren is het ultraviolet licht. De belangrijkste schade veroorzaakt door ultraviolet licht is het thymine dimeer, dat op twee manieren kan worden gevormd. ... Zie: Samenvattin

A β-hairpin epitope as novel structural requirement for protein arginine rhamnosylation

For canonical asparagine glycosylation, the primary amino acid sequence that directs glycosylation at specific asparagine residues is well-established. Here we reveal that a recently discovered bacterial enzyme EarP, that transfers rhamnose to a specific arginine residue in its acceptor protein EF-P, specifically recognizes a beta-hairpin loop. Notably, while the in vitro rhamnosyltransferase activity of EarP is abolished when presented with linear substrate peptide sequences derived from EF-P, the enzyme readily glycosylates the same sequence in a cyclized beta-hairpin mimic. Additional studies with other substrate-mimicking cyclic peptides revealed that EarP activity is sensitive to the method used to induce cyclization and in some cases is tolerant to amino acid sequence variation. Using detailed NMR approaches, we established that the active peptide substrates all share some degree of beta-hairpin formation, and therefore conclude that the beta-hairpin epitope is the major determinant of arginine-rhamnosylation by EarP. Our findings add a novel recognition motif to the existing knowledge on substrate specificity of protein glycosylation, and are expected to guide future identifications of rhamnosylation sites in other protein substrates

Thioredoxin fold as homodimerization module in the putative chaperone ERp29 : NMR structures of the domains and experimental model of the 51 kDa dimer

Funding Information: We thank Dr. William J. Griffiths for mass spectrometric analysis; Dr. Andrei Kaikkonen for the calculation of paramagnetic relaxation enhancements; and the Swedish NMR Center for access to the 800 MHz NMR spectrometer. This work was supported by the Swedish Natural Science Research Council, Swedish Medical Research Council, Swedish Society for Medical Research, and by an FRN grant for the 500 MHz NMR spectrometer. M.B. received a scholarship from the Swedish Institute and the Royal Swedish Academy. Copyright: Copyright 2012 Elsevier B.V., All rights reserved.Background: ERp29 is a ubiquitously expressed rat endoplasmic reticulum (ER) protein conserved in mammalian species. Fold predictions suggest the presence of a thioredoxin-like domain homologous to the a domain of human protein disulfide isomerase (PDI) and a helical domain similar to the C-terminal domain of P5-like PDIs. As ERp29 lacks the double-cysteine motif essential for PDI redox activity, it is suggested to play a role in protein maturation and/or secretion related to the chaperone function of PDI. ERp29 self-associates into 51 kDa dimers and also higher oligomers. Results: 3D structures of the N- and C-terminal domains determined by NMR spectroscopy confirmed the thioredoxin fold for the N-terminal domain and yielded a novel all-helical fold for the C-terminal domain. Studies of the full-length protein revealed a short, flexible linker between the two domains, homodimerization by the N-terminal domain, and the presence of interaction sites for the formation of higher molecular weight oligomers. A gadolinium-based relaxation agent is shown to present a sensitive tool for the identification of macromolecular interfaces by NMR. Conclusions: ERp29 is the first eukaryotic PDI-related protein for which the structures of all domains have been determined. Furthermore, an experimental model of the full-length protein and its association states was established. It is the first example of a protein where the thioredoxin fold was found to act as a specific homodimerization module, without covalent linkages or supporting interactions by further domains. A homodimerization module similar as in ERp29 may also be present in homodimeric human PDI.publishersversionPeer reviewe

Protein disulfide isomerase activity is essential for viability and extracellular matrix formation in the nematode Caenorhabditis elegans.

Protein disulfide isomerase (PDI) is a multifunctional protein required for many aspects of protein folding and transit through the endoplasmic reticulum. A conserved family of three PDIs have been functionally analysed using genetic mutants of the model organism Caenorhabditis elegans. PDI-1 and PDI-3 are individually nonessential, whereas PDI-2 is required for normal post-embryonic development. In combination, all three genes are synergistically essential for embryonic development in this nematode. Mutations in pdi-2 result in severe body morphology defects, uncoordinated movement, adult sterility, abnormal molting and aberrant collagen deposition. Many of these phenotypes are consistent with a role in collagen biogenesis and extracellular matrix formation. PDI-2 is required for the normal function of prolyl 4-hydroxylase, a key collagen-modifying enzyme. Site-directed mutagenesis indicates that the independent catalytic activity of PDI-2 may also perform an essential developmental function. PDI-2 therefore performs two critical roles during morphogenesis. The role of PDI-2 in collagen biogenesis can be partially restored following complementation of the mutant with human PDI

Oligomerization properties of ERp29, an endoplasmic reticulum stress protein

Funding Information: This work was supported by the Swedish Medical Research Council. We thank Prof. H.F. Gilbert for helpful discussions and critical reading of the manuscript. Copyright: Copyright 2007 Elsevier B.V., All rights reserved. Correction(s) for this article: Oligomerization properties of ERp29, an endoplasmic reticulum stress protein. FEBS Letters,Vol.433, N.3, p.335-335. - First Published online: June 28, 1999.ERp29, a novel and ubiquitously expressed endoplasmic reticulum (ER) stress-inducible protein, was recently isolated and cDNA cloned in our laboratory. Using size exclusion chromatography and chemical cross-linking we have assessed the oligomerization properties of ERp29. Purified ERp29 in solution as well as in rat hepatoma cells self-associates predominantly into homodimers. Labeling of the cells with [35S]methionine with subsequent cross-linking and immunprecipitation showed that ERp29 interacts with a number of ER proteins, one of which was previously identified as BiP/GRP78. Secondary structure prediction and fold recognition methods indicate that the native conformation of ERp29 resembles the thioredoxin fold, a structural motif characteristic of a number of enzymes with the redox function, including protein disulfide isomerase (with which ERp29 shares limited sequence similarity). Dimerization of the protein is suggested to be advantageous for the protein binding potential of ERp29.publishersversionPeer reviewe

A peptide mimic of the chemotaxis inhibitory protein of Staphylococcus aureus: towards the development of novel anti-inflammatory compounds

Complement factor C5a is one of the most powerful pro-inflammatory agents involved in recruitment of leukocytes, activation of phagocytes and other inflammatory responses. C5a triggers inflammatory responses by binding to its G-protein-coupled C5a-receptor (C5aR). Excessive or erroneous activation of the C5aR has been implicated in numerous inflammatory diseases. The C5aR is therefore a key target in the development of specific anti-inflammatory compounds. A very potent natural inhibitor of the C5aR is the 121-residue chemotaxis inhibitory protein of Staphylococcus aureus (CHIPS). Although CHIPS effectively blocks C5aR activation by binding tightly to its extra-cellular N terminus, it is not suitable as a potential anti-inflammatory drug due to its immunogenic properties. As a first step in the development of an improved CHIPS mimic, we designed and synthesized a substantially shorter 50-residue adapted peptide, designated CHOPS. This peptide included all residues important for receptor binding as based on the recent structure of CHIPS in complex with the C5aR N terminus. Using isothermal titration calorimetry we demonstrate that CHOPS has micromolar affinity for a model peptide comprising residues 7–28 of the C5aR N terminus including two O-sulfated tyrosine residues at positions 11 and 14. CD and NMR spectroscopy showed that CHOPS is unstructured free in solution. Upon addition of the doubly sulfated model peptide, however, the NMR and CD spectra reveal the formation of structural elements in CHOPS reminiscent of native CHIPS