48 research outputs found
A metabolomic, geographic, and seasonal analysis of the contribution of pollen-derived adenosine to allergic sensitization
Background
Studies on ragweed and birch pollen extracts suggested that the adenosine content is an important factor in allergic sensitization. However, exposure levels from other pollens and considerations of geographic and seasonal factors have not been evaluated.
Objective
This study compared the metabolite profile of pollen species important for allergic disease, specifically measured the adenosine content, and evaluated exposure to pollen-derived adenosine.
Methods
An NMR metabolomics approach was used to measure metabolite concentrations in twenty-six pollen extracts. Pollen count data was analyzed from five cities to model exposure.
Results
A principal component analysis of the various metabolites identified by NMR showed that pollen extracts could be differentiated primarily by sugar content: glucose, fructose, sucrose, and myo-inositol. In extracts of 10 mg of pollen/ml, the adenosine was highest for grasses (45 Ī¼M) followed by trees (23 Ī¼M) and weeds (19 Ī¼M). Pollen count data showed that tree pollen was typically 5ā10 times the amount of other pollens. At the daily peaks of tree, grass, and weed season the pollen-derived adenosine exposure per day is likely to only be 1.1, 0.11, and 0.12 Ī¼g, respectively. Seasonal models of pollen exposure and respiration suggest that it would be a rare event limited to tree pollen season for concentrations of pollen-derived adenosine to approach physiological levels.
Conclusions
Sugar content and other metabolites may be useful in classifying pollens. Unless other factors create localized exposures that are very different from these models, pollen-derived adenosine is unlikely to be a major factor in allergic sensitization
Structural studies of the PARP-1 BRCT domain
<p>Abstract</p> <p>Background</p> <p>Poly(ADP-ribose) polymerase-1 (PARP-1) is one of the first proteins localized to foci of DNA damage. Upon activation by encountering nicked DNA, the PARP-1 mediated trans-poly(ADP-ribosyl)ation of DNA binding proteins occurs, facilitating access and accumulation of DNA repair factors. PARP-1 also auto-(ADP-ribosyl)ates its central BRCT-containing domain forming part of an interaction site for the DNA repair scaffolding protein X-ray cross complementing group 1 protein (XRCC1). The co-localization of XRCC1, as well as bound DNA repair factors, to sites of DNA damage is important for cell survival and genomic integrity.</p> <p>Results</p> <p>Here we present the solution structure and biophysical characterization of the BRCT domain of rat PARP-1. The PARP-1 BRCT domain has the globular Ī±/Ī² fold characteristic of BRCT domains and has a thermal melting transition of 43.0Ā°C. In contrast to a previous characterization of this domain, we demonstrate that it is monomeric in solution using both gel-filtration chromatography and small-angle X-ray scattering. Additionally, we report that the first BRCT domain of XRCC1 does not interact significantly with the PARP-1 BRCT domain in the absence of ADP-ribosylation. Moreover, none of the interactions with other longer PARP-1 constructs which previously had been demonstrated in a pull-down assay of mammalian cell extracts were detected.</p> <p>Conclusions</p> <p>The PARP-1 BRCT domain has the conserved BRCT fold that is known to be an important protein:protein interaction module in DNA repair and cell signalling pathways. Data indicating no significant protein:protein interactions between PARP-1 and XRCC1 likely results from the absence of poly(ADP-ribose) in one or both binding partners, and further implicates a poly(ADP-ribose)-dependent mechanism for localization of XRCC1 to sites of DNA damage.</p
A comparison of BRCT domains involved in nonhomologous end-joining: Introducing the solution structure of the BRCT domain of polymerase lambda
Three of the four family X polymerases, DNA polymerase Ī», DNA polymerase Āµ, and TdT have been associated with repair of double-strand DNA breaks by nonhomologous end-joining. Their involvement in this DNA repair process requires an N-terminal BRCT domain that mediates interaction with other protein factors required for recognition and binding of broken DNA ends. Here we present the NMR solution structure of the BRCT domain of DNA polymerase Ī», completing the structural portrait for this family of enzymes. Analysis of the overall fold of the polymerase Ī» BRCT domain reveals structural similarity to the BRCT domains of polymerase Āµ and TdT, yet highlights some key sequence and structural differences that may account for important differences in the biological activities of these enzymes and their roles in nonhomologous end-joining. Mutagenesis studies indicate that the conserved Arg57 residue of Pol Ī» plays a more critical role for binding to the XRCC4-Ligase IV complex than its structural homolog in Pol Āµ, Arg43. In contrast, the hydrophobic Leu60 residue of Pol Ī» contributes less significantly to binding than the structurally homologous Phe46 residue of Pol Āµ. A third leucine residue involved in the binding and activity of Pol Āµ, is nonconservatively replaced by a glutamine in Pol Ī» (Gln64) and, based on binding and activity data, is apparently unimportant for Pol Ī» interactions with the NHEJ complex. In conclusion, both the structure of the Pol Ī» BRCT domain and its mode of interaction with the other components of the NHEJ complex significantly differ from the two previously studied homologs, Pol Āµ and TdT
NMR Solution Structure of the Focal Adhesion Targeting Domain of Focal Adhesion Kinase in Complex with a Paxillin LD Peptide: EVIDENCE FOR A TWO-SITE BINDING MODEL
Focal adhesion kinase (FAK) is a non-receptor tyrosine kinase that is regulated by integrins. Upon activation, FAK generates signals that modulate crucial cell functions, including cell proliferation, migration, and survival. The C-terminal focal adhesion targeting (FAT) sequence mediates localization of FAK to discrete regions in the cell called focal adhesions. Several binding partners for the FAT domain of FAK have been identified, including paxillin. We have determined the solution structure of the avian FAT domain in complex with a peptide mimicking the LD2 motif of paxillin by NMR spectroscopy. The FAT domain retains a similar fold to that found in the unliganded form when complexed to the paxillin-derived LD2 peptide, an antiparallel four-helix bundle. However, noticeable conformational changes were observed upon the LD2 peptide binding, especially the position of helix 4. Multiple lines of evidence, including the results obtained from isothermal titration calorimetry, intermolecular nuclear Overhauser effects, mutagenesis, and protection from paramagnetic line broadening, support the existence of two distinct paxillin-binding sites on the opposite faces of the FAT domain. The structure of the FAT domain-LD2 complex was modeled using the program HADDOCK based on our solution structure of the LD2-bound FAT domain and mutagenesis data. Our model of the FAT domain-LD2 complex provides insight into the molecular basis of FAK-paxillin binding interactions, which will aid in understanding the role of paxillin in FAK targeting and signaling
Solution Structure of Polymerase Ī¼'s BRCT Domain Reveals an Element Essential for Its Role in Nonhomologous End Joining ā
The solution structure and dynamics of the BRCT domain from human DNA polymerase Ī¼, implicated in repair of chromosome breaks by nonhomologous end joining (NHEJ), has been determined using NMR methods. BRCT domains are typically involved in proteināprotein interactions between factors required for the cellular response to DNA damage. The pol Ī¼ BRCT domain is atypical in that, unlike other reported BRCT structures, the pol Ī¼ BRCT is neither part of a tandem grouping, nor does it appear to form stable homodimers. Although the sequence of the pol Ī¼ BRCT domain has some unique characteristics, particularly the presence of > 10% proline residues, it forms the characteristic Ī±Ī²Ī± sandwich, in which three alpha helices are arrayed around a central four-stranded Ī²-sheet. The structure of helix Ī±1 is characterized by two solvent-exposed hydrophobic residues, F46 and L50, suggesting that this element may play a role in mediating interactions of pol Ī¼ with other proteins. Consistent with this argument, mutation of these residues, as well as the proximal, conserved residue R43, specifically blocked the ability of pol Ī¼ to efficiently work together with NHEJ factors Ku and XRCC4-ligase IV to join noncomplementary ends together in vitro. The structural, dynamic, and biochemical evidence reported here identifies a functional surface in the pol Ī¼ BRCT domain critical for promoting assembly and activity of the NHEJ machinery. Further, the similarity between the interaction regions of the BRCT domains of pol Ī¼ and TdT support the conclusion that they participate in NHEJ as alternate polymerases
A new method for computing the properties of negative ion resonances with applications to negative dihydrogen ion, negative hydrogen-fluoride ion, and negative hydrogen ion.
A new method for computing the properties of negative ion resonances with applications to negative dihydrogen ion, negative hydrogen-fluoride ion, and negative hydrogen ion
Nanobody Paratope Ensembles in Solution Characterized by MD Simulations and NMR
Variable domains of camelid antibodies (so-called nanobodies or VHH) are the smallest antibody fragments that retain complete functionality and therapeutic potential. Understanding of the nanobody-binding interface has become a pre-requisite for rational antibody design and engineering. The nanobody-binding interface consists of up to three hypervariable loops, known as the CDR loops. Here, we structurally and dynamically characterize the conformational diversity of an anti-GFP-binding nanobody by using molecular dynamics simulations in combination with experimentally derived data from nuclear magnetic resonance (NMR) spectroscopy. The NMR data contain both structural and dynamic information resolved at various timescales, which allows an assessment of the quality of protein MD simulations. Thus, in this study, we compared the ensembles for the anti-GFP-binding nanobody obtained from MD simulations with results from NMR. We find excellent agreement of the NOE-derived distance maps obtained from NMR and MD simulations and observe similar conformational spaces for the simulations with and without NOE time-averaged restraints. We also compare the measured and calculated order parameters and find generally good agreement for the motions observed in the ps–ns timescale, in particular for the CDR3 loop. Understanding of the CDR3 loop dynamics is especially critical for nanobodies, as this loop is typically critical for antigen recognition