Analysis of β3 Binding to the c-Src SH3 Domain

Blood ◽  
2012 ◽  
Vol 120 (21) ◽  
pp. 383-383
Author(s):  
Patrik Nygren ◽  
Lisa M. Span ◽  
David T. Moore ◽  
Hong Cheng ◽  
Heinrich Roder ◽  
...  
Keyword(s):  
Chemical Shift ◽  
Conflicts Of Interest ◽  
Chemical Shifts ◽  
Cytoplasmic Tail ◽  
Sh3 Domain ◽  
Cd Spectroscopy ◽  
Negative Control ◽  
Aromatic Residues ◽  
Trp Fluorescence ◽  
Acidic Phospholipids

Abstract Abstract 383 An essential component of αIIbβ3-mediated outside-in signaling is activation of the tyrosine kinase c-Src, some of which is constitutively bound via its SH3 domain to the C-terminal Arg759-Gly760-Thr761 (RGT) sequence of the β3 cytoplasmic tail. RGT is quite different from the canonical polyproline sequence recognized by SH3 domains in which a polyproline helix packs against a shallow groove composed of aromatic residues (Tyr93, Tyr95, Tyr139 in c-Src). A specificity pocket located at the end of the groove and composed of residues from the n-Src- and RT-loops affects substrate specificity. Because of the obvious difference between RGT and polyproline sequences, we asked how RGT binds to the c-Src SH3 domain and what implications this has for c-Src regulation by αIIbβ3. Initially, we employed CD spectroscopy and tryptophan (Trp) fluorescence because these techniques are sensitive to changes in the local environment surrounding aromatic residues. However, there were no differences in the CD spectrum of the SH3 domain in absence or presence of the β3 peptide NITYRGT, whereas there was a clear shift in the presence of the core polyproline peptide RPLPPLP. Polyproline binding to Trp in the SH3 specificity pocket also results in a blue shift in Trp fluorescence from 355 nm to 347 nm; however, the fluorescence spectrum was essentially unchanged in the presence of NITYRGT. These experiments suggest that either the interaction of NITYRGT with SH3 is extremely weak and not observed at the concentrations used or occurs outside of the aromatic groove and the specificity pocket. Accordingly, we turned to NMR, a method able to detect weak protein-protein interactions. Two dimensional 1H-15N HSQC spectra of the SH3 domain in the presence of NITYRGT exhibited a number of changes in chemical shift compared to the spectrum in the absence of ligand. Sixteen residues located in the n-Src and RT-loops, grouped around the specificity pocket, had chemical shift changes > 0.05 ppm. The largest changes occurred in residues in or adjacent to the RT-loop, especially residues Arg98, Glu100, and Asp102. Of the resides forming the aromatic groove, only Tyr95 which is adjacent to the specificity pocket was perturbed by NITYRGT. Plots of the chemical shift changes for NH groups in SH3 vs. NITYRGT concentration were linear, indicating that the majority of SH3 domain was unbound. Further, a Kd for NITYRGT binding to SH3, estimated from these experiments, was between 175–350 mM. Next, we obtained HSQC spectra for SH3 in the presence of either RPLPPLP or a negative control peptide NITYEGK. Major perturbations due to RPLPPLP occurred in three regions: residues 98–103 (RT-loop), 116–122 (n-Src loop and specificity pocket), and residues 134–138; residues in the aromatic cluster were unaffected by the ligand. By contrast, only a handful of residues showed small perturbations in the presence of NITYEGK and there was no overlap between the affected residues and those affected by RPLPPLP. In conclusion, our results indicate that compared to polyproline sequences, the C-terminus of the β3 cytoplasmic tail binds to the c-Src SH3 domain in the region of the SH3 specificity pocket. Because chemical shifts for acidic residues located in the RT-loop were particularly sensitive to the presence of NITYRGT, it is likely that Arg759 in β3 makes an important contribution to the interaction. Moreover, we found that the interaction between NITYRGT and the c-Src SH3 domain is substantially weaker than was previously reported for the interaction of β3 with c-Src. This suggest the possibility that a third component is required for this interaction to occur under biological conditions. Recently we found that the β3 cytoplasmic tail in solution has weak affinity for the talin-1 FERM domain, but appending the tail to acidic phospholipids increased its affinity by three orders of magnitude. Since the c-Src SH3 domain contains a conserved patch of basic residues that are necessary for binding to acidic phospholipids, it is possible that the interaction of c-Src with β3 is also a ternary interaction in which protein-lipid interactions play an important role. Disclosures: No relevant conflicts of interest to declare.

Characterization of a Disulfide-Crosslinked αIIbβ3 Cytoplasmic Domain Heterodimer by NMR.

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 415-415
Author(s):  
Douglas G. Metcalf ◽  
Joseph M. Kielec ◽  
Kathleen G. Valentine ◽  
A. Joshua ◽  
William F. DeGrado ◽  
...  
Keyword(s):  
Nmr Spectroscopy ◽  
Chemical Shift ◽  
Disulfide Bond ◽  
Structural Information ◽  
Chemical Shifts ◽  
Cytoplasmic Tail ◽  
Salt Bridge ◽  
Active Conformation ◽  
Peptide Backbone ◽  
Arginine Residues

Abstract The platelet integrin αIIbβ3 is the prototypic example of regulated integrin function. Thus, αIIbβ3 is inactive on unstimulated platelets, but switches to an active conformation following platelet stimulation. Recent experiments suggest that disruption of the heteromeric association of the αIIb and β3 transmembrane (TM) and/or cytoplasmic domains shifts αIIbβ3 from an inactive to an active conformation. However, structural information about these heteromeric associations is sparse. Thus far, the structure of the TM heterodimer has only been studied by molecular modeling. Although interactions between soluble cytosolic tail peptides have been studied by NMR spectroscopy, these studies may not reflect native contacts because they fail to account for constraining TM domain interactions. To obtain an NMR structure for the αIIbβ3 cytosolic tail heterodimer that reflects its native structure, we expressed 13C- and 15N-labeled peptides corresponding to αIIb residues 988-1008 and β3 residues 713-762 in E. coli. Residues 987 in αIIb and 712 in β3 were replaced with cysteines, based on modeling that predicted that a disulfide bond between these residues will fix the peptides in their native orientation. The peptides were disulfide-crosslinked using 2,2′-dithiobis(5-nitropyridine) chemistry, dissolved in dodecylphosphocholine micelles at pH 6.5, and NMR data were collected at 37 °C on a 750 MHz spectrometer. Currently, >98% of the complex’s peptide backbone and >90% of its side chains have been assigned. When compared to published chemical shift data for the monomeric β3 cytoplasmic tail, there were no differences for residues 725–741 and 747–762. However, there were chemical shift differences between the αIIb/β3 heterodimer and the β3 monomer for the membrane-embedded region of the β3 peptide, residues 713–724, suggesting that this region interacts with αIIb. Similarly, chemical shifts for the monomer and heterodimer were different for β3 residues 742–746. This region of β3 contains an NPXY motif and is a site at which the β3 cytoplasmic tail interacts with signaling and structural proteins. This result implies that the shift from heterodimer to monomer causes a structural change in this region, perhaps enabling it to interact with other proteins. Finally, we observed arginine side chain protons on the αIIb subunit. Arginine protons are usually not observable by NMR and their detection may reflect the existence of a salt bridge involving arginine. The αIIb cytoplasmic tail contains two arginine residues, one of which, Arg995, is predicted to form a salt bridge with β3 Asp723. Although the detected arginine protons could belong to Arg995 and/or Arg997, they displayed an NOE with the β3 Asp723 amide, a finding consistent with the predicted αIIb Arg995-β3 Asp723 salt bridge. In conclusion, we have characterized the structure of a disulfide-crosslinked αIIb/β3 cytoplasmic tail heterodimer using NMR spectroscopy and compared our results to prior work on the β3 cytoplasmic tail monomer. Our analysis indicates that when constrained by a proximal disulfide bond, the αIIb and β3 cytoplasmic tails interact, providing one mechanism for maintaining αIIbβ3 in an inactive state.

scholarly journals Structure of Nanobody Nb23

Molecules ◽  
2021 ◽  
Vol 26 (12) ◽  
pp. 3567
Author(s):  
Mathias Percipalle ◽  
Yamanappa Hunashal ◽  
Jan Steyaert ◽  
Federico Fogolari ◽  
Gennaro Esposito
Keyword(s):  
Nmr Spectroscopy ◽  
Chemical Shift ◽  
Solution Structure ◽  
Chemical Shifts ◽  
Molecular Size ◽  
Side Chain ◽  
3D Nmr ◽  
Target Antigen ◽  
Internuclear Distances ◽  
2D And 3D

Background: Nanobodies, or VHHs, are derived from heavy chain-only antibodies (hcAbs) found in camelids. They overcome some of the inherent limitations of monoclonal antibodies (mAbs) and derivatives thereof, due to their smaller molecular size and higher stability, and thus present an alternative to mAbs for therapeutic use. Two nanobodies, Nb23 and Nb24, have been shown to similarly inhibit the self-aggregation of very amyloidogenic variants of β2-microglobulin. Here, the structure of Nb23 was modeled with the Chemical-Shift (CS)-Rosetta server using chemical shift assignments from nuclear magnetic resonance (NMR) spectroscopy experiments, and used as prior knowledge in PONDEROSA restrained modeling based on experimentally assessed internuclear distances. Further validation was comparatively obtained with the results of molecular dynamics trajectories calculated from the resulting best energy-minimized Nb23 conformers. Methods: 2D and 3D NMR spectroscopy experiments were carried out to determine the assignment of the backbone and side chain hydrogen, nitrogen and carbon resonances to extract chemical shifts and interproton separations for restrained modeling. Results: The solution structure of isolated Nb23 nanobody was determined. Conclusions: The structural analysis indicated that isolated Nb23 has a dynamic CDR3 loop distributed over different orientations with respect to Nb24, which could determine differences in target antigen affinity or complex lability.

Circular dichroism spectra of tetraamminecobalt(III) complexes of amino alcohols

1978 ◽  
Vol 31 (11) ◽  
pp. 2399 ◽  
Author(s):  
CJ Hawkins ◽  
GA Lawrance ◽  
JA Palmer
Keyword(s):  
Circular Dichroism ◽  
Chemical Shift ◽  
Chemical Shifts ◽  
Amino Alcohols ◽  
Circular Dichroism Spectra ◽  
Chemical Shift Difference ◽  
Solvent Dependence ◽  
Cotton Effects ◽  
Circular Dichroïsm ◽  
Chiral Amino Alcohols

The circular dichroism spectra are reported for tetraamminecobalt(III) complexes with the chiral amino alcohols 2-aminopropan-1-ol, 2- aminobutan-1-ol, 1-aminopropan-2-ol, 2-amino-1-phenyl-ethanol, ψ- ephedrine and ephedrine with the alcohol groups protonated (OH) and deprotonated (O-). The solvent dependence of the chemical shifts of the NH protons was investigated to determine the effects of stereoselective solvation on the circular dichroism, but, in contrast to some other related systems, the chemical shift difference between the two NH2 protons was relatively insensitive to solvent. Consistent with this, the circular dichroism spectra of the tetraphenylborate salts of the deprotonated complexes were found not to be markedly dependent on solvent. Tetraammine-{(-)-ψ-ephedrine)cobalt(III) and tetraammine{(-)- ephedrine}cobalt(III) were found to have the same signs of Cotton effects for the various d-d transitions, whereas bis{(-)-ψ- ephedrine}copper(II) and bis{(-)-ephedrine}copper(II) had opposite signs. This has been explained in terms of different conformer populations in the cobalt(III) and copper(II) systems.

NMR studies of tandem WW domains of Nedd4 in complex with a PY motif-containing region of the epithelial sodium channel

1998 ◽  
Vol 76 (2-3) ◽  
pp. 341-350 ◽  
Author(s):  
Voula Kanelis ◽  
Neil A Farrow ◽  
Lewis E Kay ◽  
Daniela Rotin ◽  
Julie D Forman-Kay
Keyword(s):  
Chemical Shift ◽  
Sodium Channel ◽  
Chemical Shifts ◽  
Epithelial Sodium Channel ◽  
Chemical Shift Assignment ◽  
Nmr Studies ◽  
Ww Domains ◽  
Ww Ii ◽  
Py Motif ◽  
Shift Assignment

Nedd4 (neuronal precursor cell-expressed developmentally down-regulated 4) is a ubiquitin-protein ligase containing multiple WW domains. We have previously demonstrated the association between the WW domains of Nedd4 and PPxY (PY) motifs of the epithelial sodium channel (ENaC). In this paper, we report the assignment of backbone 1Hα, 1HN, 15N, 13C', 13Cα, and aliphatic 13C resonances of a fragment of rat Nedd4 (rNedd4) containing the two C-terminal WW domains, WW(II+III), complexed to a PY motif-containing peptide derived from the β subunit of rat ENaC, the βP2 peptide. The secondary structures of these two WW domains, determined from chemical shifts of 13Cα and 13Cβ resonances, are virtually identical to those of the WW domains of the Yes-associated protein YAP65 and the peptidyl-prolyl isomerase Pin1. Triple resonance experiments that detect the 1Hα chemical shift were necessary to complete the chemical shift assignment, owing to the large number of proline residues in this fragment of rNedd4. A new experiment, which correlates sequential residues via their 15N nuclei and also detects 1Hα chemical shifts, is introduced and its utility for the chemical shift assignment of sequential proline residues is discussed. Data collected on the WW(II+III)-βP2 complex indicate that these WW domains have different affinities for the βP2 peptide.Key words: WW domain, PY motif, Nedd4, ENaC, NMR.

scholarly journals Identification of SH3 Domain Proteins Interacting with the Cytoplasmic Tail of the A Disintegrin and Metalloprotease 10 (ADAM10)

PLoS ONE ◽  
2014 ◽  
Vol 9 (7) ◽  
pp. e102899 ◽  
Author(s):  
Henriette Ebsen ◽  
Marcus Lettau ◽  
Dieter Kabelitz ◽  
Ottmar Janssen
Keyword(s):  
Cytoplasmic Tail ◽  
Sh3 Domain

Determination of chemical shifts in 6-condensed syringylic lignin model compounds

Holzforschung ◽  
2021 ◽  
Vol 0 (0) ◽  
Author(s):  
Lucas Lagerquist ◽  
Jani Rahkila ◽  
Patrik Eklund
Keyword(s):  
Chemical Shift ◽  
Methoxy Group ◽  
Chemical Shifts ◽  
Model Compounds ◽  
Correlation Peak ◽  
Lignin Model Compounds ◽  
Benzylic Alcohols ◽  
Lignin Model ◽  
C Nmr

Abstract A small library of 6-substituted syringyl model compounds with aliphatic, carboxylic, phenylic, benzylic alcohols and brominated substituents were prepared. The influence of the substituents on the chemical shifts of the compounds was analyzed. All of model compounds showed a characteristic increase in the 13C NMR chemical shift of the methoxy group vicinal to the substitution. This 13C NMR peak and its corresponding correlation peak in HSQC could potentially be used to identify 6-condensation in syringylic lignin samples.

scholarly journals XPS Investigations on Solid and Vacuum Deposited, Oxidized and Non-oxidized Palladium

1995 ◽  
Vol 50 (4-5) ◽  
pp. 381-387 ◽  
Author(s):  
Jürgen Kintrup ◽  
Harald Züchner
Keyword(s):  
Chemical Shift ◽  
Curve Fitting ◽  
Photoelectron Spectroscopy ◽  
Chemical Shifts ◽  
Atmospheric Oxygen ◽  
Hydrogen Permeability ◽  
Photoelectric Effect ◽  
High Accuracy ◽  
X Ray ◽  
Charging Effect

Abstract X-ray photoelectron spectroscopy (XPS) has been carried out to study the reaction of differently prepared palladium samples (solid and film Pd) with atmospheric oxygen. A careful curve fitting of the measured Pd-3d5/2 peak allows to separate the Pd-3d5/2 peak for Pd in surface PdO from the dominant Pd-3d5/2 peak of the non-oxidized bulk palladium and to determine the chemical shift of the "oxidized" Pa line with high accuracy. Differences in the chemical shifts for the surface PdO on solid and film palladium are explained by a different charging caused by the photoelectric effect in XPS measurements. The smaller charging effect observed for film palladium as compared to solid palladium indicates a stronger oxygen bonding to the (rougher) film palladium. The strong Pd-O bonding seems to be an essential reason for the reduced hydrogen-permeability of film palladium compared to solid palladium

Are the amide bonds in N-acyl imidazoles twisted? A combined solid-state 17O NMR, crystallographic, and computational study

2015 ◽  
Vol 93 (4) ◽  
pp. 451-458 ◽  
Author(s):  
Xianqi Kong ◽  
Aaron Tang ◽  
Ruiyao Wang ◽  
Eric Ye ◽  
Victor Terskikh ◽  
...  
Keyword(s):  
Solid State ◽  
Chemical Shift ◽  
Crystal Structures ◽  
Computational Study ◽  
Chemical Shifts ◽  
Amide Bond ◽  
Chemical Shift Tensors ◽  
Amide Bonds ◽  
Bond Rotation ◽  
Quadrupole Coupling

We report synthesis of 17O-labeling and solid-state 17O NMR measurements of three N-acyl imidazoles of the type R-C(17O)-Im: R = p-methoxycinnamoyl (MCA-Im), R = 4-(dimethylamino)benzoyl (DAB-Im), and R = 2,4,6-trimethylbenzoyl (TMB-Im). Solid-state 17O NMR experiments allowed us to determine for the first time the 17O quadrupole coupling and chemical shift tensors in this class of organic compounds. We also determined the crystal structures of these compounds using single-crystal X-ray diffraction. The crystal structures show that, while the C(O)–N amide bond in DAB-Im exhibits a small twist, those in MCA-Im and TMB-Im are essentially planar. We found that, in these N-acyl imidazoles, the 17O quadrupole coupling and chemical shift tensors depend critically on the torsion angle between the conjugated acyl group and the C(O)–N amide plane. The computational results from a plane-wave DFT approach, which takes into consideration the entire crystal lattice, are in excellent agreement with the experimental solid-state 17O NMR results. Quantum chemical computations also show that the dependence of 17O NMR parameters on the Ar–C(O) bond rotation is very similar to that previously observed for the C(O)–N bond rotation in twisted amides. We conclude that one should be cautious in linking the observed NMR chemical shifts only to the twist of the C(O)–N amide bond.

scholarly journals Following excited-state chemical shifts in molecular ultrafast x-ray photoelectron spectroscopy

2022 ◽  
Vol 13 (1) ◽  
Author(s):  
D. Mayer ◽  
F. Lever ◽  
D. Picconi ◽  
J. Metje ◽  
S. Alisauskas ◽  
...  
Keyword(s):  
Excited State ◽  
Chemical Shift ◽  
Photoelectron Spectroscopy ◽  
Chemical Shifts ◽  
Excited Molecule ◽  
Charge Motion ◽  
Core Electron ◽  
Xps Spectra ◽  
X Ray ◽  
State Chemical

AbstractThe conversion of photon energy into other energetic forms in molecules is accompanied by charge moving on ultrafast timescales. We directly observe the charge motion at a specific site in an electronically excited molecule using time-resolved x-ray photoelectron spectroscopy (TR-XPS). We extend the concept of static chemical shift from conventional XPS by the excited-state chemical shift (ESCS), which is connected to the charge in the framework of a potential model. This allows us to invert TR-XPS spectra to the dynamic charge at a specific atom. We demonstrate the power of TR-XPS by using sulphur 2p-core-electron-emission probing to study the UV-excited dynamics of 2-thiouracil. The method allows us to discover that a major part of the population relaxes to the molecular ground state within 220–250 fs. In addition, a 250-fs oscillation, visible in the kinetic energy of the TR-XPS, reveals a coherent exchange of population among electronic states.

scholarly journals Protein structure refinement using a quantum mechanics-based chemical shielding predictor

2016 ◽  
Author(s):  
Lars A. Bratholm ◽  
Jan H. Jensen
Keyword(s):  
Quantum Mechanics ◽  
Simulated Annealing ◽  
Chemical Shift ◽  
Force Field ◽  
Chemical Shifts ◽  
Protein Structures ◽  
Empirical Methods ◽  
Structural Refinement ◽  
Chemical Shielding ◽  
Chemical Shift Prediction

The accurate prediction of protein chemical shifts using quantum mechanics (QM)-based method has been the subject of intense research for more than 20 years but so far empirical methods for chemical shift prediction have proven more accurate. In this paper we show that a QM-based predictor of protein backbone and CB chemical shifts (ProCS15, PeerJ 2016, 3:e1344) is of comparable accuracy to empirical chemical shift predictors after chemical shift-based structural refinement that removes small structural errors. We present a method by which quantum chemistry based predictions of isotropic chemical shielding values (ProCS15) can be used to refine protein structures using Markov Chain Monte Carlo (MCMC) simulations, relating the chemical shielding values to the experimental chemical shifts probabilistically. Two kinds of MCMC structural refinement simulations were performed using force field geometry optimized X-ray structures as starting points: Simulated annealing of the starting structure and constant temperature MCMC simulation followed by simulated annealing of a representative ensemble structure. Annealing of the CHARMM structure changes the CA-RMSD by an average of 0.4 Å but lowers the chemical shift RMSD by 1.0 and 0.7 ppm for CA and N. Conformational averaging has a relatively small effect (0.1 - 0.2 ppm) on the overall agreement with carbon chemical shifts but lowers the error for nitrogen chemical shifts by 0.4 ppm. If a residue-specific offset is included the ProCS15 predicted chemical shifts have RMSD values relative to experiment that are comparable to popular empirical chemical shift predictors. The annealed representative ensemble structures differs in CA-RMSD relative to the initial structures by an average of 2.0 Å, with >2.0 Å difference for six proteins. In four of the cases, the largest structural differences arise in structurally flexible regions of the protein as determined by NMR, and in the remaining two cases, the large structural change may be due to force field deficiencies. The overall accuracy of the empirical methods are slightly improved by annealing the CHARMM structure with ProCS15, which may suggest that the minor structural changes introduced by ProCS15-based annealing improves the accuracy of the protein structures. Having established that QM-based chemical shift prediction can deliver the same accuracy as empirical shift predictors we hope this can help increase the accuracy of related approaches such as QM/MM or linear scaling approaches or interpreting protein structural dynamics from QM-derived chemical shift.

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