Nuclear overhauser spectroscopy of chiral CHD methylene groups

Nuclear magnetic resonance spectroscopy (NMR) can provide a great deal of information about structure and dynamics of biomolecules. The quality of an NMR structure strongly depends on the number of experimental observables and on their accurate conversion into geometric restraints. When distance restraints are derived from nuclear Overhauser effect spectroscopy (NOESY), stereo-specific assignments of prochiral atoms can contribute significantly to the accuracy of NMR structures of proteins and nucleic acids. Here we introduce a series of NOESY-based pulse sequences that can assist in the assignment of chiral CHD methylene protons in random fractionally deuterated proteins. Partial deuteration suppresses spin-diffusion between the two protons of CH2 groups that normally impedes the distinction of cross-relaxation networks for these two protons in NOESY spectra. Three and four-dimensional spectra allow one to distinguish cross-relaxation pathways involving either of the two methylene protons so that one can obtain stereospecific assignments. In addition, the analysis provides a large number of stereospecific distance restraints. Non-uniform sampling was used to ensure optimal signal resolution in 4D spectra and reduce ambiguities of the assignments. Automatic assignment procedures were modified for efficient and accurate stereospecific assignments during automated structure calculations based on 3D spectra. The protocol was applied to calcium-loaded calbindin D-9k. A large number of stereospecific assignments lead to a significant improvement of the accuracy of the structure.

Study of fast exchanging processes by NMR Spectroscopy

Estel Canet Martinez

Nuclear magnetic resonance (NMR) spectroscopy is one of the most powerful and informative methods to probe molecular dynamics. Specifically, chemical exchange is an important phenomenon and one of the earliest and most vigorously investigated in NMR spectroscopy. Its effects can be observed in many NMR spectra; lines in a spectrum are broadened or averaged because the nuclei are exchanging magnetic environments. A wide variety of experimental methods exists to determine exchange rates of protons that hop between amino acids and water in the slow or intermediate exchange regime. However, so far there is a lack of methods to investigate hydrogen exchange in the fast exchange regime. In this thesis, we focus on the determination of very fast chemical exchange rates from the effects of scalar relaxation on a coupled nucleus. We quantify the effects of scalar relaxation caused by exchanging hydrogens, by detecting the decay of a 15N coherence under a multiple-refocusing Carr-Purcell-Meiboom-Gill (CPMG) pulse train in the presence or absence of hydrogen decoupling. In particular, we have adapted to the case of deuterium a method that was originally designed to study the exchange rate of the indole proton of tryptophan in water as a function of pH and temperature. We will present the exchange rates of the indole deuterium in tryptophan with solvent heavy water. After that, the proton exchanges rates have been compared with the deuterium exchange rates in order to describe the kinetic isotope effect. In a similar manner, we have quantified the proton exchange rates in pure water by using multiple refocusing of transverse 17O magnetization as a function of pH and temperature. Such measurements are widely used to obtain valuable information about molecular dynamics and structure of proteins, protein complexes and nucleic acids. The knowledge of the kinetic isotope effect may contribute to the characterization of reaction mechanisms and other dynamic parameters that can give insight into the stability of hydrogen bonded secondary structures in biomolecules. This information could form a foundation for a more thorough theoretical or modeling development of a number of long and outstanding fundamental questions. In the second part of the thesis, we combine fast exchange with dissolution dynamic nuclear polarization (D-DNP) to study intrinsically disordered proteins (IDPs). IDPs constitute a very large and functionally important class of proteins that lack stable secondary and tertiary structures. As a consequence of the broad dynamics and flexibility of IDPs, and specially under physiological conditions, the NMR spectra of IDPs typically show a strong signal overlap and broadening due to proton exchange. We present a method to overcome these limitations by means of hyperpolarized HDO produced by D-DNP. We could study the effects of conformational adaptations in Osteopontin (OPN), a metastasis- associated intrinsically disordered protein (IDP) by chemical exchange. The magnetization from hyperpolarized water is transferred to the rapidly exchanging protons of the solvent-exposed residues of the protein. The exchange with hyperpolarized water boosts the signals of fast exchanging residues above the detection limits. This allows one to follow individual resonances and draw conclusions regarding conformational adaptations due to ligand binding under physiological conditions. Thus, with our approach, exchange with the solvent is turned into an advantage

EPFL2017

Hydrogen bonds of nucleic acids and local motions of proteins studied by nuclear spin relaxation

In my thesis I shall focus on the development of new NMR experimental methods to study structure and internal motions of two kinds of biological polymers, viz. proteins and nucleic acids. I shall investigate the anisotropic local motions of peptide planes and locate amide protons in proteins by measuring three dipole-dipole cross-correlated relaxation rate constants of single-quantum coherences involving the peptide backbone nuclei. I shall also estimate the internucleotide hydrogen bond lengths in nucleic acids from the measurement of the longitudinal auto-relaxation rate constants of both donor and acceptor nitrogen-15 nuclei of Watson-Crick base pairs. Finally I shall measure and discuss the temperature dependence of internucleotide nitrogen-nitrogen scalar couplings in nucleic acids.

EPFL2004

Proton and phosphorus magnetic resonance spectroscopy of a mouse model of Alzheimer's disease

Patrick Aebischer, Cristina Ramona Cudalbu, Rolf Gruetter, Sharon Janssens, Hongxia Lei, Bernard Schneider, Lili Sun-Reimer

The development of new diagnostic criteria for Alzheimer's disease (AD) requires new in vivo markers reflecting early pathological changes in the brain of patients. Magnetic resonance (MR) spectroscopy has been shown to provide useful information about the biochemical changes occurring in AD brain in vivo. The development of numerous transgenic mouse models of AD has facilitated the evaluation of early biomarkers, allowing researchers to perform longitudinal studies starting before the onset of the pathology. In addition, the recent development of high-field animal scanners enables the measurement of brain metabolites that cannot be reliably quantified at lower magnetic fields. In this report, we studied a new transgenic mouse model of AD, the 5xFAD model, by in vivo proton and phosphorus MR spectroscopy. This model, which is characterized by an early-onset and a robust amyloid pathology, developed changes in the neurochemical profile, which are typical in the human disease, i.e., an increase in myo-inositol and a decrease in N-acetylaspartate concentrations, as early as in the 40th week of age. In addition, a significant decrease in the γ-aminobutyrate concentration was observed in transgenic mice at this age compared to controls. The pseudo-first-order rate constant of the creatine kinase reaction as well as relative concentrations of phosphorus-containing metabolites were not changed significantly in the 36 and 72-week old transgenic mice. Overall, these results suggest that mitochondrial activity in the 5 × FAD mice is not substantially affected but that the model is relevant for studying early biomarkers of AD.

Ios Press2012

Study of fast exchanging processes by NMR Spectroscopy

Estel Canet Martinez

EPFL2017