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Biomolecular Nuclear Magnetic Resonance Spectroscopy

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Presentation on theme: "Biomolecular Nuclear Magnetic Resonance Spectroscopy"— Presentation transcript:

1 Biomolecular Nuclear Magnetic Resonance Spectroscopy
01/21/04 Biomolecular Nuclear Magnetic Resonance Spectroscopy BASIC CONCEPTS OF NMR How does NMR work? Pulse FT NMR Resonance assignment NMR text: Chapter 22 in Protein and Peptide Drug Analysis “Solution Structure Determination of Proteins by NMR”

2 NMR in Medicine and Biology
MRI- Magnetic Resonance Imaging (water) In-vivo spectroscopy (metabolites) Solid-state NMR (large structures) Solution NMR Bioanalytical, primary structure Three-dimensional structure Molecular motions Molecular interactions- binding, reactions Ligand screening (Pharma)

3 Biomolecular NMR: primarily spin 1/2 nuclei (1H, 13C, 15N, 31P)
Nuclear Spin Nuclear spin angular momentum is a quantized property of the nucleus in each atom, which arises from the sub-atomic properties of neutrons and protons The nuclear spin angular momentum of each atom is represented by a nuclear spin quantum number (I) All nuclei with odd mass numbers have I=1/2,3/2... Nuclei with even mass numbers and an even number of protons have I=0 Nuclei with even mass numbers and an odd number of protons have I=1,2,3… Biomolecular NMR: primarily spin 1/2 nuclei (1H, 13C, 15N, 31P)

4 Nuclei With Non-Zero Spin Align in Magnetic Fields
DE = h g Ho Efficiency factor- nucleus Constants Strength of magnet Ho Alignment Energy parallel anti-parallel

5 NMR: The Bar Magnet Analogy
p p p ap ap ap + - + - + - + - - + - + + - Ho = - + - + - + - + - + - + + - + - + - 1. force non-alignment 2. release

6 Resonance: Perturb Equilibrium
ap 1. equilibrium DE DE = h g Ho Efficiency factor- nucleus Constants Strength of magnet Ho hn = DE H1 2. pump in energy p ap 3. non-equilibrium

7 Return to Equilibrium (Relax): Read Out Signals
p ap DE 3. Non-equilibrium hn = DE 4. release energy (detect) p ap 5. equilibrium

8 Magnetic Resonance Sensitivity
Np Nap = e -DE/kT Sensitivity (S) ~ D(population) S ~ DN = DE = h g Ho Efficiency factor- nucleus Constants Strength of magnet DE is small At room temp., DN ~ 1:105 Intrinsically low sensitivity Need lots of sample Increase sensitivity by increasing magnetic field strength

9 Intrinsic Sensitivity of Nuclei
Nucleus g % Natural Relative Abundance Sensitivity 1H 2.7 x 13C 6.7 x 15N x 31P 1.1 x

10 The Classical Treatment: Nuclear Spin Angular Momentum
Two spins All spins  Sum Bulk Magnetization excess facing down Ho parallel anti-parallel Torque + int. motion = precession Precession around Z axis Larmor frequency (): DE = hgHo  DE = hn  n = H0 = 

11 Pulse Fourier Transform NMR
90ºx RF pulse =  =  H0 Ho Ho A t Fourier Transform f NMR frequency Variation of signal at X axis vs. time

12 The Power of Fourier Transform
90ºx RF pulse + 1 =  H0 2 =  H0 A t Fourier Transform f 2 1 NMR frequency domain Spectrum of frequencies NMR time domain Variation in amplitude vs time

13 The Pulse FT NMR Experiment
equilibration 90º pulse detection of signals Experiment (t) Data Analysis Fourier Transform Time domain (t)

14 NMR Terminology Chemical Shift & Linewidth
The exact resonance frequency (chemical shift) is determined by the electronic environment of the nucleus

15 NMR Scalar and Dipolar Coupling
Through Space Through Bonds Coupling of nuclei gives information on structure

16 Resonance Assignment The key attribute: use the scalar and dipolar couplings to match the set of signals with the molecular structure CH3-CH2-OH OH CH2 CH3 Which signal from which H atoms?

17 Proteins Have Too Many Signals! 1H NMR Spectrum of Ubiquitin
~500 resonances Resolve resonances by multi-dimensional experiments


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