Download - Biochemistry 530 NMR Theory and Practice
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Biochemistry 530 NMR Theory and Practice
Gabriele Varani Department of Biochemistry and
Department of Chemistry University of Washington
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1D spectra contain structural information .. but is hard to extract: need multidimensional NMR
1D spectrum
Dispersed amides: protein is folded
Hα: protein contains β-sheet
Downfield CH3: Protein is folded
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1D vs 2D homonuclear NMR Spectroscopy
Basic structure of 1D experiment
Basic structure of 2D experiment (e.g. NOESY)
Jeener and Ernst, 1972
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2D homonuclear NMR Spectroscopy
Basic structure
Two basic experiments: NOESY and COSY
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How to generate a 2D experiment: NOESY
1. Record numerous 1D experiments by systematically incrementing time t1 from 0 to tmax; the experiment generates a matrix of points S(t1,t2) which encodes the frequency information with respect to both t1 and t2
Typical number of repetitions (t1 increments) for homonuclear NMR: 256-512
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How to process the data to obtain a 2D spectrum
2. Execute the FT for each experiment (each t1 value) with respect to time t2 to generate an interferogram S(t1, ω2) 3. Execute the FT with respect to t1 (for each ω2 value) to generate the final 2D spectrum S(ω1,ω2)
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1D vs 2D NMR spectra of a protein
1D spectrum
amides Hα Side chain CH2
Side chain CH3
NH2
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1D vs 2D NMR spectra of a protein
2D projection representation
2D contour representation
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“cross-peaks” in multidimensional NMR carry structural information
2D contour representation: peaks outside diagonal are called cross-peaks
Diagonal is closely related to 1D spectrum
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Nuclear Overhauser Effect SpectroscopY (NOESY)
The NOESY experiments detects interactions between spins that are close in space and dipolar coupled: the magnetization transfer mechanism is essentially the same as FRET in optical spectroscopy (fluorescence)
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1. Excite with 90o pulse
2. During t1, spins are labeled with their Larmor frequency
3. The second 90o pulse exchanges rotates magnetization to -z
5. The final 90o pulse makes the signal observable and signal is acquired in t2
Nuclear Overhause Effect SpectroscopY (NOESY)
4. Magnetization is exchanged between spin I and S during the mixing time
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Cross-peaks appear between spins which are close in space (<5-6 A) (assignments and structure)
When magnetization is exchanged, spin I signal contains information on spin S and viceversa (cross-peaks)
Nuclear Overhause Effect SpectroscopY (NOESY)
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The mixing coefficients, αIS = αSI are proportional to the NOE between these two nuclei
The NOE is related to the distance r between the two spins and the correlation time τc (the time for reorientation of the IS vector in the molecule): structure and motion
Nuclear Overhause Effect SpectroscopY (NOESY)
NOE ∝ r IS-6f (τc) τm
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A simple example: a small immunogenic peptide
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A simple example: a small immunogenic peptide
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COSY and NOESY connectivities in the polypeptide unit
COSY (broken lines) and NOESY (continuous lines)
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Protein chemical structure dictates ‘local’ NOE interactions
Sequential and medium range interactions in polypeptides
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Protein secondary structure determines local NOE interactions
Sequential and medium range NOE interactions in regular turns
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Protein 3D structure determines local NOE interactions
Sequential and medium range NOE interactions in an α-helix
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Protein 3D structure determines NOE interactions
Medium and long range NOE interactions in a parallel and anti-parallel β-sheets
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Patterns of NOE interactions define protein secondary structure
Observable NOE interactions (<5 A) in regular protein secondary structures
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NOE interactions, scalar couplings (and chemical shifts) can be combined to define protein secondary structure
NOE interactions (<4.5 A) and scalar coupling patterns in regular protein secondary structures
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A simple example: a small immunogenic peptide
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A simple example: a small immunogenic peptide
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COherence transfer SpectroscopY (COSY)
Cross-section of cross-peak between HN and Hα proton allows measurement of scalar couplings for residue C57
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COherence transfer SpectroscopY (COSY)
The COSY experiments detects interactions (correlation) between spins that are scalar coupled: beware, it can only be understood through quantum mechanics
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COherence transfer SpectroscopY (COSY)
1. Excite with 90o pulse
2. During t1, spins are labeled with their Larmor frequency
3. During t1, if spins are scalar coupled, the signal encodes this information as well
4. The second 90o pulse exchanges magnetization between spins: spin I now has memory of spin S and viceversa
5. Signal is acquired in t2
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COherence transfer SpectroscopY (COSY)
Cross-peaks appear between spins which are scalar coupled (assignments)
± ±
±
±The cross-peak fine structure contains information on scalar coupling (structure)
When magnetization is exchanged, spin I signal contains information on spin S and viceversa (cross-peaks)
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Structural information: scalar couplings directly gives you the torsion angles that define protein or n.a. structure
(Karplus, 1958)
3JHαN=5.9cos2φ-1.3cosφ +2.2
3Jαβ=9.5cos2χ1-1.6cosχ1+1.8
Cross-peaks in COSY experiments occur only between residues that are scalar coupled; in turns, these couplings can be measured in COSY experiments
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COSY and NOESY connectivities in the polypeptide unit
COSY (broken lines) and NOESY (continuous lines)
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Amino acid chemical structure
Different pattern of scalar couplings
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Amino acid identification from scalar coupling patterns
Different pattern of scalar couplings allows amino acid type identification in correlated spectra (COSY, 2QF-COSY, TOCSY)
This is the first step towards complete spectral assignments of a protein spectrum (at least before heteronuclear NMR)
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Amino acid chemical structure leads to distinct shift for each residue: random coil chemical shift values
Residue NH αH βH Others Gly 8.39 3.97
Ala 8.25 4.35 1.39
Val 8.44 4.18 2.13 γCH3 0.97, 0.94
Ile 8.19 4.23 1.90 γCH2 1.48, 1.19 γCH3 0.95 δCH3 0.89
Leu 8.42 4.38 1.65,1.65 γH 1.64 γCH3 0.94, 0.90
Prob 4.44 2.28,2.02 γCH2 2.03, 2.03 δCH2 3.68, 3.65
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NOE interactions, scalar couplings (and chemical shifts) can be combined to define protein secondary structure
NOE interactions (<4.5 A) and scalar coupling patterns in regular protein secondary structures