Proteins Have Too Many Signals! ~500 resonances 1H NMR Spectrum of Ubiquitin
Regions of the 1H NMR Spectrum
Resolve Peaks By Multi-D NMR A BONUSregions in 2D spectra provide protein fingerprints If 2D cross peaks overlap go to 3D
Challenges For Determining Protein Structures Using NMR Proteins have thousands of signals Assign the specific signal for each atom Thousands of interactions between atoms- also need to be assigned Need to transform representation from spectrum through interactions between atoms to spatial coordinates
Solutions to the Challenges Increase dimensionality of spectra to better resolve signals: 123 4 Detect signals from heteronuclei (13C,15N) Better resolve signals- different overlaps More information to identify signals
The Strategy to Assign All of the Resonances in a Protein Identify resonances for each amino acid Put amino acids in order - Sequential assignment (R-G-S,T-L-G-S) - Sequence-specific assignment 1 2 3 4 5 6 7 R - G - S - T - L - G - S
Homonuclear Assignment Strategy 1H strategy: based on backbone NH (unique region of spectrum, greatest dispersion of resonances, least overlap) Scalar coupling to identify resonances, dipolar couplings to place in sequence Concept: build out from the backbone to determine the side chain resonances 2nd dimension resolves overlaps, 3D rare 1H 1H 1H
Step 1: Identify Spin System
Step 2: Fit Residues In Sequence Minor Flaw: All NOEs Mixed Together Use only these to make sequential assignments Tertiary Structure Sequential Intraresidue A B C D Z • • • • Medium-range (helices)
Double-Resonance Experiments Increases Resolution/Information Content 15N-1H HSQC R R -15N - Ca- CO -15N - Ca H H
Extended Homonuclear 1H Strategy Same basic idea as 1H strategy- based on backbone NH Concept: when backbone 1H overlaps disperse with backbone 15N 3rd dimension increases signal resolution 1H 1H 15N
3 overlapped NH resonances 15N Dispersed 1H-1H TOCSY 3 overlapped NH resonances Same NH, different 15N F1 F2 F3 1H 1H 15N t1 t2 t3 TOCSY HSQC
1H-1H TOCSY
Heteronuclear (1H,13C,15N) Strategy Strategy based on backbone 15N1H (13CO) Concept: when backbone 15N1H overlaps disperse with backbone C’CaHaCbHb… 3rd/4th dimension increase signal resolution 1H 13C 15N 1H 3D/4D double/triple resonance NMR
Heteronuclear Assignments: Backbone Experiments Names of scalar experiments based on atoms detected
Heteronuclear Assignments: Side Chain Experiments
http://students.washington.edu/~baracuda/bioc530/nmr3.html
Figure 20: Example of triple resonance spectra, the HNCO/HN(CA)CO combination of ubiquitin Figure 21: Sequential connections using HNCACB & HN(CO)CACB on ubiquitin
Key Points about Heteronuclear (1H,13C,15N) Strategy Most efficient, but expts. more complex Enables study of large proteins (TROSY) Bonus: sequential assignments Requires 15N, 13C, [2H] enrichment High expression in minimal media (E. coli) Extra $$ (~$200/g 13C6-glucose)
Practical Issues: Hardware Magnet: homogeneous, high field Electronics: stable, tunable Environment: temperature, pressure, humidity Environmental: stray fields Visit to the Biomolecular NMR Center? Today at 3 PM/ SB party at 4!
Practical Issues: Sample Preparation 1D 50 μM Concentration: Cryoprobe! nD 400 μM Volume: 200 μl, 500 μl, 2 mls Quantity: @ 20kDa 1 mM = 10 mgs Purity > 95%, buffers Sensitivity () isotope enrichment (15N, 13C)
Practical Issues: Solution Conditions Variables: buffer, ionic strength, pH, T Binding studies: co-factors, ligands H20/D20 exchange- requires unfolding NO CRYSTALS!
Practical Issues: Molecular Weight 30-40 kD for 3D structure Domains >100 kD: uniform deuteration, residue- and site-specific, atom-specific labeling Symmetry reduces complexity 2 x 10 kD ≠ 20 kD TROSY- an experimental approach to higher sensitivity for large systems
Large Scalar Couplings Less Sensitive to MW of the Protein Superior to 1H homonuclear strategy: H-H couplings <20 Hz Mixing is faster so less time for signal to relax