nucleic acids nmr spectroscopytesla.ccrc.uga.edu/courses/bionmr2006/lectures/march20.pdfdepartments...
TRANSCRIPT
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Nucleic Acids
NMR SpectroscopyMarkus W. Germann
Departments of Chemistry and BiologyGeorgia State University
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Based in part on Pascale Legault lectures
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Structure Determination:
I) Assignment
II) Local Analysis•glycosidic torsion angle, sugar puckering,backbone conformationbase pairing
III) Global Analysis•sequential, inter strand/cross strand, dipolar coupling
Nucleic Acids have few protons…..•NOE accuracy
> account for spin diffusion•Backbone may be difficult to fully characterize
> especially α and ζ. •Dipolar couplings
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123
45
6
Numbering
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9
78
321
654
Numbering
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N
NN
N
OH
N
N
O
NHH
H3C
N
N
N
N
NHH
NH
H
N
NN
N
OH
O
H
N
NN
N
O
NH
H
CH3
N
NN
N HH
N
NN
N
InosineBase: Hypoxanthine
Xanthosine
NebularineO6 Me Guanosine
2Amino Adenosine
7deaza Adenosine
N
N
N
N
NCH3CH3
N
NN
N NH
H6 Dimethyl aminopurinee 2 Aminopurine 5Me Cytosine
α Adenosine
N
N
N
N
NHH
OH
OHO
Alternate bases and modifications (small selection)
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HETERO BASE PAIRS
NN
O
OH3C N
NN
N
NH
H
HN
N
NN
O N
H
H
H
NN
O
N H
H
H+
Hoogsteen
NN
O
OH3C
N
N
N
N
NHH
H
N
N
N
N
O
NH
H
HN
N
O
N H
H
Watson-Crick
N
N
O
OH3C
N
N
N
N
NHH
HN
N
N
N
O
NH
H
H
N
N
O
N HH
Reverse Watson-Crick
NN H
O
OH3C
NNH
O
O CH3N
N H
O
OCH3
NNH
O
O CH3
HOMO BASE PAIRS
NN
O
NHH
NN
O
N HH
H+
CC+
TT(I) TT(II)
N
N
N
N
N HH
N
N
N
N
NH H
AA(I)
N
N
N
N
O
N
H
H
H
N
N
N
N
O
N
H
H
H
GG(I)
N
N
N
N
N HH
N
N
N
N
NHH
AA(II) GG(II)
N N
N
NO
H
NN
N
NO
H
NH2
NH2
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α
β
δ
γ
ε
ζ
χ
O5’
O3’
ν3ν0
ν1ν2
ν4O4’
nucle
otid
e un
it
α (n-1)O3'-P-O5'-C5'β P-O5'-C5'-C4'γ O5'-C5'-C4'-C3'δ C5'-C4'-C3'-O3'ε C4'-C3'-O3'-Pζ C3'-O3'-P-O5'(n+1)
Glycosidic torsion angle χO4'-C1'-N1-C2 (pyrimidines)O4'-C1'-N9-C4 (purines)
Torsion angles in nucleic acids
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H1' 5-6H2' 2.3-2.9(A,G) 1.7-2.3(T,C)H2'' 2.4-3.1(A,G) 2.1-2.7(T,C)H3' 4.4-5.2H4' 3.8-4.3H5' 3.8-4.3H5'' 3.8-4.3
H1' 5-6H2' 4.4-5.0H3' 4.4-5.2H4' 3.8-4.3H5' 3.8-4.3H5'' 3.8-4.3
C1' 83-89C2' 35-38C3' 70-78C4' 82-86C5' 63-68
C1' 87-94C2' 70-78C3' 70-78C4' 82-86C5' 63-68
RNADNA
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9R-Borano DNA•RNA
5’-d(A T G G T G C T C)(u a c c a c g a g)r-5’
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Adenine GuanineH2 7.5-8 C2 152-156 - - C2 156H8 7.7-8.5 C8 137-142 H8 7.5-8.3 C8 131-138N6H 5-6/7-8 N6 82-84 N1H 12-13.6 N1 146-149- - - N2H 5-6/8-9 N2 72-76
C4 149-151 C4 152-154C5 119-121 C5 117-119C6 157-158 C6 161N1 214-216 N1 146-149N3 220-226 N3 167
N7 224-232 N7 228-238N9 166-172 N9 166-172
Thymidine Uridine CydidineH6 6.9-7.9 C6 137-142 H6 6.9-7.9 C6 137-142 H6 6.9-7.9 C6 136-144Me5 1.0-1.9 Me5 15-20 H5 5.0-6.0 C5 102-107 H5 5.0-6.0 C5 94-99N3H 13-14 N3 156 N3H 13-14 N3 156-162 - - N3 210- - - - - - - N4H 6.7-7/81-8.8 N4 94-98
C2 154 C2 154 C2 159C4 169 C4 169 C4 166-168C5 95-112 C5 102-107 C5 94-99N1 144 N1 142-146 N1 150-156
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No Structure Required!
Often, depending on the question asked, a full structure determination is not required
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DNA Hairpin
Does it form a duplex? Which base pairs are thermo labile? Which base pair is which… assignment? Is the loop structured? Structure
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DNA Hairpin AT GC T
Thermal lability
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DNA Hairpin
1D NOE
9090
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O
N
HN
O
O
CH3
O
O
O
N
NH
O
O
CH3
O
O
C1
C1
α
β
C G C T T A A C G-5’
C G C T A A G C G-5’
C G T T A A G C G-5’
C G C T T A G C G-5’
control 5’-G C G A A T T C G C
5’-G C G A A T C G CC G C T A A G C G-5’
αTαTalphaT
5’-G C G A A T T G CαC
αCalphaC
5’-G C G A T T C G CαAalphaA
5’-G C A A T T C G CαGalphaG
5’-G C G A A T C G CαTalphaT2 αT
αG
αA
C G C T T A A G C G-5’
Do the duplexes form, is there base pairing? Does the unusual base pair form?
New DNA constructs
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BASE PAIRING AND BACKBONE CONFORMATIONBASE PAIRING AND BACKBONE CONFORMATION
imino 1H NMR 31P NMR
T7T6G9/G1
G3
12.513.013.514.0 ppm
G3T6T7
G9/G1
T7T6 G3G9
G1
T7 T6G3G9
G1
G9 G3T6
T7
G1
control
3´-3´5´-5´
�-1.5�-1.0-0.51.0 0.5 0.0 ppm
alpha T
alpha C
alpha A
alpha G
C G C T T A A G C G-5’5’-G C G A A T T C G C
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Local Parallel Stranded Environment is Necessary forLocal Parallel Stranded Environment is Necessary forStable Duplex FormationStable Duplex Formation
15% Native PAGE, 15 mM MgCl2
O
BPB
d-GCGAATTCGCCGCTTAAGCG-d
d-GCG CGC T
A
T
Ad-GCGAATTCGCCGCTTAAGCG-d
d-GCG CGC T
A
T
A
E: alphaT (115 µM)
A: dT11B: d(CCGG)2C: alphaT (0.5 µM)D: control (0.5 µM)
F: control (115 µM)
A
B
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Solvent Suppression
The presence of an intense solvent resonance necessitates an impractical highdynamic range. 110 M vs <1mM (down to 5-10 uM)To overcome this problem several methods are currently applied:
1) Presaturation.2) Observing the FID when the water passes a null condition after a 180
degree pulse.3) Suppression of broad lined based on their T2 behavior.4) Selectively excitation, with and without gradients5a) Use of GRASP to select specific coherences thereby excluding the intense
solvent signal. In this case the solvent signal never reaches the ADC. Thisallows the observation of resonances that are buried under the solvent peak.
5b) Use of GRASP to selectively dephase the solvent resonance(WATERGATE)
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P18
90
PRESAT
Presaturation field strength:20-40 Hz corresponds to a6-12ms 90deg pulse.
Pros: Easy to set upExcellent water suppression
Cons: Resonances under water signal!(T variation)Labile protons not visible(some GC pairs may be)
90180
d1 td
x
y
z
x
y
zSolvent
WEFT
Method relies on different T1 values forwater and solute.
It fails if the relaxation times are similar.Intensity of the solute resonances may vary.For a selective 180 degree pulse on thesolvent these problems are largely avoided.
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d1 td
90x 180y
td
N times
Spin-lock along y.Resonances with short T2 (broadsignals) are suppressed. Notparticularly good for suppressingsolvent signals.
CPMG
d1 td
90x 180y
td
PRESAT with Spin Echo
Presaturation field strength:20-40 Hz corresponds to a6-12ms 90deg pulse.
Pros: Easy to set upExcellent water suppressionFlat baseline
Cons: Resonances under water signal!(T variation)Labile protons not visible(some GC pairs may be)
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Selective Excitation
90Selective rf pulse on solvent resonance followedby a z gradient pulse to dephase the water signal.This could be followed by a mild presaturationfield. The selective rf pulse (1-2ms, dependingon width to be zeroed) is usually of the gausstype.Also, the selective rf p ulse z-gradient constructscould be repeated (WET).
Bo
My
Bz
M =0
SINGLE LINE ON RESONANCE
Bz
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y
z
x
y
z
x
y
solvent
Jump and return9090
d1
x -x
tdPros: Easy to set up
Excellent water suppression(with proper setup as good as presat)Good for broad signals!
Cons: Non uniform excitationBaseline not flat
Other sequences: 1331 etc
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0
21
-2-1
+1+1Gz
Δ Δ Δ Δ-x90 90
x x90 180
-x
Watergate
Pros: Excellent water suppressionUniform excitationBaseline flat
Cons: May loose broad resonances
p1G1 + p2G2 ...... = 0
Water
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Structure Determination:
I) Assignment NOESY, COSY, HSQCTOCSY……
II) Local Analysis•glycosidic torsion angle (NOE, COSY)•sugar puckering (COSY, NOE, +)•backbone conformation (COSY, +)•base pairing (NOE, COSY)
III) Global Analysis•sequential (NOE, COSY)•inter strand/cross strand (NOE, COSY)•dipolar coupling (HSQC, HSQC)
Black unlabeled, Blue labeled DNA or RNA
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2’
2’’
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O
H1'
B
H4'
O H2''
H3' H2'
O H5'
H5''
Stereospecific Assignment
2’
2’’
How do we determine them?
a) Rules of Thumb (5’, Shugar and Remin)
b) Short mixing times NOESYCrosspeak H1’-H2’’ > H1’H2’
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Structure Determination:
I) Assignment
II) Local Analysis•glycosidic torsion angle, sugar puckering,backbone conformationbase pairing
III) Global Analysis•sequential, inter strand/cross strand, dipolar coupling
Nucleic Acids have few protons…..•NOE accuracy
> account for spin diffusion•Backbone may be difficult to fully characterize
> especially α and ζ. •Dipolar couplings
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α
β
δ
γ
ε
ζ
χ
O5’
O3’
ν3ν0
ν1ν2
ν4O4’
nucl
eotid
e un
it
Sugar puckeringThe five membered furanose ring is not planar. It can be puckeredin an envelope form (E) with 4 atoms in a plane or it can be in atwist form. The geometry is defined by two parameters: thepseudorotation phase angle (P) and the pucker amplitude (Φ).In general: RNA (A type double helix) C3' endo.DNA (B type double helix) C2' endo.
νi = Φm cos (P + 144 (j-2))
δ = ν3 + 125°
3’endo
2’endo
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N (Northern)
S
(Southern)
5’
5’
2’endo
3’endo
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2’endo sugar H1’, H2’, H2”, H3’ region
H2” H2’H1’ H3’
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3’endo sugar H1’, H2’, H2”, H3’ region
H2” H2’H1’ H3’
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2’endo sugar H1’, H2’, H2”, H3’ region
H2” H2’H1’ H3’
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2’endo sugar H1’, H2’, H2” region
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Sugar puckeringUsually (DNA) one observes equilibrium of the S and N forms sugarre-puckering. Unless one form greatly dominates the local analysisrequires quite a few parameters: PN , PS , ΦN , ΦS , fSSeveral methods for analysis exist, graphical and the more rigoroussimulation. In practice the desired outcome determines the effortto be made. Sums of the coupling constants are often easier toobtain.
fS = (Σ 1’ –9.8)/5.9
Σ 1’ = J 1’2’ + J 1’2’’
Σ 2’ = J 1’2’ + J 2’3’ + J 2’2’’
Σ 2’’ = J 1’2’’ + J 2’’3’ + J 2’2’’
Σ 3’ = J 2’3’ + J 2’’3’ + J 3’4’
If fs < 50% J1’ 2’ < J1’ 2’’If fs ca 0% J1’ 2’ very smallIf fs > 70% J1’ 2’ > J1’ 2’’
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Sugar puckering
Sugar puckering can also be studied from: CSA-DD and DD-DD cross-correlation data. CT-NOESY experiments ( 01JMR262-153)
control alphaT alphaC alphaA alphaGNt Σ1´ fs Σ1´ fs Σ1´ fs Σ1´ fs Σ1´ fs
G1 15.2 0.92 15.3 0.93 14.6 0.81 14.3 0.76 14.9 0.86
C2 15.1 0.90 14.7 0.83 15.0 0.88 15.0 0.88 (15.3) (0.93)
G3 16.2 1.00 15.9 1.00 14.9 0.86 16.0 1.00 9.4 -
A4 16.2 1.00 15.3 0.93 15.3 0.93 10.7 - 14.5 0.80
A5 15.7 1.00 15.3 0.93 15.1 0.90 12.1 0.39 14.9 0.86
T6 15.1 0.90 15.3 0.93 14.7 0.83 14.6 0.81 14.8 0.84
T7 16.0 1.00 12.3 - (15.3) (0.93) 15.0 0.88 15.6 0.98
C8 15.1 0.90 12.9 0.53 9.5 - 15.0 0.88 14.4 0.82
G9 15.7 1.00 14.7 0.83 13.5 0.63 14.3 0.76 14.9 0.86
C10 (14) (0.7) (14) (0.7) (14) (0.7) (14) (0.7) (14) (0.7)
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ΦS,N = 37°fS = 125-165PS = 0.44-0.55
ΦS,N = 37°fS = 130-155PS = 0.78-0.86
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Pseurot calculations
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Sugar puckeringHOW to obtain?
-COSY, E.COSY, low flip angle COSY
Some referencesSzyperski, T., et al . (1998) Measurement of Deoxyribose 3 JHH ScalarCouplings Reveals Protein-Binding Induced Changes in the Sugar Puckersof the DNA. JACS. 120, 821- 822.
Iwahara J, et al. (2001), An efficient NMR experiment for analyzing sugar-puckering in unlabeled DNA: J.Mag Res. 2001, 153, 262. H3’-H2” and H3’-H2’ couplings via constant time NOESY.
J. Boisbouvier, B. Brutscher, A. Pardi, D. Marion, and J.-P. Simorre, NMRdetermination of sugar-puckers in nucleic acids form CSA—dipolarcrosscorrelated relaxation, J. Am. Chem. Soc. 122, 6779–6780 (2000).
BioNMR in Drug Research 2003Editor(s): Oliver ZerbeMethods for the Measurement of Angle Restraints from Scalar, DipolarCouplings and from Cross-Correlated Relaxation: Application toBiomacromoleculesChapter Author: Christian Griesinger
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Distance information determines the glycosidic torsion angle
How do we get distance information?o Nuclear Overhauser effect (< 6Å)
2.5Å
3.8Å
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α
β
δ
γ
ε
ζ
χ
O5’
O3’
ν3ν0
ν1ν2
ν4O4’
nucle
otid
e un
it
α and ζ pose problemsDeterminants of 31P chem shift.
ε and ζ correlate. ζ = -317-1.23 ε
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Resonance Assignmnent DNA/RNA (Homonuclear)
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Resonance Assignmnent DNA/RNA (Homonuclear)
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7.4
αC8
A5
ppm
5.45.65.86.06.2 ppm
7.6
8.0
T6
C10T7C2
G1G9G3
A48.2
7.8
7.2
NOESY Connectivity (e.g. α C Decamer)NOESY Connectivity (e.g. α C Decamer)
G1-H1’
G1-H8
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7.4
αC8
A5
ppm
5.45.65.86.06.2 ppm
7.6
8.0
T6
C10T7C2
G1G9G3
A48.2
7.8
7.2
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7.4
αC8
A5
ppm
5.45.65.86.06.2 ppm
7.6
8.0
T6
C10T7C2
G1G9G3
A48.2
7.8
7.2
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7.4
αC8
A5
ppm
5.45.65.86.06.2 ppm
7.6
8.0
T6
C10T7C2
G1G9G3
A48.2
7.8
7.2
2'2''
2'2''
2'2''
G
αC
T3'-3'
5'-5'
H
H
H
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5’- CATGCATG GTACGTAC – 5’
DNA Miniduplex
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31P NMR
Two- and Three-dimensional 31P-driven NMR Procedures for completeassignment of backbone resonances in oligodeoxyribonucleotides. G.W. Kellogand B.I. Schweitzer J. Biomol. NMR 3, 577-595 (1993).
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31P NMR
ppm
4.04.24.44.64.85.05.2 ppm
�-2.0
�-1.5
�-1.0
�-0.5
1.0
0.5
0.0
P7
P8
P3
P2
P6P4
P1
P5
P9
ppm
4.04.24.44.64.85.05.2 ppm
�-2.0
-�1.5
�-1.0
-�0.5
1.0
0.5
0.0
P6
P4
P8P2P9P1P7P5
P3
ppm
4.04.24.44.64.85.05.2 ppm
�-1.5
�-1.0
�-0.5
1.0
0.5
0.0
P2
P3
P5P6 P7
P1P4
P9P8
AlphaC
3’ 4’ 5’,5’’
;****************************************;mwgcorrpt, AMX version;X-H correlation. H-detected;Sklenar et al., 1986, FEBS, 208, 94-98;****************************************d12=20up2=p1*2
1 ze d11 dhi2 d113 d12 p2 ph0 d2 lo to 3 times l1 d3 (p3 ph2):d d0 (p1 ph1) (p3 ph1):d go=2 ph31 d11 wr #0 if #0 id0 ip2 zd lo to 3 times td1 do exit
ph0=0ph1=0ph2=0 0 2 2ph31=2 2 0 0
;>>>>>>>>>>>>>>>DELAYS;d0 = 3us;d2 = 50ms;d3 = 3us;d11= 30 msec
;>>>>>>>>>>>>>>>PULSES;p1 = 90 deg proton pulse hl1 = 1;p2 = 180 deg proton pulse hl1 = 1;p3 = 90 deg X pulse;>>>>>>>>>>>>>>>LOOP-COUNTER;l1 = loop counter for presaturaton;l1*d2 = relaxation delay (l1=40, d2=50ms >>2s);>>>>>>>>>>>>>>>COMMENTS;rd=pw = 0, nd0 = 2, in0 = 1/(2*SW);ns = 4*n, ds = 4, MC2= TPPI;-----------------------END of PROGRAM---------------
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Backbone Experiments:
Harald Schwalbe, Wendelin Samstag, Joachim W. Engels, Wolfgang Bermel, and Christian Griesinger,"Determination of 3J(C,P) and 3J(H,P) Coupling Constants in Nucleotide Oligomers", J. Biomol. NMR 3, 479-486
Z. Wu, N. Tjandra, and A. Bax, Measurement of H3’-31P dipolar couplings in a DNA oligonucleotide byconstant-time NOESY difference spectroscopy, J. Biomol. NMR 19, 367–370 (2001).
G. M. Clore, E. C. Murphy, A. M. Gronenborn, and A. Bax, Determination of three-bond H3’-31P couplings innucleic acids and protein-nucleic acid complexes by quantitative J correlation spectroscopy, J. Mag. Reson.134, 164–167 (1998).
BioNMR in Drug Research 2003Editor(s): Oliver ZerbeMethods for the Measurement of Angle Restraints from Scalar, Dipolar Couplings and from Cross-CorrelatedRelaxation: Application to BiomacromoleculesChapter Author: Christian Griesinger:J-Resolved Constant Time Experiment for the Determination of the Phosphodiester Backbone Angles α and ζ.