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NOE

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The major factors are molecular tumbling frequency and internuclear distance. ... recorded using a new technique in which pulsed field gradients are used; the ... – PowerPoint PPT presentation

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Title: NOE


1
NOE
  • Transferring magnetization through scalar
    coupling is a coherent process. This means
    that all of the spins are doing the same thing at
    the same time.
  • Relaxation is an incoherent process, because it
    is caused by random fluxuations that are not
    coordinated.
  • The nuclear Overhauser effect (NOE) is in
    incoherent process in which two nuclear spins
    cross-relax. Recall that a single spin can
    relax by T1 (longitudinal or spin-latice) or T2
    (transverse or spin-spin) mechanisms. Nuclear
    spins can also cross-relax through dipole-dipole
    interactions and other mechanisms. This cross
    relaxation causes changes in one spin through
    perturbations of the other spin.
  • The NOE is dependent on many factors. The major
    factors are molecular tumbling frequency and
    internuclear distance. The intensity of the NOE
    is proportional to r-6 where r is the distance
    between the 2 spins.

2
Qualitative Description
2 spins I and S
  • Two nuclear spins within about 5 Å will interact
    with each other through space. This interaction
    is called cross-relaxation, and it gives rise to
    the nuclear Overhauser effect (NOE).
  • Two spins have 4 energy levels, and the
    transitions along the edges correspond to
    transitions of one or the other spin alone. W2
    and W0 are the cross-relaxation pathways, which
    depend on the tumbling of the molecule.

bb n4()
WI(2)
WS(2)
W2
() n2 ab
ba n3()
W0
WI(1)
WS(1)
aa n1()
3
dn1/dt -WS(1)n1-WI(1)n1W2n1
WS(1)n2WI(1)n3W2n4 etc for n2,3,4 using Iz
n1-n3n2-n4 Sz n1-n2n3-n4 2IzSz n1-n3-n2n4
One gets the master equation or Solomon
equation dIz/dt -(WI(1)WI(2)W2W0)Iz
(W2-W0)Sz (WI(1)-WI(2))2IzSz dSz/dt
-(WS(1)WS(2)W2W0)Sz (W2-W0)Iz
(WS(1)-WS(2))2IzSz d2IzSz/dt -(WI(1)WI(2)
WS(1)WS(2))2IzSz - (WS(1)-WS(2))Sz -
(WI(1)-WI(2))Iz (WI(1)WI(2)W2W0) auto
relaxation rate of Iz or rI (WS(1)WS(2)W2W0)
auto relaxation rate of Rz or rR (W2-W0) cross
relaxation rate sIS Terms with 2IzSz can be
neglected in many circumstances unless
(WI/S(1)-WI/S(2)) (D-CSA cross correlated
relaxation etc )
4
Spectral densities J(w)
  • W0 ? gI2 gS2 rIS-6 tc / 1 (wI - wS)2tc2
  • W2 ? gI2 gS2 rIS-6 tc / 1 (wI wS)2tc2
  • WS ? gI2 gS2 rIS-6 tc / 1 wS2tc2
  • WI ? gI2 gS2 rIS-6 tc / 1 wI2tc2
  • Since the probability of a transition depends on
    the different
  • frequencies that the system has (the spectral
    density), the
  • W terms are proportional the J(w).
  • Also, since we need two magnetic dipoles to have
    dipolar
  • coupling, the NOE depends on the strength of
    the two
  • dipoles involved. The strength of a dipole is
    proportional to
  • rIS-3, and the Ws will depend on rIS-6
  • for proteins only W0 is of importance W I,S,2 ltlt
  • The relationship is to the inverse sixth power
    of rIS, which
  • means that the NOE decays very fast as we pull
    the two
  • nuclei away from each other.

5
d(Iz Iz0)/dt - rI (IzIz0) - sIS
(SzSz0) d(Sz Sz0)/dt - sIS (IzIz0) - rS
(SzSz0) Note that in general there is no
simple mono-exponential T1 behaviour !!
6
Steady State NOE Experiment
For a steady state with Sz saturation
Sz0 d(IzSS Iz0)/dt - rI (IzSSIz0) - sIS
(0Sz0) 0 IzSS sIS/rI Sz0 Iz0 for the NOE
enhancement h(IzSS-Iz0)/ Iz0 sIS/rI Sz0/Iz0
7
NOE difference
Ultrahigh quality NOE spectra The upper spectrum
shows the NOE enhancements observed when H 5 is
irradiated. The NOE spectrum has been recorded
using a new technique in which pulsed field
gradients are used the result is a spectrum of
exceptional quality. In the example shown here,
it is possible to detect the enhancement of H10
which comes from a three step transfer via H6 and
H9. One-dimensional NOE experiments using pulsed
field gradients, J. Magn. Reson., 1997, 125, 302.
8
Transient NOE experiment
Solve the Solomon equation With the initial
condition Iz(0)Iz0 Sz(0)-Sz0 For small mixing
times tm the linear approximation
applies d(Iz(t) Iz0)/dt -rI(Iz(t)Iz0) -
sIS(SzSz0) 2 sISSz0 Valid for tmrS and tmsIS
ltlt 1 (i.e. S is still inverted and very little
transfer from S) h(tm) (Iz(tm ) - Iz0)/ Iz0
2sIS tm The NOE enhancement is proportional to
sIS !
9
Longer mixing times
a system of coupled differential equations can be
solved by diagonalization or by numerical
integration Multi-exponential solution the
exponentials are the Eigenvalues of the
relaxation matrix
10
NOESY
The selective S inversion is replaced with a
t1evolution period Sz(0)cosWSt1Sz0,
Iz(0)cosWIt1Iz0 (using the initial rate
appx.) Sz(tm)sIStmIz0 rStmSz0 (a)
cosWIt1sIStmIz0 (b)
cosWSt1rStm-1Sz0 (c)
11
NOE vs. ROE
12
ROESY
90s
90
tm
t1
tm
  • wSL ltlt wo, w tc ltlt 1
  • The analysis of a 2D ROESY is pretty much the
    same than
  • for a 2D NOESY, with the exception that all
    cross-peaks are
  • the same sign (and opposite sign to peaks in
    the diagonal).
  • Also, integration of volumes is not as
    accurate

13
Approaches to Identifying NOEs
  • 15N- or 13C-dispersed (heteronuclear)

14
2D - 3D NOE
3D- NOESY-HSQC
15
4D NH-NH NOE
N1 H1
H2 N2
H1
H2
N1
N2
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