Transcript Document

Areas of Spectrum
Remember - we are thinking of each amino acid as a spin system - isolated (in terms of
1H-1H J-coupling) from the adjacent amino acids by the peptide bond.
H3C
Yes 3J 2-10 Hz
O
C
C
CH
H
CH3
CH2
C
C
N
H
O
4
No J
H
O
N
C
C
Typical Amino Acid spin-system patterns on COSY spectra
1.) Just see 3J
coupling
2.) Do not
see couplings
across the
peptide bond.
3.6-4.5ppm
CH3
1.4-1.7ppm
Areas of Spectrum
COSY Fingerprint region correlating NH-H protons
COSY Spectrum of a small protein
The ambiguity of a COSY spectrum
Diagonal
X’
X
M,M’
A’
A
A
A’
M,M’
X
X’
If we had some form of SUPER COSY that could go
through many bonds at once we might get….
X’
X
M,M’
A’
A
A
A’
M,M’
X
X’
Diagonal
TOCSY - Total correlation Spectroscopy
To relieve overlap and ambiguity, methods developed to overcome
them.
One popular method is TOCSY.
Basic aim is to produce cross peaks between all of the 1H spins
which belong to the same spin system
Ideal for proteins where each amino acid is a self contained spin
system, separated by the peptide bond.
To understand (quickly!) what TOCSY is we need to introduce the
concept of a spinlock.
TOCSY
90o
t1
t2
Spin locking field
The spin locking field (a series of rapid 90o pulses of
varying phase) effectively averages the coupling 1H-1H
coupling constants over the entire spin system.
The dispersion of the NH-H region allows correlations along
the entire system to become visible.
Homonuclear Hartmann-Hahn and TOCSY experiments
Under these conditions magnetisation is transferred very efficiently,
at a rate determined by J, between coupled nuclei. The longer the
mixing time, the further through the spin system the magnetisation
propagates.
J13=0.2 Hz
1
2
3
J12=7 Hz
J23=5 Hz
Even if J13 is very small, will still see transfer to it via 2
8.83ppm
3.95ppm
1.52 bCH3
1.52ppm
ALA 49
Ala49 3.95 H
1.52 bCH3
3.95 H
8.83ppm
In the 2D NOESY experiment, an additional mixing time is
added to the basic COSY sequence. The result is a build up
of magnetisation from one nucleus to a close neighbour.
90o
t1
90o
90o
Mixing time
t2
(magnetisation components of interest lie along -z)
Cross relaxation now occurs to nearby nuclei.
The NOE operates ‘through space’, it does not require the nuclei to
be chemically bonded. The build-up is proportional to the
separation of the two nuclei
1
NOE  6
r
nuclear separation

If we calibrate this function by measuring a known distance in the
protein and the intensity of the NOE, we can write
1
NOE  k 6
r
where k is a
proportionality
constant
1
2
Sequential ‘walking’ with sequential nOes
Fingerprint region
dH
of a 2D NOESY
TOCSY
gH
bH
3
4
5
COSY
9.0
COSY
TOCSY
NOE
8.0
O
C
CH3
N
C
C
H
H
O
NOE
COO
CH2
H
H
O
N
C
C
CH2
Ala
CH
H3C
-
CH3
N
H
H
7.0
NH
NH-NH Contacts
NOE
O
C
CH3
N
C
C
H
H
O
1
COO
H
H
O
N
C
C
CH2
Ala
CH
H3C
dH
-
CH3
CH2
N
H
gH
2
bH
3
H
4
5
9.0
The ‘NH-NH’ region provides an
additional source of sequential
contacts - note the symmetry
around the diagonal and that
this contact does not give direction.
8.0
7.0
Connectivites by NOE
dN - Connects CH of residue i to NH of i+1
dbN - Connects CbH of resdiue i to NH of i+1
dNN - Connects NH of residue i to NH of i+1
LEU
dN
H
dN
dNN
N
dbN
H
ALA
VAL
C
dNN
C
H3C
H
N
CH3
CH d O
bN
C
C
H
N
C
H
CH3
dNN
O
H
dN
CH2
dbN
Hi-NHi+3
Hi-NHi+1
i+3
H
i+2
An -helix can be recognised
by repeating patterns of short
range nOes. A short range nOe
is defined as a contact between
residues less than five apart in
N
i+4 the sequence (sequential nOes
H
connect neighbouring residues)
NOE
H
For an -helix we see Hi-NHi+3
and Hi-NHi+4 nOes.
i
A b-strand is distinguished by strong CHi-NHi+1contacts and long range nOes connecting the
strands.
A long range nOe connects residues more than 5 residues apart in the chain.
Assignment of secondary structural segments
• sequential stretches of residues with consistent secondary
structure characteristics provide a reliable indication of the
location of these structural segments