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Vibrational Raman optical activity of biopolymers
Journal of
MOLECULAR STRUCTURE Journal
Vibrational
of Molecular
Structure
Raman
349 (1995)
397-400
optical
activity
of
Biopolymers L. D. Barron, Chemistry
L. Hecht,
Department,
Vibrational solution.
about
Typical
are
and D,O
and G. Wilson
Glasgow
activity
G12 8QQ,
measurements
the structure
results
in HZ0
A. F. Bell
The University,
Raman optical
new information albumin
S. J. Ford,
can now
and conformation
exemplified
solution,
here
and for
United
Kingdom
provide
a wealth
of biopolymers
for
proteins
polysaccharides
by
of
in aqueous
bovine
serum
by laminarin.
1.INTRODUCTION Raman optical vibrational
activity
Raman
polarized sensitivity in
the level 3-6
this
directly
make
parent
AND
Vibrations backbone
band
incisive only
mode
contributions
to
band patterns patterns
and
CCD
which
detection
spectra
new
probe
of of
few
local
sample
the
the
which
and
left
have
based
on
enhanced
the
biological
molecules
biopolymer
solution
vibrational skeletal
coordinates
chirality
associated
ROA
intensity,
are usually
much
simpler
carry
information
of
circularly
instrumentation
ROA
those
which
in right
in
intensity
most thereby
than
about
the
absolute
of
PROTEINS the
peptide
spectrum:
C,-N in
similarities
all
four
with
the
signatures
there
appear
great
potential
to
backbone
the backbone
stretch
at mu1230-1350 cm-‘,
clear
and
in the
and conformation.
2. PEPTIDES
the Raman
filters
an
difference
molecules
advances
to provide
because
significant
Raman
is
normal
characteristic
configuration
appear
is
a complicated
generating
notch
ROA
a small
chiral
Recent
necessary
solution.
conformation:
measures
from
light. lp2
holographic
to
aqueous
within
scattering
incident
backscattering,
(ROA)
region regions extended
be
prominent
value
in
spectra
from
Science
I region most of
protein
of tertiary
at
ROA
peptide
from
main
ru 870-950 amide
cm-‘.
regions
of
cm-‘,
the
spectra,3’4
region
III
Signals
usually
which
show
oligomers.
’ In addition to such as a-helix and P-sheet,
loops
structure
All rights reserved
four
the extended
structures
signatures B.V.
with
region
at N 1645-1680
alanyl
secondary
in the study
0022-2860/95/$09.50 0 1995 Elsevier SSDI 0022-2860(95)08793-l
stretch
at N 1020-1150 cm-‘,
and the amide ROA
are associated
C,-C
and
turns3’4
and dynamics
which
have
of proteins.
398
1
BSA (Hz01
1.4x104 >
I
,
I
,
,
,
,
,
,
,
,
,
CT:
,
I,,
1
( , , , , ,
BSA (D,O)
\
RO
1.5x10
4
CIIY
,,,,,,,,,,,),,,,,
500
Figure
1. Backscattered
serum
albumin
,
650
800
Raman
in hydrated
(IR
950
11001250
+ IL)
and deuterated
and buffer
1400
ROA (pH
(IR
I
I
I
15501 -
= 5.4).
r
IL)
spectra
of
bovine
399
D-laminaribiose
ROA
[
7.5x103 ,
I
I
V
I,,
I,
,
(I,
(
,
,
,
I,,
,
cm,
ROA
V
1.6~10~
Figure
2. Backscattered
of laminarin
Raman and ROA
in tris buffer
(pH
= 7.5).
spectra
of
cm -’
D-laminaribiose
in H,O,
and
Comparison extended by
of
amide
N-D
removes
to dominate the
ROA the
chiral
provides
a good
structure
made
the large
example
striking cm-’
loops,
of
adjacent
assignment
would
change
and
of H,O
vibrations:
in
particular
skeletal cm-’
which
a- or
spectra
information Figure of
D-laminaribiose. glycosidic the
reflect
of
strong 1245
can
at N 1125 and 900 carbonyl
remaining account
ROA
in the The
band
at m
confirms of
assigned and
The
of
measured.
outside
I couplet
by
(BSAI
NH protons was
be
cm-‘.
the
which
features
mostly
on
positive
cm-’
amide
in aqueous
their
the to
the
positive
amide a-helix
positive
ROA
band
deformations.
of
nature
OH of
solution
secondary
structure
spectrum
of
ROA
with
that
ROA
spectra
IOSO
and
contribute from
triple
to
helical
the pattern
the
normal
the dimer
of
to
structures.
hydrogen
a 8(1-3) below
where
CO
modes,
the
the
of
also
the
exocyclic
appears
linked
corresponding
are similar cm-‘,
There
about
to be
in polysaccharides.
the
IISO
information
conformation
link.6
laminarin,
of
give
the
substituents,
the glycosidic
the
on going
formation
might
*
ROA
extended
N
oxygen
are reversed
the
at
with
the
N-H
albumin
rigid
ROA
The
of
deformations
serum
of
the
solution
in a-helix
pattern
The two
between
of
band D,O
C,-H
and
Most
when
useful.
generated
a-helical
double
bridges.
positively-biased
bands
together
D-glucose,
region
the
and the
about
are
exchanged
in
just
Bovine
is highly
3 The backbone
carbohydrates
2 shows
leaving
very
replacement
the ROA is now
which
disulphide
originate
the
groups,
BSA
are
because
a-carbon.s
of
ROA
solution
AND POLYSACCHARIDES
of
l3-anomer,
CHBOH
Il.
persist
stretch
might
3. CARBOHYDRATES ROA
the
have
structures.
in
at w 400
so that
many
negative
III region backbone
of
not
D,O
informative
is the disappearance
the
to loop
and
deformations
here
(Figure
up of
number
most
N-H
modes
environment
structures
1340
in Hz0
is particularly
crucial
the normal
local
a-helix
spectra
III region
polymer
The
bonding
disaccharide
N IO.50 cm-‘. stretches signs
which
large
polysaccharide
l3(1-3)
But in the
involving
of
the
ROA
we believe
differences
above
CH,OH
groups
between
the signals
is due 1200
to
cm-’
along
the
helix. REFERENCES 1. L.
D.
Molecular
Barron,
University
Press,
2. L. D. Barron
Light
Cambridge,
and L. Hecht,
(K. Nakanishi,
N. Berova
and
Scattering
and
Optical
Activity,
Cambridge
1982. in Circular R. W.
Dichroism:
Woody,
Principles
eds.),
VCH
and
Applications
Publishers,
New
York,
1994, p. 179. 3. Z. Q. Wen, 4. Z. Q. Wen,
L. Hecht
and L. D. Barron,
J. Am. Chem.
L. Hecht
and L. D. Barron,
Protein
S. S. J. Ford,
Z. Q. Wen,
6. A. F. Bell,
L. Hecht
L. Hecht
Science,
and L. D. Barron,
and L. D. Barron,
J. Am.
Sot.,
116 (1994)
3 (1994)
Biopolymers,
Chem.
Sot.,
443.
435. 34 (1994)
116 (19941 SISS.
303.
MOLECULAR STRUCTURE Journal
Vibrational
of Molecular
Structure
Raman
349 (1995)
397-400
optical
activity
of
Biopolymers L. D. Barron, Chemistry
L. Hecht,
Department,
Vibrational solution.
about
Typical
are
and D,O
and G. Wilson
Glasgow
activity
G12 8QQ,
measurements
the structure
results
in HZ0
A. F. Bell
The University,
Raman optical
new information albumin
S. J. Ford,
can now
and conformation
exemplified
solution,
here
and for
United
Kingdom
provide
a wealth
of biopolymers
for
proteins
polysaccharides
by
of
in aqueous
bovine
serum
by laminarin.
1.INTRODUCTION Raman optical vibrational
activity
Raman
polarized sensitivity in
the level 3-6
this
directly
make
parent
AND
Vibrations backbone
band
incisive only
mode
contributions
to
band patterns patterns
and
CCD
which
detection
spectra
new
probe
of of
few
local
sample
the
the
which
and
left
have
based
on
enhanced
the
biological
molecules
biopolymer
solution
vibrational skeletal
coordinates
chirality
associated
ROA
intensity,
are usually
much
simpler
carry
information
of
circularly
instrumentation
ROA
those
which
in right
in
intensity
most thereby
than
about
the
absolute
of
PROTEINS the
peptide
spectrum:
C,-N in
similarities
all
four
with
the
signatures
there
appear
great
potential
to
backbone
the backbone
stretch
at mu1230-1350 cm-‘,
clear
and
in the
and conformation.
2. PEPTIDES
the Raman
filters
an
difference
molecules
advances
to provide
because
significant
Raman
is
normal
characteristic
configuration
appear
is
a complicated
generating
notch
ROA
a small
chiral
Recent
necessary
solution.
conformation:
measures
from
light. lp2
holographic
to
aqueous
within
scattering
incident
backscattering,
(ROA)
region regions extended
be
prominent
value
in
spectra
from
Science
I region most of
protein
of tertiary
at
ROA
peptide
from
main
ru 870-950 amide
cm-‘.
regions
of
cm-‘,
the
spectra,3’4
region
III
Signals
usually
which
show
oligomers.
’ In addition to such as a-helix and P-sheet,
loops
structure
All rights reserved
four
the extended
structures
signatures B.V.
with
region
at N 1645-1680
alanyl
secondary
in the study
0022-2860/95/$09.50 0 1995 Elsevier SSDI 0022-2860(95)08793-l
stretch
at N 1020-1150 cm-‘,
and the amide ROA
are associated
C,-C
and
turns3’4
and dynamics
which
have
of proteins.
398
1
BSA (Hz01
1.4x104 >
I
,
I
,
,
,
,
,
,
,
,
,
CT:
,
I,,
1
( , , , , ,
BSA (D,O)
\
RO
1.5x10
4
CIIY
,,,,,,,,,,,),,,,,
500
Figure
1. Backscattered
serum
albumin
,
650
800
Raman
in hydrated
(IR
950
11001250
+ IL)
and deuterated
and buffer
1400
ROA (pH
(IR
I
I
I
15501 -
= 5.4).
r
IL)
spectra
of
bovine
399
D-laminaribiose
ROA
[
7.5x103 ,
I
I
V
I,,
I,
,
(I,
(
,
,
,
I,,
,
cm,
ROA
V
1.6~10~
Figure
2. Backscattered
of laminarin
Raman and ROA
in tris buffer
(pH
= 7.5).
spectra
of
cm -’
D-laminaribiose
in H,O,
and
Comparison extended by
of
amide
N-D
removes
to dominate the
ROA the
chiral
provides
a good
structure
made
the large
example
striking cm-’
loops,
of
adjacent
assignment
would
change
and
of H,O
vibrations:
in
particular
skeletal cm-’
which
a- or
spectra
information Figure of
D-laminaribiose. glycosidic the
reflect
of
strong 1245
can
at N 1125 and 900 carbonyl
remaining account
ROA
in the The
band
at m
confirms of
assigned and
The
of
measured.
outside
I couplet
by
(BSAI
NH protons was
be
cm-‘.
the
which
features
mostly
on
positive
cm-’
amide
in aqueous
their
the to
the
positive
amide a-helix
positive
ROA
band
deformations.
of
nature
OH of
solution
secondary
structure
spectrum
of
ROA
with
that
ROA
spectra
IOSO
and
contribute from
triple
to
helical
the pattern
the
normal
the dimer
of
to
structures.
hydrogen
a 8(1-3) below
where
CO
modes,
the
the
of
also
the
exocyclic
appears
linked
corresponding
are similar cm-‘,
There
about
to be
in polysaccharides.
the
IISO
information
conformation
link.6
laminarin,
of
give
the
substituents,
the glycosidic
the
on going
formation
might
*
ROA
extended
N
oxygen
are reversed
the
at
with
the
N-H
albumin
rigid
ROA
The
of
deformations
serum
of
the
solution
in a-helix
pattern
The two
between
of
band D,O
C,-H
and
Most
when
useful.
generated
a-helical
double
bridges.
positively-biased
bands
together
D-glucose,
region
the
and the
about
are
exchanged
in
just
Bovine
is highly
3 The backbone
carbohydrates
2 shows
leaving
very
replacement
the ROA is now
which
disulphide
originate
the
groups,
BSA
are
because
a-carbon.s
of
ROA
solution
AND POLYSACCHARIDES
of
l3-anomer,
CHBOH
Il.
persist
stretch
might
3. CARBOHYDRATES ROA
the
have
structures.
in
at w 400
so that
many
negative
III region backbone
of
not
D,O
informative
is the disappearance
the
to loop
and
deformations
here
(Figure
up of
number
most
N-H
modes
environment
structures
1340
in Hz0
is particularly
crucial
the normal
local
a-helix
spectra
III region
polymer
The
bonding
disaccharide
N IO.50 cm-‘. stretches signs
which
large
polysaccharide
l3(1-3)
But in the
involving
of
the
ROA
we believe
differences
above
CH,OH
groups
between
the signals
is due 1200
to
cm-’
along
the
helix. REFERENCES 1. L.
D.
Molecular
Barron,
University
Press,
2. L. D. Barron
Light
Cambridge,
and L. Hecht,
(K. Nakanishi,
N. Berova
and
Scattering
and
Optical
Activity,
Cambridge
1982. in Circular R. W.
Dichroism:
Woody,
Principles
eds.),
VCH
and
Applications
Publishers,
New
York,
1994, p. 179. 3. Z. Q. Wen, 4. Z. Q. Wen,
L. Hecht
and L. D. Barron,
J. Am. Chem.
L. Hecht
and L. D. Barron,
Protein
S. S. J. Ford,
Z. Q. Wen,
6. A. F. Bell,
L. Hecht
L. Hecht
Science,
and L. D. Barron,
and L. D. Barron,
J. Am.
Sot.,
116 (1994)
3 (1994)
Biopolymers,
Chem.
Sot.,
443.
435. 34 (1994)
116 (19941 SISS.
303.