- Email: [email protected]
The helix-coil transition of E. coli s-RNA as measured by fluorescence polarization
Vol.
23, No.
5, 1966
BIOCHEMICAL
AND
TRE RRLIX-COIL
BIOPHYSICAL
TRANSITION
OF 9. m
AS MEASURRD BY FLUORESCENCE David
B. Hi liar
RESEARCH
COMMUNICATIONS
S-RR4
POMRIZATION*
and Maxime
MacKenzie
Laboratory of Physical Biochemistry Naval Medical Research Institute Bethesda, Maryland 20014
Received
April
29, 1966
In genera 1, the most soluble-RNA
(s-RM)
of danaturation
1965;
have
spectra
or of optical
rotatory
The sensitive
Here,
conjugate induced
results
in the acquisition
e.,
et al.,
1965).
the rotational
to a structureless,
random
measured
of a great
kinetic
unit
sophisticated
(Millar
Lamborg
and Zamecnik,
has only
taken are
been 1965). of an
through
the
interpreted
internucleotide
of freed-
of s-RNA at this
1964)
of fluorescence
The results
degree
analysis
and Steiner,
as s-RNA is
non-covalent
of
and Cantoni,
1965;
the polarization
50% of
transition
of fluorescence
transitions
transition.
of about
helix-coil
Felsenfeld
et al.,
in which
helix-coil
rupture
1963;
of polarization
of s-RNA is
that
of the
(Lamborg
Paeaan
experiments
showing
i.
et al.,
to polynucleotide
we report
thermally
1966;
studies
the use of either
dispersion
technique
applied
acriflavioe
involved (Fresco
Ray and Oikawa,
recently
rewarding
as bonds
of internal
temperature
rotation; is equivalent
coil. HBTHODS
S-RNA, 5. a, Chagrin
Falls,
phenol,
dialyzed
strain
Ohio,
freed
72 hours
B, was purchased of protein versus
from General
by repeated
frequent
changes
mechanical of doubly
Biochemicals, shaking distilled
with water
*The opinions or asserttons contaiued herein are the private ones of the authors and are not to be construed as official or reflecting the views of the Ravy Department or the naval service at large. From the Bureau of Medicine and Surgery, Navy Department, Research task RR 005.06-0001.01.
724
Vol . 23 , No .*,5 1966
BIOCHEMICAL
and lyophi lized.
The preparation
ments of polarization performed solvent
AND
in detail
for 811 measurements
RESEARCH
of the acriflavine-s-RNA
of fluorescence,
as described
BIOPHYSICAL
and relaxation
elsewhere
(Millar
was 0.3 M KCI,
0.01
COMMUNICATIONS
conjugate,
measure-
time calculations and Steiner,
KAc,
pH 7.0.
were
1965).
The
The Szo,w of
the preparation was 3.96 (average of three determinations measured at temperatures of about 23'),
the intrinsic
viscosity
0.059 dL/g (25').
and the
weight average molecular weight (determined by the Yphantis meniscus depletion methtod, Yphantis,
1964), 26,500.
Assuming the extinction
coefficient
of the dye to be unaltered by conjugation there was only slightly one mole of dye combined with one mole of s-RNA in fair results of Churchich (1963). tlnction
coefficient
less than
agreement with the
A value of 21.4 was used for the specific
ex-
of s-RNA (Stephenson and Zamecnik, 1962). RESULTS
FLg. I shows the polarization
IOII1111
20
30
of fluorescence thermal profile
40I
60
I
50t
r
60
I
70
as
1
QQ
- 55
40-
-h -‘p
Fig.
I. Polarization of fluorescence thermal profile and absorbance 260 I+ thermal profile of 3. coli S-RNA. X excitation 436 q~, X exit via Corning 510 sq.bcutoff filter. 0, l/P + l/3; 0, 480.
725
Vol.
23, No.
5, 1966
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
f+' 3 versus Fig.
I
T//l;
also
shows
scale
is
Since
P (polarization)
in
at
about
cribed
in
detail
rotational
the
technique temperature sucrose
the
that
as 45’-50’.
the
presence
L+f P
(Millar
of
fluorescent
stranded
varying
solutions.
Qby Under
of
(1963), the
these
use
of
the for
e.
by
in
small. a selective to
case)
present
P at
As
des-
gain
in
the
adenine
wFth
the
constant of
freedom
P
may heavfly
possibility
rotational
T/q.
a fall
concentrations if
of
a decrease
measuring
various
conditions,
values
bound
this
temperature
rigidity,
(covalently in
i..
with
that
1965)
terminus
The
vanishingly
Steiner, label
viscosity.
lg~.
internal
I shows
We tested
Wahl
260
register
P becomes
CCA
solvent
at
in
Fig.
and
polarization. and
.
55O-60’
0 is
profile is
elsewhere
Gottlieb
and
(centigrade)
in
the
Kelvin
thermal
At
single
and
T
a rise
apparent of
degrees
registers
freedom of
T is absorbance
so
expressed
begins
weight
the
adjusted
P is
residue
where
buffered of
the
Ei-
7
--IF0 + -,a 6
, 5
4
200
f SC
400 T’T
Fig.
IT. Polarization solutions.
values X excitation,
at
25O and 4S”. A exit as in
726
R is Figure
varied I.
0,
by the use of 4S”; 0, 2S”.
sucrose
Vol.
23, No.
label
L+1; P 3 decreases
of TIQ,
experiment. and the both
No evidence intercepts
This
at 45',
I.
BIOPHYSICAL
T/Q is
at first
rapidly.
Fig.
of curvilinearity
at T/h
temperatures. Labtel
AND
L+L P 3 versus
is. present,
values
the
BIOCHEMICAL
5, 1966
= 0 are result
the
but
COMMUNICATIONS
with
decreasing
2 shows the result shown at 25'
same within
shows that
e. at about
Linear
is
the
RESEARCH
of this
nor
at 45'
experimental
no free
transition
error
rotation
is
for
acquired
by
initiation.
DISCUSSION The estimated good agreement
Tm of the absorbance
with
the
results
(1966),
who used only
ization
becomes vanishingly
the disrupted in internal acquire that
indica,ted this
by the
tional
label
rotational
forces
melting
in
this
freedom
is
of a conformation
freedom, region
that
the
organization
influences-and
label
idea
the
for
i.
that
freedom
would
not
freely
first
find
stabilizing in
label.
and not exposed
explanation
label
by the
of the
e. always
be
due to a frac-
happen
stranded
the
however,
the acquisition
is single
loss
expect,
in part
mobility
the
does not
We did
possibly
that
label
the structurally
could
CCA terminus
we feel
that
rotational
of a-RNA-
therefore
rotational
at 55O is
-et --al
the polar-
for
the
(1964).
in
indicates
responsible
One might
This
restrains
range
at 55'.
responsible
conceivable.
That
that
and Wahl
the are
are
57O-58'
and Henley
presupposes
45o)
of Gottlieb
(1966)
strengths.
region
freedom (circa
is about
temperature
Loss in polarization
which
indicates
in the helical
the
this
conclusion
technique If
ionic
in this
begins
to be so.
evideuce
in
rotational
transition
rotational
small
This
preferential as the
different
forces
rigidity.
curve
of Kay and Oikawa
slightly
secondary
melting
is
loss But,
involved
to solvent likely
to be
more correct. One further fluorescent Steiner, from the
residue. 1965)
20*to loss
possibility
about
Some
show about !iO".
It
in P shown in Fig.
is but
a change not
all
in the excited
lifetime
(r)
Labelled
polynucleotides
(Millar
a 20% to 50% decrease
in fluorescent
intensity
can be calculated I cannot
(Millar
be accounted
727
and Steiner, for
1965)
by such a change
of the and
that in r.
Vol.
23, No. 5, 1966
BIOCHEMICAL
From our data,
we cannot
of bonds
located
a marked
conformational
in internal
rigidity.
cluded
yeast
that
between
20’
coiled
near
change
and that
loss
of bonds
in rigidity From
time
axial
ratio
The axial viscosity, equation
for
of the ratio
(1953)
any large It
is clear
perturbations by
equivalent
system
in this weight
isxnediately
distant
the polarization
of equal
the
loss
in asyxkaetry like
randomly
between
yeast
a similar
change
and
conformation
the melting
of a critically
to explain
the
of about
size.
adjacent independent
to the terminus
5-6.
Thus
since
kinetic
they
would
at 25’
does not have
rotation
localized
units
that
terminus
of the over-all
area
at 25O and under
indicates
labelled
does not preclude
1964).
by the Scheraga-Mandelkirn
result
to the
the
sedimentation,
and rotational
This
the
compute
et al.,
From our
we may compute
with
weight
(Borisova 6-7.
the translational
of the relaxation
by comparison
molecular
is
ratio
suggestion
a value
ellipsoid
data
axial
freedom this
then
and then
manner
to be of similar
rotational
does,
conformational
prolate
conditions
area
s-RNA behaves
that
in
have con-
loss
mechanism
results for
(1966)
a marked
ts possible it
loss
et al.
we may calculate
sphere
an apparent
that
Henley
of a group
at 55’.
a rigid
and molecular
experimental
helical
the
solvent
estimated
of s-RNA appear the
follow
of P at 25’
((3 of s-RNA in this calculated
If
we observe value
the
value
our
must
s-RNA.
melting
the
responsible
melting it
COMMUNICATIONS
of bonds whose
yeast
If a parallel
j$. coli
is
is primarily
above 40’
then
RESEARCH
it
s-RNA in 0.2 M NaCl undergoes
vith
set
or a set
connection,
s-RNA may be assumed,
located
whether
which
In this
and 40°,
occurs
BIOPHYSICAL
determine
the terminus
polynucleotides.
event
AND
of s-RNA.
conformational not
be detected
technique. REFERENCES
Borisova, 0. F., Kiselev, L. L., Frolova, L. JSJ., Dokl. Akad. Churchich, Jr., Biochim. Biophys. Fasman, G. D., Lindblow, C., and Felsenfeld, G. and Cantoni, G. L. (1964). Fresco, J. R., Klotz, L. C., and on Quantitative Biology 28,
Surovaia, A. I., Turner-man, L. A., and Science (NAIJK), USSR 159, 1154 (1964). Acta 75, 274 (1963). Seaman, E., J. Mol. Biol. l2, 630 (1965). Proc. Natl. Acad. Sci. U. S. 5l, 818 Richards, 83 (1963).
728
E. G.,
Cold
Spring
Harbor
Symposia
Vol.
23, No.
5, 1966
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Gottlieb, Y. and Wahl, P., J. Chim. Phya. 60, 849 (1963). Henley, D. D., Lindahl, T., and Fresco, J. R., Proc. Natl. Acad. Sci. U. S. 55, 191 (1966). Kay, C. M. and Oikawa, K., Biochemistry 2, 213 (1966). Lamborg, M. R., Zamecnik, P. C., Ting-Kai, Li, tigi, Jr., and Vallee, B. L., Biochemistry 5, 63 (1965). Lamborg, M. R. and Zamecnik, P. C., Biochem. Biophys. Res. Cormrmn. &I, 328 (1'965). Millor, D. B. and Steiner, R. F., Biochim. Biophys. Acta 102, 571 (1965). Scheraga, 8. A. and Mandelkirn, L., J. Am. Chem. Sot. 75, 179 (1953). Stephenson, M. L. and Zamecnik, P. C., Biochem. Biophys. Res. Common. 1, 91 (1962). Yphantis, D. A,, Biochemistry 2, 297 (1964).
729
23, No.
5, 1966
BIOCHEMICAL
AND
TRE RRLIX-COIL
BIOPHYSICAL
TRANSITION
OF 9. m
AS MEASURRD BY FLUORESCENCE David
B. Hi liar
RESEARCH
COMMUNICATIONS
S-RR4
POMRIZATION*
and Maxime
MacKenzie
Laboratory of Physical Biochemistry Naval Medical Research Institute Bethesda, Maryland 20014
Received
April
29, 1966
In genera 1, the most soluble-RNA
(s-RM)
of danaturation
1965;
have
spectra
or of optical
rotatory
The sensitive
Here,
conjugate induced
results
in the acquisition
e.,
et al.,
1965).
the rotational
to a structureless,
random
measured
of a great
kinetic
unit
sophisticated
(Millar
Lamborg
and Zamecnik,
has only
taken are
been 1965). of an
through
the
interpreted
internucleotide
of freed-
of s-RNA at this
1964)
of fluorescence
The results
degree
analysis
and Steiner,
as s-RNA is
non-covalent
of
and Cantoni,
1965;
the polarization
50% of
transition
of fluorescence
transitions
transition.
of about
helix-coil
Felsenfeld
et al.,
in which
helix-coil
rupture
1963;
of polarization
of s-RNA is
that
of the
(Lamborg
Paeaan
experiments
showing
i.
et al.,
to polynucleotide
we report
thermally
1966;
studies
the use of either
dispersion
technique
applied
acriflavioe
involved (Fresco
Ray and Oikawa,
recently
rewarding
as bonds
of internal
temperature
rotation; is equivalent
coil. HBTHODS
S-RNA, 5. a, Chagrin
Falls,
phenol,
dialyzed
strain
Ohio,
freed
72 hours
B, was purchased of protein versus
from General
by repeated
frequent
changes
mechanical of doubly
Biochemicals, shaking distilled
with water
*The opinions or asserttons contaiued herein are the private ones of the authors and are not to be construed as official or reflecting the views of the Ravy Department or the naval service at large. From the Bureau of Medicine and Surgery, Navy Department, Research task RR 005.06-0001.01.
724
Vol . 23 , No .*,5 1966
BIOCHEMICAL
and lyophi lized.
The preparation
ments of polarization performed solvent
AND
in detail
for 811 measurements
RESEARCH
of the acriflavine-s-RNA
of fluorescence,
as described
BIOPHYSICAL
and relaxation
elsewhere
(Millar
was 0.3 M KCI,
0.01
COMMUNICATIONS
conjugate,
measure-
time calculations and Steiner,
KAc,
pH 7.0.
were
1965).
The
The Szo,w of
the preparation was 3.96 (average of three determinations measured at temperatures of about 23'),
the intrinsic
viscosity
0.059 dL/g (25').
and the
weight average molecular weight (determined by the Yphantis meniscus depletion methtod, Yphantis,
1964), 26,500.
Assuming the extinction
coefficient
of the dye to be unaltered by conjugation there was only slightly one mole of dye combined with one mole of s-RNA in fair results of Churchich (1963). tlnction
coefficient
less than
agreement with the
A value of 21.4 was used for the specific
ex-
of s-RNA (Stephenson and Zamecnik, 1962). RESULTS
FLg. I shows the polarization
IOII1111
20
30
of fluorescence thermal profile
40I
60
I
50t
r
60
I
70
as
1
- 55
40-
-h -‘p
Fig.
I. Polarization of fluorescence thermal profile and absorbance 260 I+ thermal profile of 3. coli S-RNA. X excitation 436 q~, X exit via Corning 510 sq.bcutoff filter. 0, l/P + l/3; 0, 480.
725
Vol.
23, No.
5, 1966
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
f+' 3 versus Fig.
I
T//l;
also
shows
scale
is
Since
P (polarization)
in
at
about
cribed
in
detail
rotational
the
technique temperature sucrose
the
that
as 45’-50’.
the
presence
L+f P
(Millar
of
fluorescent
stranded
varying
solutions.
Qby Under
of
(1963), the
these
use
of
the for
e.
by
in
small. a selective to
case)
present
P at
As
des-
gain
in
the
adenine
wFth
the
constant of
freedom
P
may heavfly
possibility
rotational
T/q.
a fall
concentrations if
of
a decrease
measuring
various
conditions,
values
bound
this
temperature
rigidity,
(covalently in
i..
with
that
1965)
terminus
The
vanishingly
Steiner, label
viscosity.
lg~.
internal
I shows
We tested
Wahl
260
register
P becomes
CCA
solvent
at
in
Fig.
and
polarization. and
.
55O-60’
0 is
profile is
elsewhere
Gottlieb
and
(centigrade)
in
the
Kelvin
thermal
At
single
and
T
a rise
apparent of
degrees
registers
freedom of
T is absorbance
so
expressed
begins
weight
the
adjusted
P is
residue
where
buffered of
the
Ei-
7
--IF0 + -,a 6
, 5
4
200
f SC
400 T’T
Fig.
IT. Polarization solutions.
values X excitation,
at
25O and 4S”. A exit as in
726
R is Figure
varied I.
0,
by the use of 4S”; 0, 2S”.
sucrose
Vol.
23, No.
label
L+1; P 3 decreases
of TIQ,
experiment. and the both
No evidence intercepts
This
at 45',
I.
BIOPHYSICAL
T/Q is
at first
rapidly.
Fig.
of curvilinearity
at T/h
temperatures. Labtel
AND
L+L P 3 versus
is. present,
values
the
BIOCHEMICAL
5, 1966
= 0 are result
the
but
COMMUNICATIONS
with
decreasing
2 shows the result shown at 25'
same within
shows that
e. at about
Linear
is
the
RESEARCH
of this
nor
at 45'
experimental
no free
transition
error
rotation
is
for
acquired
by
initiation.
DISCUSSION The estimated good agreement
Tm of the absorbance
with
the
results
(1966),
who used only
ization
becomes vanishingly
the disrupted in internal acquire that
indica,ted this
by the
tional
label
rotational
forces
melting
in
this
freedom
is
of a conformation
freedom, region
that
the
organization
influences-and
label
idea
the
for
i.
that
freedom
would
not
freely
first
find
stabilizing in
label.
and not exposed
explanation
label
by the
of the
e. always
be
due to a frac-
happen
stranded
the
however,
the acquisition
is single
loss
expect,
in part
mobility
the
does not
We did
possibly
that
label
the structurally
could
CCA terminus
we feel
that
rotational
of a-RNA-
therefore
rotational
at 55O is
-et --al
the polar-
for
the
(1964).
in
indicates
responsible
One might
This
restrains
range
at 55'.
responsible
conceivable.
That
that
and Wahl
the are
are
57O-58'
and Henley
presupposes
45o)
of Gottlieb
(1966)
strengths.
region
freedom (circa
is about
temperature
Loss in polarization
which
indicates
in the helical
the
this
conclusion
technique If
ionic
in this
begins
to be so.
evideuce
in
rotational
transition
rotational
small
This
preferential as the
different
forces
rigidity.
curve
of Kay and Oikawa
slightly
secondary
melting
is
loss But,
involved
to solvent likely
to be
more correct. One further fluorescent Steiner, from the
residue. 1965)
20*to loss
possibility
about
Some
show about !iO".
It
in P shown in Fig.
is but
a change not
all
in the excited
lifetime
(r)
Labelled
polynucleotides
(Millar
a 20% to 50% decrease
in fluorescent
intensity
can be calculated I cannot
(Millar
be accounted
727
and Steiner, for
1965)
by such a change
of the and
that in r.
Vol.
23, No. 5, 1966
BIOCHEMICAL
From our data,
we cannot
of bonds
located
a marked
conformational
in internal
rigidity.
cluded
yeast
that
between
20’
coiled
near
change
and that
loss
of bonds
in rigidity From
time
axial
ratio
The axial viscosity, equation
for
of the ratio
(1953)
any large It
is clear
perturbations by
equivalent
system
in this weight
isxnediately
distant
the polarization
of equal
the
loss
in asyxkaetry like
randomly
between
yeast
a similar
change
and
conformation
the melting
of a critically
to explain
the
of about
size.
adjacent independent
to the terminus
5-6.
Thus
since
kinetic
they
would
at 25’
does not have
rotation
localized
units
that
terminus
of the over-all
area
at 25O and under
indicates
labelled
does not preclude
1964).
by the Scheraga-Mandelkirn
result
to the
the
sedimentation,
and rotational
This
the
compute
et al.,
From our
we may compute
with
weight
(Borisova 6-7.
the translational
of the relaxation
by comparison
molecular
is
ratio
suggestion
a value
ellipsoid
data
axial
freedom this
then
and then
manner
to be of similar
rotational
does,
conformational
prolate
conditions
area
s-RNA behaves
that
in
have con-
loss
mechanism
results for
(1966)
a marked
ts possible it
loss
et al.
we may calculate
sphere
an apparent
that
Henley
of a group
at 55’.
a rigid
and molecular
experimental
helical
the
solvent
estimated
of s-RNA appear the
follow
of P at 25’
((3 of s-RNA in this calculated
If
we observe value
the
value
our
must
s-RNA.
melting
the
responsible
melting it
COMMUNICATIONS
of bonds whose
yeast
If a parallel
j$. coli
is
is primarily
above 40’
then
RESEARCH
it
s-RNA in 0.2 M NaCl undergoes
vith
set
or a set
connection,
s-RNA may be assumed,
located
whether
which
In this
and 40°,
occurs
BIOPHYSICAL
determine
the terminus
polynucleotides.
event
AND
of s-RNA.
conformational not
be detected
technique. REFERENCES
Borisova, 0. F., Kiselev, L. L., Frolova, L. JSJ., Dokl. Akad. Churchich, Jr., Biochim. Biophys. Fasman, G. D., Lindblow, C., and Felsenfeld, G. and Cantoni, G. L. (1964). Fresco, J. R., Klotz, L. C., and on Quantitative Biology 28,
Surovaia, A. I., Turner-man, L. A., and Science (NAIJK), USSR 159, 1154 (1964). Acta 75, 274 (1963). Seaman, E., J. Mol. Biol. l2, 630 (1965). Proc. Natl. Acad. Sci. U. S. 5l, 818 Richards, 83 (1963).
728
E. G.,
Cold
Spring
Harbor
Symposia
Vol.
23, No.
5, 1966
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Gottlieb, Y. and Wahl, P., J. Chim. Phya. 60, 849 (1963). Henley, D. D., Lindahl, T., and Fresco, J. R., Proc. Natl. Acad. Sci. U. S. 55, 191 (1966). Kay, C. M. and Oikawa, K., Biochemistry 2, 213 (1966). Lamborg, M. R., Zamecnik, P. C., Ting-Kai, Li, tigi, Jr., and Vallee, B. L., Biochemistry 5, 63 (1965). Lamborg, M. R. and Zamecnik, P. C., Biochem. Biophys. Res. Cormrmn. &I, 328 (1'965). Millor, D. B. and Steiner, R. F., Biochim. Biophys. Acta 102, 571 (1965). Scheraga, 8. A. and Mandelkirn, L., J. Am. Chem. Sot. 75, 179 (1953). Stephenson, M. L. and Zamecnik, P. C., Biochem. Biophys. Res. Common. 1, 91 (1962). Yphantis, D. A,, Biochemistry 2, 297 (1964).
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