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Optical rotatory dispersion studies of the heat denaturation of avidin and the avidin-biotin complex
BIOCHEMICAL
Vol. 25, No. 5, 1966
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OPTICAL ROTATORYDISPERSION STUDIES OF THE HEAT DFJVATURATION OF AVIDIN AND TRE AVIDIN-BIOTIN Alan B. Pritchard,
Donald B. McCormick,
C@PLEX* and Lemuel D. Wright
Graduate School of Nutrition and Biochemistry Section, Division of Biological. Sciences, Cornell University, Ithaca, New York
Received October 31, 1966
Avidin, biotin
a protein
to yield
(Green, 1963a). stable
isolated
a complex with a dissociation The avidin-biotin
toward proteolytic
pH range (Eakin, 1942).
Snell,
of biotin
and Willisms, solutions
1964; Pai and Lichstein,
exhibits
and positive visible
at 285 mp.
region.
complexing
prominent
from its
complex
but the increased
of high ionic
strength
affinity affords
the complex with heat (Wei and
(Green and Melsmed, 1966), rotatory
Cotton effects
dispersion
the
(ORD) spectrum
which are negative
The curve approximates
The ORD spectrum of avidin
with biotin,
biotin
1964).
study shows that the optical.
of avidin
l*O),
toward disrupting
In agreement with a recent report present
as 10 -15 M
reported
1940; GyUrgy, Rose, and Tomsrelli,
was shown to release
in buffer
protection
constant
with
complex has been shown to be relatively
and Williams,
Snell,
for avidin
considerable Wright,
(Eakin,
combines firmly
enzymes (Gyisrgy and Rose, 1943) and over a wide
Steam sterilization
with avidin
from egg white,
zero rotation
is not markedly
at 245 ml.r into
changed upon
and only moderate changes occur in 8 M urea.
*This work was supported by N.I.H.
Grant No. AM-08721.
524
the
BIOCHEMICAL
Vol. 25, No. 5, 1966
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
However, we have now found that heating causes a precipitous
reversible
of avidin
above 80'
below 330 mn reflecting
increase in levorotation
denaturation
solutions
which can be prevented by complexing
ir-
with bioti.n.
Experimental CrystsLiine Biochemicsls
D-biotin
Corp.
and crude avidin
The avidin
carboxymethyl-cellulose (McCormick,
The ORD measurements were obtained with a thermostated
Spectra were determined temperatures of avidin without
by chromatography
on
(Melsmed and Green, 1963) and biotin-cellulose
1965).
Spectropolarkneter
was purified
were purchased from Nutritional
at room temperature
as specified. (0.5 mg/ml)
urea or biotin
Solutions
compartment and 2.5 cm cells. or after 15 minutes
contained
in Nf$OH-NHbC1 buffer
a constant
at such
concentration
(pH p, n = 1) tith
and
as specified. Results
The ORD spectra of native 8 M urea, and heat-denatured
+200-
cell
using a Cery 60
and Discussion avidin,
avidin
avidin-biotin are shown in Fig.
complex, avidin 1.
A
I 250
I 270
290
I 310
x w
Fig. 1. ORD spectra of avidin in buffer (o), with 2.9 x 10V5 M biotin (A), in 8 M urea (o), and when heated at 85O (0).
525
with
Vol. 25, No. 5, 1966
Avidin
BIOCHEMICAL
in distilled
exhibits
AND BIOPHYSICAL
water or buffer
a maximal positive
favorable
rotation
and a maximel negative rotation
at 260 mu.
from those of many globular
Cotton effects
in the ultraviolet
a slight
intensification
proteins,
Inclusion
rotations
complexing
of tryptophan
by N-brqPaosuccinimiae
sunewhat diminishes
260 w, but concentrations reported
to cause little
prolonged
of biotin
treatment
avidin tions
will
probably avidin
Also earlier
including
Addition
of
at both 295 and
hydrochloride
As with
(Green and Melsmed,
rotation
at
at wavelengths below 330 mp.
heated solution
avidin
does not
at room temperature
work has shown that such heat-denatured (Wei
and Wright,
at 85') may disrupt
those involved
1964).
secondary bonding
in the sub-unit
structure
The condiforces, reported
for
(Green, 183~). The heat denaturation
changes in specific The structure
of avidln
rotation
of avidin
temperature,
rapid disruption
BY 85O, extensive
bind biotin
can be followed
at either
remains stable
evidenced by lack of significant
so".
(Green, lg63b).
as the spectrum of native
not complex with biotin
used (15 minutes
impedes oxidation
as high as 9 M have been
in levorotation
reappear upon keeping a previously
elicits
at both 295 and 260 mp.
causes ccmpl.ete loss of the positive
increase
of
from
of avidin (Green, 1963~).
with 6 M gusnidine
These changes are irreversible,
for many hours.
in the solution
by avidin
solute
spectrum is some-
contributions
the dispersion
clenaturation
1966), heat denaturation 295 ~I.L and a large
of this
at 287 w
high in I,-tryptophan
of biotin
It has been shown that
8 M urea to avidin
of biotin
but the positions
reflect
reportedly
of specific
residues
The overall
expectedly
amino acid composition,
(Melamed and Green, 1963).
for binding
at 295 w with a shoulder
what different
the aromatic
RESEARCH COMMUNICATIONS
readily
295 or 260 m/~ as shown in Fig. 2. at temperatures
below 70" as
change in the ORD spectrum. of structure
loss of the original.
are found.
526
by the
Above this
occurs with an apparent structure
end ability
'Ihr of to
BIOCHEMICAL
Vol. 25, No. 5, 1966
The effect of avidin
concentration
is shown in Fig.
protection
of avidin
irreversibly required
of biotin
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3.
on preventing
All concentrations
of biotin
when heated at a temperature
denature this
protein
for a 1:1molecuJer
alone.
heat denaturation effect
(85’) sufficient
Increasing
the level
to to that
ccmplex affords maximum protection,
higher
concentrations
of biotin
biotin
complex remains stable
do not alter until
this
temperatures
some
situation.
and The avidin-
near that of boiling
water are reached. Fig.
2
Fig.
3
+300-
0
o-
p-,"-" X 295
ol ‘0 x
-3oo-
70
-200
t 0/
my
,
2. -500
-
-900
-
-6OOv I 30
I 50
‘C
I 70
8 90
d
0
1
1
2.0 Moles
I
I
I
4.0 BiotinlMole
I
60 Avidin
Fig. 2. Heat denaturation of avidin as measured by ORB changes at two wavelengths. Fig. 3. Effect of biotin concentration on preventing the heat denaturation of avidin at 85O as measured by ORB changes at two wavelengths.
Acknowledgments We wish to express our appreciation Scheraga for providing
to John Vournakis
and Harold
equipment and assistance.
References Eahin,
R. E., gnell,
801 (@a).
E. E., and Williams,
Green, N. MO, Biochem. J.,, 89, 585 (lsja). Green, N. M., Biochem. J., 3, 5gg (lg63b).
527
R. J., J. Biol.
Ghan., l&
Vol. 25, No. 5, 1966
BIOCHEMICAL
AND BlOPHYSlCAL
RESEARCH COMMUNICATIONS
Green, N. M., Biochem. J., B, 609 (1963~). Green, N. M., and Melsmed, M. D., Biochem. J., 100, 614 (1966). Gyi%v, P*, and Rose, C. S., Proc. Sot. Exptl. xl. Med., 2, 55 (1943). Gyijrfg, P., Rose, C. S., and !I!omarUi, R., proc. Sot. Exptl. Biol. Med., 3, 169 (1942). McComlck, D. B., Anal. Biochem., 13, 194 (1965). Melsmed, M. D., and Green, N. M., xochem. J., 2, 591 (1963). Pai, C. H., and Lichstein, H. C., Proc. Sot. Exptl. Biol. Med., -~6, 197 (1964). Wei, R. D., and Wright, L. I)., Proc. Sot. Exptl. Biol. Med., 117, 341 0964).
528
Vol. 25, No. 5, 1966
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
OPTICAL ROTATORYDISPERSION STUDIES OF THE HEAT DFJVATURATION OF AVIDIN AND TRE AVIDIN-BIOTIN Alan B. Pritchard,
Donald B. McCormick,
C@PLEX* and Lemuel D. Wright
Graduate School of Nutrition and Biochemistry Section, Division of Biological. Sciences, Cornell University, Ithaca, New York
Received October 31, 1966
Avidin, biotin
a protein
to yield
(Green, 1963a). stable
isolated
a complex with a dissociation The avidin-biotin
toward proteolytic
pH range (Eakin, 1942).
Snell,
of biotin
and Willisms, solutions
1964; Pai and Lichstein,
exhibits
and positive visible
at 285 mp.
region.
complexing
prominent
from its
complex
but the increased
of high ionic
strength
affinity affords
the complex with heat (Wei and
(Green and Melsmed, 1966), rotatory
Cotton effects
dispersion
the
(ORD) spectrum
which are negative
The curve approximates
The ORD spectrum of avidin
with biotin,
biotin
1964).
study shows that the optical.
of avidin
l*O),
toward disrupting
In agreement with a recent report present
as 10 -15 M
reported
1940; GyUrgy, Rose, and Tomsrelli,
was shown to release
in buffer
protection
constant
with
complex has been shown to be relatively
and Williams,
Snell,
for avidin
considerable Wright,
(Eakin,
combines firmly
enzymes (Gyisrgy and Rose, 1943) and over a wide
Steam sterilization
with avidin
from egg white,
zero rotation
is not markedly
at 245 ml.r into
changed upon
and only moderate changes occur in 8 M urea.
*This work was supported by N.I.H.
Grant No. AM-08721.
524
the
BIOCHEMICAL
Vol. 25, No. 5, 1966
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
However, we have now found that heating causes a precipitous
reversible
of avidin
above 80'
below 330 mn reflecting
increase in levorotation
denaturation
solutions
which can be prevented by complexing
ir-
with bioti.n.
Experimental CrystsLiine Biochemicsls
D-biotin
Corp.
and crude avidin
The avidin
carboxymethyl-cellulose (McCormick,
The ORD measurements were obtained with a thermostated
Spectra were determined temperatures of avidin without
by chromatography
on
(Melsmed and Green, 1963) and biotin-cellulose
1965).
Spectropolarkneter
was purified
were purchased from Nutritional
at room temperature
as specified. (0.5 mg/ml)
urea or biotin
Solutions
compartment and 2.5 cm cells. or after 15 minutes
contained
in Nf$OH-NHbC1 buffer
a constant
at such
concentration
(pH p, n = 1) tith
and
as specified. Results
The ORD spectra of native 8 M urea, and heat-denatured
+200-
cell
using a Cery 60
and Discussion avidin,
avidin
avidin-biotin are shown in Fig.
complex, avidin 1.
A
I 250
I 270
290
I 310
x w
Fig. 1. ORD spectra of avidin in buffer (o), with 2.9 x 10V5 M biotin (A), in 8 M urea (o), and when heated at 85O (0).
525
with
Vol. 25, No. 5, 1966
Avidin
BIOCHEMICAL
in distilled
exhibits
AND BIOPHYSICAL
water or buffer
a maximal positive
favorable
rotation
and a maximel negative rotation
at 260 mu.
from those of many globular
Cotton effects
in the ultraviolet
a slight
intensification
proteins,
Inclusion
rotations
complexing
of tryptophan
by N-brqPaosuccinimiae
sunewhat diminishes
260 w, but concentrations reported
to cause little
prolonged
of biotin
treatment
avidin tions
will
probably avidin
Also earlier
including
Addition
of
at both 295 and
hydrochloride
As with
(Green and Melsmed,
rotation
at
at wavelengths below 330 mp.
heated solution
avidin
does not
at room temperature
work has shown that such heat-denatured (Wei
and Wright,
at 85') may disrupt
those involved
1964).
secondary bonding
in the sub-unit
structure
The condiforces, reported
for
(Green, 183~). The heat denaturation
changes in specific The structure
of avidln
rotation
of avidin
temperature,
rapid disruption
BY 85O, extensive
bind biotin
can be followed
at either
remains stable
evidenced by lack of significant
so".
(Green, lg63b).
as the spectrum of native
not complex with biotin
used (15 minutes
impedes oxidation
as high as 9 M have been
in levorotation
reappear upon keeping a previously
elicits
at both 295 and 260 mp.
causes ccmpl.ete loss of the positive
increase
of
from
of avidin (Green, 1963~).
with 6 M gusnidine
These changes are irreversible,
for many hours.
in the solution
by avidin
solute
spectrum is some-
contributions
the dispersion
clenaturation
1966), heat denaturation 295 ~I.L and a large
of this
at 287 w
high in I,-tryptophan
of biotin
It has been shown that
8 M urea to avidin
of biotin
but the positions
reflect
reportedly
of specific
residues
The overall
expectedly
amino acid composition,
(Melamed and Green, 1963).
for binding
at 295 w with a shoulder
what different
the aromatic
RESEARCH COMMUNICATIONS
readily
295 or 260 m/~ as shown in Fig. 2. at temperatures
below 70" as
change in the ORD spectrum. of structure
loss of the original.
are found.
526
by the
Above this
occurs with an apparent structure
end ability
'Ihr of to
BIOCHEMICAL
Vol. 25, No. 5, 1966
The effect of avidin
concentration
is shown in Fig.
protection
of avidin
irreversibly required
of biotin
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3.
on preventing
All concentrations
of biotin
when heated at a temperature
denature this
protein
for a 1:1molecuJer
alone.
heat denaturation effect
(85’) sufficient
Increasing
the level
to to that
ccmplex affords maximum protection,
higher
concentrations
of biotin
biotin
complex remains stable
do not alter until
this
temperatures
some
situation.
and The avidin-
near that of boiling
water are reached. Fig.
2
Fig.
3
+300-
0
o-
p-,"-" X 295
ol ‘0 x
-3oo-
70
-200
t 0/
my
,
2. -500
-
-900
-
-6OOv I 30
I 50
‘C
I 70
8 90
d
0
1
1
2.0 Moles
I
I
I
4.0 BiotinlMole
I
60 Avidin
Fig. 2. Heat denaturation of avidin as measured by ORB changes at two wavelengths. Fig. 3. Effect of biotin concentration on preventing the heat denaturation of avidin at 85O as measured by ORB changes at two wavelengths.
Acknowledgments We wish to express our appreciation Scheraga for providing
to John Vournakis
and Harold
equipment and assistance.
References Eahin,
R. E., gnell,
801 (@a).
E. E., and Williams,
Green, N. MO, Biochem. J.,, 89, 585 (lsja). Green, N. M., Biochem. J., 3, 5gg (lg63b).
527
R. J., J. Biol.
Ghan., l&
Vol. 25, No. 5, 1966
BIOCHEMICAL
AND BlOPHYSlCAL
RESEARCH COMMUNICATIONS
Green, N. M., Biochem. J., B, 609 (1963~). Green, N. M., and Melsmed, M. D., Biochem. J., 100, 614 (1966). Gyi%v, P*, and Rose, C. S., Proc. Sot. Exptl. xl. Med., 2, 55 (1943). Gyijrfg, P., Rose, C. S., and !I!omarUi, R., proc. Sot. Exptl. Biol. Med., 3, 169 (1942). McComlck, D. B., Anal. Biochem., 13, 194 (1965). Melsmed, M. D., and Green, N. M., xochem. J., 2, 591 (1963). Pai, C. H., and Lichstein, H. C., Proc. Sot. Exptl. Biol. Med., -~6, 197 (1964). Wei, R. D., and Wright, L. I)., Proc. Sot. Exptl. Biol. Med., 117, 341 0964).
528