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Spin assay as a general method for studying plasma protein binding. Bilirubin — Albumin binding
Vol. 76, No. 3, 1977
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
SPIN ASSAY AS A GENERAL METHOD FOR STUDYING PLASMA PROTEIN BINDING. BILIRUBIN
D.J.
- ALBUMIN BINDING
Wood and J.C.
Hsia
Department of Pharmacology Faculty of Medicine University of Toronto Toronto, Canada M5S lA8
Received
April
22,1977
Summary. The binding of a spin label to pre-existing binding sites of a protein can be monitored by electron spin resonance spectroscopy and can be interpreted in terms of a spin assay for any ligand which shares these sites. As an example of this procedure, a method is presented which evaluates the reserve capacity of the bilirubin high affinity binding site of human serum albumin for additional bilirubin binding. Hyperbilirubinemia in pre-mature or low-birth-weight term infants can result in severe neurological damage. The maturation of this technique will provide a needed clinical assay in the management of jaundiced newborn infants. Hyperbilirubinemia can result
in
and in severe the
cases,
(1,2).
to the
site
% 10 a
(4);
capacity for
the
high
There
Copyright All rights
and hold,
uptake
into
site.
This
is is
site
site
is
and the with
and thus
the
binding
reserve
generally
termed
the
produced
by
blood albumin
one high
(HSA)
affinity
sites
(Ka s 10 5 litres/
taken
as a measure
much greater
secondary
bilirubin
the tissues
retardation,
circulating
to involve
due to its
tissues
1) is
human serum
of secondary
bilirubin
affinity
serum,
neonates
and motor
in the
thought
affinity
to the body
detoxification
affinity
capacity
for
in the
of the high
loss
detoxified
and number
of the high
available
is
or premature
(see Figure
to HSA is
litres/mole)
compared
bilirubin
Bilirubin
protein
of bilirubin
of HSA to bind,
The saturation
for
predominant
capacity
bilirubin,
being
death
of haem and normally
The binding
mole)
low-birth-weight
damage such as hearing
(3).
(Ka
in
neurological
catabolism
by binding
(jaundice)
sites
results the
reserve
affinity
(5).
in bilirubin
critical
capacity
of the
parameter
of the bilirubin bilirubin
binding
(RBBC). have been a number
0 I977 by Academic Press, Inc. of reproduction in an\’ form reserved.
of methods
proposed
to measure
the bilirubin
863 ISSM 0006-291X
Vol. 76, No. 3, 1977
available
for
affinity
bilirubin
BIOCHEMICAL
binding
to the tissues binding
index'(13-17).
experimentally
In addition,
optical
amount
in simulated
due to the
species. the
Also,
observed
Because
the
reserve
capacity
a spin affinity
probe
binding
are
application,
is
Figure free
separating are
distinct
calibration itself,
a detectable read,
The spin
1) so that
the
free
that
probe
the
label
from bound
and their free
can be easily with
standards
the
of the augment
spectral
understood
using
to measure
electron
technique.
spin
We propose
capacity
that
of the high
quantifiable. esr
contains
The spectra
to be
a method
method
can be tailor-made
can be determined
peak height
site
to the
compound
label.
that
here
the
of
can variably
and poorly
sense
is paramagnetic.
concentrations
straightforward,
of determining for
a nitroxyl
The amount without of the
moiety of label
which
physically free
determined (22,23).
a particular
and bound through The esr
labels a
instrument
requiring
concentration
sample-out"
label
samples
suggested
be easily
concentration
state
labeling
advantages
to macromolecule
of the is
of unique
only
the
and yet
the
to quantitate
to the binding
affinity
will
of serum.
tend
we present
which
volumes
required
complicated
spin
(4,7,18-20)
measurements
the
been
high
and the
site
requiring
or bound
a very
can be designed
parameters.
in
difficulties,
(esr)
a number
spectrum
has recently are
binding
These
species
of the bilirubin
bilirubin There
It
of these
spectroscopy label
other
of bilirubin
(21).
studies.
an "RBBC
criticized
large
usually
by the high
evaluate
or to measure
of the
from
which
require are
present
binding
absorbances.
area
resonance
is
insensitivity
spectra
characteristics
(see
which
contained
have been
and/or
measurements
RESEARCH COMMUNICATIONS
not
methods
procedures
complex
density
(i.e.
(6-12)
and also
of these
of bilirubin
any dyes used complex
site)
A number
and many are
the
AND BIOPHYSICAL
range
no day-to-day adjustments, lo-25 ul samples, -7 -6 down to 10 - 10 Molar and a 'sample-in,
procedure. MATERIALS
AND METHODS
Fraction V human serum albumin was obtained from the Sigma Chemical Co., St. Louis, MO., U.S.A. Bilirubin was also obtained from Sigma and further purified by the method of Fog (24). All procedures involving bilirubin were
864
BIOCHEMICAL
Vol. 76, No. 3, 1977
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
COOH
HOOC
BILIRUBIN
HOOC-CCH-C-COOH
TOPS
Figure
1
Structural formula oxyl&piperidylidene
of bilirubin succinic
and 2,2,6,6, acid (TOPS)
- tetramethyl-l-
A spin labeled probe, 2,2,6,6-tetramethylcarried-out in reduced light. l-oxyl-4-piperidylidene succinic acid (TOPS , see Figure 1) was synthesized by the method of Rozantsev (25). The experimental samples (100 ul) were prepared by the combination of aqueous stock solutions of TOPS, HSA and bilirubin disodium salt with a 50 ul Hamilton syringe. After vortex mixing, 25 ul of the sample was transfered to a 25 ul Micro et disposable pipette (Becton, which was used for the esr Dickinson and Company, Parsippany, N.J., T&-F The esr spectra of these samples consists of a sharp first-derivative sample. triplet due to the TOPS which is not protein bound, superimposed on a number of broad resonances near the baseline due to the TOPS which is bound to the The concentration of the TOPS which is free in solution is protein (22). proportional to the height of the high-field peak of the triplet and the proportionality can be determined through the use of standards of TOPS in 100 mM phosphate buffer. Since the total amount of added TOPS is known, the concentration of TOPS that is bound to HSA can easily be determined. The esr spectra were recorded on a Varian E6 X-band esr spectrometer at 20 t 1'C. The use of the thin capillary disposable pipettes and a variable temperature Dewar insert (J.F. Scanlon Co.) permits the recording of an entire series of samples without the need to change instrument conditions. The estimated error in these measurements under these conditions is less than 1%. Including pipetting and the other facets of sample preparation, the estimated accuracy of these measurement is 2 3%. RESULTS AND DISCUSSION TOPS was chosen similarity it
is
specific
with readily binding
for
this
bilirubin. water
soluble.
of the label
study
because
since
Furthermore, This
of the
considerably
to HSA.
865
dicarboxylic
TOPS is reduces
a small
acid polar
secondary
structural molecule,
and non-
BIOCHEMICAL
Vol. 76, No. 3, 1977
0
AND BIOPHYSICAL
10
5
2
The binding of TOPS and phosphate buffer at pH added TOPS, [TOPS] is bound [TOPSIP, for*Aodel equivalents (bilirubin of bilirubin (A ).
The proposal
that
2.
These
(not
shown)
are
with
an association
Figure
primarily
is
the shared
consistent constant
total
protein. with
Figure
constants
of bilirubin
interpretation
one,
binding
is
illustrates addition
and TOPS, this between
bilirubin
curve
of bilirubin
(bilirubin
given
displaced.
in Figure
the
the
The addition
to HSA) results This
in all
suggests
that
866
but not
label
site(s)
differing
affinity
expected.
and TOPS for
3.
of the
of bilirubin
same sites
of TOPS to HSA of one to one (27)) is more clearly
displacement
For TOPS
TOPS binding
Considering is
is
one.
binding
equivalents
inhibition
in
to albumin
binding
of around
the
given
TOPS binds
a partition
of 2.3
data
of the binding
and this
that
of TOPS to HSA.
(26) that
litres/mole
there
by the
analysis
TOPS to HSA ratios
as the
The competition
of TOPS being
the
2 also
bilirubin
inhibits
a solution
than
confirmed
a Scatchard
of 2, lo3
much greater
completely
(for
with
for
to HSA is
with
)
albumin is model sera (5 x 10 -4 HSA in 100 mM of 7.4). Total molar concentration of plotted against the molar concentration of sera with no bilirubin ( n ), with 1.1 to HSA) of bilirubin (W) and 2.3 equivalents
TOPS binds along
to one site
to HSA ratios with
data
20
15 [ M x lo4
[ TOPS],
Figure
RESEARCH COMMUNICATIONS
on HSA seen in the
of % 1.4 equivalents a four only
are
percent the
background
same sites
BIOCHEMICAL
Vol. 76, No. 3, 1977
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
.
[ Bilirubin],/[HSA]
Figure
3
Displacem nt of TOPS from HSA by bilirubin. The HSA concentration . 100 mM phosphate 4.7 x lo- EM in buffer at a pH of 7.4. The TOPS concentration is 5 x 10-4M. The square brackets denote molar concentrations.
shared
butthe
site.
Extrapolations
intersect
primary
site
of the
linear
at a bilirubin
can be interpreted to its
shared
high site.
binding
of TOPS to HSA is is
affinity
site
(free
that
the
first
four
high
sensing
and since
the
molecules
investigation
for
at the
an RBBC assay
present
curve This
equivalent
affinity
capacity
behaviour of bilirubin
of TOPS from binding
background
binding,
binding
the
site.
of the bilirubin
we can accurately
of TOPS, TOPS and molecules
probe
one.
exclusion
percent
binding
displacement
added the
to the bilirubin TOPS is
bilirubin
of approximately
of the
for
affinity of the
and consequently,
except
on albumin
or bound)
suitable this
Hence,
apparent
portions
binding
site
to this
It
the high
to HSA ratio
as the
affinity
is
follow
of similar of newborn
the binding
structure sera.
high
will
state be
We are involved
time.
ACKNOWLEDGEMENTS Financial is Dr. T.E.
support
gratefully
acknowledged.
G.W. Chance Eagles
preparation
from the
for
of the Hospital many helpful
Ontario
We would for
Ministry also
Sick
discussions
like
of Health to express
Children, and to Dr.
of TOPS. 867
is
Toronto,
(Grant our
gratitude
Canada
R. Schwenk
#PR-524)
for
and Dr. the
to
in
Vol. 76, No. 3, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. lg. 20. 21. 22. 23. 24. 25. 26. 27.
Cowger, M.L. (1971) Biochem. Med., 2, 1-1.6. Amanullah, A. (1976) Am. J. of Diseases of Children, z, 1274-1280. Odell, G.B., Storey, G.N.B., and Rosenberg, L.A. (1970) J. of Pediatr., 76, 12-21. Jacobsen, J., and Wennberg, R.P. (1974) Clin. Chem,,z, 78X-789. Wosilait, W.D. (1974) Life Sci., I&, 2189-2198. Jirsova, V., Jirsa, M., Heringova, A., Koldovsky, O., and Weichova, J. (1967) Biol. Neonatorum, 11, 204-208. Chan, G., Schiff, D., and Stern, L. (1971) Clin. Biochem., &, 208-214. Kapitulnik, J., Vdaes, T., Kaufman, N.A., and Blondheim, S.H. (1974) Arch. Dis. Childhood, 49, 886-894. Chunga, F., and Lardinois, R. (1971) Acta Paedit. Stand., 60, 27-32. Pays, M., and Beljean, M. (1975) Clin. Chim. Acta, z, 121-128. Athanassidis, S., Chopra, D.R., Fisher, M.A., and McKenna, J. (1974) J. Lab. Clin. Meth., 83, 968-976. Bratlid, D. (1972) Stand. J. Clin. Lab. Invest., 3, 91-97. Odell, G.B., Cohen, S.N., and Kelly, P.C. (1969) J. Pediatr., &, 214-230. McClusky, S.B., Storey, G.N.B., Brown, G.K., More, D.G., and O'Sullivan, W.J. (1975) Clin. Chem., 21, 1638-1643. Lee, K-S., Gartner, L.M., and Zarafu, I. (1975) J. Pediatr., 86, 280-285 Bjerrum, O.J. (1968) Stand. J. Clin. Lab. Invest., 22, 41-48. Porter, E.G., and Waters, W.J. (1966) J. Lab. Clin. Med., 67, 660-668. Lucey, J.F., Valaes, T., and Doxiadis, S.A. (1967) Pediatrics, 2, 867-883. Krasner, J., and Chignell, C.F. (1975) J. Pediatr., 5, lOO8-1009. Levine, R.L. (1976) Clin. Chem., 22, 560-561. Lee, K-S., and Gartner, L.M. (1976) Pediatr. Res., lo, 782-788. Hsia, J.C., Wong, L.T.L., and Kalow, W. (1973) J. Immunol. Meth., 3, 17-24. Copeland, E.S., and DeBaare, L. (1976) Biophys. J., 16, 1245-1255. Fog, J. (1964) Stand. J. Clin. Lab. Invest., l&, 49-5. Rozantsev, E.G. (1970) Free Nitroxyl Radicals, pp. 219-220, Plenum Press, London. Scatchard, G. (1949) Ann. N.Y. Acad. Sci., 2, 660-672. A similar result is obtained for solutions of TOPS to HSA of two to one. This collaborates the interpretation of the one to one displacement data and indicates that an exact stoichiometric ratio of TOPS and HSA is not required for the displacement phenomenon.
868
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
SPIN ASSAY AS A GENERAL METHOD FOR STUDYING PLASMA PROTEIN BINDING. BILIRUBIN
D.J.
- ALBUMIN BINDING
Wood and J.C.
Hsia
Department of Pharmacology Faculty of Medicine University of Toronto Toronto, Canada M5S lA8
Received
April
22,1977
Summary. The binding of a spin label to pre-existing binding sites of a protein can be monitored by electron spin resonance spectroscopy and can be interpreted in terms of a spin assay for any ligand which shares these sites. As an example of this procedure, a method is presented which evaluates the reserve capacity of the bilirubin high affinity binding site of human serum albumin for additional bilirubin binding. Hyperbilirubinemia in pre-mature or low-birth-weight term infants can result in severe neurological damage. The maturation of this technique will provide a needed clinical assay in the management of jaundiced newborn infants. Hyperbilirubinemia can result
in
and in severe the
cases,
(1,2).
to the
site
% 10 a
(4);
capacity for
the
high
There
Copyright All rights
and hold,
uptake
into
site.
This
is is
site
site
is
and the with
and thus
the
binding
reserve
generally
termed
the
produced
by
blood albumin
one high
(HSA)
affinity
sites
(Ka s 10 5 litres/
taken
as a measure
much greater
secondary
bilirubin
the tissues
retardation,
circulating
to involve
due to its
tissues
1) is
human serum
of secondary
bilirubin
affinity
serum,
neonates
and motor
in the
thought
affinity
to the body
detoxification
affinity
capacity
for
in the
of the high
loss
detoxified
and number
of the high
available
is
or premature
(see Figure
to HSA is
litres/mole)
compared
bilirubin
Bilirubin
protein
of bilirubin
of HSA to bind,
The saturation
for
predominant
capacity
bilirubin,
being
death
of haem and normally
The binding
mole)
low-birth-weight
damage such as hearing
(3).
(Ka
in
neurological
catabolism
by binding
(jaundice)
sites
results the
reserve
affinity
(5).
in bilirubin
critical
capacity
of the
parameter
of the bilirubin bilirubin
binding
(RBBC). have been a number
0 I977 by Academic Press, Inc. of reproduction in an\’ form reserved.
of methods
proposed
to measure
the bilirubin
863 ISSM 0006-291X
Vol. 76, No. 3, 1977
available
for
affinity
bilirubin
BIOCHEMICAL
binding
to the tissues binding
index'(13-17).
experimentally
In addition,
optical
amount
in simulated
due to the
species. the
Also,
observed
Because
the
reserve
capacity
a spin affinity
probe
binding
are
application,
is
Figure free
separating are
distinct
calibration itself,
a detectable read,
The spin
1) so that
the
free
that
probe
the
label
from bound
and their free
can be easily with
standards
the
of the augment
spectral
understood
using
to measure
electron
technique.
spin
We propose
capacity
that
of the high
quantifiable. esr
contains
The spectra
to be
a method
method
can be tailor-made
can be determined
peak height
site
to the
compound
label.
that
here
the
of
can variably
and poorly
sense
is paramagnetic.
concentrations
straightforward,
of determining for
a nitroxyl
The amount without of the
moiety of label
which
physically free
determined (22,23).
a particular
and bound through The esr
labels a
instrument
requiring
concentration
sample-out"
label
samples
suggested
be easily
concentration
state
labeling
advantages
to macromolecule
of the is
of unique
only
the
and yet
the
to quantitate
to the binding
affinity
will
of serum.
tend
we present
which
volumes
required
complicated
spin
(4,7,18-20)
measurements
the
been
high
and the
site
requiring
or bound
a very
can be designed
parameters.
in
difficulties,
(esr)
a number
spectrum
has recently are
binding
These
species
of the bilirubin
bilirubin There
It
of these
spectroscopy label
other
of bilirubin
(21).
studies.
an "RBBC
criticized
large
usually
by the high
evaluate
or to measure
of the
from
which
require are
present
binding
absorbances.
area
resonance
is
insensitivity
spectra
characteristics
(see
which
contained
have been
and/or
measurements
RESEARCH COMMUNICATIONS
not
methods
procedures
complex
density
(i.e.
(6-12)
and also
of these
of bilirubin
any dyes used complex
site)
A number
and many are
the
AND BIOPHYSICAL
range
no day-to-day adjustments, lo-25 ul samples, -7 -6 down to 10 - 10 Molar and a 'sample-in,
procedure. MATERIALS
AND METHODS
Fraction V human serum albumin was obtained from the Sigma Chemical Co., St. Louis, MO., U.S.A. Bilirubin was also obtained from Sigma and further purified by the method of Fog (24). All procedures involving bilirubin were
864
BIOCHEMICAL
Vol. 76, No. 3, 1977
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
COOH
HOOC
BILIRUBIN
HOOC-CCH-C-COOH
TOPS
Figure
1
Structural formula oxyl&piperidylidene
of bilirubin succinic
and 2,2,6,6, acid (TOPS)
- tetramethyl-l-
A spin labeled probe, 2,2,6,6-tetramethylcarried-out in reduced light. l-oxyl-4-piperidylidene succinic acid (TOPS , see Figure 1) was synthesized by the method of Rozantsev (25). The experimental samples (100 ul) were prepared by the combination of aqueous stock solutions of TOPS, HSA and bilirubin disodium salt with a 50 ul Hamilton syringe. After vortex mixing, 25 ul of the sample was transfered to a 25 ul Micro et disposable pipette (Becton, which was used for the esr Dickinson and Company, Parsippany, N.J., T&-F The esr spectra of these samples consists of a sharp first-derivative sample. triplet due to the TOPS which is not protein bound, superimposed on a number of broad resonances near the baseline due to the TOPS which is bound to the The concentration of the TOPS which is free in solution is protein (22). proportional to the height of the high-field peak of the triplet and the proportionality can be determined through the use of standards of TOPS in 100 mM phosphate buffer. Since the total amount of added TOPS is known, the concentration of TOPS that is bound to HSA can easily be determined. The esr spectra were recorded on a Varian E6 X-band esr spectrometer at 20 t 1'C. The use of the thin capillary disposable pipettes and a variable temperature Dewar insert (J.F. Scanlon Co.) permits the recording of an entire series of samples without the need to change instrument conditions. The estimated error in these measurements under these conditions is less than 1%. Including pipetting and the other facets of sample preparation, the estimated accuracy of these measurement is 2 3%. RESULTS AND DISCUSSION TOPS was chosen similarity it
is
specific
with readily binding
for
this
bilirubin. water
soluble.
of the label
study
because
since
Furthermore, This
of the
considerably
to HSA.
865
dicarboxylic
TOPS is reduces
a small
acid polar
secondary
structural molecule,
and non-
BIOCHEMICAL
Vol. 76, No. 3, 1977
0
AND BIOPHYSICAL
10
5
2
The binding of TOPS and phosphate buffer at pH added TOPS, [TOPS] is bound [TOPSIP, for*Aodel equivalents (bilirubin of bilirubin (A ).
The proposal
that
2.
These
(not
shown)
are
with
an association
Figure
primarily
is
the shared
consistent constant
total
protein. with
Figure
constants
of bilirubin
interpretation
one,
binding
is
illustrates addition
and TOPS, this between
bilirubin
curve
of bilirubin
(bilirubin
given
displaced.
in Figure
the
the
The addition
to HSA) results This
in all
suggests
that
866
but not
label
site(s)
differing
affinity
expected.
and TOPS for
3.
of the
of bilirubin
same sites
of TOPS to HSA of one to one (27)) is more clearly
displacement
For TOPS
TOPS binding
Considering is
is
one.
binding
equivalents
inhibition
in
to albumin
binding
of around
the
given
TOPS binds
a partition
of 2.3
data
of the binding
and this
that
of TOPS to HSA.
(26) that
litres/mole
there
by the
analysis
TOPS to HSA ratios
as the
The competition
of TOPS being
the
2 also
bilirubin
inhibits
a solution
than
confirmed
a Scatchard
of 2, lo3
much greater
completely
(for
with
for
to HSA is
with
)
albumin is model sera (5 x 10 -4 HSA in 100 mM of 7.4). Total molar concentration of plotted against the molar concentration of sera with no bilirubin ( n ), with 1.1 to HSA) of bilirubin (W) and 2.3 equivalents
TOPS binds along
to one site
to HSA ratios with
data
20
15 [ M x lo4
[ TOPS],
Figure
RESEARCH COMMUNICATIONS
on HSA seen in the
of % 1.4 equivalents a four only
are
percent the
background
same sites
BIOCHEMICAL
Vol. 76, No. 3, 1977
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
.
[ Bilirubin],/[HSA]
Figure
3
Displacem nt of TOPS from HSA by bilirubin. The HSA concentration . 100 mM phosphate 4.7 x lo- EM in buffer at a pH of 7.4. The TOPS concentration is 5 x 10-4M. The square brackets denote molar concentrations.
shared
butthe
site.
Extrapolations
intersect
primary
site
of the
linear
at a bilirubin
can be interpreted to its
shared
high site.
binding
of TOPS to HSA is is
affinity
site
(free
that
the
first
four
high
sensing
and since
the
molecules
investigation
for
at the
an RBBC assay
present
curve This
equivalent
affinity
capacity
behaviour of bilirubin
of TOPS from binding
background
binding,
binding
the
site.
of the bilirubin
we can accurately
of TOPS, TOPS and molecules
probe
one.
exclusion
percent
binding
displacement
added the
to the bilirubin TOPS is
bilirubin
of approximately
of the
for
affinity of the
and consequently,
except
on albumin
or bound)
suitable this
Hence,
apparent
portions
binding
site
to this
It
the high
to HSA ratio
as the
affinity
is
follow
of similar of newborn
the binding
structure sera.
high
will
state be
We are involved
time.
ACKNOWLEDGEMENTS Financial is Dr. T.E.
support
gratefully
acknowledged.
G.W. Chance Eagles
preparation
from the
for
of the Hospital many helpful
Ontario
We would for
Ministry also
Sick
discussions
like
of Health to express
Children, and to Dr.
of TOPS. 867
is
Toronto,
(Grant our
gratitude
Canada
R. Schwenk
#PR-524)
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Vol. 76, No. 3, 1977
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. lg. 20. 21. 22. 23. 24. 25. 26. 27.
Cowger, M.L. (1971) Biochem. Med., 2, 1-1.6. Amanullah, A. (1976) Am. J. of Diseases of Children, z, 1274-1280. Odell, G.B., Storey, G.N.B., and Rosenberg, L.A. (1970) J. of Pediatr., 76, 12-21. Jacobsen, J., and Wennberg, R.P. (1974) Clin. Chem,,z, 78X-789. Wosilait, W.D. (1974) Life Sci., I&, 2189-2198. Jirsova, V., Jirsa, M., Heringova, A., Koldovsky, O., and Weichova, J. (1967) Biol. Neonatorum, 11, 204-208. Chan, G., Schiff, D., and Stern, L. (1971) Clin. Biochem., &, 208-214. Kapitulnik, J., Vdaes, T., Kaufman, N.A., and Blondheim, S.H. (1974) Arch. Dis. Childhood, 49, 886-894. Chunga, F., and Lardinois, R. (1971) Acta Paedit. Stand., 60, 27-32. Pays, M., and Beljean, M. (1975) Clin. Chim. Acta, z, 121-128. Athanassidis, S., Chopra, D.R., Fisher, M.A., and McKenna, J. (1974) J. Lab. Clin. Meth., 83, 968-976. Bratlid, D. (1972) Stand. J. Clin. Lab. Invest., 3, 91-97. Odell, G.B., Cohen, S.N., and Kelly, P.C. (1969) J. Pediatr., &, 214-230. McClusky, S.B., Storey, G.N.B., Brown, G.K., More, D.G., and O'Sullivan, W.J. (1975) Clin. Chem., 21, 1638-1643. Lee, K-S., Gartner, L.M., and Zarafu, I. (1975) J. Pediatr., 86, 280-285 Bjerrum, O.J. (1968) Stand. J. Clin. Lab. Invest., 22, 41-48. Porter, E.G., and Waters, W.J. (1966) J. Lab. Clin. Med., 67, 660-668. Lucey, J.F., Valaes, T., and Doxiadis, S.A. (1967) Pediatrics, 2, 867-883. Krasner, J., and Chignell, C.F. (1975) J. Pediatr., 5, lOO8-1009. Levine, R.L. (1976) Clin. Chem., 22, 560-561. Lee, K-S., and Gartner, L.M. (1976) Pediatr. Res., lo, 782-788. Hsia, J.C., Wong, L.T.L., and Kalow, W. (1973) J. Immunol. Meth., 3, 17-24. Copeland, E.S., and DeBaare, L. (1976) Biophys. J., 16, 1245-1255. Fog, J. (1964) Stand. J. Clin. Lab. Invest., l&, 49-5. Rozantsev, E.G. (1970) Free Nitroxyl Radicals, pp. 219-220, Plenum Press, London. Scatchard, G. (1949) Ann. N.Y. Acad. Sci., 2, 660-672. A similar result is obtained for solutions of TOPS to HSA of two to one. This collaborates the interpretation of the one to one displacement data and indicates that an exact stoichiometric ratio of TOPS and HSA is not required for the displacement phenomenon.
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