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Peroxide binding to the type 3 site in Rhus vernicifera laccase depleted of type 2 copper
Vol. 108, No. 1, 1982 September
8lOCHEMlCAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
16, 1982
Pages
273-278
PEROXIDE BINDING TO THE TYPE 3 SITE IN RHUS VERNICIFERA LACCASE DEPLETED OF TYPE 2 COPPER 0.
Farver,
P. Frank
and I.
Pecht*
Department of Chemical Immunology The Weizmann Institute of Science Rehovot, Israel Received
July
19,
1982
between hydrogen peroxide and oxidized SUMMARY: The interaction Rhus vernicifera lactase from which the type 2 copper has been For that end, the circular dichroic removed, was investigated. spectrum of the modiliied enzyme has been-measured in the presence of increasing concentrations of hydrogen peroxide. The characteristic band observed upon binding peroxide to native lactase is also observed for the type 2 copper depleted enzyme. However, there are several quantitative differences in the latter one. the intensity is lower and band width is larger. Secondly, First, from the titrations, it becomes apparent that the affinity for While the lower than that of the native native enzyme is higher than 10e3YgY; it decreases for the type 2 depleted enzyme.
INTRODUCTION The reversible vernicifera of
lactase
significant
nature However,
the
its
conflicting features
of the
the
type
for
investigating copper
this (2-5).
2 copper
depleted
reverse;
namely,
(2), that
the
no change
been
while
report takes
which
about
prepared the
(2-5). spectro-
by essentially
330 nm band reported
(T2D)
and the
claimed
is
and structural
interactions
published
place
Rhus
functional
has been
lactase
from
derivative
and their
derivative
3 site
another
2 copper
an enzyme
have
Thus,
type
type
sites
enzyme
oxidized
unaffected
the
produces
reports of
remained
*Currently Chemistry Technology,
of
(l-3)
different
same procedure
istic in
value
of
scopic
removal
character-
to be absent 615 nm band
essentially
at the
the
330 nm band,
a Sherman Fairchild Distinguished Scholar, Division and Chemical Engineering, California Institute of Pasadena, California 91125.
of
0006-291X/82/170273-06$01.00/0 273
Copyright 0 1982 by Academic Press, Inc. All rights of reproduction in any form reserved.
BIOCHEMICAL
Vol. 108, No. 1, 1982
yet
a marked
recently,
decrease
evidence
and at
the
that
the
spectral
with
hydrogen
peroxide
indicated
that
the
3 site
at 615 nm (4).
type
3 site
type
at
this in
More
controversy
T2D is
reduced,
330 nm can be recovered
(5).
In
contrast,
of T2D lactase
other
is
in
by
studies
an oxidized
(2,6). The type
coupled
3 copper
binuclear site
site
shown
has been
affinity
binding
one,
and reduction
complex
(7-11).
interesting detail
in
to bind
reported
to be lost the
interaction spectrum
The near
ultra
provide
removal
of the
latter
of
peroxide, that
a characteristic
evidence
copper
site
in
hemocyanins
and tyrosinase
distinction
between
of peroxide. T2D lactase the native
complex
the
We have for
enzyme,
as evidenced
with
rather
high
The role
of that
(7-13). oxidation
of
that
still
by the
is
characteristic
its
proteins
enables
the
of
titration
shown
as other
site
to to the like
a clear
and its
affinity
binding of
compared forming
in
circular
binding
it
to
enzyme
of
been
decreased capab!-
the
course
copper
although
In order
peroxide
Hence,
some
has been
on the
monitored
as well
in
binding
the
an
of T2D lactase
2 copper.
the
is markedly it
(5)
peroxide type
is
examined
study
for
peroxy-
mechanism
has earlier
lactase
found
peroxide
peroxide
during
CD spectrum
binding this
we have
violet
binuclear
dioxygen
modifications
system
a
form,
and has been
of
is
oxidized
affinity
upon
with
dichroic
native,
mentioned
high
which
as the
reduction
issue,
the
effect
its
hydrogen
above
lactase,
proposed
dioxygen
In the
by H202,
of
(7,8,10).
the
oxidation
examine
In
and important (9-11).
site
has been
and specificity
lactase
of
occurs
features
oxidation
its
RESEARCH COMMUNICATIONS
has been made to resolve
by providing
state
BIOPHYSICAL
in extinction
an attempt
least
AND
the
to that
a peroxy-
CD band.
MATERIALS AND METHODS 7.0,
Lactase and the
solutions protein
were made up in 0.1 M HEPES buffer, concentrations were determined from 274
pH the
Vol. 108, No. 1, 1982
BIOCHEMICAL
AND BIOPHYSICAL
350
Fimre hydrogen
1.
CD-spectra
peroxide.
400
RESEARCH COMMUNICATIONS
450
X krnl of TZD lactase (23 uM) titrated with a) no peroxide; b) 23 uM; c) 115 PM; and added to solution a. All other conditions
absorbance at 615 nm (E = 5700 M-1 cm-l), Type 2 copper depleted lactase was prepared according to the method of Graziani et al (l-3). Its copper content was determined spectrophotometrically with biquinoline. The two, independently prepared samples of T2D lactase studied in this work contained 2.8 and 2.9 Cu ions per mole protein, respectively. In view of changes caused in the molar extinction at 280 nm of T2D lactase, protein concentration was determined by the Lowry method. This showed that while essentially no change occurs in the intensit of the 615 nm band, that at 280 nm increases to Q99700 M- 4: cm-l (6). T2D lactase preparations were oxidized by excess ferricyanide which was removed by extensive dialysis or gel filtration. Protein concentrations examined ranged from 23 to 70 PM. CD spectra were measured in 1 cm cuvettes on a Roussel Jouan Dichrograph III. Data were collected by means of a Tektronix minicomputer averaging 200 measurements per nm.
RESULTS AND DISCUSSION The circular the
near
Namely, are
UV region both
present
The shorter do look
the with
dichroic is
wavelength
similar.
similar
negative close
spectrum
of
to that
oxidized
T2D
of the native
(447 nm) and positive to
the
same intensity
features,
Upon addition
though of 215
H202,
in
enzyme.
(375 nm) bands (cf.
not
lactase
also
too well
changes
in
ref.
2).
resolved, the
region
Vol. 108, No. 1, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Scatchard plot derived from titrations of T2D hydrogen peroxide. L is the concentration of free ligand (H202), and N is-the fraction of complex divided by total enzyme concentration. N is determined at (AE - Ae,)/ AE - AEN) of the 330 nm band'for T2D lacease where AE is the intensity without geroxide, As is the intensity of the same band after addition of a 100 fo r d excess of H202, and AE~ denotes the intensities of the various intermediate peroxide concentration.
300-400 these
nm emerge. changes.
Figure
1 provides
A prominent
band
at 442 nm is unaffected. increases of
From
several
T2D lactase shown
in
such
Figure
near
of
of
330 nm, while
that
the
330 nm band a maximum value
of a hundred
fold
excess
done on two independently plot
of H202 prepared
was constructed
and is
2. of
shown by the
as the
presence
a Scatchard
The formation been
at
illustration
concentration,reaching
titrations,
samples,
appears
The intensity
with peroxide M -1 cm-1 in the
0.75
typical
the
peroxy
regeneration
of both
UV and visible
oxidized
TZD lactase
(6)
followed
by extensive
complex
electronic upon
the
original
This
against
by excess
has
CD as well
and EPR spectrum
reduction
dialysis
is reversible.
of
ascorbate,
ferricyanide
and and
buffer. The negative
CD-band
hydrogen
peroxide
to the
one produced
oxidized
native
formed
to oxidized
T2D lactase
when 1 mole
lactase,
at ~330 nm upon
equivalent
and shown
276
bears
addition close
resemblance
of H202 is added
to be a peroxy-lactase
of
to
Vol. 108, No. 1, 1982
BIOCHEMICAL
complex
Conspicuous
(7,8,11).
increased
width,
of peroxide the
and the
in
order
appearance
dependent
of
is
the
exhibited
by the
binuclear
copper
tyrosinase
sites
that
of a partly
several
reasons:
lactase
was dialyzed
with
H220 experiments
the
Prior
was removed
that
via
that
This
Still,
like
a T2D
spectral
as well
proteins
(6)
equivalents
to the
peroxide a large
feature
as by the
hemocyanins
and
or ascorbate
(14)
required
for
the
maximum
is
T2D
titration
shown
fully
in other
reoxidized
as can be seen in
are
is not the
that
that
complete
affected
bands
at
by
at higher
least
the
type
Finally,
anaerobic
with
benzohydro-
T2D lactase
has shown the
the
We have
beginning. of
for
the
before
demonstrating
sample
of
of ferricyanide
450 nm band
and neither
of a similar
are
excess
T2D lactase
the
as a result
titration,
just
the
at
formed
can be excluded
Secondly,
of
oxidized
is
CD spectra.
(6).
shown),
fully
titrations
enzyme
even reduced
(not
is
new band
reduced
the
of peroxide,
wave length
quinon
indicates
lactase
filtration
intensity
addition
copper
by gel
conditions
1, the
the
against
monitored
these
Figure
other
T2D lactase.
a concentration
produced. of
excess
(12,13).
reoxidation
under
in
in
intensity,
large
band with
clearly
form
a lower
a rather
nm CD band
is indeed
native
RESEARCH COMMUNICATIONS
are
of
that
manner,
The possibility
which
requirement
(-)330
complex
BIOPHYSICAL
differences
to produce
and specific
lactase-peroxy
AND
three
1
electron
reduction
of
the
615 nm
band. Taking full
formation
Scatchard constant (Figure
2).
lactase-peroxide
M-l
cm-l
of a T2D lactase-peroxide
plot of
A& = -0.75
could
10200
M-l
be constructed. a 1:l
complex
In comparison,
the
stability
complex
complex, This
for
was estimated 277
as a measure a linear
yielded
between
a stability the
constant as > 10'
for
reactants for
M-l
the native
(7.8).
Hence,
vol.
108, No. 1, 1982
the
affinity
when the It than
BIOCHEMICAL
of type
is
lactase
that
W region
the
positive
for
T2D lactase
for
native
The same is -0.75
the
M-l
of
cm-'
RESEARCH COMMUNICATIONS
decreases
while
drastically
the
and -0.2 the peroxy native
enzyme,
375 nm is intact
in
the near
significantly
smaller CAE = -0.7 M-1 cm -1
protein M-l
longer
is essentially
oxidized
with
the
at wavelengths
T2D lactase
at
for for
of
CD band
(8,9,11), case
that
the native
compared
lactase
peroxide
to note
CD spectrum
with
BIOPHYSICAL
is missing.
interesting
identical
vs.
towards
2 copper
400 nm, the
AND
cm-l
complexes
for
T2D laccase.1 (AE: = -2.6 M -1 cm -1
and T2D lactase-peroxide
complex,
respectively).
REFERENCES
1. 2. 3. 4. 5. 6. 7. 8. 9.
10. 11. 12. 13. 14.
Graziani, M. T.; Morpurgo, L.; Rotilio, G. and Mondovi, B. (1976) FEBS Lett., 70, 82-90. Morpurgo, L.; Grazizi, M. T.; Finazi-Agro, A.; Rotilio, G.; and Mondovi, B. (1980) Biochem, J., 187, 361-366. Morpurgo, L.; Graziani, M. T.; Desideri, A. and Rotilio, G. (1980) Biochem. J., 187, 367-370. Reinhammar, B. and OK Y. (1979) J. Inorg. Biochem., 11, 115-122. LuBien, C. D.; Winkler, M. E.; Thamann, T. J.; Scott, R. A.; Co, M..S.; Hodgson, K. 0. and Solomon, E. I. (1981) J. Am. Chem. Sot., 103, 7014-7016. Frank, P. anaecht, I. Submitted for publication. Farver, 0.; Goldberg, M.; Lancet, D. and Pecht, I. (1976) Biochem. Biophys. Res. Commun., 73, 494-500. Pecht, I.; Farver, 0. and Goldberg, M. (1977) Bioinorg. Chem. II. Adv. Chem. Ser. 162 (Raymond K. N., Ed), pp. 179-206, ACS, Washington, D.C. Farver, 0.; Goldberg, M. and Pecht, I. (1980) Europ. J. Biochem., 104, 71-77. Goldberg, M.; Farver, 0. and Pecht, I. (1980) J. Biol. Chem., 255, 7353-7361. Farver, 0.; Goldberg, M. and Pecht, I. (1978) FEBS Lett., 94,
383-386.
Eckerson, K. W. and van Holde, I<. E. (1971) Comp. Biochem. Physiol., 39B, 855-872. Lerch, K. m81) in "Metal Ions in Biological Systems", 13, 143-171, Sigel, H., Ed., Marcel Dekker, Inc., New York. Morpurgo, L.; Desideri, A.; Rotilio, G. and Mondovi, B. (1980) FEBS Lett., 113, 153-186.
278
8lOCHEMlCAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS
16, 1982
Pages
273-278
PEROXIDE BINDING TO THE TYPE 3 SITE IN RHUS VERNICIFERA LACCASE DEPLETED OF TYPE 2 COPPER 0.
Farver,
P. Frank
and I.
Pecht*
Department of Chemical Immunology The Weizmann Institute of Science Rehovot, Israel Received
July
19,
1982
between hydrogen peroxide and oxidized SUMMARY: The interaction Rhus vernicifera lactase from which the type 2 copper has been For that end, the circular dichroic removed, was investigated. spectrum of the modiliied enzyme has been-measured in the presence of increasing concentrations of hydrogen peroxide. The characteristic band observed upon binding peroxide to native lactase is also observed for the type 2 copper depleted enzyme. However, there are several quantitative differences in the latter one. the intensity is lower and band width is larger. Secondly, First, from the titrations, it becomes apparent that the affinity for While the lower than that of the native native enzyme is higher than 10e3YgY; it decreases for the type 2 depleted enzyme.
INTRODUCTION The reversible vernicifera of
lactase
significant
nature However,
the
its
conflicting features
of the
the
type
for
investigating copper
this (2-5).
2 copper
depleted
reverse;
namely,
(2), that
the
no change
been
while
report takes
which
about
prepared the
(2-5). spectro-
by essentially
330 nm band reported
(T2D)
and the
claimed
is
and structural
interactions
published
place
Rhus
functional
has been
lactase
from
derivative
and their
derivative
3 site
another
2 copper
an enzyme
have
Thus,
type
type
sites
enzyme
oxidized
unaffected
the
produces
reports of
remained
*Currently Chemistry Technology,
of
(l-3)
different
same procedure
istic in
value
of
scopic
removal
character-
to be absent 615 nm band
essentially
at the
the
330 nm band,
a Sherman Fairchild Distinguished Scholar, Division and Chemical Engineering, California Institute of Pasadena, California 91125.
of
0006-291X/82/170273-06$01.00/0 273
Copyright 0 1982 by Academic Press, Inc. All rights of reproduction in any form reserved.
BIOCHEMICAL
Vol. 108, No. 1, 1982
yet
a marked
recently,
decrease
evidence
and at
the
that
the
spectral
with
hydrogen
peroxide
indicated
that
the
3 site
at 615 nm (4).
type
3 site
type
at
this in
More
controversy
T2D is
reduced,
330 nm can be recovered
(5).
In
contrast,
of T2D lactase
other
is
in
by
studies
an oxidized
(2,6). The type
coupled
3 copper
binuclear site
site
shown
has been
affinity
binding
one,
and reduction
complex
(7-11).
interesting detail
in
to bind
reported
to be lost the
interaction spectrum
The near
ultra
provide
removal
of the
latter
of
peroxide, that
a characteristic
evidence
copper
site
in
hemocyanins
and tyrosinase
distinction
between
of peroxide. T2D lactase the native
complex
the
We have for
enzyme,
as evidenced
with
rather
high
The role
of that
(7-13). oxidation
of
that
still
by the
is
characteristic
its
proteins
enables
the
of
titration
shown
as other
site
to to the like
a clear
and its
affinity
binding of
compared forming
in
circular
binding
it
to
enzyme
of
been
decreased capab!-
the
course
copper
although
In order
peroxide
Hence,
some
has been
on the
monitored
as well
in
binding
the
an
of T2D lactase
2 copper.
the
is markedly it
(5)
peroxide type
is
examined
study
for
peroxy-
mechanism
has earlier
lactase
found
peroxide
peroxide
during
CD spectrum
binding this
we have
violet
binuclear
dioxygen
modifications
system
a
form,
and has been
of
is
oxidized
affinity
upon
with
dichroic
native,
mentioned
high
which
as the
reduction
issue,
the
effect
its
hydrogen
above
lactase,
proposed
dioxygen
In the
by H202,
of
(7,8,10).
the
oxidation
examine
In
and important (9-11).
site
has been
and specificity
lactase
of
occurs
features
oxidation
its
RESEARCH COMMUNICATIONS
has been made to resolve
by providing
state
BIOPHYSICAL
in extinction
an attempt
least
AND
the
to that
a peroxy-
CD band.
MATERIALS AND METHODS 7.0,
Lactase and the
solutions protein
were made up in 0.1 M HEPES buffer, concentrations were determined from 274
pH the
Vol. 108, No. 1, 1982
BIOCHEMICAL
AND BIOPHYSICAL
350
Fimre hydrogen
1.
CD-spectra
peroxide.
400
RESEARCH COMMUNICATIONS
450
X krnl of TZD lactase (23 uM) titrated with a) no peroxide; b) 23 uM; c) 115 PM; and added to solution a. All other conditions
absorbance at 615 nm (E = 5700 M-1 cm-l), Type 2 copper depleted lactase was prepared according to the method of Graziani et al (l-3). Its copper content was determined spectrophotometrically with biquinoline. The two, independently prepared samples of T2D lactase studied in this work contained 2.8 and 2.9 Cu ions per mole protein, respectively. In view of changes caused in the molar extinction at 280 nm of T2D lactase, protein concentration was determined by the Lowry method. This showed that while essentially no change occurs in the intensit of the 615 nm band, that at 280 nm increases to Q99700 M- 4: cm-l (6). T2D lactase preparations were oxidized by excess ferricyanide which was removed by extensive dialysis or gel filtration. Protein concentrations examined ranged from 23 to 70 PM. CD spectra were measured in 1 cm cuvettes on a Roussel Jouan Dichrograph III. Data were collected by means of a Tektronix minicomputer averaging 200 measurements per nm.
RESULTS AND DISCUSSION The circular the
near
Namely, are
UV region both
present
The shorter do look
the with
dichroic is
wavelength
similar.
similar
negative close
spectrum
of
to that
oxidized
T2D
of the native
(447 nm) and positive to
the
same intensity
features,
Upon addition
though of 215
H202,
in
enzyme.
(375 nm) bands (cf.
not
lactase
also
too well
changes
in
ref.
2).
resolved, the
region
Vol. 108, No. 1, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Scatchard plot derived from titrations of T2D hydrogen peroxide. L is the concentration of free ligand (H202), and N is-the fraction of complex divided by total enzyme concentration. N is determined at (AE - Ae,)/ AE - AEN) of the 330 nm band'for T2D lacease where AE is the intensity without geroxide, As is the intensity of the same band after addition of a 100 fo r d excess of H202, and AE~ denotes the intensities of the various intermediate peroxide concentration.
300-400 these
nm emerge. changes.
Figure
1 provides
A prominent
band
at 442 nm is unaffected. increases of
From
several
T2D lactase shown
in
such
Figure
near
of
of
330 nm, while
that
the
330 nm band a maximum value
of a hundred
fold
excess
done on two independently plot
of H202 prepared
was constructed
and is
2. of
shown by the
as the
presence
a Scatchard
The formation been
at
illustration
concentration,reaching
titrations,
samples,
appears
The intensity
with peroxide M -1 cm-1 in the
0.75
typical
the
peroxy
regeneration
of both
UV and visible
oxidized
TZD lactase
(6)
followed
by extensive
complex
electronic upon
the
original
This
against
by excess
has
CD as well
and EPR spectrum
reduction
dialysis
is reversible.
of
ascorbate,
ferricyanide
and and
buffer. The negative
CD-band
hydrogen
peroxide
to the
one produced
oxidized
native
formed
to oxidized
T2D lactase
when 1 mole
lactase,
at ~330 nm upon
equivalent
and shown
276
bears
addition close
resemblance
of H202 is added
to be a peroxy-lactase
of
to
Vol. 108, No. 1, 1982
BIOCHEMICAL
complex
Conspicuous
(7,8,11).
increased
width,
of peroxide the
and the
in
order
appearance
dependent
of
is
the
exhibited
by the
binuclear
copper
tyrosinase
sites
that
of a partly
several
reasons:
lactase
was dialyzed
with
H220 experiments
the
Prior
was removed
that
via
that
This
Still,
like
a T2D
spectral
as well
proteins
(6)
equivalents
to the
peroxide a large
feature
as by the
hemocyanins
and
or ascorbate
(14)
required
for
the
maximum
is
T2D
titration
shown
fully
in other
reoxidized
as can be seen in
are
is not the
that
that
complete
affected
bands
at
by
at higher
least
the
type
Finally,
anaerobic
with
benzohydro-
T2D lactase
has shown the
the
We have
beginning. of
for
the
before
demonstrating
sample
of
of ferricyanide
450 nm band
and neither
of a similar
are
excess
T2D lactase
the
as a result
titration,
just
the
at
formed
can be excluded
Secondly,
of
oxidized
is
CD spectra.
(6).
shown),
fully
titrations
enzyme
even reduced
(not
is
new band
reduced
the
of peroxide,
wave length
quinon
indicates
lactase
filtration
intensity
addition
copper
by gel
conditions
1, the
the
against
monitored
these
Figure
other
T2D lactase.
a concentration
produced. of
excess
(12,13).
reoxidation
under
in
in
intensity,
large
band with
clearly
form
a lower
a rather
nm CD band
is indeed
native
RESEARCH COMMUNICATIONS
are
of
that
manner,
The possibility
which
requirement
(-)330
complex
BIOPHYSICAL
differences
to produce
and specific
lactase-peroxy
AND
three
1
electron
reduction
of
the
615 nm
band. Taking full
formation
Scatchard constant (Figure
2).
lactase-peroxide
M-l
cm-l
of a T2D lactase-peroxide
plot of
A& = -0.75
could
10200
M-l
be constructed. a 1:l
complex
In comparison,
the
stability
complex
complex, This
for
was estimated 277
as a measure a linear
yielded
between
a stability the
constant as > 10'
for
reactants for
M-l
the native
(7.8).
Hence,
vol.
108, No. 1, 1982
the
affinity
when the It than
BIOCHEMICAL
of type
is
lactase
that
W region
the
positive
for
T2D lactase
for
native
The same is -0.75
the
M-l
of
cm-'
RESEARCH COMMUNICATIONS
decreases
while
drastically
the
and -0.2 the peroxy native
enzyme,
375 nm is intact
in
the near
significantly
smaller CAE = -0.7 M-1 cm -1
protein M-l
longer
is essentially
oxidized
with
the
at wavelengths
T2D lactase
at
for for
of
CD band
(8,9,11), case
that
the native
compared
lactase
peroxide
to note
CD spectrum
with
BIOPHYSICAL
is missing.
interesting
identical
vs.
towards
2 copper
400 nm, the
AND
cm-l
complexes
for
T2D laccase.1 (AE: = -2.6 M -1 cm -1
and T2D lactase-peroxide
complex,
respectively).
REFERENCES
1. 2. 3. 4. 5. 6. 7. 8. 9.
10. 11. 12. 13. 14.
Graziani, M. T.; Morpurgo, L.; Rotilio, G. and Mondovi, B. (1976) FEBS Lett., 70, 82-90. Morpurgo, L.; Grazizi, M. T.; Finazi-Agro, A.; Rotilio, G.; and Mondovi, B. (1980) Biochem, J., 187, 361-366. Morpurgo, L.; Graziani, M. T.; Desideri, A. and Rotilio, G. (1980) Biochem. J., 187, 367-370. Reinhammar, B. and OK Y. (1979) J. Inorg. Biochem., 11, 115-122. LuBien, C. D.; Winkler, M. E.; Thamann, T. J.; Scott, R. A.; Co, M..S.; Hodgson, K. 0. and Solomon, E. I. (1981) J. Am. Chem. Sot., 103, 7014-7016. Frank, P. anaecht, I. Submitted for publication. Farver, 0.; Goldberg, M.; Lancet, D. and Pecht, I. (1976) Biochem. Biophys. Res. Commun., 73, 494-500. Pecht, I.; Farver, 0. and Goldberg, M. (1977) Bioinorg. Chem. II. Adv. Chem. Ser. 162 (Raymond K. N., Ed), pp. 179-206, ACS, Washington, D.C. Farver, 0.; Goldberg, M. and Pecht, I. (1980) Europ. J. Biochem., 104, 71-77. Goldberg, M.; Farver, 0. and Pecht, I. (1980) J. Biol. Chem., 255, 7353-7361. Farver, 0.; Goldberg, M. and Pecht, I. (1978) FEBS Lett., 94,
383-386.
Eckerson, K. W. and van Holde, I<. E. (1971) Comp. Biochem. Physiol., 39B, 855-872. Lerch, K. m81) in "Metal Ions in Biological Systems", 13, 143-171, Sigel, H., Ed., Marcel Dekker, Inc., New York. Morpurgo, L.; Desideri, A.; Rotilio, G. and Mondovi, B. (1980) FEBS Lett., 113, 153-186.
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