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An ESR study of pseudomonas copper-protein
Vol. 10, No. 1, 1963
AN
BIOCHEMICAL
ESR
STUDY
OF
AND BIOPHYSICAL
PSEUDOMONAS
H.
Department
Received
of
November
of
tionally
low
in
and
lactase
not
and
one
of
and
suggested
unique
manner (1)
unpaired
two
and
spin
resonance
one Blue
6) and
This
Portland
in
close
that
study
pairs
we
electron
Cu
(II)
between
two
copper
that
it
was
the
,
coordiof the
Cu
(I),
but
nuclei,
spin
resonance
“similar structure
in
and
-1
cm
is
between
proximity
of
copper
atom
microorganisms
was supported United States
been
investigated
may
of the
be used
resonance
per
atoms
has
have
spin
copper-proteins
study and the indebted.
copper
electron
excep-
0.008
delocalization
hyperfine
copper-oxidases
copper
other
and
the
resonance
have
of
the
of nuclear
spin to
-1
cm
degree
examined found
them
enzymes
equally
They
are
these
electron
found
= 0.009
interaction
lack
the
a high
shared
spectroscopy the
--only
School,
to
spec-
that
of
indicates
enzyme
and
comprise
the
lactase that
undergo
at
ex-
(3).
present
determining
,+
ions
of important In the
in
associates
hypothesis
4).
(5,
his
A
involving
perhaps
The
interaction”
centers
that
oxidase.
copper
The
Medical
2) and
(1, constants,
electron
cytochrome
change
have
or
ceruloplasmin.
least
Oregon
determined
ceruloplasmin
It was
Beinert trum
of
have
splitting
electron
as
Vanngard
hyperfine
some
unpaired
Mason
28, 1962
respectively. nated
COPPER-PROTEIN*
University
Biochemistry,
Malmstrom spectra
S.
RESEARCH COMMUNICATIONS
to
considerable
interest
possibility
detect
spectra
prosthetic
such of two
that
(cf.
el’ectron
structures
by
copper-proteins
which
molecule. have
been (7).
isolated They
from have
by grants from the Public Health Service,
11
various
pseudomonads
unusually
intense
absorp-
American to whom
Cancer we are
Society greatly
Vol. 10, No. 1, 1963
tion
in
atom
the of
region
copper
of the
blue
tained
0.76
form ESR
analysis
0.84
atom
it
by
of
a Varian
trated splitting
chemical
Dr.
per
molecule,
analysis,
and as
molecule;
chemical
second
Ambler
analysis),
0.65
one
0.67
atom
a standard. 0.76
0.70
Pseudomonas
which
atom
was by
His
second
sample
per
(10)
and
by
conthe
cupric
quantitative contained was
ESR
provided
denitrificans
in
molecule
quantitative
generously
samples
of which
molecule
by
one two
per
atom
atom
and
provided
aeruginosa, of
was
16,000,
generously
0 f this,
copper-protein
from
P.
of about
Pseudomonas
cupric-EDTA per
weights
RESEARCH COMMUNICATIONS
signals
obtained
V-4500
amplitudes by
Fig. constant
from
spectrometer between 1.
A
with 8 and
They
these
had
= 0.006
32
gmax cm
two
100
kc
gauss,
field
modulation
were
, the
almost
H. in
lowest
yet
at
-165”,
and
field
identical
g-parallel
= 2.055, -1
copper-proteins
Iwasaki; the
crys-
and
using modulaare
illus-
= 2. 157,
and
a hyperfine
for
any
copper
observed
protein.
19max
Figure 1. Electron spin protein from Pseudomonas T = -165”.
resonance aeruginosa
signal in
12
(derivative) of 0.05 M ammonium
the
spectro-
Dr.
examined
in
form. The
tion
molecular
mu,
copper
copper
isolated
AND BIOPHYSICAL
from
of
(by
The
talline
610
molecule.
using
form
was
per
atom 9)
scopy.
of
copper-protein
(8,
cupric
BIOCHEMICAL
1 mM copperacetate,
pH
6.5,
Vol. 10, No. 1, 1963
BIOCHEMICAL
These
results
explanation
for
sought
small
and
spectrum, in
that,
for
hyperfine
for
due
in
the
to
in
involves
Dr.
N.
one
Horie
RESEARCH COMMUNICATIONS
copper-proteins
of absorption which
are
some
splittings
exhaltation
a configuration
Thanks with
mean
AND BIOPHYSICAL
and
at
g-parallel the
Mr.
region
610
copper
mu
atom
Paul
any
region,
rate,
the
of the
ESR
must
be
only.
McMahill
for
assistance
analyses.
References
1.
Malmstrom,
2.
Broman, Biol.,
3.
Beinert, J.
4.
Mason,
5. 6.
B., L., -5, H.,
D.
Nature,
Horio,
T.,
J.
Biochem.,
Coval, Acta.
M.
L., -51,
Stark,
G.,
9.
Griffiths, (1961). Suzuki,
246 I.
and D.
H.,
and
Dawson, E.,
and
and
Iwasaki,
79
and
D.
195
Kamen,
2,
118
Vanngard.
C.,
Anal.
J.
C.,
Biochem.,
13
D.,
Proc.
Chem., D.
(1958);45,
M.
H.,
Wharton,
Biol.,
(1960).
J. Mol.
T.,
and
Sands,
-
2.67
R.
H.
(1956).
Wilkinson,
H.,
R.,
45, -
and
C.,
Mol.
Wharton, (1962).
Tokyo, T.,
J.
Aasa,
E., 2337
177,
Horio, (1961).
W.,
T., B.,
237,
S.,
8.
10.
Griffiths, Chem.,
H.
(1962).
Vanngard,
Malmstrom, 301 (1962).
Biol.
Sutherland, 43P
7.
and
Biochem.
Biochem.
-30, J.
Biol.
Tokyo,
191
(1958). Biophys.
Sot.,
84, -
(1958).
Chem.,
236,
52, -_
193
1857
(1962).
_
AN
BIOCHEMICAL
ESR
STUDY
OF
AND BIOPHYSICAL
PSEUDOMONAS
H.
Department
Received
of
November
of
tionally
low
in
and
lactase
not
and
one
of
and
suggested
unique
manner (1)
unpaired
two
and
spin
resonance
one Blue
6) and
This
Portland
in
close
that
study
pairs
we
electron
Cu
(II)
between
two
copper
that
it
was
the
,
coordiof the
Cu
(I),
but
nuclei,
spin
resonance
“similar structure
in
and
-1
cm
is
between
proximity
of
copper
atom
microorganisms
was supported United States
been
investigated
may
of the
be used
resonance
per
atoms
has
have
spin
copper-proteins
study and the indebted.
copper
electron
excep-
0.008
delocalization
hyperfine
copper-oxidases
copper
other
and
the
resonance
have
of
the
of nuclear
spin to
-1
cm
degree
examined found
them
enzymes
equally
They
are
these
electron
found
= 0.009
interaction
lack
the
a high
shared
spectroscopy the
--only
School,
to
spec-
that
of
indicates
enzyme
and
comprise
the
lactase that
undergo
at
ex-
(3).
present
determining
,+
ions
of important In the
in
associates
hypothesis
4).
(5,
his
A
involving
perhaps
The
interaction”
centers
that
oxidase.
copper
The
Medical
2) and
(1, constants,
electron
cytochrome
change
have
or
ceruloplasmin.
least
Oregon
determined
ceruloplasmin
It was
Beinert trum
of
have
splitting
electron
as
Vanngard
hyperfine
some
unpaired
Mason
28, 1962
respectively. nated
COPPER-PROTEIN*
University
Biochemistry,
Malmstrom spectra
S.
RESEARCH COMMUNICATIONS
to
considerable
interest
possibility
detect
spectra
prosthetic
such of two
that
(cf.
el’ectron
structures
by
copper-proteins
which
molecule. have
been (7).
isolated They
from have
by grants from the Public Health Service,
11
various
pseudomonads
unusually
intense
absorp-
American to whom
Cancer we are
Society greatly
Vol. 10, No. 1, 1963
tion
in
atom
the of
region
copper
of the
blue
tained
0.76
form ESR
analysis
0.84
atom
it
by
of
a Varian
trated splitting
chemical
Dr.
per
molecule,
analysis,
and as
molecule;
chemical
second
Ambler
analysis),
0.65
one
0.67
atom
a standard. 0.76
0.70
Pseudomonas
which
atom
was by
His
second
sample
per
(10)
and
by
conthe
cupric
quantitative contained was
ESR
provided
denitrificans
in
molecule
quantitative
generously
samples
of which
molecule
by
one two
per
atom
atom
and
provided
aeruginosa, of
was
16,000,
generously
0 f this,
copper-protein
from
P.
of about
Pseudomonas
cupric-EDTA per
weights
RESEARCH COMMUNICATIONS
signals
obtained
V-4500
amplitudes by
Fig. constant
from
spectrometer between 1.
A
with 8 and
They
these
had
= 0.006
32
gmax cm
two
100
kc
gauss,
field
modulation
were
, the
almost
H. in
lowest
yet
at
-165”,
and
field
identical
g-parallel
= 2.055, -1
copper-proteins
Iwasaki; the
crys-
and
using modulaare
illus-
= 2. 157,
and
a hyperfine
for
any
copper
observed
protein.
19max
Figure 1. Electron spin protein from Pseudomonas T = -165”.
resonance aeruginosa
signal in
12
(derivative) of 0.05 M ammonium
the
spectro-
Dr.
examined
in
form. The
tion
molecular
mu,
copper
copper
isolated
AND BIOPHYSICAL
from
of
(by
The
talline
610
molecule.
using
form
was
per
atom 9)
scopy.
of
copper-protein
(8,
cupric
BIOCHEMICAL
1 mM copperacetate,
pH
6.5,
Vol. 10, No. 1, 1963
BIOCHEMICAL
These
results
explanation
for
sought
small
and
spectrum, in
that,
for
hyperfine
for
due
in
the
to
in
involves
Dr.
N.
one
Horie
RESEARCH COMMUNICATIONS
copper-proteins
of absorption which
are
some
splittings
exhaltation
a configuration
Thanks with
mean
AND BIOPHYSICAL
and
at
g-parallel the
Mr.
region
610
copper
mu
atom
Paul
any
region,
rate,
the
of the
ESR
must
be
only.
McMahill
for
assistance
analyses.
References
1.
Malmstrom,
2.
Broman, Biol.,
3.
Beinert, J.
4.
Mason,
5. 6.
B., L., -5, H.,
D.
Nature,
Horio,
T.,
J.
Biochem.,
Coval, Acta.
M.
L., -51,
Stark,
G.,
9.
Griffiths, (1961). Suzuki,
246 I.
and D.
H.,
and
Dawson, E.,
and
and
Iwasaki,
79
and
D.
195
Kamen,
2,
118
Vanngard.
C.,
Anal.
J.
C.,
Biochem.,
13
D.,
Proc.
Chem., D.
(1958);45,
M.
H.,
Wharton,
Biol.,
(1960).
J. Mol.
T.,
and
Sands,
-
2.67
R.
H.
(1956).
Wilkinson,
H.,
R.,
45, -
and
C.,
Mol.
Wharton, (1962).
Tokyo, T.,
J.
Aasa,
E., 2337
177,
Horio, (1961).
W.,
T., B.,
237,
S.,
8.
10.
Griffiths, Chem.,
H.
(1962).
Vanngard,
Malmstrom, 301 (1962).
Biol.
Sutherland, 43P
7.
and
Biochem.
Biochem.
-30, J.
Biol.
Tokyo,
191
(1958). Biophys.
Sot.,
84, -
(1958).
Chem.,
236,
52, -_
193
1857
(1962).
_