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Lysosome disruption by a free radical-like component generated during microsomal NADPH oxidase activity
Vol. 48, No. 6, 1972
BIOCHEMICAL
LYSOSOME DISRUPTION
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BY A FREE RADICAL-LIKE
COI5PONENT
GENERATED DURING MICROSOMAL NADPH OXIDASE ACTIVITY
Kuo-Lan
Biochemistry
Section,
Oklahoma
Department
of Biochemistry
University
of Oklahoma
Oklahoma
Chen and Paul
B. McCay
Medical
Research
and Molecular Health
Foundation
Biology,
Sciences
Center,
and
College
of Medicine,
Oklahoma
City,
73104
Received
June 12, 1972 Revised
August
4,
1972
Summary The oxidation of NADPH by liver microsomes produces a --in vitro factor which causes the release of hydrolases from lysosomes. The factor appears to be a free radical involved in the mechanism of NADPH oxidation. The production of the factor requires a heat labile component in the microsome and is inhibited by the addition of substances which are radical-trapping agents or substrates for the drug metabolism system. These interactions suggest possible mechanisms which might promote necrosis through the release of lysosomal enzymes --in vivo, especially in animals deficient in dietary radical-scavenging components. Oxidation
of NADPH by normal
resembling
those
production
of a highly
rapid
hemolysis
factor in
is
existing
port
The production
actively
stopped
disappeared a free
oxidized
with
inhibitors
with
introduced for
itself
by microsomes. or by mild
a very brief
component
by the enzyme system
deficient
rats
and depressed
alterations
which
occur
NADPH-dependent
electron
only
was shown
in animals
1412
to have
in microsomes
supplemented
was the
factor
the properties
The production
enhanced
trans-
when NADPH was
of the microsomes,
half-life. is
system
When the enzyme activity
heating
The factor
of initiating This
occurred
the
by the
(1).
lipid
during
conditions
was capable
into
the
under
to be accompanied
which
of the factor
immediately.
radical
factor
responsible membrane
microsomes
was shown
transient
apparently
(2).
being
--in vivo
of erythrocytes
the microsomal
liver
with
of this from higher
tocopherolthan
of
BIOCHEMICAL
Vol. 48, No. 6, 1972
normal
levels Since
of the vitamin. lysosomes
endoplasmic ping oration
are often
reticulum,
agent
in certain
in close
and because
in animal
lysosomal
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
diets
hydrolases
lack
results
tissues
proximity of a suitable
trap-
structural
by increased
we studied
of the
radical
in intracellular
characterized
(3),
to elements
the effect
deteri-
activity
of the
of acid
factor
on lysosomes.
Methods Lysosomes Leighton
were
et al.
(4)
isolated as modified
microsomes
were
microsomal
NADPH oxidase
properties
of a free
McCay (1). iron,
isolated
This
incubations a final
were concentration
Protein assays
lysosomal
determined
the method amounts
aration
(1).
by the method were
et al.
(11);
and were
o-nitrophenol
after
of the (8).
microsomes
which
was
was assayed in
terms
by of
produced,
in each lysosome
0.1% Triton
factor.
was measured
expressed
with
at
The
sulfatase
and p-nitrophenol
treatment
the
systems
et al.
phosphatase
of hydrolases
inhibits
after
generation
H-galactosidase
acid
Mnilf
to the reaction
aryl
and
of ADP and
(7).
of Lowry
(10);
Maximum activity
used by Pfeifer
as follows:
of Roy (9);
The
exhibiting
Therefore,
further
Liver
(6).
factor
reaction
et al.
of nitrocatechol,
was measured
the
Mn2+ was added
hydrolases
of Fukuzawa
respectively.
for
of 10m3 M to stop
to Sellinger
reported the
of
(5).
concentrations
factor
out,
by the procedure
according
produces
cytoplasmic
radical-like
was determined
for
and Carubelli
was the same as that
a cofactor
carried
by the procedure
as previously
which
contains
of the
tissue
by Tulsiani
system
radical
being
the production
liver
and washed
system
the latter
from
prep-
X-100.
Results Incubation of enzymically acid
phosphatase
of lysosomes oxidizing activity,
with
NADPH results while
in
the control
1413
are
a progressive system
in the process increase
(containing
of free no NADPH
Vol. 48, No. 6, 1972
showed
very
(Fig.
1).
labile.
little
increase
Enzymic
oxidation
Mild
plete
loss
like
BIOCHEMICAL
warming
of this
component.
on the
release
system
in which
release
occur.
hydrolase
release,
this is
factor
radicals.
not
II
shows
the addition
rats
before depressed versely, plemented tection perhaps,
of the
in
X-100
release
sacrificing
the animals,
rats
against is
incubation
the
considerably
donating for
a period
the
release
were
of 2 weeks, release
fact
lysosomes
that
injected
the lysosomes
more susceptible
occurred
1414
hydrolases caused of with
and N-methyl all
effective
in
by these
was
substances
systems
at the end of the
hydrolases.
In addition,
with
a-tocopherol
of lysosomal
fed
(Fig.
by the
12 hours
hydrolases
system
(Fig.
2).
was Con-
an a-tocopherol-sup-
an even greater
from animals to lysis
That
of reacting
hydrolases
active
cause
The protection
in the NADPH oxidase
hydrolase
have
hydrolases.
of fully
of
has
(1).
diphenylamine
to duplicate
were
system
would
capable
lysosomal
did not
so by the addition
santoquin,
of the lysosomal
the microsomes
during
doing
hydrolase
lysosomal
of 1 x 10e3 M were
donating
diet
from
which
the
to NADPH alone.
reported
of the
or substances
of Triton
resulted
if
systems
that
microsomes
been
in
no activation
lysosomes
the release
concentration
the release
incubation
for
by microsomes
significant
by the microsomal
has already
prevented
due to inactivation
since
of the
the radical-
Only
in essentially heated
produced
agents
at a final
preventing
does
Incubation are
Table
was occurring
exposure
was responsible
release
hydrolases.
heat
in com-
to produce
lysosomal
containing
radical
radical-trapping
aniline
did
a factor
shown as follows.
free
are
that
of a free
hydrolase
if
nor
results
of NADPH oxidation
NADPH resulted
Systems
ability
enzyme
is markedly
one minute)
and their the effect
lysosomal
microsomes
(65 O for
different
NMPH oxidation
activity.
properties
I shows
Omitting
of this
of NADPH by liver
enzyme activity
of three
Evidence
in the activity
of microsomes
Table
hydrolase
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3).
degree
of pro-
More significant,
deficient radical-like
in a-tocopherol factor
BIOCHEMICAL
Vol. 48, No. 6, 1972
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure 1. Progress curve of release of acid phosphatase from lysosomes exposed to microsomal NADPH oxidase activity. The reaction systems contained lysosomes (Lys), (0.3 mg protein/ml reaction system); microsomes (Mic), 1.0 mg protein/ml reaction system; NADPH (where indicated), 0.3 mM; ADP, 0.4 mM; Fe 3+, 0.012 mM; 0.015 M Tris-HCl buffer, pH 7.4; sucrose 0.7 M. Incubation was carried out at 37'.
Table I. Release of lysosomal Components added to incubation mediuma
hydrolases by microsomal NADPH oxidase activity. B-Galactosidase Acid phosphatase Aryl sulfatase activity activity activity umoles product/l0 min/mg protein
Lysosomes
(Lys)
1.91
.49
.05
Microsomes
(Mic)
1.18
.ll
.oo
3.82
.84
007
2.06
.53
.ll
25.74
1.93
.61
1.62
1.08
.08
6.32
.a7
.29
Lys + Mic Lys + NADPH (0.3
umole)
Lys + Mic + NADPH Lys + Mic
(A)b
+ NADPH
Lys + Mic + NADPH + Mn2+
Lys + Triton X-100 29.41 3.40 1.33 aThe incubation medium, quantity of components added and conditions of incubation were as described in Fig. 1. Incubation time was 45 min. bMic (A) = Microsomes heated at 650C for 1 min before addition to the reaction system.
than
are normal Because
studies
the effect
may have been
by the Triton with
lysosomes
lysosomes
of this dependent
injection which
(Fig.
procedure, were
isolated
3). factor
on the
lysosomes
on the lysosomes similar from
1415
having
experiments rats
using
used in been were
these
isolated carried
a discontinuous
out sucrose
Vol. 48, No. 6, 1972
Table
II.
Components incubation
BIOCHEMICAL
AND BIOPHYSICAL RESEARCh COMMUNICATIONS
Effect of free radical-scavenging agents on the release of hydrolases by microsomal NADPH oxidase activity. added to Acid phosphatase Aryl sulfatase mediuma umoles activity umoles activity umoles product/l0 minlmg
Lys + Mic Lys + Mic + NADPH
lysosomal g-Galactosidase pmoles activity protein
3.82
.58
.13
24.41
1.60
.73
Lys + Mic + NADPH + Santoquin (1 umole)
6.18
.66
.13
Lys + Mic + NADPH + N-methylaniline
4.41
.62
.27
.85
.13
(1 pmole)
Lys + Mic + NADPH + Diphenylamine (1 umole)
10.29
Lys + Triton X-100 29.41 3.15 1.07 aThe incubation medium, quantity of components added, and conditions of incubation were as described in Fig. 1 except as indicated. Incubation time was 45 min.
Figure 2. Effect of supplementing u-tocopherol to rats donating microsomes on the release of acid phosphatase from lysosomes by oxidase activity. Normal rats fed a stock ration were injected a-tocopherol (75 mg/kg body weight) 12 hours prior to preparing The conditions were as in Fig. 1. (+E) mic = microsomes isolated a-tocopherol-injected animals; other particles were from normal
gradient results
(12) were
without identical
previous with
injection those
reported
Discussion
1416
of the above.
rats
with
the liver NADPH with microsomes. from animals.
Triton.
The
BIOCHEMICAL
Vol. 48, No. 6, 1972
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure 3. Effect of dietary levels of a-tocopherol on the release of acid phosphatase from liver lysosomes by microsomal NADPH oxidase activity. N = lysosomes from normal rats; -E = lysosomes from rats fed a-tocopherol-deficient diet (15); +E = lysosomes from rats fed -E diet supplemented with 50 mg% a-tocopherol. The microsomes were from livers of normal rats. The conditions of the experiment are as in Fig. 1. -EC, NC and +EC are 45 min values for control systems in which no NADPII is added.
Previous
studies
of Zalkin
tocopherol-deficient drolases
rabbits
correlated
They concluded invasion
factors
the hydrolase by tissue
such as those
diseases
for
Evidence damage
whose
studies
cause
multiple
noted
also.
lesion
that
hydrolases structure
indicated
that
chromosome reported
release released
(3).
primary
release
radical-like could
be
or deficiency
of lysosomal
lysosomal structural
of macrophage
activity
in cells
by Allison
hy-
peroxidation.
absorption
--in vivo
Other
1417
lysosomal
lipid that
NADPH oxidase
intracellular
that
from
in tocopherol
from
degeneration
possible
was provided
breaks.
of free
tissue
was a consequence
is
the intracellular
to cell
Pearce
it with
muscle
of muscle
damage resulting
indicates
the initial
that
an excess
increase
associated
by triggering
vivo.
contains
showed
the development
investigation
responsible
severe
that
initiated
Our current
--in
with
et al.
hydrolases can cause
and Patton DNAase release
abnormalities of lysosomal
(13) could were
enzymes
Vol. 48, No. 6, 1972
may occur
BIOCHEMICAL
in some myopathies
AND BIOPHYSKAL
and followed
RESEARCH COMMUNICATIONS
by macrophage
invasion
(14).
Acknowledgement The assistance thanks.
The work
National
Institutes
of Donald
Gibson
was supported
in this
by grants
study
AM-08397
is
acknowledged
and AM-06978
with from
the
of Health.
References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Pfeifer, P.M. and McCay, P.B., J. Biol. Chem. 246, 6401 (1971). McCay, P.B., Poyer, J.L., Pfeifer, P.M., May, H.E. and Gilliam, J.M., Lipids 5, 297 (1971). Zalkin, H., Tappel, A.L., Caldwell, K.A., Shibko, S., Desai, I.D. and Holliday, T.A., .I. Biol. Chem. 237, 2678 (1962). Leighton, F., Poole, B., Beaufay, H., Baudhuin, P., Coffey, J.W., Fowler, S. and DeDuve, C., J. Cell Biol. 2, 482 (1968). Tulsiani, D.R.P. and Carubelli, R., J. Biol. Chem. 245, 1821 (1970). May, H.E. and McCay, P.B., J. Biol. Chem. 243, 2288 (1968). Poyer, J.L. and McCay, P.B., J. Biol. Chem. 246, 263 (1971). Lowry, O.H., Rosebrough, N.J., Farr, A.L. and Randall, R.J., J. Biol. Chem. 193, 265 (1951). Roy, A.B., Biochem. J. 2, 12 (1953). Sellinger, O.Z., Beaufay, H., Jacques, P., Doyen, A. and DeDuve, C ., Biochem. J. 74, 450 (1960). Fukuaawa, K., Suzuki, Y. and Uchiyama, M., Biochem. Pharmacol. 0, 279 (1971). Ragab, H., Beck, C., Dillard, C., Tappel, A.L., Biochim. Biophys. Acta 148, 501 (1967). Allison, A.C. and Patton, G.R., In: Lysosomes in Biology and Pathology, Dingle, J.T. and FellTH.B., eds. Vol. 2, p. 627, American Elsevier Publ. Co., N.Y., N.Y. (1969). Pearce, G.W., Ann. N.Y. Acad. Sci. 138, 138 (1966). Schwarz, K., Proc. Sot. Exp. Biol. & Med. '7, 818 (1951).
1418
BIOCHEMICAL
LYSOSOME DISRUPTION
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
BY A FREE RADICAL-LIKE
COI5PONENT
GENERATED DURING MICROSOMAL NADPH OXIDASE ACTIVITY
Kuo-Lan
Biochemistry
Section,
Oklahoma
Department
of Biochemistry
University
of Oklahoma
Oklahoma
Chen and Paul
B. McCay
Medical
Research
and Molecular Health
Foundation
Biology,
Sciences
Center,
and
College
of Medicine,
Oklahoma
City,
73104
Received
June 12, 1972 Revised
August
4,
1972
Summary The oxidation of NADPH by liver microsomes produces a --in vitro factor which causes the release of hydrolases from lysosomes. The factor appears to be a free radical involved in the mechanism of NADPH oxidation. The production of the factor requires a heat labile component in the microsome and is inhibited by the addition of substances which are radical-trapping agents or substrates for the drug metabolism system. These interactions suggest possible mechanisms which might promote necrosis through the release of lysosomal enzymes --in vivo, especially in animals deficient in dietary radical-scavenging components. Oxidation
of NADPH by normal
resembling
those
production
of a highly
rapid
hemolysis
factor in
is
existing
port
The production
actively
stopped
disappeared a free
oxidized
with
inhibitors
with
introduced for
itself
by microsomes. or by mild
a very brief
component
by the enzyme system
deficient
rats
and depressed
alterations
which
occur
NADPH-dependent
electron
only
was shown
in animals
1412
to have
in microsomes
supplemented
was the
factor
the properties
The production
enhanced
trans-
when NADPH was
of the microsomes,
half-life. is
system
When the enzyme activity
heating
The factor
of initiating This
occurred
the
by the
(1).
lipid
during
conditions
was capable
into
the
under
to be accompanied
which
of the factor
immediately.
radical
factor
responsible membrane
microsomes
was shown
transient
apparently
(2).
being
--in vivo
of erythrocytes
the microsomal
liver
with
of this from higher
tocopherolthan
of
BIOCHEMICAL
Vol. 48, No. 6, 1972
normal
levels Since
of the vitamin. lysosomes
endoplasmic ping oration
are often
reticulum,
agent
in certain
in close
and because
in animal
lysosomal
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
diets
hydrolases
lack
results
tissues
proximity of a suitable
trap-
structural
by increased
we studied
of the
radical
in intracellular
characterized
(3),
to elements
the effect
deteri-
activity
of the
of acid
factor
on lysosomes.
Methods Lysosomes Leighton
were
et al.
(4)
isolated as modified
microsomes
were
microsomal
NADPH oxidase
properties
of a free
McCay (1). iron,
isolated
This
incubations a final
were concentration
Protein assays
lysosomal
determined
the method amounts
aration
(1).
by the method were
et al.
(11);
and were
o-nitrophenol
after
of the (8).
microsomes
which
was
was assayed in
terms
by of
produced,
in each lysosome
0.1% Triton
factor.
was measured
expressed
with
at
The
sulfatase
and p-nitrophenol
treatment
the
systems
et al.
phosphatase
of hydrolases
inhibits
after
generation
H-galactosidase
acid
Mnilf
to the reaction
aryl
and
of ADP and
(7).
of Lowry
(10);
Maximum activity
used by Pfeifer
as follows:
of Roy (9);
The
exhibiting
Therefore,
further
Liver
(6).
factor
reaction
et al.
of nitrocatechol,
was measured
the
Mn2+ was added
hydrolases
of Fukuzawa
respectively.
for
of 10m3 M to stop
to Sellinger
reported the
of
(5).
concentrations
factor
out,
by the procedure
according
produces
cytoplasmic
radical-like
was determined
for
and Carubelli
was the same as that
a cofactor
carried
by the procedure
as previously
which
contains
of the
tissue
by Tulsiani
system
radical
being
the production
liver
and washed
system
the latter
from
prep-
X-100.
Results Incubation of enzymically acid
phosphatase
of lysosomes oxidizing activity,
with
NADPH results while
in
the control
1413
are
a progressive system
in the process increase
(containing
of free no NADPH
Vol. 48, No. 6, 1972
showed
very
(Fig.
1).
labile.
little
increase
Enzymic
oxidation
Mild
plete
loss
like
BIOCHEMICAL
warming
of this
component.
on the
release
system
in which
release
occur.
hydrolase
release,
this is
factor
radicals.
not
II
shows
the addition
rats
before depressed versely, plemented tection perhaps,
of the
in
X-100
release
sacrificing
the animals,
rats
against is
incubation
the
considerably
donating for
a period
the
release
were
of 2 weeks, release
fact
lysosomes
that
injected
the lysosomes
more susceptible
occurred
1414
hydrolases caused of with
and N-methyl all
effective
in
by these
was
substances
systems
at the end of the
hydrolases.
In addition,
with
a-tocopherol
of lysosomal
fed
(Fig.
by the
12 hours
hydrolases
system
(Fig.
2).
was Con-
an a-tocopherol-sup-
an even greater
from animals to lysis
That
of reacting
hydrolases
active
cause
The protection
in the NADPH oxidase
hydrolase
have
hydrolases.
of fully
of
has
(1).
diphenylamine
to duplicate
were
system
would
capable
lysosomal
did not
so by the addition
santoquin,
of the lysosomal
the microsomes
during
doing
hydrolase
lysosomal
of 1 x 10e3 M were
donating
diet
from
which
the
to NADPH alone.
reported
of the
or substances
of Triton
resulted
if
systems
that
microsomes
been
in
no activation
lysosomes
the release
concentration
the release
incubation
for
by microsomes
significant
by the microsomal
has already
prevented
due to inactivation
since
of the
the radical-
Only
in essentially heated
produced
agents
at a final
preventing
does
Incubation are
Table
was occurring
exposure
was responsible
release
hydrolases.
heat
in com-
to produce
lysosomal
containing
radical
radical-trapping
aniline
did
a factor
shown as follows.
free
are
that
of a free
hydrolase
if
nor
results
of NADPH oxidation
NADPH resulted
Systems
ability
enzyme
is markedly
one minute)
and their the effect
lysosomal
microsomes
(65 O for
different
NMPH oxidation
activity.
properties
I shows
Omitting
of this
of NADPH by liver
enzyme activity
of three
Evidence
in the activity
of microsomes
Table
hydrolase
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3).
degree
of pro-
More significant,
deficient radical-like
in a-tocopherol factor
BIOCHEMICAL
Vol. 48, No. 6, 1972
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure 1. Progress curve of release of acid phosphatase from lysosomes exposed to microsomal NADPH oxidase activity. The reaction systems contained lysosomes (Lys), (0.3 mg protein/ml reaction system); microsomes (Mic), 1.0 mg protein/ml reaction system; NADPH (where indicated), 0.3 mM; ADP, 0.4 mM; Fe 3+, 0.012 mM; 0.015 M Tris-HCl buffer, pH 7.4; sucrose 0.7 M. Incubation was carried out at 37'.
Table I. Release of lysosomal Components added to incubation mediuma
hydrolases by microsomal NADPH oxidase activity. B-Galactosidase Acid phosphatase Aryl sulfatase activity activity activity umoles product/l0 min/mg protein
Lysosomes
(Lys)
1.91
.49
.05
Microsomes
(Mic)
1.18
.ll
.oo
3.82
.84
007
2.06
.53
.ll
25.74
1.93
.61
1.62
1.08
.08
6.32
.a7
.29
Lys + Mic Lys + NADPH (0.3
umole)
Lys + Mic + NADPH Lys + Mic
(A)b
+ NADPH
Lys + Mic + NADPH + Mn2+
Lys + Triton X-100 29.41 3.40 1.33 aThe incubation medium, quantity of components added and conditions of incubation were as described in Fig. 1. Incubation time was 45 min. bMic (A) = Microsomes heated at 650C for 1 min before addition to the reaction system.
than
are normal Because
studies
the effect
may have been
by the Triton with
lysosomes
lysosomes
of this dependent
injection which
(Fig.
procedure, were
isolated
3). factor
on the
lysosomes
on the lysosomes similar from
1415
having
experiments rats
using
used in been were
these
isolated carried
a discontinuous
out sucrose
Vol. 48, No. 6, 1972
Table
II.
Components incubation
BIOCHEMICAL
AND BIOPHYSICAL RESEARCh COMMUNICATIONS
Effect of free radical-scavenging agents on the release of hydrolases by microsomal NADPH oxidase activity. added to Acid phosphatase Aryl sulfatase mediuma umoles activity umoles activity umoles product/l0 minlmg
Lys + Mic Lys + Mic + NADPH
lysosomal g-Galactosidase pmoles activity protein
3.82
.58
.13
24.41
1.60
.73
Lys + Mic + NADPH + Santoquin (1 umole)
6.18
.66
.13
Lys + Mic + NADPH + N-methylaniline
4.41
.62
.27
.85
.13
(1 pmole)
Lys + Mic + NADPH + Diphenylamine (1 umole)
10.29
Lys + Triton X-100 29.41 3.15 1.07 aThe incubation medium, quantity of components added, and conditions of incubation were as described in Fig. 1 except as indicated. Incubation time was 45 min.
Figure 2. Effect of supplementing u-tocopherol to rats donating microsomes on the release of acid phosphatase from lysosomes by oxidase activity. Normal rats fed a stock ration were injected a-tocopherol (75 mg/kg body weight) 12 hours prior to preparing The conditions were as in Fig. 1. (+E) mic = microsomes isolated a-tocopherol-injected animals; other particles were from normal
gradient results
(12) were
without identical
previous with
injection those
reported
Discussion
1416
of the above.
rats
with
the liver NADPH with microsomes. from animals.
Triton.
The
BIOCHEMICAL
Vol. 48, No. 6, 1972
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Figure 3. Effect of dietary levels of a-tocopherol on the release of acid phosphatase from liver lysosomes by microsomal NADPH oxidase activity. N = lysosomes from normal rats; -E = lysosomes from rats fed a-tocopherol-deficient diet (15); +E = lysosomes from rats fed -E diet supplemented with 50 mg% a-tocopherol. The microsomes were from livers of normal rats. The conditions of the experiment are as in Fig. 1. -EC, NC and +EC are 45 min values for control systems in which no NADPII is added.
Previous
studies
of Zalkin
tocopherol-deficient drolases
rabbits
correlated
They concluded invasion
factors
the hydrolase by tissue
such as those
diseases
for
Evidence damage
whose
studies
cause
multiple
noted
also.
lesion
that
hydrolases structure
indicated
that
chromosome reported
release released
(3).
primary
release
radical-like could
be
or deficiency
of lysosomal
lysosomal structural
of macrophage
activity
in cells
by Allison
hy-
peroxidation.
absorption
--in vivo
Other
1417
lysosomal
lipid that
NADPH oxidase
intracellular
that
from
in tocopherol
from
degeneration
possible
was provided
breaks.
of free
tissue
was a consequence
is
the intracellular
to cell
Pearce
it with
muscle
of muscle
damage resulting
indicates
the initial
that
an excess
increase
associated
by triggering
vivo.
contains
showed
the development
investigation
responsible
severe
that
initiated
Our current
--in
with
et al.
hydrolases can cause
and Patton DNAase release
abnormalities of lysosomal
(13) could were
enzymes
Vol. 48, No. 6, 1972
may occur
BIOCHEMICAL
in some myopathies
AND BIOPHYSKAL
and followed
RESEARCH COMMUNICATIONS
by macrophage
invasion
(14).
Acknowledgement The assistance thanks.
The work
National
Institutes
of Donald
Gibson
was supported
in this
by grants
study
AM-08397
is
acknowledged
and AM-06978
with from
the
of Health.
References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Pfeifer, P.M. and McCay, P.B., J. Biol. Chem. 246, 6401 (1971). McCay, P.B., Poyer, J.L., Pfeifer, P.M., May, H.E. and Gilliam, J.M., Lipids 5, 297 (1971). Zalkin, H., Tappel, A.L., Caldwell, K.A., Shibko, S., Desai, I.D. and Holliday, T.A., .I. Biol. Chem. 237, 2678 (1962). Leighton, F., Poole, B., Beaufay, H., Baudhuin, P., Coffey, J.W., Fowler, S. and DeDuve, C., J. Cell Biol. 2, 482 (1968). Tulsiani, D.R.P. and Carubelli, R., J. Biol. Chem. 245, 1821 (1970). May, H.E. and McCay, P.B., J. Biol. Chem. 243, 2288 (1968). Poyer, J.L. and McCay, P.B., J. Biol. Chem. 246, 263 (1971). Lowry, O.H., Rosebrough, N.J., Farr, A.L. and Randall, R.J., J. Biol. Chem. 193, 265 (1951). Roy, A.B., Biochem. J. 2, 12 (1953). Sellinger, O.Z., Beaufay, H., Jacques, P., Doyen, A. and DeDuve, C ., Biochem. J. 74, 450 (1960). Fukuaawa, K., Suzuki, Y. and Uchiyama, M., Biochem. Pharmacol. 0, 279 (1971). Ragab, H., Beck, C., Dillard, C., Tappel, A.L., Biochim. Biophys. Acta 148, 501 (1967). Allison, A.C. and Patton, G.R., In: Lysosomes in Biology and Pathology, Dingle, J.T. and FellTH.B., eds. Vol. 2, p. 627, American Elsevier Publ. Co., N.Y., N.Y. (1969). Pearce, G.W., Ann. N.Y. Acad. Sci. 138, 138 (1966). Schwarz, K., Proc. Sot. Exp. Biol. & Med. '7, 818 (1951).
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