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Characterization of immune type interferon (IFNγ)-induced cytoplasmic protein kinase activity in mouse L cells
Vol. 104, No. 2, 1982 January 29, 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 422-429
CHARACTERIZATION OF IMMUNE TYPE INTERFERON (IFNy)-INDUCED CYTOPLASMIC PROTEIN KINASE ACTIVITY IN MOUSE L CELLS Kenzo
Ohtsuki,
Department
Received
November
Barbara
A. Torres,
of Microbiology, Galveston,
and Howard
M. Johnson
University of Texas Texas 77550 U.S.A.
Medical
Branch
30, 1981
SUMMARY: Mouse immune interferon (IFNV) induced double-stranded RNA-independent protein kinase activity in the cytoplasmic fraction of mouse L cells as measured against a histone substrate. Chromatographic purification separated the activity into three distinct kinases of imolecular weights of approximately 1OOK (kinase I), 70K (kinase II), and 70K (kinase III). Partially purified IFNY was as effective as crude in inducing protein kinase activity. Induction was blocked by treatment of IFNY with specific anti-IFNr antibody or by treatment of the L cells with actinomycin D. Kinase II activity was different $$orn that of kinases I and III in that it showed Ca-dependence in the absence of My , was inhibited in activity by the SH binding agent N-ethylmaleimide, and could use the cellular enzymes RNase A The described protein kinases could play an and hexokinase as substrates. important role in mediation of IFNY effects, particularly where phosphorylated enzyme substrates were shown to have altered activity.
It
has been demonstrated
interferon protein
(IFN)
results
in increased
phosphorylation
have partially
of cellular
purified
protein
kinase,
resulting
in the
inhibition
Recently,
we reported
for
IF/$
biological
from
(9).
study
properties
of mouse L cells. cytoplasmic
protein
kinase
total
and ribosomal
phosphorylates
also
kinases
induces
that
(37K)
synthesis protein
dsRNA-
of eIF-2, (4,7,8). kinase
of If?&-induced
virus-induced
ribosomal
IFNs as was also
shown
and characterize
the
(10-12).
kinase
against
422
determine
activity
IFNy induces
0006-291X/82/020422-08$01.00/0 Cop.yright 0 1982 by Academic Press, Inc. AN rights of reproduction m any form reserved.
We and others IFN-induced
subunit
protein
of induction
to further
as measured
small
with
and increased
(l-7).
dsRNA-dependent
for
A synthetase
of IFNy-induced We found
the
of cells
activity
proteins
of viral
observed
was undertaken
treatment
a ribosomal-associated
The kinetics
that
of 2',5'-oligo
The present
that
of initiation
that
was different
induction
distinct
which
in mouse L cells
kinase
laboratories
and characterized
dependent
activity
by several
in the
an increase a histone
cytoplasmic
in at least substrate.
fraction three A possible
Vol. 104, No. 2. 1982 biological
role
BIOCHEMICAL
of the
IFNY-induced
AND BIOPHYSICAL kinases
in the
RESEARCH COMMUNICATIONS
IFN-induced
biochelnical
events
is discussed.
MATERIALS
AND METHODS
Chemicals - [Y-32P]ATP (19.0 Ci/mol) was obtained from Amersharn Corp. Casein, phosvitin, pancreatic ribonuclease A (RNase A), dithiothreitol (DTT), calf thymus histone (type II-a) and CAMP were obtained from Sigma Chemicals Corp. DEAEConcanavalin A-Sepharose and Sephacryl cellulose (DE-52) was obtained from Whatman. S-200 were obtained from Pharmacia. - IFNywas produced in C57Blj6 mouse spleen cell Mouse IFNy preparation cultures using staphylococcal enterotoxin A as an inducer as previously described (13). The produced IFNywas partially purified by adsorption to controlled Poreglass beads and elution with 20% ethylene glycol and 1 M NaCl in phosphate buffered Following dialysis against PBS, the IFNYfraction was applied on saline (PBS) (14). a concanavalin A-Sepharose column and eluted with 0.25 M a-methyl-Dgmannoside in PBS. The final product had a specific activity of approximately 10 units/mg protein. Treatment of thq cells with IFNs - Confluent monolayers of mouse L cells (about lo8 cells) in 150 cmL flasks were treated with 300 reference units/ml of IFN for 12 hrs at 37'C. The cells were harvested by scraping with a rubber policeman, centrifuged, washed twice with PBS, and cytoplasmic fractions were prepared as described below for testing protein kinase activity. Cytoplasmic fraction Icrude kinase fraction1 1 The cytoplasmic fractions fgom untreated and IFN -treated cells were prepared as follows. The cells (about 10 cells) were gently homogenated with a glass homogenizer in 3 ml of 10 IBM Tris-HCl 2 mM dithiothreitol (DTT) and 10 mM KCl, and then (pH 7.5) containing 2 mM CaCl The supernatant was recentrifuged at high centrifuged for 20 min at 12,8;0 rpm. speed (105,000 Xg for 45 min) to remove ribosomes from the fraction. The obtained supernatant was concentrated to 1.0 ml using polyethylene glycol 20000 powder. The concentrated solutions were dialyzed overnight at 4°C against 10 mM Tris-HCl (pH 7.5) containing 0.5 M KCl, 2 mM DTT and 10%glycerol (Suffer A). The dialyzed fractions were used as crude kinase preparations (cytoplasmic fractions) for the purification and kinase assay in this study. Assay of protein kinase activity - The complete reaction mixture (0.1 ml) contained 39 mM Tris-HCl (pH 7.5), 4 mM DTT, 10 ug of bovine serum albumin (BSA), 100 uE1 [yP]ATP (2,000 cpm/pmol), the indicated ayyunts o$+substrate (histone or or Ca and the indicated other proteins), the indicated amounts of either Mg amounts of protein kinase purified or unpurified from the cytoplasmic fraction of After incubation for the periods indicated at 37Y, the enzyme mouse L cells. reaction was terminated by the addition of 0.5 ml of 0.2 M sodium pyrophosphate containing BSA (1 mg/ml) and 0.5 ml of 20% trichloroacetic acid. The precipitate WJ~ collected by filtration through a Whatman glass filter (type GF/F) and the [ Plradioactivity of the filter was determined by a liquid scintillation spectrometer after drying. Protein measurement - Protein concentration of the enzyme preparations was determined by the method of Lowry et al. (15). RESULTS IFNY-induced
cytoplasmic
When mouse L cells reference (histone
units/ml)
for
phosphorylation
as compared
with
that
protein
kinase
(about
lo8
12 hrs
at 37'C,
with
cells)
activity were the
cells
(Table
423
exposed
activity
CY-~~ P]ATF)frorn
of untreated
in mouse L cells to crude of cytoplasmic
such cells 1).
mouse IFNv (300
This
protein
was significantly increased
protein
kinase increased kinase
BIOCHEMICAL
Vol. 104, No. 2. 1982
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Table 1. Characterization of interferons as stimulators cytoplasmic protein kinase activity in mouse L cells.
of
ProteQ kinase activity (pm01 cv- P]ATP/pg histone)
Treatments None Mouse IFNy Mouse IFNy + actinomycin Mouse IFNo/@ Human IFNa Mouse IFNY + anti-mouse
18.5 63.8 22.8 40.2 19.1 23.0
D IFNv antiserum
Crude kinase fractions (cytoplasmic fractions) were prepared from untreated mouse L cells or cells treated with 300 units/ml of mouse IFNy (crude), or5cells treated with 300 units/ml of human IFNa (specific activity 10 units/mg) for 6 hrs at 37*C. Actinomycin D (1 vg/ml) was Protein kinase added to the cell cultures at the same time as IFNy. activity of the fractigns was assayed using either histone (type 34-A) in the presence of Mg (3 mM) or phosvitin in the presence of Ca (3 mM) as descri!>ed in Materials and3Methods. Anti-mouse IFWy antiserum was preincubated with mouse IFNY (10 units/ml) for 30 min at 37OC before exposure to the cells, at a concentration that completely neutralized the antiviral activity.
activity
was also
However,
no increase
human leukocyte
pg/ml),
in the
interleukins strongly kinase
inhibits
antiserum
activity
suggest
Tris-HCl
(pH 7.5)
by the
antiserum
fractions S-200
and P-II) The kinase
molecular were activity
of
is
antiviral
state
with
factor
(unpublished the
treated
by IFNs.
the
in D (1
Also,
kinase lymphokines,
data).
increase
with
resistance
protein
against
for
was used.
actinomycin
induced
IFNv to induce
responsible
These
of total
data
protein
of mouse L cells,
kinases
from
untreated
(1.5
0.5
appreciable
not reactive
fraction
column
containing
by their
addition
cytoplasmic
in cells
mouse IFNv together
stimulating IFNv is
units/my)
was observed
of antiviral
of IFNy-induced
a Sephacryl
acceptor.
mouse
in the
through
(P-I
with
induce
the ability
This
that
The cytoplasmic
activities
not
the development
cells.
IFNv (lo5
activity
does
treated
neutralized
purification
kinases
which
cells
purified
kinase
1 and 2 or colony
activity
Partial
of protein
or from
which
anti-IFNv
when partially
IFN (IFNu)
L ce?ls,
mouse
obtained
X 50 cm) previously
M KCl,
size
and IFNv-treated
of the
of 10 PM CAMP, whereas
histone
first
peak
the activity 424
(or (P-I)
casein)
with
10 mM kinase
1, two distinct
as a phosphate
was significantly
of the
passed
to separate
As shown in Fig.
using
were
equilibrated
2 mM DTT and 10% glycerol
differences.
detected
cells
second
peak
stimulated (P-II)
was
Vol. 104, No. 2. 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
3s 5 8 22
0
1
0
0 1
30
40
50
Fraction
Fig.
slightly and
1.
Separation filtration. untreated units/ml) Aliquots described (Xl.
inhibited P-II)
by
from
cells
to
IFN.
37°C)
of
the
treatment
protein kinase activities by Sephacryl S-ZOO gel The cytoplasmic fractions were prepared from cells (0) and cells treated with mouse IFNY (300 for 2 hrs (A) and 6 hrs (O), respectively, at 37'C. (5 ~1) were assayed against a histone substrate as in the Materials and Methods. Absorbance at 280 nm
CAMP.
Total cells
The
activity
of
the
specific
order
to
peak cells
number
of
IFNY-treated
second
60
(P-II with
protein
kinase
activities
increased
with
increased
(histone
kinase) IFNv
time
both
increased
units/ml)
fractions
of
phosphorylation/pg
was
(300
of
exposure
of
protein/min
approximately
as
(P-I
compared
at
3-fold with
that
the
6 hr of
after
untreated
cells. In IFNu-treated column. buffer tne
The
other
kinase
2).
The
between The
active
respectively, molecular
the
was
0.2
were
eluted
as
active P-II
was
between
fractions
0.05
0.3 in
M KC1 the
immediately kinases
two
on
between
0.15
M and
and
designated
separated
into
two
kinases:
(Fig.
0.1 3).
Only
and
as 425
the
kinase
column by
III
M KC1
0.2 as the
other II
from
M KC1
the
I.
first
On
peak III)
was RNase
were 20000.
a Sephacryl
in
kinase
phosphorylated
jlycol on
P-II)
(kinase
chromatography
polyethylene deteri,rined
and
a DEAE-cellulose
pooled
M and
and
(P-I
were
DEAE-cellulose
II
kinases applied
peak
concentrated I,
distinct
separately
a single
fractions kinase
M and
of
the
fractions
eluted
and weight
characterize
the
P-I
hand, II)
eluted A.
cells,
(Fig.
(kinase
further
pooled, The
S-200
column
Vol. 104, No. 2. 1982
BIOCHEMICAL
AND BIOPHYSICAL
r
Kinase
RESEARCH COMMUNICATIONS
I
0.6
Fraction
Fig.
were
DEAE-cellulose column chromatography of P-I fraction from the cytoplasmic fraction of IFNy-treated cells. The P-I kinase fraction was applied to a column (1.5 X 8 cm) of DEAEcellulose previously equilibrated with 10 mM Tris-HCl (pH 7.5) containing 2 mM OTT and 10% glycerol. The column was washed with 10 ml of the same buffer and fractions (0.5 ml) were collected. Elutions were carried out with a linear gradient (0 M to 0.5 M KCl) in the buffer. Aliquots (5 ~1) were assayed as described in the Materials and Methods. Histone phosphorylating activity (0) and absorbance at 280 nm (X).
2.
lOOK,
approximately
marker
proteins.
318-fold
with
Requirements
activity for
histone
70K and 70K,
Kinases
I,
II
yields
respectively, III
and
kinase
conditions or casein
for were
were
as measured
purified
about
by comparison
250-fold,
350-fold
activity
of the
suitable
kinases
phosphate
Kinase
are
summarized
acceptors.
in Table
The optima1
II
I
0 50
30 Fraction
3.
and
activities
I
Fig.
with
of 45%, 25% and 38%, respectively.
IW-induced
The optima1 Either
number
70
number
DEAE-cellulose column chromatography of P-II fraction from the cytoplasmic fraction of IFNY-treated cells. The OEAEcellulose column chromatography of P-II kinase was performed as described in Fig. $+ Histone phosphorylating activity was in the presence of Mg (5 mM) (0).2+RNase phosphorylating activity was in the presence of Ca (3 mM) (0). Absorbance at 280 nm (X).
426
2.
Vol. 104, No. 2. 1982
BIOCHEMICAL
Table
Reaction
mixtures
Complete Complete Complete Complete Complete Complete Complete
+ +
2.
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Requirements for activity of from IFNY-treated cells
(pm01 Kinase
Protejs &I
kinases
kinase activity P]ATP/Pq histone) Kinase II
36.6 0.2 0.3 0.1 32.9 58.5 32.6
Mg $1 Mg + Ca2+ Histone DTT + NEM CAMP dsRNA
the
Kinase
4.9 0.1 6.4 0.1 0.1 2.8 5.0
III
15.4 0.1 0.1 1Z 14:3 14.6
The complete reaction mixture (0.1 ml) contained 20 mM Tris-HCl (pH 7.5), 3 mM MgCl or 3 rnlJ2CaC1 4 mM DTT, 10 Pg of BSA, 20 Pg of histone (type II-A), 106 PM [YPlATsland either kinase I, kinase II or kinase III at 0.5 ug each. The reaction mixture was incubated for 10 min at 37OC. The concentration of CAMP, N-ethylmaleimide (NEM) and dsRNA (poly rI:poly rC) was 3 PM, 1 mM and 100 rig/ml, respectively.
concentration absolute
of requirement
contrast
to
this,
ethylmaleimide
dsRNA
(poly
rig/ml
to
II
(3 uM) an
for
was
was
on
on
by
the
2+
I
other
three
I and
activated
absence
activity stronyly
of
iiig
2+
activities
.
an In
protein
2.6-fold.
Nthe
stirlruldt.inJ at
Ca
had
2+
for
inhibited No
III
by
about
kinases.
kinase
Kinases
not
in
SH enzymes,
the
oM.
were
Ca
kinase
of
3-5
and
activated
inhibitor
rC)
was
activity,
enhanced
no effect
poly
1 mg/rnl)
The
substrate
3.
Kinases
casein
phosphate
is
CAMP
kinases
activity
effect
any
concentration
kinases
are
of (10
observed.
requirements
Table
and
II
had
r1:
Substrate
and
but
Mg
three
2+
kinase
(NEM),
kinase
the
for
phosphorylation.
of
for
My'+
in
requirements
in
a Ca-dependent
substrate
were
presence
of
the
the
presence
protein
requirements
of
partially
similar
Mg 2+
In contrast
acceptors.
hexokinase
III
I and
the
of
in
(5 to
kinase
(in
kinase
II
phosphorylation
r&l) , while this,
Ca 2+
of
purified
the are
hexokinase
II
kinase (3
of
rtil).
These
absence
of
different
histone,
and
from
show The
those
A were both
results
of
in
lphosvitin
RNase
phosphorylated
MJ*+).
summdrized
RNase
that
data kinases
poor
kinase show
ttldt
I and
A II the
III.
DISCUSSION We have dependent
previously
protein
kinase
shown activity
that
mouse in
IFNy
mouse
can
L cells 427
induce that
ribosome-associated phosphorylates
dsRNAthe
a subunit
Vol. 104. No. 2. 1982 Table
BIOCHEMICAL 3.
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Substrate requirement of the three distinct purified from the cytoplasmic fraction of IFNv-treated cells
kinases
Protein kinase activity (pnol [Y-~~P]ATP/@ histone) Kinase I Kinase II M9*+ Ca*+ M9*+ Ca*+
Substrate Histone Casein Mouse Igti RNase A
36.5 1.4 2.9 1.7
N.D. N.D. N.D. N.D.
4.4 2.8 3.1 3.7
Phosvitin Hexokinase BSA
:':' 0:l
N'D' ND N:O:
5'2 19 N:D.
Kinase M92+
6.3 2.2 4.8 5.7 2.8 9.1 N.D.
III Ca*+ N.D. N.D. N.D. N.D. ND N'D' N:D:
14.5 8.1 1.8 1.5 1:':' N:D.
The protein kinase activity of kinase I, kinase II and kinase III (all at 0.5 ug) was incubated, respectively, for 10 min at 37Y wish variojf substrates (20 pg each) in the presence of either Mg or Ca (3 mM). The activity of kinase I was assayed in the pr!:efz!z of 3 UM CAMP. N.D. = not detected.
of eukaryotic also
peptide
induce
cytoplasmic
measured
against
Sephacryl
S-200
separated
the
a histone gel
for
observation
that:
the
kinase
(b)
specific
(c)
actinomycin
activity anti-IFNv
kinases
kinases presence
(7-11).
They are,
CAMP-dependent required
Mg2+ for
of Ca2+ (absence
II),
three
(d)
however, activity,
of
and mouse IFNa/6, species
in that
they
are
functionally
activation,
but
of Mg2+).
Only
distinct
kinases
II
only
kinase
kinase 428
II
III).
of IFNYis
as evidenced
by the
protein)
with
crude
IFNvto but
induced
mouse IFNy,
induce
not
activity,
human IFNa,
in
induction.
dsRNA-independent,
known ribosome-associated,
while
weights
specificity all
as
using
units/mg
observed
IFNy can
chromatography,
kinases
the ability
demonstrating
the well
exchange
mouse IFNy (lo5
neutralized
similar
purification,
and 40K (kinase
as that
that
in L cells
of molecular
cytoplasmic
same level
induction,
ion
shown here
activity
Kinase
kinases
purified the
thus
them from
kinase
substrate.
distinct
of the
antiserum
are
We have
protein
70K (kinase
partially
D blocked
The three differentiates
I),
to about
activity,
exhibited
three
induction (a)
(9).
and DEAE-cellulose
into
the
eIF-2
casein)
filtration
kinase
kinase
(or
1OOK (kinase
responsible
factor
dsRNA-independent
activity
approximately
induced
initiation
which
dsRNA-dependent enzymes.
and III
did
Kinase not.
II was activated was sensitive
All
protein I three
in the
to NEM, an
BIOCHEMICAL
Vol. 104, No. 2, 1982 inhibitor
of SH enzymes.
kinase
II
while
the
from
kinases
others
phosphorylation
were
activities
provides
pleiotropic
effect determine
activities,
I and III,
requirement since
inactive.
it
that
possible
in regulation possible
and the
possible
data enhances
IFN y can induce
additional
also
against
suggest
that
function. substrates
of enzyme function
II
prote in kinase IFbcan
Studies for
kinase
activity.
cytoplasmic by which
differentiated
RNase and hexokinase
enzymatic
mechanisms
enzyme
alteration
RESEARCH COMMUNICATIONS
activity
several
of cellular
cellular
for
was active
Preliminary
of RNase A sign ificantly
The demonstration
further
Substrate
AND BIOPHYSICAL
are
exert in
the cytoplasmic as a result
a
progress
to
kinase of the
phosphorylation. ACKNOWLEDGMENTS ---This
study
was supported
by NIH Grant
AI 16248.
REFERENCES 1. 32: 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Zilberstein, A., Federman, R., Shulman, L., and Revel, M. (1976) FEDS Letters 67, 119-124. Lebleu, F., and Lengyel, P. (1976) Proc. Natl. Acad. Sci. USA 73, 3107-3111. Samuel, C.E., Farris, D.A., and Eppstein, D.A. (1977) Virology 83, 56-71. Samuel, C.E. (1979) Proc. Natl. Acad. Sci. USA 76, 600-604. Gupta, S.L. (1979) J. Virol. 29, 301-310. Gupta, S.L., Rubin, B.Y., and Holmes, S.L. (1979) Proc. Natl. Acad. Sci. USA 76, 4817-4821. Ohtsuki, K., and Baron, S. (1979) J. Biochem. 85, 1495-1502. Ohtsuki, K., Nakamura, M., Koike, T., Ishida, N., and Baron, S. (1980) Nature 287, 65-67. Robbins, C.H., Kramer, G., Saneto, R., Hardesty, B., and Johnson, H.M. (1981) Biochem. Biophys. Res. Commun. (in press). Hovanessian, A.G., Riviere, Y., Robert, N., Svab, J., Chamaret, S., Gullion, H.C., and Montagnier, L. (1981) Ann. Virol. (Inst. Pasteur) 132E, 157-188. Baglioni, C., and Maroney, P.A. (1980) J. Biol. Chem. 255, 8390-8393. Breeze, R.J., Dougherty, J.P., Pichon, J., Jayaram, B.M., and Lengyel, P. (1981) J. Interferon Res. 1, 191-201. and Johnson, H.M. (1979) Infect. Immun. 23, 80 Osborne, L.C., Georgiades, J.A., 86. Georgiades, J.A., Langford, M.P., Stanton, G.J., and Johnson, H.M. (1979) IRCS Med. Sci. 7, 559. Lowry, O.H., Rosebrough, M.J., Farr, A.L., and Randall, R.J. (1951) J. Biol. Chem. 193, 265-275.
429
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 422-429
CHARACTERIZATION OF IMMUNE TYPE INTERFERON (IFNy)-INDUCED CYTOPLASMIC PROTEIN KINASE ACTIVITY IN MOUSE L CELLS Kenzo
Ohtsuki,
Department
Received
November
Barbara
A. Torres,
of Microbiology, Galveston,
and Howard
M. Johnson
University of Texas Texas 77550 U.S.A.
Medical
Branch
30, 1981
SUMMARY: Mouse immune interferon (IFNV) induced double-stranded RNA-independent protein kinase activity in the cytoplasmic fraction of mouse L cells as measured against a histone substrate. Chromatographic purification separated the activity into three distinct kinases of imolecular weights of approximately 1OOK (kinase I), 70K (kinase II), and 70K (kinase III). Partially purified IFNY was as effective as crude in inducing protein kinase activity. Induction was blocked by treatment of IFNY with specific anti-IFNr antibody or by treatment of the L cells with actinomycin D. Kinase II activity was different $$orn that of kinases I and III in that it showed Ca-dependence in the absence of My , was inhibited in activity by the SH binding agent N-ethylmaleimide, and could use the cellular enzymes RNase A The described protein kinases could play an and hexokinase as substrates. important role in mediation of IFNY effects, particularly where phosphorylated enzyme substrates were shown to have altered activity.
It
has been demonstrated
interferon protein
(IFN)
results
in increased
phosphorylation
have partially
of cellular
purified
protein
kinase,
resulting
in the
inhibition
Recently,
we reported
for
IF/$
biological
from
(9).
study
properties
of mouse L cells. cytoplasmic
protein
kinase
total
and ribosomal
phosphorylates
also
kinases
induces
that
(37K)
synthesis protein
dsRNA-
of eIF-2, (4,7,8). kinase
of If?&-induced
virus-induced
ribosomal
IFNs as was also
shown
and characterize
the
(10-12).
kinase
against
422
determine
activity
IFNy induces
0006-291X/82/020422-08$01.00/0 Cop.yright 0 1982 by Academic Press, Inc. AN rights of reproduction m any form reserved.
We and others IFN-induced
subunit
protein
of induction
to further
as measured
small
with
and increased
(l-7).
dsRNA-dependent
for
A synthetase
of IFNy-induced We found
the
of cells
activity
proteins
of viral
observed
was undertaken
treatment
a ribosomal-associated
The kinetics
that
of 2',5'-oligo
The present
that
of initiation
that
was different
induction
distinct
which
in mouse L cells
kinase
laboratories
and characterized
dependent
activity
by several
in the
an increase a histone
cytoplasmic
in at least substrate.
fraction three A possible
Vol. 104, No. 2. 1982 biological
role
BIOCHEMICAL
of the
IFNY-induced
AND BIOPHYSICAL kinases
in the
RESEARCH COMMUNICATIONS
IFN-induced
biochelnical
events
is discussed.
MATERIALS
AND METHODS
Chemicals - [Y-32P]ATP (19.0 Ci/mol) was obtained from Amersharn Corp. Casein, phosvitin, pancreatic ribonuclease A (RNase A), dithiothreitol (DTT), calf thymus histone (type II-a) and CAMP were obtained from Sigma Chemicals Corp. DEAEConcanavalin A-Sepharose and Sephacryl cellulose (DE-52) was obtained from Whatman. S-200 were obtained from Pharmacia. - IFNywas produced in C57Blj6 mouse spleen cell Mouse IFNy preparation cultures using staphylococcal enterotoxin A as an inducer as previously described (13). The produced IFNywas partially purified by adsorption to controlled Poreglass beads and elution with 20% ethylene glycol and 1 M NaCl in phosphate buffered Following dialysis against PBS, the IFNYfraction was applied on saline (PBS) (14). a concanavalin A-Sepharose column and eluted with 0.25 M a-methyl-Dgmannoside in PBS. The final product had a specific activity of approximately 10 units/mg protein. Treatment of thq cells with IFNs - Confluent monolayers of mouse L cells (about lo8 cells) in 150 cmL flasks were treated with 300 reference units/ml of IFN for 12 hrs at 37'C. The cells were harvested by scraping with a rubber policeman, centrifuged, washed twice with PBS, and cytoplasmic fractions were prepared as described below for testing protein kinase activity. Cytoplasmic fraction Icrude kinase fraction1 1 The cytoplasmic fractions fgom untreated and IFN -treated cells were prepared as follows. The cells (about 10 cells) were gently homogenated with a glass homogenizer in 3 ml of 10 IBM Tris-HCl 2 mM dithiothreitol (DTT) and 10 mM KCl, and then (pH 7.5) containing 2 mM CaCl The supernatant was recentrifuged at high centrifuged for 20 min at 12,8;0 rpm. speed (105,000 Xg for 45 min) to remove ribosomes from the fraction. The obtained supernatant was concentrated to 1.0 ml using polyethylene glycol 20000 powder. The concentrated solutions were dialyzed overnight at 4°C against 10 mM Tris-HCl (pH 7.5) containing 0.5 M KCl, 2 mM DTT and 10%glycerol (Suffer A). The dialyzed fractions were used as crude kinase preparations (cytoplasmic fractions) for the purification and kinase assay in this study. Assay of protein kinase activity - The complete reaction mixture (0.1 ml) contained 39 mM Tris-HCl (pH 7.5), 4 mM DTT, 10 ug of bovine serum albumin (BSA), 100 uE1 [yP]ATP (2,000 cpm/pmol), the indicated ayyunts o$+substrate (histone or or Ca and the indicated other proteins), the indicated amounts of either Mg amounts of protein kinase purified or unpurified from the cytoplasmic fraction of After incubation for the periods indicated at 37Y, the enzyme mouse L cells. reaction was terminated by the addition of 0.5 ml of 0.2 M sodium pyrophosphate containing BSA (1 mg/ml) and 0.5 ml of 20% trichloroacetic acid. The precipitate WJ~ collected by filtration through a Whatman glass filter (type GF/F) and the [ Plradioactivity of the filter was determined by a liquid scintillation spectrometer after drying. Protein measurement - Protein concentration of the enzyme preparations was determined by the method of Lowry et al. (15). RESULTS IFNY-induced
cytoplasmic
When mouse L cells reference (histone
units/ml)
for
phosphorylation
as compared
with
that
protein
kinase
(about
lo8
12 hrs
at 37'C,
with
cells)
activity were the
cells
(Table
423
exposed
activity
CY-~~ P]ATF)frorn
of untreated
in mouse L cells to crude of cytoplasmic
such cells 1).
mouse IFNv (300
This
protein
was significantly increased
protein
kinase increased kinase
BIOCHEMICAL
Vol. 104, No. 2. 1982
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Table 1. Characterization of interferons as stimulators cytoplasmic protein kinase activity in mouse L cells.
of
ProteQ kinase activity (pm01 cv- P]ATP/pg histone)
Treatments None Mouse IFNy Mouse IFNy + actinomycin Mouse IFNo/@ Human IFNa Mouse IFNY + anti-mouse
18.5 63.8 22.8 40.2 19.1 23.0
D IFNv antiserum
Crude kinase fractions (cytoplasmic fractions) were prepared from untreated mouse L cells or cells treated with 300 units/ml of mouse IFNy (crude), or5cells treated with 300 units/ml of human IFNa (specific activity 10 units/mg) for 6 hrs at 37*C. Actinomycin D (1 vg/ml) was Protein kinase added to the cell cultures at the same time as IFNy. activity of the fractigns was assayed using either histone (type 34-A) in the presence of Mg (3 mM) or phosvitin in the presence of Ca (3 mM) as descri!>ed in Materials and3Methods. Anti-mouse IFWy antiserum was preincubated with mouse IFNY (10 units/ml) for 30 min at 37OC before exposure to the cells, at a concentration that completely neutralized the antiviral activity.
activity
was also
However,
no increase
human leukocyte
pg/ml),
in the
interleukins strongly kinase
inhibits
antiserum
activity
suggest
Tris-HCl
(pH 7.5)
by the
antiserum
fractions S-200
and P-II) The kinase
molecular were activity
of
is
antiviral
state
with
factor
(unpublished the
treated
by IFNs.
the
in D (1
Also,
kinase lymphokines,
data).
increase
with
resistance
protein
against
for
was used.
actinomycin
induced
IFNv to induce
responsible
These
of total
data
protein
of mouse L cells,
kinases
from
untreated
(1.5
0.5
appreciable
not reactive
fraction
column
containing
by their
addition
cytoplasmic
in cells
mouse IFNv together
stimulating IFNv is
units/my)
was observed
of antiviral
of IFNy-induced
a Sephacryl
acceptor.
mouse
in the
through
(P-I
with
induce
the ability
This
that
The cytoplasmic
activities
not
the development
cells.
IFNv (lo5
activity
does
treated
neutralized
purification
kinases
which
cells
purified
kinase
1 and 2 or colony
activity
Partial
of protein
or from
which
anti-IFNv
when partially
IFN (IFNu)
L ce?ls,
mouse
obtained
X 50 cm) previously
M KCl,
size
and IFNv-treated
of the
of 10 PM CAMP, whereas
histone
first
peak
the activity 424
(or (P-I)
casein)
with
10 mM kinase
1, two distinct
as a phosphate
was significantly
of the
passed
to separate
As shown in Fig.
using
were
equilibrated
2 mM DTT and 10% glycerol
differences.
detected
cells
second
peak
stimulated (P-II)
was
Vol. 104, No. 2. 1982
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
3s 5 8 22
0
1
0
0 1
30
40
50
Fraction
Fig.
slightly and
1.
Separation filtration. untreated units/ml) Aliquots described (Xl.
inhibited P-II)
by
from
cells
to
IFN.
37°C)
of
the
treatment
protein kinase activities by Sephacryl S-ZOO gel The cytoplasmic fractions were prepared from cells (0) and cells treated with mouse IFNY (300 for 2 hrs (A) and 6 hrs (O), respectively, at 37'C. (5 ~1) were assayed against a histone substrate as in the Materials and Methods. Absorbance at 280 nm
CAMP.
Total cells
The
activity
of
the
specific
order
to
peak cells
number
of
IFNY-treated
second
60
(P-II with
protein
kinase
activities
increased
with
increased
(histone
kinase) IFNv
time
both
increased
units/ml)
fractions
of
phosphorylation/pg
was
(300
of
exposure
of
protein/min
approximately
as
(P-I
compared
at
3-fold with
that
the
6 hr of
after
untreated
cells. In IFNu-treated column. buffer tne
The
other
kinase
2).
The
between The
active
respectively, molecular
the
was
0.2
were
eluted
as
active P-II
was
between
fractions
0.05
0.3 in
M KC1 the
immediately kinases
two
on
between
0.15
M and
and
designated
separated
into
two
kinases:
(Fig.
0.1 3).
Only
and
as 425
the
kinase
column by
III
M KC1
0.2 as the
other II
from
M KC1
the
I.
first
On
peak III)
was RNase
were 20000.
a Sephacryl
in
kinase
phosphorylated
jlycol on
P-II)
(kinase
chromatography
polyethylene deteri,rined
and
a DEAE-cellulose
pooled
M and
and
(P-I
were
DEAE-cellulose
II
kinases applied
peak
concentrated I,
distinct
separately
a single
fractions kinase
M and
of
the
fractions
eluted
and weight
characterize
the
P-I
hand, II)
eluted A.
cells,
(Fig.
(kinase
further
pooled, The
S-200
column
Vol. 104, No. 2. 1982
BIOCHEMICAL
AND BIOPHYSICAL
r
Kinase
RESEARCH COMMUNICATIONS
I
0.6
Fraction
Fig.
were
DEAE-cellulose column chromatography of P-I fraction from the cytoplasmic fraction of IFNy-treated cells. The P-I kinase fraction was applied to a column (1.5 X 8 cm) of DEAEcellulose previously equilibrated with 10 mM Tris-HCl (pH 7.5) containing 2 mM OTT and 10% glycerol. The column was washed with 10 ml of the same buffer and fractions (0.5 ml) were collected. Elutions were carried out with a linear gradient (0 M to 0.5 M KCl) in the buffer. Aliquots (5 ~1) were assayed as described in the Materials and Methods. Histone phosphorylating activity (0) and absorbance at 280 nm (X).
2.
lOOK,
approximately
marker
proteins.
318-fold
with
Requirements
activity for
histone
70K and 70K,
Kinases
I,
II
yields
respectively, III
and
kinase
conditions or casein
for were
were
as measured
purified
about
by comparison
250-fold,
350-fold
activity
of the
suitable
kinases
phosphate
Kinase
are
summarized
acceptors.
in Table
The optima1
II
I
0 50
30 Fraction
3.
and
activities
I
Fig.
with
of 45%, 25% and 38%, respectively.
IW-induced
The optima1 Either
number
70
number
DEAE-cellulose column chromatography of P-II fraction from the cytoplasmic fraction of IFNY-treated cells. The OEAEcellulose column chromatography of P-II kinase was performed as described in Fig. $+ Histone phosphorylating activity was in the presence of Mg (5 mM) (0).2+RNase phosphorylating activity was in the presence of Ca (3 mM) (0). Absorbance at 280 nm (X).
426
2.
Vol. 104, No. 2. 1982
BIOCHEMICAL
Table
Reaction
mixtures
Complete Complete Complete Complete Complete Complete Complete
+ +
2.
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Requirements for activity of from IFNY-treated cells
(pm01 Kinase
Protejs &I
kinases
kinase activity P]ATP/Pq histone) Kinase II
36.6 0.2 0.3 0.1 32.9 58.5 32.6
Mg $1 Mg + Ca2+ Histone DTT + NEM CAMP dsRNA
the
Kinase
4.9 0.1 6.4 0.1 0.1 2.8 5.0
III
15.4 0.1 0.1 1Z 14:3 14.6
The complete reaction mixture (0.1 ml) contained 20 mM Tris-HCl (pH 7.5), 3 mM MgCl or 3 rnlJ2CaC1 4 mM DTT, 10 Pg of BSA, 20 Pg of histone (type II-A), 106 PM [YPlATsland either kinase I, kinase II or kinase III at 0.5 ug each. The reaction mixture was incubated for 10 min at 37OC. The concentration of CAMP, N-ethylmaleimide (NEM) and dsRNA (poly rI:poly rC) was 3 PM, 1 mM and 100 rig/ml, respectively.
concentration absolute
of requirement
contrast
to
this,
ethylmaleimide
dsRNA
(poly
rig/ml
to
II
(3 uM) an
for
was
was
on
on
by
the
2+
I
other
three
I and
activated
absence
activity stronyly
of
iiig
2+
activities
.
an In
protein
2.6-fold.
Nthe
stirlruldt.inJ at
Ca
had
2+
for
inhibited No
III
by
about
kinases.
kinase
Kinases
not
in
SH enzymes,
the
oM.
were
Ca
kinase
of
3-5
and
activated
inhibitor
rC)
was
activity,
enhanced
no effect
poly
1 mg/rnl)
The
substrate
3.
Kinases
casein
phosphate
is
CAMP
kinases
activity
effect
any
concentration
kinases
are
of (10
observed.
requirements
Table
and
II
had
r1:
Substrate
and
but
Mg
three
2+
kinase
(NEM),
kinase
the
for
phosphorylation.
of
for
My'+
in
requirements
in
a Ca-dependent
substrate
were
presence
of
the
the
presence
protein
requirements
of
partially
similar
Mg 2+
In contrast
acceptors.
hexokinase
III
I and
the
of
in
(5 to
kinase
(in
kinase
II
phosphorylation
r&l) , while this,
Ca 2+
of
purified
the are
hexokinase
II
kinase (3
of
rtil).
These
absence
of
different
histone,
and
from
show The
those
A were both
results
of
in
lphosvitin
RNase
phosphorylated
MJ*+).
summdrized
RNase
that
data kinases
poor
kinase show
ttldt
I and
A II the
III.
DISCUSSION We have dependent
previously
protein
kinase
shown activity
that
mouse in
IFNy
mouse
can
L cells 427
induce that
ribosome-associated phosphorylates
dsRNAthe
a subunit
Vol. 104. No. 2. 1982 Table
BIOCHEMICAL 3.
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
Substrate requirement of the three distinct purified from the cytoplasmic fraction of IFNv-treated cells
kinases
Protein kinase activity (pnol [Y-~~P]ATP/@ histone) Kinase I Kinase II M9*+ Ca*+ M9*+ Ca*+
Substrate Histone Casein Mouse Igti RNase A
36.5 1.4 2.9 1.7
N.D. N.D. N.D. N.D.
4.4 2.8 3.1 3.7
Phosvitin Hexokinase BSA
:':' 0:l
N'D' ND N:O:
5'2 19 N:D.
Kinase M92+
6.3 2.2 4.8 5.7 2.8 9.1 N.D.
III Ca*+ N.D. N.D. N.D. N.D. ND N'D' N:D:
14.5 8.1 1.8 1.5 1:':' N:D.
The protein kinase activity of kinase I, kinase II and kinase III (all at 0.5 ug) was incubated, respectively, for 10 min at 37Y wish variojf substrates (20 pg each) in the presence of either Mg or Ca (3 mM). The activity of kinase I was assayed in the pr!:efz!z of 3 UM CAMP. N.D. = not detected.
of eukaryotic also
peptide
induce
cytoplasmic
measured
against
Sephacryl
S-200
separated
the
a histone gel
for
observation
that:
the
kinase
(b)
specific
(c)
actinomycin
activity anti-IFNv
kinases
kinases presence
(7-11).
They are,
CAMP-dependent required
Mg2+ for
of Ca2+ (absence
II),
three
(d)
however, activity,
of
and mouse IFNa/6, species
in that
they
are
functionally
activation,
but
of Mg2+).
Only
distinct
kinases
II
only
kinase
kinase 428
II
III).
of IFNYis
as evidenced
by the
protein)
with
crude
IFNvto but
induced
mouse IFNy,
induce
not
activity,
human IFNa,
in
induction.
dsRNA-independent,
known ribosome-associated,
while
weights
specificity all
as
using
units/mg
observed
IFNy can
chromatography,
kinases
the ability
demonstrating
the well
exchange
mouse IFNy (lo5
neutralized
similar
purification,
and 40K (kinase
as that
that
in L cells
of molecular
cytoplasmic
same level
induction,
ion
shown here
activity
Kinase
kinases
purified the
thus
them from
kinase
substrate.
distinct
of the
antiserum
are
We have
protein
70K (kinase
partially
D blocked
The three differentiates
I),
to about
activity,
exhibited
three
induction (a)
(9).
and DEAE-cellulose
into
the
eIF-2
casein)
filtration
kinase
kinase
(or
1OOK (kinase
responsible
factor
dsRNA-independent
activity
approximately
induced
initiation
which
dsRNA-dependent enzymes.
and III
did
Kinase not.
II was activated was sensitive
All
protein I three
in the
to NEM, an
BIOCHEMICAL
Vol. 104, No. 2, 1982 inhibitor
of SH enzymes.
kinase
II
while
the
from
kinases
others
phosphorylation
were
activities
provides
pleiotropic
effect determine
activities,
I and III,
requirement since
inactive.
it
that
possible
in regulation possible
and the
possible
data enhances
IFN y can induce
additional
also
against
suggest
that
function. substrates
of enzyme function
II
prote in kinase IFbcan
Studies for
kinase
activity.
cytoplasmic by which
differentiated
RNase and hexokinase
enzymatic
mechanisms
enzyme
alteration
RESEARCH COMMUNICATIONS
activity
several
of cellular
cellular
for
was active
Preliminary
of RNase A sign ificantly
The demonstration
further
Substrate
AND BIOPHYSICAL
are
exert in
the cytoplasmic as a result
a
progress
to
kinase of the
phosphorylation. ACKNOWLEDGMENTS ---This
study
was supported
by NIH Grant
AI 16248.
REFERENCES 1. 32: 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Zilberstein, A., Federman, R., Shulman, L., and Revel, M. (1976) FEDS Letters 67, 119-124. Lebleu, F., and Lengyel, P. (1976) Proc. Natl. Acad. Sci. USA 73, 3107-3111. Samuel, C.E., Farris, D.A., and Eppstein, D.A. (1977) Virology 83, 56-71. Samuel, C.E. (1979) Proc. Natl. Acad. Sci. USA 76, 600-604. Gupta, S.L. (1979) J. Virol. 29, 301-310. Gupta, S.L., Rubin, B.Y., and Holmes, S.L. (1979) Proc. Natl. Acad. Sci. USA 76, 4817-4821. Ohtsuki, K., and Baron, S. (1979) J. Biochem. 85, 1495-1502. Ohtsuki, K., Nakamura, M., Koike, T., Ishida, N., and Baron, S. (1980) Nature 287, 65-67. Robbins, C.H., Kramer, G., Saneto, R., Hardesty, B., and Johnson, H.M. (1981) Biochem. Biophys. Res. Commun. (in press). Hovanessian, A.G., Riviere, Y., Robert, N., Svab, J., Chamaret, S., Gullion, H.C., and Montagnier, L. (1981) Ann. Virol. (Inst. Pasteur) 132E, 157-188. Baglioni, C., and Maroney, P.A. (1980) J. Biol. Chem. 255, 8390-8393. Breeze, R.J., Dougherty, J.P., Pichon, J., Jayaram, B.M., and Lengyel, P. (1981) J. Interferon Res. 1, 191-201. and Johnson, H.M. (1979) Infect. Immun. 23, 80 Osborne, L.C., Georgiades, J.A., 86. Georgiades, J.A., Langford, M.P., Stanton, G.J., and Johnson, H.M. (1979) IRCS Med. Sci. 7, 559. Lowry, O.H., Rosebrough, M.J., Farr, A.L., and Randall, R.J. (1951) J. Biol. Chem. 193, 265-275.
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