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Ribosome degradation in escherichia coli induced by colicin E2
BIOCHEMICAL
Vol. 54, No. 3, 1973
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RIBOSOME DEGRADATION IN ESCHERICHIA COLI INDUCED BY COLICIN E2
Akira
Yanai*,
Teruhiko
Beppu and Kei Arima
Laboratory of Microbiology and Fermentation Department of Agricultural Chemistry University of Tokyo Tokyo, Japan * Present address:Basic Research Toray Industries, Inc., 1,111 Kamakura 248 Japan Received
August
27,
Laboratory Tebiro,
1973 SUMMARY
The mode of action of colicin E2 on ribosomes in Escherichia coli cells was investigated by zonal centrifugation analysis. Ribosome particles, both 50s and 3OS, were degraded to smaller contents with the lapse of time by the action of colicin E2. Gradual reduction of S values of each particles could not be observed and degradative intermediates of possible RNA-protein complex were detected only at the position between 30s and 4s in the zonal centrifugation profile, which indicated the destruction 50s ribosome fraction of ribosome in burst-out attitude. influenced by colicin E2 contained both 23s and half-sized RNA. From these data, the mode of action of colicin E2 on ribosomes in E. coli was discussed.
INTRODUCTION Colicin
E2, one of the
Enterobacteriaceae 60,000) genus
(11, (2).
inhibition
t-RNA
division
DNA (2,4,5)
degradation in Escherichia
of
protein
by certain (molecular
strains
biochemical
action
induction
weight
of the is
(4),
colicin
23s and 16s ribosomal 413,
a defective
of degradation
1185
E2 - challenge RNA, but mutant
same
the
and RNA (4,6).
coli
Copyright @ 1973 by Academic Press, Inc. All rights of reproduction in any form reserved.
its
produced
to certain
(3) and the
previously of
a simple only
The main feature
As we reported induces
is
and bactericidal
of cell
of cellular
strains,
bacteriocins
for
not of
Vol. 54, No. 3,1973
ribonuclease
BIOCHEMICAL
I.
degradative
This
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
suggests
enzyme for
that
RNaseI,
RNA in E. coli
which
cells,
is the main
does not participate
in the r-RNA degradation. We investigated alteration
further
of ribosome
and followings degraded
constitution
action
reduction
of
only
ribosomes
could
at the
split
retain
contents
position
halves
both
not be
30s and 4s in
the ribosome
in 50s ribosomes,
before
particle
suggested
structure
of
RNA-protein
indicated
E2, which
their
could
between
Second,
into
were
were decreased.
of possible
which
by colicin
yet
cells
action,
particles
each particles
attitude.
23s RNA was first induced
of
profile,
in burst-out
destruction
E2, and the
sensitive
and the
the colicin
ribosome
intermediates
centrifugation
destruction
First,
S values
were increased
the zonal
their
in the
and degradative
complex
during
of colicin
50s and 305 particles
observed
r-RNA degradation
were suggested.
by the
Gradual
the
with
that
50s
the damaged RNA.
MATERIALS AND METHODS Colicin
E2 was prepared
was cultured (Difco)
with
supplemented
(0.5pCi/ml.) of
(10,000xg, washed cells
At
Sakaguchi
with
at
intervals,
(10,000xg, dryice-acetone
to the
E. coli
1% Penassay or
cell
Q13
broth
[3Hllysine
concentration
and washed by centrifugation
in 70ml.
broth
of
at 37“C.
1% Penassay
After
broth
the
resumed
E2 was added at 6x108 cells/ml.
50). 20ml.
20min.)
flask
37OC, colicin
multiplicity
of
(7).
(0.2pCi/ml.)
1% Penassay
resuspended
growing
(lOug/ml.,
[ 14Cluracil
and collected
15min.)
before
at 37OC in 70ml.
with
in 500ml
5.5xlOS/ml.,
normal
shaking
as reported
aliquots
of the
and the pellets
and stored
overnight
1186
culture
were rapidly at
-75'C.
were centrifuged freezed
by
The collected
BIOCHEMICAL
Vol. 54, No. 3,1973
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Fig.1 Effect of colicin E2 on zonal centrifugation profile of ribosomes in E. coli Q13 labelled with [l4C]uracil. A: Omin., B: 30min., C: 70min. Detailes are shown in Materials and Methods. Fig.2 Effect of colicin E2 on zonal centrifugation profile of ribosomes in E. coli Q13 labelled with [3H]lysine. A: Omin., B: 30min., C: 70min. cells
were suspended
buffer
(pH 7.4)
sonically
for
a needle
at
profiles
were obtained
of each fraction
The diluted
COONa, pH5.1)
(pH5.1)
SDS at and zonally (1.5
37'C,
of
and zonal
O.lM
for
centrifuged
RPS40 rotor.
1187
37,000 by
centrifugation of O.lml.
NaCl-0.05M
scintillation
- 15% sucrose
in a Hitachi
at
the radioactivities
0.4ml.
by liquid
0.2ml.
linear
was performed
505 and 30s peak fractions
0.3% recrystallized
density-gradients
with
on 4.8ml.
RPS40 rotor
of tubes
by measuring
20min.,
in 1OmM Tris-HCl-O.lmM
Fractionation
the bottom
diluted
buffer
(8),
were charged
and
condition
at lO,OOOxg,
and CentrifugedinHitachi
piercing
O.lmM MgC12
disintegration
(S-2O%w/w)
at 4OC.
Gesteland
constant
fractions
170min.,
Na-acetate
1OmMTris-HCl
centrifugation
density-gradients
MgC12 (pH 7.4)
of
30mM NH4Cl-6mM 2-mercaptoethanol
under
After
supernatant
sucrose
rpm,
containing
oscillated
(35W, -/min.). of the
in 10ml.
counting.
were incubated
30min., through in O.lM
according linear NaCl-0.05M
with
to R.F. sucrose CH3-
23s and 16s peaks of
BIOCHEMICAL
Vol. 54, No. 3,1973
RNA were detected scintillation
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
by measuring
[ 14C)radioactivities
by liquid
counting.
RESULTS AND DISCUSSION In zonal phenol
centrifugation
method from E. coli
appeared
three
We had already
induced
gradual
ribosomal
RNAs except
particles
during
investigated
reported
here inzonal
sucrose
possessing
In the profile
be observed hand,
with
we could
profile
These data
of colicin
labelled
after
the
suggested
degradative suggested degraded gradually
of RNA-protein intermediates that
ribosome
abruptly decreasing
into
smaller size
of
On the other
(Fig.2),
increased
in
there
also
same position
substances
of ribosome
Furthermore,
the
found between
fragments intermediates. 1188
not
E2 challenge.
especially
particles,
could
density-gradient
30s and 4S, the
intermediates
were not
heights
of radioactivity
[3H]lysine
these
complex.
(Fig.l-b,
decreased
In sucrose
colicin
that
cells
(S-value)
increase
with
between
size
as
particles.
E2 challenge.
the gradual
30s and 4s were degradative consisted
E. coli
in their
30s and 4s peaks.
c,
of E. coli
showed the profile
decrease
a peak increased
as in Fig.l-b,
E2 was
fraction
SOS and 305 with
of ribosomes
appeared
supernatant
lapse
two
profile.
E2-challenged
recognize
the peak between
by colicin
peaks of
the
E2
change in ribosome
density-gradient
of colicin
but gradual
of colicin
and amounts of the
Structural
(4).
there
16s r-RNA and 4s
50s and 305 peaks of ribosome
I two radioactive
appeared
S-values
by SDS-
[14C]uracil,
the addition
centrifugation
of the
through
in Fig.l-a
that
of both
t-RNA
with
23s r-RNA,
such RNA degradation
Centrifugation sonicate
peaks,
decrease
of RNAs extracted
Q13 labelled
radioactive
t-RNA.
cl
profile
particles fact
that
50s and 30s
50s particles,
without
between
producing
BIOCHEMICAL
Vol. 54, No. 3,1973
a.
8-
b
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
c
165
3-
235
b
a
C
0
r z “2.
Fig.3 Zonal centrifugation profile RNA in 50s ribosomes treated with colicin A: Omin., B: 30min., C: 70min.
of E2.
Fig.4 Zonal centrifugation profile RNA in 30s ribosomes treated with colicin A: Omin., B: 30min., C: 70min.
of E2.
Possibility particles
could
not
in the colicin-treated
extracting
operations
artificial
products
In order process
cells
further
was found treated
consisted
shoulder
S-values,
contained
but
In contrast,
reported
might
Q13 at
RNA of of the
in 50s
about
30s peaks in The
come from the contamination
activity
1189
of
of Fig.l-c.
storage
O'C for
16s
colicin-
as is shown in Fig.4.
of
purified
ribosome
a few weeks resulted
23s and 16S, to the
and endonuclease
RNAs respecRNAs or not.
each RNAs from
in 1969 that
both
intact
smaller
in the profile
from E. coli
from the
their
50s particles
of one 16s peak,
of r-RNA,
were
one peak of 23s RNA was found
cells(a),
intermediates
W. Szer
cleavage
only
shown in Fig.4-c
degradative
particles
c).
extracted
they
235 RNA in the
cells(b,
to the
on the degradation
50s and 30s particles
whether
the control
besides
ribosome
intermediates"
information
were isolated,
As shown in Fig.3, from
the
became unstable
"degradative
particles,
and analyzed
ribosome
that
by sonication.
of ribosome
tively,
however,
cells
and the
to obtain
colicin-treated
Fig.1
be excluded
fragments
of RNase IV type
with
in a half
in split
BIOCHEMICAL
Vol. 54, No. 3, 1973
protein
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
was assumed to be involved
in this
limited
degradation
(9). It dation
seems possible in E. coli
follows.
to account
413 cells
Adsorption
influences change,
slight
of RNase IV type a nick
or nicks
at first
into
in the pieces
Structural when this
entities
limited
But ribosomes
loosened
and made sensitive
loss
of
particle
fragments. give
In 50s ribosome,
about
degradation
Then further
half
with
Investigation
breakdown
unmasked and makes 23s RNA is
of r-RNA results
Dr.
into
2. 3. 4. 5. 6. 7. 8. 9.
intermediate
structure. Takahisa
Ohta
Herschman, H. R., and Helinski, D. R. (1963) J. Biol. Chem. 242, 5360-5368. Nomura, M. (1967) Ann. Rev. Microbial. 21, 257-284. Beppu, T., and Arima, K. (1972) J. Bacterial. 110, 485-493. Yanai, A., Beppu, T., and Arima, K. (1970) Agr. Biol. Chem. 34, 149-151. Beppu, T., and Arima, K. (1971) J. Biochem.(Tokyo) 7J, 263-271. Nose, K., Mizuno, D., and Ozeki, H. (1966) Biochem. Biophys. Acta. 9, 636-638. Beppu, T., and Arima, K. (1967) J. Bacterial. 93, 80-85. Gesteland, R. F. (1966) J. Mol. Biol. 18, 356-371. Szer, W. (1969) Biochem. Biophys. Res. Commun. 35, 653-658.
1190
even
from in
small
REFERENCES 1.
split
has
RNase distinct
degradative
on the ribosome to thank
RNase activity
can be retained
and degradation the
structural
damaged r-RNA are
to cytoplasmic
about
Acknowledgement: We wish for his useful advices.
induce
RNA component
a limitedly
enzymatic
somehow
S-value.
of their
conformation
some information
gets
of the ribosomes
occurred.
RNase I.
protein(s)
degra-
E2 as
surface
in the particles.
r-RNA.
with
of colicin
one by one to
unfolding, split
mode of ribosome
E2 to cell
in the cells
in the
the
by the action
of colicin
ribosomes e.g.,
for
may
Vol. 54, No. 3, 1973
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
RIBOSOME DEGRADATION IN ESCHERICHIA COLI INDUCED BY COLICIN E2
Akira
Yanai*,
Teruhiko
Beppu and Kei Arima
Laboratory of Microbiology and Fermentation Department of Agricultural Chemistry University of Tokyo Tokyo, Japan * Present address:Basic Research Toray Industries, Inc., 1,111 Kamakura 248 Japan Received
August
27,
Laboratory Tebiro,
1973 SUMMARY
The mode of action of colicin E2 on ribosomes in Escherichia coli cells was investigated by zonal centrifugation analysis. Ribosome particles, both 50s and 3OS, were degraded to smaller contents with the lapse of time by the action of colicin E2. Gradual reduction of S values of each particles could not be observed and degradative intermediates of possible RNA-protein complex were detected only at the position between 30s and 4s in the zonal centrifugation profile, which indicated the destruction 50s ribosome fraction of ribosome in burst-out attitude. influenced by colicin E2 contained both 23s and half-sized RNA. From these data, the mode of action of colicin E2 on ribosomes in E. coli was discussed.
INTRODUCTION Colicin
E2, one of the
Enterobacteriaceae 60,000) genus
(11, (2).
inhibition
t-RNA
division
DNA (2,4,5)
degradation in Escherichia
of
protein
by certain (molecular
strains
biochemical
action
induction
weight
of the is
(4),
colicin
23s and 16s ribosomal 413,
a defective
of degradation
1185
E2 - challenge RNA, but mutant
same
the
and RNA (4,6).
coli
Copyright @ 1973 by Academic Press, Inc. All rights of reproduction in any form reserved.
its
produced
to certain
(3) and the
previously of
a simple only
The main feature
As we reported induces
is
and bactericidal
of cell
of cellular
strains,
bacteriocins
for
not of
Vol. 54, No. 3,1973
ribonuclease
BIOCHEMICAL
I.
degradative
This
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
suggests
enzyme for
that
RNaseI,
RNA in E. coli
which
cells,
is the main
does not participate
in the r-RNA degradation. We investigated alteration
further
of ribosome
and followings degraded
constitution
action
reduction
of
only
ribosomes
could
at the
split
retain
contents
position
halves
both
not be
30s and 4s in
the ribosome
in 50s ribosomes,
before
particle
suggested
structure
of
RNA-protein
indicated
E2, which
their
could
between
Second,
into
were
were decreased.
of possible
which
by colicin
yet
cells
action,
particles
each particles
attitude.
23s RNA was first induced
of
profile,
in burst-out
destruction
E2, and the
sensitive
and the
the colicin
ribosome
intermediates
centrifugation
destruction
First,
S values
were increased
the zonal
their
in the
and degradative
complex
during
of colicin
50s and 305 particles
observed
r-RNA degradation
were suggested.
by the
Gradual
the
with
that
50s
the damaged RNA.
MATERIALS AND METHODS Colicin
E2 was prepared
was cultured (Difco)
with
supplemented
(0.5pCi/ml.) of
(10,000xg, washed cells
At
Sakaguchi
with
at
intervals,
(10,000xg, dryice-acetone
to the
E. coli
1% Penassay or
cell
Q13
broth
[3Hllysine
concentration
and washed by centrifugation
in 70ml.
broth
of
at 37“C.
1% Penassay
After
broth
the
resumed
E2 was added at 6x108 cells/ml.
50). 20ml.
20min.)
flask
37OC, colicin
multiplicity
of
(7).
(0.2pCi/ml.)
1% Penassay
resuspended
growing
(lOug/ml.,
[ 14Cluracil
and collected
15min.)
before
at 37OC in 70ml.
with
in 500ml
5.5xlOS/ml.,
normal
shaking
as reported
aliquots
of the
and the pellets
and stored
overnight
1186
culture
were rapidly at
-75'C.
were centrifuged freezed
by
The collected
BIOCHEMICAL
Vol. 54, No. 3,1973
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Fig.1 Effect of colicin E2 on zonal centrifugation profile of ribosomes in E. coli Q13 labelled with [l4C]uracil. A: Omin., B: 30min., C: 70min. Detailes are shown in Materials and Methods. Fig.2 Effect of colicin E2 on zonal centrifugation profile of ribosomes in E. coli Q13 labelled with [3H]lysine. A: Omin., B: 30min., C: 70min. cells
were suspended
buffer
(pH 7.4)
sonically
for
a needle
at
profiles
were obtained
of each fraction
The diluted
COONa, pH5.1)
(pH5.1)
SDS at and zonally (1.5
37'C,
of
and zonal
O.lM
for
centrifuged
RPS40 rotor.
1187
37,000 by
centrifugation of O.lml.
NaCl-0.05M
scintillation
- 15% sucrose
in a Hitachi
at
the radioactivities
0.4ml.
by liquid
0.2ml.
linear
was performed
505 and 30s peak fractions
0.3% recrystallized
density-gradients
with
on 4.8ml.
RPS40 rotor
of tubes
by measuring
20min.,
in 1OmM Tris-HCl-O.lmM
Fractionation
the bottom
diluted
buffer
(8),
were charged
and
condition
at lO,OOOxg,
and CentrifugedinHitachi
piercing
O.lmM MgC12
disintegration
(S-2O%w/w)
at 4OC.
Gesteland
constant
fractions
170min.,
Na-acetate
1OmMTris-HCl
centrifugation
density-gradients
MgC12 (pH 7.4)
of
30mM NH4Cl-6mM 2-mercaptoethanol
under
After
supernatant
sucrose
rpm,
containing
oscillated
(35W, -/min.). of the
in 10ml.
counting.
were incubated
30min., through in O.lM
according linear NaCl-0.05M
with
to R.F. sucrose CH3-
23s and 16s peaks of
BIOCHEMICAL
Vol. 54, No. 3,1973
RNA were detected scintillation
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
by measuring
[ 14C)radioactivities
by liquid
counting.
RESULTS AND DISCUSSION In zonal phenol
centrifugation
method from E. coli
appeared
three
We had already
induced
gradual
ribosomal
RNAs except
particles
during
investigated
reported
here inzonal
sucrose
possessing
In the profile
be observed hand,
with
we could
profile
These data
of colicin
labelled
after
the
suggested
degradative suggested degraded gradually
of RNA-protein intermediates that
ribosome
abruptly decreasing
into
smaller size
of
On the other
(Fig.2),
increased
in
there
also
same position
substances
of ribosome
Furthermore,
the
found between
fragments intermediates. 1188
not
E2 challenge.
especially
particles,
could
density-gradient
30s and 4S, the
intermediates
were not
heights
of radioactivity
[3H]lysine
these
complex.
(Fig.l-b,
decreased
In sucrose
colicin
that
cells
(S-value)
increase
with
between
size
as
particles.
E2 challenge.
the gradual
30s and 4s were degradative consisted
E. coli
in their
30s and 4s peaks.
c,
of E. coli
showed the profile
decrease
a peak increased
as in Fig.l-b,
E2 was
fraction
SOS and 305 with
of ribosomes
appeared
supernatant
lapse
two
profile.
E2-challenged
recognize
the peak between
by colicin
peaks of
the
E2
change in ribosome
density-gradient
of colicin
but gradual
of colicin
and amounts of the
Structural
(4).
there
16s r-RNA and 4s
50s and 305 peaks of ribosome
I two radioactive
appeared
S-values
by SDS-
[14C]uracil,
the addition
centrifugation
of the
through
in Fig.l-a
that
of both
t-RNA
with
23s r-RNA,
such RNA degradation
Centrifugation sonicate
peaks,
decrease
of RNAs extracted
Q13 labelled
radioactive
t-RNA.
cl
profile
particles fact
that
50s and 30s
50s particles,
without
between
producing
BIOCHEMICAL
Vol. 54, No. 3,1973
a.
8-
b
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
c
165
3-
235
b
a
C
0
r z “2.
Fig.3 Zonal centrifugation profile RNA in 50s ribosomes treated with colicin A: Omin., B: 30min., C: 70min.
of E2.
Fig.4 Zonal centrifugation profile RNA in 30s ribosomes treated with colicin A: Omin., B: 30min., C: 70min.
of E2.
Possibility particles
could
not
in the colicin-treated
extracting
operations
artificial
products
In order process
cells
further
was found treated
consisted
shoulder
S-values,
contained
but
In contrast,
reported
might
Q13 at
RNA of of the
in 50s
about
30s peaks in The
come from the contamination
activity
1189
of
of Fig.l-c.
storage
O'C for
16s
colicin-
as is shown in Fig.4.
of
purified
ribosome
a few weeks resulted
23s and 16S, to the
and endonuclease
RNAs respecRNAs or not.
each RNAs from
in 1969 that
both
intact
smaller
in the profile
from E. coli
from the
their
50s particles
of one 16s peak,
of r-RNA,
were
one peak of 23s RNA was found
cells(a),
intermediates
W. Szer
cleavage
only
shown in Fig.4-c
degradative
particles
c).
extracted
they
235 RNA in the
cells(b,
to the
on the degradation
50s and 30s particles
whether
the control
besides
ribosome
intermediates"
information
were isolated,
As shown in Fig.3, from
the
became unstable
"degradative
particles,
and analyzed
ribosome
that
by sonication.
of ribosome
tively,
however,
cells
and the
to obtain
colicin-treated
Fig.1
be excluded
fragments
of RNase IV type
with
in a half
in split
BIOCHEMICAL
Vol. 54, No. 3, 1973
protein
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
was assumed to be involved
in this
limited
degradation
(9). It dation
seems possible in E. coli
follows.
to account
413 cells
Adsorption
influences change,
slight
of RNase IV type a nick
or nicks
at first
into
in the pieces
Structural when this
entities
limited
But ribosomes
loosened
and made sensitive
loss
of
particle
fragments. give
In 50s ribosome,
about
degradation
Then further
half
with
Investigation
breakdown
unmasked and makes 23s RNA is
of r-RNA results
Dr.
into
2. 3. 4. 5. 6. 7. 8. 9.
intermediate
structure. Takahisa
Ohta
Herschman, H. R., and Helinski, D. R. (1963) J. Biol. Chem. 242, 5360-5368. Nomura, M. (1967) Ann. Rev. Microbial. 21, 257-284. Beppu, T., and Arima, K. (1972) J. Bacterial. 110, 485-493. Yanai, A., Beppu, T., and Arima, K. (1970) Agr. Biol. Chem. 34, 149-151. Beppu, T., and Arima, K. (1971) J. Biochem.(Tokyo) 7J, 263-271. Nose, K., Mizuno, D., and Ozeki, H. (1966) Biochem. Biophys. Acta. 9, 636-638. Beppu, T., and Arima, K. (1967) J. Bacterial. 93, 80-85. Gesteland, R. F. (1966) J. Mol. Biol. 18, 356-371. Szer, W. (1969) Biochem. Biophys. Res. Commun. 35, 653-658.
1190
even
from in
small
REFERENCES 1.
split
has
RNase distinct
degradative
on the ribosome to thank
RNase activity
can be retained
and degradation the
structural
damaged r-RNA are
to cytoplasmic
about
Acknowledgement: We wish for his useful advices.
induce
RNA component
a limitedly
enzymatic
somehow
S-value.
of their
conformation
some information
gets
of the ribosomes
occurred.
RNase I.
protein(s)
degra-
E2 as
surface
in the particles.
r-RNA.
with
of colicin
one by one to
unfolding, split
mode of ribosome
E2 to cell
in the cells
in the
the
by the action
of colicin
ribosomes e.g.,
for
may