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On the regulatory mechanism of synthesis of early enzyme induced by bacteriophage T4
BIOCHEMICAL
Vol. 11, No. 3, 1963
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ONTHE REGULATORY MECBAtiISMOF SYi1THESISOF EARLYENZYMEINDUCEDBY BACTERIOPHAGE T4:/ Makiko Kozaka, Kenichi Matsubara and Yasuyuki Takagi Department of Biochemistry, Medical School, Kanazawa University, Kanazawa, Ishikawa (Japan)
Received
April
2, 1963
One of the interesting the regulation
of protein
problems for the biologist
is the mechanismof
synthesis (see review by Jacob and Monod, 1961).
The mode of synthesis of the so called early enzymes induced by T-even phage infection
and participating
in this respect.
in the production of viral
DNAdeserves attention
These enzymes are induced on introducing
some) into the host.
phage DNA (chromo-
Synthesis takes place only during the early stage of
phage growth, coming to halt at about 15 minutes (Flaks s &., Kornberg et al.,
1959).
Presumably there is a *regulatory
1959;
mechanism" which
brings about cessation of enzyme synthesis. The synthesis of enzyme induced by ultraviolet
light
(W) irradiated
phage does not cease at the normal time, but continues so that the final enzyme level
exceeds that produced in the normal phage replication
(Dirksen et al., information
1960; Delihas, 1961).
necessary to initiate
It
appears that the phage carries
susceptible to W-irradiation.
The present work was undertaken to determine if nism" is mediated by cytoplasmic materials.
11
the introduction
the
enzyme synthesis along with something that
regulates enzyme formation and is particularly
involved,
cycle
the "regulatory
mecha-
If cytoplasmic materials are
of both W-irradiated
and non-irradiated
phage
This investigation has been aided by grants from the Rockefeller Foundation and the Jane Coffin Childs Memorial Fund for Medical Research. 244
BIOCHEMICAL
Vol. 11, No. 3, 1963
must result
AND BIOPHYSICAL
in the dominance of the non-irradiated
increase of the enzyme should level
RESEARCH COMMUNICATIONS
chromosome; that is the
off at about 15 minutes after
infection.
The experiments were carried out by studying the formation of deoxycytidine triphosphatase (dCTPase) in Escherichia &
1(12(A).
MATKXIALS AJ!lDFXTHODS The wild type T4r+ phage and two deletion deletion
in A cistron,
LV-irradiation
r196: deletion
type mutants of T4 (h'88:
in I3 cistron;
was carried out by stirring
Benzer, 1955) were used.
the phage suspensions gently at a
distance of 00 cm from a 15 watt Mazda germicidal lamp. produce 5 lethal logarithmic
hits was used.
A dose sufficient
to
KlZ(h) organisms grown to the late
phase with aeration at 37°C in a glucose-salts
synthetic
medium
(Sekiguchi and Takagi, 1960) supplemented with lOOtig/ml of DL-tryptophan were infected
with phage at an input multiplicity
(zero time).
of 10 phage particles
Incubation was continued and aliquots
were taken out at intervals,
chilled
per cell
of the infected
to stop further
synthetic
culture
reactions and
centrifuged. The collected
cells were resuspended in 0.02 M Tris-acetate
buffer,
pH
7.5 and disrupted by sonication at O'C for 2 minutes (20 KC sonic oscillator, #easuring and Scientific
Equipment Ltd.).
12,000 xg for 10 minutes.
Almost all
The sonicate was centrifuged
the cell protein
at
appeared in the
supernatant which was used as the enzyme preparation. Deoqycytidine ically
triphosphate
labeled with P32 in D and y position
was chem-
synthesized according to the procedures described by Smith and Khorana
(1958).
The assay for dCTPaseconsisted of counting the charcoal-nonadsorb-
able P3' released after Kornberg, 1961).
incubation with enzyme for 20 minutes (Zimmermanand
Protein content was determined by a modified Folin reaction
(Lowry -et al. 1951). pyrophosphate liberated
Enzyme activity
was expressed as poles
of inorganic
from dCTP per minute per mg protein. RESULTSANDDISCUSSION
In the present paper %.mited synthesis " will of dCTPase that stops after
15 minutes of infection. 245
refer
to the synthesis
Synthesis of enzyme
BIOCHEMICAL
Vol. 11, No. 3, 1963
continuing
beyond 15 minutes
Mixed infection resulted
.
.02
-
/
:
synthesis"
of dCTPase.
I,/"VI+ , ,' #' :
.03
.02 -
02
30
.Ol
0
SO
30
60
0 L!!c 0
d. -
.03
.03
.02
D2
rl96
t
.Ol
60
30
1
1
UV-HI8
.Ol
r+
0
in Fig.
e.
.03 -
H88
.
tr0
with r+ alone
This is illustrated
C.
,.-+
r’ .Ol
synthesis".
lines.
a. .03
be termed "unlimited
with H88 and r196 as well as infection
in "limited
a and b solid
will
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
0
30
60
4- r196
30
I
60
f.
0 L!!I UV-H88
0
+ r+
30
60
Figurel. Kinetics of dC!lPase synthesis in E. & K12(A) infected with bacteriophage T4. The bacteria at 7 tc 8 x 108/ml in synthetic medium were infected with various types of T4 phage as indicated in the figures at multiplicity = 10 of infection was in the case of a, c and d. In b, e and f the multiplicity 5 for each type of phage to make a total of 10. Ordinate: dC'IPase activity in poles PPij2 released / min / mg protein. Absissa: Time in minutes after infection.
"Unlimited
synthesisn
or on mixed infection
was observed on infection
with W-irradiated
with W-irradiated
H88 and W-irradiated
r+
rlg6 simulta-
neously (Fig.
confirm
of Dirksen
1 a and b dotted .lines). These observations et al. (1960) who studied the mode of synthesis
of the same enzyme
in & g&
J3 infected
with T2 phage. 246
the data
BIOCHEMICAL
Vol. 11, No. 3, 1963
The dotted
lines
AND BIOPHYSICAL
of Fig. 1 c and d show that infection
irradiated
H88 or with W-irradiated
Therefore,
there is some difference
formation
in organisms infected
phage mutants
occurred in the mixed infection.
ities
in E. coli
1961) may be responsible
rl96,
after
simultaneous
non-irradiated *Unlimited
complementary synthesisn,
Very different
of bacteria
phages: r',
results
H88,
r+),
were obtained
with one W-irradiated
and another
rI1 mutant (W-H88 + r196, or ~88 + ~496).
when bacteria
were infected
conditions,
only in those complexes mixedly
infected
production
of the
1 e) in such experiments.
that under these experimental
"unlimited
1 f).
with a W-irradiated It
should be noted
synthesis"
takes place
with the two kinds of phages.
phage behaved as if it were "dominant"
ated phage with respect
tc occur
r196 (but not W-irradiated
wild type phage (Fig.
infection
synthesis"
with any one of the following
rI1 mutant and non-irradiated
the W-irradiated
capac-
(Garen, 1961; Nomura,
that is extended and exaggerated
was obtained
of the rI1 func-
loss of synthetic
of QrU.mited
enzyme beyond 15 minutes was observed (Fig. The same result
of the rI1 bacterio-
to restoration
The general
synthesis".
infection
synthesis".
with wild type phage or mixedly
leading
H88 and W-irradiated
always leads tc "limited
W-
rI1 mutants.
of the host cell
W-irradiated
with either
infected
for the failure
with W-irradiated
Infection
in %.mited
caused by the rI1 character
KU(h)
with either
between the mechanism which stops enzyme
Complement&ion,
tion,
on infection
r196 results
separately
and that in organisms
with H88 and rl96.
RESEARCH COMMUNICATIONS
tc the mechanism for control
Thus
over the non-irradi-
of the level
of
induced dCTPase.
Wiberg --et al.
(1962) demonstrated
with the s
the occurrence of phage DNA synthesis the synthesis
of the early enzymes.
is closely It
mutants of T4 phage that related
to the cessation
seems that the accumulation
DNA is not the direct
cause for the cessation
"unlimited
of dCTPase took place in organisms mixedly
synthesis*
with both W-irradiated
and non-irradiated
phage growth ( and therefore
DNA synthesis). 247
of dCTPase synthesis,
of
of phage since infected
phages, and such organisms support Repression
due to the accumula-
BIOCHEMICAL
Vol. 11, No. 3, 1963
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
tion of enzymatic reaction products (feed back inhibition) mulation of a Qytoplasmic
repressor* (Jacob and Monod, 1961) may also be
ruled out by the samedata, since the W-irradiated as if it were dominant over the non-irradiated present together. non-irradiated
If
protein
it
is likely
that the
Therefore someother hypothesis
an operator (Jacob and Monod, 1961) on the phage chromosome
or somefunctional phage growth will
phage chromosomebehaved
chromosomewhen both were
such mechanismswere operating,
chromosomebehaves dominantly.
perhaps involving
or due to the accu-
differentiation
of the phage DNAmolecule in the course of
have to be sought to account for the regulation
synthesis in phage infected
of early
bacteria,
REFERENCES Benzer, S., Proc. Natl. Acad. S&., 4l, 344 (1955). Delihas, N., Virolopv, g, 242 (1961). Dirksen, M. L., tiiberg, J. S., Koerner, J. F., and Buchanan, J. M., proC. Natl. Acad. S&., 46, 1425 (1960). Flaks, J. G., Lichtenstein, J., and Cohen, S. S., J. Biol. Chem., 2& 1507 (1959). Garen, A., Virolorsv,
l4, 151 (1961).
Jacob, F., and Monod, J., 2. -Mol. u., 4, 318 (1961). Kornberg, A., Zimmerman,S. D., Kornberg, S. R., and Josse, J., Proc. Natl. m. a., 2, 772 (1959). Lowry, 0. H., Rosebrough, N. J., Farr, A. L., and Randall, R. J., J. u. e., m, 265 (1951). Nomura, M., Virology, l.4, 164 (1961). Sekiguchi, M. and Takagi, Y., Biochim, Biouhys. Acta., ,,41 434 (1960). Smith, M., and Khorana, H. G., J. &. w. %., 80, 1141 (1958). Wiberg, J. S., Dirksen, M. L., Epstein, R. H., Luria, S. E., and Buchanan, J. M., Proc. Natl. Acad. S&., g. 293 (1962). Zimmerman,S. B., and Kornberg, A., 2. a, 1480 (1961).
248
Vol. 11, No. 3, 1963
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
ONTHE REGULATORY MECBAtiISMOF SYi1THESISOF EARLYENZYMEINDUCEDBY BACTERIOPHAGE T4:/ Makiko Kozaka, Kenichi Matsubara and Yasuyuki Takagi Department of Biochemistry, Medical School, Kanazawa University, Kanazawa, Ishikawa (Japan)
Received
April
2, 1963
One of the interesting the regulation
of protein
problems for the biologist
is the mechanismof
synthesis (see review by Jacob and Monod, 1961).
The mode of synthesis of the so called early enzymes induced by T-even phage infection
and participating
in this respect.
in the production of viral
DNAdeserves attention
These enzymes are induced on introducing
some) into the host.
phage DNA (chromo-
Synthesis takes place only during the early stage of
phage growth, coming to halt at about 15 minutes (Flaks s &., Kornberg et al.,
1959).
Presumably there is a *regulatory
1959;
mechanism" which
brings about cessation of enzyme synthesis. The synthesis of enzyme induced by ultraviolet
light
(W) irradiated
phage does not cease at the normal time, but continues so that the final enzyme level
exceeds that produced in the normal phage replication
(Dirksen et al., information
1960; Delihas, 1961).
necessary to initiate
It
appears that the phage carries
susceptible to W-irradiation.
The present work was undertaken to determine if nism" is mediated by cytoplasmic materials.
11
the introduction
the
enzyme synthesis along with something that
regulates enzyme formation and is particularly
involved,
cycle
the "regulatory
mecha-
If cytoplasmic materials are
of both W-irradiated
and non-irradiated
phage
This investigation has been aided by grants from the Rockefeller Foundation and the Jane Coffin Childs Memorial Fund for Medical Research. 244
BIOCHEMICAL
Vol. 11, No. 3, 1963
must result
AND BIOPHYSICAL
in the dominance of the non-irradiated
increase of the enzyme should level
RESEARCH COMMUNICATIONS
chromosome; that is the
off at about 15 minutes after
infection.
The experiments were carried out by studying the formation of deoxycytidine triphosphatase (dCTPase) in Escherichia &
1(12(A).
MATKXIALS AJ!lDFXTHODS The wild type T4r+ phage and two deletion deletion
in A cistron,
LV-irradiation
r196: deletion
type mutants of T4 (h'88:
in I3 cistron;
was carried out by stirring
Benzer, 1955) were used.
the phage suspensions gently at a
distance of 00 cm from a 15 watt Mazda germicidal lamp. produce 5 lethal logarithmic
hits was used.
A dose sufficient
to
KlZ(h) organisms grown to the late
phase with aeration at 37°C in a glucose-salts
synthetic
medium
(Sekiguchi and Takagi, 1960) supplemented with lOOtig/ml of DL-tryptophan were infected
with phage at an input multiplicity
(zero time).
of 10 phage particles
Incubation was continued and aliquots
were taken out at intervals,
chilled
per cell
of the infected
to stop further
synthetic
culture
reactions and
centrifuged. The collected
cells were resuspended in 0.02 M Tris-acetate
buffer,
pH
7.5 and disrupted by sonication at O'C for 2 minutes (20 KC sonic oscillator, #easuring and Scientific
Equipment Ltd.).
12,000 xg for 10 minutes.
Almost all
The sonicate was centrifuged
the cell protein
at
appeared in the
supernatant which was used as the enzyme preparation. Deoqycytidine ically
triphosphate
labeled with P32 in D and y position
was chem-
synthesized according to the procedures described by Smith and Khorana
(1958).
The assay for dCTPaseconsisted of counting the charcoal-nonadsorb-
able P3' released after Kornberg, 1961).
incubation with enzyme for 20 minutes (Zimmermanand
Protein content was determined by a modified Folin reaction
(Lowry -et al. 1951). pyrophosphate liberated
Enzyme activity
was expressed as poles
of inorganic
from dCTP per minute per mg protein. RESULTSANDDISCUSSION
In the present paper %.mited synthesis " will of dCTPase that stops after
15 minutes of infection. 245
refer
to the synthesis
Synthesis of enzyme
BIOCHEMICAL
Vol. 11, No. 3, 1963
continuing
beyond 15 minutes
Mixed infection resulted
.
.02
-
/
:
synthesis"
of dCTPase.
I,/"VI+ , ,' #' :
.03
.02 -
02
30
.Ol
0
SO
30
60
0 L!!c 0
d. -
.03
.03
.02
D2
rl96
t
.Ol
60
30
1
1
UV-HI8
.Ol
r+
0
in Fig.
e.
.03 -
H88
.
tr0
with r+ alone
This is illustrated
C.
,.-+
r’ .Ol
synthesis".
lines.
a. .03
be termed "unlimited
with H88 and r196 as well as infection
in "limited
a and b solid
will
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
0
30
60
4- r196
30
I
60
f.
0 L!!I UV-H88
0
+ r+
30
60
Figurel. Kinetics of dC!lPase synthesis in E. & K12(A) infected with bacteriophage T4. The bacteria at 7 tc 8 x 108/ml in synthetic medium were infected with various types of T4 phage as indicated in the figures at multiplicity = 10 of infection was in the case of a, c and d. In b, e and f the multiplicity 5 for each type of phage to make a total of 10. Ordinate: dC'IPase activity in poles PPij2 released / min / mg protein. Absissa: Time in minutes after infection.
"Unlimited
synthesisn
or on mixed infection
was observed on infection
with W-irradiated
with W-irradiated
H88 and W-irradiated
r+
rlg6 simulta-
neously (Fig.
confirm
of Dirksen
1 a and b dotted .lines). These observations et al. (1960) who studied the mode of synthesis
of the same enzyme
in & g&
J3 infected
with T2 phage. 246
the data
BIOCHEMICAL
Vol. 11, No. 3, 1963
The dotted
lines
AND BIOPHYSICAL
of Fig. 1 c and d show that infection
irradiated
H88 or with W-irradiated
Therefore,
there is some difference
formation
in organisms infected
phage mutants
occurred in the mixed infection.
ities
in E. coli
1961) may be responsible
rl96,
after
simultaneous
non-irradiated *Unlimited
complementary synthesisn,
Very different
of bacteria
phages: r',
results
H88,
r+),
were obtained
with one W-irradiated
and another
rI1 mutant (W-H88 + r196, or ~88 + ~496).
when bacteria
were infected
conditions,
only in those complexes mixedly
infected
production
of the
1 e) in such experiments.
that under these experimental
"unlimited
1 f).
with a W-irradiated It
should be noted
synthesis"
takes place
with the two kinds of phages.
phage behaved as if it were "dominant"
ated phage with respect
tc occur
r196 (but not W-irradiated
wild type phage (Fig.
infection
synthesis"
with any one of the following
rI1 mutant and non-irradiated
the W-irradiated
capac-
(Garen, 1961; Nomura,
that is extended and exaggerated
was obtained
of the rI1 func-
loss of synthetic
of QrU.mited
enzyme beyond 15 minutes was observed (Fig. The same result
of the rI1 bacterio-
to restoration
The general
synthesis".
infection
synthesis".
with wild type phage or mixedly
leading
H88 and W-irradiated
always leads tc "limited
W-
rI1 mutants.
of the host cell
W-irradiated
with either
infected
for the failure
with W-irradiated
Infection
in %.mited
caused by the rI1 character
KU(h)
with either
between the mechanism which stops enzyme
Complement&ion,
tion,
on infection
r196 results
separately
and that in organisms
with H88 and rl96.
RESEARCH COMMUNICATIONS
tc the mechanism for control
Thus
over the non-irradi-
of the level
of
induced dCTPase.
Wiberg --et al.
(1962) demonstrated
with the s
the occurrence of phage DNA synthesis the synthesis
of the early enzymes.
is closely It
mutants of T4 phage that related
to the cessation
seems that the accumulation
DNA is not the direct
cause for the cessation
"unlimited
of dCTPase took place in organisms mixedly
synthesis*
with both W-irradiated
and non-irradiated
phage growth ( and therefore
DNA synthesis). 247
of dCTPase synthesis,
of
of phage since infected
phages, and such organisms support Repression
due to the accumula-
BIOCHEMICAL
Vol. 11, No. 3, 1963
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
tion of enzymatic reaction products (feed back inhibition) mulation of a Qytoplasmic
repressor* (Jacob and Monod, 1961) may also be
ruled out by the samedata, since the W-irradiated as if it were dominant over the non-irradiated present together. non-irradiated
If
protein
it
is likely
that the
Therefore someother hypothesis
an operator (Jacob and Monod, 1961) on the phage chromosome
or somefunctional phage growth will
phage chromosomebehaved
chromosomewhen both were
such mechanismswere operating,
chromosomebehaves dominantly.
perhaps involving
or due to the accu-
differentiation
of the phage DNAmolecule in the course of
have to be sought to account for the regulation
synthesis in phage infected
of early
bacteria,
REFERENCES Benzer, S., Proc. Natl. Acad. S&., 4l, 344 (1955). Delihas, N., Virolopv, g, 242 (1961). Dirksen, M. L., tiiberg, J. S., Koerner, J. F., and Buchanan, J. M., proC. Natl. Acad. S&., 46, 1425 (1960). Flaks, J. G., Lichtenstein, J., and Cohen, S. S., J. Biol. Chem., 2& 1507 (1959). Garen, A., Virolorsv,
l4, 151 (1961).
Jacob, F., and Monod, J., 2. -Mol. u., 4, 318 (1961). Kornberg, A., Zimmerman,S. D., Kornberg, S. R., and Josse, J., Proc. Natl. m. a., 2, 772 (1959). Lowry, 0. H., Rosebrough, N. J., Farr, A. L., and Randall, R. J., J. u. e., m, 265 (1951). Nomura, M., Virology, l.4, 164 (1961). Sekiguchi, M. and Takagi, Y., Biochim, Biouhys. Acta., ,,41 434 (1960). Smith, M., and Khorana, H. G., J. &. w. %., 80, 1141 (1958). Wiberg, J. S., Dirksen, M. L., Epstein, R. H., Luria, S. E., and Buchanan, J. M., Proc. Natl. Acad. S&., g. 293 (1962). Zimmerman,S. B., and Kornberg, A., 2. a, 1480 (1961).
248